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Agenda 11/03/2015 W (Water Management)
AGENDA BCC WORKSHOP MEETING November 3 , 2015 COLLIER COUNTY Board of County Commissioners ot ( 1/_ • r WORKSHOP AGENDA Board of County Commission Chambers Collier County Government Center 3299 Tamiami Trail East,3rd Floor Naples FL 34112 November 3,2015 1:00 P.M. Commissioner Tim Nance,District 5-BCC Chair Commissioner Donna Fiala,District 1-BCC Vice-Chair; CRAB Chair Commissioner Georgia Hiller,District 2 -Community&Economic Development Chair Commissioner Tom Henning District 3-Public Safety Coordinating Council Chair Commissioner Penny Taylor,District 4-TDC Chair; CRAB Vice-Chair 1. Pledge of Allegiance 2. Sustainable Integrated Water Resource Management Strategy Presentation (Dr. George Yilmaz, PUD, and David Wilkison, GMD) 3. Public Comments 4. Adjourn Notice: All persons wishing to speak must turn in a speaker slip. Each speaker will receive no more than three(3)minutes. Collier County Ordinance No. 2003-53 as amended by Ordinance 2004-05 and 2007-24, requires that all lobbyists shall, before engaging in any lobbying activities (including but not limited to, addressing the Board of County Commissioners), register with the Clerk to the Board at the Board Minutes and Records Department. Co per County Sustainable Integrated Water Resource Management Strategy Workshop November 3, 2015 Index 1. Sustainable Integrated Water Resource Management Strategy Presentation 2. Executive Summary for the Collier County 10-Year Water Supply Facilities Work Plan Update (February 2014) 3. Irrigation Quality Water Business Plan/Financial Model Co *er County Sustainable Integrated Water Resource Management Strategy Workshop November 3, 2015 1. Sustainable Integrated Water Resource Management Strategy Presentation ( \ V O �' Cr (*' 0 I L. 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Executive Summary for the Collier County 10-Year Water Supply Facilities Work Plan Update (February 2014) EXECUTIVE SUMMARY Recommendation to adopt an Ordinance proposing amendment to the Collier County Growth Management Plan, Ordinance 89-05, as amended, specifically amending the Potable Water sub-element of the Public Facilities Element to amend Policy 1.7 to reference the updated Ten Year Water Supply Facilities Work Plan, and furthermore recommending transmittal of the adoption amendment to the Florida Department of Economic Opportunity (CPSP-2013-7). OBJECTIVE: To have the Board of County Commissioners (BCC) consider a request to amend the County's Growth Management Plan (GMP) to add reference to the updated Ten-Year Water Supply Facilities Work Plan, as required of Collier County by Section 163.3177(6)(c)3, Florida Statutes, as well as to consider recommending transmittal of the adoption amendment to the Florida Department of Economic Opportunity(DEO). CONSIDERATIONS: The Florida Water Resources Act (Chapter 373, F.S.) requires the five water management districts to provide regional water supply planning in all areas of the State where reasonable anticipated sources of water are deemed inadequate to meet future projected demands. Each regional 10 year water supply plan is based on a 20-year future planning horizon, and a complete update of each plan is required every 5 years. The purpose of regional water supply planning is to develop strategies to meet future water demands of urban and agricultural uses, while meeting the needs of the environment. This process identifies historical uses of water and water source options to meet potential shortfall. Florida Statutes requires local governments to prepare a Ten-Year Water Supply Facilities Work Plan and adopt revisions to comprehensive plans within 18 months following the approval of the most current version of the applicable regional water supply plan. Collier County is within the water supply planning area under the purview of the South Florida Water Management District (SFWMD). The revised 2012 Lower West Coast Water Supply Plan Update was approved by the SFWMD Governing Board on November 15, 2012. This plan assesses projected water demands and potential sources of water for the period from 2010 to 2030. Therefore, Collier County must adopt the updated plan by May 15, 2014. Florida Statues requires review of proposed County GMP amendments by certain State agencies and departments after recommendation of"transmittal" by the BCC. The DEO then forwards the outcome of their review through a report to the County. The County then responds to the ORC report as described below and transmits its recommendation for adoption. BCC ACTION: At their December 10, 2013 meeting, the BCC unanimously approved Resolution No. 13-288, and the transmittal of this petition to DEO. DEO'S OBJECTION, RECOMMENDATIONS AND COMMENTS (ORC) REPORT: The County may respond to the ORC Report in one of four ways at Adoption: 1. not modify the amendment, but provide additional explanation of what the amendment is about, its purpose, what it will achieve [appropriate if we believe DEO simply does not understand/has misunderstood the amendment] and/or provide additional data and analysis to support the amendment; or 2. mod fy the amendment, so as to address the ORC issue; or, 3. mod fy the amendment, and provide additional explanation and/or provide additional data and analysis; or, 4. not adopt the amendment. If an Objection set forth in the ORC Report is not adequately addressed when adopted, then the DEO may find the amendment to be "Not in Compliance" with Florida Statutes, and issue a Notice of Intent (NOl) to indicate such noncompliance. The ORC Report is included as part of this amendment packet, and identifies no objections, recommendations or comments related to important state resources and facilities within the DEO's authorized scope of review that will be adversely impacted by the amendment if adopted. County staff also received correspondence from the SFWMD, the Florida Department of Environmental Protection, and the Florida Department of Agriculture and Consumer Services, all of whom offered no objections, recommendations or comments in regard to their review of the proposed amendment petition. ADOPTION CHANGES: No changes are proposed because of the ORC report. However, in response to the Collier County Planning Commission's (CCPC) requests during transmittal hearings, Section 7, the Conservation Regulations and Practices section of the proposed Collier County 10-Year Water Supply Facilities Work Plan, has been revised to include: • Proposal in regard to efforts to assemble a Low Impact Development (LID) manual, and recommendation to the BCC to consider provisions for Florida Friendly and water conservation principles. (Pages 7-1 and 7-2). • Proposal to the BCC to adopt changes to the current Irrigation Ordinance to extend its range of irrigation activities, regardless of source, so as to establish allowable hours of irrigation, days of the week, rain or soil sensor requirements, total volume and other provisions, similar to those that currently govern the use of potable water. (Page 7-2). • Suggestion for revisions of the Utility Standards manual that clarify the need for looping of water systems within and among developments; specifically, dead-ends or cul-de-sacs will be subject to a maximum unit count unless looped to another part of the system. In this way, flushing and automatic flushing will be reduced to save potable water. (Page 7- 3). • Proposal to continue pursuing water-saving opportunities in site-specific contexts; for example, in 2013, the BCC authorized the capture of flushed water by the Key Marco Community Development District for later irrigation use, thus promoting the re-use of millions of gallons of water per year. (Page 7-3). Additionally, Figure 2-2, the Water and Sewer District Map boundary has been revised to clarify the extent of boundary east of Collier Boulevard (CR 951) and north of I-75. (Page 2-2). COLLIER COUNTY PLANNING COMMISSION (CCPC)/ENVIRONMENTAL ADVISORY COUNCIL (EAC) RECOMMENDATION: The CCPC, sitting also as the EAC under Ordinances 2013-50 and 2013-51, and in its capacity as the local planning agency under Ch. 163.3174, F.S., heard this petition, at their March 6, 2014 meeting, and voted 7-0 to forward the subject petition to the BCC with a recommendation to adopt and transmit to the DEO. FISCAL IMPACT: There is no Fiscal Impact associated with this Executive Summary. LEGAL CONSIDERATIONS: This item is ready for BCC review and consideration. It is approved as to form and legality. An affirmative vote of four is necessary for Board approval at the adoption hearing. - HFAC GROWTH MANAGEMENT IMPACT: Adoption of the ten year water supply plan update and subsequent amendment to the Potable Water sub-element of the Growth Management Plan will satisfy the requirements of 163.3177(6)(C)3.F.S. RECOMMENDATION: That the BCC adopt and transmit petition CPSP-2013-7 to the Florida Department of Economic Opportunity. Prepared By: Carolina Valera, Principal Planner, Planning& Zoning Department Attachments: 1. Ordinance 2. Exhibit A 3. Staff Report 4. ORC Report 5. 10-Year Water Supply Facilities Work Plan — due to the size of the plan, it is accessible at: http://www.colliergov.net/ftp/AgendaApri12214/GrowthMgmt/10- YearWaterSupplyWorkPlan.pdf Co ier County Sustainable Integrated Water Resource Management Strategy Workshop November 3, 2015 3. Irrigation Quality Water Business Plan/Financial Model sti,N. (i) w (in a) ,., ., .. „. , c ,,,.. .... • _ (/) .., ,.. , = A\ -, • ,- co a) Ti). 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C ar :; �; a) y g ° 0 o A' Q 3 a`i 6�i C �" a Q E . i c C Q on O 3 3 ro 3 h ¢ o Q a° a a w ¢ 6 FINAL WORK PLAN Collier County 10-Year Water Supply Facilities Work Plan Update February 2014 CDM. Smith Table of Contents Executive Summary Section 1 Introduction 1-1 1.1 Plan Background 1-1 1.2 Plan Objectives 1-1 1.3 Information Sources 1-2 1.4 Plan Contents 1-3 Section 2 Water Service Areas 2-1 2.1 Overview of Collier County 2-1 2.2 Individual Utilities and Systems 2-1 2.2.1 Collier County 2-1 2.2.1.1 Collier County Water-Sewer District(CCWSD) 2-1 2.2.1.2 Goodland Water Sub-District 2-3 2.2.2 City of Naples 2-3 2.2.3 Everglades City 2-5 2.2.4 City of Marco Island Water and Sewer Service Areas 2-5 2.2.5 Immokalee Water and Sewer District(IWSD) 2-5 2.2.6 Florida Governmental Utility Authority(Golden Gate City) (FGUA) 2-6 2.2.7 Orange Tree Utility Company(OTUC) 2-6 2.2.8 Ave Maria Utility Company,LLLP(AMUC) 2-6 2.2.9 Independent Districts 2-6 2.2.9.1 Lee Cypress Water and Sewer Co-op,Inc 2-6 2.2.9.2 Port of the Islands Community Improvement District 2-6 2.2.10 Water Systems Regulated by FL Department of Environmental Protection 2-7 Section 3 Population and Demand Projections 3-1 3.1 Countywide Projections 3-1 3.2 Individual Utilities 3-1 3.2.1 Collier County Water-Sewer District(CCWSD) 3-1 3.2.2 Immokalee Water and Sewer District(IWSD) 3-2 3.2.3 Florida Governmental Utility Authority(Golden Gate City) (FGUA) 3-2 3.2.4 Orange Tree Utility Company(OTUC) 3-3 3.2.5 Ave Maria Utility Company,LLLP (AMUC) 3-4 Section 4 Existing Water Supply Facilities 4-1 4.1 Collier County Water-Sewer District(CCWSD) 4-1 4.1.1 Water Supply Permits 4-1 4.1.2 Potable Water Facilities 4-1 4.1.2.1 Wellfields 4-1 4.1.2.2 Water Treatment Facilities 4-2 4.1.2.3 Pumping,Storage,and Transmission 4-8 4.1.3 Reclaimed Water Facilities 4-9 csmith PW/6295/98609/03/11 • Table of Contents 4.1.3.1 Water Reclamation Facilities 4-9 4.1.3.2 Reclaimed Water Pumping,Storage,and Transmission 4-12 4.1.3.3 Supplemental Wellfields 4-12 4.2 Immokalee Water and Sewer District(IWSD) 4-15 4.2.1 Water Supply Permits 4-15 4.2.2 Potable Water Facilities 4-15 4.2.2.1 Wellfields 4-15 4.2.2.2 Water Treatment Facilities 4-15 4.2.2.3 Pumping,Storage,and Transmission 4-18 4.2.3 Reclaimed Water Facilities 4-18 4.3 FL Governmental Utility Authority(Golden Gate City) (FGUA) 4-18 4.3.1 Water Supply Permits 4-18 4.3.2 Potable Water Facilities 4-19 4.3.2.1 Wellfields 4-19 4.3.2.2 Water Treatment Facilities 4-19 4.3.2.3 Pumping,Storage,and Transmission 4-21 4.3.3 Reclaimed Water Facilities 4-21 4.4 Orange Tree Utility Company(OTUC) 4-21 4.4.1 Water Supply Permits 4-21 4.4.2 Potable Water Facilities 4-21 4.4.2.1 Wellfields 4-21 4.4.2.2 Water Treatment Facilities 4-23 4.4.2.3 Pumping,Storage,and Transmission 4-23 4.4.3 Reclaimed Water Facilities 4-23 4.5 Ave Maria Utility Company,LLLP (AMUC) 4-25 4.5.1 Water Supply Permits 4-25 4.5.2 Potable Water Facilities 4-25 4.5.2.1 Wellfields 4-25 4.5.2.2 Water Treatment Facilities 4-25 4.5.2.3 Pumping,Storage,and Transmission 4-25 4.5.3 Reclaimed Water Facilities 4-26 Section 5 Planned Water Supply Facilities 5-1 5.1 Collier County Water-Sewer District(CCWSD) 5-1 5.1.1 Potable Water Facilities 5-3 5.1.1.1 Wellfields 5-3 5.1.1.2 Water Treatment Facilities 5-5 5.1.1.3 Pumping,Storage,and Transmission 5-7 5.1.2 Reclaimed Water Facilities 5-9 5.1.2.1 Water Reclamation Facilities 5-9 5.1.2.2 Reclaimed Water Pumping,Storage,and Transmission 5-12 5.2 Immokalee Water and Sewer District(IWSD) 5-13 5.2.1 Potable Water Facilities 5-13 5.2.1.1 Wellfields 5-13 5.2.1.2 Water Treatment Facilities 5-15 5.2.2 Reclaimed Water Facilities 5-15 csmith ll PW/6295/98609/03/11 • Table of Contents 5.3 FL Governmental Utility Authority(Golden Gate City) (FGUA) 5-15 5.3.1 Potable Water Facilities 5-15 5.3.1.1 Wellfields 5-15 5.3.1.2 Water Treatment Facilities 5-17 5.3.1.3 Pumping,Storage,and Transmission 5-17 5.3.2 Reclaimed Water Facilities 5-19 5.4 Orange Tree Utility Company(OTUC) 5-19 5.4.1 Potable Water Facilities 5-19 5.4.1.1 Wellfields 5-19 5.4.1.2 Water Treatment Facilities 5-19 5.4.2 Reclaimed Water Facilities 5-19 5.5 Ave Maria Utility Company,LLLP(AMUC) 5-19 5.5.1 Potable Water Facilities 5-19 5.5.1.1 Wellfields 5-19 5.5.1.2 Water Treatment Facilities 5-19 5.5.2 Reclaimed Water Facilities 5-20 Section 6 Facilities Capacity Analysis 6-1 6.1 Collier County Water-Sewer District(CCWSD) 6-1 6.1.1 Concurrency Analysis 6-1 6.2 Immokalee Water and Sewer District(IWSD) 6-2 6.3 Florida Governmental Utility Authority(Golden Gate City) (FGUA) 6-3 6.4 Orange Tree Utility Company(OTUC) 6-3 6.5 Ave Maria Utility Company,LLLP(AMUC) 6-4 Section 7 Conservation Regulations and Practices 7-1 7.1 Collier County Water-Sewer District(CCWSD) 7-1 7.2 Immokalee Water and Sewer District(IWSD) 7-4 7.3 Florida Governmental Utility Authority(Golden Gate City) (FGUA) 7-5 7.4 Orange Tree Utility Company(OTUC) 7-6 7.5 Ave Maria Utility Company,LLLP (AMUC) 7-7 Section 8 Capital Improvement Projects 8-1 8.1 Collier County Water-Sewer District(CCWSD) 8-1 8.2 Immokalee Water and Sewer District(IWSD) 8-1 8.3 Florida Governmental Utility Authority(Golden Gate City) (FGUA) 8-1 8.4 Orange Tree Utility Company(OTUC) 8-1 8.5 Ave Maria Utility Company(AMUC) 8-1 Appendices Appendix A-Interlocal Agreement between CCWSD and the City of Naples Appendix B-Ordinance Integrating Goodland Water District into CCWSD Appendix C-Agreement for Potable Water Service Calusa Island Village(Goodland Area) cSmith PW/6295/98609/03/11 • Table of Contents Tables Table ES-1 Summary of Existing and Planned CCWSD Water Treatment and Water Reclamation Facilities ES-2 Table ES-2 Capacity Analysis for CCWSD ES-3 Table ES-3 Summary of Existing and Planned IWSD Water Treatment Facilities ES-4 Table ES-4 Capacity Analysis for IWSD ES-4 Table ES-5 Summary of Existing and Planned FGUA Water Treatment Facilities ES-5 Table ES-6 Capacity Analysis for FGUA ES-5 Table ES-7 Summary of Existing and Planned OTUC Water Treatment Facilities ES-6 Table ES-8 Capacity Analysis for OTUC ES-6 Table ES-9 Summary of Existing and Planned AMUC Water Treatment and Water Reclamation Facilities ES-7 Table ES-10Capacity Analysis for AMUC ES-7 Table 2-1 Summary of Small Capacity Private Sector Water Systems Operating within Collier County 2-7 Table 3-1 Collier County Peak Season Population Estimates and Projections 3-1 Table 3-2 Population Projections for CCWSD Service Area 3-1 Table 3-3 Projected Population and Demand for Areas Served by CCWSD 3-2 Table 3-4 Population Projections for Areas Served by IWSD 3-2 Table 3-5 Project Population and Demand for Areas Served by IWSD 3-2 Table 3-6 Population Projections for Areas Served by FGUA 3-3 Table 3-7 Project Population and Demand for Areas Served by FGUA 3-3 Table 3-8 Population Projections for Areas Served by OTUC 3-3 Table 3-9 Project Population and Demand for Areas Served by OTUC 3-4 Table 3-10 Population Projections for Areas Served by AMUC 3-4 Table 3-11 Project Population and Demand for Areas Served by AMUC 3-4 Table 4-1 Consumptive Use Permits Issued by SFWMD to CCWSD 4-1 Table 4-2 Existing CCWSD Golden Gate Tamiami Wellfield 4-5 Table 4-3 Existing North Hawthorn RO Wellfield Summary 4-6 Table 4-4 Existing South Hawthorn RO Wellfield Summary 4-7 Table 4-5 Summary of Existing CCWSD Water Treatment Facilities 4-8 Table 4-6 Summary of Existing CCWSD Water Storage Facilities 4-9 Table 4-7 Summary of Existing Water Reclamation Facilities 4-9 Table 4-8 Summary of Existing CCWSD Supplemental Wells 4-15 Table 4-9 Consumptive Use Permits Issued by SFWMD to the Immokalee Water and Sewer District 4-15 Table 4-10 Summary of Existing IWSD Potable Water Wells 4-16 Table 4-11 Summary of Existing IWSD Water Treatment Facilities 4-16 Table 4-12 Summary of Existing IWSD Storage Facilities 4-18 Table 4-13 Summary of Existing IWSD Water Reclamation Facilities 4-18 Table 4-14 Consumptive Use Permits Issued by SFWMD to FGUA 4-18 Table 4-15 Summary of Wells Operated by FGUA 4-19 Table 4-16 Summary of Existing FGUC Water Treatment Facilities 4-19 Table 4-17 Summary of Existing FGUA Storage Facilities 4-21 Csmlth iv PW/6295/98609/03/11 • Table of Contents Table 4-18 Consumptive Use Permits Issued by SFWMD to OTUC 4-21 Table 4-19 Summary of Wells Operated by OTUC 4-23 Table 4-20 Summary of Existing OTUC Water Treatment Facilities 4-23 Table 4-21 Summary of Existing OTUC Storage Facility 4-23 Table 4-22 Consumptive Use Permits Issued by SFWMD to AMUC 4-25 Table 4-23 Summary of Wells Operated by AMUC 4-25 Table 4-24 Summary of Existing AMUC Water Treatment Facility 4-25 Table 4-25 Summary of Existing AMUC Storage Facility 4-26 Table 4-26 Summary of Existing AMUC Water Reclamation Facility 4-26 Table 5-1 Planned NERWTP Wellfield Phase 1 Summary 5-3 Table 5-2 Major Tasks Required to Build Planned CCWSD NERWTP Phase 1 Wellfield 5-3 Table 5-3 Summary of Existing and Planned CCWSD Water Treatment Facilities 5-5 Table 5-4 Major Tasks Required to Build Planned CCWSD NERWTP Phase 1 5-7 Table 5-5 Summary of Existing and Planned CCWSD Water Storage Facilities 5-7 Table 5-6 Major Tasks Required to Build Planned CCWSD Water Storage Facilities 5-9 Table 5-7 Summary of Existing and Planned CCWSD Water Reclamation Facilities 5-12 Table 5-8 Summary of Existing and Planned Reclaimed Water Storage Facilities 5-12 Table 5-9 Major Tasks Required to Build Planned CCWSD Reclaimed Water Storage Facilities 5-13 Table 5-10 Summary of Planned IWSD Wells 5-13 Table 5-11 Major Tasks Required to Build Planned IWSD Wells 5-15 Table 5-12 Summary of Existing and Planned IWSD Water Treatment Facilities 5-15 Table 5-13 Summary of Planned FGUA Wells 5-17 Table 5-14 Major Tasks Required to Build Planned FGUA Potable Water Wells 5-17 Table 5-15 Summary of Existing and Planned FGUA Potable Water Treatment Facilities 5-17 Table 5-16 Summary of Existing and Planned AMUC Potable Water Treatment Facilities 5-20 Table 5-17 Major Tasks Required to Build Planned AMUC Potable Water Treatment Facilities 5-20 Table 5-18 Summary of Existing and Planned AMUC Water Reclamation Facilities 5-20 Table 6-1 Capacity Analysis for CCWSD 6-1 Table 6-2 Capacity Analysis for IWSD 6-2 Table 6-3 Capacity Analysis for FGUA 6-3 Table 6-4 Capacity Analysis for OTUC 6-3 Table 6-5 Capacity Analysis for AMUC 6-4 Table 8-1 CCWSD Capital Improvement Projects 8-2 cSDmith PW/6295/98609/03/11 • Table of Contents Figures Figure 2-1 Water District Boundaries of Collier County 2-2 Figure 2-2 CCWSD Potable/Reclaimed Water Composite Map 2-4 Figure 4-1 Existing CCWSD Wellfields and Raw Water Transmission Mains 4-3 Figure 4-2 Existing CCWSD Potable Water Treatment Facilities 4-4 Figure 4-3 Existing CCWSD Potable Water Storage Facilities 4-10 Figure 4-4 Existing CCWSD Potable Water Transmission Mains 4-11 Figure 4-5 Existing CCWSD Water Reclamation Facilities 4-13 Figure 4-6 Existing CCWSD Reclaimed Water Distribution System 4-14 Figure 4-7 Existing IWSD Water Supply Facilities 4-17 Figure 4-8 Existing FGUA Wellfield and Water Treatment Facility 4-20 Figure 4-9 Existing FGUA Potable Water Transmission Mains 4-22 Figure 4-10 Existing OTUC Water Supply Facilities 4-24 Figure 5-1 Existing and Planned CCWSD Wellfields and Raw Water Transmission Mains..5-4 Figure 5-2 Existing and Planned CCWSD Potable Water Treatment Facilities 5-6 Figure 5-3 Existing and Planned CCWSD Potable Water Storage Facilities 5-8 Figure 5-4 Existing and Planned CCWSD Potable Water Transmission Mains 5-10 Figure 5-5 Existing and Planned CCWSD Water Reclamation Facilities 5-11 Figure 5-6 Existing and Planned IWSD Potable Water Facilities 5-14 Figure 5-7 Existing and Planned FGUA Wellfield and Potable Water Treatment Facility5-16 Figure 5-8 Existing and Planned FGUA Transmission Pipelines 5-18 Figure 7-1 CCWSD Unaccounted-for Water Loss from FY2002 to FY 2012 7-3 Csmith vi PW/6295/98609/03/11 • Table of Contents List of Acronyms AADD Annual Average Daily Demand AADF Annual Average Daily Flow ADD Average Daily Demand AMUC Ave Maria Utility Company(AMUC) ASR Aquifer Storage and Recovery AUIR Annual Update and Inventory Report AWS Alternative Water Supply BCC Board of County Commissioners BEBR Bureau of Economic and Business Research CCCPD Collier County Comprehensive Planning Department CCWSD Collier County Water-Sewer District CDES Community Development and Environmental Services CUP Consumption Use Permits DIW Deep Injection Well EAR Evaluation and Appraisal Report ERC Equivalent Residential Connection FAC Florida Administrative Code FDEP Florida Department of Environmental Protection FGUA Florida Government Utility Authority FY Fiscal Year GMP Growth Management Plan gpcd Gallons per Capita per Day gpd Gallons per Day WTP Water Treatment Plant HPRO High Pressure Reverse Osmosis HZ1 Hawthorne Zone 1 Aquifer IE Ion Exchange IWSD Immokalee Water and Sewer District LDC Land Development Code LH Lower Hawthorne Aquifer LOSS Level of Service Standard LPRO Low Pressure Reverse Osmosis LS Lime Softening LT Lower Tamiami Aquifer LWCWSP Lower West Coast Water Supply Plan CSinith V" PW/6295/98609/03/11 • Table of Contents MF Membrane Filtration MG Million Gallons MGD Million Gallons Per Day MS Membrane Softening MMDD Maximum Month Daily Demand NCRWTP North County Regional Water Treatment Plant NCWRF North County Water Reclamation Facility NERWTP Northeast Regional Water Treatment Plant NEWRF Northeast Water Reclamation Facility OTUC Orange Tree Utility Company PBWRF Pelican Bay Water Reclamation Facility PUD Public Utilities Division PSC Public Service Commission RIB Rapid Infiltration Basin RO Reverse Osmosis RWA Rural Water Association SCRWTP South County Regional Water Treatment Plant SCWRF South County Water Reclamation Facility SERWTP Southeast Regional Water Treatment Plant SEWRF Southeast Water Reclamation Facility SFWMD South Florida Water Management District ULDC Unified Land Development Code WRF Water Reclamation Facility WT Water-Table Aquifer WTP Water Treatment Plant cSmith VIII PW/6295/98609/03/11 Executive Summary In November 2012,the Governing Board of the South Florida Water Management District(SFWMD) approved the 2012 Lower West Coast Water Supply Plan(LWCWSP) Update. Under Florida law (section 163.3177(6)(c),Florida Statutes) Collier County must adopt amendments to its comprehensive plan within 18 months of the SFWMD approval of the update. These amendments include the development of a 10-Year Water Supply Facilities Work Plan and amendments to the Growth Management Plan(GMP). Under the requirement of the Florida Statutes,the 10-Year Water Supply Facilities Work Plan for Collier County must include analysis of all water utilities in the County not serving a specific local government.These utilities include: • Collier County Water-Sewer District(CCWSD) • Immokalee Water and Sewer District(IWSD) • Florida Governmental Utility Authority(Golden Gate) (FGUA) • Orange Tree Utility Company(OTUC) • Ave Maria Utility Company,LLLP(AMUC) Utilities not included in this Plan are the City of Naples Utility Department,Marco Island Utilities,and Everglades City,each of which is responsible to develop a 10-Year Water Supply Facilities Work Plan to be included in its city's comprehensive plan. This 10-Year Water Supply Facilities Work Plan Update for Collier County has the following objectives: • Identify population and water demands of the County and each utility for the planning period of 2013 to 2023. • Present existing and planned potable and reclaimed water facilities that will be utilized to meet demand projections. • Identify sources of raw water needed for potable water and irrigation water supply to meet demands through the year 2023. • Identify the steps necessary to develop additional potable and reclaimed water supplies and specify when they must occur and how they will be funded. • Demonstrate that the water supply plans for each utility within the County are feasible with respect to facility capacity to be developed and consumptive use permit allocations required. • Describe the conservation practices and regulations utilized by each utility to meet water supply demand. CST t ES-1 PW/6295/98609/03/11 • Executive Summary The Collier County 10-Year Water Supply Facilities Work Plan Update was prepared by CDM Smith Inc. (CDM Smith)for the Collier County Growth Management Division. CDM Smith is a consulting, engineering,construction,and operations firm with a successful track record of utility-based planning and design projects.CDM Smith is a leader in providing innovative water and wastewater services throughout Southwest Florida and the world. Information for the Plan Update was solicited from each of the utilities included. All five utilities provided some level of information to CDM Smith for inclusion in the Plan. Where information gaps existed,information on the existing and planned facilities was gathered from various sources including the SFWMD LWCWSP update,SFWMD consumptive use permits,Florida Department of Environmental Protection(FDEP) public water supply and wastewater treatment facility permits,and the previous Collier County 10-Year Water Supply Facilities Work Plan,adopted in February 2009. After completion of the draft version of the Plan Update,copies were distributed to each of the utilities for review and comment. Comments provided by each of the utilities were incorporated into their sections of the Plan Update. The findings of the Plan Update are summarized below for each of the utilities. Collier County Water-Sewer District (CCWSD) During the 10-year planning period CCWSD has plans to develop a new potable water treatment facility to meet growing water demands.Table ES-1 summarizes the treatment capacity of the existing and planned potable water and water reclamation facilities for CCWSD. In addition to the construction of these facilities,CCWSD intends to construct new wellfields,finished water storage,and distribution lines,which are presented in detail in the Plan Update. The information on CCWSD is reflective of the 2008 Water and Wastewater Master Plan Updates,the Collier County 2012 Annual Update and Inventory Report on public utilities,and the Fiscal Year 2011 Water and Wastewater User Rate Study for Collier County Water-Sewer District. Table ES-1. Summary of Existing and Planned CCWSD Water Treatment and Water Reclamation Facilities1 Facility Name Year Design Capacity Project Identified In LWCWSP Online (MGD) Water Treatment Facilities NCRWTP MF Online 12.0 N/A NCRWTP LPRO Online 8.0 N/A SCRWTP LS Online 12.0 N/A SCRWTP LPRO Online 20 N/A NERWTP Phase 1 LPRO 2023 7.5 Yes NERWTP Phase 1 Ion Exchange 2023 2.5 No Total 62.0 Water Reclamation Facilities NCWRF Online 24.1 N/A SCWRF Online 16.0 N/A Total 40.1 1 Information taken from the Collier County 2008 Wastewater Master Plan Update and the 2012 AUIR. CD NI ES-2 PW/6295/98609/03/11 • Executive Summary Based on population projections available for the CCWSD service area,a capacity analysis was performed looking at projected demand versus plant capacity versus permitted allocation. The results of the capacity analysis are summarized below in Table ES-2. A discussion of the capacity analysis can be found in Section 6.1. As the capacity analysis illustrates,CCWSD has sufficient plant capacity existing or planned throughout the 2023 planning horizon. There is a calculated Permitted Deficit starting in 2023,however,this deficit is related to the planned NERWTP and associated wellfield. CCWSD will initiate the application process for a modification to its current CUP to include the planned NERWTP Wellfield in 2018 as identified in Table 5-2.The additional allocation sought will be an additional total 14.60 MGD from the LT,HZ1 and LH aquifers. Table ES-2. Capacity Analysis for CCWSD 2010 2013 2018 2023 Service Area Population 201,377 212,972 249,366 282,845 Demand Per Capita(gpcd) 170 170 170 170 Required Treatment Capacity @ 170 gpcd(MGD) 34.23 36.21 42.39 48.08 Available Facility Capacity(MGD) 52.00 52.00 52.00 62.00 Facility Capacity Surplus(Deficit)(MGD)1 17.77 15.79 9.61 13.92 Raw Water Requirement(MGD)2 40.13 42.76 51.01 57.84 Permitted Amount(MGD Annual Average)' 56.14 56.14 56.14 56.14 Permitted Surplus(Deficit)(MGD)4 16.01 13.38 5.13 (1.70) 1 Calculated by subtracting Required Treatment Capacity @ 170 gpcd from Available Facility Capacity. 2 Raw water requirement is the amount of raw water needed to make a certain amount of finished water.It is calculated by dividing the Required Treatment Capacity @ 170 gpcd by the efficiency of the treatment process. 3 CUP(11-00249-W)for 56.14 MGD annual average expires February 8,2026. Calculated by subtracting the Raw Water Requirement from the Permitted Amount. cSllth ES-3 PW/6295/98609/03/11 • Executive Summary Immokalee Water and Sewer District (IWSD) Table ES-3 summarizes the treatment capacity of the existing and planned potable water facilities for IWSD. Table ES-3. Summary of Existing and Planned ISWD Water Treatment Facilities' Facility Name Year Design Capacity Project Identified in Online (MGD) LWCWSP Jerry V.Warden WTP Online 2.25 N/A Airport WTP Online 1.35 N/A Carson Road WTP Online 2.00 N/A RO WTP 2020 3.00 Yes Total 8.60 1 Information on the existing and planned water treatment facilities was taken from the 2012 Lower West Coast Water Supply Plan Update. Based on population projections available for the IWSD service area,a capacity analysis was performed looking at projected demand versus plant capacity versus permitted allocation. The results of the capacity analysis are summarized below in Table ES-4. A discussion of the capacity analysis can be found in Section 6.2. Based on the capacity analysis,the improvements planned by the IWSD for the 10-year planning period are sufficient to meet the demands of the service area and the allocation of the underlying CUP(11-00013-W) is sufficient to cover the withdrawals required to make the finished water demand. Table ES-4. Capacity Analysis for IWSD 2010 2013 2018 2023 Service Area Population 27,273 27,848 29,414 30,939 Demand Per Capita(gpcd) 105 105 105 105 Annual Average Daily Demand(MGD) 2.86 2.92 3.09 3.25 Available Facility Capacity(MGD) 5.60 5.60 5.60 8.60 Facility Capacity Surplus(Deficit)(MGD)1 2.74 2.68 2.51 5.35 Raw Water Requirement(MGD)2 2.95 3.01 3.19 3.35 Permitted Amount(MGD Annual Average)' 3.36 4.15 4.15 4.15 Permitted Surplus(Deficit)(MGD)4 0.41 1.14 0.97 0.80 Calculated by subtracting Annual Average Daily Demand from Available Facility Capacity. 2 Raw water requirement is the amount of raw water needed to make a certain amount of finished water.It is calculated by dividing the annual Average Daily Demand by the efficiency of the treatment process. CUP(11-00013-WI for 4.15 MGD annual average expires May 23,2031. Calculated by subtracting the Raw Water Requirement from the Permitted Amount. Smith ES-4 M/6295/98609/03/11 r • Executive Summary Florida Governmental Utility Authority (Golden Gate) (FGUA) The FGUA service area is nearly built out and the utility's plans for the 10-year planning period include projects to meet minor increases in water demand. Table ES-5 summarizes the treatment capacity of the existing and planned potable water facilities for FGUA. Table ES-S. Summary of Existing and Planned FGUA Water Treatment Facilities' Facility Name Year Design Capacity Project Identified in Online (MGD) LWCWSP Golden Gate WTP(LS) Online 1.22 No Golden Gate WTP(RO) Online 0.88 No Golden Gate WTP(RO)-After Re-rating Online 0.17 No Total 2.27 Information on existing and planned water treatment facilities taken from the 2013 FGUA Updated Capacity Analysis Report. Based on population projections available for the FGUA service area,a capacity analysis was performed looking at project demand versus plant capacity versus permitted allocation. The results of the capacity analysis are summarized below in Table ES-6. The improvements planned by the FGUA for the 10-year planning period are sufficient to meet the demands of the service area and the allocation of the underlying CUP (11-00148-W) covers the withdrawals required to make the finished water demanded. Table ES-6. Capacity Analysis for FGUA 2010 2013 2018 2023 Service Area Population 15,731 16,256 16,810 17,364 Demand Per Capita(gpcd) 109 109 109 109 Annual Average Daily Demand(MGD) 1.71 1.77 1.83 1.89 Available Facility Capacity(MGD) 2.09 2.27 2.27 2.27 Facility Capacity Surplus(Deficit)(MGD)1 0.38 0.50 0.44 0.38 Raw Water Requirement(MGD)2 1.92 1.99 2.07 2.15 Permitted Amount(MGD Annual Average)3 2.49 2.49 2.49 2.49 Permitted Surplus(Deficit)(MGD)4 0.57 0.50 0.42 0.34 1 Calculated by subtracting Annual Average Daily Demand from Available Facility Capacity. 2 Raw water requirement is the amount of raw water need to make a certain amount of finished water.It is calculated by multiplying the population by the demand per capita raw water usage. 3 CUP(11-00148-W)for 2.49 MGD annual average expires March 10,2030. a Calculated by subtracting the Raw Water Requirement from the Permitted Amount. ith ES-5 Sm PW/6295/98609/03/11 • Executive Summary Orange Tree Utility Company (OTUC) The OTUC will be taken over by CCWSD in 2014. Table ES-7 summarizes the treatment capacity of the existing and planned potable water facilities for OTUC. Table ES-7.Summary of Existing and Planned OTUC Water Treatment Facilities' Facility Name Year Online Design Capacity(MGD) Project Identified in LWCWSP Orange Tree WTP Online 0.75 N/A Total 0.75 1lnformation on existing water treatment facilities taken from the 2012 Lower West Coast Water Supply Plan Update. Based on population projections available for the OTUC service area,a capacity analysis was performed looking at project demand versus plant capacity versus permitted allocation.The results of the capacity analysis are summarized below in Table ES-8. Based on the analysis the OTUC has sufficient capacity to meet the demands of the service area through the takeover by CCWSD. Table ES-8. Capacity Analysis for OTUC 2010 2013 Service Area Population 4,808 5,160 Demand Per Capita(gpcd) 100 100 Annual Average Daily Demand(MGD) 0.48 0.52 Available Facility Capacity(MGD) 0.75 0.75 Facility Capacity Surplus(Deficit)(MGD)1 0.27 0.23 Raw Water Requirement(MGD)2 0.62 0.66 Permitted Amount(MGD Annual Average)3 0.86 0.86 Permitted Surplus(Deficit)(MGD)4 0.24 0.20 Calculated by subtracting Annual Average Daily Demand from Available Facility Capacity. 2 Raw water requirement is the amount of raw water need to make a certain amount of finished water.It is calculated by dividing the Annual Average Daily Demand by the efficiency of the treatment process. 3 CUP(11-00419-W)for 0.86 MGD annual average expires November 11,2009. °Calculated by subtracting the Raw Water Requirement from the Permitted Amount. Smith ES-6 Pw/6295/98609/03/11 • Executive Summary Ave Maria Utility Company, LLLP (AMUC) Table ES-9 summarizes the treatment capacity of the existing and planned potable water and water reclamation facilities for AMUC. Table ES-9. Summary of Existing and Planned AMUC Water Treatment and Water Reclamation Facilities' Facility Name Year Online Design Capacity Project Identified In (MGD) LWCWSP Water Treatment Facilities AMUC WTP(Phase 1) Online 0.99 N/A AMUC WTP(Phase 2) TBD 1.70 Yes AMUC WTP(Phase 3) TBD 1.70 Yes Total 4.39 Water Reclamation Facilities AMUC WRF(Phase 1) Online 0.90 N/A AMUC WRF(Phase 2) TBD 1.70 Yes AMUC WRF(Phase 3) TBD 1.70 Yes AMUC WRF(Phase 4) TBD 0.90 Yes Total 5.20 1 Information on existing and planned water treatment facilities taken from the 2012 Lower West Coast Water Supply Plan Update. Based on population projections available for the AMUC service area,a capacity analysis was performed looking at project demand versus plant capacity versus permitted allocation. The results of the capacity analysis are summarized below in Table ES-10. The improvements planned by the AMUC for the 10-year planning period are sufficient to meet the demands of the service area and the allocation of the underlying CUP (11-02298-W) covers the withdrawals required to make the finished water demanded. Table ES-10. Capacity Analysis for AMUC 2010 2013 2018 2023 Service Area Population 1,435 1,886 3,468 6,070 Demand Per Capita(gpcd) 110 110 110 110 Annual Average Daily Demand(MGD) 0.16 0.21 0.38 0.67 Available Facility Capacity(MGD) 1.67 1.67 4.17 5.00 Facility Capacity Surplus(Deficit)(MGD)1 1.51 1.46 3.79 4.33 Raw Water Requirement(MGD)2 0.19 0.24 0.45 0.79 Permitted Amount(MGD Annual Average)3 3.02 3.02 3.02 3.02 Permitted Surplus(Deficit)(MGD)4 2.83 2.78 2.57 2.23 1 Calculated by subtracting Annual Average Daily Demand from Available Facility Capacity. 2 Raw water requirement is the amount of raw water need to make a certain amount of finished water.It is calculated by dividing the Annual Average Daily Demand by the efficiency of the treatment process. 3 CUP(11-02298-W)for 3.02 MGD annual average expires January 9,2017. 4 Calculated by subtracting the Raw Water Requirement from the Permitted Amount. Smith ES-7 PW/6295/98609/03/11 Section 1 Introduction 1.1 Plan Background In November 2012,the Governing Board of the South Florida Water Management District(SFWMD) approved the 2012 Lower West Coast Water Supply Plan Update. Under Florida law(section 163.3177(6)(c),Florida Statutes) Collier County must adopt amendments to its comprehensive plan within 18 months of the SFWMD approval of the update. These amendments include the development of a 10-Year Water Supply Facilities Work Plan and amendments to the Growth Management Plan (GMP). Under the requirement of the Florida Statutes,the 10-Year Water Supply Facilities Work Plan for Collier County must include analysis of all water utilities in the County not serving a specific local government.These utilities include: • Collier County Water-Sewer District(CCWSD) • Immokalee Water and Sewer District(IWSD) • Florida Governmental Utility Authority(Golden Gate) (FGUA) • Orange Tree Utility Company(OTUC) • Ave Maria Utility Company,LLLP(AMUC) Utilities not included in this Plan are the City of Naples Utility Department,Marco Island Utilities,and Everglades City,each of which is responsible to develop a 10-Year Water Supply Facilities Work Plan to be included in its city's comprehensive plan. 1.2 Plan Objectives This 10-Year Water Supply Facilities Work Plan Update(Plan Update)for Collier County has the following objectives: • Identify population and water demands of the County and each utility for the planning period of 2013 to 2023. • Present existing and planned potable and reclaimed water facilities that will be utilized to meet demand projections. • Identify sources of raw water needed for potable water supply to meet demands through the year 2023. • Identify the steps necessary to develop additional potable and reclaimed water supplies and specify when they must occur and how they will be funded. Cent t 1-1 PW/6295/98609/03/11 Section 1 • Introduction • Demonstrate that the water supply plans for each utility within the County are feasible with respect to facility capacity to be developed and consumptive use permit allocations required. • Describe the conservation practices and regulations utilized by each utility to meet water supply demand. 1.3 Information Sources The following information sources were utilized in the development of the Plan Update: • 2012 Lower West Coast Water Supply Plan Update approved by the Governing Board of the South Florida Water Management District on November 15,2012. The document is referred to as the 2012 LWCWSP Update in the Plan Update. • Collier County 2012 Annual Update and Inventory Report on public utilities adopted by Ordinance 12-42 by the Collier County Board of County Commissioners on November 13, 2012.The document is referred to as the 2012 AUIR in the Plan Update. • Collier County 2008 Water Master Plan Update adopted by the Collier County Board of County Commissioners on June 24,2008. The document is referred to as the Collier County 2008 Water Master Plan Update in the Plan Update. • Collier County 2008 Wastewater Master Plan Update adopted by the Collier County Board of County Commissioners on June 24,2008. The document is referred to as the Collier County 2008 Wastewater Master Plan Update in the Plan Update. • Fiscal Year 2011 Water and Wastewater User Rate Study for Collier County Water-Sewer District adopted by the Collier County Board of County Commissioners on February 22,2011. The document is referred to as the Fiscal Year 2011 Water and Wastewater User Rate Study in the Plan Update. • 2013 Florida Governmental Utility Authority Updated Capacity Analysis Report for Golden Gate Water Treatment Plant Collier County submitted to FDEP in May 2013. The document is referred to as the 2013 FGUA Updated Capacity Analysis Report. • SFWMD CUP numbers: o CCWSD- 11-00249-W and 11-00052-W o IWSD- 11-00013-W o FGUA- 11-00148-W o OTUC-11-00419-W o AMUC-11-02298-W • FDEP Drinking Water Database accessed on July 5,2013. http://www.dep.state.fl.us/water/drinkingwater/pws sys.htm • Responses to data requests sent to CCWSD,IWSD,FGUA,OTUC and AMUC. cSmith 1-2 PW/6295/98609/03/11 Section 1 • Introduction It is important to note that other planning documents such as Water,Wastewater and Irrigation Master Plans as well as User and Impact Fee Rate Studies are ongoing.Likewise,concurrency tools such as the 2013 Annual Update and Inventory Report were not adopted by the Board of County Commissioners until after supporting data for this Plan was provided.Accordingly,planned facilities (see Chapter 5)may move up or back within a 10 year timeframe depending on these plans and studies,as adopted.The information supporting this 10-Year Water Supply Facilities Work Plan reflects the most recent data available as of July 1,2013. 1.4 Plan Contents Section 2 introduces the utilities that serve Collier County and identifies their service areas.Section 3 presents population and water demand projections for the County and individual utilities for the planning period out to 2023.Section 4 summarizes the existing potable water supply system including fresh and brackish water wellfields,raw water transmission systems,and water treatment plants (WTPs)and reclaimed water systems(where applicable) for each utility. Section 5 summarizes the planned potable and reclaimed water systems for each of the utilities out to 2023. Section 6 presents an analysis of the ability of each utility to meet projected demands during the planning period.Section 7 summarizes current and planned conservation practices and regulations that will be utilized to meet demands. Section 8 summarizes the capital improvement plan for each of the utilities. CSmlth 1-3 PW/6295/98609/03/11 Section 2 Water Service Areas 2.1 Overview of Collier County Collier County is served by four Public Sector Water Systems,including the County,the City of Naples, Everglades City,and the City of Marco Island.The County is served by the Collier County Water-Sewer District(CCWSD)and domestic self-supply outside of the CCWSD service area.The boundaries of the CCWSD,City of Naples,Everglades City,the City of Marco Island,and the Goodland Water Sub-District are shown in Figure 2-1. In addition to the Public Sector Water Systems,Collier County is served by four Non-Public Sector Water Systems including the Immokalee Water and Sewer District(IWSD),the Florida Governmental Utility Authority(Golden Gate) (FGUA),the Orange Tree Utility Company(OTUC),and the Ave Maria Utility Company(AMUC).The boundaries of these systems are also presented in Figure 2-1.There are also two Private Sector Water Systems which include the Lee Cypress Water and Sewer Co-Op,Inc. and the Port of the Islands Community Improvement District,along with numerous small capacity water systems that are regulated by the Florida Department of Environmental Protection(FDEP). 2.2 Individual Utilities and Systems 2.2.1 Collier County 2.2.1.1 Collier County Water-Sewer District(CCWSD) The CCWSD encompasses approximately 248 square miles.This area is bounded on the North by Lee County,on the south by the City of Marco Island service area,on the west by the City of Naples service area and the Gulf of Mexico,and on the east by the Urban Planning Boundary.The CCWSD was approved by referendum in 1969 and validated by the State Legislature in 1978 by Special Act, Chapter 78-489,Laws of Florida.In 1988,the legislature approved a supplement to the Special Act, which included revisions to the District boundaries.This action significantly increased the size of the District to approximately 210 square miles.It also specifically excluded areas of the City of Naples, Marco Shores,Marco Island,and the FGUA. There is one portion of the CCWSD service area that is not served by CCWSD,that being approximately 17 square miles of unincorporated area contiguous to the City of Naples,shown as green hatch on Figure 2-1. As this area is a substantially developed part of the County,with minimal growth expected during the 10-year planning period,no plans for supplying additional water to this area are included in this Plan. The original interlocal agreement by which the City of Naples serves this area was enacted on October 16, 1977. A copy of the most recent version of the interlocal agreement is provided in Appendix A. The Water-Sewer District Boundary was expanded by a Special Act,Approved by the Governor on June 26,2003,and adopted as Chapter 2003-353,Laws of Florida.The Rural Fringe areas were incorporated within the CCWSD when the Board of County Commissioners approved Resolution 2003- 296 on September 17,2003.From the adoption date forward,the County is responsible for providing water and sewer service in the"Receiving Lands",Rural Fringe,which is approximately 38 square miles in area. C?9th 2-1 PW/6295/98609/03/11 SR 82 gl • •�•.! T T —6 I • 6 5 4 ~3 2 1 6 ; 5 4 3 2 1 5 2 ; 1 ALICO'a a to n 1z e 9 10 n.-a ] ; e s m n 1z 1 17 6 15 14 13 18 ! 17 16 15 14 13 8 17 16 15 14 IMMOKALEel 15 I 19 20 21 22 WATER/SEWER DISTRICT" 24 19 120 21 22 23 24 1 CORKSCREW RD 29 28 27 26 25 30 29 28 27 26 25 30 I 29 28 27 28 25 1 30 I 3 31 32 33 34' 35 36 31 32 33 34 35 36 31 , 32 33 34 35 36 _ I 1 CR 846 .... 3__5_ .4.. 3- -2 ' 1 1 6 5 4 3 2 1 6 5 �•—.—.—'—.—'-.—.—.—.—.1 12 7 I 8 9 10 11 12 11 7 8 9 10 11 12 7 6 9 10 11 12 ; 7 8 9 10 —. 1 •1 17 16 15 1 14 18 I 17 16 15 14 13 18 17 16 15 14 13 18 17 16 15 14 t3 118 •—1 I 19 20 21 22 23 24 19 20 21 22 23 24 119 20 21 22 23 24 • I 20 21 22 23 24 Q / 26 27 26 25 ihh N 2g• 25 30 29 28 2] 28 25 30 29 28 2] 26 25 30 7 � 30 29 28 27 —•—. 1 3k.-. 132 33i 34 35 36 31 33 34 35 3E 32 33 y' 35 36 31 32 33 34 35 36 31 31 •'•I 8r CH RD 4 1 s 4 ! 3 z i s 4 3 z 1 6 5 q z 1 6 s 3 2 ��. f 10 12 ] 8 8 I — + 10 11 12 7 9 10 11 12 5 4 I 10 11 12 ) 6 9 ] 8 9 - 11 12 8 9 10 11 1 I i'' 17 76 15 1.14 13 18 17 18 15 14 13 �—•/ 16 15 14 13 1� �I•MIA 21 22 23 24 18 17 16 15 14 13 1• 17 16 15 14 13 1 wAT�sEI__ yz 23 24 19 "' 20 21 22 23 24 19 20 21 22 23 24 EWER 20 21 22 23 24 Y 20 21 22 23 24 19 _ �IS2'�RI�gT 27 26 2s 3D .. 28 ZJ 26 25 2S 28 27 26 25 30 29 28 27 26 25 3 .: 28 LI-'- MINTY' 28 25 30 33 3d 35 3E 33 30 35 36 31 32 33 34 35 38 31 32 33 34 35 36 31 .• 3 33 • •R/S 31 R D13TR�P 35 36 31 92 7 4 3 5 4 3 2 6 �' 6 4... 1 6 5 4 3 2 1 6 5 4 3 2 1 6 5 4 3 2 1 6 N N 9 12 7 8 9 10 11 12 7 8 9 10 11 12 7 8 9 10 11 12 7 8 9 10 II 12 7 8 9 10 11 15 14 ��18 17 I 16 5 'a l 18 17 16 15 . 13 18 17 16 15 14 13 18 17 16 15 14 roe O 18 17 18 .��.L t .. J .Y.: :.Y"r.4 23 24 19 20 21 22 23 24 19 20 21 22 23 24 19 20 21 22 23 24 19 20 21 22 23 01:4::!:....):41,4��Y4 26 25 s30 29 28 27 26 25 30 29 28 27 26 25 30 29 28 27 26 25 30 29 28 27 26 Z-�,, t9� 31 32/�E� 35 36 31 32 33 34 35 36 31 321 7533 34 35 36 31 32 33 34 35 36 31 32 33 34 35 /, t, 6 5 4 3 2 1 6 5 4 3 2 1 8 5 4 3 2 1 6 5 4 3 2 1 6 5 3 2 40, elor 8 9 10 11 12 7 8 9 10 11 13 7 8 9 10 11 12 7 8 9 10 11 12 7 8 9 10 11 4` 18 17 16 15 14 13 18 17 16 15 14 13 18 17 16 15 14 13 18 17 16 15 14 13 18 17 16 15 14 1 ' /10 4.4:••r• 1 21 24 20 21 22 23 24 19 20 21 22 23 24 19 20 21 22 23 24 19 20 21 22 23 24 19 ZO 21 22 23 e26 25 30 9 28 27 26 25 30 29 28 27 26 25 30 29 28 27 26 25 30 29 28 27 28 25 30 29 28 27 26 4 35 36 31 32 3 35 36 31 32 33 34 35 36 31 32 33 34 35 36 31 32 33 34 35 36 31 32 33 34 35 3 2 1 6 5 4 2 1 6 5 4 • 2 1 6 5 4 3 2 1 6 5 4 3 2 1 6 5 4 11 12 7 8 9 A 10 11 12 7 8 9 10 II 12 7 8 9 10 11 12 7 8 9 10 11 12 7 8 9 10 11 14 13 16 17 16 15 14 13 18 17 16 15 14 13 18 17 16 15 14 1 13 18 17 18 N 15 14 13 17 16 15 23 24 19 20 21 22 23 24 19 20 21 2 23 24 19 20 21 22 23 24 19 20 21 22 23 24 19 20 21 22 23 30 29 28 27 26 25 30 29 28 26 25 30 29 28 27 26 25 30 29 28 27 26 25 30 29 28 27 34 35 36 31 32 33 34 35 36 31 32 33 34 35 31 32 33 34 35 36 31 3 33 34 35 31 32 33 5 4 3 2 1 6 5 4 3 2 1 5 4 3 2 s 5 3 2 1 8 5 4 3 2 1 ..IAMI TRAIL 6 9 10 11 12 7 8 9 10 11 12 7 8 9 10 11 12 7 8 9 10 11 ] i 9, 10 11 12 7 8 17 16 15 14 13 18 17 16 15 14 3 18 17 16 15 14 13 18 17 16 IS 14 17` 16 5 14 21 22 23 24 19 20 21 22 21 1/ 19 20 2 21 22 23 24 19 20 21 22 23 24 19 21 22 23 24 30 29 26 T7 26 25 30 29 1 28 27 26 25 30 29 28 27 26 30 29 C28 41 27 26 Legend 28 26 25 3 2 33. 34 35 36 31 ; 32 33 34 35 38 31 32 33 34 35,r. •• 31 34 . >—publish_MAIN_roads_major 3a 35 C1/�RyLA 1 _}CISt_ s a 3 2 3 2 1 6 . 5 4 3 2 1 6 5 Y S TT 1_ ccwsD ROW Locations VIATFR/SfW-R DISTRICT 9 1011 xXy Orange Tree Service Area 12 ] 8 s 10 11 12 7. W FGUA Service Area r•I 18 17 16 15 ;. 14 13 18 17 16 15 }a k 13 18 17 16 15 12 ///Area Salved by City of Naples � �- � � � � I y ®City of Naples 20 21 22 23 24 19 20 21 22 R3 Va 19 20 21 22' SECTIONS � •�• � O WATER-SEWER DISTRICT BOUNDARY 25 30 29 28 27 26%•,.``5% 30 29 28 27 =COUNTI'_PHY 36• 11 32 33 34 32 33. 34 35 -•� FIGURE 2-1 COLLIER COUNTY 10-YEAR WATER SUPPLY FACILITIES WORK PLAN M SpN WATER SEWER DISTRICT BOUNDARIES OF COLLIER COUNTY mith 0 1.5 3 A Miles Section 2 • Water Service Areas However,service in these areas is according to the following policy: "Any development occurring within the Rural Fringe within the revised Collier County Water-Sewer District Boundary will be customers of the County.Should the County not be in a position to supply potable water to the project and/or receive the project's wastewater at the time development commences,the PUD Developer,at his expense,will install and operate water and/or wastewater interim facilities adequate to meet all requirements of the appropriate regulatory agencies.These developments may receive water and wastewater services from another centralized service area provider until the County is in a position to provide service.However,these developments and the required interlocal agreement to enact this interim service will be reviewed on a case-by-case basis. Non-centralized interim service such as potable water supply wells and septic systems are allowable interim facilities." Several areas are included in the planning areas that lie outside the existing District boundaries.These areas include the OTUC service area,the FGUA service area,and potentially other partially developed areas in Golden Gate Estates within the CCWSD.The OTUC will be taken over by the CCWSD in 2014. A composite map,provided as Figure 2-2,showing the existing CCWSD potable and reclaimed water distribution systems,illustrates the actual area of the water-sewer district currently being served. In addition to interconnections with Marco Shores by which CCWSD supplies water on a bulk basis, CCWSD also maintains emergency interconnects with the City of Naples,the City of Marco Island and Bonita Springs Utilities. As the interconnects are for emergency purposes only and are not intended for bulk transfer,CCWSD does not dedicate any portion of its water supply capacity to serving these interconnections. Should CCWSD,at a future date,enter into an agreement with any additional entity to provide finished water,it will incorporate the amount of water provided to said entity into its planning documents. 2.2.1.2 Goodland Water Sub-District Until recently,the Goodland District was a separate water district serving an island community, roughly one quarter of a square mile in area.It is located about two miles east of Marco Island.The District was established by referendum in 1975.In 2012,the County abolished the District as a separate entity,thereby making it part of the CCWSD (Ord. 2012-43)Appendix B. Service to Goodland is supplied by CCWSD in all respects;bulk water is purchased for distribution from the Marco Island Utility.Accordingly,it is often referred to as a"sub-district,"although it is entirely within the CCWSD boundary.A copy of the Interlocal Agreement for the provision of water from the City of Marco Island is found in Appendix C.CCWSD maintains pumping,distribution and storage facilities in the Goodland sub-district;CCWSD serves the community of Key Marco as well as Goodland on the same basis. 2.2.2 City of Naples The City of Naples is another public sector provider of water service in Collier County. In addition to its corporate area,the City also serves approximately 17 square miles of unincorporated area contiguous to the City limits per an interlocal agreement with Collier County. There are approximately 5,900 service connections in the unincorporated area with an average daily demand of 2.20 MGD. The City allocates 38 percent of its system capacity to serve this unincorporated area. As the unincorporated area is built-out,no additional demand on the City's system is projected for the future. CJR11th 2-3 PW/6295/98609/03/11 16" c BONITA BEACH RD 'Kw 0 rt: _ 5:4,.._ ill : IMO fr 1111 < OIL WEL_RD X12 N r N N �, 10" 7. , N, 36" I T a 12„ 12" 12" - 24 ' aN- N IN�t c7-5i p IV O _ 12" m .:- 11111,MI` 6„ 30" 24" 2" w till/ill GOLDEN GATE BLVD R Lu w} • 1, 1�n D eC A U O o p U N -I c 12" N 12„ 16" T ' 4 gLADlORD 24" 16"v 1 75 1 N_ DAVI'. BLVD 1 " 16"16" rn `l : ': iD 20 M • 24" 24" nD - N 1., ,) 14 ... 76., 016" 1. ' ijoho \.\\1_,- ,=: ,,, 72,741, ‘s-.‘ . p4e T rn �'9/< ec NOTE: 77,,,„M MAINS SHOWN ARE 12"OR GREATER. J -1,Legend Water Mains ID Water Mains 1 /J(fL�,`7J/� FIGURE 2-2 COLLIER COUNTY 10-YEAR WATER SUPPLY FACILITIES WORK PLAN CDMCCWSD POTABLE/RECLAIMED WATER SYSTEM COMPOSITE MAP N Srriitli 0 7,500 15,000 30,000 45,000 Feet 2-4 Section 2 • Water Service Areas The enabling legislation,under which the City established its water service area boundary,is Chapter 180,F.S.,Municipal Public Works Law.The City's existing water supply facilities are not addressed in this 10-Year Water Supply Facilities Work Plan,since they will be discussed in the City's Plan.The service area for the utility is shown in Figure 2-1. 2.2.3 Everglades City Everglades City is also a public sector provider of water service in the County. Like Naples,Everglades City is an incorporated community that provides water service both within and beyond its corporate limits. The outlying unincorporated communities served by the City include Plantation Island and Seaboard Village in Copeland.These represent a demand of over 17 percent of Everglades City's system capacity. Unlike the unincorporated area served by the City of Naples,Plantation Island and Seaboard Village are not part of the Collier County Water Sewer District For this reason,Collier County is not responsible to provide planning efforts to supply water to these communities.These areas are analogous to the Golden Gate Estates portion of Collier County,which is served entirely by self-supply,for which the County is not responsible for providing service. Everglades City's water supply facilities are not addressed in this 10-Year Water Supply Facilities Work Plan,since they will be discussed in the City's Plan.The service area for the utility is shown in Figure 2-1. 2.2.4 City of Marco Island Water and Sewer Service Areas The City of Marco Island historically had been provided service from the private sector utility company,the Florida Water Services Corporation. A small portion of Marco Island's water and sewer infrastructure had historically been maintained by Collier County as the Marco Island Water and Sewer District. The City of Marco Island purchased the system from the Florida Water Services Corporation. The City operates the approximately 10 square mile system as a public sector utility. On February 24,2004,the Marco Island Water and Sewer District was dissolved/abolished by Ordinance No.2004-09. The infrastructure in that area was turned over from the CCWSD to the City. The City now owns and operates the only centralized utility services on Marco Island. The City's existing water supply to the Marco Shores area was replaced with a bulk water supply from the CCWSD to service the area.The bulk supply from the CCWSD is estimated at 165,000 gallons per day and is accounted for in CCWSD's population and water supply demand projections. As the Marco Shores area is built-out,no additional demand on the CCWSD system is projected for the future. The City of Marco Island's existing water supply facilities are not addressed in this 10-Year Water Supply Facilities Work Plan, since they will be discussed in the City's Plan.The service area for the utility is shown in Figure 2-1. 2.2.5 Immokalee Water and Sewer District (IWSD) The Immokalee Water and Sewer District(IWSD),located in the northeast part of Collier County,was created by Special Act of the State Legislature following a 1978 referendum. Creation of an independent district provided the means for this unincorporated community to develop its own water/sewer system,which was necessary due to the distance from the developed coastal area of the County. The boundaries of the District were expanded following a voter referendum in 2004 and a change to the enabling act was signed by the Governor in June 2005 (Chapter 2005-298). This district has a governing board whose members are appointed by the Governor of Florida. The boundaries of this independent district are shown on Figure 2-1. PMth 2-5 PW/6295/98609/03/11 Section 2 • Water Service Areas 2.2.6 Florida Governmental Utility Authority (Golden Gate) (FGUA) Florida Governmental Utility Authority(FGUA)provides water service to and slightly beyond the limits of an unincorporated area known as Golden Gate City(Golden Gate). It also owns and operates systems in other Florida counties. FGUA serves approximately 50 percent of the population within the geographic service area. The remainder of the service area is served by domestic self-supply. Figure 2-1 shows the boundaries for the utility. 2.2.7 Orange Tree Utility Company (OTUC) Orange Tree Utility Company(OTUC) received a PSC Certificate to operate in 1987 and since then OTUC has served the Orangetree Planned Unit Development which is 2,752.8 acres. In 1996,OTUC billing and customer service became regulated by the Collier County Department of Utility Franchise Regulation.In 1998,OTUC began servicing Collier County School Board facilities which now include Corkscrew Elementary,Corkscrew Middle,and Palmetto Ridge High School. In 1999,the OTUC franchise area was expanded to include the Estates of TwinEagles with specific connections along 33rd Ave NE,and 33rd Ave NW,which are located within CCWSD service area.In 2006,Orange Blossom Ranch PUD was annexed into the OTUC franchise area. The OTUC will be taken over by the CCWSD in 2014. The OTUC franchise area is located 9 miles east of I-75,as depicted in Figure 2-1. 2.2.8 Ave Maria Utility Company, LLLP (AMUC) Ave Maria Utility Company(AMUC),established in 2005,provides potable and reclaimed water service to the Town of Ave Maria.The town is located approximately 20 miles east of Interstate 75. The AMUC service area boundary is shown in Figure 2-1. 2.2.9 Independent Districts 2.2.9.1 Lee Cypress Water and Sewer Co-op, Inc. The private sector utility providing water service to Copeland is the Lee Cypress Water and Sewer Co- op,Inc. The unincorporated community of Copeland is located on SR-29 about 3 miles north of US-41. According to the SFWMD consumptive use permit for the Co-op,the population of the service area was 207 in 2004. Based on FDEP records,the utility currently has a capacity of 80,000 gpd. Between 2004 and 2025 the population of the community is projected to grow to 445 residents,according to the consumptive use permit. Assuming a per capita water demand of 170 gpcd,the required utility capacity needed in 2025 would be 75,650 gpd.Based on the projected population and assumed per capita demand,the utility should continue to meet the needs of its residents without expansion through the 10-year planning period.Therefore,no additional consideration is given to this utility in the Plan. 2.2.9.2 Port of the Islands Community Improvement District Another independent district in the County is the Port of the Islands Community Improvement District. This district encompasses approximately 1 square mile of land contiguous to and north and south of US-41,approximately 20 miles south of Naples. This district was created in 1986 by the Collier County Board of County Commissioners in response to a petition from the District's developers and was created as a mechanism to provide water and other services to this isolated area. The District is governed by an elected board of directors. The population of the District was 568 according to the 2012 LWCWSP. Based on FDEP records,the utility currently has a capacity of 435,000 gpd. Based on the projections in the 2012 LWCWSP,between 2013 and 2023 the population of the District is projected to grow to 723 residents. Assuming a per capita water demand of 170 gpcd,the required cSmith 2-6 PW/6295/98609/03/11 Section 2 • Water Service Areas utility capacity needed in 2023 would be 122,910 gpd. Based on the projected population and assumed per capita demand,the utility should continue to meet the needs of its residents without expansion through the 10-year planning period. Therefore,no additional consideration is given to this utility in the Plan. 2.2.10 Water Systems Regulated by Florida Department of Environmental Protection Table 2-1 is a summary of private sector water systems operating within Collier County,but regulated by the FDEP due to very small capacities.These systems primarily serve individual establishments,such as schools,stores,or golfing communities. The list was developed from the FDEP drinking water database and is accurate as of May 2, 2013. Table 2-1.Summary of Small Capacity Private Sector Water Systems Operating within Collier County PWS ID System Name 5114133 AMI KIDS BIG CYPRESS WILDERNESS INSITUTE 5110087 BIG CYPRESS PARK HEADQUARTERS 5114132 BONITA BAY EAST GOLF CLUB-CLUBHOUSE 5114136 BONITA BAY EAST GOLF CLUB REST SHELTER 1 5114131 BONITA BAY EASTGOLF CLUB- MAINTENANCE 5114137 BONITA BAY GOLF CLUB REST SHELTER 2 5114145 CALUSA PINES GOLF CLUB-CLUB HOUSE WTP 5114074 CENTER POINT COMMUNITY CHURCH 5110061 CORKSCREW SWAMP SANCTUARY 5114098 E'S COUNTRY STORE 5114152 ESTATES ELEMENTARY SCHOOL 5114151 FITNESS QUEST 5114141 GOLDEN GATE ASSEMBLY OF GOD 5114130 GOLDEN GATE LIBRARY 5114162 GOLDEN GATE WALGREENS 5110121 HAKAN SERVICES INC. 5114083 HARLEY DAVIDSON MOTOR COMPANY 5114139 HIDEOUT GOLF CLUB SYSTEM 5114129 1-75 RESTSTOP 5114149 LA HISPANA#2 5114161 LIVING WORD FAMILY CHURCH WTP 5114135 MONUMENT LAKE CAMPGROUND 5110195 NAPLES BINGO PALACE GG PKWY 5114108 OASIS RANGER STATION 5114158 PALMETTO J ELEMENTARY SCHOOL 5114164 PEACE LUTHERAN CHURCH OF NAPLES 5110098 PORKY'S LAST STAND BBQ 5114111 RANDALL CENTER 5114113 S.W.FLORIDA RESEARCH ED.CTR. 5114147 SABAL PALM ELEMEN/CYPRESS PALM MIDDLE 5110348 SANDY RIDGE LABOR CAMP Smith 2-7 PW/6295/98609/03/11 Section 2 • Water Service Areas PWS ID System Name 5114119 SUNNILAND COUNTRY STORE 5114127 SYNGENTA SEEDS INC. 5114077 TEMPLE BETHEL 5110288 TRAIL LAKES CAMPGROUND 5114140 TREES CAMP WTP 5114126 UNITY FAITH MISSIONARY BAPTIST 5114159 WILSON BLVD.RETAIL CENTER Smith 2-8 PW/6295/98609/03/11 � k Section 3 Population and Demand Projections Sources of information utilized to develop the included population and demand projections are historical population growth,Collier County Comprehensive Planning Department(CCCPD) forecasts, information from water use permits,and information provided by the individual water supply utilities,such as Master Plans.Population projections through 2023 are included in the following sub- sections. 3.1 Countywide Projections Table 3-1 shows the projected population for Collier County for the 10-year planning period of this plan. The population projections are for peak season,which is one key basis for planning and sizing of facilities. Table 3-1.Collier County Peak Season Population Estimates and Projections Year 2010 2013 2018 2023 Countywide"'3 387,183 402,072 438,245 477,859 1 Estimates and projections are taken from the 2012 AUIR. 2 The countywide population projection includes the unincorporated areas of the county covered in this 10-Year Water Supply Facilities Work Plan, s as well as the incorporated cities of Naples,Marco Island and Everglades City. Peak season population is provided by the Collier County Growth Management Department;it is based on medium BEBR population projections, times 1.2. The population and demand projections for each of the five utilities serving unincorporated Collier County are presented in Section 3.2. 3.2 Individual Utilities 3.2.1 Collier County Water-Sewer District (CCWSD) Table 3-2 shows the projected populations for the existing CCWSD service area. The populations are shown in 5-year increments,through 2023.The total population projections include the populations in the Rural Fringe areas,which were incorporated into the CCWSD in 2003 as described in Section 2.2.1.1,and the Orange Tree area which will be taken over by CCWSD in 2014. Table 3-2. Population Projections for CCWSD Service Area Year 2010 2013 2018 2023 Peak Served Area Population(Seasonal)" 201,377 212,972 249,3663 282,8453 1 Estimates and projections are taken from the 2012 AUIR. 2 Peak season population is provided by the Collier County Growth Management Department;it is based on medium BEBR population projections, times 1.2. 3 Starting in 2014,peak season population includes the OTUC population. The adopted LOSS for the CCWSD is 170 gallons per capita per day(gpcd). Based on the LOSS of 170 gpcd and the population projections presented in Table 3-2,the demand projections for the CCWSD were developed.Table 3-3 presents the projected population and demand for the area served by CCWSD,in 5-year increments,through 2023.Demand is provided as Required Treatment Capacity @ 170 gpcd in MGD. Required Treatment Capacity @ 170 gpcd is a metric used by Collier County in its Smith 3-1 PW/6295/98609/03/11 Section 3 • Population and Demand Projections Annual Update and Inventory Reports(AUIR) and is used to evaluate the ability of CCWSD facilities to meet peak season demand. It is calculated as the peak season population multiplied by the LOSS of 170 gpcd. Table 3-3. Projected Population and Demand for Areas Served by CCWSD Year 2010 2013 2018 2023 Peak Service Area Population(Seasonal)" 201,377 212,972 249,366 282,845 Demand Per Capita(gpcd) 170 170 170 170 Required Treatment Capacity @ 170 gpcd(MGD) 34.23 36.21 42.39 48.08 1 Estimates and projections are taken from the 2012 AUIR. 2 Peak season population is provided by the Collier County Growth Management Department;it is based on medium BEBR population projections, times 1.2. 3.2.2 Immokalee Water and Sewer District (IWSD) Table 3-4 shows the projected populations for the areas served and to be served within the existing IWSD service area. The population is shown in 5-year increments,through 2023. Table 3-4. Population Projections for Areas Served by IWSD Year 2010 2013 2018 2023 Served Area Population' 27,273 27,848 29,414 30,939 1 Population projections are based on the population estimates and projections presented in the SFWMD 2012 Lower West Coast Water Supply Plan Update. Where necessary,the population was calculated by interpolating between years identified in the Plan Update. The IWSD LOSS includes operational standards and a per capita water demand standard of 105 gpcd. Based on the LOSS of 105 gpcd and the population projections presented in Table 3-4,the demand projections for the IWSD were developed.Table 3-5 presents the projected served population and demand for the IWSD,in 5-year increments,through 2023.Demand is provided as both Annual Average Daily Demand(AADD) in MGD and Maximum Month Daily Demand (MMDD) also in MGD. MMDD is determined by multiplying the AADD by a peaking factor,which in this case is 1.2. Table 3-5. Project Population and Demand for Areas Served by IWSD Year 2010 2013 2018 2023 Service Area Population' 27,273 27,848 29,414 30,939 Demand Per Capita(gpcd) 105 105 105 105 Annual Average Daily Demand(MGD) 2.86 2.92 3.09 3.25 Maximum Month Daily Demand(MGD) 3.43 3.50 3.71 3.90 1 Population projections are based on the population estimates and projections presented in the SFWMD 2012 Lower West Coast Water Supply Plan Update. Where necessary,the population was calculated by interpolating between years identified in the Plan Update. 3.2.3 Florida Governmental Utility Authority (Golden Gate) (FGUA) Table 3-6 shows the projected populations for the areas served and to be served within the existing FGUA service area. The population is shown in 5-year increments,through 2023. Smith 3-2 PW/6295/98609/03/11 Section 3 • Population and Demand Projections Table 3-6. Population Projections for Areas Served by FGUA Year 2010 2013 2018 2023 Service Area Population' 27,890 28,229 29,144 30,016 Served Population`'' 15,731 16,256 16,810 17,364 1 Population projections are based on the population estimates and projections presented in the SFWMD 2012 Lower West Coast Water Supply Plan Update. Where necessary,the population was calculated by interpolating between years identified in the Plan Update. 2 Population projections are based 2013 FGUA Updated Capacity Analysis Report.Where necessary,the population was calculated by extrapolating from years identified in the Report. 3 As stated on page 2-6,FGUA serves approximately 50 percent of the population within the geographic service area. The remainder of the service area is served by domestic self-supply. The FGUA LOSS includes operational standards and a per capita water demand standard of 109 gpcd. Based on the LOSS of 109 gpcd and the population projections presented in Table 3-6,the demand projections for the FGUA were developed. Historic,per capita water demand for FGUA was determined to be 86 gpcd in the 2013 FGUA Updated Capacity Analysis Report. The LOSS of 109 gpcd is used for the planning purposes of this Plan. Table 3-7 presents the projected served population and demand for the FGUA,in 5-year increments,through 2023.Demand is provided as both AADD in MGD and MMDD also in MGD. MMDD is determined by multiplying the AADD by a peaking factor, which in this case is 1.2. Table 3-7. Project Population and Demand for Areas Served by FGUA Year 2010 2013 2018 2023 Served Population'" 15,731 16,256 16,810 17,364 Demand Per Capita(gpcd) 109 109 109 109 Annual Average Daily Demand(MGD) 1.71 1.77 1.83 1.89 Maximum Month Daily Demand(MGD) 2.06 2.13 2.20 2.27 1 Population projections are based 2013 FCdUA Updated Capacity Analysis Report.Where necessary,the population was calculated by extrapolating trom years identified in the Report. 2 As stated on page 2-6,FGUA serves approximately 50 percent of the population within the geographic service area. The remainder of the service area is served by domestic self-supply. 3.2.4 Orange Tree Utility Company (OTUC) Table 3-8 shows the projected populations for the areas served and to be served within the existing OTUC service area. The population is shown through 2013,as operation of the OTUC will be taken over by CCWSD in 2014. Table 3-8. Population Projections for Areas Served by OTUC Year 2010 2013 Served Area Population' 4,808 5,160 Estimates and projections are taken from the 2012 AUIR Permanent Population. The OTUC LOSS includes operational standards and a per capita water demand standard of 100 gpcd. Based on the LOSS of 100 gpcd and the population projections presented in Table 3-8,the demand projections for the IWSD were developed.Table 3-9 presents the projected served population and demand for the OTUC,through 2013.Demand is provided as both AADD in MGD and MMDD also in MGD. MMDD is determined by multiplying the AADD by a peaking factor,which in this case is 1.2. CDIVI Smith 3-3 PW/6295/98609/03/11 Section 3 • Population and Demand Projections Table 3-9. Project Population and Demand for Areas Served by OTUC Year 2010 2013 Service Area Population' 4,808 5,160 Demand Per Capita(gpcd) 100 100 Annual Average Daily Demand(MGD) 0.48 0.52 Maximum Month Daily Demand(MGD) 0.58 0.62 1 Estimates and projections are taken from the 2012 AUIR Permanent Population. 3.2.5 Ave Maria Utility Company, LLLP (AMUC) Table 3-10 shows the projected populations for the areas served and to be served within the existing AMUC service area. The population is shown in 5-year increments,through 2023. Table 3-10. Population Projections for Areas Served by AMUC Year 2010 2013 2018 2023 Served Area Population' 1,435 1,886 3,468 6,070 Population projections are based on the population estimates and projections presented in the SFWMD 2012 Lower West Coast Water Supply Plan Update. Where necessary,the population was calculated by interpolating between years identified in the Plan Update. The AMUC LOSS includes operational standards and a per capita water demand standard of 110 gpcd. Based on the LOSS of 110 gpcd and the population projections presented in Table 3-10,the demand projections for the AMUC were developed.Table 3-11 presents the projected served population and demand for the AMUC,in 5-year increments,through 2023.Demand is provided as both AADD in MGD and MMDD also in MGD. MMDD is determined by multiplying the AADD by a peaking factor,which in this case is 1.2. Table 3-11. Project Population and Demand for Areas Served by AMUC Year 2010 2013 2018 2023 Service Area Population' 1,435 1,886 3,468 6,070 Demand Per Capita(gpcd) 110 110 1• 10 110 Annual Average Daily Demand(MGD) 0.16 0• .21 0• .38 0.67 Maximum Month Daily Demand(MGD) 0.19 0• .25 0• .46 0.80 1 Population projections are based on the population estimates and projections presented in the SFWMD 2012 Lower West Coast Water Supply Plan Update. Where necessary,the population was calculated by interpolating between years identified in the Plan Update. Smith 3-4 PW/6295/98609/03/11 Section 4 Existing Water Supply Facilities 4.1 Collier County Water-Sewer District (CCWSD) 4.1.1 Water Supply Permits The SFWMD regulates withdrawals from groundwater sources in Collier County.CCWSD currently maintains two consumptive use permits (CUPs); one for potable water supply and one for supplemental supply of the reclaimed water system.One modification of the CUP for supplemental supply of the reclaimed water system is currently in process to increase the allocation of one of the two existing supplemental wellfields and to allow for two new supplemental wellfields to be constructed. Table 4-1 provides details on the CUPs CCWSD currently maintains and has requested. Table 4-1. Consumptive Use Permits Issued by SFWMD to CCWSD Consumptive Maximum Use Permit Number of Expiration Annual Average Day Monthly Aquifer Permitted Allocation Allocation Wells Date (MG) (MGD) Allocation (MG) LT1 36 02/09/14 9,673 26.50 N/A LT1 36 02/08/26 6,868 18.82 N/A 11-00249-W - HZ1 46 02/08/26 5,840 16.00 N/A LH 322 02/08/26 N/A N/A N/A Total 110 20,490 56.14 1981 LT 7 TBD 2,639 7.23 N/A 11-00052-W3 WT 6 TBD Total 13 2,639 7.23 N/A 121221-184 LT 2 TBD 1,489 4.08 N/A LT=Lower Tamiami LH=Lower Hawthorn HZ1=Hawthorn Zone 1 WT=Water Table 1 Limiting condition 5 of the consumptive use permit 11-00249-W allows for an increased allocation(up to 9,673 MG/yr)from the Lower Tamiami Aquifer through February 9,2014. If this increases allocation is not renewed,the allocation will revert to 6,868 MG/yr for the remainder of the permit duration. 2 Number of permitted Lower Hawthorn Aquifer wells includes 14 proposed wells for the proposed Northeast Regional Water Treatment Plant. 3 Consumptive use permit for supplemental reclaimed water wellfield. Permit modification/renewal application submitted December 21,2012. The CCWSD also has a permit for a 1 MGD potable water aquifer storage and recovery(ASR)well near the Manatee Pumping Station site and a 1 MGD irrigation quality water ASR on Livingston Road. 4.1.2 Potable Water Facilities 4.1.2.1 Wellfields Currently,the CCWSD operates three wellfields:the Golden Gate Tamiami Wellfield,the North Hawthorn Reverse Osmosis (RO)Wellfield,and the South Hawthorn RO Wellfield.The location of each Smith 4-1 PW/6295/98609/03/11 Section 4 • Existing Water Supply Facilities of these wellfields is illustrated in Figure 4-1.The North Hawthorn RO and South Hawthorn RO wellfields contain wells that tap the Hawthorn Zone 1 (HZ1)and the Lower Hawthorn (LH)aquifers, both of which are brackish in those areas of Collier County.The wellfields serve the low pressure reverse osmosis (LPRO)treatment trains at the North County Regional Water Treatment Plant (NCRWTP)and the South County Regional Water Treatment Plant(SCRWTP),respectively.The Golden Gate Tamiami Wellfield contains wells that tap the LT Aquifer,which contains freshwater.The wellfield serves the membrane filtration(MF)equipment at the NCRWTP and the lime softening(LS) equipment at the SCRWTP. Tables 4-2,4-3,and 4-4 summarize the existing wells in the Golden Gate Tamiami Wellfield,the North Hawthorn RO Wellfield,and the South Hawthorn RO Wellfield,respectively. 4.1.2.2 Water Treatment Facilities The CCWSD is served by two water treatment plants(WTPs),the NCRWTP and the SCRWTP,which are shown in Figure 4-2. The NCRWTP is located on the north side of Vanderbilt Beach Road Extension east of CR-951 in the northeastern quadrant of the service area.The plant utilizes groundwater withdrawn from the LT, HZ1 and LH aquifers.Water from the LT Aquifer is treated using MF,while water from the HZ1 and LH aquifers is treated by LPRO.Currently,the plant is capable of producing 20 MGD of finished water; 12 MGD from the MF process and 8 MGD from the LPRO process. The SCRWTP is located near the intersection of CR-951 and I-75 about 5.5 miles south of the NCRWTP. The plant utilizes groundwater withdrawn from the LT,HZ1 and LH aquifers.Water from the LT Aquifer is treated using LS,while water from the HZ1 and LH aquifers is treated by LPRO.Currently, the plant is capable of producing 32 MGD of finished water; 12 MGD from the LS process and 20 MGD from the LPRO process. A summary of the existing water treatment facilities is provided in Table 4-5.In addition to identifying the design capacity of each treatment train,the amount of raw water required to achieve the design capacity is also provided. cSmith 4-2 PW/6295/98609/03/11 NORTH HAWTHORN RO WELLFIELD NCRWTP VANDERBILT BEACH • e S ir GOLDEN GATE BLVD GOLDEN GATE TAMIAMI WELLFIELD PINE RIDGE RD — f GOLDEN GATE 1KWY t SOUTH HAWTHORN WELLFIELD ► . • • • I - SCRWTP RADIO RD '75 ,O my S� N rn i O� 0 • 0 • Legend • Wells • FIGURE 4-1 C DM COLLIER COUNTY 10-YEAR WATER SUPPLY FACILITIES WORK PLAN EXISTING CCWSD WELLFIELDS AND RAW WATER TRANSMISSION MAINS N Smith 0 3,200 6,400 Feet A 4-3 ,:ONITA BE'CH RD OIL WEL_RD IM OKALEE RD W c a AY NCRTP m z U, 'ri VANDE-BILT BEACH w LL o Hill J GOLDEN GATE BLVD Li w J a O w 0 C7 PINE RIDG RD } o A O U 0 I- -+ c SCRWTP 11>f G) RADIO RD 175 DAVIS BLVD 7 I' ,...1t5 Ty,,,,, L7- �/< U) a 1.Legend � - Existing Potable Water Treatment Facilities 111VVV/// AslicC i _ .0_rill Allill&1111■._ FIGURE 4-2 COLLIER COUNTY 10-YEAR WATER SUPPLY FACILITIES WORK PLAN N CEXISTING CCWSD POTABLE WATER TREATMENT FACILITIES Smith 0 7,500 15,000 30,000 45,000 Feet 4-4 Section 4 • Existing Water Supply Facilities Table 4-2. Existing CCWSD Golden Gate Tamiami Wellfieldl Well No. Aquifer Total Depth(ft) Depth of Casing Diameter Capacity(gpm) (ft) (in) 1 LT 96 50 16 700 2 LT 100 50 16 700 3 LT 100 51 16 700 4 LT 102 52 16 700 5 LT 108 50 16 700 6 LT 101 65 12 700 7 LT 106 65 12 700 9 LT 114 65 12 700 10 LT 112 71 12 700 11 LT 137 90 12 700 12 LT 133 90 12 700 13 LT 130 84 12 700 14 LT 131 85 12 700 15 LT 130 84 12 700 16 LT 150 92 12 700 17 LT 125 78 12 1000 18 LT 126 80 12 1000 19 LT 128 83 12 1000 20 LT 131 83 12 1000 21 LT 110 62 12 1000 22 LT 101 62 12 1000 23 LT 111 59 12 1000 24 LT 109 58 12 1000 25 LT 110 65 12 1000 26 LT 106 65 12 1000 27 LT 105 61 12 1000 28 LT 120 66 12 1000 29 LT 125 72 12 1000 30 LT 120 58 12 1000 31 LT 120 65 12 1000 32 LT 120 65 12 1000 33 LT 120 70 12 1000 34 LT 120 80 12 1000 35 LT 145 102 12 1000 36 LT 125 92 12 1000 37 LT 150 100 12 1000 1 Information on existing wells taken from CUP#11-00249-W. Smith 4-5 PW/6295/98609/03/11 Section 4 • Existing Water Supply Facilities Table 4-3. Existing North Hawthorn RO Wellfield Summaryl Well No. Aquifer Total Depth(ft) Depth of Casing Diameter Capacity(gpm) (ft) (in) RO-1N LH 801 705 16/122 1000 RO-2N LH 780 734 16/122 1000 RO-3N LH 800 720 16/122 1000 RO-4N LH 891 744 16/122 1000 RO-5N LH 1070 790 16/122 1000 RO-6N LH 975 740 16/122 1000 RO-7N LH 977 775 16/122 1000 RO-9N LH 952 780 16/122 1000 RO-10N LH 1011 750 16/122 1000 RO-11N LH 951 735 16/122 1000 RO-12N LH 891 730 16/123 1000 RO-13N LH 925 731 16/123 1000 RO-14N LH 950 713 16/124 1000 RO-15N LH 957 737 16/123 1000 RO-16N LH 989 751 16/123 1000 RO-17N LH 996 780 16/123 1000 RO-18N LH 1000 700 16 1000 RO-19N LH 1000 700 16 1000 RO-20N LH 1000 700 16 1000 RO-101N HZ1 512 397 16 350 RO-102N HZ1 500 400 16 350 RO-109N HZ1 475 404 16 350 RO-114N HZ1 514 412 16 350 RO-115N HZ1 500 400 16 350 RO-116N HZ1 500 400 16 350 RO-117N HZ1 500 400 16 350 RO-118N HZ1 500 400 16 350 RO-119N HZ1 500 400 16 350 RO-120N HZ1 500 400 16 350 1 Information on existing wells taken from CUP#11-00249-W. 2 16-inch casing to 100 feet,then 12-inch casing to production casing depth. 3 16-inch casing to 150 feet,then 12-inch casing to production casing depth. 4 16-inch casing to 160 feet,then 12-inch casing to production casing depth. Smith 4-6 PW/6295/98609/03/11 Section 4 • Existing Water Supply Facilities Table 4-4. Existing South Hawthorn RO Wellfield Summaryl Well No. Aquifer Total Depth(ft) Depth of Casing Diameter(in) Capacity(gpm) (ft) RO-1S HZ1 420 312 16/122 1000 RO-2S HZ1 400 292 16/122 1000 RO-3S HZ1 403 293 16/122 1000 RO-4S HZ1 402 331 16/122 1000 RO-5S HZ1 402 297 16/122 1000 RO-65 HZ1 421 317 16/122 1000 RO-7S HZ1 442 328 16/122 1000 RO-8S LH 982 660 16/122 1000 RO-9S LH 682 630 16/122 1000 RO-10S LH 842 630 16/122 1000 RO-11S LH 963 653 16/122 1000 RO-12S HZ1 422 299 16/122 1000 RO-13S HZ1 400 295 16/122 1000 RO-14S HZ1 422 298 16/122 1000 RO-15S HZ1 402 295 16/122 1000 RO-16S HZ1 420 300 16 1000 RO-17S HZ1 420 300 16 1000 RO-18S HZ1 420 300 16 1000 RO-19S HZ1 420 300 16 1000 RO-20S HZ1 420 300 16 1000 RO-21S HZ1 420 300 16 1000 RO-22S HZ1 420 300 16 1000 RO-23S HZ1 420 300 16 1000 RO-24S HZ1 420 300 16 1000 RO-255 HZ1 420 300 16 1000 RO-26S HZ1 420 300 16 1000 RO-27S HZ1 420 300 16 1000 RO-28S HZ1 420 300 16 1000 RO-29S HZ1 420 300 16 1000 RO-30S HZ1 420 300 16 1000 I Information on existing wells taken from CUP#11-00249-W. 2 16-inch casing to 120 feet,then 12-inch casing to production casing depth. Smith 4-7 MN/6295/98609/03/11 Section 4 • Existing Water Supply Facilities Table 4-4. Existing South Hawthorn RO Wellfield Summary'(Continued) Well No. Aquifer Total Depth(ft) Depth of Casing Diameter(in) Capacity(gpm) (ft) RO-31S HZ1 420 300 16 1000 RO-32S HZ1 420 300 16 1000 RO-33S HZ1 420 300 16 1000 RO-34S HZ1 420 300 16 1000 RO-35S HZ1 420 300 16 1000 R0-36S HZ1 420 300 16 1000 RO-37S HZ1 420 300 16 1000 RO-38S HZ1 420 300 16 1000 RO-39S HZ1 400 300 16 1000 RO-40S LH 1000 700 16 1000 RO-41S HZ1 400 300 16 1000 RO-42S LH 1000 700 16 1000 1 Information on existing wells taken from CUP#11-00249-W. 2 16-inch casing to 120 feet,then 12-inch casing to production casing depth. Table 4-5.Summary of Existing CCWSD Water Treatment Facilities' Facility Name Design Capacity Raw Water Raw Water Traditional/Alternative (MGD) Requirement2(MGD) Source NCRWTP MF 12.00 14.12 LT Traditional(Fresh) NCRWTP LPRO 8• .00 10.67 LH/HZ1 Alternative(Brackish) SCRWTP LS 1• 2.00 12.37 LT Traditional(Fresh) SCRWTP LPRO 2• 0.00 26.67 LH/HZ1 Alternative(Brackish) i Total 5• 2.00 63.82 1 Information taken from the Collier County 2008 Water Master Plan Update. 2 Raw water requirement is the amount of raw water needed to make a certain amount of finished water.It is calculated by dividing the finished water capacity by the efficiency of the treatment process. 4.1.2.3 Pumping,Storage, and Transmission The existing transmission facilities consist of transmission pipelines,water storage tanks,an ASR system,and pumping facilities.The storage and pumping facilities utilized by CCWSD are shown in Figure 4-3.The pumping facilities are comprised of high service pumps located at both water treatment plants,four water booster pumping stations and an in-line booster pump station.Ground storage tanks at the treatment facilities and at the booster pumping stations provide system storage and reserve capacity to help meet the peak hourly demands of the system.The booster pumping stations and storage tanks are located at the Isle of Capri,Manatee Road,and Carica Road.The CCWSD also maintains and operates the Goodland Water Booster Pumping Station,which is part of the Goodland Water Sub-District.An in-line booster station is located in the northwest portion of the system near Vanderbilt Drive.In addition to the traditional storage and pumping facilities mentioned above,CCWSD maintains a 1 MGD potable water ASR system at the Manatee Road Pumping Station. Smith 4-8 PW/6295/98609/03/11 Section 4 • Existing Water Supply Facilities Potable water is stored at various strategic points in the CCWSD distribution system to help meet diurnal peak system and fire flow demands.A summary of the existing storage facilities is provided in Table 4-6. Table 4-6.Summary of Existing CCWSD Water Storage Facilities Facility Name Tank Volume(MG) Usable Storage Volume(MG) NCRWTP 12.00 11.10 SCRWTP 14.00 12.40 Isle of Capri 0.25 0.20 Manatee Road Pumping Station 2.00 1.80 Carica Road Pumping Station 10.00 9.30 Manatee Road ASR2 N/A —1 MGD System Total 38.25 34.80 1 Information on the Collier County 2008 Water Master Plan Update. 2 Storage volume for Manatee Road ASR not included in total. Potable water is pumped from the plants into the distribution system.The distribution system includes water mains designated as either transmission or distribution mains.The CCWSD pipelines 16 inches in diameter and larger are generally termed transmission mains.These are typically located along arterial and collector roadways and convey water to major demand areas.Pipelines that are smaller than 16 inches in diameter are generally called distribution mains,branching off the transmission system to supply individual users. The transmission mains and major distribution mains that serve the CCWSD are illustrated in Figure 4-4.Overall,the CCWSD owns and maintains over 1,000 miles of water transmission and distribution pipelines,up to 48 inches in diameter,with over 55,000 individual service connections. 4.1.3 Reclaimed Water Facilities CCWSD operates one of the largest reclaimed water system in the South Florida Water Management District.Currently,the system serves customers with contractual commitments of 23.4 MGD.The majority of the existing customer base is golf courses,residential communities,environmental mitigation areas,county parks,and roadway medians.There is an additional 43.4 MGD of demand in the service area from entities that have installed dual distribution piping. 4.1.3.1 Water Reclamation Facilities CCWSD currently operates two water reclamation facilities(WRFs).The North County Water Reclamation Facility(NCWRF)and the South County Water Reclamation Facility(SCWRF),which are shown in Figure 4-5. Table 4-7 summaries the capacities of the existing reclaimed water facilities. Table 4-7.Summary of Existing Water Reclamation Facilities1 Facility Name Design Capacity(MGD)2 NCWRF 24.10 SCWRF 16.00 Total 40.10 Information taken from the Collier County 2008 Wastewater Master Plan Update and the 2012 AUIR. 2 The design capacities do not reflect the amount of reclaimed water available from the facilities. The amount of reclaimed water available is based on influent flow and treatment efficiency.For planning purposes,CCWSD considers reclaimed water availability based on 95 percent of the lowest influent day,which is currently around 11 MGD. C,Tlth 4-9 PW/6295/98609/03/11 B.NITABE CH RD OIL WELL RD o J 0 _ I MOKALEE RD Q J m NCRWTP m VANDE-BILT BEACH • w o J CARICA GOLDEN GATE BLVD c' c4 BOOSTER > STATION PINE RID RD w 0) 0 00 -O 0 r r SCRWTP vill� RADIO RD 175 AVIS BLVD �1\ 4 ! G Xv 7 1\k*, MANATEE i- -94,/ BOOSTER • 0 '94-/ii, STATION MANATEE'Qqi o ROAD ASR re ISLE OF CAPRI a BOOSTER STATION Legend y GOOD_ 4 N D • Ezisfing Potable Water Storage Facilities til*m\tb 'BOOSTER A '" . STATION li a‘ errr FIGURE 4-3 COLLIER COUNTY 10-YEAR WATER SUPPLY FACILITIES WORK PLAN N CDM EXISTING CCWSD POTABLE WATER STORAGE FACILITIES Smith 0 7,500 15,000 30,000 45,000 Feet 4-10 16" B•NITABE CH RD 0 Iry iiii w 1ti _ 2 ,i OIL WELL RD - iN 16" 16', Iii- N 30" 12" � 24" .4� 36 2CL _ �� A J m•30" tiN 30" 24" o 1 OE tt ral GOLDEN GATE BLVD I:: Mit iW r D II 1 � o rn ix Or -: U m r _, c 2 2' -n p i -:Af RA• • RD iv 24" 12" 175 A rn 1 DAVI' BLVD 12" M 1, 1 , 2 1 24" C.-s 2 = A,7 _ 16" N 00,6) .1.\, .... 45,,, 6" 1• =Z__\:,. Milike. 1;1441'411tii, T P . ‘4P47f/i3 MATE: MAINS SHOWN ARE 12"OR GREATER. 'EIS Legend .� Water Mains �1 _` . r rr Mil ✓ . FIGURE 4-4 COLLIER COUNTY 10-YEAR WATER SUPPLY FACILITIES WORK PLAN N CCWSD POTABLE WATER TRANSMISSION MAINS DM EXISTING 0 7,500 15,000 30,000 45,000 Smith1 Feet 4-11 Section 4 • Existing Water Supply Facilities 4.1.3.2 Reclaimed Water Pumping,Storage,and Transmission The reclaimed water distribution system,which consists of over 130 miles of transmission and distribution pipeline,is currently divided into two services areas;one in the north and one in the south,that are supplied by the respective WRF.There are a few small interconnects between the two service areas,but the system is hydraulically limited from passing large volumes of water from one service area to the other. Reclaimed water produced at the two water reclamation facilities(WRFs)can be temporarily stored in on-site ponds.Storage of up to 1 million gallons(MG)is also available at the former Pelican Bay WRF,which was decommissioned in 2006 and converted to a reclaimed water storage and pumping facility.Additional storage is achieved in the distribution system which provides 130 MG of wet weather storage.Excess water is pumped into deep injection wells(DIWs)for disposal.Figure 4-6 presents the reclaimed water distribution system. One of the significant issues that the reclaimed water system must contend with is wet weather storage.During the wet season,demand for reclaimed water drops off sharply and CCWSD is forced to put the reclaimed water down its DIWs from which it cannot be recovered.The County has identified this scenario as a waste of a valuable resource and is making efforts to reduce the amount of reclaimed water that is disposed during the wet season.To this end,a reclaimed water/supplemental groundwater ASR system is being developed.Construction of the first of up to five ASR wells was completed in 2007. However,due to changes in Federal and State regulations,the well was never operationally tested. In 2012,the CCWSD authorized a construction project to extend the depth of the well below the Underground Source of Drinking Water(USDW). The construction project is scheduled for completion in July 2013 with operational cycle testing to follow. Following 18 months of cycle testing,the ASR will be put into service,where it is expected to provide between 0.5 and 1 MGD of reclaimed water to meet peak season demands. 4.1.3.3 Supplemental Wellfields In addition to the two existing WRFs pumping and storage facilities,CCWSD utilizes two supplemental wellfields to meet its contractual requirements. The locations of the two wellfields,known as the Pelican Bay(Livingston Road)Wellfield and the Immokalee(Mule Pen Quarry)Wellfield,are shown in Figure 4-6.The wellfields are permitted under CUP 11-00052-W,described in Section 4.1.1,which allows CCWSD to withdraw water from the LT Aquifer in the Pelican Bay Wellfield and the WT Aquifer at the Immokalee Wellfield,to meet peak demands within the reclaimed water distribution system.A summary of the wells that make up these wellfields is provided in Table 4-8. Smith 4-12 PW/6295/98609/03/11 B•NITA BE CH RD OIL WELL RD 0 o NCWRF I MOKALEE RD 0 J c‘,, a'mm VANDE'BILTBEACH o Z Q GOLDEN GATE BLVD J C7 cC w > w PINE RID RD D o) G7 > 70 rn 0 o 0 0 r A Hm v H I-n r Z U RADIO RD 175 DAVIS BLVD S -.,1 *SCWRF Tq4ii'14 ' v_i to rn ce 47 , , „,... t Legend Existng Water Reclamation Facilities FIGURE 4-5 COLLIER COUNTY 10-YEAR WATER SUPPLY FACILITIES WORK PLAN N CDM EXISTING CCWSD WATER RECLAMATION FACILITIES Smith 0 7,500 15,000 30,000 45,000 Feet 4-13 BONITA BE• H RD 1-fil 12" OIL WELL RD am N 12'24"1. 2'" IMMOKALEE RD 24" I it NCWRF ^ 2p„ w ...> 2r, 20" V. DERBILT BEACH 'cop GOLDEN GATE BLVD rn • D 20l PINE RIDGE RD 0 A C lJ O z N a m GOLDEN GATE P- ■ Y T D Z 1 75 X RADIO RD N iAVIS BLVD 16" t 'ICA Ei 20" 'S1 • 2" 111 2 .. SCWRF*$ c) GS,. -;.t 72. -v NOTE: N MAINS SHOWN ARE 7cp> 12"OR GREATER. 4 Legend IQ Water Main Existing Water Cr) 7,,(i RecIamat on Facilities X 'r,9/< ■Supplemental Wellfields FIGURE 4-6 COLLIER COUNTY 10-YEAR WATER SUPPLY FACILITIES WORK PLAN N CEXISTING CCWSD RECLAIMED WATER DISTRIBUTION SYSTEM Siiiith 0 7,500 15,000 30,000 Feet 4-14 Section 4 • Existing Water Supply Facilities Table 4-8.Summary of Existing CCWSD Supplemental Wellsi Well No. Aquifer Total Depth(ft) Depth of Casing(ft) Diameter(in) Capacity(gpm) 1 LT 100 50 10 300 2 LT 100 50 10 300 3 LT 100 50 10 300 4 LT 100 50 10 300 5 LT 100 50 10 300 6 LT 100 50 10 300 7 LT 100 50 10 300 8 WT 35 20 10 500 9 WT 35 20 10 500 10 WT 35 20 10 500 11 WT 35 20 10 500 12 WT 35 20 10 500 13 WT 35 20 10 500 1 Information on existing wells taken from CUP#11-00052-W. 4.2 Immokalee Water and Sewer District (IWSD) 4.2.1 Water Supply Permits The IWSD maintains one CUP for potable water supply.The details of the CUP are presented in Table 4-9. Table 4-9. Consumptive Use Permits Issued by SFWMD to the Immokalee Water and Sewer District Consumptive Use Aquifer Number of Expiration Annual Maximum Permit Permitted Date Allocation Monthly Wells (MG) Allocation (MGD) 11-00013-W Lower Tamiami 16 5/23/2031 1515 147.20 4.2.2 Potable Water Facilities 4.2.2.1 Wellfields Currently,the IWSD operates three wellfields; one adjacent to each of its WTPs.The locations of each of these wellfields and WTPs are illustrated in Figure 4-7.The wells maintained by the IWSD tap the LT Aquifer,which is a traditional freshwater source.Table 4-10 summarizes the existing wells operated by the IWSD. 4.2.2.2 Water Treatment Facilities The IWSD is served by three interconnected water treatment facilities;the Jerry V.Warden WTP,the Airport WTP and the Carson Road WTP,which are shown in Figure 4-7. Smith 4-15 PW/6295/98609/03/11 Section 4 • Existing Water Supply Facilities Table 4-10. Summary of Existing IWSD Potable Water Wells Well No. Aquifer Total Depth(ft) Depth of Casing Diameter Capacity(gpm) (ft) (in) 7 LT 225 140 6 400 8 LT 315 230 8 200 9 LT 275 250 8 225 10B LT 275 236 8 225 11 LT 278 234 8 250 12 LT 200 140 8 350 13 LT 200 140 8 350 14 LT 244 134 8 400 102 LT 200 154 6 400 103 LT 210 140 8 200 104 LT 210 128 8 350 105 LT 187 137 8 400 106 LT 190 145 8 400 201 LT 180 100 8 350 202 LT 180 100 8 350 204 LT 180 116 8 400 1 Information on existing wells taken from CUP#11-00013-W. The Jerry V.Warden WTP is located on the west side of Sanitation Road,south of CR-29.Freshwater from the LT Aquifer is treated at the plant using lime softening(LS).The plant has a finished water capacity of 2.25 MGD. The Carson Road WTP is located on the west side of Carson Road,north of Lake Trafford Road.The plant utilizes LS to treat the freshwater from the LT Aquifer and has a finished water capacity of 2.0 MGD. The Airport WTP is located east of New Market Road East,north of CR-846.LS is utilized at the plant to treat freshwater from the LT Aquifer.The finished water capacity of the plant is 1.35 MGD.A summary of the existing water treatment facilities is provided in Table 4-11.In addition to identifying the design capacity of each treatment train,the amount of raw water required to make the design capacity is also provided. Table 4-11.Summary of Existing IWSD Water Treatment Facilities' Facility Name Design Raw Water Raw Water Traditional/Alternative Capacity Requirement2 Source (MGD) (MGD) Jerry V.Warden WTP 2.25 2.32 LT Traditional(Fresh) Airport WTP 1.35 1.39 LT Traditional(Fresh) Carson Road WTP 2.00 2.06 LT Traditional(Fresh) Total 5.60 5.77 1 • Information on existing water treatment facilities taken from the 2012 Lower West Coast Water Supply Plan Update. 2 Raw water requirement is the amount of raw water need to make a certain amount of finished water.It is calculated by dividing the finished water capacity by the efficiency of the treatment process. Smith 4-16 PW/6295/98609/03/11 N 4 Z "IIIIIIC . i t•-• g g A ■ �` 'fI / $ m n U 2 C� n >NN A N h N <cz ._ N I. J a tea` �`'�' `1 ER i ,.,, :„.. „:„ , .,,, N ^ „. N I n \�\��`\" 0 P';2 p gy C.R.�� H III " :sN -Niti. } J S.R. 29 S R. 29 , a o m g p Y R a a o F.; Y f T.r. cv co J_ _ 0 y CO N ! .- N N }y �0 \r N rim.y _. PEPPER RD. _ 1111.41 cn o — N ...• N I N } Z N ' zU) 'O .- `� HI ' 2 9 N o X IXOw c) m 2 < U W J -J r O J m ' 2 N V 1 F W 2 p 3 O „ 9i 'n o a z r W 0_ AiNn 3 33l O N CO L cc �pn 3 "41- IMO x 1 0€111 � 4 Section 4 • Existing Water Supply Facilities 4.2.2.3 Pumping,Storage, and Transmission The existing transmission facilities consist of transmission pipelines,water storage tanks,and pumping facilities.The transmission facilities utilized by IWSD are shown in Figure 4-7.Water from the Jerry V.Warden WTP is pumped to one ground storage tanks,with a total capacity of 1.80 MG, located on the plant site.Water from the Carson Road WTP is pumped to two 1.0 MG ground storage tank with a total storage capacity of 1.5 MG.Water from the Airport WTP is pumped to an on-site 0.75 MG ground storage tank.From the storage tanks water enters the distribution system which consists of mains ranging in size from 2-inch to 12-inch.The distribution system contains approximately 100 miles of mains. Table 4-12 summarizes the existing water storage facilities utilized by IWSD. Table 4-12.Summary of Existing IWSD Water Storage Facilities' Facility Name Tank Volume(MG) Usable Storage Volume(MG) Jerry V.Warden WTP 1.802 1.50 Carson Road WTP 2.003 1.50 Airport WTP 0.75 0.75 Total 4.55 3.75 Information provided in email from IWSD on September 23,2013. 20.3 MG tank has been taken out of service. 3 0.5 MG tank has been taken out of service. 4.2.3 Reclaimed Water Facilities Currently,IWSD disposes of all effluent wastewater via an on-site spray irrigation field,percolation ponds,or deep well injection. IWSD is served by one WRF,which is located on White Way.The WRF is capable of producing 2.50 MGD of reclaimed water.Table 4-13 summarizes the capacity of the existing reclaimed water facility. E Table 4-13.Summary of Existing IWSD Water Reclamation Facility' Facility Name Design Capacity(MGD) IWSD WRF 2.50 Total 2.50 Information on existing water reclamation facilities taken from the 2012 Lower West Coast Water Supply Plan Update. 4.3 Florida Governmental Utility Authority (Golden Gate) (FGUA) 4.3.1 Water Supply Permits The FGUA maintains one CUP for potable water supply.The details of the CUP are presented in Table 4-14. Table 4-14. Consumptive Use Permits Issued by SFWMD to FGUA Consumptive Aquifer Number of Expiration Annual Average Day Maximum Use Permit Permitted Wells Date Allocation Allocation Monthly (MG) (MGD) Allocation (MG) LT 3(proposed) 3/10/2030 495 2.62 41.25 11-00148-W WT 9 3/10/2030 752 2.68 62.64 Total 11 1247 5.30 103.89 Smith 4-18 PW/6295/98609/03/11 Section 4 • Existing Water Supply Facilities 4.3.2 Potable Water Facilities 4.3.2.1 Wellfields Currently,FGUA operates one wellfield,with wells on or adjacent to its WTP site.The locations of these wells and WTP are illustrated in Figure 4-8.The wells maintained by FGUA tap the WT Aquifer, which is a traditional freshwater source. The three permitted LT wells are proposed and discussed in Section 5.3.1.1. Table 4-15 summarizes the existing wells operated by FGUA. Table 4-15. Summary of Wells Operated by FGUA1 Well No. Aquifer Total Depth(ft) Depth of Casing(ft) Diameter(in) Capacity(gpm) GG-1 WT 22 15 6 200 GG-2A WT 22 15 8 200 GG-3 WT 45 35 6 160 GG-4 WT 45 35 8 200 GG-5 WT 22 15 8 250 GG-8 WT 22 15 8 250 GG-9A2 WT 33 8.5 14 200 GG-10 WT 22 11.6 8 200 GG-11 WT 25 15 8 200 1 Information on existing wells taken from CUP#11-00148-W. 2 Well GG-9A has been disconnected per the 2013 FGUA Updated Capacity Analysis Report. 4.3.2.2 Water Treatment Facilities FGUA operates one WTP,the Golden Gate Water Treatment Plant,which is located west of CR-951, south of Golden Gate Parkway,as shown in Figure 4-8.The WTP has a finished water capacity of 1.22 MGD using LS,which is augmented by 0.87 MGD of RO for additional capacity. A summary of the existing water treatment facilities is provided in Table 4-16.In addition to identifying the design capacity of each treatment train,the amount of raw water required to make the design capacity is also provided. Table 4-16.Summary of Existing FGUA Water Treatment Facilities1 Facility Name Design Raw Water Raw Traditional/Alternative Capacity Requirement2 Water (MGD) (MGD) Source Golden Gate WTP(LS) 1.23 1.38 WT Traditional(Fresh) Golden Gate WTP(RO) 0.87 1.16 WT Traditional(Fresh) Total 2.10 2.54 1 Information on existing water treatment facilities taken from the 2013 FGUA Updated Capacity Analysis Report. 2 Based on Monthly Operating Reports submitted to FDEP. Smith 4-19 PW/6295/98609/03/11 0 N V 1 z -4111( , I z L o � ba 1� 1 g. i�k4bY°r B ER /, / b„, hc ,) iiiiir,-.‘..,,, _,;,..,,,, .. •_,,_ ____ .,„ _ 2. INA °) �• m 1_1 1 / I W W . 1� \ A • ; p H + I_ 0 V W ce 4. LL I- // I QIQ \._ / i g` 0- 111 < , \ / w z AZ %._ = 0© X w N a�� mg r9I gk ∎ice o Z M iii L 0 �m 0I— Qo) w LL -I ° _W x ® z� _d!� �^ o Q LL gI �� 2 x g9 J �' —1 ism W J 1 II 1 tl 11 1 2 x U. 'I x \ ' I 0:ii,...„. 1 1 1 Ill I y Z�a F • _ I r� $ • _Z J X 1/+1 1 a ! x� J W Y " iei)x moo g 2P2' q Hi fir §51 -o,ru � , IV Z ��La..� s w grI f x Ps' Wg — x $g g'2 LBY4l M,B[rif5 die I- ff0 I 0 E U . . Section 4 • Existing Water Supply Facilities 4.3.2.3 Pumping,Storage, and Transmission The existing transmission facilities consist of transmission pipelines,water storage tanks,and pumping facilities.The transmission facilities utilized by FGUA are shown in Figure 4-9.Water from the WTP is pumped to a 0.52 MG ground storage tank,located on the plant site.From the storage tank water enters the distribution system which consists of mains ranging in size from 2-inch to 14-inch. The distribution system contains approximately 42.5 miles of mains.A booster pump station with a 1 MG ground storage tank on Green Boulevard is used to maintain water pressures within the distribution system.Table 4-17 summarizes the existing water storage facilities utilized by FGUA. Table 4-17.Summary of Existing FGUA Storage Facilities1 Facility Name Tank Volume(MG) Usable Storage Volume(MG) Golden Gate WTP Tank 0.52 0.52 Green Blvd.Booster Pump Station Tank 1.00 1.00 Total 1.52 1.52 Information of existing water storage facilities take from the 2013 FGUA Updated Capacity Analysis Report. 4.3.3 Reclaimed Water Facilities The FGUA currently disposes of treated wastewater using rapid infiltration basins (RIBs)and deep well injection.The existing permitted capacity of the RIB system is 1.25 MGD. However,in 2012 0.49 MGD of treated effluent was reused through these rapid infiltration basins.The remaining 0.65 MGD of treated effluent was disposed of through deep well injection. Currently,the FGUA does not operate any reclaimed water facilities,however,the FGUA has committed to the FDEP to execute a reclaimed water project that will provide at least 200,000 gpd of reclaimed water to be used on the Golden Gate Golf Course. 4.4 Orange Tree Utility Company (OTUC) 4.4.1 Water Supply Permits The OTUC maintains one CUP for potable water supply.The details of the CUP are presented in Table 4-18. Table 4-18. Consumptive Use Permits Issued by SFWMD to OTUC Consumptive Use Aquifer Number of Expiration Annual Average Day Maximum Permit Permitted Date Allocation Allocation Monthly Wells (MG) (MGD) Allocation (MG) 11-00419-W LT 6 11/11/2009 313 2.59 37.74 4.4.2 Potable Water Facilities 4.4.2.1 Wellfields Currently,OTUC operates one wellfield in the vicinity of its WTP.The locations of these wells and WTP are illustrated in Figure 4-10.The wells maintained by OTUC tap the LT Aquifer,which is a traditional freshwater source.Table 4-19 summarizes the existing wells operated by the utility. SnMi-Ith 4-21 PW/6295/98609/03/11 N N V w 7 CI f Z 0 W 1-N <<e W z c,ti ca z z NW Nt. yWJH PWP W1F;- tut WFF3LL W;F uummuwuumi•imm�aiguni uunm;e Lr n: ..71Yr(Y.IRI■Y.,.YsRR.LI1 ipguuII I. ■ •�''&. 1 Is.111111111.Lu1I1IU.Anal.IOII.1.■uI,IO1i..■!1 1■1 •I.Rv ° Z —�•Il I•U.1\• I IWY• IOR11.. +.1+Rn c.��JIIII r ■�� f 0� ::- ,.,....1.... :,�11111�;=l 11111■. 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I .•:.�•.f.•• ,o•♦ :... ^� 3C" Q Z 11t■ Ammon.RLL L11...1..yq:i. .1 :� ••Oi)•i 1�.\ �RRR .1u1n.u.1► ..._._ LL::: ..1111:±I —_1T1R�/uI i1 ��.�.� •:•.., ","4:7:410:10,41,01,:.C,...[5_ 1 .1-:.�.::i Z Lt L.1101101.1••OM.■■■,,i.t� ■■■ pp■.■;■ ♦♦,♦. 'f♦♦ ♦Y �.■l.sl . r O jig ♦ ♦�♦. .RIM h I- .r comma■11111 w.rr:Bill ♦♦ , ♦♦ ♦ 1 all a@ I.�1s 1.11I ♦ ♦ ♦ 1111 1118 .Yt �.I!!1.R•,1 11III,IP•■ar:: � ♦♦ � ♦ ♦ II •- ■ Il.r. r■r. ',al •� v t♦�♦;♦♦♦♦♦,. 1YYi....RY kli: 1^ W W II : . wrrr JE r-1E 1E �� 4.:44 11 7 I1.: ' F. L� .� C_ •ter- + Fir:C: i•♦•1 7t♦O� ow- ♦ia+a..I.nog:C�•( ''!♦ j♦ii♦♦ ; � c0 W :ruYa.►♦ Tel:**. �.o i s::I ' % p\♦..Va... ems 3C 7E (' W W J R ♦ . ♦ 3 O •" I- f„r :• •�i '>� f ♦♦•- p ��I � ri^i'Vt.7 ...RYA �° Q I i Section 4 • Existing Water Supply Facilities Table 4-19. Summary of Wells Operated by OTUC Well No. Aquifer Total Depth(ft) Depth of Casing Diameter Capacity(gpm) (ft) (in) PW1 LT 180 70 12 300 PW2 LT 180 70 12 300 PW3 LT 180 70 12 300 PW4 LT 180 70 12 300 PW5 LT 180 70 12 300 PW6 LT 180 70 12 300 Information on existing wells taken from CUP#11-00419-W. 4.4.2.2 Water Treatment Facilities OTUC operates one WTP,which is located east of SR-846,north of CR-858 as shown in Figure 4-10. The WTP has a finished water capacity of 0.75 MGD using membrane softening(MS). A summary of the existing water treatment facility is provided in Table 4-20.In addition to identifying the design capacity,the amount raw water required to produce the design capacity is also provided. Table 4-20.Summary of Existing OTUC Water Treatment Facilities" Facility Name Design Raw Water Raw Water Traditional/Alternative Capacity Requirement2 Source (MGD) (MGD) Orange Tree WTP 0.75 0.94 LT Traditional(Fresh) Total 0.75 0.94 1 Information on existing water treatment facilities taken from the 2012 Lower West Coast Water Supply Plan Update. 2 Raw water requirement is the amount of raw water needed to make a certain amount of finished water.It is calculated by dividing the finished water capacity by the efficiency of the treatment process. 4.4.2.3 Pumping, Storage,and Transmission The existing transmission facilities consist of a water storage tank at the WTP and transmission pipelines.The water storage tank at the WTP has a capacity of 0.75 MG and the transmission pipelines range in size from 3-inch to 12-inch and total approximately 9 miles in length.Table 4-21 summarizes the water storage available in the Orange Tree Utility System. Table 4-21.Summary of Existing OTUC Storage Facility' Facility Name Tank Volume(MG) Usable Storage Volume(MG) Orange Tree WTP 0.75 0.73 Total 0.75 0.73 1 Information on existing water storage facilities taken from CUP#11-00419-W 4.4.3 Reclaimed Water Facilities Currently,OTUC disposes of all effluent wastewater via RIBs.The existing permitted capacity of the RIB system is 0.4 MGD. Smith 4-23 Pw/6295/98609/03/11 N V o 1- a it % °- z ( } W wS d � ayj 6 Er __f_ G ) a .--„, 9 o N _co rn 3 3 0 M O 4 x Z a J CL N UT M N N 0 '^ ALL: ) N LW o Q W X X J y _ N N M J Q IMMOK LEE RD. > CL o M N o a S S WNW o ., •, 'e LEVARD n W I— °m Q rn L. -' o c0 N ') () 0 cc ~ � C r '„ Z to 00 Z co II__ m x airow•MI0115 OW ce w w - M n J -' 0 ci U w Q Y N � I N M I (n w J n Q MCZ - N co M kn a,_ COLLIER BO LEVARD CI try Section 4 • Existing Water Supply Facilities 4.5 Ave Maria Utility Company, LLLP (AMUC) 4.5.1 Water Supply Permits AMUC maintains one CUP for potable water supply.The details of the CUP are presented in Table 4- 22. Table 4-22. Consumptive Use Permits Issued by SFWMD to AMUC Consumptive Aquifer Number of Expiration Annual Average Maximum Use Permit Permitted Date Allocation Day Monthly Wells (MG) Allocation Allocation(MG) (MGD) 11-02298-W LT 3 1/9/2017 372 3.02 40.3 4.5.2 Potable Water Facilities 4.5.2.1 Wellfields Currently,AMUC operates one wellfield in the vicinity of its WTP. The wells maintained by AMUC tap the LT Aquifer,which is a traditional freshwater source.Table 4-23 summarizes the existing wells operated by the utility. Table 4-23. Summary of Wells Operated by AMUC Well No. Aquifer Total Depth(ft) Depth of Casing Diameter Capacity(gpm) (ft) (in) PWS-1 LT 83 61 12 700 PWS-2 LT 80 59 12 700 PWS-3 LT 71 50 12 700 1 Information on existing wells taken from CUP#11-02298-W. 4.5.2.2 Water Treatment Facilities AMUC operates one WTP,which is located west of Camp Keais Road,north of CR-858.The WTP has a finished water capacity of 0.99 MGD using MS. A summary of the existing water treatment facility is provided in Table 4-24.In addition to identifying the design capacity of each treatment train,the amount of raw water required to make the design capacity is also provided. Table 4-24.Summary of Existing AMUC Water Treatment Facility' Facility Name Design Raw Water Raw Water Traditional/Alternative Capacity Requirement Source (MGD) (MGD) Ave Maria WTP 0.99 1.15 LT Traditional(Fresh) Total 0.99 1.15 1 Information on the water treatment facilities was taken from the 2012 Lower West Coast Water Supply Plan Update. Raw water requirement is the amount of raw water need to make a certain amount of finished water.It is calculated by dividing the finished water capacity by the efficiency of the treatment process. 4.5.2.3 Pumping, Storage, and Transmission The existing transmission facilities consist of a water storage tank at the WTP and transmission pipelines.The water storage tank at the WTP has a capacity of 1.5 MG.Table 4-25 summarizes the water storage available in the Ave Maria Utilities System. CPlWIth 4-25 PW/6295/98609/03/11 Section 4 • Existing Water Supply Facilities Table 4-25.Summary of Existing AMUC Storage Facility' Facility Name Tank Volume(MG) Usable Storage Volume(MG) AMUC WTP 1.50 1.50 Total 1.50 1.50 1 Information on existing and planned water treatment facilities was taken from the Preliminary Design Report for Ave Maria Utility Company,LLLP and Florida Department of Environmental Protection as prepared by CH2M Hill,Inc.,June 2004 and supplemented with comments received from AMUC in a letter dated September 20,2007. 4.5.3 Reclaimed Water Facilities AMUC is served by one WRF,which is located within the development.The WRF is capable of producing 0.90 MGD of reclaimed water.Reclaimed water is pumped from the WRF to three reclaimed water storage ponds,which serve as the source for the Town and University's irrigation system and have a combined capacity of 23.00 MG.Reclaimed water is the most important element of the AMUC Conservation Plan,presented in detail in Section 7,and will be utilized to the fullest extent possible for irrigation of the Town and University. AMUC utilizes 100 percent of the reclaimed water generated. Table 4-26 summarizes the capacity of the existing reclaimed water facility. Table 4-26.Summary of Existing AMUC Water Reclamation Facility' Facility Name Design Capacity(MGD) AMUC WRF(Phase 1) 0.90 Total 0.90 1 Information on existing water reclamation facilities taken from the 2012 Lower West Coast Water Supply Plan Update. Smith 4-26 PW/6295/98609/03/11 Section 5 Planned Water Supply Facilities 5.1 Collier County Water-Sewer District (CCWSD) CCWSD has been and continues to be a leader in the development of alternative water supplies and integrated water resource management in Florida. Starting in the mid-1980s CCWSD realized that it could not meet the future demands of its customers solely with traditional water supplies.CCWSD committed to a program of alternative water supplies that included the use of brackish groundwater and ASR for potable supply,and reclaimed water,supplemental water wellfields and ASR for irrigation purposes. Given the success that CCWSD has had in meeting its demands with alternative water supplies,CCWSD embarked over the past 18 months to identify better ways to meet future water supply demands within its service area. The result of this effort is a paradigm shift,from thinking of potable water and irrigation water demand as two separate needs to seeing the demands as inextricably intertwined. To better serve the needs of both potable water and irrigation water demand at the best value cost for the customer,CCWSD has begun development of a new business model which will shift the focus from development of additional potable water supplies to meeting a large portion of the overall water demand with irrigation quality water supplies. CCWSD currently has an annual average daily potable demand of 24.1 MGD and an annual average daily irrigation quality demand of 15.8 MGD. The ratio of irrigation quality demand to potable demand is approximately 40:60. Of the current potable demand,approximately 1/3 is attributable to irrigation in older parts of the system. As stated in Section 4.1.3 there is an additional 43.4 MGD of irrigation quality demand in the service area from entities that have installed dual distribution piping. The vision for CCWSD is optimizing water resource usage by substituting IQ water for non-potable uses such as irrigation,which will provide both economic and environmental benefits. Through implementation of the vision,it is anticipated that within the next 20 years the source of water can shift from 40 percent IQ water and 60 percent potable water to 60 percent IQ water and 40 percent potable water. This shift will occur as supplemental water supplies and ASR storage components are added to the IQ water system and utilized to supply IQ water to customers,reserving higher quality water supplies for true potable use. It is anticipated that a portion of future potable water demand will be offset by substituting IQ water for potable water currently being used for irrigation. As a result of meeting irrigation demands with IQ water,90 percent instead of 70 percent of potable water delivered to customers will be returned to the water reclamation facilities to be reused. In addition to meeting irrigation demands,the focus on additional IQ water supplies instead of only potable water supplies provides significant benefits to the environment. By supplying IQ water to more customers,the use of potable water for irrigation and private irrigation systems will decrease. Further,the CCWSD IQ water distribution system often provides for a better temporal distribution of water to the natural system in that IQ water is provided at low rates over longer periods than typical rainfall events and is supplied during low rain periods when the aquifer system is most able to accommodate recharge thereby reducing runoff. Additionally,CCWSD's IQ water distribution system provides a net addition of freshwater to the surficial aquifer system through irrigation with treated CDAth 5-1 PW/6295/98609/03/11 Section 5 • Planned Water Supply Facilities water from the brackish Hawthorn aquifer system,which is otherwise trapped in very long term and deep hydrologic cycles,bringing it into the daily water cycle. In order to supply additional irrigation water more efficiently,CCWSD will pursue additional allocations of fresh water.This strategy is supported by recently identified groundwater trends. Through its rigorous groundwater monitoring program,CCWSD identified trends in water level data from both the Lower Tamiami(LT)Aquifer and the Water Table(WT)Aquifer(connected to surface water flows,i.e.,wetlands)in and around the CCWSD's Golden Gate Tamiami Wellfield.The data indicate that despite extended drought conditions and increased pumping from the LT Aquifer,water levels in key indicator wells are remaining steady and in some cases increasing. These trends provide evidence that the total water management approach taken by the CCWSD is yielding environmental benefits and suggest that additional pumping of the LT Aquifer is possible without impacting the WT Aquifer or wetlands,which is the main concern that directed CCWSD away from traditional sources more than twenty years ago. CCWSD's intent to pursue additional freshwater withdrawals from the LT Aquifer within the integrated total water management approach is consistent with the 2012 Lower West Coast Water Supply Plan Update (LWCWSP)published by the SFWMD,which states on page 4,"Some traditional water supply development may be possible where appropriate local hydrologic conditions are present and regulatory requirements are met."The LWCWSP also states(on page 39),"While the development of fresh groundwater in many areas of the LWC Planning Area has been maximized,fresh groundwater maybe available in some places.It is not the intent of this update to require water users,including Rural Areas of Critical Economic Concern, to use alternative water supplies when fresh water is available.As urban growth occurs,it is anticipated that some agricultural land will transition to urban community uses.These existing agricultural areas likely have consumptive use permits for use of traditional groundwater for crop irrigation.While consumptive use permits cannot be directly transferred from one land use type to another,the conversion of these lands from agriculture to another land use may result in available fresh groundwater for the new land use.It is important to note that there are different considerations for different water use categories,based on specific needs."Likewise,on page 41,"Additional supplies may be developed and permitted from these traditional(historical)sources depending on the quantities required,local resource conditions,changing land use,and the viability of other supply options." In addition to the water level trends observed in its monitoring wells,CCWSD has performed and is performing multiple studies to determine the viability of the LT Aquifer for additional allocations.To date,CCWSD has developed a calibrated groundwater model and utilized the MIKESHE model developed by the Army Corp of Engineers for the Picayune Strand Restoration Project to determine the potential impact of additional freshwater withdrawals on wetlands. The modeling efforts performed to date indicate that there would be no measurable impact on wetlands from moderate additional withdrawals. CCWSD has also constructed freshwater monitoring well clusters around the County that will provide longer term water level data for areas of the County away from its wellfields and developed four wetland monitoring sites within the Golden Gate Estates to verify that no wetland impacts are being caused by withdrawals from the Golden Gate Tamiami Wellfield. CCWSD is confident that the modeling efforts performed to date,and its on-going water level monitoring program,will provide the required assurances to allow the SFWMD to increase its permitted allocation of freshwater from the LT Aquifer. CCWSD will develop documentation demonstrating how existing and planned IQ water supplies give rise to additional potable water supplies. This analysis will consider the potential availability of impact offsets and substitution Smith5-2 PW/6295/98609/03/11 Section 5 • Planned Water Supply Facilities credits in accordance with new Florida Department of Environmental Protection and SFWMD rules. CCWSD anticipates that its planned IQ water infrastructure development will garner significant impact offsets and/or substitution credits in further support of its request to the SFWMD for additional allocations of freshwater to meet projected customer demand.These water resource benefits and associated availability of withdrawals will be in addition to the benefits already provided by CCWSD's existing IQ water system. For these reasons,CCWSD has initiated the shift in its business model based on an ability to obtain a reasonable amount of freshwater to maximize the efficiency of existing infrastructure and planned AWS projects. 5.1.1 Potable Water Facilities 5.1.1.1 Wellfields As part of the CCWSD plan to meet future water supply needs it intends to build the NERWTP Wellfield Phase 1.The NERWTP Wellfield Phase 1 will be made up of wells tapping the LT Aquifer,the HZ1 Aquifer and the LH Aquifer.The wells will serve the NERWTP Phase 1,which will treat the water using ion exchange (IE) for fresh water and LPRO for brackish water.The wellfield is scheduled to come online in 2023 to serve the first phase of the NERWTP.Table 5-1 summarizes the planned wells in the NERWTP Wellfield Phase 1.The location of the NERWTP Wellfield Phase 1 is illustrated in Figure 5-1. Table 5-1. Planned NERWTP Wellfield Phase 1 Summaryl Well No. Aquifer Total Depth(ft) Depth of Casing(ft) Diameter(in) Capacity(gpm) LT-1 LT 120 75 16 1000 LT-2 LT 120 75 16 1000 LH-1 LH 1000 700 16/122 1000 LH-2 LH 1000 700 16/122 1000 LH-3 LH 1000 700 16/122 1000 LH-13 LH 1000 700 16/122 1000 LH-14 LH 1000 700 16/122 1000 LH-15 LH 1000 700 16/122 1000 LH-16 LH 1000 700 16/122 1000 HZ1-13 HZ1 550 400 16/122 1000 HZ1-14 HZ1 550 400 16/122 1000 1 Information on planned wells taken from CUP#11-00249-W and the Collier County 2008 Water Master Plan Update. 2 16 inch casing to 100 feet,then 12 inch casing to production casing depth. Table 5-2 identifies the major tasks required to build the wellfield,along with the funding source that will be utilized and scheduled dates for studies,property acquisition,design,permitting,and construction. Table 5-2. Major Tasks Required to Build Planned CCWSD NERWTP Phase 1 Wellfield Year(s)of Execution Funding Feasibility Property Facility Name Source Study Acquisition Design Permitting Construction NERWTP Phase Impact Fees Complete Complete Complete 2018-2020 2020-2023 1 Wellfield Smith 5-3 PW/6295/98609/03/11 BONITA BE' H RD 1-.0 NERWTP OIL WELL"D ;7, 41 IMMOKALEE RD a J m NCRWTP C/) VANDE"BILT BEACH 0 Q LL CD CC Lu I GOLDEN GATE BLVD w v IA w ° MO v PINE RIDGE RD M 1 u C I Cl) r 0 a T a O O 0 GOLDEN GATE P- ■ Y T y r SCRWTP z X RADIO RD 175 DAVIS BLVD --/.. I GS 4 It rn G6v 0 Legend T'9 • Existing Wells "iiv$,,,,,,,5 ����i -Existing Raw Water Transmision Lines os rf -9/z r —Planned Raw Water Transmission Lines CO • Planned Wells FIGURE 5-1 COLLIER COUNTY 10-YEAR WATER SUPPLY FACILITIES WORK PLAN C DM EXISTING AND PLANNED CCWSD N myth WELLFIELDS AND RAW WATER TRANSMISSION MAINS 0 7,500 15,000 30,000 Feet 5-4 Section 5 • Planned Water Supply Facilities 5.1.1.2 Water Treatment Facilities The CCWSD is currently served by two WTPs;the NCRWTP and the SCRWTP.As mentioned in the previous subsection,the CCWSD intends to construct an additional treatment facility,the NERWTP to meet future demands.The locations of the existing and planned facilities are shown in Figure 5-2. The location of the planned NERWTP is approximately one mile north of CR-858(Oil Well Road) and one mile east of SR-846 (Immokalee Road) in the northeastern quadrant of the service area.The plant will utilize IE to treat fresh groundwater withdrawn from the LT and HZ1 aquifers.Water from the LH Aquifer will be treated using LPRO.The first phase of the plant is currently scheduled to come online in 2023,will have a reliable capacity of 10 MGD. The plant will be capable of expansion to an ultimate capacity of 45 MGD. As stated in Section 4.1.2.2,the NCRWTP is located on the north side of Vanderbilt Beach Road Extension east of CR-951 in the northeastern quadrant of the service area and the SCRWTP is located near the intersection of CR-951 and I-75 about 5.5 miles south of the NCRWTP. A summary of the existing and planned water treatment facilities is provided in Table 5-3. In addition to identifying the design capacity of each treatment train,the amount raw water required to make the design capacity is also provided. Table 5-3. Summary of Existing and Planned CCWSD Water Treatment Facilities1 Facility Name Year Design Raw Water Raw Traditional/ Project Identified Online Capacity Requirement2 Water Alternative In LWCWSP (MGD) (MGD) Source NCRWTP MF Online 12.0 14.1 LH Traditional N/A (Fresh) NCRWTP LPRO Online 8.0 10.7 LH/HZ1 Alternative N/A (Brackish) SCRWTP LS Online 12.0 12.4 LTA Traditional N/A (Fresh) SCRWTP LPRO Online 20.0 26.7 LH/HZ1 Alternative N/A (Brackish) NERWTP Phase 1 LPRO 2023 7.5 10.0 LH Alternative Yes (Brackish) NERWTP Phase 1 Ion Traditional Exchange 2023 2.5 2.6 LTA/HZ1 (Fresh) No Total 62.0 76.4 Information taken from the Collier County 2008 Water Master Plan Update and the 2012 AUIR. Raw water requirement is the amount of raw water need to make a certain amount of finished water.It is calculated by dividing the finished water capacity by the efficiency of the treatment process. 711111th 5-5 PW/6295/98609/03/11 BONITA BE' H RD NERWTP lill OIL WELL"D ?' ] 4 IMMOKALEE RD NCRWTP IM o m o ii,VANDE' BILT BEACH o J U- w GOLDEN GATE BLVD W D w a JO O 0 O 00 X PINE RIDGE RD u cn C I A C Z 0 0 0 0 0 Mr- --I GOLDEN GATE P t Y SCRWTP > Z 7 RADIO RD 175 DAVIS BLVD GS It 0)Cr) &d, CL 0 7 T Legend xi'jiiyM/ -5ristng Potable Water Treatment Facilities CC -Proposed Potable Water fn ���� Treatment FadlRies FIGURE 5-2 COLLIER COUNTY 10-YEAR WATER SUPPLY FACILITIES WORK PLAN C DM EXISTING AND PLANNED CCWSD N Smith 0 POTABLE WATER TREATMENT FACILITIES A 7,500 15,000 30,000 1 Feet 5-6 Section 5 • Planned Water Supply Facilities Table 5-4 identifies the major tasks required to build each of the planned water treatment facilities, along with the funding source that will be utilized and the scheduled dates for studies,property acquisition,design,permitting,and construction. Table 5-4. Major Tasks Required to Build Planned CCWSD NERWTP Phase 1 Year(s)of Execution Facility Feasibility Property Name Funding Source Study Acquisition Design Permitting Construction NERWTP Impact Fees Complete Complete Complete 2018-2020 2020-2023 Phase 5.1.1.3 Pumping, Storage, and Transmission The planned transmission facilities consist of transmission pipelines,water storage tanks,aquifer storage and recovery(ASR) systems,and pumping facilities.The pumping and storage facilities utilized by CCWSD are shown in Figure 5-3.The planned pumping facilities will include high service pumps at the new NERWTP.Additional booster pumping stations and an in-line booster pump station may be required to meet demands,but are not planned for construction during the planning period out to 2023.Ground storage tanks at the proposed treatment facility will provide system storage and reserve capacity to help meet peak hourly demands of the system.Additionally,potable water will be stored at various strategic points in the CCWSD distribution system to help meet diurnal peak system and fire flow demands. A summary of the existing and planned storage facilities is provided in Table 5-5. Table 5-5.Summary of Existing and Planned CCWSD Water Storage Facilities' Facility Name Year Tank Volume(MG) Usable Storage Volume(MG) Online NCRWTP online 12.00 11.10 SCRWTP online 14.00 12.40 Isle of Capri online 0.25 0.20 Manatee Road Pumping Station online 2.00 1.80 Carica Road Pumping Station online 10.00 9.30 NERWTP Phase 1 2023 15.00 13.50 Total 53.25 48.30 Manatee Road ASR Phase 12 online N/A '"1 MGD Total "1 MGD 1 Information taken from the Collier County 2008 Water Master Plan Update and the Fiscal Year 2011 Water and Wastewater User Rate Study. 2 Storage volume for Manatee Road ASR not included in total. Smith 5-7 Pw/6295/98609/03/11 B•NITABE•CH RD NERWTP I • OIL WELL RD 0 O I MOKALEE RD O r p J t NCRWTP CO VANDE-.BILT BEACH • p r-. Q CARICA GOLDEN GATE BLVD ti BOOSTER > STATION PINE RID RD w 1 7 ° 0) rn 0 m -- SCRWTP r -Ti Z • O I75 �f� RADIO RD l DAVIS BLVD Nei 1 G,s, v, MANATEE i- BOOSTER • • 14 STATION MANATEE'S ROAD ASR J ISLE OF CAPRI VI) -t. BOOSTER STATION Legend GOODLAND • I■viVo p Existing Potable Water Storage Facilities r\, BOOSTER • Future Potable Water Storage Facilities \ STATION I M t -"< rr (,. ( 7! A FIGURE 5-3 COLLIER COUNTY 10-YEAR WATER SUPPLY FACILITIES WORK PLAN N C DM EXISTING AND PLANNED CCWSD POTABLE WATER STORAGE FACILITIES Smith 0 7,500 15,000 30,000 45,000 Feet 5-8 Section 5 • Planned Water Supply Facilities Table 5-6 identifies the major tasks required to build each of the planned pumping and storage improvements,along with the funding source that will be utilized and the scheduled dates for studies, property acquisition,design,permitting,and construction. Table 5-6. Major Tasks Required to Build Planned CCWSD Water Storage Facilities Year(s)of Execution Facility Feasibility Property Name Funding Source Study Acquisition Design Permitting Construction NERWTP Phase 1 Impact Fees Complete Complete Complete 2018-2020 2020-2023 Storage Tanks Potable water is pumped from the plants into the distribution system.The distribution system includes water mains designated as either transmission or distribution mains.The CCWSD pipelines 16 inches in diameter and larger are generally termed transmission mains.These are typically located along arterial and collector roadways and convey water to major demand areas.Pipelines smaller than 16 inches in diameter are generally called distribution mains,branching off the transmission system to supply individual users. Overall,the CCWSD owns and maintains over 1,000 miles of water transmission and distribution pipelines,up to 42 inches in diameter,with over 55,000 individual service connections. With the construction of 10 MGD of additional finished water capacity,CCWSD will be installing a substantial number of transmission mains and major distribution mains over the next 10 years.The existing and planned transmission mains and major distribution mains that will serve CCWSD in 2023 are illustrated in Figure 5-4. 5.1.2 Reclaimed Water Facilities CCWSD currently operates one of the largest reclaimed water system in South Florida,which serves customers with contractual commitments of 23.4 MGD.The majority of the existing customer base includes golf courses,residential communities,environmental mitigation areas,county parks,and roadway medians.There is an additional demand of 43.4 MGD in the service area from entities that have installed dual distribution piping. The following subsections describe the measures CCWSD is taking to meet future wastewater demands and supply reclaimed water to its customers.In addition to the improvements described below,CCWSD is undertaking the development of the IQ Water element of its Master Plan starting in 2013 to determine the best methods for maximizing the efficient use of reclaimed water. Recommendations and findings of the IQ Water element of the Master Plan will be incorporated into future editions of the Collier County 10-Year Water Supply Facilities Work Plan. 5.1.2.1 Water Reclamation Facilities The locations of the existing NCWRF and SCWRF are shown in Figure 5-5.There are currently no plans to build additional water reclamation capacity during the 10-year planning period. Table 5-7 summarizes the capacities of the existing WRFs. Singh 5-9 PW/6295/98609/03/11 16" B�� - CH RD ce Luul aw Z imb . <1' _ 2 OIL WELL RD 311- 12" N 1N 2 N 16" 161 ^' J 24" '�� _ 36"20: 30" 12" t � r N N 3 A 2" >J m � r . 30" 24" 3 � (n w o.01414111M GOLDEN GATE BLVD I , . a / W D ' in �1 rn CK Tx 0 a 0 53 C.)m v r_ c -f RA' ' RD iv 175 1 MINIAlir "I'DAVI' BLVD 12" . 11 go 1 ,7 4 ' ?cv . 1\.3t Vn 76p 6" 1. _ t .4S /i)xi/< rlN , f141 .3 1 72p NOTE: MAINS SHOWN ARE 12"OR GREATER. it Legend N6 Water Mains 10111111_111 FIGURE 5-4 COLLIER COUNTY 10—YEAR WATER SUPPLY FACILITIES WORK PLAN N C DMEXISTING AND PLANNED CCWSD POTABLE WATER TRANSMISSION MAINS smith 0 7,500 15,000 30,000 45,000 Feet 5-10 Be CH RD OIL WELL RD o G) J 'i,, , S NCWRF I MOKALEE RD 0 3 co VANDE•BILT BEACH W a Iz Q GOLDEN GATE BLVD J ro Cr W W PINE RID RD 10Z y to rn 71 cc L U v r__ r T Z x U :f RADIO RD 175 DAVIS BLVD GS --,, 1 GS SCWRF 1) j? T94i%T s'VV Li; rn J illt Legend .* Existing Water Reclamation Facilities 11141*1111111 \,. - Ilk . ‘f 14fille 1111111. i A FIGURE 5-5 COLLIER COUNTY 10-YEAR WATER SUPPLY FACILITIES WORK PLAN N CDM EXISTING AND FUTURE CCWSD WATER RECLAMATION FACILITIES Smith 0 7,500 15,000 30,000 45,000 Feet 5-11 Section 5 • Planned Water Supply Facilities Table 5-7.Summary of Existing and Planned CCWSD Water Reclamation Facilities' Facility Name Year Online Design Capacity(MGD)2 Project Identified In LWCWSP NCWRF Online 24.1 N/A SCWRF Online 16.0 N/A Total 40.1 'Information taken from the Collier County 2008 Wastewater Master Plan Update and the 2012 AUIR. 2 The design capacities do not reflect the amount of reclaimed water available from the facilities.The amount of reclaimed water available is based on influent flow and treatment efficiency.For planning purposes,CCWSD considers reclaimed water availability based on 95 percent of the lowest influent day,which is currently around 11 MGD. As stated in the footnotes to Table 5-7,the amount of reclaimed water distributed is not directly related to the design capacity of each water reclamation facility. In addition to the limitations identified,the ability of CCWSD to utilize available reclaimed water for distribution is impacted by seasonal fluctuations in demand, with very high demands during the dry season and low demands during the wet season. 5.1.2.2 Reclaimed Water Pumping,Storage,and Transmission The current reclaimed water distribution system consists of over 130 miles of transmission and distribution pipeline and is currently divided into two services areas,one in the north and one in the south,each supplied by the respective WRF.There are a few small interconnects between the two service areas,but the system is hydraulically limited from passing large volumes of water from one service area to the other. As additional reclaimed water becomes available through population growth and increased wastewater flows,and once existing demand is met,CCWSD will need to expand the reclaimed water distribution system to serve more customers.At this time,specific distribution and transmission main projects have not been determined.These projects will be determined through analyses to be performed as part of the development of the IQ Water Master Plan described previously on page 5-7. Temporary reclaimed water is available on-site at the WRFs.Additional storage will be provided through the expansion of the existing reclaimed water ASR from a capacity of 1 MGD to 5 MGD.A summary of the reclaimed water storage that will be available with the expansion of the reclaimed water ASR is provided in Table 5-8. Table 5-8.Summary of Existing and Planned Reclaimed Water Storage Facilities' Facility Name Year Online Usable Storage Volume(MG) NCWRF online 18.95 SCWRF online 3.00 Total Reclaimed Water ASR 2013 '"1 MGD Reclaimed Water ASR Expansion TBD -4 MGD Total f 4 ,'£ �,. "5 MGD 1 Information taken from the Collier County 2008 Wastewater Master Plan Update. Table 5-9 identifies the major tasks required to build each of the planned reclaimed water storage facilities,along with the funding source that will be utilized and the scheduled dates for studies, property acquisition,design,permitting,and construction. Smith 5-12 PW/6295/98609/03/11 Section 5 • Planned Water Supply Facilities Table 5-9. Major Tasks Required to Build Planned CCWSD Reclaimed Water Storage Facilities Year(s)of Execution Facility Feasibility Property Name Funding Source Study Acquisition Design Permitting Construction Reclaimed Water ASR User Fees Complete Complete 2013 2013 2014 Well 2 Reclaimed Water ASR User Fees Complete Complete TBD TBD TBD Wells 3-5 Upsize Transmission User Fees TBD TBD TBD TBD TBD Piping from ASR Site 5.2 Immokalee Water and Sewer District (IWSD) 5.2.1 Potable Water Facilities 5.2.1.1 Wellfields Currently,the IWSD operates three wellfields; one adjacent to each of its WTPs.The locations of each of these wellfields and WTPs are illustrated in Figure 5-6.The 16 wells maintained by the IWSD tap the LT Aquifer,which is a traditional freshwater source. IWSD plans to bring four additional wells online by 2020 to address future demands.The wells will tap the Floridan Aquifer,which is a brackish water source.Table 5-10 summarizes the wells IWSD plans to construct. Table 5-10. Summary of Planned IWSD Wells1 Well No. Aquifer Total Depth`(ft) Depth of Casing(ft) Diameter(in) Capacity(gpm) FA-1 Floridan NA 788 16 695 FA-2 Floridan NA 788 16 695 FA-3 Floridan NA 788 16 695 ------------ FA-4 Floridan NA 788 16 695 Information on planned wells taken from CUP#11-00013-W. 2 NA—information not available on CUP#11-00013-W. SMIth 5-13 M/6295/98609/03/11 a LA z � ° 9 A �° ° R n W '' r n .. 2 2 9 F-PA a� g Z Oct CL ill -- ; ! s N LL M n R^ d 1 Dr - ' a v=i S.R. 29 SR 20 J i_ o �� W Ui a 880 I � yN z H — a 7 \' ' W °ce- N \ ^� N N \ >— Q PEPPER o J a N N A ' I- - r H0 Zz V 9 n 0 No a U — cc W u) N 9 R w J X J W 0 / .., it, ° N N 9 n W 3 CI } . 2 2 9 n n n W o El AiNf D 331 > O N m ce EC9 Q 3 3 Em. I I x CI C) Section 5 • Planned Water Supply Facilities Table 5-11 identifies the major tasks required to build the four wells,along with the funding source that will be utilized and the scheduled dates for studies,property acquisition,design,permitting,and construction. Table 5-11. Major Tasks Required to Build Planned IWSD Wells Year(s)of Execution Funding Feasibility Property Facility Name Source Study Acquisition Design Permitting Construction FA-1 to FA-4 USDA 2015 2018 2019 2019 2020 5.2.1.2 Water Treatment Facilities The IWSD is currently served by three interconnected water treatment facilities;the Jerry V.Warden WTP,the Airport WTP and the Carson Road WTP. During the 10-year planning period IWSD plans to construct a RO WTP.The proposed plant will have a design capacity of 2.5 MGD.Table 5-12 summarizes the treatment capacity of the existing and planned potable water facilities for IWSD. Table 5-12. Summary of Existing and Planned IWSD Water Treatment Facilities' Facility Name Year Design Raw Water Raw Traditional/ Project Identified Online Capacity Requirement2 Water Alternative In LWCWSP (MGD) (MGD) Source Traditional Jerry V.Warden WTP Online 2.25 2.32 LT (Fresh) N/A Traditional Airport WTP Online 1.35 1.39 LT (Fresh) N/A Carson Road WTP Online 2.00 2.06 LT Traditional N/A (Fresh) RO WTP 2020 3.00 3.75 FA Brackish Yes Total 8.60 9.52 Information on the existing and planned IWSD water treatment facilities was taken from the CUP#11-00013-W and the 2012 Lower West Coast Water Supply Plan Update. 1 Raw water requirement is the amount of raw water need to make a certain amount of finished water.It is calculated by dividing the finished water capacity by the efficiency of the treatment process. 5.2.2 Reclaimed Water Facilities Currently,IWSD disposes of all effluent wastewater via an on-site spray irrigation field or deep well injection.The IWSD currently has a WRF with a capacity of 2.50 MGD.Two planned future expansions of the facility will increase the capacity to 5.5 MGD. 5.3 Florida Governmental Utility Authority (Golden Gate) (FGUA) 5.3.1 Potable Water Facilities 5.3.1.1 Wellfields FGUA currently operates eight wells,six of which are located on the site of the WTP.To address future demands FGUA is planning to bring three additional wells online by 2030.The wells will tap the LT Aquifer,which is a traditional freshwater source.The locations of these wells are shown in Figure 5-7. Table 5-13 summarizes the well FGUA plans to construct. Smith 5-15 PW/6295/98609/03/11 I 1 • • 1 z -4( i la 11 q el 1. vo 11 A i. .2.... q!,.. / 4_ ' „7-- -----N_____L -,: / x , - - -.____ t ;._,, =1 _ ',( ---- + ,,, / / / 1 7t] Pc ___, _,/§2. ,,i ..az .g • ' ---------- e;i------------,- \-10 < < _1 u. a I- / / r—T----1_ 3 )) II re w 0 2 + ______L, 1 7 ( `_. i 1 < "`I • Z I ,0 co w , - w \i t4IP/,AY w ce 6 "'• Ag9 eR *,....,_ ' 1.7- I- \ 2 =I Ce 3 la / ,e brcrl . 1 I I 1 I < u.. - / g s , :_. - ig 111_, cn CO o z I 4> --N> 9x A•11111••■ 1 _1 0 LLJ LLI < . .. I u_ < gY, > < o Kx.6 .. Cli___i •r---,',. \ ,, I W C.9 07 ,PN---' , ,•.' -,- ,_ I 6i i) r >- u. il x g 1 L-w, , . i .1 § \. i § • 11 °.--'- 1- 0 0 . . w t ._ I. >- z __, . .., ( 1 /=. ( I--- Z t 1 a ,. / h' qF: ( C d . -i Mi. lg r 1-I8.,411 e w I 0 a. _ - / n. G A - LJEra. § p .,.14 :.:7 C.) 0 — 1111111 L,''' ff',° —. bKW Z 1 I W Z I i 1. w 1 I o Lz.*V 6,,n 656 c1.23 ___ L 6 4' 1 II 1 \\\:::-- ... 0 ,— ____i '''''"440,eails ILA — * * i 4`0 g r •--_,, ., o P R w IC .:(6... ,.,at 1: b2 E0 P .- ----------: EME Cli 0 Section 5 • Planned Water Supply Facilities Table 5-13. Summary of Planned FGUA Wells' Well No. Aquifer Total Depth(ft) Depth of Casing(ft) Diameter(in) Capacity(gpm) GG-12 LT 180 80 10 810 GG-13 LT 180 80 10 810 GG-14 LT 200 141 10 200 1 Information on planned wells taken from CUP#11-00148-W. Table 5-14 identifies the major tasks required to build each of the three wells,along with the funding source that will be utilized and the scheduled dates for studies,property acquisition,design, permitting,and construction. Table 5-14. Major Tasks Required to Build Planned FGUA Potable Water Wells Year(s)of Execution Funding Feasibility Property Facility Name Source Study Acquisition Design Permitting Construction GG-12 to GG-14 Water User Complete Complete Complete Complete TBD Fees 5.3.1.2 Water Treatment Facilities FGUA operates one WTP,the Golden Gate Water Treatment Plant,which is located west of CR-951, south of Golden Gate Parkway,as shown in Figure 5-7.The current capacity of the WTP is 1.22 MGD using LS and 0.87 MGD using RO. FGUA recently completed maintenance on the RO membranes which allows for increased water production through increased recovery efficiency. The production capacity of the RO membranes is now 1.05 MGD. FGUA will likely re-rate the plant to 2.27 MGD prior to any future expansion. Based on the re-rating of the plant,FGUA should not need to construct additional water treatment facilities during the next 10 year period.A summary of the existing and planned water treatment facilities is provided in Table 5-15.In addition to identifying the design capacity of each treatment train,the amount of raw water required to make the design capacity is also provided. Table 5-15. Summary of Existing and Planned FGUA Potable Water Treatment Facilities) Facility Name Year Design Raw Water Raw Traditional/ Project Identified In Online Capacity Requirement2 Water Alternative LWCWSP (MGD) (MGD) Source Golden Gate WTP(LS) Online 1.22 1.38 LTA/WT Traditional No (Fresh) Golden Gate WTP(RO) Online 0.88 1.17 LTA/WT Traditional No (Fresh) Golden Gate WTP(RO)— Online 0.17 0.23 LTA/WT Traditional Yes After Re-rating (Fresh) Total 2.27 2.78 1 Information on existing and planned water treatment facilities taken from the 2013 FGUA Updated Capacity Analysis Report. 2 Raw water requirement is the amount of raw water need to make a certain amount of finished water.It is calculated by dividing the finished water capacity by the efficiency of the treatment process. 5.3.1.3 Pumping, Storage, and Transmission As described in Section 4.3.2.3,the existing FGUA transmission facilities consist of transmission pipelines,water storage tanks,and pumping facilities.FGUA has no plans to modify the existing storage facilities.However,there are plans to expand the transmission pipelines. 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"P-� �1_ L E off) Section 5 • Planned Water Supply Facilities 5.3.2 Reclaimed Water Facilities The FGUA currently has no plans to expand the existing reclaimed water facilities. 5.4 Orange Tree Utility Company (OTUC) The OTUC will be taken over by CCWSD in 2014. 5.4.1 Potable Water Facilities 5.4.1.1 Wellfields OTUC currently operates six wells located in close proximity to the WTP.There are currently no plans to construct any additional wells. 5.4.1.2 Water Treatment Facilities OTUC is currently served by one water treatment plant with a capacity of 0.75 MGD.There are no planned expansions/projects identified in the 2012 Lower West Coast Water Supply Plan Update. 5.4.2 Reclaimed Water Facilities Currently,OTUC disposes of all effluent wastewater via RIBs. 5.5 Ave Maria Utility Company, LLLP (AMUC) 5.5.1 Potable Water Facilities 5.5.1.1 Wellfields I AMUC currently operates three wells located in close proximity to the WTP.Per the AMUC CUP and information in the 2012 Lower West Coast Water Supply Plan Update,AMUC currently has no plans to bring additional wells online. 5.5.1.2 Water Treatment Facilities Ave Maria Utilities operates one WTP,which is located west of Camp Keais Road,north of CR-858.The current capacity of the WTP is 0.99 MGD using MS. AMUC plans to expand the facility through three subsequent expansions to a capacity of 4.39 MGD by adding additional MS treatment trains.A summary of the existing and planned water treatment facilities is provided in Table 5-16.In addition to identifying the design capacity of each treatment train,the amount raw water required to achieve the design capacity is also provided. CSD 5-19 PW/6295/98609/03/11 r Section 5 • Planned Water Supply Facilities Table 5-16. Summary of Existing and Planned AMUC Potable Water Treatment Facilities' Facility Name Year Design Raw Water Raw Traditional/ Project Online Capacity Requirement2 Water Alternative Identified In (MGD) (MGD) Source LWCWSP AMUC WTP(Phase 1) Online 0.99 1.16 LT Traditional N/A (Fresh) AMUC WTP(Phase 2) TBD 1.70 2.00 LT Traditional Yes (Fresh) AMUC WTP(Phase 3) TBD 1.70 2.00 FA Brackish3 Yes Total 4.39 5.16 1 Information on existing and planned water treatment facilities taken from the 2012 Lower West Coast Water Supply Plan Update. 2 Raw water requirement is the amount of raw water need to make a certain amount of finished water.It is calculated by dividing the finished water capacity by the efficiency of the treatment process. 3 Raw water requirement is the amount of raw water need to make a certain amount of finished water.It is calculated by dividing the finished water capacity by the efficiency of the treatment process. Table 5-17 identifies the major tasks required to build each of the planned expansion phases,along with the funding source that will be utilized and the scheduled dates for studies,property acquisition, design,permitting,and construction. Table 5-17. Major Tasks Required to Build Planned AMUC Potable Water Treatment Facilities Year(s)of Execution Funding Feasibility Property Facility Name Source Study Acquisition Design Permitting Construction AMUC (Phase WTP TBD Complete Complete TBD TBD TBD AMUC WTP TBD Complete Complete TBD TBD TBD (Phase 3) 5.5.2 Reclaimed Water Facilities AMUC is served by one WRF,which is located within the development.The WRF is capable of producing 0.9 MGD of reclaimed water.AMUC plans to expand the WRF three times to a total capacity of 5.2 MGD.Table 5-18 summarizes the capacities of the existing and planned phases of the WRF. Table 5-18.Summary of Existing and Planned AMUC Water Reclamation Facilities' Facility Name Year Online Design Capacity(MGD) Project Identified In LWCWSP AMUC WRF(Phase 1) Online 0.90 N/A AMUC WRF(Phase 2) TBD 1.70 Yes AMUC WRF(Phase 3) TBD 1.70 Yes AMUC WRF(Phase 4) TBD 0.90 Yes Total 5.20 1 Information on existing water treatment facilities taken from the 2012 Lower West Coast Water Supply Plan Update. Reclaimed water is pumped from the WRF to three reclaimed water storage ponds,which serve as the source for the Town and University's irrigation system.AMUC plans to add an additional three reclaimed water storage ponds within the development in the future.The new ponds will increase the storage capacity from 23.00 MG to 44.00 MG.Additionally,AMUC is currently permitting a 289 MG wetlands storage system which will be used for wet weather storage.Reclaimed water is the most important element of the AMUC Conservation Plan,presented in detail in Section 7,and will be Smith 5-20 PW/6295/98609/03/11 Section 5 • Planned Water Supply Facilities utilized to the fullest extent possible for irrigation of the Town and University.AMUC believes it will be able to utilize 100 percent of the reclaim water generated. Smith 5-21 GW/6295/98609/03/11 Section 6 Facilities Capacity Analysis Sections 3,4,and 5 of this plan presented the population and associated water demand of the service p p area served and to be served by each utility,the existing water supply facilities in place to meet current demands,and the facilities planned to meet future water supply needs,respectively.The purpose of this section of the plan is to conveniently present a comparison of the population,water demand,facilities capacity,and permit limitations that identifies surpluses and deficits in facility and permit capacities. 6.1 Collier County Water-Sewer District (CCWSD) As described in Section 5.1,CCWSD plans to bring online a new potable water treatment facility and associated wellfield during the 10-year planning period ending in 2023. Table 6-1 illustrates how these additions to the existing system will allow CCWSD to stay ahead of the demand curve during the 10-year planning period. Table 6-1. Capacity Analysis for CCWSD 2010 2013 2018 2023 Service Area Population 201,377 212,972 249,366 282,845 Demand Per Capita(gpcd) 170 170 170 170 Required Treatment Capacity @ 170 gpcd(MGD) 34.23 36.21 42.39 48.08 Available Facility Capacity(MGD) 52.00 52.00 52.00 62.00 Facility Capacity Surplus(Deficit)(MGD)1 17.77 15.79 9.61 13.92 Raw Water Requirement(MGD)` 40.13 42.76 51.01 57.84 Permitted Amount(MGD Annual Average)' 56.14 56.14 56.14 56.14 Permitted Surplus(Deficit)(MGD)4 16.01 13.38 5.13 (1.70) 1 Calculated by subtracting Required Treatment Capacity @ 170 gpcd from Available Facility Capacity. Raw water requirement is the amount of raw water needed to make a certain amount of finished water.It is calculated by dividing the Required Treatment Capacity @ 170 gpcd by the efficiency of the treatment process. 3 CUP(11-00249-WI for 56.14 MGD annual average expires February 8,2026. °Calculated by subtracting the Raw Water Requirement from the Permitted Amount. As will be noted from Table 6-1,the allocation under CCWSD's current CUP(11-00249-W) is insufficient to meet the raw water requirement needed to make the Required Treatment Capacity @ 170 gpcd starting in 2023. This deficit is related to the planned NERWTP and associated wellfield. CCWSD will initiate the application process for a modification to its current CUP to include the planned NERWTP Wellfield in 2018 as identified in Table 5-2.The additional allocation sought will be an additional total of 14.60 MGD from the LT,HZ1 and LH aquifers. 6.1.1 Concurrency Analysis Each year,the Public Utilities Division completes a concurrency review of its"Category A"facilities, including potable water.The analysis becomes a part of the Countywide Annual Update and Inventory Report(AUIR).Although concurrency is mandated through state and local law for a two year period, the AUIR analysis goes well beyond 10 years. Smith 6-1 PW/6295/98609/03/11 Section 6 • Facilities Capacity Analysis Like the AUIR,the CCWSD uses an additional tool to assure concurrency. Known as"Checkbook Concurrency,"the tool is used quarterly to update capacity projections.While the AUIR relies on BEBR population estimates for future growth,the Checkbook tracks approved development(Planned Unit Developments and Developments of Regional Impact)as an additional measure of future capacity. It also measures 3-day peak demand rather than seasonal demand. The CCWSD Water and Wastewater Master Plans are the primary planning tools for capital planning. Nevertheless,the AUIR and Checkbook concurrency measurements serve as additional safeguards to assure future capacity. 6.2 Immokalee Water and Sewer District (IWSD) Table 6-2 shows the capacity analysis for IWSD for the 10-year planning period. The improvements planned by the IWSD for the 10-year planning period are sufficient to meet the demands of the service area and the allocation of the underlying CUP (11-00013-W) is sufficient to cover the withdrawals required to make the finished water demand. Table 6-2. Capacity Analysis for IWSD 2010 2013 2018 2023 Service Area Population 27,273 27,848 29,414 30,939 Demand Per Capita(gpcd) 105 105 105 105 Annual Average Daily Demand(MGD) 2.86 2.92 3.09 3.25 Available Facility Capacity(MGD) 5.60 5.60 5.60 8.60 Facility Capacity Surplus(Deficit)(MGD)1 2.74 2.68 2.51 5.35 Raw Water Requirement(MGD)' 2.95 3.01 3.19 3.35 Permitted Amount(MGD Annual Average)' 3.36 4.15 4.15 4.15 Permitted Surplus(Deficit)(MGD)4 0.41 1.14 0.97 0.80 Calculated by subtracting Annual Average Daily Demand from Available Facility Capacity. Raw water requirement is the amount of raw water needed to make a certain amount of finished water.It is calculated by dividing the annual Average Daily Demand by the efficiency of the treatment process. 3 CUP(11-00013-W)for 4.15 MGD annual average expires May 23,2031. Calculated by subtracting the Raw Water Requirement from the Permitted Amount. Smith 6-2 M/6295/98609/03/11 Section 6 • Facilities Capacity Analysis 6.3 Florida Governmental Utility Authority (Golden Gate) (FGUA) Table 6-3 shows the capacity analysis for FGUA for the 10-year planning period. The improvements planned by the FGUA for the 10-year planning period are sufficient to meet the demands of the service area and the allocation of the underlying CUP (11-00148-W) covers the withdrawals required to make the finished water demanded. Table 6-3. Capacity Analysis for FGUA 2010 2013 2018 2023 Service Area Population 15,731 16,256 16,810 17,364 Demand Per Capita(gpcd) 109 109 109 109 Annual Average Daily Demand(MGD) 1.71 1.77 1.83 1.89 Available Facility Capacity(MGD) 2.09 2.27 2.27 2.27 Facility Capacity Surplus(Deficit)(MGD)1 0.38 0.50 0.44 0.38 Raw Water Requirement(MGD)2 1.92 1.99 2.07 2.15 Permitted Amount(MGD Annual Average)3 2.49 2.49 2.49 2.49 Permitted Surplus(Deficit)(MGD)4 0.57 0.50 0.42 0.34 Calculated by subtracting Annual Average Daily Demand from Available Facility Capacity. 2 Raw water requirement is the amount of raw water need to make a certain amount of finished water.It is calculated by multiplying the population '.., by the demand per capita raw water usage. 3 CUP(11-00148-W)for 2.49 MGD annual average expires March 10,2030. '.. °Calculated by subtracting the Raw Water Requirement from the Permitted Amount. 6.4 Orange Tree Utility Company (OTUC) OTUC will be taken over by CCWSD in 2014. OTUC did not identify any capital improvement projects to be completed prior to the takeover. Table 6-4 shows the capacity analysis for OTUC through 2013. Based on the analysis the OTUC has sufficient capacity to meet the demands of the service area through the takeover. Table 6-4. Capacity Analysis for OTUC 2010 2013 Service Area Population 4,808 5,160 Demand Per Capita(gpcd) 100 100 Annual Average Daily Demand(MGD) 0.48 0.52 Available Facility Capacity(MGD) 0.75 0.75 Facility Capacity Surplus(Deficit)(MGD)1 0.27 0.23 Raw Water Requirement(MGD)2 0.62 0.66 Permitted Amount(MGD Annual Average)3 0.86 0.86 Permitted Surplus(Deficit)(MGD)4 0.24 0.20 Calculated by subtracting Annual Average Daily Demand from Available Facility Capacity. 2 Raw water requirement is the amount of raw water need to make a certain amount of finished water.It is calculated by dividing the Annual Average Daily Demand by the efficiency of the treatment process. 3 CUP(11-00419-W)for 0.86 MGD annual average expires November 11,2009. °Calculated by subtracting the Raw Water Requirement from the Permitted Amount. Smith 6-3 RV/6295/98609/03/11 Section 6 • Facilities Capacity Analysis 6.5 Ave Maria Utility Company, LLLP (AMUC) Table 6-5 shows the capacity analysis for AMUC for the 10-year planning period. The improvements planned by the AMUC for the 10-year planning period are sufficient to meet the demands of the service area,and the allocation of the underlying CUP(11-02298-W) covers the withdrawals required to make the finished water demanded. Table 6-5. Capacity Analysis for AMUC 2010 2013 2018 2023 Service Area Population 1,435 1,886 3,468 6,070 Demand Per Capita(gpcd) 110 110 110 110 Annual Average Daily Demand(MGD) 0.16 0.21 0.38 0.67 Available Facility Capacity(MGD) 1.67 1.67 4.17 5.00 Facility Capacity Surplus(Deficit)(MGD)2 1.51 1.46 3.79 4.33 Raw Water Requirement(MGD)3 0.19 0.24 0.45 0.79 Permitted Amount(MGD Annual Average)4 3.02 3.02 3.02 3.02 Permitted Surplus(Deficit)(MGD)5 2.83 2.78 2.57 2.23 'Calculated by subtracting Annual Average Daily Demand from Available Facility Capacity. Raw water requirement is the amount of raw water need to make a certain amount of finished water.It is calculated by dividing the Annual Average Daily Demand by the efficiency of the treatment process. 3 CUP(11-02298-WI for 3.02 MOD annual average expires January 9,2017. 4 Calculated by subtracting the Raw Water Requirement from the Permitted Amount. ( Smith 6-4 Pw/6295/98609/03/11 Section 7 Conservation Regulations and Practices As the water supply in Florida becomes more taxed over time,the need to more efficiently utilize water resources will increase. The following subsections outline the conservation regulations and practices utilized by each of the utilities covered under this plan. The information provided has been taken directly from the conservation plans approved by the SFWMD and included in each utility's consumptive use permit. 7.1 Collier County Water-Sewer District (CCWSD) The conservation plan implemented by CCWSD is described in the utility's consumptive use permit as follows: The Collier County Board of Commissioners enacted Ordinance 2002-17,which reduced watering to three days per week(three times each for odd and even numbered addresses),in an effort to reduce water consumption.This ordinance also requires that rain sensor devices be installed on automatic irrigation systems.The Board initiated an ASR program to allow for the storage of excess water that I can later be withdrawn to offset peak usage. Other water conservation measures designated by the SFWMD,which Collier County has enacted include: • Requiring low flow plumbing fixtures as part of the Land Development Code(LDC); • Encouraging the use of Florida Friendly landscapes and other drought-tolerant vegetation in portions of the LDC; • Implementing water conservation rates that increase per-thousand gallon charges as usage increases; • Monthly reading of all customers'meters to minimize losses from unaccounted-for water; • An active reuse program,which delivers over 4.5 billion gallons a year of reclaimed wastewater, to reduce irrigation withdrawals; • Filter backwashing at the SCRWTP to eliminate water lost in cleaning filters;and • Enacted in 2003 to further promote water conservation,the Board approved a mandatory water high-consumption surcharge,which is applied when the SFWMD implements water restrictions and impacts on only high-use consumers. The County continues to look for additional water saving opportunities.Currently,County staff is working on several proposals for consideration by the Board of County Commissioners: • An intra-departmental team is assembling a"Low Impact Development"(LID) manual,which will provide best management practices for storm water and landscape issues at micro and macro levels.Successes from other Florida jurisdictions and experts will be studied for PMth 7-1 PW/6295/96609/03/11 Section 7 • Conservation Regulations and Practices improvements to irrigation practices,among other things.Following the publication of the LID manual,this team,with CCWSD input,will recommend an incentive-based program to the BCC, to further the Florida Friendly and water conservation principals.Mandatory provisions may be considered. • Irrigation quality water from reclaimed and supplemental sources has gained greater recognition as a valuable commodity.The CCWSD will propose to the BCC,in FY 2014,the extension of the current Irrigation Ordinance to a wide range of irrigation activities,regardless of source.Thus,the amendment would establish allowable hours of irrigation,days of the week, rain or soil sensor requirements,total volume and other provisions,similar to those that currently govern the use of potable water. In addition to these water conservation measures,the CCWSD and other County agencies endeavor to educate the public regarding water conservation through educational and outreach programs.Staff members routinely conduct presentations for schools,civic groups,homeowner associations,and other receptive groups.Division staff participates in events,such as"Senior Expo"and"Government Days,"to take the water conservation campaign to the public.Utility bill inserts and advertising have further helped to spread the message.The County has actively been promoting the"Fridays are Dry Days"campaign,which has become the tag line on commercials airing on radio stations throughout Collier County.These stations were selected to target a large number of consumers,including those who do not speak English.The tag line has also been utilized in several productions airing on the Collier County Government Channel.Public service announcements and specially produced videos promoting water conservation also air on the County's government access television station,Channel 11/16. CCWSD has made significant strides towards improving and enhancing the efficiency of the Water Distribution System.Maintaining an efficient system with upgraded and preventive maintenance efforts keeps unplanned water losses to a minimum.CCWSD's average unaccounted-for water is currently below 5 percent,according to the unaccounted water loss report submitted to the SFWMD on September 6,2012,due to aggressive water loss management practices. The CCWSD unaccounted- for water has been decreased by over 50 percent in the past five years as reflected in Figure 7-1, which shows the unaccounted-for water loss over the past ten fiscal years. CCWSD has the long-term goal of reducing water loss to 2.5 percent or less over the next 15 years. Specific projects the CCWSD has or will undertake to further water conservation include: • Installation of additional valves in several critical areas of the water mains to effectively decrease isolation times in the event of main breaks.Decreasing the isolation time results in reduced water losses. • Mapping the entire water supply system which,in the event of a main break,aids in reducing water loss through improved location and isolation times. • Replacing over 50 galvanized service replacements throughout the Water District annually.This increases reliability of water services and reduces potential water loss. • In FY 2014 CCWSD will be starting a new meter change out program,which will go through FY 2018 and change out all 3/4"to 2"potable meters,of which there are over 56,000. Smith 7-2 PW/6295/98609/03/11 Section 7 • Conservation Regulations and Practices • Completing replacement projects on several substandard water mains.This improves service reliability and fire protection capacity,and reduces the potential for water loss. • The fifty largest users in the system have their large meters tested twice per year.All other large meters are tested annually.This decreases unaccounted-for water loss. • As part of the distribution system rehabilitation program,automatic flushing stations are installed in problem areas of the system as they are identified.This results in the reduction of overall water loss due to required flushing to maintain disinfectant residuals. • Another part of the distribution system rehabilitation program involves installing new water quality sampling stations at the ends of the system as additional locations are identified.The increase in monitoring from these locations will aid in the identification of developing water quality problems before they become critical.Proactive monitoring results in effective reduction of water loss from high volume flushing required when water quality problems develop. • As part of a proposed revision to the Utility Standards Manual,CCWSD will suggest language that clarifies the need for looping of water systems within and among developments; specifically,dead-ends or cul-de-sacs will be subject to a maximum unit count unless looped to another part of the system.In this way,flushing and automatic flushing will be reduced to save potable water. • The CCWSD will continue to seek water-saving opportunities in site-specific contexts;for example,in 2013,the BCC authorized the capture of flushed water by the Key Marco Community Development District for later irrigation use,thus promoting the re-use of millions of gallons of water per year. 15.0% o 12.5% 11.5% 12.2/ m 9.7% 10.0% 10.0% te, 8.4% 8.5% 0 7.5% 4.5% 4.9 C 5.0% 4.U% 3.3% 3.1% a 2.5% u 101 a 0.0% 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 Fiscal Year Figure 7-1 CCWSD Unaccounted-for Water Loss from FY2002 to FY2012. Cal t 7-3 PW/6295/98609/03/11 Section 7 • Conservation Regulations and Practices 7.2 Immokalee Water and Sewer District (IWSD) The conservation plan implemented by IWSD is described in the utility's consumptive use permit as follows: Pursuant to the SFWMD Basis of Review(March 1994),Section 2.6.1,Water Conservation Plans,all public water supply utilities are required to develop and implement a water conservation plan.Each of the mandatory water conservation elements must exist or have a proposed time frame for implementation.As mentioned earlier,the IWSD was established under Florida law and has specific duties and quasi-governmental rights.However,the authority to enact ordinances does not reside with that District.The applicant has stated they will request that Immokalee enact any required ordinances within a year of permit issuance.The applicant has provided the following water conservation plan elements: A. Permanent Irrigation Ordinance: An ordinance which restricts landscape irrigation to the hours of 4:00 p.m.to 10:00 a.m.,7 days per week,is currently not in effect for the service area.The utility will request that Immokalee adopt an ordinance for the service area within 1 year of permit issuance. B. Xeriscape Ordinance: An ordinance which requires the use of xeriscape landscape principles is currently not in effect.The utility will request that Immokalee adopt an ordinance for the service area within 1 year of permit issuance. C. Ultra-Low Volume Plumbing Fixture Ordinance: An ordinance which requires ultra-low volume plumbing fixtures on all new construction is in effect for the service area. D. Water Conservation Rate Structure: The applicant has a conservation-based rate structure,which includes increasing block rates as a means of reducing demands. E. Leak Detection Program: The applicant does not have an unaccounted for water and leak detection program because the unaccounted for water losses are less than 10 percent. F. Rain Sensor Device Ordinance: An ordinance which requires any person who purchases and installs an automatic lawn sprinkler system to install,operate,and maintain a rain sensor device or automatic switch which will override the irrigation system with the occurrence of adequate rainfall is currently not in effect for the service area.The utility will request that Immokalee adopt an ordinance within 1 year of the permit issuance. G. Water Conservation Education Program: The applicant distributes pamphlets,makes school visits,and provides information booths for employees and customers.Information signs,press releases,and messages about water conservation on the bills are also utilized. H. Reclaimed Water: Currently,all wastewater effluent is disposed of via a spray irrigation field and percolation ponds. Tnllth 7-4 PW/6295/98609/03/11 Section 7 • Conservation Regulations and Practices 7.3 Florida Governmental Utility Authority (Golden Gate) (FGUA) The conservation plan implemented by FGUA is described in the utility's consumptive use permit as follows: The Authority(FGUA) has an interlocal agreement with Collier County to serve portions of unincorporated Collier County.As such,the Authority follows Collier County's Water Irrigation Ordinance,2002-17,which is the District's intent to conserve water through irrigation schedules.This ordinance also refers to Chapter 373.62,F.S.with regards to use of a rain sensor or other automatic switch which will override the irrigation cycle of the irrigation system.Additionally,Chapter 40E-24 of the District's rules requires residential irrigation to follow a plan of odd-even addresses with 3 days per week irrigation.Permitted irrigation of nonathletic playing fields(golf courses,ball fields,lawn tennis,etc.) is also required to follow the same conservation practices. The current rate structure for billing customers provides for a base facility charge and a volumetric consumption charge,resulting in increased customer costs for higher consumption.The rate structure is intended to conserve water. The Authority's wastewater is 100 percent reused by routing the effluent to rapid infiltration basins to recharge the ground water system. The Authority encourages use of xeriscape practices similar to the County's xeriscape ordinance.The Authority does not have the ability to create an ordinance for the Golden Gate service area,but does promote xeriscape through a public education program.Similarly,the Authority has no plumbing ordinance for low flow fixtures,but does encourage these products through the use of public education.The public education program consists of routine mailings of water conservation literature with monthly customer billings,meeting with homeowner associations,school programs with speakers and water plant tours,and participation in community events. The Golden Gate Utility,now the Authority,implemented an unaccounted for water loss program in 2003. Unaccounted for water loss is tracked monthly with the results submitted annually. Leak detection services are budgeted for as part of the Integrated Water Resources Management Plan,but are only used if water loss is greater than 10 percent. %mith 7-5 PW/6295/98609/03/11 Section 7 • Conservation Regulations and Practices 7.4 Orange Tree Utility Company (OTUC) The conservation plan implemented by OTUC is described in the utility's consumptive use permit as follows: A. Permanent Irrigation Ordinance: OTUC enforces all watering restrictions as they are made known. This includes the District's Mandatory Year Round landscape irrigation measures for Lee,Collier,and Charlotte counties(Chapter 40E-24,F.A.C). B. Xeriscape Ordinance: OTUC highly encourages the use of Xeriscape landscaping in its service area to help reduce the need for ornamental watering. C. Ultra-Low Volume Plumbing Fixture Ordinance: It is the policy of OTUC that low volume plumbing should be installed in all new service connections,in accordance with the State building code. D. Water Conservation Rate Structure: OTUC is in the process of developing a conservation based rate structure for future use,with approval from the Collier County Water and Wastewater Authority. E. Leak Detection Program: OTUC will repair any system leaks brought to its attention in a timely fashion and will also review usage for detection of major leaks. F. Rain Sensor Device Ordinance: OTUC requires all irrigation systems to have rain sensors which override new lawn sprinkler installations. G. Water Conservation Education Program: OTUC will distribute and place on its website public service education information as it is made available by government agencies. H. Reclaimed Water: Wastewater is being reused as a source for golf course irrigation water at the present time.In the future,as more reclaimed water becomes available,it will also be used for residential irrigation. Upon taking over the OTUC in 2014,CCWSD will implement the water conservation measures described in Section 7.1 within the OTUC service area. Smith 7-6 PW/6295/98609/03/11 Section 7 • Conservation Regulations and Practices 7.5 Ave Maria Utility Company, LLLP (AMUC) The conservation plan implemented by AMUC is described in the utility's consumptive use permit as follows: Per Section 2.6.1 of the Basis of Review,public water supply in excess of 500,000 gpd requires a water conservation plan addressing the following conservation elements: Permanent Irrigation Ordinance, Xeriscape Ordinance,Ultra-Low Volume Plumbing Fixture Ordinance,Water Conservation Rate Structure,Leak Detection Program,Rain Sensor Device Ordinance,Water Conservation Education Program,and Reclaimed Water Use.The following information is provided. A. Permanent Irrigation Ordinance: One of the water conservation efforts the Ave Maria University and Town will pursue is adoption of an irrigation ordinance to limit irrigation water usage during the dry season.The planned ordinance would follow watering restrictions adopted by Collier County,including limiting daytime watering times and limiting the number of days that lawns could be watered.The irrigation ordinance would also likely follow an even/odd address watering system. B. Xeriscape Landscape Ordinance: The University and Town of Ave Maria will pursue adoption of an ordinance which recommends the use of xeriscape principles in landscape planning for all new construction.The ordinance would encourage implementation of xeriscape landscaping practices including use of mulches,native and drought tolerant plants,and limited turf areas. C. Ultra-Low Volume Plumbing Standards: The university and town of Ave Maria will pursue adopting an ordinance requiring ultra-low volume plumbing fixtures in all new construction.The standards proposed in the planned Ave Maria Plumbing Code would,in most cases,be as stringent as the ultra-low plumbing standards stipulated in the SFWMD Water Conservation Plan Development Guidelines. D. Water Conservation Rate Structure: The Town of Ave Maria plans to utilize an inclining block rate structure in order to promote water conservation.Residential and commercial water rates will consist of a monthly capacity cost charge(base rate)and a monthly commodity costs charge(volume charge).The commodity costs charges will increase with increased volume use.For example,residential costs increase from$1.75 per thousand gallons for under 5,000 gallons,to$4.00 per thousand gallons for quantities over 30,000 gallons.The details and the planned water rate schedule have not been specifically determined yet. E. Leak Detection&Distribution System Losses Program: A leak detection program will be implemented by the AMUC if system losses exceed 10 percent.The leak detection program will likely utilize the Rural Water Association(RWA)sonic type leak detection equipment. System losses may be attributable to known line breaks.The Ave Maria Utilities Department will repair water main and service line breaks as soon as possible to minimize and prevent distribution system losses. F. Sprinkler System Rain Sensor: The Town of Ave Maria will recommend installation of rain sensor devices on automatic lawn sprinkler systems for all new construction. G. Public Education Programs: The AMUC will pursue public education programs on water conservation and community responsibility.The programs could include presentations by Utility staff,such as water conservation topics discussed during tours conducted at the Csmith 7-7 PW/6295/98609/03/11 Section 7 • Conservation Regulations and Practices Water Treatment Plant and Waste Water Reclamation Facility.Educational brochures on water conservation,landscaping and xeriscape can be distributed by the Utility offices.The AMUC could also include water conservation information to all customers along with monthly billing statements. H. Reclaimed Water: The most important element of Ave Maria's Water Conservation Plan is utilization of a reclaimed water system for irrigation.The Town and University will pursue the use of as much reclaimed water as possible and will likely be able to utilize 100 percent of the reclaimed water generated. With 7-8 P4V/6295/98609/03/11 Section 8 Capital Improvement Projects Section 5 of this plan focused on the projects that each of the utilities have planned for the 10-year planning period. Attention was paid to the amount of water made available and when it would be made available. The following subsections present the capital improvement projects planned by each utility,including the funding source,project number,project name,and cost estimate for each project. 8.1 Collier County Water-Sewer District (CCWSD) The most recent lists of CCWSD water and wastewater capital improvement projects were developed as part of the Fiscal Year 2011 Water and Wastewater User Rate Study. The capital improvement projects pertinent to future water supply are summarized in Table 8-1. CCWSD funds its water and wastewater projects from four funds:411-Water Impact Fees,412-Water User Fees,413- Wastewater Impact Fees,and 414-Wastewater User Fees. Impact fees are utilized to pay for expanded supply projects,while user fees are used to fund operations,maintenance,and replacement of existing facilities. 8.2 Immokalee Water and Sewer District (IWSD) IWSD identified no major capital improvement projects planned for the 5-year planning period through 2018. Routine replacements are addressed through annual budgeting. 8.3 Florida Governmental Utility Authority (Golden Gate) (FGUA) Based on the 2013 FGUA Updated Capacity Analysis Report,no major capital improvement projects are planned for the 5-year planning period through 2018. As a utility near build out,routine replacements are addressed through annual budgeting and funded by user fees. 8.4 Orange Tree Utility Company (OTUC) OTUC did not provide a summary of its capital improvement projects. OTUC will be taken over by CCWSD in 2014. CCWSD has capital improvement projects planned for integrating the OTUC into the existing system. 8.5 Ave Maria Utility Company (AMUC) AMUC stated in an email dated August 16,2013,that no major capital improvement projects are planned for the 5-year planning period through 2018. Routine replacements are addressed through annual budgeting. RSRi ith 8-1 PW/6295/98609/03/11 W 0 0 0 O O O O N O O 0 0 0 0 0 0 V' MOO V' M r N O O O O M O V' V 0 0 0 0 0 0 M N- EA EA EA ti EA O O 00 EA N EA O O O O O Lf) CO O O M Lt7 r O O O CO N N- O Ln 00 O LE) O CO O O CO Nb 000) r- 0001.000N- OOrNr nOrNNON0000O - 00u N 00 O V' O CO r E V 00 M f) O M 0 00 N N EA N tf) O Ln n C Lf) O N Lf LC O C V CO M E 00 - 0 -- N- - M O r CO r M M O r N O)LL ti (O EA(f} N WERE,*EA CO EA N r r N CO LC) O) r r N EO r to V' EA M EA EA CA p EA d? 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C ' Ea « E a 2 a g c TL)2 3 m § 7/ - Eto_ $ o2 caw e k k < k k 20u2_ CO2 CuCu/ I- ® < E2 = _ a) 2 0 & ■ c - - < « - E / \ $ \ \ a \ u\ f / ƒ oGOOOOJ ▪ \• nr � on (No `- I >•0 0000 0. nr oS- � N- / N- / F \ o U) ® kit / f 0 § § § )§ § § k" / u_ u_ L U L L � \ DODDDDkk f 2 & a) O) a) O) a) O) 43 k k § § CO § CO CO CO %—; w COU) COU) o \ \ \ \ \ / \ \ 7 � 1 •zr .4- .4- .4- •;r � #_#_# Collier County 10-Year Water Supply Facilities Work Plan Interlocal Agreement between CCWSD and the City of Naples Appendix A COPYOF NAPLES WATER AN D WASTEWATER ERVI . j INTERLOCAL SERVICE BOUNDARY AGREEMENT AND ACCORD AND SATISFACTION � � � oa bt r m THIS INTERLOCAL AGREEMENT, (herein "this Agreement") is entered into this N o d /11 day of k(_ij'v a i , 2009, between the City of Naples, Florida ("City") and the° be be Board of County Commissioners of Collier County, Florida("County"), as the Governing Body Y of Collier County and as Ex-Officio the Governing Board of the Collier County Water-Sewer 0 District("CCWSD"). ARTICLE ONE BACKGROUND INFORMATION N d 1. By enactment of City of Naples Ordinance No. 2698 (passed 2"d reading on June 15, a e-t e r L V 1977), the City exercised its Chapter 180, Florida Statutes, power and authority to extend the City's water and wastewater utility facilities into specific geographic areas in unincorporated M r o Collier County as such areas are depicted by a one(1)page map and a twenty-one(21)page legal b Pzo description that was attached to and made a part of that Ordinance. °' E - en " w 2. The County and the City entered into a Basic Agreement(the"BA")effective October 16, r P r w •- 1977. The original BA addressed only potable water service from the City to specified geographic areas in unincorporated County (as such areas are described by the legal description I w in Exhibit "A" that was attached to the BA). The following items were attachments to the r original BA: a. Exhibit "A" - (2 pages). Page 1 of Exhibit "A" is a "metes and bounds legal description" of the City's Water Service Area Boundary. Page 2 of that Exhibit "A" is a map (graphic) depicting the then existing geographic boundaries of the City's Water Service Area. o 00 b. Exhibit "B" is a 1-page map (graphic) entitled "City Franchised Water Service - Area." c. Exhibit "C" is a 1-page map (graphic) denoted as "City Raw Water Transmission Main and Supply Wells." d. Exhibit "D" is a 5-page "preliminary report" (in letter form) signed by Ted Smallwood on behalf of"BC&E/CH2M Hill." That Report (at its page 5) states that it is "... a preliminary report intended only to provide general guidance to Page 1 of 16 both the City and County in establishing policy for the future of the respective governing bodies' utilities." 3. Addendum#3 to the BA addressed(for the first time)wastewater service from the City to specified geographic areas in unincorporated Collier County. 4. The original BA has been amended by two (2) "Amendments" and by nine (9) "Addendums." The BA and the eleven(11) amending agreements are: City's Authorization Effective Date Item's Description Applicability City Res.No. 2783 October 16, 1977 The Basic Agreement Active City Res.No.3284 June 20, 1979 Addendum#1 Added 2 water meter sites City Res.No.3305 August 1, 1979 Addendum#2 Added 1 water meter site City Res.No.3502 April 2, 1980 AMENDMENT# 1 Fully Executed o City Res.No.84-4526 August 15, 1984 AMENDMENT#2 Fully Executed al=b rts City Res.No. 84-4598 November 7, 1984 Addendum #3 Active b City Res.No.86-5136 November 3, 1986 Addendum#4 Fully Executed City Res. No. 86-5160 December 3, 1986 Addendum#5 Fully Executed City Res.No. 87-5430 November 18, 1987 Addendum#6 Fully Executed I City Res.No. 89-5733 February 1, 1989 Addendum#7 Fully Executed Qty Res.No.90-6117 May 16, 1990 Addendum#8 Fully Executed City Res.No.91-6347 April 3, 1991 Addendum#9 Fully Executed Informational Notes: The original BA agreed that the City would supply water at the following four(4)water interconnect locations: U.S. 41 and Thomasson Drive; Radio Road one mile north of Pine Ridge Road; Pulling Road two miles north of Pine Ridge; and U.S. 41 and 91's Avenue North,Naples Park. Addendum #1 agreed that the City would supply water at the following added two (2) interconnection points: Lakewood Unit #7 — Boca Cieca Drive and Marcor Drive; and Kings' Lake—Evergreen Lake Road in the vicinity of Lakewood Boulevard. Page 2 of 16 Addendum#2 added one(1)additional water service connection point as follows: King's Lake North—Eastern end of Estey Drive. AMENDMENT #1 (a) amended BA paragraph 13 to agree that the City was to quitclaim specified utility facilities to the County regarding the City's water service to the BA's Exhibit B water service area; (b) added a new paragraph 13A into the BA (regarding planned relocation of City-owned water tank)and(c)amended BA paragraphs 7, 8, 11 and 21. AMENDMENT #2 (a) added a new subparagraph (h) to BA paragraph 2 (to add one additional connection point to the City's 5 million gallon water storage tank, located at Carica Road, subject to the County assuming permanent water service to the geographic areas described as south of township line between Townships 48 South and 49 South, outside of the City's water service area as depicted on the BA's Exhibit "A;" (b) Amended the BA's paragraph 3 to establish a rate payment formula applicable to only BULK water sold by the City to the County; (c) Amended paragraph 7 to the BA to agree that the water meter at U.S. 41 and Thomason Drive would remain in place and continue to be used;(d)Also amended the BA's paragraph 8 to agree that the City could limit the quantities of its supply of BULK rate City treated water; (e) Deleted BA paragraphs 9 and 10;(f)Amended BA paragraph 12 to agree that the City could limit the quantity of the City's supply of BULK water if the County did not commence construction of specified water facilities by January 1, 1989;and(g)Amended BA paragraph 13A to agree that the County would pay interest regarding specified construction costs. o c Addendum #3 acknowledged that the City was serving (and would continue to permanently ..P serve)twenty-two (22)geographic areas listed therein with wastewater service and also agreed to is:. many specifics regarding that wastewater service. Paragraph 7 in Addendum #3 refers to then existing contingencies regarding possible wastewater service from the City to the Pine Ridge Industrial Park. (Permanent wastewater service to the Pine Ridge Industrial Park is currently __ being provided by the CCWSD.) 00 cr Addendum #4 transferred the Pelican Bay Improvement District to the CCWSD for permanent potable water service and transferred the following (as therein described) water service sites: Located on the west side of Airport Road and south of Pine Ridge Road) to the City for permanent wastewater service from the City: Bear's Paw, Poinciana Village,Poinciana School, " Pine Woods,Naples Bath and Tennis,and The Falls. Addendum #5 transferred the Sutherland Center to the City for five (5) years of interim water service from the City. (The CCWSD now supplies permanent water service to the Sutherland Center.) Addendum#6 agreed that the City would provide interim water service to the Pine Ridge Middle School. (The CCWSD now supplies permanent water service to that school.) Addendum #7 agreed that the City would provide interim water service to the East Naples Community Park. (The CCWSD now supplies permanent water service to that Park.) Addendum #8 agreed that the City would supply bulk potable water service to the Wyndemere Subdivision. (The CCWSD now supplies permanent water service to that subdivision) Page 3 of 16 Addendum#9 agreed that the City would provide interim water service to the North Naples Fire Station. (The CCWSD now supplies permanent water service to that Fire Station.) 5. Only the original BA (regarding water service), and Amendment #2 (amending the BA's Paragraph 3 to create a rate payment formula applicable to BULK water sold by the City to the County), and Addendum #3 (regarding City wastewater service to twenty-two listed geographic areas) have provisions that have not been fully executed. All of the other ten (10) above-listed items have been fully executed. Several of those items applied for limited time periods that have come and gone. 6. Except as provided in paragraph 5,above,this Agreement cancels and supersedes the BA, the two (2)amendments to the BA and the nine (9)addendums to the BA. This Agreement does not affect any previously executed aspect of the BA, or any amendment or addendum to the BA, such as and without limitation: (a) transfer of title to any real property and/or any previously executed transfer of title to any personal property; (b) any prior grant of, transfer of, or any other right to use any property including easements; nor(c)any prior grant of any right to use personal «A property. This Agreement does not affect any now existing water interconnection service site, b any right of any water or sewer service customer or service site,or any third party beneficiary. ao 7. Term of this Agreement. This Agreement shall continue for a period of thirty (30) years a'' unless terminated in writing by the City and the County. 8. Amendments to this Agreement. This Agreement shall be amended only by written amending agreement(s) executed by the City and by the County and which shall include the following example (title): "This First Amending Agreement amends the 2009 City of.Naples, Collier County Interlocal Agreement — Accord and Satisfaction." The Second Amending Agreement shall be titled"This Second Amending Agreement ...." 9. Successors and Assigns. This Agreement shall be binding on the successors and/or assigns, if any,of the City,the County and/or the CCWSD. 10. Definitions. "Complex" refers to the present County Government Complex. "County" means "Collier County." "CCWSD" means "the Collier County Water-Sewer District." Page 4 of 16 "Imputed sewer service gallonage"means the quantity of sewer service gallonage determined by a percentage of water supplied by the City to the respective service site or service geographic area. "Horseshoe Drive Areas" refers to the South Horseshoe Drive Area/Collier Industrial Park, plus the Coconut River Estates Area (in residential use), and plus the River Reach Area (in residential use). "In-City rates" means City water service rates and/or sewer service rates that do not include any surcharge. "Out-of City rates" means City water service rates and/or sewer service rates that can include the City's discretionary 25% surcharge. "Meter measured gallonage" refers to the gallons of water and/or sewage gallonage measured by a water meter. In that sewer flow meters are inaccurate, sewer flow equivalency will be based upon the metered water bill. "School site" refers to the Shadowlawn Elementary School site. "Sewer" and "wastewater" are synonymous. "Surcharge" means the City's Subsection 180.191(1)(a), Florida Statutes, twenty-five percent(25%)surcharge. ARTICLE TWO CITY'S EXISTING WATER AND SEWER SERVICE CD TO UNINCORPORATED AREAS OF COLLIER COUNTY -- 1. CITY'S EXISTING WATER SERVICE AREA BOUNDARIES IN w UNINCORPORATED COLLIER COUNTY. The geographic boundaries of the City's existing water service areas in unincorporated Collier County are depicted in Exhibit"A"attached to this �. -�a Agreement. Pursuant to this Agreement, the City shall continue to provide those water services to those geographic areas. 2. CITY'S EXISTING SEWER SERVICE AREA BOUNDARIES IN UNINCORPORATED COLLIER COUNTY. The geographic boundaries of the City's existing sewer service areas in unincorporated Collier County are depicted in Exhibit"A"attached to this Agreement. The City shall continue to provide its sewer service to those geographic areas, excepting only the Complex and the School site. Throughout the term of this Agreement the City's sewer rates,fees and charges to be applied to the Complex shall be and remain the same as the City's then existing in-City sewer rates, fees and charges as set forth in the City of Naples Utilities Rate Schedule for Commercial Customers. For sewer rates fees and charge purposes, throughout this Agreement,the Complex shall be treated as if it is physically located within the Page 5 of 16 City's geographic boundaries. Those geographic areas at the time of this Agreement are depicted in Exhibit"A"attached to this Agreement. ARTICLE THREE 1. WATER AND SEWER SERVICE TO THE COMPLEX, SCHOOL SITE,AND THE HORSESHOE DRIVE AREAS. A. City Water Service to School site. The City shall continue to supply water service to the School site,shall invoice the school site and retain all such water service revenues. B. City Water Service to the Complex; Rates; Minimum Water Pressure. The City shall continue to supply water service to the Complex. The City shall apply its generally applicable in City water service rates to the Complex as set forth in the City of Naples Utilities Rate Schedule for Commercial Customers (no water surcharge). Provided an adequate and appropriate meter o size is in use, the water pressure shall not be less than fifty (50) pounds per square inch as pressure tested at the water meters that interconnect that water to the Complex. C. Sewer Service Supplied by the City to the Complex and School Site Transferred to the .d CCWSD; City Sewer Rates to School Site. The City has been supplying sewer service to the c) Complex and School site (through the Linwood Avenue force main). At no cost to the City,the 00 County will disconnect the Complex and School site from the Linwood force main and concurrently connect both of these two service sites to the CCWSD's sewer system. This Agreement does not control the City's sewer rates to be applied by the City to the School site. Applying the City's then generally applicable sewer service rates,the City shall collect and retain all of those revenues. D. Sewer Gallonage Imputed to the School site. Each billing-cycle the sewer service gallonage to be imputed to the School Site shall be fixed by applying 100%of the City's metered water gallonage supplied to the School site. E Quantity of Sewer Service Imputed to the Complex City's in-City sewer service rates. The sewer service gallonage to be imputed to the Complex shall be fixed by 100%of City meter measured gallons of only the "net potable water" supplied to the Complex each City billing-cycle. The following City supplied water shall be excluded to calculate the sewer service gallonage imputed to the Complex: City water for irrigation; City water for use by the County's cooling tower; and City water for other future water uses, if any, if that water will not increase Page 6 of 16 • the sewage gallonage coming from the Complex(into the CCWSD's sewer system). The City shall apply its generally applicable in-City sewer service rates to the Complex as set forth in the City of Naples Utilities Rate Schedule for Commercial Customers (no sewer surcharge). For these sewer rate purposes the Complex shall be treated as if it is (and remains)wholly within the City's geographic boundaries. 2. THE HORSESHOE DRIVE AREAS; WATER AND SEWER SERVICE TO THESE AREAS; SEWAGE EQUALIZATION TRANSFERS FROM CCWSD TO CITY. A. City Water Service to the Horseshoe Drive Areas. The following three geographic areas are referred to in this Agreement as the "Horseshoe Drive Areas": (1) South Horseshoe Drive/Collier Industrial Park (the "Park") which is in industrial or commercial uses; (2) the Coconut River Estates, and(3)the River Reach area,which are both in residential uses. The City will continue to supply water to these areas by applying the City's then generally applicable water service rates. The Horseshoe Drive Areas are depicted in Exhibit "B" attached to this Agreement. w B. Transfer of the Horseshoe Drive Areas Sewer Service from the CCWSD to the City. As contemplated by paragraph 5 of an Interlocal Service Boundary Agreement between and among the City, County and the East Naples Fire Control and Rescue District dated cc a November 2, 2007,in conjunction with the Collier Park of Commerce annexation(OR: 4298,PG 2715, Public Records of Collier County), the City shall provide sewer service as soon as possible, to the Horseshoe Drive Areas (through the Horseshoe Drive Interconnection - See Paragraph E, below). C. Sewer Service Gallonage to the Imputed to the Horseshoe Drive Areas. The amount of City supplied sewer gallonage to be imputed to the Park area shall be fixed by 100% of the metered water gallons supplied by the City to the customers in the Park area during each billing-cycle. The amount of sewer service gallonage to be imputed to the Coconut River Estates and to the River Reach areas shall be eighty percent (80%) of the City's metered water gallonage supplied to those areas each City billing-cycle. D. Sewer Service to the Horseshoe Drive Areas. The CCWSD has been providing sewer service to the Horseshoe Drive Areas, and by agreement with the CCWSD, applying the CCWSD's sewer service rates, the City has been collecting these revenues and has been Page 7 of 16 remitting those revenues to the CCWSD. The City shall continue to collect those revenues from the customers in the Horseshoe Drive Areas and shall continue to remit those sewer service revenues to the CCWSD. By means of the sewage equalization transfers (See Paragraph E, below), and that the School administration shall pay the City for the sewer service gallonage imputed to the School site (as invoiced by the City to the School site), and that the County shall pay the City for the sewer service gallonage imputed to the Complex (as invoiced by the City to the County), the City will thereby be paid in full for the sewage equalization transfers delivered to the City through the Horseshoe Drive Interconnection (the net result being the same as if that sewage gallonage is delivered to the City's system from the Complex and from the School site). This interconnection point is located near the southwest.corner of Airport Pulling Road and North Horseshoe Drive(The location is depicted on Exhibit"C"attached to this Agreement). E. Sewage Flow Equivalency Transfers. The intent of this Agreement is that, equivalent sewer flows will be diverted to the City, as measured by the City of Naples metered water bill. The amount of equivalent sewage to the City's sewer system from the area (as described in Pzi Article Three, item 2.A.) connected to the Interconnect ("I/C") will be diverted by the CCWSD opening the I/C located at the southwest corner of Horseshoe Drive and Airport Pulling Road. w Throughout the first year of the agreement, the staffs of City of Naples and the CCWSD will jointly monitor the City of Naples Water bills to determine equivalent sewer flows as noted in other sections (Article Three, item 1. D., item 1. E., and item 2.C.) of this agreement. After the o 0 first year of execution of this agreement, equivalent sewer flows will be adjusted in the months following based on the joint agreement between the CCWSD and the City of Naples staff. If all possible flow from the area connected to I/C and diverted to the City at maximum hydraulic flow capacity of the UC, said flow will be deemed equivalent. The process described herein will be repeated each year following the first year during the life of this agreement. F. Reimbursement Payment from County to City regarding the Horseshoe Drive Interconnect. The CCWSD has expended $138,159.25 to interconnect a CCWSD-owned wastewater force main to the City's wastewater facilities for delivery of sewage into the City's wastewater system from the CCWSD and/or from the.City's system into the CCWSD'S system during emergencies. The CCWSD managed and paid for that work and the City paid the CCWSD already incurred costs of$50,935.62. As this interconnection is not to be limited to emergencies,the County will promptly remit the already incurred costs to the City. Page 8of16 3. LINWOOD AVENUE FORCE MAIN QUIT-CLAIMED TO COUNTY. Only the Complex and the School site (until such service is soon to be transferred from the City's system to the CCWSD's system) are supplied with sewer service through a six-inch (6") wastewater force main,referred to in this Agreement as the "Linwood Avenue force main." This force main is now of insufficient size to comply with the Florida Department of Environmental Protection's requirements applicable to transfer of the current combined quantities of sewage gallonage from the Complex and the School site to the City's sewer system. This force main shall not provide any service to the School site, to the Complex, nor to any other site after the Complex and the School site are disconnected from this force main. There is doubt regarding ownership of the property title to this force main. To remove this doubt the City hereby quit-claims to the County (not the CCWSD) all rights, title and interests the City has or may have in this force main. At the County's discretion, some or all of this force main (but not the City's lift station) may eventually be removed from the ground at no cost to the City. The location of this force main 0 and lift station is depicted on Exhibit"D"attached to this Agreement. Pri sue. 4. CITY'S UTILITY BILLING ORDINANCE. The City's current water and sewer service w rates are listed on a two (2)page schedule attached hereto as Exhibit"E". The Complex shall be treated in the same manner as other City commercial customers. ARTICLE FOUR ACCORD AND SATISFACTION The City and the County agree that this Agreement settles and forever resolves any and all claims and disputes of every description that each party hereto had, may have had, now has or now may now have, against any other party arising out of, or associated with, the 1977 Basic Agreement (the "BA") and/or either or both of the BA's two (2) amendments, and/or any of the BA's nine (9) addendums, including with regard to any and all utility rates, fees, charges, surcharges, impact fees, water and/or wastewater service, water and/or sewer pressures, water quality, all service area boundaries, and otherwise. ARTICLE FIVE EXHIBITS ATTACHED TO THIS AGREEMENT The Exhibits attached to this Agreement are: Page 9 of 16 - I 1. Exhibit A: The geographic boundaries of the City,the boundaries of the existing water service areas,and the boundaries of the City's existing sewer service areas in unincorporated Collier County. 4. Exhibit B: Depiction of the Horseshoe Drive Areas 5. Exhibit C: Depiction of Horseshoe Drive Interconnection Point 6. Exhibit D: Depiction of Linwood Avenue force main point. 7. Exhibit E: City of Naples Wastewater and Water Rates IN WITNESS WHEREOF, the County (including the Collier County Water-Sewer District) and the City hereby enter into this Interlocal Agreement - Accord and Satisfaction, this ,,2t-( ' day of k.io ru pt ,2009. CITY OF NAPLES ATTEST: o --By:"d16/#4411 .� By: 1.��� I�S,jIZI.�r, BILL BARNETT,MAYOR Tara A.No City Clerk �"' b ca ATTEST: BOARD OF COUNTY COMMISSIONERS ,tea DWIGHT :H>2OCK Clerk OF COLLIER COUNTY,FLORIDA,AS `/< 'VO ,�� ;� THE GOVERNING BODY OF COLLIER `" ��` ...,--t...,-., COUNTY AND AS EX-OFFICIO THE W f , "raj• ` I .,. e GOVE' I: BOARD OF THE COLLIER { COUNT WATER-SEWER ISTRICT hieb4 0..4-0400 By 11 btt∎S". DO A FIALA, CHAIRMAN Approved as to form Approved as to form an legal sufficiency: and legal sufficiency: ti . A- Ct0 ' a f-1.., e y A.Klatzkow Robert D. Pritt, ity ttorney County Attorney /revised 2/6/09 12:00 p.m. Page 10 of 16 '� a•s a.,1 cam. 5 0r = ILI j Y o. °V . rF s� 0 5 0 Cat 1. 1 . `,, �, 9' ► pfd • � _- iiii / ra,gitt Op t J vaDo . • '+ �i / R I' a r ',.II 1 A,O i eP. A, 4 /AA . ,,1 ‘,. .., . i. = i or 4 P _ ., 100 or - O V m • b 44 ...aali • ` �, ; eiir At i \J /' + 3 di d I 4 d •0 5 w v FTC— ,,,� 101(ja ,, 1 , fa 0 . ck Ade 17 f -- ' 1 r j v_ a( r., g U . O Ail f skill . a _ o . Ce). Nts 11 j • rig*-v4i 41 fr ..„:„, Water&Sewer j 0 Service Areas ill, D a °'i =0 ay d Napier,Timm abigilma r..a.. SWIMMER tr.:;• - 7' rw...�.r.m.lrrI + ` .W.l...r M.IMr.ft..MM / rjj I~ ! :V . GIS Divisisa fid.igrl..ir+7q.r.r s.w...ru.w • 1—LJU 1 wes sgl.an.7u!! •..Rr. .',r, 0 0.3 0D 12 r.xcaw.M.rfrro~weal l•4-,a A_'1 r,i .-':.:?,0, , Pagel 1 of 16 • 4. T Li CO 1 11 Te W 1 1• . 1 1 ) FS t I Lama t` 4 Le H . to• E I . I i 1 xT ; • } .rte ''''."=' T �s� L� i 1 • 4,w +/., t V I N �� L I N� v C d N i H 6.1=• _.. i cu , i I / u` tii r . v • r D C r s 2 ? L w • • A X ,\ .. - `�F W� on ww.e•bs---- • • i 3 '` ' • w Ia O M> l W k oo s 0 • f . t N a J J hind i dOd IIV . c «... 04g v Aft 03 C z � - - i- •c o c� • `. # � VJ • lig CO. #: z C 7C �. U U m ' •v I I > • L c c W m y m • C) m � m 7 2 w -J ii i° c4 < L. Itlipiy 3 • , ,. / W e • x1tn o 14 l'i„if aE O v S rj c-.,, Sa o x g v .e s oN mnd laodLUV .9 . A,cA . W L 'v X G` p ,o.P o(.." (/) Z 0-c �:. ID U U . , l.,z ....c N CO U .-I 0 c c M 9 V 2,1, . , • • Exhibit E § 30-36. Water service rates. Meter Size Monthly Base Charge (all Equivalency Factor customer classes) 5/8"-1/4″ $7.05 1.0 1.0″ 17.62 2.5 1.5″ 35.23 5.0 2.0″ 56.37 8.0 3.0″ 112.74 16.0 4.0″ 176.16 25.0 6.0″ 352.31 50.0 8.0″ 563.70 80.0 All customer classes will be charged the base rate according to their actual installed meter size. Monthly Consumption Charge/1,000 gallons All Customer Classes Block 1 Block 2 Block 3 Block 4 5/8″-3/4″ 0-7,500 7,501-15,000 15,001-22,500 Above 22,500 1.0″ 0-18,750 18,751-37,500 37,501-56,250 Above 56,250 1.5″ 0-37,500 37,501-75,000 75,001-112,500 Above 112,500 2.0″ 0-60,000 60,001-120,000 120,001-180,000 Above 180,000 3.0″ 0-120,000 120,001-240,000 240,001-360,000 Above 360,000 4.0″ 0-187,500 187,501-375,000 375,001-562,500 Above 562,500 6.0″ 0-375,000 375,001-750,000 750,001-1,125,000 Above 1,125,000 8.0″ 0-600,000 600,001-1,200,000 1,200,001-1,800,000 Above 1,800,000 Usage rates: p • Block 1: $1.14 per 1,000 gallons. sP. Block 2: $2.00 per 1,000 gallons. Cr-) b Block 3: $2.85 per 1,000 gallons. - Block 4: $3.42 per 1,000 gallons. Irrigation meters are billed in the same way as a potable water meter with the base charges and consumption charges listed here. The bulk potable water rate is$1.85/1,000 gallons.This rate will be adjusted annually as indicated under section 30-33(g),Annual Rate Adjustment by Index. Page 15 of 16 • Collier County 10-Year Water Supply Facilities Work Plan Ordinance Integrating Goodland Water District into CCWSD Appendix B ORDINANCE NO.2012-4 3 rA AN ORDINANCE OF THE BOARD OF COUNTY COMMISSIONER OF COLLIER COUNTY, FLORIDA, AS THE EX OFFICIO GOVERNING BOARD OF THE COLLIER COUNTY WATER SEWER DISTRICT AND THE GOODLAND WATER DISTRICT, REPEALING IN ITS ENTIRETY ORDINANCE NO. 80.43, WHICH CREATED THE GOODLAND WATER DISTRICT. -< WHEREAS, Collier County Ordinance No. 75-5 created the Goodland Water District f , with all of the powers and duties prescribed by Section 125.01 (q),Florida Statutes;and `:j WHEREAS, on April 22, 1980, the Board of County Commissioners (Board) adopted Ordinance No. 80-43, which superseded Ordinance No. 75-5, in order that the Goodland Water District would be granted the powers and authority of a Municipal Service Taxing and Benefit Unit under Section 125.01(1),Florida Statutes;and WHEREAS, it is the intent of the Board to repeal Ordinance No. 80-43 so the Goodland pi Water District may be dissolved and integrated into the Collier County Water Sewer District;and hi WHEREAS, the Board finds that it is in the interest of health, safety,and welfare of the Collier County citizens to repeal Ordinance 80-43 in its entirety,which established the Goodland t Water District. NOW, THEREFORE, BE IT ORDAINED BY THE BOARD OF COUNTY COMMISSIONERS OF COLLIER COUNTY, FLORIDA, AND AS EX-OFTAO ',CIE GOVERNING BOARD OF THE COLLIER COUNTY WATER-SEWER DISTRICT,that:° `°1 F SECTION ONE Repeal of Ordinance No 80-43. v;- _� .+.� il Collier County Ordinance No.80-43 is hereby repealed in its entirety. o SECTION TWO: inclusion is the Code of Laws and Ordinances. :1 The provisions of this Ordinance shall become and be made a part of the Code of Laws and Ordinances of Collier County,Florida. The sections of the Ordinance may be renumbered or re-lettered to accomplish such,and the word"ordinance"may be changed to"section,""article," or any other appropriate word. t %i SECTION THREE: Conflict and Severability. . In the event this Ordinance conflicts with any other Ordinance of Collier County or other applicable law,the more restrictive shall apply. If any phrase or portion of the Ordinance is held invalid or unconstitutional by any court of competent jurisdiction,such portion shall be deemed a ., separate, distinct and independent provision and such holding shall not affect the validity of the ^9 remaining portion. x 1 SECTION FOUR: Effective Date. 4' This Ordinance shall take effect upon filing with the Florida Department of State. • 1 PASSED AND DULY ADOPTED by the Board of County Commissioners of Collier County,Florida,this 11 m day of December,2012. ATTEST: BOARD DWIGHT E.BROCK,CLERK OLLIEROCOUNTY FLORID S AND A S� . A,ANDAS '� EX-OFFICIO THE GOVERNINo$OARD' � OF THE COLLIER COUNTY;WATER- :: a.•.1a3•80epQ'-.. SEWER DISTRICT AND THE • ��1 ........,'•.�•� ;� GOODLAND WATER DIST$I, >:1 '1Rt�`� ! By. FRED W. � .COYLE, .� ,Nt' CHAIRMAN • ' Approved a +to orm and legal sufficiency: :. Stif k2244L ,-,. Scott R.Teach >'; Deputy County Attorney This ordinance.,filed'ittfl. its ?-1` Scre��off # the Y . ^ 4rcok wi Fd 9em t that.. r fi'' .91'0,0...14 this day 7/ 'Plot. .1%4..1: 2 STATE OF FLORIDA) COUNTY OF COLLIER) I, DWIGHT E. BROCK, Clerk of Courts in and for the Twentieth Judicial Circuit, Collier County, Florida, do hereby certify that the foregoing is a true and correct =.4 copy of: N g ORDINANCE 2012-43 which was adopted by the Board of County Commissioners on the 11th day of December, 2012, during Regular Session. WITNESS my hand and the official seal of the Board of County Commissioners of Collier County, Florida, this 17th day of December, 2012. DWIGHT E. BROCK Clerk of Courts ,, ' V14i* Ex-officio to f, , � County Commie�s4os ''3 N c;'c7+/ ',; mac' oarce:0: By: Martha Vergara';, . . Deputy Clerk Collier County 10-Year Water Supply Facilities Work Plan Agreement for Potable Water Service Calusa Island Village (Goodland Area) Appendix C 1 16 C2 AGREEMENT FOR POTABLE WATER SERVICE CALUSA ISLAND VILLAGE (GOODLAND AREA) n ~ The effective Date of this Agreement is the q"' day of March,2004. � M � R O THIS AGREEMENT FOR POTABLE WATER SERVICE to be provided by the County E. o to the Development Site is between the Board of County Commissioners of Collier County, 8 Florida, as the Governing Body of Collier County, as the Ex-Officio Governing Body of the al Collier County Water-Sewer District and the Goodland Water District hereinafter(the "County") and Calusa Island Village, L.C., a Florida Limited Liability Company ("Developer"). One primary purpose of this Agreement is to contract with the Developer to grant to the Developer O C ten (10) years to recover some of its costs if and when other specified lot(s) or parcel(s) of land °I Ne connect to the subject system. ofto RECITALS E O cn WHEREAS, Developer requests the County to supply potable water to and for the 0 Development Site (which Development Site land area is described in Exhibit "A", attached :1.14 C 7° hereto); and 8 ca, WHEREAS, the proposed Development is in need of a supply of potable water from the I� . NNW County to the Development Site. The total anticipated water demand from the Development Site �, 8 m . may not be available from the now existing Goodland water utility facilities, and these facilities 2 ao may have to be rehabilitated, renewed and/or upgraded before the County can provide the total potable water demand required by the Development Site; and t" WHEREAS, all lots except those noted in the Chart (page 4) are grandfathered against a C mm reimbursement to Developer and each such lot has a claim to water capacity from the facilities that is superior to the reserved water rights of the Development Site, and one (1) or more of such N M+ vested lots/parcels could possibly request water service from these facilities anytime during the ® e ten(10) year reimbursement time frame: and WHEREAS, County shall supply the subject potable water to the Development Site by purchasing potable water from the City of Marco Island pursuant to assignment to that City of a former agreement between the County and a private utility, Florida Water Services Corporation (FWSC). The City of Marco Island has recently purchased the Marco Island Utility System from FWSC and as a result the source of the subject potable water is now and is anticipated into the foreseeable future to be that City;and 1 OR: 3518 PG: 1802 16C2 WHEREAS,before the total demand of the subject potable water can be supplied by the County to the Development Site, the Capital Improvements described in Exhibit `B". Goodland Water Booster Pumping Station Upgrade— Phase I, from Greeley and Hansen, (attached hereto) may or may not have to be completed, depending of the extent, if any, that vested lots may request service and the fact that the total actual excess capacity in the existing facilities has not been quantified; and WHEREAS, Developer agrees to pay all project costs associated with design,permitting and construction of the growth components of the Capital Improvements(the component parts of which are described in Exhibit `B", attached hereto) to enable the County to provide adequate pressure, quantity and quality of potable water by improving the current facilities to meet the (increased) build-out demands of the Development Site (current and future uses), which maximum average daily demand is projected by the Developer to approximate but not exceed sixty-eight thousand three-hundred and thirty (68,330) gallons per day (GPD) and an anticipated average daily demand of 10,400 GPD for Calusa Island Village;and WHEREAS, Developer and County estimate that the projected costs of design, permitting and construction of the growth portion of these capital improvements will total approximately $173,200, and may exceed that sum, but Developer's obligation under this Agreement shall not exceed$200,000; and WHEREAS, the total, actual costs shall be advanced to the County by Developer according to the payment schedule specified herein; and WHEREAS, the total of these costs shall be adjusted as appropriate (by mutual agreement of the parties) based upon determination of the final,actual costs; and WHEREAS, if at anytime within ten (10) years from the effective date of this Agreement, any representative of any non-vested lot(s)or parcel(s), identified below in the Chart (page 4) (the legal descriptions of which are in Exhibit "C" attached hereto), applies to the County (or later possibly to the City) for any County authorization and the respective County approval will require that the respective non-vested lot or parcel will require water service from the subject water system, a pro-rata share shall be applied to each such non-vested lot or parcel of real property and the Developer shall be reimbursed by the landowner (or representatives of the landowner) prior to the County providing water service to the respective non-vested lot or non-vested parcel of land. It is possible that within the ten (10) year reimbursement time frame 2 OR: 3518 PG: 1803 16C2 the subject facilities and service area may be transferred by the County to the City by Interlocal Agreement. In that event the County shall make such transfer subject to this Agreement; and this Agreement shall to the greatest extent allowed by law shall be binding on the City during the 10 year reimbursement time frame; and WHEREAS,the applicable payment shall be determined by the future estimated average daily water demand for each non-vested lot or parcel, and shall be paid by the respective non- vested property owners directly to the Developer for the purpose of reimbursement to the Developer for such property's pro-rata hydraulic share of the Capital Improvements paid for by Developer under this Agreement. It is not anticipated that any non-vested lot/parcel will be eligible for water service from the subject utility facilities, but in the event that any non-vested lot(s)/parcel(s) listed in the Chart(which are described in Exhibit"C") should be eligible for and require water from the subject facilities, that parcel must pay to Developer the applicable pro- rata hydraulic share of the improvements in accord with the Chart subject to adjustments determined by the final actual costs; and WHEREAS, no such County approval with regard to any non-vested lot or non-vested parcel of property shall be vested unless and until County staff is convinced that the applicable reimbursement has been received by Developer. The County shall not operate as a collection agent. Although County will administer this Agreement in good faith, the County shall not be liable to Developer or any other individual or entity in the event that any reimbursement(s) is/are not paid to Developer; and WHEREAS, no such application received by County staff after the ten (10) year anniversary of this Agreement shall require any non-vested lot or parcel of land to make any reimbursement to Developer pursuant to this Agreement; and WHEREAS, the amount of reimbursement money to be paid by each respective non- vested property shall be the total future contribution calculated on the basis of $2.53476 per gallon per day average daily water demand (based upon the estimated $173,200). The amounts calculated below are estimated to be 3 OR: 3518 PG: 1804 1 6 Chart Area/Property of the Non- Future Estimated Future Vested Lots/Parcels Average Daily Contribution for Water Demand Growth Component Calusa Island Village 10,400 gpd $26,361 Calusa Island Marina 18,200 gpd $46,133 Palm Ave. Tract 2,930 gpd $ 7,427 Future County Park 8,000 gpd $20,278 Moran Condos(48 units) 28,800 gpd $73,001 Totals 68,330 gpd $173,200 Only each above-listed non-vested lot/parcel must pay to the original Developer its respective pro-rata share of the actual total costs for the subject Capital Improvements in the event that the respective non-vested lot/parcel is to have access for service from these utility facilities. The applicable pro-rata share shall be allocated to the Developer in relation to the original contribution as adjusted by mutual agreement of the parties, as appropriate,to reflect the final actual costs; and WHEREAS, the Developer shall be eligible to be reimbursed its actual expenditures for the specified items, which, as specified in this Agreement, shall not exceed $200,000; and WHEREAS, the entire Developer Site must connect to the County Water Facilities upon completion of the Project, subject to payment to the County of all then applicable charges related to water meters,tapping charges and other generally applicable charges for such service; and WHEREAS, with regard to these capital improvements,the County shall not impose any water or wastewater impact fees against the Development Site; and WHEREAS, Developer has accepted the terms and conditions in this Agreement as part of the County's review and approval of the Developer's land use petitions. 4 OR: 3518 PG: 1805 WITNESSETH 1 C 2 NOW,THEREFORE,the parties hereto agree as follows: 1. The above WHEREAS Clauses are incorporated herein as if set out herein. 2. The Developer agrees that the County shall design, permit, and construct the Capital Improvements to the Goodland potable water facilities as needed to upgrade the County's existing water system as described above, with the Developer funding the growth portion of said costs, and Developer agrees to connect the Development Site to the County's existing water utility system, at Developer's sole expense and at no cost to the County. 3. Pro-Rata Reimbursement to Developer for Later Physical Access to the Capital Improvements. Representatives regarding each non-vested lot or non- vested parcel of land, if any, that requires water service from these Capital Improvements shall be required to pay its pro-rata reimbursement to the Developer if, within (10) years from the effective date of this Agreement, a representative for one or more below-described lot(s) or parcel(s) of land then requires water service from these Capital Improvements, and at any time within this ten(10)year time frame applies to the County for any permission or approval that will require the respective lot(s) or parcel(s) of land to connect into the Capital Improvements for water service. 4. The potable water service to the lands within the Calusa Island Village ("Development Site") shall be connected to the County's potable water utility system at a connection point approved by the County. 5. Developer shall be allowed thirty (30) days to review and comment upon the reasonableness of the proposed project budget and specifications. 6. Subject to adjustments as specified, the Developer shall make a payment of the estimated amount ($173,200)to the County in exchange for the County providing potable water service at adequate pressure, fire flow,quantity and quality of water for service to the Development Site. Subject to adjustments as specified, this estimated sum of$173,200 shall be paid to the County as follows: 5 OR: 3518 PG: 1806 6C2 a. Eighty-six thousand six hundred dollars ($86,600) shall be delivere to staff within thirty (30) days of execution of the Agreement by the Chairman of the Board of County Commissioners; and b. The remaining unpaid balance shall be delivered to staff before any Certificate of Occupancy is issued with regard to the Development Site. If the final, actual-costs are NOT known at that time, the second installment payment shall be $86,600. If the final costs are known at that time and total less than $173,200, Developer shall pay such smaller balance due. If the final actual costs exceed $173,200, the Developer shall pay the remaining balance up to, but not to exceed, a total of both payments of $200,000. If Developer's costs (now estimated) are less than $173,200, the difference shall be reimbursed to Developer within thirty (30) workdays after those actual costs have been finalized. 7. Although the Developer desires that the subject potable water be available to serve the Development Site not later then October 1, 2004, the County cannot make a firm promise to meet that date or meet any other estimated deadline date. However, the County will proceed in good faith to try to provide service to the Development Site as reasonably possible. To the extent that effective service can be provided to the Development Site from the now existing facilities, and subject to priority of vested lots, and notwithstanding completion of the subject capital improvements but subject to the Developer paying the applicable fees to the County as scheduled, Developer shall be allowed to make connections to the subject water system and receive the concurrent applicable Certificates of Occupancy. 8. The Developer will pay all costs associated with installation of water meters and water tapping charges by the County as applicable at the date of connection of the Development Site to the County's potable system. 9. The County and the Developer agree that, to the greatest extent allowed by law, all the terms, covenants and conditions herein contained are and shall be binding upon their respective assigns or other transferee(s) of this Agreement, including, with regard to the County, the City of Marco Island should within the ten (10) 6 OR: 3518 PG: 1807 1602 year reimbursement time frame, this system is sold to or otherwise transferred to the City of Marco Island by Interlocal Agreement. In such event the County will expressly make such Interlocal Agreement subject to this Agreement to be binding on the City to the greatest extent allowed by law. 10. If either party (successor, assign or transferee) desires to give notice or to make any tender to the other party hereto, such notice or such tender must be in writing and shall be deemed delivered when actually received by the other party via hand delivery or by delivery through the United States certified mail, return receipt requested, and addressed to the party for whom it is intended as follows: Collier County Water-Sewer District Attn. Public Utilities Administrator 3301 East Tamiami Trail,Building H Naples, FL. 34112 * * * * * Calusa Island Village 5130 Main Street, Suite 6 New Port Richey,Florida 34652 Copy to: Leo J. Salvatori, Esq. 4001 Tamiami Trail North, Suite 330 Naples, Florida 34103 Nothing herein shall be construed to prevent either party from changing above- stated place in Florida to which subsequent notice should thereafter be addressed, but no such notice of change of address shall be valid unless given in accordance with the terms of this paragraph 10. 11. Failure of County or Developer to comply with any provision of this Agreement shall be sufficient basis upon which the other party may terminate this Agreement except to the extent, if any, that such failure or delay(s) have been caused by Act of God, war, strike, fire, flood, weather, lack of supplies, breakdown or shutdown of equipment, failure and capacity of transportation facilities, or any law, rule or regulation, or order or action of any court or agency of instrumentality of any government, or any other cause beyond the control or the party hereto responsible for or charged with such failure or delay. However, the nature of this Agreement requires both parties, and their successors and/or transferees, must administer this 7 OR: 3518 PG: 1808 of this Agreement shall 1 e C 2 Agreement in utmost good faith and that termination g last resort remedy. IN WITNESS WHEREOF,the parties hereto, acting under authority of their respective authorized offices, have caused this Agreement to be duly executed as of the day and year first above issued. Calusa Island Village, L.C.,a Florida Limited ' Liabi • y Comp a i2f ,.,-il tk. .).),.__H—\2A.0.-14.4 ` I First Witness Robert . Re d, II,as Manager _ Printed - .-; .,f First Wi ess L / <- I c lip• . ' ' (typed)name of 2°' Witness ACKNOWLEDGMENT STATE OF FLORIDA) COUNTY OF COLLIER) '( The foregoing agreement was acknowledged before me this <<tr-.. day of 3anraay, 2004 28e& by ROBERT M. REED, H, as Manager of the -. 1..• Island Village, L.C., who is c0 -known to me OR • •. - as Identification: ?'�Y'i'' , LEO J.SAt'VA I Notary'ubli State of Flo 'da +. ■ MY COMMISSION N CC 987892 My C, ,':.--:.-,-.,.���eyember28,2004 n Noury Public UntlnwtlYn "ti - " i- ' Typed,printed or stamped name of Notary Public .g. ' '-. #' BOARD OF COUNTY COMMISSIONERS *D 40H1'I ;4 �7C Clc k OF COLLI OUNTY,FLO DA n - C c.-, 47 ......4, R *Elie ,SI r°,' 'i DO A FIALA, Chairman Approved asr&tb -.and legal sufficiency: By: 'Thin Thom Palmer, 8 OR: 3518 PG: 1809 16C2 Assistant County Attorney 9 OR: 3518 PG: 1810 EXHIBITS FOR CALUSA ISLAND VILLAGE AGREEMENT 16C2 Exhibit"A"—Development Site—Calusa Island Village. [Attached] Exhibit"B"—Capital Improvements. [Attached] Exhibit"C"—Legal Descriptions of the Non-Vested Lots (listed in the Chart). [Attached] 10 '1tfNI0I2i0 undno?300d V 2 ., . . „ ,,A1:,•Eli.,..91.1,,.„... — �/EfEf �� p � . W 1 i' 1 w ✓".'it :ate i'a a P 1 N 11 ill I;\., `a r�� ° I' �Y a�L__-..- 1 0[31 1�1 �I f g 1 UI gag ci illt C ::1c 1 ''�1 { A m .rl. j-) E 1:: null i \\ 1 2 .0. / C3 g, l' rn him i r r ' 6 \11 WU i I 111 A Itiri I \ t 511 1 1 ' �, . r I it) :C.A.,. „ 00 II E f Q C rn r .....■ CO .41 --qir 64/ r Im...1 1 f�ill r e, I ;�I r E ' a' ' IrII t1vi• 11.11 f 1 q r=1 I I + 1 I 1 I ii j Mii -r ; j,, '1i i 1 Rl I 1 M''•' �` 1 1 ,I ' : lii III ;I .� H1191 hi 1 1 1' G ,€i Hx3 I J' i 11 1; it p ®'a, ANA , N ‘ i I e i a ti. OR: 3518 PG: 1812 EXHIBIT 1602 o a 7 C-) - C - E *V. E L�pi 70 p7 i 1 1. c .. to m O W, ,- n O s y w b y > cn m3 x g3 C t� ..�� Z7 { �' W- el y M N Cil m O Q. ti,el A N 0. 6. (14 n c d g 1 c = .., n 5- c, "a v ° va , m N• — W 4 P . v�'i N a w 64 bA N N N C H y eH.., r I E. o_. C .� 00 c::, 8 p �o o. t� 9p, q gcli i m1 o c) g c o g 8 o O °o g S 1 a $ X $. cO b .ry CA • 1 Er R ' C --- - - - - rtr b p) — .. ..... 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' -eft ""- WAD 7.414,[ a :.■ rile&al* o.2".G■4F-7771),%,1u.'"g 1,00,...., Avl I N i ,,,,,,,; . 411,,A•0`.______ ir -I-4-M 019 .e.e.e e7e e W,.: s. '-' ...,„.747' WIT • . t..! ' telil',...,.–.----.1. • .1 1 1 CALU8A i8C1 D '' ■ ',X, iiik$ ,- VILLAGE 4 - ., :,- .yr• ---..* „ ,..,„„ 1 ‘,/ ,•, iippift... --.P.r....,_i•r.,\ , ,,,...,,,,17-",w;7.:,-,.n.7"-''.-S., 7 ., OF \ ,■:',,,:r.:7 t:v.`;:'°--1-* .........0., . ."'","=..., •.,,,,,.•47," •■ i /'// - ....-::1-"---..G..•Ig - .1.4+5.'.L:-L' :L ..'.". ''.4i . _aft. // ...• , \\\\ \,\•';' . 16.'‘'' ' .v;+2 AicA'/, , 1... • ^ ''' . •-•• _ . ' ''' (--.. ,_ cliumNAALusA usLAND .. . .,,,,,,\:,...‘,‘,‘,,,;,:,,,,,.,,,,,,,,f2.,/,.,-. ', • ..r -'i>•,..:.tr: i'l,'.:/.4,/,,,,:.„7„,,,?///:, ,\:::_mf t \. - • -....... ' .. - is Vz";,;2,,, . .. -1(,,,,*--'1.- ",/''' ./. A--•*Iii '■ ,'''‘-‘,.'-": ,.- Na.ft v , „, I , \\N.', ‘".,' .' / ', ,,, 'N,:\ •. \--2 ' ,6 //-';'// ////,- PAW AVE. TRACT r • ,,, ,e1PAUAER RANCH ,.N \.\‘‘.. *it. 0" = • ■, DEVELOPMENT) _., _ „...t.,. ____ .. •\ , - --,„„ ,.. _ .--mr I ,,a.1 — ---- — Ce . ''lit) FUTURE PA* , . . ■ , ..,/ ....... , 1 „ ---1-- 7, < 0 Ce 0 1 IrIM 900 Emote FL 1 1111115111111 rhonolootrlulCaS la r2i5fi4e—d342'10 0o0 f MOOL D e iM0la Y t : MD.1A F0.W L0.E 2.N.0IMs 0A M 1 0 g NONESTED . L /1511 No.1772 1E: M - 11/3 DOI 2 3 / ...t . , EXHIBIT C•' W r` ` PAGE 2 OF 14 y f David D 6 C2 1 Pnted Y ... ... „. REC M.ilsrden, k - Dep.d Rel Fasts tervkoe s • 4 a _ C Tw evitone Cosse stes � 3290 6.W.Z11ird Av e DOC Miami.FWida 11125 INT— o noo .oa ,� Irie7S day of ixbnury-r A.D., 191$, •f�, his zt9a �+ Haas this zQyi Y between OHLTO1A 0.5113 a ISTESTAISET MU., a Florida corporation, harninaftet referred to as the •Grantor' and 118814X83 YOU I e mm 40 a 1'lorien general pxa`narchip, whose mailing addrss■ is P.O. los Baca, Maple, Florida 311161 heretnattsr referred to as the a N +Ceantae•. t. - That tha said Grantor, fax and in oonaideraticn of the sue of Ten oollsre (010,00) and other good and valuable C2.. consideration, to it in head paid by the said `Grantee, the 0 t eaa receipt and sufficiency whereof is hereby acknowledged, has y1 C . CO ear O m granSe3, bargained, soda need conveyed to the *aid Grantee, its Ys CD sueaae5orm and assigns forever, the following described land .. �+ -+Situate, lying end being in the County of Collier and State of 4 V �,—s Florida, to-wits (8115 IC20:RIT •A' ATTACHED SBRSTO ALD ''d :� s R9FE8t cO it ns APART HEREOF) +n This deed is executed subject to the Following terms and p-a . i 1 CXM conditions: "p t 1. The Grantee shall be responsible for the ad valorem . i • Lases end all assessments, if any, imposed upon the real property begi nice with the 1988 tax year. 2. The Grantee takes the property subject to all easements, " ' soning and ors:cer restrictions and reservations or record. The said Grantor does hereby fully warrant the title to said 1 v. lend, and will defend the saes against the lawful claims of all 1. pardons whomsoever. TO =AVM RED TO BOLD the premised herein granted unto the 10 Grantee, its successors and assigns f in C Sam s� i eocumanterStamp Tax g Received$ ^, Cccume a Slam i Fo_cived S t i(A nonol PrfloertY let • COWER 11NTY CLERK OF CC RTS M 1 . a n:wm.:— ;•.-..x.'rT7ntM-ra:'?`?e."r'-,' , POOR QUALITY ORIGINAL • • EXHIBIT C • PAGE 3 OF 14 -----...,•.,..z•-•--,;,•-: ter;.:.F�+tv ' - ' ' ;• -" -'�;-°.°lam. �_�.- • " .. N IQ ', '_ ro XIrfI•.iZ Oi1tE!> 3, rise Grantor has caused these presents to be signed in its name by its authorized officers and its cor;�,ssi•+ seal to b:1 alfixad tbs s►Y and year above written. 4 a. .: CORP. : ig:.ed, ssalsd and da`ivsr.d D�iOdsA L7MIO 1r I'rYTAlRI<MT . 0 p�reit*.ce ors �! (1 1i1 .r sly y I BY 1 '.'.p it ......-- .:,�le�[ -- president k• d t ATTRST t sl Fr i; . i ilicut......a.lizta . Corporate oaarstary,.t. 1.J••.; 1 s OTR:S Or MORIOA I sr. ) an. '. COD STY Oa DADE ) 0 ' 29th day of Peisrsary r '� I fiSR68Y CeRTIFY that on thiseared BAtda Do CORT>I11 jR, ,cl iu a.0., 293e, before me personally appeared W and RICSBLIE R. GARS1S, president and Corporate wearetida' �f respectively, of DELTOEiA TARO a lgyggT11Ei1T CORP., ♦� corporation, to me known to ha the per.:ons who signed the Cf0 ^%t execution thereof to be their free acts tu!that they s 101 such h • a"Cy execution ' tbeteto for the purposes therein mentioned r's tpereto the official coal of said corporstioo=;tion that the said •.;Vy instrument is the act and deed of said corporation. spa• • WITNESS my Signature and official the day andmi, in CIO seal at :- Dade and State of Florida, s—a County of CIO aforesaid. 1(1 Ytt�41 . 'rotary Pnbl c, tate oc r. o . • a , at Large _ ..+ rt ; ..f:-'� Witt•KOIQ tiatt a<rlOtSO/ M amens 10,fa U.11n " ;1 My comtiesion expirsns WWII MI,aaau nt.tu• ; 1s: 2 I POOR QUALITY ORIGINAL i __ ._ __......_. - XHI-$-I•T C._ . . .. _...•.r Y ..►i' ";r-.mot.re,:r'`nti 5-_. - R�""^ .,ss.i.rj .-" -. . i - : - tottel esislt_ roe - RYHZ919 •t►' • r.eeel aekalRt 4 lag 'e `" ¢is' Po`Yioo�afi t • h pexael of lend, lying in and being ;act cR the plat of W?RCO ' BBAv't CELT a1*TR9•k, according to the pat thereof as reuordsd in x . pzat::took- E, Peeve 115 thrseegn 119 of the fubLLO Reoecds of y Chiller Ccuntty, .p tolthe the past-of ammo sons Plat SookM6- - !4Rl;t'., awotslfin¢ n, ;alga :+-A through 10-A of the !While Reoocds of Collier County. 71OrLda, being note particularly desocibsd ae tcilova; ' Range 25 seat,K Collier tCounty, tlori o MIS at the cornor of daracid• h mealieibei g on uthe 6aoterly pat boundary of suoreaaid Macao aaaoh Unit Six-teen, tharica run blong said Bastarty plft boundacy 80561 /42°E E S distance 512.11 feet; thenea leaving boundary a°t' 23'4 a distance-of 691.30 feet to an intersection •{ with the grly plat hOundary of'said Unit fiateea; thence . .long said Bautharly plat boundary run 8g2.26•272f a distance of I 15.5L foQtc thence leaving said Southerly plat boundary- run teat distance W05°41'41°0 0 558.67,feet ; of thence 532.12 St h 0 °6 a of ndlstanoa N27'22'45'6 26.10 O•c N{9•.43'02'8 a distance of 25.20 feet, thence p feat; 1301 e s • Casten s o 3 distance thence�B3 9t01.14'Shandistance9of 24.51 - teatanca of 18.54 sett. ,ZOe •e W test; thence 833°l$'4?"s a distance of 30�•B6 feet= thence • 1183•'10'A3"1+ a distance of 139.38 feet; these M05'1. distance 'Of 907.73 feet; thanes^587°01'44'W a distance ofs27.85 thanes -S89.2_2'30•ei a dirtartce of 79.90 feet; thence ,sat; ' of 27.08 feet; thence Z;84•54'10'i5 a i. distance o a distant; thence'879•42'S8°W a distefl b o 30.86 destance of e3.20 feat, C teat; thence `N83.12'ZB'ii a distance' of 32.30 fast= dietane@7 of 37.95 sfasts thence 4867°31059 H aadiatance�of 52.09 feet; thence 8 3.37'15'p a distance otthenee fita00r19thence s 4 1353•63136°e; a distance of 30.56 feat; X71 diat5nCe of 24J1W-feet; thence 834.31'S,4'ft a distance of 149.60 of :'''.' ' feat to an intersection with the -Southerly Right of s Way on State Road .No. 92-A (100^ wide Right of Way) nfccesaid plat of Mete* Beach Unit Twenty; thence run the following _courses along said Southerly Right cure;turene. S ! 545•02'43 a distnnee of 186.86 feat to a po ft a circular curve,'concave to the portheaet a d haw of s id iasrof 369.31 foot; thence Southeasterly along =i thcoltto a e poinl of of distance of 280.11 of • ,1„ 110. 7 tet toint o_ g plat boundary at aforesaid Marco • -.-. Hatch h? feet to the Easterly p line ofnSec ion sixteen, boundary also Range 26 ,Teat, Collier County. Band laeati section line asdistande of along 1293.57 tiaetnrly pint boundary said :'_.4. Foote to the point of Beginning. r Containing 15.02 acres, soca or luau. Fs • ``',t %OK/44 and vented , . IM On{.N S,W{a sou ua Cauu;r.FLOMOA q"__ma�y lulu C ULU.f, W1 • • POOR QUALITY ORIGINAL EXHIBIT C 16C2 PAGE 5 OF 14 2711140 OR: 2741 PG: 0671 81m Is IIPIWL me m of CIIL1R cant,11 2110121N d N:SiI m!@f L 14004 QiRt NIB 1?SIN.S IiC 11S IS.N IIt-.1I 3175 N This instrUnient prepared by: Lv: DAVID C. EO GBAD t1M!lint I BMW SW ILM a BOURGEAU, P.A. HQ N 2378 Tamiaiii Trail N., Suite 308 • Naples, Florida 34103 Property Appraisers Parcel Identification Number: , Kr_70'2,iv44z6; WARRANTY DEED TBIB WARRANTY DEED made this 31st day of October , 2000, by GOQDLAN , nIC., a F14r, i�A,g ra" ig., hereinafter called the Grantor, to f"a' i."; • W Company . whose post office address is 655 Center Road, Frankfurt, IL 60423, hereinafter called the Grantee: CID 1lITN8ssETa: That the Grantor, for and in consideration of the G0-CS N sum of $10.00 and other valuable considerations, receipt Whereof is hereby acknowledged, hereby grants, bargains, sells, aliens, remises, releases, conveys and confirms unto the Grantee all that certain land situate in Collier County, State of Florida. viz: SEE EXHIBIT "A" ATTACHED HERETO AND INCORPORATED HEREIN Subject to zoning, building code and other restrictions imposed by governmental authority, outstanding oil, gas and mineral interests of record, if any, restrictions and easements common to the subdivision, and ad valorem real propesty taxes accruing subsequent to December 31, 1999. TOGBTEER, with all tenements, hereditaments and appurtenances thereto belonging or in anywise appertaining. TO NAVE AND TO HOLD, the same in fee simple forever. AND the Grantor hereby covenanta with said Grantee that the Grantors is lawfully seized of said land in fee simple; that the Grantor has good right and lawful authority to sell and convey said land, and hereby warrants the title to said land and will defend the same against the lawful claims of all persons whomsoever; and that said land is free of all encumbrances, except taxes accruing subsequent to.December 31, 1999. IPOOR QUALITY ORIGINAL EXHIBIT C V PAGE 6 OF 14 L. _ . ._ _______ , I OR: 2741 PG: 0875 IN WITNESS WHEREOF, the said Grantor has signed and sealed these presents the day and year first above written. in.the P -- - ce of: ASS G000LMgD, INC., sss 01 -- Si- • Lure a Florida 4:T. :oration, Witness *1 - Prin.!. Name 5.E. 'Curcie, as its President — 'tao ►-mss P.O. 4ox 125 pt __ re Goodlsnd.l+1orida 34140 Post Office Address Witness *2 - Printed • (Corporate Seal) w STATE OF FLORID4 c.a+ COUNTY OF COLLIER °° b GI The foregoing imprument was acknowledged before me this _22_ day of Je 2000, by J.B. Curcio, as President of GO )L ND, INC., a Florida corporation, who is ly known . cpp to we or who has produced , •••_ co as identification. i Ne tic Sigaat ra . 4 � '. 1��a2..sr✓iil Notary Public Printed Name My commission expires: (seal) iielti,.. one lm ILw_UCHM 00 umwametaw i°.'• .OraINYMs II POOR QUALITY ORIGINAL II . EXHIBIT C I 5 r PAGE 7 OF 14 C2 *** 01: 2741 PG: 0876 ** EXHIBIT_ - To all dal certain reel popery wrote,tying and being in the eoun Y ofCoUier,State ofirterlda,described as foam: �! C.") cr 1---4 The upland portion ofa parcel of land lying GOODLAND ISLES,as recorded In P1 Book 6,Page 7 Block Public Records of Collier County,Florida. Beginning at the Southeast comer ofLot 24,GOODLAND ISLES,FIRST ADDITION;as relCorded in Plat Book 8,Page I,of the Public Records of Collier County,Florida;Thence South 16 degrees 06'17"West 64.00 feet to the point of curvature of a circular curve concaveto the Northwest having a radius of 50.00 fee4 Thence along the arc ofsaid curve to the right for a distance of23.21 feet hurt a central angle of 26 degrees 35'42";Thence South IS s•44 47'East 27.88 feet;Thence South 16 degrees 06'17" West 94.03 feet Thence•Sooth SS degrees 38'23'•'Fast 216.47 foe Thence North 16 degrees 06'!?East 295.43 feet to the point of curvature of a circular curve concave to the Southwest having a bus of 100.00 feet; Thence along the are of said curve to the left fora distance of 181.41 feet thtu a central angle of 104 degrees 00'00";Thence North 87 degrees 53'43" West 117.28 fleet;Thence South 02 degrees 06'17"West 95.00 feet to the Place of Beginning. • t POOR QUALITY ORIGINAL 1 . '( . • • .. 1 •• . f .., .___. • ; • • . .... _ . L.... • - EXHIBIT C ......,.. : PAGE- 8 OF 14 . • ..„.• . . . . . • - ... .. __ _. . .,. . . - '• - - '- .. , . . - • - .- .• . • . _.7..r. ..,7 • *11111/1111111ir IIIIIIIM wavelosia ....— • et II. OW%/Xiang ' i Ott 01•114 rr.ml • 115t h Collier Ord. 18211 001118$ -- .Nos.IsTeed,FL 33537 liiii*agIMpossilbs it OR BOOK PME. 4rAter 41. Sorokoty . -t aft"' 945 Central Arafat boile44$12152abosombry Sim Ili MON. FL 33940-6394 1 Imbed 3 Clue't•istufhle . omens Tint fano Asesemn Fuld 1111.111irkm VIM NosimIdi .INCIM. OF IT COAT .. tSK "1.1 iffitlimaania m A. . • ausimemrisimet ma • =COX "Air.JAY.22073M'IMUZLVSILITES11"" r ,-. 100 Sagilitirt Ma tie 12th day V Aril • AIL la 10. • atettilltli Lawreice G. Mounter • efthc Gime gr .is Or Mar 0 Oh la .Pan I if 911firsilai al Marisa Neve, la. cr did Omit 4f Col ier .ia ONO&y' Florida .vise MI effse addrete C) N c/a The terse at Saadi end M M Midge, 3300 Stabs Id. 92. Goateed.Ft 33937 PiletY Vdis same pare • =1 .. 61 fill111011014. Ilia the add pert if As Jhot pes4 lb.sod te sonslimia ef Sr see ef "'L. a Tan.aed 00/100-- -- • ($10.00)------.----------dhers C...." • ia ails is bed Paid hp ils&WPM,' efila mall For.tit mot slaw,/Ulan*ealoonfoliet c_ri kw pronead,hopshis4 end add le the said part dice owed par;its kis eel Odra firm.At B Nimbvisowilatles4,80044outiotogastleColoppV Cell ler Aisne/ Florida • • &lab As described as di. attached UMW°A" • • 1-C3 The pruperty described In Exhibit 'V, is memo al property. CIO - IV Tualadios e11 riparian and animrsod lea cigar.of iddah fraater is$eised. to. 1 C=1 ... . .... Vil as . "".... And Ile add pm? if the first pot MN kinktfidb alma die Mb le old hod.ad WS Oa r* the mut etedest tie faufai rhea earl perms atmons. . 3a atom laniilf,fk aridparey erkdietpere As s havorms Ms hoed - and eat de day preritrstabovo orient Nana& . and - -- /* liti4v1"4"41k#644444MM ' .--..-.-•:' - .z, ...._'• - • .'. 1110 1 4111111!. ... .... aura a. NeUrilkr. .= ArWAr7 laiLlzele Lane.Isedniv.ON 44470 • ....... '- r • MN , 114,...11,.......s......." OymarmomoVig.) Ild...1.4•11.ie.ry owsnstror ake OWN..XIMOI . won= atnrstr011e____ I may obareamormalmaansomodisolaiod counrrop*/pow 1 L.sUllahlwrdbealkilllowlowlelemboormayoniena I r.ripnew IS Iliturehr. • — • . Innarybaolokahaperam drasillostlaanduhuseerinktfiregdne Iralnard.IdPiedowslolateiimMILILJALL mirodallmar•LailtroliVathabINOVI•mk_AhallpidWohlissimaumeltenuojla itivr•r Mem!. . ..parsamalxteate____zAai..."2...____ adosamaelloonsonIoaak r-----saawaiselieas=--1 loan. imaanootarsoo.o.aaarermanannseo . •• FL• _____ • .__ , ,.. ta /. • . , • IgYeaalleiKe DailaaR14101 ardiiiiiigertaikokasaatAitio...0%X"ri7n1...9",1/0milikA:.... - . ■•e•;".•'7 - 7 II POOR QUALITY ORIGINAL • . • . . • . , . . . . 16L 2 _ ..... . ... . . . . . . . . , .. . . ... EXHIBIT �C • -- -- — - PAGE 9 OF 14 • J sees... . • -. r _ .wM . - - .•yy�y+�,'[ _ - •' ' ....1mdpR!,./.. -....r L..ix7 ,y � gip•• .MS ,t. w •-• . •• ' .��yw , r • • 1S WT GA. undivided An � (1/2) interest in end to the following - a co a.. we Nhat 718.M tot et Tr at M..RUM NOO 11214 w snPterhw . aeo0410 to the 1040 114 Ors t 4.00i e et the N w or Cet1be • Cove0.emus. 0.0011.1.31 ease..eon or loss. ., • And Al NMhid.4 /Was bear (1/21 illtarslt in end to the following described properly. O nivel ix illucla•ii.01555144 0 soma a In NO> of t.aa.°aiss:e..�V• I .r Prue wean . Oa A Ise a pluai d t M ilia es tea math sift K state ? fPf 40 . . ter et P le.is at 5001111112 Ytlles U. latk.lame 44 Fj • Wq- asitasli Int arewMe in Aeank 0 steep C C> WO N Sts pills r sais el ndllee esenq:.ttet aro m pa.L b llssdtei a•!.Pier. rd seor ate emmeste motamet Site.•teen ear 00 10 W . C) waver as eta wee ISIS d ssu Gedst tL : 4 i'Sa• r W.slap swig.M•it on in 40155 4114 Ni.emot•hammer-Pitt,•Wto s.1 as tee mow? t`� slrityt-sip Um A NUN Mt II.via Wow intim a We um delta Out M.51 Ma M•RIM M eM uriedim C CP al sate rs.tr Sawa ao N.tnMN 16 dtae sill With+ -. N ueu W 144.14 100 te•keel asp Is tee ssisu•Y site er•ailSes thews ws ashle•as the setts sssiss 1113.14 F'i Go to-Islet 11.11 tart toss elf tow west r it■lisp .. Meets hale Perm es Mil.t•• .Idle MMus ease.a•L•it' R.tee III test te a seise M the M/Mar11 dIN.*rst ._.. ISIS K aeu State Yet W.Pr 000 sr S.pave V. ;;.. • aloes ael. Or oral petal M 1zeIneswtldus see K atlsoaeisW.saada r- .57 Ii•o`W.dr.1 vale eip5tre6.0 Use roe!MU eater t . . theme tae a 40 1.2.11'.L tar 2.11 roue to•oweests ••eer eittee seem ow pone••tb easomer Um K Pau Went demob by ea t NBA eeserh It as. A i U K Me 1qt maths.on ste saes.sees tae y.:, 131.11 at s Il aet ht Mary utbus o - • a Ste Pace dun tar lt.it tab 000 rile I..1 41 W V. 55511134 W smut ot,0 h eta m.111.15.24`1.me mod 144 Gee P es eta 010 al 1.0000 as 514 PMM lust s4aaahist • . ago.estoleGi 1.0 asses. •. . r • tee aatt.dt use Si the MreSwsb.w l.wdtsaP.real 55.• 55 the vans d tares Neer or sass.Itlth et ttla 3000 is aeeetll.ae 03144 oostsi err.to sort•headse is to lvelt,lal� epaeed as 40mdtq earns,a■a. 7.11 tveta/i 0010 00 00100 an hr ter ftor80 oat Om Mal RSIMmate lMtr 4.614 sae V.e.Lee..• . Radiate t.etm erlaefetatter atattane le PnrSf 11.•.555.• • I t�►�.�. wj • ' ,.e. 4.1:: ..N•• •r • ♦.-. - • sees-.-w,_ . w-' ' 1 . . • , • . ,.. j.- ______ . . __, • POOR QUALITY ORIGINAL . . i , . . . • ! . 1& 32 2 ...____.• . . • . , EXHIBIT C .. • . • _.. _ _.- • _`1 PAGE 10 OF 14 •�•• • • . ..... . . . . . . . • _ __. _ . _._ .___. _ ______ _ _ __ _ .. ,. __ . • . . . . . , , . . „ _... _ . _ . . . . _. .... . . ,.. .. . .. ., . ,, _ • .. , ... . . . _ .... r " • .. ......... _ .. ....,,,,..4 . .- ... _°_1,m•,�..>. •., .,. .: •t•.weNar Haas mums n.e.r.at ^' N Iw1.,Attaeaefy 8 601137 ' OR PARE lDJ:.Md'th Collier RM. -Mute 16104 FLnen d!1eM Igiiter L Sarakety • s°• 01I Mural Ave. Reaped f lC sltuj 5t i Ta■ I glsi.FL 33,404214 t se!et ae Vas'V'L.ttygle sow*^.Im WM11a______ Yarwsiaae es b mat trorert,Ts. t r.I•447 R or CL IT Val diode Li elk _ -e., 11.101seitwe..cs au a ' ,oew INK we wit No cwt ' a�e�M ilsiumbtre. Mao Mb lttk dq of April . A.D. till . ifilips Oettf•eh Lyon Cowen Delq ifM ar idd lof Col 1ter .de*Slab V Florida .pay elfMebrtNrL cad Reins wren.Lac. rfehisCeent 1f CMI I for .site Seisms aft Florida ,chew pat Wm address it O it CJo The Versa It headland Bridal,3200 State Rd. art. boodlend_FL 33137 MO i parer fibs send par& •• in. Oat dr y el do JEret�!t end Os aw(Jenuaa of do.awed W �1bo---- rio --LreCan6 c-rl le her to iced peed$ du add prey fit send pert eAe recipe eeMeddl UM,«kawrb.ukat, 1-..: Liu pooh larpziont ad add is Al odd prey eta oiscodpore.its Aero aad ouleas.b'iTe de - — JidbwhydrvArdbadauk and Myieli CcaelyV Coll it .8811af Florida , Yadz as described on attached Exhibit'A' "-y the property described in Eihibtt 'A• Is comnercial property. CO • l• ea $b3eat In araaaasea,ieaasvatfine ace mulattos.of sword and red otata N tau far Mayen 1113 end sabapnet years. • os coolidlos on riparian and ewbasniud rod rtdlete of*soh hector to esiswd. r e aAnd di and peed y of do fret fare es es Sri/Mk aerrwl!dad*teasel Lad and will sided tlit sew meant bAten.1dafae ef all penny aelrwsers li Elam std RRtu add Pi/ wilts roe post Aa s brans brans ae her Paid rat MI chip saeyFrwt above aside dradd mei and . . • ti do peerwea Ms . u MS Lynn Delay _/'� +�a -r.r.a..acrd-_ eve ens ' •aei(X4s31dtd:' Rsplee.<Z 3310! • e111.a.• Mrrw • Mir wer p-w.ft.rsrtit M Nod am --S r alolior..._lrfe.tAi — _.._) roe.hOaMcasmtheoneW..ua,....wwMiM•9end aewwrar colic.* _._J is.e.ea tarawnnttik was+l.er.-i i nb+ward ht..rwe•I yea ebel•r - atr.wYw6Padvervaa_._.a--nib:itseriviorr.e*4terl+oedt bieroaRala.enwhdMde.ansrlYae, t.. onn edihmoaienel.datw.eh 6t.elentillonsaddrawvrnalpe.. __SSAS4.`.—......-..:. —. - A.40Ke WaMiirrmetakea .• . aaribwaO011Sa aaat ��'eat.•r. P..iadal6NWaitOrO..a•..awwnser.nuila4 .r�i rind :d. dprll... AD.UM. "`"'s.wirn F= [ POOR QUALITY ORIGINAL .1'• . - • . , . . • ..______... 6 c 2. EXHIBIT.. C 16C2 L PAGE 11 OF 14 . . =no OA. • • in laleliVieled amt hall (1/11 iaterost la and to thee following • o drsot3bed psapsft7. CO tie ms*0.1*tees et Waist'1•.iM__O saeea amts . a. ea +aMtlns fa rig/ es}met as ewtstN 4i pore M it N =lrif sin th emes.et tfe bile Masse Cantor 7e OD t,0Yl11,q.1.12 arise.ma••1aee. ' &ad An undividod o a halt (I/t} interest in and to tltc following described psaplrty. wow es ammo i1.amide P tenth a.R.IS LMt• ..earl*/L1 agog.pet et.Ms wwwei 4l m Q • M aas ta M e ass at as pia UP,Water wntP• 0 hear*11,020 • - _ a 1st at papal K lad lake to NI ages*sue et tb.te • m q , O net tor.O e a/Y.U.tr.oaMy A atata.aaa0t s4� fel 0% .. ~'d sm.saw•pmt ad ttollaxY mods"to sarwedaade 00 syq swat lull*toll woosstd la a.W.sad we ss wags 1 . m/at tea peblto era,0et K Oiime 41010;ratio Ie2 wound is aol,0tN/w Atie.at " t� tea tae oota,0s aeeaent Meg•drum W esehba/na t.T* oatiss•,0etlw otiose so O1 roes lose a eat fa.a1M ~� 11.two 1.1Yli•ea'M.May gat sass!me tof 11142 r CO hat to•sa*nte MOONS rifts braes lap N Oa sweNt1p ea.a —..tar 11 Ittes Vase tau ae•s 1St urs EN the sesterllas at sat pet NSW we W.N•e1•er S.maw x014 ee tar• Ito at UCH mss M•data up to ell p,01Nnt le •• 7a1t'YMii3Ot wtases r,0elaea a tow stag WON 1102.14 tell N•pela 12.12*wet Met K she ogee ell d•Nlase t erm Memo Peas o talc et.te rills**sign sea M."Mr( ~' I.for III bas a•riot w the.tttlrlp OL 1 S•2Mss ( CD Sae at 1.54 am W/M.Us Wass ern I.STUMP M r. N awtw laid ritbt`M^ro U..ire Its too so 021 petal at La - 2tsotq. 1.•aria d tatt.Mq•,0a*Ytw IV .. Moroi.11•V.sissy WA ett14•N•Np Una/w 314.1*tool tlsmw oar s.e1•et/Ir WI.feu DM/wt w•grata%$ . • .eeprlle Koh a Nea0 asp food w Me wow*;tae at . sat pans&eoaewad by end nsY/d to e.2.Soma . n at par her.121111,0Ytr on she Na.aeawe tar Uhl!amt.mow UN aetetosm s toad,down ess11705 ▪ Y ON ewe e.s ter 11.et aeq Mlles sus a.averse*1. - gar Mat 1011*Pow 11V5 /1l1'N l ink N*• a n tie p lias et 1.51102•$w 0144 etaae Mad rie)t•.1•1ar am..aae.lIMt t..*ease. I M 1s,.ol2erls*100.1 lut 2sma10Aw•417.etb.R passel soar Js tN rasp se 112,0 Mawr Sr tat.121.5 d Ybte law2La • • utelal Ii II.. .1.20ad1pawsi%aael ra�.tl2q••••••••r all a taegdar.11tormt. . all Nallp!M1mlteabew smseHMt/1111 he sate slsrtda Cot tow Plasm NY/msh at0.emaa/Ina a.S.Mesa s aelma1 germ ea.*.woo b pe•SFe tratear.0. And all of the entire priori dosCribsd as follenals . r- •• yet at•piing ea she gaga MMas at trset.s 11 =rra.5lp U*11,014 as tort.Ca12*eersw.holdss,,IA 1e 201 Y ;111 test toe era eetethtre wean ae.et Omar O des • ltd it s alma leas ea•oststt sharer MIA all 431 r i a nee se• �faaw It Vs A'at'V Sma•36 Spas N • thaws if its M 1110.0*owe a s�dat�tb e. a I la'M 1110.16 so•petits same* 1s 4 1 s 112.1*goo sea pant la Mss eea11s11ea se Waal Sato Mraeaa ,0 awe Noe••,0ee twee*MI Mates M WY 110 110°A a4wa tee trmeltas et salt west 1•.11 Seat to a rotas (w Saab roes or mil Maas st a ded•p•a..*,01.o MOH aims M p tr • IP 0106.0 Sus.a realms 120 argue�21y dear shwa;e1 *std owl to Mae Of NI ell 1as1e berms drwetlb4 .ad ad Was e.sta to a i 5120510 220_I with•bteaa asp. �__r,H .Mara eaaetorios a le 461 0011 s 111.6 hat so•aMSSatO tommo i Keg a bass sap.IMa roe.K toollo l!wen *hence wstlsw visor" .ta. low a is tt•Sr a M.e mse 1.a}deaf Also,4•6!0•01 t0"r 0.24,p- swim 1 VV�r a do weabsrl ripaet are K Gaul rod leo.t tea' • is d yera�ssess mmem$a'2r/Sp1 W so.*[see Be a poise w tar 1414?u1/lstk a ' m ai av _._.. 11nar tar. .. I POOR QUALITY ORIGINAL t.te: 2/20/2004 Time: 11 :02 AM To: @ 6490158 Page: 003-005 PAGIB1 C j 6 c2 PAGE 12 2 OF 14 IMAGE01 : FL-04-3874-2 02/20/2004 11:00:11am Page 1 of 3 2924999 OR: 2972 PG: 2967 PROJECT: Dolphin c ovetWa ed iowu L e net=L tart at aunt harm,I FOLIO: 46372900201 /tlaltu2 it ens watt t.ItRI,ant O N 1atal.N Mt alt Is.N W.11 MOM area I.N Wm WARRANTY DEED IWael @ lull Nita THIS WARRANTY DEED is made this WA._ day of tzLiAg.1 . 2002. by DOLPHIN COVE DEVELOPMENT OF 000DLAND, INC.. a Florida sorpomtion, whose post office address is P.O.Box 158,Marco Island.Florida, 34146(hereinafter related to as'Grantor').to COWER COUNTY,a political subdivision of the Stale of Florkla,is successors and assigns,whose post Moe address Is 3301 Tumiani Tral East.Naples,Florida.34112(hereinafter referred to as`Grantee). (Wherever used herein the terms'Grantor and'Grantee'include all the panes to this instrument and their respective heirs, legal mpnaerMWves, successors and assigns.) WITNESSETH: That the Grantor, for and in consideration ol the sum ci'Ten Dollars ($10.00) and other valuable consideration, receipt whereof is hereby O sdaowledged,hereby grants,bargains,sells,done,reedses.reissue,conveys and lid centime unto the Grantee,ell that certain lend situate in Collier County,Florida.to wit w cal See Attached Exhibit eAe which is incorporated herein by re erence. ♦'' too Sent to real estate taxes for the currant year and thereafter, ems easements,restrictions,and reservations of record. CI THIS IS NOT HOMESTEAD PROPERTY f--, Ca N TOGETHER with al the tenements, heredlaments and appurtenances thereto `a• belonging or In anywise appertaining. TOGETHER with al rIghts or permits to bold docks or rights to leases of submerged ands or leases to submerged ands that arise from,relate to,refer to or are corrected in any way with Grantors property or plane to develop the property and d other properly rights arising from misting to or connected In any way with the property and pare to develop the property. TO HAVE AND TO HOLD the tame in fee simple forever. AND the Grantor hereby covenants with said Grantee that the Grantor is lawfully seized of said and In fee simple:that the Grantor has good right and lawful authority to sell and convey said land;that the Grantor hereby fully warrants the tltls to said land and wil defend the sane against the lawful claims of d persons whomsoever•,and that said and Is tree of all encumbrances except as noted above. IN WITNESS WHEREOF,the said Grantor has signed and sealed these presents the day and year first above written. / DOLPHIN COVE DEVELOPMENT t OF 000 DL AND,INC.,a Florida Witness: ) ocrporafon j. , BY: G t 1 ._ Nicole Oink,President P.O.Boor 168 : : /..', t/ MarcoaWnd,Roride 34146 -' Type) was eerrravwres_AOCIPM111 n Tilt soma OP corm Gralerasirothil. CALM dawn FLORTIA. ^" I POOR QUALITY ORIGINAL 1 k Lte: 2/20/2004 Time: 11 :02 AM To: @ 6490158 Page: 004-005 EXHIBIT C PAGE 13 OF 14 1 6 C2 IMAGE01 : FL-04-3874-2 02/20/2004 11:00:11am Page 2 of 3 OR: 1971 PG: 2968 STATE of. 'I.;_L COUNTY OF c.a `The foregoing Warmly Deed was aokmwbdged before me this LI day of 2002, by NICOLE GINIC, President, on behalf �1-llolpl cl� Development of Goodland,Inc.,a Florida corporation, krrawn toms who has produced as Montilla �_:. _ - (affix notarial seal) { n of Notary Public) ap,po° W ((Print name of Notary Publics) w�. tr. NOTARY PUBLIC Serial/Commission A:If any My Commission Expires; 7c7 II fo • f I 1 ,.Y/f..letMer $.1:14 / � Ca.) Mristset fasts&h.) ono LTS "C7 rr-+ Co �.a Cal POOR QUALITY ORIGINAL Lte: 2/20/2004 Time: 11 :02 AM To: @ 6490158 Page: 005-005 EXHIBIT C PAGE 14 OF 14 IMAQE01 : FL-04-3874-2 02/20/2004 11:00:11am Page 3 of 3 1 6 132 I t OR: 2972 PG: 1969 n: man"A" A pocel of laod being a portion of Tact 1,as shown on but not ape oldie Plat of Cleansed Isles Second Addition,a recorded in Plat Book 8,Page 19, of the Public Records of Collier County, Florida, more particularly described as follows: . Begientog at the southeaatealy comer of Lot 33,Block F of said Ooodlend Isles Second Addition;thence S 15'11'20"E 390.48 feet;thence s 72'IS' 19" E 128.00 feet; thence S 13' 50' 44" E 180.00 het to the southerly bomsdsry line of mid'Erect 1;thence 28.70 feet along the are of a circular ae curve concave to the northwest,radius of 100.00 fleet,chord bearing N S l' O 23'18"E 28.60 feet;thence N 43'10'00"E 230.00 feet;thence N 12'20' 7_ 20" B 381.83 feet; thence 87.47 feet along the arc of a circular curve ' concave to the southwest„ radhli of 50.00 feet, chord bearing N 37'46' w 41.5"W 76.74 feet thence N sr 53'43"W 66.88 feet thence 162.41 feet along the arc of a circular curve concave to the southeast,radius of 1365.08 Qo feet,chord bearing S 88'41'47"W 162.31 feet;thence S 85' 17' 17"W ,.d 201.52 feet thence N 18'12'43"W 87.42 feet to the southerly right-ol way GI line of Palm Avenue;thence S 85'17' 17"W 10.28.feet thence S 74'49' .. 12"W 60.08 feet to the northeast corner of said Lot 33.Block F;thence S 18'12'43"B 96.75 feet to the southeast comer of said Lot 33,Block F end a° the Place ofbeglnning. be- Panel contain 5.22 acres,more or less. 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C LI- CD 1 a. till E 1,2 = I f f 0 C •• > 7, ci *- ›. 0 i 1 E eL • - '''',iia LA >- 0 • 4:44 1. %I,* 1 s- c _ CU —1 't i- .•-• = 03 0 4- 5: 0 0D 1 , At I 1 LL1 4-' 1- as Ci- s- t13 F-- / i 4-+ 0 rsi i ' 44 I— •— D ° I .7.- , ' CU .c > — 4-, N c E c (-) " C 0.1 s_ 14 1_ 0 cu 1:2 . 1 cu o td c ti, LJ 0 S O U T H f I O R I I) A W A 1 1 R M A N A C I M l N I E/ ISIRICI Planning Document wx ' a.. -:: I ill p 1 1 - �, -y w .." , . ?rm sk i a y LOWER WEST COAST ,. WATER SUPPLY PLAN UPDATE _ ., H Acknowledgements The South Florida Water Management District (SFWMD) recognizes and thanks the Water Resources Advisory Commission Regional Water Supply Workshop participants for their contributions, comments, advice, information, and assistance throughout the development of this plan update. Furthermore,the SFWMD expresses appreciation to all SFWMD staff who contributed to the development and production of this plan update. For further information about this document, please contact: Linda Hoppes,AICP South Florida Water Management District 3301 Gun Club Road West Palm Beach, FL 33406 Telephone: (561)682-2213 Email: lhoppes@sfwmd.gov November 2012 2012 LWC Water Supply Plan Update I i Errata The South Florida Water Management District's Governing Board approved this 2012 Lower West Coast Water Supply Plan Update in November 2012.Since approval,the publication dates of two documents cited in this update have changed as follows: ♦ The 2011-2012 Water Supply Plan Support Document (SFWMD 2012a) will be published as the 2011-2013 Water Supply Plan Support Document. ♦ The 2012 Lower East Coast Water Supply Plan Update (SFWMD 2012b) will be published as the 2013 Lower East Coast Water Supply Plan Update. ii 1 Errata Executive Summary This plan update provides an assessment of the water supply for the South Florida Water Management District's (SFWMD's) Lower West Coast (LWC) Planning Area through 2030. The first Lower West Coast Water Supply Plan,completed in 1994,was updated in 2000 and again during 2005-2006. This plan update augments the knowledge and assumptions of past plans, including local and regional efforts completed since the last update.This current plan update presents water demand estimates, water supply issues and evaluations, water source options, and water resource and water supply development projects to ensure that future water supplies are adequate to support the region's growth while sustaining its natural systems. This plan update concludes that the future water demands of the LWC Planning Area can continue to be met through the 2030 planning horizon with appropriate management and continued diversification of water supply sources. Several steps are needed to achieve this conclusion: ♦ Completion of water supply utility projects ♦ Evaluation of site-specific refinement of groundwater availability ♦ Completion of the Comprehensive Everglades Restoration Plan (CERP) Caloosahatchee River(C-43)West Basin Storage Reservoir Project The water supply needs for natural systems are discussed in Chapter 3,and Appendices G and H and are considered a limitation on water available for allocation.These water supply needs are addressed through a variety of regulatory mechanisms and projects. In the Lake Okeechobee Service Area portion of the planning region, local conditions limit the volume of available fresh water.Specifically,the Lake Okeechobee Waterbody,a defined source that includes hydraulic connections that receive water from the lake such as the Caloosahatchee River (C-43 Canal), is a limited source due to implementation of the 2008 Lake Okeechobee federal regulation schedule, referred to as 2008 LORS, and concerns regarding the lake's Minimum Flow and Level (MFL) criteria. Concerns about integrity of the Herbert Hoover Dike and the lake's ecology prompted in the United States Army Corps of Engineers (USACE) to implement the 2008 LORS. This schedule operates the lake at lower levels. Analysis associated with the 2008 LORS assessed impacts on water supply performance and projected a decline in the physical level of certainty of users reliant on lake water supplies. This level of certainty is projected to decline from experiencing water shortage restrictions only every 1-in-10 years to experiencing restrictions every 1-in-6 years while the lake is being operated under the 2008 LORS. Repairs to the dike are under way and are expected to be completed by 2030,which is the end of the planning horizon for this plan (current estimated schedule for completion is 2022 — S. Kaynor, USACE,personal communication). As a result of the impacts to water supply, the SFWMD enacted rules to limit future additional withdrawals from the Lake Okeechobee Waterbody in order to prevent further degradation of the level of certainty for existing legal users.Any increase in 2012 LWC Water Supply Plan Update I Iii the lake's regulation schedule as a result of the Herbert Hoover Dike repairs by the USACE would be evaluated by the USACE through a National Environmental Policy Act analysis. It is anticipated the additional water from Lake Okeechobee as a result of Herbert Hoover Dike repairs and a revised regulation schedule would return the lake from MFL recovery status to MFL prevention status, enhance the level of certainty to existing permitted users now receiving less than 1-in-10 level of certainty,and support environmental objectives. Construction of the CERP Caloosahatchee River(C-43)West Basin Storage Reservoir Project will allow capture and storage of surface water runoff from the C-43 Basin and Lake Okeechobee to provide a consistent flow of fresh water to the estuary. After construction and flow-through testing, operation of this project is expected to improve the Caloosahatchee Estuary's salinity balance by reducing a portion of the peak discharges during the wet season and providing essential flows during the dry season. The project is awaiting congressional authorization and appropriation of funds to start construction. The USACE anticipates the project authorization will occur in August 2013 with appropriation of funding to follow later. Once congressional funding has been appropriated, a timetable for the completion of the reservoir will be developed. To meet the region's future water needs,this plan update advocates continued development of alternative water supplies, including increased use of the Floridan aquifer system and reclaimed water, as well as increased emphasis and implementation of appropriate water conservation practices and water storage for dry season use. In addition, continued construction of area-critical ecosystem restoration projects and studies to identify additional sources of water for agriculture are needed. Water users, including utilities and local governments, are recognized for their proactive efforts, including previous and ongoing development of alternative water sources. These contributions help to ensure that the water needs of this region will be met. This plan update incorporates the water supply development projects proposed by Public Water Supply utilities to meet their future needs. Local governments, in coordination with utilities,will address these projects as they revise their 10-year water supply facilities work plans,which require submittal to the State of Florida Department of Economic Opportunity and reviewing agencies within 18 months of approval of this plan update. This plan update was developed in an open public forum with water utilities, local governments, environmental organizations, agricultural interests, and other stakeholders through the SFWMD's Water Resources Advisory Commission. The process to develop the population and water demand projections began in 2009. It included many meetings with water users,local governments,industry representatives,agencies,and utilities.Workshops were also held during the plan development process to solicit input and provide information about planning results and progress. This update includes this document, referred to as the Planning Document, as well as an accompanying Appendices, and the 2011-2012 Water Supply Plan Support Document (SFWMD 2012a). All of these documents are available in PDF format from http://www.sfwmd.gov/watersupply. iv Executive Summary Introduction (Chapter 1) The LWC Planning Area includes all of Lee County, most of Collier County, and portions of Hendry, Glades, Charlotte, and mainland Monroe counties. The region generally reflects the drainage patterns of the Caloosahatchee, Imperial, Estero, and Cocohatchee river basins. This planning area includes numerous coastal and inland natural systems including Big Cypress Swamp, Fakahatchee Estuary and Picayune Strand State Forest, Estero Bay, Caloosahatchee River and Estuary, and Ten Thousand Islands. Big Cypress Basin and the Picayune Strand State Forest are extraordinary natural areas in south Florida, both containing a variety of wetlands and forest types specific to the region. Estero Bay is one of Florida's most significant natural watershed resources, and Estero Bay Preserve State Park was designated as the state's first aquatic preserve. The Rookery Bay National Estuarine Research Reserve encompasses 110,000 acres of native habitat located at the western edge of the Everglades. The LWC Planning Area is currently home to nearly one million permanent residents who live mainly in the northwestern, coastal portions of the planning area. Information in this plan update reflects the influence of significant fluctuations in the economy, residential and commercial development, and agricultural commodity markets on water users and the projected water needs of the planning area. Demand Estimates and Projections (Chapter 2) The population of an area greatly affects its water needs. The LWC Planning Area's population is projected to increase 51 percent over the 20-year planning horizon.This rise in population creates significant increases in water demands for Public Water Supply, Recreational/Landscape Self-Supply,and Power Generation Self-Supply uses. In 2010, average annual gross water demands for all categories in the LWC Planning Area totaled 971.1 million gallons of water per day (MGD). By 2030, the projected total average annual gross water demands are estimated to range from 1,217.9 to 1,262.9 MGD, an increase of 25 to 30 percent. The figure on the next page shows the estimated 2010 gross demands and projected 2030 gross demands for all water use categories. Agriculture remains the largest water user in the LWC Planning Area and is expected to continue as the dominant land use. Citrus is the area's primary crop.Agricultural acreage is predominantly located inland in north-central Collier, eastern Lee, Hendry, and Glades counties. Current lands used for agricultural operations are expected to remain in service during the planning horizon despite recent acreage losses due to economic challenges,lands needed for the CERP, hurricane damage, and citrus diseases. For this plan update, actively cultivated agricultural acreage is expected to range from 333,127 to 362,127 acres by 2030, with a gross water demand estimate of approximately 696 to 741 MGD. 2012 LWC Water Supply Plan Update I V Estimated daily gross demands for an average year by water use category for 2010 and 2030 800 700 II >, 600 cv 500 c 0 400 - •2010 C7 •2030 o 300 200 100 0 AGR PWS DSS ICI REC PWR Industrial/ Public Domestic Commercial/ Recreational/ Power Agricultural Water Self- Institutional Landscape Generation Self-Supply Supply Supply Self-Supply Self-Supply Self-Supply Total Estimated 630.0 156.3 18.9 35.3 130.1 0.5 971.1 2010 MGD Projected 695.9— 232.1 24.0 35.3 188.5 42.1 1,217.9— 2030 MGD 740.90 1,262.9 Percent 10-18% 49% 27/° 45% Change 0% 45/° 8,320% 25-30% Percent of Projected 57-59% 19% 2% 3% 15% 3% 2030 Total Notes:The bar chart compares demands by use category in million gallons of water per day(MGD),and the table shows the percentage of growth in each category. Percent of Projected 2030 Totals other than Agricultural Self- Supply are calculated based on the upper range limit of demand(1,266.1 MGD). Projected total 2030 gross water demands are 522 MGD for all water uses except Agricultural Self-Supply. Urban demand estimate and projection highlights for the planning area include the following: • The greatest regional population growth is expected in Lee and Collier counties, where most of the planning area population currently lives. ♦ Public Water Supply and Domestic Self-Supply gross demands are projected to increase by 46 percent, from an estimated 175 MGD in 2010 to 256 MGD by 2030, representing at least 20 percent of the region's total gross demands by 2030. vi I Executive Summary ♦ Recreational/Landscape Self-Supply gross demands are expected to increase from an estimated 130 MGD in 2010 to 188.5 MGD by 2030,a gain of 45 percent with most of the additional demand originating from areas other than golf course acreage. ♦ Power Generation Self-Supply demands are expected to increase from 0.5 MGD in 2010 to 42.1 MGD by 2030. Such an increase may occur to support new or expanded power generation facilities planned by Florida Power & Light, south Florida's major power supplier. Issues and Evaluation (Chapter 3) As a result of the water supply planning effort required to produce this plan update, the SFWMD has determined that the conclusions of previous evaluations are applicable to the current 20-year planning horizon.No additional numerical modeling was conducted. The primary water supply issues influencing water supply planning efforts to meet 2030 projected water needs in the LWC Planning Area include the following: ♦ Increased withdrawals from the surficial aquifer system and the freshwater portion of the intermediate aquifer system are generally limited due to potential impacts on wetlands and existing legal water users including Domestic Self- Supply, the potential for saltwater intrusion, and the possibility of reaching the maximum developable limits of aquifers. New or increased allocations will be evaluated on an application-by-application basis to determine if the project meets consumptive use permitting criteria. • In some areas, Domestic Self-Supply cumulative withdrawals are having an effect on aquifer water levels. ♦ Surface water allocations from Lake Okeechobee and hydraulically connected • surface waters are limited by the Lake Okeechobee Service Area Restricted Allocation Area criteria. • The results of the 2008 LORS process indicated that the level of certainty is projected to decline from the consumptive use permitting standard of experiencing water shortage restrictions every 1-in-10 years to experiencing restrictions every 1-in-6 years while the lake is operated under the 2008 LORS. ♦ Peak freshwater discharges during the wet season are affecting the health of the Caloosahatchee Estuary and additional storage is required in both the basin and the regional system to attenuate damaging peak flow events. ♦ Surface water availability and current storage capacity is insufficient for the Caloosahatchee River and Estuary during dry conditions. The assessment contained in Chapter 3 also confirms that historically used water sources alone are not adequate to meet the LWC Planning Area's growing water needs through 2030. 2012 LWC Water Supply Plan Update I Vii Over the past decade, water users have already made significant progress by diversifying supply sources and reducing reliance on the surficial and intermediate aquifer systems: ♦ The majority of coastal utilities within the planning area are using brackish water from the Floridan aquifer system to meet all or a portion of their future water demands. The following utilities use all or some of the Floridan aquifer system for production of their drinking water: Cape Coral, Fort Myers, Clewiston,Island Water,and Greater Pine Island. ♦ Reclaimed water use in the area has increased significantly, offsetting the use of groundwater. ♦ Conversion to more efficient irrigation systems and implementation of agricultural best management practices continue. For Public Water Supply, continued development of the Floridan aquifer system and expansion of utility service areas to meet the growing needs for potable water show the most promise for satisfying future water demand. To meet landscape irrigation needs, increased use of reclaimed water and conservation are the region's best options. Agricultural irrigation uses surface water from primary canals supplemented with groundwater. Tailwater recovery systems are successful in reducing resource use, but adequate slope and drainage conditions are necessary and this does not meet the water needs in a drought. Increased water conservation is essential among all water users. However, some water resource problems can be solved only on an application-by- application basis due to the high variability of the water supply across the region. In 2001, the SFWMD established MFL criteria for the Caloosahatchee River and Estuary. Because the MFL criteria was projected to be exceeded until storage in the watershed was constructed,a recovery strategy was also established.An updated MFL recovery strategy is contained in Appendix G. Evaluation of Water Source Options (Chapter 4) In the LWC Planning Area, historical water sources include fresh groundwater from the surficial and intermediate aquifer systems, and surface water primarily from the Caloosahatchee River and canals. However, from a regional perspective,development of the surficial and intermediate aquifers for potable water has been generally maximized over time, and potential increases in production are limited, especially in coastal areas. The region's alternative water supply sources include brackish groundwater from the Floridan aquifer system, reclaimed water, and limited storm water captured and stored during the rainy season for later beneficial use. Water conservation is also an essential water source option for the planning area. In the LWC Planning Area, the Floridan aquifer system and portions of the intermediate aquifer system are brackish (slightly salty) water sources that require desalination treatment before potable use. In 2009, 42 percent (45 MGD) of the water used to meet drinking water needs originated from these brackish aquifers. Over the 20-year planning period, development of these brackish sources will far outpace development of freshwater sources. In this plan update,local governments propose 70 MGD of brackish water treatment capacity for the planning area by 2030.Agricultural Self-Supply viii Executive Summary and Recreation/Landscape Self-Supply users continue to rely primarily on fresh water with stormwater retention ponds as supplemental water supply for crop irrigation. Storage is an essential component of any water supply system experiencing fluctuation in supply and demand. Two-thirds of south Florida's annual rainfall occurs in the wet season, but without sufficient storage capacity, much of this water discharges to tide. In the LWC Planning Area,potential types of needed water storage include aquifer storage and recovery wells,off-stream reservoirs,and surface water impoundments and ponds. Reclaimed water is a key component of water resource management in the planning area. Thirty-eight wastewater treatment facilities reuse all or a portion of their wastewater. Potential uses of reclaimed water include landscape and agricultural irrigation, groundwater recharge, industrial uses, and environmental enhancement. In the LWC Planning Area, the volume of reclaimed water used for beneficial purposes has doubled from 1994 to 2010. In 2010, over 77 MGD (91 percent) of the wastewater treated in the planning area was reused for a beneficial purpose,primarily for irrigation. However,9 MGD of potentially reusable water was disposed of via deep well injection or discharged to surface waters.Wastewater flows are projected to increase to more than 139 MGD by 2030. To maximize the use of reclaimed water, utilities should continue to implement feasible options to extend their supply of reclaimed water, such as supplemental sources, metering for residential customers, tiered rate structures, limiting days of the week for landscape irrigation,and interconnects with other reclaimed water utilities. Proactive, cooperative water conservation efforts among water users, utilities, local governments, and the SFWMD are also necessary to accomplish water savings. Efficient water use and conservation produces the most inexpensive water—water not wasted. It is possible to achieve significant potential water savings through increased water conservation efforts, such as retrofitting older plumbing fixtures with high efficiency fixtures in residential, industrial, commercial, and institutional units, and increased limitations on landscape irrigation. Goal-based water conservation plans allow utilities to achieve goals within their consumptive use permits to help meet future water supply needs. Water conservation plans should include general policies, such as water conservation ordinances,public education,and retrofits of indoor and outdoor devices. Since 2003, the LWC Planning Area has implemented year-round landscape irrigation conservation measures. In March 2010, this was expanded throughout the SFWMD boundaries with the adoption of the Mandatory Year-Round Landscape Irrigation Conservation Measures Rule (Chapter 40E-24, Florida Administrative Code). Broadly, this rule limits landscape irrigation to two days per week, with a provision for irrigation up to three days per week in counties wholly located within the jurisdictional boundaries of the SFWMD, including Collier, Glades, Hendry, and Lee counties. The rule also provides local governments with the flexibility to adopt alternative landscape irrigation ordinances that are at least as stringent as the Mandatory Year-Round Landscape Irrigation Conservation Measures Rule. In the planning area, Lee County and the City of Cape Coral have adopted two-day-per-week irrigation limits. 2012 LWC Water Supply Plan Update I iX Water Resource Development Projects and Water Supply Development Projects (Chapters 5 and 6) Florida water law identifies two types of projects to meet water needs: water resource development projects and water supply development projects. Water resource development projects, such as regional modeling and data collection, are generally the responsibility of the SFWMD. Water users are generally responsible for water supply development projects. In the LWC Planning Area, the SFWMD's corporate environmental database, DBHYDRO, for monitoring stations includes 298 surface water stations and 157 wells in Lee, Collier, Glades, and Hendry counties combined. A Floridan aquifer system monitor well network was established in the planning area to monitor water levels and quality. Water level and salinity monitoring is critical to assess the potential for movement of highly saline water from the deeper portions of the Floridan aquifer system or inland from the coast. During 2011, the calibration of the Lower West Coast Floridan Aquifer System Model was completed and peer review recommendations based on the previously developed model were implemented. The completed model will be placed in the SFWMD's Library of Models for future application and to answer specific planning-level questions. The Lower West Coast Surficial Aquifer System Model, a groundwater flow model, needs to be updated to include the intermediate aquifer system and will then require a peer review that is tentatively scheduled for Fiscal Year 2014. This model examines the potential impacts of existing and future groundwater withdrawals from the surficial aquifer system and intermediate aquifer system. The SFWMD offers two cost-share funding programs to assist local water users with development of alternative water supplies and water conservation: the Alternative Water Supply Funding Program and the Water Savings Incentive Program, referred to as WaterSIP: ♦ The Alternative Water Supply Funding Program provides cost-share funding for conservation or alternative water supply sources including brackish water from the Floridan aquifer system, reclaimed water (treated wastewater), excess storm water during the rainy season, sources made available through the creation of new storage capacity, and any other sources designated as nontraditional. Between Fiscal Years 2007 and 2012, 78 water supply development projects were funded by the Alternative Water Supply Funding Program in the LWC Planning Area and have created a total of 104 MGD of new water capacity. • Through the WaterSIP,the SFWMD provides matching funds up to$50,000 to water providers and users for non-capital water efficiency improvement projects. In the LWC Planning Area, between Fiscal Years 2007 and 2012, the SFWMD awarded $627,456 for 23 WaterSIP projects, representing a projected savings of 178 million gallons per year. x I Executive Summary A table summarizing the implementation schedule and costs for districtwide water resource development projects through Fiscal Year 2014 is included in Chapter 5. The 36 multiphased Public Water Supply facility projects proposed for Fiscal Years 2012 through 2030 (Chapter 6) are anticipated to add 141.1 MGD of new capacity, which is more than sufficient to meet future projected Public Water Supply demands.These proposed projects include 17 potable and 19 non-potable water supply development projects. The SFWMD's planning process is closely coordinated and linked to the water supply planning of local governments and utilities. In the LWC Planning Area, 24 utilities serve 17 local governments.A utility summary is included at the end of Chapter 6 for each Public Water Supply utility supplying 0.1 MGD or greater to its service area. These summaries provide population and demand projections, proposed water sources, and specific Public Water Supply development projects. Future Directions (Chapter 7) The future direction of water supply for the LWC Planning Area includes further diversification of water sources to meet the needs of all water users, as well as water conservation, coordination, and monitoring to respond to rising sea levels. The SFWMD's guidance concerning water source options includes the following: ♦ Gaining an improved understanding of the impact of long-term, sustained withdrawals from the Floridan aquifer system. Upon completion of the Lower West Coast Surficial Aquifer System Model, the SFWMD intends to examine the potential impacts of existing and future groundwater withdrawals from the surficial aquifer system. • To maximize the use of reclaimed water, utilities should continue to implement feasible options to extend their supply of reclaimed water,such as supplemental sources, metering for residential customers,tiered rate structures,limiting days of the week for landscape irrigation, and interconnects with other reclaimed water utilities. ♦ Continuing a strong emphasis on water conservation, the SFWMD suggests implementing user-specific water conservation plans and two-day-per-week irrigation ordinances where feasible. • Regularly reviewing saltwater intrusion monitoring and revising monitoring regimes to address and respond to the effects of climate change. • Construction of the CERP Caloosahatchee River (C-43) West Basin Storage Reservoir Project and other CERP and local government projects to provide additional water storage. All of the water made available by the CERP Caloosahatchee River (C-43) West Basin Storage Reservoir Project will be reserved. The SFWMD's objective is to ensure that all water contained in the reservoir is protected for the natural system. The SFWMD is currently in the process of developing a water reservation rule for the CERP Caloosahatchee River(C-43)West Basin Storage Reservoir Project. 2012 LWC Water Supply Plan Update I Xi • Additional efforts to better understand the aquifer system, including the Sandstone aquifer and identification of areas of available fresh water, are needed to meet future needs,especially agriculture. • Facilitate discussions with local governments to assist with a long-term water supply strategy for sustainable Domestic Self-Supply in the Lehigh Acres area. The SFWMD concludes that the future water demands of the region can continue to be met through the 2030 planning horizon with appropriate management and continued diversification of water supply sources.Several steps are needed to achieve this conclusion: • Completion of water supply utility projects ♦ Evaluation of site-specific refinement of groundwater availability ♦ Completion of the CERP Caloosahatchee River (C-43) West Basin Storage Reservoir Project Successful implementation of this plan update requires coordination with other regional and local government planning efforts and continued public participation in guiding the plan implementation process. xii I Executive Summary Table of Contents Acknowledgements Executive Summary iii Introduction (Chapter 1) v Demand Estimates and Projections(Chapter 2) v Issues and Evaluation (Chapter 3) vii Evaluation of Water Source Options(Chapter 4) viii Water Resource Development Projects and Water Supply Development Projects(Chapters 5 and 6) x Future Directions (Chapter 7) xi List of Tables xvii List of Figures xix Acronyms and Abbreviations xxi Chapter 1: Introduction 1 Population Projections and Water Demands 1 Current Update 2 Legal Authority and Requirements 2 Consumptive Use Permitting 3 Restricted Allocation Areas 3 Water Reservations 3 Need for Alternative Water Sources 4 Water Supply Planning 4 Planning Process 5 Regional Water Supply Plans 6 Public Participation 7 Goal and Objectives 7 Planning Area Background 8 Overview of Water Resources 10 Progress Since the 2005-2006 LWC Plan Update 14 Water Conservation 15 Modeling and Studies 15 Regulatory Protection and Water Quality Efforts 16 Water Storage 17 Restoration 17 Water Supply Development Projects 17 Outlook on Climate Change 18 Water Supply Planning for the Next 20 Years 18 2012 LWC Water Supply Plan Update I Xiii Chapter 2: Demand Estimates and Projections 21 Descriptions of Water Use Categories 23 Population and Water Use Trends 23 Net Water Demands 24 Public Water Supply and Domestic Self-Supply 26 Gross Water Demands 28 Agricultural Self-Supply 30 Industrial/Commercial/Institutional Self-Supply 33 Recreational/Landscape Self-Supply 33 Power Generation Self-Supply 34 Demand Projections in Perspective 34 Chapter 3: Issues and Evaluations 37 Approach 37 Summary of Issues Identified for 2030 38 Surface Water Availability is Limited 40 Fresh Groundwater Availability Is Limited 41 Resource Protection 42 Consumptive Use Permitting 43 Minimum Flows and Levels 45 Water Reservations 47 Evaluation and Analysis 48 Previous Analyses 48 Existing Conditions and Implementation of Previous Recommendations 49 Outlook on Climate Change 64 Affect on LWC Planning Area 65 Summary 66 Additional LWC Water Supply-Related Efforts 67 Chapter 4: Evaluation of Water Source Options 69 Water Source Options 69 Groundwater 69 Surface Water 75 New Storage Capacity for Surface Water or Groundwater 77 Reclaimed Water 80 Seawater 85 Summary of Water Source Options 86 Water Conservation 87 Comprehensive Water Conservation Program 88 Urban Use—Tools, Programs,and Potential Savings 88 Agricultural Use—Tools, Programs, and Potential Savings 113 Alternative Water Supply Projects 115 Water Conservation Summary 116 Xiv I Table of Contents Chapter 5:Water Resource Development Projects 117 Regional Water Resource Development Projects 118 Hydrogeologic Investigation of the Top of the Sandstone Aquifer 118 Numerical Models 119 Other Efforts 120 Districtwide Water Resource Development Projects 120 Hydrogeologic Assessment and Monitoring 121 Feasibility Studies 123 Natural Systems Protection 124 Comprehensive Water Conservation Program 127 Summary 129 Chapter 6:Water Supply Development Projects 131 Regional and Local Planning Linkage 132 Consumptive Use Permitting 134 Projects Identified for This Plan Update 134 Public Water Supply 136 Domestic Self-Supply 139 Agricultural Self-Supply 140 Industrial/Commercial/Institutional Self-Supply 142 Recreational/Landscape Self-Supply 142 Power Generation Self-Supply 143 Coordination Between Water Supply PlanNing and Consumptive Use Permitting 143 Funding 144 Alternative Water Supply Funding Program 145 Water Savings Incentive Program 145 Summary 145 Public Water Supply Utility Summaries 147 Chapter 7: Future Direction 173 Water Sources 174 Groundwater 175 Surface Water 177 Reclaimed Water 178 New Storage Capacity for Surface Water or Groundwater 179 Aquifer Storage and Recovery 179 Seawater 179 Water Conservation 179 Coordination 181 Climate Change 181 Conclusion 181 Glossary 183 References 199 2012 LWC Water Supply Plan Update I XV XVI I Table of Contents List of Tables Table 1. Planning process for developing this update. 5 Table 2. Projections of permanent population in the LWC Planning Area, 2010-2030. 27 Table 3. Net PWS and DSS water demands in the LWC Planning Area, 2005-2030 27 Table 4. Estimated irrigated agricultural acreages and average year gross demands by crop type for 2010 and 2030 30 Table 5. Gross demands projected in the 2005-2006 LWC Plan Update versus this update 35 Table 6. Summary of statutory resource protection tools 44 Table 7. Other resource protection terms. 45 Table 8. PWS water sources and use in MGD for 1998-2009. 57 Table 9. Reclaimed water use in the LWC Planning Area in MGD for 1994-2010. 63 Table 10. Regional utility PCURs in the LWC Planning Area using overall finished water. 64 Table 11. PCURs in the LWC Planning Area (using overall finished water) 89 Table 12. Cost comparison of water conservation versus nanofiltration and RO treatment technologies for 1,000 gallons of water. 92 Table 13. Daily cost of water conservation versus nanofiltration and RO for 1 MGD,3 MGD, and 5 MGD of water supply 92 Table 14. Gallons of water consumed for common indoor water fixtures and appliances 95 Table 15. Potential water demand reduction in Lee County based on implementation of Florida Water Stars"" 97 Table 16. Potential water demand reduction in Collier County based on implementation of Florida Water Stars"' 98 Table 17. Landscape Irrigation Rules within the LWC Planning Area 100 Table 18. Estimates of possible impact of the Mandatory Year-Round Landscape Irrigation Conservation Measures Rule concerning potable water use 100 Table 19. Reductions in irrigation water use based on device type versus systems governed by timers alone 102 Table 20. Potential water savings of the Water CHAMP in Lee and Collier counties. 106 Table 21. Residential units in Lee County and potential savings of indoor water use through water conservation 110 Table 22. Estimated water use and potential savings through improved water use efficiency within the ICI Self-Supply water use category. 111 Table 23. Summary of potential savings of the ICI Self-Supply water use category and residential indoor water use through water conservation. 112 2012 LWC Water Supply Plan Update I XVii Table 24. Implementation schedule and costs for districtwide water resource development projects, FY 2012—FY 2016. 130 Table 25. PWS net demand projections for 2010 and 2030. 137 Table 26. Proposed potable water supply development projects and capacity for 2012-2030. 138 Table 27. Proposed non-potable water supply projects and capacity for 2012-2030 138 XViii I List of Tables List of Figures Figure 1. Linking regional water supply planning with local government comprehensive planning. 6 Figure 2. LWC Planning Area. 9 Figure 3. Generalized hydrogeologic cross-section of the LWC Planning Area. 11 Figure 4. Population projections, 2005-2006 LWC Plan Update versus this plan update 24 Figure 5. Estimated average year net demands by water use category for 2010 and 2030. 25 Figure 6. Estimated daily gross demands for an average year by water use category for 2010 and 2030 29 Figure 7. Conceptual relationship among the harm,significant harm, and serious harm water resource protection standards 42 Figure 8. Long-term water level trends in SAS wells C-953 and C-492 in northwestern Collier County 51 Figure 9. Sandstone aquifer water levels at Well L-729 in southern Lehigh Acres 52 Figure 10. Mid-Hawthorn aquifer water levels at Well L-581 in southern Cape Coral and Well L-4820 in northern Cape Coral in Lee County. 53 Figure 11. Chloride levels from USGS monitor wells C-525 and C-489 for 1975-2010. 55 Figure 12. Water levels in an Upper Floridan monitor well at a location and depth typical of agricultural withdrawals in Glades County. 58 Figure 13. Water levels in an Upper Floridan monitor well at a location and depth typical of PWS withdrawals in Lee County. 58 Figure 14. Raw water chloride concentrations and withdrawals from the Cape Coral Southwest brackish water wellfield. 60 Figure 15. Chloride concentrations from production wells at the North Lee County FAS wellfield. 60 Figure 16. Generalized hydrogeologic cross-section of the LWC Planning Area. 70 Figure 17. Location of permitted production wells and associated aquifer sources as of 2010 in the LWC Planning Area. 71 Figure 18. PWS withdrawals from brackish water sources in the LWC Planning Area 1990-2009. 74 Figure 19. Annual reclaimed water reuse history in the LWC Planning Area 1994-2010. 82 Figure 20. Linking regional water supply planning with local government comprehensive planning...134 2012 LWC Water Supply Plan Update I XIX XX I List of Figures Acronyms and Abbreviations 1994 LWC Plan 1994 Lower West Coast Water Supply Plan (SFWMD 1994) 2000 LWC Plan 2000 Lower West Coast Water Supply Plan (SFWMD 2000b) 2005-2006 LWC Plan 2005-2006 Lower West Coast Water Supply Plan Update(SFWMD 2006) Update 2008 LORS 2008 Lake Okeechobee Regulation Schedule AFSIRS Agricultural Field Scale Irrigation Requirements Simulation AGR Self-Supply Agricultural Self-Supply ASR aquifer storage and recovery Basis of Review Basis of Review for Water Use Permit Applications within the South Florida Water Management District(SFWMD 2010a) BEBR Bureau of Economic and Business Research BMP best management practice CERP Comprehensive Everglades Restoration Plan cfs cubic feet per second CREW Corkscrew Regional Ecosystem Watershed DBHYDRO South Florida Water Management District's corporate environmental database DSS Domestic Self-Supply EQIP Environmental Quality Improvement Program ET evapotranspiration F.A.C. Florida Administrative Code FAS Floridan aquifer system FAWN Florida Automated Weather Network FDACS Florida Department of Agriculture and Consumer Services FDEP Florida Department of Environmental Protection FGUA Florida Government Utility Authority FPL Florida Power&Light F.S. Florida Statutes FY Fiscal Year GPD gallons per day IAS intermediate aquifer system 2012 LWC Water Supply Plan Update I XXi • ICI Self-Supply Industrial/Commercial/Institutional Self-Supply IFAS Institute of Food and Agricultural Sciences LWC Planning Area Lower West Coast Planning Area LWCFAS Model Lower West Coast Floridan Aquifer System Model LWCSAS Model Lower West Coast Surficial Aquifer System Model MDL maximum developable limit MFL Minimum Flow and Level MGD million gallons of water per day mg/L milligrams per liter MGY million gallons of water per year MIL mobile irrigation laboratory MODFLOW Modular Three-dimensional Finite-difference Groundwater Flow Model NA not applicable NGVD National Geodetic Vertical Datum of 1929 PCUR per capita use rate psu practical salinity unit PWR Self-Supply Power Generation Self-Supply PWS Public Water Supply REC Self-Supply Recreational/Landscape Self-Supply RO reverse osmosis SAS surficial aquifer system SEAWAT fully coupled or uncoupled density-dependent flow and transport model SFWMD South Florida Water Management District Southwest Florida Draft Southwest Florida Feasibility Study Integrated Feasibility Report Feasibility Study and Environmental Impact Statement(USACE and SFWMD 2009) Support Document 2011-2012 Water Supply Plan Support Document(SFWMD 2012a) USACE United States Army Corps of Engineers USDA United States Department of Agriculture USEPA United States Environmental Protection Agency USGS United States Geological Survey Water CHAMP Water Conservation Hotel and Motel Program WaterSIP Water Savings Incentive Program WCAs Water Conservation Areas WRAC Water Resources Advisory Commission XXii I Acronyms and Abbreviations Introduction The South Florida Water Management District TOPICS (SFWMD) updates regional water supply plans to provide for current and future water needs, while • Population Projections and protecting south Florida's water resources. This plan Water Demands update assesses existing and projected water needs and water sources to meet those needs over a • Current Update 20-year planning horizon from 2010 to 2030 for the • Legal Authority and Lower West Coast (LWC) Planning Area. The update Requirements presents current and projected populations, water demand, water resource and water supply • Need for Alternative development projects, and related water supply Water Sources planning information. The plan also describes • Water Supply Planning proposed water supply projects and regional project • Planning Area Background implementation strategies for Fiscal Year (FY) 2010 through FY 2030.This current plan is a five-year plan • Progress Since the 2005-2006 update of the 2005-2006 Lower West Coast Water LWC Plan Update Supply Plan Update (2005-2006 LWC Plan Update; • Outlook on Climate Change SFWMD 2006), which updated the 2000 Lower West • Water Supply Planning for the Coast Water Supply Plan (2000 LWC Plan; Next 20 Years SFWMD 2000b). POPULATION PROJECTIONS AND WATER DEMANDS Projections developed for this update estimate the LWC Planning Area's NAVIGATE • population will increase by over 51 percent, from approximately 993,000 This update consists of this Planning Document, residents in 2010 to more than 1.5 million an Appendices, and the 2011-2012 Water residents by 2030. In contrast, the 2005- Supply Plan Support Document(SFWMD 2012a). 2006 LWC Plan Update projected the These documents are available from the planning area's population to increase by SFWMD's Water Supply website at 74 percent, with the total population http://www.sfwmd.gov/watersupply. reaching 1.5 million by 2025. 2012 LWC Water Supply Plan Update I 1 In this update,projected gross water demands for 2030 for the region's Public Water Supply (PWS) and Domestic Self-Supply (DSS) are 256.1 million gallons of water per day (MGD). This demand projection represents a 46 percent increase from 175.2 MGD in 2010. While PWS and DSS are anticipated to be at least 20 percent of the LWC Planning Area's total gross demands by 2030, the Agricultural (AGR) Self-Supply use category is projected to remain the LWC Planning Area's single largest water user category in 2030.Agricultural gross water demand is projected to increase from 630 MGD in 2010 to approximately 696- 741 MGD in 2030, representing at least 57 percent of the LWC Planning Area's total gross demands. CURRENT UPDATE This plan update reflects the influence of significant fluctuations in the economy,residential and commercial development, agricultural commodity markets, and sustainable use of natural resources on the projected water needs of the LWC Planning Area.Chapter 2 of this update documents the population growth and water demand by each water use category. Chapter 3 discusses changes to the water resources, their availability, and related issues facing the region. Chapter 4 evaluates the planning area's various water source options. Chapter 5 identifies water resource development projects while Chapter 6 describes water supply development projects. Chapter 7 provides future guidance and direction.A glossary and a reference section are provided at the end of the document. LEGAL AUTHORITY AND REQUIREMENTS LAW / CODE Q The legal authority and requirements for Subsection 373.709(1), F.S. states the following: water supply planning are included in Chapters 373,Florida Statutes (F.S.),with The governing board of each water management additional direction located in Chapters district shall conduct water supply planning for 403 and 187, F.S. In accordance with any water supply planning region within the Florida's Water Protection and district identified in the appropriate district Sustainability Program, regional water water supply plan under Section 373.036, F.S., supply plans and local government where it determines that existing sources of water are not adequate to supply water for all comprehensive plans must ensure existing and future reasonable-beneficial uses adequate potable water facilities are and to sustain the water resources and related constructed and concurrently available natural systems for the planning period. with new development. 2 I Chapter 1: Introduction Consumptive Use Permitting GOAL The SFWMD's Consumptive Use Permitting Program minimizes The SFWMD's strategic goal for all of its water contention for water resources and supply planning efforts is to ensure an adequate plays an important role in resource supply of water to protect natural systems and protection. Consumptive use meet all existing and projected reasonable- permitting protects the supply and beneficial uses, while sustaining water resources quality of groundwater and surface for future generations. Specifically,the goals of this water resources by ensuring that update are to identify enough sources of water to meet the needs of all reasonable-beneficial uses water use is reasonable,beneficial,and within the LWC Planning Area through 2030 during consistent with the public interest,and a 1-in-10 year drought event (a drought expected that it does not interfere with existing to have a return frequency of once in 10 years),and legal uses (see Chapter 40E-2, Florida to sustain the region's water resources and Administrative Code [F.A.C.], and natural systems. Section 373.223,F.S.). Restricted Allocation Areas Restricted Allocation Areas limit specific water resources from further allocation in various geographic areas. In October 2008, the SFWMD adopted Restricted Allocation Area criteria for the Lake Okeechobee Service Area.This criterion is provided in Section 3.2.1 of the Basis of Review for Water Use Permit Applications within the South Florida Water Management District, referred to as the Basis of Review (SFWMD 2010a). These criteria limit surface water withdrawals from Lake Okeechobee and all surface water hydraulically connected to the lake. By connection to the lake, the Caloosahatchee River (C-43 Canal) and the St. Lucie River (C-44 Canal) in the Upper East Coast Planning Area are subject to these Restricted Allocation Area criteria. By limiting the availability of surface water for new consumptive use allocations,these criteria protect the rights of existing legal users,as well as the region's water resources. For more information see the 2012 Lower East Coast Water Supply Plan Update(SFWMD 2012b). Water Reservations j` A Water Reservation is a legal lr'r mechanism to set aside water from ,,i( ""', 1; consumptive water use for the I '_ protection of fish and wildlife or 1 public health and safety. �„, s ,,, �4 . 4,, — A Water Reservation in support of the ro' Comprehensive Everglades Restor- ation Plan (CERP) Picayune Strand e` Restoration Project became effective in July 2009. This reservation sets Picayune Strand aside water for the natural system , 2012 LWC Water Supply Plan Update 13 (Rule 40E-10.041,F.A.C.).It also affects the availability of surface water and groundwater in the Picayune Strand area of the LWC Planning Area as described in the Basis of Review (see also Chapter 3 of this update). NEED FOR ALTERNATIVE WATER SOURCES The collective result of economic, commercial, and residential development, and market changes in the LWC Planning Area reinforces the need for local governments to develop alternative water supply sources to ensure adequate future water supplies.As stated in the 2005-2006 LWC Plan Update,traditional (historical water sources) fresh groundwater and surface water supplies are not expected to be adequate to meet projected water demands for the region.Meeting water supply demand projections over the 20-year planning horizon (2010-2030) requires a continued focus on water conservation and non-traditional water supply solutions. As part of the 2005-2006 LWC water supply planning effort, local governments and water suppliers in the LWC Planning Area worked closely with the SFWMD to identify and develop potable water supply projects to meet projected water needs. Proposed projects were then included in local government comprehensive plans.Since the 2005-2006 LWC Plan Update, the SFWMD has continued to work closely with staff from PWS utilities to identify water supply development projects for this update. Chapter 6 of this update discusses water supply development projects for the LWC Planning Area and Appendix C summarizes these projects. WATER SUPPLY PLANNING This update describes how anticipated water supply needs will be met in the LWC SFWMD e Planning Area for the 20-year planning horizon (2010-2030). This update also Role of the SFWMD describes and meets existing statutory requirements, including listing proposed The SFWMD performs water supply planning water supply projects and regional project for each region within its jurisdiction. The implementation strategies for planners, SFWMD's mission is to manage and protect policy makers, and utility directors. This the water resources of the region by update contains a list of water supply balancing and improving water quality, flood projects for FY 2010 through FY 2030. The control, natural systems, and water supply. majority of new water needs will be met The agency serves local governments by through the development of alternative supporting efforts to safeguard existing water supplies. Some traditional water natural resources and meet future supply development may be possible where water demands. appropriate local hydrologic conditions are present and regulatory requirements are met. 4 I Chapter 1: Introduction Consistent with the state's statutory requirements, as long as funding is available, the alternative water supply projects listed in this update are eligible for cost-sharing consideration through a separate annual funding process established by the SFWMD's Governing Board. Planning Process The planning process for developing this update is described in Table 1 and Figure 1. Table 1. Planning process for developing this update. PLANNING PROCESS CI 3 Data Collection of Population,Finished Identification of Water,and Proposed Evaluation of Water Water Resource and Projects;Analysis;and Resources and Water Water Supply Planning and Assessment Issue Identification Source Options Development Projects The development process for this Using the 2005-2006 LWC The next phase of the Water supply projects plan update incorporated Plan Update as a planning process intended to meet water extensive public participation, foundation,this water involved reviewing needs for the next 20 including seven public supply plan update existing solutions or years were identified, workshops,as well as involved collecting the developing new solutions compiled,and evaluated coordination with local latest information about to address the identified by the SFWMD with input governments,adjoining water water resources,rainfall, issues. In areas where from stakeholders,the management districts,and other natural resources,water projected demands public,and other agencies. state and federal agencies.A demands,water exceed available The projects have review of previous planning conservation,and land use. supplies,solutions undergone initial efforts in the region and Analyses,such as include alternative water screening for feasibility documentation of activities since groundwater and surface supplies and water and has a likelyhood of the approval of the 2005-2006 water evaluations, conservation.Source being permitted.This LWC Plan Update were key regulatory information, options were evaluated information was used to starting points of this process. mapping,wetland studies, and appropriate create Chapter 6:Water Planning integrated development and other related data, responsibilities were Supply Development of 2030 demand projections; confirmed the validity of identified. Projects,which evaluates assessment of existing and previously identified issues existing and proposed projected resource conditions; and helped identify supplies relative to and formulation of strategies to new issues. projected future meet urban,agricultural,and water demands. environmental water needs. 2012 LWC Water Supply Plan Update 15 6 Months 2 12 Months 18 Months I 0 Ill— OIL " Role of SFVVMD Role of PWS Entitles Within 12 monthsof notiAcdion by Water supplyplen upddesevery nsixmorths of v�eter supply SFWMD' I 'i Ave years .date adoption: 1 •PWS entities seledprojedsto be •Subsection 373.709,FS. DnctitesPWSent Alesof implemented 1 supply development •SFWMD norksnithPWSenttiesm L______ ".edsinduded in plan up date ensure projectsmeetfuture needs •section 373.709(8Xb),F.S. t -dion 373 709(8)(a),F.S. ( I I I I November 15 Annually Annually Roleof Local Governments Role of PVVS Entities of ocal Goven nents emonthsalerveetersupplyplan PWSentities submit annual governments may update date is adopted: progress report about statusof bd improvement element by Water suppyfaciltiesvnork writer supp ly projedsto the Inane Wthout amending -plensane am en dmerts adopted SFWMD. g Into l ocal goverrmets' !"comprehensive plen. comprehensive p len •SFWMD reviemsprogress •Subsection 163.3177(3Xb),F.S. ..Sr644dlon/83A1 .J y ,.,,,�„,, reportsantl provitlesassistance as appropriate.di L on 373.709(8)(b),F.S. Figure 1. Linking regional water supply planning with local government comprehensive planning. Regional Water Supply Plans The SFWMD prepares regional water supply plans for each of the four planning areas in its jurisdiction (Kissimmee Basin, Upper East Coast, LWC, and Lower East Coast) to effectively support planning initiatives and address local issues. Updated every five years, each regional water supply plan encompasses a 20-year planning horizon.All local governments within each planning area are required to update their 10-year water supply facilities work plans, which identify water supply projects. Revisions to local government comprehensive plans must be adopted within 18 months following the approval of this update. Each regional water supply plan update provides the following: • Revised water demand estimates and projections • An evaluation of existing regional water resources ♦ Identification of water supply-related issues ♦ A discussion of present water source options ♦ Water resource and water supply development components, including funding strategies • Recommendations for meeting projected demands in the region 6 I Chapter 1: Introduction This update also includes a discussion of Minimum Flows and Levels (MFLs) established within the planning area, MFL recovery and prevention strategies where appropriate,Water Reservations adopted by rule,technical data,and supporting information. Public Participation The SFWMD established the Water Resources Advisory Commission (WRAC) to serve as an advisory body to the Governing Board. The WRAC is the primary forum for conducting workshops, presenting information, and receiving public input on water resource issues affecting south Florida. Commission members represent environmental, urban, and agricultural interests from all four of the SFWMD's water supply planning areas. The SFWMD held WRAC issue workshops on the plan updates throughout the water supply planning process. Stakeholders representing a cross-section of interests in the region — agricultural, industrial, environmental protection, utilities, local government planning departments, and state and federal agencies — were invited to attend the workshops as well as the general public. During the workshops, participants reviewed and provided comments regarding projected demands and other key plan elements compiled by SFWMD staff. In addition to WRAC issue workshops, water demand projections were coordinated through individual meetings with local government planning departments, utilities, and agricultural industry representatives. Participants also reviewed and provided input on water supply issues, the condition of regional water resources, water source options, and other key aspects of the water supply plan update.Ultimately,the plan was presented to the SFWMD Governing Board for their consideration for approval at a publicly noticed meeting. Goal and Objectives INFO Q The goal for this water supply plan update, derived from state statutes, is to identify A reasonable-beneficial use is use of sufficient water supply sources and future water in such quantity as is needed for projects to meet existing and future economic and efficient use for a purpose, reasonable-beneficial uses during a 1-in-10 which is both reasonable and consistent year drought condition through 2030 while with the public interest. sustaining water resources and natural systems. A 1-in-10 year drought is of such intensity that it is expected to happen only once in The objectives developed for the 2005-2006 10 years. A drought of this magnitude results LWC Plan Update were modified for this in an increase in water demand that would update. The following objectives for this have a 10 percent probability of being update provide an overall framework for the exceeded during any given year. planning process: • Water supply. Identify sufficient sources of water to meet reasonable-beneficial consumptive uses projected through 2030 under a 1-in-10 year drought event, without causing harm to natural systems. 2012 LWC Water Supply Plan Update 17 ♦ Natural systems. Enhance and INFO protect wetland systems and the water resources from harm due to water use, including drawdowns and A natural system is a self-sustaining living harmful movement of saline water. system that supports an interdependent ♦ Estuarine and riverine systems. network of aquatic, wetland-dependent, and Protect and enhance estuarine and upland living resources. riverine systems through effective water deliveries and management of A wetland is an area inundated or saturated water resources. by surface water or groundwater with vegetation adapted for life under those soil ♦ Water conservation and conditions(e.g.,swamps, bogs, marshes). alternative source development. Encourage water conservation An estuary is the part of the lower end of a measures to improve the efficiency of water use, and support and river where fresh water and salt water meet. promote the development of alternative sources. Water conservation is the permanent, long- term reduction of daily water use requiring ♦ Linkage with local governments. the implementation of water saving Provide linkage between the update technologies and measures that reduce and local government water water use while satisfying consumer needs. supply elements. • Compatibility and linkage with Alternative sources include salt water, other entities.Achieve compatibility brackish water, groundwater, increased with other related planning activities storage, and reclaimed water. within the region and with adjacent water management districts. ♦ Floridan aquifer system (FAS). Continue to encourage development of the FAS as an alternative to water sources that depend on local rainfall for recharge. Work with utilities and other water users for monitoring to describe the relationships of water use,water levels,and water quality. PLANNING AREA BACKGROUND The LWC Planning Area includes all of Lee County, most of Collier County, and portions of Hendry, Glades, Charlotte, and mainland Monroe counties (Figure 2). The region extends approximately 5,129 square miles, generally reflecting the drainage patterns of the Caloosahatchee, Imperial,Estero,and Cocohatchee river basins,and the Big Cypress Swamp. The LWC Planning Area also contains the SFWMD Big Cypress Basin, which has its own board of directors. The Big Cypress Basin encompasses all of Collier County and part of Monroe County. 8 I Chapter 1: Introduction 1 1 1 ._: LAKE OKEECHOBEE rberlore• Glades ` rmrnw i Charlotte 1 • ° FWMD Ir. — — — — N I • Q 4 Hendry ".aw 1..2e' �' a W E S T t kabaceoolve , 1 Slough L4COAS — " — - 1 :4 I r l-3W I tfa'r., ',.. takscrev+ i,... .. S4,2 1 knperiai R�1O"'� C) I - t .. .hatchee I .. � lite N W�E Ittriri - I-75 C-rral V \\%. Collier �ryil.•s Big Cypress B o Nadorwl Preserve 4. /*-, ` It-. , ., GULF _ k OF —i ,I— — MEXICO _ -::fig... '! —' a• — — _ I — i •r/' I%, 1 Figure 2. LWC Planning Area. 2012 LWC Water Supply Plan Update 19 The following descriptions highlight characteristics of the LWC Planning Area. Additional detail about the LWC Planning Area is provided in the 2011-2012 Water Supply Plan Support Document(Support Document) (SFWMD 2012a). • Population projections show an increase from an estimated 992,486 in 2010 (BEBR 2009) to more than 1.5 million by 2030, a 51 percent gain. Most of the population is expected to remain clustered in coastal Lee and Collier counties. ♦ Most, if not all, of the planning area's 2030 net demand for PWS (192.0 MGD) will be met using alternative water sources,includin: water conservation. • The LWC Planning Area is a leader in brackish and reclaimed water I N F 0 source development. In 2009, brackish water sources provided Reclaimed water has received at least about 41 percent of the planning secondary treatment and basic disinfection and area's potable PWS. In 2010, is reused after flowing out of a wastewater 91 percent of the planning area's treatment facility. wastewater flow was reused. ♦ Agriculture continues to be the largest water consumer in the LWC Planning Area. Overall, gross water use for agriculture is projected to stabilize at an approximate range of 696-741 MGD through 2030. Agricultural acreage is predominantly located inland in north- central Collier,eastern Lee,Hendry,and Glades counties. • The region's traditional water sources include fresh groundwater from the surficial aquifer system (SAS) and intermediate aquifer system (IAS), and surface water from the Caloosahatchee River(C-43 Canal)and Big Cypress Basin canals and artificial ponds. ♦ Additional water sources in the LWC Planning Area include reclaimed water, surface water captured during wet-weather flows,aquifer storage and recovery (ASR)wells,surface reservoirs,and brackish surface water and groundwater. Overview of Water Resources Water for urban and agricultural uses originates from surface water and groundwater throughout the LWC Planning Area Determining the zrz: availability of water needed to meet �p projected demands (Chapter 2) ' requires consideration of the area's available water resources. In mirwa'ov"""' t wat'1011r O r 1111111111,11•1•10 war addition to this overview, extensive op-tm information related to the LWC Planning Area and its water Urban Fort Myers resources is contained in the Support Document. 10 I Chapter 1: Introduction Groundwater Sources The LWC Planning Area uses water from the SAS, IAS, and FAS. These aquifer systems are shown in Figure 3. N Northwest °c 2 Southeast oar N (..)1,-; N Hydrogeologic cs z a Sea Unit m �' Water Table {r Level Suficial 0 Aquifer mi Confinin, Unit Upper Hawthorn Confining Bed �n... :� Depth Intermediate Sandstone Aquifer (feet) Aquifer System Mid-Hawthorn Confining Bed Mid-Hawthorn Aquifer — -500 Lower Hawthorn Confining Bed Upper — -1,000 Lower Hawthorn Producing Zone/Suwanee Producing Zone Floridan Aquifer Confining Unit 1 — -1,500 Avon Park Permeable Zone Confining Unit 2 —-2,000 Lower Floridan • Lower Floridan Aquifer — -2,500 Aquifer -3,000 -3,500 Figure 3. Generalized hydrogeologic cross-section of the LWC Planning Area (section extends from northwest Lee County through southeast Collier County). 2012 LWC Water Supply Plan Update 111 Surficial Aquifer System The SAS is the traditional source of water, including potable water, for urban uses within the LWC Planning Area. It is typically divided into two aquifers, the water table and Lower Tamiami, which are separated by leaky confining beds. In the northern portion of the LWC Planning Area, the Lower Tamiami aquifer thins and merges with the unconfined water table aquifer, or loses permeability and merges with confining material beneath the SAS. The water table aquifer is in direct contact with the atmosphere and receives rainfall recharge.Rainfall is the primary source of recharge to the SAS. Intermediate Aquifer System Depending on location,two or three producing zones are present within the IAS,referred to as the Sandstone and Mid-Hawthorn aquifers. The IAS recharges from the SAS in areas where a hydraulic connection exists between the two systems. The Sandstone and Mid- Hawthorn aquifers have variable physical rock characteristics and thickness, which affect the Sandstone aquifer's degree of connection with the SAS,and overall water production for both aquifers. The Mid-Hawthorn aquifer underlies the Sandstone aquifer and does not receive recharge from the SAS. In some locations, these two aquifers provide adequate production for agricultural and PWS wells. The SAS and IAS supply the fresh water for all the domestic wells within the LWC Planning Area. Floridan Aquifer System The FAS is a thick multilayered sequence of predominantly carbonate rocks that underlies all of Florida and parts of Alabama, Georgia, and South Carolina. The FAS is generally subdivided into upper and lower sections, separated by a continuous low permeability confining unit (see Confining Unit 2 in Figure 3). The upper half of the FAS contains multiple producing zones, separated by less permeable zones of varying degrees. The deepest regions of the FAS contain some of its most permeable zones. However, native water at this depth is highly mineralized, with salinity exceeding that of seawater in some areas. This lower section includes the Boulder Zone, where brine by-products from reverse osmosis (RO)treatment and other permitted discharges are disposed. The portion of the FAS targeted for water supply production in the LWC Planning Area includes the Lower Hawthorn and the Suwannee producing zones, referred to collectively as the Upper Floridan aquifer, as shown in Figure 3. In general, productivity in the Lower Hawthorn section of the Upper Floridan aquifer is slightly higher than in the Suwannee,and salinity differences are common. For these reasons, many wells are constructed to isolate the Lower Hawthorn producing zone. In the LWC Planning Area, the FAS is not hydraulically connected to any freshwater source at the surface. Freshwater recharge must come from outside the LWC Planning Area, but use of the Floridan aquifer north of the planning area effectively intercepts the southward migration of fresh water. The lack of freshwater recharge limits long-term availability of slightly brackish water from the FAS. 12 I Chapter 1: Introduction Surface Water Sources Surface water bodies in the LWC Planning I N F 0 O Area include canals, lakes, and rivers, which provide storage and conveyance of surface Surface water is water above the soil or water. These canals and rivers drain into substrate surface, whether contained in Estero Bay, the Caloosahatchee River and bounds, created naturally or artificially, or Estuary, or the Gulf of Mexico. Although Lake diffused. Water from natural springs is Trafford and Lake Hicpochee are the two classified as surface water when it exits largest lakes within the LWC Planning Area, from the spring onto the earth's surface. neither lake is considered a good source of water supply. Canals Most of the canals in the LWC Planning Area were constructed as surface water drainage systems.The Caloosahatchee River (C-43 Canal) is a key source of fresh water for irrigation and the estuary. Dredged as a canal to connect the Caloosahatchee River to Lake Okeechobee, the C-43 Canal is the freshwater portion of the Caloosahatchee River and extends eastward from the Franklin Lock and Dam to Lake Okeechobee.Three lock and dam structures control flows and water levels in the lake and canal: 1) S-77 at Moore Haven, 2) S-78 at Ortona,and 3) S-79 (Franklin Lock and Dam) at Olga,the latter of which serves as a saltwater barrier.The operation schedules for these structures are adopted by the United States Army Corps of Engineers (USACE)and consider a variety of factors. Rivers • The Caloosahatchee River and Estuary is the most important source of surface water in the region, extending across seven of the ten drainage basins in the LWC Planning Area. The river receives inflows from Lake Okeechobee and runoff from within its own watershed. West of the S-79 structure, the river mixes freely with estuarine water as it empties into the Gulf of Mexico. • The Estero and Imperial rivers drain southern Lee, northern Collier, and southwestern Hendry counties, covering approximately a 400-square mile area. The watershed includes significant wetlands, such as Imperial Marsh, Flint Pen Strand,Corkscrew Swamp,and portions of the Corkscrew Marsh. • The Gordon and Cocohatchee rivers connect to a canal system in western Collier County that serves primarily as a drainage network, directing flows into Naples Bay and the Gulf of Mexico located within the Big Cypress Basin. Because the primary source of water for these rivers is rainfall, the rivers have little or no flow during the dry season. Other Major Water Bodies • Lake Okeechobee is a key component of the south Florida hydrologic system. The 2008 Lake Okeechobee Regulation Schedule, referred to as 2008 LORS (USACE 2007) is designed to maintain Lake Okeechobee water levels one foot 2012 LWC Water Supply Plan Update 1 13 lower than the previous schedule to attain a water level of 12.5-15.5 feet National Geodetic Vertical Datum of 1929 (NGVD). Chapter 3 of this document and Chapter 4 of the Support Document provide additional information about the 2008 LORS. Lake Okeechobee has many functions, including flood protection, urban and agricultural water supply, navigation, fisheries, and wildlife habitat. The lake is critical for flood control during wet seasons and water supply during dry seasons. In the LWC Planning Area, outflows from the lake are received primarily by the Caloosahatchee River (C-43 Canal). For more information see the 2012 Lower East Coast Water Supply Plan Update (SFWMD 2012b). • Estero Bay is a long, narrow, and very shallow body of water with barrier islands separating it from the Gulf of Mexico. The bay's __ watershed includes central and southern Lee County and parts of northern Collier County. Estero Bay is one of Florida's most significant natural watershed resources, and Estero Bay Preserve State Park was designated as the state's first aquatic preserve. Estero Bay • Naples Bay originates at the mouth of the Gordon River in downtown Naples. Fresh water flows into Naples Bay from the Golden Gate Canal, Gordon River, Rock Creek to the north, Haldeman Creek to the east,and runoff from the urban areas surrounding the bay. Wetlands The LWC Planning Area contains 1,779,772 acres of wetlands (USFWS 2010). Key wetlands in the LWC Planning Area include Big Cypress National Preserve, Corkscrew Regional Ecosystem Watershed (CREW), Okaloacoochee Slough, Picayune Strand State Forest, and Fakahatchee Strand Preserve State Park. PROGRESS SINCE THE 2005-2006 LWC PLAN UPDATE The 2000 LWC Plan and the 2005-2006 LWC Plan Update identified several main regional issues concerning water conservation, groundwater resources, reclaimed water, the regional irrigation distribution system, seawater, storage, surface water, and related implementation strategies.Annual progress is summarized in the Five-Year Water Resource Development Work Program contained in Chapter 5A of SFWMD's 2012 South Florida Environmental Report(Martin 2012)available from http://www.sfwmd.gov/sfer. Since the 2005-2006 LWC Plan Update, the following activities and programs have been implemented in the LWC Planning Area to enhance the region's water resources, water supply,and natural systems. 14 I Chapter 1: Introduction Water Conservation ♦ In September 2008, the SFWMD adopted a Comprehensive Water Conservation Program to establish proactive water savings through demand management throughout the SFWMD boundaries. ♦ The Mandatory Year-Round Landscape Irrigation Conservation Measures Rule became effective in March 2010 (Chapter 40E-24, F.A.C.), consistent with the Comprehensive Water Conservation Program. ♦ The Water Savings Incentive Program (WaterSIP) provides up to 50-50 cost- sharing funds to utilities, municipalities, property owner associations, and large water users for non-capital projects; specifically the purchase and installation of high efficiency indoor plumbing fixtures and outdoor irrigation retrofits. From FY 2007 to FY 2012, the SFWMD awarded $627,456 for 23 LWC Planning Area WaterSIP projects, representing a projected savings of 178 million gallons per year (MGY). For more information about water conservation see Chapter 4 and Appendix E of this plan update. Modeling and Studies ♦ In 2005, the SFWMD and United States Geological Survey (USGS) began a cooperative study to measure evapotranspiration (ET) in south Florida using the eddy-covariance method. Spatially extensive plant communities within Big Cypress National Preserve were studied individually, including dwarf cypress, cypress swamps, pine uplands, wet prairies, and marsh as mapped by Duever et al. (1986). In 2007, the USGS installed two ET monitoring sites within differing vegetation communities in the Big Cypress National Preserve and completed the construction of three towers. The fieldwork was completed in 2010. Results from this study are published in Shoemaker et al. (2011),which is available from http://pubs.usgs.gov/sir/2011/5212/. This study provides the first quantitative measurements of ET for the major natural plant communities in south Florida. The ET data from this study will be used to improve hydrologic models. ♦ An independent peer review panel reviewed the original version of the density- dependent Lower West Coast Floridan Aquifer System Model (LWCFAS),and the panel's recommendations were incorporated into a new model.During FY 2010, a revised steady-state model was created to represent estimated predevelopment conditions in the FAS. In FY 2011, the model was recalibrated to transient conditions.The LWCFAS Model is designed to evaluate future effects of the proposed use of the aquifer system, and will be available for future plan updates. ♦ The USACE and the SFWMD completed the Draft Southwest Florida Feasibility Study Integrated Feasibility Report and Environmental Impact Statement, referred to as the Southwest Florida Feasibility Study (USACE and SFWMD 2009), which examines potential resource restoration projects for the entire southwest Florida area. The study provides a comprehensive watershed master plan, including marine/estuary restoration and protection, environmental quality,flood protection,water supply,and other water-related purposes. 2012 LWC Water Supply Plan Update 115 ♦ An integrated surface water-groundwater model of southwest Florida (SDI Environmental Services, Inc. et al. 2008) was developed as part of the Southwest Florida Feasibility Study. The model examines the influences of proposed environmental projects on surface water hydrology and shallow groundwater systems. ♦ The Lower West Coast Surficial Aquifer (LWCSAS) Model was developed by the SFWMD to simulate groundwater flow and levels to represent existing and potential future hydrologic conditions in the LWC Planning Area.The model will be updated to include simulation of the IAS, and following this,a peer review of the updated model will be conducted in FY2014. Regulatory Protection and Water Quality Efforts ♦ The SFWMD's first Water Reservation rule was adopted for the support of the CERP Picayune Strand Restoration Project and Fakahatchee Estuary on July 2,2009 (Chapter 40E-10, F.A.C.). (See the Water Reservations section of this chapter and Chapters 3 and 5). ♦ In October 2008, the SFWMD adopted rule criteria for the Lake Okeechobee Service Area to limit allocations from Lake Okeechobee and connected surface waters including the Caloosahatchee River (C-43 Canal) and St. Lucie River (C-44 Canal) to historical condition water uses that occurred from April 1, 2001 to January 1, 2008 (see the Restricted Allocation Areas section of this chapter and Chapters 3 and 5, and Appendix I). For more information see the 2012 Lower East Coast Water Supply Plan Update(SFWMD 2012b). The Dispersed Water Management Program is a collective and collaborative entity effort designed to encourage property owners to retain water on their land rather than drain it, accept regional excess runoff for storage, or both. The program uses three different approaches: cooperative projects, easements, and payment for environmental services. Based on data from initial pilot projects, the SFWMD expanded participation in the program. Since 2005, through a combination of dispersed water management and regional projects, landscape storage has increased a total of 138,016 acre-feet throughout the Everglades system, including the Caloosahatchee Estuary and St. Lucie Estuary watersheds, and sites north and south of Lake Okeechobee. Currently, six dispersed water management cooperative projects are occurring within the Caloosahatchee Watershed: 1) Nicodemus Slough Water Retention Project, 2) South Lake Hicpochee, 3) BOMA Site Interim Project, 4) C-43 Reservoir Site Interim Project, 5) Caloosahatchee River Estuary water farming pilot projects (locations to be determined), and 6) Northern Everglades Payment for Environmental Services Solicitation projects (locations to be determined). See Appendix I for more information. The SFWMD is funding a pilot water farming study in the planning region to assess the overall feasibility of water farming citrus lands that are currently fallow. Primary goals are to identify costs associated with on-site construction, infrastructure improvements, environmental assessments, and facility maintenance. The objective is to determine the cost-benefits and other benefits associated with water farming as a means of increasing local/regional storage and improving water quality to benefit both the natural system and 16 I Chapter 1: Introduction the agricultural industry.Water farming has the potential to reduce environmental impacts and provides an opportunity to improve water quality for the Caloosahatchee River and Estuary. Water Storage • Over the past five years, the Big Cypress Basin Board of Directors funded a program to improve the water control infrastructure and management operations of its 44 water control structures. The reconstructed Faka Union Canal Weir 4 provides the ability to store 3 billion gallons of water during the dry season. Reconstructed weirs in the Corkscrew Canal have increased average annual groundwater storage by approximately 424 million gallons. The retrofitted Golden Gate Weirs 2 and 3 have increased groundwater levels from 0.1 feet to 1.5 feet between Weirs 2 and 3, and provide annual average surface water storage of 1.6 billion gallons. • The purpose of the CERP Caloosahatchee River (C-43) West Basin Storage Reservoir Project is to improve the quantity, timing, and distribution of freshwater flows to the Caloosahatchee River and Estuary. This planned reservoir project will capture and store surface water runoff from the C-43 Basin and Lake Okeechobee to provide a more natural and consistent flow of fresh water to the estuary. After construction and flow-through testing, operation of this project is expected to improve the Caloosahatchee Estuary's salinity balance by reducing a portion of the peak discharges during the wet season and providing essential flows during the dry season. To date, land has been cleared and designs for construction are permitted.The project is awaiting congressional authorization and appropriation of funds to start construction. The USACE anticipates project authorization to occur in August 2013 with appropriation of funding to follow at a later date. Once congressional funding has been appropriated, a timetable for the completion of the reservoir will be developed. Restoration ♦ The first phase of the CERP Picayune Strand Restoration Project is complete. The initial phase filled or plugged seven miles of Prairie Canal and removed 65 miles of adjacent roadways, restoring 13,000 acres of the 55,000 acres in the project area. The SFWMD's Water Reservation for the Picayune Strand and Fakahatchee Estuary supports this restoration project. Water Supply Development Projects • Water supply development in the LWC Planning Area included both traditional (fresh and surface water and groundwater) and alternative sources. Through the Alternative Water Supply Funding Program, the SFWMD assisted water users in the development of alternative water projects, including reclaimed water, water reclamation facilities, brackish water wellfields, RO treatment facilities, and ASR well systems (see Chapters 5 and 6). For the 2007-2012 period,the SFWMD,in cooperation with the State of Florida,provided more than 2012 LWC Water Supply Plan Update I 17 $123 million in alternative water supply funding for 212 projects, with 78 projects occurring in the LWC Planning Area. ♦ Between FY 2007 and FY 2012, water supply development projects funded by the Alternative Water Supply Funding Program in the LWC Planning Area have created a total of 104 MGD of new water capacity.The new sources of this water include 37 MGD of brackish water, 33 MGD of reclaimed water, 16 MGD of Hawthorn aquifer water, 3 MGD of ASR water, and 15 MGD of surface water/storm water and other projects. OUTLOOK ON CLIMATE CHANGE Southwest Florida is particularly vulnerable to the effects of climate change and sea level rise. The topography of the area is generally flat, naturally poorly drained, and has an average elevation of 16 feet above mean sea level. The regional economy has major investments within close proximity of the coast or lake water bodies (SWFRPC and CHNEP 2009). As sea level rises, low elevation coastal areas will be increasingly subject to flooding, especially during spring and fall high tides,storms,and strong onshore winds (Murley et al. 2008). The canal networks of the SFWMD in much of the LWC Planning Area are typically maintained at predetermined water levels to reduce the potential for saltwater intrusion into the PWS wellfields and to provide flood protection. Projected sea level rise may reduce the flood discharge capacity of coastal structures, thus affecting flood protection in urban areas (SFWMD 2009a). Other changes, such as increased ET,and changes in weather patterns,are less predictable. If temperatures and ET increase as many experts expect, both PWS and AGR Self-Supply water demands may increase. More frequent intense rainfall events with longer interim dry periods could increase total annual rainfall, but decrease effective rainfall, as more water may be lost to runoff or tide (see Chapters 3 and 7). In 2010, Lee County developed a climate change resiliency strategy to guide the county plans and strategies relating to specific vulnerabilities and priorities of the county. Previously, the Southwest Florida Regional Planning Council had prepared the Comprehensive Southwest Florida/Charlotte Harbor Climate Change Vulnerability Assessment (SWFRPC and CHNEP 2009). The Southwest Florida Regional Planning Council indicated that this study would be used to facilitate the work of local government elected officials and staff to consider sea level rise when planning for public facility expansions and reconstruction after hurricane damage or due to old age (SWFRC and CHNEP 2009). WATER SUPPLY PLANNING FOR THE NEXT 20 YEARS The stronger statutory link between local governments' comprehensive plans and the SFWMD's regional water supply plans, data sharing, and collaborative planning are all 18 I Chapter 1: Introduction credited with improving the water supply planning process. Moreover, SFWMD staff responsible for water supply development closely coordinate with SFWMD staff responsible for managing the Consumptive Use Permitting Program during the water supply planning process. This continued coordination will only improve by fulfilling the guidance provided by the Florida Department of Environmental Protection (FDEP) to the water management districts. Water suppliers are not required to choose a water supply development project identified in a regional water supply plan.However,if a water supply project included in the LWC Plan Update is pursued, consumptive use permit applicants should have confidence that the project has undergone initial screening for feasibility and has a likelihood of being permittable. In early 2012, SFWMD staff did an initial screening for feasibility of the proposed water supply development projects included in this water supply plan. The proposed projects have not been analyzed to the level of detail required to determine if the proposed project meets the conditions for consumptive use permit issuance; however, the proposed projects are likely permittable. Additionally, in 2012, FDEP launched a statewide effort, known as CUPcon to improve consistency in the Consumptive Use Permitting Programs implemented by the water management districts. Updates to local governments' water supply facilities work plans and the next SFWMD's five-year water supply plan update will continue to refine 20-year demand estimates and projections. 2012 LWC Water Supply Plan Update 19 20 I Chapter 1: Introduction Demand Estimates and Projections This chapter discusses water demand estimates and TOPICS projections for the Lower West Coast (LWC) Planning Area. The development of water demand projections is a complex 41 Water Use Categories process accomplished in coordination with staff from local governments,utilities,other agencies,and stakeholder groups. Population and Water Data collection and analysis to support the projections Use Trends included in this plan began in summer 2009. ♦ Net Water Demands After publication of the 2005-2006 Lower West Coast Water • Gross Water Demands Supply Plan Update (2005-2006 LWC Plan Update; SFWMD ♦ Demand Projections in 2006), a national economic downturn occurred and Perspective population growth in the LWC Planning Area slowed significantly, leading to a reduced rate of increase in future urban water demands. In this chapter, water demands for the water use categories established by the Florida Department of Environmental Protection (FDEP) are projected for a 20-year planning horizon of 2010 through 2030. Water demands are described in two ways, gross and net. Both gross water demands and net water demands are calculated in million gallons of water per day(MGD).The demands discussed in this chapter do not address natural system water supply needs. The water supply needs for natural systems are discussed in Chapter 3 and Appendices G and H and are considered a limitation on water available for allocation. These water supply needs are addressed through a variety of regulatory mechanisms and projects. Gross water demand is also called raw water demand. Gross or raw water demand is the amount of water withdrawn from the water resource to meet a particular need of a water user or customer. Gross demand is the amount of water allocated in a consumptive use permit. In the Public Water Supply (PWS) use category, net water demands are commonly termed finished water demands. Net demand is the volume of water needed by an end user or customer, after deducting treatment and process water losses, and system inefficiencies. Gross demands are usually higher than net demands as most uses lose water through the treatment and/or transport of the water, in system inefficiencies, or irrigation delivery. 2012 LWC Water Supply Plan Update 121 A PWS facility that uses brackish water as one of its sources and employs reverse osmosis (RO) treatment is a good example to demonstrate the difference between net and gross water demands.While customer need for finished water may be 10 MGD (net demand), 13.5 MGD of raw water(gross demand) must be withdrawn from the water source to account for water losses in the treatment process. A 75 percent efficiency factor is assumed because, typically, for every 100 gallons pumped and treated through RO, the process results in 75 gallons of finished water and 25 gallons of reject water and water lost in transit. This chapter provides demand projections in LAW / CODE La of average annual rainfall conditions and anticipated growth in the LWC Planning Area through 2030. As water demands may A 1-in-10 year drought event is a rainfall be significantly impacted by weather, deficit that would have a 10 percent particularly rainfall, gross and net demands probability of occurring during any given for 1-in-10 year drought conditions are year. Paragraph 373.709(2)(a), F.S., states the estimated and projected in Appendix A. level-of-certainty planning goal associated with identifying demands shall be based on Demand projections in the 2005-2006 LWC meeting demands during a 1-in-10 year Plan Update were determined using 2000 drought event. Droughts generally create an baseline data. For this plan update, a new increased water demand. baseline incorporating 2005 data was established to estimate demand projections. The 2005 baseline was developed from a variety of data sources including permanent population estimates, land use, crop production,irrigation systems,historical water use,and climatic conditions.Data from 2005 were also used to develop water use factors, such as finished water per capita use rates (PCURs) by utility, and irrigation system efficiency by crop type. These factors, along with projected variables, such as population and irrigated acres, were used to project future water demands for the 2010 to 2030 planning horizon. The future water demands were based on historical rainfall conditions. Uncertainty about the degree of future climate change precluded projecting possible deviations in rainfall and evapotranspiration(ET). Appendix A provides a full description of the methods used to estimate water use for each major use category, and includes estimates of both the customer demands discussed here and the raw water withdrawals. This appendix also provides both gross and net water demand projections for average year and 1-in-10 year drought conditions, as well as additional information about water demand within each water use category. For agriculture, irrigated acreage and demands by crop type are included. For PWS,permanent population and demands by utility are provided. Although not quantified in this chapter, environmental demands are addressed during the water supply planning process using resource protection criteria. 22 I Chapter 2: Demand Estimates and Projections DESCRIPTIONS OF WATER USE CATEGORIES Gross and net water demands for 2005 and projections through 2030 are estimated in five- year increments for each of the six water use categories established by the FDEP (see Appendix A): ♦ Agricultural (AGR) Self-Supply. Water used for commercial crop irrigation, livestock watering,and aquaculture. ♦ Public Water Supply (PWS). Water supplied by water treatment facilities for potable use (drinking quality) with projected average pumpages equal to or greater than 100,000 gallons per day(GPD)or 0.1 MGD. • Domestic Self-Supply (DSS). Water used by households served by small utilities (less than 0.1 MGD)and private wells. ♦ Industrial/Commercial/Institutional (ICI) Self-Supply. Self-supplied water consumed by business operations and institutions, such as schools, hospitals and prisons that have demands of 0.1 MGD or greater. ♦ Recreational/Landscape (REC) Self-Supply. Water used for irrigation of golf courses, parks, cemeteries, large common areas such as homeowner associations and commercial developments, and other self-supplied irrigation uses with demands of 0.1 MGD or greater. ♦ Power Generation (PWR) Self-Supply. Water consumed by power plants in the production of electricity,excluding use of seawater sources. Urban demands are the combined total of PWS, DSS, ICI Self-Supply, REC Self-Supply, and PWR Self-Supply user demands.By 2030,these use categories are expected to account for at least 47 percent of the LWC Planning Area's total net water demands, with PWS net demands expected to increase by 60.6 MGD (46 percent) from the 2010 estimated net demand. Agricultural water use is projected to remain the LWC Planning Area's single largest water use category in 2030. Estimates indicate AGR Self-Supply gross water demand will represent at least 57 percent of the planning area's total gross demands by 2030. The Net Water Demands section discusses the average year net demand projections for PWS and DSS. The Gross Water Demands section discusses the average year gross demand projections for AGR Self-Supply, ICI Self-Supply, REC Self-Supply, and PWR Self-Supply.The water supply development projects proposed to meet LWC Planning Area demands are in Chapter 6. POPULATION AND WATER USE TRENDS Population estimates for the LWC Planning Area include the permanent populations of Collier and Lee counties and portions of Hendry, Glades, and Charlotte counties. The LWC Planning Area's population is expected to increase by 51 percent from 2010 to 2030, with 2012 LWC Water Supply Plan Update J 23 Collier and Lee counties attracting the greatest number of new residents. While this projection represents a significant population increase, it is a slower rate of growth than projected in the 2005-2006 LWC Plan Update (Figure 4). The portion of Charlotte County within the South Florida Water Management District (SFWMD) is expected to experience the highest rate of growth, due primarily to the Town and Country Utilities' service area, which includes Babcock Ranch. 1,800,000 1,600,000 1,400,000 - i a 600,000 400,000 - f2012 LWC Plan Update 200,000 - x-2005-2006 LWC Plan Update 0 2000 2005 2010 2015 2020 2025 2030 Figure 4. Population projections, 2005-2006 LWC Plan Update versus this plan update. NET WATER DEMANDS PWS and DSS are discussed in this section. I N F O All other water use categories are discussed in the Gross Water Demands section. The PWS and DSS use categories are presented in Net Water Demand or User/Customer net water demand terms because they are Water Demand is the water demand of the generally focused on finished (treated) end user after accounting for treatment and water. The use of net or finished water process losses and inefficiencies. When demands allows utilities to compare actual discussing PWS, the term "finished water water delivered from the treatment facility demand" is commonly used to denote even as they change source waters that net demand. require different treatment processes. By using net demands for PWS, water losses occurring during water treatment and transport are eliminated. The change in net demands for the 20-year planning horizon for all water use categories is presented in Figure 5. 24 I Chapter 2: Demand Estimates and Projections Net Demands 700 600 500 400 — 0 To •2010 c 300 — •2030 200 — 100 — 0 AGR PWS DSS ICI REC PWR Industrial/ Public Commercial/ Recreational/ Power Agricultural Water Domestic Institutional Landscape Generation Self-Supply Supply Self-Supply Self-Supply Self-Supply Self-Supply Total Estimated 403.1 131.4 15.7 35.3 97.5 0.5 683.5 2010 MGD Projected 442.4-477.4 192.0 19.9 35.3 141.5 42.1 873.2-908.2 2030 MGD Percent 10-18% 46% 27% 0% 45% 8,320% 28-33% Change Percent of Projected 50-52% 21% 2% 4% 16% 5% 2030 Total Note: The bar chart compares demands by use category in MGD, and the table shows the percentage of growth in each category. Percent of Projected 2030 Totals other than AGR Self-Supply are calculated based on the upper range limit of demand(908.2 MGD). Figure 5. Estimated average year net demands by water use category for 2010 and 2030. 2012 LWC Water Supply Plan Update 125 Public Water Supply and Domestic Self-Supply PWS is the water supplied by water treatment facilities for potable use (drinking quality) to users, such as homes, office and retail facilities, schools, and institutions. The PWS use I h 407.w-4.-- category comprises utilities with °-- projected average pumpages equal to greater than 0.1 MGD through 2030. Water used by households or facilities - served by small utilities (less than 0.1 MGD) or private wells are categorized Fort Myers/Caloosahatchee River Estuary as DSS. Development of the water demand projections for the LWC Planning Area was a multistep process. The process began with the medium-range population projections established by the University of Florida's Bureau of Economic and Business Research (BEBR) for each county and finished water use data as reported to the FDEP. These data were used to establish 2005 population and PCUR estimations (BEBR 2006).The 2009 BEBR data (BEBR 2009) were then used in conjunction with information from 10-year water supply facilities work plans and local government comprehensive plans adopted by the Florida Department of Economic Opportunity, SFWMD's consumptive use permits, metropolitan planning organizations,traffic analysis zones,and FDEP-permitted PWS capacity. To prepare draft population and water demand projections for the PWS and DSS categories within the LWC Planning Area,a status check of active and inactive development of regional impact orders was conducted through the local planning councils. Throughout the process, draft projections were discussed with each utility and local government planning department to coordinate the final projections published in this plan update. It is important to note that the BEBR projections use permanent population projections and do not include seasonal residents, tourists, and migrant workers. Several areas in the LWC Planning Area have a large number of seasonal residents, which are considered in PCURs. The PCURs reflect all usage, because they are based on finished water as reported by each utility to the FDEP, including the water used by permanent and seasonal residents, as well as tourists and migrant workers. A per capita figure is the total use divided by the permanent population. This approach produces higher PCURs for utilities with large seasonal populations than other approaches that include a factor for seasonal residents. Projected demands for each utility service area assume a constant PCUR for the 20-year planning horizon. Three primary sources were used to calculate population projections for PWS. The 2009 BEBR county population projections were examined as an overall control for each county. To obtain the detailed distributions needed for the utility estimates and projections, historical and projected populations from traffic analysis zones were used. Traffic analysis 26 I Chapter 2: Demand Estimates and Projections zones, which are based on 2000 United States census data, are defined by the Florida Department of Transportation and local metropolitan planning organizations. A compound annual growth rate is used to distribute the projected population from 2010 to 2030 in five- year intervals for each utility service area. DSS projections are based on a countywide average PCUR from the utilities. Water conservation measures were not factored into the demand projections used in this chapter. Rather,water conservation is considered a water source option (see Chapter 4). Table 2 provides a summary of the population estimates for the counties or portions of counties located in the LWC Planning Area, and Table 3 lists the projected net water demands from the base year, 2005,through the planning horizon, 2030. During the next 20 years, the LWC Planning Area population is projected to increase from an estimated 992,486 in 2010 to more than 1.5 million by 2030 (Table 2). PWS demands increase significantly through the 2030 projection horizon, primarily due to this anticipated population increase (Table 3). DSS demand growth is less significant, as most new potable water demand will be served by PWS systems. In some counties, DSS decreases due to expansion of PWS distribution systems into areas that are currently DSS. Table 2. Projections of permanent population in the LWC Planning Area, 2010-2030. Collier 341,565 310,952 30,613 471,999 410,126 61,873 Lee 606,949 542,432 64,517 957,100 917,012 40,088 Hendry (portion in LWC Planning Area)b 37,493 24,279 13,214 51,023 28,793 22,230 Glades (portion in LWC Planning Area)b 6,413 2,857 3,556 8,413 3,776 4,637 Charlotte (portion in SFWMD boundaries)b 66 0 66 14,166 13,948 218 a.Source:BEBR 2009 b.Sources:U.S.Census Bureau 2001,BEBR 2009 Table 3. Net PWS and DSS water demands in the LWC Planning Area, 2005-2030. Public Water Supply 121.5 131.4 142.6 156.7 173.0 192.0 Domestic Self-Supply 15.0 15.7 16.6 17.8 19.3 19.9 2012 LWC Water Supply Plan Update 127 GROSS WATER DEMANDS INFO Q Gross water demand is the amount of raw Gross Water Demand or Raw Water Demand water needed for a specific use. Gross water is the amount of water withdrawn from the demand differs from net water demand in water resource to meet a particular need of a that water lost during treatment, transport, water user or customer. Gross demand is the or irrigation delivery is included in gross amount of water allocated in a consumptive water demand values but not in net water use permit. Gross or raw water demands are demand values. This section reviews the nearly always higher than net or user/ gross water demands of the AGR, ICI, REC, customer water demands. and PWR Self-Supply water use categories. As mentioned earlier, there is generally a difference between gross and net water demands. Variations in treatment, distribution, and irrigation methods can increase or decrease the gross demand. The difference between gross and net demands can be reduced through water conservation practices that,in turn,reduce demands on the water resource. In 2010, average annual gross water demands for all categories in the LWC Planning Area totaled 971.1 MGD. By 2030, the projected total average annual gross water demands are estimated to range from 1,217.9 to 1,262.9 MGD,an increase of 25-30 percent(Figure 6). Average annual estimates are used to demonstrate general projected trends,including these key highlights: ♦ AGR Self-Supply gross demands represent agricultural lands that are regularly irrigated to produce crops and water for livestock.These demands are projected to increase from an estimated 630 MGD in 2010 to 695.9-740.9 MGD by 2030. This accounts for 57-59 percent of the region's gross water withdrawal demands by 2030. ♦ PWS and DSS gross demands are projected to increase by 47 percent, from an estimated 175 MGD in 2010 to 256 MGD by 2030, representing at least 21 percent of the region's total gross demands by 2030 (see also the Net Water Demands section of this chapter). ♦ ICI Self-Supply gross demand is anticipated to remain unchanged. ♦ REC Self-Supply gross demands are expected to increase from an estimated 130 MGD in 2010 to 188.5 MGD by 2030,a gain of 45 percent. ♦ PWR Self-Supply gross demands are expected to increase from 0.5 MGD in 2010 to 42.1 MGD by 2030. Such an increase may occur to support new or expanded power generation facilities proposed by Florida Power & Light (FPL), south Florida's major power supplier. The increase in demand for this category is lower than the 2005-2006 LWC Plan Update's 2025 estimate of 67 MGD. Figure 6 shows the estimated 2010 gross demands and projected 2030 gross demands for all water use categories. 28 I Chapter 2: Demand Estimates and Projections ■ 800 600 700 >, as Ii N 500 C 0 400 •2010 �7 •2030 p 300 2 200 100 0 IL --IIIIII—r--It AGR PWS DSS ICI REC PWR Industrial/ Public Commercial/ Recreational/ Power Agricultural Water Domestic Institutional Landscape Generation Self-Supply Supply Self-Supply Self-Supply Self-Supply Self-Supply Total Estimated 630.0 156.3 18.9 35.3 130.1 0.5 971.1 2010 MGD Projected 695.9-740.9 232.1 24.0 35.3 188.5 42.1 1,217.9— 2030 MGD 1,262.9 Percent 10-18% 27% 0% 8,320% Change 49% 27/° 0/ 45°° 8,320% 25-30% Percent of Projected 57-59% 19% 2% 3% 15% 3% 2030 Total Notes: The bar chart compares demands by use category in MGD, and the table shows the percentage of growth in each category. Percent of Projected 2030 Totals other than AGR Self-Supply are calculated based on the upper range limit of demand(1,262.9 MGD). Figure 6. Estimated daily gross demands for an average year by water use category for 2010 and 2030. 2012 LWC Water Supply Plan Update 129 Agricultural Self-Supply AGR Self-Supply includes water used for commercial crop irrigation, livestock watering, and aquaculture. Agriculture is a key industry in southwest Florida and is expected to9 ��+ remain the dominant land use in the /1. region despite economic challenges and damage from hurricanes and diseases, such as citrus canker and greening.The importance of the region's agricultural industry is reflected in projections that show it will continue to be the leading Low-volume Drip Irrigation water use category. Agricultural acreage and associated water demands are challenging to project because of the various economic,weather,and disease issues that impact production. In addition,market-driven factors affect the crops grown and volume of water used. Therefore, to estimate future gross water demand, it was deemed appropriate to use ranges for future acreage and demand projections. Gross irrigation requirements are the amount of water that must be withdrawn from the source in order to be delivered to the plant root zone. The volumes in Table 4 account for soil type and irrigation system efficiency. Net demands reflect an estimate of the amount of water that farmers need to place into the root zones of crops.Appendix A presents both net and gross irrigation demands by crop type under average year and 1-in-10 year drought conditions from the 2005 baseline through the 2030 planning horizon. Table 4. Estimated irrigated agricultural acreages and average year gross demands by crop type for 2010 and 2030. 2010 2010 Demand 2030 Demand r Category Acres (MGD) 2030 Acres (MGD) Citrus 118,065 182.8 123,177-152,177a 190.8-235.8 Field Crops—Sugarcane 94,426 232.6 111,479 274.9 Field Crops—Other 3,322 8.6 3,322 8.6 Vegetables, Melons,and Berries 82,202 181.4 82,202 181.4 Sod 3,867 11.9 8,524 26.1 Greenhouse/Nursery 3,569 11.9 3,855 13.3 Other Fruits and Nuts 568 0.8 568 0.8 Total 3t, $ rssk 4 } a. Includes 29,000 acres of transitional land. Note:Perceived discrepancies in totals between this chapter and Appendix A are due to rounding. 30 Chapter 2: Demand Estimates and Projections For 2005 and 2010, estimates of active cultivated acreage with irrigation are based on various industry statistical surveys, including the United States Department of Agriculture (USDA),citrus industries,and information from the following sources: ♦ USDA-National Agricultural Statistics Service ♦ Florida Department of Agriculture and Consumer Services (FDACS) ♦ Gulf Citrus Growers Association,Inc. ♦ Local agricultural extension offices ♦ University of Florida's Institute of Food and Agricultural Services (IFAS) 0 Florida Farm Bureau and SFWMD agricultural stakeholders ♦ SFWMD Water Use Regulatory Database • Southwest Florida Water Management District ♦ Southwest Florida Feasibility Study geographic information system land use layers (SDI Environmental,Inc.2008,Liebermann 2006) For this plan update, actively cultivated agricultural acreage is expected to increase from 306,019 in 2010 to 333,127-362,127 acres by 2030 (Table 4).Acreage projections by crop are provided for each county in Appendix A. In terms of gross demands, water use is expected to increase to 695.9-740.9 MGD by 2030. The 2010 cultivated and irrigated acreage of 306,019 is significantly less than the 2005 acreage reported in the 2005-2006 LWC Plan Update. The difference between acreage estimates is attributed to many factors, including acreage loss due to hurricanes; citrus canker and greening; a decline in sod and landscape nurseries due to the economic downturn; changes in commodity markets; and clearing of about 10,000 acres for the Comprehensive Everglades Restoration Plan (CERP) Caloosahatchee River (C-43) West Basin Storage Reservoir Project. The total agricultural acres listed in the 2005-2006 LWC Plan Update used the yo-' best information available at that time s. for the 2025 planning horizon, which did not reflect the loss of citrus acres caused by hurricanes or disease. Asa $ result of the challenges occurring in the citrus industry, the USDA is \ preparing annual citrus inventories to •monitor the industry's growth. The *„ \ -\ citrus acres included in this plan update are based on the USDA reports Citrus Farming of these inventories (USDA-NASS 2004,2006, 2008, 2009). 2012 LWC Water Supply Plan Update 131 Within the region, there are local declines in cultivated acreage in Hendry County and increases in cultivated acreage in Charlotte and Glades counties. Lee County's cultivated agricultural acreage levels are projected to remain stable. Based on input from agricultural industry and agricultural agency representatives, the SFWMD anticipates most agricultural land will remain in agriculture use within the LWC Planning Area. As future markets warrant, either historical crops will be replanted or the land will be converted for use with new crops. Projections in this plan update include approximately 29,000 acres of transitional land not assigned within a specific county. The SFWMD's stakeholders anticipate this land will remain in agricultural production and will likely be used for citrus crops. The LWC Planning Area experienced the loss of about 34,000 acres of citrus between 2004 and 2009 due to hurricane damage and the proliferation of canker and greening diseases. In addition,about 10,000 acres were permanently taken out of production when the land was cleared for the CERP Caloosahatchee River(C-43)West Basin Storage Reservoir Project. Researchers are evaluating options to manage the occurrence of disease, develop disease- resistant rootstock, and establish production practices, such as the advanced production and open hydroponic systems. The outcome of this research will help determine the crops grown on the region's agricultural land; that is,whether the land will continue to be farmed in citrus or will transition to another crop. Agricultural industry and agency representatives indicate that peaches, blueberries, strawberries, and plants for biofuel or landscape material are viable crop alternatives for transitional LWC Planning Area agricultural lands (see Appendix A). In addition, the agricultural community anticipates regional movement of some crops from northern counties because of issues related to freezes, freeze protection water, and varying restrictions in other regions. The FDACS indicates that Florida's climate is well suited for production of biofuel. The growing season positions Florida to become a leader in cellulosic ethanol production. Significant research is under way to evaluate biofuel crops best suited for Florida and several pilot projects have begun. Biofuel crops could be significant in the future within the LWC Planning Area (see Appendix A). Agricultural water demand reflects projected irrigated acreage,crop and soil types,growing seasons, and irrigation system types and strategies. AGR Self-Supply demand calculations for this plan update applied results from the Agricultural Field Scale Irrigation Requirements Simulation (AFSIRS) Model (Smajstrla 1990). The model calculates average and 1-in-10 year drought conditions water demands using 35 years of daily rainfall and evaporation records. Acreage projections are based on the data and methods contained in the land use projection analysis completed by the SFWMD to support this plan update. Agricultural acreage estimates from the USDA and the SFWMD Water Use Regulatory Database were also used to 32 I Chapter 2: Demand Estimates and Projections confirm or revise previous analyses. In addition, agricultural industry experts provided input on agricultural acreage estimates,which were considered in the overall analysis. The increase in actively cultivated agricultural acreage from 2010 to 2030 is expected to range from 27,108 to 56,108 acres. The acres dedicated to citrus, sugarcane, greenhouse /nursery, and sod, are all expected to increase during the planning horizon. Estimated agricultural irrigated acreages and average year gross demands by crop type for 2010 and 2030 are presented in Table 4. Current (2010) agricultural water use accounts for 65 percent of the region's total gross demands. By 2030, the LWC Planning Area's total gross agricultural demands are projected to increase 10-18 percent. Industrial/Commercial/Institutional Self-Supply ICI Self-Supply demands through 2030 are not projected to exceed the projections used in the 2005-2006 LWC Plan Update. In this region,the major industrial water use is limerock production, which was at a peak in 2005 and 2006. For this production process, water is continually recirculated; therefore,an increase in limerock production does not necessarily relate to an increase in water use. Although several proposed limerock mines are planned during the next 20 years,the production of rock and resulting water use are not expected to be any more than the 2005 production levels. Citrus and sugar processing are other industrial water uses in the region.These industries strive to maintain consistent production that,in turn,results in consistent annual water use. Many other ICI Self-Supply facilities receive water from PWS and are, therefore, included in PWS use. Reports from the SFWMD Water Use Regulatory Database in 2005 were used to calculate ICI Self-Supply water use demands. Individual self-suppliers for commercial and institutional facilities typically have demands less than 0.1 MGD. Finally, because this demand category is a composite of different use types such as those previously discussed, and historical water use data do not demonstrate clear trends, the demands are held constant through the 20-year planning horizon. Gross and net water demands are not distinguished for this use category,as most of the water withdrawn is recycled. Recreational/Landscape Self-Supply Gross demand for REC Self-Supply is projected to increase by 45 percent from the estimated 130.1 MGD in 2010 to 188.5 MGD in 2030. REC Self-Supply demands supplied by PWS utilities are included in the PWS net demands. REC Self-Supply water use projections include landscape and golf course irrigation demands, as well as water needs for parks; communities and homeowner associations with large common areas and consolidated irrigation systems; and areas with large green spaces, such as ball fields, stadiums, and cemeteries. 2012 LWC Water Supply Plan Update 133 Estimated landscape and golf course acreage was based on the total number of landscape and golf course consumptive use permits registered in the SFWMD Water Use Regulatory Database. Future year demands were projected using county population growth rates and information provided by local planning officials. Based on input received from golf course stakeholders and planning staff, golf course water demands are expected to increase minimally during the next 20 years. Landscape acres are projected to increase based on population growth rates calculated in the plan update for each county.The estimated 2005 acreage and projected gross demands were calculated using acreage and the AFSIRS Model. The AFSIRS Model calculates the net irrigation requirements of a landscape and its irrigation system.Details regarding the future acreage projections for permitted landscape irrigation for each county are available in Appendix A. Power Generation Self-Supply The need for additional power supplies is expected to grow as the population in the LWC Planning Area and other portions of south Florida grow (see Table 2). FPL,which provided input for this plan update, utilizes an assessment method incorporating environmental, economical, and technical feasibility when selecting power generation and cooling technologies most appropriate for site-specific conditions, including water supply and wastewater disposal. The different technologies may require and utilize traditional (fresh) and alternative water sources. More power generation facilities are expected to be added to the south Florida system, which may potentially expand its Fort Myers Plant Facilities or begin new generation projects. If an expansion occurs at the Fort Myers Plant, PWR Self-Supply water demands are projected to increase from 0.5 MGD in 2010 to 42.1 MGD by 2030 (Figures 5 and 6). These projections represent the fresh and brackish water needed to support all power generating capacity increases in the LWC Planning Area at this time. DEMAND PROJECTIONS IN PERSPECTIVE The demand projections presented in this plan update are based on the best information available. However,these projections reflect trends, circumstances,and industry intentions that change over time.For example,this plan update expects slower population growth than was anticipated in the 2005-2006 LWC Plan Update (Table 5). However, anticipated growth remains large enough to require infill and redevelopment of existing urban areas,as well as development outside of current urban service boundaries, to accommodate this growth.The location of new development and the extent to which such growth may include historically rural portions of the LWC Planning Area (especially in Charlotte, Glades, and Hendry counties) are important planning considerations. 34 I Chapter 2: Demand Estimates and Projections Table 5. Gross demands projected in the 2005-2006 LWC Plan Update versus this update. Agricultural Self-Supply 729.2 695.9-740.9 Public Water Supply 272.2 232.1 Domestic Self-supply 31.1 24.0 Industrial/Commercial/Institutional Self-Supply 28.9 35.3 Recreational/Landscape Self-Supply 167a 188.5 Power Generation Self-Supply 66.9 42.1 a. Adjusted from 62.2 MGD to 167 MGD to account for landscaping. In addition, there are a number of proposed comprehensive plan amendments that have been approved by the Florida Department of Economic Opportunity for large developments that may not be reflected in current BEBR projections. For example, in Hendry County approved developments such as Rodina, Gardinier, and South LaBelle Village represent significantly greater 2030 population growth than the latest BEBR projections. These additional proposed developments will likely require a significant water supply initiative in this area,which is not included in the demand projections in this update. It should be noted that BEBR updates their projections based on key events and expectations for anticipated growth given changes in economic cycles and migration patterns. As the target dates for building these developments comes closer and the anticipated level of growth changes, future BEBR population projections will capture the latest growth expectations and reflect the expected demand for housing. To account for dynamic growth patterns, water supply plans are updated every five years in order to plan and depict increases and decreases in growth and water supply demands. The SFWMD will continue to work closely with local governments and water supply facilities to monitor growth decisions in these areas and ensure that adequate and sustainable water supplies are identified to support these developments. In summary, the overall projected gross demands for 2030 (Table 5) have decreased slightly (less than 3 percent) compared to the 2025 projections. The LWC Planning Area's total population growth of approximately 510,000 residents from 2010 (992,486) through 2030 (1,502,701) is slightly less than the population growth projection of 674,042 residents from 2000 to 2025 in the 2005-2006 LWC Plan Update. Since we began the development of this plan update,the 2010 United States Census Bureau population numbers were released (U.S. Census Bureau 2010) and the 2010 medium BEBR population projections were released (BEBR 2011). In reviewing the census population numbers, it was found there was less than a one percent lower difference in the census population from the 2010 population in the plan.The 2011 medium BEBR 2030 population projections decreased slightly by three percent from the plan's 2030 population projections. 2012 LWC Water Supply Plan Update 135 In summary, in this plan update, 2010 and 2030 population numbers are still reflective of the best available data. Projected 2030 urban gross water demands (for all water uses except AGR Self-Supply) for this plan update are 522.0 MGD. Urban demand estimate and projection highlights for the LWC Planning Area include some of the following: • The growth in Lee County is projected to increase 58 percent from 607,000 in 2010 to approximately 957,000 in 2030. ■ Growth in the portion of Collier County within LWC Planning Area is projected to increase by 38 percent from approximately 342,000 in 2010 to 472,000 in 2030. ♦ 2030 PWS gross demands are expected to increase by 49 percent from 156.3 MGD in 2010 to 232.1 MGD by 2030. ♦ 2030 REC Self-Supply gross demand are projected to increase from 130.1 MGD in 2010 to 188.5 MGD by 2030. The majority of future landscaped areas will be associated with residential developments. • PWR Self-Supply demands are expected to increase from 0.5 MGD in 2010 to 42.1 MGD by 2030. Analyses, strategies, options, and development projects to meet these water demand estimates and projections are described in the following chapters. For the 20-year planning horizon in this plan update, PWS demands are to be met by the proposed water supply development projects identified in Chapter 6. 36 I Chapter 2: Demand Estimates and Projections 3 Issues and Evaluations This chapter reviews water resource issues that affect the Lower West Coast (LWC) Planning Area and past and ongoing TOPICS water resource evaluations.The issues identified in this chapter potentially affect the use of existing water resources and 41 Approach development of new supplies to meet projected water demands • Summary of Issues for 2030 within the planning area. Evaluations and analyses are Identified for 2030 discussed in the context of water resource issues. A brief • Resource Protection summary of the resource protection tools available under Florida law is also provided. This chapter builds on resource • Evaluation and evaluation efforts described in the 2005-2006 Lower West Coast Analysis Water Supply Plan Update (2005-2006 LWC Plan Update; • Outlook on SFWMD 2006). Additional water resource information can be Climate Change found in the 2011-2012 Water Supply Plan Support Document • Summary (Support Document;SFWMD 2012a). APPROACH In addition to utilizing the work done for the earlier LWC water supply plans and updates, analysis and projects completed since the 2005-2006 LWC Plan Update,current population and demand projections, and local government comprehensive planning documents were reviewed as part of this update. The sources used to identify and evaluate water resource issues include the following: • Input from the planning area stakeholders and the public ♦ Analysis and results from previous LWC Planning Area water supply plan efforts ♦ Water supply facilities work plans and capital improvements elements for the local governments in the planning region • Consumptive use permits and permit applications • Water supply demand projections for 2030 ♦ Data from the Comprehensive Everglades Restoration Plan (CERP) Caloosahatchee River (C-43) West Basin Storage Reservoir Project's preconstruction test cells • Data from the aquifer storage and recovery (ASR) pilot test at the CERP Caloosahatchee River(C-43)West Basin Storage Reservoir Project 2012 LWC Water Supply Plan Update 137 ♦ Analyses performed in conjunction with the 2008 Lake Okeechobee Regulation Schedule (2008 LORS) and the development of adaptive protocols for Lake Okeechobee (see Appendix H) in support of the revised lake schedule. Based on the input, it was concluded that issues identified in the 2005-2006 LWC Plan Update are still valid.A review of the projected water demands in this update are similar to those previously analyzed, and the findings of the previous plans are representative of current and 2030 scenarios. Therefore, new modeling was deemed unnecessary for this current update. SUMMARY OF ISSUES IDENTIFIED FOR 2030 Primary freshwater sources in the LWC Planning Area may not be sufficient to meet 2030 projected water use demands. Past analysis (SFWMD 2000b) indicated that fresh water in the surficial aquifer system (SAS) and intermediate aquifer system (IAS),and surface water in the Caloosahatchee River (C-43 Canal) Watershed are not adequate to meet the growing needs of the LWC Planning Area during 1-in-10 year drought conditions. The water supply issues continuing to influence water supply planning efforts to meet 2030 projected water needs in LWC Planning Area are as follows: ♦ Increased withdrawals from the SAS and the freshwater portion of the IAS are generally limited due to potential impacts on wetlands and existing legal water users including Domestic Self-Supply (DSS), the potential for saltwater intrusion, and the possibility of reaching the maximum developable limits (MDLs) of aquifers. New or increased allocations will be evaluated on an application-by-application basis to determine if the project meets consumptive use permitting criteria. • In some areas DSS cumulative withdrawals are having an effect on aquifer water levels. ♦ Surface water allocations from Lake Okeechobee and hydraulically connected surface waters are limited by the Lake Okeechobee Service Area Restricted Allocation Area criteria. • The results of the 2008 LORS process indicated that the level of certainty is projected to decline from the consumptive use permitting standard of experiencing water shortage restrictions every 1-in-10 years to experiencing restrictions every 1-in-6 years while the lake is operated under the 2008 LORS. ♦ Peak freshwater discharges during the wet season are affecting the health of the Caloosahatchee Estuary and additional storage is required in both the basin and the regional system to attenuate damaging peak flow events. ♦ Surface water availability and current storage capacity is insufficient for the Caloosahatchee River and Estuary during dry conditions. Previous LWC water supply plans identified a variety of alternative water supply development projects to avoid water resource impacts and competition between water users as well as provide a sustainable supply of water. Projects include 38 I Chapter 3: Issues and Evaluation increased water conservation, reuse of reclaimed water,storage of water using ASR wells, and development and use of brackish water sources. The implementation of these projects is well under way. While the development of fresh groundwater in many areas of the LWC Planning Area has been maximized, fresh groundwater may be available in some places. It is not the intent of this update to require water users, including Rural Areas of Critical Economic Concern, to use alternative water supplies when fresh water is available. As urban growth occurs, it is anticipated that some agricultural land will transition to urban community uses. These existing agricultural areas likely have consumptive use permits for use of traditional groundwater for crop irrigation. While consumptive use permits cannot be directly transferred from one land use type to another, the conversion of these lands from agriculture to another land use may result in available fresh groundwater for the new land use. It is important to note that there are different considerations for different water use categories,based on specific needs.These considerations are discussed in more detail in the Resource Protection section later in this chapter. Since the 2005-2006 LWC Plan Update was published, changes have occurred that affect the Caloosahatchee River and Estuary. These include operational, regulatory, and planning changes such as the following: e The Lake Okeechobee Regulation Schedule was changed in 2008 to, in general, lower lake levels to address concerns regarding integrity of the Herbert Hoover Dike stability and the ecological impacts of high lake levels on the lake's ecosystem. The new Lake Okeechobee Regulation Schedule, 2008 LORS, has a variety of consequences that were analyzed by the United States Army Corps of Engineers (USACE) and described in the Final Supplemental Environmental Impact Statement Including Appendices A through G - Lake Okeechobee Regulation Schedule (USACE 2007). The environmental impact statement provides the following: • The USACE addressed the interim nature of 2008 LORS and provided the schedule formulated to address specific conditions existing in 2007. As circumstances change, the USACE will adapt its Lake Okeechobee operations accordingly.The USACE expects to operate under 2008 LORS until the earlier of either 1) the implementation of a new Lake Okeechobee schedule as a component of the systemwide operating plan to accommodate the CERP Band 1 projects or 2) the completion of the seepage berm construction or equivalent(USACE 2007).Herbert Hoover Dike repairs for reaches 1, 2 and 3.The occurrences of these events are expected to allow for greater operational flexibility,potentially including higher lake levels for increased water storage. In balancing the multiple project purposes,the USACE,will timely shift from the interim LORS to a new schedule with the intent to complete any necessary schedule modifications or deviations concurrent with completion of (1) or (2) (USACE 2007). • The environmental impact statement analyses indicated that LORS is projected to adversely impact water supply at low lake levels with the 2012 LWC Water Supply Plan Update 139 current South Florida Water Management District (SFWMD) water supply triggers (USACE 2007). • Analyses associated with 2008 LORS assessed impacts on water supply performance and projected a decline in the physical level of certainty of users reliant on lake water supplies. This level of certainty is projected to decline from experiencing water shortage restrictions only every 1-in-10 years to experiencing restrictions every 1-in-6 years while the lake is being operated under the 2008 LORS. • Repairs to the Herbert Hoover Dike are under way and are estimated to be completed by 2022 (S.Kaynor,USACE,personal communication). O Adaptive protocols for Lake Okeechobee were updated in 2010,with a key goal to improve water supply, flood protection, and ecosystem benefits within the constraints of the 2008 LORS and the Central and Southern Florida Project Water Control Plan for Lake Okeechobee and Everglades Agricultural Area (USACE 2008).For further discussion of these changes,see Appendix H. As a result of the impacts to water supply, SFWMD enacted rules to limit future additional withdrawals from the Lake Okeechobee Waterbody in order to prevent further degradation of the level of certainty for existing legal users and to address the lake's Minimum Flow and Level (MFL) criteria and Everglades restoration. For further discussion of the effects of 2008 LORS, see Appendix H and the 2012 Lower East Coast Water Supply Plan Update (SFWMD 2012b) for more information. Surface Water Availability is Limited Traditionally, surface water has been the primary source of water supply for the agricultural industry in the Caloosahatchee River (C-43 Canal) Watershed. As described above, surface water availability from the existing canal and storage networks alone is insufficient to meet agricultural water use demands and environmental needs during 1-in-10 year drought conditions (SFWMD 2000a). Past analyses concluded that additional storage was necessary to provide adequate resources to meet existing legal user and natural system needs in the LWC Planning Area (SFWMD 2000b). The lack of storage within the Caloosahatchee River (C-43 Canal)Watershed contributes to the following: • The discharge of large volumes of water to tide, which adversely impacts estuarine ecosystems due to sudden declines in salinity during major storm events ♦ The discharge of water to tide during the wet season so it is no longer available to the ecosystem during the dry season or for use by consumptive users • The lack of sufficient dry season flows, which causes elevated salinity within the estuary Reduced dry season base flows to the estuary adversely affect habitats and organisms dependent on brackish or freshwater areas during their life cycle. High volume surface 40 I Chapter 3: Issues and Evaluation water discharges to the Caloosahatchee River and Estuary from local basin runoff,which are sometimes coupled with Lake Okeechobee releases,produce rapid salinity fluctuations.The resultant changes in estuarine aquatic communities are indicated by a reduction in oysters and marine seagrasses at high flows, and mortality of tape grass in the upper estuary at low flows. Construction of the CERP Caloosahatchee River(C-43)West Basin Storage Reservoir Project includes development of surface water storage for the watershed.The main objective of this project is to enhance dry season flows to the Caloosahatchee Estuary.Additional reservoirs or water storage solutions are needed to increase water storage capacity. Currently, water supplies from the Caloosahatchee River (C-43 Canal) are dependent on Lake Okeechobee for supplemental water during the dry season. Fresh Groundwater Availability Is Limited Surficial Aquifer System Throughout the LWC Planning Area,the SAS historically served as the major source of fresh groundwater for Public Water Supply (PWS), Recreational/Landscape (REC) Self-Supply, and Agricultural (AGR) Self-Supply. However,past and present analyses of the SAS indicate it is a limited water resource in many areas. Previous analyses demonstrated that the SAS did not have the capacity to be the primary source for projected urban water demands beyond 1990 base year demand levels. Although the number of SAS withdrawals has increased since the 1990s, withdrawal quantities remain limited. Increases in withdrawals from the SAS will continue to be constrained by saltwater intrusion, wetland impacts, impacts to existing legal users, and other regulatory considerations. Additional supplies may be developed and permitted from these traditional (historical) sources depending on the quantities required, local resource conditions, changing land use, and the viability of other supply options. In 2010, treatment capacity of water from the SAS accounted for approximately 48 percent of the region's PWS. By 2030, the treatment capacity of SAS water for PWS is projected to decrease to 34 percent, as infrastructure to develop additional alternative water sources, such as brackish groundwater and reclaimed water, increase. Further development of the SAS may be accomplished by relocating production wells further from wetlands and existing legal users to maximize use and minimize negative impacts. Changes in land use/land cover also affect potential development of the SAS. However, new or increased allocations from the SAS will be evaluated on an application-by-application basis to determine if the project meets consumptive use permitting criteria. Additional study is needed to identify potential sources of fresh water for uses such as agriculture. Saltwater intrusion is an ongoing concern resulting from continued use of shallow groundwater sources near the coast and potential sea level rise as well as the upward movements of saline water from the deeper aquifers. Coordination with utilities and other water users assists with comprehensive data collection and monitoring. 2012 LWC Water Supply Plan Update I 41 Intermediate Aquifer System Historically,the Sandstone and Mid-Hawthorn aquifers within the IAS have been important freshwater sources for portions of Lee and Hendry counties. However, these local aquifers are not fresh or productive throughout the LWC Planning Area. Analyses indicate these localized aquifers are limited water sources in portions of the planning area due to the cumulative effects of withdrawals by all water users,which decrease water levels in the IAS and could cause harm to the resource or saltwater intrusion. MDLs have been adopted for the IAS. Proposed allocation increases from the IAS in Lee and Hendry counties will continue to be evaluated on an application-by-application basis to determine if the project meets consumptive use criteria'. Additional data is needed to help identify areas where water is potentially available. RESOURCE PROTECTION A goal of Chapter 373, Florida Statues (F.S.),is to ensure the sustainability of Florida's water resources.Various water resource protection standards have been developed to accomplish this goal. The levels of harm — harm, significant harm, and serious harm — are relative resource protection terms,each playing a role in the ultimate goal of achieving a sustainable water resource. For instance, programs regulating surface water management and consumptive use permitting must prevent harm to the water resource. The conceptual relationship among the various harm standards and associated conditions and water shortage severity is shown in Figure 7. Water Resource Protection Standards Observed Impacts Water Permittable Water NO HARM , Normal Permitted Operations levels/flow I Reservation of Water I (1-in-10 level of certainty) Environmental Restoration decreasing Phase I Water Shortage Temporary loss of water Phase II Water Shortage HARM resource functions taking 1 to 2 years to recover MINIMUM FLOWS&LEVELS Drought Water resource functions severity increasing Phase III Water Shortage SIGNIFICANT HARM require multiple years to recover Phase IV Water Shortage SERIOUS HARM Permanent or irreversible loss of water resource functions Figure 7. Conceptual relationship among the harm,significant harm, and serious harm water resource protection standards. 42 I Chapter 3: Issues and Evaluation To ensure the sustainability of Florida's water resources, Chapter 373, F.S., provides the water management districts with several tools to protect water resources: ♦ The Consumptive Use Permitting Program protects the water resources from harm by ensuring water use is reasonable-beneficial, does not interfere with existing legal users, and is consistent with the public interest (Sections 373.219 and 373.223, F.S.). Harm is the temporary loss of water resource functions that results from a change in surface or groundwater hydrology, and takes a period of one to two years of average rainfall conditions to recover (Rule 40E-8.021(9), Florida Administrative Code [F.A.C.]). ♦ MFL criteria define the point at which additional withdrawals will result in significant harm to the water resources or ecology of an area (Sections 373.042 and 373.0421, F.S.). Significant harm is the temporary loss of water resource functions that results from a change in surface water or groundwater hydrology that takes more than two years to recover, but which is considered less severe than serious harm (Rule 40E-8.021(31),F.A.C.). • Water Reservations set aside water for the protection of fish and wildlife or public health and safety so that water cannot be allocated for consumptive use permitting(Subsection 373.223(4),F.S.). * Water shortage restrictions are used to limit water use when sufficient water is temporarily unavailable to meet user needs or when conditions require temporary reduction in use to prevent serious harm to water resources (Sections 373.175 and 373.246,F.S.).Serious harm is the long-term loss of water resource functions resulting from a change in surface water or groundwater hydrology(Rule 40E-8.021(30),F.A.C.). Table 6 summarizes the statutory resource protection tools and definitions. Table 7 summarizes definitions of other resource protection terms. Consumptive Use Permitting Consumptive use permitting protects the water resources from harm by ensuring water use is reasonable-beneficial, does not interfere with existing legal users, and is consistent with the public interest.The 2000 Lower West Coast Water Supply Plan (2000 LWC Plan; SFWMD 2000b) recommended incorporation of resource protection criteria, level of certainty, special designations, and permit durations into the consumptive use permitting criteria. A series of rulemaking efforts was completed in September 2003, resulting in amendments to Chapters 40E-1, 40E-2, 40E-5, 40E-8, 40E-20, and 40E-21, F.A.C. and the Basis of Review for Water Use Permit Applications within the South Florida Water Management District referred to as the Basis of Review (SFWMD 2010a). Among the most significant changes were the amendments to permit duration, permit renewal, wetland protection, supplemental irrigation requirements, saltwater intrusion, ASR, and model evaluation criteria. The renewal process for irrigation class consumptive use permits in the LWC Planning Area began in 2004 and was mostly complete in 2006.Many of the permits for PWS utilities were 2012 LWC Water Supply Plan Update 143 renewed with 20-year durations. The processing of permit renewals, modifications, and new applications has assisted in the evaluation of conditions for this plan update. Table 6. Summary of statutory resource protection tools. p ^xSr G6 Ir iNU 11 �ri1ll1 1tlilh�Ili�iII�Ih�V C�I I�Il�iI ill +lf 11 ^�'r ii llllllljl h�l�l Inp 11 lq illy i....,..,,tta�f ��V M,�I��N .vx '�v�. aw...r� ..�. ,.»n��r,.,- 9,. �.G..raw,� v� �..�uw�+c�b,.a,&axidh��..s rl d The right to use water is authorized by permit. The conditions of permit issuance are more specifically enumerated in Chapters 40E-2 and 40E-20, F.A.C. In order to provide reasonable assurances that the conditions of permit issuance are met, applicants must meet consumptive use permitting criteria. The technical criteria used to evaluate the purpose, quantity, and source of proposed water to be used include the following: • Saltwater intrusion Consumptive Wetland and other surface water body impacts Use Permitting • Pollution • Impacts to off-site land uses • Interference with existing legal users • MFLs • Regulatory components of MFL prevention and recovery strategies, including aquifer MDLs. MFLs are the flows or levels at which the specific water body would experience significant harm if further withdrawals are authorized. If water flows or levels are below the MFL, or projected to fall below the MFL within the next 20 years, the SFWMD must expeditiously Minimum implement a recovery or prevention strategy (Subsection 373.0421(2), F.S.). These Flows and strategies may include the construction of new or improved water storage facilities, Levels development of additional water supplies, implementation of water conservation, etc. The strategy is to be developed in concert with the water supply planning process and coincide with the 20-year planning horizon for the area. A Water Reservation sets aside water for the protection of fish and wildlife or public health and safety. When a volume of water is reserved, it is not available for allocation to Water consumptive uses. Water reservations can be developed based on existing water Reservations availability and/or consideration of future water supplies made available by water resource projects. Water provided by CERP projects under the Water Resources Development Act of 2000 require the SFWMD to reserve or allocate the water for the natural system identified for each CERP project. Water shortages are declared by the SFWMD's Governing Board when available groundwater or surface water is not sufficient to meet users' needs or when conditions require temporary reduction in total use within the area to protect water resources from serious harm. The SFWMD's Water Shortage Plans are contained in Chapters 40E-21 and Water 40E-22, F.A.C.The purposes of the plans are to protect the water resources of the SFWMD Shortage from serious harm; assure equitable distribution of available water resources among all water users during times of shortage, consistent with the goals of minimizing adverse economic, social, and health related impacts; provide advance knowledge of the means by which water apportionments and reductions will be made during times of shortage; and promote greater security for consumptive use permittees. 44 I Chapter 3: Issues and Evaluation Table 7. Other resource protection terms. lIorl VV+ >c .�u..V ww ���d r�."�pw IdV,C 4e'1 y�, v �.y, 7, •7° I11,. 11,4 :1 - „V,Il.hll fit .V.".. Section 373.709, F.S., requires regional water supply plans to identify the water supply needs of existing and future reasonable-beneficial uses based upon meeting those needs for a 1-in-10 year drought event.A 1-in-10 year dought is a below average rainfall year of such intensity it is expected to have a return frequency of once in 10 years. It results in an increase in water demand to a magnitude that would have a 10 percent probability of being exceeded during any given year. Level of The SFWMD has incorporated this level of certainty into its consumptive use permitting Certainty program. When determining whether the permit applicant has provided reasonable assurances the conditions for permit issuance are met, the SFWMD will consider the projected impact of the proposed withdrawal, along with impacts from any existing legal uses and other pending applications under conditions up to and including a 1-in-10 year drought event.The level of certainty is a concept providing a probability of certainty that, given a specific drought event, demands for reasonable-beneficial uses of water will be fully met and that the water resource will be protected from harm. Restricted Allocation Areas are those areas designated within the SFWMD for which allocation restrictions are applied with regard to the use of specific sources of water.The water resources in these areas are managed in response to specific sources of water in Restricted the area for which there is a lack of water availability to meet the projected needs of the Allocation region from that specific source of water. The criteria governing Restricted Allocation Areas Areas are contained in Section 3.2.1 of the Basis of Review. Restricted Allocation Area criteria have been developed as the regulatory components of the MFL recovery strategies for the Lake Okeechobee Waterbody, the Everglades, and the Northwest Fork of the Loxahatchee River. Minimum Flows and Levels MFLs define the point at which additional withdrawals will result in significant harm to the water resources or ecology of the area. These criteria are applied individually to affected water bodies and define flow,duration of flow,or water stage.When setting a MFL,changes and structural alterations to watersheds, surface waters, and aquifers and the effects such changes or alterations have had, and the constraints such changes or alterations have placed on the hydrology of an affected watershed, surface water, or aquifer shall be considered (Subsection 373.0421(1),F.S.). For further discussion on hydrologic alterations that have occurred in the LWC Planning Area,see Appendix G. Within the LWC Planning Area, MFL criteria were established in 2001 for the Caloosahatchee River (Rule 40E-8.221(2), F.A.C.), and the Lower Tamiami, Sandstone, and Mid-Hawthorn aquifers (Rule 40E-8.331,F.A.C.)that occur within Charlotte,Hendry,Glades, Lee,and Collier counties.For more information,see Appendix G. When a MFL is established, it must be evaluated to determine if the existing flow or level criteria is currently being exceeded or will be exceeded within the next 20 years. If the existing water flow or level is below the MFL, or projected to fall below the MFL within the 2012 LWC Water Supply Plan Update 145 next 20 years, the SFWMD must develop and expeditiously implement a recovery or prevention strategy,which includes the development of additional water supplies and other actions to achieve recovery of or prevent the existing flow or level from falling below the established MFL (Subsection 373.0421(2), F.S.). A recovery strategy is needed when the water body currently exceeds the MFL. The goal of a recovery strategy is to achieve the established MFL as soon as practicable.The recovery strategy must include the provision of sufficient water supplies for reasonable-beneficial uses, and may include the development of additional supplies, construction of new or improved storage facilities, and implementation of conservation or other efficiency measures. A prevention strategy is necessary when the MFL is not currently violated, but is projected to be exceeded within the next 20 years. The goal of a prevention strategy is for the water body to continue to meet the established MFL in the future. Both recovery and prevention strategies must include phasing or a timetable that allows for the provision of sufficient water supplies for all existing and projected reasonable-beneficial uses.The strategy should include development of additional water supplies and implementation of water conservation and other efficiency measures consistent with the provisions in Sections 373.0421 and 373.709, F.S. Caloosahatchee River MFL In 2001, the SFWMD established an MFL for the Caloosahatchee River. A minimum mean monthly flow of 300 cubic feet per second (cfs) (equivalent to 194 million gallons of water a day [MGD]) at the S-79 structure was determined necessary to maintain sufficient salinities to prevent a MFL exceedance. A minimum flow of 300 cfs would create salinity conditions that support a sustainable population of submersed aquatic vegetation beds in the upper estuary. A MFL exceedance occurs during a 365-day period when a) a 30-day average salinity concentration exceeds 10 practical salinity units (psu) at the Fort Myers salinity station, or b) a single, daily average salinity exceeds a concentration of 20 psu at the Fort Myers salinity station. Exceedance of either "a" or "b" for two consecutive years is a violation of the MFL. Analyses completed for the 2000 Lower East Coast Water Supply Plan (SFWMD 2000a) demonstrated that long-term regional storage was necessary to achieve proposed MFL criteria, and that MFL violations would continue until implementation of the recovery strategy.As a result,the SFWMD projected that a recovery strategy based on construction of regional storage would be necessary to achieve the MFL. The structural features of the recovery plan are described in Appendix G. Lower West Coast Aquifers MFL In 2001, the SFWMD's Governing Board adopted a MFL rule specifying that the minimum water levels for the Lower Tamiami, Sandstone,and Mid-Hawthorn aquifers must equal the structural top of the aquifer (SFWMD 2000b).A violation of the criteria occurs when water 46 I Chapter 3: Issues and Evaluation levels drop below the top of the uppermost geologic strata comprising the aquifer at any point in time. Water level measurements used to determine the conditions of the aquifers for the purpose of this rule will be located no closer than 50 feet from any existing pumping well (Rule 40E-8.331,F.A.C.). In order to prevent these aquifers from falling below the minimum water level,the SFWMD adopted MDLs. The MDL (contained in the Basis of Review) prohibits consumptive uses from lowering the potentiometric head within the Lower Tamiami, Sandstone, and Mid- Hawthorn aquifers to less than 20 feet above the top of the uppermost geologic strata that comprises the aquifer at any point during a 1-in-10 year drought condition (SFWMD 2010a).This prevention strategy is described in greater detail in Appendix G. Water Reservations A Water Reservation sets aside water for the protection of fish and wildlife or public health and safety. When a volume of water is reserved, it is not available for allocation to consumptive uses. Water Reservations can be developed based on existing water availability and/or consideration of future water supplies made available by water resource projects. The SFWMD is required to reserve or allocate water for natural systems provided by CERP projects under the Water Resources Development Act of 2000 and Section 373. 470, F.S. Picayune Strand and Fakahatchee Estuary SFWMD adopted a Water Reservation for the Picayune Strand and Fakahatchee Estuary in February 2009 in support of the CERP Picayune Strand Restoration Project. This reservation sets aside water for the protection of fish and wildlife (Rule 40E-10.041, F.A.C.) and affects the availability of surface water and groundwater in the Picayune Strand area. Consumptive use permit applicants must provide reasonable assurances that their proposed use of water will not withdraw water reserved for the natural system. The regulatory criteria to provide such reasonable assurances are described in Section 3.11.1 of the Basis of Review. CERP Caloosahatchee River(C-43) West Basin Storage Reservoir Project The SFWMD initiated rule development for a Water Reservation in December 2009 to fulfill its project assurance commitments for the CERP Caloosahatchee River (C-43) West Basin Storage Reservoir Project.The Water Reservation rule will require consumptive use permit applicants to provide reasonable assurances that their proposed use of water will not withdraw water reserved for the natural system.The SFWMD's objective in establishing this Water Reservation is to ensure that all water contained in the C-43 Reservoir is protected for the natural system. Additional information regarding this Water Reservation can be found in Appendix G. 2012 LWC Water Supply Plan Update 147 EVALUATION AND ANALYSIS This section of the chapter provides an overview and summary of previous analyses. The findings and conclusions of the 1994 Lower West Coast Water Supply Plan (1994 LWC Plan; SFWMD 1994), 2000 LWC Plan,and 2005-2006 LWC Plan Update are still representative of the LWC Planning Area. Previously identified water resource and water supply issues remain considerations in this current update.Previous modeling analyses used assumptions and general hydrogeologic conceptualization that are consistent with current understanding of the groundwater systems. The projected 2030 gross water demands for all categories of water use in this plan update are three percent less than the projected demands in the 2005-2006 LWC Plan Update for 2025 (see Chapter 2). Because the previously identified issues are still valid,and projected water demands are similar to those previously analyzed, new modeling scenarios were not deemed necessary for the current update. For further information, refer to the 1994 and 2000 LWC plans and 2005-2006 LWC Plan Update. Previous Analyses Previous water supply planning efforts analyzed the ability of traditional freshwater sources to meet future water demands. Evaluation tools used in these analyses included surface water budgets, groundwater models, integrated surface water and groundwater models, and saltwater intrusion vulnerability mapping. Additionally, the South Florida Water Management District (SFWMD) examined projected demands, land use, and basin renewals of consumptive use permits, performed field inspections, and revised consumptive use permitting rules (SFWMD 2010a). Three subregional groundwater models simulated the potential impacts of water use: 1) Collier County Ground Water Flow Model, 2) Hendry County Ground Water Flow Model and 3) Lee County Ground Water Flow Model. Results from these models were used in vulnerability mapping to identify areas where potential for future saltwater intrusion in the SAS and IAS may occur. A detailed review of these modeling efforts conducted by the SFWMD for the LWC Planning Area can be found in the 1994 and 2000 LWC plans. Simulations of SAS and IAS withdrawals and associated drawdowns examined estimates of future water use under 1-in-10 year drought conditions. Performance targets were developed to simulate resource protection criteria and were applied to predict areas with potential wetland harm and possible saltwater intrusion. Based on extensive field research, updated resource protection criteria were ultimately developed and adopted as regulatory strategies (see the Resource Protection section of this chapter). Other models developed for the LWC Planning Area, or portions of the planning area, evaluated environmental, water quality, and water quantity concerns. These models were not developed specifically for water supply analysis but provided additional understanding of surface hydrology and hydrogeology. 48 I Chapter 3: Issues and Evaluation These modeling efforts include the following: ♦ Regional Integrated Surface Water-Groundwater Model -the Southwest Florida Feasibility Study Integrated Hydrology Model (SDI Environmental Services, Inc.et al.2008) ♦ Subregional Integrated Surface Water-Groundwater Model - Caloosahatchee River Basin(C-43) Model (DHI, Inc.and Stanley Consultants,Inc.2005) ♦ Subregional Integrated Surface Water-Groundwater Model - Big Cypress Basin Subregional Model (CDM 2006a) ♦ Subregional Integrated Surface Water-Groundwater Model - Tidal Caloosahatchee River Basin Model (CDM 2006b) ♦ Subregional Integrated Surface Water-Groundwater Model - Estero Basin Subregional Model (CDM 2006c) ♦ SEAWAT Density-dependent Solute Transport Model - Big Cypress Basin Saltwater Intrusion Pilot Model (Schlumberger Water Services 2010). In addition to demonstrating potential harm to water resources under certain planning conditions, previous LWC modeling results indicated that historically used water sources (fresh groundwater from the SAS and IAS,and surface water from the Caloosahatchee River [C-43 Canal]) were not adequate to meet the LWC Planning Area's growing water needs through 2020. Most agricultural water users in the Hendry and Glades counties portions of this area use surface water for irrigation and analyses also indicated that surface water supplies were inadequate to meet existing and future agricultural irrigation demands. Updates related to this conclusion are discussed in the next section of this chapter. Previous Plan Recommendations The 1994 and 2000 LWC plans recommended new sources of water be identified and used to reduce the potential for harm to water resources where appropriate. The 2005-2006 LWC Plan Update continued emphasizing increased development of alternative water supplies to meet future needs including use of the Floridan aquifer system (FAS) and reclaimed water, increased water conservation efforts, and use of innovative water treatment technologies to assist in meeting future water needs. Existing Conditions and Implementation of Previous Recommendations This section discusses recent water resource trends and summarizes progress made in implementing prior recommendations. For purposes of water supply planning, the focus of this section is water resources in relation to the user demand categories presented in Chapter 2. Discussions concerning environmental restoration projects follow in later sections of this chapter. Existing conditions of fresh groundwater sources reflect multiple physical changes in land use/land cover, stormwater management, water use, and climatic variations. Agricultural and residential development within the region changed surface drainage patterns and 2012 LWC Water Supply Plan Update 149 increased water demands affecting groundwater resources.While hydrologic conditions at some locations have improved with the implementation of 2005-2006 LWC Plan Update recommendations, in other areas, natural changes (e.g., drought) and southwest Florida activities have intensified stress in locations with existing long-term declining water levels. Surficial and Intermediate Aquifer Systems Water Levels The hydrologic data used in this analysis was from the past five years and it has shown great variation in rainfall as well as changing water use volumes and increases and decreases in water levels in the SAS and IAS.The SAS depends on local rainfall for recharge. The wetland systems that are part of this aquifer system are dependent on rainfall and support from groundwater levels in the SAS. During dry or drought conditions, recharge diminishes, drainage persists, and irrigation demands and other demands increase, compounding stress on the aquifer and wetland systems. Typically, the IAS receives little direct recharge from rainfall but is recharged by seepage from above or laterally from outside the boundaries of the planning area.Increased demand from the IAS source is therefore dependent upon available seepage from overlying strata and is limited. Water demands from 2006 to 2008 increased due to population growth and an increase in recreational landscape irrigation acreage. Drought conditions started in 2007 and continued through much of 2008 and 2009.The resulting water demands placed additional stress on both the SAS and IAS and record low water levels were set in 2007 at many IAS monitoring wells.Water demand declined in late 2008 and 2009, and again in 2011 due to water shortage restrictions imposed across the region. Chapter 4 of this document and Chapter 9 of the Support Document provide a review of the LWC Planning Area's water sources. Surficial Aquifer System Water Levels The Surficial (water table) and Lower Tamiami aquifers within the SAS are the primary sources for self-supplied potable drinking water and irrigation water as well as a major source for PWS in Collier, Lee, and Hendry counties. As such, the aquifers are critically important to the region. Throughout the LWC Planning Area, no consistent downward or upward trend in water levels is apparent in the SAS. However, individual wells may show upward or downward trends in their periods of record. This demonstrates the importance of local hydrogeologic conditions.Figure 8 shows water levels and trends for two SAS wells in northwestern Collier County that are about ten miles apart. Seasonal variations in levels from wet and dry seasons are typical in rainfall-driven aquifers. The trend lines shown in the graphs were calculated by performing a regression against the daily water level elevations for the last 35 years at each well, which were taken from the United States Geological Survey(USGS) National Water Information System database in 2012. 50 I Chapter 3: Issues and Evaluation Water-level elevations from the past 35 years at C -953(261347081351201) PROVISIONAL DRAT--Subject to Revision. Statistical measure..re based on the last 35 years ofPUBLISHED continuously-recorded data N14 I l I t t I I t t l l > 13 — 0 z - w 122 — I > - 0 . n — F 4 w 10 - . v l' i 9 _ 1 I y z° 1111 ; 8 , ft, 7 .t 1.13 i w .. > 6 w .a 111 i I 1 1111 - Ix 5 — Q : Plot of U.S.Geological Survey data prod ed for http://www.sflorida.er.sg.g v/,January 23,111. 3 4 I ltttltl 1979 1982 1985 1988 1991 1994 1997 2000 2003 2006 2009 2012 YEAR — Daily maximum water-level elevation v Water levels measured at site visits — Long-term water level trend Water-level elevations from the past 35 years at C -492(262228081361901) PROVISIONAL DRAFT--Subject to Revision. Statistical mecums arc based on the last 35 years of PUBLISHED continuously-recorded data v. - C>7 I S . Z a T v > 17 eN 1 1 16 1 vvv Z v v 015 1 V 1, P. v > 14 V .W.1 - w - I_1 13 — . w I > w - ,-1 12 — 64 QPlot of U.S.Geological Survey data produced for h ttp://www.sflorida.er.usgs.gov/.January 23,2012. 11 1979 1982 1985 1988 1991 1994 1997 2000 2003 2006 2009 2012 YEAR — Daily maximum water-level elevation v Water levels measured at site visits — Long-term water level trend Figure 8. Long-term water level trends in SAS wells C-953 (top panel) and C-492 (bottom panel) in northwestern Collier County (Source: USGS). (Note: NGVD 1929—National Geodetic Vertical Datum) 2012 LWC Water Supply Plan Update 151 To increase surface and groundwater storage,which could diminish the affects of water use and drought, the SFWMD Big Cypress Basin Capital Improvement Program has made structural, operational, and monitoring improvements to the Golden Gate Canal System to retain stormwater within the canal system. Intermediate Aquifer System Water Levels In the LWC Planning Area,the IAS includes the Sandstone and Mid-Hawthorn aquifers (see Chapter 9 of the Support Document). There appears to be a slight overall downward trend in water levels over the last 10 years, with some evidence of a slight rise in water levels over the last three years.Figure 9 shows Sandstone aquifer water levels in southern Lehigh Acres. Since 2005, record low water levels have occurred for the period of record in Well L-729 and other Sandstone aquifer wells in Lehigh Acres (Figure 9). These reduced water levels caused some DSS wells to become inoperable.During the 2007 drought,64 percent of the 526 replacement wells permitted by Lee County were in Lehigh Acres. However, Sandstone aquifer water levels have recovered in wellfield areas where Lee County Utilities has reduced its withdrawals from this aquifer (Figure 9). Overall, DSS and other withdrawals from the Sandstone aquifer have increased in the LWC Planning Area. L-729 25 20 15 1,, 1 i 11 ili 1 III '!! 1 ! I! 11 1 ILA , f 1111 10 —Wel Level —Poter ly_(W lev at: 5 0 I .5 1/1/2002 1/1/2003 1/1/2004 1/1/2005 1/1/2006 1/1/2007 1/1/2008 1/1/2009 1/1/2010 1/1/2011 1/1/2012 Figure 9. Sandstone aquifer water levels at Well L-729 in southern Lehigh Acres. 52 I Chapter 3: Issues and Evaluation In 2010, the SFWMD conducted a preliminary drilling and testing project adjacent to two Sandstone aquifer wells that are used to monitor conditions in Lehigh Acres to more accurately delineate the top of the Sandstone aquifer in that area. These efforts and the results from other drilling in the area demonstrate that the hydrogeology is variable and data from a site cannot be used to establish the elevation of the aquifer at a different location. As the top-of-aquifer elevations are used in determining the Sandstone aquifer's associated MDLs, the study needs to be expanded to account for variability and provide a more comprehensive understanding of the aquifer. In contrast to the general declining trend observed for the IAS,water levels within the Mid- Hawthorn aquifer have risen significantly in southern Cape Coral due to decreasing DSS withdrawals (Figure 10).PWS for this portion of the City of Cape Coral is now derived from the underlying FAS,which is hydraulically isolated from the overlying IAS or SAS.Expansion of the city utility's service area and increased use of the FAS and reclaimed water were identified in the 2005-2006 LWC Plan Update as partial solutions for diminishing IAS water availability in this location. In the northern portion of Cape Coral and in the southern portion of Fort Myers not served by PWS, water levels in the Mid-Hawthorn aquifer have continued to decline (Figure 10). Because continual, increasing use of the Mid-Hawthorn and Sandstone aquifers is not sustainable, alternative water supply development is needed to ensure adequate future supply(see Chapter 4). Jun-80 Jun-85 Jun-90 Jun-95 Jun-00 Jun-05 Jun-10 20 - 10 - •y L-4820 0 • •h► 1 ?f�!y•. 10 r .• ---s lef 4r yiv r=;" '-- /4 -20 30 L-581 -60 -70 -80 -90 Figure 10. Mid-Hawthorn aquifer water levels at Well L-581 in southern Cape Coral and Well L-4820 in northern Cape Coral in Lee County. 2012 LWC Water Supply Plan Update 153 Surficial and Intermediate Aquifer Systems Chloride Levels Elevated salinity content above the amount allowed in drinking water, in the form of total dissolved solids and chloride and sodium concentrations, is present in various SAS and IAS locations. The United States Environmental Protection Agency (USEPA) drinking water standard for chloride is 250 milligrams per liter(mg/L). Saltwater intrusion is the inland movement of the saltwater interface or the sustained upward movement of saline groundwater (upconing). In the LWC Planning Area, the potential for both saline sources to migrate into freshwater sources exists. Another mechanism is upward leakage from wells with open intervals that cross multiple aquifers (short-cased) or leaking casings (Schmerge 2001, Shoemaker and Edwards 2003,Sherwood and Klein 1963,Burns 1983). Lateral encroachment of seawater into the Lower Tamiami aquifer has occurred to varying extents in the region. Saline groundwater beneath the Gulf of Mexico could move through the permeable rock comprising the Lower Tamiami aquifer to come into equilibrium with modern natural and anthropogenic stresses, such as withdrawals, sea level, and drought. Some evidence indirectly suggests the occurrence of lateral encroachment in the Lower Tamiami aquifer near Bonita Springs (Shoemaker and Edwards 2003). Since 2006, monitoring sites and consumptive use permit application submittals have shown that some areas inland of coastal Collier and Lee counties have salinity content above 250 mg/L in the SAS and IAS. Data with sufficient periods of record indicate chloride concentrations have increased over time at some locations, but concentrations have decreased at other locations. Appendix F contains chloride concentration data for the water table and the Lower Tamiami, Sandstone,and Mid-Hawthorn aquifers within the SAS and IAS. The Lee County Natural Resource Division plugged and abandoned 68 Floridan aquifer wells from June 12, 2007 through March 24, 2010 (Lee County 2012) that allowed saline water to migrate into the overlying Mid-Hawthorn and Sandstone aquifers. In 2011,the SFWMD examined April-May 2009 chloride data from a number of USGS wells and from data submitted by consumptive use permittees in compliance with permit limiting conditions. A series of isochlor maps were developed to show the locations of data source wells, proximal wellfields, and lines where wells at any depth in a specific aquifer showed chlorides greater than 250 mg/L. These maps are provided in Appendix F. Maps such as these are very useful in maintaining a watchful eye for changes in water quality including possible migration of the saltwater interface. Increasing chloride trends can be seen in two Lower Tamiami aquifer wells (Figure 11). Chlorides in Well C-525 (top panel of Figure 11) have increased significantly over the 250 mg/L drinking water standard since 1998. In other wells, such as C-489 (bottom panel of Figure 11), chlorides have increased more gradually and are well below the drinking water standard. 54 I Chapter 3: Issues and Evaluation Chlorides from USGS Monitor Well C-525 1200 1100 1000 900 800 700 w 600 NI o` r 500 U 400 300 250r118/1.plinking Water Standard 200 100 Chlorides from U5G5 Monitor Well C-489 1200 1100 1000 900 800 m 700 E d 600 0 500 U 400 300 2S&1me/t Drinking Water Standard 200 100 �`�`' a'`� o'`�' �`�' o�x� cP&' fag cP �4a5 0 F cP ci> ci> ci> ci> Figure 11. Chloride levels from USGS monitor wells C-525 (top panel) and C- 489 (bottom panel)for 1975-2010. 2012 LWC Water Supply Plan Update 155 Saltwater intrusion can be exacerbated by excessive drainage, canal leakage, and water supply withdrawals. The Big Cypress Basin Board, in collaboration with the USGS, is developing a Saltwater Encroachment Monitoring Network Improvement Plan for Big Cypress Basin,which was part of its 2010-2015 Strategic Plan (SFWMD 2010b). Floridan Aquifer System Monitoring Network As recommended in the 2000 LWC Plan, the local FAS water level and water quality monitoring network was expanded in the LWC Planning Area. This network includes cooperative agreements with agricultural owners and PWS utilities. The data gathered are used to evaluate current conditions and trends, and provide additional observed data for calibration of an updated numerical model of the FAS for the LWC Planning Area. As a greater understanding of the FAS evolves, modification of the monitoring network may be required. Use Trends Over the last decade,a number of utilities have developed the FAS as a water source to meet a portion of existing and future demands. These efforts were initiated by Marco Island Utilities and Cape Coral Utilities.Additional utilities using the FAS in the LWC Planning Area include the City of Fort Myers Public Utility,Clewiston Utilities, Collier County Water-Sewer District, Bonita Springs Utilities, Greater Pine Island Water Association, Island Water Association, Lee County Utilities, and LaBelle Department of Public Works. Also, approximately 20 percent of the golf courses in this region use the FAS to meet a portion of their demand for landscape and golf course irrigation. Table 8 shows an increasing use of the FAS by LWC utilities. Withdrawals from the FAS by utilities averaged 53.51 MGD in 2009 compared to 21.93 MGD in 1998 — an increase of 31.58 MGD. From 1998 to 2009, use of the SAS decreased from 52.58 to 48.95 MGD. The SFWMD anticipates this trend will continue as most utilities in the LWC Planning Area intend to use the FAS for future water supplies.Appendix D contains more information on PWS use of the FAS. Water Levels Regional potentiometric surface maps of FAS water level data, prepared by the USGS (Johnston and Bush 1988) and Florida Atlantic University and the SFWMD (2008),estimate potentiometric surfaces of the FAS for predevelopment and average 2004 conditions, respectively. These maps, provided in Appendix F, display similar areal distribution of hydraulic gradients and water levels. Some differences between the maps are evident along the coast and in the northern portion of the LWC Planning Area because the average 2004 water levels are lower. The maps also illustrate how most of south Florida has FAS potentiometric levels well above land surface, indicating the wells are under artesian pressure. 56 I Chapter 3: Issues and Evaluation Table 8. PWS water sources and use in MGD for 1998-2009. .. v ,r a� m =a R.., :,sic..— sue...... %^ r s..v....ov I'ImM '. :1 Anuu:5". .1,,,16 un w.-.. .3 dE,x..l Total from FAS 21.93 23.93 20.01 48.64 53.51 Percent of total withdrawals 23% 24% 19% 37% 41% K .... .., -a.r d-.vvK1 i 1 . "17 r ur i 1n . _ .t x.2.' 64'4- x s Y Total from IAS 13.66 14.68 15.18 23.13 20.41 Percent of total withdrawals 14% 15% 15% 18% 16% r geld r111� 1 II .N°,h.� u 11W vW".n °3. ' 4.�-��.�'x 16 a..y.VVVI Vm.�W, ..�..K}u.0 t�;;.7, ���..�1 r.�..�„,,,'1.�.I��wwCP. �..#u �w� ...,,. Total from SAS 52.58 51.70 61.07 50.26 48.95 Percent of total withdrawals 55% 53% 58% 38% 38% r t tv.trto va ,w f 'fM ,R r iilQtiKr `K J` 1%hK � Iuv°�� �,d e»', "& 1H�IA� 2 r1 ,,u d u. I 1 u 1 � a w' � . .w, a 9 � Total from surface water 8.29 7.71 8.51 9.67 6.66 Percent of total withdrawals 8% 8% 8% 7% 5% �� . K I s - .'� �IJ'IiY '144 . S x vA �'.N 1, �y ' _ a w.�,.E L._ aim . Figure 12 presents water level data from an Upper Floridan monitor well at a location and depth typical for agricultural withdrawals in Glades County. The data show seasonal variations in water levels and declines in levels during drought periods where increased irrigation use of the FAS occurs due to lack of rainfall. The period of record (1973-2011) indicates water levels have declined approximately five feet and that a declining trend is apparent over the past 13 years. Figure 13 presents water level data from an Upper Floridan monitor well at a location and depth typical for PWS withdrawals in Lee County.Again,the data show swings of a few feet over the period of record due to seasonal variations and levels declining during droughts because of the need for increased supplemental irrigation. Major PWS wellfields withdrawing water from the FAS produce drawdowns in the potentiometric surface that may reach 60 feet, depending on the wellfield and proximity to production wells. However,these depressed water levels remain hundreds of feet above the top of the aquifer system and are not as important as the changes in hydraulic gradients that may induce the upward movement of higher salinity water into the wells' producing zones. Increases in salinity of groundwater are important because they can increase water treatment costs or negatively affect users that do not require treatment prior to use. 2012 LWC Water Supply Plan Update 157 50 Water Levels for USGS Well GL-267 w> 40 - 35 c 0 2 d al 30 > 4; 25 _. 20 15 `13 1y `41 `1q `3ti `3 `�y `y1 `y, `9ti `93 `pp `31 `y0 A'b �3 Ay �1 cPi �tib tP' 4,4 ti 4' c�° tP� 01 a tt`1 a � tr° 44' � � le Fg � t° to Figure 12. Water levels in an Upper Floridan monitor well at a location and depth typical of agricultural withdrawals in Glades County. 35 Water Levels for USGS Well 1-2435 30 %/411111\k\kl‘AINVO 25 � k i\iyv G 20 W 15 I 10 5 0 13 1y 11 1°j ,► b3 6y 0 by 4 93 41 1 er pdi p) si∎ rf" �1 tt`1 4,2: try 4,0. a. t1`'� ti`�� tek tt`'� 44 tt.". `ev qi `�� 4, `'t Ao Figure 13. Water levels in an Upper Floridan monitor well at a location and depth typical of PWS withdrawals in Lee County. (Note NGVD—National Geodetic Vertical Datum of 1929) 58 I Chapter 3: Issues and Evaluation Chloride Levels The FAS contains brackish water with varying chloride and total dissolved solids concentrations, from just above allowable drinking water standards to concentrations typical of seawater. Generally, salinity in the FAS is lower in the northern portion of the LWC Planning Area than in the southern and coastal areas. In all areas, salinity levels are higher at the bottom of the FAS than levels near the top of the system. The occurrence of more saline water in lower portions of the FAS is a consideration in the development of the upper portion of the FAS for water supply. Overpumping of the upper portions of the FAS can result in upconing of more saline water from the lower portions of the FAS. The treatment of brackish water for potable drinking water and the blending of brackish and fresh water for irrigation purposes become more costly as salinity increases. Based on regional areal extent, thickness, and average yielding capabilities, a large volume of brackish water is available from the FAS. However, local aquifer variability, the pumping rates of production wells, and the proximity of these wells to saltwater sources will influence the long-term sustainability of the FAS for specific locations. The Lower Hawthorn aquifer producing zone, a portion of the Upper Floridan aquifer, is targeted for water supply production in the LWC Planning Area. Tables F-7 and F-8 in Appendix F contain chloride concentration data for the Lower Hawthorn producing zone in the LWC Planning Area. Raw water chloride concentrations and withdrawals from the Cape Coral Southwest brackish water wellfield are depicted in Figure 14 (Schers et al. 2007). This figure reflects trends in average monthly chloride concentrations and wellfield pumping over time in Cape Coral. These trends suggest that proper monitoring, maintenance, and wellfield operation management can moderate the rate of increase in chloride concentrations. Although average chloride concentration increased approximately 50 percent in 20 years, from about 600 to 900 mg/L, it remains well within the treatment capabilities of the Cape Coral treatment facility. Figure 15 illustrates changes in chloride concentrations over time from FAS production wells at the North Lee County wellfield.The use of Production Well 6 was discontinued due to high chloride concentrations.Additional FAS production wells were subsequently added with greater spacing between wells to reduce the potential for upconing of saline water and provide greater operational flexibility and capacity. FAS Demands The projected 2030 gross water demands for all categories of water use in this plan update are approximately three percent less than the 2025 projected demands in the 2005-2006 LWC Plan Update (see Chapter 2). Previous water supply planning analyses of the FAS and consumptive use permitting activities have indicated that the FAS has the potential for supplying sufficient water to meet the regional PWS demands through the 20-year planning horizon. However, the rate of withdrawals is dependent on localized aquifer properties, water quality,and proximity to other FAS production wells. 2012 LWC Water Supply Plan Update 159 u City of Cape Coral-Southwest Wellfield Trend of Chloride-Pumpege In Wells 2000 - m 1000 •--- ----..._-. _ 1600 u 1.703 = 16 1 i° Iwo c 1eu0 u w IL'7 I Tr' 'Y W s lido ri Al M111111. 11000 ' a `o V Boo I ^6 eoc no I qt coo Air 0 sac .. Ave.a6e Monthly Chlordes in hrodLctlon WNIs —Monthly WedrleId P+oduefoa Figure 14. Raw water chloride concentrations and withdrawals from the Cape Coral Southwest brackish water wellfield (Schers et al. 2007). North Lee County RO WTP Production Wells 4500 - 4000 P 3500 3000 E 1 2500 0 2000 1500 1000 — i. .„, ■ /ivhA '_ 0 500 s 0 Lo to to 10 10 n n n n n n n co 0o 0 o 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 o c n > c oa a c a n O -`° a co a o ai a z o LL 2 a g < tr, 0 Z o _ Well PW-1 Well PW-2 --Well PW-3 --Well PW-4 —Well PW-5 -Well PW-6 —Well PW-7 —Well PW-8 Figure 15. Chloride concentrations from production wells (PW) at the North Lee County FAS wellfield. 60 I Chapter 3: Issues and Evaluation Experience gained from the past five years demonstrates the variability and complexity of the FAS system and the need for testing and long-term monitoring to better understand this resource. The depth, location, withdrawal rates, and well spacing of a proposed FAS wellfield needs to be carefully investigated and planned to minimize the potential for salinity increases that compromise the proposed existing treatment technologies. Lower West Coast Floridan Aquifer System Model The Lower West Coast Floridan Aquifer System Model (LWCFAS) has the ability to incorporate density effects while calculating hydraulic head, groundwater flow, and chloride concentration within the modeled system on a monthly basis. This model was developed in 2008 and uses the USGS's SEAWAT-2000 program to numerically represent the hydrogeology of the region, nearshore portions of the Gulf of Mexico and Florida Bay. Model boundaries allow interaction with external flow and solute transport to simulate the effects from internal sources and sinks. This model was reviewed by an independent peer review panel and the recommendations were incorporated into the model. During Fiscal Year (FY) 2010, a revised steady state model was created to represent estimated predevelopment conditions in the FAS.The model was recently updated and recalibrated to transient conditions (Schlumberger Water Services and SFWMD 2011). This revised model will be used for future regional water supply planning efforts to evaluate the use of the FAS and potential impacts of water withdrawals on the resource. Once models are peer reviewed and those comments are addressed, the updated model's documentation is downloadable from our website, and electronic model input files are available upon request. Surface Water Most surface water in the LWC Planning Area is derived from rainfall making the resource seasonally variable and subject to extreme rainfall events or droughts.The Caloosahatchee River (C-43 Canal) is the major surface water source used for agricultural water supply in the portions of Hendry, Glades, and Lee counties in the LWC Planning Area. To a lesser extent, the canal systems in the City of Cape Coral and Big Cypress Basin provide surface water for water supply but these canals were originally designed to convey water for drainage. Surface water availability and level of certainty in the Lake Okeechobee Service Area has been reduced since the Lake Okeechobee regulation schedule was modified as a result of dike integrity in 2008 (see Appendix H and the 2012 Lower East Coast Water Supply Plan Update(SFWMD 2012b) for more information). Reservoirs and changes to local and regional surface water management systems can be used to increase surface water availability. These include the CERP Caloosahatchee River (C-43) West Basin Storage Reservoir Project, Big Cypress Basin surface water control modifications, and local drainage district improvements including Cape Coral and East County Water Control District. 2012 LWC Water Supply Plan Update 161 CERP Caloosahatchee River(C-43)West Basin Storage Reservoir Project The purpose of the CERP Caloosahatchee River(C-43)West Basin Storage Reservoir Project is to improve the quantity, timing, and distribution of freshwater flows to the Caloosahatchee River and Estuary. This planned reservoir project will capture and store surface water runoff from the Caloosahatchee River (C-43 Canal) Basin and Lake Okeechobee to provide a more natural and consistent flow of fresh water to the estuary. After construction and flow-through testing,operation of this project is expected to improve the Caloosahatchee Estuary's salinity balance by reducing a portion of the peak discharges during the wet season and providing essential flows during the dry season. The project includes an above-ground reservoir located south of the Caloosahatchee River (C-43 Canal) and west of the Ortona Lock (S-78) on a 10,700-acre parcel west of LaBelle formerly known as Berry Groves. The reservoir will provide a total storage capacity of approximately 170,000 acre-feet of above-ground storage volume in a two-cell reservoir. The land is cleared and designs for construction are permitted. The project is awaiting congressional authorization and appropriation of funds to start construction. The USACE anticipates project authorization to occur in August 2013 with appropriation of funding to follow at a later date.Once congressional funding has been appropriated,a timetable for the completion of the reservoir will be developed. Caloosahatchee River Watershed Protection Plan The Caloosahatchee River Watershed Protection Plan (SFWMD et al. 2009) identifies the need for additional storage and proposes reservoirs and stormwater treatment areas to address the volume and timing of fresh surface water for the Caloosahatchee Estuary.These efforts were planned to meet the natural system needs.The Caloosahatchee River Watershed Protection Plan is part of the Northern Everglades and Estuaries Program, which is discussed in Appendix G and the Support Document. Big Cypress Basin The Big Cypress Basin canal systems also provide surface water supply, and to a lesser extent, local stormwater ponds for landscape irrigation.The Big Cypress Basin canal system was constructed as a surface water drainage system; however,improvements to structures, operations and management,and monitoring have resulted in an estimated 850 acre-feet of additional surface water storage in canals since 2000. Local Drainage District Improvements The Canal Weirs Improvement Program for the City of Cape Coral added higher control elevations to operable weirs to store more fresh water in the canal system during wet conditions. This provides 1.7 MGD additional supply to the city's reclaimed irrigation system. 62 I Chapter 3: Issues and Evaluation The East County Water Control District Consolidated Plan for Water Management (ECWCD 2008) includes improvement projects to reduce high flows to the Orange River, which currently discharges into the Caloosahatchee Estuary,capture and store stormwater runoff, and raise groundwater levels for wetland restoration,water storage,and aquifer recharge. Reclaimed Water Since 1994, the volume of reclaimed water use has doubled in the region. In 2010, the reclaimed water use rate was 70.4 MGD (Table 9) (FDEP 2010a). Where available, reclaimed water provides many communities with all or a portion of their irrigation demands. Water supply development projects (Chapter 6) under way or proposed by utilities are expected to continue this trend.The LWC Planning Area's increasing production of reclaimed water may require utility reclaimed water interconnects and construction of seasonal storage,such as ASR. Table 9. Reclaimed water use in the LWC Planning Area in MGD for 1994-2010. " u � o,r 0 r - ��ee rr o�P �� p t F4 � EZAV A.if"a j dic.i. w11 � a„Zu g .P 11�r� 4;:$ '.r Annual Average(MGD) 32.30 44.70 50.24 63.19 61.90 71.69 68.93 68.25 70.40 Aquifer Storage and Recovery ASR is the underground storage of storm water,surface water,fresh groundwater,drinking water or reclaimed water,which is treated to appropriate standards (dependent upon the water quality of receiving aquifer). The aquifer (typically the FAS in south Florida) acts as an underground reservoir for the injected water. The water is stored with the intent to recover it for use in the future. To date, over 19 ASR wells have been built by water and wastewater utilities in the LWC Planning Area. Many of these wells store treated drinking water, although some store raw groundwater and raw or partially treated surface water. Approximately half of these ASR wells are fully permitted for operation. The remaining wells are in operational testing or are inactive. Water Conservation Several SFWMD water conservation programs have been initiated since publication of the 2005-2006 LWC Plan Update. These include the approval of the Comprehensive Water Conservation Program and adoption of the Mandatory Year-Round Landscape Irrigation Conservation Measures Rule (Chapter 40E-24, F.A.C.). For more details about the Comprehensive Water Conservation Program, see Chapter 4 of this document, and Chapters 4 and 5 in the Support Document. The Mandatory Year-Round Landscape Irrigation Conservation Measures Rule became effective March 15, 2010.This rule limits landscape irrigation to two days per week with no irrigation allowed between 10 a.m. and 4 p.m. and an allowance for three days a week in 2012 LWC Water Supply Plan Update 163 identified counties. However, three-day-per-week year-round measures have been in place in the LWC Planning Area since 2003. Some municipalities and counties in the LWC Planning Area, such as Lee County and Cape Coral, enacted a two-day-per-week irrigation schedule. The SFWMD has observed reductions in regional utility base year per capita finished water use since 1990 (Table 10).The base year regional utility per capita use rates (PCURs) in the 1994 and 2000 LWC plans and 2005-2006 and current plan updates have decreased from a high in the 1994 LWC Plan of 194 gallons per day(GPD) per person to a low of 151 GPD per person in this plan update.These values are calculated by dividing the utility finished water produced by the estimated permanent population connected in the service area for that year. Since the 2005-2006 LWC Plan Update, several conditions contributed to declining PCURs including the SFWMD's Comprehensive Water Conservation Program, local government conservation programs, water shortage restrictions, and the economic downturn. Table 10. Regional utility PCURs in the LWC Planning Area using overall finished water. 1994 1990 194 2000 1995 167 2005-2006 2000 176 2012 2005 151 OUTLOOK ON CLIMATE CHANGE Climate change, especially sea level rise, has the ability to affect water supply in the LWC Planning Area.While climate change is occurring across the globe, the impact to individual regions varies, and the degree and rate of change remains uncertain. Lonerm data show changes in parameters,such as temperature and sea level.Despite the uncertainties,climate change and its related affect on hydrogeologic conditions must be included as a consideration in water supply planning(see Chapters 1 and 7). As sea level rises, low elevation coastal areas will be increasingly subject to flooding, especially during spring and fall high tides,storms,and strong onshore winds (Murley et al. 2008). The canal networks of the SFWMD in much of the Lower East Coast and LWC planning areas are typically maintained at predetermined water levels to reduce the potential for saltwater intrusion into the PWS wellfields and to provide flood protection. Projected sea level rise may reduce the flood discharge capacity of coastal structures, thus affecting flood protection in urban areas (SFWMD 2009a). In addition to concerns of climate change on water supply and flood protection, rising sea level could cause groundwater near the coast to become more saline and groundwater levels to increase.This has the strong potential to increase the salt content of water leaking 64 I Chapter 3: Issues and Evaluation into sewer collection systems and complicate the operations of wastewater treatment plants (Bloetscher et al.2009). Other changes,such as increased evapotranspiration (ET),and changes in weather patterns, are less predictable.If temperatures and ET increase as many experts expect,both PWS and AGR Self-Supply water demands may increase. More frequent intense rainfall events with longer interim dry periods could increase total annual rainfall, but decrease effective rainfall, as more water may be lost to runoff or tide. Precipitation in Florida varies in many ways. Annual rainfall is affected by decadal-scale variability such as the Atlantic Multidecadal Oscillation and the El Nino-Southern Oscillation (warming phenomenon in the Pacific Ocean). Natural, climate, and human-induced changes to freshwater inflow into estuaries have changed estuarine circulation patterns and salinity regimes (Scavia et al.2002). Affect on LWC Planning Area Southwest Florida is particularly vulnerable to the effects of climate change and sea level rise because the topography of the area is generally flat and naturally poorly drained. The regional economy has major investments within close proximity of the coast or lake water bodies (SWFRPC and CHNEP 2009). In the LWC Planning Area, anticipated sea level rise may increase the intrusion of salt water into groundwater. Miami-Dade and Broward counties have both initiated action plans to help with this determination and recommendations. Additional analysis is needed in the LWC Planning Area to better understand the vulnerability of its aquifers to climate change. Anticipated sea level rise may increase the intrusion of salt water into groundwater. Miami- Dade and Broward counties (located in the Lower East Coast Planning Area) have both initiated action plans to help with this determination and recommendations. Additional analysis is needed in the LWC Planning Area to better understand the vulnerability of the LWC aquifers to climate change. According to the Southwest Florida Regional Planning Council,the LWC Planning Area could see some agricultural production patterns shift. Warmer temperatures and less soil moisture due to increased evaporation may increase the need for irrigation and an increase in climate variability could make farming more difficult. Analyses based on changes in average climate, and that assume farmers effectively adapt, suggest that aggregate United States food production will not be harmed, although there may be regional changes (SWFRPC and CHNEP 2009). In 2010, Lee County developed a climate change resiliency strategy to guide the county plans and strategies relating to specific vulnerabilities and priorities of the county. Previously, the Southwest Florida Regional Planning Council and the Charlotte Harbor National Estuary Program had prepared the Comprehensive Southwest Florida/Charlotte Harbor Climate Change Vulnerability Assessment (2009).. They concluded that this study would be used to work with local government staff to consider sea level increases when planning for public facility expansions and reconstruction after hurricane damage or due to 2012 LWC Water Supply Plan Update 165 old age. The intent of the study was to facilitate the work of local government elected officials and staff as they consider how to best plan for the impacts of sea level rise (SWFRPC and CHNEP 2009) While the Community Planning Act(in Chapter 163, F.S.),passed in 2011,does not require local governments to address climate change and sea level rise issues in their comprehensive plans,it provides an option for a local government to develop an adaptation action area designation in the coastal management element (Section 163.3177). The designation would be for those low lying coastal zones that are experiencing coastal flooding due to extreme high tides and storm surge and are vulnerable to the impacts of rising sea level. SUMMARY The findings and conclusions of the previous LWC plans and updates are still representative of the issues involved in meeting the 2030 projected water demands in the LWC Planning Area. These findings were considered in the development of this plan update. Projected 2030 gross water demands for all categories of water use in this plan update are three percent less than the projected demands in the 2005-2006 LWC Update (see Chapter 2). The following accomplishments have been made towards fulfilling recommendations made in previous plans: • Users of the SAS and IAS have diversified their supply sources and reduced their reliance on these aquifers. Most coastal utilities are using the FAS or other alternative water supply sources to meet some of the current needs and their future needs. Of the total water withdrawn by major PWS utilities, use of brackish water increased from 23 percent in 1998 to 41 percent in 2009. • Reclaimed water use has doubled since 1994 and offsets existing and proposed use of fresh groundwater. Utilities have successfully increased the use of reclaimed water from an annual average of 32.3 MGD in 1994 to 70.4 MGD in 2010. • Water conservation measures have resulted in reduced PWS PCURs over last two decades.The overall PCUR has decreased from 194 GPD per person in 1990 to 151 GPD per person in 2005. • Over 19 ASR wells have been constructed. • IAS water levels at some locations have risen,likely because of reduced usage. • A Water Reservation rule was developed for Picayune Strand and Fakahatchee Estuary. • Plans continue on construction of the CERP Caloosahatchee (C-43) West Basin Storage Reservoir Project and other storage projects. 66 I Chapter 3: Issues and Evaluation The following are ongoing concerns and future activities: • To update the Caloosahatchee River MFL criteria, the SFWMD will evaluate the new information to determine if a revision of the MFL is necessary. • Rule development has been initiated for a Water Reservation to ensure the CERP Caloosahatchee River (C-43) West Basin Storage Reservoir Project provides water needed by the natural system. • IAS water level declines persist in some locations. • Saltwater intrusion into coastal aquifers is an ongoing concern due to a variety of factors,including wellfield withdrawals and potential sea level rise. • Surface water supplies continue to be limited for agriculture. Additional LWC Water Supply-Related Efforts Significant water supply development and restoration efforts are under way throughout the LWC Planning Area including CERP projects.Appendices G,H,and I provide descriptions of the additional water supply-related activities in and around the LWC Planning Area. 2012 LWC Water Supply Plan Update 167 68 I Chapter 3: Issues and Evaluation Evaluation of Water Source Options Historically, the Lower West Coast (LWC) Planning Area has relied on water from aquifers, canals, and the Caloosahatchee TOPICS 47 River(C-43 Canal)to meet the region's water supply needs.This chapter presents an evaluation of water source options and • Water Source Options water conservation measures available within the LWC Planning ♦Water Conservation Area through the 2030 planning horizon. To accommodate future urban and agricultural growth while still meeting the needs of the ecosystem, region-specific evaluations were conducted within the context of the issues identified in Chapter 3. In the LWC Planning Area, freshwater source options include groundwater from the surficial aquifer system (SAS) or intermediate aquifer system (IAS),and surface water from the Caloosahatchee River (C-43 Canal) and connected canals and water bodies. Additional water source options include brackish groundwater from the IAS and Floridan aquifer system (FAS), reclaimed water, new storage capacity for surface water or groundwater using reservoirs and aquifer storage and recovery(ASR),seawater,and water conservation. WATER SOURCE OPTIONS Each water source option presented in this chapter includes a brief discussion about resource sustainability and potential natural systems impacts.Additional information about water source options, including water conservation and related costs, is provided in Chapter 5 of the Support Document.Water treatment technologies and associated costs are presented in Chapter 6 of the Support Document and in the Water Supply Cost Estimation Study (CDM 2007a) and Water Supply Cost Estimation Study - Phase 11 Addendum (CDM 2007b). Groundwater Three major aquifer systems—the SAS,IAS,and FAS—lie beneath southwestern Florida.As Figure 16 illustrates, these systems are composed of multiple, discrete aquifers separated by confining units with low permeability. The hydrogeology of these aquifer systems is 2012 LWC Water Supply Plan Update 169 complex, and continue to be studied due to spatial variability in productivity. More information about these aquifers, including yields and characteristics specific to the LWC Planning Area,is provided in Chapter 9 of the Support Document. N Northwest m c Southeast m u1 N >`O H Hydrogeologic r` d ce Unit Cl) m Z Sea Surficial Aquifer Semi Confining Unit 0 Level - „,; .... ,• yorn Confining Bed Lower Tamiami Aquifer Depth Intermediate Sandstone Aquifer (feet) Aquifer System Mid-Hawthorn Confining Bed Mid-Hawthorn Aquifer `. -500 Lower Hawthorn Confining Bed Upper Lower Hawthorn Producing Zone/Suwanee Producing Zone — 1,000 Floridan Aquifer Confining Unit 1 '— -1,500 Avon Park Permeable Zone Confining Unit 2 -2,000 Lower Floridan Aquifer Lower Floridan Aquifer —-2,500 -3,000 -3,500 Figure 16. Generalized hydrogeologic cross-section of the LWC Planning Area. In the LWC Planning Area, different aquifers are tapped in specific areas to meet user needs from a water quantity and quality perspective. Figure 17 shows the distribution of South Florida Water Management District(SFWMD)-permitted consumptive use production wells. This demonstrates the spatial variability of the aquifers. 70 I Chapter 4: Evaluation of Water Source Options E I-..-- -----i i I i r7 C3 _.-1 — ._. :fit 1 Port Charlotte ® '3t rt-3 I. ..`.—.1 Myakku R Peace R ~J Punta CHARLOTTE It i*1ltx! • NLJ----^�`�t•le Luke I �` Okeechobee Gorda S%%FM'\tD` x Ire:. i GLADES �J� Moore S F% M D : +.s x■�1'�R ten ell Charlotte —•-+, Harbor fir. • `^� •�ltiv.r Lake iL:_. 1 A�._.�.���. _.;� 'ton 4,• tt• • Cafoa !thee� • • + • R 4 • k\ t S c Mmali e . . 1 a 1�— L—J1 Pale ;V c •�I► I + HENDRI` 1 *S d . 4 'J '' ale Lehr ; ii • • • �� i ilk x 4 1 San x . ' 1.E 41 L; ,L.... s tr a• • :' i \ I y x �1 „ J i +� Este Lake••.r1 r y m fr ord a N ; Boundary of the i t\ 1 } -r ..r •• , Lower West Coast i =._i=', a• i rPtanning Region 1 Ar •st f s 1a • 4` .t. - . I • • • w .......�.—.—. i • •• • • L. �...�\�Ipti OM i c . ® t 1 f. T 1 I. t, 1 I a ` c#, COLLIER \ i•t• X • * .......J CI •IP t—a X Marco Port of the \Island#j1R Islands • • • \ • x • .city woes 47 I S.J.R.W.M.o. S.W.F.W.M.D. \ a \ Area shown to on maim f��w ) i Wells with Water-Use Permits MONROE �; Primary Aquifer Source / Lower S.EW.M,D. / i `� � 1 • Sudicial,Water Table ` Guff \CO•O t • Lower Tamiam Aquifer \ // i II Of Mexfro `\,' Sandstone Aquifer i - Mrc4Mawlhorn Aquifer 0 10 20 Wes i x Floridan.Lower Hawthorn ( r I r I I I I I r I L 0 10 20 Kilometers Figure 17. Location of permitted production wells and associated aquifer sources as of 2010 in the LWC Planning Area. 2012 LWC Water Supply Plan Update 171 Fresh Groundwater WATER OPTIONS Fresh groundwater is the primary potable water Freshwater sources include those supply source for public consumption and urban historically used as the region's primary irrigation in the LWC Planning Area. The SAS is sources of water. Water quality and unconfined, consisting of varying amounts of availability determine the viability of limestone and sediments that extend from the freshwater sources, and differ from land surface to the top of an intermediate region to region within the SFWMD. confining unit. The IAS consists of five zones of Where freshwater sources are alternating confining and producing units. The determined to have limited availability, producing zones include the Sandstone and Mid- alternative water sources must be Hawthorn aquifers. identified and developed. In 2009,62 million gallons of water per day(MGD),approximately 50 percent of the potable water produced by utilities with capacity equal to or greater than 0.1 MGD (public water supply [PWS]), and all of the estimated 16 MGD of Domestic Self-Supply (DSS) water originated from fresh groundwater. It is projected that only 8.8 MGD of additional future PWS demand will be met with fresh groundwater.The anticipated increased PWS demands in 2030 will be met primarily using brackish groundwater(70 MGD). Information from the SFWMD's Water Use Regulatory Database shows that fresh groundwater is the primary source for 67 percent of permitted allocations for landscape and golf course irrigation, and 49 percent of agricultural irrigation. Other sources for landscape and golf course irrigation are storm water, brackish water when blended with fresh groundwater,and reclaimed water. Within this area, the SAS and IAS are the sources of fresh groundwater. These aquifer systems are sources of limited availability as defined by the Basis of Review for Water Use Permit Applications within the South Florida Water Management District, referred to simply as the Basis of Review (SFWMD 2010a). The limitations are related to wetland harm and saltwater intrusion concerns. In areas where the Lower Tamiami aquifer of the SAS is absent and the water table aquifer is not productive, the IAS has historically met local water demands. Within the SAS, the local water table and Lower Tamiami aquifers produce good quality fresh water from shallow wells. In many cases, the ambient water quality meets primary and secondary drinking water standards. These aquifers are recharged by local rainfall and provide water storage during dry seasons and support the hydrology of natural systems at the land surface. In western Lee County, the Mid-Hawthorn aquifer within the IAS is the historically used source for DSS and Industrial/Commercial/Institutional (ICI) Self-Supply because it has acceptable water quality. Elsewhere in the LWC Planning Area,the Mid-Hawthorn aquifer is not a historically used source because the groundwater is brackish. The Sandstone aquifer of the IAS is a major source of groundwater for agricultural use in southwestern Hendry and northern Collier counties. The Sandstone aquifer has variations in water quality, and the 72 I Chapter 4: Evaluation of Water Source Options chloride levels range from about 200 milligrams per liter (mg/L) to about 1,000 mg/L.This aquifer is present primarily west of State Road 29 in Hendry County, and available data indicate it pinches out laterally a few miles east of there (Smith 1990). Information on the hydraulic properties of the Sandstone aquifer in rural Hendry and Glades counties is limited.Future use of the Sandstone aquifer in the Lehigh Acres area and the Mid-Hawthorn aquifer in Cape Coral (aquifers within the IAS) will likely be limited due to current cumulative water level drawdowns from existing users and the maximum developable limits (MDLs) defined in Section 3.2.4 of the Basis of Review. However, new or increased allocations will be evaluated on an application-by-application basis to determine if the project meets consumptive use permitting criteria. Increased use of fresh groundwater sources to meet future demand in the LWC Planning Area is highly dependent on location, source limitations, natural system requirements, reclaimed water availability,and water conservation measures. Opportunities may exist for limited development of fresh groundwater sources through the following: ♦ Changes in land use/land cover and water use distributions allowing existing permitted allocations to be redistributed in more efficient ways ♦ Modifications to wellfield locations,configurations,and pumping regimes ♦ Blending multiple alternative water sources to achieve acceptable water quality and distribute potential impacts across these multiple sources ♦ Conversion of fresh groundwater sources to reclaimed water for landscape and golf course irrigation Any significant increase in withdrawals from fresh groundwater sources must be balanced against resource protection criteria, and will be reviewed on an application-by-application basis through the consumptive use permitting process. Brackish Groundwater Brackish water is water that has a chloride level greater than 250 mg/L and less than 19,000 mg/L. The water quality in the FAS decreases significantly from central Florida to south Florida, increasing in hardness, chlorides, and salinity. Salinity also increases with depth, making the deeper producing zones less desirable for development than shallower parts of the system. The upper portion of the FAS is the principal source of brackish groundwater supply in the LWC Planning Area and is not considered a limited resource in the region based on current criteria and the quality of the water. The IAS also produces brackish water in many locations. With limitations on fresh groundwater in the SAS and IAS, most utilities have developed brackish water sources from either the FAS or IAS. 2012 LWC Water Supply Plan Update j 73 Brackish water use from the FAS and the IAS began in the late 1970s, and increased in the 1990s, with more significant use after 2000 (Figure 18). In 2009, 41 percent (53.51 MGD) of PWS was produced from brackish water sources in the LWC Planning Area. Public Water Supply Brackish Water Withdrawals (1990-2009) 70 0 60 2 50 b 40 cts > 30 20 < 10 0 1990 1995 2000 2005 Figure 18. PWS withdrawals from brackish water sources in the LWC Planning Area 1990-2009. LWC utilities are proposing significant increases in brackish water source BRACKISH development over the next 20 years. The GROUNDWATER 4 anticipated increased PWS demands in 2030 will be met primarily using brackish groundwater from the IAS and FAS (see Brackish (saline) groundwater is defined as Chapter 6). water with a total dissolved solids concentration greater than 250 mg/L and less Brackish groundwater is also a source of than 19,000 mg/L. The terms fresh, brackish, water for agricultural and landscape saline, and brine are used to describe the irrigation needs. The FAS is a source for quality of the water. Although brackish Agricultural (AGR) Self-Supply in northern supplies in the low range of these salinities Charlotte County, though supplemental may be used for some agricultural purposes, this raw water does not meet public drinking surface water is often added to reduce water standards. Desalination treatment salinity and improve water quality for the technologies, such as reverse osmosis, intended crop. Some FAS wells are used to electrodialysis, or electrodialysis reversal, provide frost and freeze protection for citrus must be used before this type of water groves but fresh surface water and supply is suitable for human consumption. groundwater are the preferred water supply sources for this use category. 74 I Chapter 4: Evaluation of Water Source Options Use of the brackish FAS as a supplemental source for landscape irrigation has increased in the past 10 years as the availability of additional fresh groundwater has diminished. This water may be blended with groundwater and surface water in stormwater ponds to produce acceptable irrigation quality water. Blended water supplies are dependent on water sources, stored water volume, and natural system requirements, and require monitoring to ensure acceptable water quality. As discussed in Chapters 3 and 5 of this plan update, a FAS monitor well network was established in the planning area to monitor water levels and quality. Conclusions of previous LWC plans with similar projected demands did not anticipate major regional reductions in water levels or deterioration in water quality (SFWMD 1994, 2000b, 2006). Unexpected water quality changes appear to be related to aquifer variability, insufficient well spacing, and possibly overpumping of production zones close to zones with upconing (saline water underlying fresh water in an aquifer rises upward into the freshwater zone as a result of pumping water from the freshwater zone).The amount of water withdrawn from the FAS by existing and proposed users is very small relative to the amount of water contained within the system. However, the response to increased withdrawals is not fully understood and the distribution of water quality within the FAS is not well established. Water level monitoring is critical to assess the potential for movement of highly saline water from the deeper portions of the FAS or inland from the coast. Most of the current water use is located in coastal Collier and Lee counties,with some withdrawals in Charlotte and Glades counties. Consumptive use permits for withdrawals from the FAS have chloride monitoring requirements. Data from uses permitted after the 2005-2006 Lower West Coast Water Supply Plan Update(2005-2006 LWC Plan Update; SFWMD 2006)was published will improve understanding of the distribution of chloride concentrations within the FAS. Much of the FAS monitoring and analysis completed to date in the LWC Planning Area provides critical information for developing more sophisticated analyses using computer modeling. The SFWMD has developed a revised Lower West Coast Floridan Aquifer System (LWCFAS) Model based on a peer review of its original density-dependent solute transport model (see Chapter 5). Calibration of the model has been completed with significant changes. The peer review comments have been incorporated. Finally, the transient model with draft documentation has been completed (Schlumberger Water Services and SFWMD 2011).The revised model is expected to be used as a tool to evaluate potential water quality changes in the IAS and FAS due to the cumulative withdrawals of existing and future water users.This model maybe able to determine long-term availability of this water source. Surface Water Surface water is water above the soil or substrate surface, whether contained in bounds created naturally or artificially or diffused. Water from natural springs is classified as surface water when it exits from the spring onto the earth's surface. 2012 LWC Water Supply Plan Update 175 Primary surface water sources in the LWC Planning Area include the Caloosahatchee River(C-43 Canal) and connected water bodies,such as the Townsend Canal, Roberts Canal, and City Ditch. The Cape - Coral and Big Cypress Basin canal systems also provide surface water supply, and to a lesser extent, local stormwater ponds provide water for landscape irrigation. AGR Self-Supply is the largest water use category in the planning area and the primary consumer of surface water. Use of surface water in stormwater ponds for recreational and landscape irrigation is a common practice. However,in most cases,the surface water is a supplemental supply to a primary groundwater source.AGR Self-Supply water users may also have stormwater impoundments to provide additional water supply or storage for blending with brackish groundwater. Caloosahatchee River As discussed in Chapter 3, in October 2008, (C-43 Canal) Restricted Allocation Area criteria for the Lake Okeechobee Service Area were developed as part of the Minimum Flow and Level (MFL) recovery strategy for Lake Okeechobee.The criteria limits allocations from Lake Okeechobee and connected surface waters, including the Caloosahatchee River (C-43 Canal) and St.Lucie River (C-44 Canal),to base condition water uses that occurred from April 1, 2001 to January 1, 2008. MFL criteria have also been established for the Caloosahatchee River (C-43 Canal). For more information see the 2012 Lower East Coast Water Supply Plan Update(SFWMD 2012b). The SFWMD initiated rule development for a Water Reservation for the C-43 Basin Storage Reservoir Project in December 2009. The purpose of the Water Reservation is to identify and reserve water from consumptive use for the Comprehensive Everglades Restoration Plan (CERP) Caloosahatchee River (C-43) West Basin Storage Reservoir Project to ensure the project provides the intended benefits to the natural system. MFLs, Water Reservations, and Restricted Allocation Areas (see Chapter 3) must be considered when determining surface water availability. The development of additional surface water sources is dependent on development of additional storage capacity.Proposed new storage projects creating additional water supply may be considered alternative water supply sources (see the New Storage Capacity for Surface Water or Groundwater section later in this chapter). For example, the Big Cypress Basin canal system in Collier County was constructed as a surface water drainage system; however, improvements to structures, operations, management, and monitoring since 2000 have resulted in an estimated 850 acre-feet of 76 I Chapter 4: Evaluation of Water Source Options additional surface water storage in canals. The Big Cypress Basin Capital Improvement Program (Fiscal Year [FY] 2005—FY 2014) includes projects for the Golden Gate Canal System, Henderson Creek, and Barron River. These projects and others provide water resource benefits through reduction of overdrainage and restoration of groundwater and surface water levels to more natural conditions. In addition to providing environmental benefits, these improvements serve to enhance water supply opportunities by increasing groundwater storage and improving the timing and duration of surface water discharges.As a result,the canal system now holds more water for longer periods of time,capturing water previously lost to tide.The City of Naples Utility Department is developing a surface water source from the Big Cypress Basin canal system to supplement its reclaimed water supply (see the Future Reuse in the LWC Planning Area section later in this chapter). Cape Coral Utilities also uses a freshwater canal system to augment the City of Cape Coral's reclaimed water supply for residential and commercial landscape irrigation. The Canal Weirs Improvement Program for the City of Cape Coral added higher control elevations to operable weirs to store more fresh water in the canal system during wet conditions, providing 1.7 MGD additional supply to the city's reclaimed irrigation system. Additional improvements are planned to add transfer pumps to move water between basins,and allow three completed ASR wells to store peak flows for irrigation use during dry periods. The City of Marco Island (Marco Island Utilities) uses surface water from Henderson Creek/Marco Lakes, and Lee County Utilities uses some surface water from the Caloosahatchee River (C-43 Canal). For more information about these projects, see the utility summaries provided in Chapter 6. New Storage Capacity for Surface Water or Groundwater Storage is an essential component of any supply system experiencing fluctuation in supply and demand. Capturing excess surface water and groundwater during wet conditions for use during dry conditions increases the availability of water when demand is highest. Two-thirds of south Florida's annual rainfall occurs in the wet season. Without sufficient storage capacity, much of this water discharges to tide through surface water management systems and natural drainage to coastal estuaries. In the LWC Planning Area,potential types of water storage include ASR wells,surface water impoundments,ponds,and reservoirs. Aquifer Storage and Recovery ASR is the underground storage of storm water,surface water, fresh groundwater,drinking water or reclaimed water, which is treated to appropriate standards (dependent upon the water quality of the receiving aquifer).The aquifer (typically the FAS in south Florida) acts as an underground reservoir for the injected water. The water is stored with the intent to recover it for use in the future. Potable water, surface water, groundwater, or reclaimed water can be stored using ASR technology. The water that is recovered depends on subsurface conditions and the level of treatment required after storage. Recovery also depends on whether the water is for public consumption,irrigation,surface water augmentation,or wetlands enhancement. 2012 LWC Water Supply Plan Update 177 The volume of water made available through WATER OPTIONS II ASR wells depends on factors such as well yield, water availability, variability in water ASR is the underground storage of water supply and demand, and use type. Uncertainty into an acceptable aquifer. Available of storage and yield capabilities and water waters are collected during times when quality characteristics present associated risks water is plentiful (typically during the wet for success, but ASR provides storage of water season in south Florida), and then pumped that would otherwise be lost to tide into an aquifer through a well. In south or evaporation. Florida, most ASR systems store treated water in the FAS, which contains brackish To date, 19 ASR wells have been constructed water. When discharged into the aquifer, within the LWC Planning Area.An ASR location the fresh water displaces the brackish map is provided in Figure D-4 in Appendix D. water. The aquifer acts as an underground All but one of these wells were built by reservoir for the injected water, reducing water/wastewater utilities. The remaining water lost to evaporation. The water is well is an inactive United States Geological stored with the intent to later recover it for Survey (USGS) test well. Many of these ASR treatment and use during future wells store treated drinking water, although dry periods. other source waters include raw groundwater, raw or partially treated surface water,and reclaimed water. Inactivity at some of these wells is related to a regulatory change in the primary drinking water standard for arsenic (i.e., 50 to 10 parts per billion).This change has introduced some uncertainty in obtaining an operational permit from the Florida Department of Environmental Protection (FDEP) for ASR systems. Through site testing, new treatment technology, and possible changes in regulatory criteria, ASR wells are considered a viable option for providing future water supply to meet growing demands. The SFWMD and the United States Army Corps of Engineers (USACE) are conducting pilot tests on two ASR systems within the SFWMD to evaluate the feasibility of ASR for the large- scale storage of excess surface water as part of the CERP.A report about the CERP ASR pilot testing is expected in 2013. The City of Marco Island has the largest ASR system within the boundaries of the SFWMD and has the capacity to 1.7 billion gallons of water. At the local level, the city's drinking water .. :�� supply depends on its ASR system for supply during high demand months. � The city's system includes seven wells ll that store partially treated surface water in the FAS for retrieval to its treatment facility. Marco Island Utilities - : intends to increase ASR capacity to Part of Marco Island's ASR System meet the city's future potable water 78 I Chapter 4: Evaluation of Water Source Options needs. Lee County Utilities also stores treated drinking water from its Corkscrew Treatment Facility in ASR wells for retrieval during peak demand periods. The county intends to expand ASR capacity at its west ASR wells for reclaimed water for non-potable use and at its Gateway Wastewater Treatment Plant ASR well system. For more information about these projects,see the utility summaries provided in Chapter 6. Aquifer Storage and Recovery Pretreatment Investigation This project investigates methods to suppress the freeing of arsenic from aquifer bedrock associated with ASR activities. It is co-funded by the Southwest Florida Water Management District, St. Johns River Water Management District, and SFWMD (through the CERP). The pilot project began in 2008 and was completed in 2011. The project consisted of 1)evaluation of arsenic mobilization processes occurring during ASR activities, which is being pursued by two independent consultant teams, 2) benishale leaching studies on storage zone cores, and 3) development of a degasification system to remove dissolved oxygen from source water prior to injection.Dissolved oxygen has been identified as a likely suspect in mobilization of arsenic from the FAS strata. The project concluded that the degasification technology was successful at reducing arsenic concentrations in recovered water; however, the process was expensive and required expanded operations and maintenance activities. Local and Regional Reservoirs Surface water reservoirs provide storage of water, primarily captured during wet weather conditions for use in the dry season.Water is typically captured and pumped from rivers or canals and stored in reservoirs. For example, small-scale (local) reservoirs are used by individual farms for storage of recycled irrigation water or the collection of local stormwater runoff, such as tailwater recovery. Tailwater recovery is addressed under agricultural best management practices (BMPs) later in this chapter. These reservoirs may also provide water quality treatment before off-site discharge. Large-scale (regional) reservoirs are used for stormwater attenuation, water quality treatment in conjunction with stormwater treatment areas, and storage of seasonally available supplies for use during dry periods. Projects to Capture, Treat, and Store Water Captured stormwater projects are planned for water management,water quality,and water supply purposes. A brief overview of projects planned to capture, treat, and store water in the LWC Planning Area are provided in the following sections. CERP Caloosahatchee River(C-43)West Basin Storage Reservoir Project This project is an above-ground reservoir located on the south side of the Caloosahatchee River (C-43 Canal) and west of the Ortona Lock (S-78). It is on a 10,700-acre parcel west of 2012 LWC Water Supply Plan Update 179 LaBelle formerly known as Berry Groves. The purpose of the project is to improve the quantity, timing, and distribution of freshwater flows to the Caloosahatchee River and Estuary.This proposed reservoir project would capture and store surface water runoff from the C-43 Basin and Lake Okeechobee to provide a more natural and consistent flow of fresh water to the estuary. After construction and flow-through testing, operation of this project is expected to improve the Caloosahatchee Estuary's salinity balance by reducing a portion of the peak discharges during the wet season and providing essential flows during the dry season. The reservoir will provide a total storage capacity of approximately 170,000 acre-feet of above-ground storage volume in a two-cell reservoir. For further information refer to Appendix G. CERP Picayune Strand Restoration Project This project is under construction with several phases completed. It is designed to restore and enhance over 55,000 acres of public lands by reducing overdrainage and returning the natural and beneficial sheetflow of water to the project site and adjacent areas, including the Fakahatchee Strand Preserve State Park, Florida Panther National Wildlife Refuge, Ten Thousand Islands National Wildlife Refuge,and Collier-Seminole State Park. In addition,this project is expected to improve aquifer recharge and maintain existing flood protection for private properties. A Water Reservation in support of this project became effective in July 2009 (see the Water Reservations section of Chapters 1,3,and 5). Dispersed Water Management Program This program is a collective and collaborative effort designed to encourage property owners to retain water on their land rather than drain it, accept regional excess runoff for storage, or both.Managing water on public,private,and tribal lands is a way to reduce the amount of water delivered to Lake Okeechobee and discharged to coastal estuaries for flood protection purposes. This program complements water storage options available through public facilities, such as reservoirs, restoration projects, and stormwater treatment areas. For further information refer to Appendix I. East County Water Control District The East County Water Control District is an independent 298 Special Water Control District that manages storm water in Lehigh Acres in Lee County. The East County Water Control District Consolidated Plan for Water Management (ECWCD 2008) includes improvement projects to reduce high flows to the Orange River,which currently discharges into the Caloosahatchee Estuary, capture and store stormwater runoff, and raise groundwater levels for wetland restoration,water storage,and aquifer recharge. Reclaimed Water Reclaimed water is water that has received at least secondary treatment and basic disinfection and is reused after flowing out of a domestic wastewater treatment facility (Rule 62-610.200, Florida Administrative Code [F.A.C.]). Reuse is the deliberate application 80 I Chapter 4: Evaluation of Water Source Options of reclaimed water for a beneficial purpose. Criteria used to classify projects as "reuse" or "effluent disposal"are contained in Rule 62-610.810, F.A.C.The term "reuse"is synonymous with"water reuse." Reclaimed water is a key component of water resource management in southwest Florida. WATER OPTIONS e Potential uses of reclaimed water include landscape irrigation (e.g., medians, residential lots, Reclaimed water has received at least and golf courses), agricultural irrigation, secondary treatment and basic groundwater recharge, industrial uses, disinfection. It is reused after flowing environmental enhancement,and fire protection. out of a domestic wastewater treatment facility. Reuse is the The State of Florida encourages and promotes the deliberate application of reclaimed use of reclaimed water. The Water Resource water for a beneficial purpose in Implementation Rule (Chapter 62-40, F.A.C.) compliance with the FDEP and water requires the FDEP and water management districts management district rules. advocate and direct the use of reclaimed water as an integral part of water management programs, rules,and plans.The SFWMD requires all applicants for consumptive use permits proposing to use more than 0.1 MGD of water to use reclaimed water if it is environmentally, technically,and economically feasible to do so,as determined in the permitting process. Wastewater reuse conserves resources and is an environmentally sound alternative to traditional disposal methods, such as surface water discharge and deep well injection. Although back-up disposal methods are needed in wet periods with low irrigation demands, wastewater reuse minimizes disposal of needed water resources. Reclaimed water also provides additional water supply for water uses not requiring potable water, such as irrigation. Existing Reuse in the LWC Planning Area The primary use of reclaimed water in the LWC Planning Area is for irrigation of public access areas including golf courses, residential lots, parks, schools, and other green spaces. Reclaimed water is also used to recharge groundwater. Use of reclaimed water for industrial cooling is expected to grow as Power Generation (PWR) Self-Supply demands increase during the 20-year planning horizon (see Chapter 2). In the LWC Planning Area, wastewater management has evolved over the past 15 years from package plants and smaller subregional facilities to an integrated system of larger regional facilities and a network of reclaimed water pipelines carrying treated water. The volume of reclaimed water used for a beneficial purpose,such as groundwater recharge and landscape irrigation, has more than doubled from 1994 to 2010 as shown in Figure 19. Over this period,the volume of reclaimed water use varied from year to year, depending on the addition of new users and area rainfall. 2012 LWC Water Supply Plan Update I 81 80 70 60 to 50 d c c 40 30 Z0 10 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 Figure 19. Annual reclaimed water reuse history in the LWC Planning Area 1994-2010(Sources: FDEP Reuse Inventories 1994-20101). In 2010, there were 41 wastewater treatment facilities in the LWC Planning Area with a capacity of 0.1 MGD or greater.These facilities had a total wastewater treatment capacity of 148 MGD to meet peak daily flows and treated 77 MGD of wastewater. Collier County Water-Sewer District's North County Water Reclamation Facility, with a capacity of 24.1 MGD,remains the area's largest wastewater treatment/reclamation facility. Of the 41 wastewater treatment facilities, 38 facilities reuse all or a portion of their wastewater. In 2010, 71 MGD (91 percent) of the wastewater treated in the LWC Planning Area was reused for a beneficial purpose. Approximately 61 MGD of reclaimed water was used for irrigation of more than 51,000 residential and commercial lots, 77 golf courses, 48 parks,and 24 schools (FDEP 2011).About 4 MGD of the planning area's reclaimed water supply was used for groundwater recharge through rapid infiltration basins and spray fields.The remainder was used for miscellaneous uses, such as for industry and agriculture. The reuse of reclaimed water in lieu of traditional fresh groundwater and surface water in the LWC Planning Area has helped reduce potential resource impacts. In 2010, 9 MGD of the LWC Planning Area's 77 MGD of the wastewater treated, which is potentially reusable,was disposed of through injection wells.The City of Fort Myers,Naples, and Lee County also use surface water discharge. However, each of the utilities plans to minimize future wastewater discharges.A listing of reclaimed water facilities and capacities is provided in Appendix D. 1 FDEP 1995, 1996, 1997, 1998, 1999,2000,2001,2002,2003,2004,2005,2006,2007,2010a,2010b,2011 82 I Chapter 4: Evaluation of Water Source Options Reclaimed Water System Interconnects Reclaimed water system interconnects are connections between two or more L, reclaimed water distribution systems. +� 1 These systems may be owned or operated by different utilities, or may be shared - between two or more domestic wastewater treatment facilities that provide reclaimed water for reuse l activities. When two or more reclaimed — water systems are interconnected, additional system flexibility is attained, which increases efficiency and reliability. City of Fort Myers Reclaimed Water Facility For example, possibilities exist for regionalization, where flows from smaller water treatment facilities are diverted to larger regional facilities. For example, Fort Myers produces excess reclaimed water and Cape Coral's irrigation water demand exceeds its reclaimed water supply, thus, the reclaimed water connection between them is beneficial for both utilities. Lee County Utility's Waterway Estates facility currently sends some wastewater to the City of Cape Coral in an effort to increase overall efficiency and to reduce discharges to the Caloosahatchee River(C-43 Canal). 2012 Reclaimed Water Bill In 2012, the Florida legislature amended Section 373.250, Florida Statutes (F.S.). The amendments required the FDEP to initiate rulemaking to incorporate criteria for the use of "substitution credits"and"impact offsets"when a water management district is reviewing a consumptive use permit application. Impact offsets are derived from the use of reclaimed water to reduce or eliminate a harmful impact that has or would otherwise occur as a result of a surface or groundwater withdrawal. A substitution credit means the use of reclaimed water to replace all, or a portion of, an existing permitted use of a resource-limited surface water or groundwater, allowing a different user or use to initiate a withdrawal or increase its withdrawal from the same resource-limited water resource.Water management districts rules will be modified,as needed,to be consistent with the amendments to Section 373.250, F.S.,and amendments to FDEP's Chapter 62-40,F.A.C. Future Reuse in the LWC Planning Area Utility wastewater flows are projected to increase to an estimated 139 MGD by 2030.All of the major utilities (greater than 0.1 MGD capacity) have excess treatment capacity at this time and plan to expand their reuse systems as additional reclaimed water becomes available and demand increases.Most of the utilities plan to reach full reuse of their average daily wastewater flow by 2030. The utilities that still have FDEP-issued surface water discharge permits intend to minimize or eliminate those discharges through either reuse or deep well injection. In many cases, future reuse will occur in new residential developments, 2012 LWC Water Supply Plan Update 183 as many local governments have requirements for reclaimed water line installation. Consumptive use permits for landscape irrigation in the LWC Planning Area require the use of reclaimed water when environmentally, technically, and economically feasible, as determined in the permitting process. The City of Naples reused 71 percent of the wastewater generated in 2010 for public access landscape irrigation, primarily golf courses. The city plans to expand its reclaimed water distribution to reach more residential irrigation systems and facilitate 100 percent use of its reclaimed water supply. Many residential irrigation systems currently use potable water; consequently potable water demand will decrease with the increased use of reclaimed water. The City of Naples intends to supplement its reclaimed water supply with captured storm water and will provide irrigation water to customers currently using potable water for irrigation. The city's plan is designed to reuse all of its wastewater, decrease the per capita use rate (PCUR) of its potable water supply, and eliminate the need for additional potable water treatment capacity over the next 20 years. The City of Marco Island has an ongoing septic system replacement program in place. The city has upgraded its wastewater treatment and reclaimed water production capacity. By adding reclaimed water lines to its distribution system to provide more reclaimed water supply for landscape irrigation, the city is reducing its reliance on potable water for irrigation. In 2010, the average daily reuse flow for the City of Marco Island was 1.5 MGD, nearly 81 percent of its average wastewater flow. By 2030, the city projects its average reuse flow will reach 2.5 MGD,which is 86 percent of its projected 2030 wastewater flow. Supplemental Sources The use of supplemental water supplies to meet peak demands for reclaimed water may enable a water utility to maximize its use of reclaimed water resources. However, during times of drought, other water sources, such as surface water, groundwater,or storm water, may not be available to supplement reclaimed water supplies in some areas. Use of supplemental water supplies is subject to consumptive use permitting by the SFWMD, and the availability of these supplies to supplement reclaimed water will be evaluated on an application-by-application basis. The use of supplemental water supplies to meet peak demands for reclaimed water may enable a water utility to maximize its use of reclaimed water resources. However, during times of drought, other water sources, such as surface water, groundwater, or storm water, may not be available to supplement reclaimed water supplies. Use of these sources as supplemental water supplies is subject to consumptive use permitting by the SFWMD. The availability of surface water, groundwater, or storm water to supplement reclaimed water will be evaluated on an application-by-application basis. The FDEP is amending provisions of Chapter 62-40, F.A.C. to recognize and promote the supplementation of reclaimed water supplies with surface water and groundwater sources in order to maximize the reuse of reclaimed water. 84 I Chapter 4: Evaluation of Water Source Options The Golden Gate Canal Irrigation Quality Facilities Project proposed for the City of Naples will develop a 10 MGD water supply from captured storm water to supplement a reclaimed water system for irrigation. 7, f - The City of Cape Coral supplements its r ;/-' reclaimed water supply with water y from the freshwater canal system. The canal system has the capacity to supply 46 MGD of surface water to its Water Independence for Cape Coral system, Golden Gate Main Canal which has 715 miles of reclaimed water lines and irrigates about 8,000 acres of residential and commercial landscape. The planned 4,000-acre expansion of the system to provide irrigation for over 12,000 acres will require additional reclaimed water and supplemental sources. The Collier County Water-Sewer District utilizes supplemental /, - groundwater supply to help meet "� irrigation demands when reclaimed I J .tiakiig ., " • water supply declines and irrigation -�'�' demands peak. The Collier County Water-Sewer District's Irrigation .. Quality Water System supplies irrigation water to over 50,000 end users, including 21 golf courses, 11 6 county parks and schools, residential ;=- � communities, and 65 miles of roadway Collier County Water-Sewer District irrigation medians. The Collier County Water- quality water pump station at Pelican Bay Sewer District has identified future irrigation quality water customers and is developing additional irrigation water supply through the use of ASR,which will utilize a combination of reclaimed water,groundwater,and storm water. Seawater Seawater or salt water is defined as water with a chloride concentration at or above 19,000 mg/L. Seawater requires desalination treatment prior to being used as potable water. Desalination is the process of removing or reducing salts and other chemicals from seawater or other highly mineralized water sources, resulting in the production of fresh water. 2012 LWC Water Supply Plan Update 185 The use of desalinated seawater from the Gulf of Mexico is an additional water source option for the LWC Planning Area. The Gulf of Mexico is essentially an unlimited source of water. However, desalination treatment is required before potable or irrigation uses are feasible. Desalination treatment technologies include reverse osmosis (RO), electrodialysis, or electrodialysis reversal. While seawater treatment costs are declining, costs remain moderately higher than brackish water desalination. In December 2006, the SFWMD completed a feasibility study for co-locating seawater treatment facilities with power plants in south Florida (Metcalf& Eddy 2006). The study's most feasible three sites are co-located with Florida Power & Light's (FPL's) facilities in Fort Myers, Fort Lauderdale,and Port Everglades. Summary of Water Source Options Historical water sources include fresh groundwater from the SAS and IAS, and surface water, primarily from the Caloosahatchee River (C-43 Canal) and canals. However, from a regional perspective,development of the SAS and IAS for potable water has been maximized over time in certain areas, and potential increases in production are limited, especially in coastal areas. New or increased allocations will be reviewed on an application-by- application basis to determine if the project meets consumptive use permitting criteria. Alternative water supply sources include brackish groundwater from the FAS, reclaimed water,and captured storm water. The FAS and portions of the IAS in the LWC Planning Area are brackish water sources that require blending or desalination treatment before use. Over the 20-year planning horizon, development of these brackish sources will exceed development of freshwater sources. Two-thirds of south Florida's annual rainfall occurs in the wet season,but without sufficient storage capacity, much of this water discharges to tide. In the LWC Planning Area, potential types of needed water storage include ASR wells, reservoirs, and surface water impoundments and ponds. Reclaimed water is a key component of water resource management in south Florida. Thirty-eight out of 41 wastewater treatment facilities in the LWC Planning Area reuse all or a portion of their wastewater. In 2010, 71 MGD (91 percent) of the wastewater treated in the LWC Planning Area was reused for a beneficial purpose, primarily for irrigation. However, 9 MGD of potentially reusable water was disposed of via deep well injection. Utility wastewater flows are projected to increase to an estimated 139 MGD by 2030. The utility interconnects discussed in this plan update could significantly increase water reuse in the planning area. Desalinated seawater is an additional water source option for the LWC Planning Area. Water conservation is also considered a water source option.Water conservation measures, as discussed in the following section, present feasible options for all locations and use types to meet the water needs of the region by reducing water use demands. 86 I Chapter 4: Evaluation of Water Source Options Water source options are dependent on location, use type, demand, regulatory requirements,and cost.As competition for limited water resources increases, development of alternatives has become more common. WATER CONSERVATION • Water conservation, also known as DISTRICT demand management, is an integral part of water supply planning and The SFWMD's consumptive use permitting rules water resource management. For require PWS utilities to plan and implement water conservation measures. These rules have been in planning purposes, water place since 1991. conservation is also considered a water source option because it can As detailed in Section 2.6.1 of the Basis of Review, reduce the need for expansion of the these rules include the following: water supply infrastructure. • Adoption of an irrigation The first part of this section identifies days/hours ordinance the water conservation opportunities, • Adoption of a Florida-Friendly programs, and tools available for LandscapeTM ordinance urban water use along with examples • Adoption of an ultralow volume of potential water savings. The fixtures ordinance majority of these programs and tools apply to the PWS use category, which • Adoption of a rain sensor device ordinance provides water for residential, • Adoption of a water conservation-based industrial, commercial, institutional, rate structure landscape, and recreational needs. The second part of this section • Implementation of a utility leak detection reviews BMPs and water and repair program conservation opportunities for • Implementation of a water conservation agricultural and urban irrigation. public education program Information about the SFWMD's • An analysis of reclaimed water feasibility Comprehensive Water Conservation Program, water conservation-related More information about water conservation is laws and rules, available planning provided in the Support Document. resources, and funding opportunities is also presented. Generally,water conservation promotes permanent water use efficiencies and increases the available supply of water from existing sources to support growth and maintain natural resources. It is also more immediate, significantly less costly, and more energy efficient to conserve water than to develop new sources of water. Water demand reduction is a viable alternative to new water supply development and enhances existing water supplies. While short-term water restrictions imposed during a water shortage can temporarily relieve pressure on water sources, lasting water conservation involves a combination of retrofits, 2012 LWC Water Supply Plan Update 187 new water saving appliances, maintenance of infrastructure, and a collective water conservation ethic focused on resource use,allocation,and protection. At the utility level, a well crafted water conservation or demand management plan can improve a utility's systemwide operational efficiency and reduce, defer, or eliminate the need for investments in new production capacity.Quantitative analysis of a utility's current and future water production, service area characteristics, and population can yield robust estimates of water and cost savings achievable through water conservation. The SFWMD recommends that utilities compare the cost of water conservation measures and the resultant water savings with production costs for new sources. Comprehensive Water Conservation Program The SFWMD's Comprehensive Water Conservation Program is a series of implementation strategies approved by the SFWMD's Governing Board in September 2008. The program is the result of a Water Conservation Summit hosted by the SFWMD's Water Resource Advisory Commission (WRAC)and a series of stakeholder meetings. The Comprehensive Water Conservation Program is designed to bring about a permanent reduction in individual water use and is organized into 1) regulatory, 2) voluntary and incentive-based, and 3) education and marketing initiatives. Under the umbrella of these initiatives, the SFWMD and other agencies offer numerous water conservation tools, building codes requiring use of water efficient appliances and fixtures, and more efficient landscape and irrigation practices. Chapter 5 in the Support Document provides additional background information about the development of the Comprehensive Water Conservation Program. Urban Use — Tools, Programs, and Potential Savings In this section,urban use is defined as water used for non-agricultural purposes. It includes the water used in homes and businesses, landscape irrigation, and power generation. The majority of water consumed for residential and commercial use is provided by PWS utilities. This PWS consumption is included in each utility's PCUR. However, some homes and businesses use well water for their source of potable water and irrigation water, which is DSS and classified as urban use. Collectively, south Florida's PCUR is the highest in the state. It is estimated that south Florida uses 179 gallons per day (GPD) per person (Marella 2009), including approximately 70 GPD indoors. While this plan update concentrates on water conservation for PWS utilities because savings can be quantified, the SFWMD's recommended water conservation measures are applicable to both PWS and DSS water users. 88 I Chapter 4: Evaluation of Water Source Options Measuring the Effects of Water Conservation The key indicator of long-term water conservation effectiveness is PCURs and their fluctuations over time. Per capita consumption is calculated as PWS withdrawals in GPD (Marella 2009)divided by the number of permanent residents. While a PCUR is an effective measure of conservation effectiveness for a single community or utility over time, it is much less effective when comparing one community or utility to another. Significant differences between communities, such as industrial use, seasonal populations, and other demographic differences affect the total amount of water used by a community. This is because these factors are not accounted for in the calculation of per capita consumption. Table 11 shows the base year regional utility PCUR for this plan update as well as those cited in the 1994 Lower West Coast Water Supply Plan (1994 LWC Plan; SFWMD 1994),2000 Lower West Coast Water Supply Plan (2000 LWC Plan; SFWMD 2000b), and 2005-2006 Lower West Coast Water Supply Plan Update (2005-2006 LWC Plan Update; SFWMD 2006). The PCUR has gone down from 194 GPD per person, in the 1994 LWC Plan, to a low of 151 GPD per person in this plan update. Table 11. PCURs in the LWC Planning Area (using overall finished water). 1994 1990 194 --- 2000 1995 167 13.42 2005-2006 2000 176 10.72 2012 2005 151 34.35 These numbers show a pronounced downward trend in the use of finished water per person per day. This reduction in water use may suggest that a water conservation ethic is emerging or dependence on potable water for irrigation is declining due to increased water reuse or the use of private wells for irrigation. Water efficient appliances, plumbing retrofits, minimum building code standards, education, and other water conservation- oriented practices contribute to the reduction in finished water use.The SFWMD's objective is to continue this water use trend by working with water users to achieve significant long- term water savings. For a discussion about estimating the effects of water conservation, see the Support Document. Public Water Supply Use: Utility and Local Government Programs A variety of options are available to municipalities and water supply utilities for developing and enhancing water conservation programs. These options include comprehensive plans, such as goal-based programs, as well as specific solutions, such as plumbing retrofits and advanced irrigation technology. Many of the options prescribed for PWS users are also applicable for DSS users. 2012 LWC Water Supply Plan Update 189 Utilities may direct conservation measures to individual users through water conservation rate structures, retrofits, and rebates. Water conservation can also be promoted at the utility level by addressing plant efficiencies,use of reclaimed water, and automatic flushing devices. An effective program includes several programmatic water conservation components. Appendix E provides the status for PWS water conservation program implementation for municipalities and water utilities in the LWC Planning Area. Water Conservation Rate Structures Water pricing is an effective means to promote water conservation. A water conservation-based rate structure provides a financial incentive to reduce use. Users faced with higher rates will often achieve water conservation by implementing a number of the conservation measures discussed in this chapter. Water conservation-based rates may include the following: ♦ Increasing the block rate - the marginal cost of water to the user increases in two or more steps as water use increases ♦ Seasonal pricing-water consumed during peak season (October through May), is billed at a higher rate than water consumed in the off-peak season • Quantity-based surcharges • Time-of-day pricing Utilities seeking a consumptive use permit must adopt a water conservation-based rate structure as part of their water conservation plan.In the LWC Planning Area,the majority of PWS providers have a block rate structure (also referred to as a"tiered"rate structure).The block rate structure is generally expected to have the largest impact on heavy irrigation users. The responsiveness of customers to water conservation rate structures depends on the existing price structure, incentives of the new price structure, the customer base, and their water uses. Appendix E provides single family water use rates in the LWC Planning Area. Goal-based Water Conservation Plans A goal-based water conservation plan allows utilities to achieve agreed upon conservation goals within their consumptive use permits to help meet future water supply needs and possibly eliminate the need to construct additional facilities or wells. A well designed program identifies a variety of methods and practices that decrease water demand to meet numeric goals. Water conservation planning tools are available to help PWS utilities develop water conservation plans with a numerical goal for achievable water savings. The practices selected should reflect, among other parameters, population projections, existing PCURs, the ability of the population to make the necessary changes, and the service area's water use profile. It is important for the plan to project the costs for supplying the additional water needed to meet water supply objectives.The SFWMD recommends regular review and analysis of plan results,which allow for program adjustments as needed to meet 90 I Chapter 4: Evaluation of Water Source Options water conservation goals. More information about goal-based water conservation is provided in Appendix E. Water Conservation Program Planning Tools for Public Water Supply Utilities PWS Utilities in the LWC Planning Area are strongly encouraged to use a water conservation planning tool offering conservation standards to create goal-based demand management plans for their service areas. Upon request, the SFWMD provides support and assistance to utilities in creating a service area demand management plan. In general,water conservation planning tools can help a utility to do the following: ♦ Develop a service area water use profile ♦ Evaluate and compare the costs and benefits of various conservation measures ♦ Create a mid-to long-range conservation(or demand management)plan The Conserve Florida Water Clearinghouse's EZ Guide (2009) generates estimates of indoor water use and savings for utility service areas using data from entities such as county property appraiser offices and the Florida Department of Revenue. The entities maintain detailed data on all land parcels in the state. For each parcel,these data typically include the age of a structure, number of bathrooms,total square footage of the parcel,and total square footage of the built structure on the parcel.These data,along with population estimates,are used to create estimates of water consumption for structures built during each plumbing code era and for each water use sector (e.g., single and multiple family residential, industrial,commercial,and institutional). The EZ Guide output results include water savings, costs, and net benefits for each recommended water conservation option, and each water use sector is subdivided by plumbing code dates. In addition, the EZ Guide produces a ranked and optimized list of water conservation actions based on cost benefits and gallons of water saved.The EZ Guide is available at no cost from the Conserve Florida Water Clearinghouse website (http://www.conservefloridawater.org). The Alliance for Water Efficiency's Water Conservation Tracking Tool is a Microsoft®Excel- based model, which uses baseline demand data for each water use sector (customer class) and avoided cost data to evaluate and design utility conservation programs. It contains a library of predefined water conservation measures users can select for evaluation. Water savings, costs, and benefits of each measure can be examined and tracked for each year of the proposed program. The tracking tool features comprehensive and highly developed economic analyses of each water conservation option accounting for program costs using time-valued dollars. Yearly peak and off-peak demands and savings are calculated to identify specific points of capacity deferment and present value benefits.The tool's avoided cost calculator includes analysis of short-term avoided costs and long-term avoided or deferred capacity expenses. The analysis functions of the tool include utility revenue and rate impact calculations. The tool recently concluded a beta testing period and is now available free of charge to Alliance for Water Efficiency members from http://www.allianceforwaterefficiency.org. 2012 LWC Water Supply Plan Update 191 Water Conservation versus Development of Additional Water Supplies Most water supply development options require significant upfront investments and ongoing operations and maintenance costs. In many cases, demand management is often a more immediate and cost-effective means of meeting water supply needs.Tables 12 and 13 compare the unit costs to save or create 1,000 gallons of water using an aggressive water conservation program or common water treatment technologies. Based on the costs in Table 12, Table 13 shows the daily cost to produce 1 MGD, 3 MGD, and 5 MGD of water using nanofiltration and RO as compared with water conservation. Table 12. Cost comparison of water conservation versus nanofiltration and RO treatment technologies for 1,000 gallons of water. Water High-efficiency Purchase and installation of hardware plus program Conservations fixtures/appliancesb $0.40 to$3.00 administration costs IVI�i^aM z,f r 1 � r Y W 4 'W �l vI wuI W IIl" d r 1 V14". '""114 r —i q 3 v sr7b m a rV 1411'I W h a r a w Y M4a(� E' # i III •f ql '':11'44;44'41 ` 11 n 1 ti i 1,�� "�L vM"_rc`H.sN�i i .., ,aw_.�..:. �x...�r4�W�' :�.�����.��..lun'J�IIW�...�... .k,,.4�JnaP. ., _.,,A...ti µw'e�.�. .. �...ur;4.3 �.�.,ar.Wl'r,`✓�w�.J�.�.'r:'�J�. Expansion of Nanofiltration $3.13 to$9.07' Nanofiltration or RO membrane units and associated Existing Facility` RO $3.69 to$10.38. equipment,filters,piping,and supplies a. Cost of 1,000 gallons saved is based on the cost of all devices across the service life and the number of gallons saved per day normalized to 1,000 gallons. b. Fixtures and appliances include,but may not be limited to,toilets,faucet aerators,showerheads,irrigation spray heads,rain and soil moisture sensors,and computerized irrigation controllers for large-scale irrigation. c. Costs are considered to be order-of-magnitude estimates as defined by the American Association of Cost Engineers. d. Amortization of initial capital investments is a term of 20 years at a 7 percent discounted rate. Table 13. Daily cost of water conservation versus nanofiltration and RO for 1 MGD,3 MGD, and 5 MGD of water supply. 1 MGD $400—$3,000 $9,460 $11,330 $9,070 $10,380 3 MGD $1,200—$9,000 $13,500 $17,430 $12,330 $14,580 5 MGD $2,000—$15,000 $17,100 $22,050 $15,650 $18,450 The cost ranges for common water treatment technologies shown in Table 12 illustrate an inverse relationship of cost to production. This is due to initial fixed capital costs and economies of scale in production. The cost range for conservation items (per 1,000 gallons saved) relates to the costs for the various conservation items themselves (faucet aerators, toilets, irrigation hardware, etc.), minus any shared costs with end users (via utility rebate programs) and the cost of program administration. The fixed savings rates of each conservation item can have a linear effect on total program cost as the program size increases, in contrast to common water treatment technologies. Once administrative and end user shared costs have been established, the costs and savings rates of the individual conservation items are likely to be the strongest driver of conservation program expenses. 92 I Chapter 4: Evaluation of Water Source Options Tables 12 and 13 indicate that the unit and daily cost of water conservation is significantly less than new water production through expansion of an existing facility or construction of a new facility. In addition, indoor water conservation measures reduce wastewater generation and flows that have to be treated and disposed of, resulting in additional cost savings not addressed in these tables. Appendix E contains a comparison of water conservation measures and alternative water supply development. A well crafted water conservation or demand management plan can improve a utility's systemwide operational efficiency and reduce, defer, or eliminate the need for investments in new production capacity. Utilities should consider water conservation as a water source option to meet future growth and water production needs. Case Study The Miami-Dade Water and Sewer Department is a real world example of how a utility was able to capitalize on cost and water savings through water conservation. The department implemented a goal-based water conservation plan that shows actual savings in dollars and gallons.This example presents compelling evidence of how water conservation can be used in combination with,or in lieu of,developing alternative water supplies. EXAMPLE Case Study The Miami-Dade County Water Use Efficiency 20-Year Plan (Miami-Dade County 2007) estimates the conservation program could generate 19.6 MGD in water savings by 2026. The Miami-Dade Water and Sewer Department used the Conserve Florida Guide (a predecessor to the EZ Guide) to create a goal-based water conservation plan consisting of non-quantifiable measures and quantifiable BMPs to achieve water savings. The plan involves indoor plumbing fixture retrofit projects, permanent two-day-per-week irrigation restrictions, residential irrigation efficiency improvement projects, and other measures. Based on the initial cost estimates of water supply development and quantified water conservation savings observed to date, each dollar the Miami-Dade Water and Sewer Department spent on implementing its water conservation plan since 2006 has deferred or eliminated between $5 and $9 in capital project costs. Due in large part to water conservation plan implementation, per capita water demand has been reduced from 154 gallons per capita per day in 2005 to 140 gallons per capita per day in 2009. The drop in overall water demand, together with slower population growth rates, has allowed the county to reschedule its water supply development plan, eliminate two alternative water supply projects, and postpone four alternative water supply projects. In addition,the county was able to extend the duration of its current consumptive use permit. 2012 LWC Water Supply Plan Update 193 More information about this goal-based water conservation example and water conservation is available in Appendix E and the Support Document. Indoor Use The indoor use category represents the water used within homes, businesses, and institutions to take care of everyday needs and commercial operations. Examples of indoor use include preparing food, washing dishes, taking showers, flushing toilets, and operating equipment. Plumbing Fixture Efficiency To help reduce indoor PCURs,the SFWMD supports the efforts of municipalities and utilities in implementing high efficiency indoor retrofit programs. Programs that provide funding, hardware,or support for plumbing retrofits,including WaterSense,Water Savings Incentive Program (WaterSIP), Water Conservation Hotel and Motel Program (Water CHAMP), and Florida Water StarSM,are discussed in the following sections. EXAMPLE The School District of Lee County The School District of Lee County partnered with FPL to assess and implement water conservation and cost reduction measures in Lee County schools. During FY 2009, Phase II of the program targeted Estero High School. The school lavatories were retrofitted with technologies to reduce consumption well below the conventional flow rates for water closets, urinals, and faucets. The following high efficiency plumbing fixtures were purchased and installed: 97 toilets, 26 urinals, 46 aerators, 20 faucets, and five kitchen pre-rinse sprayers. Actual usage rates per fixture type were based on site visits and interviews with school personnel, as well as the ratio between males and females at the high school. In 2009, before the retrofit program began, Estero High School's water usage was 3.56 million gallons per year (MGY). In 2010, after the retrofit program was implemented, the school's water usage was 2.78 MGY. The Estero High School retrofit program provided an actual water savings of 0.78 MGY, about 22 percent. WaterSense The SFWMD became a WaterSense Promotional Partner in 2009.WaterSense is a program established by the United States Environmental Protection Agency (USEPA) to protect the future of our nation's water supply by promoting water efficiency and enhancing the market for water efficient products, programs, and practices.WaterSense helps consumers identify water efficient products that meet rigorous efficiency and performance criteria. Products tested and proven at least 20 percent more efficient than those meeting current federal standards without compromising performance standards are awarded the WaterSense label. 94 I Chapter 4: Evaluation of Water Source Options When designing and planning a retrofit program, the SFWMD recommends utilities and municipalities refer to the WaterSense Program for standards, criteria, and information. The SFWMD also refers to WaterSense products and standards for use in the WaterSIP.The SFWMD also encourages local municipalities to become a WaterSense Promotional Partner and to amend or enact local plumbing ordinances to require WaterSense fixtures in new construction and in retrofit programs. Island Water Association, Inc., of Sanibel Island is a WaterSense utility partner. More information about this program is available from the WaterSense website,http://www.epa.gov/waterSense. Water Use Appliances Retrofits Newer water fixtures and appliances provide significant water savings compared to older appliances and fixtures. For example, a more efficient washing machine generates a potential estimated savings of 20 gallons of water per use, so a household washing five loads of laundry each week could save more than 5,000 gallons of water per year.Table 14 shows water consumption for common indoor fixtures and appliances. In addition, Table 14 includes the WaterSense Program's maximum allowable consumption rate, as well as flow rates for the highest efficiency fixtures and water using appliances currently manufactured. A quantification of water savings is provided in the Potential Urban Water Savings section of this chapter. Table 14. Gallons of water consumed for common indoor water fixtures and appliances. Pre-1984 5.0-7.0 5.0-8.0 4.0-7.0 5.0 14.0 56.0 1984-1994 3.5-4.5 2.8-4.0 2.8-3.0 1.5-4.5 10.5-12.0 39.0-51.0 Post-1994 1.6 2.5a 2.5' 1.0 10.5 27.0b WaterSense Max 1.3 2.0 1.5 0.5 -- -- Highest Efficiency 0.8-1.0 1.2-1.5 0.5-1.0 0.0-0.1` 4.5-6.5 16.0-22.0 a. At 80 pounds per square inch or 2.2 gallons per minute at 60 per square inch. b. Post-1998. c. Waterless urinals are only recommended under specific conditions. The SFWMD recommends several online resources for consumers, building managers, utilities, and municipalities for research and comparison of indoor retrofit program water using devices: • ENERGY STAR®Program (http://www.energystar.gov) • Consortium for Energy Efficiency(http://www.ceel.org) • Food Service Technology Center(http://www.fishnick.com) • USEPA WaterSense Program (http://www.epa.gov/WaterSense/) • Alliance for Water Efficiency(http://www.allianceforwaterefficiency.org) • California Urban Water Conservation Council (http://www.cuwcc.org) 2012 LWC Water Supply Plan Update 195 Indoor/Outdoor Use Florida Water Stars' Florida Water StarSM is a points-based recognition program that promotes water efficient household appliances, plumbing fixtures, irrigation systems, and landscapes. The program is a voluntary water conservation initiative begun by the St.Johns River Water Management District and is now in place in three of Florida's water management districts, including the SFWMD. Residences, business, and communities can earn water conservation certification through meeting efficiency standards during new construction or retrofit projects. The Florida Water StarSM Program offers three forms of certification: • Residential certification of new or existing residences in two tiers: Silver or Gold ♦ Certification of new or existing commercial/institutional buildings (offices, retail, and service establishments, and institutional and non-industrial commercial buildings) ♦ Community certification of a master-planned community A single family home built to meet Florida Water StarSM Silver criteria uses at least 40 percent less water outdoors and at least 25 percent less water indoors than a home built to current Florida building standards. Similarly, a single family home built to Florida Water StarSM Gold criteria uses at least 50 percent less water outdoors and at least 35 percent less water indoors than a home built to current Florida building standards. Local governments that adopt Florida Water StarSM Silver criteria as their water conservation standard for new residential properties can expect new residential homes in their jurisdictions to use as much as 35 percent less water than their current residential stock of single family homes with permanent inground irrigation systems. Savings of up to 45 percent may be reasonably anticipated for such homes built to Florida Water StarSM Gold criteria. Tables 15 and 16 show PWS demand data for the LWC Planning Area (see also Chapter 2). These tables include available USGS data (Marella 2008), which were used to calculate the percentage of total PWS attributable to residential PWS. Housing data from The State of Florida's Housing,2009(White and Stroh 2010) was also used to calculate the percentage of water use attributable to single family housing.Housing projections are based on 2010 data, assuming that the number of persons per household and the number of single family homes as a percentage of total housing units remain constant through 2030. For the purposes of this analysis, it was also assumed that all new single family homes have permanent inground irrigation systems. The tables show the estimated demand reduction potentially achieved with implementation of Florida Water StarSM of Silver and Gold certifications for new single family homes in Collier and Lee counties. More information about the Florida Water StarSM Program is included in Chapter 5 of the Support Document. 96 I Chapter 4: Evaluation of Water Source Options Table 15. Potential water demand reduction in Lee County based on implementation of Florida Water Stars"' Permanent residentsa 606,950 671,921 753,272 850,561 957,100 Y; Ik 71 4yl IW li,...Y W� i +I h- .r i �e_l:�yi�tir111•li IIVu. i_.. ,.. �.°... W wti� .., �E ,: �'�1Y"Ilr�'i1u,1111 ail "wu°.".. a �.�y. ..., Incremental housing 20,698 25,916 30,994 33,940 increase Single family water demand without Florida Water Stars"' 23.62 24.86 26.37 28.07 30.03 '� r4 ^V �' r , . °.f 1w r ."Y'"�M,N I?"'w F IynP N Vry°mMl>' ✓a r u"'' � Ip"iN'"' 3.µ' I wWgy 9 r u ,h€ - w w`'� wa�"w^ w mr~,uII 1 4 �w .. :'1 9w ul r' 1 W r l V w � -a,. I�IN 4 "�.° IpI kl it kul ,huly l9P�uV t 9 r +I i�IW41W'{III{rSl (T ' llrl'II IfIIIPU0h,,.. II °, -Y3N Irl.;alll`♦' PI4gIWPWwi, h II '� uw. If p711 IdII Iy1 r'llukihmu,rV'� l lllw W Ih V L .14 s n liwlr,. I without ; ° w $ Ii lulWkluPI IIryiNlyli4i* II C ,r j�I'.. w � 11404$1'1�til tlri�Sii l~i r°" r c,?°u. ° A r' iN Ii:�NIIrP VI rIVP��W� !� ali S rP Q <fwV V WI VII �k� M IV Ikidr al lull llV� °1819{^.$ i Z' '.41 VI '"*IIrw oWe-aly wu uIl( n,• a a IIIah till :,:w��g �I 'PI ° _ °.m lr.w water v�, "W� W. a '� re.. � °wuu N rl IJP, d auuu ww w.wua ua Single family housing waer demand assuming new stocks are built to Florida 24.43 25.84 27.48 29.34 Water Stars"'Silver criteria 35%demand reduction gy "" 4s r`Gxacuy�ur �, """'+ss N„IW�"'RF�'WW^'vI�,WW�In" °9°n�'"" .s" s fir' Ni'"luN�' VI PI 'fl"°I' S re gg4s N rw v a pa N n✓WVww..,� s w,€ °w k k a¢ i E� � mS r i t � a. auW P rrNk � k NJ I I u hfl hl V4wi s f4 ^,� r4 �wr • ri 4 �€� P z-' b ... ,, r4i I Plhl 11 reS1 I(^6 S * a ` l re d e a € - N�' d r5ucti n „ s +rre r.41 fig' a�' fl uw"`�0'I� ��1 ai. yVl�t I�, i ` fit` ' L • _ = Ij .c a ii+u _ to-, sv�py ^- r #u o ne,n a l I r r w 0.E re V� FA-R.: t '�p�yu IrrlulVM " > I G i W .4 y`r a �S x _ ., r n t v re,ti, o w °t rew 4rz°PI p I Wh inu,E F �..� r ,C uf"'k �w V v„s' ;>s , 1+'� , IMt �9,>I� Arplli�IlpllilEll�+ll ' 're. Sir iL- to dS Ir Ih ¢ NRUyV l �r aV v 11 I� rf r re �, z kt 'V VIVV{h r uP vl ! u n. �'kwrG�'ih"r - �` II r N-, r Ili ,A� � i >J" d" , d t ri V II IVji1 IVI du d r bra- + - l _'p, ' F_' pul wI„'V�I1.1:1 y3` i, al I�I1911R 1 4�iVM "rti* .', .ry fyy�4��r - { �I 35 6- �m. 1"vI,5,1' ® ! yd��3"kF..u��wuW,r✓J°�sk3 `- .✓�Lu�W�' y,"�dk.`' _ �..w ..„�.rwL°_m..a.0,. y.n xrlL.a. �. Single family housing water demand assuming new stocks are built to Florida 24.30 25.69 27.31 29.15 Water Stars"'Gold criteria 45%demand reduction � y - 9�u r '"'"^t,n. r� ,ct m Fsnwr'S tea. fw r r� ry G�� r�_ I f”S � v^ e w r�S S' d"p x e. .' 'i are i.. .. ` , • ._,-, �w r t •r x Ig I VVr yi IW ?� li6 �El � 1€ Ty II ul�l ri dWr�R Mk �'> re,ww V r r i Cr VI IW n+le y'w"�dreay�p ,,� 5 rf' r n y 4 I PwNI a II P tlP y r w - _ c - 7 O re I II, f PACi��'I��II�INrewl I IGanria—€. , ." { w1111l ulll fr w` - - [ _ - pA 'il ".� t EW rW, �PNV VtioSt @� w nl d t ; 'w �^ ar u� re W 61+Sf btlili iw III IP�s Ez r liul ut i r.i, ' gf r I G7 idcr-_} ' rlr Ilr r1 -s^a k IPI' a S- y ' r: S �- w �;; re'P'..�... S iii.ry�I rIIIII�SrIk Nl4 i" v re l is -; VP1 INV I^"Wuu'VU r 1 v w 9 r A5%d: . , ® Q v .W , y�"°"• .. .r, .I r{ sk .�-. � � ��._�. �.�4I�. e �. .W°�,M„LI��.�au,.�. ^: �S: Iww�w�auun�P�le. a.Permanent resident population from Appendix A. b.Single family housing projections(units)are from The State of Florida's Housing,2009(White and Stroh 2010). c.Percent of water attributed to single family units is from Water Use in Florida,2005 and Trends 1950-2005(Marella 2008). I 2012 LWC Water Supply Plan Update Table 16. Potential water demand reduction in Collier County based on implementation of Florida Water Stars"' Permanent residentsa 341,565 366,442 396,202 430,761 471,999 • ,447 A 82,015 • - . Incremental housing increase` 5,568 6,661 7,735 9,230 Single family water demand 20.89 23.35 26.43 30.05 34.35 without Florida Water Stars"' Net-daiLy`five-year c an: single family water de i � • r " • - '1346 without Florida !...ter Single family housing water demand assuming new stocks are built to Florida Water Stars"' 22.49 25.35 28.78 32.85 Silver criteria 35%demand 14t,daily frve.y_ewrfchange in a single family water demarid " .• • .=,: trf assuming new stocks 2ra built Y' , r n,, ' 160 e0 5 s 35 � �2'g� • to Florida Water Star r' =_ fir. , • Silver criteria ,L N _ �r , a� '.. 35%demand reduction . r ; - SYStLU:a:..i F:si6�t:.Je...._._ .pare �ss:�Gia•..,...e-Single family housing water demand assuming new stocks are built to Florida Water Stars"' 22.24 25.04 28.42 32.42 Gold criteria 45%demand reduction Net daily five-year change in u, yzd 4 rrigle family water demand :_ ssu Ming new stocks a,re built T �1 M a ^]� ,„ es} A/ ,, - M P+ r,y .x3i .{i;w.�E 99 5. 37, f •i 7!f"/4 f , o Florida Water Star vv{ r1 P Gold criteria , s� r,; Y 45%demand reductlo Ym v a.Permanent resident population is from Appendix A. b.Single family housing projections(units)are from The State of Florida's Housing,2009(White and Stroh 2010). c.Percent of water attributed to single family units is from Water Use in Florida,2005 and Trends 1950-2005(Marella 2008). 98 I Chapter 4: Evaluation of Water Source Options Outdoor Use/Landscape Irrigation Nationally, 58 percent of average annual , water use is for outdoor purposes (Mayer et al. 1999), and 80-90 percent of outdoor water use is for landscape irrigation (USEPA 2011). Up to 50 percent of the water applied to urban landscapes is lost to wind, evaporation, and improper irrigation system design, installation, or maintenance with no direct benefit to the landscape (USEPA 2011).As one of the largest water uses in the LWC Planning Area, landscape irrigation has many water conservation Water Conservation Audit- opportunities. Outdoor water Irrigation Controller conservation has a dual objective: reduce the amount of water used and accommodate attractive and healthy landscaping. Demand reduction is possible through the use of efficient landscape irrigation measures, which include Florida-Friendly Landscaping'' principles, rain sensors, advanced irrigation technology, and proper irrigation system design and scheduling, and maintenance of automatic irrigation systems. Mandatory Year-Round Landscape Irrigation Conservation Measures The LWC Planning Area has been under three-day-per-week year-round landscape EXAMPLE irrigation restrictions since 2003. In 2005, Lee County adopted two-day-per-week Under a two-day-per-week watering irrigation limits within its jurisdictional schedule, the 44 largest utilities in the boundaries (Table 17). The City of Cape SFWMD saved an estimated 138 MGD over a Coral also adopted a two-day-per-week six-month period in 2007-2008 during an schedule based on numeric street address to emergency water shortage. As demonstrated reduce the impacts of peak demands on its in Table 18, utilities in Lee and Collier water delivery system. counties saved an average of nearly 28 MGD during periods of two-day-per-week Other municipalities in Lee County can irrigation, an average demand reduction of irrigate up to three times per week, in 24 percent compared with pre-water accordance with the SFWMD rule. Collier shortage demand levels, which already County has adopted a local watering reflected three-day-per-week irrigation limits ordinance limiting irrigation to three days in most areas. per week,only during morning hours. 2012 LWC Water Supply Plan Update 199 Table 17. Landscape Irrigation Rules within the LWC Planning Area Lee County yes 2 Local&SFWMD Collier County yes 3 Local&SFWMD On March 15, 2010, the Mandatory Year-Round Landscape Irrigation Conservation Measures Rule went into effect, following considerable input from various water use stakeholders, including utilities and large water users. These measures are codified in Chapter 40E-24,F.A.C. Broadly, this rule limits irrigation of existing landscapes to two days per week districtwide with no sprinkler irrigation allowed between 10 a.m. and 4 p.m.There is a provision for up to three-day-per-week irrigation in counties wholly located within the jurisdictional boundaries of the SFWMD, including Collier, Glades, Hendry, and Lee counties. The rule provides local governments across the region the flexibility to adopt alternative landscape irrigation ordinances that are at least as stringent as the SFWMD's rule. Counties or cities may limit irrigation to two days per week or adopt alternative irrigation days within their jurisdictional boundaries based on local demand patterns, system limitations, or resource availability. Irrigation using reclaimed water, cisterns, rain barrels, and various low volume methods,such as microirrigation,container watering,and hand watering with a hose equipped with an automatic shutoff nozzle,may be used at any time. The SFWMD estimates that implementation of the Mandatory Year-Round Landscape Irrigation Conservation Measures Rule may reduce overall potable water demand by up to five percent districtwide. This estimate is based on the Water Utilities Water Demand Reduction during the 2007-2009 Water Shortage (SFWMD 2009b) report. Potential water savings for the rule may be calculated as shown in Table 18. Demand projections for 2030 are derived from the PWS demand data in Chapter 2. Table 18. Estimates of possible impact of the Mandatory Year-Round Landscape Irrigation Conservation Measures Rule concerning potable water uses. Potable water use 63.00 114.31 54.11 75.76 Possible demand reduction with two-day-per- 12.33 week irrigation ordinance implementation 15.56(24.7%) 28.23 0 17,27 (22.8/0) Possible water demand with two-day-per- week irrigation ordinance implementation 47.44 86.08 41.78 58.49 a. Water Utilities Water Demand Reduction during the 2007-2009 Water Shortage Restrictions(SFWMD 2009b). b. Assuming irrigation water demand reductions experienced during the 2007-2009 water shortage remain consistent through 2030. 100 I Chapter 4: Evaluation of Water Source Options The SFWMD provides a model irrigation ordinance and technical support for local governments seeking to adopt an ordinance consistent with the rule. For additional information,see the Support Document. Florida-Friendly Landscaping" In 2009, changes to Section 373.185, F.S., replaced the term "XeriscapeTM" with "Florida- Friendly LandscapingTM" as the state's landscape design standard. The FDEP and the state's water management districts are complying with the statutory requirements by providing a model Florida-Friendly LandscapingTM ordinance, as well as technical support for local governments electing to adopt Florida-Friendly LandscapingTM ordinances. The FDEP and University of Florida's Florida-Friendly Landscape Guidance Models for Ordinances, Covenants, and Restrictions (FDEP and University of Florida 2009) is available from the SFWMD's Conservation website at http://www.savewaterfl.com under Governments/Utilities (see Guidance for Adoption of Florida-Friendly LandscapingTM Ordinances). See also Chapter 5 of the Support Document and the Florida-Friendly LandscapingTM website at http://www.floridayards.org. As part of the SFWMD's effort to lead other state and local agencies by example,the SFWMD has begun an effort to have all of its owned facilities achieve Florida-Friendly yard certification (Section 373.187, F.S.). Such landscapes follow and maintain Florida-Friendly LandscapingTM principles as outlined by the University of Florida's Institute of Food and Agricultural Sciences (IFAS) Florida-Friendly LandscapingTM Program. These are attractive, low impact landscapes that protect Florida's natural environment and wildlife. As of May 2012, nine SFWMD facilities have been certified by the IFAS under the Florida-Friendly LandscapingTM Program. Rain Sensors and Advanced Irrigation Technology In 2009, Section 373.62, F.S., was amended, requiring all automatic landscape irrigation systems to be fitted with properly installed automatic shutoff devices, regardless of the systems' installation date. These l I devices automatically override scheduled irrigation events when t sufficient moisture is present in the microclimate. Automatic shut-off devices include rain sensors as well as Rain Sensor more efficient advanced irrigation technologies, such as soil moisture sensors, evapotranspiration (ET) sensors, or weather- based shutoff devices. Advanced irrigation technology consists of irrigation system components that regulate the frequency or duration of irrigation events in response to site- specific conditions. 2012 LWC Water Supply Plan Update 1 101 Research in controlled settings confirms the water savings potential of properly installed and maintained automatic irrigation shutoff devices (Table 19) (Cardenas-Lailhacar et al. 2010). An IFAS study involving 59 residential homes in Pinellas County demonstrated that soil moisture sensor irrigation systems realized significant water savings compared with automatic inground irrigation systems incorporating rain sensors and timed irrigation controllers (Dukes and Baum-Haley 2009). Table 19. Reductions in irrigation water use based on device type versus systems governed by timers alone.' Device Percent Reductionb Weather Conditions Rain sensor Up to 34% Normal to Rainy Rain sensor Up to 15% Dry Soil moisture sensor 70-90% Normal to Rainy Soil moisture sensor 40-65% Dry ET-based sensors 60%or more Normal to Rainy ET-based sensors 40-50% Dry a.Cardenas-Lailhacar et al.2010 b.Two or three days per week Section 373.62, F.S., also requires licensed contractors who install or work on automatic r " irrigation systems to test existing shutoff devices for proper operation before completing other work 'y ; l ' • on the system and to replace any devices or switches that are not in proper working order. As ,1 +� directed in the legislation, water conservation ordinances must require contractors to report any ' + non-compliant property to the proper local authorities. In addition, ordinances must impose .I. minimum penalties for property owners and contractors who fail to comply. Funds generated by penalties imposed under the ordinance are to be ' used by the local government to further water conservation activities including the administration and enforcement of the ordinance. The law also provides a statewide process for obtaining a variance from the applicable water management district day-of-week watering restrictions for users Irrigation System Check of advanced irrigation systems meeting the specific requirements outlined in Subsection 373.62(7),F.S. Urban Mobile Irrigation Labs The Mobile Irrigation Laboratory (MIL) Program began in south Florida in 1989. The mission of the labs is to educate agricultural and urban water users about irrigation efficiency and to evaluate the performance of irrigation systems for potential water savings. See the Agricultural Use - Tools, Program, and Potential Savings section for information on 102 I Chapter 4: Evaluation of Water Source Options agricultural MILs. The Lee County Urban MIL was in operation until FY 2008. The 219 audits conducted in FY 2008 on 170 acres by this urban MIL identified potential water savings of 55.30 MGY or 0.15 MGD. The Big Cypress Basin Urban MIL has been in operation for a decade, and works with homeowner and condominium associations, and interested individual homeowners, to provide evaluations of landscape irrigation efficiency. It is a service provided by the Collier Soil and Water Conservation District under a contract with SFWMD Big Cypress Basin Board. Through this service, participants learn to use water more efficiently including the adjustment of on-site timers. A total of 480 audits were conducted during 2008-2011 on 549 acres of urban landscapes within the Big Cypress Basin, and potential water savings of 211.4 MGY(0.58 MGD)were identified. Outdoor Use/Recreational Irrigation Recreational/Landscape (REC) Self-Supply water use includes water to irrigate parks, athletic fields, golf courses, large landscaped areas (e.g., homeowner association common areas,and the areas around malls and office buildings), roadway medians,golf courses,and cemeteries.The demand for water used for this purpose generally increases at a rate similar to population growth. Florida-Friendly LandscapingTM and advanced irrigation technologies help minimize the demand increase. Golf Course Water Conservation DISTRICT As of 2010, 165 permitted golf courses were located within the LWC Planning Individual permit applicants for landscape and Area. The combined irrigated area of golf course irrigation projects shall develop and these golf courses is approximately implement a conservation program 25,253 acres, with an estimated annual incorporating the following mandatory elements gross irrigation demand of 51.4 MGD. (Sections 2.3.1 and 5.2.3, Basis of Review): Golf course irrigation accounts for e Use of Florida-Friendly LandscapingTM approximately 39 percent of the region's principles for proposed projects and total REC Self-Supply water demand. For modifications to existing projects where it is a summary listing of permitted golf determined that Florida-Friendly courses in the LWC Planning Area and Landscaping" is of significant benefit as a respective irrigation water sources, see water conservation measure relative to the Appendix E. cost of implementation. ♦ Installation and use of rain sensor devices, The Comprehensive Water Conservation automatic switches or other automatic Program calls for SFWMD staff to confirm methods that have the capability to override the use of appropriate irrigation the operation of the irrigation system when inhibiting technology, such as properly adequate rainfall has occurred is required. functioning rain sensors or soil moisture sensors, on existing golf courses. According to program guidelines, golf courses must also continue to employ best management and design practices, as well as adopt new irrigation technologies to improve landscape water use efficiency wherever feasible. 2012 LWC Water Supply Plan Update 1 103 The SFWMD partnered with the Florida Golf Course Superintendents Association to create an inventory of the types of irrigation scheduling technologies currently employed by south Florida golf courses for irrigation of their play areas.Together,the SFWMD and Florida Golf Course Superintendents Association developed an informal short survey tool to gather data from area golf course superintendents. The survey was distributed to approximately 400 south Florida golf course superintendents districtwide in 2010. Responses were received from approximately 25 percent of the survey recipients. Among other findings, the survey results suggest a growing trend toward the use of on-site advanced irrigation technology, and soil moisture sensors to help them make irrigation decisions.Superintendents of newer courses (less than 10 years old) were three times more likely to employ advanced technologies than superintendents of older courses, which mainly use rain sensor- based scheduling. The information collected will be used to develop programs that encourage water use efficiency in the golf industry and promote the water conservation practices many area golf courses follow. The SFWMD anticipates that increased widespread use of advanced irrigation technology, improved landscape design and management practices, and implementation of recognition programs will further optimize landscape water use efficiency in this sector. Industrial/Commercial/Institutional Use Self-Supply All applications for a consumptive use permit for ICI Self-Supply use must demonstrate that the volume requested is reasonable and relates to planned facility operations. The request must contain a water balance for the complete operation that includes the needs of the production process, personal needs of the employees and customers, and any treatment losses. ICI Self-Supply water use category permit applicants must submit a water conservation plan at the time of permit application. The water conservation plan shall be prepared, implemented, and at a minimum, incorporate the following mandatory components (Section 2.4.1,Basis of Review): ♦ A water audit for current operational processes ♦ Within the first year of permit issuance or audit completion, if found to be cost- effective,the following shall be implemented: - A leak detection and repair program - Recovery/recycling or other program providing for technological,procedural,or programmatic improvements to the facilities - Use of processes to decrease water consumption ♦ Develop and implement an employee awareness and consumer education program concerning water conservation ♦ Procedures and time frames for implementation 104 I Chapter 4: Evaluation of Water Source Options EXAMPLE MI li II,South Florida Water Management District In 2009, the SFWMD conducted indoor and outdoor water use assessments of its 12 facilities. The results of the assessments indicated the SFWMD facilities are generally well maintained, but also revealed specific opportunities for improvements at each facility. If all recommended improvements at the facilities are implemented, the SFWMD could save as much as 3.5 million gallons of water and $8,700 annually for a total investment of $63,000. The prescribed recommendations are expected to be implemented as regular maintenance over the next several years based on individual facility budgets. In August 2011, the SFWMD released the Water Efficiency Self-Assessment Guide for Commercial and Institutional Facility Water Efficiency Managers (SFWMD 2011b). This guide SELF-ASSESSMENT GUIDE was developed to walk facility managers for Cantonal and instinrt;anal Burldeg faddy Modnoyers through self-conducted water use assessment procedures, in a detailed step-by-step manner, for the most common points of water use at commercial or institutional facilities. The guide comprehensively covers both -- indoor and outdoor water use and is __ accompanied by a series of water use and savings calculators to help facility " II� _- managers quantify potential water — — _______w__ savings and investment recovery periods. By using this information rich South Florida Water Management Dsfict Water Supply Development Section guidebook, the user will immediately wn,Polm enorh fliridn become familiar with the general s,M.md,gov concepts of water use efficiency and conservation. The guide recently Water Efficiency Self-Assessment Guide for received the Florida Section of American Commercial and Institutional Facility Managers Water Works Association's 2011 Water Conservation Award for Excellence, Best in Class. Utilities are encouraged to incorporate this guide into their outreach efforts toward commercial and institutional water users. The manual and the companion water use and savings calculators are available free for download from the SFWMD's conservation webpage (http://www.savewaterfl.com) under"Businesses". 2012 LWC Water Supply Plan Update I 105 Water Conservation Hotel and Motel Program The Water CHAMP recognizes WATER CHAMP lodging facilities that have taken • steps to increase water use efficiency. Specifically, participating The Water CHAMP was originally launched by the properties conduct voluntary linen Southwest Florida Water Management District in and towel reuse programs and 2002. In 2010, the SFWMD introduced the Water install high efficiency (1 gallon per CHAMP in the Florida Keys. All materials to begin the minute) faucet aerators in guest program — the high efficiency faucet aerators, staff bathrooms. Participation in the training materials, linen reuse pillow cards, towel Water CHAMP supports the water reuse door hangers, and promotional materials for conservation criteria needed to join guests — were supplied to the property owners by the Florida Green Lodging Program, the SFWMD at no cost. Hotels may save up to 20 pending approval by the FDEP. gallons of water per occupied room per night. Actual Table 20 summarizes the Water water savings by program participants in the Florida CHAMP water conservation Keys was still being assessed at the time this plan potential for the LWC Planning Area. update was written. Table 20. Potential water savings of the Water CHAMP in Lee and Collier counties.' Lee County 9,205 4,245 4,960 21.7 Collier County 16,136 4,491 11,645 51.0 a i lI i I s ., 11 a. Source:Florida Department of Business and Professional Regulation(http://www.myfloridalicense.com/dbpr).Accounts for hotels,motels,resorts,and bed and breakfast properties. b. Potential savings over non-conserving lodging facilities built to current plumbing standards. In the LWC Planning Area, there are 16,605 potential Water CHAMP rooms after deducting the number of rooms in hotels and motels in the Florida Green Lodging Program. If all hotels in the LWC Planning Area not currently in the Florida Green Lodging Program become SFWMD Water CHAMP lodging facilities, approximately 72.7 MGY of potential water could be saved (assuming an annual occupancy rate of only 60 percent). Projecting potential savings of hotels and motels to be built may not be possible, as improved efficiency standards of future plumbing codes for new construction cannot be made with certainty. These standards affect the savings rates of individual rooms. In addition, the expansion of the Florida Green Lodging Program may also affect projected savings. 106 I Chapter 4: Evaluation of Water Source Options Power Generation Power generation requires large amounts of water for steam generation and cooling purposes. FPL has the only power generation facility in the LWC Planning Area (Fort Myers Energy Center). Nearly 78 percent of the water used at FPL's generating sites comes from non-potable water sources, such as oceans or estuaries. FPL also employs water reuse technologies such as cooling ponds and canals and cooling towers. These closed-loop technologies reduce their impacts to the aquatic environment by reducing the amount of water withdrawn. FPL's parent company, NextEra Energy, has reduced its fleetwide water withdrawal rate at power generating sites by more than 28 percent and reduced total water withdrawals by nearly 22 percent since 2007. Efficient water use comes from utilizing the best available technologies at power plant facilities,which is why,during the preconstruction planning process, FPL identifies the best available generating technologies in order to minimize impacts to air, land, and water. In addition to preconstruction design efforts, FPL develops site-specific plans and processes to ensure that once these projects are brought online, they are operated in a responsible and sustainable manner. FPL also works with the regional water management districts and other state and federal agencies to ensure that their water management plans and practices meet or exceed all statutory requirements. FPL recently began several modernization projects at existing sites using the newest natural gas combined-cycle technology including its Fort Myers facility. Modernizing older, less efficient power plants will result in an increase in power generating capacity; however,the design of these modernized facilities will ensure that total water withdrawal will either remain the same or decrease in the coming years and water withdrawal rates will decrease since these plants are more efficient. Other Urban Water Conservation Programs The SFWMD's Comprehensive Water Conservation Program consists of numerous efforts to promote water conservation by a variety of means. In addition to programs already described, the following programs are applied across user groups for either indoor or outdoor use. Water Savings Incentive Program The WaterSIP is the SFWMD's flagship funding assistance program. Through the WaterSIP program, the SFWMD provides 50-50 cost-share funding for implementation of water savings projects that reduce urban water use. The SFWMD provides matching funds up to $50,000 to water providers and users (i.e., cities, utilities, industrial groups, schools, hospitals, and homeowners associations) for water saving technologies.These technologies include low flow plumbing fixtures, rain sensors, fire hydrant flushing devices, and other hardware. 2012 LWC Water Supply Plan Update I 107 Local governments, businesses, and non-profit organizations may apply for WaterSIP funding annually during an open application period.Applications are reviewed and ranked based on established criteria that account for each project's water savings potential, cost efficiency, technological innovation, and other characteristics. Appendix E provides WaterSIP projects funded through 2012. Since its inception in 2003, the WaterSIP has supported 151 local water conservation projects, representing a total estimated water savings of approximately 2.6 billion gallons of water per year, at a $4.37 million cost to the SFWMD. In FY 2012, the SFWMD supported nine local projects at a total cost of$250,000. These projects represented more than 43.9 MGY in potential water savings. In the LWC Planning Area, the SFWMD allocated $627,456 for 23 projects funded from FY 2007 to FY 2012. These projects have an estimated potential savings of 178 MGY. Appendix E provides an overview of the specific projects funded in the LWC Planning Area through the WaterSIP to date including approved funding amounts and water savings estimates for each. Education, Outreach, and Marketing Education, outreach, and marketing are essential to accomplish a measurable change in water conservation and instill a lasting conservation ethic in south Florida businesses and communities. The SFWMD has supported the following programs, which are designed to build a water conservation culture, instill a stewardship ethic, and permanently reduce individual and commercial water use: ♦ Water Conservation Public Service Announcements ♦ WaterSense ♦ The Great Water Odyssey ♦ SFWMD Xtreme Yard Makeover ♦ SFWMD Water Conservation Website ♦ Big Cypress Basin Conservation Outreach ♦ Florida Atlantic University's Center for Environmental Studies ♦ Teacher Training ♦ Loxahatchee Impoundment Landscape Assessment ♦ Florida Gulf Coast University's Wings of Hope ♦ Student Field Study Programs and Service Learning at DuPuis Management Area ♦ Everglades:An American Treasure More information about each of these programs is provided in the Support Document. 108 I Chapter 4: Evaluation of Water Source Options Potential Urban Water Savings The SFWMD advocates the adoption of local building ordinances that incorporate the WaterSense and ENERGY STAR fixture and appliance standards and/or follow the Florida Water StarSM or Leadership in Energy and Environmental Design building criteria. For example, the Toho Water Authority requires all new single family homes be built to Florida Water StarSM standards. In turn,the Toho Water Authority offers a free Florida Water StarSM inspection and developers receive a 20 percent rebate on the utility connection fee following the execution of a developer service agreement. Water savings resulting from residential indoor retrofits were estimated for Lee, Collier, Hendry, Charlotte, and Glades counties using county parcel and population data, and a methodology similar to that used by Conserve Florida Water Clearinghouse's EZ Guide (2009). These estimates include, but do not isolate, potential savings derived from DSS water users. Table 21 shows the number of residential dwelling units in Lee, Collier, Hendry, Charlotte, and Glades counties in the single and multiple family water use sectors, further divided by plumbing code era. Estimates of total potential water savings for each subsector are also provided. This planning-level information can help planners and water conservation professionals identify areas with the greatest savings potential from retrofit and water conservation initiatives,and quantify potential savings at the local level. These data assume all homes have replaced all older fixtures and appliances with newer efficient ones and reflect the full theoretical potential savings available in each county. Current water use and savings for residences in each year built/plumbing code era were calculated using standard use frequency rates for each appliance and plumbing fixture (Vickers 2001) and average persons per household figures for each county (BEBR 2010). The number of residential units in each plumbing code era and water use sector was obtained from the Florida Department of Revenue's parcel data sets. Natural replacement rates of fixtures and appliances were taken into account (Maddaus Water Management 2009, NAHB and Bank of America Home Equity 2007). Savings figures do not account for replacements of fixtures or appliances that may have occurred as a result of past local conservation programs and do not reflect theoretical program or market saturation rates. Therefore, these data are meant to aid program planning and design, but not to serve as numerical objectives. Savings resulting from water conservation efforts targeting outdoor water use are more difficult to estimate. By using Florida-Friendly Landscaping'M principles and improving irrigation efficiency through the use of advanced irrigation technology,such as rain and soil moisture sensors, an estimated water savings of 35 percent can be realized (Cardenas- Lailhacar et al. 2010, McCready et al. 2009, Pottorff et al. 2010). A typical quarter-acre lot equipped with a five-zone irrigation system irrigating for 30 minutes per zone uses approximately 2,250 gallons per irrigation event.A savings of 35 percent would amount to approximately 82,000 or 123,000 gallons of water per year for each property irrigating two or three times per week,respectively. 2012 LWC Water Supply Plan Update 1 109 Table 21. Residential units in Lee County and potential savings of indoor water use through water conservation. 1 d,9 kr lu Y _, _m,md.. +Ery°uw�,.rEN�'�� Pre-1984 70,450 1,973.0 13,198 369.6 1984-1994 46,657 915.5 9,180 180.1 Post-1994 102,541 959.3 19,601 183.4 mrr 'd r ,31 >t r u k r W - ,.:"#. F�'i'�k a Ky n ..� wr r���f s fi"l � �+ � ." -, -nom %'" � Pre-1984 24,292 710.03 6,155 179.9 1984-1994 18,566 380.2 3,073 62.9 Post-1994 39,697 387.6 3,311 32.3 {Rp r��uN�l IfIIIW ���9d��i �d b{.I_V x �,� o-�.ea-„ �,➢u . r�1 s u m +� r�” ' '1 I 1 t k !'P'1 r L � Pre-1984 3,780 139.6 -- -- 1984-1994 2,671 69.1 -- -- Post-1994 2,360 29.12 -- -- qv t ash °` a ,rh, 'IXti4'In,a"„ aIM1RIVR, Ws a W1 '' 3 �rx - ` a _ Irkr �r� Pre-1984 71 1.9 13 0.3 1984-1994 68 1.3 26 0.5 Post-1994 76 0.7 '9 1r 7 0r�Ivllru.2 kl11 Pre-1984 844 25.5. 140 4.2 1984-1994 525 11.1 53 1.1 Post-1994 741 7.5 26 0.3 a. High efficiency water use rates are as follows:toilets 1.28 gallons per flush,showerheads 2 gallons per minute,faucets 1 gallon per minute,dishwashers 4.5 gallons per load,and clothes washers 16 gallons per load. An exact quantification of countywide outdoor water use and savings cannot be made directly through parcel data alone; however, if the number of residential units falling within the as-built plumbing code era is known, planners in the LWC Planning Area can estimate the water conservation potential of outdoor water use. Planners who are familiar with the area should be able to estimate the typical lot size and the prevalence of automatic irrigation systems for each of the plumbing code eras. Water consumption within the ICI Self-Supply water use category has been correlated to square footage of building space under climate control (heating ventilation and conditioning, referred to as heated area) (Morales et al. 2009). Efficiency improvements in this water use category have been shown to produce water savings from 15 to 50 percent, with 15 to 35 percent being typical (Dziegielewski et al. 2000). Industrial operations may 110 I Chapter 4: Evaluation of Water Source Options see similar savings.Using Florida Department of Revenue parcel data,which include square footage of heated area, and water use per square foot of heated area coefficients, estimates of water use and potential savings (in MGY) for the ICI Self-Supply water use category are provided for Lee,Collier,Charlotte,and Glades counties in Table 22. Table 22. Estimated water use and potential savings through improved water use efficiency within the ICI Self-Supply water use category. Lt,„v ,ky y C yy sJ i'rl q �' 4 k r1.ia .. Ybd-Lx.-a:�w�J e."uu&..a'�`'J.�6UilL+�WIIWYU miw"3 SFV14o.$iWr"4'�.°�.{ ICIkV]uuu�w.x.�.l Ig�.IILy uJC45N.de''w�s.W� Industrial 30.4 477.3 71.6-167.0 Commercial 63.3 3,058.8 458.8-1,070.5 Institutional 36.2 1,187.5 178.1-415.6 ,vs re � V m � r9I�I�I+. ayi "imvw+r " IV dip d "y"F'r' x, r III,III�;."I �tirE + CII s+ I"1 ,Irm rI�&S,II�I r a ^';h kr:1�r�o 1 s Y" wr I��rra� k I'T'V�ill'.I z 3i -e' 1 in ry�11� r 61f, .udv.�.re°+�..Su'ilil�" ter V , ze � � Industrial 9.9 155.7 23.4-54.5 Commercial 74.7 3,610.4 541.6-1,236.6 Institutional 23.6 772.2 115.8-270.3 �� tiwll+~I4�IF Ire r 7 k`Ar Br - n an 11� t- V rI - ij ;l l r^9 wl l 7 i k x y II I S � ' IL' 'Y l d = $ X14 � ��s r # �W�1�."� :�k rzE„�,:5... �-a"",1������. ��idrluvd , �a .�a1wy.�,,�.�� d.� � Industrial 0.021 0.30 0.050-0.100 Commercial 0.003 0.20 0.020-0.050 Institutional 0.004 0.01 0.002-0.004 £ „9, �. R.r. 4 41: a l W Industrial 0.15 2.4 0.4-0.9 Commercial 0.34 16.6 2.5-5.8 Institutional 0.30 9.3 1.4-3.2 a. Aggregate coefficients for converting square footage to water use are 1.31 gallons per square foot per month for industrial, 4.03 gallons per square foot per month for commercial,and 2.73 gallons per square foot per month for institutional. b. 15-35 percent potential reductions of current estimated water use. The residential and non-residential water use and potential savings in the LWC Planning Area are highest in Lee and Collier counties (Table 22). These counties represent an estimated potential savings of 5,289 MGY and 2,434 MGY,respectively,using the 15 percent estimates for the non-residential sectors. The combined estimated potential savings for Charlotte,Glades,and Hendry counties totals 297 MGY. Appendix E includes a comparison of water conservation measures and alternative water supply development. 2012 LWC Water Supply Plan Update 1 111 Maximizing Water Savings Table 23 summarizes potential water use savings in the LWC Planning Area based on the following assumptions: ♦ High efficiency fixtures are implemented by both single and multiple family residential units. ♦ Measures to realize a 15-35 percent reduction in water use are implemented by all ICI Self-Supply equivalent square footage. Table 23. Summary of potential savings of the ICI Self-Supply water use category and residential indoor water use through water conservation. „i! it G 641ti"lyµq! ,. iP r.i 4I'P! mw u.N. { r ,lµu . t 7 & d � �� tr�..� Iry"1- III II ^ ! fl •§ �swr �n mgt ....µc I� ..I.�'a�u'��WV��N�IL+,�:�y.:�.�,�« wlaa�lulaJ3..a...�,.�a�y"!,taus..:..ar, �ma��at^w�;u[uWi Pre-1984 1,973.0 710.0 1.9 25.5 139.6 1984-1994 915.5 380.2 1.3 11.1 69.1 Post-1994 959.3 387.6 0.7 7.5 29.1 ,11,0M v ^ I f 44M, 1 ' � v aar7 1 1p P ro hy�^ !s ' 4 ' 7,a*4,��1'§ Pre-1984 369.6 179.9 0.3 4.2 NAb 1984-1994 180.1 62.9 0.5 1.1 NA Post-1994 183.1 32.3 0.2 0.3 NA Total Residential 4,580.6 1,752.9 4.9 49.7 237.8 Savings Industrial 71.60 167.00 23.40 54.50 0.050 0.100 0.40 0.90 NAb NA Commercial 458.80 1,070.50 541.60 1,236.60 0.020 0.050 2.50 5.80 NA NA Institutional 178.10 415.60 115.80 270.30 0.002 0.004 1.40 3.20 NA NA ��pY'.x v1'r�,b terr r. -71 Fes_+ I 4!1!� .✓.'... .i....,. .' :'?„111 7 I!u a. For the purposes of this table,Hendry County has negligible multiple family ICI Self-Supply uses. b. NA-not applicable The estimated water use reductions in Table 23 assume 100 percent participation in conservation activities for the ICI Self-Supply water use category and residential indoor water use. These numbers are meant to illustrate maximum potential water savings based on a particular set of assumptions and are not intended to serve as a realistic objective. 112 I Chapter 4: Evaluation of Water Source Options Agricultural Use —Tools, Programs, and Potential Savings Agriculture remains the largest water user in the LWC Planning Area. As . such, the AGR Self-Supply water use category offers significant water conservation potential. In the consumptive use permitting process, water allocations for agriculture are based on a number of factors, including the crop type, growing and irrigation methods, and site-specific parameters such as soil type and anticipated rain. Because a number of Agricultural Irrigation these factors are fixed, demand reduction must be based on aspects ' that can be changed, such as irrigation and growing methods. Generally, these types of changes are expensive and require careful planning and consideration. Citrus growers continue to increase their irrigation efficiency.Approximately 98 percent of the citrus acreage in the LWC Planning Area is irrigated using low volume systems, and the remaining two percent uses flood irrigation or traditional spray irrigation (sprinklers). For certain crops, such as citrus and container nursery, the SFWMD requires new consumptive use permit applicants to use low volume irrigation or other systems of equivalent efficiency whose irrigation systems are not constructed (Section 2.3.3.3.1, Basis of Review). Flood/seepage irrigation type systems are typically used for tomato, corn, rice, and sugarcane production. While these types of irrigation are not as efficient as microirrigation,flood irrigation does provide some recharge to the SAS. Agricultural Best Management Practices Agricultural BMPs are actions agricultural businesses can take to protect or improve water quality or quantity while maintaining or even enhancing agricultural production. The Florida Department of Agriculture and Consumer Services (FDACS) and the FDEP develop and adopt BMPs by rule for different types of agricultural operations. Most BMPs in the region are established to improve water quality; however, some contain an implicit water conservation component. Tailwater recovery and irrigation efficiency are BMPs identified as having implicit water conservation benefits. Tailwater recovery is a planned system to conserve irrigation water supplies through the capture and recycling of water that runs off the field while also improving off-site water quality. This system normally includes a combination of practices and equipment that collects, conveys, stores, and recycles irrigation runoff water for reuse.Common components include pickup ditches, sumps, pits, pumps, and pipelines. Data were not available for the tailwater recovery BMP program for inclusion in this plan update. 2012 LWC Water Supply Plan Update 1 113 Irrigation efficiency is defined as the proportion of the water that is beneficially used to meet the crop's water demands. Irrigation efficiency can be improved by either replacing an irrigation system or by optimizing the operations and maintenance of an existing irrigation system.The selection of a new system depends on the type of crop, soil, water source, and water availability. A review of irrigation scheduling — time between irrigation events and amount of water applied—might result in an increase of irrigation efficiency. Growers and ranchers in the LWC Planning Area commonly rely on visual inspections and climatic conditions such as rainfall gauges, ET, and weather forecasts to schedule their irrigation. Many farmers use soil moisture sensors to understand soil conditions for particular fields and crops. Soil moisture sensors can be valuable tools for agricultural irrigation scheduling. Agricultural Mobile Irrigation Labs Agricultural MILs evaluate the performance of irrigation systems and encourage the adoption of efficient irrigation management practices that conserve water. The LWC Agricultural MIL is managed and administered by the Collier County Soil Water Conservation Service. Funds are traditionally provided by the FDACS and the SFWMD. More information about the Agricultural MIL Program is provided in the Support Document. Real-time Weather Data—Florida Automated Weather Network The Florida Automated Weather Network (FAWN) provides weather information from a number of locations throughout the state at 15-minute intervals and is operated by the University of Florida's IFAS. The FAWN management tools provide decision support functions to growers,using historical weather data and crop modeling technology to help in short- and long-term planning, thereby maximizing the efficiency of their irrigation practices. In the LWC Planning Area,the IFAS maintains weather stations in Immokalee,Palmdale,and Clewiston. When funds are available, the SFWMD plans to assist in expanding the scope of this network within the LWC Planning Area. Access to the network is available from http://fawn.ifas.ufl.edu/data/. Environmental Quality Incentives Program The Environmental Quality Incentives Program (EQIP), implemented through the United States Department of Agriculture - Natural Resources Conservation Service, was reauthorized in the Farm Security and Rural Investment Act of 2002 to provide a voluntary conservation program for farmers and ranchers. The program promotes agricultural production and environmental quality as compatible national goals. Financial and technical assistance is offered for eligible participants to install or implement structural and management practices that address impaired water quality and conservation of water resources on eligible agricultural land. For example, reduction of soil erosion and sedimentation can have a positive impact on water quality and improve irrigation 114 I Chapter 4: Evaluation of Water Source Options efficiency. During FY 2009 and FY 2010, in the LWC Planning Area, 28 farms, covering 34,348 acres, and 37 farms, encompassing 46,181 acres, participated in the program,respectively. Potential Agricultural Water Savings Agricultural crops in the LWC Planning Area include citrus, sugarcane, vegetables, nursery, and sod. Ninety- eight percent of citrus acreage is irrigated by low volume systems,and the remainder is irrigated using flood irrigation or spray irrigation (sprinklers). Sugarcane is irrigated exclusively with flood/seepage systems. Most vegetables grown in the region use seepage irrigation while some use low volume systems. Some crops are grown Sugarcane Crop with a combination of flood and low volume systems. Details about crop irrigation are provided in Appendix A. Alternative Water Supply Projects Although water conservation helps to reduce or defer development of new water production capacity,in most cases,new water supplies will also be needed to accommodate the region's growth in the future. Through Florida's Water Protection and Sustainability Program, funds provided by the state are matched dollar for dollar with SFWMD funds for Alternative Water Supply Funding Program projects. Up to 40 percent of a project's construction cost can be funded through this program to qualified applicants seeking cost- sharing assistance. For the 2007-2012 period, the SFWMD, in cooperation with the State of Florida, provided more than $123 million in alternative water supply funding for 212 projects, with 78 projects occurring in the LWC Planning Area. Between FY 2007 and FY 2012, water supply development projects funded by the Alternative Water Supply Funding Program in the LWC Planning Area have created a total of 104 MGD of new water capacity. The new sources of this water include 37 MGD of brackish water, 33 MGD of reclaimed water, 16 MGD of Hawthorn Aquifer water, 3 MGD of ASR water, and 15 MGD of surface water/stormwater and other projects. For more information on local governments proposed water supply development projects for this plan update,see Chapter 6. 2012 LWC Water Supply Plan Update 1 115 Water Conservation Summary Cooperative water conservation efforts among water users,utilities,local governments,and the SFWMD are also necessary to accomplish water savings. The SFWMD will continue to track the progress of utilities and municipalities developing sources to meet future demands, but funding is not anticipated to return to preFY 2009 levels for some time. For this reason, demand reduction is important and necessary. The SFWMD intends to effect long-term reductions in water consumption across all water use categories by promoting and implementing many of the water conservation measures and the Comprehensive Water Conservation Program initiatives presented in this chapter. Appendix E of this update includes the status of water conservation implementation,water conservation rate structures, water conservation versus development of additional water supplies, goal-based water conservation plans and associated water sources/irrigated acreage,and the WaterSIP projects. 116 I Chapter 4: Evaluation of Water Source Options Water Resource Development Projects The role of the South Florida Water Management District (SFWMD) in water supply is primarily planning and water TOPICS resource development (Section 373.705, Florida Statues [F.S.]). This chapter addresses the functions of the SFWMD and other Regional Projects parties in water resource development projects and provides a ♦ Districtwide Projects summary of projects in the Lower West Coast (LWC) Planning a Summary Area.This document uses the Fiscal Year (FY) 2012 budget as a base and includes the schedules and costs of water resource development projects by category for FY 2012 to FY 2016. Florida water law identifies two types m of projects to meet water needs: water LAW / CODE Ea resource development projects and water supply development projects. Water resource development is defined in Water resource development projects Subsection 373.019(22), F.S., as "the formulation are generally the responsibility of and implementation of regional water resource water management districts. These management strategies, including the collection projects support water resource and evaluation of surface water and groundwater development and are intended to data; structural and non-structural programs to ensure the availability of an adequate protect and manage water resources; the supply of water for all competing uses development of regional water resource deemed reasonable and beneficial, implementation programs; the construction, including maintaining the functions of operation, and maintenance of major public works natural systems. Water supply facilities to provide for flood control, surface and development projects are generally the underground water storage, and groundwater responsibility of local users, such as recharge augmentation; and related technical utilities, and involve the water source assistance to local governments and to options described in Chapter 4 to government-owned and privately owned provide water to users. Water supply water utilities." development projects are discussed in Chapter 6. Although water resource development projects serve an important supporting role for water supply development projects,by themselves these projects often do not yield specific 2012 LWC Water Supply Plan Update 1 117 quantities of water. For example, hydrogeologic investigations, groundwater monitoring, and numerical modeling provide important information about aquifer characteristics, such as hydraulic properties and water quality, but do not generate water. These efforts help quantify water resources that may be available and are useful in developing appropriate facility design, estimating sustainable yield, and evaluating the economic viability of water supply development projects. Water resource development projects include well drilling and aquifer testing, groundwater and evapotranspiration (ET) assessments, groundwater and wetland monitoring, districtwide feasibility studies, numerical modeling, water conservation, Minimum Flows and Level (MFL) criteria, and Water Reservations. Water conservation encourages the efficient use of water so that what has been saved can be used to meet potential future demands. In effect, water conservation may expand current water supplies. The water resource efforts in the LWC Planning Area presented in this chapter reflect the current budget categories the SFWMD uses for funding both new and ongoing water resource development projects. Information about the status of these projects and implementing entities is also included. Annual updates on the status of water resource development projects are provided in Chapter 5A: Five-Year Water Resource Development Work Program (Hopper 2009, Martin 2010, 2011, 2012) of the annual South Florida Environmental Reports-Volume II available at http://www.sfwmd.gov/sfer. REGIONAL WATER RESOURCE DEVELOPMENT PROJECTS The SFWMD funds water resource development projects such as hydrogeologic studies that provide greater understanding of the aquifers and the potential for additional water for permit holders in the j Fi r' planning area. The SFWMD also uses �;+�`� ' +��► ' numerical models to evaluate groundwater ,�- >�f 7f" and surface water resources. Some projects 4 are co-funded with local, state, and 4111, federal agencies. Monitor Well Drilling Hydrogeologic Investigation of the Top of the Sandstone Aquifer In 2010, due to declining water levels and reported well problems in the Lehigh Acres area of Lee County and insufficient geologic information in that vicinity, a drilling project was completed by the SFWMD to establish elevations of the top of the Sandstone aquifer in the intermediate aquifer system (IAS) at two existing monitoring sites. Drilling, coring, and geophysical logging were performed to determine aquifer elevations for the maximum developable limits (MDLs) at these two locations. During 2011, documentation of the drilling and coring at the two Sandstone aquifer wells adjacent to monitoring wells L-2186 118 I Chapter 5:Water Resource Development Projects and L-729 were completed to better develop lithologic descriptions of the aquifer, which will be used in defining the top of the aquifer.These efforts and the results for other drilling in the area demonstrate that the hydrogeology is variable and data from a site cannot be used to establish the elevation of the aquifer at a different location. As the top-of-aquifer elevations are used in determining the Sandstone aquifer's associated MDLs, the study needs to be expanded to account for variability and provide a more comprehensive understanding of the aquifer. Numerical Models Computer models developed by the SFWMD support development of water supply plans, MFLs, Water Reservations, and projects in the SFWMD's four regional planning areas. Collier and Lee counties and the City of Cape Coral have developed numerical groundwater flow models to address their particular needs. Modeling tools developed by MWH Global, Inc. (2008a) for Cape Coral and by RMA GeoLogic Consultants, Inc. (2007) for Lee County may be incorporated into or adapted to future SFWMD modeling efforts. Information about other SFWMD modeling efforts can be found in the regional water supply plan update for each planning area or on the SFWMD's website at http://www.sfwmd.gov (click"Scientists and Engineers" and then click "Modeling."). The modeling effort the SFWMD is currently performing in the LWC Planning Area is discussed next. Lower West Coast Floridan Aquifer System Model The Lower West Coast Floridan Aquifer System Model (LWCFAS) Model is a groundwater simulation model that uses the United States Geological Survey (USGS) SEAWAT-2005 code to numerically represent the hydrology of the region, nearshore portions of the Gulf of Mexico, and Florida Bay. The LWCFAS Model focuses primarily on the various production zones comprising the Floridan aquifer system (FAS) within the study area in Charlotte, Glades, Lee, Hendry, and Collier counties, as well as the Mid-Hawthorn aquifer of the IAS. The main advantage of this model is its ability to include the effects of fluid density in calculating hydraulic head,groundwater flow,and chloride concentration in the system on a continuous time series. Boundary interactions and stresses from internal sources and sinks are used to simulate transient hydrologic conditions. During FY 2008, the SFWMD retained three independent groundwater modeling experts to conduct a technical peer review of its draft LWCFAS Model. Independent peer reviews are conducted per policy direction to ensure that models are developed under established groundwater modeling procedures and meet industry standards. The peer review panel completed its report in August 2008 and the SFWMD began the process of incorporating the panel's recommendations. The revised model is expected to be used as a tool to evaluate potential water quality changes in the IAS and FAS due to the cumulative withdrawals of existing and future water users and may be able to determine long-term availability of this water source. During 2011-2012, the calibration of the model was completed and peer review recommendations based on the previously developed steady-state model were implemented.A technical manuscript summarizing the model was published in FY2012 and 2012 LWC Water Supply Plan Update 1 119 placed in the SFWMD's Library of Models for future application. Once models are peer reviewed and comments are addressed, the updated model's documentation is downloadable from the SFWMD website, and electronic model input files are available upon request. Lower West Coast Surficial Aquifer System Model The Lower West Coast Surficial Aquifer System (LWCSAS) Model was developed for the SFWMD by Marco Water Engineering, Inc. (2006) to simulate groundwater flow and water levels in the surficial aquifer system (SAS) in the LWC Planning Area. The LWCSAS Model was developed using the industry-standard Modular Three-dimensional Finite-difference Groundwater Flow Model (MODFLOW) computer code to evaluate this traditional source of fresh groundwater supply. This model needs to be updated to include the IAS and will then require a peer review that is tentatively scheduled for FY 2014. This model examines the potential impacts of existing and future groundwater withdrawals from the SAS and IAS. Other Efforts Efforts initially cited in the 2005-2006 Lower West Coast Water Supply Plan Update (2005- 2006 LWC Plan Update; SFWMD 2006) fall under the auspices of the Comprehensive Everglades Restoration Plan (CERP), the Caloosahatchee River Watershed Protection Plan, and other local initiatives. Chapter 4 of this document includes discussions about the Big Cypress Basin's and the East County Water Control District's water source options. DISTRICTWIDE WATER RESOURCE DEVELOPMENT PROJECTS Projects encompassing more than one planning area are considered districtwide projects. Table 24 at the end of this chapter summarizes the estimated costs and time frames for completion of the described districtwide water resource development projects. Aspects specifically pertaining to or having relevance to the LWC Planning Area are identified within the context of these districtwide projects. Table 24 does not include other programs with water resource development components,such as the CERP and Big Cypress Basin projects, which are primarily budgeted as ecosystem restoration projects. 120 I Chapter 5: Water Resource Development Projects Hydrogeologic Assessment and Monitoring Well Drilling and Aquifer Testing Program This program provides an improved understanding of the geology and hydrogeology of the aquifers in south Florida as new exploratory or test wells are constructed. This hydrogeologic information is used to assess groundwater availability and support other projects. In addition, increased understanding has improved the accuracy of groundwater modeling and decision making regarding the approval of consumptive use permits.Sites for new drilling and testing are selected based on need.This program provides new data about aquifer parameters, improves the characterization of aquifer systems, and helps quantify hydraulic responses to stresses such as pumping. These data help produce more accurate modeling results and provide increased knowledge for water supply development and management. Full documentation of each well site, including location, well construction details, geophysical logging, and aquifer testing data, is provided in SFWMD technical publications. Data are also loaded into the hydrogeologic portion of the SFWMD's corporate environmental database, DBHYDRO, available from the SFWMD website at http://www.sfwmd.gov/dbhydro. Groundwater and Evapotranspiration Assessments Over the years,a number of specialized hydrogeologic and ET studies have been completed by the USGS in cooperation with the SFWMD. The information afforded from these studies enhances the understanding of groundwater conditions and ET rates across the SFWMD. Typically, each project requires several years of effort by the USGS, including rigorous analysis of the data. Some projects were conducted in cooperation with other water management districts or other governmental agencies. The USGS reports, maps, and data are peer reviewed, respected, and considered valuable references for groundwater modeling and environmental assessments,as well as for policy and decision making. USGS/SFWMD Evapotranspiration Study In FY 2012, the USGS completed its multiyear ET study. The study's objective was to determine ET rates over pine uplands, marshes, wet prairies, and cypress stands in south Florida, presenting a broader representation of ecological communities than previously investigated. These data are used to better estimate ET rates in regional numerical modeling efforts, for example. Three years of simultaneous data collection at five stations were completed in 2010.Following quality assurance/quality control of the data by SFWMD staff, finalized data was uploaded to DBHYDRO (http://www.sfwmd.gov/dbhydro) with the final study report published in December 2011 by the USGS available at http://pubs.usgs.gov/sir/2011/5212/. 2012 LWC Water Supply Plan Update 1 121 Transport and Reaction Simulation Engine for Modeling of Water Quality A FY 2009 study developed water quality modeling components and applied these components to the SFWMD Regional Simulation Model.As a result of this study, a spatially distributed water quality model for phosphorus transport and cycling in wetlands was developed for application throughout the SFWMD Uawitz et al. 2008). Saltwater Intrusion Monitoring and Saltwater Interface Mapping In August 2011, the SFWMD completed maps that estimate the position of the freshwater- saltwater interface in the Surficial, Lower Tamiami, Sandstone, Mid-Hawthorn, and Lower Hawthorn aquifers in Lee and Collier counties based on chloride data obtained in April-May 2009 (i.e., the end of the dry season). The maps were based on measured or estimated chloride concentrations in water samples from three primary sources: 1) wells from consumptive use permittees from the SFWMD Water Use Regulatory Database 2) USGS wells,and 3) SFWMD wells. Note that wells with no chloride data from May-June 2009 due to technical difficulties will also be used to assist in future map preparation, as will wells installed by others in the future.The maps are provided in Appendix F. Review of previous freshwater-saltwater interface maps prepared in south Florida indicated that the interface is dynamic but has not moved appreciably over time, due in large part to coastal salinity control structures maintaining adequate freshwater heads. Given this fact, it is recommended that maps be prepared every 3 to 5 years.This will allow for comparison with previous maps so that the progression of the saline front within the aquifers can be tracked over time. Each time maps are prepared, the data sources noted above will be compiled and analyzed. Hydrogeologic Investigation of Aquifer Systems in Highlands County A hydrogeologic and water quality investigation of the SAS, IAS, and FAS in Highlands County was completed by the USGS in 2010. The resulting report, Hydrogeology and Groundwater Quality of Highlands County, Florida (Spechler 2010), enables water resource managers to better evaluate current hydrologic conditions, define present day baseline conditions, and identify additional hydrologic data needs. The findings from this investigation provide new insights into regional groundwater flow patterns within the IAS and FAS,which provide lateral recharge to the LWC Planning Area. According to the study, the Lake Wales Ridge cuts through the county. West of the ridge, groundwater flow is southwest, while flows east of the ridge are toward the Kissimmee River.The groundwater flows to the southwest have the potential of affecting the northern portion of the LWC Planning Area as Highlands County is bordered by Glades County to the south and Charlotte County to the west. Both of these counties are partially located in the LWC Planning Area. In general, the study reports the groundwater resources of Highlands County is of good chemical quality and is of sufficient quantities for present and future needs. Additional studies on the quantity and quality of the groundwater resources in the 122 Chapter 5:Water Resource Development Projects county are warranted because of the expected continued growth in both population and agriculture in Highlands County and adjacent counties. Surface and Groundwater Monitoring To understand the current conditions and monitor changes, the SFWMD has an 111 extensive groundwater and surface water monitoring program. SFWMD staff conducted a query of the SFWMD's 1. DBHYDRO database for monitoring stations { active as of January 1, 2012 on July 19, 2012. •4 The query revealed 1,249 surface water stations and 760 groundwater stations districtwide. Of these numbers, there were 298 surface water stations and 157 wells in Lee, Collier, Glades, and Hendry counties Floridan Aquifer Well Screen Installation combined. Some sites are owned and maintained by the SFWMD, some are private wells whose owners allow the SFWMD to perform monitoring, and some belong to other agencies, such as the USGS and the United States Army Corps of Engineers (USACE). Monitoring sites are located throughout the SFWMD in all of the aquifers. Surface water sites are located in wetlands, lakes, canals,and headwater and tailwater areas of water control structures. Historical surface water stage time series data from the SFWMD and other external government agencies are available in DBHYDRO. The SFWMD maintains this extensive network of monitoring sites,most of which date back several decades,and archives the data in its DBHYDRO database. Data from sites monitored by the USGS are published annually.Lee and Collier counties maintain their own monitoring site networks. Monitoring of groundwater levels and water quality provides necessary information to develop and calibrate numerical models. In addition, groundwater and surface water monitoring supplies data to better understand trends, aquifer response to varying climatic conditions,pumpage over time,and the effects of changing water levels on natural systems. Feasibility Studies The SFWMD has performed feasibility studies to determine the viability of water resource development options to increase water supply through water resource alternatives. These efforts involved collecting and analyzing data and numerical modeling. The SFWMD recently funded several studies, including the St. Lucie and Indian River Counties Water Resources Study (HDR Engineering and HSW Engineering, Inc. 2009), the Water Desalination Concentrate Management and Piloting Study (Carollo Engineers, Inc. 2009), and water reuse pilot projects partnering with the City of Plantation and the City of Sunrise as separate initiatives (Hazen and Sawyer 2008,MWH Global,Inc.2008b). 2012 LWC Water Supply Plan Update ( 123 Water Desalination Concentrate Management and Piloting Study This study was conducted to evaluate ways to increase treatment efficiency, decrease desalination concentrate by-products, and identify affordable and sustainable brackish water treatment technologies in south Florida (Carollo Engineers, Inc. 2009). The overall goal of the study was to evaluate alternatives for concentrate minimization in south Florida and provide recommendations through identification of affordable and sustainable treatment technologies. The study provided a systematic evaluation of a concentrate minimization approach, which demonstrated its feasibility as a representative brackish water treatment. Existing treatment schemes for four representative reverse osmosis (RO) facilities were evaluated and four promising approaches for concentrate minimization were broadly evaluated for these facilities in terms of several economic and non-economic criteria. The evaluated concentrate minimization approaches included 1) dual RO system with intermediate chemical precipitation, 2) brine concentrator and evaporation ponds, 3) brine concentrator and crystallizer,and 4) salt recovery and extraction.The dual RO process with intermediate chemical precipitation was selected as the preferred approach for inland desalination plants within the SFWMD. The total treatment cost with this approach was estimated to be about half that of product water generated with a brine concentrator approach. Because of the similarity of the recovery limiting salts at most of the inland brackish water plants in the SFWMD, a common solution to concentrate management/minimization can likely be applied at multiple plants. Natural Systems Protection PROTECTION Minimum Flow and Level Activities Minimum Flow and Level Criteria The SFWMD develops MFL criteria MFL technical criteria are important management for specific water bodies to protect tools used by the SFWMD to protect major water these water bodies from significant bodies from significant harm due to reduction in harm due to a reduction in water water levels or flows. These criteria provide a basis levels or flows. A Priority Water for defining the point at which additional withdrawals Bodies List and Schedule for MFLs is will result in significant harm to water resources. developed and submitted annually to If the water body is below the MFL or expected to fall the Florida Department of below the MFL within 20 years, a recovery or Environmental Protection (FDEP) in prevention strategy is required. The recovery accordance with 373.041(2), F.S. To strategy may include phases or a timetable to achieve date,MFLs have been adopted for the the MFL. The strategies may include construction of following surface waters and new or improved water storage facilities, aquifers within the SFWMD's development of additional water supplies, and boundaries: implementation of water conservation. New or ♦ Caloosahatchee River additional withdrawals may be limited until the water and Estuary body is no longer experiencing significant harm. ♦ Lake Okeechobee 124 I Chapter 5:Water Resource Development Projects ♦ The Everglades (including Water Conservation Areas (WCAs) 1, 2, and 3; Holey Land and Rotenberger wildlife management areas; and Everglades National Park) ♦ The northern portion of the Biscayne aquifer ♦ The LWC aquifer system encompassing three semi-confined units (Tamiami, Sandstone,and Mid-Hawthorn) ♦ North Fork of the St.Lucie River ♦ Northwest Fork of the Loxahatchee River and Estuary • Lake Istokpoga ♦ Florida Bay The SFWMD's Governing Board has listed the Caloosahatchee River and Estuary as a 2012 Priority Water Body to continue data collection and analysis and model development to support an update to the Caloosahatchee River and Estuary MFL. Water Reservations and Restricted Allocation Areas Activities The SFWMD also provides a list to the FDEP specifying water bodies where PROTECTION NA Water Reservation and Restricted Allocation Area criteria will be Water Reservations developed to protect natural system A Water Reservation is a legal mechanism to set water from future consumptive use aside water for the protection of fish and wildlife or allocations. The SFWMD is required to public health.The volume of water to be reserved is use its Water Reservation or determined through scientific analysis. The SFWMD Restricted Allocation Area authority to then undertakes rulemaking to ensure that the protect water for natural systems volume of water is not allocated for identified by CERP projects in advance consumptive uses. of executing agreements with the USACE to construct these projects. Restricted Allocation Areas Currently, the SFWMD is pursuing A Restricted Allocation Area is a legal mechanism Water Reservations associated with for protecting water resources from adverse the CERP Caloosahatchee River (C-43) impacts due to consumptive uses of water. Section West Basin Storage Project and the 3.2.1 of the Basis of Review for Water Use Permit Biscayne Bay Coastal Wetlands Phase I Applications within the South Florida Water project. No additional Restricted Management District (Basis of Review; SFWMD Allocation Area rulemakings are 2010a) contains the SFWMD's Restricted Allocation contemplated at this time. Area rules. 2012 LWC Water Supply Plan Update 1 125 Some significant water bodies covered by Restricted Allocation Area rules include the following: e Loxahatchee River Watershed — Northwest Fork of the Loxahatchee River — Kitching Creek — Cypress Creek — Hobe Grove Ditch — Moonshine Creek — Jonathon Dickinson State Park — DuPuis Reserve — J.W.Corbett Wildlife Management Area — Pal Mar — Loxahatchee Slough (C-14,C-18,C-18W,and C-18E canals) — Grassy Waters Preserve — Riverbend Park — L-8 Reservoir — L-8 Canal (from C-51 Canal to L-8 Tieback Canal) — M Canal — L-8 Tieback Canal — Integrated conveyance systems that are hydraulically connected to the water bodies identified above e Everglades — WCA 1 (Arthur R.Marshall Loxahatchee National Wildlife Refuge) — WCAs 2A and 2B — WCAs 3A and 3B — Everglades National Park — Holey Land Wildlife Management Area — Rotenberger Wildlife Management Area — Integrated conveyance systems that are hydraulically connected to the water bodies identified above e Lake Okeechobee — Lake Okeechobee — Integrated conveyance systems hydraulically connected to the Caloosahatchee River(C-43 Canal),the St.Lucie River(C-44 Canal),or secondary canal systems that receive water from Lake Okeechobee 126 I Chapter 5:Water Resource Development Projects The SFWMD's first Water Reservation rule was adopted in support of the CERP Picayune Strand Restoration Project and Fakahatchee Estuary in July 2, 2009. On March 18, 2010,the SFWMD adopted a Water Reservation for the North Fork of the St. Lucie River in support of the CERP Indian River Lagoon - South Project. Draft Water Reservation rules are expected to be ready for Governing Board consideration in 2013 for the CERP Caloosahatchee River (C-43) West Basin Storage Reservoir Project. Further details on MFLs,Water Reservations, and Restricted Allocation Area rules are available on the SFWMD's website at http://www.sfwmd.gov/reservations. Related rule development and peer review activities are presented at http://sfwmd.websitetoolbox.com/?forum=174677. Comprehensive Water Conservation Program Water savings achieved through water conservation measures are the most cost-efficient way to expand current water supplies. The SFWMD's overall water conservation goal is to prevent and reduce wasteful, uneconomical, impractical, or unreasonable uses of water resources. To achieve this, the SFWMD has a number of conservation programs in place to cultivate a water conservation ethic within the LWC Planning Areas. These are discussed in the following subsections. For more information about the SFWMD's Comprehensive Water Conservation Program,see Chapter 4 of this document and the Support Document. WaterSIP The Water Savings Incentive Program (WaterSIP) provides matching funds of up to$50,000 to water providers and high volume users (i.e., cities, utilities, and industrial groups; schools; hospitals; and homeowners associations) for water saving technologies. These technologies include low flow plumbing fixtures,rain sensors,and other hardware.Between FY 2007 and FY 2012, the SFWMD awarded $627,456 for 23 LWC Planning Area WaterSIP projects, representing a projected savings of 178 million gallons per year (MGY) (see Chapter 4 and Appendix E of this plan update for more information on WaterSlP). Mobile Irrigation Laboratory Program This program provides funding to conduct efficiency audits of agricultural and urban irrigation systems by working with homeowner and condominium associations and interested individual homeowners to provide evaluations of landscape irrigation efficiency. In the LWC Planning Area, the Collier Soil and Water Conservation District provides this assistance under a contract with the SFWMD Big Cypress Basin Board. The Big Cypress Basin Urban Mobile Irrigation Laboratory(MIL),which had received funding in FY 2010 and FY 2011,will continue to receive funding in FY 2012. From 2008 through 2011, 480 audits were conducted on 549 acres of urban landscapes within the Big Cypress Basin, and potential water savings of 211.4 MGY (0.58 MGD) were identified. In FY 2010, five MILs were operating throughout the SFWMD — four agricultural MILs in Miami-Dade, Palm Beach, Martin, and St. Lucie counties and the one SFWMD-funded agricultural MIL serving the Big Cypress Basin area. Anticipated water savings from the MIL Program districtwide for FY 2010 to FY 2014 are approximately 438 MGY. 2012 LWC Water Supply Plan Update I 127 Water Conservation Outreach Programs The SFWMD also funds water conservation outreach programs in the LWC Planning Area. The amount of money budgeted for water conservation activities in FY2012 as well as projected expenditures for each fiscal year between FY 2012 and FY 2016 are reported in 0 in the Summary section of this chapter and in Chapter 5A: Five-Year Water Resource Development Program of the 2012 South Florida Environmental Report- Volume 11 (Martin 2012), which is available at http://www.sfwmd.gov/sfer. Some of the outreach programs are discussed in the following subsections. Great Water Odyssey This program conducts online water resource training for teachers to educate elementary school students (third, fourth, and fifth graders) throughout the SFWMD region. The students use a computer-based interactive curriculum that focuses on water conservation, providing a multidisciplinary educational experience consistent with Florida's Sunshine State Standards. Approximately 200 teachers are involved with this program that assist students in the successful completion of the Florida Comprehensive Assessment Test. Wings of Hope Program Florida Gulf Coast University's Wings of Hope Program in Big Cypress Basin introduces their students to native Southwest Florida wildlife species, habitats, water conservation, and environmental sustainability. The students share this knowledge with younger students in fourth and fifth grades through science-based environmental education programs at public and private schools in Collier County. Big Cypress Basin Conservation Outreach Program This program provides grant funding through the Education Foundation of Collier County's "Connect with a Classroom." This online program provides opportunities for teachers and community members to improve the quality of instruction in local schools. Grants will focus on projects related to water conservation. Partnership with the Water Symposium of Florida Big Cypress Basin Service center staff partner with the Water Symposium of Florida, Inc.to hold outreach seminars on water supply and water conservation for homeowners associations, civic groups,and businesses.These seminars are among the Big Cypress Basin and SFWMD ongoing efforts to create a year-round water conservation ethic that can help protect the area's water supply from regional weather extremes. Additionally, the Water Symposium of Florida creates a demonstration project displaying water conservation and water quality for the community. 128 I Chapter 5: Water Resource Development Projects Florida Automated Weather Network The University of Florida operates the Florida Automated Weather Network (FAWN), a statewide research and data program that provides accurate and timely weather data to a wide variety of users. There are 35 stations located in Florida, two of which are located in the LWC Planning Area: Immokalee, and Clewiston. Ongoing enhancements of the FAWN network occur annually and include site field tests, database enhancements, and continued development of information provided on the web page. SUMMARY Water resource development projects serve various purposes in support of water supply development.Benefits of the water resource development projects discussed in this chapter include the following: ♦ Improved understanding of the hydrogeologic system that is the source of both traditional and alternative water supplies for the LWC Planning Area ♦ Prevention of the loss of natural resources ♦ Preservation of existing supplies through better resource understanding and management and continued implementation of regional resource monitoring ♦ Water conservation to protect water sources and provide an efficient way to expand current water supplies ♦ Increased future supply availability The CERP projects are not reported as water made available in this plan update. Future water supply plan updates will reconsider this assessment as projects are completed and water needed for environmental protection is identified and reserved. Table 24 provides the estimated costs and timeframes for completion of water resource development projects described in this chapter,including districtwide projects. 2012 LWC Water Supply Plan Update 1 129 Table 24. Implementation schedule and costs for districtwide water resource development projects, FY 2012—FY 2016. Well Drilling and Aquifer Testing Program Estimated start date:1990 $2,004 $2,000 $1,000 $0 $0 $5,004 Estimated finish date:ongoing r N £,€s - � ^ �«y9d II#I' al _ m a Isl I�V TMil k `* u € ti mw r"11'1V� ( 1 s it € '�E_# sK uVk >b ',!°{IICI 3 ;•' 4 .9, €n'I ,11111, 7,1 M1 VY w ; Y III P € III III�yNl iYVV p V € I Ir - Ixlbkl,w"ti.. wI. s ..wS.4 - s�.�.�tiy 6�Y .� . s by h� @0 u x ;� x ,r€Llir IG�h�!.I ..0_ .�.,...i dd 9 u.l ��. r _ ..;r6r a,>r„�L,L�, Groundwater and Wetland Monitoring Estimated start date:2002 $703 $702 $702 $702 $702 $3,511 Estimated finish date:ongoing 1� 5'� '�'2 'IV<✓IINP”..F 1 'T r w y r. u"ii d"11 A dV € �-"' '#ar h-... i',", 7 dkd d+1i �: a V T m,�wdr�V V x l� r 0. �.F. � ( _ € l�.L r,,; •krlu .r����S" VwIO'�Iilod�ll! I>wi s '� tl� ��"#�c-,. ���"��Illll II"�'u '�y,..... I *r.ull�"y��"vd ul d'V,".,.+„y +�I�gl��l�"�u���_. .r1 v~7 m t A i q0b 6 •V,H a€ "V N"li q�l " n,, ri y F' ,,¢¢1 aVl 0 4r�"' tly x4 IIPI Fw,`tu,°uN'.:%fl„,� h : «-, 1 Tm dJ I�{�r I�.# V of l#k w##l✓ vv u.��.,V�.WII8{W1,"I rVy I �t�88 IR k�I lr ti't'i..-1.I.I',n"Imr�5#'r^a;^+r.d0.k£v Y�Nm d;��'plldl`IFF V k,i I*a,Sx,y.,= - mr!a�`'^ra1F"a Iy...Mh *,"�p,1k 1 I k w^1n a��411` II tl ., P,s'r-5 `sd ry s tf)-t',k'3UII LII I Vila o s ,„,1 10';;41:z IP,,yl�r rXy4liF,.7.k Modeling Estimated start date:1998 Staff Staff Staff Staff Staff Staff Time Time Time Time Time Time Estimated finish date:ongoing t3f1{ avrr _hc '# ,awf'h•tr' " (BN ,^ it >�lir lia xr "' .,?y'.yIl'"� 1 < k 1� P R fl r q^ iAWA � � fi4"v rrY h Y r s 3 F `°4 r11l�£ �S'"#° y �# j l f�,' # ' "d.i NV.. ..a. 1 J%m` ? ,II rld�pjll r#ai 'Vd 4 4r Il-- d€ 7 s'.'4 �. { I d r 4€y1'k 1dl r il i ” � VIII s u 4.,i�y m wJV'ka w uIk�I_�� �r"�(•II V�.-m".a vI�ekw I l=pdlPi fm°li lIh,#�,€u l"v Ga'r�i 1ll l�l Y k'y1 l§#h fi l t r P�I L r y_ .a-.;4�s�f a S�w x"i�9�u i"�)k u F rld�rp d k�M,N�F y�?lIF. .�,n.6. I t�1 S �1 1 € �VI „ 6 Iw um h � 0111,11,f111,'14 I I 1 F:. V 0�u r 4 0b1 ssIS V { '. u:k u1$ 19y„k tk a a~ { r. ;1 w" uI 411,019 T ' v I a .... Afm— #w IMi Ill wik it! a 4 r IPA dG � �£ yY'iN� fe �" a0"yt_ # w�#y ,# Ill �"1 Y�" 3 '�/d� ,a•. iF wu . _��� ����N.rIVII,NKUP6W yNr'0a4. i�a_,��.,���ur..'adh�JuwLJ«� �#�== r._ '� ikd"?',.,1'.','*,u.9 iia ,�.,�>4..,,.r.�,u,.l..�rr.�_...a... 0...y iulw..,h,�-.,d,Lsf Source: 2012 South Florida Environmental Report— Volume II, Chapter 5A: Five-Year Water Resource Development Work Program,Table 5A-1(Martin 2012). 130 I Chapter 5:Water Resource Development Projects Water Supply Development Projects This chapter provides a summary of the water supply TOPICS C� development projects anticipated to meet the water needs of the Lower West Coast (LWC) Planning Area during the 2010 to Regional and Local 2030 planning horizon. Information is provided for each water Planning Linkage use category (see Chapter 2), with an emphasis on the Public Water Supply (PWS) category. Additional details about demand • Projects Identified for projections, local government information, and water supply This Plan Update development projects can be found in Appendices A, B, ♦ Coordination Between and C,respectively. Water Supply Planning and Consumptive Use Growing population in the LWC Planning Area is driving the Permitting need for water supply development. The region's population is expected to increase by 51 percent, from approximately Funding 992,486 in 2010 to more than 1.5 million by 2030. Net water ♦ Summary demand for all water use categories is projected to increase • PWS Utility Summaries about 28-33 percent, from 683.5 million of gallons of water per day(MGD) in 2010 to an estimated 873.27-908.2 MGD by 2030. Gross water demand for all water use categories is projected to increase from 971.1 MGD in 2010 to as much as 1,262.91 MGD by 2030,an increase of 25-30 percent. Gross agricultural water demand is projected to increase 10-18 percent over the 20-year planning horizon from 630 MGD to as much as 741 MGD. As discussed in previous chapters, the availability of fresh groundwater is limited to LAW / CODE ID meet the needs of future growth in the LWC Planning Area. Therefore, the additional water Water supply development is defined in needed to meet increased future urban Subsection 373.019(24), Florida Statues demand is expected to be developed from (F.S.),as the planning,design,construction, other sources, primarily through continued operation, and maintenance of public or development of brackish groundwater private facilities for water collection, resources, surface water captured during wet production, treatment, transmission, or weather, new storage capacity of both surface distribution for sale, resale,or end use. water and groundwater, and expansion of reclaimed water systems. 2012 LWC Water Supply Plan Update 1 131 Agriculture, the largest water user in the LWC Planning Area, relies almost exclusively on fresh surface water and groundwater. Because surface water supplies are limited in this region, agricultural water users must consider alternative water supply sources, including water conservation to meet future water demands. Water supply options, such as blended sources and tailwater/stormwater recovery systems could also reduce agricultural water demand on freshwater supplies. The implementation of robust water conservation programs throughout the LWC Planning Area offers water use savings potential to reduce future water demand. Water users, such as utilities, local governments, and self-suppliers, including Agricultural (AGR) Self-Supply and Industrial/Commercial/Institutional (ICI) Self-Supply, are primarily responsible for water supply development projects. For each PWS utility supplying more than 100,000 gallons per day(0.1 MGD)to its service area,a summary is included at the end of this chapter. In the LWC Planning Area, 25 utilities serve 17 local governments (listed in Appendices B and D). The utility summaries provide population and demand projections and list proposed sources and specific PWS development projects to meet future demands. For other water use categories,specific projects by other entities are identified as provided to the South Florida Water Management District(SFWMD) for this plan update. REGIONAL AND LOCAL PLANNING LINKAGE The SFWMD's water supply planning process is closely coordinated and linked to the INFO water supply planning of local governments and utilities. Significant coordination and Planning Area The SFWMD is divided into collaboration throughout the water supply four areas within which water supply plan development and approval process planning activities are focused: Kissimmee occurs among all water supply Basin, Upper East Coast, LWC, and Lower planning entities. East Coast. The water supply development projects Utility Service Area The geographical region in which a water supplier has the ability and proposed in the 2005-2006 Lower West the legal right to distribute water for use Coast Water Supply Plan Update (2005-2006 (SFWMD 2010a). LWC Plan Update; SFWMD 2006) for PWS utilities proved useful to local governments preparing their 10-year water supply facilities work plans.The SFWMD has worked closely with staff from these utilities to identify water supply development projects for this plan update. Many of the projects listed in the utility summaries at the end of this chapter are also included in respective local government 10-year water supply facilities work plans. With the exception of projects using 100 percent seawater or reclaimed water, all water supply projects must obtain consumptive use permits from the SFWMD. 132 I Chapter 6:Water Supply Development Projects Although comprehensive plans, facilities work plans, and consumptive use permits are prepared at different times, each use the latest and best available data. Local governments' future projects should generally be consistent among plans and permits,and meet projected water demands. Appendix B provides information and statutory requirements relevant to local government comprehensive plans. The regional and local water supply planning process is described as follows and is illustrated in Figure 20. PROCESS ED Regional and Local Water Supply Planning Process The SFWMD is required to notify each PWS utility of the projects identified in this plan update for that utility to consider and incorporate into its corresponding local government required water supply facilities work plan in meeting future water demands. This notification must occur within six months following approval of the water supply plan update. Once the notice is received, PWS utilities then must respond to the SFWMD within 12 months about their intentions to develop and implement the projects identified by the plan or provide a list of other projects or methods to meet these needs [Paragraph 373.709(8)(a), F.S.]. In addition to the utility requirements above, local governments are required to adopt water supply facilities work plans and related amendments to their comprehensive plans within 18 months following approval of the regional water supply plan. The work plans contain information to update the comprehensive plan's capital improvements element,which outlines specifics about the need for, and the location of, public facilities, principles for construction, cost estimates, and a schedule of capital improvements. The local governments are required by Paragraph 163.3177(6)(c)3, F.S. to modify the potable water sub-elements of their comprehensive plan to do the following: • Incorporate the water supply project or projects selected by the local government from those projects identified in the updated regional water supply plan or proposed by the local government. ♦ Identify water supply projects to meet the water needs identified in the updated regional water supply plan within the local government's jurisdiction. • Include a work plan, covering at least a 10-year planning period,for building public, private, and regional water supply facilities, including the development of alternative water supplies, which are identified in the potable water element to meet the needs of existing and new development. By November 15 of every year, all utilities are required to submit a progress report about the status of their water supply projects (completed, underway, or planned for implementation)to the SFWMD. By December 1 of each year, local governments are required to submit updated capital improvement information to the Florida Department of Economic Opportunity and the SFWMD. Figure 20 shows the linkage and sequence of the water supply planning process with local government water facilities work plans and comprehensive plans, beginning with the adoption of a water supply plan update. 2012 LWC Water Supply Plan Update 1 133 a AMY A 6 Months 12 Months 18 Months ORLI ole of PWS Enntea W lth in 12 modheofndHcdlm by Watersupplyplaiupdatesevery"` .'h six months of meters • SFWMD + the years ,`Update adoption _ •PWS entities sated projedsto be •Subsedion(low D notitiesPWS entitles: implemented r _ ,.. , --supplydevelopment •SFWMD nor kswithPWSentitiesbh • _;.`jedsinduded inpiar update ensureprgectsmeet future needs .Subsection 373.709(8)(b),F.S. •■ •section 373.709(8xa),F.S. 1 1 1 # November Annually "1i;iii Annually 1.4t,_i a.1,i,i a Role of PWS Entities ., G.-` ..s months alter voter supplyplan PWS entities submit annual ° Local govammentsmay update x•date is adopted. progress report about statusof ltal improvement element by Water sup pyfaciktiesvwrk water supplyprojedsto the lnance without amending "}flans and amendmentsedopted -Comprehensive plan Into Iocalgoverrmels' SFWMD. p !comprehensive pie, •SFWMD revi ewsprogress •Subsection 163.3177(35b),F.S. ., .section 163.3177(6Xc),F.$. reportsandprovidesassistance as appropriate. teection 373 709(8)(b),F.S. Figure 20. Linking regional water supply planning with local government comprehensive planning. Consumptive Use Permitting Consumptive use permits are required for all water supply development projects,except for those using 100 percent seawater or reclaimed water.While this plan identifies a number of projects, each project must be permitted by demonstrating the following (Section 373.223,Florida Statutes [F.S.]): ♦ Reasonable-beneficial use of water ♦ Project does not interfere with existing legal users ♦ Project is consistent with the public interest PROJECTS IDENTIFIED FOR THIS PLAN UPDATE Regional water supply planning is a critical tool for ensuring that existing and future water needs of the state are met while also protecting our valuable natural systems. Regional water supply plans are developed through collaboration among the water management districts, water providers, water users, and other stakeholders when future projected demands are estimated to exceed existing water supplies. The resulting plan provides a blueprint for the development of sustainable water sources by identifying water supply 134 I Chapter 6:Water Supply Development Projects options, from which local water suppliers can choose, that will be more than sufficient to meet future needs while protecting the water resources of an area, 373.709, F.S. (FDEP 2012). To manage the water resources in the region,this plan update promotes the diversification of sources for water supply projects needed to meet future demands. Projects proposed for inclusion in this plan update were evaluated based on factors such as resource constraints, including Minimum Flows and Level (MFL) criteria and Water Reservations, and whether a project actually contributes to new water supply.Included in these project evaluations were projects proposed in local governments' 10-year water supply facilities work plans and identified in the annual utility progress or inventory reports.Some of the projects identified in this plan update were listed in the 2005-2006 LWC Plan Update and have proposed future expansion phases, or were delayed or modified due to fluctuations in population and demand projections. Water suppliers are not required to choose a water supply development project identified in a regional water supply plan. However, if they do select a project from this plan update, the applicant should have confidence that the project was screened for feasibility and has a likelihood of being permittable. The PWS utilities submitted water supply development projects for this plan update to meet their 2030 water demands. With the exception of projects using 100 percent seawater or reclaimed water,all water supply projects require a consumptive use permit from the SFWMD. These projects will be evaluated on an application-by-application basis to determine if the project meets consumptive use permitting criteria. Thirty-six multi-phased PWS facility projects are proposed for Fiscal Year (FY) 2012 to FY 2030. The diverse water sources for these projects are fresh surface water or fresh groundwater from the surficial aquifer system (SAS); brackish groundwater from the Floridan aquifer system (FAS); reclaimed water; aquifer storage and recovery (ASR); and surface water storage. These proposed projects include 17 potable and 19 non-potable water supply development projects (see utility summaries at the end of this chapter). In the LWC Planning Area, all utilities indicated adequate water supplies to meet projected demands through 2030 with a combination of submitted projects and existing supplies. Appendix C provides a summarized list of proposed projects submitted for this plan update. Furthermore, a project identified for inclusion in this plan update may not necessarily be selected for development by the utility. In accordance with Section 373.709(6), F.S., nothing contained in the water supply component of a regional water supply plan should be construed to require local governments, public or privately owned utilities,special districts, self-suppliers,multijurisdictional entities,and other water suppliers to select that identified project. If the projects identified in this plan update are not selected by a utility, the utility will need to identify another method to meet its needs and advise the SFWMD of the alternative projects(s), and a local government will need to include such information in its 10-year water supply facilities work plan. 2012 LWC Water Supply Plan Update 1 135 Projects are also proposed for the other water use categories.AGR Self-Supply water users continue to use surface water and fresh groundwater and can benefit from projects,such as stormwater and tailwater recovery, and more efficient water conservation practices. Increases in demand for Recreation/Landscape (REC) Self-Supply uses for this planning horizon are expected to be met, for the most part, by the proposed reclaimed water projects. Power generation entities are planning power plants that will make use of brackish water,surface water,and reclaimed water where available. A discussion of the demand and supply conditions for each of the six major water use categories follows. Because most of the growth in demand during the next 20 years will occur in the urban sector,and more specifically within the public water systems, emphasis is placed on evaluating future needs and recommending water supply projects within the PWS category. Public Water Supply PWS demand includes all potable uses served by public and private utilities with a pumping capacity equal to or greater than 0.1 MGD. The PWS net demand is projected to grow from 131.4 MGD in 2010 to - 192.0 MGD by 2030, which is approximately _ ,T 21 percent of the total projected net water demand by 400/ 2030.In Appendix B,current and future utility service area maps reflect the proposed changes in service area boundaries and legal municipal boundaries. Utilities that produce or pump less than 0.1 MGD on an annual basis were not evaluated and do not appear on the service area maps in the appendix. The populations served by these smaller utilities are included in the Domestic Self-Supply (DSS) category. Utilities currently in this category include Silver Lakes Utilities in Glades County, Florida Government Utility Water Treatment Facility Authority (FGUA) in Hendry County, and Charlotte County Correctional Institution in Charlotte County. The facilities and service area of Charlotte County Utilities are evaluated and permitted by the Southwest Florida Water Management District. However, Charlotte County Utilities provides potable water supplies to Burnt Store Marina in Lee County,and this population is included in this plan update (see Appendix B and Appendix D). In addition, Charlotte County Utilities received a consumptive use permit from the SFWMD in 2011 to develop facilities at Babcock Ranch in southeastern Charlotte County, which is located in the LWC Planning Area. Both the Southwest Florida Water Management District and the SFWMD are coordinating their respective water supply plans to consider the future demands of Charlotte County, most of which falls under the Southwest Florida Water Management District's jurisdiction. 136 I Chapter 6: Water Supply Development Projects PWS demand is currently met through a combination of fresh groundwater from the SAS and intermediate aquifer system (IAS), brackish groundwater from the IAS and FAS, and fresh surface water. In addition, many utilities are responsible for wastewater management and most have implemented use of reclaimed water. For consistency in the water supply planning process, the SFWMD, local governments, and utilities worked closely with the Florida Department of Economic Opportunity to project demands and propose water supply projects for the future. Table 25 lists the LWC Planning Area's PWS net demands for 2010 and 2030 by county. Table 25. PWS net demand projections for 2010 and 2030. Charlotteb 0.0 1.4 'ri.s tliM 1In : .s 1 - ' r j pRr a 3.;."m � f i� r ,i rl } Vrl r �,� �d hl�n ra;I�NP M a , � xr d au tl"11ry^�u hr I i a d!i a €- v u•f rl "�I•r. N++higi ✓nnt�a�l Vi�4.�' r ,.. . 1. .L. r�.wd uo 5 k" .c w��, Gladesb 0.5 0.8 91H RI, ,'. ay," hF a - =r C 'y,,.r uglir���� �4144* A 0 a `I��µp�mr�N e �ingml o''s.erpr i��r eev, Lee 68.5 111.0 y l ��� �� sr i r,.e 0. I21.,*,. LWC Net PWS Demand Total 131.4 192.0 a. Projected supplies include only potable water delivered by PWS systems. Areas served by only DSS are not included and shown as"zero"values. b. Portion of county in the LWC Planning Area. c. No development is anticipated in the mainland portion of Monroe County,which is the portion of the county within the LWC Planning Area. Approximately 11 percent of projected PWS net demand is met using fresh groundwater supply. The availability of new supplies from the freshwater aquifers in the LWC Planning Area is limited due to existing water demands, source limitations,and resource issues, such as saltwater intrusion, environmental needs, and aquifer protection criteria (see Chapter 3). The availability of and the ability to permit for freshwater supplies to meet projected water demands through 2030 are determined on an application-by-application basis. Some freshwater supply development may be feasible given local conditions, such as reductions in historical water use and availability of new resources. Therefore, only a few proposed freshwater supply projects are included in this plan update. Data in the Utility Summaries The individual utility summaries at the end of this chapter provide baseline information about finished water demands, existing permitted sources and allocations, proposed projects that create water capacity, and other related information. The population and water demands for each utility are based on the methodology and results provided in Appendix A. The water demand projections represent finished water per capita use rates (PCURs) and net water demands. These are different from raw water PCURs and gross demands that reflect water withdrawn at the source prior to treatment. There may be 2012 LWC Water Supply Plan Update 1 137 significant differences in the quantity of raw water and finished water delivered due to differences in treatment process efficiencies. This plan update uses permanent population for existing demand projections. This is consistent with the methodology used by the University of Florida's Bureau of Economic and Business Research (BEBR) for population estimates. Tables 26 and 27 summarize the 36 projects proposed by PWS entities and the estimated new water supplies to be produced by 2030. Table 26. Proposed potable water supply development projects and capacity for 2012-2030. Fresh Water 6 8.8 I� - - ti a ""r v 3 . 'iiL"001�ll4 l . , ....-d l u V n 6q.6.. , .L116 it..66, iliu4 ' 6U,e.. � s .il k6 .,62.66116,66t-662.62P ...r. .� Project Total 17 78.8 a.Projects designed to expand distribution of treated water are not included because they do not generate new water. b.One 3.40-MGD freshwater ASR project with storage in the FAS is not included in the new treatment capacity total. Table 27. Proposed non-potable water supply projects and capacity for 2012-2030. Reclaimed WaterII�s""' 11 r m n f 35.0 il.l P " T u,T" -7 �'7 i 4 1 r m '171"1"v w 2 sm n rry Fresh Water(Supplemental Groundwater)b 2 6.0 r r MII ri Ey. WiTA i xn a NNk 9 i¢d am" R,a -`� Y`3#7, c k1 �'"< _ � � '��' ra x a llll� H" a� �wnli ti da 1 h. 9a a.Projects designed to expand distribution of treated water are not included because they do not generate new water. b.Supplemental non-potable water supply for irrigation and one 3.40-freshwater ASR project with storage in the FAS. The proposed potable water supply development projects(Table 26)will potentially create 78.8 MGD of new water treatment capacity to meet the PWS net demand of 192.0 MGD, exceeding the 60.6 MGD of net potable water needed from 2010 to 2030 to meet PWS demand. The new capacity consists of 70.0 MGD produced by brackish water source projects and an additional 8.8 MGD produced by freshwater source projects. The brackish water projects proposed for the planning area include construction of reverse osmosis (RO) treatment plants, expansion of existing plants, and construction of new production wells. Brackish water projects are proposed by most of the major utilities requiring additional treatment capacity within the next 20 years.The design capacity listed for each project reflects finished water capacity. 138 I Chapter 6:Water Supply Development Projects The proposed non-potable water supply projects (Table 27) will potentially create 62.3 MGD of additional water supply for landscape irrigation and groundwater recharge. These proposed projects include multi-phased reclaimed water production facility construction and expansion projects,as well as reuse distribution line and storage facility projects. Six of the non-potable supplemental water sources may provide up to 21.3 MGD of new non-potable water supply and include reclaimed water in ASR facilities, as well as fresh groundwater. It is important to note that although projects involving new distribution lines and other infrastructure may qualify for the Alternative Water Supply Funding Program, they are not included as reclaimed water projects because they do not generate new supply (see Alternative Water Supply Funding Program section later in this chapter). The LWC Planning Area has achieved significant progress in reclaimed water use.The 2010 FDEP Reuse Inventory Report (FDEP 2011) indicates that 95 percent of the wastewater generated in Lee County and 83 percent of the wastewater generated in Collier County is reclaimed and primarily used for irrigation and to recharge aquifers.Treated wastewater in Hendry County is reused 100 percent through aquifer recharge using spray fields and rapid infiltration basins.Glades County has no water reuse facilities. The 78 water supply development projects funded by the Alternative Water Supply Funding Program in the LWC Planning Area between FY 2007 and FY 2012 have created a total of 104 MGD of new water capacity.The new sources of this water include 37 MGD of brackish water, 33 MGD of reclaimed water, 16 MGD of Hawthorn aquifer water, 3 MGD of ASR system water,and 15 MGD of surface water/stormwater and other projects. Five utilities in the LWC Planning Area constructed ASR well systems within the past 10 years.These systems added storage to accommodate additional water supply during the dry season to meet peak potable water demands. Domestic Self-Supply DSS gross demands in the LWC Planning Area are projected to increase from 18.9 MGD in 2010 to 24 MGD in 2030. DSS refers to potable water from a private supply, usually a domestic well serving a private residence. DSS needs are met primarily with fresh groundwater. All future needs in this use category are expected to be met using fresh groundwater supplies. However, residential areas of concentrated domestic wells, such as portions of Cape Coral and Lehigh Acres, have experienced well problems during the dry season because pumps become inoperable due to reduced water levels. Cape Coral Utilities has connected several sections of the city (city project areas Sections SW4 and SW5) to utility service to eliminate the need for domestic wells in these areas. The stress on wells still in use is reduced, and well problems have been eliminated in Sections SW4 and SW5. Utility service connecting the northern half of the city's service area is scheduled for 2018. 2012 LWC Water Supply Plan Update 1 139 To minimize well problems in the Lehigh Acres area,the Lee County Department of Natural Resources modified the well construction standards for the southeastern portion of Lehigh Acres.Wells are now required to have deeper well casings,which allow the pumps to be set at greater depths to minimize problems caused by depressed water levels. However, continued urban development and resulting increases in domestic well installations in these areas may create additional well problems. Declines in water levels of the Lower LAW / CODE 01 Tamiami, Sandstone,and Mid-Hawthorn aquifers may reach maximum developable limits (MDLs) in an area Maximum Developable Limit that may preclude future well MDL consumptive use permitting criteria provide construction in the stress aquifer. reasonable assurances the proposed water use does not cause harmful drawdowns that Potential solutions include, but are not overdraw semi-confined freshwater aquifers. The limited to, connection of such areas to potentiometric head with the Lower Tamiami, PWS systems and adoption of additional Sandstone, and Mid-Hawthorn aquifers is not landscape ordinances that serve to allowed to drop to less than 20 feet above the top minimize outdoor irrigation. When of the uppermost geologic strata that comprises public supply becomes available to a the aquifer at any point during a 1-in-10 year particular area, DSS wells that are no drought condition (SFWMD 2010a). longer used require proper plugging and abandonment. Agricultural Self-Supply AGR Self-Supply is expected to remain the largest water use category in the LWC Planning Area Agricultural water use includes supplies for irrigated, ` °` r PP g � ik �,- ,�: � �+, commercially grown crops. Because w� t l r +;:+ � sy , agricultural demand projections are , t complex, ranges of projections are 1 ; � = used Gross agricultural demand over the next 20 years is projected to ' ' increase 10-18 percent from 630 MGD a :=.'1 `` in 2010 to 695.9-740.9 in 2030.Actual demand depends on how much citrus Sugarcane in the Lower West Coast transitional land (currently fallow) goes into production within the planning horizon.Appendix A provides more information about agricultural water use and projected demands. The region's dominant crops in the area are citrus, small vegetables, and sugarcane, which account for over 93 percent of the projected 2030 AGR Self-Supply water use demand. Although active crop cultivation has declined in recent years, the agricultural industry considers this decline temporary. Therefore, the projections in this plan update show an increase in both agricultural water use demand and acreage. 140 I Chapter 6:Water Supply Development Projects The renewal process for irrigation class consumptive use permits in the LWC Planning Area began in 2004 and was mostly complete in 2006.Consumptive use permits renewed during that time are still in effect,and most are valid for 20 years. Fresh surface water and groundwater are the primary water sources for agricultural irrigation in this region. However, historically used freshwater sources, including fresh surface water from lakes and canals and the SAS, are not adequate to meet all projected demands during a 1-in-10 year drought.As mentioned in Chapter 3, the Lake Okeechobee Service Area is designated as a Restricted Allocation Area. These criteria restrict the allocation of surface water derived from Lake Okeechobee water bodies for consumptive use. Lake Okeechobee water bodies include integrated conveyance systems that are hydraulically connected to and receive water from Lake Okeechobee, such as the Caloosahatchee River (C-43 Canal). These criteria apply to new projects, existing unpermitted projects, and modifications or renewals to existing projects located within the Lake Okeechobee Service Area. Permitted allocations cannot cause an increase in the volume of surface water withdrawn from Lake Okeechobee water bodies over the entire base condition water use unless one of the alternatives is identified as listed in Section 3.2.1 of the Basis of Review for Water Use Permit Applications within the South Florida Water Management District, referred to as simply the Basis of Review (SFWMD 2010a). For more information see the 2012 Lower East Coast Water Supply Plan Update(SFWMD 2012b). Development of groundwater and surface water may be practicable in some areas; however, permitting new freshwater supplies will essentially depend on local resource conditions, and some options are not available for all crop types. New water supply opportunities for agriculture may be available in the future by capture and use of water normally lost to a farm's water management system (tailwater recovery), capture and use of storm water (stormwater retention), and blending of brackish groundwater with fresh water. The storage and application of reclaimed water may be used for some crops, but there are no sources near the areas with agricultural needs. Furthermore, the use of more efficient irrigation systems for various agricultural operations could significantly reduce the amount of water needed to meet crop demands for an average year, but this would not provide the water needed in a 1-in-10 year drought. The continued use of best management practices (BMPs), including water conservation, could reduce the amount of water needed to meet crop demands (FDACS 2010). These efforts are discussed in Chapter 4. In addition, the Florida Department of Agriculture and Consumer Services (FDACS) develops and adopts by rule agricultural BMPs addressing water quality.Some BMPs contain an implicit water conservation component.Growers who enroll in the FDACS BMP Program and implement the BMPs demonstrate their commitment to water resource protection, have a presumption of compliance with state water quality standards, and are eligible for technical and financial assistance toward meeting water resource protection goals. 2012 LWC Water Supply Plan Update I 141 Industrial/Commercial/Institutional Self-Supply In the LWC Planning Area, the ICI Self-Supply use category includes citrus and sugar processing plants, and rock mines. The projected demand for this category is estimated to be 35.3 MGD by 2030, which is no change from current demands. This user group is not expected to exceed the high volume demands experienced in 2005. Many of these water users are supplied by PWS utilities. Other users are self-supplied because they are located away from PWS lines, and/or their use is under 0.1 MGD. Estimates in this plan update include larger self-supplied users, most of which have historically relied on fresh groundwater and,to a limited extent,fresh surface water. The ICI Self-Supply use category has sufficient supply to meet future needs.Although fresh groundwater supplies are generally considered adequate to meet the relatively small new demands projected for this use category, alternative water supply options should be considered based on location and local conditions. If reclaimed water is available to meet existing and new industrial, commercial, and institutional water demands, the feasibility of such opportunities will be evaluated through consumptive use permitting. Recreational/Landscape Self-Supply The REC Self-Supply category includes irrigation for large landscaped areas, such as parks, golf courses, community common areas, and cemeteries. Historically, irrigation supplies for this category include local fresh groundwater and surface water captured from canals or ponds in stormwater management systems. In recent years, irrigation for new golf courses often includes reclaimed water and on-site blending of brackish groundwater with surface water, which Golf Course—Lower West Coast satisfies consumptive use permit requirements and meets demands. In the LWC Planning Area, REC Self-Supply gross demand is projected to increase from 130.1 MGD in 2010 to 188.5 MGD in 2030. The projected increase in growth for this category is expected to be met, for the most part, by currently proposed reclaimed water projects.In the LWC Planning Area,reclaimed water is used to irrigate large landscaped areas, such as golf courses, parks, and cemeteries, as well as residential and commercial parcels. Projects submitted by utilities and wastewater treatment facilities specify that significant additional reclaimed water will be made available in the future. Expanded wastewater treatment capacity is expected to add 46.5 MGD of reclaimed water by 2030.The additional supply may also provide an opportunity to 142 I Chapter 6: Water Supply Development Projects allow current irrigation to change from fresh water to reclaimed water. Where reclaimed water is not available, users may qualify for limited freshwater withdrawals on an application-by-application basis. Power Generation Self-Supply The Power Generation (PWR) Self-Supply water use category is projected to increase from 0.5 MGD in 2010 to 42.1 MGD in 2030. Florida Power&Light (FPL) may potentially expand its Fort Myers Plant facilities. FPL utilizes an assessment method incorporating generation and cooling technologies most appropriate for site-specific conditions, including water supply and wastewater disposal. The different technologies may require and utilize traditional and alternative water sources. Presently, cooling water for this facility is supplied primarily through an intake located on the Caloosahatchee River(C-43 Canal).The primary sources of water for a possible plant expansion may include traditional or alternative water sources such as captured excess stormwater, surface water, brackish water from the FAS, and reclaimed water. Because the availability of fresh water is limited in the LWC Planning Area, alternative water sources may be the most feasible options for meeting future PWR Self-Supply use. COORDINATION BETWEEN WATER SUPPLY PLANNING AND CONSUMPTIVE USE PERMITTING The development and implementation of regional water supply plans at the SFWMD is done in close coordination with several units of the agency. In particular, the consumptive use permitting and intergovernmental coordination play key roles in the water supply plan process. Representatives of other units across the SFWMD serve as members of internal teams established for updating the water supply plans every five years. Meetings to identify and resolve issues related to water supply planning and permitting are held regularly throughout the year. The importance of this coordination was underscored when the Florida Department of Environmental Protection (FDEP) issued a memorandum to the water management district's on March 23, 2012 providing guidance on improving linkages between regional water supply plans and consumptive use permitting. Key objectives in the memorandum included ensuring that water supply projects incorporated into regional water supply plans have a likelihood of being permittable and that staff would be knowledgeable of these projects and facilitate permitting. Proposed projects are reviewed before inclusion in a water supply plan, but they are not analyzed at a level of detail necessary to determine if a project can meet all conditions for issuance of a consumptive use permit.Applications for new or expanded consumptive use allocations are still reviewed on an application-by-application basis in the consumptive use permitting process.The water management districts were directed to improve coordination between permitting and planning staff, and ensure planning staff know permit criteria 2012 LWC Water Supply Plan Update 1 143 while permitting staff are knowledgeable of the recommended projects contained in the plans. Planning staff already participate in permit application reviews and provide input on population and demand projects, reuse and water conservation programs, and other aspects of the permitting process. The SFWMD began implementation of the memorandum immediately by documenting the planning-level criteria used to screen proposed water supply projects for regional water supply plans and establishing a more formal coordination process between permitting and planning staff. Permitting staff has also taken on a more formal and better defined role in screening proposed water supply projects for inclusion in water supply plans. All proposed projects considered for this plan update were reviewed by staff from Water Use Permitting and Water Supply Development using the following set of questions: ♦ Does the project propose use of a source of limited availability? ♦ Is the project located in a Restricted Allocation Area? ♦ Is the proposed source a MFL water body or is it connected, directly or indirectly,to a MFL water body? If yes, is the proposed use consistent with MFL recovery or prevention strategies? ♦ What other environmental water needs (e.g., Comprehensive Everglades Restoration Plan [CERP] targets and Water Reservations)may be impacted? ♦ What resource issues have been identified in recent permit applications in the general area for same source (e.g.,wetlands,saltwater intrusion,and MFLs)? ♦ Have there been resource-related compliance issues of existing legal users of same source? ♦ Are there any new technical studies related to source availability? Based on the planning-level screening,water supply projects are recommended in this plan to meet the demands projected for 2030 and generally have a likelihood of being permittable. If the screening process suggests that a new project may be less likely to be permitted due to resource constraints, the SFWMD may propose an alternative project in recognition that the more detailed, permit-level analysis may not result in full allocation needed to meet the applicant's demand. FUNDING Funding for water supply development and water conservation at the local level is the shared responsibility of water suppliers and users. The State of Florida and the water management districts have provided funding assistance to local water users developing alternative water supplies and measurable water conservation programs. In most cases, funding is allocated to projects included in a region's water supply plan update. Some projects not in this plan update, but consistent with the plan's goals, may also be funded. When the SFWMD deems it appropriate,a plan update may specifically identify the need for multijurisdictional approaches to project options based on analysis, financial and technical 144 I Chapter 6:Water Supply Development Projects feasibility, and feasibility of permitting.The SFWMD provides funding for alternative water supply and measurable water conservation through its Alternative Water Supply Funding and Water Savings Incentive Program (WaterSIP) programs. An alternative water supply project or water conservation project identified in this plan update makes that project eligible for future funding, although funding is not guaranteed. An application must be submitted and processed for the determination of an award. Alternative Water Supply Funding Program Alternative water supply sources in the LWC Planning Area include brackish water from the FAS, reclaimed water (treated wastewater), excess storm water during the rainy season, sources made available through the creation of new storage capacity,and any other sources designated as non-traditional. In addition, water conservation projects that result in quantifiable water savings are eligible for funding. For the 2007-2012 period, the SFWMD, in cooperation with the State of Florida, provided more than $123 million in alternative water supply funding for 212 projects, with 78 projects occurring in the LWC Planning Area. Between FY 2007 and FY 2012, water supply development projects funded by the Alternative Water Supply Funding Program in the LWC Planning Area have created a total of 104 MGD of new water capacity. The new sources of this water include 37 MGD of brackish water, 33 MGD of reclaimed water, 16 MGD of Hawthorn aquifer water, 3 MGD of ASR water,and 15 MGD of surface/storm water and other projects. Water Savings Incentive Program As described in Chapter 5, the WaterSIP provides 50-50 cost-share funding for implementation of water savings projects that reduce urban water use. The SFWMD provides matching funds up to $50,000 to water providers and users (i.e., cities, utilities, industrial groups, schools, hospitals, and homeowners associations) for water saving technologies. These technologies include low flow plumbing fixtures, rain sensors, fire hydrant flushing devices, and other hardware. Between FY 2007 and FY 2012, the SFWMD awarded $627,456 for 23 LWC Planning Area WaterSIP projects, representing a projected savings of 178 million gallons per year (MGY) (see Chapter 4 and Appendix E of this plan update for more information). SUMMARY Meeting the projected increase in net water demand in the LWC Planning Area during the next 20 years requires continued emphasis on water supply development of brackish groundwater resources, reclaimed water, seasonally available surface water, and water conservation. Developing additional storage, such as ASR, is also critical to improve access 2012 LWC Water Supply Plan Update 1 145 to seasonal supplies for future needs. Large-scale projects are needed to facilitate development of seasonal water supplies. Population growth over the next 20 years will significantly increase the region's PWS demands, particularly within the urban sector. During this period, the PWS use category projects a 46 percent increase in net demand. The AGR Self-Supply category projects an increase in gross demand of 10-18 percent. Fresh groundwater and surface water supplies are not adequate to meet all projected demands.The Lake Okeechobee Service Area is designated as a Restricted Allocation Area, which limits proposed use of surface water from Lake Okeechobee and hydraulically connected canals, such as the Caloosahatchee River (C-43 Canal).Although development of groundwater and surface water may be practicable in some areas, permitting new freshwater supplies will depend on local resource conditions. To meet projected water demands, more than 36 new PWS multi-phased projects were evaluated for this plan update. The proposed potable drinking water supply development projects (Table 26) will potentially create 78.8 MGD of new water treatment capacity to meet the PWS net demand of 192.0 MGD, exceeding the 62.9 MGD of net potable water needed from 2010 to 2030 to meet PWS demand.The proposed design capacity includes the need for peak demands, backup capacity, and operational capacity of the treatment facility. Most water supply development options require significant upfront investments and ongoing maintenance costs. Individual utilities may find that a component of future water needs can be met in a more immediate and cost-effective way through a demand management program or reclaimed water project. DSS gross demand is projected to increase 27 percent by 2030. Declining water levels in northern Cape Coral and Lehigh Acres, and the additional development of DSS wells, calls for the extension of public water service to these areas. AGR Self-Supply gross demand is dependent on citrus transitional lands returning to production and any changes in crops that have different irrigation needs. Therefore, the AGR Self-Supply gross demand projection for 2030 is a range. It is expected to increase 10- 18 percent. Traditional fresh surface water and groundwater sources are generally expected to be sufficient to meet this AGR Self-Supply projected increase in average rainfall years, but not during a 1-and-10 year drought.Additionally, some local conditions limit the volume of available fresh water. Agricultural users, as well as all water users, should investigate and implement alternative water supplies in basins where water availability is limited. ICI Self-Supply demand is expected to remain stable.Water use in this category typically has a recycling component,which should continue and gain efficiency to reduce water demands in the future. REC Self-Supply is another high growth water use category. Gross demand is projected to increase by 45 percent for this use category by the end of the 20-year planning horizon. Future water needs are expected to be met primarily by developing and using reclaimed 146 I Chapter 6:Water Supply Development Projects water systems, and blending surface water and brackish groundwater. Conservation methods using more efficient irrigation systems and Florida-Friendly LandscapingTM plants offer potential cost savings by reducing demands for water. PWR Self-Supply needs are projected to increase significantly with the potential development of additional power generation at the Fort Myers Power Plant. Meeting the water needs for the new facility requires additional water source options, such as brackish groundwater or reclaimed water. PUBLIC WATER SUPPLY UTILITY SUMMARIES This section includes utility summaries for all the PWS utilities that provide potable water greater than 0.1 MGD for the LWC Planning Area. In May 2012, SFWMD staff updated the utility summaries by querying the FDEP website for both drinking water capacity (FDEP 2011) and reclaimed water capacity (FDEP 2010b). In addition, the proposed projects were updated with information supplied to the SFWMD in the statute-required November 2011 utility reports and from direct contact with the utilities during May-July 2012. Potential future water conservation savings are not included in the following utility summaries unless a specific project is identified by the utility.Chapter 4 of this plan update addresses conservation and potential water savings. 2012 LWC Water Supply Plan Update 1 147 TOWN AND COUNTRY UTILITIES COMPANY County:Charlotte County Description: Potable water supplies consist of 100 Service Area: Unincorporated Charlotte County in the percent fresh groundwater from the Sandstone Babcock Ranch Special Development District aquifer system and are projected to remain the same in the future. Population 0.00 Per Capita(gallons per day[GPI)]finished water) 0.00 100 100 "gar°f V Su u.l��rs x .,,... „„�,,♦♦ - +� }."r i i ii a� 6 �! * 4�91y1p ,4� i I � u�'� ,.. �� a l- ,.i 44 r sl s ¢�� i �° 1 c,,.... . . ,. uu ... ,. . .i. ..... .., ate.-r._Ft m..,,. ku,.i.... . _. ,. " IAS 0.43 „? �s l� .. ::.. '� s 1 u �",,.}"�f rr Gli ilr° a7, °IVIVI➢ i S Iii �4 r ho �' � SAS 0.00 0.00 0.00 IAS 0.50 1.25 4.00 FAS 0.00 0.00 0.00 "ar I Un x ��?� 4ti�il j Io wr b,r 9 a�it5�3�eh�a r s i�,6uk lH'fial 111 Reclaimed Water 0.20 0.20 0.20 Ira � %ye �`�` - '� a Ira f u:� - �da"�utui k4�•,.c° u•.-' , #x+�,�, 0.75-MGD Expansion of Water Treatment Facility Fresh from 0.5 MGD to 1.25 MGD(2018) Water $7.0 0.75 0.75 1.25-MGD Expansion of Water Treatment Facility Fresh from 1.25 MGD to 2.5 MGD(2021) Water $8.0 0.00 1.25 1.5-MGD Expansion of Water Treatment Facility Fresh from 2.5 MGD to 4.0 MGD(2026) Water $11.0 0.00 1.50 Total Potable Water $26.0 0.75 3.50 1 .= zF Non.'-'.otable'-W er 4` ,. e?r»� _,. '. . , 0.8-MOD Expansion of Wastewater Treatment Reclaimed $6.0 0.80 0.80 Facility from 0.2 MGD(2015)to 1.0 MGD(2018) 1.0-MGD Expansion of Wastewater Treatment Reclaimed $8.0 0.00 1.00 Facility from 1.0 to 2.0 MGD(2021) 1.5-MGD Expansion of Wastewater Treatment Facility from 2.0 MGD to 3.5 MGD(2026) Reclaimed $12.0 0.00 1.50 otal Non potable Water $26 0 0.80n, 3.30 �S,_ h, 1� ,fir&i"I~•,.Ire s vl+f r } V 11014 Note: Original franchised area modified by the transfer of ownership to the State of Florida to include only the proposed Babcock Ranch Project. 148 I Chapter 6:Water Supply Development Projects AVE MARIA UTILITY COMPANY County:Collier County Description: Potable water supplies consist of 100 Service Area: Portion of unincorporated Collier County percent fresh groundwater from the Lower Tamiami serving Ave Maria aquifer and are projected to be 61 percent fresh groundwater and 39 percent brackish water supplies in the future. This utility is reusing 100 percent (0.14 MGD) of its wastewater and 1.38 MGD with supplementations. Population 1,435 4,850 16,378 Per Capita(GPD finished water) 121 121 121 '�rfl F�yyn " i lrr rbartl wkh I�V� r^ ` ris Y E_ '� 3 . .r .z Nluw"{r ������'� :., { �.. ie�C� I^I i u SAS 1.02 u yr?I rri ailr' uil�KK W �niur e i .r 71 V 1 «r�,� yz, , ��i a >'✓•a __ �.,.hl,r�4 u SAS 0.99 2.69 2.69 IAS 0.00 0.00 0.00 0.00 1.70 1.70 7:'°41~ti �i cgii�pgn r o ' .s"fir wWgr 1"- r r�Iv5{ndI r iNtlYP H '1: d"w 4 i irkrp 1 i!µ' _.� . I;V.S Wr "4 rtiI ���I'�. .J. P . r�,�i l.' uP� �1 ' � iitil M1� 4 t`1 _ ..� f s�h�%�.��sus�.WU.�.�r.x�,�,r..., '� ..�........ 1i.u....._.�.�.�..,. u�ii ......�tl..�V .�,us...a«,.,...�...�.. Reclaimed Water 0.90 3.90 5.20 I11 11 : .wuearw.1"a=1V .1. a; r I ;..$J.,u:wr."..,w I',>Wrusww. aigNIr<,. 1.7-MGD Fresh and 1.7-MGD Brackish Water Fresh Water/ Treatment Facility Expansion Brackish $20.5 1.70 3.40 Total Potable Water $20.5 3.40 3.40 r t iyr�..� y'4 % r r rl{ 4.3-MGD Phase Expansion of Wastewater Treatment Facility Reclaimed $17.0 3.00 4.30 Total Non-potable Water $17.0 3.00 4.30 { eJEr V >a- �eFr�4 : w q i1 r ,, e r� r a k Iwl ro r M 9 w ui{�h1" ,� .�Yr "Tlluh�� RT � i _ ,a. i Atm. 2012 LWC Water Supply Plan Update 149 COLLIER COUNTY WATER-SEWER DISTRICT County:Collier County Description: Potable water supplies consist of 41 percent Service Area: Portions of unincorporated Collier fresh groundwater and 59 percent brackish groundwater County is served including Goodland and Golden Gate and are projected to be 38 percent fresh groundwater and Estates, and a small portion of City of Naples, and 62 percent brackish water supplies in the future.This utility Orange Tree in 2013 is reusing 86 percent (12.28 MGD) of its wastewater(FDEP 2010b) and has reused 92 percent of its wastewater over the past five years(2007-2011). Bulk water: Provides potable water supply to Marco Shores in the City of Marco Island, and receives potable water supply from Marco Island Utilities for unincorporated Key Marco and Goodland. Population 164,933 195,601 232,197 Per Capita(GPD finished water) 176 176 ME= SAS 26.50 IAS 16.00 FAS 10.00 §° d =.= "u,uk�� �-��«« o"..,,,,.a ... .. Lul, ._ .. 3__ _ ... SAS 24.00 24.00 24.00 IAS 0.00 0.00 0.00 FAS 28.00 28.00 40.00 _,....-, 1�.° '1 yle . x-r -7.7t7 . ... I 7 r...* r...P� r NdM I"+ Reclaimed Water 40.10 42.60 42.60 - u lil sy�. a JI x h a - - f "pall w��w� °:,�.�.,.":.��ul�c� � �-. �� �,�. �u.F � = �„�..... �_,�.�wz� _.��,,�.� .._. .L�,.._, �¢_w,�,-� ���� v Construct 10.0-MGD Northeast County RO Water reatment Facility(including Floridan wells)(2024) Brackish $120.0 0.00 10.00 2.0-MGD Expansion of North County Regional High Brackish $9.0 0.00 2.00 Pressure RO Train(2030) Total Potable Water $129.0 000 12.00 4k � JM � .-1.h-la ,m, mr 1 3ry itd ..°u ' 1G 7Y j. 9 50. , «1S H il gi0. ° ASR(2013-2015) Reclaimed $5.0 2.50 2.50 r f.} a ". Notes: Franchise area of Orange Tree Utility Company is planned to be added to the county's service area in 2013. Pelican Bay Reclamation Facility(1.2MGD)was decommissioned in 2005.Collier County Water-Sewer District supplements their reclaimed water with fresh water from SFWMD permit number 11-00052-W and allocates 1.65 MGD from the Tamiami aquifer and 3.5 MGD from the water table aquifer. 150 I Chapter 6: Water Supply Development Projects CITY OF EVERGLADES County:Collier County Description: Potable water supplies consist of 100 Service Area: Everglades City and portions of percent fresh groundwater and are projected to unincorporated Collier County serving Plantation remain the same in the future.This utility is reusing 28 Island and Seaboard Village in Copeland percent (0.07 MGD) of its wastewater that is reclaimed through a rapid infiltration basin. Population 1,523 1,715 1,929 Per Capita(GPD finished water) 167 167 167 Gi SAS 0.29 SAS 0.50 0.50 0.50 IAS 0.00 0.00 0.00 FAS 0.00 0.00 0.00 till)lh' ,illi -- �' pss.. �ws.u. u ...qW . ... _. ,. .._.�a.w��..�. W, ..I. _,.. . _ ., _. ate. Reclaimed Water 0.16 0.16 0.16 No projects - - - - 2012 LWC Water Supply Plan Update 151 FLORIDA GOVERNMENTAL UTILITY AUTHORITY (FGUA)- GOLDEN GATE County:Collier County Description: Potable water supplies consist of 100 Service Area: Portion of unincorporated Collier County percent fresh groundwater and are projected to serving Golden Gate remain the same in the future.This utility is reusing 43 percent(1.2 MGD)of its wastewater that is reclaimed through a rapid infiltration basin. Population 27,890 29,727 31,711 Per Capita(GPD finished water) 54 54 54 p 1e e�..j.0n�410P In a a a f 41`FY-S.°�'� MA l! .,. SAS 3.42 SAS 2.10 2.40 2.40 IAS 0.00 0.00 0.00 FAS 0�.00 ...N. a...._ ._._0_.00 . .. ..� A..r0.0.0 r17 rv: 1 ,, , S f 1. +Yt �au.. Reclaimed Water 1.50 1.50 1.50 ta' i l+ 4w^w' hk y�. /1;,�"b' m d!'' Y ..y..a. , 0.3-MGD Expansion of Fresh Water Treatment Fresh $1.9 0.30 0.30 Facility(with RO Treatment)and SAS wells,Phase 4 Water Total Potable Water $1.9 0.30 0.30 Ni,�? a 7 ; 'k ,1'4111 '9A"Taabie No projects - ta e� *, du", :!:Ar xfi ':. ry eekk p m .S % '. Tfiq y� y�ill....�"� ih ti � ��,.,� � � _ �r�ar+ s�- �W �,I �,� �� � "" �� Ne ,.��n , .� I ^� .�^:ry r'� a.L� r n.a�,..,ata�-,.�.,:�,Ya+�� >.�riy. Note:Combined RO and lime softening treatment,1.1 MGD and 1.3 MGD,respectively,due to poor water quality. P.. 152 I Chapter 6:Water Supply Development Projects IMMOKALEE WATER AND SEWER DISTRICT County:Collier County Description: Potable water supplies consist of Service Area: Portion of unincorporated Collier County 100 percent fresh groundwater from the Lower serving Immokalee Tamiami aquifer and are projected to to be 65 percent fresh groundwater and 35 percent brackish water supplies in the future.This utility is reusing 36 percent (0.54 MGD)of its wastewater through a spray field. Population 27,273 30,426 33,947 Per Capita(GPD finished water) 95 95 95 ��' H'"Yror n i yariu�„a.,Myl� s� X � . "Y y I�u y,ul �Mm4�r ". 1Nl ��X IM .( q(4i .:: ill pF��A l�f f, N 9 1�u wR1,a��,it,wu ^.., � az� SAS 3.45 FAS 0.70 r ill fill w.it a �'�r4Poi r i''lY�vf r,',�"d t'"¢N�f f irru' i RI If1 �3. �1I r SAS 5.60 5.60 5.60 0.00 0.00 0.00 FAS 0.00 0.00 3.00 Alr.oYo 1, erh �y'I f, Reclaimed Water 2.50 5.50 5.50 'II , r ! o-i .^.;VLG�+�� _ maw�Vi I SI §���°�..�,.. s.a,�a..-.u§.�_...,... .._.'.r¢. ,.urn.^a�k�.rYY�»,sa�.r�e�;'.^,L ,.. .. .� .. .i. . .... �.�a3�P..,._.....r,.. . . .. ... ...W,� 2.5-MGD RO Water Treatment Facility and Brackish $10.0 2.50 2.50 Floridan Wells(2020) Total Potable Water $10.0 2.50 2.50 . ..�Luw�wY.➢rna^�!� N'� .. �w u� .�,^.�"_�.�,k9U�aa�., 3.0-MGD Wastewater Treatment Facility(2013) Reclaimedy $2.0 3.00 3.00 Total Non-potable Water $2.0 3.00 3.00 !® iN�, r i ,.. V a fur. Note:Wastewater treatment facilities require improvements before public access irrigation is possible. 2012 LWC Water Supply Plan Update 1 153 MARCO ISLAND UTILITIES County:Collier County Description: Potable water supplies consist of 53 percent surface water from the Service Area: City of Marco Henderson Creek/Marco Lakes ASR System, and 47 percent IAS groundwater from Island, including Key Marco, and the Mid-Hawthorn aquifer and is projected to be 63 percent surface water and a portion of unincorporated 37 percent brackish water in the future. This utility is reusing 82 percent Collier County serving Goodland (1.55 MGD)of its wastewater that is reclaimed through a rapid infiltration basin and public access irrigation. Bulk water:Marco Island Utilities provides potable water to unincorporated Goodland and Key Marco in Collier County. Marco Island Utilities receives potable water from Collier County Water-Sewer District to serve Marco Shores. Population 19,424 19,560 19,707 Per Capita(GPD finished water) 428 428 428 L.I„ 171V dd :.11111q1 p; fY PVy�IWl a .. . 61 � vW.7 SAS 4.38 IAS 4.00 FAS ° 4.38 fp l )R1,1'a 9 a I - , -wur . a q u tom.. SAS 6.70 10.03 10.03 IAS 6.00 6.00 6.00 FAS 0.00 0.00 0.00 111r,t a .F17 r 1#..1 u 4 __....I w.s.Y 1fy,.s74'!. i Iln... &" i i���.. 4 au Reclaimed Water 3.80 4.10 4.10 3.3-MGD North Water Treatment Facility Expansion with Two Pall Membrane Trains Followed by Replacement of Lime Softening System with Fresh $10.0 3.33 3.33 Low Pressure RO Total Potable Water $10 0 3.33 3.33 310 7'1111101 �l'P"Yr ll ' �r" wi;l a :, , . d. xae 7-21 a§c,. •..'IN` n �I11 k :.'b." 4'"3'111 ; Marco Island Wastewater Treatment Facility(existing capacity 4.92 MGD) Reclaimed $6.2 0.00 0.00 Two Pipeline Extensions(Club Marco and West Elkcam)b 0.3-MGD Expansion of Marco Shores Wastewater Treatment Facility Reclaimed $1.6 0.30 0.30 Total Non-potable Water $7.8 0.30 0.30 a.Does not include a large seasonal population. b.Not included as new treatment capacity. 154 Chapter 6:Water Supply Development Projects CITY OF NAPLES UTILITY DEPARTMENT County:Collier County Description: Potable water supplies consist of 100 Service Area: City of Naples and portion of Collier percent fresh groundwater from the Lower Tamiami County serving unincorporated East Naples aquifer and is projected to remain the same in the future.This utility is reusing 71 percent(4.65 MG D)of its wastewater that is reclaimed through public access irrigation. Additions: Provides potable water to serve East Naples in unincorporated Collier County, which accounts for 56 percent of the total area served. Population 66,645 70,123 73,348 Per Capita(GPD finished water) 260 260 260 p ii lr Vi lIAIn Y, 4 Yi - _ Y+ ,� 'II Vul IN i,l , SAS 18.42 p� �BPr Ru'4tl�i°i11r1N - a�" x1 il['11111t SAS 30.00 30.00 30.00 IAS 0.00 0.00 0.00 FAS 0.00 0.00 0.00 ppdS�m'�el'L.1, JV 1 11 1 '177 s E ¢ x ir',I-A'. 1 v tl } 1 Ci mu�'.��.aduVi ,11 7 r,, W m '"p Reclaimed 10.00 10.00 10.00 Surface Water 0.00 10.00 10.00 ASR Wells 0.00 4.00 4.00 4 .rlt. - � IrX�11 , �rr ��. i � �.x,�. ..�tn,�6 t^� �$ r. � 1 �.r B �hV d s YR...11 ', k IIV Id111� M1 l VINI Rti °,a„t`a Vcn w xv4�t ', 11 °'' ww�u.v,� ;,. •.�: No projects - - - - Total Potable Water - - - -_ � III $ t w=� 1 M1++aa�S VB Re r r w'�" �• �4�r' mIn °. srM1 r .'�r��b � i a' 'If s� f'1 r no i err n4 M1 d w, iv rVy tl4 M1r v �'�'�5 1 tl '.t a Construct 4.0-MGD ASR Wells to Supplement Reclaimed Water During Dry Season with Surface ASR $6.0 4.00 4.00 and/or Reclaimed Water Construct 10.0-MGD Pump Station and Transmission Main from Golden Gate Canal to Surface $5.5 10.00 10.00 Wastewater Treatment Facility Total Non potable Water $11.5 14.00 14.00 a^ �� IY�bi �" '.Y @U�11 VI u J l ltl : 1 k IIU " 8. lk�.' �V",ntl iry 1 2012 LWC Water Supply Plan Update 1 155 ORANGE TREE UTILITY COMPANY County:Collier County Description: Potable water supplies consist of Service Area: Portion of unincorporated Collier County 100 percent fresh groundwater from the Lower serving Orange Tree Tamiami aquifer. Additions:Collier County Water-Sewer District plans to add this franchise area in 2013. Population 1,261 0 0 Per Capita(GPD finished water) 238 0 0 .. �� by4{V IVi V u:.Il.n . hl Vy l m Ivl III°�ll1t• Irvin. .. s .u '^r P _ ''�' s —1 cU..,� �` lud � SAS 1.30 P Mf M IYnIir S r' 'N r, r' gY�Il rr, �VV I.� i �kh Ip 1 I��� , I SAS 0.75 0.75' 0.75 IAS 0.00 0.00 0.00 FAS 0.00 0.00 0.00 J� n ry ih h^4wIV II h' a9 I1,1 6' h'�pwi s r Y > „ � ..... �.�.. .s;u a v'I itimx.z..�.. �. :._. ` _... 17i _.W..,�. , f 6 14 w r 1 .._�... I �r� .�.... .� _. .r�W��... _.. �.�a<... ..I Id��,E.s. Reclaimed Water 0.40 0.40 0.40 No projects - - - - a.Capacity will be added to Collier County Water-Sewer District. 156 I Chapter 6:Water Supply Development Projects PORT OF THE ISLANDS COMMUNITY IMPROVEMENT DISTRICT County:Collier County Description: Potable water supplies consist of Service Area: Portion of unincorporated Collier County 100 percent fresh groundwater from the SAS and is serving the Port of the Islands projected to remain the same in the future.This utility is reusing 100 percent (0.05 MGD and 0.19 MGD with supplementation) of its wastewater that is reclaimed through public access irrigation. Population 568 682 819 Per Capita(GPD finished water) 174 174 174 11re W'. 14'14'- �L-r�111 N i .r1 111 r u 1r WW1 X1 i.,!,T �^aylN:.! ad I v= - 1 .� � dz � = r �- ,r �X ����,� �� FbrE ����_ ' SAS 0.55 s 1m'11''1'7" 1 ,111X1111 11119 T"^ ", YA tl n "ah' r 19T"""P 9p 43xr1""#'"�h"M1 ),, p 1 '7 .ice `a 5:1pY *� y ^1°iI �1 1111 11 r �Xd 1�� 1IS E 3 k tl�NI 1 1 y 0 y. I1 4 1 r a'"'v', . 111nN�wl.P.�..»�.�..- ,.��,. _�._ ... E..f".v�+t„`1 .w..,. 111P..as�. .. .... �XIJI"V. _,� SAS 0.44 0.44 0.44 IAS 0.00 0.00 0.00 FAS 0.00 0.00 0.00 y prr y,17�u 3�uw 70"..�r 1',14,1 h�.. _N e 11 1x,1�1�N.,...* n ifI.WA k-1.. �? s, �. ,,_. ..,... 1,x,=.2 Reclaimed Water 0.20 0.20 0.20 No projects - - - 2012 LWC Water Supply Plan Update 1 157 MOORE HAVEN UTILITIES County:Glades County Description: Potable water supplies consist of Service Area:City of Moore Haven and unincorporated 100 percent fresh groundwater from the SAS and is Glades County projected to remain the same in the future. Wastewater use not reported in the FDEP inventory. Population 2,927 ® 4,735 Per Capita(GPD finished water) 140 140 140 t: r�°: k t a Fd�y ^�.1..�. l:.. d :.da:i i .1a 131.4! ✓I �. .; 7d bi SAS 0.89 .;��.u�3s `3Yd uhyll 1 �I EP°u' r M per 'e `(.e lu�lli�l SAS 0.96 0.96 0.96 IAS 0.00 0.00 0.00 FAS 0.00 0.00 0.00 "4V"v n W6 � 1d f u1iigl9�li r a iIPilPy�l4 r, - +k iu.. � 1111 n� 1!�" t`1�.......�dd�Pa�u�ll�.�. ._....a.� �.��=_a:. .,W �-.,V �x...,', ..,.y�4 id .. -.......��d�w�. �. .u.�uu�� _., ....��',, Wv d�W ..�_ .... .. .w.. _rte..�.�1 .0 _ Reclaimed Water 0.20 0.20 0.20 No projects - - - 158 I Chapter 6:Water Supply Development Projects CLEWISTON UTILITIES County: Hendry County Description: Potable water supplies consist of Service Area: City of Clewiston and portions of 100 percent brackish groundwater from the FAS and is unincorporated Hendry and Glades counties projected to remain the same in the future.This utility is reusing 100 percent (1.18 MGD) of its wastewater that is reclaimed through a spray field and two rapid infiltration basins. Bulk water:Provides potable water to South Shore Water Association,serving Harlem and Airglades Airport. Population 15,287 15,618 16,001 Per Capita(GPD finished water) 104 104 104 d II,.,, { s ` ,!i I• _ i I III p .• hr!°!�°. m^^a 11 l ^a V I! FAS 2.58 'a.a. ri�I�I rrr". VIII I ^' r.m :ci '�+m ^,f• a ..Ir n I,"- SAS 0.00 0.00 0.00 IAS 0.00 0.00 0.00 FAS 3.00 3.00 3.00 �� m al lff aM ra% O 1 P.1141 '7:'' '''''''',,'' 1 P a:a7r'1 �, i_ ¢ .,uIII�Ij.. ,�_e�� �....,,.a� —s,::.� __ v_.a wl ... s.�u, � �..:.4 ... I,.. �... .fi4 ., ^.. ,t�u@ ___r,.. Reclaimed Water 1.50 2.25 2.25 rF:a v,lu d w. 4,IV Ir.r wV" # 4e II d Irdl 4 i.::. ,.aM4 1"� . '� ��.. - ., r, v' + ,,, �. ,,,—.,„ VUtl���a^,. .. . No projects - - - - Total Potable Water N{ r rgr V - , q ,4 ,, I 1. I l .- 4 p I' 'AID 1 w _':f it { a: L iv,Lio .—.,,,,%,,,; . ,,,,t,v . „., i ,,— . —, ..� , 0.75-MGD Water Treatment Facility for Public Reclaimed $1.5 0.75 0.75 Access Irrigation(Golf Course)(2014) Total Non-potable Water $1.5 0.75 0.75 . y - _ 4 =P° i 5 u P" W � ' ._ - - s i” ^,.,;I, m # Mw; ,' y i � ,5k r' r aw.^ T " d :m , : • r L°12, .v.VI.p ere:9i ,0 ' d , ,,,, 3 4h ,. aa J � Note:No longer associated with U.S.Sugar Corporation(Consumptive Use Permit 26-00024-W). 2012 LWC Water Supply Plan Update 1 159 HENDRY COUNTY CORRECTIONAL INSTITUTION FLORIDA DEPARTMENT OF CORRECTIONS County: Hendry County Description: Potable water supplies consist of Service Area: Portion of unincorporated Hendry 100 percent fresh groundwater from the SAS and is County serving Hendry County Correctional Institution projected to go to nothing in the future. This utility is reusing 100 percent (0.24 MGD) of its wastewater that is reclaimed through a spray field and two rapid infiltration basins. In 2010,this institution's average inmate population was 1,450.This correctional facility closed in June 2011 and the work camp(350 people)is projected to close in July 2012. Population 0 0 0 Per Capita(GPD finished water) not applicable not applicable not applicable law�^?9 w'Fo 0iw °,!.i uw: l 0 W7 f *f .04 "s . -B . 6 CI 1111 . ^...s i w.. r)16' ve.:...!4) SAS 0.07 Nildi I�ulwwp� l li �r xFy :r,' ',4_11I-1'1` w ii1� J�N�q "1 7,*, pt-191"1, .� _,k,I.w,, SAS 0.60 0.60 0.60 IAS 0.00 0.00 0.00 FAS 0.00 0.00 0.00 nt rIT3 1, 4 s fll � �. �' � i pw �'r l��vo v. ard 1 v Reclaimed Water 0.36 0.36 0.36 No projects - - 160 I Chapter 6:Water Supply Development Projects CITY OF LABELLE DEPARTMENT OF PUBLIC WORKS County: Hendry County Description: Potable water supplies consist of Service Area: City of LaBelle and a portion of 100 percent fresh groundwater from the SAS and is unincorporated Hendry County projected to be 40 percent fresh water and 60 percent brackish water in the future.This utility is reusing 100 percent (0.33 MGD) of its wastewater that is reclaimed through an infiltration basin. Population 5,804 6,298 6,831 Per Capita(GPD finished water) 124 124 124 rrrrirri s..= �' 1' �,'� €#^°ra in h IP t ,+4,r ilf r wl V e VIII f°F+„Irr SAS 0.93 FAS 0.12 -�, hR liq ny ilk hC�,y uu, 'R' h ... "d {il 1i �w .I III r 7 w � F �� � -��;V&r��udaa �'' � } '���I��rt��.� � I II . � � itl�I` ..- .,. �.�_ .�u...... + SAS 1.00 1.00 1.00 IAS 0.00 0.00 0.00 FAS 0.00 1.50 1.50 � nr , joF ”.l pirrf I r 9 pwi u,Mx .n i rm '"Y...�.�.z..fr,ti.f.�¢y"aid.. Reclaimed Water 0.75 1.05 1.05 Construct 1.5-MGD RO Water Treatment Facility Brackish $18.0 1.50 1.50 and FAS(Lower Hawthorn)Wells(2011-2013) Total Potable Water $18.0 1.50 1.50 �.. x. rrt,} + us� u�+i4! w1P'�b� �'.t r r w�yll d�k� �. ' —`aa�' wX� 1'iy tr �} 1, # -# '�l' 'l' f I m u i a� Z �*. t w t W -r Sid k ltk' �. -:fd ���r`, .�)�.�.:.��Ir_�,�"a� .d���t.� ,�:����.�4 a. .. ,�_. , a,�,�l�. ,�awui.u.�� .,a��r�,.�d,�.�,���,4�. ,, 0.3-MGD Wastewater Treatment Reclaimed $4.0 0.30 0.30 Facility Expansion Total Non potable Water $4.0 0.30 0.30 Notes: Potable water previously purchased from Port LaBelle Utility System of Hendry County has been discontinued. Potable water treatment facility is adding membrane treatment to keep current treatment capacity and to resolve the FDEP Consent Order to replace the plant. 2012 LWC Water Supply Plan Update 1 161 PORT LABELLE UTILITY SYSTEM OF HENDRY COUNTY County: Hendry County Description: Potable water supplies consist of Service Area: Portions of unincorporated Hendry and 100 percent fresh groundwater from the Sandstone Glades counties aquifer system and is projected to remain the same in the future. This utility is reusing 100 percent (0.23 MGD) of its wastewater that is reclaimed through a rapid infiltration basin. Population 3,957 5,294 7,084 Per Capita(GPD finished water) 85 85 85 Il i fVM§'.. :. Cww a s r _0 i1� ms's . ui ll4 -� a"W �{ t lu izv' iw { il,tiFi H °W..1 iF :`a IAS 0.56 11111 11'1 1,1111 't SAS 0.00 0.00 0.00 0.90 0.90 0.90 0.00 0.00 0.00 ijld �ywR T i� 4#a K 4 'J� �r v !!i n�i� in�.V wd Reclaimed Water 0.50 0.50 0.50 No projects - - - - Note:Bulk potable water sales to the City of LaBelle have been discontinued. 162 I Chapter 6:Water Supply Development Projects BONITA SPRINGS UTILITIES County: Lee County Description: Potable water supplies consist of Service Area: City of Bonita Springs and a portion of 58 percent fresh water from the Lower Tamiami aquifer unincorporated Lee County serving Estero and 42 percent brackish groundwater from the FAS and is projected to be 48 percent fresh water and 52 percent brackish water in the future. This utility is reusing 99 percent(3.88 MGD)of its wastewater that is reclaimed through public access irrigation(7.20 MGD). Populationa 50,866 66,849 87,845 Per Capita(GPD finished water) 199 199 199 r � a ,. I i3 d° i, flAtTl 9sj e "�� { sins�.`YI•r�I 11 � ak�rlti Ir` t3,��"«. SASb 5.74 0.00 FAS 0.00 13.07 III III II 1 I la 0.H, iI ]7vW I. I J�1 I r.. � ,.. ;I iG " �wa� SAS 9.00 9.00 9.00 IAS 0.00 0.00 0.00 FAS 6.60 9.60 9.60 P- .� yrr g'�11111Np1",I i' Reclaimed Water` 11.00 11.00 11.00 �r�; 'w.�.w�.:ma.. iw�a�,4.w' ." I"wG.. V..uw"Jall,.��iau s.0.,�d.k"'W.,V� ...s:FU,'.w.. a::•» ,«... ��w..w�u .�. ..�w,.40A.+ 3.0-MGD Water Treatment Facility RO Expansion, Brackish $30.0 3.00 3.00 Phase 2(2020) otal Potable Water $30.0 3.00 3.00 �'k I �a "1 r N o ° Q ...... r wrd n u"41 a ..on °'b° b�lr :225111 ,L, ,nl.,Yw: ," ,.�,�� ._.n ua tx� ,���R��.4 ,. 1.ku�V,'dr. .WfLUra+:s.,�r,I9d�V�r��.,..�. .S�tlmV'&.w8!.i. ""u�SVm '.i," .. No projects - . 3 a era _ .. r1 y 1ul 9 9 I I .�o��u.�,�..�..__-�._.-. ��rLuc.�VluLFseVr. �_,..I.� _ .,I�4. ....� w ti.,� .„XL— a. Does not include a large seasonal population. b.Limitations on source(Lower Tamiami aquifer). c.All reclaimed water is supplied to Resource Conservation Services. Note: Bonita Springs Utility has two-way interconnects in place for Lee and Collier counties.Other than testing purposes,the interconnects have not been utilized since 2008. 2012 LWC Water Supply Plan Update 1 163 CAPE CORAL UTILITIES County: Lee County Description: Potable water supplies consist of Service Area:City of Cape Coral 100 percent brackish groundwater from the FAS. This utility is reusing 99 percent of its wastewater that is reclaimed through public access irrigation(23.39 MGD). Bulk water: Provides potable water to Greater Pine Island Water Association as needed. Population 136,694 199,249 290,717 Per Capita(GPD finished water) 101 101 101 FAS 39.25 - ' fppry IMI�Iwrr 1'1'I; I II I r: SAS 0.00 0.00 0.00 IAS 0.00 0.00 0.00 FAS 30.00 54.00 54.00 a 11, §IJ�i14uo, Reclaimed 20.00 20.00 20.00 Canal system 0.00 1.80 1.80 �� urr v} EhilP JI aeuof r 6 Y r { E i .,:. w.. E E� «.„§ t'. .F_.....,,.... .....i,4{+:LWvler� .,r,.sS.�Y ....a,J, .... .... ''....nW A ._.. . y . ._. . ,.a . 24.0-MGD Expansion of the North RO Water Treatment Facility,Expansion from 12 MGD to Brackish $134.0 24.00 24.00 36 MGD,Phase 1 Total Potable Water $134.0 24.00 24.00 r`"IrN E I;, T4106 1.8-MGD Canal Weir Improvements Surface $3.5 1.80 1.80 Total Non-potable Water $3.5 1.80 1.80 I�°o rltl a s9 - r .13E'd I1" an§41i4 �' II4� + II IIUI1d n � § Y, r a�'E rkI Note:The Water Independence for Cape Coral system combines reclaimed water and surface water for irrigation(Consumptive Use Permit 36-00998-W). 164 I Chapter 6:Water Supply Development Projects CITRUS PARK RV RESORT County: Lee County Description: Potable water supplies consist of Service Area: Citrus Park located within the City of 100 percent fresh groundwater from the Lower Bonita Springs Tamiami aquifer.This utility is reusing 100 percent of its wastewater that is reclaimed through a rapid infiltration basin(0.09 MGD). Population 1,706 1,749 1,795 Per Capita(GPD finished water) 113 113 113 11 II hall, I I SASa 0.21 til-I Plr�,. v r' ' vlllll r ' w. 1 r ruw.. �,..'1 )0!„-1,I ._- - yr v. _ ... SAS 0.54 0.54 0.54 IAS 0.00 0.00 0.00 FAS 0.00 0.00 0.00 :'�'y 7_11'a "141 'Sri 1) 57 I� a 4" ,wI 1 4 sr L3Y ' . �. 45 Rvr s��p 4P s` S imrry &r a,11 r .,p 4' II i� i � � � � d Y� � "1�Iidti�i. �f I l� a w w I Iw� mile CIF i rr aFV`� .� � �"��n�CU�h,l i.. -, ��_ ? �S8 �3.fr ��'� 4 ��-.,� W��..�.�' n Reclaimed Water 0.20 0.20 0.20 No projects a - - a.Source limitation on Lower Tamiami aquifer 2012 LWC Water Supply Plan Update 1 165 FLORIDA GOVERNMENTAL UTILITY AUTHORITY (FGUA)- LAKE FAIRWAYS County: Lee County Description: Potable water supplies consist of 100 Service Area: A portion of Lee County serving percent fresh groundwater from the Mid-Hawthorn unincorporated North Fort Myers aquifer. This utility is reusing 50 percent of its wastewater that is reclaimed through public access irrigation(0.09 MGD). Additions: Potable water and wastewater treatment is currently provided by the Florida Government Utility Authority(FGUA)—North Fort Myers,which purchased Lake Fairways/Pine Lakes in 2010. Population 3,322 0 0 Per Capita(GPD finished water) 57 57 57 IAS 0.10 "q01NIf I =fi> * aer F'F4 ry� r.1I "a $1,p' HI66q hkIS.�.. ..... SAS 0.00 0.00 0.00 IAS 0.20 0.20 0.20 FAS 0.00 0.00 0.00 '. fi ,),,r rp rG lwa� j1 r tl €a4MLl><:"z "alltll'wP1 ' r ix�n�vM,taGpw .;3S+pC7 `' 4,r 1QV .]9l ppu Itl 11101" e0� Nat ti4 Reclaimed Watera 0.30 0.30 0.30 .w :77 r aPr . S" g xa ,4414 No projects a.Reclaimed water available from North Fort Myers Utility. 166 I Chapter 6:Water Supply Development Projects FLORIDA GOVERNMENT UTILITY AUTHORITY (FGUA)- LEHIGH ACRES County: Lee County Description: Potable water supplies consist of Service Area: A portion of unincorporated Lee County 100 percent fresh groundwater from the Sandstone serving Lehigh Acres aquifer, and are projected to be 27 percent fresh groundwater and 73 percent brackish in the future. This utility is reusing 86 percent of its wastewater that is reclaimed through public access irrigation (1.70 MGD). Bulk water:FGUA has an interlocal agreement with City of Fort Myers to purchase up to 1.0 MGD in the future and is currently receiving between 0.1 to 0.5 MGD water. Population 29,050 53,431 98,298 Per Capita(GPD finished water) 80 80 80 u 9 ..�x 11 IIIN r QIl' ar, i sabiwl Ir r r ,..r t'atPws ilr:i o'.: +a v"' ''n 4 w .ii °' r,,ry I N�, j Mlii lrly` SAS 3.30 r(i s ! e - s k SAS 0.00 0.00 0.00 IAS 4.70 4.70 4.701 FAS 0.00 10.00 10.00 —1,q„""N: °1"11„,'r wntw.i ohw6' 6 Reclaimed Water 2.50 2.50 2.50 ' -wT 10.0-MGD Phased Expansion of Mirror Lakes RO Water Treatment Facility including FAS Wells and Brackish $91.0 10.00 10.00 Distribution Lines(contingent upon growth) Total Potable Water $91.0 10.00 10.00 .77 ia s {w rr No projects - ���wNy., u _ pw i rNwa . rw 1 lrP ''q .rSS1 u u"Nry �"°i " i �Ni �.,'k I!w' r i `. a���� x^ 1i,� s91 w�� wNi h� - r#' } `� tl�&w �Ii i'$6 ° Vrii f,f�&"i.4mriw"� ���0 wrr�i ��� a�� I i§r y u jaw .,A",4 x l ...���.v .41E�,....�+�1�6°6��� � �.,�� rw����.�_,.��.r,r..�ti��w..r. v v�°t .__�a=��,' .�. 2012 LWC Water Supply Plan Update 167 CITY OF FORT MYERS PUBLIC UTILITY County: Lee County Description: Potable water supplies consist of Service Area: City of Fort Myers and a few areas in 100 percent brackish groundwater from the FAS, and unincorporated Lee County are projected to remain the same in the future. This utility is reusing 45 percent of its wastewater that is reclaimed through public access irrigation (2.56 MGD). Bulk water: Potable water sold to Florida Government Utility Authority (FGUA) — Lehigh Acres, which may receive up to 1.0 MGD in the future. Population 62,964 72,929 84,528 Per Capita(GPD finished water) 133 133 133 411711,11Y':, n,., , °:s 1° y x r r ., y ! x4 ➢ 1 u — t r ._ aga" a, � 'yi I �uWlim y y ""u1+; � d Y"II°tll°rf W.u1 ��11i FAS 11.95 y 1 i $ , f m.ue.? ks,.�1.2. s i9,1111110'1 ti,1111 D ..a..µr r,..a..d� f 1 1'1,' t D m&1v 7� e• 1 p "."I SAS 0.00 0.00 0.00 IAS 0.00 0.00 0.00 FAS 13.00 13.00 13.00 �s �!*arr... 74 ;1�1 i., 1N,.r C.ad,i u r14i� r " s 7*`. �L7 T W*r...� m ,F 1-k z T- xaa �' s 06 1 1111 Reclaimed Water 11.00 34.00 34.00 No projects 12.0-MGD Expansion of the South Advanced Wastewater Treatment Reclamation Facility Reclaimed $13.2 12.00 12.00 (2013) 11.0-MGD Upgrades at the Central Advanced Reclaimed $10.0 11.00 11.00 Wastewater Treatment Facility(2011-2014) Total Non-potable Water $23.2 23.00 23.00 °A +)1,• a s:.4 L. .. a 4,a&s,°,1�uI 11✓uw..�....„.�u�u,c._w�_ - :,.��..,.Jy'I,J,1°�.ua,.�:.,a:..�uL�.:,..�'�`�:m`.,::�...., , V,a': ,,°, .. ! .w111. ... ..,.,.1.�1 !_u,.° ,. +fiu.�m�....._...�wLs3 168 I Chapter 6:Water Supply Development Projects GREATER PINE ISLAND WATER ASSOCIATION County: Lee County Description: Potable water supplies consist of Service Area: A portion of unincorporated Lee County 100 percent brackish groundwater from the Lower serving Pine Island and Matlacha, and a portion of Hawthorn aquifer, and are projected to remain the Cape Coral same in the future. This utility is reusing 100 percent of its wastewater that is reclaimed through a spray field and rapid infiltration basin(0.09 MGD). Bulk water:Receives potable water from Cape Coral Utilities as needed. Population 13,877 17,781 22,795 Per Capita(GPD finished water) 110 110 110 J44i1 = , .� _3. r� v Iu, ry. FAS 2.44 u x111111 SAS 0.00 0.00 0.00 IAS 0.00 0.00 0.00 FAS 3.30 3.30 3.30 r A ' ik wh ` mo Ml 11 c1 d i ^ rn �tlryIdrfE a }�1�1� Lid 2 1 1 tl ., u91�uu1ul�i� 1. Reclaimed Water 0.25 0.25 0.25 No projects - - _111.11111111 Note:Lee County Utilities provides wastewater service. 2012 LWC Water Supply Plan Update 1 169 ISLAND WATER ASSOCIATION County: Lee County Description: Potable water supplies consist of Service Area: Sanibel and a portion of unincorporated 100 percent brackish groundwater from the FAS. This Lee County serving Captiva utility is reusing 72 percent of its wastewater that is reclaimed through public access irrigation (1.03 MGD). Populations 8,509 9,042 9,605 Per Capita(GPD finished water) 377 377 377 FAS 4.96 ., SAS 0.00 0.00 0.00 IAS 0.00 0,00 0.00 FAS 6.00 6.00 6.00 6u y14 d r i� `i� xW�IJsk+ti�5 '"�.,5'i 'rk® hea d.i �.a, � I..�� ,. ..,..., Reclaimed Water 2.38 2.38 2.38 No projects - - - a.Does not include a large seasonal population. Note:City of Sanibel and South Seas Plantation provide wastewater service. 170 I Chapter 6:Water Supply Development Projects LEE COUNTY UTILITIES County: Lee County Description: Potable water supplies consist of Service Area: Unincorporated Lee County and some 20-percent brackish groundwater from the FAS, parcels in the City of Fort Myers 65 percent fresh water from the SAS and IAS, and 15 percent fresh surface water from the Caloosahatchee River (C-43 Canal). This utility is reusing 82 percent of its wastewater that is reclaimed through public access irrigation (8.35 MGD). Population 233,637 272,484 317,567 Per Capita(GPD finished water) 121 121 121 i" I d of.� ,.�k" ,� Surface water 0.00 4.43 0.00 SAS 0.25 7.84 2.29 IAS 0.56 10.61 0.74 FAS 9.98 14.21 3.06 �.Gzs rrat)j Ilul .f ri I : .. ylll�� �....�� ;4tii 1g yui Fnw���, �,. { . �'3r °� .�sa ...allr' I ., p, f SAS 5.00 5.00 5.00 IAS 28.10 28.10 28.10 FAS _ ,.. _ ., m.� . ,,... k 14.30 24.30 24.'30 l:pm l I _. ;.T _ , 11,:II n° , ' Reclaimed 21.55 21.55 21.55 ASR 0.00 3.00 3.00 Fresh 0.00 2.60 2.60 �,{ y4 �, r'r F• VkV �ulirw gm's i¢ '� y�� ✓i prt i ar"M^F .. Otai:CAp..��ar�avl�! i uCV �'8�.�.�l..�e�nuiuW�.�u.�..�xnu�c_ ...o��W�"ud.ulmll,....« _h,..v,.�{ r��:.�„ ay„ .y�.Wl a.�. ,. � ��. : �....w a.Limitations on sources. Note:Potable water interconnects with the Cities of Cape Coral,Fort Myers,and Bonita Springs for emergency use. 2012 LWC Water Supply Plan Update 1 171 LEE COUNTY UTILITIES (CONTINUED) Green Meadows Water Treatment Facility RO Expansion (includes FAS wells).(This water treatment facility currently has 9 MGD of freshwater capacity.) Brackish $53.4 5.00 5.00 (2011-2013) North Lee County Water Treatment Facility 5.0-MGD RO Brackish $21.0 0.00 5.00 Expansion from 10.0 MGD to 15.0 MGD(2025) Olga Water Treatment Facility RO Expansion from 5 MGD Brackish $40.0 0.00 5.00 to 10 MGD(2025) Green Meadows ASR Wells for Potable Water- Fresh $21.0 3.40 3.40 FAS Storage(2018)a otal Potable Water $135.4 8.40 18.40 _-M q ,!' p Ipp i��r�°�'1 iSW rr114 r �.ry,ry«, 'm`�mm -:*� 9 19.1-,Y �R .«r,. =r1 P�N'�'Ir w uSw gum" .- ,. , L,..a l,I�Vh�rVlll��r.�ti �,'}��a-.s'.-���.:y'k�e �`�. ',i�.. �6� - �_,� >� Construct the 2.0 MGD West ASR Wells for Reclaimed ASR $5.4 2.00 2.00 Water Storage (2018) Construct the 1.0-MGD Gateway Wastewater Treatment Facility ASR Well System for Reclaimed Water Storage ASR $2.5 1.00 1.00 (2018) 2.6-MGD Three Oaks Irrigation Quality Water Fresh Supplemental Reclaimed Supply(2013) Water $0'7 2.60 2.60 Total Non-potable Water $8.6 5.60 5.60 ;, '.nAu+r�7 u2u. Mi uipII"iil Y i r-� s i I a.Not included as new treatment capacity. 172 I Chapter 6:Water Supply Development Projects Future Direction This chapter summarizes the future direction for water supply TOPICS in the Lower West Coast (LWC) Planning Area. As this plan update confirms, utilities serving the LWC Planning Area have ♦ Water Sources established or identified water source options to address the water supply needs of the region through at least 2030. This ♦ Coordination plan update also concludes that the future water demands of the ♦ Climate Change region can continue to be met through the 2030 planning horizon with appropriate management and continued Conclusion diversification of water supply sources. Several steps are needed to achieve this conclusion: ♦ Completion of water supply utility projects ♦ Evaluation of site-specific refinement of groundwater availability ♦ Completion of the Comprehensive Everglades Restoration Plan (CERP) Caloosahatchee River(C-43)West Basin Storage Reservoir Project. Any increase in Lake Okeechobee's regulation schedule as a result of the Herbert Hoover Dike repairs by the United States Army Corps of Engineers (USACE) will be evaluated by the USACE through a National Environmental Policy Act analysis. It is anticipated the additional water from Lake Okeechobee as a result of Herbert Hoover Dike repairs and a revised regulation schedule would return the lake to Minimum Flow and Level (MFL) prevention status, enhance the level of certainty to existing permitted users now receiving less than 1-in-10 level of certainty,and support other environmental objectives. The water supply needs for natural systems are discussed in Chapter 3 and Appendices G and H and are considered a limitation on water available for allocation.These water supply needs are addressed through a variety of regulatory mechanisms and projects. The guidance offered in this chapter should be considered in developing water source options to meet future needs. Statutory requirements, existing conditions, resource constraints (including protection tools and criteria), and the needs of all water users are addressed, with emphasis placed on alternative water supply development, water conservation, and storage for environmental needs. The South Florida Water Management District's (SFWMD's) future direction for water supply planning in the LWC Planning Area also involves coordination between utilities and other water users and monitoring to respond to sea level rise. 2012 LWC Water Supply Plan Update 1 173 The renewal process for irrigation class consumptive use permits in the LWC w Planning Area began in 2004 and was mostly complete in 2006, except for the Lake Okeechobee Service Area. In r addition, many of the permits for Public /7 Water Supply (PWS) have been renewed for 20-year durations since the 2005- 2006 Lower West Coast Water Supply Plan Update (2005-2006 LWC Plan Update; SFWMD 2006) was published. Suburban Collier County The water source options from these permits were used in the development of this plan update. WATER SOURCES Withdrawals from the surficial aquifer system (SAS) are limited due to potential impacts on wetlands,as well as the increased potential for saltwater intrusion into freshwater sources. Withdrawals from the freshwater portion of the intermediate aquifer system (IAS) are also limited due to potential saltwater intrusion, or the potential for reaching maximum developable limits (MDLs). Therefore, new or increased allocations from the SAS and IAS will be reviewed on an application-by-application basis to determine if the project meets consumptive use permitting criteria. The Floridan aquifer system (FAS) is the source planned to meet many of the future PWS water demands in the LWC Planning Area. Most PWS utilities in the LWC Planning Area have diversified supply sources,and plan to increase their use of the FAS in the future. Blending brackish water from the FAS with fresh water may be a practical solution for meeting some of region's PWS and irrigation demands. In addition, the use of reclaimed water has increased significantly since the 2005-2006 LWC Plan Update,offsetting the use of groundwater to meet future water supply needs. Water needed to meet increased future PWS demand in the LWC Planning Area is expected to be developed primarily through the continued development of brackish groundwater resources,surface water captured during wet weather,new storage capacity of both surface water and groundwater, and expansion of reclaimed water systems. Power generation entities are planning power plants that will make use of brackish, surface, and reclaimed water where available. Agricultural water users continue to use surface water and fresh groundwater.Some water users can benefit from projects,such as stormwater and tailwater recovery,and more efficient water conservation practices. Primary surface water sources in the LWC Planning Area include the Caloosahatchee River (C-43 Canal) and connected canals, such as the Townsend Canal, Roberts Canal, and City Ditch. The Cape Coral and Big Cypress Basin canal systems also provide surface water supply, and to a lesser extent, local irrigation needs are met using stormwater ponds. Agricultural (AGR) Self-Supply is the largest water use category in the planning area, and 174 I Chapter 7: Future Direction AGR Self-Supply is the primary user of surface water for crop irrigation.Traditional sources may or may not be available to meet all new irrigation requirements depending on the specific locations for new operations. Fresh groundwater may be available, but quantities will depend on local conditions,including other uses in the area. Water availability from the Caloosahatchee River (C-43 Canal) and its tributaries is significantly limited due to implementation of the 2008 Lake Okeechobee Regulation Schedule (2008 LORS) and recently adopted SFWMD consumptive use permit criteria. Concerns about the integrity of the Herbert Hoover Dike, which surrounds Lake Okeechobee, have resulted in a lowered operating schedule that, in turn, has reduced the level of certainty of Lake Okeechobee Service Area users experiencing water shortage restrictions only every 1-in-10 years to experiencing restrictions every 1-in-6 years. The estimated completion date for the Herbert Hoover Dike rehabilitation is 2022. Currently, a dam safety modification report is being prepared, which is expected to be completed in 2016.The report will include results from pilot tests. Findings in this report may influence the expected 2022 completion date (S.Kaynor,USAC E,personal communication). The SFWMD offers recommendations and guidance in the following sections for consideration by local governments, utilities, other water users, and SFWMD water supply managers and staff as a basis for the future direction of water supply planning in the LWC Planning Area. Groundwater Increased use of fresh groundwater sources to meet future demand in the LWC Planning Area is highly dependent on location, source limitations, natural system requirements, reclaimed water availability, and water conservation measures. Approximately 50 percent of the PWS demand in 2009 was met using fresh groundwater. Fresh groundwater is the primary source of supply for potable drinking water consumption and urban irrigation in the LWC Planning Area. Opportunities may exist for limited development of fresh groundwater sources through the following: ♦ Careful design of wellfield locations, configurations, and pumping regimes to maximize withdrawals while not impacting water quality or natural systems. • Blending multiple alternative water sources to achieve acceptable water quality and distribute potential impacts across these multiple sources. • Additional efforts to better understand the aquifer system, including the Mid- Hawthorn and Sandstone aquifers, and identification of areas of available fresh water are needed to meet future needs,especially agricultural water demands. 2012 LWC Water Supply Plan Update 1 175 Surficial Aquifer System ♦ The potential use of the SAS for new or increased allocations will be evaluated on an application-by-application basis to determine if the project meets consumptive use permitting criteria. To reduce the LWC Planning Area's reliance on the SAS, water users are encouraged to continue developing alternative water sources to meet future water demands. ♦ Utilities should consider using concentrate water from membrane softening of SAS water beneficially(e.g.,blending with reclaimed water if feasible). ♦ Coordinated saltwater intrusion monitoring is essential to ensure resource protection of the SAS and the Lower Tamiami aquifer. The Lower West Coast Surficial Aquifer (LWCSAS) Model was developed by the SFWMD to simulate groundwater flow and levels to represent existing and potential future hydrologic conditions in the LWC Planning Area. The model will be updated to include simulation of the IAS, and following this, a peer review of the updated model will be conducted in Fiscal Year(FY) 2014. Intermediate Aquifer System ♦ Aquifer water level in the Sandstone/Mid-Hawthorn aquifer in the Cape Coral area is declining over time. Additionally, in the Sandstone aquifer in Lehigh Acres, there appears to be a slight overall downward trend in water levels over the last 10 years,with some evidence of a slight rise in water levels over the last three years. The 2005-2006 LWC Plan Update indicated that accelerating the extension of PWS lines to such communities coupled with mandatory hook-up to available municipal lines and required proper abandonment of Domestic Self- Supply(DSS)wells should be considered. ♦ Facilitate discussions with local governments to assist with a long-term water supply strategy for sustainable DSS in the Lehigh Acres area. • Mapping of the top of the Sandstone aquifer in Lehigh Acres should be undertaken using available data from all sources, including the SFWMD, United States Geological Survey(USGS),and Lee County,to better determine the MDL at any location. Joint data collection is encouraged when drilling activity is occurring in the area. Floridan Aquifer System ♦ Local utilities are proposing significant increases in FAS water source development over the next 20 years. Local water users and utilities developing FAS well drilling programs and gathering data are encouraged to collaborate with the SFWMD. Water quality, water level, and hydrologic data from these wells can be utilized in SFWMD models, and to increase the knowledge and understanding of the FAS. Brackish water from the FAS may be blended with groundwater and surface water in stormwater ponds to produce acceptable irrigation quality water. Blended water supplies are dependent on the water sources, volume of stored water, and natural system requirements, and require monitoring to ensure acceptable water quality. 176 I Chapter 7: Future Direction ♦ Local governments, such as Collier and Lee counties and the City of Cape Coral, have developed numerical groundwater flow models to address their needs. These modeling tools may be integrated with or adapted to future SFWMD modeling efforts. ♦ The Lower West Coast Floridan Aquifer System (LWCFAS) Model focuses primarily on the various production zones that comprise the FAS in the study area within Charlotte, Glades,Lee, Hendry,and Collier counties.The recalibrated and revised transient model will be used in water supply planning efforts regarding the use of the FAS and potential impacts of water withdrawals on the resource and existing users. ♦ Landowners are encouraged to plug and abandon inactive or dysfunctional FAS wells in accordance with existing oilk rules and regulations. " I_ ♦ An incremental wellfield oi l: I development approach - mites should be used by utilities to design, test, and monitor production wells to minimize sudden changes in water Collier County Water-Sewer District South quality due to inconsistencies County Regional Water Plant in the FAS and overstressing production zones. Surface Water ♦ The Caloosahatchee River (C-43 Canal) is subject to Restricted Allocation Area criteria, which limit surface water withdrawals within the Lake Okeechobee Service Area.Accordingly,no allocations may cause a net increase in the volume of surface water withdrawn from the Lake Okeechobee Waterbody over a defined base condition water use (SFWMD 2010a). See the 2012 Lower East Coast Water Supply Plan Update for more information (SFWMD 2012b). ♦ The CERP Caloosahatchee River (C-43) West Basin Storage Reservoir Project should be implemented to help meet the MFL criteria for the Caloosahatchee River. Implementation of local storage projects is encouraged. A Water Reservation rule is currently under development for the CERP Caloosahatchee River(C-43)West Basin Storage Reservoir. ♦ Local governments and utilities are encouraged to create additional storage capacity for surface water,when feasible. ♦ Irrigation for new golf courses should use reclaimed water when available or continue to include on-site blending of brackish groundwater with surface water,if consumptive use permit criteria are met. 2012 LWC Water Supply Plan Update I 177 Reclaimed Water ♦ To plan for and increase the use of reclaimed water, local governments should consider requiring construction of ' a. reclaimed water infrastructure in new development projects exceeding specified acreage "` thresholds,and use of reclaimed + water (where appropriate) °-. » � •°- when it becomes available as part of their building codes and land development regulations. Expansion and Regionalization of Reclaimed • Local utilities are urged to Water Use is Encouraged expand the use of reclaimed water and minimize deep well disposal practices. ♦ To maximize the use of reclaimed water, utilities should continue to implement feasible options to extend their supply of reclaimed water,such as supplemental sources, metering for residential customers,tiered rate structures,limiting days of the week for landscape irrigation, and interconnects with other reclaimed water utilities. • Development of additional reclaimed water lines for landscape irrigation can decrease dependence on DSS and Recreational/Landscape (REC) Self-Supply surface water pumps and wells. ♦ Technical assistance to establish mandatory reuse zones will be provided to local governments by the SFWMD. Reuse zones are geographic areas designated by local governments through ordinance where reclaimed water use is required. ♦ The amendments to Section 373.250, Florida Statutes (F.S.) recognize the use of "substitution credits"and"impact offsets" to promote increased availability and distribution of reclaimed water and decrease impacts on traditional sources of water. Rulemaking is under way by the Florida Department of Environmental Protection (FDEP) to include this language into Chapter 62-40, Florida Administrative Code (F.A.C.). Once the FDEP concludes its rulemaking effort,the SFWMD will adopt the changes into their rules to be consistent with Chapter 62-40,F.A.C.,where appropriate. • The use of supplemental water supplies to meet peak demands for reclaimed water may enable a water utility to extend its supply of reclaimed water system over a larger area. However, during times of drought, availability of supplemental water sources such as surface water,groundwater,or storm water to supplement reclaimed water supplies may be limited in some areas. Use of these sources to supplement reclaimed water supplies is subject to consumptive use permitting by the SFWMD. 178 I Chapter 7: Future Direction New Storage Capacity for Surface Water or Groundwater ♦ New uses of surface water are possible only when new storage and stormwater capture options are developed. In the LWC Planning Area, potential types of water storage include aquifer storage and recovery (ASR) wells, reservoirs, and surface water impoundments and ponds. Six supplemental PWS utility water projects are proposed by 2030. These projects will add 11.8 million gallons per day (MGD) from captured storm water in canal systems. In addition, reclaimed water stored in ASR facilities may provide 9.5 MGD of seasonal capacity. Proposed projects that develop new storage and create additional water supply may be considered alternative water sources.The Dispersed Water Management Program sponsored by the SFWMD is designed to encourage property owners to retain water on their land rather than drain it,accept regional runoff for storage, or use both options. ♦ Improvements have been made to the Golden Gate Canal System to retain storm water.The effect of this project on local groundwater and its role during periods of atypical rainfall should be monitored for discussion in future plan updates. ♦ Construction of new or retrofitted surface water storage systems for agricultural operations could provide additional supply for irrigation and maintenance of wetland hydroperiods. Aquifer Storage and Recovery ♦ Continued use of ASR and other viable " 4 . storage options is needed to extend the use of current water resources to meet future demands. ASR extends water supplies for use during peak demand periods. Permitting considerations should be included in the evaluation process. ♦ Studies to address local and regional ASR issues such as arsenic mobilization should continue. Seawater ♦ Where appropriate, utilities may consider Cape Coral ASR Well Project the use of desalinated seawater from the Gulf of Mexico as an additional water source option for the LWC Planning Area. Water Conservation • The implementation of robust water conservation programs throughout the LWC Planning Area offers water use savings potential to reduce future water demand. All water users are urged to implement water conservation measures to further reduce water supply needs. 2012 LWC Water Supply Plan Update 1 179 • The SFWMD will continue to implement the 2008 Comprehensive Water Conservation Program, and plans to continue supporting programs such as the Big Cypress Basin Mobile Irrigation Lab (MIL),Water Savings Incentive Program (WaterSIP),Water Conservation Hotel and Motel Program (Water CHAMP),and Florida Water StarsM. • Local governments should evaluate the implementation of water conservation measures appropriate for their jurisdiction. PWS utilities are encouraged to use a water conservation planning tool to develop plans to implement water conservation measures with a numerical goal for achievable water savings.As a guideline, water conservation measures should include general policy considerations and technology retrofits as described in this plan update. SFWMD staff is available to provide assistance with the use of the Conserve Florida Water Clearinghouse's EZ Guide(2009). • Utilities are encouraged to develop goal-based water conservation plans. SFWMD staff is available to assist utilities in developing such plans. • Local governments should develop or enhance existing ordinances to be consistent with Florida-Friendly Landscaping' provisions (Section 373.185, F.S.). • Implementation of advanced irrigation technology, improved landscape design and management practices, and implementation of recognition programs can further increase landscape water use efficiency in this sector. • Water conservation public education programs help instill a year-round conservation ethic. Local governments and utilities are encouraged to continue providing water conservation-related educational programs in cooperation with the SFWMD. ♦ Local governments are encouraged to implement two-day-per-week landscape irrigation ordinances. Upon request, SFWMD staff is available to assist local governments with model ordinance methodologies, as well as to assist in implementing such an ordinance. • When applicable, agricultural water users are encouraged to use the Florida Automated Weather Network(FAWN)irrigation tools. ♦ Installation of higher efficiency irrigation systems by agricultural water users is encouraged where applicable and appropriate for specific crop types. ♦ Implementation of best management practices (BMPs) to improve water conservation and water use efficiency are economical measures to help meet future demands. ♦ Industrial, commercial, and institutional entities are encouraged to utilize the Water Efficiency Self-Assessment Guide for Commercial and Institutional Managers (SFWMD 2011b), to improve water use efficiency and reduce operating costs. 180 I Chapter 7: Future Direction COORDINATION • Coordination and collaboration throughout the water supply planning process is essential among regional and local governments,and utility planning entities. ♦ 10-year water supply facilities work plans are due within 18 months of the adoption of this plan update. Local governments and utilities need to provide linkage and coordination between this plan update and the local government water supply-related components of comprehensive plans. O Agricultural communities and agencies need to work together to develop methodologies and data sources for future crop projections. CLIMATE CHANGE Climate change has the potential to affect hydrologic conditions and thus water supply sources, as well as patterns of water demand. The degree of climate change in various regions and the possible impacts to those regions is highly uncertain. Despite uncertainties, the SFWMD is considering climate change and related effects on hydrologic conditions in the water supply planning process. Some types of change in climate and subsequent effects on hydrologic conditions have been observed by the scientific community. Long-term data show increasing temperatures and a corresponding sea level rise. For planning purposes, the SFWMD is estimating a sea level rise of 5 to 20 inches in south Florida by 2060 (SFWMD 2009a).The anticipated rise in sea level may change the hydrodynamics of the coastal estuaries and the location and shape of the freshwater—seawater interface,and may increase the intrusion of salt water into coastal aquifers. Analysis is needed to identify the potential impact of sea level rise on utility wellfields and other users at risk of saltwater intrusion within the SFWMD. In addition, comprehensive monitoring is needed to accurately characterize and measure aquifer conditions and saltwater movement. The following direction and guidance is provided for climate change and sea level rise within the SFWMD's water supply planning areas: ♦ Saltwater intrusion monitoring may be reviewed for adequacy by utilities and the SFWMD. Recommendations may be needed for additional or revised monitoring regimes. ♦ Use existing and future modeling tools that integrate density-dependent flow and solute transport to evaluate the consequences of sea level rise and cumulative impacts to existing legal users. CONCLUSION Future challenges in water resource development and natural resource protection require concerted efforts to monitor, characterize current hydrologic conditions, and predict future 2012 LWC Water Supply Plan Update 1 181 conditions. Existing analytical and numerical tools should be used to assess and reduce uncertainty, and to optimize the use and protection of water resources and other natural resources. Successful implementation of this plan update requires close coordination with other regional and local governments, and utility water supply planning entities. Collaboration among stakeholders is also essential for directing implementation of the preceding guidance. Public and private partnering can ensure that water resources in the LWC Planning Area are prudently managed and available to meet future demands. 182 I Chapter 7: Future Direction Glossary 1-in-10 year drought A drought of such intensity that it is expected to have a return frequency of once in 10 years.A drought in which below normal rainfall occurs and has a 90 percent probability of being exceeded over a 12-month period. A drought event that results in an increase in water demand to a magnitude that would have a 10 percent probability of being exceeded during any given year. 1-in-10 year level of certainty(see Level of Certainty) Acre-foot,acre-feet The volume of water that covers 1 acre to a depth of 1 foot; the equivalent of 43,560 cubic feet, 1,233.5 cubic meters, or 325,872 gallons, which is approximately the amount of water it takes to serve two typical families for one year. Agricultural best management practice (Agricultural BMP) A practice or combination of agricultural practices, based on research, field testing, and expert review, determined to be the most effective and practicable means of improving water quality or quantity while maintaining or even enhancing agricultural production. Agricultural Field Scale Irrigation Requirements Simulation (AFSIRS) Model A simple water budget model for estimating irrigation demands that estimates demand based on basin-specific data. The AFSIRS Model calculates both net and gross irrigation requirements for average and 1-in-10 year drought irrigation requirements.A crop's net irrigation requirement is the amount of water delivered to the root zone of the crop, while the gross irrigation requirement includes both the net irrigation requirement and the losses incurred in the process of delivering irrigation to the crop's root zone. Agricultural (AGR) Self-Supply The water used to irrigate crops, water livestock, and for aquaculture (e.g.,fish production)that is not supplied by a Public Water Supply utility. Alternative water supply "Salt water; brackish surface water and groundwater; surface water captured predominately during wet-weather flows; sources made available through the addition of new storage capacity for surface water or groundwater,water that has been reclaimed after one or more public supply, municipal, industrial, commercial, or agricultural uses; the downstream augmentation of water bodies with reclaimed water; storm water; and, any other water supply source that is designated as non-traditional for a water supply planning region in the applicable regional water supply plan" (Section 373.019,Florida Statutes). Aquatic preserve Water body set aside by the state to be maintained in essentially natural or existing condition for protection of fish and wildlife and public recreation so the aesthetic, biological,and scientific values may endure for the enjoyment of future generations. Aquifer A geologic formation, group of formations, or part of a formation that contains sufficient saturated,permeable material to yield significant quantities of water to wells and springs. 2012 LWC Water Supply Plan Update 1 183 Aquifer storage and recovery (ASR) The underground storage of storm water, surface water, fresh groundwater, drinking water, or reclaimed water that is treated to appropriate standards (dependent upon the water quality of the receiving aquifer). The aquifer (typically the Floridan aquifer system in south Florida)acts as an underground reservoir for the injected water.The water is stored with the intent to recover it for use in the future. Aquifer system A heterogeneous body of (interbedded or intercalated) permeable and less permeable material that functions regionally as a water-yielding hydraulic unit and may be composed of more than one aquifer separated at least locally by confining units that impede groundwater movement,but do not greatly affect the hydraulic continuity of the system. Artesian A commonly used expression, generally synonymous with "confined," referring to subsurface (ground) bodies of water, which, due to underground drainage from higher elevations and confining layers of soil material above and below the water body (referred to as an artesian aquifer),result in groundwater at pressures greater than atmospheric pressures. Available supply The maximum amount of reliable water supply including surface water, groundwater,and purchases under secure contracts. Base flow Sustained flow of a stream in the absence of direct runoff. It includes natural and human- induced stream flows.Natural base flow is sustained largely by groundwater discharges. Baseline condition A specified period of time during which collected data are used for comparison with subsequent data. Basin (groundwater) A hydrologic unit containing one large aquifer or several connecting and interconnecting aquifers. Basin(surface water)A tract of land drained by a surface water body or its tributaries. Basis of Review The publication Basis of Review for Water Use Permit Applications within the South Florida Water Management District(SFWMD 2010a). Read in conjunction with Chapters 40E-2 and 40E-20, Florida Administrative Code, the Basis of Review further specifies the general procedures and information used by South Florida Water Management District staff for review of consumptive use permit applications with the primary goal of meeting South Florida Water Management District water resource objectives. Biscayne aquifer A portion of the surficial aquifer system,which provides most of the fresh water for Public Water Supply and Agricultural Self-Supply within Miami-Dade, Broward, and southeastern Palm Beach County. It is highly susceptible to contamination due to its high permeability and proximity to the land surface in many locations. Boulder Zone A highly transmissive, cavernous zone of limestone within the Lower Floridan aquifer used to dispose of secondary treated effluent from wastewater treatment plants and concentrate from membrane water treatment plants via deep injection wells. 184 I Glossary Brackish water Water with a chloride level greater than 250 milligrams per liter and less than 19,000 milligrams per liter(Basis of Review; SFWMD 2010a). Capacity Represents the ability to treat, move, or reuse water. Typically, capacity is expressed in million gallons of water per day. Comprehensive Everglades Restoration Plan (CERP) The federal-state partnership framework and guide for the restoration, protection, and preservation of the south Florida ecosystem. The CERP also provides for water-related needs of the region, such as water supply and flood protection. Confining unit A body of significantly less permeable material than the aquifer or aquifers that it stratigraphically separates. The hydraulic conductivity may range from nearly zero to some value significantly lower than that of the adjoining aquifers,and impedes the vertical movement of water. Conservation (see water conservation) Conservation rate structure(see water conservation rate structure) Consumptive use Any use of water that reduces the supply from which it is withdrawn or diverted. Consumptive use permitting The issuance of permits by the South Florida Water Management District,under the authority of Chapter 40E-2, Florida Administrative Code,allowing withdrawal of water for consumptive use. Control structure An artificial structure designed to regulate the level/flow of water in a canal or other water body(e.g.,weirs,dams). Cubic feet per second (cfs) A rate of flow (e.g., in streams and rivers) equal to a volume of water 1 foot high and 1 foot wide flowing a distance of 1 foot in 1 second. One cfs is equal to 7.48 gallons of water flowing each second. For example, if a car's gas tank was 2 feet by 1 foot by 1 foot (2 cubic feet),then gas flowing at a rate of 1 cfs would fill the tank in two seconds. Consumptive Use Permitting Consistency (CUPcon). A statewide effort led by the Florida Department of Environmental Protection to improve consistency in the Consumptive Use Permitting Programs implemented by the water management districts. The individual water management district consumptive use permitting rules, while all developed under the authority of Chapter 373, Florida Statutes, are inconsistent. While some of the differences may be based on differing physical and natural characteristics,others are the result of development of separate rules and procedures over time. Goals of the effort include making programs less confusing for applicants, treat applicants equitably statewide, provide consistent protection of the environment, streamline the process, and incentivize behavior that protects water resources, including conservation. DBHYDRO The South Florida Water Management District's corporate environmental database, storing hydrologic,meteorologic,hydrogeologic,and water quality data. 2012 LWC Water Supply Plan Update 1 185 Demand The quantity of water needed to fulfill a requirement. Demand management Reducing the demand for water through activities that alter water use practices, improve efficiency in water use,reduce losses of water, reduce waste of water,alter land management practices,and/or alter land uses. Desalination A process that treats saline water to remove or reduce chlorides and dissolved solids resulting in the production of fresh water. Discharge The rate of water movement past a reference point,measured as volume per unit of time (usually expressed as cubic feet or meters per second). Disinfection The process of inactivating microorganisms that cause disease. All potable water requires disinfection as part of the treatment process prior to distribution. Disinfection methods include chlorination,ultraviolet radiation,and ozonation. Disposal Effluent disposal involves the wasteful practice of releasing treated effluent back to the environment using ocean outfalls,surface water discharges,and deep injection wells. Dissolved oxygen The concentration of oxygen dissolved in water, sometimes expressed as percent saturation, where saturation is the maximum amount of oxygen that theoretically can be dissolved in water at a given altitude and temperature. Domestic Self-Supply (DSS) The water used by households whose primary source of water is water treatment facilities and/or private wells with pumpages of less than 100,000 gallons per day. Drainage basin Land area where precipitation runs off into streams,rivers,lakes,and reservoirs.It is a land feature that can be identified by tracing a line along the highest elevations between two areas on a map,often a ridge.The drainage basin is a part of the earth's surface that is occupied by a drainage system,which consists of a surface stream with all its tributaries and impounded bodies of water.It is also known as a watershed,a catchment area,or a drainage area. Drawdown 1) The vertical distance between the static water level and the surface of the cone of depression, 2)A lowering of the groundwater surface caused by pumping. Drought A long period of abnormally low rainfall, especially one that adversely affects growing or living conditions. Ecology The study of the inter-relationships of plants and animals to one another and to their physical and biological environment. Ecosystem Biological communities together with their environment,functioning as a unit. Ecosystem restoration The process of reestablishing to as near its natural condition as possible, the structure,function,and composition of an ecosystem. 186 I Glossary Effective rainfall The portion of rainfall that infiltrates the soil and is stored for plant use in the crop root zone. Effluent Treated water that is not reused after flowing out of any plant or other works used for treating,stabilizing,or holding wastes. Effluent is"disposed"of. Electrodialysis Dialysis that is conducted with the aid of an electromotive force applied to electrodes adjacent to both sides of the membrane. Elevation The height in feet above mean sea level according to National Geodetic Vertical Datum (NGVD) or North American Vertical Datum (NAVD). May also be expressed in feet above mean sea level as reference datum. Environmental impact statement Required under United States environmental law by the National Environmental Policy Act for federal government agency actions "significantly affecting the quality of the human environment." An environmental impact statement evaluates the positive and negative environmental effects of a proposed agency action. Estuary The part of the wide lower course of a river where the current is met by ocean tides or an arm of the sea at the lower end of a river where fresh water and salt water meet. Evapotranspiration (ET) The total loss of water to the atmosphere by evaporation from land and water surfaces and by transpiration from plants. Exceedance The violation of the pollutant levels permitted by environmental protection standards. Existing legal use of water A water use authorized under a South Florida Water Management District consumptive use permit or existing and exempt from permit requirements. Fallow Land left unseeded during a growing season. The act of plowing land and leaving it unseeded.The condition or period of being unseeded. Finished water Water that has completed a purification or treatment process. Water that has passed through all the processes in a water treatment plant and is ready to be delivered to consumers.Contrast with raw water. Finished water demand (see Net water demand) Fiscal Year (FY) The South Florida Water Management District's fiscal year begins on October 1 and ends on September 30 the following year. Florida Administrative Code (F.A.C.) The Florida Administrative Code is the official compilation of the administrative rules and regulations of Florida state agencies. 2012 LWC Water Supply Plan Update 1 187 Florida-Friendly Landscaping'"'Quality landscapes that conserve water,protect the environment, are adaptable to local conditions, and are drought tolerant. The principles of such landscaping include planting the right plant in the right place, efficient watering, appropriate fertilization, mulching, attraction of wildlife, responsible management of yard pests, recycling yard waste, reduction of stormwater runoff, and waterfront protection. Additional components include practices such as landscape planning and design, soil analysis, the appropriate use of solid waste compost,minimizing the use of irrigation,and proper maintenance. Florida Statutes (F.S.) A permanent collection of state laws organized by subject area into a code made up of titles, chapters, parts, and sections. The Florida Statutes are updated annually by laws that create,amend,or repeal statutory material. Floridan aquifer system (FAS) A highly used aquifer system composed of the Upper Floridan and Lower Floridan aquifers. It is the principal source of water supply north of Lake Okeechobee. The Upper Floridan aquifer is used for drinking water supply in parts of Martin and St. Lucie counties. From Jupiter to south Miami, water from the FAS is mineralized (total dissolved solids are greater than 1,000 milligrams per liter)along coastal areas and in south Florida. Flow The actual amount of water flowing by a particular point over some specified time. In the context of water supply,flow represents the amount of water being treated,moved,or reused.Flow is frequently expressed in million gallons of water per day. Fresh water An aqueous solution with a chloride concentration less than or equal to 250 milligrams per liter(Basis of Review;SFWMD 2010a). Geophysical log A record of the structure and composition of the earth with depth encountered when drilling a well or similar type of test or boring hole. Gross irrigation demand or gross irrigation requirement (term used in AFSIRS Model) The amount of water that must be withdrawn from the source in order to be delivered to the plant's root zone. Gross irrigation demand includes both the net irrigation requirement and the losses incurred irrigating the plant's root zone. Gross water demand (or raw water demand) is the amount of water withdrawn from the water resource to meet a particular need of a water user or customer. Gross demand is the amount of water allocated in a consumptive use permit.Gross or raw water demands are nearly always higher than net or user/customer water demands. Groundwater Water beneath the surface of the ground,whether or not flowing through known and definite channels. Specifically, that part of the subsurface water in the saturated zone, where the water is under pressure greater than the atmosphere. Harm As defined in Chapter 40E-8, Florida Administrative Code, the temporary loss of water resource functions that result from a change in surface or groundwater hydrology and takes a period of one to two years of average rainfall conditions to recover. 188 I Glossary Headwater 1) Water that is typically of higher elevation (with respect to tailwater) or on the controlled side of a structure, 2) The waters at the highest upstream point of a natural system that are considered the major source waters of the system. Hydrogeology The geology of groundwater, with particular emphasis on the chemistry and movement of water. Hydrologic condition The state of an area pertaining to the amount and form of water present. Hydrology The scientific study of the properties, distribution, and effects of water on the earth's surface,in the soil and underlying rocks,and in the atmosphere. Impoundment Any lake, reservoir, or other containment of surface water occupying a depression or bed in the earth's surface and having a discernible shoreline. Indian River Lagoon A lagoon extending 156 miles from north of Cape Canaveral to Stuart along the east coast of Florida.The lagoon is one of America's most diverse estuaries, home to thousands of plant and animal species. Industrial/Commercial/Institutional (ICI) Self-Supply Water used by industrial, commercial,or institutional operations withdrawing a water quantity of 100,000 gallons per day (0.1 million gallons per day) or greater from individual,on-site wells. Infiltration The movement of water through the soil surface into the soil under the forces of gravity and capillarity. Inflow 1) The act or process of flowing in or into. 2) The measured quantity of water that has moved into a specific location. Injection well Refers to a well constructed to inject treated wastewater directly into the ground. Wastewater is generally forced (pumped) into the well for dispersal or storage in a designated aquifer. Injection wells are generally drilled below freshwater levels, or into unused aquifers or aquifers that do not deliver drinking water. Intermediate aquifer system (IAS) This aquifer system consists of five zones of alternating confining and producing units. The producing zones include the Sandstone and Mid- Hawthorn aquifers. Irrigation efficiency 1) A measure of the effectiveness of an irrigation system in delivering water to a plant for irrigation and freeze protection purposes. It is expressed as the ratio of the volume of water used for supplemental plant evapotranspiration to the volume pumped or delivered for use. 2) The average percent of total water pumped for use that is delivered to the root zone of a plant. 3)As a modeled (AFSIRS Model) factor, irrigation efficiency refers to the average percent of total delivered water applied to the plant's root zone. Irrigation water use Uses of water for supplemental irrigation purposes, including agricultural lands,as well as golf courses,nurseries,recreational areas,and landscapes. 2012 LWC Water Supply Plan Update 1 189 Landscape irrigation The outside watering of shrubbery,trees,lawns,grass, ground covers,vines, gardens, and other such flora, not intended for resale, which are planted and are situated in such diverse locations as residential and recreational areas, cemeteries, public, commercial and industrial establishments,and public medians and rights-of-way. Leaching The process by which soluble materials in the soil, such as salts, nutrients, pesticide chemicals,or contaminants,are washed into a lower layer of soil or are dissolved and carried away by water. Leak detection Systematic method to survey the distribution system and pinpoint the exact locations of hidden underground leaks. Level of Certainty A water supply planning goal to assure at least a 90 percent probability during any given year that all the needs of reasonable-beneficial water uses will be met, while sustaining water resources and related natural systems during a 1-in-10 year drought event. Marsh A frequently or continually inundated unforested wetland characterized by emergent herbaceous vegetation adapted to saturated soil conditions. Maximum developable limit (MDL) Maximum developable limit consumptive use permitting criteria provide reasonable assurances that the proposed water use does not cause harmful drawdowns to semi-confined freshwater aquifers. In the Lower West Coast Planning Area, the potentiometric head within the Lower Tamiami, Sandstone, and Mid-Hawthorn aquifers shall not be allowed to drop to less than 20 feet above the top of the uppermost geologic strata that comprises the aquifer at any point during a 1-in-10 year drought condition. Microirrigation The application of small quantities of water on or below the soil surface as drops or tiny streams of spray through emitters or applicators placed along a water delivery line. Microirrigation includes a number of methods or concepts, such as bubbler, drip, trickle, mist or microspray,and subsurface irrigation. Million gallons of water per day(MGD)A rate of flow of water equal to 133,680.56 cubic feet per day, or 1.5472 cubic feet per second, or 3.0689 acre-feet per day.A flow of one million gallons per day for one year equals 1,120 acre-feet(365 million gallons).To hold one million gallons of water,a swimming pool approximately 267 feet long (almost as long as a football field), 50 feet wide, and 10 feet deep would be needed. Minimum Flow and Level (MFL) The point at which further withdrawals would cause significant harm to the water resources or natural systems. An MFL is established by water management districts pursuant to Sections 373.042 and 373.0421, Florida Statutes, for a given water body and set forth in Parts II and III of Chapter 373,Florida Statutes. Mobile irrigation laboratory(MIL) A vehicle furnished with irrigation evaluation equipment that is used to carry out on-site evaluations of irrigation systems and to provide recommendations on improving irrigation efficiency. 190 I Glossary Model A computer model is a representation of a system and its operations, and provides a cost- effective way to evaluate future system changes,summarize data,and help understand interactions in complex systems. Hydrologic models are used for evaluating, planning, and simulating the implementation of operations within the South Florida Water Management District's water management system under different climatic and hydrologic conditions. Water quality and ecological models are also used to evaluate other processes vital to the health of ecosystems. MODFLOW A modular,three-dimensional, finite-difference groundwater modeling code created by the United States Geological Survey, which is used to simulate the flow of groundwater through aquifers. The South Florida Water Management District uses it for subregional groundwater modeling. Monitor well Any human-made excavation by any method to monitor fluctuations in groundwater levels,quality of underground waters,or the concentration of contaminants in underground waters. National Geodetic Vertical Datum of 1929 (NGVD) A geodetic datum derived from a network of information collected in the United States and Canada. It was formerly called the "Sea Level Datum of 1929" or "mean sea level." Although the datum was derived from the average sea level over a period of many years at 26 tide stations along the Atlantic,Gulf of Mexico,and Pacific coasts,it does not necessarily represent local mean sea level at any particular place. Natural system A self-sustaining living system that supports an interdependent network of aquatic,wetland-dependent,and upland living resources. Net irrigation demand or net irrigation requirement (term used in the AFSIRS Model) The amount of water the plant needs in addition to anticipated rainfall. This is an estimate of the amount of water(expressed in inches per year)that should be delivered to the plant's root zone. Net water demand (or finished water demand) is the water demand of the end user after accounting for treatment and process losses, and inefficiencies. When discussing Public Water Supply,the term"finished water demand"is commonly used to denote net demand. Outflow 1)The act or process of flowing out of. 2)The measured quantity of water that has left. Per capita use rate (PCUR) 1) The average amount of water used per person during a standard time period,generally per day.2)Total use divided by the total population served. Permeability The capacity of a porous rock,sediment,or soil for transmitting a fluid. Planning Area The area within the South Florida Water Management District's jurisdiction is divided into four areas within which planning activities are focused: Kissimmee Basin, Upper East Coast, Lower West Coast (LWC),and Lower East Coast. Potable water Water that is safe for human consumption. 2012 LWC Water Supply Plan Update 1 191 Potentiometric head or potentiometric surface A surface that represents the hydraulic head in an aquifer and is defined by the level to which water will rise above a datum plane in wells that penetrate the aquifer. Power Generation (PWR) Self-Supply The difference in the amount of water withdrawn by electric power generating facilities for cooling purposes and the water returned to the hydrologic system near the point of withdrawal. Process water Water used for non-potable industrial usage,e.g.,mixing cement. Public Water Supply(PWS)Water supplied by water treatment facilities for potable use (drinking quality) with projected average pumpages equal to or greater than 100,000 gallons per day (0.1 million gallons per day). Public Water Supply (PWS) demand All potable (drinking quality) water supplied by water treatment facilities with projected average pumpages of 100,000 gallons per day (0.1 million gallons per day)or greater to all types of customers,not just residential. Rapid infiltration basin A wastewater treatment method by which wastewater is applied in deep and permeable deposits of highly porous soils for percolation through deep and highly porous soil. Raw water 1)Water that is direct from the source—groundwater or surface water—without any treatment. 2) Untreated water, usually entering the first unit of a water treatment plant. Contrast with finished water. Raw water demand(see gross water demand) Reasonable-beneficial use Use of water in such quantity as is needed for economic and efficient use for a purpose,which is both reasonable and consistent with the public interest. Recharge(groundwater) The natural or intentional infiltration of surface water into the ground to raise groundwater levels. Recharge (hydrologic) The downward movement of water through soil to groundwater, the process by which water is added to the zone of saturation, or the introduction of surface water or groundwater to groundwater storage, such as an aquifer. Recharge or replenishment of groundwater supplies consists of three types: 1) Natural recharge, which consists of precipitation or other natural surface flows making their way into groundwater supplies. 2) Artificial or induced recharge, which includes actions specifically designed to increase supplies in groundwater reservoirs through various methods, such as water spreading (flooding),ditches and pumping techniques. 3) Incidental recharge,which consists of actions,such as irrigation and water diversion,which add to groundwater supplies,but are intended for other purposes. Recharge may also refer to the amount of water so added. 192 I Glossary Reclaimed water Water that has received at least secondary treatment and basic disinfection and is reused after flowing out of a domestic wastewater treatment facility (Rule 62-610.200, Florida Administrative Code). Recreational/Landscape (REC) Self-Supply Water used for landscape and golf course irrigation. The landscape subcategory includes water used for parks, cemeteries, and other irrigation applications of 100,000 gallons per day (0.1 million gallons per day) or greater. The golf course subcategory includes those operations not supplied by a Public Water Supply or regional reuse facility. Regional irrigation distribution system An interconnection pipeline system to deliver irrigation water, which incorporates reuse and alternative water supplies, such as supplemental surface water. Regional Simulation Model (RSM) A regional hydrologic model developed principally for application in south Florida. The RSM is developed on a sound conceptual and mathematical framework that allows it to be applied generically to a wide range of hydrologic situations.The RSM simulates the coupled movement and distribution of groundwater and surface water throughout the model domain using a Hydrologic Simulation Engine to simulate the natural hydrology and a Management Simulation Engine to provide a wide range of operational capability. Restricted Allocation Areas Areas designated within the South Florida Water Management District for which allocation restrictions are applied with regard to the use of specific sources of water. The water resources in these areas are managed in response to specific sources of water in the area for which there is a lack of water availability to meet the projected needs of the region from that specific source of water(Basis of Review;SFWMD 2010a). Retention The prevention of stormwater runoff from direct discharge into receiving waters. Included as examples are systems that discharge through percolation, exfiltration, filtered bleed- down,and evaporation processes. Retrofit 1) Indoor: the replacement of existing water fixtures, appliances, and devices with more efficient fixtures, appliances, and devices for the purpose of water conservation. 2) Outdoor: the replacement or changing out of an existing irrigation system with a different irrigation system,such as a conversion from an overhead sprinkler system to a microirrigation system (Basis of Review; SFWMD 2010a). Reuse The deliberate application of reclaimed water for a beneficial purpose. Criteria used to classify projects as "reuse" or "effluent disposal" are contained in Rule 62-610.810, Florida Administrative Code The term"reuse"is synonymous with"water reuse." Reverse osmosis (RO) A membrane process for desalting water using applied pressure to drive the feedwater(source water)through a semipermeable membrane. Runoff That component of rainfall,which is not absorbed by soil, intercepted and stored by surface water bodies, evaporated to the atmosphere, transpired and stored by plants, or infiltrated to groundwater,but which flows to a watercourse as surface water flow. 2012 LWC Water Supply Plan Update 1 193 Saline water 1)An aqueous solution with a chloride concentration greater than 250 milligrams per liter and less than that of seawater(Basis of Review; SFWMD 2010a). Saltwater interface The hypothetical surface of chloride concentration between fresh water and seawater where the chloride concentration is 250 milligrams per liter at each point on the surface. Saltwater intrusion The invasion of a body of fresh water by a body of salt water due to its greater density. It can occur either in surface water or groundwater bodies. The term is applied to the flooding of freshwater marshes by seawater, the upward migration of seawater into rivers and navigation channels,and the movement of seawater into freshwater aquifers along coastal regions. Salinity Of or relating to chemical salts usually measured in parts per thousand, milligrams per liter,or practical salinity units. Salt water(see seawater) Seasonal capacity The planned storage available from recharge and recovery operations, to assist in meeting peak demands.Seasonal capacity is not factored into total new treatment capacity. SEAWAT A program developed to simulate three-dimensional, variable density, transient groundwater flow in porous media. The source code for SEAWAT was developed by combining MODFLOW and MT3DMS into a single program that solves the coupled flow and solute transport equations. Seawater Water with a chloride concentration at or above 19,000 milligrams per liter (Basis of Review; SFWMD 2010a). Sedimentation The action or process of forming or depositing sediment. Seepage irrigation Irrigation that conveys water through open ditches.Water is either applied to the soil surface (possibly in furrows) and held for a period of time to allow infiltration,or is applied to the soil subsurface by raising the water table to wet the root zone. Seepage irrigation system A means to artificially supply water for plant growth that relies primarily on gravity to move the water over and through the soil, and does not rely on emitters, sprinklers,or any other type of device to deliver water to the vicinity of expected plant use. Self-supplied The water used to satisfy a water need,not supplied by a Public Water Supply utility. Semi-confined aquifer A completely saturated aquifer that is bounded above by a semi-pervious layer, which has a low, though measurable permeability, and below by a layer that is either impervious or semi-pervious. Serious harm As defined in Chapter 40E-8, Florida Administrative Code, the long-term, irreversible, or permanent loss of water resource functions resulting from a change in surface water or groundwater hydrology. 194 I Glossary Service area The geographical region in which a water supplier has the ability and the legal right to distribute water for use. Significant harm As defined in Chapter 40E-8, Florida Administrative Code,the temporary loss of water resource functions, which result from a change in surface water or groundwater hydrology, that takes more than two years to recover,but which is considered less severe than serious harm. Storm water Water that does not infiltrate, but accumulates on land as a result of storm runoff, snowmelt runoff,irrigation runoff,or drainage from areas,such as roads and roofs. Stormwater treatment area A system of constructed water quality treatment wetlands that use natural biological processes to reduce levels of nutrients and pollutants from surface water runoff. Submersed aquatic vegetation Aquatic plants that exist completely below the water surface. Substrate The physical surface upon which an organism lives.The natural or artificial surface upon which an organism grows or to which it is attached. Surface water Water above the soil or substrate surface, whether contained in bounds, created naturally or artificially,or diffused.Water from natural springs is classified as surface water when it exits from the spring onto the earth's surface. Surficial aquifer system (SAS) Often the principal source of water for urban uses within certain areas of south Florida. This aquifer is unconfined, consisting of varying amounts of limestone and sediments that extend from the land surface to the top of an intermediate confining unit. Tailwater Water that is typically of lower elevation or on the discharge side of the structure. Time series A statistical process analogous to the taking of data at intervals of time. Treatment facility Any facility or other works used for the purpose of treating, stabilizing, or holding water or wastewater. Turbidity The measure of water clarity caused by suspended material in a liquid. Ultralow-volume fixtures Water-conserving plumbing fixtures that meet industry standards at a test pressure of 80 pounds per square inch. Unconfined aquifer 1) A permeable geologic unit or units only partly filled with water and overlying a relatively impervious layer. Its upper boundary is formed by a free water table or phreatic surface under atmospheric pressure.Also referred to as water table aquifer. 2) An aquifer containing water that is not under pressure.The water level in a well is the same as the water table outside the well. Upconing Process by which saline water underlying fresh water in an aquifer rises upward into the freshwater zone as a result of pumping water from the freshwater zone. 2012 LWC Water Supply Plan Update 1 195 Uplands An area with a hydrologic regime that is not sufficiently wet to support vegetation typically adapted to life in saturated soil conditions. Uplands are non-wetlands. Upland soils are non-hydric soils. Utility Any legal entity responsible for supplying potable water for a defined service area. Wastewater The combination of liquid and water-carried pollutants from residences, commercial buildings, industrial plants, and institutions together with any groundwater, surface runoff, or leachate that may be present. Water budget An accounting of total water use or projected water use for a given location or activity. Water conservation The permanent,long-term reduction of daily water use. Permanent water use reduction requires the implementation of water saving technologies and measures that reduce water use while satisfying consumer needs. Water conservation is considered a water source option because it reduces the need for future expansion of the water supply infrastructure. Water Conservation Areas (WCAs) Part of the original Everglades ecosystem that is now diked and hydrologically controlled for flood control and water supply purposes.These are located in the western portions of Miami-Dade, Broward and Palm Beach counties, and preserve over 1,350 square miles,or about 50 percent of the original Everglades. Water conservation rate structure A water rate structure designed to conserve water. Examples of conservation rate structures include,but are not limited to,increasing block rates,seasonal rates, and quantity-based surcharges. Water quality 1) A term used to describe the chemical, physical, and biological characteristics of water, usually in respect to its suitability for a particular purpose. 2) The physical, chemical, and biological condition of water as applied to a specific use. Federal and state guidelines set water quality standards based on the water's intended use, whether it is for recreation, fishing, drinking, navigation,shellfish harvesting,or agriculture. Water Reservation A Water Reservation is a legal mechanism to set aside water for the protection of fish and wildlife or the public health and safety from consumptive water use. The reservation is composed of a quantification of the water to be protected, which includes a seasonal and a location component. Water Resources Advisory Commission (WRAC) The South Florida Water Management District Water Resources Advisory Commission serves as an advisory body to the Governing Board. It is the primary forum for conducting workshops, presenting information, and receiving public input on water resource issues affecting central and south Florida. 196 Glossary Water resource development The formulation and implementation of regional water resource management strategies, including 1) the collection and evaluation of surface water and groundwater data, 2) structural and non-structural programs to protect and manage the water resources, 3) the development of regional water resource implementation programs, 4) the construction, operation and maintenance of major public works facilities to provide for flood control, surface and groundwater storage,and groundwater recharge augmentation,and 5) related technical assistance to local governments and to government-owned and privately owned water utilities (Section 373.019,Florida Statutes). Watershed A region or area bounded peripherally by a water parting and draining ultimately to a particular watercourse or body of water. Watersheds conform to federal hydrologic unit code standards and can be divided into sub-watersheds and further divided into catchments, the smallest water management unit recognized by South Florida Water Management District operations. Unlike drainage basins, which are defined by rule, watersheds are continuously evolving as the drainage network evolves. Water Shortage Plan This effort includes provisions in Chapters 40E-21 and 40E-22, Florida Administrative Code, and identifies how water supplies are allocated to users during declared water shortages. The plan allows for supply allotments and cutbacks to be identified on a weekly basis based on the water level within Lake Okeechobee, demands, time of year and rainfall forecasts. Water supply development The planning, design, construction, operation, and maintenance of public or private facilities for water collection, production,treatment,transmission, or distribution for sale,resale,or end use. (Section 373.019,Florida Statutes) Water Supply Plan Detailed water supply plan developed by the South Florida Water Management District under Section 373.709, Florida Statutes, providing an evaluation of available water supply and projected demands at the regional scale. The planning process projects future demand for 20 years and recommends projects to meet identified needs. Water table The surface of a body of unconfined groundwater at which the pressure is equal to that of the atmosphere. Defined by the level where water within an unconfined aquifer stands in a well. Water use Any use of water that reduces the supply from which it is withdrawn or diverted. Wellfield One or more wells producing water from a subsurface source. A tract of land that contains a number of wells for supplying a large municipality or irrigation district. Wetland An area that is inundated or saturated by surface water or groundwater with vegetation adapted for life under those soil conditions (e.g.,swamps,bogs,and marshes). Wild and Scenic River A river as designated under the authority of the of Public Law 90-542, the Wild and Scenic Rivers Act, as amended. This designation is a means to preserve selected free flowing rivers in their natural condition and protect the water quality of such rivers. A portion of the North Fork of the Loxahatchee River was federally designated as the first Wild and Scenic River in Florida on May 17, 1985. 2012 LWC Water Supply Plan Update 1 197 Withdrawal Water removed from a groundwater or surface water source for use. Yield The quantity of water (expressed as rate of flow or total quantity per year) that can be collected for a given use from surface or groundwater sources. 198 I Glossary References BEBR. 2006. Projections of Florida population by county 2005-2030. In Florida Population Studies. Volume 39, Bulletin 144, Bureau of Economic and Business Research, University of Florida, Gainesville,FL. (Authors: S.K.Smith and S.Rayer) BEBR. 2009. Projections of Florida population by county 2008-2035. In Florida Population Studies. Volume 42, Bulletin 153. Bureau of Economic and Business Research, University of Florida, Gainesville,FL. (Authors: S.K.Smith and S.Rayer) BEBR. 2010. Number of households and average household size in Florida:April 1, 2009. In Florida Population Studies, Volume 43, Bulletin 155, Bureau of Economic and Business Research, University of Florida,Gainesville,FL. (Authors:S,K.Smith and S.Cody) BEBR. 2011. Projections of Florida Population by County, 2010-2040. In Florida Population Studies Volume 44, Bulletin 159, Bureau of Economic and Business Research, University of Florida, Gainesville,FL. (Authors: S.K.Smith and S.Rayer). Bloetscher, F., D.H. Meeroff and B.N. Heimlich. 2009. Improving the Resilience of a Municipal Water Utility Against the Likely Impacts of Climate Change—A Case Study:City of Pompano Beach Water Utility. Florida Atlantic University,Boca Raton,FL. Burns,W.S. 1983. Well Plugging Applications to the Inter-aquifer Migration of Saline Groundwater in Lee County, Florida. South Florida Water Management District, West Palm Beach, FL. Technical Publication 83-8. Cardenas-Lailhacar, B., M.D. Dukes and G.L. Miller. 2010. Sensor-based automation of irrigation on Bermudagrass during dry weather conditions.Journal of Irrigation and Drainage Engineering 136(3):161-223. Carollo Engineers, Inc.2009. Water Desalination Concentrate Management and Piloting.Prepared by Carollo Engineers, Inc., Sunrise, FL, for South Florida Water Management District, West Palm Beach,FL. CDM. 2006a. Big Cypress Basin, Southwest Florida Feasibility Study: Hydrologic Model Development, Final Report. Prepared by Camp Dresser & McKee, Inc., Naples, FL, for South Florida Water Management District,West Palm Beach,FL. CDM. 2006b. Tidal Caloosahatchee Basin Modification of Hydrologic Model. Prepared by Camp Dresser & McKee, Inc., Naples, FL, for South Florida Water Management District, West Palm Beach,FL. CDM. 2006c. Estero River Basin Modification of Hydrologic Model. Prepared by Camp Dresser & McKee, Inc., Naples,FL,for South Florida Water Management District,West Palm Beach, FL. CDM. 2007a. Water Supply Cost Estimation Study. Prepared by Camp Dresser&McKee, Inc., Naples, FL,for South Florida Water Management District,West Palm Beach,FL. 2012 LWC Water Supply Plan Update 1 199 CDM. 2007b. Water Supply Cost Estimation Study-Phase II Addendum. Prepared by Camp Dresser& McKee,Inc.,Naples, FL,for South Florida Water Management District,West Palm Beach,FL. Conserve Florida Water Clearinghouse. 2009. EZ Guide, Version 1.1. University of Florida, Gainesville,FL. DHI, Inc.and Stanley Consultants, Inc. 2005. C-43 Basin Hydraulic Model:C-43 Basin Phase 1 Storage Reservoir Project Implementation Report. Prepared for South Florida Water Management District,Fort Myers,FL. Duever, M.J., D.P. Spangler, R.L. Myers, T.R. Alexander and L.A. Riopelle. 1986. The Big Cypress National Preserve.National Audubon Society,New York, NY. Dukes, M.D. and M. Baum-Haley. 2009. Evaluation of Soil Moisture-Based On-Demand Irrigation Controllers, Phase II, Final Report.Agricultural and Biological Engineering Department, Institute for Food and Agricultural Sciences,University of Florida,Gainesville,FL. Dziegielewski, B., J. Kiefer, E. Opitz, G. Porter, G. Lantz, W. DeOreo, P. Mayer and J. Nelson. 2000. Commercial and Industrial End Uses of Water. American Water Works Association Research Foundation, Denver,CO. ECWCD. 2008. East County Water Control District Consolidated Plan for Water Management. East County Water Control District,Lehigh Acres,FL. Florida Atlantic University and SFWMD. 2008.A Density-Dependent Groundwater Flow Model of the Lower West Coast Florida Aquifer System. Prepared by Florida Atlantic University, Boca Raton, FL in association with South Florida Water Management District,West Palm Beach,FL. FDACS. 2010. Email message to L. Hoppes, December 8, 2010. From Florida Department of Agriculture and Consumer Services, West Palm Beach, FL to South Florida Water Management District,West Palm Beach, FL. FDEP. 1995. 1994 Reuse Inventory. Water Reuse Program. Florida Department of Environmental Protection,Tallahassee,FL. FDEP. 1996. 1995 Reuse Inventory. Water Reuse Program. Florida Department of Environmental Protection,Tallahassee,FL. FDEP. 1997. 1996 Reuse Inventory. Water Reuse Program. Florida Department of Environmental Protection,Tallahassee,FL. FDEP. 1998. 1997 Reuse Inventory. Water Reuse Program. Florida Department of Environmental Protection,Tallahassee,FL. FDEP. 1999. 1998 Reuse Inventory. Water Reuse Program. Florida Department of Environmental Protection,Tallahassee,FL. FDEP. 2000. 1999 Reuse Inventory. Water Reuse Program. Florida Department of Environmental Protection,Tallahassee,FL. 200 I References FDEP. 2001. 2001 Reuse Inventory. Water Reuse Program. Florida Department of Environmental Protection,Tallahassee,FL. FDEP. 2002. 2002 Reuse Inventory. Water Reuse Program. Florida Department of Environmental Protection,Tallahassee,FL. FDEP. 2003. 2003 Reuse Inventory. Water Reuse Program. Florida Department of Environmental Protection,Tallahassee,FL. FDEP. 2004. 2004 Reuse Inventory. Water Reuse Program. Florida Department of Environmental Protection,Tallahassee,FL. FDEP. 2005. 2005 Reuse Inventory. Water Reuse Program. Florida Department of Environmental Protection,Tallahassee,FL. FDEP. 2006. 2006 Reuse Inventory. Water Reuse Program. Florida Department of Environmental Protection,Tallahassee,FL. FDEP. 2007. 2007 Reuse Inventory. Water Reuse Program. Florida Department of Environmental Protection,Tallahassee,FL. FDEP. 2010a. 2008 Reuse Inventory. Water Reuse Program. Florida Department of Environmental Protection,Tallahassee,FL. FDEP. 2010b. 2009 Reuse Inventory. Water Reuse Program. Florida Department of Environmental Protection,Tallahassee,FL. FDEP. 2011. 2010 Reuse Inventory. Water Reuse Program. Florida Department of Environmental Protection,Tallahassee,FL.Available at http://www.dep.state.fl.us/water/reuse/inventory.htm. FDEP. 2012. Guidance for Improved Linkage between Regional Water Supply Plans and the Consumptive Use Permitting Process. Florida Department of Environmental Protection, Tallahassee, FL. Memo dated March 23, 2012. FDEP and University of Florida. 2009. Florida-Friendly Landscape Guidance Models for Ordinances, Covenants, and Restrictions. Florida Department of Environmental Protection, Tallahassee, FL, and University of Florida,Gainesville,FL.Available at www.dep.state.fl.us/water/nonpoint/docs/nonpoint/ffl-mo-ccr-1-09.pdf. Hazen and Sawyer. 2008. City of Plantation Final Report Advanced Wastewater Treatment Pilot Project. Prepared by Hazen and Sawyer Environmental Engineers & Scientists, Hollywood, FL, for the City of Plantation,Plantation, FL. HDR Engineering and HSW Engineering, Inc. 2009. St. Lucie and Indian River Counties Water Resources Study: Final Summary Report. Prepared by HDR Engineering, Jacksonville, FL, and HSW Engineering, Inc., Tampa, FL, for South Florida Water Management District, West Palm Beach,FL,and St.Johns River Water Management District, Palatka,FL. Hoppes, L. 2009.Chapter 5A: Five-Year Water Resource Development Work Program.In 2009 South Florida Environmental Report,South Florida Water Management District,West Palm Beach,FL. 2012 LWC Water Supply Plan Update 1 201 Jawitz,J.W., R. Munoz-Carpena,S. Muller, K.A. Grace and A.I.James. 2008.Development, Testing, and Sensitivity and Uncertainty Analyses of a Transport and Reaction Simulation Engine (TaRSE)for Spatially Distributed Modeling of Phosphorous in South Florida Peat Marsh Wetlands. Florida Integrated Science Center, United States Geological Survey, Reston,VA. Scientific Investigations Report 2008-5029. Johnston, R.H, and.P.W. Bush. 1988. Summary of the Hydrology of the Floridan Aquifer System in Florida and in Parts of Georgia, South Carolina, and Alabama. United States Geological Survey, Washington,D.C.Professional Paper 1403-A. Liebermann, T.D. 2006. Estimation of spatially distributed future land use in a rapidly developing area: A case study for southwest Florida. In Proceedings in American Water Resources Association (AWRA)Spring Specialty Conference on GIS and Water Resources IV, May 8-10, 2006, available from American Water Resources Association, Middleburg, VA, or www.awra.org/proceedings/cdrom.html. Maddaus Water Management. 2009. Conservation Technical Analysis. Prepared by the Maddaus Water Management,Alamo,CA,for East Bay Municipal Utility District,Oakland,CA. Marella, R.L. 2008. Water Use in Florida, 2005 and Trends 1950-2005. United States Geological Survey,Orlando, FL.Fact Sheet Series 2008-3080.Available at pubs.usgs.gov/fs/2008/3080/. Marella, R.L. 2009. Water Withdrawals, Use, and Trends in Florida, 2005. United States Geological Survey, Orlando, FL. Scientific Investigations Report 2009-5125. Available at pubs.usgs.gov/sir/2009/5125/. Marco Water Engineering, Inc. 2006. Lower West Coast Surficial Aquifer System Model Report. Prepared by Marco Water Engineering, West Palm Beach, FL, for South Florida Water Management District,West Palm Beach,FL. Martin, P.J. 2010. Chapter 5A: Five-Year Water Resource Development Work Program. In South Florida Environmental Report- Volume II,South Florida Water Management District,West Palm Beach, FL. Martin, P.J. 2011. Chapter 5A: Five-Year Water Resource Development Work Program. In 2011 South Florida Environmental Report, South Florida Water Management District, West Palm Beach, FL. Martin, P.J. 2012. Chapter 5A: Five-Year Water Resource Development Work Program. In 2012 South Florida Environmental Report, South Florida Water Management District, West Palm Beach,FL. Mayer, P.W.,W.B. DeOreo, E.M. Opitz, J.C. Kiefer,W.Y. Davis, B. Dziegielewski and J.O. Nelson. 1999. Residential End Uses of Water. American Water Works Association Research Foundation, Denver,CO. McCready, M.S., M.D. Dukes and G.L. Miller, 2009. Water conservation potential of smart irrigation controllers on St.Augustine grass.Agricultural Water Management 96(11):1623-1632. 202 I References Metcalf & Eddy. 2006. Technical and Economic Feasibility of Co-located Desalination Facilities. Prepared by Metcalf&Eddy,Wakefield,MA,for South Florida Water Management District,West Palm Beach, FL. Miami-Dade County. 2007. Miami-Dade County Water Use Efficiency 20-Year Plan. Miami-Dade County Water and Sever Department,Miami,FL. Morales, M.A.,J.M. Martin and J.P. Heaney. 2009. Methods for estimating commercial, industrial and institutional water use. In Proceedings of Florida Section of American Water Works Association Fall 2009 Conference, Orlando, FL. Florida Section of the American Water Works Association, St. Cloud,FL. Murley,J., B.N. Heimlich and N. Bollman. 2008.Florida's Resilient Coasts—A State Policy Framework for Adaptation to Climate Change. Center for Urban and Environmental Solutions and National Commission on Energy Policy,Florida Atlantic University,Fort Lauderdale,FL. MWH Global, Inc.2008a.Southwest Wastewater Treatment Facility Advanced Wastewater Treatment (AWT)and Reuse Pilot Testing Program, Final Report.Prepared by MWH Global, Inc.,Sunrise,FL, for the City of Sunrise,Sunrise,FL. MWH Global, Inc. 2008b. W-10 Water Supply Resource Study, City of Cape Coral, Groundwater Flow and Solute Transport Model. Prepared by MWH Global, Inc., Fort Myers, FL, for Cape Coral Utilities,Cape Coral,FL. NAHB and Bank of America Home Equity. 2007. Study of Life Expectancy of Home Components. National Association of Home Builders and Bank of America Home Equity,Washington, D.C. Pottorff, L., D. Whiting and C. Wilson. 2010. Efficient Landscape Irrigation during Drought and with Limited Water Availability in Colorado. Colorado State University Extension, Fort Collins, CO. Available at http://www.ext.colostate.edu/drought/eff landscape.html. RMA GeoLogic Consultants, Inc. 2007. Water Use Permit Application Modification and Supporting Documentation for the North Lee County Reverse Osmosis WTP Lower Hawthorn Aquifer Wellfield. Prepared by RMA GeoLogic Consultations, Inc., Fort Myers, FL for Lee County Utilities, Lee County,Fort Myers,FL. D. Scavia,J.C. Field, D.F. Boesch, R.W. Buddemeier,V. Burkett, D.R. Cayan, M. Fogarty, M.A. Harwell, R.W. Howarth, C. Mason, D.J. Reed, T.C. Royer, A.H. Sallenger, and J.G. Titus. 2002. Climate change impacts on U.S.coastal and marine ecosystems.Estuaries 25(2):149-164. Schers,G.J.S.Kopko,A. Fenske, M.Cason,G.P. Kennedy,and MWH . 2007. Reducing adverse impacts of declining water quality on RO WTP by implementing operational changes to the wellfield. In 82nd Annual Florida Water Resources Conference Technical Program and Proceedings, Orlando, FL,Florida Water Resources Conference,Inc.,Bradenton,FL. Schlumberger Water Services. 2010. Big Cypress Basin Saltwater Intrusion Pilot Modeling Study, Phase 2. Prepared for the South Florida Water Management District, Big Cypress Basin, Naples,FL. 2012 LWC Water Supply Plan Update 1 203 Schlumberger Water Services and SFWMD. 2011. Lower West Coast Floridan Aquifer System Model Development. Prepared for the South Florida Water Management District, Big Cypress Basin, Naples,FL. Schmerge, D.L. 2001. Distribution and Origin of Salinity in the Surficial and Intermediate Aquifer Systems, Southwestern Florida. United Society Geological Society, Tallahassee, FL. Water Resource Investigations Report 01-4159. SDI Environmental Services, Inc., BPC Group Inc. and DHI, Inc. 2008. Southwest Florida Feasibility Study Integrated Hydrologic Model, Model Documentation Report. Prepared for the South Florida Water Management District,West Palm Beach,FL. SFWMD. 1994. 1994 Lower West Coast Water Supply Plan. South Florida Water Management District,West Palm Beach,FL SFWMD. 2000a. 2000 Lower East Coast Regional Water Supply Plan. South Florida Water Management District,West Palm Beach,FL. SFWMD. 2000b. 2000 Lower West Coast Water Supply Plan. South Florida Water Management District,West Palm Beach,FL. SFWMD. 2006. 2005-2006 Lower West Coast Water Supply Plan Update. South Florida Water Management District,West Palm Beach,FL. SFWMD. 2009a. Climate Change and Water Management in South Florida. South Florida Water Management District,West Palm Beach,FL. SFWMD. 2009b. Water Utilities Water Demand Reduction during the 2007-2009 Water Shortage. South Florida Water Management District,West Palm Beach,FL. SFWMD. 2010a. Basis of Review for Water Use Permit Application within the South Florida Water Management District.South Florida Water Management District,West Palm Beach,FL. SFWMD. 2010b.Big Cypress Basin Strategic Plan 2010-2015. SFWMD,West Palm Beach,FL. SFWMD. 2011b. Water Efficiency Self-Assessment Guide for Commercial and Institutional Facility Managers.South Florida Water Management District,West Palm Beach,FL. SFWMD. 2012a.2011-2012 Water Supply Plan Support Document. SFWMD,West Palm Beach,FL. SFWMD. 2012b. 2012 Lower East Coast Water Supply Plan Update. South Florida Water Management District,West Palm Beach,FL. SFWMD, FDEP and FDACS. 2009. Caloosahatchee River Watershed Protection Plan. South Florida Water Management District, West Palm Beach, FL; Florida Department of Environmental Protection, Tallahassee, FL; Florida Department of Agriculture and Consumer Services, Tallahassee, FL. Sherwood,C.B.and H.Klein. 1963.Saline groundwater in southern Florida.Groundwater 1(2):4-8. 204 I References Shoemaker,W.B. and K.M. Edwards. 2003.Potential for Saltwater Intrusion into the Lower Tamiami Aquifer near Bonita Springs, Southwestern Florida.United States Geological Survey,Tallahassee, FL.Water Resources Investigations Report 03-4262. Shoemaker, W.B., C.D. Lopez and M.J. Duever. 2011. Evapotranspiration over Spatially Extensive Plant Communities in Big Cypress National Preserve, Southern Florida, 2007-2010. United States Geological Survey, United States Department of the Interior, Washington, DC. SIR 2011-5212. Available at http://pubs.usgs.govfsir/2011/5212/. Smajstrla, A.G. 1990. Technical Manual, Agricultural Field Scale Irrigation Requirements Simulation (AFSIRS) Model, Version 5.5. Prepared by Agricultural Engineering Department, University of Florida, Gainesville, FL, for St. Johns River Water Management District, Palatka, FL. Special Publication SJ2008-SP17. Smith, K. 1990.A Three-Dimensional Finite Difference Ground Water Flow Model of Hendry County. South Florida Water Management District,West Palm Beach,FL.Technical Publication 90-04. Spechler, R.M. 2010. Hydrogeology and Groundwater Quality of Highlands County, Florida. United States Geological Survey,Reston,VA.Scientific Investigations Report 2010-5097. SWFRPC and CHNEP. 2009. Comprehensive Southwest Florida/Charlotte Harbor Climate Change Vulnerability Assessment. Southwest Florida Regional Planning Council, Fort Myers, FL, and Charlotte Harbor National Estuary Program, Fort Myers, FL. Technical Report 09-3. September 15,2009. USACE. 2007. Final Environmental Impact Statement Including Appendices A through G - Lake Okeechobee Regulation Schedule.United States Army Corps of Engineers,Jacksonville, FL. USACE. 2008. Central and Southern Florida Project Water Control Plan for Lake Okeechobee and Everglades Agricultural Area.United States Army Corps of Engineers,Jacksonville,FL. USACE and SFWMD. 2009. Draft Southwest Florida Feasibility Study Draft Integrated Feasibility Report and Environmental Impact Statement. United States Army Corps of Engineers, Jacksonville,FL,and South Florida Water Management District,West Palm Beach, FL. U.S. Census Bureau. 2001. Florida 2000 Census of Population and Housing. United States Census Bureau, United States Department of Commerce, Economics and Statistics Administration, Washington,DC.Available at http://www.census.gov/. U.S. Census Bureau. 2010. 2010 Census. United States Census Bureau, United States Department of Commerce, Economics and Statistics Administration, Washington, DC. Available at http://2010.census.gov/2010census/ USDA-NASS. 2004, 2006, 2008, 2009. Commercial Citrus Inventory. United States Department of Agriculture - National Agriculture Statistics Service, Orlando, FL. Available at http://www.nass.usda.gov/Statistics by State/Florida/Publications/Citrus/index.asp. USEPA. 2011. WaterSense/Outdoor, Smart Outdoor Practices. United States Environmental Protection Agency,Washington, DC.Available at www.epa.gov/WaterSense/outdoor/. 2012 LWC Water Supply Plan Update 1 205 USFWS. 2010. National Wetlands Inventory. National Wetlands Inventory Program, Branch of Resource and Mapping Support, United States Fish and Wildlife Service, Washington, DC. Available at http://wetlands.fws.gov. Vickers,A.2001.Handbook of Water Use and Conservation.Waterplow Press,Amherst,MA. White, D.and R.C. Stroh,Sr. 2010. The State of Florida's Housing,2009.Shimberg Center for Housing Studies, University of Florida, Gainesville, FL. Available at http://flhousingdata.shimberg.ufl.edu/. 206 I References l 1°:, . :.,:_42:- .� k, 1 ‘4101111 ,f t... .I. \ _ 116104111 ' —10.10. i tea _. , I .. +11 li-77......-__ , Meeting South Florida's water supply needs while safeguarding its natural systems \' W requires innovative ti w W ; \ — '— solutions, cohesive planning,and a shared vision. j , 604. South Florida Water Management District Committed to managing and protecting our region's water resources a°�4Ai M'�; South Florida Water Management District . 3301 Gun Club Road•West Palm Beach,Florida 33406 �= =d 561-686-8800•FL WATS 1-800-432-2045•wwwsfwmd-gov 5f wmd"9ov \,04..1."y'�i' '. MAILING ADDRESS.P 0 r r_9f80•West Palm Beath,FL 33416-4680 in .4t4 F.- in aI W ... ,.. ,. IL V W . _,, Z Z 06 O caw V J W � Q W � > P - Z >. WZW 4_, •...... 0 ii-....... 4.) ariii ce D 0c3 °' a Z a (0 Q 0 E 0 4_, . / 0 . . . 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