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NC0000396_Other Agency Documents_20180914
• le:s DUKE ENERGY PROGRESS Garry A.Whisnant Plant General Manager Asheville Steam Electric Plant Certified Mail: 7014 1820 0001 7891 4791 Duke Energy Progress ASVL PLT/200 CP&L Dr File: 12520A Arden,NC 28704 o: 828-687-5201 September 14, 2018 t. 828-687-5204 garry.whisnant@duke-energy.com Ms.Julie Grzyb, Supervisor NPDES Complex Wastewater Permitting NC DEQ/DWR/WQ Permitting Section 1617 Mail Service Center Raleigh NC 27699-1617 Subject: Asheville Steam Station,NPDES Permit NC0000396 New Combined Cycle Facility 316(b) Report Submittal Dear Ms. Grzyb, Enclosed please find the required reports necessary per the 316(b)Existing Facilities Rule(40 CFR 125.95(b)(1)) for the Asheville Steam Station,NPDES Permit NC0000396. We believe that the provided reports are complete and satisfies the Rule's requirements. Specifically,the enclosed reports are to support new combined cycle units that are currently under construction. Soon after commercial operation of the new combined units,the existing two coal-fired units with once-through cooling will be retired. Relative to the 316(b)Existing Facilities Rule for the new combined cycle units,following are the major characteristics which are fully described in the reports: • Cooling type: closed-cycle recirculating cooling with mechanical draft towers • Through-screen velocity for makeup pumps: 0.049 feet/second • Design maximum withdrawal: 5.2 MGD (includes water for non-cooling needs) • Average makeup intake structure withdrawal: 2.85 MGD • Cooling tower blowdown: minimized via optimized cycles of concentration The design of the new combined cycle units meets or exceeds the impingement and entrainment standards imposed by the 316(b) Rule. Closed-cycle recirculating cooling with minimized blowdown satisfies the required entrainment standard. Compliance with the impingement standard is with closed-cycle cooling and an intake through-screen velocity approximately ten times less than the 0.5 feet/second alternative. The existing cooling water intake structure will be modified for installation of finer mesh fixed screen and installation of new lower flow pumps. No other modifications to the existing cooling water structure will be performed. Per the 316(b) Rule, a permittee is required to submit the required reports at least 180 days prior to cooling water withdrawals for a new unit at an existing facility(40 CFR 125.95(b)), such as the new Asheville combined cycle units. Although these reports are timely submitted as required,we would • Asheville Steam Station,NPDES Permit NC0000396 New Combined Cycle Facility 316(b)Report Submittal Page 2 sincerely appreciate the Department's expeditious review to preclude any potential construction schedule conflicts. Please contact Tina Woodward(704-382-4585) or Michael Smallwood(704-382-4117)if you have any questions regarding the enclosed 316(b) Rule reports to support the new Asheville combined cycle units. Sincerely, Mr.Jeff McFee Asheville Steam Station, Acting Plant Manager cc: Sergei Chernikov Complex NPDES Permit Supervisor 1617 Mail Service Center Raleigh, NC 27699-1617 . s ' .41,-.,,.;, •F:' , tz 4 : Clean Water Act .. .“,- . ,..--5,,, , *No, - §316(b) Compliance . � Submittal t. Prepared for: N . I *4 Duke Energy Progress, LLC J -F ---‘,..-.%' .,. 'j • a� , _ Prepared by: ..- , i: t' ' HDR , t 'i .� '' September 11 , 2018 1'`amo 4- .f: Asheville Combined Cycle Station . . w, Arden, North Carolina + NPDES Permit No. NC0000396 `., Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station • Contents Page Executive Summary 1 1 Introduction 2 2 Source Water Physical Data [§122.21(r)(2)] 6 2.1 Description of Source Waterbody 6 2.2 Characterization of Source Waterbody 7 2.2.1 Geomorphology 7 2.2.2 Hydrology 7 2.2.3 Water Quality 7 2.3 Determination of Area of Influence 11 2.3.1 Methods—Desktop Calculation 12 2.3.2 Results—Desktop Calculations 13 3 Cooling Water Intake Structure Data [§122.21(r)(3)] 15 3.1 Configuration 15 • 3.2 Operation 17 3.3 Latitude and Longitude of Structures 18 3.4 Engineering Drawings of CWIS 18 4 Source Water Baseline Biological Characterization Data [§122.21(r)(4)] 19 4.1 Review of Available Biological Data 19 4.2 Species and Relative Abundance near the CWIS 19 4.2.1 Lake Julian Environmental Monitoring Program 19 4.2.2 Conclusions from Lake Julian Sampling Program 22 4.3 Primary Growth Period 23 4.3.1 Period of Peak Abundance for Relevant Taxa 24 4.4 Seasonal and Daily Activities of Organisms in the Vicinity of the CWIS 25 4.5 Species and Life Stages Susceptible to Impingement and Entrainment 27 4.5.1 Impingement 27 4.5.2 Entrainment 28 4.5.3 Life History Information for Species Susceptible to Entrainment 30 4.6 Threatened, Endangered, and Other Protected Species Susceptible to Impingement , and Entrainment at the CWIS 32 4.7 Documentation of Consultation with Services 34 4.8 Incidental Take Exemption or Authorization from Services 34 4.9 Methods and Quality Assurance Procedures for Field Efforts 34 4.10 Protective Measures and Stabilization Activities 35 Duke Energy I ii Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station 4.11 Fragile Species 35 5 Cooling Water System Data [§122.21(r)(5)] 37 5.1 Cooling Water System 37 • 5.1.1 Proportion of Design Flow Used in the Cooling Water System 41 5.1.2 Temporal Characteristics of Cooling Water System Operation 41 5.1.3 Distribution of Water Reuse 42 5.1.4 Description of Reductions in Total Water Withdrawals 42 5.1.5 Description of Cooling Water Used in Manufacturing Process 42 5.1.6 Proportion of Source Waterbody Withdrawn 42 5.2 Design and Engineering Calculations 42 5.3 Description of Existing Impingement and Entrainment Reduction Measures 43 5.3.1 Asheville Plant 43 5.3.2 The ACC 43 5.3.3 Best Technology Available for Entrainment 44 6 Chosen Method(s)of Compliance with Impingement Mortality Standard [§122.21(r)(6)] 45 6.1 Design TSV 45 6.2 Requirements of Make-up Water Minimization for Closed-Cycle Recirculating System 45 7 Entrainment Performance Studies [40 CFR§ 122.21(r)(7)] 47 7.1 Site-Specific Studies 47 7.2 Studies Conducted at Other Locations 47 8 Operational Status [§122.21(r)(8)] 48 8.1 Asheville Plant Units 1-4 48 8.2 ACC Units 5-8 48 8.3 Major Upgrades in Last 15 Years 48 8.4 Descriptions of Consultation with Nuclear Regulatory Commission 48 8.5 Other Cooling Water Uses for Process Units 48 8.6 Description of Current and Future Production Schedules 48 8.7 Description of Plans or Schedules for New Units Planned within 5 years 49 9 New Units [§122.21(r)(14)] 50 9.1 BTA Standards for Impingement Mortality and Entrainment for New Units at Existing Facilities 50 10 References 51 Duke Energy I iii Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station Appendices Appendix A Permit for Impounding and Maintenance of Impounded Water Issued in 1963 • Appendix B ..Asheville Combined Cycle Station §122.21(r)(2)—(8), (14) Submittal Requirement Checklist Appendix C Asheville Combined Cycle Station, Engineering Calculations for Through-Screen Velocity Appendix D Asheville Combined Cycle Station, Design Drawings Duke Energy I iv Clean Water Act§316(b)Compliance Submittal FIN Asheville Combined Cycle Station J Tables Page Table 1-1. Facility and Flow Attributes and Permit Application Requirements 2 Table 1-2. Submittal Requirements for New Unit(s) at an Existing Facility for Compliance Under Clean Water Act§316(b) §122.21(r)(2)-(8)and (r)(14) 5 Table 2-1. Annual Mean Concentration for Select Parameters Documented in Surface Water Samples Collected in Lake Julian (Station D2) (Progress Energy 2013) 10 Table 2-2. Summary of Input Parameters for TSV Calculations of CWIS on Lake Julian 14 Table 3-1. Existing and Repurposed Cooling Water Intake Structure Components 16 Table 3-2. Cooling Water Intake Structure Coordinate Information (Source: DEP 2005, DEP 2007) 18 Table 3-3. List of Engineering Drawings for ACC Intakes 18 Table 4-1. Relative Abundance of Fish Collected in Electrofishing Samples on Lake Julian, 2000, 2010, 2015, 2016 (CP&L 2001 and Progress Energy 2013, DEP 2017b) 21 Table 4-2. Mean Number per 24-Hour Set of Fish Collected during Gillnet Sampling on Lake Julian, 2000 (Source: CP&L 2001) 22 Table 4-3. Known Spawning and Recruitment Period of Native Species with Documented Occurrence in Lake Julian, North Carolina (Sources: Rohde et al. 1994; Rohde et al. 2009; Etnier and Starnes 1993 ) 24 Table 4-4. Seasonal and Daily Activities of Species Present in Lake Julian (Sources: Rohde et al. 2009; Rohde et al. 1994; Etnier and Starnes 1993) 25 Table 4-5. Entrainment Potential for Fish Species Identified in Lake Julian 29 Table 4-6. Rare, Threatened, or Endangered (RTE)Aquatic Species Listed for Buncombe County, North Carolina, and Record of Occurrence or Potential to Occur in Lake Julian 33 Table 4-7. List of Fragile Species as Defined by the EPA and their Occurrence in Lake Julian and/or the French Broad River near Asheville Combined Cycle Station 35 Table 5-1. Water Balance Diagram and Associated Flows under Various Design Conditions for the ACC (Source: CB&I 2018) 1 40 Table 6-1. Site-Specific Design of ACC Closed-Cycle Cooling System (CB&I 2018) 46 Duke Energy I v Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station • Figures Page • Figure 1-1. Site Layout at Asheville Combined Cycle Station, Buncombe County, North Carolina 3 Figure 2-1. Map of French Broad-Holston Basin Hydrologic Unit Code 06010105 8 Figure 2-2. Duke Energy Progress Environmental Monitoring Program Water Quality Sampling Stations on Lake Julian (Progress Energy 2013) 9 Figure 3-1.Asheville Combined Cycle Cooling Water Intake Structure on Lake Julian, Buncombe County, North Carolina 15 Figure 3-2. Layout of the Repurposed Lake Julian Cooling Water Intake Structure(not to scale) 16 Figure 3-3. Photograph of a 1-inch Hexagonal Mesh Screen Panel Employed at the Cooling Water Intake Structure on Lake Julian 17 Figure 4-1. Shoreline Habitat Types and Locations Sampled with Nighttime Electrofishing in Lake Julian, 2000-2016 (CP&L 2001, Progress Energy 2013, DEP 2017b) 20 Figure 5-1. Water Balance Diagram of the Asheville CombinedCycle Station, Arden, North Carolina (Source: CB&I 2018) 38 Duke Energy I vi Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station JJ Acronyms and Abbreviations °C degrees Celsius °F degrees Fahrenheit ACC Asheville Combined Cycle Station AIF actual intake flow AOI area of influence Asheville Plant Asheville Steam Electric Plant BTA Best Technology Available CCRS closed-cycle recirculating system CFR Code of Federal Regulations COC • cycles of concentration CP&L Carolina Power and Light Company CWA Clean Water Act CWIS cooling water intake structure DIF design intake flow Director NPDES Director DO dissolved oxygen DEP Duke Energy Progress, LLC EPA U.S. Environmental Protection Agency EPRI Electric Power Research Institute fps feet per second ft msl feet above mean sea level gpm gallons per minute HRSG heat recovery steam generator HUC Hydrologic Unit Code IPAC Information for Planning and Consultation m meters pS/cm micro Siemens per centimeter MGD million gallons per day mg/L milligrams per liter MW megawatt NCDEQ North Carolina Department of Environmental Quality NCDNCR North Carolina Department of Natural and Cultural Resources NPDES National Pollutant Discharge Elimination System NTU Nephelometric Turbidity Units Program Environmental Monitoring Program RTE Rare,threatened, or endangered Rule Clean Water Act§316(b)rule TSV through-screen velocity USFWS 1 U.S. Fish and Wildlife Service WOTUS Waters of the United States Duke Energy I vii Clean Water Act§316(b)Compliance Submittal FIN Asheville Combined Cycle Station Executive Summary On August 15, 2014, regulations implementing §316(b) of the Clean Water Act(CWA) for existing facilities (the Rule) were published in the Federal Register with an effective date of October 14, 2014. Facilities subject to the Rule are required to develop and submit technical material in accordance with §122.21(r) that will be used by the National Pollutant Discharge Elimination System (NPDES) permit Director(Director) to make a Best Technology Available (BTA) determination for the facility. Duke Energy Progress, LLC (DEP) is constructing a new combined cycle unit at the existing Asheville Steam Electric Plant(Asheville Plant) in Buncombe County, North Carolina. The generation capacity of the Asheville Plant will be replaced with the Asheville Combined Cycle Station (ACC), which will consist of two combined cycle power blocks with a summer/winter net electrical generating capacity of 250 MW/280 MW per block. Approximately 36 percent of this generation will be produced from a steam cycle turbine that requires cooling water; however, the ACC will utilize closed-cycle cooling towers, which will reduce cooling water withdrawals from the current average of 225 MGD to a proposed average of 2.85 MGD, and will eliminate thermal inputs to Lake Julian from the existing coal-fired units. The ACC will utilize the existing CWIS on Lake Julian for raw water supply, including cooling tower make-up water. The new ACC is defined as a "new unit" at an existing facility' per 40 CFR 125.92(u). As such, • DEP is providing the following information, as required at §122.21(r)(2)-(8) and (r)(14), at least 180 days prior to the commencement of cooling water withdrawals for the operation of the new unit. Functional testing is scheduled to begin in March, 2019 and the commercial operation date is currently scheduled for November 2019. The existing Asheville Plant will be retired upon commencement of the new combined cycle operations. To meet the impingement mortality and entrainment reduction standards in §125.94(e), the ACC will be equipped with closed-cycle recirculating mechanical draft cooling towers. The §122.21(r) submittal material provided herein supports a conclusion that the ACC will fully meet the new unit BTA standards at §125.94(e) for impingement and entrainment reductions and minimizes potential adverse environmental impacts. ' The Rule states in§ 125.92(u)that a"New unit means a new`stand-alone'unit at an existing facility where construction of the new units begins after October 14, 2014 and that does not otherwise meet the definition of a new facility at§ 125.83 or is not otherwise already subject to subpart I of this part.A stand-alone unit is a separate unit that is added to a facility for either the same general industrial operation or another purpose. A new unit may have its own dedicated cooling water intake structure, or the new unit may use an existing or modified cooling water intake structure." Duke Energy 11 Clean Water Act§316(b)Compliance Submittal Inun Asheville Combined Cycle Station 1 Introduction Section 316(b) was enacted under the 1972 Clean Water Act (CWA), which also introduced the National Pollutant Discharge Elimination System (NPDES) permit program. Certain facilities with NPDES permits are subject to §316(b) requirements, which mandate that the location, design, construction, and capacity of the facility's cooling water intake structure (CWIS)2 reflect Best Technology Available (BTA) for minimizing potential adverse environmental impacts. On August 15, 2014, regulations implementing §316(b) of the final CWA rule (Rule) for existing facilities were published in the Federal Register with an effective date of October 14, 2014 (EPA 2014). The Rule applies to existing facilities that withdraw more than 2 million gallons per day (MGD) from Waters of the United States (WOTUS), use at least 25 percent of that water exclusively for cooling purposes, and have an NPDES permit. Facilities subject to the Rule are required to develop and submit technical material that will be used by the NPDES Permit Director (Director) to make a BTA determination for the facility. The actual intake flow (AIF)3 and design intake flow (DIF)4 at a facility determine which submittals will be required, as shown in Table 1-1. Table 1-1. Facility and Flow Attributes and Permit Application Requirements Facility and Flow Attributes Applicable Requirements Existing facility with DIF of 2 MGD or less, or less Best Professional Judgment of Director than 25 percent of AIF used for cooling purposes Existing facility with DIF greater than 2 MGD and §122.21(r)(2)-(8) AIF less than 125 MGD Existing facility with DIF greater than 2 MGD and §122.21(1)(2)-(13) AIF greater than 125 MGD New units at existing facility* §122.21(r)(2), (3), (5), (8), and(14)and applicable paragraphs in(r)(4), (6), and(7)of§122.21(r) *ACC falls into this category based on the withdrawal volumes anticipated under the proposed operational scenario. 2 A CWIS is defined as the total physical structure and any associated constructed waterways used to withdraw cooling water from WOTUS. The CWIS extends from the point at which water is first withdrawn from WOTUS up to, and including, the intake pumps. 3 AIF is defined as the average volume of water withdrawn on an annual basis by the CWIS over the past 3 years initially and past 5 years for NPDES Permit Applications submitted after Oct. 14, 2019. The calculation of AIF includes days of zero flow. AIF does not include flows associated with emergency and fire suppression capacity. 4 DIF is defined as the value assigned during the CWIS design to the maximum instantaneous rate of flow of water the CWIS is capable of withdrawing from a source waterbody. The facility's DIF may be adjusted to reflect • permanent changes to the maximum capabilities of the cooling water intake system to withdraw cooling water, including pumps permanently removed from service, flow limit devices, and physical limitations of the piping. DIF does not include values associated with emergency and fire suppression capacity or redundant pumps(i.e., back- up pumps). Duke Energy 12 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station Based on the Rule, facilities with an AIF of 125 MGD or less have fewer application submittal requirements and will generally be required to select from the impingement compliance options contained in the Rule. Facilities with an AIF in excess of 125 MGD are required to address both impingement and entrainment, and provide specific entrainment studies, which may involve extensive field studies and the analysis of alternative methods to reduce entrainment (§122.21(r)(9)-(13)). The existing Duke Energy Progress, LLC (DEP) Asheville Steam Electric Plant (Asheville Plant) is located on Lake Julian in Buncombe County, North Carolina (Figure 1-1). Cooling water for the existing plant is withdrawn from the CWIS on Lake Julian. Supplemental water to maintain water levels in Lake Julian is withdrawn from an intake located on the adjacent French Broad River. 1.JJJa_ r v, E.xlalflCl '' JJJAII'iant - LEGEND vU Existing Asheville Plant 1 ;Ash Basins d • CWIS I -Karl srr 0 River Intake n,.,a�re,� av • outran 001 ASH R A S IN � ; 0 Mrs 015 1902 ASN BAS14 .y u'��k,J Ns'✓iJ!- e: • ^AtiiJA�itl L' t� r a bin 140'1111:, , : , .' ��s. :i � c>i :1 111 Buncombe County, 'WIC dote.This maps for planniig purposes only R does rot North Carolina contain survey information,and no attempt should be made b represent any pert of this drawing as such Figure 1-1. Site Layout at Asheville Combined Cycle Station, Buncombe County, North Carolina Duke Energy 13 Clean Water Act§316(b)Compliance Submittal F1JZ Asheville Combined Cycle Station Per Section 2 of the Mountain Energy Act, coal-fired operations at the Asheville Plant are required to cease by January 31, 2020. NPDES permit proceedings for Asheville Plant began prior to October 14, 2014 and DEP is expecting a permit to be issued with a 5-year permit term; r therefore, per 40 CFR 122.21(r)(1)(ii)(F), the permit application requirements listed in Table 1-1 are not applicable for the coal-fired units. Existing generation at the Asheville Plant will be replaced with two combined cycle power blocks, each with one combustion turbine, one heat recovery steam generator (HRSG), and one steam turbine. The Asheville Combined Cycle Station (ACC) will employ closed-cycle recirculating cooling towers, which will significantly reduce water withdrawal and remove thermal impacts to Lake Julian. The ACC units will utilize the existing CWIS on Lake Julian for raw water supply, including cooling tower make-up; therefore, the CWIS on Lake Julian is the point of compliance for the Rule. The existing river intake on the French Broad River will continue to be used for occasional withdrawals to offset drops in lake level resulting from low precipitation and losses due to dam seepage, evaporation, and raw water withdrawals for the ACC operations. The new ACC is defined as a "new unit" at an existing facility5 per 40 CFR 125.92(u). The new ACC has a DIF greater than 2 MGD and an AIF less than 125 MGD and, therefore, is not required to submit information detailed in §122.21(r)(10)-(r)(13) of the Rule. As such, DEP is providing the information detailed in §122.21(r)(2)-(8) and (r)(14), and summarized in Table 1-2, at least 180 days prior to the planned commencement of cooling water withdrawals for the operation of the new unit. Cooling water withdrawals will commence during functional testing, approximately six months prior to the scheduled commercial operation date of the units. Functional testing is scheduled to begin in March 2019 and commercial operation is currently scheduled to begin in November 2019. Appendix B provides a checklist summary of the specific information needs listed under each of the §122.21(r)(2)-(8) and (r)(14) submittal requirements and indicates how each of the requirements are addressed in this report. 5 The Rule states that"New unit"means a new"stand-alone" unit at an existing facility where construction of the new units begins after October 14, 2014 and that does not otherwise meet the definition of a new facility at§ 125.83 or is not otherwise already subject to subpart I of this part. A stand-alone unit is a separate unit that is added to a facility for either the same general industrial operation or another purpose.A new unit may have its own dedicated cooling water intake structure, or the new unit may use an existing or modified cooling water intake structure." Duke Energy 14 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station • Table 1-2. Submittal Requirements for New Unit(s) at an Existing Facility for Compliance Under Clean Water Act §316(b) §122.21(r)(2)-(8) and (r)(14) . Submittal Requirements at Submittal Description §122.21(r) (2) Source Water Physical Characterization of the source waterbody including intake area of Data influence is provided in Section 2.0. Characterization of the cooling water intake system; includes drawings (3) Cooling Water Intake and narrative; and a description of operations are provided in Section 3.0. Structure Data A water balance diagram and description of the process are provided in Section 5.0. As appropriate for closed cooling, characterize the biological community in Source Water Baseline the vicinity of the intake; life history summaries; susceptibility to (4) Biological impingement and entrainment; existing data; identification of missing data; Characterization Data threatened and endangered species and designated critical habitat summary for action area; identification of fragile fish and shellfish species list(<30 percent impingement survival).Addressed in Section 4.0. Narrative description of cooling water system and intake structure including water balance diagram; proportion of design flow used;water (5) Cooling Water System reuse summary; proportion of source waterbody withdrawn(monthly); Data seasonal operation summary;existing impingement mortality and • entrainment reduction measures; flow/MW efficiency.Addressed in Section 5.0. Chosen Method of As appropriate for closed cooling , provide the facility's proposed • Compliance with approach to meet the impingement mortality requirement(chosen from (6) seven available options); provides detailed study plan for monitoring Impingement Mortality compliance, if required by selected compliance option; addresses Standard entrapment where required. Provided in Section 6.0. As appropriate for closed cooling, summarize relevant entrainment studies (7) Entrainment Performance (latent mortality,technology efficacy); can be from the facility or elsewhere Studies with justification; studies should not be more than 10 years old without justification; new studies are not required.Addressed in Section 7.0. Provides operational status for each unit; age and capacity utilization for the past 5 years; upgrades within last 15 years; uprates and U.S. Nuclear (8) Operational Status Regulatory Committee relicensing status for nuclear facilities; decommissioning and replacement plans; current and future operation as it relates to actual and design intake flow. Provided in Section 8.0. Identifies the chosen compliance method for the new unit; based on the method selected will provide information to demonstrate closed-cycle (14) New Units cooling or entrainment reductions that are commensurate with closed- cycle cooling; may also include additional data and information, as determined by the Director. Provided in Section 9.0. Duke Energy 15 Clean Water Act§316(b)Compliance Submittal FN Asheville Combined Cycle Station 2 Source Water Physical Data [§122.21 (r)(2)] 2. 1 Description of Source Waterbody Once operational, the new ACC will withdraw raw water for cooling purposes at the existing CWIS on Lake Julian, the source waterbody. An aerial photograph of the future location of the ACC and its environs is shown on Figure 1-1 in Section 1 of this report. Lake Julian and the adjacent French Broad River are located within the French Broad-Holston River basin, which includes watersheds in North Carolina and Tennessee. The North Carolina portion of the French Broad-Holston River basin is 2,830 square miles and lies entirely in the Blue Ridge ecoregion. The French Broad River originates in Transylvania County, North Carolina, and flows north for 210 miles through western North Carolina into Tennessee, where it joins the Holston River near Knoxville to form the Tennessee River (NCDEQ 2017). The French Broad-Holston River basin is predominantly forested; however, it also contains some of the most populated urban areas in the region, including the mountain municipalities of Asheville, Waynesville, Hendersonville, and Black Mountain, North Carolina. Lake Julian was created to serve as part of the cooling system for the Asheville Plant by impounding Powell's Creek, a tributary of the French Broad River (North Carolina State Board of Health 1963). The freshwater lake reached full-pool elevation in June 1963 and the Asheville Plant began commercial operation in 1964. The shoreline-situated CWIS is located within an intake cove on the main body of Lake Julian. Cooling water for the existing coal units is currently circulated from the main body of the lake through the plant and into the discharge arm. The discharge arm of the lake has a surface area of 106 acres and a mean depth of 13 feet (Progress Energy 2013). The water from the discharge arm returns to the intake side of the lake via an opening underneath the railroad trestle (Figure 1-1). The main body of the lake has a surface area of 215 acres, a maximum depth of 108 feet, and a mean depth of 30 feet. Average surface water elevation on Lake Julian is approximately 2,160 feet above mean sea level (ft msl). The average impounded volume (at elevation 2,160) is approximately 8,819 acre-feet. Land use in Lake Julian's 4.8-square mile watershed is primarily residential and urban. Lake Julian is a relatively steep-sided, deep lake devoid of aquatic vegetation and other types of naturallyoccurringunderwater structure, resultingin less than optimal shallow-water fish habitat P (Progress Energy 2013). Artificial structures (submerged and cabled trees, fish reefs, etc.) have been placed along shorelines by DEP during periodic fish habitat enhancement activities to improve fish habitat in Lake Julian. With the retirement of the coal units, cooling tower make-up water for the new ACC units will be withdrawn from the existing CWIS on Lake Julian with the cooling tower blowdown being discharged to an existing outfall on the French Broad River. As such, the remainder of this document is focused on Lake Julian, the source waterbody for the ACC CWIS, for establishing compliance with the Rule's impingement and entrainment BTA standards. Duke Energy l 6 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station 2.2 Characterization of Source Waterbody To identify and characterize the primary source waterbody (i.e., Lake Julian), the following resources were reviewed: • Limnology of Lake Julian (2000, 2001, 2004, 2007, 2010) (CP&L 2001; Progress Energy 2010, Progress Energy 2013); and • Ecoregions of North Carolina (Griffith et al. 2002). Data were compiled, synthesized, and are summarized below. 2.2.1 Geomorphology Lake Julian is located within the Blue Ridge Level III ecoregion and, more specifically, the Broad Basins (Level IV) of the Blue Ridge ecoregion. The Blue Ridge ecoregion extends from southern Pennsylvania to northern Georgia and varies in topography from narrow ridges to hilly plateaus to more mountainous areas with high peaks. The mostly forested slopes, high-gradient streams, and rugged terrain occur over a mix of igneous, metamorphic, and sedimentary bedrock (Griffith et al. 2002). 2.2.2 Hydrology Lake Julian is located within the French Broad-Holston Basin, which is divided into eight U.S. Geological Survey hydrologic units, each designated by a Hydrologic Unit Code (HUC). Lake Julian lies within the Upper French Broad River subbasin HUC 06010105 (Figure 2-1). The drainage area of the Upper French Broad River subbasin is approximately 1,864 square miles. 2.2.3 Water Quality Water quality data from Lake Julian has been collected by DEP since 1973 as part of their Environmental Monitoring Program (Program). The Program includes periodic data collections targeting water chemistry, phytoplankton, zooplankton, benthic invertebrates, and fish communities (Progress Energy 2013). The Program originally consisted of annual sampling at select locations in Lake Julian (Figure 2-2), but was reduced in scope to a triennial frequency beginning in 2001. Water quality sampling for Lake Julian is performed on alternate months (i.e., January, March, May, July, September, and November) at Stations A2 and D2 (depth profile from surface to bottom) and at Station GS2 (i.e., February, April, June, August, October, December) (see Figure 2-2). These data are summarized in the following section. Water quality and limnological data collected from Lake Julian (Station D2) in 2000, 2001, 2004, 2007, and 2010 under the Program (Progress Energy 2013) are summarized in Table 2-1. Duke Energy 17 Clean Water Act§316(b)Compliance Submittal FIN Asheville Combined Cycle Station LEGEND Boone Fayette 8 Digit Hydrologic Units • Station Location 06010101 -North Fork Holston French Broad -Holston River Basin 06010102-South Fork Holston Raeigt County Boundaries 06010103-Watauga '� i or-^g D State Boundaries Summers 06010104 -Holston DATA SOURCE.V:;AE4 51E. Mercer 06010105-Upper French Broad McDowell 06010106-Pigeon k }\'' l�, �r 06010107-Lower French Broad Q Miles 2 Gds Bland 06010108-Nolichucky Tazewell "je Knox Russell E Harlan Wythe Smyth Bell Whitley Lee Scott .d'"� ' ashington .p„r Carroll r,, Grayson § Claiborne Hancock VIIjilliliarl E Haw;.= Alleghany Ashe Sum Union Gram e Washrgton g Ca r Hamblen I Greene ga Wilkes c Jefferson I e,w Mitchell as # ^' Caldwell Bison Yancey Alexander Sevier I t &cunt t Iredell Burke 9 ie McDowell Catawta be Asheville Combined H ----- Cycle Station Swain L ncoln Graham I Jackson Iowa Michigan Pennsylvania Pol lilanois Indiana Otii° Cherokee Macon Trans 1a West Virginia Maryland Delaware Clay issoun Kentucky Virginia "—""'" GreenvIle Tennessee --,• North Caroi na Towns .. ,_ Rabun Pickens South Carolina ,.inion • Oconee Mississippi Alabama Georgia White Habersham Anderson ouisiana Florida Figure 2-1. Map of French Broad-Holston Basin Hydrologic Unit Code 06010105 Duke Energy 18 Clean Water Act§316(b)Compliance Submittal Im) Asheville Combined Cycle Station LEGEND River Intake Outfall 001 Fi CWIS Existing Asheville Plant 1004, — S......Ash Basins a� ,, Iii.i ,46 ka 1 0 Miles 0.25 DATA SOURCE:erg re!Corwbubrs • o 141i.,4''''''' -i ,s, it 7.: 1 . • F is ft.r cul ; ''r fi Reefs f �` D2 Lake Julian AZ / a utfll �F.rmer , Skimmer Wall rr-. xi • r': •N'L `.�tT y GS2 Il.t;P`t:;a uli n ; - " I • *4... it 1.—J L�A�RR,, Ctiq,9 . . T s 1111 1 r . 1 a i I. ``*. 1964 r'......• ••. , •: 's ASH BASRA f 1982 ••.• . ,+' ASH BASINS • F til' • t •4.•tl+t.' l y`[ i).112 ,r Figure 2-2. Duke Energy Progress Environmental Monitoring Program Water Quality Sampling Stations on Lake Julian (Progress Energy 2013) Duke Energy 19 Clean Water Act§316(b)Compliance Submittal FIN Asheville Combined Cycle Station Table 2-1. Annual Mean Concentration for Select Parameters Documented in Surface Water Samples Collected in Lake Julian (Station D2) (Progress Energy 2013) Parameter 2000 2001 2004 2007 2010 Water Temperature(°C) 27.1 25.4 26.3 26.1 27.0 Specific Conductance at 25°C 118 110 94 118 105 (NS/cm) Dissolved oxygen(mg/L) 7.1 7.6 6.9 7.5 7.2 Total dissolved solids(mg/L) 51 57 57 57 90 Turbidity(NTU) 2.5 1.8 1.0 2.2 3.0 Secchi disk transparency(m) 3.0 3.7 3.0 2.7 2.6 Chlorophyll a(pg/L) 4.6 2.3 6.2 7.1 13.2 Nutrients(mg/L) Ammonia-N <0.05 0.06 0.02 <0.02 0.03 Nitrate+nitrite-N 0.07 0.04 0.12 0.06 0.019 Total nitrogen 0.39 0.34 0.53 0.49 0.028 Total phosphorus 0.012 0.009 0.010 0.010 0.010 Total organic carbon(mg/L) 3.6 2.4 1.9 2.0 2.7 Ions(mg/L) Calcium 4.0 3.1 2.2 8.0 5.7 Chloride 10.7 9.0 9.5 12.5 10.0 Magnesium 2.7 2.5 2.3 2.5 2.8 Sodium 9.5 9.5 7.3 6.1 5.5 Sulfate 10 11.6 7.7 6.8 7.9 Total alkalinity(mg/L as CaCO3) 23 20 15 31 18 Hardness(mg equiv. CaCO3/L) 21 18 15 30 26 mg/L: milligrams per liter; m: meter; NTU: nephelometric turbity units pg/L:micrograms per liter;CaCO3/L:calcium carbonate The mean annual nutrient concentrations (i.e., ammonia-N, nitrate+nitrite-N, total nitrogen, total phosphorus, total organic carbon) measured in Lake Julian from 2000 to 2010 were consistent both spatially and temporally, with the exception of total nitrogen. Mean total nitrogen concentrations were elevated in 2004 and 2007 compared to the remaining data years (i.e., 2000, 2001, and 2010). No adverse trends were observed for water chemistry characteristics of Lake Julian during the period of study. Mean trace element concentrations (i.e., metals and metalloids) in surface water samples were below their respective reporting limits during the data collection period. These data demonstrate that Lake Julian water quality is consistently within state water quality limits. The retirement of the coal units and subsequent operation of the new ACC units are not anticipated to have an adverse effect on water chemistry in Lake Julian. Duke Energy 110 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station • Water clarity (transparency) depth as measured by Secchi disk in Lake Julian was consistently between 2.6 and 3.7 meters (m) (see Table 2-1). Turbidity was also low with an average of 2.1 NTU across all years. The annual mean concentrations of total dissolved solids were consistent between 2000 and 2007, but displayed an increase during 2010 (Progress Energy 2013). However, the overall values observed across the data period were within the normal variation typically observed in comparably-sized reservoirs in the region. Thermal stratification typically develops during the spring/summer months in the main body of the lake resulting in low dissolved oxygen (DO) conditions (i.e., less than 4 mg/L) in the hypolimnion (the bottom strata of a thermally stratified reservoir or lake). Typically, by November, oxygenated water returns to the deeper portions of Lake Julian after lake turn over (Progress Energy 2013). Historical DO concentrations were consistently greater than 4 mg/L (minimum DO required by most healthy fish) in the epilimnion (Progress Energy 2013). Mean specific conductance data were consistent across the data collection period, with values between 94 micro Siemens per centimeter(pS/cm) in 2004 to 118 pS/cm in 2000 and 2007 (Table 2-1). The range of values documented for Lake Julian between 2000 and 2010 is consistent with freshwater systems in the region (Progress Energy 2013). The annual mean surface water temperatures recorded at Station D2 for the data period (2000, 2001, 2004, 2007, and 2010) exhibited minimal inter-annual variation, ranging between 25.4 degrees Celsius (°C) (2001) and 27.1°C (2000) (see Table 2-1). Upon commencement of ACC operations, blow-down and other byproducts of the ACC units will be routed to an existing outfall on the French Broad River and the thermal discharge into Lake Julian from the existing coal- fired operations will be terminated. As a result, the annual average water temperatures in Lake Julian are expected to return to ambient conditions more reflective of a small, mountain watershed. Changes in water temperatures have the potential to impact the occurrence and extent of thermal stratification of Lake Julian during the summer months, which would also potentially result in a slight improvement in DO conditions during the same time period. The absence of the thermal inputs from the coal-fired operations would also improve fish habitat for the native fish species in Lake Julian, as those species are well-adapted to the ambient water temperatures that will occur under operation of the ACC. 2.3 Determination of Area of Influence Reference to the area of influence (AOI) relative to a CWIS appears in three of the §122.21(r) sections of the Rule6: • §122.21(r)(2) Source Water Physical Data requires information on "the methods used to conduct any physical studies to determine the intake's area of influence in the waterbody and the results of such studies." 6 http://www.cipo.gov/fdsys/pkq/FR-2014-08-15/pdf/2014-12164.pdf Duke Energy I 11 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station • §122.21(r)(4) Source Water Baseline Biological Characterization Data states: "The study • area should include, at a minimum, the area of influence of the cooling water intake structure." • §122.21(r)(11) Benefits Valuation Study states: "The study would also include discussion of recent mitigation efforts already completed and how these have affected fish abundance and ecosystem viability in the intake structure's area of influence." Although the Rule does not provide a definition of AOI, the §316(b) Phase I rule for new facilities' states that: "The area of influence is the portion of water subject to the forces of the intake structure such that a particle within the area is likely to be pulled into the intake structure." While neither a formal definition of the AOI nor guidance for its estimation is provided in the Rule, it is assumed that the AOI is that area of the source waterbody from which organisms are drawn into the intake and either entrained or impinged. 2.3.1 Methods — Desktop Calculation For impingeable-sized organisms (i.e., generally juvenile and adult fish and shellfish), the AOI can be defined as the region in which organisms are not capable of overcoming the influence of water withdrawal and become impinged upon an intake screen (EPRI 2007). The Rule allows an intake through-screen velocity (TSV) of 0.5 feet per second (fps)8 or less as a compliance option for impingement reduction. This threshold is based on the assumption that, at velocities below this value, healthy impingeable-sized fishes will be able to swim freely and avoid impingement. Based on this assumption, a conservative definition of the AOl9 for impingement is the area encompassed by the 0.5 fps velocity contour at the CWIS. At this boundary and beyond it, the potential for impingement is approximately zero. Within the 0.5 fps boundary, the potential for impingement increases with increasing proximity to the intake structure. However, because juvenile and adult fish have varying swimming abilities and preferred habitats, including those that involve velocities above 0.5 fps (Leonard and Orth 1988), fish within the area contained by the 0.5 fps velocity threshold will not necessarily become impinged. The threshold velocity for entrainment is reflected by the velocities (above ambient velocities) created by the CWIS, such that plankton may be drawn into the intake structure rather than transported away in the ambient flow. Wind-induced surface drift velocities are typically two to three percent of the average wind speed (Wiegel 1964). At a location where the intake-induced velocity is less than 0.1 fps to 0.3 fps, the ambient wind-induced currents will likely dominate the flow patterns and the hydraulic influence of the intake structure will no longer be significant (Golder Associates 2005). 66 FR 65318, December 18, 2001. 8 As per the Rule, the design TSV of less than 0.5 fps meets the impingement mortality reduction standard through Compliance Alternative 2(§125.94(c)(2)). 9 This approach was proposed to Ohio EPA(OEPA)by Dayton Power&Light in their Proposal for Information Collection for the Stuart Generating Station on the Ohio River. Their approach was accepted by OEPA and also recommended as a model for other facilities on the Ohio River(EPRI 2007). Duke Energy 112 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station (' • These threshold values are consistent with those used in other AOI studies. For example, the Electric Power Research Institute (EPRI) used threshold velocities of 0.1, 0.5, and 1.0 fps in their desktop analysis presented in "Cooling Water Intake Structure Area-of-Influence Evaluations for Ohio River Ecological Research Program Facilities" (EPRI 2007), and Golder Associates (2005) used 0.1 and 0.3 fps in their desktop calculation of AOI for the Crystal River Energy Complex in Florida. The entrainment AOI is evaluated as the approximate area within the 0.3 or 0.1 fps velocity contours in the vicinity of a CWIS. For an organism to become entrained, it must enter the entrainment AOI of a CWIS. Physical and temporal factors that influence the entrainment AOI of a CWIS include (EPRI 2004): a) the speed, direction, and distribution of flow in the waters that surround the CWIS; b) the bathymetry of the waters that surround the CWIS; c) the intake flow rate and variability of flow to the intake; and d) the design of the intake. 2.3.2 Results — Desktop Calculations Cooling tower make-up water will be withdrawn at the existing Lake Julian CWIS which is comprised of four identical intake bays. Each bay will be equipped with a submersible pump with a design capacity of approximately 1,800 gallons per minute (gpm) (2.6 MGD). The ACC consists of two units (Unit 05/06 and Unit 07/08) that are designed to operate with two pumps • (one per unit), with the remaining two pumps providing redundant pumping capacity. As a result, the combined DIF capacity for the new ACC units will be 3,600 gpm (5.2 MGD). The CWIS is equipped with 1-inch hexagonal mesh fixed screens attached to the upstream face of the bar racks and oriented perpendicular to the direction of flow. In addition, new '/4-inch mesh fixed screens will be installed on the downstream side of the 1-inch hexagonal mesh panels as additional protection for the new submersible pumps. TSV calculations for were performed for both the existing 1-inch hexagonal mesh screens and new 1/4-inch mesh screens under normal and low water surface elevations (2,160.0 feet and 2,158.0 feet, respectively). Inputs used to perform TSV calculations are provided in Table 2-2; the TSV calculation package is provided in Appendix C. The average TSV under existing conditions (1-inch hexagonal mesh screen) at design flows and normal water surface elevation is 0.034 fps, and at low water surface elevation is 0.039 fps (Table 2-2). The average TSV for the new 1/4-inch mesh screen panels at design flows and normal water surface elevation is 0.043 fps, and at low water surface elevation is 0.049 fps (Table 2-2). These calculated TSVs are considerably lower than the 0.5 fps threshold used as the BTA standard for impingement mortality (§125.94(c)(2)). Impingement at the CWIS on Lake Julian is negligible because the impingement AOI does not extend beyond the face of the screen. Duke Energy I 13 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station Table 2-2. Summary of Input Parameters for TSV Calculations of CWIS on Lake Julian • Existing 1-inch Hexagonal New 1/4-inch Mesh Fixed Mesh Fixed Screens* Screens TSV Calculation Inputs Unit 05/06 Unit 07/08 Unit 05/06 Unit 07/08 Number of screens 2 2 2 2 Elevation at bottom of intake(feet) 2,144 2,144 2,144 2,144 Normal water surface elevation(ft msl) 2,160 2,160 2,160 2,160 Low water surface elevation(ft msl) 2,158 2,158 2,158 2,158 Screen width(feet) 9 feet 2 inches 9 feet 2 inches 9 feet 2 inches 9 feet 2 inches Mesh size(L)(inches) 1 1 0.25 0.25 Mesh size(W)(inches) 1 1 0.25 0.25 Mesh gauge number 19 19 16 16 Cooling Water Pump 1 Rating (gpm) 1,800 1,800 1,800 1,800 Cooling Water Pump 2 Rating(gpm) 1,800 1,800 1,800 1,800 TSV at normal water surface elevation 0.034 0.034 0.043 0.043 (fps) TSV at low water surface elevation(fps) 0.039 0.039 0.049 0.049 *Represents the TSV inputs based on the existing screens at the CWIS on Lake Julian • The calculated entrainment AOI, based on a 0.3 or 0.1 fps threshold velocity for the %-inch mesh screens is also considered negligible because, under the operational conditions for the ACC, the maximum TSV at design flows is 0.049 fps. At a TSV of 0.049 fps, the intake-induced velocity would not exceed 0.1 fps and would not extend beyond the face of the screens. As such, the AOI for entrainment at the CWIS on Lake Julian approximates zero. In an evaluation of fish swimming speed versus body length relative to the 0.5 fps impingement compliance alternative, the U.S. Environmental Protection Agency (EPA) concluded that a TSV of 1.0 fps would protect 78 percent of tested fish, and a velocity standard of 0.5 fps would protect 96 percent of tested fish (EPA 2014). Based on this information, a maximum TSV of 0.049 fps at ACC will likely protect greater than 96 percent of fish from impingement at the CWIS on Lake Julian. Duke Energy I 14 Clean Water Act§316(b)Compliance Submittal 1.01 Asheville Combined Cycle Station 3 Cooling Water Intake Structure Data [§122.21 (r)(3)] Cooling water for the ACC will be supplied though the existing CWIS on Lake Julian situated on the southern shoreline of the western arm of Lake Julian (Figure 3-1).The following sections provide additional information on the configuration and proposed operations of the CWIS on Lake Julian. ,, r o .°* >. lake Julian re Broad River Existing Units 1&2 CWIS (ACC Unit 05/06&' 07/08) River Intake Structure Intake Cove • • Ott, Figure 3-1. Asheville Combined Cycle Cooling Water Intake Structure on Lake Julian, Buncombe County, North Carolina 3. 1 Configuration The approximately 60-foot-wide CWIS on Lake Julian was originally constructed in the early 1960s for the Asheville Plant and will be repurposed for the ACC. The CWIS is comprised of four equally-sized intake bays (referred to as Intake Bays 1, 2, 3, and 4). A summary of the existing CWIS major components and those that will be repurposed or replaced is provided in Table 3-1. The general layout of the repurposed CWIS is shown in Figure 3-2. The opening of each of the four intake bays is approximately 21 feet high by 9 feet, two inches wide with an invert elevation of 2,144 ft msl (see drawing G-171048 in Appendix D). Each bay is equipped with a bar rack, two sets of fixed mesh screen panels (1-inch and 1/4-inch), and a submersible make-up cooling water pump. Duke Energy I 15 Clean Water Act§316(b)Compliance Submittal FIN Asheville Combined Cycle Station Table 3-1. Existing and Repurposed Cooling Water Intake Structure Components • Existing Intake Structure Repurposed Intake Structure Description of Major CWIS Components , Unit 1 Unit 2 Unit 05/06 Unit 07/08 Number of intake bays 2 2 same same 21 feet high x 21 feet high x Intake bay dimensions 9 feet, 2 9 feet,2 same same inches wide inches wide Elevation at bottom of intake(feet) 2,144 2,144 same same 1-inch hexagonal mesh fixed screen panel 2 2 same same Bar racks 2 2 same same '/4-inch mesh fixed screen panel -- -- 2 new 2 new Once-through condenser cooling water pump capacity(gpm) 2 x 48,300 2 x 61,500 Submersible make-up cooling water pump capacity(gpm) -- -- 2 x 1,800* 2 x 1,800* `Units 05/06 and 07/08 are designed to operate using one 1.800 gpm each. the remaining pump is for backup Units 5 6 Units 7/8 Pump Pump Pump Pump 5A 58 7A 76 Y.-inch screen -a inch screen '/.-inch screen /.-inch screen ) :::::.,..,,,,..._: :.. Bar Rack Bar Rack Bar Rack Bar Rack 1-inch hexagonal I-inch hexagonal 1-inch hexagonal 1 inch hexagonal mesh screen mesh screen mesh screen mesh screen Intake Bay 1 intake Bay 2 Intake Bay 3 Intake Bay 4 T T T T Lake Julian Figure 3-2. Layout of the Repurposed Lake Julian Cooling Water Intake Structure (not to scale) Duke Energy I 16 Clean Water Act§316(b)Compliance Submittal 01 Asheville Combined Cycle Station r . Near the entrance of the CWIS, 1-inch hexagonal mesh screens (comprised of 19-gauge wire) are overlain on the exterior side of the bar racks (3/8-inch thick steel bars with 3-inch on center spacing) to help prevent large debris from entering the structure, as illustrated in Figure 3-3. The new 1/4-inch mesh (16-gauge wire) fixed screen panels will be located approximately 16.5 feet downstream of the bar racks in the slots formerly used for traveling screens (see drawing G- 171048 in Appendix D). The new screens will be on the upstream side of the new submersible cooling water make-up pumps and provide an added layer of protection from debris that is able to pass through the outer 1-inch hexagonal mesh screens and bar racks. Wffinilialiffillilinfilir /111111111 ip-. 1.1111111111111111.11P. 4-11101014011110... 4111 s" Q'0.+• .dr'2:1-:3' N. IA; r Y� � - � , r Figure 3-3. Photograph of a 1-inch Hexagonal Mesh Screen Panel Employed at the Cooling Water Intake Structure on Lake Julian Each bay will be equipped with a submersible pump with a design capacity of approximately 1,800 gpm (2.6 MGD). Raw water will be withdrawn from Lake Julian, where it will pass through the 1-inch hexagonal mesh screen panels, bar racks, and 1/4-inch mesh screen panels before entering the submersible pumps. Design drawings for the Lake Julian CWIS are provided in Appendix D. 3.2 Operation The ACC facility is anticipated to operate as a base load facility with year-round condenser cooling water operations. The ACC will operate by utilizing one 1,800 gpm (2.6 MGD) capacity um per Unit (power block) for a total facilityDIF of 5.2 MGD. Raw water pump5A or 5B1°will pump supply raw water, including cooling water, to Unit 05/06 and raw water pump 7A or 7B will supply raw water, including cooling water, to Unit 07/08 (Figure 3-2). Note only two pumps (one for each power block) will be operational at any one time, with the remaining two pumps providing redundant pumping capacity. 10 Each of the power blocks will be operated with cooling water supplied from one of the two pumps dedicated to the power block. For example, with Units 05/06 only one of the two pumps(5A or 5B)will be actively pumping water at any given time. The remaining pump serves as a redundant or back-up pump to maintain operations during scheduled or unplanned repairs to the other pump. Duke Energy 117 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station 3.3 Latitude and Longitude of Structures The latitude and longitude (in degrees, minutes, and seconds) of the CWIS on Lake Julian is provided in Table 3-2. Table 3-2. Cooling Water Intake Structure Coordinate Information (Source: DEP 2005, DEP 2007) Intake Latitude Longitude Intake on Lake Julian 35°28'20.7"N 82°32'35.4"W 3.4 Engineering Drawings of CWIS A list of design drawings for the CWIS on Lake Julian is provided in Table 3-3 and the drawings are provided in Appendix D. Table 3-3. List of Engineering Drawings for ACC Intakes Structure Type Drawing No. Drawing Title CWIS on Lake Julian As-built C-219-D Concrete Intake Structure CWIS on Lake Julian Plan&Sections G-170903 Cooling Water System (Unit 1 Intake) Intake-MAS SH NO 1 CWIS on Lake Julian Plan&Sections G-171048 Intake Steel&Screens '/4 inch Mesh Fixed General Arrangement E117624 Static Screen Screen Panel Duke Energy 118 Clean Water Act§316(b)Compliance Submittal FYR Asheville Combined Cycle Station 4 Source Water Baseline Biological Characterization Data [§ 122.21 (r)(4)] 4. 1 Review of Available Biological Data The biological data needed to prepare the information required under 40 Code of Federal Regulations (CFR) §122.21(r)(4) are available. A list of historical data reviewed to develop the baseline biological characterization of the source waterbody, Lake Julian, includes the following: • 2015 and 2016 Lake Julian Electrofishing Study, unpublished data (DEP 2017b); • 2010-2011 Environmental Monitoring Report (Progress Energy 2013); • Electrofishing data presented from 2002, 2005, 2008, and 2010 sampling activities; and • 2000 Environmental Monitoring Report (CP&L 2001), including electrofishing (1998 and 2000) and gillnet (2000 only) data. These data were compiled and analyzed for this report and are summarized below. This report was developed utilizing the existing, available data for Lake Julian. As the selected ACC technology is fully compliant with the Rule, no impingement or entrainment studies were performed in support of the development of this compliance documentation. No additional • studies were performed to support the baseline biological characterization for the proposed ACC. 4.2 Species and Relative Abundance near the CWIS Since 1973, DEP has performed sampling of the fish community at multiple locations within Lake Julian (Figure 4-1). The objectives of the Lake Julian Environmental Monitoring Program (Program) are to assess the lake's overall water quality and the fishery community and document the introductions and/or possible impacts of non-native or exotic species to the lake. The following sections summarize the data collected from Lake Julian under the Program. 4.2.1 Lake Julian Environmental Monitoring Program Under the Program, as described in Section 2, data are collected and used to characterize the fish community in Lake Julian. Data from sampling activities performed on Lake Julian from 2000 through 2016 are summarized below. Electrofishing Studies (Carolina Power and Light Company 2001, Progress Energy 2013, and DEP 2017b) DEP, previously Carolina Power & Light Company (CP&L), performed nighttime boat electrofishing in October 2000 at 30 shoreline sampling locations in Lake Julian, representing 6 shoreline habitat types (CP&L 2001). These long-term sampling locations are shown on Figure 4-1. Duke Energy 119 Clean Water Act§316(b)Compliance Submittal EN Asheville Combined Cycle Station J LEGEND . i - - • Station Location / *V a 0 Sampling Locations a ix,,. J T Habitat Type Bare Shoreline iBS) Developed Shoreime with Bulkhead IDS) Overhanging Vegetation(OV Overhanging Vegetation w' Downed Timber(OT) 0 C _ Overhanging Vegetation w i - " �r Raprap(OR) i r; Riprap Embankment(RR) , '' ()ATA SOtURCE'.Lv.tic.-•_r9t99.949,,ortne..9rt•.and t,n J - (D i. .. 7 Pt e' )2400 co�.w < £:: C' . i s Cly C) crr-7 ,c E 1 ��+ f r'+`u Lake Julian , Station 30 0 IBSI " ' Station 29 Q _ , 0 IRRI �jr'^.M,� t5� 7J 1c, (a.1) .:1;'^'Station 27 " ' RRi • k Station 22 ,_ Stabon23 (BSp""'�• "' ,2 (RRI •,,L,.5 ^U•• Slat ori. ••t . SLitio i 16 r.s' Station 24 .1r • �Rk iBSI ati 'DS)* t •i • ,A Stati 25 < , glikiiik. -:,°wr: w (RR( 1 i'.. 4 OM Mari Two Swarm V�0~�1 Penne YT ICY ._,., .. �r''' ..- Ram Mn+hr¢5: 927 /041q 1919 099•1e0•e sPonie•CS 1 a.10 710 a 13 +!. y ' / % \ 9N-Fta=”i3OVa 1 L K /0121 as \\ V.!'.99.g VeRUMbn.T 9999.tn•w or, 7 st s4 1.11r 0 a.S 0.9999•99.9 9•9999999.w.p99..019, n.N Ise• d r 1„Nevili cin•. ", al yIOQi _ *•<^ H V' 1.11 27 ORS 110 TRIM UP*Mine ht11.1•f M.K LISSA 71• Cyte Statiop� 0".i^`,• TOW••...r. 7 34E w! Figure 4-1. Shoreline Habitat Types and Locations Sampled with Nighttime Electrofishing in Lake Julian, 2000-2016 (CP&L 2001, Progress Energy 2013, DEP 2017b) The entire length of the shoreline for each sampling location was sampled and catch rates were adjusted to number per hour of sampling time. Since 2002, triennial sampling has been • performed, consisting of spring (March) and fall (October) sampling at 16 shoreline locations in Lake Julian representing the same 6 shoreline habitat types (Progress Energy 2013). . Unpublished data from additional electrofishing studies performed in 2015 and 2016 (DEP 2017b), and using the program methodology described here, were also reviewed and included below. Duke Energy 120 Clean Water Act§316(b)Compliance Submittal L�� Asheville Combined Cycle Station (� Relative abundance for the species collected during electrofishing of Lake Julian in the more recent years (2000, 2010, 2015, and 2016) is summarized in Table 4-1. Species composition in Lake Julian has remained fairly consistent, varying between 12 species in 2000 and 16 species in 2010. Mean catch rates based on historical electrofishing data (2002, 2005, 2008, 2010, 2011) indicated that game fish species such as Bluegill (Lepomis macrochirus), Redear Sunfish (Lepomis microlophus), Redbreast Sunfish (Lepomis auratus), Largemouth Bass (Micropterus salmoides), and Channel Catfish (Ictalurus furcatus)were the dominant species (80 percent) across all habitat types for Lake Julian (Progress Energy 2013). Threadfin Shad (Dorosoma petenense) were also consistently collected in electrofishing efforts on Lake Julian. Table 4-1. Relative Abundance of Fish Collected in Electrofishing Samples on Lake Julian, 2000, 2010, 2015, 2016 (CP&L 2001 and Progress Energy 2013, DEP 2017b) Relative Abundance(Percent) Scientific Name Common Namea 2000b 2010° 2015° 20168 Lepomis macrochirus Bluegill(R) 68.7 64.2 39.2 45.7 Lepomis spp. Hybrid Sunfish(R) 0.4 19.0 11.4 16.4 Lepomis auratus Redbreast Sunfish(R) 11.7 2.1 2.4 4.4 Lepomis cyanellus Green Sunfish(R) 9.1 4.7 17.4 13.1 Lepomis gulosus Warmouth(R) 1.3 0.1 1.7 0.4 Lepomis microlophus Redear Sunfish(R) 0.2 2.7 5.7 5.4 Micropterus salmoides Largemouth Bass(R) 4.7 0.9 3.2 3.9 Micropterus punctulatus Spotted Bass(R) -- 0.4 6.4 4.8 Micropterus sp. Largemouth Bass x Spotted Bass Hybrid(R) -- -- -- 0.03 Pomoxis nigromaculatus Black Crappie(R) -- 0.5 0.04 - lctalurus punctatus Channel Catfish(R) 2.6 1.3 2.2 2.1 Ameiurus platycephalus Flat Bullhead(R) -- <0.1 -- -- Dorosoma petenense Threadfin Shad(F) 0.4 1.4 7.7 3.0 Dorosoma cepedianum Gizzard Shad(F) -- <0.1 -- 0.03 Tilapia aurea Blue Tilapia(E) 0.6 2.5 2.5 0.7 Pterygoplichthys pardalis Amazon Sailfin Catfish(E) 0.2 <0.1 0.1 -- Cyprinus carpio Common Carp(R) 0.2 -- -- -- Ctenopharyngodon idella Grass Carp(S) -- -- - 0.02 Gambusia holbrooki Eastern Mosquitofish(F) -- <0.1 -- -- - Carassius auratus Goldfish(F) -- -- 0.02 -- a) R: Recreational; F: Forage; E: Exotic, non-native; S: Stocked b) Relative abundance calculated from catch per unit effort(CPUE) • c) Relative abundance calculated from total number collected (not standardized on effort) Duke Energy 121 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station Annual stock indices (e.g., proportional size distributions) were compiled from sample results from 2002, 2005, 2008, and 2010, and were used to evaluate the Largemouth Bass population in Lake Julian. The proportional size distribution for Largemouth Bass for all sample years and over the entire data range was indicative of a balanced bass management strategy (Progress Energy 2013). 2000 Gillnet Study (CP&L 2001) In October 2000, two experimental monofilament gillnets were fished targeting additional data on species that were collected in low numbers or otherwise poorly represented in electrofishing studies but consistently reported by anglers, primarily Black Crappie (CP&L 2001). Gillnets were 30.5-m long and 2.4-m deep with equal sections of 25-, 50-, 75-, and 100-millimeter stretch- mesh monofilament. Nets were set for two days and fished at approximately 24-hour intervals. Catch rates are expressed as mean number of fish per 24-hour set (Table 4-2). A total of seven fish species were collected during gillnet sampling of Lake Julian in 2000. The dominant species collected was Channel Catfish, followed by Threadfin Shad, and Blue Tilapia (Tilapia aurea). Table 4-2. Mean Number per 24-Hour Set of Fish Collected during Gillnet Sampling on Lake Julian, 2000 (Source: CP&L 2001) Family Name Scientific Name Common Name Mean(per 24-hour set) Ictaluridae Ictalurus punctatus Channel Catfish 17 • Clupeidae Dorosoma petenense Threadfin Shad 10 Cichlidae Tilapia aurea Blue Tilapia 7 Micropterus salmoides Largemouth Bass 4 Lepomis macrochirus Bluegill 3 Centrarchidae Lepomis microlophus Redear Sunfish 1 Pomoxis nigromaculatus Black Crappie <1 Total Number of Species 7 4.2.2 Conclusions from Lake Julian Sampling Program Long-term fish community monitoring results indicate the fish community is not dominated by pollution-tolerant species, but rather by native sunfish (centrarchids) and other recreational species from multiple size classes indicating a self-sustaining biological community with the capacity to sustain themselves through cyclic seasonal changes (Progress Energy 2013). Two exotic (non-native) species were also documented in Lake Julian, (i.e., Blue Tilapia and Amazon Sailfin Catfish [Pterygoplichthys pardalis]). The Amazon Sailfin Catfish was first documented during 1997 and was most recently collected in 2015, although relative abundance was low at 0.1 percent (Progress Energy 2017b). In 1965, Blue Tilapia were experimentally stocked by the North Carolina Wildlife Resources Commission to provide additional forage for Largemouth Bass. Blue Tilapia subsequently became established in Lake Julian; however, results from periodic electrofishing studies consistently indicate low relative abundance (varying between 0.6 to 2.5 percent from study data collected between 2000 and 2016). Duke Energy 122 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station Potential changes associated with operation of the ACC facility (i.e., elimination of the thermal plume in Lake Julian) is not expected to result in an adverse environmental impact to the native aquatic organisms in Lake Julian because they are naturally adapted to the ambient conditions of Lake Julian (a small, mountain lake). However, populations of the exotic Blue Tilapia and Amazon Sailfin Catfish are expected to be reduced or eliminated from Lake Julian with the removal of the thermal inputs from the retiring fossil station. Threadfin Shad is a fragile species that typically experiences varying levels of winter mortality in response to cold shock. As such, the removal of thermal inputs from the retiring fossil station may result in winter mortalities or potentially lead to the elimination of this species in Lake Julian. 4.3 Primary Growth Period Fish are cold blooded, thus primary growth occurs when water temperatures are 10°C or above. The conventional view on seasonal variation in fish growth in North America is that growth is fastest in the spring and early summer, slows in the late summer and fall, and virtually stops in the winter (Gebhart and Summerfelt 1978). The majority of fishes will have their highest densities shortly after the hatch occurs when larvae are concentrated and natural mortality has not yet reduced numbers. Feeding competition is especially important during late spring through early summer when the bulk of fish are in their early life stages and are more susceptible to starvation (May 1974). This is a critical stage in development, where larval fish have a short time period to initiate exogenous feeding before starving (Ehrlich 1974; Miller et al. 1988). Fish reproduction for the species in Lake Julian occurs via external fertilization", which is principally controlled by water temperatures. Fish reproduction has the potential to produce high yields; however, mortality rates can also be high compared to other organisms. Additionally, a majority of fish spawn only once a year regardless of prior success. Fecundity, the number of eggs a female produces, can vary depending on the life history of the species. Species-specific spawning information is summarized in Section 4.4 of this report (Seasonal and Daily Activities of Organisms in the Vicinity of the CWIS). Monitoring data collected on Lake Julian indicate the presence of multiple size classes indicating good reproductive success. Generally, larval recruitment to the juvenile life stage in North Carolina begins in November and continues until April or May, depending on the life history strategy of individual species (Page and Burr 2011). As a result, peak larval fish entrainment also commonly occurs during the period immediately prior to larval recruitment to the juvenile or young-of-year stage. During this period, the smaller larval stage fish are less adept at maintaining their position in currents compared to larger fish and are more susceptible to entrainment. The majority of the native fish species present in Lake Julian are nest builders; the eggs remain in the nest and newly hatched larvae do not travel far from the nest. Others are broadcast spawners with demersal and adhesive eggs that stick to the substrate. 11 The release of both sperm and egg outside of an organism is defined as external fertilization. Duke Energy 123 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station 4.3.1 Period of Peak Abundance for Relevant Taxa • Fish spawning is a direct function of water temperature, and most activity is constrained to the spring and early summer months. As a result, an influx of egg, larval, and juvenile fishes occurs in Lake Julian each year when water temperatures begin to rise. Under ACC operations, spawning is anticipated to initiate around March or April. As such, peak abundance for most early life stages and juvenile fishes in Lake Julian is expected to occur between April and June depending on each species' unique spawning habitats, as presented in Table 4-3. Table 4-3. Known Spawning and Recruitment Period of Native Species with Documented Occurrence in Lake Julian, North Carolina (Sources: Rohde et al. 1994; Rohde et al. 2009; Etnier and Starnes 1993 ) Common Namecji Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec Black Crappie --- Bluegill I __- Green Sunfish I 111_-- Largemouth ■� Bass Largemouth X Spotted Bass Centrarchidae Hybrid Redbreast I ■_ Sunfish Redear Sunfish --- Bmallmouth ■■■ Bass Spotted Bass --� Warmouth I Clupeidae Gizzard Shad -_- Threadfin Shad ■■- Common Carp -_-- Cyprinidae Goldfish ---- Grass Carp 1111 ._. Brown Bullhead I Ictaluridae Channel Catfish I Flat BullheadEI - tern Poeciliidae Mosquitofish ■- tofish Gray-shaded months indicate the known spawning Darker shaded months and recruitment period. indicates period of potential peak abundance. Note: The data presented here represent the spawning and recruitment windows that are typical of the region and that are anticipated for Lake Julian after operations of ACC begin. Duke Energy 124 Clean Water Act§316(b)Compliance Submittal rLYZ Asheville Combined Cycle Station 4.4 Seasonal and Daily Activities of Organisms in the Vicinity of the CWIS There are no diadromous fish species in Lake Julian. Most species undergo short or local migrations for spawning and/or overwintering. Table 4-4 summarizes seasonal (i.e., spawning) and daily (i.e., feeding and habitat preference) activities for species observed in Lake Julian. Table 4-4. Seasonal and Daily Activities of Species Present in Lake Julian (Sources: Rohde et al. 2009; Rohde et al. 1994; Etnier and Starnes 1993) Species (Common Seasonal Activities/Spawning Migration Daily Activities/Daily Migration/Habitat Name) Usually found in vegetated areas of backwaters in Spawning occurs from late February to early streams and rivers in ponds and reservoirs.Prefer Black Crappie May.Nests are constructed in shallow water clearer and cooler waters than White Crappie.Young sometimes in close proximity to each other. Black Crappie feed on aquatic insects and small fishes and adults feed primarily on fishes. Spawning occurs from May through the end of Tolerant of many conditions,and utilize most of the summer(typically August)with a peak generally habitats available to the species in North Carolina. • Bluegill in June.Colonies of nests are constructed by Natural habitats are pools in creeks and rivers,swamps, males in shallow water areas on variable oxbow lakes,impoundments,and ponds,with cover of substrates. vegetation,submerged wood,or rocks.Their diet consists of aquatic insects,small fishes,and crayfishes. Prefer slow pools and backwaters of low-and moderate Spawning occurs from April through August. gradient streams and rivers,but also occur in ponds, Green Sunfish Colonies of nests are almost always constructed lakes,and reservoirs.Highly tolerant of conditions such near shelter such as a log or clump of as turbidity and drought and can rapidly colonize new vegetation. habitats. Food preferences are aquatic insects and small fishes. Spawning occurs late April to June.Nests are Occupy a wide variety of habitats.Prefer warm,calm, Largemouth Bass generally located in sand or gravel at the base of and clear water and thrive in slow streams,farm ponds, logs,stumps,and emergent vegetation along lakes,and reservoirs.Adults feed on fishes,frogs,and shorelines. almost any other animal of appropriate size. Spawning generally occurs from late May Typically found in pools and backwaters of streams and Redbreast through the end of July,with a peak in June. rivers of low to moderate gradient where the species is Sunfish Nests are larger saucer-shaped depressions usually associated with woody debris,stumps,and swept out in a substrate of coarse sand and undercut banks. Preferred foods include terrestrial gravel and typically made in shallow water. insects,aquatic insects,small clams and fishes. Found in a variety of habitats in ponds,lakes,reservoirs, Spawning generally occurs from late spring to swamps,sluggish streams,small rivers,and backwaters Redear Sunfish early summer. Nests are constructed in colonies often in or near vegetation and over a mud or sand in shallow waters. bottom.Prefer to feed on hard invertebrates such as snails and small clams. Spawning occurs from late spring to early Prefer clear water but occasionally can be found in Smallmouth Bass summer.Nests are constructed in coarse gravel either cool or warm waters of mountain rivers and deep in less than three feet of water near the margins rivers.Young feed on insects while adults feed primarily of streams or lakes. on crayfishes and fishes. Duke Energy 125 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station rJ Species (Common Seasonal Activities/Spawning Migration Daily Activities/Daily Migration/Habitat Name) Spotted Bass spawn between mid-April and mid- Preferred habitat is long deep pools in medium to large June.The males construct nests over rocky or streams and rivers.They avoid shallow,heavily Spotted Bass gravely substrate near cover.They will spawn in vegetated,still,waters preferred by Largemouth Bass, deeper water than the other two species of Black and the swift flowing rocky waters preferred by Bass. Smallmouth Bass.Young feed on insects while adults feed primarily on crayfishes and fishes. ! ± tEt pawning ours from late spring thrWarmouth and reservoirsepecially in shallow and well vegetated llow water. areas.They eat only crayfishes and insects. Cichiidae Blue Tilapia Young develop inside of female Nest builders Inhabit lakes,ponds,pools,and backwaters of low- Spawning occurs in the spring and summer,from gradient streams.Gizzard Shad are filter feeders, Gizzard Shad March through August,usually near the surface consuming copepods,cladocerans,phytoplankton and and in large aggregations. zooplankton.Feeding activity is highest during the day with minimal activity at night. Spawning occurs from April to July,during the - Threadfin Shad brief interval between dawn and sunrise,near Occur in large schools in mid-water and feed on the shoreline,and over aquatic plants and other phytoplankton and zooplankton. submerged objects. Cyprinid` Tolerant of a wide range of environmental conditions. Typically found in the calm and mud-bottomed waters of sluggish pools,backwaters,and reservoirs where Spawning occurs in the spring in shallow,warm, vegetation is present.Common Carp are omnivores. Common Carp and vegetated waters.The small eggs attach to They ingest mouthfuls of the soft bottom sediments vegetation or sink into the muddy substrate. (detritus),expels them into the water,and then feed on the disclosed insects,crustaceans,annelid worms, mollusks,weed and tree seeds,aquatic plants,and algae. This benthic species is commonly found in still water of Goldfish Spawning occurs in the spring and summer. lakes,reservoirs,ponds,rivers,and quite streams Adhesive eggs are scattered. dominated by vegetation.It tolerant clear or turbid waters. During spawning season,Grass Carp will Found in quiet or slow-moving waters,in ponds,lakes, Grass Carp migrate up rivers.They typically lay eggs over pools,and backwaters of larger rivers.Young are known shoals and a large female can produce more to eat small invertebrates and microcrustaceans while than a million eggs. adults are omnivorous. Ictaluridae Occur over soft substrates in pools,slow-moving creeks, Spawning begins in April and May and continues and any-sized rivers and in various lentic habitats.They Brown Bullhead into late summer;adults build circular,shallow are bottom feeders with a wide variety of diet consisting nests. of crustaceans,insects,worms,algae,mollusks,and fishes. Duke Energy 126 Clean Water Act§316(b)Compliance Submittal FinL Asheville Combined Cycle Station (� Species (Common Seasonal Activities/Spawning Migration Daily Activities/Daily Migration/Habitat Name) Inhabit a wide range of habitats from small to large creeks,rivers,reservoirs,and ponds.The species can Channel Catfish Spawning begins in April and May and continues occur over a range of substrates.The young feed on into early summer. plankton and aquatic insect larvae while juveniles and adults prefer crayfishes,mollusks,immature mayflies, and caddisflies. Occupy a variety of habitats.Adults are more common Spawning occurs in June and July,at water in slow areas of rivers with a mud or sand bottom and Flat Bullhead organic debris.The young frequently inhabit smaller, temperatures of 21-24°C. clearer streams.Prefer aquatic insects,small fishes, and snails. Amazon Sailfin Introduced species that excavates river banks to Catfish create burrows in which an attracted female will Feeds on algae,benthic organisms,and detritus. lay and guard her eggs. 3,'"rs S a ki. Primarily inhabit slow-moving,larger creeks,and rivers. Eastern Spawning occurs in the spring when large Generally found in pools and backwaters,often over a Mosquitofish schools migrate to reproduce in calm sand bottom.Mainly feed on surface-dwelling aquatic backwaters. insects and their larvae. Water column migration or diel vertical migration in Lake Julian is typical for fish species that inhabit lacustrine environments. During a daily cycle, zooplankton and fish exhibit synchronized movements up and down in the water column and this movement is referred to as diel vertical migration (Brierley 2014). Diel vertical migration in freshwater fish is primarily triggered by the diel change in light intensity, with declining illumination at dusk triggering the ascent to the surface and increasing illumination at dawn triggering the descent back to deeper water (Mehner 2012). This is the typical pattern for many species; however, reverse migration can also occur. Additional triggers for vertical migration include hydrostatic pressure and water temperature, which may guide fish into particular water layers at night (Mehner 2012). Pelagic (open water) organisms use diel vertical migration to balance the competing objectives of growing quickly and minimizing predation risk. In fish species that perform diel vertical migration, there are two similar ecological traits: 1) they are planktivorous; and 2) they require cold or cool water and live primarily in the pelagic zone of deep, thermally stratified lakes (Mehner 2012). In Lake Julian, diel vertical migration can be considered characteristic of many freshwater fish species, particularly juveniles or species that are small in adulthood. 4.5 Species and Life Stages Susceptible to Impingement and Entrainment • 4.5.1 Impingement The degree of vulnerability to impingement exhibited by adult and juvenile fish species depends upon biological and behavioral factors including seasonal fish community structure, spawning Duke Energy 127 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station effects on distribution, habitat surrounding intake structures, high flow'events, and attraction to the flow associated with the intake. In addition, swimming speed, intake velocity, screen mesh size, trash rack spacing, and other intake configurations will also affect the susceptibility to impingement. For example, clupeids have high susceptibility to impingement based on multiple factors such as schooling behavior, distribution in the water column, negative rheotactic response to intake flows, and poor swimming performance in winter months due to lower water temperatures (Loar et al 1978). No ongoing or historical impingement studies have been performed at the CWIS on Lake Julian. The ACC makeup cooling water will be withdrawn from Lake Julian through fixed mesh screen panels with a TSV of much less than 0.5 fps; thus, the ACC closed-cycle cooling system design is fully compliant with Compliance Alternative 2 (§125.94(c)(2)). As such, no species or life stages are anticipated to be susceptible to impingement at the Lake Julian CWIS. In addition, the ACC's closed-cycle recirculating cooling water system (CCRS) is compliant with §125.94(e)(1). 4.5.2 Entrainment Ichthyoplankton, which is defined as the egg and larval life stage of fishes, exhibit the highest degree of susceptibility to entrainment based on body size and swimming ability. Therefore, an organism will spend only a portion of its life cycle susceptible to entrainment, as larger juvenile and adult life stages are excluded by screens at the CWIS. Life history characteristics can influence the vulnerability of a fish species to entrainment. For example, broadcast spawners have free-floating eggs which drift with water currents and can be entrained in a CWIS; however, species with adhesive eggs or nest building species will be less susceptible to entrainment of early life stages. DEP has regularly performed electrofishing surveys in Lake Julian near the CWIS. Historical electrofishing sampling results for Lake Julian were used to determine species composition of Lake Julian and to identify those species potentially susceptible to entrainment at the CWIS on Lake Julian. The evaluation of species-specific susceptibility to entrainment is presented in Table 4-5. Based on the anticipated make-up water withdrawal volumes that will be required for operation of the ACC, and the calculated TSV values presented in Section 3, interactions with aquatic organisms are expected to be limited, with an extremely low potential for adverse environmental impacts. Two species in Lake Julian are considered "likely to be" susceptible to entrainment, Gizzard and Threadfin Shad (Table 4-5) are broadcast spawners with high fecundity. While there is some potential for species in Lake Julian to be susceptible to entrainment, the low TSV and low make- up water withdrawal rate at this facility are expected to minimize entrainment and related potential for adverse impacts to the biological community. Duke Energy 128 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station Table 4-5. Entrainment Potential for Fish Species Identified in Lake Julian Species Habitat Use/Preference Potential for Entrainment* (Common Name) Centrarchidae Construct nests around vegetation Unlikely due to water depth in the vicinity of the Black Crappie close to other nests CWIS, demersal and adhesive eggs, parental care of nest until larvae swim-up Nest generally constructed in Unlikely due to water depth in the vicinity of the Bluegill shallow waters CWIS, demersal and adhesive eggs, parental care of nest until larvae swim-up Green Sunfish Construct nests around vegetation Unlikely; limited quantity of vegetation available in the vicinity of the CWIS Largemouth Bass Nest constructed in shallow areas Unlikely due to water depth in the vicinity of the of one to six feet CWIS Construct nests over silt-free or Redbreast Sunfish lightly silted sand and gravel in Unlikely;specific substrate type not present cover Nest generally constructed in Unlikely due to water depth in the vicinity of the Redear Sunfish shallow waters CWIS,demersal and adhesive eggs, parental • care of nest until larvae swim-up Unlikely due to water depth in the vicinity of the Spotted Bass Nest builder CWIS, demersal and adhesive eggs, parental care of nest until larvae swim-up Warmouth Construct nests in cover Unlikely; no cover near intake ,...,,., ........ .- ..-... ,��., .�-'.,._a.r .� Cichlidae Blue Tilapia Nest builders and young develop Unlikely due to habitat preference and inside of female reproduction tendency Clupeidae Gizzard Shad Broadcast spawners Potential, broadcast spawner increases susceptibility Threadfin Shad Broadcast spawners Potential, broadcast spawner increases susceptibility Cyprinidae ,,.m. r,..�,r ..n,... mnm<rn� .rrw„w<w. .:,m,.0 • , Common Carp Lays adhesive eggs in shallow Unlikely due to absence of shallow, vegetated vegetation habitat in the vicinity of the CWIS Goldfish Lays adhesive eggs in shallow Unlikely due to absence of shallow, vegetated vegetation, introduced species habitat in the vicinity of the CWIS Demersal eggs, stocked Grass Carp populations are triploid and sterile. Unlikely; stocked species are triploid and Illegal to stock this species unless sterile triploid Duke Energy 129 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station Species Habitat Use/Preference Potential for Entrainment* (Common Name) Brown Bullhead Females lay eggs in dark shallow Unlikely due to habitat preference • areas under rocks and inside logs Cavity nesters, found in large open Channel Catfish areas with woody debris, bank Unlikely due to habitat preference cavities; moderate currents Flat Bullhead Cavity nesters Unlikely due to habitat preference Amazon Sailfin Lay eggs in burrows and guard Catfish eggs Unlikely due to habitat preference Eastern Young develop inside female Unlikely because they are live-breeders Mosquitofish *TSV below 0.5 fps at the CWIS will minimize potential for entrainment for all species based on their ability for avoidance of the intake. Species with floating eggs would continue to have some susceptibility to entrainment. The retirement of the Asheville Plant and commissioning of the new ACC will reduce the potential for entrainment on Lake Julian and will result in a reduction of total withdrawal volumes at the intake structure. The change from once-through cooling to closed-cycle cooling will therefore have a positive impact on the health of the native fishery and reduce the potential for entrainment on Lake Julian. 4.5.3 Life History Information for Species Susceptible to Entrainment A subset of species present in Lake Julian with the likelihood to be entrained was selected for detailed life history descriptions including reproduction, recruitment, and peak abundance. Threadfin Shad and Gizzard Shad were selected as target species because of reproduction (i.e., broadcast spawner or floating eggs). Bluegill was also selected as a target species because it was the most abundant species in historical electrofishing collections, is a substantial contributor to the recreational fishery, and is an important forage species for game fish. Other selected species that contribute to the recreational fishery of Lake Julian and were among the most dominant species collected in historical electrofishing sampling include Green Sunfish, Largemouth Bass, and Spotted Bass. Of the selected species, two (i.e., Threadfin Shad and Gizzard Shad) are recognized as having the highest potential for entrainment at the CWIS. Threadfin Shad Spawning occurs in shallow waters such as near shorelines or riverbanks. Threadfin Shad spawn from April to July in water temperatures above 16°C between dawn and sunrise. • Spawning occurs near the shoreline and over aquatic plants and other submerged objects with Duke Energy 130 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station eggs that are demersal and adhesive. Threadfin Shad are sensitive to sudden changes in water temperature and oxygen content resulting in frequent die-offs in late summer and winter . Gizzard Shad Gizzard Shad spawning can occur from mid-March to late August, with peak population spawning in May and June at water temperatures ranging from 15.6-22.8°C (Wallus et al. 1990). They spawn in large schools and their adhesive eggs are deposited on roots, fibers, and debris along the shore (Miller 1960). Gizzard Shad are extremely prolific spawners and can deposit as many as 400,000 eggs at one time (Tomelleri and Eberle 1990). Bluegill Bluegill occur in most rivers and lakes in the southeastern U.S. and are frequently found in backwater habitats containing vegetation and woody debris. Bluegill spawn at water temperatures between 19.4 and 26.7°C (Cornish and Welke 2004; Spotte 2007). The spawning season begins in spring or early summer when the water temperature reaches approximately 21.1°C with the peak of spawning in the mid-Atlantic region occurring in May or June. Individual fish may spawn several times within the same season (Rohde et al. 1994). Bluegill are colonial breeders in the sense that spawning fish build nests that are usually in close proximity to each other. Males construct nests that are approximately 1 foot in diameter in shallow water (i.e., depths of 1 to 3 feet). The eggs from several females can be fertilized and deposited in the nest, which is then defended by the male until the eggs have hatched. Because the nests are located in shallow depths, water level fluctuations can severely impact successful reproduction as nests can be stranded by low water level or disrupted by strong wave action. The adhesive eggs hatch after 72 hours at 22.2°C and 34 hours at 26.7°C (Cornish and Welke 2004). The yolk sac is absorbed when larvae are 6 millimeters long, at which time they leave the nest and move into littoral vegetation. Fry are free swimming after approximately 10 days (Carlander 1977). Fecundity ranges from 2,000 to 8,000 eggs at age 3 and up to 60,000 eggs at ages 4 to 8. Green Sunfish Green Sunfish have a wide tolerance to many different aquatic conditions. They prefer smaller, low-velocity streams and ponds but can inhabit lakes with weedy shorelines and shallow rivers. Green Sunfish are tolerant to both turbid and clear water(Etnier and Starnes 1993). Green Sunfish have an extended spawning period from June to August during which time a single male will construct several nests (Hunter 1963). Green Sunfish are prolific colonizers and are tolerant of warm, turbid water making them the most abundant and adaptable of all the sunfishes. Spawning occurs when the water temperature rises above 21°C. Bluegill and Green Sunfish have similar fecundity rates and produce approximately up to 50,000 eggs. Eggs hatch after 1 to 2 days and generally stay with the male for 5 to 7 days for protection before the fry become independent. Duke Energy 131 Clean Water Act§316(b)Compliance Submittal FIN Asheville Combined Cycle Station Largemouth Bass Largemouth Bass spawn when water temperatures reach 15.6-23.9 °C (Heidinger 1975). The male builds a nest in substrate typically comprised of rocky sand or gravel and cleared of • organic debris and silt (Emig 1966; Rohde et al. 1994; Pflieger 1997). The nests are 2 two 3 feet in diameter and usually widely spaced (i.e., 30 feet apart) unless the available nesting area is limited. Nests are built in areas of no current or wave action (Pflieger 1997) at depths of 1 to 15 feet. Males remain at the nest to fan the eggs to keep them silt-free and to protect the young for up to two weeks (Pflieger 1997). Eggs hatch in 2 to 5 days (Emig 1966) and the fry form tight schools over the nest and begin to feed in five to eight days. The schools break up approximately 1 month after hatching when the young bass are approximately one inch long. Growth rates are variable and depend on the lake productivity and food availability. Largemouth Bass typically mature at about ages 1 to 2 in the region (Carlander 1977; Rohde et al. 1994), or when they reach approximately 10 inches long (Pitlo et al. 2004). Spotted Bass The natural range of the Spotted Bass includes western North Carolina and western Virginia. Similar to the Smallmouth Bass (Micropterus dolomieu), it spawns in late spring or early summer (Rohde et al. 1994). The Spotted Bass constructs a solitary, saucer-shaped nest which the male guards until the eggs hatch and the fry are capable of leaving the nest. Generally, growth is faster in reservoirs than in flowing water (Rohde et al. 2009). The species is not long- • living, with individuals typically not living past 6 years of age; maturity is reached at 2 to 3 years of age. 4.6 Threatened, Endangered, and Other Protected Species Susceptible to Impingement and Entrainment at the CWIS The Rule requires the permittee to document the presence of federally listed species and designated critical habitat in the action area (see 40 CFR 125.98[f]). For the purpose of defining listed species, the action area is defined as Lake Julian. A desktop review of available resources was performed to develop a list of species with protected, endangered, or threatened status that might be susceptible to impingement and entrainment at the CWIS on Lake Julian. The USFWS's map-based search tool (Information for Planning and Consultation [IPAC])was used to identify state or federally listed rare, threatened, or endangered (RTE) aquatic species or critical habitat designations within Lake Julian. The North Carolina Natural Heritage Program was consulted for state-protected species. Because the ACC will be located in a freshwater environment, marine and anadromous federally listed species and designated critical habitat under National Marine Fisheries Service jurisdiction were not considered. State or federally listed RTE aquatic species or critical habitat designations for Buncombe Duke Energy I 32 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station County, North Carolina, are provided in Table 4-6. Federal species of concern and candidate species were omitted from the list (unless they were also state threatened or endangered), as there are no requirements to address those species under the Rule or Section 7 of the Endangered Species Act. Table 4-6. Rare, Threatened, or Endangered (RTE) Aquatic Species Listed for Buncombe County, North Carolina, and Record of Occurrence or Potential to Occur in Lake Julian Scientific Common Status* Record of occurrences or potential to occur in Lake Julian Name Name Polyodon FSC, No record of occurrence in Lake Julian. s athula Paddlefish SE Very low-believed extirpated from the region, never collected in P electrofishing samples taken near the CWIS Erimonax Spotfin No record of occurrence in Lake Julian. monachus Chub FT, ST Very low-believed extirpated from the region, never collected in electrofishing samples taken near the CWIS Percina Blotchside FSC, No record of occurrence in Lake Julian. burtoni Logperch SE Very low-believed extirpated from the region, never collected in electrofishing samples taken near the CWIS No record of occurrence in Lake Julian. Very low—occurs in lotic habitat(riverine), never documented in Alasmidonta Appalachian FE, SE Lake Julian and host fish not documented in Lake Julian; not raveneliana Elktoe collected in recent survey of French Broad River(Alderman 201512, NatureServe 2017) No record of occurrence in Lake Julian. Epioblasma Tan Very low—occurs in lotic habitat(riverine), never documented in florentina Riffleshell FE Lake Julian and host fish not documented in Lake Julian; not walkeri collected in recent survey of French Broad River(Alderman 2015, NatureServe 2017) No record of occurrence in Lake Julian. Alasmidonta Slippershell FSC, Very low—occurs in lotic habitat(riverine), never documented in viridis Mussel SE Lake Julian and host fish not documented in Lake Julian; not collected in recent survey of French Broad River(Alderman 2015, NatureServe 2017) No record of occurrence in Lake Julian. Very low—occurs in lotic habitat(riverine), never documented in Lake Julian; not collected in recent survey of French Broad River Strophitus Cree per ST (Alderman 2015).Although host fish species(which may include undulatus p Green Sunfish, Creek Chub, Channel Catfish, Largemouth Bass, Black bullhead(Ameiurus metas),Yellow Perch(Perca flavescens), and Spotfin Shiner(Cyprinella spiloptera)exist,the general habitat of Lake Julian would be unsuitable(NatureServe 2017) *Status: FE—federal endangered, FT—federal threatened, FSC—federal species of concern, SE—state endangered, ST—state threatened. 12 Results of a 2015 mussel survey performed in the upstream and downstream vicinity of the Asheville Plant river intake structure on the French Broad River did not collected any specimens federal or state-listed mussels (Alderman 2015). Duke Energy 133 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station The following materials were reviewed to develop the species list in Table 4-6: • IPAC (httos://ecos.fws.gov/ipac/) (USFWS 2017) for the search area shown on Figure 4- 2, and • North Carolina Department of Natural and Cultural Resources (NCDNCR) Natural Heritage Program (http://www.ncnhp.orq/data/species-community-search) (topographic maps used: Skyland, NC) (NCDNCR 2017). Historical electrofishing results for Lake Julian are discussed in Section 4.1 of this report. No federally or state-listed species were collected during the historical electrofishing sampling of Lake Julian. Several factors will contribute to the protective nature of the ACC's cooling system toward aquatic species, such as closed-cycle cooling (BTA), a CWIS design and TSV below 0.5 fps, and the minimal amount of make-up water withdrawn from Lake Julian in support of the ACC units. The repurposed Lake Julian CWIS uses fixed mesh screen panels with a TSV of much less than 0.5 fps, resulting in a negligible AOI for impingement (i.e., the AOI does not extend beyond the face of the screens). Operating as a CCRS substantially reduces intake volume and is also reflected in the Rule as an impingement mortality BTA. In addition, the ACC's closed-cycle configuration will be compliant with §125.94(e)(1) for entrainment BTA for new units at existing facilities. 4.7 Documentation of Consultation with Services In preparing this response package for compliance with the Rule, there has been neither public participation, nor coordination undertaken with the Services. DEP has not submitted information to obtain incidental take exemption or authorization from the Services. 4.8 Incidental Take Exemption or Authorization from Services DEP has not submitted information to obtain incidental take exemption or authorization from the Services; nor is such an exemption necessary based on the ACC technology to be employed and the lack of any relevant species in Lake Julian. 4.9 Methods and Quality Assurance Procedures for Field Efforts Data presented in this report were compiled from DEP's historical and ongoing Environmental Monitoring Program on Lake Julian. Copies of reference documents may be made available upon request. Duke Energy I 34 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station • 4.10 Protective Measures and Stabilization Activities DEP has performed habitat improvements in Lake Julian to provide additional cover for juvenile and small fishes and to increase angling success by recreational users. During March 2010, an artificial concrete reef was constructed in approximately 25 feet of water on the north side of Lake Julian, east of the planned ACC footprint (Figure 2-2). In March 2010 and 2011, discarded Christmas trees were added to the artificial reef to improve the fishery habitat within the lake and provide additional fish attraction areas, away from the facility, for shoreline and boat anglers (Progress Energy 2013). The tree reefs are replenished on an annual basis. Additional shoreline habitat enhancement efforts (1998 and 2002) have included the felling and cabling of trees along targeted sections of shoreline (Progress Energy 2013). The design of the ACC cooling water system (i.e., use of closed-cycle cooling) and the cooling water intake (i.e., TSV less than 0.5 fps) are anticipated to minimize impingement and greatly reduce entrainment. 4.11 Fragile Species In the Rule, the EPA identifies 14 species of fish as fragile or having post-impingement survival rates of less than 30 percent. Occurrence of fragile species in Lake Julian was evaluated using historical sampling data and is summarized in Table 4-7. Table 4-7. List of Fragile Species as Defined by the EPA and their Occurrence in Lake Julian and/or the French Broad River near Asheville Combined Cycle Station ScientificOccurrence in Lake Julian in Name Common Name vicinity of ACC CWIS* Alosa pseudoharengus Alewife No Alosa sapidissima American Shad No Clupea harengus Atlantic Herring No Anchoa mitchilli Bay Anchovy No Alosa aestivalis Blueback Herring No Pomatomus saltatrix Bluefish No Poronotus triacanthus Butterfish No Dorosoma cepedianum* Gizzard Shad Yes Lutjanus griseus Grey Snapper No Alosa mediocris Hickory Shad No Brevoortia tyrannus Atlantic Menhaden No Osmerus mordax Rainbow Smelt No Etrumeus sadina Round Herring No Engraulis eurystole Silver Anchovy No *Gizzard Shad is not included on the EPA Fragile Species list; however, it is in the same family as Alewife and is documented as having a post-impingement survival rate of less than 30 percent. Duke Energy 135 Clean Water Act§316(b)Compliance Submittal EIN Asheville Combined Cycle Station Gizzard Shad was the only species from the list that has been documented in Lake Julian. • Threadfin Shad, a closely related species expected to have very low post-impingement survival, have also been documented in electrofishing surveys performed on Lake Julian. Threadfin Shad and Gizzard Shad typically exhibit a greater likelihood for entrainment and impingement at CWIS due to reproductive habits, habitat preferences, and sensitivity to temperature extremes. Mass die-offs of shad species have been documented in response to extreme winter temperatures (at or below 9°C) resulting in large collected events at CWIS (Loar et al. 1978, Griffith 2011). 9°C. Shad in Lake Julian may experience die-offs during winter months in response to the loss of thermal discharges that will occur when ACC begins operations. The facility is fully compliant with BTA alternative §125.94(e). Note however, that the repurposed CWIS has fixed mesh screen panels with a TSV substantially less than 0.5 fps and impingement is anticipated to be negligible at this facility based on the low TSV; therefore, a discussion or assessment of potential fragile species is not provided in this report. Duke Energy 136 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station 5 Cooling Water System Data [§122.21 (r)(5)] The ACC will utilize a closed-cycle circulating water system to supply cooling water to the steam surface condenser and auxiliary cooling system to remove heat from the power cycle. The circulating water system will also provide station service water(e.g., fire water and HRSG wash water). A water balance diagram showing flow distribution at the existing facility (e.g., cooling water and service water systems) is provided on Figure 5-1 and Table 5-1 presents the average annual and maximum design flows (developed by CB&I North Carolina, Inc. [CB&I]) for the ACC. 5.1 Cooling Water System Raw water pumped from the new submersible pumps at the repurposed CWIS will supply make- up water to the recirculating cooling towers and other plant needs for Units 05/06 and 07/08. Each unit will consist of a dual fuel (natural gas/fuel oil) combustion turbine combined with an HRSG that captures the exhaust heat from the combustion turbine unit, generates steam, and delivers the steam to a steam turbine to generate additional power. Each unit will also be equipped with a mechanical draft cooling tower. Each cooling tower will have five main components: 1) the fans which direct the airflow upward, 2) the heat transfer section made up of corrugated polyvinyl chloride sheets commonly called the "fill", 3) the water distribution system, 4) the drift eliminator section, and 5) the concrete basin which collects water to return to the condensers and auxiliaries. Each of the 50-foot-tall ACC towers will consist of four cells, four 200-horsepower fans (one per cell), a 3-pass drift eliminator, and will have a total circulating water flow of 65,106 gpm. Heated water from each unit's condenser cooling system will be routed to the cooling tower via circulating water piping. The heated circulating water will be cooled by the cooling tower, collected in a basin beneath the tower, and pumped back to the condenser cooling system where the cycle is repeated. The recirculating cooling water system is designed to operate at 10 COC during typical operations, meaning the circulating water constituents concentrate approximately 10 times or more during operation. The heat transferred to the circulating water in the condenser will be rejected to the atmosphere by evaporation in the cooling tower. Evaporation does not carry away solids in the water such as mud, silt, or dissolved solids; therefore, it is necessary to control the COC by continuously discharging some of the circulating water to remove waste and prevent a buildup of solids in the circulating water. This discharge, called blowdown, will be routed to the wastewater pump and discharged to the French Broad River via the existing Outfall 001. Duke Energy 137 Clean Water Act§316(b)Compliance Submittal FY Asheville Combined Cycle Station r Asheville Combined Cycle Uttralilr,,tion Service Water/fire Water Service Water Equipment Drains Lake Julian )• ). ) ........ ), Tank ) Users ) Sump 10 Loop k o Simple CoolingaaM B Makeup Unit 07/08 Raw \ Standby RO/Demm Water SuppiY / ) Trailers V TworPess Reverse Osmosis Mixed-Bed Uemineranted ) Dern.neraieer �) Water Tanks CTG NO.election> Note:Units 05/06 and 0708 are I / identical in design and layout.As such.this water balance diagram I Atmosphere represents the design layout for both Units. (Atnwwhere I( • V RAG Biowdown HRSG H Coring Tower&Basin Tank/Sump {—�� W I A W WON Treatment ) ( C15 Wash ``j Building Sump A W Water Transfer Truck / Sample Panel A Unit weTo I Unit 07/08 CoolingTo losser < Oil.Water Separator] Mr Slowdown Side-Stream Uniti ihiNen� i( Pikers CRI-Waterer Separator Sludge ThiTluckener t A ---V--Y-- Y YY /umro7roe finer redI `Audge ThirkMN .11 —...—..^ Isnd(Pal ) Waste water Sump (Shared/ ) French Broad River Outfall 001 Transfer Truck Figure 5-1.Water Balance Diagram of the Asheville CombinedCycle Station,Arden,North Carolina(Source:CBS!2018) Duke Energy 138 Clean Water Ad§316(b)Compliance Submittal Asheville Combined Cycle Station [This page intentionally left blank] Duke Energy 39 Clean Water Act§316(b)Compliance Submittal EN Asheville Combined Cycle Station J Table 5-1. Water Balance Diagram and Associated Flows under Various Design Conditions for the ACC (Source: CB&I 2018) 1 Case Name Average Annual Max Flow Design Stream# Design Flows 2 Flows 3 rt�� �� :, +CRI• ; ,an+ ,a"` "";^a*a?'�xn.w:w,'"�''�A»�' "✓�'":J a a ' A;��i MGD „�,��i MGD,� 1 Total Facility Raw Water Supply 1,980 2.85 2,816 4.05 2 Raw Water to Unit 05/06 990 1.43 1,408 2.03 3 Raw Water to Unit 07/08 990 1.43 1,408 2.03 4 Cooling Tower Make-up 919 1.32 1,126 1.62 5 Cooling Tower Blowdown 93 0.13 235 0.34 6 Cooling Tower Evaporation and Drift 841 1.21 940 1.35 7 Raw Water to Ultrafiltration Inlet 71 0.10 282 0.41 8 Raw Water to Service Water Tank 67 0.10 267 0.38 9 Ultrafiltration Reject&Strainer Backwash 4 0.01 15 0.02 10 Service Water to Users 50 0.07 50 0.07 11 Condenser Circulation Water Quench Water to HRSG 4 0.01 4 0.01 Blowdown Tank 12 Service Water to Two-Pass Reverse Osmosis Skids 17 0.02 103 0.15 13 Reverse Osmosis Permeate to Mixed Bed Demineralizer 12 0.02 75 0.11 14 Reverse Osmosis Reject 5 0.01 28 0.04 15 Demineralized Water System Make-up 12 0.02 75 0.11 16 Service Water Users to Oil Water Separator 50 0.07 50 0.07 17 Service Water to Unit 3&4 Evaporation Cooling&Cycle 0 0.00 0 0.00 Make-up 18 CTG NOx Injection Water 0 0.00 177 0.25 19 CTG Wash Water note 4 note 4 note 4 note 4 20 HRSG Make-up 11 0.02 11 0.02 21 HRSG Blowdown 5 0.01 5 0.01 22 HRSG Blowdown Tank Evaporation& Losses 2 0.00 2 0.00 23 Quenched HRSG Blowdown Sump Flow 13 0.02 13 0.02 24 Sample Panel Flow 6 0.01 6 0.01 25 Oil Water Separator Discharge Flow 50 0.07 50 0.07 26 Total Facility Waste Water to Plant Discharge 286 0.41 569 0.82 27 Side-Stream Filter Flow 1,912 2.75 1,912 2.75 28 Side-Stream Filter Backwash Flow 17 0.02 17 0.02 29 Sludge to Transfer Truck 6 0.01 6 0.01 30 Sludge Thickener Overflow 14 0.02 14 0.02 31 Side-Stream Filtrate 1,802 2.59 1,660 2.39 32 Unit 07/08 Waste Water Flow 50 0.07 50 0.07 • 33 Sludge Thickener Underflow 4 0.01 4 0.01 34 Filter Press Supernatant 1 0.00 1 0.00 Duke Energy 140 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station Case Name Average Annual Max Flow Design Stream# Design Flows 2 Flows' Stream Description GPM MGD GPM MGD 35 Water Treatment Building Sump Flow 18 0.03 29 0.04 36 Unit 07/08 Sludge Thickener Underflow 4 0.01 4 0.01 37 Unit 07/08 Sludge Filter Press Supernatant 1 0.00 1 0.00 38 Standby Demineralizer Trailer Flow 0 0.00 114 0.16 39 Unit 07/08 Cooling Tower Blowdown 93 0.13 235 0.34 Total Facility Inflow 1,980 2.85 2,816 4.06 Total Facility Evaporation, Losses, and NOx Injection 1,686 2.43 2,238 3.22 Total Facility Offsite Transfers 8 0.01 8 0.01 Total Waste Water Discharge 286 0.41 569 0.82 Total Facility Outflow 1,980 2.85 2,816 4.06 1) Flows for continued operation of existing Asheville Plant Units 1 and 2 during the commissioning process are not included in this water balance table. These values do not include fire protection system flows and service water system usage was estimated by assuming two users each at 25 GPM. 2) 58°F DB, 60%RH, Natural Gas, 10 COC 3) 86°F DB, 55%RH, Fuel Oil, 5 COC 4) CTG wash water will be appropriately managed with no direct surface water discharge 5.1 .1 Proportion of Design Flow Used in the Cooling Water System As illustrated in the water balance diagram provided on Figure 5-1, an average of 71 gpm per unit will be used for service water(see Stream #7: raw water to ultrafiltration inlet). Therefore, based on the design pumping capacity of 1,800 gpm per unit, approximately 3.9 percent of the raw water coming into ACC will be used for service water; the remaining 96.1 percent will be used for cooling purposes. Based on the anticipated AIF of 1,980 gpm (2.85 MGD) under the Average Annual Design scenario presented in Table 5-1 (CB&l 2018), approximately 7.2 percent (71 gpm x 2 units/ 1,980 gpm) of the raw water coming into ACC will be used for service water; the remaining 92.8 percent will be used for cooling purposes. 5.1 .2 Temporal Characteristics of Cooling Water System Operation The cooling water system design incorporates two operating scenarios; Average Annual Design and Maximum Flow Design (see Table 5-1). Average Annual Design assumes the ACC would operate using natural gas as the fuel source and operate the cooling towers at 10 COC. This design scenario represents typical or normal operations. The Maximum Flow Design scenario assumes the ACC would operate using fuel oil with 5 COC at the cooling towers. This operating scenario is considered to be a relatively infrequent event, for example, upon startup commissioning and during periods of natural gas curtailment. DEP will operate the ACC facility year-round with an expected annual capacity factor of greater than 75 percent. However, withdrawal volumes from Lake Julian for ACC will be significantly lower than the actual intake flows (AIF) during the previous three-year period (between January Duke Energy 141 Clean Water Act§316(b)Compliance Submittal FIN Asheville Combined Cycle Station FIN 2015 and December 2017) in support of coal fired operations at the Asheville Plant (225 MGD • at AIF versus 2.85 MGD anticipated average withdrawal for the ACC). 5.1 .3 Distribution of Water Reuse The new ACC units will not reuse cooling water as process water, reuse process water for cooling purposes, or use grey water for cooling purposes. Therefore, this subsection is not applicable to the ACC units. 5.1 .4 Description of Reductions in Total Water Withdrawals The retirement of the Asheville Plant's Units 1 and 2 and conversion to new combined cycle units utilizing a closed-cycle recirculating cooling system will result in reductions in total water withdrawals at the Lake Julian CWIS for ACC operations. Conversion of the existing once- through operations to the new combined cycle operations decreases the DIF capacity from 316.2 MGD (i.e., 2 pumps at 48,300 gpm + 2 pumps 61,500 gpm = 219,600 gpm) to 5.2 MGD (i.e., 2 pumps at 1,800 gpm = 3,600 gpm) for a net reduction of 311 MGD, or 98.4 percent. Actual withdrawals are expected to be approximately 2.85 MGD on an average annual basis, which would result in a 99 percent reduction in total water withdrawals at the CWIS. 5.1 .5 Description of Cooling Water Used in Manufacturing Process • Cooling water from the ACC will not be used in a manufacturing process, either before or after the water is used for cooling; therefore, this subsection is not applicable to the ACC. 5.1 .6 Proportion of Source Waterbody Withdrawn The Lake Julian water surface elevation is dependent on rainfall runoff, natural evaporation, seepage through the dam, and withdrawals to support plant operations. Water from the French Broad River can also be pumped to Lake Julian to support pond elevations. At the normal lake elevation of 2,161 ft msl, Lake Julian's storage capacity is 8,819 acre-feet(2,874 million gallons) (WSP 2015). To determine the proportion of water withdrawn from Lake Julian on a monthly- average basis, the estimated average withdrawal volume needed to support ACC operations was divided by the total capacity of Lake Julian at the normal lake elevation. The proportion of Lake Julian withdrawn for cooling purposes by the ACC plant is anticipated to be approximately three percent based on an anticipated AIF of 2.85 MGD. 5.2 Design and Engineering Calculations Engineering calculations of TSV for the 1-inch hexagonal mesh fixed panels and the 1/4-inch mesh fixed screen panels are provided in Appendix C. Duke Energy 142 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station • 5.3 Description of Existing Impingement and Entrainment Reduction Measures Substantial reductions in rates of impingement for the ACC compared to the existing Asheville Plant will be accomplished through a TSV of less than 0.5 fps (as discussed in section 2.3 and Appendix C). The TSV calculated for the Lake Julian CWIS for Unit 05/06 and Unit 07/08 meets the BTA standard for new units at an existing facility at§125.94(e). The ACC facility will also achieve substantial reductions in entrainment and impingement by means of flow reduction. The underlying assumption for entrainment is that entrainable organisms have limited or no motility and are conveyed passively with water entering the power plant. Therefore, reduction in flow results in a commensurate reduction in entrainmentt3. Reduction in flow will be accomplished by retiring Units 1 and 2. The design and operation of two new natural gas-fired combined cycle units is estimated to reduce the DIF at the Lake Julian CWIS (for the ACC facility) by approximately 98.4 percent (as discussed in Section 5.1.4). 5.3.1 Asheville Plant With the retirement of existing Unit 1 and Unit 2, coupled with startup of the new ACC units, the total facility DIF will be reduced by approximately 98.4 percent (from 316.2 MGD to 5.2 MGD). This should result in a commensurate reduction in the potential entrainment and impingement associated with the facility. 5.3.2 The ACC The new ACC will be compliant with §125.94(e) BTA standards for impingement mortality and entrainment for new units at existing facilities by installing mechanical draft cooling towers which will reduce the DIF for the new unit to a level commensurate with a CCRS. The ACC will employ the following supplemental measures to reduce impingement mortality and entrainment at the CWIS on Lake Julian: • TSV (provided in Section 2.3) at the Lake Julian CWIS will be substantially less than 0.5 fps. • Because the expected AIF (2.85 MGD) at the Lake Julian CWIS represents a greater than 95 percent reduction in withdrawal rates and the facility-induced TSV at the intake will be less than 0.5 fps (regulatory threshold), the AOI for the Lake Julian CWIS's will not extend beyond the surface of the intake screens. • The ACC will employ a closed-cycle recirculating cooling water system by utilizing wet mechanical draft cooling towers designed to reduce make-up water requirements. While the number of COCs can change depending on operational conditions, an estimated 10 COC will provide a flow reduction of 98.4 percent compared to a once-through system. Since reductions in impingement and entrainment can be assumed to be commensurate 13 This is the underlying assumption in EPA's calculation of entrainment reduction associated with closed-cycle cooling —see EPA 2014. Duke Energy 143 Clean Water Act§316(b)Compliance Submittal L1� Asheville Combined Cycle Station rJ with reductions in flow, it is assumed that the use of closed-cycle cooling at the ACC will reduce potential impingement and entrainment by 98.4 percent. In addition to the design aspects and expected operations of the ACC facility, the following are • also important considerations in determining BTA standards for impingement mortality and entrainment: • The ACC will withdraw water from Lake Julian; a cooling pond (impoundment) permitted and constructed in part on WOTUS for the purpose of providing cooling for electric generation (North Carolina State Board of Health 1963)(see Appendix A). All of the species identified as potentially subject to entrainment are common to the region. • The species found to have a higher likelihood of entrainment at Lake Julian (Threadfin Shad and Gizzard Shad) comprise a low relative abundance of fish sampled through electrofishing surveys (between 0 and 7.7 percent). As described in Section 4.2, electrofishing studies indicate Lake Julian exhibits a balanced fish community. This suggests Lake Julian contains a sufficient foundation of reproduction, recruitment, and mortality for sustainable predator populations and prey base. Further, Lake Julian supports an active recreational fishery. • No federally listed fish species or critical habitat designations exist within Lake Julian near the CWIS (USFWS 2017). As outlined above and in the section that follows, the design and operations of the ACC facility will employ measures to minimize impingement mortality and entrainment such that no additional control measures are considered necessary. 5.3.3 Best Technology Available for Entrainment Although the ACC closed-cycle cooling system will be compliance with the BTA requirement for new units at an existing facility (§125.94(e)), the following information is provided to support the conclusion that the retirement of the existing Asheville Plant and operation of the new ACC units will result in the maximum reduction in entrainment warranted. The number of organisms expected to be entrained is low. Since entrainment is proportional to flow, reductions in flow equate to commensurate reductions in entrainment. The retirement of Units 1 and 2 reduced the DIF by 98.4 percent (from 316.2 MGD to 5.2 MGD). As a result of the proposed flow-reduction measures, AIF is expected to be approximately 2.85 MGD at the ACC. No federally or state-protected species were collected in previous electrofishing sampling on Lake Julian. In addition, according to the USFWS IPAC database, there are neither protected species nor critical habitat designations for Lake Julian (USFWS 2017). Duke Energy 144 Clean Water Act§316(b)Compliance Submittal FOR Asheville Combined Cycle Station r 6 Chosen Method(s) of Compliance with Impingement Mortality Standard [§122.21 (r)(6)] The new ACC units will be equipped with a CCRS in the form of cooling towers. A closed-cycle recirculating system satisfies the impingement mortality and entrainment BTA standards for new units at§125.94(e). 6.1 Design TSV It is recognized by the EPA that an intake TSV of 0.5 fps or less establishes a threshold based on the assumption that, at velocities below this value, most healthy impingeable-sized fishes will be able to swim freely and avoid impingement. . The ACC cooling tower make-up water will be withdrawn at the repurposed Lake Julian CWIS, which is comprised of four identical intake bays. Each bay will be equipped with a new (replacement for historic) submersible pump with a design capacity of approximately 1,800 gallons per minute (gpm) (2.6 MGD). The ACC units are designed to operate with two pumps (the remaining two pumps provide redundant pumping capacity). As a result, the combined DIF capacity for the new ACC units is 3,600 gpm (5.2 MGD). The average design TSV based on the existing hexagonal mesh screens is between 0.034 fps (at normal water surface elevation) and 0.039 fps (at low water surface elevation). The average design TSV based on the new 1/4-inch mesh screens is 0.043 fps (at normal water surface elevation) and 0.049 fps (at low water surface elevation). At DIF the average TSV for the hexagonal mesh screens at the front of the CWIS and the new '/4-inch mesh screens (to be located inside of the CWIS) for both units (at normal or low water surface elevations) is considerably lower than the 0.5 fps threshold established by the Rule. As such, the impingement AOI at the ACC is negligible because the area over which the intake-induced velocity is greater than 0.5 fps does not extend beyond the face of the screens. The ACC design TSV (which is substantially lower than the 0.5 fps threshold established for impingement BTA) would protect greater than 96 percent of fish from impingement at the CWIS on Lake Julian. 6.2 Requirements of Make-up Water Minimization for Closed-Cycle Recirculating System According to the Rule at §125.92, a CCRS is "...designed and properly operated using minimized make-up and blowdown flows withdrawn from a water of the United States to support contact or non-contact cooling uses within a facility...". A CCRS withdraws significantly less water from its source water body than a once-through cooling system. The actual reduction in withdrawal volume depends on the design and operation of the recirculating cooling system. The site-specific design and operating parameters of the closed-cycle cooling system at ACC are presented in Table 6-1. Duke Energy 145 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station Table 6-1. Site-Specific Design of ACC Closed-Cycle Cooling System (CB&l 2018) Design and Operational Parameters Values Condenser cooling water flow and The cooling towers for ACC are designed to cool 65,106 gpm condenser temperature rise (i.e., delta T) with a temperature range of 17.7° Fahrenheit(°F) (-7.94°C). COC at which the cooling tower is The circulating water system is currently expected to operate typically operated at 10 COC. Drift eliminator efficiency Drift loss (% of cooling water flow) is estimated to be 0.0005 percent. The design MW rating of ACC is 560 MW(2 power blocks at MW rating of ACC generating blocks 280 MW each). The summer/winter net electrical generating capacity of each block is estimated at 250 MW/280 MW. Evaporation, drift, and blowdown rates are compiled and summed to determine volume of make-up water withdrawn at the CWIS: Make-up flow = Evaporation (E) + Drift (D) + Blowdown (B) where: E = 0.0008 x Condenser temperature delta T (°F) x Condenser CW flow rate (gpm) D = Drift eliminator efficiency x Condenser cooling water flow (gpm) B = [E-{(COC-1) x D}]/(COC-1) Then, make-up flow is compared with condenser cooling water flow (i.e., once-through flow) to determine the degree of flow reduction. Using the cooling tower flow of 65,106 gpm, delta T of 17.7°F (-7.94°C), drift eliminator efficiency of 0.0005 percent and 10 COC (CB&I 2018), the calculations for evaporation, drift, and blowdown rates are as follows: E = 0.0008 x 17.7°F x 65,106 gpm = 921.9 gpm D = 0.0005 x 65,106 gpm = 32.6 gpm B = [921.9 —{(10-1) x 32.6}]/(10-1) = 69.8 gpm Make-up Flow for 10 COC = 921.9 + 32.6 + 69.8 = 1,024.3 gpm Therefore, the calculated total ACC make-up water flow14 for 10 COC is 1,024.3 gpm (1.48 MGD). As a result, the percent flow reduction compared to a once-through cooling system is 98.4 percent ([65,106-1,024.3]/65,106 X 100). DEP anticipates that the make-up water flow to the cooling towers installed at ACC will be minimized to the maximum extent possible within the constraints of practicality, scaling, other operational issues, and the need to comply with NPDES discharge limits. 14 Based on CB&I Document No.ACC00-SP-M-CW-01; represents the total designed capacity for the cooling towers. Duke Energy 146 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station 7 Entrainment Performance Studies [40 CFR § 122.21 (r)(7)] 7. 1 Site-Specific Studies Site-specific entrainment has not been evaluated for the new ACC units as they have not commenced operation. Site-specific studies are neither required by the Rule nor relevant to the ACC because the facility meets the entrainment BTA standards for new units. 7.2 Studies Conducted at Other Locations As of the date of this report, no entrainment performance studies conducted at other facilities have been determined relevant for documentation in this section. Duke Energy I 47 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station 8 Operational Status [§122.21 (r)(8)] The existing Asheville Plant Units 1 and 2 are scheduled for decommissioning and demolition. • The construction and commissioning of the ACC is scheduled for completion by November 2019. 8. 1 Asheville Plant Units 1 -4 Asheville Plant coal-fired Units 1 and 2 were commissioned in 1964 and 1971, respectively and are 54 and 47 years old, respectively. Units 1 and 2 will be retired following the completion of the new ACC. Asheville Units 3 and 4 consist of 324 MW GE 7FA simple-cycle combustion turbines constructed in 1999 and 2000. These combustion turbine units use compressed air to supplement the power supply when electricity demands are highest. Units 3 and 4 will continue to operate as required to meet electrical demand. The operation of Units 3 and 4 do not result in cooling water withdrawals. 8.2 ACC Units 5-8 ACC Unit 05/06 and Unit 07/08 are currently under construction with an anticipated completion of construction and commissioning by November 2019. Units 05 and 07 are natural gas/fuel oil combustion turbines, which generate heat that will be captured and delivered to steam turbines, Units 06 and 08. 8.3 Major Upgrades in Last 15 Years The ACC represents a new unit at an existing facility. No major upgrades have been completed that would be applicable to the ACC or its operations. 8.4 Descriptions of Consultation with Nuclear Regulatory Commission Neither the ACC nor the existing Asheville Plant units are nuclear facilities; therefore, consultation with the U.S. Nuclear Regulatory Commission is not required and was not initiated. 8.5 Other Cooling Water Uses for Process Units The ACC will not use cooling water for process units; therefore, this subsection is not applicable. 8.6 Description of Current and Future Production Schedules The ACC is not a manufacturing facility; therefore, this subsection is not applicable. Duke Energy 148 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station 8.7 Description of Plans or Schedules for New Units Planned within 5 years A 186-MW, natural gas-fueled simple cycle F-frame combustion turbine may be added to the ACC facility around 2023 (DEP 2015) depending on energy reduction efforts, technology advancements, and peak load demand in the region. In response to growing customer demand for renewable generation, other plans for the ACC include the addition of solar generation, which would be installed on a portion of the land made available after the decommissioning of the 1964 Ash Basin (refer to Figure 1-1 for location). No additional water withdrawals are anticipated for the future plans of the ACC facility. Duke Energy 149 Clean Water Act§316(b)Compliance Submittal L11 Asheville Combined Cycle Station rJ` 9 New Units [§122.21 (r)(14)] The new ACC Units 05/06 and 07/08 are considered new units at an existing facility (as defined at §125.92(u)); therefore, the ACC is required to be compliant with the impingement mortality and entrainment BTA standards under §125.94(e) of the Rule. 9.1 BTA Standards for Impingement Mortality and Entrainment for New Units at Existing Facilities Under§125.94(e) of the Rule, a new unit at an existing facility must achieve the impingement mortality and entrainment standards provided in either paragraph (e)(1) or(2). Under requirements of§125.94(e)(1), the new unit must reduce DIF, at a minimum, to a level commensurate with a CCRS. The new ACC units will use closed-cycle cooling systems that meet the definition of§125.92(c) and comply with §125.94(e)(1). Further, the TSV at DIF for the repurposed CWIS, based on the anticipated operations of ACC, is substantially less than 0.5 fps of the Rule. While the number of COCs can change depending on the operating conditions, the cooling towers will generally be operated at 10 COC and will provide a flow reduction of at least 98.4 percent from the withdrawals required under the existing once-through system. Since reductions in impingement and entrainment can be assumed to be commensurate with reductions in flow, the retirement of the existing coal units and commencement of closed-cycle cooling at the ACC is assumed to reduce potential impingement and entrainment by at least 98.4 percent. Calculations of COC will be performed to document the minimization of make-up water to the closed-cycle recirculating cooling water system. Duke Energy 150 Clean Water Act§316(b)Compliance Submittal 1j Asheville Combined Cycle Station 10 References Alderman Environmental Services, Inc. (Alderman). 2015. French Broad River Mussel Surveys. Prepared for Duke Energy. September 22, 2015. Brierley, A. 2014. Diel vertical migration. Current Biology, Volume 24, Issue 22: R1074-R1076. November 2014. Carlander, K.D. 1977. Handbook of Freshwater Fishery Biology. Vol. 2. The Iowa State University Press, Ames, IA. 431 pp. Carolina Power and Light (CP&L). 2001. Asheville Steam Electric Plant, 2000 Environmental Monitoring Report. Environmental Services Section, Progress Energy Company. New Hill, North Carolina. June 2001. CB&I North Carolina, Inc (CB&I). 2018. Asheville Combined Cycle Project, Document No.: ACC00-ME-M-WB-01. Prepared for. Duke Energy Progress, LLC. Cornish, M. and K. Welke. 2004. Bluegill (Lepomis macrochirus). In: Pitlo, J.M. Jr. and J.L. Rasmussen (eds.). UMRRC Fisheries Compendium. 3rd Edition. Upper Mississippi River Conservation Committee. Rock Island, Illinois. January 2004. p. 177-180. Duke Energy Progress, LLC (DEP). 2005. §316(b) Supplement to NPDES Permit NC000396 Reissuance Application Package, submitted to NC Division of Water Quality, 2005. . 2007. Asheville Steam Electric Plant, NPDES Permit Renewal Application Package, submitted to NC Division of Water Quality, 2007. . 2015. Clean Water Act§316(b) Strategic Plan-Asheville Steam Station. . 2017a. North Carolina Integrated Resource Plan, September 1, 2017. . 2017b. Unpublished data from Environmental Monitoring Program on Lake Julian and the French Broad River, electrofishing data 2015 and 2016. Ehrlich, K. F. 1974. Chemical changes during growth and starvation of herring larvae. Pages 301-323 in J. H. S. Blaxter, editor. The early life history of fish. Springer-Verlag, New York. Electric Power Research Institute (EPRI). 2004. Using Computational Fluid Dynamics Techniques to Define the Hydraulic Zone of Influence of Cooling Water Intake Structure. 1005528. EPRI, Palo Alto, CA. . 2007. Cooling Water Intake Structure Area-of-Influence Evaluations for Ohio River Ecological Research Program Facilities. 1015322. EPRI, Palo Alto, CA. Emig, J.W. 1966. Largemouth bass. In: A. Calhoun (ed.). Inland Fisheries Management. State of California, Department of Fish and Game. Etnier, D. and W. Starnes. 1993. The Fishes of Tennessee. Knoxville: The University of • Tennessee Press. 1993. Duke Energy 151 Clean Water Act§316(b)Compliance Submittal FIN Asheville Combined Cycle Station Gebhart, G. E., and R.C. Summerfelt. 1978. Seasonal Growth of Fishes in Relation to Conditions Of Lake Stratification. "Oklahoma Cooperative Fishery Research Unit 58 (1978): 6-10. Oklahoma State University, Stillwater, Oklahoma. Golder Associates. 2005. Crystal River Energy Complex Proposal for Information Collection. NPDES Permit No. FL0000159. Prepared for Progress Energy. Griffith, G.E., J.M. Omemik, J.A. Comstock, M.P. Schafale, W.H. McNab, D.R. Lenat, D.R. and T.F. MacPherson. 2002. Ecoregions of North Carolina. U.S. Environmental Protection Agency, Corvallis, Oregon. (map scale 1:1,500,000). Griffith, J.S. 2011. Effects of Low Temperature on the Survival and Behavior of Threadfin Shad, Dorosoma petenense. Transactions of the American Fisheries Society, Vol. 107 (1). Heidinger, R.C. 1975. Life history and biology of the Largemouth Bass. Pages 11-20 In: R.H. Stroud and H. Clepper (eds.). Black Bass Biology and Management. Sport Fishing Institute, Washington, D.C. Hunter, J.R. 1963. The Reproductive Behavior of the Green Sunfish, Lepomis cyanellus. Zoological 48(1): 13-24. Loar, J.M., J.S. Griffith, and K.D. Kumar. 1978. An analysis of factors influencing the impingement of threadfin shad at power plants in the southeastern United States. Pages 245-255 in L.D. Jensen, editor. Fourth national workshop on entrainment and • impingement. EA Communications, Melville, New York. Leonard, P.M., and D.J. Orth. 1988. Use of habitat guilds of fishes to determine instream flow requirements. North American Journal of Fisheries Management 8:399-409. May, R. C. 1974. Larval mortality in marine fishes and the critical period concept. Pages 3-19 in J. H.S. Blaxter, editor. The early life history of fish. Springer-Verlag, New York. Mehner, T. 2012. Diel vertical migration of freshwater fishes— proximate triggers, ultimate causes and research perspectives. Freshwater Biology, 57: 1342-1359. Miller, R.R. 1960. Systematics and biology of the gizzard shad (Dorosoma cepedianum) and related fishes. U.S. Fish and Wildlife Service, Bulletin 60: 371-392. Miller, T.J., Crowder, L.B., Rice, J.A., Marshall, E.A. 1988. Larval size and recruitment mechanisms in fishes: toward a conceptual framework. Canadian Journal of Fisheries and Aquatic Sciences 45:1657-1670 p. NatureServe. 2017. NatureServe Explorer: An online encyclopedia of life [web application]. Version 7.1. NatureServe, Arlington, Virginia. Accessed: October 2, 2017. http://www.natureserve.orq/. North Carolina Department of Environmental Quality (NCDEQ). 2017. French Broad River Basin Documents. Accessed March 6, 2017. https://deq.nc.gov/about/divisions/mitiqation- services/dms-planning/watershed-planning-documents/french-broad-river-basin. Duke Energy 152 Clean Water Act§316(b)Compliance Submittal FI Asheville Combined Cycle Station r . 2018. Water Withdrawal and Transfer Registration Annual Water Use Reports. Accessed August 7, 2018. http://www.ncwater.orq/Permits and Registration/Water Withdrawal and Transfer Re qistration/report. North Carolina Department of Natural and Cultural Resources (NCDNCR). 2017. North Carolina Natural Heritage Program. Accessed January 17, 2017. North Carolina State Board of Health. 1963. Permit for Impounding and Maintenance of Impounded Water, North Carolina State Board of Health, Sanitary Engineering Division. Raleigh, North Carolina. July 12, 1963. Page, L.M. and B.M. Burr. 2011. A field guide to freshwater fishes of North America north of Mexico. Boston : Houghton Mifflin Harcourt. Pflieger, W.L. 1997. The Fishes of Missouri. Missouri Department of Conservation, Jefferson City, MO. 372 pp. Pitlo, J., D. Dieterman, and G. Jones. 2004. Largemouth bass (Micropterus salmoides). In: Pitlo, J.M. Jr. and J.L. Rasmussen (eds.). UMRRC Fisheries Compendium. 3rd Edition. Upper Mississippi River Conservation Committee. Rock Island, Illinois. January 2004. pp. 169- 173. Progress Energy Carolinas, Inc. (Progress Energy). 2010. NPDES Permit Renewal Request Asheville Steam Electric Plant. Permit Number: NC0000396—Attachment#2. 2013. Asheville Steam Electric Plant, 2010-2011. Environmental Monitoring Report. Water and Natural Resources Section Environmental Services Department, Progress Energy Carolinas, Inc. New Hill, North Carolina. April 2013. Rohde, F.C., R.G. Arndt, D.L. Lindquist, and J.F. Parnell. 1994. Freshwater Fishes of the Carolinas, Virginia, Maryland, & Delaware. The University of North Carolina Press. Chapel Hill, NC. 222 pp. Rohde, F. C., R. G. Arndt, J. W. Foltz, and J. W. Quattro. 2009. Freshwater Fishes of South Carolina. University of South Carolina Press, Columbia, SC. 430 pp. Spotte, S. 2007. Bluegills: Biology and Behavior. American Fisheries Society, Bethesda, Maryland. 214 pp. Tomelleri, J.R. and M.E. Eberle. 1990. Fishes of the Central United States. University Press of Kansas. Kansas. U.S. Environmental Protection Agency (EPA). 2014. Technical Development Document for the Final Section 316(b) Existing Facilities Rule. EPA-821-R-14-002. Washington, DC. U.S. Fish and Wildlife Service (USFWS). 2017. Information for Planning and Conservation Data Search. Accessed October 1, 2017. https://ecos.fws.gov/ipac/user/login. Wiegel, Robert L. 1964. Oceanographic Engineering, Prentice-Hall, Inc. Englewood Cliffs, NJ. WSP. 2015. Bathymetric Survey Asheville Cooling Lake (Lake Julian). Arden, NC. Duke Energy 153 Clean Water Act§316(b)Compliance Submittal En Asheville Combined Cycle Station r A Appendix A Permit for Impounding and Maintenance of Impounded Water Issued in 1963 C MEMOCRS XC .'':'i t CA:.v_; CHARLES R CUCG_ M. D., PnCn. F.ALLICK :OHN R. CCNZ t, !d.7-•V1CC.PRC>f. WINSTON:.ALCM �,. A. ! .r►. '1 t .�.. T • L. ED'.VAROS. D.O.G. .. •. . WASNINtTON �` lr�i.. ..% �/ a ... Mn J. E. LATTA MILLcnon7, RT I LEN.OX D. DAK=R, M.D. DunNAM t,i, .. !l ROGER W. MORRISON. M.D. . . A ILLC • \'' ' .. __ •• EARL W. CRIAN, b..D. . RAtCICN F'ir.LriC:'{ JASPER C, JACKSON. P4. C. . . LUMUCR:ON GEN W. DAWSEY. D,V.Lt. . GASTOhIA J W A. NORTO\. t-: 6. AS PH. :T'TL K.A4 n CIr,CCTOR Ahs SCCRCTARY.1 RCASuw:n t'• 1 v 1 2, 1 .. I7A7C KCALTn niRCCTon (Pcn d No. 1?, County E�cc,'oo Dear Sir: Enclosed ?s your UPerrit for impounding and :aa?n_'us- T3 Ince o= T:no'L^_ded 1.7ata_ tt with a copy of your applica- tion attached& Very truly yours j / Charles M0 White, Chief insect and Rodent Control Section Sanitary Engineering Division Enclosures CC: Health Officer CC: Soil Conservztiorist c C. ir.ctr3' tions for Izreparation of Appli tion For Approval of Plano end isseanee of "Certificate of .';rival" or "Pe-emit" 1. Application must be made in duplicate on this form. Failure to ' do so, or to fill in c:.':nr•l:?tel:e ._il blank spaces and f:,.rniah all in- formation regi ir-d will dela;, tho e:-•amination and approval of the plans and the issuance of a 'Certificate of Approval" or "Per.9it". 2. The application Lust be signed by the Mayor or City Manager of a municipalit7-, the Cheirm7n of a z:ritary district board, the owner or proper officials of a corporation, or the legally constituted board or commission having charge of the proposed works. The signature of the designing engineer or other agent will be accepted only if accompanied by a letter of authorization. 3. Plans, sp' cif tcations and other supporting data must be_-submitted-•---- ' in.duoliaate in accordance with the Rules and 'ste al .tions of the Com- mittee .regarding the preparation and submission of same. 4. The Committee will expedite the studs and review of all applica- tions and plans relating to proposed pallu ion_aba.temart projects as rapidly as rossic_c; however, the applicant shvrld allot: a period of at least 30 days for .. :?ch study and- revieri after all documents have been furiiiJheti. The applicant should take into account this period of delay when scheduling other action, such as s.ivertising and receiving • bids, aw .rdi:;g ccntrecte.ei d bei;•i,ra.'.ing construction of the proposed works. • C \\Pond No. 13 .-. North Carolina State 3oard of Health Sanitary _nsineering Division Raleigh, North Carolina PERMIT FOR IMPOUNDING AND MAINTENANCE OF IMPOUNDED WATER Issued to: Name Carolina Power ? LigLt Conpa.ny Address -1,1 ci�'h i.or a Carol: a The construction of an im ou_ded water project, described in an an- Junolication for a permit to impound water dated_ i , 1963 having been completed in accordance with the requirements of the N. C. ;:v,* .. Board of Health, this permit for impounding and maintenance of impounded water is issued this day of y , 196 3 Section P. of Regulation No. 32 of the Regulations of the N. C. State Board of Health Governing the Control of Communicable Diseases, a copy of which is attached and forms a part of this permit, shall be observed ex cent provisions thcr.:oi as may be specifically waived in writing. This permit shall remain in force so long as the holders thereof maintain the impounded water in a condition which does not render it a menace to the public health. J. W. R. Norton, N. D. State Health Director • By i" Charles M. White, Chief Insect and Podc;it Control Section Sanitary Engineering Division ,r° APTh?CI i"E TS 7-Y ;,7E i'.i L i'_" :1't' To be s bm.itte:i in yltr.ipli;tc ',;c: North Car,:].;_na State B .rd of Hcalth Sanitary Ln!3incc'rir.g Division "s l eirh, I'or tir Carolina (a) To imnoand anter For - -]=._nd. :s. (b) To raise the level of an existing pond 1, County i uncombe Township Limestone 2; Location in relation to two or more well-kncton lcndt;arks: Lake is locat-d on Ioke11 Creek 2000 feet upstream of confluence with French Bror.:i F'ive.r anac::?:.. s urc ri - i.noroximately 1 1e to a point adjacent to Tii-rhwav U.S. 29. 3, Pe;snn nuking, oprlicatior as owner Caroline, Pnwer T,ictt Company Ii. A 1.reas rf c rrrr .. Caroli 7. Purpose of the pr'`jcct i, a for tl l l `lric t.tio`: 6. Approximate n'.mibr of persons l:virlx; Within on :Wile of f,.� proposed res- ervoir or pon l 7. kpprnxi:ratc area to Le cover'' 'ry rc scrroirM._ 320 acres 8. Uiarc f;er cf Irai n 1t bt.ttvm of dam :o faci]iti el for ful]v empty' h 9. U::scri:t,ir. c.f :c.vice for fluct.atirlr water 1c:vcl 1000' wide uncontrolled spillway with creta et no water e1° v. 2160' p',is 36" concr•ete_i.pe e_r'a in with in,' 1 10. ►5i11 stiff c:irn� t" :no be :w3liable fr'r .' aintaini.ri? ponq after it poundage so that it will not i rodh.',ce T?c:,q'ti`,r es? 11. Date ;when it is dcsircci to start co :stcuctiott Actually started nay 1962 12. u'te when it is •.I�s_.red to impound water Ac'. :'illy started April 1, 1963 In naki n" 't.ti s al.plielLicn) 1 3 ,rcL to cvinr.ly w?to t4ie reuia4icn povc.rnin imroandld Crater a-:a so 'r-tintain trio pt:ii that it will not produce mosquitoes and thcr by become a n.i: once :i in erc'.ts t_ U::e r. blic health. Place Ralei h, Nori.h Carolina Date June 12, 1963 Car40a.2Xwer & Light Company nature 76.:41.•••C-/,%!1/..'-5{f E::ecutive Vice President ,.._ • 3. i : B . 1 ,SL� 0 Sfit, B \ 1 (' L' S •;N I ti r n B I' ri a A c E n • ENGINEERS • CONSTRUCTORS - MANAGEMENT CONSULTANTS TWO RECTOR STREET NLt`, iUith b Cwb5CC:' Carotin_.' Power ...• Lio"b C4mpany P 0 o:: 1551 Ra1eit,h, :tionth C�:rolirc CAROLI;,., PC7....R ?' L1027' CL + a_11r S?iLTl" IDE S .''i:_: C0UL' ,s Sear Colby: : .m ncicoc art four copies of the o.pol'?cation for permit to l n,.e to be S'fc ._ttc'a to the North Carolina "'7 3f Also e::e. 'r .... are U_`=.. ':'. T. ... ..z o dr .r.i-_ t. .l �' with aheS`. ». L.tI' aa.. .. r�».J�r LLe ^L.`:.r:: ioo ana of • '.. re have -..isellosed this rl^ztte. ._with . T Ch?r1es t Y� 1Lt e,yChief of R.Dclen . Cor Ses i� ofDiv rjon. o the he ...f.. .,.:>e•2 .,_. M it 111 _... :ti:-,_,__._ to E,ub.';it Ftr a... ti-...... ..-� ,.t.. ..L._...5, U:.....0 ...L«la s.+ he ..<... ...,..... yr...6::.LE.'.°.... l Ver: truly o,.xs, H W Chief Co c C:'•._ 'F,ydraulie Ln,ineer Fly 01'6' `rA cc: # Fuson 0 i � J Jones n .a !'. J E C ,W r/a Pu1ito/\ Cher L C Ya z/C E Dyer/P R Lo}as o T C Aoyt/J F ;L..,..11/V S E "i .:vuber/0 D lies/J A Scarola 'a H '-tern NORTH CAROLINA !DEPARTMENT OF WATER RESOURL ..4 STATE STREAM SANITATION COMMITTEE i7RALEIGH RALEIGH t dr t`4 1 X1 I1 1 January 2, I963 Yr. E. B. Hebinson Vice President &rtd General Manager Carolina rower 1 L c;uht Company ._.�..�.. Raleigh, :"oath Co.e.Ai.na Tp) Subjects Permit/ o. 260 Carolila Power & Lam: u Company SkylLnd Steaa,cleotrio Plant Eunoo:�D'e v-ity, North Galina v Dear Ni'. Robinson: Iii accordance with your application dated October 16, 1962, we are forwrding• herewith Permit i.e. 260, d.at.:3 Sane.=ary 2, 1962, to Caro- lina. Power Light Company, Steam :.i:.eotrio Plant, authorizing the construction of a 330-nose cooling pond for Unit ro. 1 for an c ti- m^tell a7cr..Go daily flow of 3.0 ii.G.D., ani. the diioh.l.rge of the efflu- ent into ro:rell Creek, a tributary in the _`Tench Broad River twain. This Permit shall bo effective from the d7te of issuance until modified or rove ¢.ur uant to ('•. S. 143-215.1 and shall be subject to the cohlitionlimitations as specified. therein. ;.e co:apleta sets of the approved plans are being returned to you. Sincerely yours, ;Is 7 V 1 „.0 7. C. .usbard, 1%ireo uor Division of Stream bauitc,tion ea Hydrology • closure cotMr. s. A. J. S?:a 1e✓r • • Mr. C. P. Rouse Nr. t.. E. i o"iorio ] t NORTH CAROLINA ,r► t'j STATE STREAM SANITATION COti`�ITTEE di c?'rRaleigh . �r � 1•¢" PERMIT Far the Discharge -of Sewage, I duatrial "astas and Other Wastes In accordance with tho provisions of Article 21 of Chapter 143, General Statutes of horth Carolina as amended, and other applicable Laws, Rules, and Regulations, PERMISSION IS HEREBY GRANTED TO Carolina Power a Light Company Skyland Steam .lectrio Plant Buncombe Counter, 'NIorth Carolina FOR THE oonstruotion of a 330-acre cooling pond for Unit No. 1 for an estimated average daily flow of 3.0 M.G.D., and the discharge of the effluent into Powell Creek, a tributa.y in the French Broad River :Bae in, in accordance with the application dn.tod uotaber 16. 1362 ,, and in conformity with the plans and, other supporting Oata, all of w .ich are filed with the State Stream Sanitation Committee, and are considered a part of this Permit. This Permit shall bs effective from the date of its issuance until modified or re- . vo ad pursuant to C. S. 143-215.11 and snail be subject to the following specified . conditions and limitations' 1. This Permit shall become void unless the facilities are oon- _ struated in accordance with the approved plans, e1ecificatiome, and other supporting data and are completed and placed in opera- tion on or before aly 1, 1;7-4_, or aa this date may be amended by t_:e State Stream sanitation Coamittee. 2. Thio Permit is effective only with respect to the nature and volume of waste <; coolingwater ecoriaed in the application and other supporting data for 'Unit ?.o. 1. 3. The cooling pond shall be prorerly operated and ,:maintained in such a manner as to effect overall reduetiona in thermal pol- lution substantially in keeping with thn e indicated in the sup- porting data submitted with the application and to produce an overflow spillage of such quality as to trotoat the receiving stream in accordance with tho assigned olcesiuication and water quality standards. Permit issued this the 2nd day of 1511. w . n Si7ned �. C. i.0 ivard, .7tcrota1y State atrsam Sanitation Committee Permit No. 60 NORTH Ce,lt0 ". wTnTc: SlitSAII Si,:.Ir., fi4 :(i".'..�T..'.l': STATE DEele:Tie.N:i OF :lei-a :1;..;0URCES 1t P. O. 30X 9392 r� RALEIGH �� � . �>Wr APPLICATION FOR liFltl+�lnla OF ?Ecol; AND ISSII,;CIC: OF "CERTIFICATE OF APPROVAL" OR "PERM" ,,re TO tp DISC;iARGE SE'•1AG3, INDUSTRIAL '.!A`Si' $ OR TREATMENT ?L.,2iT . ' EFFLUENTS MO TIG; 1i'TtlU OF THS STATE c October 16, .19 62 To: The State Stream Sanitation Committee Raleigh, Norte Carolina Gentlemen: In accordance with the provisions of Article 21 of Chapter 143, General Statutes of Perth Carolina (Chapter 606, Session Laws of 1951), application is hereby rade by an officer of the Cirolina Power & Light Company, 'Name of board, individual or others) (Same of city, village, town, A Public S rviec Corporeticn , in the county of Wake , to the State ' sanitary district or eetabliahaent) (!Iare of county) Streen Sanitation Committee for approval o.' the accomrennying plans, opecifications and other data ssbaitted herewith covering a 330 acre cooling pond for the proposed _ 19C 1"d unit a; the Ccapany's new Skyland Steam Electric •&tat•}ea in Buncomb Coun'y. W.;er use data is shown in the accorpar{ing Exhibit "A". and for a "Certificate of Approval" and/or "Permit" for the discharge of setra:'o, Heated water from the Condenser for serving . industrial waste or combinations) (sewers or treatment plant) Unit No. 1 of the Skyland Plant into Ssrface t (Neee of meeicipelity, 'nctitution, or indisLry, etc.f Teurface o.• ground .rate . waters of Powell Creek__ ___ _ _ ._ (:lane of water course if surface :raters; if ground watera, state waxer at S3850; W7900 (Plant Coord_5vete _____^ course to wuich they are tributary) (Exact location of mint of discins__a The plans for the proposed works have been prepared by Ebanco Sic Sneerp'r ed • ( naineering 'ire) of 2 Rrctor St, New York 6. NIt in estimat^d that treatment worka will provide (address) r', adequate capacity to serve tho Skyland Steam ElectriceStet•ftrn for a (City, town, eanit.ary district or establishment) period of `;r) years, at 'which time it is estir.::ted the average drily,, ewaye,Or waste flow will not exceed 3,eee,0e0 eedlone. It is further expected that the treatment works will effect overall reductions in pollution an follow: B.O.D. (5-day 20°C A °o, etteren cd colitis A /, total solids P _, coliform bacteria A % and toxic materials * A '4. The cost of the eropased works is estimated to be: sewers S A , pumping stations S A , treatment plant S A , others $ A . The works will be completed and in operation on or before f May 1, 1964 . The applicant hereby nerees that the proposed works will be constructed in strict accordance with tie, approved plans earl a 'ecificationa or auh^e.lunntly approved c:ren.;o: therein and further ngroes to ?dace its operation under the care of a competent perste . and to maintein and operate the plant accordin, to the best accepted practice and in accordance wit:: the plans and opecificatione approved by the Committee. j Signature . Title Mailing address * Specify ecreentngn reinn/inn far nar'h toxic n+:hntence, tieing cE!ditional sheet, if nocennary. A Not applicable f ($ w L ,, inr*:ru'tinus on reverse aid:) qtr r �r • `'. ;r [ 13 \ SL' {:i sI1, [� \ ICES ' .-.t•Nf✓ I . rnitI' 0 [t .% tI: 11 ENGINEERS - CONSTRUCTERS - MANAGEMENT CONSULTANTS nr.crou '.;TNI"ET • •1._ i _ : . :. P 0Box 15; S Dear Colby: fox.: cop:c5 of ...3 appliesti:R for permit to to to s....:'4tC:1 ;;o the iTorth Cerolsha _r G Z:_.:C e .......... • V r ... w�. . .. - �..._ . r.... r..r. _ _ .__� :4�Jr". J.. v.:3i1 4L:: Io catio.. of . .:: have iic^.:.s'r_ this : i.`er 'ith ::r Charles i i ..:i1t:e, Chief of Divl.s4.c:Z o. T.Lo . . r f ... .1.. .. _.'�:':_ _'3 ...;.: _� fid.. jj 4'.r.. _7J........r r.. 4'. a . �..� G1 rrii.. :.,; £♦ .ac`1' ::: szar4:ca:•. • Vcr tra1. W S r♦- Chief Co_.c_c a c'r:�ulic L sneer y G. f . GJI: 0 D ��cs cc: :i J :a +4z rson E :•1 A ulit.L i Chen E C Y: '/CE *}rcr/P Lo_.so ',I .r r O D ? :.lA 3v..r:.l^./r. ;:ern J :' Cr_.. n ".t .. -or E✓ t, ,_ r., . .'Z Q.T.I.M. .1:-,: r3 t•. .t�.. ..i� L •, To be :Amitt:: in t.!'iL'3ica'.a to: A'crth Car.1.1..a St,atc 5.:rd of ?i;.oith Sanitar;i Division (i) To t.` s.".: i'.u•^.` t-•d,. _E,-._a -- • (b) To raise ti.e 3evc1 of an ex:sti:ig pond 1, County = . .c^c^ Township Li''ostone 2. Location ir relation to 'tws or more well-knc -:n l;ndnarks: LLkc ;o lr_n-c.. .^.- Inc"_ Creel 2000 feet urstre^m of confluence with French Brow'. river -11r.-1rnt:roximate1v 1 74le to a roint O.d.1acent to Hi-h;.. . U.S. 2S. 3. Penson r:a',fin^ oprlica sior as ^;liter 7ri7-ht CQnt:?n;► 4, A1Hrc.sa r'f cun-r :T "' -'ro11: 5. Pt:r iowe cd. tF.e pr':,jcct, T-'-e for t. . . '..,ter i c Ftpt;a^ �. Appre xir..t n'.;nb+ r of pers l`.s 1iviri^ within on_ mile of prc .'csed res- ervoir cr tori ?. Arrrn{it- tc aroa t, Le cove c1 �J r.�.,,.720 acres s U, Diac..o tier t'i Train at be tt,::t of dam no favi,°tL c i for ful)i er?I:ty'Ari lehe. o, Of.scrirti.r. cf 1cvico for fluct.ating water level 1600' vide uncontrolled spil1,4 y wi'n crf.st at nor __ vat_r elev. 2210;:.0 conc*_'ete_ye err'.;1 10.- Will sn..= cin-:, t:.,ncy be r'i- ll nblo frr nein tai nim pont! after ir.pcundage so that, it ncit i rodi:c?.. mosquit.r. s? Yea 11. Date whoit is d-sired to start co,.structiott Actually started flay 1962 12. Late uhei it is :'.esiz'c't to imp:,:n•1 water Acts:111v started April 1, 11#63 In rcki n ' 'ti.i`'+ 3c.p1io.Lim, I 9:;mc t c:,m ly with tie e re;.ula icn £:ovornin in."'oln-1-6 so .1%-Main otic. r'.ni tt:ct it will not pro.:'ico mJs! hoes an.1 •..i.:...r.cc : ..; ..':� t: 471:: [...bliC .halt;1. Place n:1. it h, N irih Carol in., p:tto Juno 11, 1963 Carl-A ir_i fer & Light Company ; 1 � . �. :Gift•. r 't . , . i .. •t:ULivt: Vico. fresiu'nt • r.�.. ••, F _ 4CMOCRS CHARLES R. CLOG. M. D., Pau. RAL9GM if L•• - .\ �. \ . :OH. R.CL:SZ:i1.M.O.. Vicc•Pats. W�wS:O N.�w�LM ••••••••••••• � "' t ^ tT"� _ 1 Z. L. ED•.VAR;S. D.D.S. . WAsiiiw:soei 71• ' 1 L. . .t : ., «,�•ftre .w . Mn$. J. C. LATA liil.LaZana, RT t LENOX O. CAK:R. M.D DUAn AM ROGER W. 5.1.7RRISON. M.O. • . . AsaCvit,Ct EARL W. CaAN. A+.D. . RAi.C,a1. C. -IA.:AEON. PH. C. . . Li.K�: tea•. . 1d V.. D.4CY LY. D.V.M. . . GASTow14 1 \'J R L :C't,:' L :? h. 4w S.:CHT.TART.:.iCA..Jw:.,7 7 �:►:. i:A:C niCA::n G.6....ri • (?end No 13, County Bts cc:b a Cow_iuJ Dear Si:': Enclosed 4s your 1:?e_mit for Impounding and. Mei nte- ±qwh+ce of T. o tided i:ith a copy of your applica- tion attached. Ve_r uru y your , • Char?es M. White, Chief insect and Rodent Control Section Saniter-y En zincering Division • Enclosures CC: Health Officer CC: Sail Consc:nr.;.tionist • Pond No. 13 North Carolina State 3card of Health S....-_ tea:f .�..,..C:C�.. _• ::��•r_:_c r. Raieic:h, North Carolina P=1::Ii TOR II:PO:;;:C::; AND .;I::::::.;::C`, OF II-:POUNDED WATE Issued to: Name Car o?iaa Pc::e_ ILL:;'.2.; Co:.;any hddress Z i C'„�� i. . .:1 The construction of an imrounded water project, described in an an-. JI:=0 12 63 lication for a permit to impound water dated , 19 having been coy_leted in accort:ance with the requirements of the N. C. ::v,„1 . Board of Health, this permit for imnou^nin- and maintenance of impounded water is issued tLis 72"ta day of , 196 ? Section P. of Regulation No. 32 of the Regulations of the N. C. State Board of Health Governing the Control of Communicable Diseases, a copy of which is attached and forms a part of this permit, shall be observed ex- cent provisions thcrof as may be specifically waived in writing. This permit shall remain in force so long as the holders thereof maintain the imnou.ded water in a condition which does not render it a menace to the public health. 3. W. R. Norton, :i. D. State Health Director By _ Crarlcs Z. White, Chief Insect and 2odcnt Control Ctction Sanitary Engineering Divi:ion I I , TENNESSEE VALLEY AUTHORITY KNOXVILLE. TENNESSEE tv" March 29, 1962 -4 Mr. A. J. Skaale, Vice President Operating & Engineering Department Carolina Power & Light Company Raleigh, North Carolina Dear Mr. Skeml e : Enclosed are two copies of an Approval of Plans approved by our Board of Directors on March 22, 1962, covering the construction of a dam and cooling pond on Powell Creek at mile 0.6 and a water intake at French Broad River mile 161.38. You will note that we have shown on one of your drawings the ele- vation of maximum known flood regulated and extreme drawdown and the datum to which these elevations refer. Will you please indicate your acceptance of this Approval of Plans by signing and returning the extra copy for our files': As you will note from Section 8, this Approval of Plans is not valid until accepted by you. As required by Section 3 of this Approval of Plans, will you kindly inform this office of the date of beginning and of completion of this project'. Very truly yours, TENNESSFF VALLEY AUTHORITY °- eed A. Elliot, Chairman U Committee for Administration of Section 26a _ 7/ 5- / Enclosures 7 f. 6 • • C jI Ie, r •z_ 2. yam. m et_e c•-o• t*s. • r TENNESSEE VALLEY AUTHORITY KNOXVILLE. TENNESSEE -296-Er " t ' May 2 2,2962. CarolinR Power & Light Company Raleigh North Carolina Dear Sirs: This confirms TVA's position concerning the provisions in Article 4 of the Approval of Plans dated March 22, 1962, for your proposed dam and cooling pond on Powell. Creek and water intake on the French Broad River at Mile 161.3R near Asheville, North Caroling, as explained to your representatives by TVA's Committee for Admin- istration of Section 26a in their discussion May 3, 1962. In issuing approvals of plans pursuant to the provisions of section 26a of the Tennessee Valley Authority Act of 1933, as amended, TVA's purpose under Article 4 is to acquaint the applicant with the right of the United States and TVA to protect paramount federal interests if and when it becomes necessary to do so in the public interest, and with the fact that the federal interests may require the alteration or removal of applicant's facilities at applicant's expense under such circumstances. It is not TVA's purpose in in- cluding this provision in the Approval of Plans to deprive the ap- plicant of whatever rights it may have to contest the Board's find- ings under established principles of law. Any finding by the TVA Board of Directors will be made only on the basis of facts deter- mined by the Board in accordance with the authority set forth in the provisions of the Tennessee Valley Authority Act of 1933, as amended (16 U.S.C. §§ 831-831dd), and in accordance with any other applicable provisions of law including the Administrative Proced- ure Act (5 U.S.C. §§ 1001-1011) . The acceptance of an approval does not constitute any modification or waiver of the applicant's rights afforded by these statutes. Very truly yours, TENNESSEE VALLEY AUTHORITY Vii L. J. Van Mol General Manager I' APPROVAL OF PLANS OF CAROLINA POWER AND LIGHT COMPANY FOR CONSTRUCTION, MAINTENANCE, AND OPERATION OF A DAM AND COOLING POND ON POWELL CREEK AT MTTJ 0.6 A WATEit INTAKE AT FRENCH BROAD RIVER MILE 161.3R Pursuant to the authority vested in it by Section 26a of the Tennessee Valley Authority Act, as amended, the Tennessee Valley Authority hereby approves the plans submitted by Carolina Power and Light Company (hereinafter called "applicant"), covering the construction, maintenance, and operation of a dam and cooling pond and water intake in the location and according to the plans which are attached hereto as Exhibits A,B,C,D,E and made a part hereof. The approval is granted upon the following terms and conditions. 1. Applicant shall obtain all such licenses and permits as may be required by federal or state law. 2. No changes in the plans submitted by the applicant shall be made unless and until such changes have been submitted in writing to the Chairman of the Committee for Ac9ministration of Section 26a of TVA and applicant has received either a revised approval or a notice in writing from the Chairman of the Committee authorizing construction in accordance with the revised plans and advising the applicant that formal approval of the revised plans is unnecessary. 3. Applicant shall notify the Chairman of the Committee for Administration of Section 26a in writing of the time of commencement of work and shall also notify him promptly in writing of any suspen- sion of work if for a period of more than one month, resumption of work and its completion. 4. If any future operations of the United States or TVA, or agents of either, require an alteration in the structure or work herein authorized, or if the Board of Directors of TVA shall find at any time that it has an adverse effect upon navigation, flood control or public lands or reservations, applicant shall, upon due notice in writing from TVA, remove or alter the structure or work, or obstructions caused thereby, without expense to the United States or TVA, and if upon the expiration or revocation of this Approval of Plans, the structure, fill, excavation or other work hereby authorized shall not be completed, applicant shall , without expense to the United States or TVA and to such extent and in such time and manner as TVA may require, remove all or any portion of the uncompleted structure or fill and restore to its former condition the navigable capacity of the watercourse. No claim shall be made against the United States or TVA on account of any such removal or alteration. -2- 5. This Approval of Plans does not constitute a conveyance by TVA or by the Federal Government of any property or interest in any property covered by or used in connection with this project nor does it constitute a waiver on the part of the Federal Government of any of its rights in such property. 6. This Approval of Plans does not give any property rights in real estate or material and does not authorize any injury to private property or invasion of private or public rights. It merely con- stitutes a finding that the facility, if constructed at the location specified in the plans submitted and in accordance with said plans, would not at this time constitute an obstruction unduly affecting navigation, flood control, or public lands or reservations. 7. In issuing this Approval of Plans, TVA makes no representa- tions that the structures herein authorized or property used or stored in connection therewith will not be subject to damage due to fluc- tuations in elevations of the water surface of the river or reservoir. By the acceptance of this approval, applicant covenants and agrees to mAkP no claim against TVA or the United States by reason of any such damage, and to indemnify and save harmless TVA and the United States from any and all claims by other persons arising out of any such damage. 8. This approval shall not become effective until accepted by the applicant. The Tennessee Valley Authority has accordingly caused this Approval of Plans to be executed on this day of Unless the construction of the project herein approved shall be initiated before a year from the date of approval has elapsed, this approval shall automatically expire and future construction there- after even of the same character shall require a new approval. TENNESSEE: VALLEY AUTHORITY ig 6-.1" t Accepted: Carolina Power & Light Co. Applicant By: i` C. n..a a---% Vice Pres. • .040 Approv by TVA Boa.cl of Directors MAR 221962 ASSISTAN t SELRE AItY • N /1 ) - , c!' O 0--------- ..,'.....—© 1-, (11 .,,7NC (if o J •7‹ Q��SI; d . ogisr y o c. ir � t oLc:e. �s. 1 --, er '4.),-;*+0'. ,A T. y',4,-• Cir\ :VI 161 -t,l `; ecwRll, i t Q0 t u k}` ,; Z`�'� Creek - ' _?*S`; O•sQ x\60 0 ,r.,1r ,{, + ._ X F i t PT ti �� ti G\S \L 1\ O'f' _121 A 0 - A \ % 7' i► R cy L c', 9 O \\\\ 1to to s CI MI62 \k \ ' O \--. 4- \ : -� ° ti /,: Scale 1000 0 moo 2000 Feet H i--t-f 1 -----7.3 i _.•:,.., PROPOSED DAM & RIVER INTAKE NOTES. AREA PLAN Elevotlons Ye;t:r tc rr t 1 r .. ea f- v: I CAROLINA POWER & LIGHT • COMPANY A 17/,[fG0 2.0 ��� L MAX. PROBABLE FLOOD `` \-4,cOtiT A % N. : p W ELL Cil.. ... ... ' w , ` J \ _1 1 C.' ' / * ...h........ It•.,... lit if. .....*1 2150 1 k 1 `` a'j A Cl*' I 4ti> 0 I'i 699.E 1 :, . ♦ i 4.CHANNEL 1'0. ,'moi' • �:� i . � -t_ '14 !( '1.1'7 . I,I-arm 1 ' I-NJ-44J 1 ti . iItil,!_t.aa - . �JC G St �_41 • 1` t`,'� PROPOSED 4 DAM & SPILLWAY GENERAL PLAN i CAROLINA POWER LIGHT ioo o t200 .. f COMPANY 6CALE 1"=200' _ ., A- 170859 • N \ / 1 205005 \c`/ • Zo...._.........-....- \ 2Q�.o 0 ria ' �oa r 3571 2�3 1 Ir." SIaOADL TIoN 111 G p,CC E 5 TD Ham{ coN S� . �.: pR1OR \ ` LL CR EE K .,,r �=. _ --- - - -\ - poli - i; -7-----------.2030 FUTURE a LVEZT5iii . �� ...._ 235 PARKING AREA\\ `� irk a, ZO¢5 2040 E L 2032.5 . ; - 2050 �41 i . ' r# ‘ \ `TOE 2 • Ilk. OF FILL 455 ''771 ©� I i lOk Q ��� wA ' �\ 2 p 6 p �.r� a Cti5 9' \ 2p S , O \ 1 \ \ 65 C <\0 NDN ° . • \ -A \A, 0fig- ��z_ �y�.p 1‘ \ s'\.,Q -ii3 t 3 \ ra tr,), \ L 17 1- tP "V°0' PROPOSED :i RIVER INTAKE GENERAL PLAN 5Q O by 100 CAROLINA POWER a LIGHT \ SCALE l': loo' COMPANY L._ A-170861 "'—'--- ROAD IzJ,i .. EL 7110.01 .r- –j /r-5'RIPRAP cNWL 2160.o 2IGNARRY-RUN ROCK 1 21 --R �DOM FILL '_-- .. _ 30 MSN _ P. 3 22QUARR`(-RUN FUCK—\ SJL7.. 1' 11 EL Z169.0 ` ROCK UNE SE CT A-A CREST EL 2160.0 SYM ABOUT t i; I 1 - 60.-0 . 1-; _ D E T'Ay E DET �`8' �T'f� - , SECT C-C / r ' zo-o E .. t % APPRoX ROCK LINE _ - 1 of , k,' SECT. B -B J" - 10010 D xi O10-0 loo - I– TOP OF Z co SHEET i 0----e - GATE FOR RESERVOIR D D I DRAIN ATO LOWER WL TO C M PILING i EL Z1G9.0 2150.03) o cn ,. mina . c O 0 cn -0 '4 ., SPILLWAY CRE. im f EL 21E0.0 .122-°= (' 7-1 Dm O r I. r off, ti- sn - .., . 1 OUTLET PIPE 4 RIPRAP - '+ v SHEET PILING- o SECT EE. DE T A o = ''' = 40 = �0 1 20-0 C�ET 'IB4 APPRUX SANK OF R1VEK fi mstU1J MAX. PROBABLE FLOOD kr PLAN EL. 2050 . 8. I'-0 MAX. KNOWN FLOOD EL. 20 45 I ESTIMATED REGIONAL FLOOD EL. 5000 GPM PUMP I1= 0 . MAX. OPERATING LEV L ..L.- IO YEAP FLOOD LEVEL. EL 2033.04 I I _ I 4--EL 2032.5 EL. 2031-+ (,20,000 CFE'); / ji r ri7 4.--ORIG. GRD LINE 6 " �WL ON 10f 27f G1 MIN. RATING LEVEL L u- 1 a Z , EL 2024.15 #' TOP of CNC k ez 1 4 . STOP-LOG O 1 -&- x EXT LW EL 2022. 0± � ELZ02I.5 14 o 1i3 :k. TRASH RACK\f'J.4 w`' / 41w/7EL 201$.0* L,i. EIb ` I— [I, aI`' `"`RocK Y APPROX RIS{ER ' _ NF' r _,M Kr BOT EL 2.0 2 0.0 SECT D-D e='Lb COAST AND G�'CCD:T1C Si:R;'=Y '1 V29 DATUM, PROPOSED THRicuC:: Ti :_ MM :DIUM C- T. :" I^.5 SOUTH- . OUTI I- RIVER INTAKE EASTERN SUPP�=M:N T ARY ADJ'JSTM=IVT. PLAN a SECTION CAROLINA POWER a LIGHT • COMPANY A_17/10G7 Clean Water Act§316(b)Compliance Submittal Asheville Combined Cycle Station Appendix B Asheville Combined Cycle Station §122.21 (r)(2) — (8), (14) Submittal Requirement Checklist for a New Unit at an Existing Facility Clean Water Act§316(b)Compliance Submittal L�'] Asheville Combined Cycle Station Citation Title 40 CFR Requirement Provided in 122.21(r) Report? m o (2)(i) Narrative description and scaled drawings of source Yes Ta waterbody U T Identification and characterization of the source waterbody's Yes; note that no hydrological and geomorphological features, as well as the physical studies (2)(ii) methods used to conduct any physical studies to determine were conducted to intake's area of influence within the waterbody and the determine the area results of such studies of influence 0 (2)(iii) Locational maps Yes Narrative description of the configuration of each CWIS and (3)(i) Yes where it is located in the waterbody and in the water columnas c zr,• o (3)(ii) Latitude and Longitude of CWIS Yes 0) 3 (3)(iii) Narrative description of the operation of each CWIS Yes 0 o in v (3)(iv) Flow distribution and water balance diagram Yes (3)(v) Engineering drawing of CWIS Yes A list of the data supplied inparagraphs r 4 ii through(vi) Yes, but not pp ( )( )( ) g applicable because (4)(i) of this section that are not available and efforts made to all data are identify sources of the data available 0 C O — :Z A list of species(or relevant taxa)for all life stages and their N `° (4)(ii) Yes relative abundance in the vicinity of CWIS � rn U c N oo 4 Identification of the species and life stages that would be v a> ( )(iii) Yes most susceptible to impingement and entrainment 0 U U o m Identification and evaluation of the primary period of m o (4)(iv) reproduction, larval recruitment, and period of peak Yes a)c abundance for relevant taxa Cl) o m m Data representative of the seasonal and daily activities of a) CO Yes (4)(v) Ybiological organisms in the vicinity of CWIS aa)• m Identification of all threatened, endangered, and other eo CCa (4)(vi) protected species that might be susceptible to impingement Yes cn and entrainment at cooling water intake structures Documentation of any public participation or consultation No consultation (4)(vii) with Federal or State agencies undertaken in development of required the plan Clean Water Act§316(b)Compliance Submittal FIN Asheville Combined Cycle Station Citation Title 40 CFR Requirement Provided in 122.21(r) Report? (4)(viii) Methods and QA procedures for any field efforts Yes In the case of the owner or operator of an existing facility or Yes, noted in report new unit at an existing facility,the Source Water Baseline that(i)through (xii) (4)(ix) must be addressed Biological Characterization Data is the information included in (i)through(xii) in this submittal package Identification of protective measures and stabilization activities that have been implemented, and a description of (4)(x) Yes how these measures and activities affected the baseline water condition in the vicinity of CWIS Yes but not List of fragile species as defined at 40 CFR 125.92(m)at the required because (4)(xi) facility new unit at an existing facility Information submitted to obtain Incidental take exemption or authorization for its cooling water intake structure(s)from the Yes, but not (4)(xii) U.S. Fish and Wildlife Service or the National Marine applicable Fisheries Service Narrative description of the operation of the cooling water (5)(i) Yes system and its relationship to CWIS Number of days of the year the cooling water system is in Yes, anticipated (5)(i) operation and seasonal changes in the operation of the seasonal osystem operations E (5)(i) Proportion of the design intake flow that is used in the Yes system is Proportion of design intake flow for contact cooling, non- (5)0) Yes contact cooling, and process uses 0 U Distribution of water reuse to include cooling water reused as (5)(i) process water, process water reused for cooling, and the use NA of gray water for cooling Description of reductions in total water withdrawals including (5)(i) cooling water intake flow reductions already achieved Yes through minimized process water withdrawals Clean Water Act§316(b)Compliance Submittal rLYZ Asheville Combined Cycle Station Citation Provided in Title 40 CFR Requirement 122.21(r) Report? Description of any cooling water that is used in a (5)(i) manufacturing process either before or after it is used for NA cooling, including other recycled process water flows (5)(i) Proportion of the source waterbody withdrawn(on a monthly Yes basis) Design and engineering calculations prepared by a qualified (5)(ii) professional and supporting data to support the description Yes required by paragraph(r)(5)(i)of this section Description of existing impingement and entrainment (5)(iii) technologies or operational measures and a summary of NA their performance Identification of the chosen compliance method for the entire CWIS or Yes each CWIS at its facility Impingement Technology Performance Optimization Study for Modified Travelling Screen _c •O 8 F Two years of biological data collection c o Q m 8 (6)(i) • a) U T v o ami Demonstration of Operation that has been optimized to • o minimize impingement mortality U 0 m 06 None Available • E o Complete description of the modified traveling screens and associated equipment E a U a Impingement Technology Performance Optimization Study co m for Systems of Technologies as BTA for Impingement Mortality (6)(ii) Minimum of two years of biological data measuring the reduction in impingement mortality achieved by the system Clean Water Act§316(b)Compliance Submittal I-) Asheville Combined Cycle Station J Citation Title 40 CFR Requirement Provided in 122.21(r) Report? oami Site-specific studies addressing technology efficacy,through E o > (7)(i) plant entrainment survival, and other impingement and None Available Zs m ; entrainment mortality studies a> ° a a .. cm c i5 a) .S ' m O o Studies conducted at other locations including an E C (7)(ii) None Available o explanation of how they relevant and representative o U Lu ((n o W 1) Studies older than 10 years must include an explanation of C as (7)(iii) why the data are still relevant and representative None Available Description of individual unit age, utilization for previous 5 (8)(i) year, major upgrades in last 15 years Yes, where relevant U) Descriptions of completed, approved, or scheduled uprates Y (8)(ii) and Nuclear Regulatory Commission relicensing status of Yes,where relevant 1 co each unit at nuclear facilities 1 Toc O .i Other cooling water uses and plans or schedules for a (8)(ui) decommissioning or replacing units Yes 0 8 ,v For all manufacturing facilities, descriptions of current and ( )( ) future production schedules NA Descriptions of plans or schedules for any new units planned (8)(v) within the next 5 years Yes Applicant must identify the chosen compliance method for Yes, but will not the new unit. In addition,the owner or operator that selects need to comply with c BTA standards for new units at 40 CFR 125.94(e)(2)as its route to compliance must submit information to demonstrate Entrainment Characterization Z (14) entrainment reductions equivalent to 90 percent or greater of Study because dthe reduction that could be achieved through compliance facility does not with 40 CFR 125.94(e)(1). The demonstration must include withdrawal greater the Entrainment Characterization Study at paragraph(r)(9)of than 125 MGD AIF this section Appendix C Asheville Combined Cycle Station (ACC), Engineering Calculations for Through-Screen Velocity Asheville Combined Cycle Station(ACC) Duke Energy Carolinas Through-Screen Velocity Calculation-Lake Julian Cooling Water Intake Structure Prepared by HDR Originator: Mark Bailey,EIT 8-Sep-15 Reviewer:Radhika de Silva,PhD,PE 8-Jan-16 Revision No. Performed by Description of Revision 0 RDS 8/7/17-updated pump ratings 1 SRL 5/24/18-incorporated 0.5 inch mesh retrofit 2 SRL 7/27/18-incorporated 0.25 inch mesh and 3 SRL 8/15/18-incorporated bar rack data Duke Energy-Asheville Combined Cycle Station(ACC) 1/6 Through-Screen Velocity 9/11/2018 Asheville Combined Cycle Station(ACC) Through-Screen Velocity Calculation-Lake Julian Cooling Water Intake Structure Calculation Purpose: 1. Calculate the through-screen velocity at Asheville Combined Cycle Stations's cooling water intake structure(CWIS)on Lake Julian when the intake pumps operate at full capacity under normal and low water level conditions. Calculation Objectives: 1. Identify the screen physical parameters and design intake flow rates. 2. Calculate the fraction of the screen open for water flow. 3. Calculate the typical through-screen velocity under typical water elevation/flow conditions and design intake rate. System Description: The Asheville Combined Cycle Station(ACC)is an electric power generating facility that will consist of two combined-cycle power blocks with a summer/winter net electrical generating capacity of 250 MW/280 MW.The existing CWIS on Lake Julian will be repurposed to provide make- up cooling water and service water from Lake Julian for both units.Each unit will have two dedicated intake bays and two circulating pumps, one of which will be for redundancy,for a total of four intake bays and 4 circulating water pumps per unit..Lake Julian,located in Buncombe County,North Carolina,was created to serve as part of the cooling system for the existing Asheville Steam Electric Plant(Asheville Plant)by impounding Powell's Creek,a tributary of the French Broad River.The existing Asheville Plant also has a make-up water intake structure (MWIS)located on the French Broad River which will continue to be used to replenish Lake Julian water levels during low water conditions.Thi repurposed CWIS on Lake Julian will consist of the existing 1-inch hexagonal mesh screens(to prevent trash and debris from contacting the pumps or passing through into the station),bar racks,and new 0.25-inch mesh screens to be retrofitted at the CWIS.This evaluation will present the through-screen velocity at the CWIS under normal and low(design)water level conditions in Lake Julian under proposed operations of the ACC. Duke Energy-Asheville Combined Cycle Station(ACC) 2/6 Through-Screen Velocity 9/11/2018 Asheville Combined Cycle Station(ACC) Through-Screen Velocity Calculation-Lake Julian Cooling Water Intake Structure Calculation Methodology: The through-screen velocity will be calculated using the continuity equation as follows: Formula 7 Ven=Q/EOA where: Q=flow rate in gallons per minute(gpm) V=through-screen velocity in feet per second(fps) WD=wetted screen depth in feet(ft) OA=proportion of screen open area to total screen area TW= nominal screen basket width in ft Formula2 OA=(W*L)/((W+D)*(L+d)) where: d=horizontal(shute)wire diameter in inches(in) D=vertical(warp)wire diameter(in) W=width of mesh opening(in) L=vertical length of mesh opening(in) Formula 3 EOA=PC*OA Formula4 Ven=Q/(WD*EOA*TW*K) where: EOA= proportion of effective open area PC= screen percent clean(%) K= Conversion factor from gallons per minute to cubic feet per second,449 Ven=effective through-screen velocity(fps) Duke Energy-Asheville Combined Cycle Station(ACC) 3/6 Through-Screen Velocity 9/11/2018 Asheville Combined Cycle Station(ACC) Through-Screen Velocity Calculation-Lake Julian Cooling Water Intake Structure Design Inputs: Lake Julian CWIS Unit 1 Unit 2 Number of screens 2 2 Ref.5;Ref.6 Elevation at bottom of intake 2,144.0 2,144.0 ft Ref 5;Ref.6 Normal water surface elevation 2,160.0 2,160.0 ft Ref.5;Ref.6 Low water surface elevation(design) 2,158.0 2,158.0 ft Ref.5;Ref.6 Screen width 9.17 9.17 ft Ref.5;Ref.6 Hexagonal mesh size(L) 1.0 1.0 in As.7 Hexagonal mesh size(W) 1.0 1.0 in As.7 Hexagonal mesh vertical wire gauge number 19 19 gauge As.7 Hexagonal mesh vertical wire diameter 0.044 0.044 in As.7 Hexagonal mesh horizontal wire gauge number 19 19 gauge As.7 Hexagonal mesh horizontal wire diameter 0.044 0.044 in As.7 Bar Rack Width of Spaces(bs) 2.5 2.5 in Ref.2 Bar Width(bw,) 0.375 0.375 in Ref.2 0.25-inch mesh size(L) 0.25 0.25 in Ref.8;Ref.9 0.25-inch mesh size(W) 0.25 0.25 in Ref.8;Ref.9 0.25-inch mesh vertical wire gauge number 16 16 gauge As.8;Ref.8 0.25-inch mesh vertical wire diameter 0.063 0.063 in As.8;Ref.8 0.25-inch mesh horizontal wire gauge number 16 16 gauge As.8;Ref.8 0.25-inch mesh horizontal wire diameter 0.063 0.063 in As.8;Ref.8 Screen percent clogged 0% 0% Cooling Water Pump 1 Rating 1,800 1,800 gpm Ref 7 Cooling Water Pump 2 Rating 1,800 1,800 gpm Ref.7 Duke Energy-Asheville Combined Cycle Station(ACC) 4/6 Through-Screen Velocity 9/11/2018 Asheville Combined Cycle Station(ACC) Through-Screen Velocity Calculation-Lake Julian Cooling Water Intake Structure Assumptions: 1 Water elevation inside screenhouse is same as in the source waterbody immediately outside the bar racks. 2 Intakes have not been modified since dates of references used. 3 All screens function similarly. 4 Flow rates are pump design maximum and are most conservative. 5 The constant in Formulae 1 and 4 include units conversion from gpm to cfs. 6 The screen parameters found in the drawings remain accurate. 7 The hexagonal mesh screens at Asheville are approximately 1-inch in diameter and 19 gauge steel wire based on visual observations. 8 The proposed 0.25-inch mesh screens have a wire diameter of approximately 0.063 inches(16 gauge)based on physical measurement by vendor. 9 The bar racks have a bar spacing of 3 inches on-center,and a bar width of 0.375 inches(Ref.2) References [1]Lide,D.R.,CRC Handbook of Chemistry and Physics(Ed.72),Chemical Rubber Publishing Co.,USA, 1991-1992. [2]Ebasco Services Inc.Skyland Steam Electric Plant Intake Steel and Screens,Drawing G-171048,Rev.3 Dated 5/28/1963. [3]Duke Energy (January,2015).Clean Water Act§316(b)Strategic Plan-Asheville Steam Station. [4]B.L.Montague Co.Inc(March, 1963).River Intake Screens.Drawing 43363-155. [5]Brown&Root,Inc.Asheville Steam Electric Plant,Concrete Intake Structure Plan @ Top of Slab,Sections and Details,Drawing C-219-D,As-built 5/15/1972. [6]Ebasco Services,Inc.Skyland Steam Electric Plant Circulating Water System Intake,Drawing G-170903,Rev.4 Dated 1/24/1963. [7]HDR,Ziegler Communication 12/29/2015. [8]Beaudrey.Correspondence to Duke Energy.Dated 6/5/2018. [9]Beaudrey.Asheville Static Screen General Assembly.Drawing E117624.7/12/2018. Duke Energy-Asheville Combined Cycle Station(ACC) 5/6 Through-Screen Velocity 9/11/2018 Asheville Combined Cycle Station(ACC) Through-Screen Velocity Calculation-Lake Julian Cooling Water Intake Structure Calculation Summary: Unit 1 Unit 2 The estimated hexagonal mesh through-screen velocity at normal water level: 0.034 0.034 fps The estimated hexagonal mesh through-screen velocity at low(design)water level: 0.039_ 0.039 fps The estimated 0.25-inch mesh through-screen velocity at normal water level: 0.043 0.043 fps The estimated 0.25-inch mesh through-screen velocity at low(design)water level: 0.049 0.049 fps Calculations: 1. Screen Physical Parameters and Design Intake Flow Rate Given: Unit 1 Unit 2 Qrer„ 3,600 3,600 gpm Q= 1,800 1,800 gpm per screen Dhex 0.044 0.044 in dhex 0.044 0.044 in Loo. 1 1 in Whex- 1 1 in Do25-m= 0.063 0.063 in d025-in.= 0.063 0.063 in Lo25-in= 0.250 0.250 in W0 25-in= 0.250 0.250 in Dbar= 0.38 0.38 in dbar= 0.0 0.0 in Lear= 2.5 2.5 in Wbar= 2.5 2.5 in WC)normal 16.0 16.0 ft WDiow 14.0 14.0 ft K= 448.8 448.8 TW= 9.2 9.2 ft PC= 100% 100% 2. Proportion of Effective Open Screen Area to Total Screen Area Formulae Used: Formulae 3 and 4 Given: Screen parameters as above Calculate: Screen Unit 1 Unit 2 OA=(W*L)/((W+D)*(L+d))= 0.92 0.92 for hexagonal mesh OA=(W*L)/((W+D)*(L+d))= 0.87 0.87 for bar rack EOA=PC*OA= 0.80 0.80 for hexagonal mesh OA=(W*L)/((W+D)*(L+d))= 0.64 0.64 for 0.25-inch mesh EOA=PC*OA= 0.64 0.64 for 0.25-inch mesh 3. Through-screen Velocity Formulae Used: Formula 4 Given: Screen parameters as above and calculated screen open area proportior Calculate: Unit 1 Unit 2 Vel=Q/(WD*EOA*TW*K) hexagonal mesh at normal water level 0.034 0.034 fps Ven=Q/(WD*EOA*TW*K) hexagonal mesh at low(design)water level 0.039 0.039 fps Vey=Q I(WD*EOA*TW*K) 0.25-inch mesh at normal water level 0.043 0.043 fps Vee=Q/(WD*EOA*TW*K) 0.25-inch mesh at low(design)water level 0.049 0.049 fps Duke Energy-Asheville Combined Cycle Station(ACC) 6/6 Through-Screen Velocity 9/11/2018 Appendix D Asheville Combined Cycle Station (ACC), Pertinent Design Drawings • -----........11111111111111111111111111111111 • 1 'f i 1 i ° i i i i° It X4:10' ------- -, ¢S S-21 MCI" 6=D2• Z-I• b'-3`4" • T=6'IC 3•q' I DETAIL B- * I VOTE: r RELOCATE EXISTING HANDRAIL c ON NORTH SIDE OF UNIT 1 To #NJ{AKE I y I. - 1 NORTH SIDE OF UNIT 2. I 3 STOP I.04 1i ''';RAV. GP,-:N c' 1r y, �uloEs fi '40RA.a 3; _ 28''!. e- ',I I COME a1r11 .r Ne SCE.E GUIDE --- - (cu.) 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I .. .rte - SCALE:IEn_I'o' _- - -A r -_ _ _-__- 47-11•. _ •8'-I I. * I-6N SECT.E-E • • NOTE SECTION A A • .. N Foe GEESAL NOTES 4 EEFEKLJN E4CE G6. CALE:14'•ISECTION E-E SE C-201., . N.r4. UNLESE:ALL BOTDED NERw SEEN TED. FIELD ?URcHASED • ANCHOR BOLT SCHEDULE SEE DWG.AB-I5-I __„,,,,, AS BUILT PSAWI �., RRAWISR TITLE CONTRACT N0. DATE 6-7.o-..3 D In.LL-♦4Rluw. FL.OItl1N.ADOED wMP17M(IS-G 6,(u7 BROWN & ROOT,INC. CAROLINA POWER & LIGHT COMPANY C 9.0-10 ADDED PIPE SLEEVE L6. PM If. �^ Lir CONC RETE 01-32 SEMI_'s NO 1} B 6py REmo/a Las%L DROLPV'E LOCATION.45. _cp., 66 f/•'44' ENGINEERS AND CONSTRUCTORS;mss'`�`�; l ADDED T/ENCNNTOP SLAN`ADDED MT.J-J,GeriED.SICL Fri RP2P■rtar -4t (3`B) ASHEVILLE STEAM ELECTRIC PLANT INTAKE STRUCTURE A 74749 MN/DEO Toe SGML E csaioNc E-E(F-F,Al3GQ.AIAsIEA. P.- IIt./( { t!„..)„,(1 --^ R R E DRAWEE N. 4-404elaaueo FOR OONSTRUOTION nnI tc919NSTOYERAPI. HOUSTON,TEXAS 1971.200,000 KW EXTENSION-UNIT NO. 2.• PLAN TOP OF SLAB NIun 11111111111111 ' NT ONL IPA SECTIONS DETAILS C-219 O 1 1 T t 4 T T T T 'p i' I _ b4ao' . T_ _ j_'�9' }. 5-01 _,_ Lal^ 5x'4' t'I" .-_b'.3T4' ----" 6�s I --- ---��'� - ai 6-� I9 L9 s'-4`.48'o• T �'� �.- � I I -DETAILB�- __a.- -j.- -�.___ _ __ -1I }- OWG.0-280' NOTE: !I J RELOCATE EXISTING HANDRAIL f ON NORTH SIDE OF UNIT I To INTAKE I _ GUIDESCVARSE SCREE, Q.PINE SCFE I NORTH SIDE OP UNIT 2. D oRA.: { y GUIDES I - _ � u F. 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N.w.l. wl F3 .' 1%�I �� ,yc4(JLViZFIFE-.-�'. � in11 EL 7.160.0g �' r. �, x'�aoc EL.21A.co I f 'Ta+ J $O` C• d 510' 2=d vs' 2•V 11 EL 2138;00. g 1 DEs Lw.L. T 6' , h !` v - , j' DETAIL-A ELEISAOC _ cwaT..bwT-' r _ If I . - EL.21Sa.00 IIII �y - -._----_ _- .--- --_ - - I'PJF __,______3„._ J y {��w ----"''fir=___���� ��� 11. 3NGGROUT (rYR) i G I ,. :'L_ T r �. L 1� S' ,,y IE BY OTNER6 IL gw /. 3 EL.2165.Od 7 F3 �{ DIFFERENTI4L LEVEL t . W0 b+ R of I - 1`tb'STeAPs , _"'D� IC,'',lo)Fug P�+.rz. _s „Ibi _couTaoL .. III I ll l E7•' Sq - 4.a, EL.2168.00 eG'e.c. - _ -- 4-17 m t ' i i. Ji ,4 t l 1-b+!I } 3-4 ILo- SECTION G G SECTION J J EL 2144.00' I fPl ., 2. -ALE:IE'-ILCJ' It, N 1 L21ss21,I6 I'x I: FLAT BAR I ...... - HKD lk[41139.70' _if i4 3'SEAL SLAC VIIF +r,' I'f18'STRAPs T-•� _�-7;47_14_ SECTION C C A- E0 O.C.- y .. ;L/L4_,..-8, • •N SCALEEde"=ILO" _. -. -A �. -_ -_ - -_- 47-II• _ .8-I I' " _ _ LI-6" SECT.E-E - . NOrE i yy SECTION A-A Foe. GENEZ.AL NOTES 4 2EFE2ENGE cur..... • SCA•LE:14'-II'o' SECT ION E__-E SEE `�'' UT 4. ALL UNLEEMEMBEDDED EDNEDW TEEN TED. FIELD ?URcHASED c ANCI0P 80LT SCHEDULE SEE DWG.85-IS-I , �,L:n AS til)I RUWR c.H. BREWING TITLE SOITRIST N0. DATE A- °-.�9 D y_qo Eatuao-TEV FL.CIRIIR,ADDED wNw IMIS-a. NtI57 BROWN&ROOT,INC. C gmEo ADDED PIPE SLEEVE EA. PM .-CIEOEEoCAROLINA POWER & LIGHT COMPANY saw As i-or-D a rips,,FrVISEDDOT LEVELCOREN-FIFE LGGTIDI14MEE,, _ _GN EG _ �1. .... CONCRETE CF-32 _ ADDED TRENCH NIP SLAB ADDED SECTJ'J,DEEIEDSER.FrF RPP DYEEpp _ s;;ENGINEERS AND CONSTRUCTORS b ; ASHEVILLE STEAM ELECTRIC PLANT INTAKE STRUCTURE A T-O-49 RNISED Top EL AD E sncnoei E-E EF FAEL4,Brads Eb. R•r- $„r,.7I,T Imo,-y,,.nq - tEt B i R HAWING N0. 6-2of4 l3su@D FOR CONSTRUCTION P'° ec OBSTONER APP. ' >' HOUSTON,TEXAS , 1971-200,000 KW EXTENSION-UNIT NO" 2. PLAN TOP OF SLAB No. BATE REVISION IT REL APP. SECTIONS It DETAILS C-219-D a t.'I a- G-170903 t TQAV SCREEN GUIDES BELALY_STEEL PIPE STOP LOG:GUIDES A - ?(ITN".6LN0 FLAKE F.21-4 LC) N ',COARSE SCREt:N.GUIDES -f_y&tINE SCREEN GUIDES/ &C.W,PUMPS 124H0LES ■,r -- 2x°n- -�i • . • C M.H'SELADDFA. �LAODE0. �.SERVICE_ -1:1 `11,4 HOLES-COUNTER BORE ►GanA� . �`_� RUNGS 54'10 RUNGS ( PUN�►s- _t , - + L L0. j KI•pEFP ..,cKDe� __Ir .R f 1 { 11 • 3-5 1 Tl-2. _• 10'-I 61 6'-5# .2'.1 - -S'-lo'2. 8'-o is'-9 • f_ _ MI ePia6.2.6'-Sa JJJ�i°A' _ { 1 z-6 e'-B 3'-BV 2'-sig %D . . .a.y z ITAE2 TvPEit TYPE 36 TYn2t I NPI"SHEET PILE ., Y_, Y-- f >, ,ir�4{EI- I.1 S[44 MPIIe;f I. 6,_+0 I -...__ '-2 NUT6 i z x 8-814r+ANCHOR BOOS PILE • 8 '� '�"' 0 B•t!2-r4ANGHOR BOILS _ 1:-`ZI. TIO I RPIA w .wFwu Fw - -.L r {oI { I n __p y:-:c4/ �`R� ■ I I IA' s ■sem '. _.._ '1 I ✓ _� ■giyiG�dir II I,Iy • N '0M--._ 7-.4'L' ! -al- Ill B' b !- C'PUNP • -�I5 B Is.o u - . � ! __-- IPA- -, s _ �NP 112 SHEET PILE _ ___ _� 4 m AVIDAY�� • ANGHORt-� "THREAD�_ 146 : ` -n h _. - - TYrEY TYPE PORTES $• -• I ..ti C 9 TOBE�IIILL FINISH Yr y IV■1 I BOLT :SigLEgyE 4NCMOR TOP 6-0 .- FNS� r31 --k ; 11 -1! (, 4 _ __ �`\ PIB- - _`S l ' 6 1111-^. tl r __1 R > • 0 I I _\, _ ___ /• • r Ip{II� - I • -I-_I -- ELEV.--� F. I / •\. f \ III f� _. 'j - •:NE PI ,"� I ; RPIA 8.2T BI - •u 3''6 6...5 I r. m® 6 ' ` 02 m[�m I . $ Iv SEE E(6M!`.I I 18' 9til * Willa�0000��4.4„ 2167.99 T + j 1 N 1 - -Q ( \. 71T I _ NA- 1 6 I7t. aI 11 _ ' • � ` 1 E9 277,28 y Lb' 1'-8 t.Ith EYA�f'-6 i N7! 16-1•6 TAPERED 1,DOWELs (BY FIELD) 64®tl '©1 ®®0�®S!DWlS11B15EE PIAN I ` 1 4 44 L t Er 1 o ■ Fd - ! 4\ =.: 6LJN BOaLOGATT 11OENiluL . -•/L----\ DETAIL.OF FRAME P! 133-1J11 g b 113-1-111:111102O 'INTAKE _. \ r-r _N82-4AJK. 86 1Q _' . .. ■ _s Ef __ I MPO ••L6 l-14_-•'E 2'6,...,1" __- _ _ a' 0 2010> .WASNEe 2K8.46 • _II.Lr _-EL 5263 _ TAPERED DOWEL a -- ' "----- _ _'-_ LBS •SERV Z'-'�j r -_1 -�- �` - C.W.PUMP BASE - ffi ®COvO - I' I i� 11 Y L (' t I�_LP!EL.216&46 BY MFR N. _ ffi noovv - 2:.69... , / �� D wI r 1 \ ' / PUMP f. }I SFE G-P71048I.•'- 1 71'f'- 0®la�e - 2168.81. SI 'N 1 I \ I a_�z8 so° FRA EPI j 1 r 'iiYi \iUiTlAv - L� N i _ • .- I I I I� i. 1 \�. M t \ r SE F 18/41 ! I I �i--- LEVEL.NUT-. 1 OD; 10 m.:.. - _ -. 0■.._t..._ • w•.. I 11110 GROUT "4 ! I �..Z'"p� 11 0 "�A!' II • IIIIMP �•'71'II• • I I - I I ! I 1 n I ti pt KK�Tj-6'T tl I '' MI. \ fi " // 82 1 I I PACK SLEEVE WITH GR uT I -,,.....-\\ r YY J. tl 1' .\--, , I r ( e.-� • .r NOTE:BACK OFF ALL E {�(OF SUB-SOLE PLA ESE7TINfi 1 ! -�I 1_- I-•, B4\A- t• -j7 .1116 +. \.•. t J79' .-. I,{: s / .SEE G-F70916 NUTS AFTER WEDGES 1 i • _,�_. 1 •I '`____• rr',�■ R 'A I v _ I -f� -_ 1- 4-,.....,,,, .r5 -- -- HAVE TING.BEEN SET FOR '.I E N�� ?' -6 5,'; e, S 84 I " - y -9 GROUTING. SECT U-U r T :I -I ------- E I - -- "ICA -r if,i,. 88214 ANCHOR BOL- E - !TOP QF PAD COIlS Y ! •�"' p 4 --_-_ U� 14 0 PIPE - • g I,.J I&&-LIC'.ANCHOR BOLTS --- FOR CONTINUATION QUANTITIES! FIELD EXCEW AS NOfEO p - - I -T EI.21@8. CU0. - "Ay-- 1 A i SEE 6-170868 CONC cuss's' (3000 P51 , 7D - - - .-1 1CtYP)-O _ -'-'�` J. a - CONC CLASSS ) r3�_W:.OS I '•-Y Lo GALV.STEF t7PE IC 7lG) - 1 4$4 E 8-65-INF ANCHOR BODS 6 CAW,STttL PIPt f 7 L6) 1L�ADDER RUNGS AS PER DET•A 138 CuEQ'D L_ FOR LOCATION SEE G-171048 1.9- JL'-.0- 4', 4L5 .k .y (----- If'OIBRAH55 PIPE I�LIN FT / �,' WATERSTOP(6-POLYVINYL CHLORIDE F ,C ''WR HANDRAIL SEE G-171048 ,.' -2,6 4 � jai Ej " " L OR 18 GA.CAPPER) 44 LIN FT 1•PRENDLDED JOINT FILLER 40 54 FI- F 61 .4 STALV.STEEI i 85L10TPE5f'Ot RYPOCHLORRE 3.0 ZLRN ZB500 OR®IAAI_ 2 REO'D P1PEi(T4 - '-P_IPE L•115�. - UHE YEL2164.0) 8'GALV.STEEL MME 2L6-lb)wow BLWD.RANGE IIMO 1'-7 LG) 1 Rea0 E 7 IG - 2 REO D 1 __:_ I Rffi'D PLAN AT EL.2168.0 E01(_ALKN0 MTS SEE S�11eQAE TIES sever G r2•[6 :toz SOLE PEAT E-SEE 6.170904- 30EQ'D I 'E.0._!.1'..3'0 r 2 R Qb G E SERVICE PIMPS IdSIV ' I - - r 2-69-.1,4ANGHOR BoorsOE•PR41! y 76 E iV 9 RNRS REVD-SEE EI.kV F-F FOR LOCATION c.w.PUMP NPTES 3ppQ :4 '\ • - •---.I rEL216EOO �I -T • EECSPECIFICA ON EBASCO-TE SHALL BE C3ASS OE44 'ON I- EiT.o.D219102 1 6'= 2 O / 9'-2 �2 04 _ ¢BRASS PI PE_I 2b BRASS PIPE- h. I /81 6 �21 B4 I RETE 90NRY - T H EL 216a•00� I I- m. m ;rp i .•. C I i 1-I, ,� ANCHOR BOLTS EMBEDDED STEEL EELEC CONDUITS _-= , ___ om-- Cp OE ELl2iB750 - - _„EL.7168,00 TO BE SET IN F751TION FORE CONCRETE ISRACED H OI =i �.. p .COAT.ALL EXPOSED STEEL FOR FUTURE _ _ . EXTENSION WITH BITUNASTIC(LADDER RUNGS NOT MAX.H.W LEVEL EL,2165.00-s y --^ _ - �. s� O�k1•GR,ADl1 P3 INCLUDED). iPJF "'* � 'F� o 0 . ,: {, 1 . '' j II 1----" { _ _ ' --'�.` .• Y-0 •�F=-- -` -- :,„../9----4C:'FL'2Kr4.0 - _ i-' •* '1-3 A 4,44 BRASS ; , 1 __ -- _-�" �I III (�EL 216EDD f } �BSLV'S % • p Iy �M TRAY.SCREENl 9 PIPE--. _ 1, i ! 1 L,I L I NORMAL WATER LEVEL Ei.216D•'0' ^�Y"I GUIDE l r_ _ ._. , Ii 11 1 44dlNN V d - FINE SCREEN �� I F• ��•'+414'I • _ 1 ly- G-IT046 .. L, o _.- - Lq� GUIDES _ / + L_ I ' r-1}'IflPE u) DEG.L.W..LEVEL EL2158.D0 Q i ! ®¢ I/ a 1 •) yT�,___L- HP L21 1 O l/ , c I E ✓14 [ il r ��. u ..... _ �,-4"-i i T- �' - •'i.3- o i El 21$600. N R z ;111I I• 1n L J • DIFF,LEVEL CONTROL a1 ;. R 1_1 ¢ -' r. J 1 0 1 0 n+ S j Np REFERENCE DRAWINGS I LIST OF DRAWINGS ( A-110744 J • TOP WEATHERED -I _[_..._ - • -• -'HO -• - I J-4• 9'-S LW.PUMP-(C HINTAKE STEEL 6 SWHEELERA_S, 9-111048 .GNEISS- GWS.-INTAKE-MAS 5H2 ) -110500 ! C-W5-INTAKE-REINF 5E1 G-110904 ._ _-_ 4`O ;I p'-0 r CIRCULATING WATER PPE(A-S) G-170975 1 =. C.W.E.BLOCKS IA,IB 5 9-111046 LIJ/ V V LADING 6-170919 K _): EL 2144,00 J_ ,! "Y > 41'6 -lL :. 2 _1___ SCREEN ...-_ ..4/0 6& AORRANEC) A G-1710134 a - P NE 4 0 I o U) II FORAPGE'NENi CLINK-BELT) 787-105c,K 5 NI -' YARD PIPING DET'Stl'INTAKE 5 W DM'S 2ucruRE 7110775 i //TpV 3'°CLA55'D"CANC. ., L N i SCREEN I E II`5EEWCE PW(IAfipTNJNUTON) 727-1476 I6 3.[ 1 -5IJr6-� 45' i L SECTAA SECT B-B Y59 L SCRED✓I GUIDE 7-T _ - - - - --- -. I!i'00RA.•5 Pi PES 0. BYLI K-BLLT•. --,,,.,:-..,,,,,7,_ �i • H • • !-). �fy C , �- ”ay... 1a1! _ OP1H C'LRO(f J • R1 - T IN, �, EL2168.00 a IIIII- WpJp91AOE- S)OM tl 1i s� nI , BLOCKS- FIELDy-TAry. No.2433 4r d /FII ' i EL 2163.0 V101' MOy -6 •CTS-Sdam: rIli� TgFC•STrt,,,,Y�'t'''‘ 7 , 1, 1'-2 _ __.y. . - ■M REV([7)�CT7)(N7)SERNCE PUMPS �'cS �! • FORM 4 I. ADDED-(00.8.(4101,716 'DONAO ' -. j k� Inl _'aK_ ..T_T 24-65 ;x181RV OK A.N. .6-170906 - I`--YI! POCKETS SECT V-V DElE7E0(Lt61fiP5LA8 NOT REUSED ✓. �i WORK THt$DRAWING WITH FOR DIFFERENTIAL SEDT $-$ del,-O 3 II-7-62 PLE.ffF'91NG L°CATIONLLENGTNDF E1 EY 5, IRIUYER Dxxxsanb ET =A'u PIy CAROLINA POWER a LIGHT COMPANY ILO 1 `i'¢PLAIN STEEL ROO LEVEL CONTROL .SECT T-T REv:$nBIv°cKen PoR FUT Vx1i (1 (6ALVAN1EED) 2it.(-o H4 D5A6 iocrv-v";i(OxN3 ft M,• S%a LAND STEAM ELECTRIC PLANT fyWl N 1 •42.__:., Z_ ro_2-‘2 sMks `[CT V-V�(E3r�bGr F61 ;p 190,Dp0 NW INSTwLLATN)N-ono'Np.1 SECTION ELEVATION TYPICAL CONST.JT.DET. SECT R R • 1,6dT V RA■L-o55 sx E r J ' si ORCULATING WATER SYSTEM N A05E0.1E�,ET HH MB11SLElFV"4' s, y)'EO K 161tISAd. Nllb, ' _ fc%kFtlIEDDowELG. INTAKE-MAS SH NOI DETAIL A E 1'-D EGVIgFAn�HIS Wu7 1Cw`"s nABCp gtRVICEB INCORPORATIEp New YORK 1=1'O " / 5� REV:ItLb-b Uta BOE%A EIA SFcr _ w • I �ywH E p7A.CIT �-5�A E7 v...•'I'-Q w's■DVm lllnnnI'41 R CDL 4` Der JUL 23,1962 ■4 ■ [T(?a3 5,m,LocAt,O1 3 • Ts D.'Y/S IV! 1na0146 ay.fa+C-1.40 IBA 0i4'IE`isMlG-! 003DEe IMAM BY AErR01m CIETRINGALI 1 2 3 4 5 6 7 8 9 10 11 12 13 14 35 _ 16 17 16 19 6-171048 fI Z♦TAT HEAD a1K snxoN a zxfte MxJR f ! A STOP LOG F,COARSE SCREEN 4TRAV SCREEN �4,FINE SCREEN K[OFSC Z-L MAK.LTRS,MINgj(&E PEj - N woes GUIDES I GUIDE9 GUIDES CW PUMPS I lO CWEI•CO IT FOR.HINGED Cov ERSV 5.EEL c A flki, 1 STEEL NINGFE BTRASS qN � 3'-$ 5'-2 10'•1 GL B� �211 ( 10'-b4__-,- t'"9 _� • EAK 6.1. 1'T SI O- RONiP�E7µ;OCT* LI.�. t '''iii NTS. I SILICON D"•GDOUT 1•IOLES 1 3b 6:0 5 5'-4 �'&.q 519E. �r3 r. 5'j-o . NTS: G•-4 ,` ,SECT A-A II �,Cxa.RHINGEDAPT TO C (Deli FOR YIELD WELD 3io". I W _ R-MOV.11'�NPI PE HANDRAILS DET D 2-Eti R> - •I WOOD _ONL CWFR S) 4n ' -.-_ - -.- lQSt4+LD'4 I_D }TOP .',tr. ....t."'• '1' BAC11111W Fc CNKD R L8*2•i __ ID.tT ScvtNi G SB , {� 1 "0.'7?� 1 1 f NIN6f> 6 , RlRI'- $='-11�� ��• -- ( I _. -T- row L,VPFIR i:•yl V4.44 -3=•Zz•` 4 FOGA I.: GLKSPON GA�DIKDR L3'A•p2 WEIR Ofxt02.4TaG I 1 v RE,A1pVABLE DFM1S 117 VI w d� alN Ai a Co•ERS(TIP) '„c. _ - 6 _ r 1 •-� n -I 1 N OE ' 'I J• .o DOLTS 0 „I , p MIOIIO[y E-GCTL7 CR SCREwS cms "DIN F I Y I -J I 1� - 'AWLIONLRAfKJ'oE3 SEF SECT A•A I SEE PLAN L•6!LLT CTES Wx. > F D O 9_e ( I •AlYy ti -- .- - - ---, • G8 SEE SEGS NOT SHOWN HCCIWNL. ' ! - ' 1 ` I SECT A-A as SHOWN 4NOTED) SECT B-B-(T.{% SECT C-C SECT A-A ' C z I I • F00.PLATY DEIGN mea SECT K K(SIMILAR) S=I=o SECT D D(TYP) • SECT E E iSEEPt mi.EL miss-f----- I r : s.rvo 5,rto SECT-F=F c LI m ` 7 • J I C •.E-. -- ± z D L_� - - �n(LLry�♦_V__A__�n -•• 4.• IL II -� _I -_-I�• �� CSti ^F SHALL BE IN ACCO I �(� RDANGE WITH AIDC]PFG r- --�---. fin r AtNGEO- cert, REVISED JUNE 1949 WITH SUPPLEMENTART +I_ 1 ( A 11, -+� � MI 1 �--g d W PROVIyoNs FOR VSE OF A•34 STEEL Af}oPTED { U ilKoLES-FOIC 29 AD JUNE TGF 1960. D • s O It) L L • 1 I 6D•2 I Ail -`".l•E G_tzo9og Fo0.-GET5AACE Ill YEEOENG MNERE-AIPROYED SRAM 7E:IM ACCORD- b i a - F F I 1• I _ AGlu wG r'46AR ILF14Fi REYISIpfN�E AFEROFRIATE•WERICAEp +TESF;, It L- L5 Al. 111•DRO1 T WELD TO OW I J 0►E•9R-S HOARD-SFEf`YFI z Q ��TG EL IGE.0O' 5GRATING 2ia� CHECKERED PLATES TRAIL HE 9 -WAY SAFETY TREAD., ' ( Eli I rA SRATING Lia i Y ,EI • I atm V 1 ��11111111111. �¢M>Ai!>G ? -� PROTIDE LES 1-I/2•AIANEEER LIFT OT ROTES PER 1 y--o--T �7 �� FI ATE UNLESS O7NERVI SE SNOYN OR NOTED. EACH • ir 'K^I C�g ILIG iI0 of.=-1 q L4•j.e(GA•I$) °CNKD IE- /LATE sNAll DE FASTEtFO MI7M NOT E55 THAN FOUR,-�1 t'" I I ( t A.:� a ONLY f/2'DIANETER CWMTERSUNK FLAT HEAD 7RON2E TAE,> F •+0 1 2 ,A N PrdR SEG7 M-N L • I _-_ " .....)..........IT____ I �- _J"-,--• , five 2 .4,..„.,:i...„,,..ocr,A2mr,...., . ; -- SCREWS UNLESS NOTED' HAEININ SPACING 2F-8.ON ' is"- I•.F 6Ap ; F.''v- l 3Y ---•1----------- IEAR, CEYTERS. ALL CHECKERED RATES CURB ELATES,AMD, E "{M L±11 Q '�'T ,WELD TOL• _ G I _ _ SVF MR DIM SEE PLAN ONLY SHALL RE NEATLY FINISHED A7 CORNERS AND �' �--- -'- e4- ------ I I 'oluii•Ec7 AT-M'- I- UFT{N6 HOLES-T1 -1 �� 6 BOLTS ALE GRAVING SMALL 7E RECTANGULAR WELDED MON- LIFTING HANDLE- I ITYP) 1 1 I FOR DIN SEE PLAN SEE SECiWA SAA H(NOt3 REYERSI DLE TORE YI TH 3/18'TWICE NEARING CARS (SEE TYP.DET) w•, { I 1 i r 1 .�T 1 { I AND CROSS/ARS SPACED ROT MORE THAN N•ON CENTERS. VI 'f' ----- 1 I S ECT G- G(TVP) SECT H-H(TVP) FOR DIM SEE PLAN GRATING SHALL NE SECURELT FASTENED 70 SUPPDRT- 1 SECT J-JLNG STEEL. ALL CRATING SHALL BE NOT DIPPEO SHOP-ASSENDLED FAANE 4COVER.rsPS I 1 SECT 1-1 (As SHOWN) GAL TAXI ZED IM ACCORDANCE YI7H ASA.SPECI SPECIFICATION _i_ LJ `` -SECT lv}'o(AS NOTED) G8.1 (ASTM SPEC!FI CATION A-123): L 1 W SHELF>1k, (L-2.2.0 F 95.8 CNKD R +r�NC1LES FOA?�,AO. RUNG 5 ALL NANDRAILING AND PORTS SHALL NE.I-1/4• i'.1 PIPE HANDRAIL.SEE DET•A - 1RENOVABLU fa.:-......:_-_.. +MD• DI ANETEt STANDARD IRS. POTS SHALL RE WELDING F -�A°- IN ELEIINYS.9UlLAE16'1TItnt YrtFe Pn D.C.WELDING MCINNES USED FOR FIELD WELDING ��.� 'Ja A,D SEF _•.._ "-,___' SHALL 1E GROUNDED IN ACfAR01NCE'YIM THE MIN-.: --PLAN._.EL 2168.00'__ c•noepa 1,.....,e,,„,..„ e I• - LL•LOO FSF 7 1c� IDR-OKTk I CIPCES SET FORTH IN ELECTRICAL ENGI NEERIMG IF FILA 'tor y ^Hun.971114LTOP DP DET C I IGUIDE$AND OA7A.-612E- QRAp1YG A-NEG7p.,RtYD.) • xRES DESIGA4,FO0=2BAR 4• 0'9CNAO A. NTS .4OF HHEAD•E- jIT0.ES 1 CNKD DRILLED.t'".LADDER N ILOOEl 2141.75 :•: (j,:t•r••••••y� ias TO BE aI.GTO!LN +>. IN TICOP,EXCESIN LS I 1 G6 LO DE DRILLED G G• Y)rt./Soil'T "E INTAKE'S V ■', P I TN Tlam - y, IN FIELD EXCEPT FOR%LOP ASSEMBLED FRAMES, ('173 ` LADDER �� TL ES ..,� LADDER i •, ` SURFACED OP OF{L.EMDEDO_D 0 C0NG0.ETt G L IV Set DET-)- +u �i+iii ` SHALL NOT BE PAINTEC+ )•2 SLOT FOR 3'BAR LTV% ( /2. $� L DOGGING WTI PLAN -- Df111.5 --L-4.3+>q *'' SE7ER TNatCLEAN CLEANING BY TNECQAMETt- I{ANGES) k•f-0 8C _-el 21f-DOe {RENOY}� (N.S.ONLY) �2k I C1AL.9LA87 CLEANING-METHOD,As PER 5YM ART E i 1 I 54EUF1GTION,ZINC SPC,ALL STEEL SURFACES EE Eia.00' j 3 2=1 2=2 4X2.12 �e.,R,rr.„FF, ,- m.,_I 'D -^- --- t - Dnu•s Q ✓� LT "' G'�+2 T '" ■,� 1 QE DEDANDDE,ZINC RICH PAINT IN ACCORD- Av { (( A SNAEL BE SHOE+"PAINTED,WITH H ONE COAT 0 S� { `, ( Co.-4. '` CONE WALL :E o S•1NwGS I __I S• Rte.1 ORCARP OYE EQVA CIFICA JON T•••21 • t sLEwF j "r t�� w4MDtEFRf R- ITER"SPOT PAINTING ABFe/,pED AREAS, H .-101 /� / G. LO U-DOLTS'THO Du II Ill C EYP•ell :: •jF -7- - SPPLY ONE ( �4 MEK HUTS LDY GIRO) i� • 111 RKN PANNI 10 ACCOORDA1JLe T OF BANODE•willi SICNAC H 0 •••';' EAR ��1 DLTG PRi71CLY/ t b SEECtFi401 U7E5 FABRIUR APPROVED E@WL / \ N �` 4� G OQ'S SufSS71TUTON, 0 I - EgwEEP xolEs PLAN-Et 24GX(.75F SEDT=.P-P. EL zmins` 'DG n L•a+2 _--- - K _ + ' I 4 BVF 17 '2l0 O.L- =PLATE L.L.•IOOPSF I>1'-0 FOR SCREYJS I • ge•t'•o at gctt AA S ��� "°E =TYP LIFTING HANDLE DET 1 1� , is. 1,811771 1: i .2 G 2 / "w.8.MOLES IN LIan NT�i 0 j � eWID►FOR :JA r. 'o mgsCGA•Ta ELL,/ II L_-_--+JE74. - LADDER RETS T- BVFI TYP l.4HOLES� N ��OS LIL.r,R+ BLOCK l AS SHOWN LINKS 8 REC3D Lg'24 LAoceE 1111111 c "o� TYP;: I L2i21 NTS DET4 Docs) 1D I 2100.00 I-I et / 3•i BAR(TYP) ) 1 \ 1 ` ! 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O 11=11311111111111111.1111.F— DETAIL 1 SCALE 1/5 SECTION A—A SECTION B—B ,:1- . 03 B 1771.65[5.-93"1 I q ...I'... 1117.6(3'-8"] -p GRATING GRATING SUPPORTING BEAM (FOR INFORMATION ONLY) . I+21 68 DETAIL 5 �] L UU J / h j I / 1I DETAIL27 A �HWL+2165 / lIT .. .71/ !- . DETAIL 1 / / r� F / �— �€_� �LWL+2158' / t / 6 1.1 ,. DETAIL z / ^ iii. DETAIL 3 f SCALE 1/5 1 "^ / i u — -- IP MOO- UNSCREENED I SCREENED / / _ ,% 5 WATER FJ WATER BOTTOM SEAL DETAIL 4 P ti e / SCALE 1/5 o / 1\' /I DETAIL 3 _ __ •A" v IFt; J+2144' / �� \� 4 1_ :A I I,- 1�-J.J---3,. -I_ I / , I 15.2 1.1 0 9 /./ 75.6 [3"] F 83 B� _ 26.6 [1"]LI — F A4 PLAN VIEW SECTION C—C iso SCALE 1/5 rn _T_________ 3 lR2A'i 3 s \-- --_ ------ THICKNESS 20mm[d] 060 AT] ig 2794 9'-2"] ' 41111161r ' r''LJ , _i+ \ GENERAL DIMENSIONS mm [INCHES] 2 • t TA A \ .-��_�r�� DEMANDER EN CAS DE DOTE/IF IN DOUBT ASK • 71A du plan n' 113369/E117616 Annuls la plan n 'I i�mN.ee�,r n e.uNw"M.n w war Irv.m rwraaan..r.emm,,,,I.A e Nw a `�.* DETAIL 4 \ 1nN e..m p E.aEAUDRFY A CO a oanwl w ma,nNrvaucM.rren bciwM wr Mer..xr..wIml.Mw. 1pwnr." .min.a..N/er e • , A Dal. Auf.ur/AuMer 0841. Ap b" _ I \ \ /1 GRILLE DE MODIFICATIONS/MODIFICATION TABLE ' \ 13n/07/7016 JSC PC CJU A a410^eNan:Emi bn PA — — — — — — — \ E. BEAUDREY et Cie TM.:tuz,S,�ss4.°tl%NJN.I9 DESSRIEMIARR .a•.rMwuarn.i. nC ASHEVILLE DATE 12/07/2016 STATIC SCREEN — ECNEUE/SCALE I/70 1n GENERAL ARRANGEMENT S. CODE PLAN M MM DE COANDS N OE DOSSIER N.D ORDRE ` ICB632D C113618 E117624 H F G F F E F 0 F F B F A