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NC0004979_Entrainment Characterization Study Plant_20160502
DUKEEnvironmental Services ENERGY, Duke Energy 526 South Church Street Charlotte, NC 28202 Mailing Address: Mail Code EC13K!P.O. Box 1006 Charlotte, NC 28201-1006 May 31, 2016 REC E!V EDINCDEQIDWR Mr. Tom Belnick, Supervisor JUN 0 2 2016 NPDES Complex Permitting Water Quality NC DEQ/DWR/WQ Permitting Section Permitting Section 1617 Mail Service Center Raleigh, NC 27699-1617 Subject: Allen Steam Station National Pollutant Discharge Elimination System - Permit No. NC0004979 316(b) Entrainment Characterization Study Plan (ECSP) Dear Mr. Belnick: Please find enclosed the final Entrainment Characterization Study Plan (ECSP) for Allen Steam Station. The plan incorporates comments from the fisheries biologists peer reviewers, as well as comments from the North Carolina Department of Environmental Quality (NCDEQ) received on March 3, 2016. Responses to comments from NCDEQ are also enclosed. If you have any questions or comments, please contact Nathan Craig at Nathan.Craig@duke- energy.com/704-382-9622 or Randy Gantt at Michael.Gantt@duke-energy.com /704-829-2587. Sincerely, nAJjq- P. Brent Dueitt General Manager II Allen Steam Station Attachments: Bc: Randy Gantt Ross Hartfield Nathan Craig Linda Hickok Tom Thompson Matt McKinney HDR, Inc. (Ty Ziegler) UPS Tracking: 12)(67 601 42 9802 4805 1 t RECEIVEDiNCDEQIDVJR JUN 0 2 2015 Water Quality Permitting Section Response to NCDEQ Comments: Entrainment Characterization Study Plan — Allen Steam Station Prepared for: etioN EUKE NERGY Prepared by: HDR Engineering, Inc. � r Entralmnent Ctractatation Study Plan ��� Response to NCDEO Comments-Men Steam Station Contents 1 Introduction 1 2 Development of Entrainment Characterization Study Plans 1 3 Twice per Month Sampling fa Estimating Entrainment 3 3.1 Conclusion 5 References 6 Duke Energy I I Entrainment Characterization Study Plan ��� Response to NCDEQ Comments—Men Steam Station 1 Introduction The U.S. Environmental Protection Agency's (EPA) rule implementing §316(b) of the Clean Water Act(the rule)was published on August 15, 2014 in the Federal Register. The rule applies to existing facilities with design intake flows (DIF)of more than 2 million gallons per day(MGI)) that withdraw from Waters of the United States, use at least 25 percent of that water exclusively for cooling purposes, and have or require an NPDES permit. Existing facilities with an actual intake flow x 125 MGD are required to provide an entrainment characterization study (at 40 CFR 122.21(rx9)) as part of its permit renewal application materials. Duke Energy facilities in the Carolinas that meet the 125 MGD flow threshold are proposing a two-year entrainment sampling program to gather the information necessary to fulfill the entrainment characterization requirements. The goal of the proposed program is to estimate the seasonal and annual total abundance of fish eggs and larvae that are drawn into the cooling water systems. Entrainment sampling at each facility is proposed from March through October of 2016 and 2017. 2 Development of Entrainment Characterization Study Plans An Entrainment Characterization Study Plan (ECSP) was developed Allen Steam Station (Allen). The ECSP describes the sampling design and site-specific approach being used at Allen to sample for entrainment; the rationale for the selection of gear type, sampling location, and other components of the sampling design; and a discussion on how the study fulfills the requirements of the rule. While not required to undergo a peer-review, a draft of the ECSP was sent to a subject matter expert in fisheries biology for an independent review. After addressing comments and incorporating relevant changes, the final ECSP was sent to the Director for comment. Comments were received from Bryn H. Tracy(Senior Environmental Specialist, North Carolina Department of Environmental Quality [NCDEQ]) by email on March 3, 2016. We thank Mr. Tracy for his comments and have provided responses in Table 2-1. Duke Energy 17 Entrainment Characterization Study Plan Response to NCDEQ Comments-Allen Steam Station Table 2-1. Responses to Bryn H. Tracy (Sr. Environmental Specialist, North Carolina Department of Environmental Quality) Comments on the Entrainment Characterization Study Plan for Allen Steam Station Facility Comment Response and Resolution The pumps at Allen are not equipped with variable speed pumps so each pump is on or off.The difference between actual intake flow and design intake flow rates(as shown in Table 2-1 of the ECSP)is determined by the number of pumps and units in operation and the length of time they are operated. Page 6,Table 2-1:a)Do the pumps operate variably or do they operate at maximum design flow all the time? If they operate variably,how will you For entrainment,the underlying assumption used by EPA is that entrainable organisms Allen account for this? For example,would you expect more or fewer organisms to are passive and move with the flow.Therefore,reduction in flow results in a be entrained when the pumps are operating at the design flow rate vs.when commensurate reduction in entrainment.In your scenario,we would anticipate that a 50 they are operating at 50%of the design flow rate? percent reduction in flow would result in a 50 percent reduction in entrainment. Entrainment data will be normalized by the volume of water sampled so that it will be expressed as the number of organisms per volume of water.This convention will allow for estimation of changes in entrainment rates based on the number of pumps and units in operation. Units are dispatched to meet system loads,at the lowest possible costs,and subject to Allen b)This relates to your choice of using Units 2 and 3: are Units 2 and 3 always transmission and operational constraints.Units 2 and 3 were selected because they are in use? Why not use Units 4 and 5 or Units 1 and 2? centrally located In the CWIS and are more frequently operated than some of the other units. Page 16,first and second paragraphs a)Please provide reason(s)as to why you decided on bi-weekly sampling(or is it just twice a month?)vs.weekly Allen sampling.I attended an NC AFS workshop in 2005 lead by Dr.Doug Dixon Please see Section 3-Twice per Month Sampling for Estimating Entrainment. (EPRI)and I have in my notes that bi-weekly sampling is more biased than more frequent sampling. b)Please provide reason(s)as to why you decided on bi-weekly sampling(or Allen is it just twice a month?)vs.weekly sampling.I attended an NC AFS workshop Please see Section 3-Twice per Month Sampling for Estimating Entrainment in 2005 lead by Dr.Doug Dixon(EPRI)and I have in my notes that bi-weekly sampling is more biased than more frequent sampling. c)Given that the limited historical studies(page 11)showed very few Laboratory costs are charged on a per sample basis.Even samples with little debris and organisms collected in the 1970s,it would seem that adding replication to your few eggs and larvae still need to be processed and subjected to QC procedures to Allen study design would not substantially increase your laboratory time,unless the ensure all organisms have been removed for identification.Replication increases the reservoirs productivity is far greater(more eutrophic)than it was 40 years ago number of samples and directly affects costs. and you now encounter greater densities of ichthyoplankton. Allen Page 17,Section 6.2,first paragraph,last sentence:Please provide citation(s) Please see Section 3-Twice per Month Sampling for Estimating Entrainment justifying as to why twice per month sampling is sufficient. You might as well add Alewife,Blueback Herring,Blue Catfish,Flathead We will add Alewife,Blueback Herring,Blue Catfish,Flathead Catfish,and Spotted Bass Allen Catfish,and Spotted Bass to your appendix.They are all in Lake Norman and to Appendix A of the ECSP. probably in Lake Wylie by now or will be soon. Duke Energy, 2 Entrainment Characterization Study Plan Response to NCDEQ Comments—Allen Steam Station 3 Twice per Month Sampling for Estimating Entrainment Sampling interval — or the time between sampling events — is typically assigned to a regular schedule(e.g., one month,two weeks, one week, etc.). In some cases, the interval may change on a seasonal basis (EPRI 2014). In the Rile and its preamble, EPA provides no guidance on the sampling interval associated with entrainment characterization studies required under §122.21(rX9). The ECSPs reviewed by NCDEQ are based on twice per month 24-hour sampling events where each sampling event contains four samples collected throughout the 24- hour period, resulting in eight depth integrated entrainment samples per month. This sampling frequency was selected based on careful consideration of study objectives, gear selection, and historical 316(b) studies. This section provides additional clarification on sample frequency selection based on NCDEQ comments. The Electric Power Research Institute (EPRI), in its 2014 entrainment abundance monitoring support document, took advantage of a large dataset from an intensive entrainment monitoring program undertaken at the Indian Point Generation Station on the Hudson River, NY. These data were collected over 5 years (1983-1987) continuously or near-continuously (24-hours per day, 7-days per week). Using these data, different sampling frequency and intensity scenarios, including monthly, twice per month, and weekly sampling frequency, were modeled for their effect on entrainment abundance estimates. A sampling frequency of one day in a twice per month interval produced a coefficient of variation (CV—the ratio of the standard deviation to the mean)of annual entrainment estimates ranging from 750 percent for taxa entrained at very low densities (0.001 per 100 m3) to roughly 50 percent at the highest densities (100 per 100 m3). The CV declined as the frequency of sampling increased (Table 3-1). At densities between 0.1 and 1.0 per 100 m3 and greater, the CV stabilized between 25-50 percent for weekly sampling and 50-75 percent for twice per month sampling. The Hudson River estuary is a dynamic and variable environment that is affected daily by tides, salinity and temperature gradients, and freshwater and nutrient inputs. At locations such as this, species compositions and their relative abundance can fluctuate rapidly. In addition, the spawning season is more spread out than in freshwater (i.e., spawning can take place in any month of the year). Comparatively, a southeastem Piedmont reservoir represents a more stable ambient sourcewater system and the spawning season is discrete within the year. Based on these factors, it is assumed that comparable levels of precision can be achieved with less frequent sampling in southeastern Piedmont reservoirs than would be needed on the Hudson River. Even Brunswick Steam Electric Plant (BSEP), which withdraws from an estuary, exhibits similar estimates in entrainment based on monthly and twice per month sampling as described below. Organisms collected at very low densities will generally not contribute substantially to the economic benefits valuation and as a result selection of fish protection technologies will not Duke Energy l 3 Entrainment Characterization Study Plan F•�'� Response to NCDEQ Comments—Allen Steam Station typically be driven by species rarely entrained'. Therefore, greater variability (CV) in estimates for these rarely collected species should be acceptable for the Entrainment Characterization Study and the analyses these data support. In addition, as shown in Table 3-1, there is relatively little difference in the CV between the weekly and twice per month sampling frequencies for the more abundant species which have a greater affect on the valuation of economic benefits and the selection of fish protection technologies. Table 3-1. Estimated Mean Coefficient of Variation of Annual Entrainment Estimates Based on 100 Iterations of Different Sampling Scenarios (100 m3 per Sample) Applied to Indian Point Entrainment Data from 1983-1987 (Modified from EPRI 2014) Approximate Coefficient of Sample Mean Variation (%) Density Weekly Twice per Month (No./100 m3) Sampling Sampling 425-750 0.01 125-50 350-150 0.1 50-75 50-150 1 25-50 50-75 10 25-50 50-75 100 25-50 50-75 We note EPRI (2014) did not provide entrainment estimates associated with the sample frequencies modeled. Our assumption is the total estimated entrainment generally remains consistent regardless of the frequency of sampling, but the CV around the estimate decreases with increased sampling. This is consistent with observations at BSEP. Data from yearly sampling at BSEP from 1979 to 2004 were used to demonstrate that estimates of entrainment based on weekly sampling were similar to those based on a monthly sampling frequency (see green and blue lines in Figure 3-12). Based on this data, and consultation with NCDEQ, Duke Energy decreased the sampling frequency at BSEP from weekly to monthly. 1 A potential exception to this rule is when Federally-listed species may be involved in entrainment, however, no Federally listed species are associated with potential for entrainment at these Duke Energy facilities. 2 Baseline and Post-baseline refer to prior to and after the installation of entrainment reduction technology and operation measures (fine-mesh panels and seasonal flow reduction) at BSEP, respectively. The post-baseline data includes all sampling frequencies(i.e., weekly and monthly combined). Duke Energy 14 Entrainment Characterization Study Plan Response to NCDEQ Comments—Allen Steam Station 100 r... • 80 a. 60 a 40 50th Percentile 80th Percentile Nu. % Nu. % • 20 -. Baseline 9.45 18.46 (� Weekly 1.44 84.7 4.13 77.6 Monthly 2.38 74.9 5.06 72.6 Post-baseline 1.79 81.1 4.79 74.0 0 0 10 20 30 40 50 60 70 80 90 100 110 120 130 140 150 Number entrained (millions) —Baseline Weekly —Monthly Post-baseline Figure 3-1 Cumulative Distribution of Total Entrainment at Brunswick Steam Electric Plant under Varying Sampling Frequency 3.1 Conclusion In determining sampling frequency, twice per month sampling was selected to balance the level of uncertainty and costs with rule requirements and considerations of how these data would be used in the later §122.21(r) reports. Changing the sample frequency from twice per month to weekly would double or more3 the program costs yet not materially improve the quality of the larger technology evaluations required under the rule. For these reasons, the twice per month sample frequency was proposed in the study plans and remains the recommendation after both peer review and NCDEQ comments have been received. 3 Increasing sample frequency from twice per month to weekly will at least double the cost of the entrainment characterization program. Given the scale of Duke Energy's fleet-wide entrainment characterization effort, such an effort may require hiring of additional contractors and field/laboratory staff raising the potential for even further cost escalation. Duke Energy 15 Entrainment Characterization Study Plan inn to NCDE0 Comments—Allen Steam Station References Donner, M.T. and R. Eckmann. 2011. Diel vertical migration of larval and early-juvenile burbot optimises survival and growth in a deep, pre-alpine lake. Freshwater Biology 56: 916-925. Electric Power Research Institute (EPRI). 2014. Entrainment Abundance Monitoring Technical Support Document Updated for the New Clean Water Act §316(b) Rule. 3002001425. EPRI, Palo Alto, CA. 156 pp. Duke Energy i 6 1 1 FY 1 �1 1 _I I I Entrainment Characterization I Study Plan IPrepared for: (ft) ENERGY I Prepared by: 1 HDR Engineering, Inc. I April 15, 2016 I -1 Allen Steam Station I I I I RECEIVEDINCDEOJD\VVR JUN 0 2 2016 Water Q Section Permitting Entrainment Characterization Study Plan Prepared for: UDNERUKE �') ENERGY 1 Prepared by: ' HDR Engineering, Inc. ' April 15, 2016 Allen Steam Station I ' Entrainment Characterization Study Plan rLpl Allen Steam Station ' Contents 1 Introduction 1 1.1 Regulatory Background 1 1.2 Study Plan Objectives and Document Organization 3 I 2 Generating Station Description 3 2.1 Source Waterbody 3 2.2 Station and Cooling Water Intake Description 6 ' 2.2.1 Intake Structure 6 3 Historical Studies 11 4 Threatened and Endangered Species 11 5 Basis for Sampling Design 12 I 6 Entrainment Characterization Study Plan 17 6.1 Introduction 17 8.2 Sample Collection 17 6.2.1 Location 18 6.3 Sample Sorting and Processing 23 6.4 Data Management 24 6.5 Data Analysis 25 I 6.6 Field and Laboratory Audits 25 6.7 Laboratory Quality Control 26 6.8 Reporting 26 I6.9 Safety Policy 27 7 References 28 ' APPENDIX A—Select Species Spawning and Early Life History Data 29 I Life History References 33 APPENDIX B—Response to Informal Review Comments 34 APPENDIX C—Comparison of Pumps and Nets for Sampling Ichthyoplankton 39 I I I I Duke Energy I i Entrainment Characterization Study Plan )1 Mien Steam Station r Tables Table 1-1. §316(b)Rule for Existing Facilities Submittal Requirements Summary 2 Table 2-1. Allen Steam Station Design Intake Flow Rate by Unit and Daily Average Water Withdrawal from Lake Wylie, 2011-2014 8 ' Table 5-1. Advantages and Disadvantages of Hoop Nets and Pumped Samplers for Estimating Ichthyoplankton Density in Cooling Water Intake Structures (some information adapted from EPRI 2014) 14 Table 5-2. Potential Disadvantages of Pumped Ichthyoplankton Sampling at Allen Steam Station 15 Table 5-3. Summary of Approach for Development of §122.21(rx9) Required Entrainment Characterizations 16 ' Table 6-1. Entrainment Sampling Details 18 Table B-1. Directed Charge Questions 34 ' Table B-2. Peer Reviewer Responses to Directed Charge Questions 36 Table C-1. Advantages and Disadvantages of Hoop Nets and Pumped Samplers for Estimating Ichthyoplankton Density in Cooling Water Intake Structures (some information adapted from EPRI 2014) 41 ' Table C-2. Total Number (N) and Mean Densities (MD) (mean number of shad/ 1,000 m3) of All Shad Collected with Comparison Gear and Shad <28 mm Total Length Collected with a Tucker Trawl on Lake Norman, North Carolina, 6-10 June 1982, with Average Volume of Water Filtered per Sample (m3) (Leonard and Vaughn 1985) 50 Table C-3. Summary of Major Studies Designed to Comparatively Evaluate the Sampling Efficiency of Various Large-Volume Pumps and Tow Nets(Taggart and Leggett 1984) 52 1 Duke Energy i ii Entrainment Characterization Study Plan �L Allen Steam Station r Figures Figure 2-1.Allen Steam Station Vicinity Map(Source: Duke Energy 2014) 5 Figure 2-2. Plan View of Allen Steam Station CWIS(Alden 2012) 7 ' Figure 2-3. Section View of Allen Steam Station CWIS(Alden 2012) 8 Figure 2-4. Site Configuration of Allen Steam Station(Source:Alden 2012) 9 ' Figure 2-5.Aerial View of South Fork portion of Lake Wylie(Image Modified from: ESRI) 10 Figure 4-1. Geographical Boundary of the IPAC Search 12 Figure 6-1. Plan View of the Allen Steam Station Cooling Water Intake Structure with Approximate Sampling Locations(Unit 3, Screen a and Unit 2, Screen b)(Image Modified from:Alden 2012) 19 Figure 6-2. Section View of the Allen Steam Station Cooling Water Intake Structure with Approximate Location of Sample Inlet—Sampler pipe (in red) not Shown to Scale (Image Modified from: Alden 2012) 20 ' Figure 6-3. Aerial View Showing Approximate Locations of Sampling Gear (Image Modified from: Bing Maps) 21 Figure 6-4. Example Entrainment Pump Sampling System Configuration 22 Figure 6-5. 7.5-Horsepower Electric Pump Used for Entrainment Sampling 23 1 Duke Energy 1 Iii IEntrainment Characterization Study Plan / �� Allen Steam Station r IAcronyms and Abbreviations I ¶ degrees Fahrenheit AIF actual intake flow Alden Alden Research Laboratory, Inc. ' Allen Allen Steam Station AOQL Average Outgoing Quality Limit BTA Best Technology Available 1 CSP continuous sampling plan CWIS cooling water intake structure DIF design intake flow ' Director National Pollutant Discharge Elimination System Director Duke Energy Duke Energy Carolinas, LLC ' El. elevation ECSP Entrainment Characterization Study Plan EPRI Electric Power Research Institute I gpm gallons per minute HDR HDR Engineering, Inc. IPAC Information for Planning and Conservation (website) ' m3 cubic meter MW megawatt pm micrometer or micron ' mm millimeter MGD million gallons per day ' MIL-STD military-standard NPDES National Pollutant Discharge Elimination System NCDENR-DWQ North Carolina Department of Environment and Natural Resources,Division of Water Quality ' NCDEHNR Normandeau North Carolina Department of Environment, Health, and Natural Resources Normandeau Associates, Inc. PVC Polyvinyl chloride ' QA Quality Assurance QC Quality Control SOP Standard Operating Procedures IUSFWS U.S. Fish and Wildlife Services I I I I Duke Energy l Iv I ' Entrainment Characterization Study Plan L1� Allen Steam Station rJ ' 1 Introduction 1 .1 Regulatory Background The Clean Water Act was enacted in 1972 and introduced the National Pollutant Discharge Elimination System (NPDES) permit program. Facilities with NPDES permits are subject to §316(b) of the Act, which requires that the location, design, construction and capacity of cooling water intake structures (CWIS) reflect best technology available (BTA) for minimizing adverse environmental impacts. Cooling water intakes can cause adverse environmental impacts by drawing early life-stage fish and shellfish into and through cooling water systems (entrainment) or trapping juvenile or adult fish against the screens at the opening of an intake structure (impingement). ' On August 15, 2014, the final §316(b) rule for existing facilities was published in the Federal Register. The rule applies to existing facilities with design intake flows (DIF) of more than 2 million gallons per day (MGD) that withdraw from Waters of the United States, use at least 25 percent of that water exclusively for cooling purposes, and have or require an NPDES permit. The rule supersedes the Phase II rule, which regulated large electrical generating facilities until it was remanded in 2007, and the remanded existing-facility portion of the previously promulgated Phase Ill rule. The final rule became effective on October 14, 2014. Facilities subject to the new rule are required to develop and submit technical material, identified at §122.21(rX2)-(14), that will be used by the NPDES Director (Director) to make a BTA determination for the facility (Table 1-1). The specific information required to be submitted and ' compliance schedule are dependent on actual intake flow rates (AIF) at the facility and NPDES permit renewal date. Existing facilities with an AIF s 125 MGD are required to address both impingement and entrainment and provide explicit entrainment studies which may involve extensive field and economic studies (§122.21(rx9)-(13)). Existing facilities with AIF < 125 MGD have fewer application submittals. For such facilities, the Director must still determine BTA for entrainment on a site-specific basis and the applicant may supply information relevant to the ' Director's decision. Facilities are to submit §316(b) application materials to their Director along with their next permit renewal, unless that permit renewal takes place prior to July 14, 2018, in which case an alternate schedule may be negotiated. 1 Duke Energy Carolinas, LLC's (Duke Energy) Allen Steam Station is subject to the existing facility rule and, based on its current configuration and operation, is anticipated to be required to ' develop and submit each of the §122.21(rX2)-(13) submittal requirements with its next permit renewal in accordance with the rule's technical and schedule requirements. Within the ' §122.21(rX2)-(13) requirements, (rX4), (7), (9), (10) and (11) have specific requirements related to entrainment evaluations (refer to Table 1-1 for additional detail). This document provides an Entrainment Characterization Study Plan (ECSP) to support §316(b) compliance at the facility with consideration of these specific requirements. As a part of development of this Study Plan, Duke Energy submitted an earlier draft of this document to review by a subject matter expert in the field of fisheries(see Appendix B)and identified to the State as a peer reviewer. Duke Energy I 1 Entrainment Characterization Study Plan ��'] ` Allen Steam Station IWhile the equipment and methods contained in this Study Plan were developed with the intent to be implemented as written, changes to the Study Plan may be required based on facility Irequirements and/or situations encountered during execution. III Table 1-1. §316(b) Rule for Existing Facilities Submittal Requirements Summary Submittal Requirements Submittal Descriptions at •122.21 r (2) Source Water Physical Data Characterization of the source water body including intake area of influence. (3) Cooling Water Intake Characterization of cooling water system;includes drawings and narrative;description of operation; 1 Structure Data water balance. Source Water Characterization of biological community in the vicinity of the intake;life history summaries; (4) Baseline Biological susceptibility to impingement and entrainment;must include existing data;identification of missing data;threatened and endangered species and designated critical habitat summary for action area; I Characterization data identifies fragile fish and shellfish species list(<30 percent impingement survival). Cooling Water Narrative description of cooling water system and intake structure;proportion of design flow used; (5) System Data water reuse summary;proportion of source water body withdrawn(monthly);seasonal operation summary;existing impingement mortality and entrainment reduction measures;flow/MW efficiency. Chosen Method of Provides facility's proposed approach to meet the impingement mortalityrequirement(chosen fromCompliance with I (6) Impingement Mortality seven available options);provides detailed study plan for monitoring compliance,if required by Standard selected compliance option;addresses entrapment where required. Entrainment Provides summary of relevant entrainment studies(latent mortality,technology efficacy);can be (7) Performance studies from the facility or elsewhere with justification;studies should not be more than 10 years old without justification;new studies are not required. Provides operational status for each unit;age and capacityutilizations for the past five years; I (8) Operational Status upgrades within last 15 years;uprates and Nuclear Regulatory Commission relicensing status for nuclear facilities;decommissioning and replacement plans;current and future operation as it relates to actual and design intake flow. Requires at least two years of data to sufficiently characterize annual,seasonal,and diel variations I in entrainment,including variations related to climate,weather,spawning,feeding,and water column migration;facilities may use historical data that are representative of current operation of the Entrainment facility and conditions at the site with documentation regarding the continued relevance of the data 9 Characterization document total entrainment and entrainment mortality;includes identifications to the lowest taxon I • tudy j ssible;data must be representative of each intake;must document how the location of the intake the water body and water column are accounted for;must document intake flows associated with the data collection;documentation in the study must include the method in which latent mortality would be identified(including QAQC);sampling and data must be appropriate for a quantitative survey. I Comprehensive (10) Technical Feasibility Provides an evaluation of technical feasibility and incremental costs of entrainment technologies; &Cost Evaluation Net Present Value of facility compliance costs and social costs to be provided;requires peer review. Study I Provides a discussion of monetized and non-monetized water quality benefits of candidate entrainment technologies from(r)(10)using data in(r)(9);benefits to be quantified physical or Benefits Valuation biological units and monetized using appropriate economic valuation methods;includes changes in I .Study fish stock and harvest levels and description of monetization;must evaluate thermal discharges, facility capacity,operations,and reliability;discussion of previous mitigation efforts and affects; benefits to environment and community;social benefits analysis based on principle of willingness-to-1 pay;requires peer review. I (12 Other Impacts Non-Water Quality Provides a discussion of non-water quality factors(air emissions and their health and environmentalp noise,safety,grid reliability,Environmental and impacts,energypenalty,thermal discharge, consumptive water use, ) p Assessment etc.)attributable to the entrainment technologies;requires peer review. I I Duke Energy 12 IEntrainment Characterization Study Plan L�� Men Steam Station r'IMF" 1 I Documentation of external peer review,by qualified experts,of submittals(r)(10),(11),and(12). (13) Peer Review Peer Reviews must be approved by the NPDES Director and present their credentials.The applicant must explain why it disregarded any significant peer reviewer recommendations. IMONew Units Identify the chosen compliance method for the new unit. 1 .2 Study Plan Objectives and Document Organization IThe ECSP provided in this report was developed to support Allen's §316(b) compliance through development of a site-specific ECSP with the following key objectives in mind: I1. Collect data to support development of§122.21(rx9)which requires at least two years of entrainment studies be conducted at the facility; I2. Collect data to support development of §122.21(rX7) which allows for summaries of relevant technology efficacy studies conducted at the facility; and I 3. Collect data to support Duke Energy's objective of having data sufficient to evaluate biological efficacy of potential alternative intake technologies that may require site specific evaluations and support social cost-benefit analyses as a part of the I §122.21(rx10)-(12) compliance evaluations. While not a primary objective, the entrainment data gathered will help support development of I §122.21(rX4)which requires a listing of species and life stages most susceptible to entrainment at the facility. I To meet these objectives, this document provides summaries of the station's configuration and operations (Section 2), historical biological sampling efforts conducted at the facility that are relevant to cooling water intake evaluations (Section 3), a summary of Threatened and I Endangered Species identified near the facility (Section 4), a sampling program design justification based on this information (Section 5), the recommended study methods including key parameters of gear, schedule, frequency, and quality control procedures (Section 6), I references cited (Section 7), life history information on species likely to be entrained that supports reducing sampling from 12-months per year to 8-months per year (Appendix A), documentation of the subject matter expert review of an earlier draft of this study plan (Appendix IB), and a white paper on the use of pumped samplers in entrainment monitoring (Appendix C). I 2 Generating Station Description This section presents background information on the source waterbody(Lake Wylie)from which Allen withdraws cooling water and the design and operation of the cooling water intake Istructure. I2.1 Source Waterbody Lake Wylie was created in 1904 by damming the Catawba River near Fort Mill, South Carolina ' (Figure 2-1). The lake straddles the North Carolina — South Carolina border. The original dam IDuke Energy 13 ' Entrainment Characterization Study Plan Allen Steam Station was rebuilt in 1924 and the lake's surface expanded to approximately 13,440 acres and 325 miles of shoreline. The lake has a mean depth of 23 feet and a usable storage capacity of 40,145 acre-feet at a full pond elevation of 569.4 feet. The hydraulic retention time is approximately 39 days. Land use surrounding the lake is primarily residential, forested, and agricultural lands. In addition to supporting Wylie Hydroelectric Station, Lake Wylie supports Allen and Duke Energy's Catawba Nuclear Station by providing cooling water and a dependable municipal water supply for the cities of Belmont, North Carolina and Rock Hill, South Carolina. Lake Wylie extends from the base of Mountain Island Dam downstream to Wylie Dam and is one of eleven lakes on the Catawba River. Historical water quality assessments characterized Lake Wylie as a mesotrophic to eutrophic waterbody (Weiss and Kuenzler 1976; NCDEHNR 1994). Fluctuations in trophic classifications ' were attributed to temporal variations in meteorological conditions, closely linked to hydroelectric generation and watershed inputs. Inflows from the relatively large basin have led to spatial patterns of varying water quality within the reservoir. 1 1 Duke Energy 14 IEntrainment Characterization Study Plan I..)� Allen Steam Station Mountain Island Dam I 'N---f\-."--. — . $1* I ' rig" 2 Ilit(iiii WI' - SR-'255 1 l �;.c=qq , P • Y ' Mon --* Steam I n ' leadon take Nyle .� I \,...„.• 4/77 �aJ \p Gram b NORTH Ggpum I iv.........---.__...--1 11111111,4411t \ I OA ) -----_,. ...," ^eAcpA . _ �rece&a '' \\ I ..r" _. , In 0'4" Catawb.Nudes MOWAir N I ( +1.- !r' Willa Dam 0 1 2 A� >. �. f I i6,es )53 IS Figure 2-1. Allen Steam Station Vicinity Map (Source: Duke Energy 2014) I IDuke Energy 15 IEntrainment Characterization Study Plan F)� Allen Steam Station r 1 2.2 Station and Cooling Water Intake Description I Allen has five coal-fired units with a combined electric generating output of 1,145 megawatts (MW). Units 1 and 2 are rated at 165 MW each and began operation in 1957. Units 3, 4, and 5 are rated at 265 MW, 280 MW, and 270 MW, respectively and began commercial operation in 1 1959, 1960, and 1961, respectively. Units 1-5 operate in a once-through cooling mode. The design pumping capacity for the station is 861.1 MGD (Table 2-1). I Table 2-1. Allen Steam Station Design Intake Flow Rate by Unit and Daily Average Water Withdrawal from Lake Wylie, 2011-2014 I Design Flow Rate (MGD) Average daily water withdrawal (MGD)from Lake Wylie Unit 2011 2012 2013 2014 1 132.5 I2 132.5 3 198.7a ` 1 4 198.7 546.9 5 198.7 I Facility 861.1 1 2.2.1 Intake Structure Circulating water for all five units is withdrawn through a common CWIS located in a small 1 embayment along the west bank of Lake Wylie (Figures 2-2 and 2-4). The CWIS is approximately 246.5 feet long and is divided into 15 screen bays, three per unit. Each screen bay is 14 feet wide and equipped with a trash rack and traveling water screen. The trash racks at the face of the screen bays prevent large debris from entering the CWIS and damaging the traveling water screens. Each trash rack is approximately 14 feet wide. The steel I trash racks are made of 4 inch by 0.375 (i.e. 3/8) inch bars spaced 3 inches on-center, providing 2.6 inch clear openings. Cooling water for each intake passing through the trash racks then water flows through an isolation gate prior to reaching the traveling screens. The isolation gates 1 for Units 1 and 2 are 6 feet by 8 feet, and the Units 3-5 gates are 8 feet by 8 feet. Fifteen traveling water screens (three screens per unit) are located downstream of the isolation I gates. Each screen is 10 feet wide and incorporates #12 gage wire mesh with 0.375 inch square mesh openings (Figure 2-3). A high-pressure front wash spray system is used to remove impinged fish and debris from the traveling water screens. The wash water flows into a single 1 trough that travels approximately 370 feet back to the lake. The discharge point is approximately 770 feet southeast (i.e., on the downstream) of the CWIS. I The circulating water pumps are located downstream of the traveling water screens. Cooling water is drawn through the traveling water screens via ten cooling water pumps (i.e. two circulating water pumps per unit). The four circulating water pumps serving Units 1 and 2 are I IDuke Energy I 6 ' Entrainment Characterization Study Plan Allen Steam Station rated at 132.5 MGD (92,000 gallons per minute [gpm]) while the six circulating water pumps serving Units 3, 4 and 5 are rated at 198.7 MGD (138,000 gpm)for a total combined flow of 861 ' MGD (598,000 gpm) when all ten pumps are in operation. After passing through the condensers, heated effluent is returned to the lake via the South Fork arm (west of the plant) of the Catawba River(Figure 2-5). ' 24T-2- 50'UNIT 1-÷-49.8 UNIT -49'-8'UNIT 3- -48'UNIT 450'UNIT 5 j[ .11 1. ,j1 urrt SCREEN _ • _ L , 1 SSREEh GUIDES ;_ �f if` Lir f It : I GUIDES 0;1 LL 0' 20' 40' Figure 2-2. Plan View of Allen Steam Station CWIS (Alden 2012) Duke Energy I 7 IEntrainment Characterization Study Plan F)1 Men Steam Station I I i Z ILI LIJ OD N rtW CAD (71 I �•____;./I/a lI r ELY 58 .0' , .„ ' _ I r EL 580.0'Y 1 ._EL 575.8_' . ` I ,1 I n I YI ' r \ f \ • 1 Y/ 1I .- . I IY1 1 EL 5520' b I 1 i \. EL 547.75' l/- }'\ I ., . a ` I d EL 5455 1- , . Y A a Y EL 5420' I 0' S 10' 11.11111 I IFigure 2-3. Section View of Allen Steam Station CWIS (Alden 2012) I I 1 1 Duke Energy 18 INIII MN N 1 IIIIIII M = = M - i♦ IIIIIII - M E INIIII M - M Entrainment Characterization Study Plan FN Allen Steam Station \IltkItt ..... ....- 1\0'1, 4 , . 4 ,., , - ' iii -,,i-''.' ` ,1 ' r _.4� • s ,{ • 4 ', ..: .. , -,, . S LAKE '` WYLIE ' t� / ` t ' . ` cl A; EN EXISTING =,TEAM :1 ` •r CWIS TATION UIQ t. I IARi,F • -CANAL % r' l { 11. a t }i..K t u P • 0. yry _iiiii. S' W Y y gyp. &�• .� , ,IU {,n „ } h• '• • TTf : - r t- ,- Figure 2-4. Site Configuration of Allen Steam Station (Source: Alden 2012) Duke Energy 19 IINI M lid lid N M 111111 ININ N I I 1 I N N INNI I I N Entrainment Characterization Study Plan FINL Allen Steam Station r 411, t , ,; '*41 Or' 4 iii, • w.. I aa ., Allen CWIS R, . wc. 4 Discharge Canal ,, ', I4y , a .f: .: . , ..4 n. Et. 0AS'1 • . ,. 'ry "Y w *; :.''7••s. .,Y k' ' >I 1'.. '' a '11 1 y!;_ , ''.1";+,- "4 4" , r4-',-,'"' ♦.. y tt fi 4:0'' ''' w 1 � >�-' R sok'•` Aiiit y5, �:e a. A, .„. ,,,yr"..74..,. 'biek,#0 Ail. . - . if„ le.f`41,.,r,,, 4-4 i , --, A tt. _ r .ir ' k �`^rt ,may, -� ''�- y�g) � ,�'! E�' 1t,�� .wf+ .'7r� ,1 y,x�` 4r '44,:;,,...•._a•�'x ti n• "E�- t1` -Y• iR'! I x, + ,7t a I t t "t°+,i4+ :, i ,.;',.'• ;::' � �'"St"4 !'• I� +1.* �` A w l�� .. +" I }tii. 4 9 it., '6' v '!`J , • ! y ,;62-,,-,4;—"':::1)::,,,,t, Y' .�.. —" ,.,, 1 F . `' - _ Fish and Debris e "1 .<,iY K'�.R A.,-.-.* !'nR r:. t, iA ' • 'p° r''`aft• A-. -•' d" yr `f t .. • Return Po.; � ' s �rce USGS L - .... •�' :}��: a` ..•So u,[e.NASA NGA.OSCS .. ',� i Dort e:Esrl,glglta lGlo. �e,i [u� ` y USDA,USG S,A!%,Gclm'I.P1ny,As•Oq , ;. , 1 77016 SKr, � � �� mmun y Figure 2-5. Aerial View of South Fork portion of Lake Wylie (Image Modified from: ESRI) Duke Energy i 10 ' Entrainment Characterization Study Plan Men Steam Station 3 Historical Studies ' Duke Energy conducted extensive entrainment and ichthyoplankton sampling at Allen in the 1970s. The first entrainment study was conducted from September 1973 to July 1974. During this study, samples were collected at the intake and discharge 1 meter below the surface using a filter-pump system and 153 micron (pm) mesh netting. Sample volumes averaged 200 cubic meter (m3) per sample. No fish eggs or larvae were collected in the intake or discharge during ' the 1973-1974 study. However, lake sampling at five locations indicated that larvae were present from 27 March to 2 July in 1974. Lake samples were dominated by shad (Dorosoma spp.), sunfish (Lepomis spp.), Yellow Perch (Perca flavescens), and unidentified larval fish. Common Carp (Cyprinus carpio), buffalo (lctiobus sp.), redhorse (Moxostoma spp.), White Bass (Morone chrysops), Largemouth Bass (Micropterus salmoides), crappie (Pomoxis spp.), and Johnny Darter(Etheostoma nigrum)were also collected. ' Follow-up studies were conducted from 16 May 1975 through 24 August 1976. In this study, samples were collected from a 2-inch diameter gate valve located upstream of the water box on ' Unit 5's main condenser. Water flowed into a 794-pm plankton net suspended in a 55-gallon drum. Flow rates were determined by measuring the time required to fill the drum. Sample volume was calculated using flow rate and sample time to the nearest minute. In 1975, duplicate ' one-hour samples were collected during the day and night once per week. Average sample volume was 17 m3. In 1976, 24-hour samples were collected three times each week. Sample ' volumes averaged 450 m3. During 1975, 144 eggs and 18 larval fish were collected. Shad and White Catfish (Ameiurus catus) were the only species of larval fish collected. Eggs and/or larvae were present from 16 ' May to 22 August, which is essentially the entire period during which samples were collected. During 1976, 1,430 eggs and 288 larval fish were collected. Catch was dominated by shad, ' Yellow Perch, and catfish (lctalurus spp.). Based on time of year and size, all eggs were identified as shad. Fish eggs and/or larvae were present in entrainment samples from 20 March to 2 August. 4 Threatened and Endangered Species There are no State or Federal rare, threatened or endangered species or critical habitat designations near Allen. The U.S. Fish and Wildlife's map-based search tool (IPAC) was consulted to generate a resource report and determine the potential presence of Federally-listed ' species within Lake Wylie and the surrounding land (Figure 4-1; USFWS 2015). The only aquatic species identified was the endangered Carolina Healsplitter (Lasmigona decorate). However, the Carolina Healsplitter is usually found in mud, muddysand, or muddy gravel ' substrates along stable, well-shaded stream banks (USFWS 1996). The habitat near Allen's intake is not suitable to Carolina Healsplitter and it is not anticipated to reside anywhere near ' the Allen CWIS. Duke Energy 111 UEntrainment Characterization Study Plan �L Allen Steam Station r I . ',fancy L''w . Dallas \.. -\ �w�- Es r • Mo . bessemerCttY Holy,Pw 'lECK.I.. Cds A, 14 4 al, re ,,. I r� , - SII to, 1 ' Sit,' ' x itis 4k, Charlotte ' i 13 1 ff~ 4 ' / ¢ —J465-- .,n, ° :700:_ ' -11 , (,,,,,....,----7. I as % 1 rr m'rlr7. —w•4, 4",r ( 7 1 L. .nn..• H III IFigure 4-1. Geographical Boundary of the IPAC Search 1 5 Basis for Sampling Design p J J I HDR Engineering, Inc. (HDR) and Normandeau Associates, Inc. (Normandeau) participated in a site visit to Allen on April 23, 2015 to evaluate potential entrainment sampling methods and locations that would be practicable based on best professional judgment and previous I entrainment sampling. During the site visit, it was determined that pumped samples from within the CWIS would best represent entrainment rates at Allen. Sampling at the intake with a Ipumped-sampler eliminates the potential damage to or loss of organisms that can occur if organisms pass through the cooling water system and are sampled at the discharge. In addition, properly designed and operated pumped systems have shown collection efficiency of 95 I percent or greater for fish eggs and larvae with little or no organism damage (EPRI 2014). Two primary methods that have been historically used to estimate ichthyoplankton entrainment I at power plant intakes are utilizing streamed/towed nets and collecting pumped samples. Traditional ichthyoplankton nets can be used to filter water as it enters the intake and collect organisms. Alternatively, pumps can be used to convey water from the intake structure to a fine- I mesh net onshore. Onshore nets are suspended in a buffering tank to minimize damage and extrusion of eggs and larvae. I I Duke Energy 112 Entrainment Characterization Study Plan Allen Steam Station Each method has advantages and disadvantages and a comparison of the two methods are summarized in Table 5-1. Pumped sampling was selected as the preferred sampling method for ' Allen. The primary advantages of utilizing pumps at this location include metering precise sample flows, longer sample collection times, reduce the potential to miss samples due to inclement weather or other events, and increase the ability for technicians to safely observe net ' filtering and other aspects of the data collection. Pumped samplers are among the preferred gear types accepted by the EPA and have been used extensively to successfully monitor entrainment at power plant intakes for decades. Their versatility includes being utilized in fresh, estuarine, and marine water environments. Properly designed and operated systems can be accurate and effective. While no sampling method is perfect, we believe pumped samplers offer the best, most cost-effective, and consistent sampling method available for Allen. 1 t Duke Energy 113 ' Entrainment Characterization Study Plan Allen Steam Station ' Table 5-1. Advantages and Disadvantag4ne information adapted from EPRI 2014) Gear Type vantages ' Hoop Nets Deployed in the Intake - Large volurrrfined space of intake structures—precludes the use samples),ston nets, or Tucker trawls). - If net frame modifications to intake structures (e.g., frame- ' deploymel -No potentialers. less temporal variability as compared to pumped structure offer a small spatial sample. Multiple nets cost of additional samples to be processed in the rid (commonly used during ichthyoplankton ' majority of intakes. e. life stage (e.g., late larvae and early juvenile). ial for avoidance, but would require a larger ' to opening diameter in properly sized nets'. nples (no buffering tank). ' ys and associated safety concerns. Pumped Samplers in the Intake - 100 msame life stage(e.g., late larvae and early juvenile). variability i age to organisms during sampling. t - Limited mod the samoity, because pump inlets are generally smaller than - In-line flow n ' - Some poterr damage or ' - Fixed pipe a - Less potenti - Lower poter -Allows techr>I use of 330 required di 1 1 'A general rule of thumb,as described in EPRI 2014,states that tl to mouth opening diameter ratio of three or more. 1 Duke Energy 114 ' Entrainment Characterization Study Plan F)� Allen Steam Station ' While all sampling techniques are biased to some degree, the design of the Allen intake is ideal for pumped entrainment sampling. Potential disadvantages to pumped entrainment sampling at intake structures (compared to sampling at the discharge) have been studied by EPRI (2014). An explanation of how these potential disadvantages are minimized at Allen is provided in Table 5-2. Despite some potential disadvantages, pumped samples collected at the intake structure ' remain a better option than sampling at the discharge because: (1) organisms will be less damaged due to passage through the plant (resulting in a higher probability of taxonomic identification); (2) access to the intake structure is easier logistically; (3) lower velocities will ' result in less extrusion of larvae and/or damage to nets; and (4) safety issues and inclement weather will not be major factors resulting in lost sampling dates. ' Table 5-2. Potential Disadvantages of Pumped Ichthyoplankton Sampling at Allen Steam Station t Potential Disadvantage Sampling at Allen (as described in EPRI 2014) Non-random vertical distribution may Sampler at Allen will collect from the midway point of a relatively require depth-stratified sampling small intake opening. (see Section 6) ' Low water velocities at some CWIS my increase likelihood of active gear Intake velocities below the curtain wall at Allen are likely greater than avoidance for more motile larval and 1.0 fps reducing the potential for avoidance to occur. ' juvenile stages Potential uncertainty as to whether Only the late larvae and early juvenile fish might escape entrainment ' organisms were destined to be entrained below the curtain wall where velocities are likely greater than 1.0 fps. The recommended approach for Allen is to pump water from between the trash racks and the traveling screens to an entrainment sampling tank. The sampling system will utilize a fixed pipe with a single orifice located near mid-point between the bottom of the curtain wall (— El. 552.02) and the bottom of the intake structure (— El. 545.5) at —. El. 549. The vertical fixed pipe will be secured to the stop log I-beams using riser clamps on the pipe. The riser clamps will have I- beam clamps welded to them for fastening to the I-beams. Two identical pipes will be installed ' at Units 2 & 3 to allow flexibility in sampling (i.e., if one unit is not in operation on any given sampling trip, samples can be taken from the other unit). These locations are near the horizontal ' mid-point of the CWIS and will sample the units that have the highest capacity factors; resulting in samples that are representative of plant operation. Both sampling pipes will be equipped with quick-connect couplings to allow either pipe to be sampled from a single pump. The quick- connect couplings will also allow above deck piping to be removed between sampling events to facilitate on-deck access between sampling events. 2 Elevations in this document refer to Mean Sea Level 1 Duke Energy 115 IEntrainment Characterization Study Plan F) Allen Allen Steam Station r IEntrainment sampling will be conducted twice per month between March 1 and October 31 in 2016 and 2017. This period corresponds to when fish eggs and larvae are likely present in Lake I Wylie based on spawning characteristics of the species most likely to be entrained (see Appendix A). To account for potential shifts in spawning time periods, the sampling program will be run adaptively in response to entrainment densities. For example, if the densities of I entrainable organisms remain high during October 2016 sampling, additional sampling events will be added to the program in 2016 and the sampling period in 2017 will be extended accordingly. Similarly, if densities of entrainable organisms are high in early March 2016 when Ithe program is initiated, the 2017 sampling plan will be extended to begin earlier (e.g., February). As a result, the adaptive management plan will provide the greatest potential to collect representative samples throughout the entrainment season. I Each sampling collection event will be conducted over a 24-hour period with sample sets collected in four, 6-hour intervals. This sampling frequency will provide fish taxa, density Idistribution, and seasonal/diel variation in data collected over the two year period. Factors important to meeting §122.21(r)(9) requirements, along with a basis for how these Irequirements will be addressed at Allen, are summarized in Table 5-3. Table 5-3. Summary of Approach for Development of§122.21(r)(9) Required Entrainment ICharacterizations 122.21(r)(9)Requirement Basis for Meeting the Requirement I Two years of data and annual Evaluation of species and life stage composition and densities based variation on March through October 2016(Year 1)and March through October 2017 (Year 2)entrainment studies. I Seasonal variation Evaluation of monthly species and life stage compositions based on the Year 1 and Year 2 studies. Diel variation Evaluation of densities in 6-hour intervals in the Year 1 and Year 2 I studies. Variation related to climate and Evaluation of Year 1 and Year 2 data relative to water temperature weather and weather events(e.g., rain events) IEvaluation of Year 1 and Year 2 data to determine species and life Variation related to spawning, stage period of occurrence for spawning and feeding variation; feeding and water column Sampling from an area well mixed and representative of water I migrations entrained will account for depth variability by species and life stage for water column migrations. The resolution of taxonomic and life stage designations will be I Identification of lowest taxon monitored through regular evaluations of catch data with the goal of possible reducing percent of unidentified organisms and increasing resolution of genera and higher taxonomic designations. IData must be representative of each Sampling in Units 2 &3 are expected to be representative of the total intake CW IS. I A curtain wall in the intake extends to about 6.5 feet above the How the location of the intake in the bottom of the intake structure.A sample collected at the midpoint of water body is accounted for this opening will be well mixed and representative of the intake location within the waterbody. I IDuke Energy 116 IEntrainment Characterization Study Plan L)� Allen Steam Station 122.21(r)(9) Requirement Basis for Meeting the Requirement Document flow associated with the Facility will monitor flows for period of sampling for use in the final Idata collections report produced after sampling. Methods in which latent mortality will Latent mortality will not be evaluated as a part of the study and be identified therefore methods are not provided. IData must be appropriate for a Data will be expressed as taxon and life stage specific densities which can be multiplied by flow to support quantification of quantitative survey entrainment. I ll 6 Entrainment Characterization Study Plan 6.1 Introduction IThis section of the ECSP provides methods, materials, and procedures for entrainment sample collection and processing. A site-specific Standard Operating Procedure (SOP) will also be Ideveloped and serve as a companion document to this ECSP. The SOP will lay out detailed field sampling procedures, laboratory procedures, data quality assurance and quality control I (QA/QC), and database management. This will ensure field sampling and laboratory methods are adhered to and provide a base level of consistency with other plants in Duke Energy's fleet where entrainment sampling is required. I 6.2 Sample Collection I Entrainment sampling will be conducted twice per month between March 1 and October 31, in 2016 and 2017. This frequency should be sufficient to capture the annual, seasonal, and diel variability in entrainment with acceptable confidence levels (inferred from EPRI 2014). This I period corresponds to when fish eggs and larvae are likely present in Lake Wylie based on spawning characteristics of the species with the potential to be entrained and historic sampling described in Section 3 (see Appendix A). To account for potential shifts in spawning time I periods, the entrainment sampling program will be modified, if necessary, in response to entrainment densities. For example, if the densities of entrainable organisms remain high during October 2016 sampling, additional sampling events will be added to the program in 2016 and Ithe sampling period in 2017 will be extended accordingly. Similarly, if densities of entrainable organisms are high in early March 2016 when the program is initiated, the 2017 sampling plan will be extended to begin earlier (e.g., February). These adjustments, if necessary, will provide I the greatest potential to collect representative samples throughout the entrainment season. Coordination with station operations will be necessary to ensure pumps are scheduled to I operate for the duration of the sampling period in order to obtain representative density measurements. This twice per month sampling frequency should be sufficient to adequately describe seasonal patterns in entrainment as requested in the final §316(b) rule for existing Ifacilities. During each 24-hour sampling event, the Unit 2 or Unit 3 intake bay will be sampled (depending I upon which unit is in operation) within the following discrete 6-hour time intervals: 2100-0300 IDuke Energy 117 Entrainment Characterization Study Plan Allen Steam Station (night), 0300-0900 (morning), 0900-1500 (day) and 1500-2100 hours (evening). During each 24- hour sampling event, 2-hour samples will be taken within each of the above 6-hour sampling windows resulting in four samples during each sampling event. In the crepuscular periods, target sample collection times will be 1 hour preceding and 1 hour following sunrise and sunset. A total of 64 samples will be collected during each year over the entrainment season for a ' program total of 128 for the two years of study (Table 6-1). This sampling frequency will provide fish taxa, density distribution, and seasonal variation in data collection over the two year period. Table 6-1. Entrainment Sampling Details Details Units to be Sampled Unit 2 or Unit 3 Thirty-two(32)sampling events total(16 sampling events per year); Sampling Events(Days) twice per month; March 1 and October 31,2016 and between March ' 1 and October 31, 2017 . Daily Collection Schedule Samples collected within every 6 hours in a 24-hr period (4 collections/24-hr period) ' Targeted Organisms Fish eggs, larvae,and juveniles Depths Sample collected from the midpoint between the bottom of the intake ' structure and the bottom of the curtain wall (—El. 549). Sample Duration Approximate 2-hour samples collected within each 6-hour sampling interval. ' Number of Samples per Sampling Event(Day) Four samples per sampling day Total Number of Samples Sixteen(16)sampling events/year x 4 samples/sampling event (days)x 2 years= 128 samples 6.2.1 Location ' Entrainment samples will be collected from either the northern-most pump bay of Unit 2 or southern-most pump bay of Unit 3, which are immediately adjacent to one another. If both ' pumps are operational on a given sampling date, the Unit 3 pump will be selected preferentially, because it is more centrally located within the CWIS. The pipe sampler will be situated near the middle of selected intake opening, which should reduce the risk of turbulence and any hydrodynamic proceeses. Sampling near the middle of the intake opening will still allow for secure attachment of the sampling pipe. Samples will be collected between the trash racks and ' the traveling screens at -El. 549, which represents the near midpoint between the bottom of the curtain wall and bottom of the intake structure. (See Figures 6-1 and 6-2). The sampling pipe will be oriented with the opening forward facing and sized to allow the pump to reach the target ' pumping rate. The electric pump and buffering tank will be located on the CWIS deck south of Unit 2 with PVC ' or flexhose piping running on the concrete deck of the intake structure to the sampling locations for Units 2 and 3 (Figure 6-3). Changes or variations in the sampling location over the duration of the 2-year study will require Duke Energy notification and approval. Duke Energy 118 EN N NM 11111 11111 EN — NM H MN r MI MI N — — 1 1 NM Entrainment Characterization Study Plan �1� Allen Steam Station J ` C 24T.r I: 50'UNIT 1--41++-49W UNIT 2--e÷+-4w-r UNIT 3-s.f's 411'UNIT 4--+ --60r UNIT S i 1 !J I. � SCREEN !0 _ ®l i SCREEN ,IDES rig - -- .1 tii • ;i - - r i . g _ ,, I k, E E E Sampling Location i Sampling Location d 0. 20' 40' 6111W.11111 Figure 6-1. Plan View of the Allen Steam Station Cooling Water Intake Structure with Approximate Sampling Locations (Unit 3, Screen a and Unit 2, Screen b) (Image Modified from: Alden 2012) Duke Energy 1 19 IEntrainment Characterization Study Plan EN Allen Steam Station I I R 2 ' / b / (7 -n I \ / `� I, I I iEL 583.0' - � •• I EL 580.0' • , 1 r 5.8'7 i 1 1 I \ f . I s ISampling Point I 1 . (-El. 549) 1L..552.a I II �---- El_ ` 547 '5' of Flow IDirection I ELS S ' ' �� \�1 EL 542.0' Ia 5. 10' I IFigure 6-2. Section View of the Allen Steam Station Cooling Water Intake Structure with Approximate Location of Sample Inlet— Sampler pipe (in red) not Shown to Scale (Image I Modified from: Alden 2012) I I I Duke Energy 120 IEntrainment Characterization Study Plan EN Steam Station ~fir`;•.�Y m s ` '- . j, Electric Pump Flex-hose or :rte ; , - and Tank Piping 1 - -•--• -'" — Location Connecting - !_10„,.--4'4: —; i Pump to In i' ` M water Sampler „` r ,, Sampling ,--- �. .� Location �. Sampling M . - Location I Overflow Water Discharge _ �r Flex-hose or �..-.. Piping %_� ,. Connecting 1 Pump to In- water Sampler , IFigure 6-3. Aerial View Showing Approximate Locations of Sampling Gear (Image Modified from: Bing Maps) I The volume sampled will be measured using an in-line flowmeter. Depending upon pump flow rates, this sample will require approximately 2 hours to collect with additional time required to wash down nets and prepare the samples for shipping. These samples will be processed Idiscretely to investigate diel variability in ichthyoplankton composition and abundance. Pumped water from the sampler will be filtered through 330-pm plankton nets suspended in a Iwater-filled tank to reduce velocity and turbulence and prevent extrusion of larvae through the mesh. A larger mesh (e.g., 505 pm) may be used if net clogging precludes sampling with 330- pm mesh. An example ichthyoplankton sampler is shown on Figure 6-4. The proposed electric ' pump has been used successfully at other power plant intake structures to collect entrainment samples with little or no damage to eggs and larvae (Figure 6-5). Pump specifications are Iprovided below: • Capacity: 240 gpm; I • Range: 5 gpm — 380 gpm • 7.5 horsepower • Inlet diameter: 3 inches I • 230/460 volts • 18/9 amps • 3 Phase I • Length: 36 inches • Self Priming I • Suction Lift: approximately 25 feet IDuke Energy 121 IEntrainment Characterization Study Plan ��� Allen Steam Station I • Impeller: Urethane coated steel • Weight: 230 lbs 1 The net mouth will be suspended above the water line in the tank to prevent overflow and loss of organisms in the event of tank overflow. In an effort to minimize organism damage, the net I will be washed down at least twice during each 100 m3 pumped sample collection. Washdowns will be combined in the field to provide a single concentrated 100 m3 sample. If high debris buildup leads to net clogging then more frequent net washdowns may be required. The net and I collection cup will be carefully rinsed into sample jars with preprinted labels and preserved in 5- 10 percent formalin solution containing Rose Bengal stain. I Total sample volume, total sample duration, intake water temperature, dissolved oxygen, pH, and conductivity will be recorded on pre-printed field data sheets. Samples will be transported back to the laboratory for analysis under a required chain-of-custody, provided in the SOP. I I JOINT MUST SWIVEL APPROX.90" r 1 (POSSIBLY MORE) SAMPLE FLOW RATE-240 gpm I ,c77..--•,----=:-.--- ---- , -- ---- , 3"0 ADAPTER SOCKET I WOODEN CRADLES(typ.2) i [ ) 3'0 OVERFLOW DRAIN ISTAINLESS STEEL BANDS(typ.2) 330p ICHTHYO-NET ...9.:,�, / IINLINE ,,. / FLOW TOTALIZING 3"0 PVC VALVE METER (PVC SADDLE MOUNT) ` / 3"0 PVC Iv 330p ` ( 110 gal t�� .4—'---(PASSIVE DISCHARGE) COO END- III -1. POLYETHYLENE, L J BUCKET IM TANK „ . _– , j SAMPLER FLOW IN — _ /// //17;3// l//// /- 3"0 PVC NIPPLEpvc / / / /, / % ISCHARG£THROUGH NET) 3'0 RADIAL FLEX HOSE 3"0 QUICK-CONNECT 3'0 PVC VALVE INOT TO SCALE Figure 6-4. Example Entrainment Pump Sampling System Configuration I I I I IDuke Energy 122 IEntrainment Characterization Study Plan F)? Allen Steam Station I 1i 1 ,. f v -1 • ^ .;/.. a . / I pum •,,o I .11 - i I Figure 6-5. 7.5-Horsepower Electric Pump Used for Entrainment Sampling I6.3 Sample Sorting and Processing I Upon arrival in the laboratory, all ichthyoplankton samples will be logged on an lchthyoplankton Sample Control Sheet/Sorting Form. Because Lake Wylie is a freshwater reservoir, we do not anticipate shellfish larvae, as defined as commercially important crustaceans or bivalves, will be Ipresent in the samples. Therefore, procedures for identifying shellfish larvae are not presented. Before sorting, ichthyoplankton samples will be rinsed using a U.S. Standard Sieve with a mesh I size opening of less than or equal to 330 pm to remove excess detritus and formalin. All fish eggs and larvae retained on the sieve will be hand-sorted from the debris with the aid of an illuminated magnifier. Samples that are estimated to contain more than 400 fish eggs and larvae I (all taxa combined) will be split with a plankton splitter and to a subsample quota of about 200 eggs and larvae combined and then analyzed. The number of eggs and larvae present in the sample will be recorded. If possible, long-dead and/or non-viable eggs will be identified using Iappropriate and well-defined techniques identified in the SOP and categorized in the database accordingly. For example, the SOP may require that eggs collected live be whole, show signs of fertilization and not be covered with fungus at the time of their entrainment. Ichthyoplankton I from each sample will be placed in individually labeled vials and preserved in 5 to 10 percent formalin prior to taxonomic analysis. Examples of organisms identified as long-dead or non- Iviable will be stored in separate vials. Fish eggs, larvae, and juveniles will be identified using a dissecting scope equipped with a I polarizing lens. Identifications will be made to the lowest practical taxonomic level using current I Duke Energy 1 23 ' Entrainment Characterization Study Plan Allen Steam Station references and taxonomic keys (e.g., Auer 1982, Wallus et al. 1990, Kay et al. 1994, Simon and Wallus 2004, EPRI Larval Fish Identification Key http://www.larvalfishid.com/). Larvae and ' juveniles will be categorized as follows: • Yolk-sac larvae: Phase of development from the moment of hatching to complete absorption of the yolk; • Post yolk-sac larvae: Phase of development from complete absorption of yolk to development of the full complement of adult fin rays and absorption of finfold; ' • Juvenile: Complete fin ray development and finfold absorption. lchthyoplankton larval life stage will be identified as "larvae" if they are damaged to the point that they cannot be confidently classified as yolk-sac or post yolk-sac. For each diel (6-hour) sample, the following morphometric data will be collected: ' • Up to 10 yolk-sac, post yolk-sac and "larvae" of each fish species will be measured for total length, greatest soft tissue body depth, and head capsule depth to the nearest 0.1 mm. Among dorso-ventrally compressed organisms whose body or head capsule width exceeds the body or head capsule depth, soft tissue body and head capsule width will also be measured to the nearest 0.1 mm. ' • Up to 10 eggs of each taxon will be measured for minimum and maximum diameter to the nearest 0.1 mm. ' Only whole organisms will be subject to morphometric evaluations. If more than 10 eggs or larvae are present, a random subset of each species and life stage will be measured. Length measurements will be performed with a calibrated ocular micrometer or other calibrated tool ' (e.g., ImageToolTA° Software). Organism identification will be cross-checked using the QC procedure described below. 1 6.4 Data Management ' Field and laboratory data will be recorded on forms compatible for computer entry and data processing activities will be recorded on log sheets for each batch of data. A digital image of the datasheet will be taken in the field prior to the datasheets leaving the site. Data sheets will be ' inspected for completeness prior to data entry. The data will be entered using a double data entry software, a feature that ensures entry errors will be caught and corrected as the operators key the data. Using this procedure, data sets are entered twice in succession and the software compares the first and second entries and identifies any discrepancies. Discrepancies must be resolved before the second data entry can continue. Keyed data sets will be error checked. If ' any errors are encountered, they will be corrected in the database. Once the database is cleared of errors, the data file compared to the data sheets will be audited to ensure an Average Outgoing Quality Limit (AOQL) of 1 percent (>_ 99 percent accuracy). The data set will then be ' ready for the production of summary tables, which will be proofed to confirm that the summary program worked properly. The data editor will sign and date each proofed summary table and include notations as to which values were verified. ' Duke Energy 124 ' Entrainment Characterization Study Plan Ln Men Steam Station 6.5 Data Analysis ' Data analysis will be performed using the QAQC'ed database and will include summaries of proposed vs actual samples collected, sample volumes, entrainment densities, morphometric measurements, and water quality parameters. Generally, minimum, average or median, and ' maximum values will be provided by sample event or month. Collection densities, expressed as number per 100 m3, will be calculated from entrainment catch data for each taxon and life stage by month of sampling, sample event (i.e., including all samples collected within a 24-hour ' period), and by six hour diel intervals (e.g., 2100-0300 [night], 0300-0900 [morning], 0900-1500 [day] and 1500-2100 hours [evening]) across all sampling events. Average concentration of organisms per unit volume in the hth stratum (i.e., month, sample event or six hour interval),Xk , will be calculated as: 1 " )37 = n ixm nh where: ' nh = the number of samples in the hth stratum xh, is the i'" observation in the hth stratum. ' Next, these densities will used to estimate the total entrainment at cooling water intake based on design and actual intake flows. The estimated total entrainment will be calculated in the following manner. First, the average concentration of organisms per unit volume in the h1h month will calculated using the equation provided above. The total number entrained (E) during the sampled months will then then calculated as: H E= EVASell n=t ' where: ' H = total number of months sampled Vh = volume of water withdrawn by the station in the hth stratum. ' 6.6 Field and Laboratory Audits Prior to the first scheduled sampling, an experienced senior staff member will accompany and ' train field personnel, including: protocols for site access and contact with facility personnel; safety requirements as contained in the Health and Safety Plan, implementation of the field SOP including the operation of the pump samplers, sample collection, sample preservation, proper datasheet documentation, chain-of-custody, and shipping. At this time, a readiness ' Duke Energy 125 Entrainment Characterization Study Plan L1� Allen Steam Station rJ review will be conducted to ensure that trained personnel, required equipment, and procedural controls are in place. In addition, equipment will be tested to ensure its proper operation. ' After initiation of sampling, two trained QA staff members (one each from HDR and entrainment sampling contractor) will each conduct separate independent QA audits to ensure that the SOP ' is being implemented correctly. Results of the audit will be summarized in a technical memo. This memo will categorize deviations from the SOP into three categories: (1) those that do not affect the quality of the data, (2) those that may affect the quality of the data, and (3) those that ' affect the quality of the data. Variances from approved procedures will be documented and corrected, either by modifying the SOP to address systematic problems or by testing and/or retraining staff, as necessary. Any changes to the SOP will be discussed with and agreed upon by Duke Energy representatives before being implemented in the field. Partway through the sampling program a trained QA staff member from HDR will conduct an independent QA audit ' following the same procedures to provide on-site training, to observe sampling activities, and to verify that the project's SOP is being followed. In addition, senior staff will observe initial laboratory and data management activities to verify the same. Implementation of the laboratory SOP will be overseen by a senior laboratory manager who will also ensure that staff technicians have been properly trained. Once during each year of ' sampling, an independent QA trained HDR employee will conduct an audit to ensure that the SOP is followed. These audits will include safety, sampling procedures, sample processing, and identification. Audit reports will be prepared and any substantial shortcomings identified will be addressed prior to the next sampling event. Samples from the first collection event will be analyzed prior to the initiation of the second event to ensure that organisms are being collected with limited damage to allow identification. 1 6.7 Laboratory Quality Control ' Quality control methods for split, sort and identification of ichthyoplankton will be checked using a continuous sampling plan (CSP) to assure an AOQL of 10% (a90% accuracy). Identification checks will be inspected using a QC procedure derived from MIL-STD (military-standard) 1235B ' (single and multiple level continuous sampling procedures and tables for inspection by attributes). Detailed methods for quality control will be provided in the SOP developed by the entrainment contractor. The QC checks will be recorded on appropriate datasheets and these ' records will be maintained for review. Samples will be stored for a minimum of three years after the end of the project or longer if Duke Energy requests additional storage time. ' 6.8 Reporting During the study, monthly progress updates will outline the status of the on-going sampling and laboratory processing. At the end of the first year of study, preliminary results of testing will be provided to Duke Energy, which will include entrainment estimates by month and diel period using design intake flow. At the completion of the study, a comprehensive report describing all aspects of the study program (facility description, study design, sampling methods, data analysis methods, and results) will be generated. The final report will include all tables, figures, photographs and engineering drawings as necessary to fully document the evaluations ' Duke Energy I 26 ' Entrainment Characterization Study Plan )1 Allen Steam Station r conducted. Included will be estimates of entrainment by species, life stage, month, and diel period under design and actual intake flows. The report will be organized with supporting information and detail in attached appendices, as needed. 6.9 Safety Policy ' All work performed under the direction of Duke Energy on Duke Energy properties and/or on properties owned or operated by third parties (i.e., not owned or operated by the contractor or ' Duke Energy) will be performed using safe work practices that are at least equivalent to those required for Duke Energy personnel and of any third party owner or operator. At a minimum, all contractors are expected to be aware of, and adhere to, Duke Energy's Corporate Safety Policy, and other location-specific safety policies and procedures. 1 1 1 1 1 1 Duke Energy 127 Entrainment Characterization Study Plan Allen Steam Station ImLn 7 References ' Alden Research Laboratory, Inc. (Alden). 2012. Generating Station Assessment Draft 316(b) Rule Compliance Options, Allen Steam Station. Prepared for Duke Energy and the Electric Power Research Institute. ' Auer, N.A. (ed.). 1982. Identification of Larval Fishes of the Great Lakes Basin with Emphasis on the Lake Michigan Drainage. Great Lakes Fisheries Committee Special Publication 82-3, Ann Arbor, MI. 744 pp. Duke Energy. 2014. Assessment of Balanced and Indigenous Populations in Lake Wylie near Allen Steam Station. Duke Energy, Environmental Services. Huntersville, NC. EPRI (Electric Power Research Institute). 2014. Entrainment Abundance Monitoring Technical Support Document. Updated for the New Clean Water Act §316(b) Rule. 3002001425. EPRI, Palo Alto, CA. ' Kay, L.K., R. Wallus, and B.L. Yeager. 1994. Reproductive Biology and Early Life History of Fishes in the Ohio Drainage. Volume 2: Catostomidae. Tennessee Valley Authority, Chattanooga, TN, USA. ' North Carolina Department of Environmental and Natural Resources, Division of Water Quality (NCDENR-DWQ). 2010. Catawba River Basin Plan: Basin Overview. Raleigh, NC, ' September 9, 2010. North Carolina Department of Environment, Health, and Natural Resources (NCDEHNR). 1994. ' Basinwide assessment report support document, Catawba River basin. NCDEHNR, Water Quality Section, Raleigh, NC. ' Simon, T.P. and R. Wallus. 2004. Reproductive Biology and Early Life History of Fishes in the Ohio River Drainage, Volume 3: lctaluridae—Catfish and Madtoms. CRC Press. 204 pp. ' U.S. Fish and Wildlife Service (USFWS). 2015. Information for Planning and Conservation (IPaC) Report for Allen Steam Station (Lake Wylie). Generated November 05, 2015. ' . 1996. Recovery Plan for Carolina Healsplitter (Lasmigona decorata). U.S. Fish and Wildlife Service, Southeast Region, Atlanta, GA. 30 pp. Wallus, R., B.L. Yeager, and T.P. Simon. 1990. Reproductive Biology of Early Life History Fishes in the Ohio River Drainage, Volume 1: Acipenseridae through Esocidae. Tennessee Valley Authority, Chattanooga, TN. 273 pp. ' Weiss, CM and EJ Kuenzler. 1976. The trophic state of North Carolina Lakes. University of North Carolina, Water Resources Research Institute. July 1976. Chapel Hill, NC. 1 Duke Energy l 28 IIIII N i 1 — — M M I MI — M M MO l— — OM INN INS Entrainment Characterization Study Plan L1� Allen Steam Station rJ APPENDIX A - Select Species Spawning and Early Life History Data Sampling for entrainment year-round at Allen is expected to be a poor allocation of resources, since few if any eggs or larvae are likely to be present in Lake Wylie during the winter months. Several species were identified as likely to be present in entrainment samples and life history information for these species is summarized here and supports a sampling period of March through October. It is important to note that low densities of entrainable organisms at the outset and conclusion of the sampling period are unlikely to change the estimates of entrainment in any meaningful way and thus do not warrant the additional sampling costs necessary to extend the sampling season. NCDENR Young-of- Spawning Spawning Habitat/ Egg Fecundity the-Year Cut- Larvae Species Period Nest Structure Characteristics Rates off Lenghts Size References Family Centratchidae Bluegill Spring and Early Shallow waters with Adhesive Up to 60,000 <50 mm YS 4-6 mm 2, 3 (Lepomis Summer sand and gravels. eggs macrochirus) Average PYS 7-14 Water Nests are saucer- diameter: 1.0-1.4 mm Temperatures 70- shaped depressions mm 75°F in sand or gravel. Black Crappie Spring Shallow calm Demersal and 3,000 to <75 mm YS 2-4 mm 1, 2, 3 (Pomoxis waters near adhesive 188,000 eggs nigromaculatus) vegetation or cover. PYS 3-18 Average mm Depression in sand diameter: 0.93 or gravel mm Green Sunfish Spring and Early Shallow waters with Demersal and Up to 50,000 <50 mm YS 3-6 mm 2, 3, 4 (Lepomis Summer sand and gravels. adhesive eggs cyanellus) Nests are saucer- PYS 7-11 Water shaped depressions Average mm Temperatures 60- in sand or gravel. diameter: 80°F 1.O to 1.4 mm Duke Energy 129 n MI 1 MI all all OM OM MI I MS OM EN N NM = 1 N M Entrainment Characterization Study Plan �� Allen Steam Station r NCDENR Young-of- Spawning Spawning Habitat/ Egg Fecundity the-Year Cut- Larvae Species Period Nest Structure Characteristics Rates off Lenghts Size References Largemouth Bass Early Spring Shallow water on Demersal and 5,000 to <100 mm YS 3-8 mm 2, 3,4 (Micropterus bottoms composed adhesive 43,000 eggs salmoides) Water of sand, gravel, or PYS 6-16 Temperatures 60- pebbles near cover. Average mm 75°F Nests are circular diameter: and clear of organic 1.4 to 1.8 mm debris and silt. Redbreast Spring and Early Shallow water on Demersal and Up to 14,000 <50 mm PYS 7-11 2, 3, 4 Sunfish Summer bottoms composed adhesive eggs mm (Lepomis auritus) of sand, gravel, or Water pebbles near cover. Average Temperatures 65- Nests are saucer- diameter: 75°F shaped depressions 1.8 to 2.1 mm in sand or silt. Redear Sunfish Spring Shallow water on Adhesive 2,000 to <50 mm YS <5 mm 2, 3, 5 (Lepomis firm substrates often 10,000 eggs microlophus) Water in locations exposed PYS 5-15 Temperatures 68- to the sun. Nests Average mm 70°F are depressions in diameter: sand to soft mud in 1.3 to 1.6 mm areas containing aquatic plants. Family Clupeidae Gizzard Shad Spring and Early Shallow water. Demersal and Up to 50,000 <100 mm 2, 3 (Dorosoma Summer adhesive eggs cepedianum) Eggs broadcast in open water. Duke Energy 130 M E I IIIIIII M OM M M MO E MO OM NM I OM M M I NM Entrainment Characterization Study Plan FIN Steam Station NCDENR Young-of- Spawning Spawning Habitat/ Egg Fecundity the-Year Cut- Larvae Species Period Nest Structure Characteristics Rates off Lenghts Size References Threadfin Shad Spring and Early Eggs broadcast Demersal and 2,000 to <100 mm YS 3-7 mm_ 2, 3, 4 (Dorosoma Summer over plants or loose semi-adhesive 24,000 eggs petenense) sediments. PYS"6-20, Water Average mm Temperatures 60- diameter: 0.75 to 80°F 1.2 mm Family Cyprinidae Golden Spring through Eggs are scattered Adhesive 10,000 to <75 mm YS 3-6 mm 2, 3, 6 Shiner Late Summer over filamentous 20,000 eggs (Notemigonus algae or rooted Average PYS 5-11 crysoleucas) Water aquatic plants and diameter: 1.0 mm mm Temperatures sometimes over >70°F nest of largemouth bass. Common Carp Spring and Early Eggs scattered in Demersal and 36,000 to <150 mm YS 3-8 mm 1, 3, 4, 8 (Cyprinus carpio) Summer shallow waters with adhesive 2,000,000 aquatic vegetation, eggs PYS 8-21 dilt Water mud bottoms, and Average . mm Temperatures 60- over debris; open diameter: 1.5 to 80 °F waters 2.1 mm Whitefin Shiner Spring and Early Shallow waters with Demersal and 10,000 to <50 mm 2, 4 (Cyprinella Summer typically with adhesive 20,000 eggs galactura) filamentous algae or Water root aquatic plants. Average Temperatures Eggs are deposited diameter: 1.6 mm >68°F beneath bark, in crevices of rock, or on the undersides of logs, rock, or other structures. Family Morodidae Duke Energy 131 IIIIII - MI IMIN = N MN MN M Entrainment Characterization Study Plan L_1� Allen Steam Station rJ NCDENR Young-of- Spawning Spawning Habitat/ Egg Fecundity the-Year Cut- Larvae Species Period Nest Structure Characteristics Rates off Lenghts Size References White Bass Spring Shallow waters on Eggs are Adhesive 60,000 to 75-126 1,4,6 (Morone stream or reservoir deposited over 900,000 eggs mm Chrysops) bottoms sands and gravel. Average Water diameter: Temperatures 0.8-0.9 mm >60 (°F) Family Percidae Yellow Perch Late Winter or Shallow waters with Demersal and 23,000 eggs <80 mm YS 8-20 1, 3, 8 (Perca Early Spring moderate adhesive mm flavescens) vegetation; Eggs deposited over PYS 8-21 submerged plants, mm logs, gravel, and rocks; eggs laid in log "ropes." Family lctaluridae White Catfish Early Summer Shallow waters Demersal and 10,000 to <50 mm 1 (Ameiurus catus) typically filamentous adhesive 20,000 eggs Water algae or rooted Temperatures aquatic plants; Eggs 65-75 °F are deposited Average diameter beneath bark, in 1.6 mm crevices of rock, or on the undersides of logs, rock, or other structures Duke Energy 132 ' Entrainment Charaderization Study Plan Allen Steam Station 1 ' Life History References 1) Rohde, F.C., R.G. Amdt, D.L. Lindquist, and J.F. Pamell. 1994. Freshwater fishes of the ' Carolinas, Virginia, Maryland, & Delaware. The University of North Carolina Press. Chapel Hill, NC ' 2) //www.flmnh.ufl.edu/fish/gallery/Descript/BlackCrappie/BlackCrappie.html 3) Auer, N.A. 1982. Identification of larval fishes of the Great Lakes Basin with emphasis on the Lake Michigan drainage. Great Lakes Fishery Commission, Ann Arbor, MI 48105. Special Pub. 82-3 744 pp. 4) Hendrickson, Dean A., and Adam E. Cohen. 2015. "Fishes of Texas Project Database (Version 2.0)" doi:10.17603/C3WC70. Accessed (insert date). 5) Carlander, K.D. 1977. Handbook of freshwater fishery biology. Vol. 2. The Iowa State University Press, Ames, IA. 431 pp. 6) Ross, S. T. 2001. The Inland Fishes of Mississippi. University Press of Mississippi, ' Jackson. 7) Wang, J.C.S and R.J. Kemehan. 1979. Fishes of the Delaware Estuaries. A guide to the early life histories, Towson, MD. pp. 410. ISSN 0-931842-02-6. 8) Animal Diversity Web. http://animaldiversity.org/ 9) Lazur A.M. and F.A. Chapman. 1996. Golden shiner Culture: A reference profile. Department of Fisheries and Aquatic Sciences, Florida Cooperative Extension Service, Institute of Food and Agricultural Sciences. University of Florida. 1 1 1 Duke Energy 133 ' Entrainment Characterization Study Plan Allen Steam Station APPENDIX B - Response to Informal Review Comments While not required to be peer reviewed under the Rule, Duke Energy engaged subject matter ' experts to informally review this Entrainment Characterization Study Plan. The purpose of the informal review was to afford the Biology Peer Reviewer the opportunity to evaluate the entrainment study objectives and methodology, and to comment if the proposed methods do not t meet industry standards. Duke Energy's intent was to ensure that if data were collected as detailed in the ECSP that the data would be sufficient for the intended use in the Best Technology Available (BTA) determination process required in §122.21(r)(10)-(12), and would ' not be questioned at a later time. In order to help focus the review, charge questions were developed (Table B-1). The primary ' goal was to develop a study that meets the objectives of the Rule-required Entrainment Characterization Study. Table B-1. Directed Charge Questions Question Entrainment Characterization Study Response Comments(if any) ' Number Plan Will the proposed sampling depth(s) Yes/No 1) and location provide for a representative sample of the water ' column? Considering fish and shellfish known or Yes/No expected to be in the source waterbody, ' 2) will the proposed sampling period (months) provide the ability to understand seasonal variations in entrainment? ' Is the sampling equipment proposed Yes/No 3) appropriate to collect entrainable organisms at this type of intake ' structure? Does the plan lay out QA/QC Yes/No 4) requirements clearly? Are these requirements adequate? Identifying eggs and larvae to species is Yes/No often difficult and sometime impossible. ' Does the sampling plan provide 5) sufficient measures to preserve organism integrity and support identification to the lowest taxon ' practicable? Does the study design meet the Yes/No 6) requirements of the Rule at 40 CFR ' 122.21(r)(9)? Duke Energy 134 ' Entrainment Characterization Study Plan Allen Steam Station Question Entrainment Characterization Study Response Comments(if any) Number Plan ' Will the study design provide sufficient Yes/No data to support a benefits analysis of 7) entrainment reducing technologies required to be evaluated by the Rule ' including biological performance as required in 40 CFR 122.21(r)(11)? Are there any deficiencies in the stud > Yes/. plan that might prevent you or others 8) (e.g., Regulators) from understandin what is being proposed for sampling? I so,what needs to be added or clarified?' After receipt of the peer reviewer's comments, the following responses were developed and the ' ECSPs were updated to reflect those changes. Comments were divided into four categories as follows: ' • Category 1: Comments that are clearly applicable (i.e., relevant under the charge and improve the quality of the work product). These comments were incorporated into the ECSP. ' • Category 2: Comments that represent a misunderstanding by Informal Reviewers. These comments were not incorporated into the ECSP. ' • Category 3: Comments that are minor and do not materially change or lend additional value to the ECSP (e.g., comments that were meant as "FYI", or meant as preferential suggestions, or are beyond the scope of the charge). These comments may or may not ' have been incorporated into the ECSP at the discretion of the Report Originator. • Category 4: Major Peer Reviewer comments that the Report Originators do not agree with and choose not to incorporate into the ECSP. Below are the site-specific responses to comments received on the Allen ECSP. I 1 ' Duke Energy 135 . Entrainment Characterization Study Plan Allen Steam Station ITable B-2. Peer Reviewer Responses to Directed Charge Questions Category Charge No. Comment Response and Resolution I3 f Given the design of this CWIS a single orifice for the in-water sampler,at the depth proposed, is adequate to obtain a No response required. representative sample. I Regarding the location(s)of sample collection I agree that samples from the pump bays of Units 2 and 3 should be To the extent possible the entrainment sampling pipe will be placed in an area of the intake that is representative for this CWIS. From the information provided it appears that the sampler orifice will be situated near the ' well mixed and typical of hydraulic conditions within the intake.That is,away from structures that middle of the intake opening,well away from the walls or other physical structure of the bays.This should minimize the.: ,could be causing vortices(highly turbulent areas)or in eddies or other areas of stalled flows.At risk that flow at the collection point might not be representative of flow across the mouth of the intake in general due to _ some facilities we may be limited by where we can access the intake(e.g.,a facility with an existing I eddies,turbulence or other hydrodynamic processes. If there is any question about this,a few strategically located access grate on the deck would be used preferentially to cutting through the concrete decking). In "' measurements with a current meter may be sufficient to confirm it. many cases,best professional judgment can be used. If velocity measurements are warranted they will be undertaken. I Note:midway between the bottom of the curtain wall(-El. 552.01)and 1 the bottom of the intake structure(-El.545.5) 1 1 is at El. 548.75, so closer to 549 than 548;so better to say at-549,or at least indicate sampling will occur near the ECSP was changed to indicate both-549 and near the midpoint midpoint. The proposed sampling period and frequency are appropriate to encompass the periods when fish eggs and larvae are I likely to be present,and to provide information on seasonal patterns of entrainment(but see concerns regarding the No response required. Concerns addressed below in Question 3. need for sample replication in response to question 3). 1.111111111 The historical data indicate that white catfish larvae were collected in entrainment samples in 1975-1976, but no life I 2 history information on them is provided in Appendix 1.You might want to consider adding that,to document that the Additional species were added to Appendix A proposed sampling period would encompass their spawning period. _, It isn't clear why life history information is provided for some species and not others. Detailed life history information of I the type provided is reasonable for the primary entrainment candidates,but at least limited,key information ought to provided on the other species present in the reservoir.Consider providing a complete species list in table form that This is an excellent idea.This was added to this and other ECSPS See tablular format of Appendix gives the spawning period for each species,the kind of eggs and larvae they have(e.g.,adhesive eggs, pelagic larva A and other key relevant information,along with the source reference(s),to provide some evidence that the sampling I " period is sufficient for all of them.That would be more valuable than extensive narratives on each species that include ""' information that isn't particularly relevant. Pump sampling has been used in a variety of settings to sample zooplankton and fish early life history stages.However, I sampling efficiency of pump sampling is likely to be different(likely lower)than traditional net sampling approaches. Traditional net deployment and retrieval methods may not be feasible in the intake bays, but if a judicious number of 4 3 samples could be collected with another method,at a time when densities are relatively high),that would go a long way Please see white paper on use of pumped samplers and a comparison of their performance to nets toward addressing any concerns about if,or how much,this method underestimates actual entrainment. If such (Appendix C). I comparisons are already available from other studies, so much the better;note them.Another approach that might allow a useful comparison would be to collect samples using a Schindler-Patalas trap. However,this gear samples a very small volume of water,so even at peak densities it may not be feasible. I pow , - - - • •- ,• - Allen,where sampling will happen at only one depth the bottom of the sampling pipe will be a 3- inch diameter elbow with the open end facing into the incoming current. it would be difficult to simulate the flow field conditions from a power plant in a laboratory setting. I Presumably one would want to test at the approach velocities similar to levels in the field.This What size will the orifice be,and what will the flow velocity be at the opening(not the normal flow through the intake,bwould require a test flume with flow control to achieve the desired test velocities.Since one would the flow into the orifice)? Both could affect capture efficiency,given escape behaviors and rheotaxis exhibited by larval. be removing organisms and water while sampling,one would have to develop a method to replace fish.If this is a concern,it might help to have the sampler intake end in a flange that widens out from the orifice. If the removed organisms and water. If you use a recirculating flume,so only the volume of water I necessary,test runs could be done in the lab,sampling larvae of a known density out of a tank. removed would need to be replaced,then that replacement water would have to seeded with organisms of a known number.The test pump would be removing 240 gallons per minute,so your total capacity in your flume would likely need to be at least 5x this volume,if not much higher (otherwise the pump sampler would be inducing flows not the circulating pump on the flume). If you I ant to test different species,life stages and/or organism sizes,then several tests would be •.At required.What at first glance appears to be a simple test,is actually quite complicated. t,---11,..--- —MIMI If a 330-pm mesh net works without clogging,that would be ideal;but if problems occur then use of a-500 pm mesh 1 311.1111111 net would be acceptable for egg and larval fish collections.That mesh size is often used in larval fish collections. We agree. rmukP FnPrn,I 3fi 111 Entrainment Characterization Study Plan Allen Steam Station ICategory Charge No. Comment Response and Resolution The lab and field SOP and audit plans are generally sound.However,an Average Outgoing Quality Limit(AOQL)of 1% I (?99%accuracy)strikes me as rather liberal for data entry. It seems to me that an error rate of one error per 100 Typically the average outgoing quality(AOQ)is better than the AOQL. Both this and the AOQL for entries is too high. How does it compare to the observed error rate on similar work(I expect actual accuracy is typically larval identification are industry standard for entrainment sampling. better than that)? If it is feasible to commit to a lower error rate that would be preferred. I The sampling plans implemented under our proposed QC procedures have a specified average Likewise, an AOQL of 10 percent for organism identification seems pretty high to me(I expect the error rate will be outgoing quality limit(AOQL)of 10 percent,which represents the maximum fraction of all items lower than that for experienced personnel). I recognize that identifying fish eggs and larvae is tricky, so I fully expect (e.g.,measurements,taxonomic identifications or counts)that could be defective as a worst case.A some individuals to end up in broader categories(e.g., unidentified shiners or unidentified larvae)- I don't consider that I 4 defective item could be a measurement or count that falls outside of a specified tolerance limit(e.g., plus or minus 1 to 10 percent).Typically the average outgoing quality(AOQ)is better than the an identification error. But I would expect organisms identifiable to a given taxonomic level to be correctly classified AOQL. Items are inspected using a QC procedure derived from MIL-STD(military-standard)1235B more than 90%of the time.Again,what is the observed error rate on similar analyses? Maybe my expectations are too (single and multiple level continuous sampling procedures and tables for inspection by attributes)to high. the 10 percent AOQL .Both this and the AOQL for data entry are industry standard for entrainment I sampling. The data security and chain-of-custody plan is good,but one can never be too careful.Data remain vulnerable to loss 1 4 during the period when they exist only on one hardcopy datasheet,particularly while still in the field.You might consider This is a good idea.We added words that a digital image of the datasheet will be taken in the field 111 taking a picture of each datasheet when completed,to have an electronic backup until the datasheet can be scanned or prior to the datasheets leaving the site. entered into a computer. 1 4 Given that regulatory compliance is sometimes the subject of litigation, I think that retaining samples for only three years ECSP was revised to indicate samples will be held until Duke Energy authorizes their disposal. I is not sufficient. My sense is that something on the order of seven years would be a better safeguard. 3 5 Adequate information is provided to document that the specific pump to be used are of the type that will not cause No response required. organism damage as noted in EPRI(2005). I 3 6 Proposed preservation methods will fix organisms in a manner that will maintain their morphological integrity for No response required. identification purposes. The proposal indicates that"To the extent practicable, long-dead,moribund,and/or non-viable eggs will be identified I >using appropriate and well-defined techniques developed in the SOP and categorized in the database accordingly. When estimates of entrainment are generated,moribund,dead,and non-viable individuals will not be included." The ;Agreed.We will look at the data inclusive and exclusive of our two categories and both will be discrimination of dead,moribund or non-viable eggs from live eggs is a critical step because it directly affects ;preserved for future inspection.At present there are few reliable methods that are not time entrainment estimates. Differences between live and dead individuals are often fairly obvious in fresh samples, but can ,consumptive or expensive to implement.Here we are thinking of excluding only the most obvious I <be markedly reduced after preservation. Because any error in this process will bias entrainment estimates downward I f ]categories of organism.For example,we might require eggs be whole,show signs of fertilization, 'expect this step would receive heightened scrutiny.Therefore the methodology should be fully explained,and be pretty i and not be covered with fungus. iron-clad. Even if it is, I certainly recommend retaining both groups of eggs in separate vials,and be prepared to provide entrainment estimates based on both groups combined as a conservative measure of entrainment if necessary. IIIThe final Rule does not require replication nor is there an obligation to provide confidence intervals or bounds around the entrainment estimates generated. The study must be sufficient to show diel, monthly,and annual variation,which this study plan addresses. IWe interpret the Rule as requiring sufficient sampling to collect data over the range of conditions The Rule requires"sufficient data to characterize annual, seasonal, and diel variations in entrainment, including but not that are likely to occur and to prevent bias through selective sampling. For example, you could not limited to variations related to climate and weather differences, spawning, feeding, and water column migration." The Propose to sample only during the day, because you would miss any density differences due to diel U proposed sampling plan calls for collecting a single, large sample in each sampling period. I believe that this collection variability. You could not propose to sample only on sunny days, because you would miss any Ian willprovide data representative of the entrainment at the intakes, but determiningif apparentpatterns or density differences due to weather. You could not propose to sample only from near the bottom of P P the intake, because you would miss any density differences due to vertical stratification in the water differences are real (as the requirements seem to call for) requires some measure of variability in the estimates. That column. I 4 6 requires replicates. The number of samples collected over the course of the project will be sufficient to detect annual variation between the two years, but seasonal, diel and weather effects would be confounded with each other. We believe that the way in which these data will be used do not justify extensive replication. Additional replication is necessary in order to determine if any of these factors affect entrainment. For example, one Relationships between weather, climate, spawning, and feeding (as a few examples) and could not separate weather effects from temporal differences in this sampling design. If it is necessary to be able to entrainment rates are not going to change the determination of best technology available for I show whether or not there are effects of weather, enough samples will be needed to use weather variables(e.g., water temperature,cloud cover)as covariates to test for effects. entrainment reduction or the outcome of any social cost/social benefit calculations. In addition, the study plan includes some replication. Each sampling event is divided into four independent samples based on time of collection. 11 In addition sampling events occur twice in each month. If necessary, confidence intervals can be generated based on these 8 samples within a month. Determination of whether confidence intervals are beneficial can be made at the end of the program. ft do)Fnarnv I 37 ' Category Charge No. Comment Response and Resolution That said, I think this issue could be addressed with a modicum of additional effort.The simplest approach would be to We disagree that splitting each 2-hour sample into smaller sub-samples requires only a small ' r 4 6 divide each 2-hour sample into at least three, preferably four, samples collected immediately one after the other. The additional effort. While it is true that the extra effort in the field will be minimal (extra net wash- collection cup (or entire net) could be swapped out after a sample and processed while the next sample is being downs, extra datasheets to fill out), the effort (and associated labor costs) in the laboratory will collected. This replication would allow straightforward statistical analysis to determine if these factors (or their increase proportionally. So splitting the 2-hour samples into four sub-samples will quadruple the lab interaction)affect entrainment. costs. ' Replication is important for density estimates, but it would not be necessary to have morphometric measurements on a 3 6 full compliment of individuals from each replicate; one pooled sample for each six-hour period would suffice.A total of Agreed. up to 10 individuals of each taxon could be drawn at random from all the individuals collected in all replicates combined g ' within one six-hour sampling period. 3 With minor modifications as noted in responses to other questions, this study design should provide a sound basis to No response necessary support the required benefits analysis. ' 1 8 Section 2.2.1 Intake Structure would benefit from some further detail. It is unclear whether there is one isolation gate per unit, or one per intake bay. Inclusion of a figure with the features in this section noted, like figure 6.1,would help(on We modified the figure and figure numbering. a related note, it is curious that there are Figures 2.1 and 2.3 but no Figure 2.2). ' 1 8 A table number is missing on p. 14,line 35 of the Allen ECSP document(Table 6.2 I think). We corrected figure and table numbering and checked all captions 1 8 In Table 6.2, second row,either indicate 64 sampling events, or 32 sample events per year. We modified accordingly I r U I I i I I I 1 Allen Entrainment Steam StationCharacterization Study Plan 0 / APPENDIX C - Comparison of Pumps and Nets for ' Sampling Ichthyoplankton I • 1 I I I I I I I I I I I Duke Energy 139 Entrainment 1 Allen Steam Stationcterizatlon Study Plan Hn iComparison of Pumps and Nets for Sampling lchthyoplankton Prepared by: 1 -)1 440 S. Church Street, Suite 900 1 Charlotte, NC 28202-2075 February 19, 2016 1 Introduction As a part of Duke Energy compliance projects associated with the 2014 Clean Water Act §316(b) rule for existing facilities (Final Rule), the company submitted draft Entrainment 1 Characterization Study Plans (ECSPs) to informal review by subject matter experts. In the comments received on the draft ECSPs and during discussions at a peer review kick off meeting', there was a concern among the biological reviewers that the proposed pumped 1 ichthyoplankton sampling method could impart a systematic bias compared to nets for estimating power plant entrainment. In particular, there was a concern that pumped samples could underestimate entrainment and that additional gear efficiency testing could potentially be 1 undertaken periodically throughout the entrainment sampling period to determine if a bias exists and quantify the magnitude of difference if it exists. As a preliminary step, HDR conducted a literature review. The sections that follow provide background, the methods and results for the 1 literature review, and conclusions. Background Two primary methods have been historically used to estimate ichthyoplankton entrainment at power plant intakes: streamed/towed nets and pumped samplers. Traditional ichthyoplankton 1 nets can be used to filter water as it enters the intake or exits the discharge and collect organisms. Alternatively, pumps can be used to convey water to a fine-mesh net onshore. Onshore nets are typically suspended in a buffering tank to minimize damage and extrusion of 1 eggs and larvae. Each method has advantages and disadvantages and a comparison of the two methods are 1 summarized in Table C-1. The primary advantages of utilizing pumps include ability to meter precise sample volumes, longer sample collection times, reduction in the potential to miss samples due to inclement weather or other events, and increased ability for technicians to safely ' observe net filtering and other aspects of the data collection. Their versatility includes being utilized in fresh, estuarine, and marine water environments. Properly designed and operated systems can be accurate and effective. While no sampling method is perfect, pumped samplers Held at HDR offices in Charlotte,NC,January 28-29,2016. 1 1 Duke Energy I 40 Entrainment Characterization Study Plan ��� Allen Steam Station were determined to offer the best, most cost-effective, and consistent sampling method for Duke Energy and therefore were included in the draft ECSPs. Pumped samplers have been used in sampling plankton as far back as 1887 (Gibbons and Fraser 1937; Aron 1958; both as cited in Taggart and Leggett 1984) and have a long history of ' successful application for collecting ichthyoplankton samples at power plants (Bowles and Merriner 1978; as cited in EPRI 2014). Pumped samplers are among the preferred gear types accepted by EPA and have been used extensively to successfully monitor entrainment at power plant intakes for decades. At present, HDR is aware of on-going or state approved plans for pumped entrainment sampling at power plants to support the Final Rule in at least seven states: Florida, Wisconsin, New York4, Pennsylvania, New Hampshire5, Massachusetts, and Virginia. If this list of states is expanded to include sampling under the remanded Phase II Rule, then the list of states would ' be expanded to include Connecticut, Louisiana, Texas, Ohio, Michigan, New Jersey, and Maryland. In addition, there may be other states that HDR is unaware of, that have also approved this approach. Still other States could be added to the list as more power generating companies begin entrainment studies over the next few years under the Final §316(b) Rule. Table C-1. Advantages and Disadvantages of Hoop Nets and Pumped Samplers for Estimating lchthyoplankton Density in Cooling Water Intake Structures (some information adapted from EPRI 2014) Gear Type Advantages Disadvantages Hoop Nets - Large volumes are sampled quickly(less - Can be difficult to deploy and retrieve in the 111 Deployed in the manpower required for the same number of confined space of intake structures— Intake pumped samples). precludes the use of some net types(e.g., - If net frames are not used,then there is standard bongo, neuston nets,or Tucker trawls). limited to no modifications to the intake required for deployment. -Depending on deployment method,may No potential for mechanical damage require modifications to intake structures - (e.g.,frame-mounted nets in frame guides). associated with pump passage. - Less precise flow metering than pumped samplers. -Large volumes are sampled quickly- I capturing less temporal variability in a single sample as compared to pumped samples. - Relatively small nets needed to fit in the ' intake structure offer a small spatial sample. Multiple nets can be used to increase sampled area at the cost of additional samples to be processed in the laboratory. I 4 New York State applies a more stringent standard than the Final Rule under the New York State Department of Environmental Conservation Policy CP-52 for Best Technology Available(BTA)for Cooling Water Intake Structures. s The states of New Hampshire and Massachusetts do not have delegated authority to issue NPDES permits and are administered by EPA Region 1. I IDuke Energy 141 Entrainment Characterization Study Plan Allen Steam Station Gear Type Advantages Disadvantages - Tow speeds in the range of 1-2 meters per second(commonly used during ichthyoplankton sampling)is above the intake velocities at the majority of intakes. ' - Some active avoidance possible by larger motile life stage(e.g.,late larvae and early juvenile).Larger hoops can be used to decrease potential for avoidance, but would require a larger deployment area,since length is proportional to opening diameter in properly sized nets6. - Greater potential for extrusion than pumped samples(no buffering tank). - Boat deployed nets are subject to weather delays and associated safety concems. - May be restricted to relatively deep areas that are free of floating debris,submerged snags,and other obstructions Pumped -Sample durations are typically longer - Some active avoidance possible by larger Samplers in the increasing the potential to capture temporal motile life stages(e.g.,late larvae and early Intake variability in ichthyoplankton densities not juvenile). observed in net samples. - Improperly designed samplers can lead to - Limited modifications to intake or discharge damage to organisms during sampling. structures are required to install—usually just anchoring points for the sample pipe. - Samples a smaller portion of the spatial variability, because pump inlets are - In-line flow metering offers greater precision generally smaller than net openings. in measuring the volumes of flow sampled. -Some potential for mechanical damage. However,correctly designed systems can offer<5%damage or destruction of eggs and larvae. - Fixed pipe allows precise control over water depth and orientation to intake flows. -Less potential for extrusion than nets, because the filtering net sits in a buffering tank. - Lower potential for missed samples due to severe weather. -Allows technicians to observe sample collections and minimize potential for invalid samples(e.g.,use of 330-urn nets 1 increases potential for net occlusion and frequent net change outs may be required during certain times of the year). I 9 A general rule of thumb, as described in EPRI 2014, states that the total effective open area of the netting(percent open area x area of netting)should be at least twice the area of the net mouth opening.Others have suggested a net length to mouth opening diameter ratio of three or more. 1 Duke Energy 142 ' Allen Steam Staattioona��don Study Plan ImN Literature Review Methods HDR conducted a literature review to assemble and assess the available data on the ' comparative effectiveness of pumped entrainment samplers and nets to estimate power plant entrainment. Available data were identified via online electronic searches for published articles and government and industry reports. The electronic literature search used Google, Google Scholar, and the ProQuest Aquatic Science Collection database accessed through the University of Massachusetts, Amherst. In addition, we consulted the EPRI technical support document on entrainment abundance monitoring (EPRI 2014) to identify relevant literature. The literature search revealed a short list of relevant citations and abstracts. Several of these were available in HDR's corporate library and some were obtained from the publishers. For some of the industry gray literature and less common symposium papers, we relied on abstracts or 1 summaries presented in other documents (primarily EPRI 2014). Below is an annotated bibliography of several of the key references that were reviewed. To the extent practical, these studies were critiqued and the results and findings put in the context of the goals of entrainment monitoring at the Duke Energy facilities. Annotated Bibliography Cada, G.F. and J.M. Loar. 1982. Relative Effectiveness of Two Ichthyoplankton Sampling Techniques. Canadian Journal of Fisheries and Aquatic Sciences 39(6): 811-814. Cada and Loar (1992) collected triplicate pump and towed-net samples during both day and night near the water's surface to detect differences in the effectiveness of a pumped sampler and towed nets for collecting ichthyoplankton. The effectiveness of 1.1 m3/min (290 gallons per minute [gpm]) pump' was compared to a 2 m long (6.6 feet), 0.5-m (1.6-feet) diameter, 243-pm mesh conical plankton net in the headwaters of Watts Bar Reservoir in eastern Tennessee. The net was towed for 5 minutes at velocities between 120 and 189 cm/s (4 to 6 feet per second), which resulted in sample volumes of 85 to 100 m3. The pump system used a 7.6-cm (3-inch) 1 diameter intake hose that had a cylindrical trash screen with 6.4-cm2 (1-inch) openings. This hose inlet was placed 0.25 m (10 inches) below the surface and slowly moved through the water. Both gear collected clupeid larvae (Threadfin Shad and Gizzard Shad) between 4 and 17 mm (0.16 to 0.67 inches) although larvae greater than 10 mm (0.4 inches) long were collected in relatively low numbers. Clupeid larvae 4-10 mm (0.16 to 0.4 inches) long were collected in sufficient numbers to make meaningful statistical comparisons based on date, station, diel period (day vs. night), and fish length. Due to the difficulty in differentiating small Dorosoma spp. both species were combined for the analysis. The differences in the mean densities of most length groups between nighttime pump and tow samples were not statistically significant. 'By comparison,the pumps proposed for use for entrainment sampling at Duke Energy facilities have a target capacity of 240 gpm with a range from 5 to 380 gpm depending upon head. ' Duke Energy 143 Entrainment Allen Steam Station ation Study Plan Ln However, the pump collected significantly more 4-mm larvae and the towed net collected more 5- to 10-mm larvae during the day. Cada and Loar (1992) concluded that based on sampler intake velocities and the potential for avoidance, it would generally be expected that pumps are more effective than fixed nets, that towed nets are more effective than low volume pumps, and that high volume pumps are equally or more effective than towed nets in collecting ichthyoplankton. The lack of differences between densities of ichthyoplankton at night suggests that gear avoidance is associated with a visual escape response and not a tactile response to changes in hydraulic conditions. The authors caution that any gear comparisons should account for sizes of sampled organisms and how that could impact performance and that care should be used when using pumped samplers, because pumps may not adequately sample all entrainable organisms. These results should be used with caution and may not be representative of what would be observed with a fixed entrainment sampler at a cooling water intake. First, Cada and Loar (1992) moved the pump inlet though the water which could alter the flow fields relative to what would be observed around a static system. Second, the distance from the boat that these two systems were deployed is unknown. Theoretically, boat-induced hydraulics, noise, and/or shadow could have induced differential behavioral responses between the two gear types if deployment distances were different. Third, the inlet to the pump had a trash screen with 1-inch ' openings. The authors did not describe the size of the trash screen. This screen and its wake could have acted as visual avoidance stimuli. Elder, J.A., J.W. Icanberry, D.J. Smith, D.G. Henriet, and C.E. Steitz. 1979. Assessment of a Large Capacity Fish Pump for Sampling ichthyoplankton for Power-plant Entrainment Studies. California Cooperative Oceanic Fisheries Investigation 20: 143-145 A centrifugal, single-port bucket-style pump that delivered 3.0 m3/min (793 gpm) at a 3-m (10- feet) head and in excess of 4.3 m3/min (1,136 gpm) at lower heads was evaluated for sampling entrainment. These pumps were originally designed for hatchery and aquaculture use and were reported by the manufacturer to lift 30-cm (12-inch) trout 3 m (10 feet) above water surface with 99.5 percent survival. The pump discharged into a 505-pm mesh net with a cod-end bucket suspended in a 2 m3 (528 gallon) box. The inlet to the pump was a 15.2-cm (6-inch) diameter pipe. The exit pipe was larger (25.4-cm [10-inch] diameter) to reduce velocity entering the net. This pump sampler was compared to the sampling efficiency of a 1.0-m [3.3-feet] 505-pm nylon mesh net towed across the mouth of the intakes near where the pump was operating. During 20 paired samples, there were no statistical differences in larval fish densities captured by the net and the pump. There were statistically higher densities of opossum shrimp (Neomysis spp.) collected by the pump than by the nets. Damage to pumped specimens was limited. Specimens collected by pump remained highly identifiable and were in the same physical condition as net- captured specimens. Given that the pumps evaluated by Elder et al. (1979) had a much higher capacity than those proposed for use at the Duke Energy facilities, it is difficult to make a direct comparison, but the results indicate that a pumped sampler could be as efficient as nets for sampling entrainment. ' Duke Energy 144 Entrainment tlon Study PlanNe Steam StationF�� ' Gale, W. R, and H.W. Mohr, Jr. 1978. Larval Fish Drift in a Large River with a Comparison of Sampling Methods. Transactions of the American Fisheries Society 107:46-55. While this study was primarily designed to test the drift of larvae in the Susquehanna River (1974-1975), use of a pumped sampler and nets simultaneously allows for a comparison of the two gear types. Samples were collected from April 10 to October 10, 1974 with boat mounted nets. The nets were made of nylon and had 0.4 x 0.8-mm mesh and 24 x 54-cm (9.4 x 21.3- inch) rectangular mouths. Simultaneous samples were collected at near each shore and the main channel (about 80 m [262 feet] from the west shore) at set intervals (0800-1000 h and 2300-0100 h). Five-minute fixed net samples were collected from a stationary boat and push-net samples were collected propelling the boat slowly downstream for abut 300 m (984 feet). From March through August 1974 a high capacity trash pump, raised and lowered by a hand winch, was used to collect samples. Replicate pump samples were collected about 50 cm from the surface and 10-20 cm (4-8 inches)from the bottom at 3-hour intervals for a 24-hour period near the middle of the river. Flow rate was about 2,500 liters per minute(660 gpm). Based on surface samples only,e the pumped and fixed net samples collected about the same number of larvae ' per 10 m3 and no statistical differences were detected. Harris, R.P. L. Fortier, and R.K. Young. 1986. A Large-Volume Pump System for Studies of the Vertical Distribution of Fish Larvae Under Open Sea Conditions. Journal of the Marine Biological Association of the United Kingdom 66(4): 845-854. ' Harris et al. (1986) evaluated a pumped sampler for application in an open ocean setting. The pump was 2.8 m3/min (740 gpm) submersible, centrifugal pump designed for pumping waste water. Comparative efficiency trials by day and night showed that the pump was generally as efficient, or in some cases more efficient, in capturing larvae than towed 200-pm WP2 nets9, although there was some evidence of visual avoidance by particular larval size classes during daylight. The authors indicated that fine-scale temporal and spatial resolution is necessary to study the distribution of larval fish and that large-volume pumps, sampling at rates in excess of 1 m3/min (264 gpm) can be used as an alternative to conventional nets. The design and application of the pump sampler used by Harris et al. (1986) is substantially different (e.g., 15- cm [6-inch] intake line; boat-mounted and sampled while in motion; and marine open-water ecosystem) than what is being proposed for use at the Duke Energy facilities. For this reason, the results have limited direct applicability to the Duke Energy fleet. I Sampler efficiency was only presented for surface sampler in Gale and Mohr 1978. 9 The WP2 Net is a vertical plankton net with messenger operated closing mechanism based on the design of the UNESCO Working Party 2. Duke Energy 145 Entrainment Allen Steam Station Characterization Study Plan L1� ' King, L. R., B. A. Smith, R. L. Kellogg and E. S. Perry. 1981. Comparison of lchthyoplankton Collected with a Pump and Stationary Plankton Nets in a Power Plant Discharge Canal. Fifth National Workshop on Entrainment and Impingement. San Francisco, CA, May 1980. Loren D. Jensen, Ed. King et al. (1981) compared the performance of pumped samples and nets in the discharge canal at Indian Point Generating Station on the Hudson River. Simultaneous ichthyoplankton sampling was completed using a 15-cm (6-inch) pump/larval table system and stationary 0.5-m (1.6-feet) diameter conical plankton nets. A total of 79 paired samples were collected on 6 days in June and July 1978. The average density of total ichthyoplankton collected was 3.0/m3 for pump samples and 3.3/m3 for net samples. No significant differences (P> 0.05) were detected between density estimates for total ichthyoplankton determined from pump and net samples for eggs, yolk-sac larvae, post yolk-sac larvae, and juveniles. Thirteen out of 14 taxa compared ' showed no significant difference between pump and net collections. The pump and net collection systems were equally effective for estimating densities of most ichthyoplankton. Petering, R W; Van Den Avyle, MJ. 1988. Relative Efficiency of a Pump for Sampling 1 Larval Gizzard and Threadfin Shad. Transactions of the American Fisheries Society 117: 78-83. ' Efficiency of a pump sampler and a plankton net were compared based on monthly nighttime collections on Lake Oconee, Georgia10 from April through August 1982. The two samplers were used on the same night or on two consecutive nights. The gasoline-powered pump had a 1.18 m3/sec (312 gpm) capacity. Pumped samples were discharged into a 297-pm mesh net suspend over the side of a boat. A cylindrical metal sieve with 8 mm (5/16 inch) holes was 1 attached to the inlet of the pump to exclude large debris. Three, 10-minute samples were collected by slowly raising and lowering the intake hose in the upper 2-m (6.6 feet) of the water column. Sample volumes were assumed to be 11.8 m3 (3,117 gpm) based on manufacturer's 1 pumping specifications. Triplicate samples (75 m3) were collected with a towed net that was 0.25-m2 (2.7 feet2)with 0.5-m (5.4 foot) square opening that was towed at 1.0 m/s (3.3 feet per second)for 5 minutes. Net samples contained seven fish taxa whereas only two were collected by pumps; however, Gizzard Shad and Threadfin Shad accounted for more than 97 percent of the specimens caught in both samplers. The authors conclude that the pumped sampler collected fewer taxa and that the estimates of shad density were lower and less precise than net samples. There are serious concerns with this study design that call into question the authors' findings. First, when calculating organism density, the authors used pump flow rates as defined by the manufacturer's specifications rather than metering the flow. The authors evaluated the pump in 1 the laboratory and determined that the intake rates were typically within 10 percent of advertised values, but no methods or results for the laboratory evaluation are provided to allow a critique. This lack of metering casts doubt on the accuracy of the entrainment estimates. Second, similar 0A 7,709-hectare pumped storage reservoir in central Georgia.Not to be confused with Duke Energy's Oconee Nuclear Station on Lake Keowee in South Carolina. 1 IDuke Energy 146 AllemSSSteaamm Characterization Study Plan L1� Station to Cada and Loar(1982), the inlet to the pumped sampler was screened and moved through the water. The screening could alter the localized hydraulics (e.g., increase in velocity entering the screening), which may be perceived and avoided by later larvae and early juveniles with sufficient swimming capacity. Moving the inlet through the water could also induce hydraulic changes perceptible to fish. It is also unknown if, or to what extent, entrainment rates with the pumped sampler could have been affected by its proximity to a moving boat. Finally, samples were not necessarily collected on the same night with both gear types. Daily variability in ichthyoplankton density was likely an unaccounted for confounding factor. Leithiser, R.M., K.F. Ehrlich, and A.B. Thum. 1979. Comparison of a High Volume Pump and Conventional Plankton Nets for Collecting Fish Larvae Entrained in Power Plant Cooling Systems. Journal of the Fisheries Research Board of Canada, 1979, 36(1): 81-84 Leithiser et al. (1979) compared a high volume pump to conventional ichthyoplankton nets for entrainment monitoring. The pumping system had a capacity of about 2.5 m3/sec(660 gpm). No information was given about the size of the piping on the suction end of the pump. The nets used by Leithiser et al. (1979)were 0.5-m (363-pm) and 1.0-m (335-pm mesh) conical plankton nets. The average density of large larvae (> 5 mm Total Length [TL))was significantly greater with the ' pumped sampler than what was observed with the 1-m plankton nets. Compared to the pump, both sizes of plankton nets (0.5 and 1.0 m diameter) in each test greatly under sampled larvae over 5.0 mm TL. The data suggest that the pump and plankton nets sampled the small larvae equally well, but that the larger larvae were better able to avoid the plankton net than the pump inlet. Leithiser et al. (1979) collected samples in the power plant intake canal at different 1 approach velocities. While it was expected that larval avoidance would decrease with increasing channel velocity, this was not observed with either the pumped or net samples, but the number of channel velocities tested were limited. ' The authors concluded that the high volume pump was a more effective larval fish sampler than the conventional plankton nets. It is important to note that on the California coast where these studies were undertaken, there are greater densities of small larvae (< 5 mm TL) than would be expected in southeastern Piedmont reservoirs, which would make the differences between these two gear types more dramatic at the Duke Energy facilities. It is unclear how these results can be transferred directly to what is being proposed at the Duke Energy facilities because of the higher flow rate used in this study(660 gpm vs. 240 gpm). 1 I ' Duke Energy 147 Allen Steam Stationerizau«,Study Plan Leonard, T.J. and G.E. Vaughn. 1985. A Comparison of Four Gear Types to Measure Entrainment of Larval Fish. Proceedings of the Annual Conference of the Southeast Association of Fish and Wildlife Agencies 39: 288-297. A study was undertaken at the McGuire Nuclear Station (MNS) on Lake Norman, North Carolina. The purpose of this program was to determine the relative efficiency, reliability, and cost of four different systems for measuring larval fish entrainment into the cooling water system: 1) a tap valve in the condenser, 2) a pump-net system, 3) a fine-mesh screen; and 4) a stationary net. Night samples were collected on five consecutive nights 6-10 June 1982, which was anticipated to coincide with the peak abundance of Threadfin Shad and Gizzard Shad. The stationary net was a single 0.5-m conical net (2.5-m [8-feet] long, 800-pm mesh) was suspended from a barge located 7 m [23 feet] upstream of the intake. A flow meter was placed in the mouth of the net to monitor the volume of water sampled. The net was fished by quickly ' lowering the net to the bottom of the intake structure and raising it in 1-m intervals over the 9.5- m high effective opening to the intake. Rapidly lowering and raising of the net caused the net to collapse, preventing the flow meter from recording flow during the decent and retrieval. On the first night the net was raised at 1-m (3-feet) increments at 2-minute intervals, but this resulted in less than desirable volumes sampled and on subsequent nights the net was raised at 1-m (3- feet) increments at 3-minute intervals for the remainder of the study, resulting in an average sampling duration of 27 minutes. The fine-mesh screen was a 9-cm (3.5-inch) deep rectangular wooden frame that had a 50.8 x 1 57.5-cm (20 x 22.6-inch) mouth opening covered on one side with 800-pm mesh. This panel was attached to a traveling screen in the intake bay being sampled. The traveling screen was rotated manually to position the fine-mesh panel into the flow. The screen was rotated so that the fine-mesh panel was raised in approximate 1-m (3-feet) increments at 4 minute intervals, resulting in an average duration of 38 minutes. Once at the water surface, the screen was rotated without stopping to retrieve the sample. The pumped sample was collected using a 10.1-cm (4-inch) diameter centrifugal pump (2,270 L/min [600 gpm] pumping capacity at 0.6 m head). Water was withdrawn through a 10.1- cm (4-inch) diameter flex hose and discharged via a 10.1-cm (4-inch) PVC pipe into a plankton net. An ultrasonic flow meter was used to measure flow through the discharge pipe. The hose was lowered as close to the bar racks as possible and raised at 1-m (3-feet) increments at 3- minute intervals starting at just above the bottom of the intake opening. Water from the pump was discharged just below the water surface into a 2.4-m (8-feet) long, 794-pm mesh suspended from the side of the barge. Water was sampled through a 7.6-cm (3-inch)gate valve on the condenser and discharged into ' an 800-pm mesh plankton net suspended in a 208-L (55-gallon) drum. Two consecutive samples averaging 192 minutes each were collected on each night. Though longer duration than the other sampling techniques, the volumes of water sampled were similar. All four gear types were compared to Tucker trawls taken from the intake embayment and used to estimate density and length frequency distributions of larvae potentially susceptible to 1 Duke Energy 148 Entrainment 1 Allen Steam Characterization on Study Plan ' entrainment. The Tucker trawl had 710-pm mesh with a 1 m2 (10.8 feet2) effective opening. Samples were collected perpendicular to the intake (starting as near as possible to the intake). Samples were collected at two depths—surface to the top of the intake structure opening (about 4.6 m [15 feet])and from the intake opening to the bottom of the intake structure (4.6 m [15 feet] to 14 m [50 feet]). Each stratum was towed obliquely. Trawl durations were 2 to 5.5 minutes and collected every two hours starting at about 30 minutes after sunset and extending until sampling with all the other gear types was completed. Two or three sets of tows were made on each night. Results were variable by gear type (Table C-2). Few shad were collected by pumped sampler on 6 and 7 June due to a ripped seam in the net. Trawl samples from the upper stratum were greater in number than the lower stratum. While not identified by the authors, it should be noted that it is difficult to measure the flow sampled with the fine-mesh screen approach. Differential ' open area between the fine-mesh overlay and the surrounding coarse-mesh panels would likely have resulted in flow diverting to the coarse-mesh panels or gaps between panels, side seals, and the screen boot preventing accurate measurement of volumes sampled. In most cases, the 1 samples collected at the condenser tap were higher than what was observed in the lower trawls. There were no significant differences in ichthyoplankton density by date (P = 0.83), but there were differences by gear type. Mean densities of the pumped samples were not significantly different from the tap samples (P= 0.60). Stationary nets and fine-mesh screen collections were significantly different from one another and from the pumped and tap collected samples (P < 0.05). Length frequencies between the pump and tap samples were not significantly different from one another. Mechanical damage from collection was minimal for all four techniques with the highest observed damage associated with pump passage (3 percent unidentifiable). Tap 1 sampling was considered for use at McGuire for the 2016 entrainment program, but was eliminated because of concerns with access to secure locations within the power plant. This study indicates that the selected method for entrainment monitoring (pumped sampling) is 1 statistically no different than measuring ichthyoplankton density at the condenser tap and better than a streamed net. 1 1 1 1 1 1 Duke Energy 149 I Entrainment Characterization Study Plan L Allen Steam Station 1 )I � Table C-2. Total Number (N) and Mean Densities (MD) (mean number of shad/ 1,000 m3) of All Shad Collected with Comparison Gear and Shad <28 mm Total Length Collected with I a Tucker Trawl on Lake Norman, North Carolina, 6-10 June 1982, with Average Volume of Water Filtered per Sample (m3) (Leonard and Vaughn 1985) Net Screen Pump Tap Upper Trawl Lower Trawl I Date © MD N MD N MD © MD ' 1 N MD N MD Jun 6 0 0.0 2 a 1° 5 56.4 164 195.3 27 27.9 1 Jun 7 0 11 0.0 8 34.0 6° 12 182.0 590 410.5 190 70.7 Jun 8 1 4.7 15 53.0 38 91.1 10 103.0 659 536.4 75 43.1 Jun 9 1 ,I 7.0 11 43.0 80 196.9 25 346.1 511 666.1 86 76.4 IJun 10 0 11 5.0 10 32.1 36 82.4 4 82.0 279 406.5 134 85.7 Total illa 0.0 46 161 56 2,203 512 Ave. 29 92 65 38 206 317 Sample I Volume (ms) I a-Unable to calculate volume -Number not considered valid due to malfunctioning equipment `-Density not calculated on invalid data ITaggart, C.T. and W.C. Leggett. 1984. Efficiency of Large-Volume Plankton Pumps, and Evaluation of a Design Suitable for Deployment from Small Boats. Canadian Journal of IFisheries and Aquatic Sciences 41(10) 1428-1435. Taggart and Leggett (1984) identified and evaluated five major studies that compared the I efficiency of large-volume pumps (defined as withdrawing > 0.5 m3/min [132 gpm]) and nets (Table C-3). In addition the authors evaluated a boat mounted large-volume pumping system. I Taggart and Leggett (1984) found, in general, that among the reviewed studies, densities of organisms sampled with the pumps was equal to or greater than the densities in the towed net samples, but there were differences based on length classes and time of day. The authors I pointed out that the gear configurations relative to towed net diameters, pump intake diameter, the presence of intake screens, intake velocities and mesh sizes were highly variable between the studies, which made it difficult to compare. The authors were particularly critical of the lack I of accurate flow measurement used in many of these studies. Despite these challenges, no systematic biases were detected. I In addition to the literature review, Taggart and Leggett (1984) tested a large-volume pump system with standard plankton nets. The boat mounted system used a 22.2-cm (8.7-inch) impeller that could pump up to 1.7 m3/min (450 gpm) depending upon head. Divers confirmed ' the inlet was oriented into the direction of travel. Simultaneously to pump sampling, a 0.5-m (1.6-feet) diameter 2-m (6.6 feet) long 80- and 153-pm mesh standard plankton nets were also fished. Three sets of comparisons were made. In 1981 an 80-pm net was towed immediately IDuke Energy 150 nt Allen Steaam Characterization Study Plan ' below the surface 2 m (6.6 feet) behind the pump intake. In 1982 and 1983 a 153-pm net was towed immediately below the surface 13-15 m (43-50 feet) astern of the pump sampler. The ' pump intake was maintained at a depth of 0.25 m (0.8 feet)for all comparisons. The authors concluded that the nets and pumped sampler were equally effective in capturing capelin (Mallotus villosus) larvae (5-mm length), herring (Clupea harengus) larvae (9-mm length), large copepods (>750 pm), small jellyfish, and hyperiid amphipods, despite only sampling 8 percent of the water volume sampled by the nets. In addition, the pump was more efficient at collecting crab zoea and megalops larvae and efficiency of collecting euphausiids and chaetognaths increased as their natural densities increased. Nets were superior in the capture of fish eggs (primarily cunner, Tautogolabrus adspersus), possibly due to the vertical distribution of eggs in the water column. The average length of capelin larvae captured by pumping was consistently 0.2 mm longer than that of larvae taken in nets, but the length— frequency distribution of larvae sampled was similar to that of larvae entering the pelagic environment. The very fine meshes and small organism sizes likely contributed to the high collection efficiency of the pumped sampler used by Taggart and Leggett(1984)as other studies reviewed here indicate it is the larger more motile life stages that tend to be collected more efficiently by ' nets than by pumped samplers. Like other studies that have towed the pumped sampler inlet through the water, it is unclear whether these results are directly applicable to the application being implemented by Duke Energy. Despite these uncertainties, this study seems to support use of pumped samples for estimating ichthyoplankton and zooplankton densities. I 1 ' Duke Energy 151 1.11 IIIIII IIIIII 11111 11111 all. 1011 110.1 aglina IIIII a 11.111 11.11 111111 1.111 Entrainment Characterization Study Plan En Allen Steam Station r Table C-3. Summary of Major Studies Designed to Comparatively Evaluate the Sampling Efficiency of Various Large-Volume Pumps and Tow Nets (Taggart and Leggett 1984) Pump Tow or current Suction speed Volume sampled Type and Tow net and (mis) (ms) mesh size Row Diameter Velocity mesh size Reference (µm) (m3/min) (m) (mis) (pm) Pump Net Pump Net Gear comparison protocol Aron 1958 Centrifugal, 1.514 0.076 5.55 0.5-m-dia.std., 1.7' 1.7' 15 200 50 paired hauls"near 544 silk 476 sites surface"(marine) Partner and Rohde Tandem propeller, 8.6 0.20 4.60 0.5-m-dia.std., Local current 86' 44' 1 1 I paired stationary 1977 500 nitex 500 Sex 0.4 sanpies at 4.5,8,and 9 m(riverine) Gale and Mohr Open impeller 2.5 0.10 5.30 0.24 x 0.54-m-rec., Local current 7 stationary sets of 4 pump 1978 centrifugal, 400 x 800 niter "modaae–strong" — — and 8 net replicates 400 x 800 niter (0.24)° (0.92)° at surface and bottom (riverine) I.eithiser et al. Fish transfer, 2.1 0.15 1.92 (a)l-m-dia.cyl.cone, Local current (a)62 121 (a)10 stationary pairs at 1979 335 niter 335 obex (a)0.26 0.5-1.5 m depth (riverine) (b)as in(a)and (b)0.30 (b)64 414 (b)as in(a)above 0.5-m dia.std., 64 105 363 Sex Cada and Loar Open impeller 1.10 0.076 4.04 0.5-m-dia. "Slowly" 1.2-1.9 17 85-100 3 sets of 3 replicates not 1982 243 nimx (0.021)° (1.1)° Hensen net, paired in time at 243 nitex 0-0.5 m depth(rivedne) 'Estimated from data provided in paper referenced. °Measured at intake,which differs in size from suction hose. Duke Energy 152 ' Entrainment tr in ent Characterization m Study PlanALn N ' Results The literature review, as described in detail above, indicates that there have been several studies that have compared the effectiveness of pumps and net sampling. In general, the results have been equivocal with no clear pattern of one gear type out performing the other. The most ' extensive power plant entrainment gear comparison studies were undertaken at the Indian Point Generating Station on the Hudson River (EA 1978; 1979; 1981; King et al. 1981; NAI 1982; 1987—as cited in EPRI 2014)". The results of these studies indicated no consistent differences in estimated densities between the two gear types (EPRI 2014). There is some indication that at relative low velocities, high-volume pumped samples collect higher densities of ichthyoplankton than nets(Leithiser et al. 1979). In a southeastern reservoir(Tennessee), Cada and Loar(1982) ' found that for most length classes there were no significant differences in density between pump and net samples. The data suggest that avoidance is more common during daylight hours ' in clear water when organisms can observe and avoid the gear. At night and/or in turbid water avoidance is minimized (Cada and Loar 1982; Harris et al. 1986). Petering and Van Den Avyle (1988) collected significantly lower densities of fish larvae in a Georgia reservoir using a ' pumped sampler as compared to nets, but there are concerns with the methods and gear, as described in detail above, that could account for some of these differences. Leonard and Vaughn (1985) sampled Threadfin Shad (Dorosoma petenense) and Gizzard Shad (Dorosoma ' cepedianum) using pumps, a streamed net, a fine-mesh panel on a traveling screen, and a tap at the condenser at the McGuire Nuclear Station and reported the highest density at the condenser tap where the water was well mixed. Leonard and Vaughn (1985) reported the highest rate of damaged larvae from the pumped samples, but damage was s 3 percent. Gear avoidance occurs with both pumps and nets and increases with increasing fish length, which is likely a result of increased swimming ability, maturing fish sensory systems, and avoidance ' behavior. Caution should be used when applying the results of specific previous gear efficiency studies to the Duke Energy entrainment program because of the variability in gear types and sampling techniques used in these studies (e.g., net type and shape; mesh sizes and material; methods of gear deployment; deployment location; flow metering; inlet orifice size, shape, and orientation; inlet velocity; impeller size, shape and material; mechanism for suction [vacuum, diaphragm, centrifugal]; and pumping capacity). Instead, the weight-of-evidence across scientifically sound studies should be used which supports pumped samples as being generally equal in terms of collection efficiency to towed and streamed nets. ' Conclusions Nets and pumps are the two primary methods by which ichthyoplankton densities are estimated ' at power plant intakes. Pumped samplers have been used successfully in a wide variety of 'I During the peer review kick off meeting,a biological peer reviewer mentioned an Indian Point Generating study evaluating the effectiveness of fine-mesh wedgewire screens to reduce entrainment.As part of that study, samples were collected by nets and ' pumps. That study was not reviewed here for several reasons: a) the study was not designed to compare gear types; b) the sampler used for pump sampling at Indian Point was a unique design that is dissimilar from what is being proposed at the Duke Energy facilities;and c)Indian Point is part of on-going 316(b)-related litigation and those study reports are not readily available to the public. ' Duke Energy I 53 Entrainment ' Allen Steam Station Characterization Study Plan ' deployment conditions at power plants in the U.S. routinely since the 1970s. This method has been well vetted by regulatory agencies including in the northeastern U.S., which along with California, has historically applied the most stringent 316(b) requirements in the nation. In addition, pumped samplers continue to be accepted for 316(b) monitoring as evidenced by the list of states where these samplers are deployed or approved to be deployed to support 316(b) evaluations under the final Rule. Importantly, the final Rule became effective October 14, 2014 and many facilities have not yet chosen the method by which they intend to sample entrainment and the list of states approving pumped samplers is likely to increase. Studies that have evaluated nets and pumps have shown no clear pattern of one technology outperforming the other. The results from published and unpublished industry studies are equivocal with some examples suggesting that pumped samples outperform netted samples and vise-versa. ' Perhaps the greatest impediment to determining the collection efficiency of gear from existing data is the lack of standardized techniques for netting (e.g., net type, net shape, mesh sizes, mesh materials, methods of deployment, deployment location, and flow metering) or pumped ' samples (e.g., orifice size, orifice orientation, inlet velocity, impeller size, impeller shape, impeller material, mechanism for suction [vacuum, diaphragm, centrifugal], deployment location, ' and pumping capacity). These factors, along with site-specific hydraulics and life history characteristics of the early life stages of fish sampled, are likely to impact the performance of both collection systems. Further, short of a duplicative sampling with both sampling systems in ' tandem, it is unlikely that a study program could be developed that would provide the necessary data to develop a universal correction factor that could be used to quantitative adjust entrainment estimates. We acknowledge that no system for sampling ichthyoplankton densities is perfect given the patchy temporal and spatial distribution of fish eggs and larvae and inherent biases of all gear types. That said, the available data indicate that pumped samplers can be as efficient as nets. Because entrainment monitoring by pumped sampling is commonly used, widely accepted, and has practical advantages over using nets at the Duke Energy facilities, our recommendation is that no gear efficiency testing is necessary or warranted. 1 ' Duke Energy 154 Allen Steam Station edzation Study Plan IL-n ' References ' Aron, W. 1958. The Use of Large Capacity Portable Pump for Plankton Sampling, with Notes on Plankton Patchiness. Journal of Marine Research 16: 158-173. ' Bowles, R.R. and J.V. Merriner. 1978. Evaluation of ichthyoplankton sampling gear used in power plant entrainment studies. In L. Jensen (ed.). Fifth National Workshop on Entrainment and Impingement. Pp. 149-158. ' Cada, G.F. and J.M. Loar. 1982. Relative Effectiveness of Two Ichthyoplankton Sampling Techniques. Canadian Journal of Fisheries and Aquatic Sciences 39(6): 811-814. Ecological Analysts, Inc. (EA). 1978. Indian Point Generating Station Entrainment Survival and Related Studies 1977 Annual Report. Consolidated Edison Company of New York, Inc. ' EA. 1981. Indian Point Generating Station Entrainment and Near Field River Studies: 1979 Annual Report. Consolidated Edison Company of New York, Inc.; Power Authority of the State of New York. Elder, J.A., J.W. Icanbery, D.J. Smith, D.G. Henriet, and C.E. Steitz. 1979. Assessment of a Large Capacity Fish Pump for Sampling lchthyoplankton for Power-plant Entrainment Studies. California Cooperative Oceanic Fisheries Investigation 20: 143-145 Electric Power Research Institute (EPRI). 2014. Entrainment Abundance Monitoring Technical ' Support Document: Updated for the New Clean Water Act §316(b) Rule. 3002001425. EPRI, Palo Alto, CA. 156 pp. ' Gale, W. R, and H. W. Mohr, Jr. 1978. Larval Fish Drift in a Large River with a Comparison of Sampling Methods. Transactions of the American Fisheries Society 107:46-55. Gibbons, S.G. and J. H. Fraser. 1937. The Centrifugal Pump and Suction Hose as a Method of Collecting Plankton Samples. Journal du Conseil / Conseil Permanent International pour l'Exploration de la Mer. 12: 155-170. ' Harris, R.P. L. Fortier, and R.K. Young. 1986. A Large-Volume Pump System for Studies of the Vertical Distribution of Fish Larvae Under Open Sea Conditions. Joumal of the Marine Biological Association of the United Kingdom 66(4): 845-854. King, L.R., B.A. Smith, R.L. Kellogg, and E.S. Perry. 1981. Comparison of ichthyoplankton ' collected with a pump and stationary plankton net in a power plant discharge canal. In L. Jensen (ed.), Issues associated with Impact Assessment, Fifth National Workshop on Entrainment and Impingement. Pp. 267-276. ' Leithiser, R.M., K.F. Ehrlich, and A.B. Thum. 1979. Comparison of a High Volume Pump and Conventional Plankton Nets for Collecting Fish Larvae Entrained in Power Plant Cooling ' Systems. Journal of the Fisheries Research Board of Canada, 1979, 36(1): 81-84. 1 ' Duke Energy 155 En inment Allen Steam Station Characterization Study Plan Ln Leonard, T.J. and G.E. Vaughn. 1985. A Comparison of Four Gear Types to Measure Entrainment of Larval Fish. Proceedings of the Annual Conference of the Southeast ' Association of Fish and Wildlife Agencies 39: 288-297. Normandeau Associates, Inc. (NAI). 1982. Gear comparability study for entrainment sampling of ' juvenile fish at the Indian Point Station, 1981. NAI. 1987. Indian Point Generating Station Entrainment Abundance Program 1985 Annual ' Report. Prepared for Consolidated Edison Company of New York, Inc. and New York Power Authority. ' Petering, R W; Van Den Avyle, MJ. 1988. Relative Efficiency of a Pump for Sampling Larval Gizzard and Threadfin Shad. Transactions of the American Fisheries Society 117: 78-83. Taggart, C.T. and W.C. Leggett. 1984. Efficiency of Large-Volume Plankton Pumps, and ' Evaluation of a Design Suitable for Deployment from Small Boats. Canadian Journal of Fisheries and Aquatic Sciences 41(10) 1428-1435. Waite, S.W. and S.M. O'Grady. 1980. Description of a new submersible filter-pump apparatus for sampling plankton. Hydrobiologia 74(2): 187-191. ' Welch, P.S. 1948. Limnological Methods. McGraw-Hill Co., New York. 318 pp. 1 1 1 1 1 1 Duke Energy 156