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Home My WebLink About20080915 Ver 1_Draft Quality Assurance Plan_20080421Pagb Duke Energy. April 18, 2008 08- 0 916 PAT, Mr. John Dorney North Carolina Department of Environment And Natural Resources Division of Water Quality 2321 Crabtree Blvd Raleigh, NC 27604 Re: Catawba-Wateree Relicensing Project (FERC No. 2232) Draft Quality Assurance Project Plan (QAPP) Dear Mr. Dorney: As you know, Duke Energy Carolinsa, LLC (Duke) will be submitting a 401 Water Quality Certification Application in early June of 2008 as part of the relicensing process associated with our Catawba-Wateree Hydroelectric Project. Per our discussion in late January, we have developed a draft Quality Assurance Project Plan as required by the regulations. We would like to request your review of the draft QAPP prior to the submission of the formal 401 application in hopes that your comments would help us provide a more complete application. Please contact me at (704) 382-0293 if you would like to discuss this further or you may send comments to me at tsstyer(? ,duke-energy.com. We appreciate your assistance and look forward to your comments. Regards, T ara Styer, Project Man ager Hydro Licensing and Lake Services Duke Energy Carolinas, LLC Attachment - QAPP xc w/o att: Mark Oakley Diane Reid - NCDWQ 1617 Mail Service Center Raleigh, NC 27699-1617 w rm Do APR ? 1 2008 DENk - `NA I Eii Q0AU It WETLANDS AND STORYMAIr `R kOANCH Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan CATAWBA-WATEREE TAILWATER DISSOLVED OXYGEN MONITORING FERC PROJECT NO. 2232 QUALITY ASSURANCE PROJECT PLAN (QAPP) DRAFT Effective Date: Revision No. ?Energya Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan QUALITY ASSURANCE PROJECT PLAN CATAWBA-WATEREE PROJECT, FERC No. 2232 Effective Date: TBD DOCUMENT APPROVAL PAGE Enter name of Duke Project Manager sianature Enter his or her title(s) below Enter name of Duke Quality Assurance Manager signature Enter his or her title(s) below (independent from data collection organization) Enter name of another important party (Hydro Central Manager) Enter his or her title(s) below singa Enter name of another important party siknature (NCDWQ representative) Enter his or her title(s) below Enter name of Field Monitoring Manager si ng a (Field Monitoring Manager) Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan TABLE OF CONTENTS GROUP A - PROJECT MANAGEMENT ALO .......................................................................................................Distribution List A2.0 ................................................................................................ Project Organization A3.0 ................................................................................ Project Definition/Background A4.0 ..........................................................................................Project Task Description A5.0 ............................................................................... Quality Objectives and Criteria A6.0 ................................................................................. Special Training/Certification ATO .......................................................................................... Documents and Records GROUP B - DATA GENERATION AND ACQUISITION 131.0 .................................................................................Study Design B2.0 ........................................................................... Sampling Methods B3.0 .............................................................Sample Handling and Custody B4.0 ..........................................................................Analytical Methods B5.0 ............................................................................. Quality Control B6.0 ........................ Instrument/Equipment Testing, Inspection and Maintenance B7.0 .....................................Instrument/Equipment Calibration and Frequency B8.0 ................................. Inspection/Acceptance of Supplies and Consumables B9.0 .................................................................Non-Direct Measurements 1310.0 .........................................................................Data Management GROUP C - ASSESSMENT AND OVERSIGHT C 1.0 .......................................................Assessment and Response Actions C2.0 ........................................................................ Report Management GROUP D - DATA VALIDATION AND USABILITY D1.0 ..............................................Data Review Verification and Validation D2.0 ...................................................Verification and Validation Methods D3.0 .................................................Reconciliation with User Requirements Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan REFERENCES APPENDIX A - Standard Operating Procedures for In-Situ Compliance Monitoring APPENDIX B - Supplemental Trout Habitat Monitoring Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan LIST OF TABLES Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan LIST OF FIGURES Duke Energy Carolinas GROUP A - PROJECT MANAGEMENT A1.0 Distribution List Catawba-Wateree Project No. 2232 Quality Assurance Project Plan This Quality Assurance Project Plan (QAPP) will be distributed to the following agencies and entities with an interest or role in water quality monitoring conducted by Duke Energy Carolinas, LLC (Duke or Licensee) for the Catawba-Wateree Hydroelectric Project (FERC No. 2232). Table 1: Contacts Receiving Duke Energy Catawba-Wateree QAPP Dianne Reid North Carolina Division of Water Quality John Dorney North Carolina Division of Water Quality Heather Preston South Carolina Department of Health and Environmental Control Chuck Hightower South Carolina Department of Health and Environmental Control Rusty Weneri ,, South Carolina Department of Health and Environmental Control Ben West U.S Environmental Protection Agency Scott Holland Duke Energy Corporation Mark Oakley Duke Energy Corporation George Galleher Duke Energy Corporation Scott Fletcher Devine Tarbell and Associates Steve Johnson Devine Tarbell and Associates Jon Knight Devine Tarbell and Associates v Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan A2.0 Project Organization The Duke Energy Carolinas, LLC (Duke) Hydro Operations Compliance Engineer will serve as the Project Manager (PM) and is responsible for overseeing all aspects of the continuous dissolved oxygen (DO) monitoring program in the Catawba-Wateree Project tailwaters, including oversight of the subcontractor collecting the data in accordance with the Water Quality Monitoring Plan (WQMP) (Appendix A) for the Project and this QAPP. The Duke PM is responsible for reporting data to the North Carolina Division of Water Quality (NCDWQ) and the South Carolina Department of Health and Environmental Control (SCDHEC) as described in Section A4. The Duke Hydro Operations Compliance Engineer also acts as the Project Quality Assurance (QA) Manager and is responsible for maintaining the QAPP and Quality Assurance/Quality Control (QA/QC) files. The Duke PM/QA Manager does not supervise or manage the personnel responsible for collecting the data. The Duke PM/QA Manager is responsible for the final review of documentation for the QA/QC file and that data collection is consistent with this QAPP. The Monitoring Field Manager (subcontractor) is responsible for the review of data and supporting documentation prior to submittal to the Duke PM/QA Manager. The Monitoring Field Manager is also responsible for directly overseeing the Monitoring Field Staff (subcontractor) and the day-to-day coordination of field collection and equipment maintenance in accordance with this QAPP, the Water Quality Monitoring Plan (WQMP) and all associated Standard Operating Procedures (SOPs). The Monitoring Field Manager is responsible for reporting any equipment/calibration issues to the Data Processor and for making decisions related to corrective action related to equipment/calibration issues encountered by Monitoring Field Staff. The Monitoring Field Manager also makes recommendations for flagging data that may be affected due to known equipment/calibration issues. The Monitoring Field Staff (subcontractor) are responsible for maintaining functioning instruments, performing calibration procedures as required, collecting and downloading data, and maintenance of field log books in accordance with this QAPP, the WQMP and all associated SOPs. Field Staff are responsible for reporting any equipment/calibration issues to the Monitoring Field Manager. The Data Processor is responsible for the data that are processed into an annual database and electronic spreadsheets. The Data Processor is responsible for software support and maintaining the interface between the instruments and the receiving station, for reviewing selected portions of the individual data files and for maintaining records of changes or flagging of data in the database. The organizational relationship of these functions is presented in Figure 1. Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Duke Project Manager/Quality Assurance Manager (PM/QA Manager) _]? Monitoring Field Manager Data Processor (Subcontractor) Monitoring Field Staff (Subcontractor) Figure 1: Program Organization Chart A3.0 Project Definition/Background A3.1 Background Duke Energy Carolinas, LLC (Duke) is applying for a new operating license from the Federal Energy Regulatory Commission (FERC) for the Catawba-Wateree Hydro Project (all eleven impoundments and thirteen powerhouses are included in the Catawba-Wateree License, see Figure 2). Along with development of its license application, Duke has developed a Comprehensive Relicensing Agreement (CRA) along with stakeholders to address many Project-related issues. One of the proposed license articles in the Application for New License stipulates a Flow and Water Quality Implementation Plan (FWQIP) to enhance the aquatic resources by improving flow conditions for fish and wildlife and by meeting state dissolved oxygen standards. Even though Duke has previously modified many of the turbines to increase the capacity to aerate the downstream releases, additional plant modifications are necessary to enhance the aeration capacity and/or meet the minimum flow requirements stipulated in the CRA. The FWQIP describes the additional physical modifications, the schedule for completion of the modifications, and any interim measures prior to the physical installation of the equipment. This document is available in Appendix ? of the 401 Water Quality Certification Application. An additional proposed article for the new license is the Water Quality Monitoring Plan (WQMP). This proposed article describes a monitoring program at each hydroelectric station. The WQMP discusses two major activities for water quality monitoring. The Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan first activity is the measurement and reporting of dissolved oxygen concentrations (DO) for the duration of the license (this activity is the focus of this QAPP). The second activity is the measurement of temperature and flow downstream of the Bridgewater project to verify the computer modeling used to establish the flow release patterns into the bypassed reach and the downstream river channel (discussed in Appendix B). The purpose of this QAPP is to provide a quality assurance/quality control program for the proposed DO monitoring described in the WQMP. This QAPP documents the data collection procedures and database management activities to ensure that valid data are used by Duke, NCDWQ, and SCDHEC to evaluate compliance to state dissolved oxygen (DO) standards. This QAPP was developed in accordance with the USEPA guidance document "Guidance for Quality Assurance Project Plans, EPA QA/G-5" dated December 2002. Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Figure 2: Catawba-Wateree Project Location Map LENOIR ' LAKE JAMES SHOALS LAKE LAKE RHODHISS LINCOLNTON MTN. ISLAND LAKE WE NORMAN MOORESVILLE NORTH CAROUNA GASTONIA SOUTH CAROLINA CHARLOTTE LAKE WY LIE FORT MILL I ROCK HILL i (CHESTER .?_ NORTH CAROLINA SOUTH CAROLINA CREEK LAKE ULS LAKE :REEK LAKE LAKE WATEREE Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan 3.2 Problem Statement The goal of the Catawba-Wateree QAPP/WQMP is to provide quality, real-time dissolved oxygen (DO) and temperature data for the project releases. This real-time data will be used by operators to adjust hydro operations to maintain compliance with state DO standards and the requirements of the FERC license. In addition, this data will be used for reporting compliance, and/or non-compliance events to appropriate agencies, as well as conducting on-going evaluations regarding equipment performance and operational guidelines. A4.0 Project Task Description Duke's Monitoring Field Staff will collect DO and water temperature data in accordance with the WQMP. Table 2 summarizes the tasks anticipated to occur under the WQMP and this QAPP. The QAPP will become effective upon final 401 Water Quality Certification by NCDWQ and SCDHEC. The following is a general schedule for the monitoring activities discussed here: Table 2. Water Quality Monitoring Schedule Task Timeframe Notes Water 12 months after FERC At several locations, the installation of water Quality approves the FWQIP quality monitors will precede the installation Monitor (subject to approval in NC of the equipment modifications necessary to installation and SC 401 Water Quality achieve compliance. In these cases, the Certification) per CRA, monitors will assist Duke in the Appendix M implementation of interim measures per the FWQIP. However, these monitor results are not suitable for compliance assessments until the necessary equipment modifications have been implemented (refer to CRA Section 13.2) DO April 1 -November 30 Each year for the term of the license, per Monitoring WQMP/FWQIP Temperature April 1- November 30 Each year for the term of the license, per Monitoring WQMP/FWQIP Annual June 30 The annual report will reflect previous year's Report data; annual reports submitted for the term of Submitted the license A5.0 Quality Objectives and Criteria M The objectives of data measurement, collection, and retention are to provide real-time, continuous information to hydro operators to ensure compliance with applicable State Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Water Quality Standards and FERC license requirements and to provide historical information to operators for continuous improvement of procedures and operations. The following considerations are necessary that the DO sensor be: a. representative of water quality conditions during all Project operations; b. secure (minimize probability of vandalism); c. accessible for maintenance at all flows; and; d. at a distance downstream to achieve a small time-lag between changes in Project operations and monitor response e. maintained to enable a performance within the manufacture's stated accuracy Calibrated and well maintained water quality sensors usually provide more accurate readings than those given by the manufacturer. Routine maintenance and calibration of oxygen sensors is critical since the DO probes are prone to fouling (biological and chemical), which typically results in readings of lower DO concentrations than actually exist. The maintenance and calibration procedures (see Section B7.0) are designed to keep the measurements well within the limits specified by the manufacturer. A6.0 Special Training/Certification All personnel responsible for field monitoring must be familiar with this QAPP and the attached Standard Operating Procedures (SOP). The Monitoring Field Manager will review, and, if necessary, train the Monitoring Field Staff prior to each monitoring season. The training will consist of • Current field procedures and SOP's • Changes, if any, from previous years • Continuous improvement items identified from past data analysis The Monitoring Field Manager will observe the field techniques of the Field Staff at periodic intervals throughout the monitoring season. Any issues with technique will be corrected at that time and documented in the appropriate field log book. All personnel responsible for field monitoring must complete safety training as required by regulating agencies and Duke. Completion of this training will be required on an annual basis will be documented. All training records will be maintained by the Duke PM/QA Manager. A7.0 Documents and Records All personnel with a role in implementing the WQMP will receive the most recently approved QAPP and associated documents. These documents will be updated as necessary by the Duke PM/QA Manager and distributed to all parties listed in Section Al. Any revisions to the QAPP will be noted on the title page with the revision number and effective date. Only the Duke PM/QA Manager will have access to making revisions to the electronic copy of the QAPP, Duke's PM/QA manager is also responsible for Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan obtaining appropriate revision approvals by NCDWQ and SCDHEC and retention of all revisions to the QAPP. Revisions to the QAPP may include but not limited to: • Procedural changes due to continuous improvement activities identified throughout the course of monitoring • Procedural changes due to technological changes and/or improvements • FERC License revisions or requirements • Water quality agency revisions or requirements As specified in the SOP's, during the monitoring season, the Monitoring Field Staff will: • maintain records of calibration • maintain records of maintenance, • maintain records of instrument failure • maintain records of corrective action • any other field notes/information in field log books The field staff will transfer these records electronically to the Monitoring Field Manager on a periodic basis as specified in the SOP'S. The Monitoring Field Manager will summarize all field staff records and monitoring data on a periodic basis throughout the monitoring season. These electronic summaries will be reviewed by the Field Manager and transferred to the Duke PM/QA Manager periodically throughout the monitoring season. All original raw data records (paper and electronic) collected by the field staff during the monitoring season will be transferred to the Duke PM/QA Manager at the end of the monitoring season. The Duke PM/QA Manager will maintain copies of these records in the QA/QC files for this monitoring project for the term of the Catawba-Wateree Project FERC License. The Monitoring Field Manager will maintain scans of all forms and all data files in electronic format for five years. Access to these files is controlled by the Monitoring Field Manager. All non-compliance communications and annual compliance reports submitted to NCDWQ and SCDHEC (see Section A4) will also be maintained in hard copy and electronic format by the Duke PM/QA Manager for the term of the new License. Details of electronic data management are further described in Section B 10 of this QAPP. GROUP B - DATA GENERATION AND ACQUISITION B1.0 Study Design The purpose of monitoring temperature and dissolved oxygen in the water released from the hydro is to ensure that the DO concentration in that water meets or exceeds applicable state WQ standards. The study design was based upon the work by Wagner et al. (2000) Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan and modified to meet specific monitoring objectives described in the License Application. The basic components of the monitoring system are (1) sensors that measure the temperature and dissolved oxygen, (2) a means of getting the sensor data to an appropriate database, and (3) a database capable of meeting the operational and reporting requirements. Duke Energy Carolinas Catawba-Wateree Project No. 2232 Figure 3: System Overview - this configuration will be provided at each hydro facility Located in the Tailrace Lightening Rod Note: Dashed Lines Indicate for Calibration only, one system used at all sites 1211 Power S Pb i -? I Field Data Log" I Underwater Cable - I Calibration Water Quality Monitor SCADA Wave Radio Located at the Hydro Quality Assurance Project Plan Located in Charlotte (Hydro Central) s station Pi Wave A -? Operation Database Radio Computer Underwater Cable Programs for: e Operational Decisions • Compliance Reporting Perforated Standpipe Tailrace Water Quality Monitor I I Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Component Description Tailwater Water Quality Monitor The DO sensor utilizes the most current, practical technology to measure dissolved oxygen. Currently, a luminescence quenching sensor (LDO) to measure dissolved oxygen is planned for tailrace monitoring. This type of sensor is the latest technology which drastically reduces the frequency of maintenance and calibration of the DO electrode (contrasted to the traditional Clark Cell). The monitor also has a temperature sensor. The sensor has a Modbus communication protocol for direct connection to the SCADA wave radio (no additional programming is necessary). Perforated Standpipe This 6-inch diameter, PVC pipe is attached to a structure (concrete wall, bridge piling, etc.) to provide a permanent housing for the sensor. This pipe, perforated on the lower end allows for free exchange of water and protects the sensor and cables from physical damage, vandalism, and lightening. Tailwater Sensor Cables Standard, off-the-shelf, cables are supplied by the sensor vendor. These cables allow power to be supplied to the instrument as well as data transmittal to the SCADA wave radio. Each cable end has a specified fitting for the designated mated end. These cables were chosen (in lieu of custom fabrication of wiring components) to allow rapid troubleshooting and replacement (if necessary). Power Supply, 12 v Supplies power to SCADA wave radio and sensors SCADA Wave Radio This is the standard Duke radio link to send and receive data. The SCADA radio transfers data from remote sensors to the Fix32 system computer. Line of sight clearance is required between radio links. Station Computer The tailrace water quality monitoring data is received by the current operating program at all Catawba Hydros, the system receives sensor input (all plant sensors) and displays the readings. The tailrace water quality monitoring data is integrated into plant operations and is part of the display that the operators are accustomed. In addition, the station computer serves as a backup database. PI Database This is the database currently used by Duke for storing all generation data from all facilities. PI has the ability to record and store data at specified intervals. Standard software extracts data from PI to be used in display formats for operators and/or reporting. The first criteria for the placement of the water quality monitors follows the requirements of the Catawba-Wateree Comprehensive Relicensing Agreement. A schematic of the Catawba River (Figure 4) illustrates the various developments, water release points, and required monitoring locations. Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Figure 4: Schematic Drawing of the Catawba River Catawba River •-- u of Lake James e dba Paddy Ck Paddy Ck E ? I Paddy creek ------------------±-------------: Catawba River Bypassed Reach J Muddy / Creek Notes: 1. Overflow spillway 2. Gated spillway COMPLIA NCE MONITORING LEGEND USGS gage (flow) Duke gage (flow) Reservoir Level Water Quality (Temp & DO) USGS type Staff gage Plate LEGEND ? Powerhouse release - - Recreation release --+ Continuous release -? Regulated reach or River tributary inflow - - - -00. Bypassed reach Lake Resrevoir Dam Structure Arm of Linville River River Catawba River Dam' I Powerhouse Lake Hickory Oxford Oxford Powerhouse Dame Catawba River Lookout Shoals Lake Lookout Lookout Shoals Dam' Shoals PH Lake Norman Cowans Cowans Ford PH Ford Dame Mountain Island Lake Mountain Mountain Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan South Fork Catawba River Notes: 1. Overflow spillway 2. Gated spillway 3. With flash boards Fishing Creek (Continued ) is Mountain Island Lake Mountain Mountain Island PH Island Dam' Aft Lake Wylie Wylie Wylie Dam2 Powerhouse Catawba River Fishing Creek Lake Fishing Fishing Great Falls Reservoir .E N Great Falls Great Falls Dearborn Great Falls N A Great Falls Powerhouse Dam Powerhouse Headwork'.3 Diversion' 3 I Rocky Short Creek Bypass .' Long Bypass V t Cedar Creek Reservoir Rocky Rocky Crk Cedar ou n__1,2 rll__i. nu 4 0 f Lake Wateree Wateree Wateree Powerhouse Dam' Wateree River Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan The figures below show the proposed locations and discuss the rationale of the monitoring equipment location at each of the Catawba-Wateree Developments. The specific locations are based upon the criteria identified in Section A5.0 and downstream field testing. Figure 5: Bridgewater Water Quality Monitoring Location Approximate Map Data Recommended Distance Comments Data Collection Location Location Downstream (miles) Wireless Bypassed Telemetry to Reach Minimum Catawba Dam 0 00 Flow sensor at Station Continuous . flow release valve Computer and Flows Staff Gage for Visual Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Approximate Map Location Data Recommended Location Distance Downstream Comments Data Collection (miles) Minimum Continuous Flows Downstream of USGS Gage and 2 Recreational 1 St Bridge 0 65 USGS Gage Turbine Flows Powerhouse . (New Gage) Generation Project Hourly Road Records Flows 1 St Bridge Powerhouse In Situ - Pipe and Temperature Road Instruments on Wireless 3 Dissolved Linville River 0.25 Bridge Telemetry to Oxygen Downstream (NCDOT approval Station Bridgewater required) Computer Hydro 4 Reservoir Levels Bridgewater n/a Current Device on the Intake Wired to Station Forebay Structure Computer Device Location Rationale The valve at the Catawba Dam will be designed to supply seasonal minimum continuous flows in the Catawba River Bypassed Reach (Location 1). A sensor in the flow pipe or valve, calibrated for flow, will provide a continuous reading of the flow being released into the Catawba River Bypassed Reach. Since the sensor is located directly on the valve or flow pipe, which is on the dam, the sensor should be secure from vandals. The channel configuration at the proposed site for the new USGS gage is ideally suited for the expected range of flows originating from the Linville Dam. The site is located on private property providing a measure of security. The previous water quality monitoring site was located on the downstream side of the powerhouse. Even though that site adequately represented the turbine flow water quality, the future configuration of the Bridgewater Powerhouse is not known, and, therefore, the recommendation for the future water quality monitoring location is at the first downstream bridge (on Powerhouse Road). The bridge provides an existing structure to place the water quality monitor in the center of the narrow river channel. The temporary monitors placed at this site during the Bridgewater downstream investigations (Knight 2003) illustrated similar water quality values to the tailrace monitor at all flows except the 50 cfs leakage flows that will be replaced by 75, 95 or 145 cfs minimum continuous flows in the future depending on the month. This site will represent the water quality conditions of any combination of hydro unit flow (including minimum flow). In addition, the site would be accessible under all Project flows, and would provide a rapid response at the station to water quality conditions. Security from vandals is a concern at this site. Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Map Location Data Recommended Location Approximate Distance Downstream (miles) Comments Data Collection In Situ - Pipe in Temperature Rhodhiss Road Center of Channel Wireless 1 Dissolved Bridge 0 35 and Instruments Telemetry to Oxygen Downstream . Mounted on Station Rhodhiss Hydro Bridge (NCDOT Computer approval required) 2 Reservoir Levels Rhodhiss n/a Current Device on the Intake Wired to Station Forebay oreb y Structure Computer Device Location Rationale The previous water quality monitoring site was located on the south corner on the downstream side of the powerhouse. That site adequately represented the water quality of the turbine flow when all the units were identical, however, the turbine venting tests (Duke Power 2005a), indicated that this location was not representative of the combined flows from units with differing aeration capability. Therefore, the monitor should be Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan moved to the center of the river channel at the downstream bridge (Location 1). The bridge not only provides an existing structure to place the water quality monitor in the center of the channel, but this site represents the water quality conditions of any combination of hydro unit flows (Duke Power, 2005a). This site is accessible under all Project flows, and may provide a rapid response at the station to water quality conditions. Security from vandals may be a slight concern at this site. Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Location F"a ta# . Proposed Flow Valve Monitor o Reservoir Level Monitor c-4AAA'"' V Proposed j WO Monitor USGS type Staff gage 1 ? xF s t a . !.' x WA 4 Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Approximate Map Data Recommended Distance Comments Data Collection Location Location Downstream (miles) In Situ - Pipe Highway 16 South Channel Wireless Temperature Bridge and Instruments Telemetry to 1 Dissolved Downstream 0.15 Mounted on Station Oxygen Oxford Hydro Bridge Computer (NCDOT approval required) Minimum Wireless 2 Continuous Oxford Dam 0 00 Flow sensor at Telemetry to Flows . flow release valve Station Computer Recreational Staff Gage for 3 Flows Riverbend Park 0.30 USGS-Type Plate Visual and Turbine Project Hourly Turbine Records Gage Generation Flows Records Current Device on Wired to Station 4 Reservoir Levels Oxford Forebay n/a the Intake Structure Computer Device Location Rationale An aerating flow valve will be designed to supply and measure a constant minimum continuous flow in the downstream channel (Location 2). A sensor in the discharge pipe or valve, calibrated for flow, will provide a continuous reading of the flow being released into the river channel. Since the sensor is located directly on the valve or flow pipe, which is on the dam, the sensor should be secure from vandals. The flow valve will provide the minimum continuous flow during periods of no hydro unit generation. Generation and recreational flow requirements will be recorded from the generation records for each turbine. A manually read, USGS type plate staff gage will be placed at the boat put-in at Riverbend Park (Location 3) for independent verification. The previous water quality monitoring site was located in the corner of the powerhouse and wingwall. That site adequately represented the water quality of the turbine flow when all the units were identical and prior to the recent installation of the tailrace buttresses. However, this site would probably not be representative of the combined flows from hydro units with differing aeration capability and the buttresses would effectively prevent Unit 2 water from reaching the sensor when Unit 1 was generating. Therefore, the monitor should be moved to the Highway 16 Bridge immediately downstream of the turbines (Location 1). The bridge not only provides an existing structure to place the water quality monitor in the channel, but this site will represent the water quality conditions of any combination of hydro unit flows. This site will be accessible under all Project flows, and will provide a rapid response of the station to water quality conditions. Security from vandals may be a concern at this site. Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Approximate Map Data Recommended Distance Comments Data Collection Location Location Downstream (miles) Temperature East W l - In Situ - Pipe, Wired to Station 1 Dissolved Tailrace race 0.01 Monitor Location Computer Oxygen Unchanged Minimum Continuous Turbine 2 Flows Turbine Records n/a n/a Generation Project Hourly Records Flows Current Device on Wired to Station 3 Reservoir Levels Lookout Forebay n/a the Intake Computer Structure Device Location Rationale The minimum continuous flow will be provided by either one of the small auxiliary hydro units (Location 2) during periods when the larger hydro units are not operating. The configuration of the Lookout Shoals tailrace (large pool upstream of first downstream hydraulic control) exhibits very little stage change with or without the Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan auxiliary hydro unit generation. In addition, the elevation of the tailrace is also a function of Lake Norman's reservoir level (at full pond, the reservoir level extends upstream of the hydraulic control). Therefore, the minimum continuous flow and hourly flow rates would be best monitored by the individual generation records of each hydro unit at Lookout Shoals Hydro. The previous water quality monitoring site was located on the east wingwall downstream of Unit 1. That site adequately represented the water quality of the turbine flow when all the hydro units were identical. The nearest downstream structure to place a monitor in the center of the channel is the I-40 Bridge which is 1.3 miles downstream. The I-40 Bridge site is strongly influenced by Lake Norman's reservoir level, and the long travel time of the minimum flow would influence the water quality at minimum flow. Therefore, the I-40 Bridge location is not preferred for water quality monitoring. Since no other downstream structure exists to place a monitor in the center of the river, the wingwall site (Location 1) represents the best logistical option available for water quality monitoring. This wingwall site will be accessible under all Project flows, and will provide a rapid response of the station to water quality conditions. The monitor will be secure since it is located inside the security fence. Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Map Location Data Recommended Location Approximate Distance Downstream (miles) Comments Data Collection In Situ - Pipe West Temperature Railroad Bridge Channeland Instruments Wireless 1 Dissolved Downstream 0 50 Mounted on Telemetry to Oxygen Cowans Ford . Bridge n Station Hydro (Railroad approval Computer required) 2 Reservoir Levels Cowans Ford n/a Current Device on Wired to Station Forebay Intake Structure Computer Device Location Rationale Even though the previous monitor was placed on the tail-deck of the hydro, this location probably represented the water quality of the released flow. However, under multi-unit Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan operation, the monitor would only record data from the hydro unit flows adjacent to the monitor. In addition, security at the Cowans Ford Hydro facility is controlled by the McGuire Nuclear site (Nuclear Regulatory Commission guidelines) and is difficult to enter when operators are not present. This security issue limits maintenance accessibility. Therefore, the recommended site for the future temperature and dissolved oxygen monitoring is at the railroad bridge 0.5 miles downstream (Location 1). This site would enable the monitor to measure water quality from the high-volume hydro unit flow as well as provide a somewhat secure and accessible site. Location of the monitor just west of the downstream tip of the island would insure that the monitor would be out of the influence of the wastewater discharge from McGuire Nuclear Station. Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Approximate Map Data Recommended Distance Comments Data Collection Location Location Downstream (miles) Temperature Tail Deck - In Situ - Pipe, Wired to Station 1 Dissolved Tailrace 0.00 Monitor Location Computer Oxygen Unchanged 2 Reservoir Levels Mt. Island n?a Current Device on Wired to Station Forebay Intake Structure Computer Device Location Rationale Even though the present monitor is on the tail-deck of the hydro (Location 1), this location probably represents the water quality of the released flow. However, under multi-unit operation, the monitor would only record data from the hydro unit flows adjacent to the monitor. Since no other structure, (e.g., bridge), exists in the center of Mountain Island's tailrace, this tail-deck location represents the best logistical location available. It is secure and provides ready access for maintenance. Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Map Location Data Recommended Location Approximate Distance Downstream (miles) Comments Data Collection Flow-Through Temperature 12 mile System Auto Wireless 1 Dissolved Downstream 0 50 Calibration Sensor Telemetry to Oxygen from Hydro (pier . (Island property ' Station on Ferrell Island) owner s approval Computer required) Small Unit USGS Gage USGS Gage and Minimum Turbine Records 0 00 (Catawba River Turbine 2 Continuous Highway 21 . 3.60 near Rock Hill, Generation Flows USGS Gage ) Records (02146 Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Map Location Data Recommended Location Approximate Distance Downstream (miles) Comments Data Collection Recreational USGS Gage USGS Gage and Flows Turbine Records 0 00 (Catawba River Turbine 3 Project Hourly Y Highway 21 . 3.60 near Rock Hill, Generation Flows USGS Gage SC ) Records (02146000) Current Device on Wired to Station 4 Reservoir Levels Wylie Forebay n/a the Intake Computer Structure Device Location Rationale The USGS gage at the Highway 21 Bridge (Location 2/3) is well established and will be used for verification of minimum continuous flow, recreational flows, and hourly Project flows. In addition, generation records will be used to supplement the USGS data. The previous water quality monitoring site was located in the corner of the powerhouse and wingwall. Extensive monitoring of dissolved oxygen concentrations in the Wylie tailrace was conducted during the 2002 turbine venting test (Duke 2005a). These results indicated that the proposed monitoring location was the closest point to the hydro that best represented the water quality of the multi-unit flows (Location 1). This test included detailed water quality sampling along several downstream transects, as opposed to just at the monitoring site. Furthermore, the Wylie tailrace is very complicated since the island immediately downstream of the powerhouse splits the water released from the hydro. The flow, from either a single unit or multiple unit operation, moves around the island and finally merges just upstream of the small island across the channel from the proposed monitoring location. Use of this location is contingent on being able to get permission for access from the property owner and on obtaining any necessary easements. Security from vandals is of some concern at this site. Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Map Location Data Recommended Location Approximate Distance Downstream (miles) Comments Data Collection In Situ - Pipe Highway 97/200 West Channel Wireless Temperature Bridge and Instruments Telemetry 1 Dissolved Downstream Fishing 0.15 mounted on to Station Oxygen Creek Hydro Bridge Computer (SCDOT approval required) Reservoir Fishing Creek Existing Device Wired 2 Levels Forebay N/A on the Intake to Station Structure Computer Device Location Rationale The previous water quality monitoring site was located on the wingwall, west of the Fishing Creek Powerhouse. That site adequately represented the water quality (temperature and dissolved oxygen) of the turbine flow when all the hydro units were identical and prior to the recent installation of the tailrace buttresses. However, this site would probably not be representative of the combined flows from hydro units with differing aeration capability since the flows will be directed downstream due to the newly Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan installed buttresses. Therefore, the monitor will be moved to the Highway 97/200 Bridge immediately downstream of the turbines (Location 1). The bridge not only provides an existing structure to place the water quality monitor in the channel, but this site will represent the water quality conditions of any combination of hydro unit flows. This site is accessible under all Project flows, and will provide a rapid response of the station to water quality conditions. Security from vandals may be a concern at this site. Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Figure 13: Great Falls / Dearborn Diversion Dam Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Headworks Main Dam Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Approximate Map Data Recommended Distance Comments Data Location Location Downstream Collection (miles) Pressure Sensor Bypassed calibrated to Wireless Reaches Diversion Dam correspond to Telemetry Minimum Long Bypassed 0.25 mi. from minimum continuous to Station 1 Continuous Reach Downstream Fishing Creek pond level. Pressure l. Computer Flows Recreational Fishing Creek Dam Sensor calibrated to and Staff Gage Flows Hydro correspond to for visual recreational flows and pond level. Gate Position Sensor calibrated to gate Bypassed Headworks opening Wireless Reaches Short Bypassed corresponding to Telemetry Minimum Reach 1.95 mi. from minimum continuous to Station 2 Continuous Downstream Fishing Creek flow. Computer Flows Fishing Creek Dam Pressure Sensor and Recreational Hydro calibrated to Staff Gage Flows correspond to for visual recreational flows and pond level. Temperature Duke Bridge 0.1 mi. from In Situ - Pipe, Wired to 3 Dissolved Downstream of Great Falls - Monitor Location Station Oxygen Hydros Dearborn Dam Unchanged Computer Reservoir Great Falls Existing Device Wired 4 Levels Forebay N/A on the Intake to Station Structure Computer Device Location Rationale Ideally, measurement of the minimum continuous flows and recreational flows in the Great Falls Long and Short Bypassed Reaches would be taken directly in the respective channels. However, the irregular channel configuration in both reaches prevents accurate flow measurements from stage changes. In addition, the difficult access to the bypassed reaches poses substantial personnel safety limitations to the calibration and maintenance of the gages. Therefore, the best measurement of the flow in the bypassed reaches is at the source of the flows (Locations 1 and 2). Although the exact design of the minimum continuous flow delivery mechanism has not been completed, the measurement of flow will be a stage-discharge relationship between the pond level and the flow being delivered. Continuous flow monitoring for the Long Bypass will be located at the Great Falls Diversion Dam immediately downstream of Fishing Creek Hydro (Location 1). The continuous flow monitoring for the Short Bypassed Reach will be provided at the Great Falls Headworks spillway, both upstream and downstream of the headworks structure (hence a flow measurement system upstream and downstream of the headworks) (Location 2). Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Recreational flows will be provided as spill over the Great Falls Diversion Dam and the Great Falls Headworks. Again, the water level over the spillways will be measured and stage-discharge equations will relate stage to flow. Manually read, new USGS type plate staff gages will be placed at the Great Falls Diversion Dam and upstream of the Great Falls Headworks. The previous water quality monitor mounted on the Duke Energy bridge immediately downstream of Great Falls and Dearborn Hydros is ideally located since it is in the center of the channel (Location 3). This position captures the water quality (temperature and dissolved oxygen) from both hydros and is in a secure location. Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Approximate Map Location Data Recommended Location Distance Downstream Comments Data Collection (miles) Temperature Downstream In Situ - Pipe 1 Dissolved Face of Cedar 0.00 , Monitor Location Wired to Station Oxygen Creek Unchanged Computer Powerhouse 2 Reservoir Levels Cedar Creek n/a Current Device on the Intake Wired to Station Forebay Structure Computer Device Location Rationale The previous water quality monitor is located in the center of the Cedar Creek tailrace. It was mounted directly on the powerhouse. Since the hydro units at Cedar Creek were identical, the temperature and dissolved oxygen monitor adequately measured the water quality released from Cedar Creek Powerhouse (Location 1). The water quality of the Cedar Creek hydro flow represents the overall tailrace water quality since: Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan • Cedar Creek Powerhouse flow is significantly greater than Rocky Creek Powerhouse flow and dominates the downstream flow (capacity of Cedar Creek units is three times the capacity of the Rocky Creek units). • Rocky Creek Hydro is operated infrequently; it is operated only after Cedar Creek Reservoir pond level cannot be maintained by Cedar Creek Hydro (three Units at Cedar Creek). • Both hydros draw water from the same forebay and the water quality is similar. Thus, no water quality monitoring device is necessary at the Rocky Creek Hydro. Unlike Great Falls-Dearborn, there is no structure downstream of Cedar Creek Powerhouse to mount a water quality monitor in the center of the channel. Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Map Location Data Recommended Location Approximate Distance Downstream (miles) Comments Data Collection Temperature Probably Flow- 1 Dissolved West Platform - 0'02 Through System Wired to Station Oxygen Tailrace Auto Calibration Computer Sensor USGS Gage USGS Gage and Minimum Highway 1/601 (Wateree River Turbine 2 Continuous USGS Gage 7.4 near Camden, Generation Flows SC) Records (02148000) Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Approximate Map Data Recommended Distance Comments Data Collection Location Location Downstream (miles) Recreational USGS Gage USGS Gage and Flows Turbine Records (Wateree River Turbine 3 ject Hourl Project Y Highway 1/601 7.4 near Camden, Generation Flows USGS Gage SC ) Records (02148000) Wateree Current Device on Wired to Station 4 Reservoir Levels Forebay n/a the Intake Computer Structure Device Location Rationale The USGS gage at Highway 1/601 (Location 2/3) is well-established and will be used for verification of minimum continuous flow, recreational flows, and hourly Project flows. Generation records will be used to supplement the USGS data. The Wateree tailrace is a relatively simple channel, with the flows from the various hydro units moving directly downstream. However, the tailrace does not lend itself to simple water quality monitoring due to the various aeration capabilities of the individual hydro units and subsequent multi-unit flow patterns (Duke Power 2005a). Moving the monitor location downstream to capture a multi-unit flow is not an option because, at flows greater than provided by 2-3 unit operations, a significant volume of water flows out of the main channel to the east within a few hundred yards of the powerhouse. The existing monitor location (Location 1) was built to extend a short distance into the tailrace with the goal of better measurements than at the face of the powerhouse. The existing monitor location is the best logistical location available to measure water quality because no structure exists in the center of the channel, nor is the east side of the channel a viable option because that area is heavily used by fisherman (creating damage and security issues) and is prone to flooding and further potential damage or loss. The next available location at the Highway 1/601 Bridge is not suitable because of its distance from the Powerhouse and the presence of aquatic plants and shoals between the Powerhouse and bridge that significantly influence the DO levels. 132.0 Sampling Methods All dissolved oxygen and temperature data will be collected In Situ using submerged instruments within standpipes attached to a permanent structure in the tailrace. The instruments will be powered by an external power source and data transmitted to the station operational computer. The data are available in real-time for operational decisions regarding aeration. The tailrace data will be collected between April 1 and November 30 each year, with an annual report available June 30 of the following year. This monitoring period was Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan selected based upon the 10-year monitoring presented in the License Application. At no time were dissolved oxygen concentrations less than 5 mg/l during the period December through March. B3.0 Sample Handling and Custody No samples will be collected, transported, or stored since all dissolved oxygen and water temperature measurements will be recorded in situ. B4.0 Analytical Methods The Winkler determination for dissolved oxygen is the only chemical analytical method employed for the monitoring. This technique forms the basis of all instrument calibrations. B5.0 Quality Control Quality control measures for Dissolved Oxygen and Temperature measurements will include proper calibration and regular tracking and servicing of instruments (see Sections B6 and 137). Quality assurance activities include documentation of field procedures, data back-up, automatic data logging, training, etc. B6.0 Instrument/Equipment Testing, Inspection, and Maintenance The Monitoring Field Manager is responsible for establishing the proper procedures for testing, inspection, calibration, and maintenance of all water quality instruments. The procedures will include a thorough evaluation of instrument performance; evaluations will include sensor response times for large concentration differences and linearity checks of instrument calibration from less than 10% DO saturation to greater than 100% saturation. Quality control charts will be maintained for each instrument (tracked by serial number) for response times and linearity over the lifetime of the instrument. In addition to obvious problems, these charts will be used to evaluate the suitability of instrument deployment, instrument repair, and/or return for manufacturer servicing. All maintenance and servicing of instruments will be recorded by the field staff in a maintenance log book and in an established electronic format. B7.0 Instrument/Equipment Calibration and Frequency Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Calibration of the Dissolved Oxygen Sensor(s) consists of either a primary calibration or a secondary calibration. Primary Dissolved Oxygen Calibration This calibration consists of adjusting an instrument to read at the primary standard concentration (manufacturer calibration method). This calibration is performed in the laboratory by adjusting all instruments to a known concentration of oxygen, as determined by the Winkler method. Each instrument, prior to deployment in a tailrace, shall be calibrated to the Winkler standard. Secondary Dissolved Oxygen Calibration This calibration is reserved for evaluation of whether an instrument that has been deployed shall remain deployed or taken back to the laboratory for maintenance. One designated instrument (primary calibration performed that same day) shall be used at all sites that day to compare its readings side-by-side with the deployed. If the differences between the two instruments are greater than the manufacturers' tolerances, the deployed instrument shall be calibrated to the recently calibrated instrument. If the deployed instrument does not calibrate or the differences are greater than the control chart limits (see next paragraph), the deployed instrument shall be returned to the laboratory for maintenance and be replaced with a recently calibrated (primary) instrument. Quality control charts shall be maintained for all comparisons of instruments. These charts shall be maintained by individual instruments and by location. This data shall be used to determine the limits of out of calibration tolerance for instrument field calibration criteria. Initially, calibrations and checks on calibration will be conducted weekly. However, over time the quality control charts will be used to adjust calibration frequency, especially if the technologically advanced sensors require far less maintenance than conventional sensors. ? ) o A B8.0 Inspection/Acceptance of Supplies and Consumables The Monitoring Field Manager approves all orders for supplies required for instrument maintenance and calibration. Upon receipt, all supplies will be inspected for damage. All supplies and equipment ordered will be stored and documented in accordance with Duke's Chemical Inventory and approved through Duke's chemical approval process. B9.0 Non-Direct Measurements Measurement data not obtained directly under the DO Monitoring Plan and this QAPP, including hydro plant generating data, reservoir elevation data, National Weather Service weather data, and U.S. Geological Survey (USGS) gage stream flow data, may be used Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan for interpretation of continuous DO monitoring data. Data collected by regulatory and governmental agencies will be used and considered as valid data since these agencies have independent QA/QC programs to ensure valid data. Catawba-Wateree Project generation data will be acquired through Duke Energy's Hydro Fleet Operations. Data from universities, non-governmental organizations, or industries may be used to analyze continuous monitoring results depending upon methods, sampling design, and QA/QC limitations. Citations will be made when such data are used. 1310.0 Data Management The continuous DO and water temperature data are collected and monitored on a real time basis. As the sensor detects the concentrations, the data is automatically transmitted to the PI data system via the station computer. The PI database provides for permanent records storage while the station computer temporarily stores the data should the transfer link to the PI system fail. Once in the PI data system, the data, or its derivatives, will be provided to Duke's real time Hydro Operations Center. The protocol for data transmission, storage, and retrieval is controlled by the Plant Information (PI) database management team. Data files are stored for the duration of the project on the PI data server, which is backed up electronically on a daily basis. GROUP C - ASSESSMENT AND OVERSIGHT C1.0 Assessment and Response Actions The Monitoring Field Manager or a qualified QA/QC Auditor appointed by the Monitoring Field Manager will perform an annual (after the field monitoring season) internal self-assessment of the QA program to ensure the QA/QC records are complete and accountable. The self-assessment results will be documented and provided to the Duke PM/QA Manager for the project QA/QC files. Any corrective actions, as required, will be implemented and documented. The Duke PM/QA Manager provides additional oversight through the review of the QA/QC records generated for the continuous DO and water temperature monitoring. The Duke PM/QA Manager will review and verify field data collection, data processing and data file submittals; submittal of QA records to the QA/QC file; corrections or revisions to data files and any subsequent documentation in the QA/QC file; and self-assessment results. The Monitoring Field Manager will observe the field techniques of the Field Staff at periodic intervals throughout the monitoring season. Any issues with technique will be corrected at that time and documented in the appropriate field log book. C2.0 Reports to Management Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan The process for reporting significant issues will follow a chain of command structure. The Monitoring Field Manager will report problems to the Duke PM/QA Manager and will address the problem. The Duke PM/QA Manager will receive annual reports, copies of log books, and calibration forms for review and will ensure that these records are maintained in a designated QA/QC file. GROUP D - DATA VALIDATION AND USABILITY D1.0 Data Review, Verification, and Validation Throughout the monitoring season, the Monitoring Field Staff or Monitoring Field Manager will periodically transfer data from the PI system to software designed to perform provisional data summaries and trend analysis. Calibration and maintenance data will be incorporated into this program/database. The Monitoring Field Manager will review this data for completeness and flag suspect data and/or evaluate anomalies, trends, compliance issues, etc and will provide the provisional data, along with recommendations, to the Duke PM/QA Manager after it is processed. Only the Monitoring Field Manager has access to the database to change or correct data. The Monitoring Filed Manager will provide the Duke PM/QA Manager with a copy of the final Annual Database at the end of the field monitoring season. Supporting calibration forms and maintenance records will be transferred to the Duke PM/QA Manager. D2.0 Verification and Validation Methods Throughout the entire monitoring season the database is archived systematically to ensure no loss of data and to guarantee database integrity. At the end of the field monitoring season, all forms, original data, and the database will be archived in electronic format on digital media; and stored in an electronic storage format as well as by the Duke PM/QA Manager. D3.0 Reconciliation with User Requirements The real time data will be available in the Hydro Operating Center which will be displayed with real-time trending analysis "process book" and PI related calculation tools. The real time presentation allows for quick identification of instrument and or operational issues with the data and allows for immediate problem identification and resolution. Duke Energy Carolinas Catawba-Wateree Project No. 2232 Quality Assurance Project Plan Data collected during the Catawba-Wateree Compliance Monitoring program will be used to adjust hydro operations to comply with the requirements of the 401 Water Quality Certification and the FERC license and provide water quality data for reporting compliance, and/or non-compliance events to appropriate agencies, as well as conducting on-going evaluations regarding equipment performance and operational guidelines. In the event that anomalies are found in the data, the Duke PM/QA Manager will review the field notes taken by the Monitoring Field Manager and look for storm events or unusual watershed conditions and assess their effects on data. Data collected for each monitoring season will be put in report form and provided to NCDWQ, SCDHEC, Duke and FERC, as well as archived in the PI system. Any anomalies and analysis for any peaks or changes in data throughout the year will be documented in the reports provided by the Field Manager to the Duke PM/QA Manager. Any sampling design modifications will be considered only after consultation with NCDWQ/SCDHEC. REFERENCES Duke Energy. 2006. Catawba-Wateree Project FERC # 2232 Application for New License Exhibit E - Water Quantity, Quality, and Aquatic Resources, Study Reports. Duke Energy. Charlotte, NC. Wagner, R.J., H.C. Mattraw, G.F. Ritz, and R.A. Smith. 2000. Guidelines and Standard Procedures for Continuous Water-Quality Monitors: Site Selection, Field Operation, Calibration, Record Computation, and Reporting. U. S. Geological Survey, Water-Resources Investigations Report 00=4252. Reston, Virginia. United States Environmental Protection Agency. 2001. EPA Requirements for Quality Assurance Project Plans. EPA QA/R-5, EPA/240/B-01/003. USEPA, Office of Environmental Information, Washington D.C. APPENDIX A Standard Operating Procedures for In Situ Compliance Monitoring (to be completed upon receiving equipment and manufacturer's operating manuals) 1. Laboratory Evaluation of Water Quality Sensor Performance (make sure sensor performs as designed) 2. Configuration and Calibration of Water Quality Sensors Prior to Field Deployment (setup and calibration of instrument before deployed in tailrace) 3. Determination of Dissolved Oxygen Using the Winkler Method. (used for laboratory calibration of sensors) 4. Routine Maintenance of Water Quality Sensor After Field Deployment (cleaning, troubleshooting, and storing instrument between field deployments) 5. In-field Instrument Performance Check, Calibration, and Criteria for Instrument Replacement (verification of instruments calibration while deployed and/or instrument replacement) APPENDIX B Bridgewater Development Supplemental Trout Habitat Monitoring The Catawba River Bypassed Reach and Bridgewater minimum continuous flows have been selected and evaluated to provide flows and water temperatures suitable for protection and enhancement of mussels in the bypassed reach and the maintenance of a stocked trout fishery downstream of Bridgewater Hydro. The volume of warmwater flows provided to the Catawba River Bypassed Reach to maintain mussel habitat are balanced against the coldwater minimum flow from the Linville Dam to maintain suitable temperatures for trout downstream of the confluence of the Catawba River Bypassed Reach and the Linville River. The flows and temperatures provided to each channel to achieve the desired, but conflicting temperature requirements were analyzed by the CE- QUAL-W2 reservoir model and the River Modeling System (RMS). The results of these computer models were evaluated by the Aquatics/Terrestrial and Water Quality Resource Committees. Bypassed Reach and Linville Dam minimum continuous flows stated in the CRA are the result of the recommendations from the evaluations by the resource committees. Monitoring Due to the hydraulic complexity and apparent conflicts of resource management interests (differing trout and mussel temperature preference) in this area, supplemental monitoring will be used to support future evaluations of whether trout management goals in the mainstem Catawba River continue to be supported. This supplemental trout habitat monitoring will commence after the Bridgewater Powerhouse has been replaced with either a new powerhouse or valve system and compliance operations have begun. This measurement and evaluation will continue through the next cycle of NCDWQ Catawba River Basinwide Assessment period, but not beyond Year 2019. Results of this monitoring are not intended to be used for water quality certification compliance purposes, but for continued aquatic resource assessments. These monitoring results may be used to determine if flow reductions need to be made in the Catawba River Bypassed Reach. Sensor Locations The temperature and level logger placement is designed to be able to record temperatures, flow (level logger with stage-discharge relationship) from the inflows, and empirically determine the temperatures at the appropriate downstream river reaches. An additional temperature and level logger will be provided at the Watermill Bridge (RM 271.7) in Glen Alpine, NC which is in the middle of the primary trout habitat. Level loggers (devices to record river stage from which a stage-discharge relationship may be developed to calculate flow) and temperature loggers will be placed in the river and periodically downloaded to obtain the respective data. Stage-discharge curves will be developed at the level logger sites. Rer)ortina Requirements Annual reports will be provided to NCDWQ and NCWRC (30 April) for the duration of the supplemental trout habitat monitoring detailing the previous calendar year's temperatures and levels. Flow-weighted temperatures will be calculated for the downstream sites. Bridgewater Supplemental Trout Habitat Monitoring