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Home My WebLink About#248_2022_0718_MC_Revised_FINAL On-Site Inspection Report LABORATORY NAME: Duke Power Company LLC d/b/a Duke Energy Carolinas LLC NPDES PERMIT #: NC0001422, NC0003417, NC0003425, NC0003433, NC0003468, NC0004774, NC0004979, NC0004987, NC0005088, NC0005363, NC0024392, NC0024406, NC0038377, NC0039586 ADDRESS: 13339 Hagers Ferry Road Huntersville, NC 28078-7929 CERTIFICATE #: 248 DATE OF INSPECTION: July 18, 2022 TYPE OF INSPECTION: Industrial Maintenance AUDITOR(S): Michael Cumbus, Jill Puff, Tonja Springer and Beth Swanson LOCAL PERSON(S) CONTACTED: Girish Sharma, Garrett Hutchings, Chad Spence, Maggie Hall, Jesse Arias, Bonnie Young, Dale Mace and Johnny Haynes I. INTRODUCTION: This laboratory was inspected by a representative of the North Carolina Wastewater/Groundwater Laboratory Certification Branch (NC WW/GW LCB) to verify its compliance with the requirements of 15A NCAC 02H .0800 for the analysis of compliance monitoring samples. II. GENERAL COMMENTS: The facility is neat, well maintained and well organized and has all the equipment necessary to perform the analyses. Staff were very knowledgeable, forthcoming and responded well to suggestions from the auditors. All required Proficiency Testing (PT) Samples have been analyzed and the laboratory has fulfilled its PT requirements for the 2022 PT Calendar Year. The laboratory is reminded that any time changes are made to laboratory procedures, QA/SOP document(s) must be updated and relevant staff retrained. Staff must acknowledge that they have read and understand the changes as part of the documented training program. The same requirements apply when changes are made in response to Findings, Recommendations or Comments listed in this report, to ensure the methods are being performed as stated, references to methods are accurate, and the QA and/or SOP document(s) is in agreement with each approved practice, test, analysis, measurement, monitoring procedure or regulatory requirement being used in the laboratory. In some instances, the laboratory may need to create an SOP to document how new functions or policies will be implemented. Revisions to the SOPs, based on the Findings, Comments and Recommendations within this report must be submitted to this office by November 30, 2023. The laboratory is also reminded that SOPs are required to be reviewed at least every two years and are intended to describe procedures exactly as they are to be performed. Use of the word “should” is not Page 2 #248 Duke Power Company LLC appropriate when describing requirements (e.g., Quality Control (QC) frequency, acceptance criteria, etc.). Evaluate all SOPs for the proper use of the word “should”. Laboratory Fortified Matrix (LFM) and Laboratory Fortified Matrix Duplicate (LFMD) are also known as Matrix Spike (MS) and Matrix Spike Duplicate (MSD) and may be used interchangeably in this report. Laboratory Fortified Blank (LFB) is also known as Laboratory Control Standard (LCS) and may be used interchangeably in this report. Contracted analyses are performed by Pace Analytical Services LLC – West Columbia (Certification #329), Pace Analytical Services LLC – Huntersville (Certification #12), Pace Analytical Services LLC – Asheville (Certification #40), and GEL Laboratories LLC (Certification #233). At the time of the inspection, the following parameters were being subcontracted to other laboratories for compliance sample analyses: Phosphorus, Turbidity, Ammonia-Nitrogen, Nitrate + Nitrite Nitrogen, Total Kjeldahl Nitrogen (TKN) and Alkalinity. III. FINDINGS, REQUIREMENTS, COMMENTS AND RECOMMENDATIONS: Documentation Comment: The laboratory recently acquired a second instrument for Mercury analysis. The analyst commented that they anticipate separating Methods EPA 245.1 and SW-846 7470A and eliminate combined runs. The instrument identification is located on the initial page of the raw data package as part of the data software. However, the data package cover sheets, QC batch reports and instrument run logs list only the model number of the instrument. The laboratory must update all associated paperwork to ensure that traceable links include the correct instrument. A. Finding: Error corrections are not always properly performed. Requirement: All documentation errors shall be corrected by drawing a single line through the error so that the original entry remains legible. Entries shall not be obliterated by erasures or markings. Wite-Out®, correction tape, or similar products designed to obliterate documentation shall not to be used; instead, the correction shall be written adjacent to the error. The correction shall be initialed by the responsible individual and the date of change documented. Ref: 15A NCAC 02H .0805 (a) (7) (E). Comment: Several instances were noted where changes were written over the initial data. (e.g., The temperature reading for the Metals Hot Block #22 on June 9, 2022 was written over, and lacked a date of change and the analyst’s initials. B. Finding: Documentation for the Standard Preparation Logs for metals standards is sometimes lacking pertinent information: the final concentration of the prepared solutions. Requirement: All analytical records, including original observations and information necessary to facilitate historical reconstruction of the calculated results, shall be maintained for five years. All analytical data and records pertinent to each certified analysis shall be available for inspection upon request. Ref: 15A NCAC 02H .0805 (a) (7) (E). Comment: The Standard Preparation Log for the Reporting Limit Standard (RLS) for Inductively Coupled Plasma-Optical Emission Spectrometry (ICP-OES) analyses lacks the final concentration for individual analytes. Page 3 #248 Duke Power Company LLC C. Finding: Some benchsheets do not fully reference the approved methods. Requirement: All laboratories shall use printable laboratory benchsheets. Certified Data shall be traceable to the associated sample analyses and shall consist of: the method or Standard Operating Procedure. Each item shall be recorded each time samples are analyzed. Ref: 15A NCAC 02H .0805 (a) (7) (F) (i). Comment: The QC Batch reports and Water Quality Data benchsheets for Total Suspended Residue (TSR) and Total Dissolved Residue (TDR) are missing the method year. Comment: The analytical benchsheet, QC Batch reports and Water Quality Data benchsheets for pH are missing the method year. Comment: The Order Summary Report lacks revision numbers for EPA Methods and the method year for Standard Methods analyses. D. Finding: The preparation of standards and use of reagents and consumables are not always documented in such a way as to provide traceability from preparation to analysis. Requirement: Chemical containers shall be dated when received and when opened. Reagent containers shall be dated, identified, and initialed when prepared. Chemicals and reagents exceeding the expiration date shall not be used. The laboratory shall have a documented system of traceability for the purchase, preparation, and use of all chemicals, reagents, standards, and consumables. Ref: 15A NCAC 02H .0805 (a) (7) (K). Requirement: 15A NCAC 02H .0805 (a) (7) (K) and (g) (7) requires laboratories to have a documented system of traceability for the purchase, preparation, and use of all chemicals, reagents, standards, and consumables. That system must include documentation of the following information: Date received, Date Opened (in use), Vendor, Lot Number, and Expiration Date (where specified). A system (e.g., traceable identifiers) must be in place that links standard/reagent preparation information to analytical batches in which the solutions are used. Documentation of solution preparation must include the analyst’s initials, date of preparation, the volume or weight of standard(s) used, the solvent and final volume of the solution. This information as well as the vendor and/or manufacturer, lot number, and expiration date must be retained for primary standards, chemicals, reagents, and materials used for a period of five years. Consumable materials such as pH buffers, lots of pre-made standards and/or media, solids and bacteria filters, etc. are included in this requirement. Ref: NC WW/GW LCB Traceability Documentation Requirements for Chemicals, Reagents, Standards and Consumables Policy. Comment: The laboratory retains Certificates of Analysis (COA) for purchased metals stock solutions in the receiving department. These are labeled with a unique tracking number and include a space for the Date Opened. However, that location is not utilized and the Date Opened is only recorded on the bottle. While this can provide a traceability link to analyses while the chemicals are still in use, that link is lost once the bottles are discarded. Comment: The laboratory is lacking documentation for the lot numbers of the Stable-Weigh bags used in residue analyses. Comment: There was no documentation of the preparation of the working Internal Standard (IS) solution or the Spectral Interference Check (SIC) working solution for samples analyzed by ICP-OES. Page 4 #248 Duke Power Company LLC Comment: The laboratory benchsheets for Mercury analysis and metals analyses by Inductively Coupled Plasma - Mass Spectrometry (ICP-MS) and ICP-OES do not document the lot numbers of the spiking solutions used to prepare the LFB or LFM/LFMD. Comment: Preparation of the MS and MSD samples for Total Kjeldahl Nitrogen (TKN), Nitrate + Nitrite (NO2+NO3) Nitrogen, Ammonia Nitrogen and Total Organic Carbon (TOC) is not being documented. E. Finding: The laboratory benchsheet is lacking required documentation: units of measure. Requirement: All laboratories shall use printable laboratory benchsheets. Certified Data shall be traceable to the associated sample analyses and shall consist of: the proper units of measure. Each item shall be recorded each time that samples are analyzed. Ref: 15A NCAC 02H .0805 (a) (7) (F) (xii). Comment: The QC Batch sheets for metals analyses record the volume of spiking solution added to the sample but lack the units of measure for the spiking solution. F. Finding: The laboratory benchsheet for ICP-OES is lacking required documentation: the spectral wavelength used to report results. Requirement: All laboratories shall use printable laboratory benchsheets. Certified Data shall be traceable to the associated sample analyses and shall consist of: any other data needed to reconstruct the final calculated result. Each item shall be recorded each time that samples are analyzed. Ref: 15A NCAC 02H .0805 (a) (7) (F) (xviii). Requirement: Detection limits and linear ranges for the elements will vary with the wavelength selected, the spectrometer, and the matrices. Table 1 provides estimated instrument detection limits for the listed wavelengths.7 However, actual method detection limits and linear working ranges will be dependent on the sample matrix, instrumentation, and selected operating conditions. Ref: EPA Method 200.7, Rev. 4.4 (1994), Section 1.10. Requirement: The wavelengths listed are recommended because of their sensitivity and overall acceptability. Other wavelengths may be substituted if they can provide the needed sensitivity and are treated with the same corrective techniques for spectral interference (see Section 4.1). Ref: EPA Method 200.7, Rev. 4.4 (1994); Table I, Footnote a. Comment: The laboratory currently calibrates and monitors multiple wavelengths for a number of elements. However, there is no documentation to show which wavelength is used to report data. Additionally, there is no indication as to why a particular wavelength is selected, and reporting limits in the SOP are only established for the primary wavelength. G. Finding: The laboratory benchsheet is lacking required documentation: acceptance criteria for the analytical balance verification checks. Requirement: All laboratories shall use printable laboratory benchsheets. Certified Data shall be traceable to the associated sample analyses and shall consist of: all quality control assessments. Each item shall be recorded each time that samples are analyzed. Ref: 15A NCAC 02H .0805 (a) (7) (F) (xv). Comment: This Finding applies to Oil & Grease samples analyzed by EPA Method 1664, Rev. B. Page 5 #248 Duke Power Company LLC H. Finding: The laboratory MDL spreadsheet is lacking required documentation: instrument identification. Requirement: All laboratories shall use printable laboratory benchsheets. Certified Data shall be traceable to the associated sample analyses and shall consist of: the instrument identification. Ref: 15A NCAC 02H .0805 (a) (7) (F) (iii). Comment: The laboratory SOP “Determination of the Method Detection Limit” (document #: ADMP-ENV-ENS-00128) states in Section 9.2.1.1 “If there are multiple instruments that will be assigned the same MDL, then the sample analyses must be distributed across all of the instruments.” Further, Section 9.2.1.2 states “A minimum of two spiked samples and two method blank samples prepared and analyzed on different calendar dates are required for each instrument.” However, the spreadsheet provided in the SOP only contains a space for the instrument identification in the Header, and not with each replicate. Please submit an updated MDL spreadsheet with data with your Response. Comment: The laboratory currently has two instruments for ICP-MS, two instruments for anions and two for Mercury analyses. General Comment: The term “batches” is not consistently defined or applied from parameter to parameter. Some parameters (e.g. Mercury) have only an analytical batch and not a preparation batch. Some parameters (e.g. ICP-OES) define a Preparation Batch and Analytical Batch by job number. While no instances were noted where QC was lacking due to variances in batch size, this can make review by outside parties difficult if laboratory personnel are not present to answer questions. Recommendation: It is recommended that during the next round of SOP revisions, the laboratory replace references and examples of handwritten and manually entered data, with discussion of uploading data electronically to the LIMS or server. Quality Assurance / Quality Control (QA/QC) I. Finding: The Reference Temperature-Measuring Device (TMD) calibration has expired. Requirement: A Reference Temperature-Measuring Device is an NIST traceable temperature-measuring device used only to verify the calibration of other temperature- measuring devices (i.e., limited use only). This device must be able to distinguish temperature changes of 0.1°C and equilibrate rapidly. It must be recalibrated in accordance with the manufacturer’s recalibration date (not to exceed five years). If no recalibration date is given, the Reference Temperature-Measuring Device must be recalibrated, at a minimum, every five years. A new certificate of traceability must be issued and maintained for inspection upon request. Recalibrate sooner if the device has been exposed to temperatures beyond the manufacturer’s recommended range of use. Ref: NC WW/GW LCB Temperature-Measuring Devices used for Laboratory Operations Policy. Comment: The calibration certificate for the Reference TMD (serial number ELCHM31663), performed by Trescal on January 18, 2018 expired on January 31, 2019 as stated on the certificate. NC WW/GW LCB Temperature-Measuring Devices used for Laboratory Operations Policy states: “Temperature-measuring device calibrations are performed by NIST, the manufacturer or any International Organization for Standardization (ISO) 17025 compliant vendor and results in the issuance of a new certificate of traceability to NIST standards.” It is recommended that the laboratory inquire whether a longer Page 6 #248 Duke Power Company LLC expiration date, up to five years, can be included on the vendor's calibration certificate. Please include a copy of the new calibration certificate with your Response. J. Finding: Laboratory temperature-measuring devices are not replaced if the reading is >1 °C different from the Reference Temperature-Measuring Device. Requirement: Digital temperature-measuring devices not used in an incubator must verify within 1.0 °C of a Reference Temperature-Measuring Device with a stated accuracy of at least ± 0.5 °C. These devices must be able to distinguish temperature changes of 1.0 °C and equilibrate rapidly. If the temperature-measuring device reading differs from the Reference Temperature-Measuring Device by ≤ 1.0 °C during subsequent verifications, a correction factor must be applied. If the reading differs by > 1.0 °C, the temperature- measuring device must be replaced. Ref: NC WW/GW LCB Temperature-Measuring Devices used for Laboratory Operations Policy. Comment: The laboratory submitted the verification for the TDR oven. The laboratory needs to review the Policy and ensure that the 1.0 °C requirement is being applied to all temperature-measuring devices used for laboratory operations. K. Finding: Thermometers in the TSR and TDR ovens are not being verified at the appropriate frequency. Requirement: Digital temperature-measuring devices and temperature-measuring devices used in incubators shall be verified at the temperature of use every three months against a Reference Temperature-Measuring Device and their accuracy shall be corrected. Ref: 15A NCAC 02H .0805 (a) (7) (N) (iii). Comment: The digital TMD on the ovens for TDR and TSR are being verified annually. L. Finding: The laboratory is not evaluating the recovery of the SIC. Requirement: Each laboratory shall develop documentation outlining the analytical quality control practices used for the Parameter Methods included in its Certification, including Standard Operating Procedures for each certified Parameter Method. Quality assurance, quality control, and Standard Operating Procedure documentation shall indicate the effective date of the document and be reviewed every two years and updated if changes in procedures are made. Each laboratory shall have a formal process to track and document review dates and any revisions made in all quality assurance, quality control, and Standard Operating Procedure documents. Supporting Records shall be maintained as evidence that these practices are implemented. The quality assurance, quality control, and Standard Operating Procedure documents shall be available for inspection by the State Laboratory. Ref: 15A NCAC 02H .0805 (a) (7). Comment: The data packages for ICP-OES includes a checkbox that the SIC is within ±10% but the true value of the SIC is not documented on the laboratory benchsheet. As noted in Finding D, the preparation of the SIC for ICP-OES is not being documented, so the true value of the solution is noted only in the SOP. M. Finding: The MS/MSD recoveries are not calculated correctly for some methods. Requirement: The volume of spike solution used in MS preparation must in all cases be ≤ 5% of the total MS volume. It is preferable that the spike solution constitutes ≤ 1% of the total MS volume so that the MS can be considered a whole volume sample with no adjustment Page 7 #248 Duke Power Company LLC (i.e., volume correction) by calculation necessary. If the spike solution volume constitutes >1% of the total sample volume, the sample concentration must be adjusted by calculation. Ref: NC WW/GW LCB Matrix Spiking Policy. Comment: The spike concentration is 2% of the total volume for Total Organic Carbon (TOC) and 5% of the total volume for Total Kjeldahl Nitrogen (TKN) and these volumes are not taken into account during the recovery calculation. N. Finding: Duplicate analyses are not performed for aqueous Oil & Grease samples. Requirement: Except where otherwise specified in an analytical method, laboratories shall analyze five percent of all samples in duplicate to document precision. Laboratories analyzing fewer than 20 samples per month shall analyze one duplicate during each month that samples are analyzed. Ref: 15A NCAC 02H .0805 (a) (7) (C). Comment: The duplicate may be a sample duplicate or an MSD. O. Finding: The Method Detection Limits (MDLs) for metals by ICP-OES have not been properly established for all spectral wavelengths. Requirement: Method Detection Limits (MDLs) must be established for all wavelengths utilized, using reagent water (blank) fortified at a concentration of two to three times the estimated instrument detection limit. Ref: EPA Method 200.7, Rev. 4.4 (1994), Section 9.2.4. Comment: The laboratory submitted their MDLs during the inspection. However, only a single MDL is listed for each element, and no wavelength is documented. Several elements are monitored at multiple wavelengths. Please submit an updated MDL list for each wavelength that is or potentially may be used to analyze Compliance Samples as part of your Response. Reporting P. Finding: Data for Oil & Grease is not being reported to the proper number of significant figures. Requirement: Reporting–Report results to three significant figures for HEM and SGT-HEM found at or above 10 mg/L, and report results to two significant figures for HEM and SGT- HEM found below 10 mg/L. Ref: EPA Method 1664, Rev. B, February 2010, Section 12.3. Requirement: Samples–Report results for HEM and SGT-HEM found below the ML as < 5.0 mg/L, or as required by the permitting authority or permit. Ref: EPA Method 1664, Rev. B, February 2010, Section 12.3.1. Comment: The laboratory reported data for order #J21110079 below the reporting limit as < 5 mg/L instead of < 5.0 mg/L. Mercury – EPA 245.1, Rev. 3.0, 1994 (Aqueous) Mercury – SW-846 Method 7470 A (Aqueous) Comment: It was noted during data review that a Mercury sample (ID# 2022008048) analyzed April 5, 2022 had a concentration of 0.043175 µg/L at a forty-fold dilution, giving a final concentration of 1.727 µg/L. Although the QC batch report lists the elevated reporting limit as 2 µg/L, there was no Page 8 #248 Duke Power Company LLC qualifier or notation on the data package that the elevated reporting limit was used as the reported value. No qualifier was attached to the QC batch report that summarizes sample results and QC results. The sample data was determined to be process control, so data impact was minimal. Metals – EPA 200.7, Rev. 4.4, 1994 (Aqueous) Metals – SW-846 6010 D (Aqueous & Non-Aqueous) Q. Finding: Acceptance criteria have not been established for the internal standards. Requirement: Unless specified by the method or this Rule, each laboratory shall establish performance acceptance criteria for all quality control analyses. Each laboratory shall calculate and document the precision and accuracy of all quality control analyses with each sample set. When the method of choice specifies performance acceptance criteria for precision and accuracy, and the laboratory chooses to develop laboratory-specific limits, the laboratory-specific limits shall not be less stringent than the criteria stated in the approved method. Ref: 15A NCAC 02H .0805 (a) (7) (A). Comment: The laboratory is currently using an internal standard to eliminate bias due to physical interferences for ICP-OES methods. The SOP does not include which elements are used as internal standards, nor does it provide acceptance criteria for the internal standards. Since instrument software adjusts the results of the target analytes based on the ratio of the internal standard response from both the sample and the calibration, it is necessary to set criteria that will reject data impacted by excessive interferences. R. Finding: An inconsistency was noted between the SOP and laboratory practice as follows: the laboratory is running a SIC daily, but the SOP does not address this. Requirement: Each laboratory shall develop documentation outlining the analytical quality control practices used for the Parameter Methods included in its Certification, including Standard Operating Procedures for each certified Parameter Method. Quality assurance, quality control, and Standard Operating Procedure documentation shall indicate the effective date of the document and be reviewed every two years and updated if changes in procedures are made. Each laboratory shall have a formal process to track and document review dates and any revisions made in all quality assurance, quality control, and Standard Operating Procedure documents. Supporting Records shall be maintained as evidence that these practices are implemented. Ref: 15A NCAC 02H .0805 (a) (7). Comment: The analysis of the daily SIC is not required by EPA 200.7 (Section 7.13) unless interelement corrections are applied. However, the use of the SIC is required for SW-846 Method 6010D (Sections 7.12 and 9.9), whether or not interelement corrections are being applied. Metals – EPA 200.8, Rev. 5.4, 1994 (Aqueous) Metals – SW-846 6020 B (Aqueous & Non-Aqueous) Comment: The laboratory is determining which elemental mass to monitor in each mode (Helium Mode and Hydrogen Mode) by both manufacturer recommendations and instrument performance. S. Finding: An inconsistency was noted between the SOP and laboratory practice as follows: the laboratory SOP for analysis of metals by ICP-MS includes techniques for reduction of interferences that are no longer in use. Page 9 #248 Duke Power Company LLC Requirement: Each laboratory shall develop documentation outlining the analytical quality control practices used for the Parameter Methods included in its Certification, including Standard Operating Procedures for each certified Parameter Method. Quality assurance, quality control, and Standard Operating Procedure documentation shall indicate the effective date of the document and be reviewed every two years and updated if changes in procedures are made. Each laboratory shall have a formal process to track and document review dates and any revisions made in all quality assurance, quality control, and Standard Operating Procedure documents. Supporting Records shall be maintained as evidence that these practices are implemented. Ref: 15A NCAC 02H .0805 (a) (7). Comment: The SOP (document #ADMP-ENV-EVS-00125) states that the instrument reduces interferences by use of a collision/reaction cell operated in three different modes: Helium, Hydrogen and No-Gas. No-Gas mode is no longer being used, according to the analyst. T. Finding: An inconsistency was noted between the SOP and laboratory practice as follows: the laboratory is analyzing rinses as samples to determine cleanliness of the system between standards during the calibration process. Requirement: Each laboratory shall develop documentation outlining the analytical quality control practices used for the Parameter Methods included in its Certification, including Standard Operating Procedures for each certified Parameter Method. Quality assurance, quality control, and Standard Operating Procedure documentation shall indicate the effective date of the document and be reviewed every two years and updated if changes in procedures are made. Each laboratory shall have a formal process to track and document review dates and any revisions made in all quality assurance, quality control, and Standard Operating Procedure documents. Supporting Records shall be maintained as evidence that these practices are implemented. Ref: 15A NCAC 02H .0805 (a) (7). Comment: The normal calibration routine for ICP-MS consists of running several Calibration Blanks, an RLS, 10, 50, 100, 200 and 500 ppb standards, followed by several “Rinses”, a Calibration Blank and a 1 ppb standard. Only the Calibration Blank run prior to the 1 ppb standard is used as a calibration point. The analyst noted that this sequence was performed to monitor and reduce certain element carryover (e.g., Thallium), but this is not documented in the SOP. The analytical methods do not require that calibration standards be run in a specific order. Comment: The method flexibility of EPA methods permits additional rinses. However, this must be applied to all samples and standards if the laboratory chooses to continue the practice. The laboratory must also incorporate the change in procedure into the SOP. U. Finding: The MDL does not support the current reporting level for Iron. Requirement: The MDL is defined as the minimum measured concentration of a substance that can be reported with 99% confidence that the measured concentration is distinguishable from method blank results. Ref: Code of Federal Regulations, Title 40, Part 136; Federal Register Vol. 82, No. 165, August 28, 2017; Appendix B–Definition and Procedure for the Determination of the Method Detection Limit–Revision 2. Comment: The Reporting Limit for Iron is currently < 2 µg/L. The current MDL for Iron is 2.38 µg/L. The laboratory must either elevate the reporting level above the MDL or repeat the MDL study with results determined to be less than the reporting level. Page 10 #248 Duke Power Company LLC Anions (Br-, Cl-, F-, SO42-, NO3+NO2) – EPA 300.0, Rev. 2.1, 1993 (Aqueous) Anions (Cl-, F-, SO42-, NO3+NO2) – SW-846 9056 A (Aqueous) V. Finding: The continuing calibration verification is not always mid-range. Requirement: Instrument Performance Check Solution (IPC) - For all determinations the laboratory must analyze the IPC (a mid-range check standard) and a calibration blank immediately following daily calibration, after every tenth sample (or more frequently, if required) and at the end of the sample run. Ref: EPA Method 300.0, Rev. 2.1 (1993), Section 9.3.4. Requirement: Verify the accuracy of the working calibration curve on each working day, or whenever the anion eluent composition or strength is changed, and for every batch of 10 or less samples, through the analysis of a continuing calibration verification (CCV) standard. The CCV should be made from the same material as the initial calibration standards at or near mid-range. The acceptance criteria for the CCV standard should be ± 10% of its true value for the calibration to be considered valid. Ref: EPA SW-846 Test Methods for Evaluating Solid Waste, Physical/Chemical Methods; 3rd Edition, Method 9056 A. Rev. 1, February 2007, Section 10.7. Requirement: The NC WW/GW Laboratory Certification Branch must confirm that analytical data is valid by reviewing the QA/QC data generated during the sampling and analysis procedures when implementing SW-846 methods in order to be assured that scientifically sound decisions are made which will be protective of human health and the environment. To promote consistency with the use of SW-846 methods and to assure generation of data of known quality, the minimum recommended quality control benchmarks in the methods will be considered the minimum QA/QC requirements. For example, where a method states, “Documenting the effect of the matrix on target analyte measurements should include the analysis of at least one matrix spike and one duplicate unspiked samples or one matrix spike/matrix spike duplicate pair.”, the laboratory must analyze at least one matrix spike and one duplicate unspiked sample or one matrix spike/matrix spike duplicate pair. Laboratories may adopt more stringent QC acceptance criteria for method performance but may not omit or use less stringent criteria than that stated in SW-846 methods. Ref: NC WW/GW LCB SW- 846 Method Implementation Policy. Comment: The laboratory uses two instruments for Anion analysis "System 7" and "System 8". A technician from the instrument manufacturer programmed "System 7" to analyze continuing calibration verification (CCV) standards at a concentration of 2 mg/L, which does not meet the requirement of a mid-range check standard. The current calibration range is 0.1 to 10 mg/L. The CCV standards analyzed on "System 8" are 5 mg/L. The initial calibration verification (ICV) is mid-range on both instruments as required. W. Finding: The laboratory is diluting the MS and MSD before adding the spiking solution. Requirement: The concentration of the spiked samples must be bracketed by the calibration range. If the spiked sample result is over the calibration range, the spiked sample must be diluted and re-analyzed. It is not acceptable to dilute the sample first and then add the spike solution so as not to affect bias attributed to matrix. Ref: NC WW/GW LCB Matrix Spiking Policy. Comment: The analyst has concerns about samples that are considerably above the calibration range and need significant dilutions before the spike solution is even added. Page 11 #248 Duke Power Company LLC Comment: If the concentration of a spiked sample is considerably above the calibration range, the laboratory may choose to dilute the spiked sample to determine if the concentration of the spiking solution needs to be increased. In this situation, the unspiked sample must be spiked with a higher concentration spiking solution and then diluted to bring the value within the calibration range of the instrument. Nitrogen, Ammonia – EPA 350.1, Rev. 2.0, 1993 (Aqueous) Nitrogen, Nitrate + Nitrite – EPA 353.2, Rev. 2.0, 1993 (Aqueous) Nitrogen, Total Kjeldahl – EPA 351.2, Rev. 2.0, 1993 (Aqueous) Comment: The analyst trained to perform these methods is currently on leave and the laboratory has been sending samples to a contract laboratory during this timeframe. The plan is to bring these analyses back into the laboratory after the analyst returns and performs any demonstrations of capability that are required. Recommendation: A calibration curve is analyzed every analysis day for these methods and each standard is back-calculated with the percent error from the expected concentration documented. The SOPs for the methods all state that the acceptance criterion for the minimum reporting limit standard is ±50% of the reporting limit. It is recommended that the Data Review Checklist for each method include a check for the back-calculated reporting limit standard to demonstrate that the analyst would be aware of any results that do not meet the acceptance criterion. Organic Carbon, Total – Standard Methods, 5310 C-2014 (Aqueous) X. Finding: The calibration points are not compared to the curve and recalculated. Requirement: Compare each calibration point to the curve and recalculate its concentration. If any recalculated values are not within the method's acceptance criteria—≤3 times the MRL ±50%; between 3 and 5 times the MRL ±20%; or >5 times the MRL ±10%, unless otherwise specified in individual methods—identify the source of any outlier(s) and correct before sample quantitation. Ref: Standard Methods, 5020 B-2017. (1) (b). Y. Finding: The laboratory is analyzing two replicate injections. Requirement: Sample injection: See 5310B.4c. Ref: Standard Methods, 5310 C-2014. (4) (c). Requirement: Repeat injection until at least three replicate measurements are reproducible to within ±10%. Ref: Standard Methods, 5310 B-2014. (4) (c). Z. Finding: The laboratory is not performing a TOC carryover check. Requirement: TOC carryover check—Immediately following the analysis of the highest calibration standard, analyze a blank. The concentration of the blank must be <1/2 of the MRL. If the blank has a value >1/2 of the MRL, then the highest calibration point must be lowered until the blank immediately following the point has a value <1/2 of the MRL. Analyze the high calibration point/blank pair at the beginning of every analytical day to verify that carryover is not occurring. Ref: Standard Methods, 5310 A-2014. (5) (a) (4). AA. Finding: The continuing calibration check is not being varied between low, medium and high- range concentrations. Page 12 #248 Duke Power Company LLC Requirement: Continuing calibration check—After every 10 samples, analyze one of three calibration check samples—low-range, mid-range, and high-range standard concentrations— on a rotating basis. The low-range standard should be at or below the minimum reporting level. The low-range sample should agree within 50% of the true value, and the mid- and high- range samples should agree within 15%. Ref: Standard Methods, 5310 A-2014. (5) (b) (7). Comment: The laboratory's SOP states that the concentration is to be varied. However, there is no frequency, concentration or acceptance criteria specified and the procedure has not been put into practice. Turbidity – EPA 180.1, Rev. 2.0, 1993 (Aqueous) BB. Finding: The Instrument Performance Check (IPC) standard is not at a mid-range concentration. Requirement: For all determinations, the laboratory must analyze the IPC (a mid-range check standard) and a calibration blank immediately following daily calibration, after every tenth sample (or more frequently, if required) and at the end of the sample run. Ref: EPA Method 180.1, Rev. 2.0 (1993), Section 9.3.2. Comment: Laboratory practice is to verify calibration with a standard of 15 NTU immediately after calibration, rather than a mid-range standard of 20 NTU. The laboratory is calibrating with standards up to a concentration of 2000 NTU. Recommendation: It is recommended that the laboratory tighten the range of calibration standards used if they wish to continue using a 20 NTU standard as the IPC. Alternatively, they may use an IPC with a value of 1000 NTU and continue to calibrate with standards up to a concentration of 2000 NTU. IV. PAPER TRAIL INVESTIGATION: The paper trail consisted of comparing original records (e.g., laboratory benchsheets, logbooks, etc.) and QC Batch Reports for permittees. Data were reviewed for Jobs J21110063 and J2110079. No transcription errors were observed. The facility appears to be doing a good job of accurately transcribing data. V. CONCLUSIONS: Correcting the above-cited Findings and implementing the Recommendation(s) will help this laboratory to produce quality data and meet Certification requirements. The inspector would like to thank the staff for their assistance during the inspection and data review process. Please respond to all Findings and include supporting documentation, implementation dates and steps taken to prevent recurrence for each corrective action. Report prepared by: Michael Cumbus Date: August 4, 2022 Report reviewed by: Jason Smith Date: August 5, 2022