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Home My WebLink AboutNC0000752_Fact Sheet_20240205NC0000752 Fact Sheet NPDES Permit No. NC0000752 Permit Writer/Email Contact Sergei Chernikov, sergei.chemikov@deq.nc.gov: Date: October 3, 2022 Division/Branch: NC Division of Water Resources/NPDES Industrial Permitting Fact Sheet Template: Version 09Jan2017 Permitting Action: ❑ Renewal ❑ Renewal with Expansion ❑ New Discharge ❑X Modification (Fact Sheet should be tailored to mod request) Note: A complete application should include the following: • For New Dischargers, EPA Form 2A or 2D requirements, Engineering Alternatives Analysis, Fee • For Existing Dischargers (POTW), EPA Form 2A, 3 effluent pollutant scans, 4 2nd species WET tests. • For Existing Dischargers (Non-POTW), EPA Form 2C with correct analytical requirements based on industry category. Complete applicable sections below. If not applicable, enter NA. 1. Basic Facility Information Facility Information Applicant/Facility Name: WestRock Paper, LLC /Roanoke Rapids Mill Applicant Address: North Roanoke Avenue, Roanoke Rapids, NC 27870 Facility Address: North Roanoke Avenue, Roanoke Rapids, NC 27870 Permitted Flow: 28.0 MGD Facility Type/Waste: MAJOR Industrial Facility Class: Class 4 Treatment Units: ♦ Mechanical bar screen ♦ Primary clarifier ♦ Emergency holding pond ♦ Sludge lagoon ♦ Aeration basin ♦ Three stabilization ponds Pretreatment Program (Y/N) N/A County: Halifax Region Raleigh Page 1 of 15 NC0000752 This is a Major Modification for WestRock Paper. The facility requested to incorporate a Thermal Mixing Zone into the permit in accordance with the 15A NCAC 2B .0200. The facility conducted a CORMIX modeling of the thermal plume and established the size of the mixing zone during the most critical month of the year(September). It is 700 ft. long and 200 ft. wide. This represents only 36% of the river width, which will allow safe passage for fish. DEQ biologists also determined that this plume will not have significant deleterious effect on the macroinvertebrate community. The DWR staff have conducted instream temperature sampling and confirmed that the CORMIX modeling accurately represents instream temperature impacts. Therefore, the DWR establishes a mixing zone in the permit and implements monthly temperature sampling at the following locations to assure compliance with the state temperature standard: 1) Point A - middle of the lower boundary of the mixing zone. 2) Point B — the edge of the lower boundary of the mixing zone located closer to the middle of the stream. Both sampling points are identified on Attachment 1. The addition of the mixing zone is the only significant change being implemented during this Major Modification. The rest of the permit conditions remain unchanged. Briefly describe the proposed permitting action and facility background.- West Rock Paper, LLC operates an unbleached (Cluster Rule is not applicable) paper mill in Roanoke Rapids producing high quality unbleached Kraft paper and paperboard. The mill is integrated including power generation, chemical recovery, pulp production and final paper and paperboard manufacturing. The site operates a WWTP to treat the wastewater generated during the process. The facility is permitted to discharge 28.0 MGD of process water through Outfall 001 and non -contact cooling water from the evaporator cooling tower through Outfall 002. Process wastewaters are conveyed to the WWTP through a concrete lined open channel. The WWTP consists of a bar screen, 200 ft diameter primary clarifier, 28 million gallon emergency pond, 21.5 acre aeration pond with 31 aerators, four stabilization ponds with a total of 370 acres, an effluent defoamer addition system, four solids treatment sludge neutralization tanks, two rotary screen thickeners, two screw presses and a sludge lagoon. The emergency pond is used to divert process flow in the event they have a power failure, mechanical problems or high strength waste. The water from the emergency pond is pumped back to the influent channel at a controlled rate. Condensate collected from the process areas is piped directly to the influent of the aeration basin. Sludge is landfilled on site under permit WQ0000436. 2. Receiving Waterbody Information: Receiving Waterbody Information Outfalls/Receiving Stream(s): Outfall 001/002- Roanoke River Stream Segment: 23-(26) Stream Classification: C Drainage Area (m12): 8,384 Summer 7Q10 (cfs) 1,120 Page 2 of 15 NC0000752 Winter 7Q10 (cfs): 30Q2 (cfs): 1,120 Average Flow (cfs): 2400 IWC (% effluent): 3.73 303(d) listed/parameter: No Subject to TMDL/parameter: Statewide Mercury TMDL Subbasin/HUC: Roanoke; 030208 USGS Topo Quad: B28NW/Roanoke Rapids 3. Effluent Data Summary Effluent data is summarized below for the period 2015-2020. Table. Effluent Data Summary — Outfall 001 Parameter Units Average Max Min Permit Limit Flow MGD 18.9 26.7 28.0 MA BOD lb/day 1,796 4,087 6,852 MA NH3N mg/L 2.8 TSS lb/day 2,774 7,431 15,576 MA pH SU 8.0 6.9 6.0-9.0 Temperature °C 30.6 14.0 MA -Monthly Average, WA -Weekly Average, DM -Daily Maximum 4. Instream Data Summary Instream monitoring may be required in certain situations, for example: 1) to verify model predictions when model results for instream DO are within 1 mg/l of instream standard at full permitted flow; 2) to verify model predictions for outfall diffuser; 3) to provide data for future TMDL; 4) based on other instream concerns. Instream monitoring may be conducted by the Permittee, and there are also Monitoring Coalitions established in several basins that conduct instream sampling for the Permittee (in which case instream monitoring is waived in the permit as long as coalition membership is maintained). Page 3 of 15 NC0000752 If applicable, summarize any instream data and what instream monitoring will be proposed for this permit action: The current permit requires instream monitoring for dissolved oxygen, conductivity, and temperature. Review of instream data for the past five years indicates that the dissolved oxygen standard of 5 mg/L was always maintained, and there was very little difference between upstream and downstream stations. This draft permit maintains the same instream monitoring requirements. Is this facility a member of a Monitoring Coalition with waived instream monitoring (YIN): NO Name of Monitoring Coalition: NA 5. Compliance Summary Summarize the compliance record with permit effluent limits (past 5 years): The facility reported no limit violations during the last 5 years. Summarize the compliance record with aquatic toxicity test limits and any second species test results (past 5 years): The facility passed 18 of 18 quarterly chronic toxicity tests. Summarize the results from the most recent compliance inspection: N/A 6. Water Quality -Based Effluent Limitations (WQBELs) — Outfall 001 Dilution and Mixing Zones In accordance with 15A NCAC 213.0206, the following streamflows are used for dilution considerations for development of WQBELs: 1Q10 streamflow (acute Aquatic Life); 7Q10 streamflow (chronic Aquatic Life; non -carcinogen HH); 30Q2 streamflow (aesthetics); annual average flow (carcinogen, HH). If applicable, describe any other dilution factors considered (e.g., based on CORMIX model results): NA If applicable, describe any mixing zones established in accordance with 15A NCAC 2B. 0204(b): NA Oxygen -Consuming Waste Limitations Limitations for oxygen -consuming waste (e.g., BOD) are generally based on water quality modeling to ensure protection of the instream dissolved oxygen (DO) water quality standard. Secondary TBEL limits (e.g., BOD= 30 mg/1 for Municipals) may be appropriate if deemed more stringent based on dilution and model results. Ifpermit limits are more stringent than TBELs, describe how limits were developed: N/A Ammonia and Total Residual Chlorine Limitations Limitations for ammonia are based on protection of aquatic life utilizing an ammonia chronic criterion of 1.0 mg/1(summer) and 1.8 mg/1 (winter). Acute ammonia limits are derived from chronic criteria, utilizing a multiplication factor of 3 for Municipals and a multiplication factor of 5 for Non -Municipals. Limitations for Total Residual Chlorine (TRC) are based on the NC water quality standard for protection of aquatic life (17 ug/1) and capped at 28 ug/1(acute impacts). Due to analytical issues, all TRC values reported below 50 ug/1 are considered compliant with their permit limit. Page 4 of 15 NC0000752 Describe any proposed changes to ammonia and/or TRC limits for this permit renewal: There are no proposed changes. Reasonable Potential Analysis (RPA) for Toxicants If applicable, conduct RPA analysis and complete information below. The need for toxicant limits is based upon a demonstration of reasonable potential to exceed water quality standards, a statistical evaluation that is conducted during every permit renewal utilizing the most recent effluent data for each outfall. The RPA is conducted in accordance with 40 CFR 122.44 (d) (i). The NC RPA procedure utilizes the following: 1) 95% Confidence Level/95% Probability; 2) assumption of zero background; 3) use of/2 detection limit for "less than" values; and 4) streamflows used for dilution consideration based on 15A NCAC 2B.0206. Effective April 6, 2016, NC began implementation of dissolved metals criteria in the RPA process in accordance with guidance titled NPDES Implementation of Instream Dissolved Metals Standards, dated June 10, 2016. A reasonable potential analysis was conducted on effluent toxicant data collected during the last 5 years. Pollutants of concern included toxicants with positive detections and associated water quality standards/criteria. Based on this analysis, the following permitting actions are proposed for this permit: • Effluent Limit with Monitoring. The following parameters will receive a water quality -based effluent limit (WQBEL) since they demonstrated a reasonable potential to exceed applicable water quality standards/criteria: N/A • Monitoring Only. The following parameters will receive a monitor -only requirement since they did not demonstrate reasonable potential to exceed applicable water quality standards/criteria, but the maximum predicted concentration was >50% of the allowable concentration: N/A. • No Limit or Monitoring: The following parameters will not receive a limit or monitoring, since they did not demonstrate reasonable potential to exceed applicable water quality standards/criteria and the maximum predicted concentration was <50% of the allowable concentration: As, Be, Cd, Cr, Total Phenolic Compounds, Cu, F, Pb, Hg, Mo, Ni, Se, Ag, and Zn. Attached is a spreadsheet of the RPA results as well as a copy of the Dissolved Metals Implementation Fact Sheet for freshwater/saltwater to this Fact Sheet. Toxicity Testing Limitations — Outfall 001 Permit limits and monitoring requirements for Whole Effluent Toxicity (WET) have been established in accordance with Division guidance (per WET Memo, 8/2/1999). Per WET guidance, all NPDES permits issued to Major facilities or any facility discharging "complex" wastewater (contains anything other than domestic waste) will contain appropriate WET limits and monitoring requirements, with several exceptions. The State has received prior EPA approval to use an Alternative WET Test Procedure in NPDES permits, using single concentration screening tests, with multiple dilution follow-up upon a test failure. Describe proposed toxicity test requirement: This is a Major Facility, and a chronic WET limit at 3.7% effluent will continue. Mercury Statewide TMDL Evaluation— Outfall 001 There is a statewide TMDL for mercury approved by EPA in 2012. The TMDL target was to comply with EPA's mercury fish tissue criteria (0.3 mg/kg) for human health protection. The TMDL established a wasteload allocation for point sources of 37 kg/year (81 lb/year), and is applicable to municipals and Page 5 of 15 NC0000752 industrial facilities with known mercury discharges. Given the small contribution of mercury from point sources (-2% of total load), the TMDL emphasizes mercury minimization plans (M1VIPs) for point source control. Municipal facilities > 2 MGD and discharging quantifiable levels of mercury (>1 ng/1) will receive an MMP requirement. Industrials are evaluated on a case -by -case basis, depending if mercury is a pollutant of concern. Effluent limits may also be added if annual average effluent concentrations exceed the WQBEL value (based on the NC WQS of 12 ng/1) and/or if any individual value exceeds a TBEL value of 47 ng/L. Describe proposed permit actions based on mercury evaluation: The facility provided only one mercury result of <150.0 ng/L and the allowable limit is 321.7 ng/L. Since no annual average mercury concentration exceeded the WQBEL, and no individual mercury sample exceeded the TBEL, no mercury limit is required. Other TMDL/Nutrient Management Strategy Considerations If applicable, describe any other TNDDLs/Nutrient Management Strategies and their implementation within this permit: N/A Other WQBEL Considerations If applicable, describe any other parameters of concern evaluated for WQBELs: NA If applicable, describe any special actions (HQW or ORW) this receiving stream and classification shall comply with in order to protect the designated waterbody: N/A If applicable, describe any compliance schedules proposed for this permit renewal in accordance with 15A NCAC 2H 0107(c)(2)(B), 40CFR 122.47, and EPA May 2007 Memo: N/A If applicable, describe any water quality standards variances proposed in accordance with NCGS 143- 215.3(e) and 15A NCAC 2B. 0226 for this permit renewal: NA 7. Technology -Based Effluent Limitations (TBELs) Industrials (if not applicable, delete and skip to next Section) Describe what this facility produces: producing high quality unbleached Kraft paper and paperboard. List the federal effluent limitations guideline (ELG) for this facility: §40 CFR 430.32 and §40 CFR 430.34. If the ELG is based on production or flow, document how the average production/flow value was calculated. This ELG is based on production. The annual average production (tons/day) for the past 5 years was reported as 1,458 tons/day. For ELG limits, document the calculations used to develop TBEL limits: The limits in the Table below are based on production of 1,458 tons/day and the effluent guidelines in §40 CFR 430.32 and §40 CFR 410.34. Monitoring for pentachlorophenol and trichlorophenol is not required if the facility doesn't use chlorophenolic-containing biocides. Page 6 of 15 NC0000752 Table. TBEL Development per 40 CFR 430.32/13PT and 40 CFR 430.34/13AT Daily Maximum Daily Maximum Monthly Average Monthly Average Pollutant BPTBAT Limit BPTBAT Limit (lb/1000 lb) (lb /d) (lb/1000 lb) (lb/d) BOD5 5.6 18,289 2.8 9,145 TSS 12 39,191 6 19,596 Pentachloro phenol 0.00058 1.89 Trichlorophe nol 0.00053 1.73 If any limits are based on best professional judgement (BPJ), describe development: NA Document any TBELs that are more stringent than WQBELs: NA Document any TBELs that are less stringent than previous permit: Proposed TBELs for BOD are slightly higher than in the previous permit due to the increases in production. In 1995, DWQ developed a field -calibrated, steady-state model for dissolved oxygen in approximately 74 miles of the Roanoke River, which extends from NC 48 bridge at Roanoke Rapids to the Wildlife Resources Commission boat ramp at Hamilton. At existing permitted loads during low flow conditions, the predicted minimum dissolved oxygen level is approximately 6.0 mg/L. The instream monitoring indicates that the predictions are correct and slight increase in the BOD should not result in the contravention of the instream DO standard of 5.0 mg/L. The DWR will continue to evaluate DO concentrations in this portion of the Roanoke River. Proposed TBELs for TSS, pentachlorophenol, and trichlorophenol are also increasing due to the increase in production. 8. Antidegradation Review (New/Expanding Discharge): The objective of an antidegradation review is to ensure that a new or increased pollutant loading will not degrade water quality. Permitting actions for new or expanding discharges require an antidegradation review in accordance with 15A NCAC 2B.0201. Each applicant for a new/expanding NPDES permit must document an effort to consider non -discharge alternatives per 15A NCAC 2H.0105(c)(2). In all cases, existing instream water uses and the level of water quality necessary to protect the existing use is maintained and protected. If applicable, describe the results of the antidegradation review, including the Engineering Alternatives Analysis (EAA) and any water quality modeling results: NA 9. Antibacksliding Review: Page 7 of 15 NC0000752 Sections 402(o)(2) and 303(d)(4) of the CWA and federal regulations at 40 CFR 122.44(1) prohibit backsliding of effluent limitations in NPDES permits. These provisions require effluent limitations in a reissued permit to be as stringent as those in the previous permit, with some exceptions where limitations may be relaxed (e.g., based on new information, increases in production may warrant less stringent TBEL limits, or WQBELs may be less stringent based on updated RPA or dilution). Are any effluent limitations less stringent than previous permit (YES/NO): Yes If YES, confirm that antibacksliding provisions are not violated.- The antibacksliding provisions are not violated since the new limits are based on the 40 CFR 430 Subpart C requirements for the new production value and they are not expected to negatively impact the instream DO concentrations. 10. Monitoring Requirements Monitoring frequencies for NPDES permitting are established in accordance with the following regulations and guidance: 1) State Regulation for Surface Water Monitoring, 15A NCAC 2B.0500; 2) NPDES Guidance, Monitoring Frequency for Toxic Substances (7/15/2010 Memo); 3) NPDES Guidance, Reduced Monitoring Frequencies for Facilities with Superior Compliance (10/22/2012 Memo); 4) Best Professional Judgement (BPJ). Per US EPA (Interim Guidance, 1996), monitoring requirements are not considered effluent limitations under Section 402(o) of the Clean Water Act, and therefore anti - backsliding prohibitions would not be triggered by reductions in monitoring frequencies. For instream monitoring, refer to Section 4. 11. Electronic Reporting Requirements The US EPA NPDES Electronic Reporting Rule was finalized on December 21, 2015. Effective December 21, 2016, NPDES regulated facilities are required to submit Discharge Monitoring Reports (DMRs) electronically. Effective December 21, 2020, NPDES regulated facilities will be required to submit additional NPDES reports electronically. This permit contains the requirements for electronic reporting, consistent with Federal requirements. 12.Summary of Proposed Permitting Actions: Table. Current Permit Conditions and Proposed Changes Parameter Current Permit Proposed Change Basis for Condition/Change Flow — Outfall 001 MA 28.0 MGD No change 15A NCAC 2B .0505 Outfall 002 Unlimited No change BODs-Outfall 001 DM 17,361 mg/L DM 18,289 mg/L TBEL. Based on increased MA 8,680 mg/L MA 9,145 mg/L production per 40 CFR 430 Subpart C. Page 8 of 15 NC0000752 NH3-N-Outfall Monitor only No change WQBEL. Based on protection of 001 State WQ criteria. 15A NCAC 2B.0200 TSS-Outfall 001 DM 37,202 mg/L DM 39,191 mg/L TBEL. Based on increased MA 18,601 mg/L MA 19,596 mg/L production per 40 CFR 430 Subpart C. Pentachlorophenol DM 1.8 lb/day DM 1.89 lb/day TBEL. Based on increased -Outfall 001 production per 40 CFR 430 Subpart C. Trichlorophenol- DM 1.64 lb/day DM 1.73 lb/day TBEL. Based on increased Outfall 001 production per 40 CFR 430 Subpart C. DO-Outfall 001 Monitor only - effluent No change WQBEL. State WQ standard, 15A and instream NCAC 2B.0200 and 15A NCAC 2B .0500 pH-Outfall 001 6.0 — 9.0 SU No change WQBEL. State WQ standard, 15A and Outfall 002 NCAC 2B.0200 pH-Outfall 002 Monitor only, effluent No change WQBEL. State WQ standard, 15A and instream NCAC 2B .0500 Total Nitrogen- Monitor only No change State WQ standard, 15A NCAC 2B Outfall 001 .0500 Total Phosphorus- Monitor only No change State WQ standard, 15A NCAC 2B Outfall 001 .0500 Conductivity- Monitor only - effluent No change State WQ standard, 15A NCAC 2B Outfall 001 and instream .0200 and 15A NCAC 2B .0500 Toxicity Test — Chronic limit, 3.7% No change WQBEL. No toxics in toxic Outfall 001 effluent amounts. 15A NCAC 2B.0200 and 15A NCAC 2B.0500 Temperature- Monitor only Addition of Thermal State WQ standard, 15A NCAC 2B Outfall 001 and Mixing Zone .0500 Outfall 002 Temperature- Monitor only, effluent Addition of Thermal State WQ standard, 15A NCAC 2B Outfall 001 and instream Mixing Zone .0200 and 15A NCAC 2B .0500 Total Copper- DM 227.36 µg/L Remove the limits WQBEL. State WQ standard, 15A Outfall 001 MA 211.25 µg/L NCAC 2B.0200. Based on the RPA results. Total Hardness Effluent and upstream No change Needed for implementing new state monitoring WQ standards, 15A NCAC 2B .0200. Page 9 of 15 NC0000752 Electronic Electronic Reporting No change In accordance with EPA Electronic Reporting- Outfall Special Condition Reporting Rule 2015. 001 and Outfall 002 MGD — Million gallons per day, MA - Monthly Average, WA — Weekly Average, DM — Daily Max 13. Public Notice Schedule: Permit to Public Notice: 10/18/2022 Per 15A NCAC 21-1.0109 & .0111, The Division will receive comments for a period of 30 days following the publication date of the public notice. Any request for a public hearing shall be submitted to the Director within the 30 days comment period indicating the interest of the parry filing such request and the reasons why a hearing is warranted. 14. Fact Sheet Addendum (if applicable): Were there any changes made since the Draft Permit was public noticed (Yes/No): Yes, please see Section 16. If Yes, list changes and their basis below: NA 15. Fact Sheet Attachments (if applicable): • RPA Spreadsheet Summary • Dissolved Metals Implementation/Freshwater or Saltwater • ELG calculations 16. Changes in the Final Permit. NPDES Imnlementation of Instream Dissolved Metals Standards — Freshwater Standards Page 10 of 15 NC0000752 The NC 2007-2015 Water Quality Standard (WQS) Triennial Review was approved by the NC Environmental Management Commission (EMC) on November 13, 2014. The US EPA subsequently approved the WQS revisions on April 6, 2016, with some exceptions. Therefore, metal limits in draft permits out to public notice after April 6, 2016 must be calculated to protect the new standards - as approved. Table 1. NC Dissolved Metals Water Quality Standards/Aquatic Life Protection Parameter Acute FW, µg/1 (Dissolved) Chronic FW, µg/1 (Dissolved) Acute SW, µg/1 (Dissolved) Chronic SW, µg/1 (Dissolved) Arsenic 340 150 69 36 Beryllium 65 6.5 --- --- Cadmium Calculation Calculation 40 8.8 Chromium III Calculation Calculation --- --- Chromium VI 16 11 1100 50 Copper Calculation Calculation 4.8 3.1 Lead Calculation Calculation 210 8.1 Nickel Calculation Calculation 74 8.2 Silver Calculation 0.06 1.9 0.1 Zinc Calculation Calculation 90 81 Table 1 Notes: FW= Freshwater, SW= Saltwater Calculation = Hardness dependent standard Only the aquatic life standards listed above are expressed in dissolved form. Aquatic life standards for Mercury and selenium are still expressed as Total Recoverable Metals due to bioaccumulative concerns (as are all human health standards for all metals). It is still necessary to evaluate total recoverable aquatic life and human health standards listed in 15A NCAC 213.0200 (e.g., arsenic at 10 µg/1 for human health protection; cyanide at 5 µg/L and fluoride at 1.8 mg/L for aquatic life protection). Table 2. Dissolved Freshwater Standards for Hardness -Dependent Metals The Water Effects Ratio (WER) is equal to one unless determined otherwise under 15A NCAC 02B .0211 Subparagraph (11)(d) Metal NC Dissolved Standard, µg/1 Cadmium, Acute WER*{1.136672-[ln hardness](0.041838){ e^{0.9151 [ln hardness]- 3.1485{ Cadmium, Acute Trout waters WER*{1.136672-[ln hardness](0.041838){ e^{0.9151[ln hardness] - 3.62361 Cadmium, Chronic WER*{1.101672-[ln hardness](0.041838){ e^{0.7998[ln hardness]- 4.4451 { Chromium III, Acute WER*0.316 e^{0.8190[ln hardness]+3.7256{ Chromium III, Chronic WER*0.860 e^{0.8190[ln hardness]+0.6848{ Copper, Acute WER*0.960 e^{0.9422[ln hardness]-1.700{ Page 11 of 15 NC0000752 Copper, Chronic WER*0.960 • e^{0.8545[ln hardness]-1.702{ Lead, Acute WER* {1.46203-[ln hardness](0.145712){ • e^ { 1.273 [ln hardness]-1.460{ Lead, Chronic WER*{1.46203-[lnhardness](0.145712){ • e^{1.273[lnhardness]-4.705{ Nickel, Acute WER*0.998 e^{0.8460[ln hardness]+2.255{ Nickel, Chronic WER*0.997 e^{0.8460[ln hardness]+0.0584{ Silver, Acute WER*0.85 • e^{1.72[ln hardness]-6.59{ Silver, Chronic Not applicable Zinc, Acute WER*0.978 e^{0.8473[ln hardness]+0.884{ Zinc, Chronic WER*0.986 e^{0.8473[ln hardness]+0.884{ General Information on the Reasonable Potential Analysis (RPA) The RPA process itself did not change as the result of the new metals standards. However, application of the dissolved and hardness -dependent standards requires additional consideration in order to establish the numeric standard for each metal of concern of each individual discharge. The hardness -based standards require some knowledge of the effluent and instream (upstream) hardness and so must be calculated case -by -case for each discharge. Metals limits must be expressed as `total recoverable' metals in accordance with 40 CFR 122.45(c). The discharge -specific standards must be converted to the equivalent total values for use in the RPA calculations. We will generally rely on default translator values developed for each metal (more on that below), but it is also possible to consider case -specific translators developed in accordance with established methodology. RPA Permitting Guidance/WQBELs for Hardness -Dependent Metals - Freshwater The RPA is designed to predict the maximum likely effluent concentrations for each metal of concern, based on recent effluent data, and calculate the allowable effluent concentrations, based on applicable standards and the critical low -flow values for the receiving stream. If the maximum predicted value is greater than the maximum allowed value (chronic or acute), the discharge has reasonable potential to exceed the standard, which warrants a permit limit in most cases. If monitoring for a particular pollutant indicates that the pollutant is not present (i.e. consistently below detection level), then the Division may remove the monitoring requirement in the reissued permit. To perform a RPA on the Freshwater hardness -dependent metals the Permit Writer compiles the following information: • Critical low flow of the receiving stream, 7Q10 (the spreadsheet automatically calculates the I Q 10 using the formula 1 Q 10 = 0.843 (s7Q 10, cfs) 0.993 • Effluent hardness and upstream hardness, site -specific data is preferred • Permitted flow • Receiving stream classification In order to establish the numeric standard for each hardness -dependent metal of concern and for each individual discharge, the Permit Writer must first determine what effluent and instream (upstream) hardness values to use in the equations. Page 12 of 15 NC0000752 The permit writer reviews DMR's, Effluent Pollutant Scans, and Toxicity Test results for any hardness data and contacts the Permittee to see if any additional data is available for instream hardness values, upstream of the discharge. If no hardness data is available, the permit writer may choose to do an initial evaluation using a default hardness of 25 mg/L (CaCO3 or (Ca + Mg)). Minimum and maximum limits on the hardness value used for water quality calculations are 25 mg/L and 400 mg/L, respectively. If the use of a default hardness value results in a hardness -dependent metal showing reasonable potential, the permit writer contacts the Permittee and requests 5 site -specific effluent and upstream hardness samples over a period of one week. The RPA is rerun using the new data. The overall hardness value used in the water quality calculations is calculated as follows: Combined Hardness (chronic) _ (Permitted Flow, cfs *Avg. Effluent Hardness, mg/L)+s7Q10, cfs *Avg. Upstream Hardness, mg/L) (Permitted Flow, cfs + s7Q10, cfs) The Combined Hardness for acute is the same but the calculation uses the 1Q10 flow. 3. The permit writer converts the numeric standard for each metal of concern to a total recoverable metal, using the EPA Default Partition Coefficients (DPCs) or site -specific translators, if any have been developed using federally approved methodology. EPA default partition coefficients or the 'Traction Dissolved" converts the value for dissolved metal at laboratory conditions to total recoverable metal at in -stream ambient conditions. This factor is calculated using the linear partition coefficients found in The Metals Translator: Guidance for Calculating a Total Recoverable Permit Limit from a Dissolved Criterion (EPA 823-B-96-007, June 1996) and the equation: Cdiss - I Ctotal I + { [Kpo] [ss(l+a)] [ 10 6] 1 Where: ss = in -stream suspended solids concentration [mg/1], minimum of 10 mg/L used, and 4. The numeric standard for each metal of concern is divided by the default partition coefficient (or site -specific translator) to obtain a Total Recoverable Metal at ambient conditions. In some cases, where an EPA default partition coefficient translator does not exist (le. silver), the dissolved numeric standard for each metal of concern is divided by the EPA conversion factor to obtain a Total Recoverable Metal at ambient conditions. This method presumes that the metal is dissolved to the same extent as it was during EPA's criteria development for metals. For more information on conversion factors see the June, 1996 EPA Translator Guidance Document. Page 13 of 15 NC0000752 5. The RPA spreadsheet uses a mass balance equation to determine the total allowable concentration (permit limits) for each pollutant using the following equation: Ca = (s7Q10 + Qw) Cwgs) — (s7Q10) (Cb) Qw Where: Ca = allowable effluent concentration (µg/L or mg/L) Cwqs = NC Water Quality Standard or federal criteria (µg/L or mg/L) Cb = background concentration: assume zero for all toxicants except NH3* (µg/L or mg/L) Qw = permitted effluent flow (cfs, match s7Q10) s7Q10 = summer low flow used to protect aquatic life from chronic toxicity and human health through the consumption of water, fish, and shellfish from noncarcinogens (cfs) * Discussions are on -going with EPA on how best to address background concentrations Flows other than s7Q10 may be incorporated as applicable: 1Q10 = used in the equation to protect aquatic life from acute toxicity QA = used in the equation to protect human health through the consumption of water, fish, and shellfish from carcinogens 30Q2 = used in the equation to protect aesthetic quality The permit writer enters the most recent 2-3 years of effluent data for each pollutant of concern. Data entered must have been taken within four and one-half years prior to the date of the permit application (40 CFR 122.21). The RPA spreadsheet estimates the 95th percentile upper concentration of each pollutant. The Predicted Max concentrations are compared to the Total allowable concentrations to determine if a permit limit is necessary. If the predicted max exceeds the acute or chronic Total allowable concentrations, the discharge is considered to show reasonable potential to violate the water quality standard, and a permit limit (Total allowable concentration) is included in the permit in accordance with the U.S. EPA Technical Support Document for Water Quality -Based Toxics Control published in 1991. 7. When appropriate, permit writers develop facility specific compliance schedules in accordance with the EPA Headquarters Memo dated May 10, 2007 from James Hanlon to Alexis Strauss on 40 CFR 122.47 Compliance Schedule Requirements. The Total Chromium NC WQS was removed and replaced with trivalent chromium and hexavalent chromium Water Quality Standards. As a cost savings measure, total chromium data results may be used as a conservative surrogate in cases where there are no analytical results based on chromium III or VI. In these cases, the projected maximum concentration (95th %) for total chromium will be compared against water quality standards for chromium III and chromium VI. Page 14 of 15 NC0000752 9. Effluent hardness sampling and instream hardness sampling, upstream of the discharge, are inserted into all permits with facilities monitoring for hardness -dependent metals to ensure the accuracy of the permit limits and to build a more robust hardness dataset. Page 15 of 15