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Home My WebLink AboutNC0004987_GW Monitoring Program Sampling, Analysis, and Reporting Plan_20141015 FYZ October 10, 2014 Ms. Kim Hutchinson, P.E. Via Email: kim.hutchinson@duke-energy.com Duke Energy Carolinas, LLC Mail Code EC13Z P.O. Box 1006 Charlotte, NC 28201-1006 Subject: Generalized Groundwater Flow Directions Figure Duke Energy Carolinas, LLC Marshall Steam Station Ash Basin Dear Ms. Hutchinson: HDR is pleased to provide the attached figure presenting generalized groundwater flow directions for the shallow water table aquifer adjacent to the ash basin at the Duke Energy Carolinas, LLC (Duke Energy) Marshall Steam Station (MSS). This letter provides the background on the development of this information. 1.0 Background Duke Energy owns and operates MSS, a coal-fired electric generating station, located in Catawba County, North Carolina. MSS uses an ash basin for disposal of ash generated by the coal combustion process and other water treatment at the coal-fired plant. In 2011, Duke Energy provided Altamont Environmental, Inc. (Altamont)information on the groundwater monitoring wells installed at the ash basin and information on the water levels in the ash basin. Altamont utilized this information along with consideration of adjacent bodies of water and site topography to develop generalized groundwater direction flow arrows for the areas adjacent to the ash basins. This information was presented in the report titled Generalized Groundwater Flow Direction Maps for Ash Basins, Duke Energy Carolinas, LLC, Fossil Stations, December 12, 2011 (2011 Altamont report). The report contained figures with similar generalized groundwater flow arrows for all seven of the Duke Energy Carolinas fossil station ash basins. The report was prepared by Altamont staff and was sealed by William M. Miller, PE. The information from that report is used with the permission of Duke Energy. As stated in Section 3.0 of the 2011 Altamont report: The purpose of the Generalized Ash Basin Groundwater Flow Direction Maps, Figures 1 through 7, is to provide Duke with an interpretation of the generalized hdrinc.com 440 S.Church Street,Suite 900.Charlotte.NC 28202 T 704-338-6700 Ms.Kim Hutchinson,P.E. October 10,2014 Page 2 groundwater flow directions in the areas surrounding the ash basins. The maps were developed utilizing existing data that were readily available and with data collected as part of on-going monitoring at the ash basins. No additional field investigation was conducted as part of the development of the maps. The maps are not intended to provide absolute groundwater flow direction data at a specific location. Rather, they are an interpretation of the generalized groundwater flow direction for the shallow water table based on readily available data. As described in the following sections(Section 4.0, Section 5.0, and Section 6.0), there may be hydrogeologic conditions present at the ash basins that cause groundwater flow conditions to differ from the generalized groundwater flow directions shown on Figures 1 through 7. The generalized groundwater flow directions were determined based on a consideration of the information described above, most notably that the sites are located in the Piedmont physiographic province(Piedmont). In addition,the generalizations of typical Piedmont hydrogeology found in A Master Conceptual Model for Hydrogeological Site Characterization in the Piedmont and Mountain Region of North Carolina(LeGrand 2004)apply to these sites. As stated in Section 5.0 of the 2011 Altamont report,the possible effects of pumping from adjacent water supply wells were not considered in the development of the generalized groundwater flow direction arrows. The groundwater elevations used in development of the generalized groundwater direction flow arrows were from the compliance groundwater monitoring wells(compliance wells)-wells monitored in association with the National Pollution Discharge Elimination System(NPDES)permits -and from groundwater monitoring wells voluntarily(voluntary wells)installed by Duke Energy. Consistent groundwater elevation readings were not measured in the voluntary wells after February 2010. The compliance wells were installed in July and August 2010. Section 7.0 of the 2011 Altamont report discusses the development of the generalized groundwater flow direction arrows and the relative level of confidence in the interpretation of the generalized flow direction. The text below was copied from that report: Groundwater flow direction arrows are used to depict the interpreted direction of generalized groundwater flow. Three different colors of arrows were used to indicate the relative level of confidence in the interpretation of the generalized groundwater flow direction. The relative level of confidence in the interpretation of flow direction was determined by. Ms.Kim Hutchinson.P.E. October 10,2014 Page 3 • The distance from groundwater monitoring wells or surface water elevation data • The number of groundwater data elevation points utilized • Consideration of the surface topography Descriptions of the relative confidence levels indicated by groundwater flow direction arrow colors are as follows: • Black arrows represent high confidence in the groundwater flow direction interpretation. The black arrows were used in areas in which there were several known groundwater or surface water elevation data points and the surface topography supported the interpretation of groundwater flow characteristic of typical Piedmont groundwater flow. • Gray arrows represent moderate confidence in the groundwater flow direction interpretation. The gray arrows were used in areas where at least one groundwater or surface water elevation point was known or in areas where there was strong surface topographic data to support the groundwater flow direction interpretation. • White arrows represent estimated groundwater flow direction interpretation. The white arrows were used in areas where there was little or no groundwater or surface water elevation data and there was not conclusive surface topographic data to support a gray arrow. 2.0 Scope of HDR Review and Results Since limited groundwater elevation data readings were performed on the voluntary wells after the installation of the compliance wells during July and August 2010, HDR reviewed the historic groundwater level data available from the compliance groundwater monitoring wells in conjunction with the current approximate ash basin pond elevation data. HDR found the generalized groundwater flow direction arrows presented in the 2011 Altamont report to generally represent the probable direction of groundwater flow for the shallow water table aquifer. As stated in the 2011 Altamont report,the generalized groundwater flow direction arrows present an interpretation of flow direction based on data from the shallow water table aquifer and do not consider the possible effects of pumping from adjacent water supply wells. Ms.Kim Hutchinson.P.E October 10,2014 Page 4 The ash basin pond elevation at MSS is essentially unchanged from the ash basin pond elevation utilized in the 2011 Altamont report. Based on the topography of the site,the ash basin pond elevation, and the water levels measured in the compliance wells, it is unlikely that there would be a significant change in the direction of the groundwater flow as represented by the generalized groundwater flow direction arrows developed by Altamont. The generalized groundwater flow directions for the area adjacent to the MSS ash basin are found on the attached Marshall Steam Station Ash Basin Figure MSS-1. HDR appreciates the opportunity to provide continued support to Duke Energy. Should you have any questions regarding this submittal or need further information, please do not hesitate to contact me. Respectfully submitted, HDR Engineering, Inc.of the Carolinas oQ`�N C °k�y,, , SEAL - 2243 g Scott A. Spinner, P.G. �5�•��'�: Environmental Geologist f7j�DLO�,��,`��• A. Sp cc: Ty Ziegler, HDR William M. Miller, HDR Attachments: Marshall Steam Station Ash Basin Figure MSS-1 GROUNDWATER FLOW DIRECTION ARROW LEGEND: GENERALIZED GROUNDWATER FLOW DIRECTION (HIGH CONFIDENCE) ' • Supported by several groundwater elevation data points and strong topographic data GENERALIZED GROUNDWATER FLOW DIRECTION (MODERATE CONFIDENCE) n. • Supported by at least one groundwater elevation data point and/or strong c: ` topographic data GENERALIZED GROUNDWATER FLOW DIRECTION (ESTIMATED) ',; __J\ Groundwater flow direction estimated due to lack of groundwater data and/or strong topographic data NOTES FOR GENERALIZED GROUNDWATER FLOW DIRECTION ARROWS: 1. GENERALIZED GROUNDWATER FLOW DIRECTION ARROWS PRESENT PROBABLE GENERALIZED GROUNDWATER FLOW DIRECTION FOR THE SHALLOW WATER TABLE AQUIFER BASED ON MONITORING WELL WATER LEVELS,TOPOGRAPHIC AND HYDROLOGIC FEATURES SHOWN ON THIS FIGURE. THESE GENERALIZED GROUNDWATER FLOW DIRECTION ARROWS WERE DEVELOPED IN THE REPORT y, TITLED"GENERALIZED GROUNDWATER FLOW DIRECTION MAPS FOR ASH BASINS,DUKE ENERGY CAROLINAS,LLC,FOSSIL STATIONS, DECEMBER 12,2011",WILLIAM M.MILLER,P.E.ALTAMONT ENVIRONMENTAL,ASHEVILLE,NC,PROJECT NUMBER 2370.07. 2. AS NOTED IN THIS REPORT,THESE GENERALIZED GROUNDWATER FLOW DIRECTION ARROWS DO NOT CONSIDER THE EFFECTS OF PUMPING FROM POTENTIAL WATER SUPPLY WELLS. INFORMATION FROM THIS REPORT USED WITH PERMISSION OF DUKE ENERGY CAROLINAS,LLC- 3. SEE HDR LETTER REPORT SCOTT A.SPINNER(HDR)TO KIM HUTCHINSON(DUKE ENERGY),DATED SEPTEMBER 12,2014. LEGEND: DUKE ENERGY PROPERTY BOUNDARY ' ASH BASIN COMPLIANCE BOUNDARY - ASH BASIN COMPLIANCE BOUNDARY COINCIDENT }y. WITH DUKE ENERGY PROPERTY BOUNDARY * r r. ASH BASIN WASTE BOUNDARY r STRUCTURAL FILL,ASH LANDFILL-LIMIT OF WASTE LANDFILL COMPLIANCE BOUNDARY ASBESTOS-C&D LANDFILL BOUNDARY g 'e TOPOGRAPHIC CONTOUR(4 FOOT) ASH BASIN COMPLIANCE GROUNDWATER 4 MONITORING WELL ASH BASIN VOLUNTARY GROUNDWATER '.� MONITORING WELL LANDFILL GROUNDWATER MONITORING WELL LANDFILL SURFACE WATER SAMPLE LOCATION _ �r STREAM GENERAL NOTES: 1.PARCEL DATA FOR THE SITE WAS OBTAINED FROM DUKE ENERGY REAL ESTATE AND IS APPROXIMATE. 2.ASH BASIN WASTE BOUNDARY,ASH LANDFILL LIMIT OF WASTE,AND STRUCTURAL FILL BOUNDARY ARE APPROXIMATE. DATE 3.AS-BUILT MONITORING WELL LOCATIONS PROVIDED BY DUKE ENERGY. GENERALIZED GROUNDWATER FLC_'W5`ffW_0LR/DWR 4.SHALLOW MONITORING WELLSIS)-WELLSCREENINSTALLEDACROSSTHESURFICIALWATERTABLE. DUKE ENERGY CAROLINAS, LLC OCT. 10, 2014 5.DEEP MONITORING WELLS(D)-WELL SCREEN INSTALLED IN THE TRANSITION ZONE BETWEEN COMPETENT BEDROCK AND THE REGOLITH. 6.TOPOGRAPHY DATA FOR THE SITE WAS OBTAINED FROM NC DOT GEOGRAPHIC INFORMATION SYSTEM(GIS)WEB SITE. MARSHALL STEAM STATION 0 C T 1 5 2014 7.ORTHOPHOTOGRAPHY WAS OBTAINED FROM NC ONEMAP GIS WEB SITE(DATED 2010). FIGURE NPDES PERMIT#NC0004987 8.THE ASH BASIN COMPLIANCE BOUNDARY IS ESTABLISHED ACCORDING TO THE DEFINITION FOUND IN 15A NCAC 02L0107(a)- 1000' 0 5130' 1000 ..,� ...�a....,,m.,.,.o CATAWBA COUNTY, NORTH CAROLINA Water uuaiity MSS-1 SCALE Permitting Section Marshall Steam Station Ash Basin Groundwater Monitoring Program Sampling, Analysis, and Reporting Plan NPDES Permrt NC0004987 October 10, 2014 •a ,i r� Duke Energy Carolnas,LLC I Groundwater Monitoring Program Sampling. Analysis. and Reporting Plan Marshall Steam Station Ash Basin I-P ' Report Verificatior. Report Verification PROJECT: GROUNDWATER MONITORING PROGRAM ' MARSHALL STEAM STATION ASH BASIN NPDES PERMIT NC0004987 ' TITLE: GROUNDWATER MONITORING SAMPLING,ANALYSIS,AND REPORTING PLAN This document has been reviewed for accuracy and quality commensurate with the intended application. Prepared by: Date: !oh%4-0i14 ' Checked by: Date: 8 `opo y ' Approved by: ()hDate: 10IO 20 14- Project Manager. Brooke Ahrens, PE Professional Geologist Seal: C SM 22a3 o�0aw� A. s� ' HDR Engineering, Inc. o "Carolinas 440 South Church St., Suite 1000 Charlotte, NC 28202 North Carolina Geology License Number C-503 1 ' Duke Energy Carolnas,LLC I Groundwater Monitoring Program Sampling,Analysis,and Reporting Plan Marshall Steam Station Ash Basin FN Table of Contents Table of Contents Page ReportVerification .......................................................................................................................i Tableof Contents........................................................................................................................ii 1 List of Figures............................................................................................................................iv Listof Tables..............................................................................................................................v Section1 - Introduction...............................................................................................................1 ' Section 2-Site Description.........................................................................................................2 2.1 Plant Description..................................................................................................2 ' 2.2 Ash Basin Description..........................................................................................2 Section 3-Site Geology and Hydrogeology................................................................................3 ' 3.1 Geologic/Soil Framework.....................................................................................3 3.2 Hydrogeologic Framework...................................................................................3 Section 4-Monitoring Program...................................................................................................5 4.1 Regulatory Requirements for Groundwater Monitoring ........................................5 4.2 Description of Groundwater Monitoring System...................................................5 4.3 Monitoring Frequency..........................................................................................6 4.4 Sample Parameters and Methods........................................................................6 4.5 Data Quality Objectives........................................................................................7 Section 5-Sampling Procedures................................................................................................8 5.1 Sampling Equipment............................................................................................8 5.1.1 Equipment Cleaning Procedures............................................................8 5.2 Groundwater Sampling........................................................................................8 5.2.1 Development of Monitoring Wells...........................................................8 5.2.2 Groundwater Level and Total Depth Measurements..............................8 ' 5.2.3 Well Purging and Sampling..................................................................19 5.3 Sample Collection.............................................................................................. ' 5.4 Sample Containers, Volume, Preservation, and Holding Time...........................11 5.5 Sample Tracking................................................................................................11 5.6 Sample Labeling................................................................................................11 1 5.7 Field Documentation..........................................................................................11 5.8 Chain-of-Custody Record...................................................................................13 ' 5.9 Sample Custody, Shipment, and Laboratory Receipt.............................................13 Section 6-Analytical Methods..................................................................................................15 II 1 1 Duke Energy Carolnas,LLC I Groundwater Monitoring Program Sampling,Analysis,and Reporting Plan Marshall Steam Station Ash Basin F'� Table of Contents Section 7- Internal Quality Control Checks...............................................................................16 Section 8-Validation of Field Data Package ............................................................................17 Section 9-Validation of Laboratory Data..................................................................................18 1 Section 10- Report Submittal ...................................................................................................19 Section11 - References............................................................................................................20 APPENDICES 1 A- Boring Logs and Monitoring Well Construction Records B - Permit Condition A(11)Attachment XX, Version 1.1, dated June 15, 2011 C- Monitoring Well Locations 1 1 1 1 I 1 III 1 1 1 Duke Energy Carolnas,LLC I Groundwater Monitoring Program Sampling,Analysis,and Reporting Plan Marshall Steam Station Ash Basin FN List of Figures ' List of Figures 1 Figure 1 -Site Location Map Figure 2-Site Layout Figure 3-Typical Monitoring Well Construction Details Figure 4- Example Groundwater Monitoring Data Sheet Figure 5- Example Field Sampling Calibration Form Figure 6-Chain-of-Custody Record and Analysis Request Form Figure 7- North Carolina Groundwater Sampling Site Checklist 1 1 i 1 1 iv 1 1 ' Duke Energy Caroinas,LLC I Groundwater Monitoring Program Sampling.Analysis, and Reporting Plan Marshall Steam Station Ash Basin FN List of Tables List of Tables Table 1 - Monitoring Well Information Table 2-Sample Parameters and Analytical Methods 1 Table 3-Sample Containers, Preservatives, and Holding Times 1 1 I i ' 1 1 1 1 1 1 1 1 1 1 1 1 Duke Energy Carolinas,LLC I Groundwater Monitoring Program Sampling.Analysis,and Reporting Plan Marshall Steam Station Ash Basin FN Section 1 -Introduction Section 1 - Introduction This Groundwater Monitoring Program Sampling, Analysis, and Reporting Plan (Plan) is ' developed to support the Duke Energy Carolinas, LLC(Duke Energy) requirement for groundwater monitoring around the Marshall Steam Station (MSS)ash basin operated under National Pollutant Discharge Elimination System (NPDES) Permit NC0004987. 1 This Plan describes the groundwater monitoring network, methodologies of field sampling, record-keeping protocols, laboratory analytical methods, data quality objectives, data validation, and reporting that will be used for the MSS ash basin groundwater monitoring program. 1 1 Duke Energy Carolinas,LLC I Groundwater Monitoring Program Sampling.Analysis, and Reporting Plan Marshall Steam Station Ash Basin�'� Section 2-Site Description Section 2 - Site Description 2.1 Plant Description MSS is a coal-fired electricity-generating facility with a capacity of 2,090 megawatts located on the west side of Lake Norman in Catawba County, North Carolina, as shown on Figure 1. MSS 1 is a four-unit station which began commercial operation in 1965. Lake Norman is part of Duke Energy's Catawba-Wateree Hydroelectric Project(Federal Energy Regulatory Commission Project No. 2232), has a surface area of approximately 32,475 acres, and provides cooling water for the station. 1 2.2 Ash Basin Description The coal ash residue from the coal combustion process has historically been disposed of in the MSS ash basin. The ash basin currently receives waste streams from the MSS wastewater and 1 yard drain sump, coal pile runoff,treated flue gas desulfurization (FGD)wastewater, ash removal system, and stormwater. The discharge from the ash basin is permitted by the North Carolina Department of Environment and Natural Resources(NCDENR) Department of Water ' Resources(DWR) under NPDES Permit NC0004987. The ash basin system consists of a single cell impounded by an earthen dike located on the southeast end of the ash basin. The ash basin system was constructed in 1965 and is located approximately 2,000 feet northeast of the power plant. The waste boundary for the ash basin encompasses approximately 382 acres. The full pond elevation for the MSS ash basin is approximately 790 feet. The normal pond elevation of Lake Norman is approximately 760 feet. Figure 2 is shown with an ash basin 1 elevation at 790 feet. Due to the nature of MSS operations, inflows to the ash basin are highly variable. The inflows from the station to the ash basin are discharged to the northwest portion of the ash basin. The ash basin pond elevation is controlled by the use of concrete stop logs. The discharge from the ash basin is through a concrete discharge tower located in the eastern portion of the ash basin. ' The concrete discharge tower drains through a 30-inch-diameter slip-lined corrugated metal pipe which discharges into Lake Norman. 1 1 ' 2 Duke Energy Carolinas,LLC I Groundwater Monitoring Program Sampling,Analysis,and Reporting Plan Marshall Steam Station Ash Basin FN Section 3-Site Geology and Hydrogeology Section 3 - Site Geology and Hydrogeology 3.1 Geologic/Soil Framework MSS and its associated ash basin system are located in the Kings Mountain Belt of the Piedmont physiographic province of North Carolina (Piedmont). The rocks of the Kings Mountain Belt were formed during the late Proterozoic to Early Paleozoic era. The Kings Mountain Belt bedrock consists of metasedimentary and metavolcanic rocks including schist, phyllite, marble, metavolcanic rock, quartzite, and gneiss(North Carolina Geologic Survey 1996). The soils that overlie the bedrock in the area have generally formed from the in-place I weathering of the parent bedrock. The fractured bedrock is overlain by a mantle of unconsolidated material known as regolith. The regolith, where present, includes the soil zone; a zone of weathered, decomposed bedrock known as saprolite; and alluvium. Saprolite, the product of chemical and mechanical weathering of the underlying bedrock, is typically composed of clay and coarser granular material up to boulder size and may reflect the texture of the rock from which it was formed (LeGrand 2004). ' Based on a review of the monitoring well installation logs provided by Duke Energy, the soils comprising the saprolite layer on site were characterized as ranging from micaceous clay to ' gneissic and granitic partially weathered rock. Bedrock encountered on site consists of biotite gneiss, quartz schist, and granite. 3.2 Hydrogeologic Framework The groundwater system in the Piedmont Province in most cases is comprised of two interconnected layers or mediums: 1) residuum/saprolite and weathered rock(regolith) overlying, and 2)fractured crystalline bedrock(Heath 1980; Hamed and Daniel 1992). Within the regolith layer, a thoroughly weathered and structureless material termed residuum occurs near the ground surface with the degree of weathering decreasing with depth. The residuum grades into a coarser-grained material that retains the structure of the parent bedrock and is termed saprolite. Beneath the saprolite, partially weathered bedrock occurs with depth until sound bedrock is encountered. This mantle of residual soil, saprolite, and weathered rock is a ' hydrogeologic unit that covers and crosses various types of rock(LeGrand 1988). It provides an intergranular medium through which the recharge and discharge of water from the underlying fractured rock occurs. The bedrock layer consists of fractured, nonporous crystalline bedrock. The fractures control both the hydraulic conductivity and storage capacity of the rock mass. A transition zone at the base of the regolith has been interpreted to be present in many areas of the Piedmont. The zone consists of partially weathered/fractured bedrock and lesser amounts of saprolite that grades into bedrock and has been described as"being the most permeable part of the system, even slightly more permeable than the soil zone" (Hamed and Daniel 1992). The ' zone thins and thickens within short distances and its boundaries may be difficult to distinguish. 3 ' Duke Energy Carolinas,LLC I Goundwater Monitoring Program Sampling,Analysis, and Reporting Plan Marshall Steam Station Ash Basin 01 Section 3-Site Geology and Hydrogeology It has been suggested that the zone may serve as a conduit of rapid flow and transmission of contaminated water(Hamed and Daniel 1992). Piedmont topography is characterized by gently rounded sloped hills and valleys. Recharge typically occurs on upland areas and slopes while groundwater discharge is concentrated in surface water bodies and lowland areas. LeGrand's (1988, 2004)conceptual model of the groundwater setting in the Piedmont incorporates the above two medium systems into an entity that is useful for the description of groundwater conditions. That entity is the surface drainage basin that contains a perennial stream or river(LeGrand 1988). Each basin is similar to adjacent basins and the conditions are generally repetitive from basin to basin. Within a basin, movement of groundwater is generally restricted to the area extending from the drainage divides to a perennial stream or river(Slope-Aquifer System; LeGrand 1988, 2004). Rarely does groundwater move beneath a perennial stream or river to another more distant stream (LeGrand 2004). Therefore, in most cases in the Piedmont, the groundwater system is a two-medium system (LeGrand 1988) restricted to the local drainage basin. The groundwater occurs in a system composed of two interconnected layers: residuum/saprolite and weathered rock overlying fractured crystalline rock separated by the transition zone. Typically, the residuum/saprolite is ' partly saturated and the water table fluctuates within it. Water movement is generally through the fractured bedrock. The near-surface fractured crystalline rocks can form extensive aquifers. The character of such aquifers results from the combined effects of the rock type, fracture system, topography, and weathering. Topography exerts an influence on both weathering and the opening of fractures while the weathering of the crystalline rock modifies both transmissive and storage characteristics. The aquifer system in the Piedmont typically exists in an unconfined or semi-confined condition in the bedrock zone. Under natural conditions, the general direction of groundwater flow can be approximated from the surface topography. Groundwater moves both vertically down through the regolith and parallel to the bedrock surface to areas where groundwater discharges as seepage into streams, lakes, or other surface water bodies. ' A surface water divide is located to the west of the MSS ash basin approximately along Sherrills Ford Road to the west of the ash basin (Figure 2). A surface water divide is also located ' approximately along Island Ford Road to the north of the ash basin. Lake Norman is located to the southeast of the ash basin. The geology/groundwater conditions at the site are expected to be generally consistent with the characteristics of the conceptual groundwater model developed ' by LeGrand for the Piedmont region. 1 ' 4 Duke Energy Carolinas,LLC I Groundwater Monitoring Program Sampling.Analysis,and Reporting Plan Marshall Steam Station Ash Basin FN Section 4-Monitoring Program Section 4 - Monitoring Program 4.1 Regulatory Requirements for Groundwater Monitoring The NPDES program regulates wastewater discharges to surface waters to ensure that surface water quality standards are maintained. MSS operates under NPDES Permit NC0004987 which authorizes discharge of cooling water and intake screen backwash (Outfall 001), treated wastewater(consisting of metal cleaning wastes, coal pile runoff, ash transport water, domestic I wastewater, low volume wastes, and FGD wet scrubber wastewater)(Outfall 002), yard sump overflows (Outfalls 002A and 002B), and non-contact cooling water from the induced draft fan control house(Outfall 003)to the Catawba River(Lake Norman) in accordance with effluent limitations, monitoring requirements, and other conditions set forth in the permit. The NPDES permitting program requires that permits be renewed every 5 years. The MSS NPDES permit requires groundwater monitoring. Permit Condition A(11)Attachment I XX, Version 1.1, dated June 15, 2011, lists the groundwater monitoring wells to be sampled,the parameters and constituents to be measured and analyzed, and the requirements for sampling frequency and results reporting. Attachment XX also provides requirements for well location ' and well construction. A copy of Attachment XX is included as Appendix B. The compliance boundary for groundwater quality at the MSS ash basin site is defined in ' accordance with 15A NCAC 02L .0107(a) as being established at either 500 feet from the waste boundary or at the property boundary, whichever is closer to the source. 1 Sampling at the compliance groundwater wells commenced in February 2011. Analytical results have been submitted to the NCDENR Department of Water Resources(DWR) before the last day of the month following the date of sampling for all monitoring wells. In the future, analytical ' results will be submitted to the DWR within 60 days of the date of sampling for all monitoring wells. 4.2 Description of Groundwater Monitoring System The groundwater monitoring for the MSS ash basin consists of the following monitoring wells: MW-4, MW-4D, MW-10S, MW-10D, MW-11 S, MW-11 D, MW-12S, MW-12D, MW-13S, ' MW-13D, MW-14S, and MW-14D. With the exception of monitoring wells MW4 and MW-4D, the compliance monitoring wells were installed in July and August 2010. Monitoring well MW-4 was installed by Duke Energy in 1989 as part of the Marshall Dry Ash Landfill (Permit No. 1804) ' groundwater monitoring network. Monitoring well MW-4D was installed by Duke Energy in 2006 prior to the installation of the ash basin compliance monitoring wells as part of a voluntary monitoring system. Based on the locations of monitoring wells MW-4 and MW-4D relative to the ash basin, they were incorporated into the ash basin compliance monitoring network. Well construction data is provided in Table 1. A copy of the boring logs and monitoring well construction records are provided in Appendix A. 5 1 ' Duke Energy Carolinas,LLC I Goundwater Monitoring Program Sampling.Analysis,and Reporting Plan ♦1 Marshall Steam Station Ash Basin J< Section 4-Monitoring Program The locations for the compliance boundary monitoring wells were selected in consultation with 1 the DWR Aquifer Protection Section. The locations of the monitoring wells, the waste boundary, and the compliance boundary are shown on Figure 2. A summary of the monitoring well location data is included in Appendix C. Based on the slope-aquifer system conceptual model, groundwater at the site is expected to flow downward from the topographic divides along Sherrills Ford Road on the west side of the ash basin and Island Ford Road on the north side of the ash basin. As described below, the wells provide monitoring data on the groundwater 1 adjacent to the ash basin. Monitoring wells MW-4', MW-10S2, MW-11S, MW-12S, MW-13S, and MW-14S were installed by rotary drilling methods using hollow stem augers,with the well screen installed above auger refusal to monitor the shallow aquifer within the saprolite layer. These wells were installed with screen lengths of either 10 feet or 15 feet. The screens were installed with screen intervals ranging from 3 feet to 18 feet below ground surface (bgs) at MWA 3S and 37 feet to 52 feet bgs at MWA1S. Monitoring wells MW-10D, MWA1D, MWA2D, MWA3D, and MWA4D were installed by rotary drilling methods using hollow stem augers and by rock coring techniques(HQ diameter barrel). Monitoring well MW-4D3 was installed using hollow stem augers and rock coring techniques I with an NQ diameter barrel. These monitoring wells were installed in the fractured rock transition zone with screen lengths of 5 feet. The screens were installed with screen intervals ranging from 41.5 feet to 46.5 feet bgs at MWA3D and 90 feet to 95 feet bgs at MWA2D. The monitoring wells at MSS are equipped with dedicated bladder-type pumps. Groundwater monitoring wells MW-6S, MW-6D, MW-7S, MW-7D, MW-8S, MW-8D, MW-9S, ' and MW-9D were installed by Duke Energy in 2006 as part of a voluntary monitoring system. No groundwater samples are currently collected from these wells under the compliance monitoring program. 1 4.3 Monitoring Frequency The monitoring wells will be sampled three times per year in February, June, and October. 4.4 Sample Parameters and Methods 1 The monitoring program consists of sampling and analysis for parameters and constituents identified in Attachment XX of the NPDES permit(Appendix B). The parameters and constituents and the analytical methods are presented in Table 2. Duke Power Company, Marshall Steam Station, Dry Ash Landfill, Monitoring Well Drill Records, July 1989. 2 Wells other than MW-4 and MW-4D have the boring log and well record found in MACTEC's Ash Basin ' 3 Monitoring Well Installation Report(MACTEC Project No. 6228-10-5284)dated August 26,2010. S&ME, Inc., Ash Basin Monitoring Well Installation, Duke Power—Marshall Steam Station, S&ME Project No. 1356-06-834, December 4,2006. 6 Duke Energy Carolinas,LLC I Goundwater Monitoring Program Sampling,Analysis, and Reporting Plan Marshall Steam Station Ash Basin FN Section 4-Monitoring Program The analytical results will be compared to the 2L Standards for the parameter or constituent. 4.5 Data Quality Objectives The overall Quality Assurance(QA)objective is to ensure that reliable data of known and ' acceptable quality are provided. All measurements will be documented to yield results that are representative of the groundwater quality. Data will be calculated and reported in units as required by the NCDENR. 1 The analytical QA objectives for precision, accuracy, and completeness have been established by the laboratory(s) in accordance with the Environmental Protection Agency(EPA)or other ' accepted agencies for each measurement variable where possible. The objectives are outlined in the Duke Energy Analytical Laboratory Procedures Manual and are available upon request. ' Appropriate methods have been selected to meet applicable standards for groundwater quality. Instances may occur, however, in which the condition of the sample will not allow detection of the desired limits for various parameters either because of matrix interference or high analyte concentrations requiring sample dilution. The laboratory(s)will provide sufficient documentation with each data package to notify reviewers about any analytical problems with the data, if needed. 1 Duke Energy Carolinas,LLC I Groundwater Monitoring Program Sampling,Analysis,and Reporting Plan Marshall Steam Station Ash Basin FN Section 5-Sampling Procedures Section 5 - Sampling Procedures i 5.1 Sampling Equipment Development, purging, and sampling equipment shall be selected to ensure that materials are compatible with the sample parameters and comply with state and federal regulatory ' requirements for sampling. Positive-gas-displacement fluorocarbon resin bladder pumps are installed in each monitoring well as dedicated purging and sampling systems. ' 5.1.1 Equipment Cleaning Procedures Dedicated sampling equipment has been installed in each monitoring well. In the event non-dedicated equipment is used between monitoring wells, equipment will be cleaned before ' use and between wells in accordance with standard EPA-approved cleaning procedures for field equipment. This standard is outlined in the Standard Operating Procedures and Quality Assurance Manual, Engineering Support Branch, EPA Region IV, February 1, 1991. 5.2 Groundwater Sampling ' 5.2.1 Development of Monitoring Wells All 12 monitoring wells addressed in this sampling plan have been developed. ' If new monitoring wells are installed, they will be developed prior to initial sampling. Development removes silt that has settled into the bottom of the well following installation and removes fine silt and clay particles from the well screen and sand-pack surrounding the screen. Well development is necessary to eliminate potential clogging and enhance well performance. Development involves removing an estimated ten or more well volumes from the well using a positive-gas-displacement fluorocarbon resin bladder pump with up-and-down agitation to ' loosen particles from the well screen. After development of a well, a true well depth is recorded referencing the top of well casing (TOC). ' 5.2.2 Groundwater Level and Total Depth Measurements Water level measurements shall be collected and recorded to determine the groundwater elevations and groundwater flow direction and to calculate the volume of standing water in the well. All monitoring wells have been surveyed to determine the elevation of the TOC. All depth and water level measurements shall be referencing the TOC and recorded to the nearest one-hundredth of a foot. ' Water level measurements shall be made with an electronic measuring device consisting of a spool of dual-conductor wire and sensor. When the sensor comes in contact with water, the circuit is closed and a meter light and/or buzzer are attached to the spool to signal the contact. The sensor is lowered further until it rests on the bottom of the well to determine the total depth of the well referencing the TOC. The depth and water level measurements shall be used to verify that the well has not filled with silt and to calculate the volume of water in the well. iThe volume of well water(in gallons) is calculated using the following equation: s i ' Duke Energy Carolinas,LLC I Goundwater Monitoring Program Sampling.Analysis, and Reporting Plan Marshall Steam Station Ash Basin 01 Section 5-Sampling Procedures V= h '`Tr" rz "(7.48052 gal/ft)' Where: V=volume of water in the well screen and casing (gallons) h = height of standing water(feet) =total well depth -water level ' r= radius of well casing (feet) For example, a 2-inch-diameter casing will have a volume of 0.1631 gallons per foot. ' In dedicated sampling systems, an accurate well depth is determined, as indicated above, after development of the well and prior to installation of the dedicated bladder pump. The well depth ' will be re-measured any time the dedicated sampling system is removed for repair or replacement. The well depth, water level measurement, and calculated well volume are recorded on the Groundwater Monitoring Data Sheet(Figure 4). ' 5.2.3 Well Purging and Sampling The selection of purging technique is dependent on the hydrogeologic properties of the aquifer and hydraulic characteristics of each well. Hydraulic conductivity, water column, well volume, ' screen length, and other information are evaluated to select the purging technique to acquire groundwater representative of the aquifer conditions. The Groundwater Monitoring Data Sheet (Figure 4) is used to record purging methods and measurements. A multi-parameter water quality monitoring instrument is used to measure field stabilization or indicator parameters for determining representative groundwater during purging. These ' instruments measure pH, specific conductance, temperature, dissolved oxygen (DO), and oxidation-reduction potential (ORP). Instrument calibration must be performed and documented before and after each sampling event. The pH subsystem will be calibrated with two pH ' standards (pH 7.0 and 4.0) bracketing the expected groundwater pH. The specific conductance subsystem will be calibrated using two standards bracketing the expected groundwater conductivity. Calibration results will be recorded on a Field Sampling Calibration Form (Figure 5). Various well purging techniques are described below. The purging method utilized at any t particular well will be selected after considering the characteristics of the well and the purging method(s) used during previous sampling events. ' CONVENTIONAL PURGING This technique entails removing one equivalent well volume and measuring the indicator parameters(temperature, pH, and speck conductance). When the parameters have stabilized ' to within t0.2 pH units and ±10 percent for temperature and conductivity over three to five well volumes, representative groundwater has been achieved for sampling. It is acceptable to begin sampling after five complete well volumes have been removed, even when Indicator parameters have not stabilized. Groundwater is pumped into a graduated container to measure the volume g i ' Duke Energy Carolinas,LLC I Goundwater Monitoring Program Sampling,Analysis, and Reporting Plan FN Steam Station Ash Basin Section 5-Sampling Procedures of water purged. Under normal rates of recovery, samples should be collected immediately iafter purging in accordance with EPA guidelines. For low-yield wells incapable of yielding three to five well volumes in a reasonable amount of ' time(e.g., 2 hours or less), groundwater is purged to the elevation of the pump intake while measuring indicator parameters. Typically, low-yield wells are evacuated to dryness one time and sampled when sufficient water level recovery occurs. Turbidity is not a required i stabilization parameter, but turbidity levels of 10 nephelometric turbidity units(NTU)or less should be targeted. LOW-FLOW PURGING Low-flow purging and sampling are appropriate when the recharge rate of the well approximates or equals the discharge rate of the pump with minimal drawdown of the water column (5 1 foot). ' During low-flow purging and sampling, groundwater is pumped into a flow-through chamber at flow rates that minimize or stabilize water level drawdown within the well. Indicator parameters are measured over time(usually at 5-minute intervals). When parameters have stabilized within ' t0.2 pH units; t10 percent for temperature, conductivity, and DO; and t10 millivolts(mV)for ORP over three consecutive readings; representative groundwater has been achieved for sampling. Turbidity is not a required stabilization parameter, but turbidity levels of 10 NTU or ' less should be targeted. MODIFIED LOW-FLOW PURGING ' This technique is considered a viable option particularly in the Piedmont region due to the likely presence of fine-grained soils where water level drawdown cannot be stabilized while pumping. When the well recharge rate is less than the pump discharge rate, excessive drawdown (>1 foot)of the water column occurs and mixes with stagnant water located above the screened interval. One equivalent well volume is removed initially before measuring indicator parameters. Frequently, removal of the initial well volume reduces the hydraulic head and allows for i matching of the recharge rate with the pumping rate providing stabilization of drawdown. Indicator parameters should be measured at 5-minute intervals using a flow-through chamber attached to a multi-parameter water quality instrument. When parameters have stabilized to i within t0.2 pH units; t10 percent for temperature, conductivity, and DO; and t10 mV for ORP over three consecutive readings; representative groundwater has been achieved for sampling. Turbidity is not a required stabilization parameter, but turbidity levels of 10 NTU or less should ' be targeted. VERY LOW-YIELD WELL PURGING ' This technique provides the best option for monitoring wells that historically purge to dryness and do not sufficiently recharge to provide adequate volume for sample collection. Wells that yield less than 100 milliliters per minute(mL/min)frequently incur significant drawdown during well purging. Therefore, if the well yield is less than 100 mUmin, the volume of the pumping system (i.e., the pump bladder,tubing, and flow-through chamber) shall be calculated and two pumping system volumes shall be removed. Indicator parameters will be measured and ' recorded initially, and then sample collection will begin. ' 10 1 ' Duke Energy Carolinas,LLC I Goundwater Monitoring Program Sampling.Analysis,and Reporting Plan Marshall Steam Station Ash Basin ri Section 5-Sampling Procedures 5.3 Sample Collection ' Groundwater samples are collected after representative groundwater has been determined by purging and stabilizing the indicator parameters. ' Sampling personnel wear clean, disposable, non-powdered nitrile gloves at each location. Samples are collected in the order of the volatilization sensitivity of the parameters: ' • Metals, metalloids, and selenium • Sulfate and chloride 1 • Total dissolved solids After collection, samples will be preserved and stored according to parameter-specific methods and delivered to the laboratory under proper Chain-of-Custody(COC) procedures. All pertinent notations, water-level measurements, removed well volumes, and indicator parameters shall be documented on the Groundwater Monitoring Data Sheet(Figure 4). ' 5.4 Sample Containers, Volume, Preservation, and Holding Time ' All sample containers supplied by the laboratory for the collection of groundwater samples shall be new and pre-cleaned as approved by EPA procedures appropriate for the parameters of interest. Table 3 summarizes the sample containers, sample volume, preservation procedures, ' and holding times required for each type of sample and parameter. Sample containers will be kept closed until used. All sample containers will be provided by Duke Energy or vendor laboratories. 5.5 Sample Tracking The COC procedures allow for tracing the possession and handling of individual samples from ' the time of field collection through laboratory analysis and report preparation. Samples shall be pre-logged prior to sample collection. This process assigns a unique tracking number for each sample and generates corresponding labels. An example of the COC Record is provided as Figure 6. 5.6 Sample Labeling ' Sample containers shall be pre-labeled and organized prior to field activities as part of the pre-sampling staging process. As samples are collected, the sampling personnel shall write the following information directly on the label: sampling date and time, and initials of sample ' collector. This information is also recorded on the Groundwater Monitoring Data Sheet (Figure 4)and the COC Record (Figure 6). ' 5.7 Field Documentation Field documentation from each sampling event is recorded on the Groundwater Monitoring Data Sheets (Figure 4), the Field Sampling Calibration Form (Figure 5), and the Chain-of-Custody 1 Record (Figure 6). Additionally, a Groundwater Sampling Site Checklist(Figure 7) is completed indicating information about the monitoring well such as proper identification (ID)tag and 1 1 ' Duke Energy Carolinas,LLC I Goundwater Monitoring Program Sampling.Analysis, and Reporting Plan Marshall Steam Station Ash Basin Section 5-Sampling Procedures condition of protective casing and pad. Field notations shall be made during the course of the ' field work to document the following information as applicable: • Identification of well ' e Well depth ' e Static water level depth and measurement technique e Presence of immiscible layers and detection method e Well yield—high or low e Purge volume or pumping rate 1 e Sample identification numbers ' e Well evacuation procedure/equipment e Sample withdrawal procedure/equipment ' e Date and time of collection • Types of sample containers used ' e Identification of replicates or blind samples 1 e Preservative(s) used e Parameters requested for analysis e Field analysis data and methods ' e Sample distribution and transporter e Field observations during sampling event ' e Name of sample collector(s) e Climatic conditions including estimate of air temperature ' This field notation information will be entered on the Groundwater Monitoring Data Sheets (Figure 4), the Field Sampling Calibration Form (Figure 5), or the Chain-of-Custody Record and Analysis Request Form (Figure 6)which are filled out for each sampling event. These documents will be arranged and filed by project and date. Recorded entries will be made on electronic forms or on paper forms in indelible ink. Errors on paper documents will be corrected by drawing a line through the error, initialing and dating the correction, and starting a new entry on the next line (if necessary). ' 12 ' Duke Energy Carolinas,LLC I Goundwater Monitoring Program Sampling,Analysis,and Reporting Plan Marshall Steam Station Ash Basin�'� Section 5-Sampling Procedures 5.8 Chain-of-Custody Record The COC Record (Figure 6)accompanies the sample(s), traces sample possession from time of collection to delivery to the laboratory(s), and clearly identifies which sample containers have ' been designated for each requested analysis. The record includes the following types of information: • Sample identification number • Signature of collector ' • Date and time of collection • Sample type (e.g., groundwater, immiscible layer) ' • Identification of well ' • Number of containers • Parameters requested for analysis 1 • Preservative(s) used • Signature of persons involved in the chain of possession • Inclusive dates of possession ' 5.9 Sample Custody, Shipment, and Laboratory Receipt For the purpose of these procedures, a sample is considered in custody if it is: • In actual possession of the responsible person • In view, after being in physical possession ' • Locked or sealed in a manner so that no one can tamper with it after having been in physical custody or in a secured area restricted to authorized personnel ' All samples shall be maintained in the custody of the sampling crew during the sampling event. At the end of each sampling day and prior to the transfer of the samples off site, entries shall be completed on the COC form for all samples. Upon transfer of custody,the COC form is signed by a sampling crew member, including the date and time. If outside vendor laboratories are utilized, samples shall be delivered to these facilities by Duke Energy personnel or courier. j All COC forms received by the laboratory(s)shall be signed and dated by the respective supervising scientist(s)or their designee(at the Duke Energy lab)or the laboratory sample custodian (at vendor labs) immediately following receipt by the laboratory. 13 1 Duke Energy Carolinas,LLC I Goundwater Monitoring Program Sampling,Analysis, and Reporting Plan Marshall Steam Station Ash Basin F,I Section 5-Sampling Procedures The analysts at the laboratory(s) maintain a sample tracking record that will follow each sample through all stages of laboratory processing. The sample tracking records show the date of sample extraction or preparation and analysis. These records are used to determine compliance with holding time limits during lab audits and data validation. Custody procedures followed by Duke Energy laboratory personnel are described in detail in the Duke Energy Laboratory Services Procedures Manual. 1 r t ' 14 Duke Energy Carolinas,LLC I Groundwater Monitoring Program Sampling,Analysis,and Reporting Plan Marshall Steam Station Ash Basin 01 Section 6-Analytical Methods Section 6 - Analytical Methods The main analytical laboratory used in this program is the Duke Energy Laboratory Services Laboratory: N.C. Drinking Water(NC37804)and Wastewater(#248) Certifications. The organizational structure and staff qualifications of the laboratory are discussed in its generic Quality Assurance Program(QAP). The QAP and the Analytical Laboratory Procedures Manual are available for review upon request. Vendor laboratories that meet EPA and North Carolina certification requirements may be used for analyses with approval by Duke Energy. The analytical methods used for the samples analyzed for this Groundwater Monitoring Program are listed in Table 2. Specific conductance, field pH, and temperature are measured in the field according to the Duke Energy Groundwater Monitoring and Sample Collection Procedure or the instrument manufacturer instructions. 1 1 15 1 ' Duke Energy Carolinas,LLC i Groundwater Monitoring Program Sampling.Analysis, and Reporting Plan Marshall Steam Station Ash Basin 01 Section 7-Internal Quality Control Checks Section 7 - Internal Quality Control Checks Internal laboratory QC checks used by the laboratories are described in each laboratory's generic QAP and procedures manual. Using the internal laboratory QC checks, the laboratories demonstrate the ability to produce acceptable results using the methods specified. Internal quality control checks for sampling procedures and laboratory analyses will be conducted with each sampling event. These checks will consist of the preparation and submittal of field blanks, trip(travel) blanks, and/or field replicates for analysis of all parameters at frequencies described in the laboratory(s) procedures manuals. The field QC blanks and replicates that may be included as internal QC checks are described 1 below. The specific type and number of blanks used may vary depending on the sampling event and will be determined by the Duke Energy field sampling personnel: • Field Blanks: A field blank consists of a sample container filled in the field with organic- free, deionized, or distilled water prepared and preserved in the same manner as the samples. The field blank is transported to the laboratory with the samples and analyzed along with the field samples for the constituents of interest to check for contamination imparted to the samples by the sample container, preservative, or other exogenous sources. Field blanks are typically utilized for each sampling event. The field blanks are ' typically analyzed for major anions, cations, and metals. • Trip Blanks: A trip (travel) blank is a sample container filled with organic-free water in ' the laboratory that travels unopened with the sample bottles. Trip blanks are typically utilized when sampling for volatile organic compounds. The trip blank is returned to the laboratory with the field samples and analyzed along with the field samples for ' parameters of interest. • Equipment Blanks: If non-dedicated equipment is used between wells, it is recommended that equipment blanks be collected. The field equipment is cleaned following documented cleaning protocols. An aliquot of the final control rinse water is passed over the cleaned equipment directly into a sample container and submitted for analyses. • Field Replicates: A field replicate is a duplicate sample prepared at the sampling locations from equal portions of all sample aliquots combined to make the sample. Both the field replicate and the sample are collected at the same time, in the same container type, preserved in the same way, and analyzed by the same laboratory as a measure of sampling and analytical precision. 16 ' Duke Energy Carolinas,LLC I Groundwater Monitoring Program Sampling,Analysis,and Reporting Plan Marshall Steam Station Ash Basin 01 Section 8-Validation of Field Data Package Section 8 - Validation of Field Data Package The field data package includes all of the field records and measurements developed by the sampling team personnel. The field data package validation will be performed by Duke Energy personnel. The procedure for validation consists of the following: • A review of field data contained on the Groundwater Monitoring Data Sheets for completeness. ' • Verification that equipment blanks, field blanks, and trip blanks were properly prepared, identified, and analyzed. • A check of the Field Sampling Calibration Form for equipment calibration and instrument conditions. • A review of the COC Record for proper completion, signatures of field personnel and the laboratory sample custodian, dates and times, and for verification that the correct analyses were specified. 1 1 I 1 1 1 1 ,7 I Duke Energy Carolinas,LLC I Groundwater Monitoring Program Sampling,Analysis, and Reporting Plan Marshall Steam Station Ash Basin FN Section 9-Validation of Laboratory Data Section 9 - Validation of Laboratory Data The laboratory will perform a validation review of the submitted samples and analytical results to ensure that the laboratory QA/QC requirements are acceptable. 1 1 18 ' Duke Energy Carolinas,LLC I Groundwater Monitoring Program Sampling,Analysis,and Reporting Plan Marshall Steam Station Ash Basin 01 Section 10-Report Submittal Section 10 - Report Submittal A report of the monitoring results for all wells will be submitted to the DWR within 60 days of the date of sampling. The monitoring results will be submitted on NCDENR Form GW-59CCR. The DWR will be notified in the event that vendor lab analyses have not been completed within ' this time frame. All Groundwater Monitoring Data Sheets, Field Calibration Forms, Chain-of- Custody Records, Laboratory QA data, and Data Validation Checklists shall be kept on file by Duke Energy and are available upon request. 1 1 r i 19 i ' Duke Energy Carolinas,LLC I Groundwater Monitoring Program Sampling.Analysis,and Reporting Plan Marshall Steam Station Ash Basin F,l Section 11 -References i Section 11 - References Duke Power Company, Marshall Steam Station, Dry Ash Landfill, Monitoring Well Drill Records. ' July 1989. Hamed, D.A. and Daniel, C.C., III. 1992. The Transition Zone Between Bedrock and Regolith: Conduit for Contamination? p. 336-348, in Daniel, C. C., III,White, R. K., and Stone, P.A., eds., Groundwater in the Piedmont: Proceedings of a Conference on Ground Water in the Piedmont of the Eastern United States, October 16-18, 1989, Clemson University, 693p. iHeath, R.C. 1980. Basic elements of ground-water hydrology with references to conditions in North Carolina: U. S. Geological Survey Water-Resources Open-File Report 80-44, 86p. LeGrand, H.E. 1988. Region 21, Piedmont and Blue Ridge, p.201-208, in Black,W., Rosenhein, J.S., and Seaber, P.R., eds., Hydrogeology: Geological Society of America, The i Geology of North America, v. 0-2, Boulder, Colorado, 524p. LeGrand, Harry, Sr. 2004. A Master Conceptual Model for Hydrogeologlcal Site Characterization in the Piedmont and Mountain Region of North Carolina, North Carolina ' Department of Environment and Natural Resources. MACTEC. 2010. Ash Basin Monitoring Well Installation Report, Marshall Steam Station, iMACTEC Project No. 6228-10-5284. August 26, 2010. SBME, Inc. 2006. Ash Basin Monitoring Well Installation, Duke Power—Marshall Steam Station, SBME Project No. 1356-06-834, December 4, 2006. North Carolina Geologic Survey. 1996. Generalized Geologic Map of North Carolina, 1991, Reprinted 1996. i i 1 1 20 t 1 Figures ' ISLA,ND POINT RD gp m g N INDUSTRIAL �a LANDFILL#1 H� PERMIT N0. 1812 ASBESTOS LANDFILL �c0 LANDFILL PERMIT sic ND. 1804 t o �0 ASH LANDFILL o PERMIT No. 1804 _ v m 0 STf blPTq�lp ��ds'�./O o P D ASH LANDFILL PERMIT N0. 1804 f 1 h H p ;= ASH BASIN `� FGD LANDFILL PERMIT N0. 1809 Midway o � � Marina m 850 I� op T 85� MARSHALL STEAM STATION gp� 800 m o NC HIGHWAY I50 C' 1 ti � Terrell Lake�rman 1 � ,, f"Catawba �a = B �o 0 � NORMAN 0 ' NOTES: I. SOURCE: USGS TOPOGRAPHIC MAP - LAKE NORMAN NORTH QUADRANGLE. CREATED 1993. UPDATED 2011. ASCADf ST 2. MAP DOES NOT REFLECT REALIGNMENT OF STEAM PLANT ROAD. SCALE (FEET) 1,000 D 1,000 2,000 ' SITE LOCATION MAP DATE DUKE ENERGY CAROLINAS, LLC OCT. 10, 2014 MARSHALL STEAM STATION ASH BASIN NPDES PERMIT #NC0004987 FIGURE Lken.e NunEa!'FOIN CATAWBA COUNTY, NORTH CAROLINA uo seen cn„2n se..cn.ns..xc:om t 1 ' 1 1 ZT, W. 1 FA LEGEND: DUKE ENERGY PROPERTY BOUNDARY ASH BASIN COMPLIANCE BOUNDARY , ASH BASIN COMPLIANCE BOUNDARY COINCIDENT ' — — WITH DUKE ENERGY PROPERTY BOUNDARY ASH BASIN WASTE BOUNDARY 1 t LANDFILL(ASH OR FGD RESIDUE)OR STRUCTURAL FILL _ ' LIMIT OF WASTE a M- � I LANDFILL COMPLIANCE BOUNDARY ASBESTOS-C&D LANDFILL BOUNDARY " :p — — TOPOGRAPHIC CONTOUR(4 FOOT) STREAM ASH BASIN COMPLIANCE GROUNDWATER —�'- ' MONITORING WELL NOTES: 1.PARCEL DATA FOR THE SITE WAS OBTAINED FROM DUKE ENERGY REAL ESTATE AND IS APPROXIMATE. DATE 2.ASH WASTE BOUNDARY,STRUCTURAL FILL,AND LANDFILL BOUNDARIES WERE PROVIDED BY DUKE ENERGY AND ARE APPROXIMATE. SITE LAYOUT MAP 3.AS-BUILT MONITORING WELL LOCATIONS PROVIDED BY DUKE ENERGY. OCT. 10, 2014 4.SHALLOW MONITORING WELLS(S)-WELL SCREEN INSTALLED ACROSS THE SURFICIAL WATER TABLE. DUKE ENERGY CAROLINAS, LLC S.DEEP MONITORING WELLS(D)-WELL SCREEN INSTALLED IN THE TRANSITION ZONE BETWEEN COMPETENT BEDROCK AND THE REGOLITH. MARSHALL STEAM STATION ASH BASIN ' 6.TOPOGRAPHY DATA FOR THE SITE WAS OBTAINED FROM NC DOT GEOGRAPHIC INFORMATION SYSTEM(GIS)WEB SITE. FIGURE 7.ORTHOPHOTOGRAPHYWAS OBTAINED FROM INC ONEMAPGIS WEB SITE(DATED 2009). 1.000' 0 500 .No NPDES PERMIT#NC0004987 S.THE ASH BASIN COMPLIANCE BOUNDARY IS ESTABLISHED ACCORDING TO THE DEFINITION FOUND IN 15A NCAC 02L.0107(a). CATAWBACOUNTY, NORTH CAROLINA L) SCALE ,.o.... r.....,o 1 ' ABOVEGROUND WELL PROTECTOR (4 INCH X 4 INCH X 5 FOOT STEEL CASING WITH HINGED LOCKABLE LID) ' I DRILL�" DIAMETER VENT HOLE BELOW PLUG 2'-6" TO 3'-0" (NOMINAL) 2" DIA. PVC ' STICK-UP WELL CASING GROUND SURFACE CONCRETE PAD ' 6" MIN. 2 FT X 2 FT SQUARE NEAT CEMENT OR NEAT CEMENT BENTONITE MIX FROM BENTONITE SEAL TO GROUND SURFACE BORING (8" NOMINAL DIAMETER) BENTONITE SEAL ' 2 -O" (MINIMUM) 2 -0" (MINIMUM) WELL SCREEN (0.010" MANUFACTURED SLOTS, TYPICAL) WELL PACKING (TYP. #1 OR #2 SAND) SCREEN LENGTH VARIES (5 TO 15' TYP.) MALE PVC PLUG ' 6±" OF WELL SAND ' Typical Well Construction Details (no scale) 1 INFORMATION PROVIDED BY DUKE ENERGY CAROLINAS, LLC ' DATE TYPICAL OCT. 10, 2014 MONITORING WELL CONSTRUCTION FIGURE DETAILS 3 t PROCEDURE NO 3175.1 p DUKE DUKE ENERGY ENERGY GROUNDWATER MONITORING DATA SHEET ' FOR CONVENTIONAL SAMPLING SITE NAME Marshall Steam Station PERMIT q NC0004987 SITE ID N/A PROJECT NAME Ash Basin Groundwater Monitoring FIELD CREW l � SAMPLING DATE(s) WELL/LOCATION NAME MONITORING WELL INFORMATION 1 WELL DIAMETER(in) TOC ELEV(ft msl) MIDDLE OF WETTED SCREEN(ft toc) WELL DEPTH(ft TOC) GS ELEV(ft msl) PUMP INTAKE DEPTH(ft TOC) ' SCREEN LENGTH(ft) ELEV REF SCREEN INTERVAL(ft TOC) TO EQUIPMENT INFORMATION LEVEL METER SERIALit SAMPLING EQUIPMENT PURGE METHOD TUBING DIAMETER(in) PUMP CONTROLLER SETTINGS PRESSURE (psi) RECHARGE (sec) I DISCHARGE (sec) SAMPLING INFORMATION INITIAL DEPTH TO WATER(ft TOC) WATER COLUMN(ft) well volume=water column X conversion factor WATER ELEVATION(ft msl) WELL VOLUME (gal) iC—version factor dependent on well diameter DETECTED ODOR None CONVERSION FACTOR 0.1631 and selected well volume units) APPEARANCE Normal _ 7 r ❑ (gal) PURGE WATER LEVEL COMPLETE TEMP SPECIFIC pH TURBIDITY ORP DISSOLVED WELL VOL VOLUME AFTER PURGE` EVACUATION COND. OXYGEN (recalculateson current water Ipq (ft) (YES/NO) (deg C) (umho/cm) (SU) (NTU) (mV-NFH) mg/L) levee 1 TOTAL PURGE Optional measurement to recalculate well CHLORINE Imrs/i) VOLUME volume when purging results in substantial SAMPLE COLLECTED BY DATE TIME 0.00 drawdown of water column @ NA IFQC By: WELL CONDITION ADDITIONAL WELL CONDITION NOTES ' PROTECTIVE CASING WELL PAD WELL CASING WELL TAG ' SAMPLING NOTES FIGURE 4: EXAMPLE GROUNDWATER MONITORING DATA SHEET FIELD SAMPLING CALIBRATION FORM ' STUDY: Marshall Steam Station Ash Basin Groundwater Monitoring DATE(s): SURFACE UNIT READER: COLLECTORS: SURFACE UNIT SERIAL M ANALYZER MODELM ANALYZER SERIAL M OTHER EQUIPMENT: WEATHER CONDITIONS: PROCEDURE#: I HYDROLAB 3210.3 VALIDATED BY: Calibration Date/Time DATE: I I TIME: I DATE: TIME: BP(mm% BP [mmHg) Calibation Instrument Standard Instrument Standard Parameter Calibration Results Calibration Results Standard Value Value Value Value SS 0.0 --► 0.0 Instrument Zeroed 0.0 --► 0.0 Zero Pass SPEC.COND. (US/cm) SS —► 350 —► 350 SS --► 150 --► 150 B(7.00) —► 7.00 —► pH B(4.00) —► 4.00 --► (units) B(10.00) —/—► 10.00 —► ..�.Buffer Temp. 25.00.. .�..�..�. ..�.Buffer TemP:�..�.. ..�..�..�..�..�.. Mid-Day Ck B(7.00) —► Time: Buffer Temp. ' p ORP SS(7.00) —► 285 —► 285 (mV) SS(4.00) NIA —► 462 N/A —► 462 ORP Temp. 25.00 ORP Temp. 25.00 ❑ w DO (mg IL) W AW —► �—► ❑ TURB Intu) SS Temp Cert Device# TEMP NIST N/A --► N/A Adjustment Not Available N/A —► N/A Adjustment Not Available ' (deg C) AMMONIUM SS N/A —► N/A N/A --► N/A (mg/L) SS N/A —► NIA N/A —► N/A INSTRUMENT MAINTENANCE DATE I TIME Conductance Subsystem pH Subsystem ❑ Cleaned Electrodes ❑ Cleaned Electrodes ❑ Tested-OK ❑ Replaced ref Electrode KCL ❑ See Notes ❑ Replaced Ref,Electrode Tip ❑ Tested-OK ❑ See Notes Dissolved Oxygen Subsystem Ammonium Subsystem 1Replaced Teflon Membrane ❑ Cleaned Electrode Tip ❑ Replaced DO electrolyte ❑ Installed New Electrode ❑ Cleaned Electrode ❑ Removed Electrode/Installed Plug ❑ See Notes ❑ Tested-OK ❑ See Notes Oxidation Reduction Subsystem Turbidity Subsystem ❑ Cleaned Electrode Cl Cleaned Electrode&Wiper ❑ Tested-OK See Notes ❑ Tested-OK 11 See Notes Temperature Subsystem Depth Subsystem ' ❑ Cleaned Electrode ❑ Reset/Calibrated ❑ Tested-OK See Notes ❑ Tested-OK f 3 See Notes KEY: B=Buffer W=Winkler —►=Adjusted To N/A=Not Applicable SS=Standard solution AW=Average Winkler —1—►=Not Adjusted To NOTES: FIGURE 5: EXAMPLE FIELD SAMPLING CALIBRATION FORM i r� rr r r r r rr r rr rr rr rr rr r� rr rr r� rr �r CHAIN OF CUSTODY RECORD AND ANALYSIS REQUEST FORM Duke �._._._._._._._._._._._._._._._._._._._._._._._._._._._._._._._._._., Duke Energy Analytical Lab Services i j Analytical Laboratory Use Onl i Energy Mail Code MG03A2 (Building 7405) ! ILIMS# NC J I 9Page 1 of 1 I i Originating 1 DISTRIBUTION 13339 Hagers Ferry Rd I i From SC i Huntersville, N.C. 28078 i !Logged B Date&Time SAMPLE PROGRAM 1 ORIGINAL to LAB, For Detailed Instructions,see: gg Y COPY to CLIENT (704)875-5245 j j i Groundwater http://dewww/essenv/coc/ F 704 ............_ax: 875-5038 I j i 1)Project Name 2)Phone No: Vendor Drinking Water_ a 1 UST 1 a i Cooler Tem C 1 E 3)Client 4)FaxNo: iPO# "Preserv.:1=HCL 2=1112SO4 3=HNO3 4=lce 5=None E 5)Business Unit: 20036 6)Process: 7)Resp.To: :MR# E 8)Project ID: 9)Activity ID: 10)Mall Code: o �j Custo rner_to complete all_a ro ,,. Q (2 NON-SHADED are is. t! M m ----------- 0 i LAB USE ONLY i 14Collection Information E a j 12Chem Desktop o 10 "Lab ID No. "Sam le Description or ID Date FTi.. Signa ure v i I i ! I I •- 0 i I c 1 IE I c I I m I I•10 a 1 1 0 a I a m I 1 a+ a i io U I O E I to H I I � C i U Customer to sign&date below 21)Relinquished By Date/Time Accepted By Date/Time m 22 Requested Turnaround .y Relinquished By Date/Time Accepted By Date/Time 14 Das J o v y Relinquished By Date/Time Accepted By Date/Time E 0 o `7 Days - d A 23)Seal/Locked By Date/Time Sealed/Lock Opened By Date/Time c v 48 Hr N � 24)Comments FIGURE 6 - CHAIN OF CUSTODY RECORD AND ANALYSIS REQUEST FORM L) A 'Other a `Add.Cost Will Apply �r r r r �r r rr r �■r r rr rr rr rr r r� rr �r rr NORTH CAROLINA GROUNDWATER SAMPLING SITE CHECKLIST LOCATION/SITE Marshall Steam Station/Ash Basin Groundwater Monitoring PERMIT N NC0004987 SAMPLE DATE SITE CONTACT FIELD CREW WEATHER PAGE 1 OF 1 MW-4 MW-4D MW-10S MW-10D MW-11S MW-110 MW-12S MW-121) MW-13S MW-13D MW-14S MW-140 ACCESS TO WELLS Access cleared into well Access cleared around well Tall grass or weeds-needs mowing Road washing out/mud /needs grading Fallen tree blocking access WELL SECURITY Well found locked Well found unlocked WELL LOCK CONDITION Lock in good condition Lock rusted,difficult toopen/needs re lacin Replaced damaged lock WELL CASINGS Casing in good condition Dameed rosin /still functional Damaged casing/repair required CONCRETE PADS Pad in good condition Minor cracks Major cracks/broken/repair required Undermined/washing out Fire ants around concrete pad WELL PROTECTIVE CASINGS Casing in good condition Dama ed casing/still functional Damaged casing/repair required Broken hinge on protective Ilei Wasp nest inside protective casing Ants inside protective casing WELL CAPS Well cap in good conditon Damaged/needs replacement Replaced damaged well cap PLUSH MOUNT WELLS Vault in good condition Water inside vault Vault bolt holes broken or stripped Botts stripped Vault lid cracked or broken WELL ID TAGS Well tag in good condition Well tag missing Well tag damaged/illegible Lacks required information-Driller Reg N Lacks required Information-Completion date Latksr wired information-Total well depth Lacks required information-Depth to screen Lacks required informatmn-Non bk tag NOTE: FIGURE 7: GROUNDWATER SAMPLING SITE CHECKLIST Tables 1 RECEIVED/DENR/DWR OCT 15 2014 I vvater uumity Permtmng Section Table 1 Monitoring Well Information Marshall Steam Station Ash Basin MW-4 MW-4D MW-10S MW-101D MW-11S MW-11D MW-12S MW-12D MW-13S MW-13D MW-14S MW-14D North(ft) 686,723.33 686,715.82 681,328.43 681,327.13 682,062.41 682,060.69 683,414.08 683,409.20 685.021.83 685.017.16 683,629.12 683.626.47 East(ft) 1,414,467.78 1,414,462.36 1,418,114.26 1,418,119.07 1,411,706.21 1,411,710.71 1,410.714.04 1,410,712.50 1.410.462.33 1,410,464.23 1,416.995.37 1,416,999.23 Top of PVC Casing Elevation(ft) 866.42 866.74 772.05 772.04 584.99 884.67 871.86 871.88 847.49 847.05 811.29 811.43 Well Diameter 2" 2" 2" 2" 2" 2" 2" 2" 2" 2. 2" 2" Well Stick-up(ft) 2.16 3.36 2.30 2.04 2.70 2.55 2.63 2.51 2.43 2.52 2.92 2.76 Type of Casing PVC PVC PVC PVC PVC PVC PVC PVC PVC PVC PVC PVC Total Depth below TOC(ft) 50.20 64.18 29.21 87.47 54.12 93.10 25.10 98.30 20.88 48.55 46.87 62.60 Screen Length(ft) 10 5 15 5 15 5 15 5 15 5 15 5 Screen Interval (ft below TOC) 40.20-50.20 59.18-64.18 14.21-29.21 82.47-87.47 39.12-54.12 88.10-93.10 10.10-25.10 93.30-98.30 5.88-20.88 4155-48,55F3187-46.87 57.60-62.60 Notes: 1.ft indicates feet. 2.TOC indicates top of casing. 3.As-built well coordinates(NAD 83)and top of PVC casing elevations(NAVD 88)provided by Duke Energy. 4.Well diameter,type of casing,and screen lengths were obtained from Well Construction Records provided by Duke Energy. 5.Well total depth below TOC and well stick-up measurements provided by Duke Energy. Page 1 of 1 1 Table 2 Sample Parameters and Analytical Methods Marshall Steam Station Ash Basin PARAMETER UNITS ANALYTICAL METHOD In Situ Parameters Field pH pH Units Hydrolab ' Conductivity pmhos/cm Hydrolab Temperature 0C Hydrolab Water Level ft Water Level Meter ' Laboratory Analyses Antimony pg/L TRM/ EPA 200.8 I Arsenic pg/L TRM/ EPA 200.8 Barium mg/L TRM/ EPA 200.7 Boron mg/L TRM/ EPA 200.7 Cadmium pg/L TRM/ EPA 200.8 Chloride mg/L EPA 300.0 Chromium mg/L TRM/ EPA 200.7 Copper mg/L TRM/ EPA 200.7 Iron mg/L TRM/ EPA 200.7 Lead L TRM EPA 200.8 1 u� / Manganese mg/L TRM/ EPA 200.7 Mercury pg/L EPA 245.1 Nickel mg/L TRM/ EPA 200.7 Nitrate(as Nitrogen) mg/L EPA 300.0 Selenium pg/L TRM/ EPA 200.8 Sulfate mg/L EPA 300.0 Thallium pVL TRM/ EPA 200.8 Total Dissolved Solids pg/L SM 2450C Zinc mg/L TRM/ EPA 200.7 Notes: 1.umhos/cm indicates micro-mhos per centimeter. 2.ft indicates feet. 3.pg/L indicates micrograms per liter. 4.mg/L indicates milligrams per liter. I5.TRM indicates total recoverable metals. 6.EPA indicates Environmental Protection Agency. 7.SM indicates Standard Method. Page 1 of 1 1 Table 3 Sample Containers, Preservatives, and Holding Times Marshall Steam Station Ash Basin PARAMETER CONTAINERS PRESERVATIVES HOLDING TIMES /n Situ Parameters ' Field pH In Situ None Analyze Immediately Conductivity In Situ None Analyze Immediately Temperature In Situ None Analyze Immediately ' LaboratoryAnaiyses Antimony 500 ml HDPE pH<2 HNO3 6 months Arsenic 500 ml HDPE pH<2 HNO3 6 months Barium 500 ml HDPE pH<2 HNO3 6 months Boron 500 ml HDPE pH<2 HNO3 6 months Cadmium 500 ml HDPE pH<2 HNO3 6 months Chloride 500 ml HDPE Cool 4°C 28 days Chromium 500 ml HDPE pH<2 HNO3 6 months Copper 500 ml HDPE pH<2 HNO3 6 months Iron 500 ml HDPE pH<2 HNO3 6 months Lead 500 ml HDPE pH<2 HNO3 6 months IManganese 500 ml HDPE pH<2 HNO3 6 months Mercury 500 ml HDPE pH<2 HNO3 6 months ' Nickel 500 ml HDPE pH<2 HNO3 6 months Nitrate(as Nitrogen) 500 ml HDPE Cool 4'C 48 hours Selenium 500 ml HDPE pH<2 HNO3 6 months 1 Sulfate 500 ml HDPE Cool 4°C 28 days Thallium 500 ml HDPE pH<2 HNO3 6 months Total Dissolved Solids 500 ml HDPE Cool 4°C 7 days —A Zinc 500 ml HDPE pH<2 HNO3 6 months Notes: ' 1.ml indicates milliliter. 2.HNO3 indicates nitric acid. 3.HDPE indicates high density polyethylene. Page 1 of 1 ' Appendix A - Boring Logs and Monitoring Well ' Construction Records Form 25630 (R3-87) FORM M-26C REVISION 2 � DUKE POWER COMPANY PAGE_Z—OF 1 CONSTRUCTION DEPARTMENT PROJECT SOIL TEST BORING FIELD REPORT STARTING TIME JOB NO. ! GROUND SUR€ACE ELEV. JOB NAME L ` Fi /1 s HRS.DRILLING HRS.MOVING DATE `V"1''�" WEATHER INSPECTOR �• C�Sa�-I BORING NO. ' SAMPLING SCALE UD SOIL CLASSIFICATION AND REMARKS 1 - W I _ oz 7 110 — J - �J zd b W O� Lr z m _ °z Mi I G r• o� I �' ' '---- 0 x �3 __ NW W!i um G. — ,J4:z- —AD W W - Z m T i s ;7> ruc Z6 W d N O : o ' s zco 3 fo BORING TERMINATED ETHOD OF ADVANCING BORING DEPTH ' BORING REFUSAL POWER AUGER TO WATER TOB DEPTH HAND CHOP:W/MUD:W/WATER TO WATER 24 HR: DEPTH ROTARY DRILL: W/MUD:W/WATER TO ' WATER LOSSES DIAMOND CORE TO CASING SIZE LENGTH Form 25630(R3.87) FORM M-26C REVISION 2 � DUKE POWER COMPANY PAGE Z OF ' CONSTRUCT DEPARTMENT PROJECT G• SOIL TEST BORING FIELD REPORT / STARTING TIME �! JOB NO. GROUND SLIPACE ELEV. JOB NAME 5 HRS.DRILLING HRS.MOVING�� DATEiw �9 WEATHER INSPECTOR -�eSD� BORINGNO.LL_'��_ SAMPLING SCALE UD SOIL CLASSIFICATION AND REMARKS f57 3R06" 5 a�N �✓ oZ — _ 'D D�y 0 �Z Q-1 ' <LL b W C� i 5 1 ) _ Oz NO O� 04 ' = mox �3 N va Z-K <N I �J N W ' W� _ Om � N i = Zri Zp a er o 0:0 ' — <cc 0 BORING TERMINATED METHOD OF ADVANCING BORING DEPTH ' BORING REFUSAL POWER AUGER TO WATER TOB DEPTH HAND CHOP: W/MUD: W/WATER TO WATER 24 HR: DEPTH ROTARY DRILL:W/MUD: W/WATER TO 1 WATER LOSSES DIAMOND CORE TO CASING SIZE LENGTH ' Form 25630(R3-87) FORM M-26C REVISION 2 DUKE POWER COMPANY PAGEOF CONSTRUCTION DEPARTMENT PROJECT SOIL TEST BORING FIELD REPORT 114 STARTING TIME JOB NO. GROUND SU DACE ELEV. JOB NAME GL s HRS.DRILLING_ _HRS.MOVING 1'114 / 4 DATE to "�'�� WEATHER INSPECTOR -D---re.� a2_BORINGNO.- n' '_�_� ' SAMPLING SCALE UD SOIL CLASSIFICATION AND REMARKS iST • E O ' — EGL o (f . Si i ' 5 � �N W °U ' 72) Czp4e-!5c- O o'G M J - 0 J Zt N 15 �z i = °° Z S mg 105. o Uam. �3 ' -_ 'r l a S. I Ile5 I to �U Z� N-j W N� - W �< I Z Oo O <a N ' 9c' - z C Z W� IL fV ° d'0 ' — /t/L� Ave L /.f p 5 ' - Lol A41C,4- 167V I-P O w 7> L BORING TERMINATED L... METHOD OF ADVANCING BORING DEPTH ' BORING REFUSAL CJC�t�A� G�•Ia POWER AUGER ©TO¢j. WATER TOB DEPTH •D d^� ' :361APIQ 91 —TO— WATER 24 HR: DEPTH �� j-4 - —TO-- WATER LOSSES DIAMOND GORS --TO— CASING SIZE AZ ZA LENGTH Form 25630 iR3 37) r FORM M-26C REVISION 2 PAGE Z DUKE POWER COMPANY CONSTRUCTION DEPARTMENT PROJECT_,J�'/ .CStfF�GC� SOIL TEST BORING FIELD REPORT / ' STARTING TIME JOB NO.__ _ GROUNDSU F CE ELEV. JOB NAMEJCx"464 LA, vF��c- �� HRS.DRILLINGHRS.MOVING DATE -�e S-7 WEATHER INSPECTOR _PfC&_'S., LBORING NO.-,E��, ' SAMPLING SCALE UD SOIL CLASSIFICATION AND REMARKS IST - RD 6" O 7,01 — 5 w >N w U OZ p . Z, D 1� /G co � J - 0 J _ Za aLL ow zm O00 C z z I N -- — 3:0 m� O S V3 — v1 Ln w Wa U� Z 5 F u4i N J -W uj N m ma I zom 1-J <N _ z D ZO W. C3 - mo ' — a 5 z: a� 00 �M O BORING TERMINATED METHOD OF ADVANCING BORING DEPTH BORING REFUSAL POWER AUGER LI) T049 WATER TOB DEPTH �L J` O (p3 - WATER 24 HR: DEPTH--3/--7 °� 2l- TO_ WATER LOSSES '� —TO CASING SIZE LENGTH d — ' NORTH CAROLINA DEPARTMENT OF NATURAL RESOURCES AND COMMUNITY DEVELOPMENT FOR OFFICE USE ONLY DIVISION OF ENVIRONMENTAL MANAGEMENT -GROUNDWATER SECTION ' P.O.BOX 27887-RALEIGH,N.C.27811,PHONE(919)733-5083 Quad. No. Serial No. Lat. Long. PC Minor Basin WELL CONSTRUCTION RECORD Basin Code ' — Header Ent. OW-1 Ent. DRILLING CONTRACTOR � PL) 4 STATE WELL CONSTRUCTION ' DRILLER REGISTRATION NUMBER e32 PERMIT NUMBER: ' 1. WELL LOCATION: (Show sketch of the location below) Nearest Town: c� County: tk :�; ��.4'� �SV Depth DRILLING LOG (Road, Community, or Subdivision and Lot' No.) From To Formation Description 2. OWNER -TD L)k' /D Wce Gni ADDRESS - d 0�/- a/15, Street or Route No. City or Town State Zip Code 3. DATE DRILLED 4 FJ `2 USE OF WELL '4. TOTAL DEPTH � •(� CUTTINGS COLLECTED 2-res ❑No 5. DOES WELL REPLACE EXISTING WELL? ❑ Yes D-wo 6. STATIC WATER LEVEL:2`f. -3 FT. ❑ above TOP OF CASING, ' �• FT. ABOVE ow TOP OF CASING IS LAND SURFACE. - 7. YIELD (gpm): af� METHOD OFTEST �! 8. V'•TER ZONES (depth): -1174 9, CHLORINATION: Type 1'11� Amount '10. CASING: Wall Thickness If additional space is needed use back of form. Depth Diameter or Weight/Ft. Material LOCATION SKETCH From 0 To 274 Ft. i 4ZuC (Show direction and distance from at least two State Roads, ' From To Ft. or other map reference points) From To—Ft,- 11 Ft.1tGROUT: Depth Material Method From 0 To -3r '5F t. G�7►� � From To Ft. ' 12. SCREEN: Depth' Diameter Slot Size Material �- From � !et��m ToFt. in. 010 in. From To Ft. in. in. From To Ft. In. in. ' 13. GRAVEL PACK: Depth Size Material From • S To4F6C Ft. ' From To Ft. r 14. REMARKS: lam'- �TGI Te✓ i'L�C �yti� Z'S - ��' ' I DO HEREBY CERTIFY THAT THIS WELL WAS CON TRUCTEQ IN ACCORATHELL WITH 15 NCAC 2C, WELL CONSTRUCTION STANDARDS, AND THAT A COPY OF THIS RECORD S BEE ROVIDED TO OWNER. ,,✓ SI NATURE OF CONTRACTOR OR AGENT DATE GW-1 Revised 11/84 Submit original to Division of Environmental Management and copy to well owner. N. C. Department of Human Resources Division of Health Services WELL COMPLETION RECORD ' MPLETE ALL INFORMATION REQUESTED BELOW FOR EACH WELL INSTALLED,AND RETURN FORM TO THE DEPARTMENT OF HUMAN RESOURCES, SOLID AND HAZARDOUS WASTE MANAGEMENT BRAN P. O. BOX 2091,RALEIGH,N.C. 27602 NAME OF SITE: PERMIT NO.: ADDRESS: OWNER(print): ' DRILLING CONTRACTOR:, REGISTRATION NO.: 1r Casing Type: �c iX�r AIA?� �IG dia. 47 in. Grout Depth: from to ? ft. -dia. Casing Depth: fromy to�ft. -dia. '� in. Bentonite Seal: from 32r to ft. .dia. Screen Type: i I/K t-ADr-%7 i�L dia. in. Sand/Gravel PK: from�`�S to 4q ft. .dia. ' Screen Depth: from ' ' to '—Z 4 ft. -dia. 7_ in. Total Well Depth: from f to 41:9 (--ft. -dia. Static Water Level: ^`� feet from top of casing Date Measured 7 / ' Yield(gpm): Method of Testing: Casing is 0- Le feet above land st ' DRILLING LOG LOCATION SKETCH DEPTH (show distance to numbered roads,or other map reference po FROM TO FORMATION DESCRIPTION c' 7 1 1 f LARKS: =E'r" cl /--DI -'Z4-'E7 IV6 �£�,�rE; /4k' �f�,.11/{iC'�iliiC.+�� /7'�� fc�•/!�` DATE: SIGNATURE: ` ' Form CI-olp Revision 0 pace O= POM COWANT — ' AS-BUILT IRS•fAt UTTIN to Instnument No. Al kl- Station - Offset �✓�/� By -�. 7 r iS: .1 Date it , L�✓E� ,�G � 4's'TG c� 1 1 fVC S-raAlpFlre G,2 oar - j%Zv��•lTo...lr7� rJ '•' �GOTT�D 7�'iG�C flit o Z_ 4s tilo.rl . moiA JU c�a 1 ' S&ME,Inc. 1.BORING AND SAMPLING IS INACCORDANCE tS&ME WITH ASTAI D-1586. 2.PENETRATION(N-VAL UE)IS THE NUMBER OF ' ENGINEERING • TESTING Telephone: BLOWS OF 140 LB.HAMMER FALLING 30 IN.REQUIRED TO ENVIRONMENTAL SERVICES Fax: DRIVE 1.4 IN.LD.9..4AfPLER 1 FT Project: Duke Power-Marshall Steam Station-Ash Basin Monitor Well Installation Boring No. MW-4D ' Location: Terrell,North Carolina Number: 1356-06-834 Sheet No. I of 2 Boring Depth(ft): 60.5 Elevation(ft): TBD Driller: Larry Shrader,NC Date Drilled: 10/12/06 Cert.No.3349 ' Logged By: Courtney Withers Water Level: 25.5 ft his at 24 hrs Drilling Method: 4%"H.S.A. Elev. Depth Lith- Material Description Well Penetration Resistance(Blows/Foot) (Feet) (Feet) ology Construction 0 50 100 ' FILL: Firm Red Slightly ClaYaY.Silty,Coarse to Fine SAND With Rock Fragments 13 5 SAPROLITE: Loose,White,Brown,and Orange, 10 10 Micaceous,Silty,Very Fine SAND ' SAPROLITE: Loose,White and Orange,Micaceous, Coarse to Fine SAND 10 ' 15 ' SAPROLITE:O E: Firm,Orange,Brown,and White, Micaceous,Coarse to Fine SAND 10 20 • o z 12 g 25 � SAPROLITE: Finn,Brown,White,and Red,Micaceous, Silty,Very Fine SAND .1 z m a J SAPROLITE: Firm,White and Orange,Coarse to Fine < SAND SAPROLITE: Stiff to Very Hard,Brown,White,and 30 11 ' Orange,Micaceous,Very Fine Sandy SILT With Coarse Sand Lenses x c� 0 J L) Z 0 11 ' m ' S&ME,Inc. L BORING AND SAMPLING ISINACCORDANCE tS&ME WITH ASTNI D-1586. 2.PENETRATION(N-VALUE)IS THE NUMBER OF ' ENGINEERING • TESTING Telephone: BLOWS OF 140 LB.IIAMMER FALLING 30 IN.REQUIRED TO ENVIRONMENTAL SERVICES Fax: DRIVE 1.41N.I.D.SAMPLER I FT. Project: Duke Power-Marshall Steam Station-Ash Basin Monitor Well Installation Boring No.MW-4D Location: Terrell,North Carolina Number: I356-06-834 Sheet No. 2 of 2 Boring Depth(ft): 60.5 Elevation(ft): TBD Driller: Larry Shrader,NC Date Drilled: 10/12/06 Cert.No.3349 ' Logged By: Courtney Withers Water Level: 25.5 ft his at 24 hrs Drilling Method: 4'/;'H.S.A. Elev. Depth Lith- Well Penetration Resistance(Blows/Foot) (Feet) (Feet) ology Material Description Construction ' 0 50 100 19 ' 40 Q 1 52 45 ' 50/ PARTIALLY WEATHERED ROCK: When Sampled ® 2 ' Becomes Very Dense,Black and White,Medium to Very 50 Fine SAND u er Refusal at 50.5 ft bls BEDROCK: Fine-Grained Biotite Gneiss 1 ' 55 ' o c� 0 2 Boring Terminated at 60.5 ft his ' g 60 See Attached Core Picture for Recovery and RQD 'a C7 Z ' a m x U3 J Cn CDQ Q w5J r 0 0 J z Z X O M MONITORING WELL CONSTRUCTION WELL ID: MW-4D TOTAL DEPTH: 60.5 ft bls $S&ME S&ME PROJECT AND NO: WELL USE/TYPE: INSTALLATION DATE: Marshall Steam Station,1356-06-834 1 Monitoring 10/12/2006 DRILLING CONTRACTOR: DRILLER AND LICENCE NO.: DRILLING METHOD: S&ME,Inc. I Larry Shrader,3349 4.25 H.S.A. 24-HR WATER LEVEL: NORTHING: FASTING: TOP OF CASING ELEV. GROUND SURFACE ELEV.: 25.5 ft bls TBD TBD TBD TBD PAD TYPE: Stickup(ft): —3.0 ft 2'x2'Concrete PROTECTIVE CASING: Depth BLS 4"x4"Lockable Steel I 0 ft-Top of Grout CASING TYPE: 2-inch Sch.40 PVC /,,/ CASING INTERVAL: iai//ii 0 to 55.5 ft bls SCREEN TYPE: 2-inch 0.010 Slot Sch.40 PVC SCREEN INTERVAL 55.5 to 60.5 ft bls '/% j j GROUT TYPE: Neat Cement GROUT INTERVAL 51.5 ft-To of Seal Top Oto 51.5ftbls 1 53.5 ft-Top of Filter Pack SEAL TYPE:Bentonite ' SEAL INTERVAL: 55.E It-"fop of ScreCrl 51.5 to 53.5 ft b1s FILTER PACK: ' #3 Filter Sand FILTER PACK INTERVAL: 53.5 to 60.5 ft bls Screened DEVELOPMENT: Interval Purged—35 Gallons 5 feet NOTES: ' TBD-To Be Determined 60.5 ft-Bottom of Screen 1 60.5 ft -Total Depth For Lithologic Information See Attached Boring Log ' WELL CONSTRUCTION RECORD (MW-4D) North Carolina-Department of Environment and Natural Resources-Division of Water Quality-Groundwater Section WELL CONTRACTOR(INDIVIDUAL)NAME(pirin Larry Shrader CERTIFICATION N 3349 1 WELL CONTRACTOR COMPANY NAME S&ME,Inc. PHONE a 704-523-4726 STATE WELL CONSTRUCTION PERMIT# ASSOCIATED WQ PERMIT# (if applicable) (if applicable) L WELL USE(Check Applicable Box):Residential❑ Municipal/Public❑ Industrial❑ Agricultral❑ Monitoring Recovery❑ Heat Pump Water Injection❑ Other❑ If Other,List Use 2, WELL LOCATION: Topographic/Land setting ' Nearest Town: Terrell County Iredell ❑ Ridge ❑ Slope ❑ Valley)Q Flat Marshall Steam Station (check appropriate box) (Suss Name,Numbers.Community,Sudivision,Lot No..Zip Code) Latitude/longitude of well location ' 3. OWNER: Duke Power (degrees/minutes/seconds) Address 526 South Church Street latitude/longitude source:❑GPS❑Topographic Map (Street or Rome No.) (check box) Charlotte NC 28202 DEPTH DRILLING LOG City or Town State Zip Code From To Formation Descrpition (704)373-7900 0 to 9 Fill Arca code-Phone Number 9 to 13 Silty Very Fine Sand 4. DATE DRILLED 10/1212006 13 to 24.5 Coarse to Fine Sand 5. TOTAL DEPTH 60.5 24.5 to 28 Silty Very Fine Sand 6. DOES WELL REPLACE EXISTING WELL? YES❑ NO% 28 to 28.5 Coarse to Fine Sand ' 7. STATIC WATER LEVEL.Below Top of Casing: 28.5 R. 28.5 to 48.5 Very Fine Sandy Silt (Use"-"if Above Top of Casing) 48.5 to 50.5 P W R 8. TOP OF CASING IS -3 FT.Above Land Surfaces 50.5 to 60.5 Bedrock ' *Top of casing terminated attar below land surface requires■ variance in accordance with 15A NCAC 2C.01 18. 9. YIELD(gpin) n/a METHOD OF TEST 1118 10. WATER ZONES(depth): n/a ' LOCATION SKETCH 11. DISINFECTION:Type n/a Amount n/a Show direction and distance in miles from at least 12. CASING: Wall Thickness two State Roads or County Roads.Include the road Depth Diameter or Weight/Ft. Material numbers and common names. From 0 To 55.5 Ft. 2-inch Sch.40 PVC From To Ft. a From-To-Ft. 13. GROUT: Depth Material Method From 0 To 51.5 Ft. Neat Cement Pour From 51.5 To 53.5 Ft. Bentonite Pour 14. SCREEN: Depth Diameter Slot Size Material ~ « From 55.5 To 60.5 Ft. 2-inch in. 0.01 in. PVC From To Ft. in. in. 15. SAND/GRAVEL PACK: Depth Size Material L + From 53.5 To 60.5 Ft. #3 Silica Sand From To Ft. 11 ♦ ' ' 16. REMARKS: I DO HERE BY CERTIFY THAT THIS WELL WAS CONSTRUCTED IN ACCORDANCE WITH 15A NCAC 2C,WELL CON UCf10N STAN S,AN H T A COPY OF THIS RECORD HAS BEEN PROVIDED TO THEW � I , L OWNER SIGNATURE OF PERSON CONSTRUCTING THE WELL DA 'n Submit the original to the Division of Water Quality,Groundwater Section,1636 Mail Service Center-Raleigh,NC 27699-1636 Phone No.(919)733-3221,within 30 days. GW-I REV.07/2001 t tJ MACTEC .f engineering and constructing a better tomorrow t August 26,2010 tMr.Jim Lindquist,Engineer Duke Energy Corporation Marshall Steam Station ' 8320 East NC Highway 150 Terrell,North Carolina 28682 ' Subject: Ash Basin Monitoring Well Installation Report Marshall Steam Station Terrell,Catawba County MACTEC Project No.:6228-10-5284 tDear Mr.Lindquist: ' The purpose of this report is to present the results of monitoring well installation and evaluation activities conducted between July 26 and August 13, 2010 at the above-referenced site (Figure 1). The well installation and testing was conducted in general accordance with the requirements outlined in the Ash ' Basin Groundwater Monitoring Well Installation Project Work Summary (Work Summary)provided by Duke Energy(Duke)and dated May 21,2010. The following Figures,Tables and Appendices have been ' included: Figure l:Site Location Map ' Figure 2:Monitoring Well Location Map Table 1:Summary of Well Construction Details Table 2:Summary of Slug Test Results Appendix A:Rock Core Photographs ' Appendix B:Soil Boring Logs Appendix C:Monitoring Well Records Appendix D:Monitoring Well Development Records t Appendix E: Photographs of Completed Well Pairs Appendix F:Slug Test Data Five Type II groundwater monitoring well pairs(a total of 10 wells) were installed between July 26 and tAugust 6,2010 at the locations shown on Figure 2. The well locations were pre-determined by Duke and marked in the field with wooden stakes and survey flagging. Each well pair consisted of one shallow well ' (using the identifier "S") set into overburden soils and one deep well (using the identifier "D) set into bedrock. Standard Penetration Testing (SPT) and split-spoon sampling was performed at five-foot intervals from the surface to bedrock during installation of the deep well at each well pair. Soils observed ' in the split-spoon samples were logged in the field in accordance with the Unified Soil Classification System (ASTM D2487/D2488). Upon auger refusal, each deep boring was extended a minimum of 10 ' feet into competent bedrock using HQ-sized rock core techniques. ' MACTEC Engineering and Consulting, Inc. 2801 Yorkmont Road, Suite '100 -Charlotte, NC 28208 - Phone 704 357.8600 - Fax: 704.357.8638 License Number: F-0653 www.madec.com r....n. r rte.. ' Ash Basin Monitoring Well Installation Report August 26,2010 Marshall Steam Station ' Terrell,Catawba County,North Carolina MACTEC Project 6228-10-5284 Rock core samples were logged in the field in accordance with the Field Guide for Rock Core Logging ' and Fracture Analysis established by Midwest Geosciences. As specified in the Work Summary, split- spoon sampling and rock coring were not performed during installation of the shallow wells. ' Photographs of rock cores obtained during installation of the five deep wells are included as Appendix A. ' Shallow wells were installed using 4.25-inch ID hollow stem augers; deep wells were installed using 4.25-inch ID hollow stem augers to refusal, then HQ-sized rock core approximately 10 feet into competent bedrock. Total depths for shallow wells ranged from 18 feet below ground surface (bgs) in MW-13S to 52 feet bgs in MW-I IS. Total depths for bedrock wells ranged from 46.5 feet bgs in MW- 13D to 95 feet bgs in MW-12D. Shallow wells were constructed with 15 feet of 0.010-slot 2-inch ' diameter PVC well screen and riser with well screens set so that 10 feet of screen is below the static water table at the time of installation. Deep wells were constructed with 5-foot well screens set across low- RQD bedrock core intervals in the deep wells to facilitate maximum water flow through each well. Filter sand was placed in the annular space between the augers and the casing from the total depth of the well to approximately 2 feet above the screen. A bentonite seal was placed on top of the filter pack and the well was grouted to the surface. Please note that shallow well depths were typically adjusted after installation, but prior to placement of bentonite, to account for rise in hydraulic head observed at each location. In ' these instances, additional filter sand was placed between the bottom of the borehole and the bottom of the well. Each well was completed with a stand-up well cover that extends approximately 30 inches above-grade and set into a 2-foot by 2-foot concrete pad. Monitoring well ID tags were secured to the ' outside of the stand-up covers and well numbers were etched into the wet concrete pad. Soil boring logs and well construction records for the 10 monitoring wells installed in during this work have been included ' as Appendix B and C,respectively. Subsequent to installation,each well was developed using a submersible or bladder pump to remove fine- grained material. In general, each well was purged until the development water appeared visually clear, at which time,water quality parameters(temperature, pH, conductivity and turbidity)were recorded in 5- gallon increments until turbidity readings were less than or equal to 10 NTUs. Purge water generated during well development ranged from 60 gallons to 140 gallons and was discharged to the ground surface ' adjacent to each well. Please note that water quality parameters were not recorded for well MW-12S. However, 140 gallons of water were purged from the well during well development. Monitoring well development records are included as Appendix D. Photographs of the completed monitoring well pairs Iare included as Appendix E. 2 1 Ash Basin Monitoring Well Installation Report August 26,1010 Marshall Steam Station ' Terrell,Catawba County,North Carolina MACTEC Project 6228-10-5284 Rising head slug tests were performed on each well on August 12 and 13,2010. Prior to the tests an In- situ Level Troll pressure transducer and 2-foot long stainless steel slug were placed into the well. The water level in the well was recorded as a"Background"test until the well recharged to within 90%of the ' original measurement. Subsequent to normalization, the rising head test was started, the slug was removed and the change in head versus time was measured using a Rugged-reader data logger. Slug test data was analyzed using Aqtesolv software to estimate hydraulic conductivity in each well. A summary of slug test data is presented in Table 2. Copies of raw data generated during completion of the rising head slug tests are included in Appendix F. 1 Please contact the undersigned at (704) 357-8600, if you have questions or comments concerning this 1 project. Sincerely, MACTEC ENGINEERING AND CONSULTING,INC. i 'A k Mark P.Filardi,P.G. Robe ster, stG; Senior Geologist Princi��C'� �' 1 Enclosures 1 cc: William M. Miller,PE,PLS,S&ME 1 For ,,� P. =-I�Q L With PerMISM0111 ' 3 Ash Basin Monitoring Well Installation Report August 26,2010 Marshall Steam Station Terrell, Catawba County,North Carolina MACTEC Project 6228-10-5284 1 FIGURES 1 ti ► F J ' WE Ar ��" -'{�• ;� �*+�y�~ � �- - � �� ;1�.� YIN - .. r P `, .z,:�t =.t 4A j i w rad I ""P7 Yr , ' 4r 4 RAA Source: USDA-NRCS Digital Raster Graphic Mosaic for Catawba County,NC.dated 2005. Site Location 1 1,000 2,000 4,000 . 111 8111 i FeetSITE LOCATION STATIONOMAI"TEC DUKE ENERGY MARSHALL STEAM COUNTY,CATAWBA • ' CAROLINA • ,/ •: NUMBER 6228-10-5284 1 . • n r ,y r MW-13S MW-13D MW-14S MW-12S , MW-14D MW-12D 4 � MW-11 S .- MW-11 D MW-10S -10D Source Mecklenburg County Geographic Information Systems(GIS),dated 2009 ' N C Site Location ® Monitoring Well Location 1 0 625 1,250 2,500 3,750 5,000 ' Feet OMACTEC MONITORING WELL LOCATIONS DUKE ENERGY ' MARSHALL STEAM STATION CATAWBA COUNTY, NORTH CAROLINA PREPARED DATE CHECKED DATE JOB NUMBER FIGURE BY r+, PF - o BY Q 8-a o_to 1 6228-10-5284 2 Ash Basin Monitoring Well Installation Report August 26,2010 Marshall Steam Station Terrell, Catawba County,North Carolina MACTEC Project 6228-10-5284 TABLES r r� rr rr rr r rr r� rr rr r �r rr �r rr r� r r r Table 1 Summary of Well Construction Details Marshall Steam Station,Terrell,North Carolina Coordinates Construction Details Measured Details Well Number Drilling Method Well Diameter Borehole Depth Well Depth(ft Screen Interval Wali Depth Depth to Water Water Column Latitude Longitude (I.D.in.) (ft bgs) bps) (ft bgs) (ft below TOC) (ft below TOC) Thickness(ft) MW-10S 35'36.36690 80'58.42864 Hollow-stem Auger 2 35.0 27.0 12-27 29.44 16.64 12.80 MW-10D 35'36.36670 80'58.44289 HSA/Rock Core 2 85.4 85.4 80.4-85.4 87.69 16.23 71.46 MW-11S 35736.47900 80.58.76251 Hollow-stem Auger 2 55.0 52.0 37-52 54.38 43.77 10.61 MW-11D 35'36.47871 80.58.76130 HSA/Rock Core 2 90.5 90.5 85.5-90.5 93.32 43.40 49.92 MW42S 35'36.42126 80.58.28485 Hollow-stern Auger 2 40.0 22.0 7-22 25.32 14.28 11.04 MW-12D 35'36.43905 80.68.31988 HSA/Rock Core 2 106.4 95.0 90-95 98.59 15.21 83.38 MW-13S 35`38.50564 80.58.42262 1 Hollow-stem Auger 1 2 25.5 18.0 1 3-18 21.12 5.70 1 15.42 MW-13D 35"38.50991 80.58.43568 HSA/RockCore 2 46.5 46.5 41.5-46.5 48.61 3.59 45.02 MW-14S 35'36.39923 80.58.30479 Hollow-stem Auger 2 49.0 43.0 28-43 47.13 36.36 10.77 MW-14D 35`38.39410 80.58.31292 HSA/Rock Core 2 60.0 60.0 55-60 62.85 38.98 25.87 ft bgs=feet below ground surface Prepared by/Dale: ep Checked bylDate: g_ e_1G ■r �r �r �r �r r� �r �r rr rr r rr r� r �r rr r� r �r TABLE2 Summary of 9ug Test Results Marshall Steam StaHoa MACI'EC Engineering and Consulting,lna MACTEC Project Ne.6228.18-5284 Rising Head Test Results h rsdsec Well Diameter Borehole Depth Well Depth Screw Interval Well Depth Depth to Wear Water Cduma TOP of Seraan Avenge K Sell Test ID Test Type Test Date (1 D.In.) (ft bp) (ft bp) (ft bp) (ft below TOC) (ft below TOC) Thickness(ft) (ft below TOC) Bomwe& gaot Hvonlw em/set MW-10S Rising Head 8/16!1010 2 35.0 27.0 12 -27 29.44 16.64 12.80 14.44 7.491:04 9.22E-04 1.36E-03 I.OIE-03 MW-IOD Rising Head 8/162010 2 85.4 85.4 80.4 -85.4 87.69 - 16.23 71.46 _82.69 1.13E-04.... - 1.19E-04 1.16E-04 MW-IIS Rising Head 811620)0 2 55.0 52.0 37 -52 54.38 43.77 10.61 39.38 1.54E-03 1.29E-03 2.05E-03 1.62E-03 MW-IID Rising Head 8/162010 2 90.5 90.5 85.5 -90.5 93.32 43.40 49.92 88.32 343E-05 345E-05 3.44E-05 MW-12S Rising Head 8/162010 2 40.0 22.0 7 -22 25.32 14.28 11.04 10.32 1.56E-03 1.79E-03 1,45E.03 1.60E-03 MW-12D Rising Heed 8/162010 2 100.4 95.0 90 -95 96.59 1521 83.38 93.59 1 3411.04 1 130E-04 I 1,32E-04 MW-13S Rising Heed 8/16/2010 2 25.5 18.0 3 - 18 21.12 5.70 15.42 6.12 2.40E-04 - 2.73E-04 2.56E-04 MW-13D Rising Head 8/162010 2 48.5 46.5 41.5 -46.5 48.61 3.59 45.02 43.61 792E-04 - 7.05E-04 7.48E-04 MW-14S Rising Head 8/162010 2 49.0 43.0 28-43 47.13 36.36 10.77 32.13 957E-04 8.91E-04 I.OIE-03 9.52E-04 MW-14D Rising Head 8/16/2010 2 60.0 60.0 55 -80 62.85 36.98 25.87 57.85 602F-04 648E-04 6.25E-04 Notes: 1-Dapn method applicable to wells screened across the water table 2-Barka-Black is a fracWrd rock nMhod and was not used on saprolite wells. ft bgs-few below ground surface TOC-Top of casing 14epued by: CHB Date: 824/10 Checked by:-CP Date.S-?.q-)O i Ash Basin Monitoring Well Installation Report August 26,2010 Marshall Steam Station Terrell,Catawba County,North Carolina MACTEC Project 6228-10-5284 1 1 APPENDICES 1 i 1 1 1 Ash Basin Monitoring Well Installation Report August 26,2010 Marshall Steam Station Terrell,Catawba County,North Carolina MACTEC Project 6228-10-5284 IAPPENDIX A ROCK CORE PHOTOGRAPHS 1 1 urr r m} ► r r�rrru t �ut�!''��ii--'� nrr i■n ■► n■ ■ ■nrm ■u►► ................. ...... • • Well t t` i ► ► - i 1 r Rv! Stna r -K r y_ _ y Photo 3: MW-IOD,Core Run#2(75.2—80.4 n.) 1 1 r Photo 4: MW-IOD,Entire Core including Core Run#3 (80.4—85.4 ft.) 1 1 tr . t 1 1 Photo 5: MW-14D,Core Run#1 (50.0—51.3 ft.) . t f 4 Q� Photo 6: MW-14D,Core Run#2(51.3—56.2 ft.) 1 M fra� ta- T`, Photo 7: MW-14D,Core and Run#3 (56.2—60.1 ft.) 14 Qu��t 1�D �w• i .N illl i--A ' Photo 8: MW-11D,Core Run#1 (80.5—80.8 ft.) 1 Photo • 1 Core r, - - - Photo •i . w 9 �nna////u l0/ ■10//11 h//q/Uiuun.N.o.n//N//N///p///p////pU//K///M iou.•o■■ .uN /t/ ■■Nt /MYt s i % K� �,t►.,+p� � , ,fir��s��, • � t s,r{�'/ Photo I Top / Core (94.0 96.2 1 (96.2 uv/R • //NNO/q//////URo....=u...na//q tlliL -.� ��.e 1"f% `.,► .` '• �' �e��":1, d.,�r�,,.,fes� ?..�,�`li Photo 1 Bottom 1 Core ' (94.0 96.2 1 '1 1 r ��r�rS-TiTiIZ1.n7SIi71_�7�7�JVlT�J'�7S7�Z�_'1n n -1' i Awa 4 - L L, Photo 15: MW-12D,Entire Core 1/!/!!/!!!■!!/�/�/!1!/rili/ LFwr■rrarrrrrvr■��f/! ■//11!1!1!///!/iliiililL011� rr Photo 16: MW-13D,Core Run#1 ® 4 � nm■■sllsullrrrnnmml��alr■••,•....,..--•■nnu■rrlrn■■■�■■■■r■ (36.0-40.2 z � OJ L fpl5•Yv■■�o■uu■A/U! !!!U!!UO!!p/ ■�Mu■o//li!!!!!W!!W!! �V�IWI Res................■//////•////U!■■////! 1/Yft//1.........,........most■■u■u• mass.......uu.■ I FA 3v kl,,VA I RME'A Ell-119M � ..y. +�...-+ts--�•�--Www-..�-..a-_ � ,�,,��' •/r. syr�'y :,F''' 1 1 1 WWII Photo 19: MW-131),Bottom of Core Run#2(40.2—45.1 ft.) y pS\'• - ,yam, .,. 1 d � ' Photo 20: MW-131),Entire Core including Run#1 (36.0—40.2 ft.), Run#2(40.2—45.1 ft.)and Run#3(45.1 —46.4 ft.) ' Ash Barin Monitoring Well Installation Report August 26,2010 Marshall Steam Station Terrell, Catawba County,North Carolina MACTEC Project 6228-10-5284 i 1 1 1 APPENDIX B SOIL BORING LOGS i i 1 i 1 1 D L E SAMPLES 1 P SOIL CLASSIFICATION 1 D I N c OUN T E v Y H SEE KEN'SYMBOL SHEET FOR EXPLANATION OF N E P c T (�) SYMBOLS AND ABBREVIAFIONS BELOW'. D (11) E l " N ` REMARKS Red to orange clayey silt(MI.);dry. i 5 Clay contcnt increase at 6' 10 1 ---------------------- Tan clay(CH);High mica content ' IS Moist at 15' 20 25 30 35 Boring terminated at 35.0'BGS v, a 40 v z it ' o m h 45 ' DRILLER: Abel McGuire-AE Drillutg SOIL TEST BORING RECORD EQUIPMEN'I: CME-750 METHOD: HSA HOLE DIA.: PROJECT: Duke Energy Marshall Steam Station REMARKS: 42W- o-to V1'ELL ID: Mw-los July 26,2010 THIS RECORD IS A REASONABLE INTERPRETATION PROD.NO.: 6228-10-5284 PAGE 1 OF I OF SUBSURFACE CONDITIONS AT THE EXPLORATION LOCATION. SUBSURFACE CONDI'T'IONS AT OTHER M A ^TT LOCATIONS AND AT OTHER TIMES MAY DIFFER. '�` 1 1/�1Iv 11 .HL INTERFACES BEWEE-N STRATA ARE APPROXIMATE. ' TRANSITIONS BETWEEN STRATA MAY BE GRADUAL. DL E SAMPLES 1 E E P SOIL CLASSIFICATION L L 1 T N-COUNT T E V 0 Y 1, E SEE KEY SYMBOL SHEET FOR EXPLANATION OF N P N 00 T SYMBOLS AND ABBREVIATIONS BELOW. D (ft) E 7. -E r REMARKS O Red to tan(15YR 518)silt),fine sand(SM) SS 3 Strong brown(7.5YR 4/6)silty fine sand(SM) Micaceous 10 SS-2 2-4-4 Quartz mineral banding .j Strong brown 17.5YR 4/6)silty clay(CL) SS-3 3-2-1- Micaceous;Mafic mineral handing 15 (14'-15') Pale brown(I OYR 6/31 silty fine sand(SM) SS-4 2-34 Micaceous;Coarse quartz sand(191-20') -0 Flowing sand(22'-23') Gravisb brown(I OYR 502)silty fine sand(SM) Quartz banding with trace Fe stained 25 SS-5 2-24 gravel SS-6 X 1-2-3 30 Vertical quartz hand with Fe staining from 29.5'-30.0' SS-7 2-'_-4 35 o Yellow(I OYR 7/6)clayey sand(SC) SS-8 X 24-6 40 Coarse quartz sand(39.5'40.0')-possible top of PIWR ' m 45 SS-9 1-34 DRILLER: Abel McGuire-AE Drilling SOIL TEST BORING RECORD EQUIPMENT: CME-750 METHOD: HSA/NQ Rock Core HOLE DIA-; PROJECT: Duke Energy Marshall Steam Station REMARKS: t0 5.7 to WELL ID: MW-10D July 27,2010 THIS RECORD IS A REASONABLE INTERPRETATION PROJ.NO.: 6228-10-5284 PAGE I OF 2) OF SUBSURFACE CONDITIONS AT THE EXPLORATION LOCATION. SUBSURFACE CONDITIONS AT OTHER LOCATIONS AND AT OTHER TIMES MAY DIFFER. OMACTECINTERFACES BEWEEN STRATA ARE APPROXIMATE. TRANSITIONS BETWEEN STRATA MAY BE GRADUAL. I D L F SAMPLES ' L P SOIL CLASSIFICATION G E l 1 N-COUNT T E `. £ y H SEE KEY SYMBOL SHEE'l FOR EXPLANATION OF N N P `c (til SYMBOLS.AND ABBREVIATIONS BELOW. D (ft) 3 E = REMARKS 4 Yellow(I OYR 7/6)clays y sand(SC) Subvemcal quartz banding and Fe staining SS-10 1-3-3 throughout 50 Brownish yellow(1 OYR 61)clayey sand(S(') Coarse quartz sand and abundant Fe SS-11 X 3-5-7 staining 55 Very dark grayish brown(2.5Y 3'2)PWR Biotite layering(60');Fe staining 60 \/// SS-12 7-1419 Yellow(I OYR 7!8)PWR SS-13 10-'_2-27� Quartz,biotite,k-feldspar 65 Browmish yellowy(I OYR 6/8)clayey sand(SC) SS-14 5-10-17 70 1 Olive yellow(2.4Y 6/6)PWR Quartz,mica,trace Fe staining SS-15 50/2 7S Biotite Gneiss;strong,light gray(1 OYR 7/1)oxidized, RC-16 RQD:0°.b Refusal at 75.0' gneissic,laminated,slightly decomposed slightly RC-17 RQD:24% disintegrated unfractured.conformable Fracture zone(76.4'-76.5') ' Shear zones(76.8',77.15') Brief H2O loss(79.0'-79.6) 80 ' Biotite Gneiss;very weak.dark reddishbrown(5YR 3/4). gneissic,laminated,moderately disintegrated,moderately to RC-18 RQD:28% Hard drilling(80.9') intensely fractured;80.9'-hard drilling n ii 1 v 85 _ Boring terminated at 85.5'BGS c z ' 90 DRILLER: Abet McGuire-AE Drilling SOIL TEST BORING RECORD EQUIPMENT: CME-750 METHOD: HSA/NQ Rock Core HOLE DLA.: PROJECT: Duke Energy Marshall Steam Station ' REMARKS: ng��Ilo WELL ID: MW-10D July 27,2010 THIS RECORD IS A REASONABLE INTERPRETATION 1YROJ.NO.: 6228-10-5294 PAGE 2 OF 2 OF SUBSURFACE CONDITIONS AT THE EXPLORATIONLOCATION. SUUFACE OMArTEC DIONS AT OTHER I/ LOCATIONS ANDAT THEROTIMESMAY DIFFR. INTERFACES BEWEEN STRATA ARE APPROXIMATE. TRANSITIONS BETWEEN STRATA MAYBE GRADUAL. L E SAMPLES E T CO L G P D SOIL CLASSIFICATION E N-COUNT F T E v E Y H SEE KEY SYMBOL SHEET FOR EXPLANATION OF N P t, SSYMBOLSANDAN BBREVIATIONS BELOW. D (11) F -2 T REMARKS U Red (2.5YR 518)clayey silt(ML) Dr) Yellow(2.518 8/6)to light yellowish brown(2.5Y6/3)silty EID, fine sand(SM) 10 IS 20 25 30 35 i h 40 Yellow(10YR 5/8)to light gray(10YR 7/2)clayey fine sand . . .. Increasing mica content (SW) Moist at 45'BGW 45 . . . . DRR.LER: Abel McGuire-AE Drilling SOIL TEST BORING RECORD EQUIPMENT: CME-750 F METHOD: HSA HOLE DIA-: PROJECT: Duke Energy Marshall Steam Station 1 REMARKS: pW g+"/Io WELL ID: MW-11S July 30,2010 THIS RECORD IS A REASONABLE INTERPRETATION PROJ. NO.: 6228-10-5284 PAGE LPF 2) OF SUBSURFACE CONDITIONS AT THE EXPLORATION LOCATION. SUBSURFACE CONDITIONS AT OTHER MACTEC LOCATIONS AND AT OTHER TIMES MAY DIFFER. W INTERFACES BEWEEN STRATA ARE APPROXI-MATE. TRANSITIONS BETWEEN STRATA MAYBE GRADUAL. D L E SAMPLES ' P SOIL CLASSIFICATION E L l T N-COUNT T E `, D H SEE KEY SYMBOL SHEET FOR EXPLANATION OF N N P c o Ic �� SYMBOLS AND ABBREVIATIONS BELO%k'. D (it) T E REMARKS Yellou(10YR 5/8)to light gray(10YR 7!7)clayn fine sand (SW) 50 55 Boring terminated at 55.0'BGS 60 ' 65 70 75 80 N a v 85 c � z c 90 r DRILLER: Abel MoCjuirc-AE Drilling SOIL,TEST BORING RECORD ' FQl11PMFNT: CML 750 METHOD: HSA HOLE DIA.: �C PROJECT: Duke Energy Marshall Steam Station REMARKS: Ao FI-01(c WELL ID: MW-11S July 30,2010 ' THIS RECORD IS A REASONABLE INTERPRETATION PROJ.NO.: 6228-10-5284 PAGE 2 OF 2 OF SUBSURFACE CONDITIONS AT THE EXPLORATION LOCATION. SUBSURFACE CONDITIONS AT OTHER MACTEC LOCATIONS AND AT OTHER TIMES MAY DIFFER. .+` INTERFACES BEWEEN STRATA ARE APPROXIMATE. 1 TRANSITIONS BETWEEN STRATA MAY BE GRADUAL. D L E SAMPLES ' E P SOLI.CLASSIFICATION L E 1 T N-COUNT T E V E y H SEE KEY SYMBOL SHEET FOR EXPLANATION OF N N P `c ((I) SYMBOLS AND ABBREVLATIONS BELOW. D (ti) T F v. M IZE(VLkI S 0 Red(2.51'R 5'8)clayey silt(ML) ',nine mica;dry 1 ' SS-1 5-8-11 5 Yellow(2.5YR 8i6)fine sand(SW) Dry,thinly laminated with quartz and Fe SS-2 2-3-3 stained bands 10 Light yellowish brown(2.5N'6/3)silty fine sand(SAI) Micaceous SS-3 X 2-3=3 IS 20 SS-1 2-24 Some gravel sized white clay(19.5'-20.0') Increasing secondary mineralization(white SS-5 3-3-5 clav) 25 I 30 SS 6 3-3-5 L Increasing Fe staining SS-7 X 3-313 35 .10o i� Yellow(IOYR V8)clayey fine sand(SC) Micaceous v SS-8 X 4-54 40 Moist at 40.0' U z o O SS-9 3-34 w 45 ' DRILLER: Abel McGuire-AE Drilling SOIL TEST BORING RECORD EQUIPMENT CME-750 METHOD: HSA'NQ Rock(bre ROLE DIA: PROJECT: Duke Energy Marshall Steam Station ' REMARKS: O g/f �(Zdjjb WELL ID: MW-11D VV�� II July 29, 2010 THIS RECORD IS A REASONABLE INTERPRETATION PROJ.NO.: 6228-10-5284 PAGE 1 OF 3 OF SUBSURFACE CONDITIONS AT'THE EXPLORATION LOCATION. SUBSURFACE CONDITIONS AT OTHER � MACTEC LOCATIONS AND AT OTHER TIMES MAY DIFFER. INTERFACES BEWEEN STRATA ARE.APPROXIMATE. TRANSITIONS BETWEEN STRATA MAY BE GRADUAL. D I L SAMPLES ' E SOIL CLASSIFICATION c � I f N couNT P T F `, D Y. H SEE KEY SYMBOL SHEET FOR EXPLANATION OF N N P o (ft) SYMBOLS AND ABBREVIATIONS BELOW. D (ft) T E = N M REMARKS 45 YelIoH(10)'R 7/8)clayey fine sand(SC) ' Gray(7.5)R 511)clayey medium to fine sand(SC)with Water dripping from spoon quartz gravel SS-10 X 3-5-5 50 ' Light gray(I ON'R V2)fine sand(SW),thinly laminated Some Fe staining SS-II 12-21-37 55 ' 60 SS 12 37-50-4 SS-13 50i4 ' 65 SS-14 503 70 Light gray(10Y 7/1);PWR;foliated 75 SS-15 X 4649-50/4 1 .. SS-16 5013 80 Quartz Schist;weak,bluish black(Gley2 2.5/IOB),schistose, RC-17 RQD:0% Refusal at 80.5'BGS ' laminated,moderatcly decomposed,slightly disintegrated, o Hard drilling from 80.8'-84.3';easier to c RC-18 RQD:O o moderately fractured 85.8' N Bedding plane fractures every 0.1-0.2 co inches from 81.2'-81.9' ' V v 85 V RC'-19 R D:34*6 Bedding plane fractures%ith Fe staining at z Strong,black(Gley)2."),gnessic,thinly bedded slightly Q 85.9',87.5'and 89.T x Fracture zones at 86.1'-86.5',86.9'-87.I' decomposed,slightly disintegrated,moderately fractured and 88.0'-88.2' ' Near horizontal joints at 86.4',86.7.86.91, 87.6',884,89.2'and 89.3' ' DRILLER: Abel McGuire-AE Drilling SOIL TEST BORING RECORD i F,QIIIPNIENT: CME-750 METHOD: HSA,/NQ Rock Core HOLE DIA.. ,tu PROJECT: Duke Energy Marshall Steam Station L ' REMARKS: lD(� 8 ' WELL ID: MW-11D July 29,2010 ' THIS RECORD IS A REASONABLE INTERPRETATION 11PROJ.NO.: 6228-10-5284 PAGE 29F 3 OF SUBSURFACE CONDITIONS AT THE EXPLORATION LOCATION. SUBSURFACE CONDITIONS AT OTHER MACTEC LOCATIONS AND AT OTHER TIMES MAY DIFFER. INTERFACES BEWEEN STRATA.ARE APPROXIMATE. ' TRANSITIONS BETWEEN STRATA MAY BE GRADUAL. D L E SAMPLES 1 E P SOIL CLASSIFICATION E E I T N-COUNT T E `, D Y }I SEE KEY SYMBOL SHEET FOR EXPLANATION OF N P o III) SYMBOLS AND ABBREVIATIONS BELOW. D (Il) T F. = c ? REMARKS ' 90 Boring terminated at 90.6'BOS ' 95 100 ' 105 ' 110 1 I15 ' 120 125 o C a J 130 U z a L 135 ' DRILLER: Abel McGuire-AF:Drilling SOIL TEST BORING RECORD EQUIPMENT: CME-750 METHOD: HSA,/NQ Rock Core HOLE DIA.: PROJECT: Duke Energy Marshall Steam Station REMARKS: go gl'"Ito WELL ID: MW-11D July 29,2010 ' THIS RECORD IS A REASONABLE INTERPRETATION PROJ.NO.: 6228-10-5284 PAGE 3 OF 3 OF SUBSURFACE CONDITIONS AT THE EXPLORATION LOCATION. SUBSURFACE CONDITIONSOTHER MACTEC LOCATIONS AND AT OTHER TIMES MAI''DIFFER. - � INTERFACES BEWEEN STRATA ARE APPROXIMATE. TRANSITIONS BETWEEN STRATA MAYBE GRADUAL. D 1. E SAMPLES ' E P SOIL CLASSIFICATION E e I t N-COUNT 3E %, D Y. H SEE KEY SYMBOL SHEET FOR EXPLANATION OF N P c c T (�) SYMBOLS AND ABBREVIATIONS BELOW. D (ft) E REMARKS Light red(2.5YR 6?6)clayey silt(ML) Dry 1 5 Yellow(I OYR 7/8)clay silt(ML) Dry-,trace gravel 10 15 1 _D 1 25 Water on augers at 26' Yellowish brown(10YR 5r(i)silty clay(CL) Moist 1 30 35 h N e'o Wet at 38' . 40 Boring terminated at 40.D'BGS v z c 45 DRILLER: Abel McGuire-AE Drilling SOIL TEST BORING RECORD EQUIPMFNT: CME-750 METHOD: HSA HOLE DIA.: PROJECT: Duke Energy Marshall Steam Station REMARKS: gptu Ito WELL ID: MW-12S August 3,2010 ' THIS RECORD IS A REASONABLE INTERPRETATION PROD.NO.: 6228-10-5284 PAGE 1 OF 1 OF SUBSURFACE CONDITIONS AT THE EXPLORATION LOCATION. SUBSURFACE CONDITIONS AT OTRER41 MATT^ LOCATIONS AND AT OTHER TIMES MAY DIFFER. � (lJ .1L([lJ INTERFACES BFWEEN STRATA,ARE APPROXIMATE. TRANSITIONS BETWEEN STRATA MAY BE GRADUAL. D 1 F SAMPLES ' LE CLASSIFICATION E I T N c'o() P NT I E N' E Y H SEE FEY SYMBOL SHEF,'l FOR EXPLANATION OF N N P o (ti) SYMBOLS.AND ABBREVLATIUNS BELOW'. 1) 1'N) I E � c � REMARKS 0 Light red(2.5YR 6/6)clayey silt(ML) Dry,layered.hard ' S SS-1 X 3-6-15 SS-2 5-8-1' IU fellow(10YR 7!8)clayey silt(ML) Dry,mottled ' IS SS-3 5-6-11 Some Fc staining 20 SS4 9-23-50'5 Soft at 22.0' SS-5 12-I8-1 S `S Coarse sand to gravel-sized k-feldspar ' (24.5'-24.6') ' Light gray(I OYR 71)silty clay.(CL) 30 SS-6 ?-6-8 Coarse sand to gravel(29.5'-29.6) Wet at 32.0' Yellow(10YR 7/8)clayey silt(ML) SS-7 10-7-9 35 White clay(k-feldspar)band(35.0') o — 37.0'-40.0'6g bouncing c c; SS-8 —3-8 40 0 z it Variagated white(I OYR 8!1)to vellow(I OYR 7/8)partial IN Abundant Fe staining o weathered granite SS-9 4-7-I8 45 ' DRILLER: Abel McGuire-AE Drilling SOIL TEST BORING RECORD EQUIPMENT: CME-150 METHOD: HSA/NQ Rock Core HOLE DIA.: PROJECT: Duke Energy Marshall Steam Station ' REMARKS: g(/�-� 51zkJ10 WELL ID: MW-12D August 3,2010 ' THIS RECORD IS A REASONABLE INTERPRETATION NIPROJ. NO.: 6228-10-5284 PAGE 1 OF 3 11 OF SUBSURFACE CONDITIONS AT THE EXPLORATION LOCATION. SUBSURFACE CONDITIONS AT OTHER /MACTEC LOCATIONS AND AT 0-1-HER TIMES MAY DIFFER. ,rd ' INTERFACES BEWEEN STRATA ARE APPROXIMATE. ' TRANSITIONS BETWEEN STRATA MAYBE GRADUAL. D 1 E SAMPLES ' E P SOIL CLASSIFICATION G E I T N-COUNT T F V D Y H SEE KEY SYMBOL SHFFT FOR EXPLANATION OF N P c ° (H) SYMBOLS AND ABBREVIATIONS BELOW. D U)) T E v N REMARKS 4 Variagated white(IOYR 811)to yellow(IOYR 7/8)partially — ' weathered granite ' Yelloe(IOYR 8/6)rn(A urn sand(SW) 50 SS-10 25-50/4 ' Variagated white(IOYR 8,,l)to yellow(IOYR 7/8)partially Abundant Fe staining 55 weathered granite SS-11 X 13-2-1-25 Rig bouncing at 56.0' ' 60 SS-12 6-7-13 Fe-stained zone(59.3-59.7') ' Abundant Fe staining 65 SS-13 5-10-13 SS-14 20-32-35 7(1 ' Dark greenish gray(Gley)4/59)foliated chlorite I'WR SS-15 30-5014 75 ' Dusky red(I OR 3/2)PWR 80 SS-16 14-50.-4 ' o N Variagated while(I OYR 8/1)to yellow(IOYR 7/8)partially ' q weathered granite SS-17 50/3 N 85 V z r ' 90 SS-18 50/4 ' DRILLER: Abel McGuire-AE Drilling SOIL TEST BORING RECORD EQUIPMENT CNIE-750 METHOD: HS.A/NQ Rack Core HOLL DIA.: ^ g(�I(Q PROJECT: Duke Energy Marshall Steam Station ' REMARKS: �( NVELL ID: MW-12D August 3,2010 ' THIS RECORD IS A REASONABLE INTERPRETATION PROD.NO.: 6228-10-5284 PAGE 2 OF 3 OF SUBSURFACE CONDITIONS AT THE EXPLORATION' LOCATION. SUBSURFACE CONDITIONS AT OTHER MACTEC LOCATIONS AND AT OTHER TIMES MAY DIFFER. OAA' INTERFACES BEWEEN STRATA ARE APPROXIMATE. ' TRANSITIONS BETWEEN STRATA MAY BE GRADUAL. 1 D L E SAMPLES ' F P SOIL CLASSIFICATION E E 1 T N-COUNT r E Y, D Y H SEE KEY SYMBOL SHEET FOR EXPLANATION OF N P 'o ° 90) SYMBOLS AND ABBREVIATIONS BELOW. D (11) T E c T } MAI S �JO Variagated white(I OYR 81)to yellow(I OY'R 7i8)partially jr weathered granite ' Granite,strong,dark gray(Gley!4/N)phaneritic,massive, SS-19 50/21 Refusal at 94.0'BGS 95 slightly foliated,slightly decomposed(94.0'-95.6')to fresh RC-20 RQD:59% (95.6'to 96.2'),competent,slightly fractured Bedding plane fracture with Fe staining RC-21 RQD:7710 100 ' RC-'_2 RQD:69% Foliated Granite:weak,dark gray(Gley)4,'N).Gneissic. foliated,moderately decomposed,disintegrated,unfractures Chlorite Mica Shisr strong,very dark gray(Gleyi 31N), 1 105 shistose,laminated,fresh,competent,unfractured Boring terminated at 106.4'BGS ' 110 i 1 115 120 t 125 1 c ao c 1 U 130 V 7 d 1 R 135 DRILLER: Abel McGuire-AE Drilling SOIL TEST BORING RECORD EQUIPMENT: CME-750 METHOD: HSA/NQ Rock Core HOLE DIA.: PROJECT: Duke Energy Marshall Steam Station REMARKS: 1`/Ac $(toll, WELL ID: MW-12D August 3,2010 ' THIS RECORD IS A REASONABLE INTERPRETATION PROJ.NO.: 6228-10-5284 PAGE 3 OF_3, OF SUBSURFACE CONDITIONS AT THE EXPLORATION LOCATION. SUBSURFACE CONDITIONS AT OTHER �� MACTEC LOCATIONS AND AT OTHER TIMES MAY DIFFER. INTERFACES BEWEEN STRATA ARE APPROXIMATE. TRANSITIONS BETWEEN STRATA MAY BE GRADUAL. D L F SAMPLES E P SOIL CLASSIFICATION E e I� . N-COUNT T E V F �. H SEE KEY SYMBOL S11EL-T FOR EXPLANATION OF N P ° `o (fl) SYMBOLS AND ABBREVIATIONS BELOW. D (tl) REMARItS ' 0 Red(2.5YR 5!8)silt(ML) Dry S Brownish yellow(I OYR 6/6)silty clay(CL) Dry Very pale brown(10YR 713)tnediwn sand(SP)with gravel Moist 10 Light olive brown(2.5)'5/3)clayey sand(SC) Dry i 15 i 20 1 25 ' -,Light olive brown(2.5Y 5/3)sande clay(CL) Boring terminated at 25.5'BGS Wet Oou ing ' 30 35 c 40 :7 _Z C J45 ' DRILLER: Abel McGuire-AE Drilling SOIL TEST BORING RECORD EQUIPMENT: CMF-750 METHOD: HSA HOLE DIA.: PROJECT: Duke Energy Marshall Steam Station REMARKS: R(�S(Zolfo WELL ID: MW-13S August 6,2010 THIS RECORD IS A REASONABLE INTERPRETATION 11PROJ.NO.: 6229-10-5284 PAGE 1 OF 1 OF SUBSURFACE CONDITIONS AT THE EXPLORATION SUBSURFACE O LOCATIONS ANDATTOIHERTIM SIOTHER MAY DIFFER. ONS AT , t/,'M ArTEC INTERFACES BEWEEN STRATA ARE APPROXIMATE. ' TRANSITIONS BETWEEN STRATA MAYBE GRADUAL. D L E SAMPLES 1 E P SOIL CLASSIFICATION E � I r N Co(1NT I `, D F y. H SEE KF)'SYMBOL SHEET FOR EXPLANATION OF N N P tfl) SYMBOLS AND ABBREVIATIONS BELOW. D 01) T E = REMARKS 0 Yellowish red(5YR 518)sandy silt(ML) Dry SS-I _-6-8 5 Very pale brown(105'R 73)medium sand(SP);some gravel Moist to wet (quartz) SS-22 X -4-15 10 Light olive brown(2.5Y 5.3)clayey sand(SC):laminated- possible saprolitic soil SS-3 3-4-5 15 ' Spoon impecded by quartz gravel(approx- 2 0 SS4 6-2---32 4 cm);wet 1 Light brownish grey(2.5Y 6/2)PWR;quartz;mica SS-5 50;4 Hard at 24.0' 25 Flowing sand 27.0'-28.0' Light olive brown(2.5Y 513)clayey sand(SC);laminated 30 SS-6 12-11-15 Quartz banding(29.2') Water in hole Some Fe staining SS-7 50/4 35 ' o Grande:very strong,light grey(10)'R 72)aphanitic,intensely Refusal at 36.0'BGS Foliated,slighth decom unfractured RC-8 RQD:20°roo Biotite Gneiss:weak,greenish black(Gley)25'5GY), shislose,laminated,highly decomposed,intensely ^a disintegrated intensely fractured ' v 40 o RC-9 RQD:13% z it 45 DRILLER: Abel McGuire-AE Drilling SOIL TEST BORING RECORD EQUIPMENT: CME-750 METHOD: HSAlNQ Rock Core HOLE DIA.: PROJECT: Duke Energy Marshall Steam Station REMARKS: $�lP�10 WELL ID: MW-13D August 4,2010 THIS RECORD IS A REASONABLE INTERPRETATION PROJ. NO.: 6228-10-5254 PAGE 1 OF 2 OF SUBSURFACE CONDITIONS AT THE EXPLORATION LOCATION. SUBSURFACE CONDITIONS AT OTHER WMACTEC LOCATIONS AND AT OTHER TIMES MAY DIFFER. INTERFACES BEWEEN STRATA ARE APPROXIMATE. TRANSITIONS BETWEEN STRATA MAY BE GRADUAL. D I F SAMPLES E P SOIL CLASSIFICATION E E I T N-COUNT T E v D Y H SEE KEY SYMBOL SHEET FOR EXPLANATION OF N N P c a (ft) SYMBOLS AND ABBREVIATIONS BELOW. D (ft) T E H '2 IZEMAIZI{S 4 RC-I RQD:0% Borine terminated at 46.6'BGS 50 55 601 65 70 1 i5 80 a ' V 85 J J z s ' 90 ' DRILLER: Abel McGuire-AE Drilling SOIL TEST BORING RECORD EQUIPMENT: CME 750 METHOD: HSARJQ Rack Core HOLE DIA.: PROJECT: Duke Energy Marshall Steam Station REMARKS: n, $Iw�lp N ELL ID: MW-13D August 4,2010 ' THIS RECORD 1S A REASONABLE INTERPRETATION 11PROJ. NO.: 6228-10-5294 PAGE 2 OF 2 OF SUBSURFACE CONDITIONS AT THE EXPLORATION LOCATION. SUBSURFACE CONDITIONS AT OTHER MACTEC LOCATIONS AND AT OTHER TIMES MAY DIFFER. INTERFACES BEW'EEN STRATA ARE APPROXIMATE. TRANSITIONS BETWEEN STRATA MAYBE GRADUAL. r D L F SAMPLES E P SOU.CLASSIFICATION E � I T N-COUNT T F \' Y H SEE KEY SYMBOL SHEET'FOR EXPLANATION OF N P c 7 (R) SYMBOLS AND ABBREVIATIONS BELOW. D (11) T E = I ,. REMARKS r0 Red(2.5YR 5/8)silty sand(SM) Dry 5 Light brownish yellow(1 OYR 6/4)silty sand(SM) Dn:micaceous r 10 r ' IS r _0 r 25 30 rTrace clay at 33.0' 35 o h Some gravel at 37.0' n a ' U 40 U ' C RL 45 W. ' DRILLER: Abel McGuire-AF Drilling SOIL TEST BORING RECORD EQUIPMENT: CME-750 METHOD: HSA HOLE DIA.: PROJECT: Duke Energy Marshall Steam Station REMARKS: n Uf Q (Io NVELL ID: MW-14S 1�`" (J I July 30,2010 1 THIS RECORD IS A REASONABLE INTERPRETATION PROJ.NO.: 6228-10-5284 PAGE 1 OF 2 OF SUBSURFACE CONDITIONS AT THE EXPLORATION LOCATION. SUBSURFACE CONDITIONS AT OTHER LOCATIONS AND AT OTHER TIMES MAY DIFFER. O'MAcTEC INTERFACES BEWEEN STRATA ARE APPROXIMATE. TRANSITIONS BETWEEN STRATA MAY BE GRADUAL. DL E SAMPLES 1 F P SOIL CLASSIFICATION E L l T N-COUNT 1 D SEE KFY SYMBOL SHEET FOR EXPLANATION OF N P c 10 SYMBOLS AND ABBREVIATIONS BELOW. D (Il) N E & c 7 REMARKS ;� Light brownish yellow(I0YR 64)silty sand(SM) 1 Boring terminated at 49.0'BGS 50 55 60 65 1 ' 70 15 1 BO o a V 85 z ' 90 ' DRILLER: Abel McGuire-AE Drilling SOIL TEST BORING RECORD EQUIPMENT: CME-750 METHOD: HSA HOLE DIA: PROJECT: Duke Energy Marshall Steam Station ' REMARKS: it$11,0((0 "'ELL ID: MW-14S July 30,2010 ' THIS RECORD IS A REASONABLE INTERPRETATION PROD. NO.: 6228-10-5284 PAGE 2 OF 2 OF SUBSURFACE CONDITIONS AT THE EXPLORATION LOCATION. SUBSURFACE CONDITIONS AT OTHER 16 'M AcTEC LOCATIONS AND AT OTHER TIMES MAY DIFFER. > INTERFACES BEWEEN STRATA ARE APPROXIMATE-. TRANSITIONS BETWEEN STRATA MAY BE GRADUAL. DL E SAMPLES 1 EG L P SOIL CLASSIFICATION E L N-COUNT D T T E V Y 11 E SEE KFYI;YMBOL SHEET FOR EXPLANATION OF N N 10 14 — 01) SYMBOLS AND ABBREVIATIONS BELOW. D (fl) T F 5. REMARKS 0 Red(2.5YR 51)silly sand(SM) Dry SS-1 4-5-6 Light brownish yellow(I OYR 64)silly sand(SM) :7 4. Micaceous,dry SS-2 x 2-34 10 A. Trace coarse-grained quartz banding and SS--, 244 Fc-staining;dry 15 SS-4 4-5-620 SS-5 X 6-11-12 25 Quartz and maric min banding from 30 SS-6 x 9-16-20 29.8'-30.0' w' SS-7 11-1-0-27 35 Coarse-grained to gravel sized quartz and mafic banding(34.5'-35.0') 2- Light yellowish brown(2.51'614)sand with quartz gravel(SP) SS-8 11-26-36 vi 40 0- Gray(Gley) 5/N)granite rock(RK) Fe-stained,weathered SS-9 5014 45 DRILLER: Abel McGuire-AE Drilling SOIL TEST BORING RECO" EQUIPMENT: CME-750 F METHOD: HSANQ Rock Core 11 HOLE DIA-: PROJECT: Duke Energy Marshall Steam Station 1 "MAR": R(,r,g(olle WELL ID: MW-14D July 28,2010 THIS RECORD IS A REASONABLE INTERPRETATION LPROJ.NO.: 6229-10-5284 PAGE I OF 2 OF SUBSURFACE CONDITIONS AT THE EXPLORATION LOCATION. SUBSURFACE CONDITIONS AT OTHER x . LOCATIONS AND AT OTHER TIMES MAY DIFFER. OMArTEC INTERFACES BEWEEN STRATA ARE APPROXIMATE. TRANSITIONS BETWEEN STRATA MAY BE GRADUAL. D L E SAMPLES 1 L P SOIL CLASSIFICATION E 1. 1 N-COLIN'1 T E `, F �. H SEE KE'SYMBOL SHEER FOR EXPLANATION OF N N P o (H) SYMBOLS AND ABBREVIATIONS BELOW. D (ft) l E = REMARKS 4 Gray(Gley)5,N)granite rock(RK) +++:— +++ +++ Chlorite vein at 487 50 Biotite gneiss:bluish gray(Gley2 511),strong,gneissic, Refusal at 50.0'BGS laminated,slightly decomposed,slightly disintegrated. RC-I I Bedding plan joint at 50.25',50.45',50.91, moderately fractured 51.15'(45') R('-I'_ Shear at 50.35'with Fe-staining Fracture zone at 52.0'-52.4' Bedding plane foliation infilled with quartz Joints with Fe-staining at 52.8'-52.9' 55 Fe-stained joint at 53.6' Joint at 53.75' Granite,white(5YR 8./1)moderate strength,Fe-staining, R(-1', coarse grained,laminated,moderately decomposed, moderately dismtcgrwecL unfractured Healed bedding plane joint at 57.6'infilled White(5YR 8/I),weak,abundant Fe-staining,gneissic, with quartz intensely foliated,intensely disintegrated,intensely fractured Joint t�ith Fe-staining at 58.6' 60tJoint with Fe-staining at 58.6' Boring terminated at 60.1'BGS 1 65 1 70 75 80 1 r b V 85 0 z 0 90 ' DRILLER: Abel McGuire-AE Drilling SOIL TEST BORING RECORD EQUIPMENT: CME-750 METHOD: HSA/NQ Rock Core HOLE DLa: PROJECT: Duke Energy Marshall Steam Station 1 REMARKS: 9(/(- s(��to «'ELL ID: MW-14D July 28,2010 1 THIS RECORD IS A REASONABLE INTERPRETATION PROD.NO.: 6228-10-5284 PAGE 2 OF 2 OF SUBSURFACE CONDITIONS AT THE EXPLORATION LOCATION. SUBSURFACE CONDITIONS AT OTHER �J` , LOCATIONS AND AT OTHER TIMES MAY DIFFER. %, M��j 1 EC INTERFACES BEWEEN STRATA ARE APPROXIMATE. 11 ii 1��J TRANSITIONS BETWEEN STRATA MAY BE GRADUAL. 1 r Ash Basin Monitoring Well Installation Report August 26,2010 1 Marshall Steam Station Terrell,Catawba County,North Carolina MACTEC Project 6228-10-5284 t r 1 1 r r APPENDIX C MONITORING WELL RECORDS 1 1 r r r r r �( NONRESIDENTIAL ONRESIDENTIAL WELL CONSTRUCTION RECORD North Carolina Department of Environment and Natural Resources-Division of Water Quality °g,a;",,s• WELL CONTRACTOR CERTIFICATION N 3r7I 1.WELL CONTRAC R: C �d. TOP OF CASING IS 3 FT.Above Land Surface' G 'Top of casing terminated at/or below land surface may require Well Contractor(Individual)Name a variance in accordance with 15A NCAC 2C.0118. A E DRILLING E VI LLQ :e. YIELD(gpm): Allof- METHOD OF TEST—" Well Contractor Company Name :f. DISINFECTION:Type AYA Amount N/ T Two United Way Street Address :9. WATER ZONES(depth): Greenville SC 29607 Top Bottom Top Bottom City or Town State Zip Code Top Bottom Top Bottom 8( 64 ) 288-1986 :Top Bottom Top Bottom Area code Phone number Thickness/ 2.WELL INFORMATION: :7. CASING: Depth Diameter Weight Material WELL CONSTRUCTION PERMIT# Top O Bottom. to .Ft. Ola QVC- OTHER ASSOCIATED PERMIT#(if applicable) Top Bottom Ft. SITE WELL 10#(if applicable) :Top Bottom Ft. 3.WELL USE(Check One Box)Monitoring N Municipal/Public❑ :8. GROUT: Depth Material Method Industrial/Commercial❑ Agricultural❑ Recovery❑ Injection❑ Jop_01 Bottom_Ft. 1�'q&' TiAJ/t✓ Irrigation❑ Other❑ (list use) :Top 16 Bottom 9 Ft. 'q _ �� i L t DATE DRILLED 7-. Top Bottom Ft. 4.WELL LOCATION: :9. SCREEN: Depth Diameter Slot Size Material .10 wC" 1 �� ZR- ;Top /.V Bottom a�� Ft .2' in. In. (Street Name,Numbers.Community,Subdivision,Lot No.,Parcel,Zip Code) :TOp Bottom Ft. In. in. CITY: COUNTY Top Bottom Ft. In. In. ITOPOGRAPHIC/LAND SETTING: (check appropriate box,Slope ❑Valley C]Flat []Ridge ❑Other :10.SANDIGRAVEL PACK: LATITUDE 0 Depth Size Material ^DMS OR 3X.xxXXXXxxX DD :Top�_Bottom a7' Ft. L Sin LONGITUDE DMS OR 7X.XXXXXXXXX DD ;Top Bottom Ft. ' Latitude/longitude source: (SPS QTopographic map :Top Bottom Ft. (location of well must be shown on a USGS topo map andattached to this form it not using GPS) : 11.DRILLING LOG S.FACILITY(Name of the business where the well is located.) Top Bottom Formation Description ' Marsha �Qmfn S Pa11,on _Ql _ Stc x.ou-,L oyXt-Zt rltA Facility Name Facility ID#(if applicable) / gDo Calf Alr 8/ ht my 10 J Street Address "� / T�eg N.C_. af3�Fd l City or Ton ` State Zip Code J ' Contact Name / Mailing Address / City or Town State Zip Code 12.REMARKS: Area code Phone number 4 6.WELL DETAILS: I DO HEREBY CERTIFY THAT THIS WELL WAS CONSTRUCTED IN ACCORDANCE WITH 15A NCAC 2C,WELL CONSTRUCTION STANDARDS,AND THAT A COPY OF THIS a. TOTAL DEPTH:_ �9y :RECORD HA E PROVIDED TO THE WELL OWNER. b. DOES WELL REPLACE EXISTING WELL? YES❑ NO 094-/O SIGNATUTIE OF CERTIFIED LLVDIE CONTRACT DATE c. WATER LEVEL Below Top of Casing: ICP C0 FT. . ' (Use"+"if Above Top of Casing) PL. I'A�W I I>-[PRINTED NAME OF PERSON CONSTRUCTING THE WELL Form GW-1b Submit the original to the psYiS��Qn *�t118tp'r tl [1t 0 HISS Attn:'informAtion fltt9t., Rev.11/08 ' 1617 Mail Service Center i3�1feres 117"53QD' 1 _ J NONRESIDENTIAL WELL CONSTRUCTION RECORD North Carolina Department of Environment and Natural Resources-Division of Water Quality i •a,, "�fWELL CONTRACTOR CERTIFICATION# 3,571 1.WELL CONT T R: :d. TOP OF CASING IS 3 FT.Above Land Surface' o f�44 `Top of casing terminated at/or below land surface may require Well Contractor(Individual)Name a variance in accordance with 15A NCAC 2C.0118. A E DRILLING SERVICES, LLC :e. YIELD(qpm): N/9 METHOD OF TEST N/� Well Contractor Company Name TWO United Way f. DISINFECTION:Type �/A Amount Street Address :g. WATER ZONES(depth): Greenville SC 29607 :Top Bottom Top Bottom City or Town State Zip Code Top Bottom Top Bottom— (864 ottom 8( 64 ) 288-1986 :Top Bottom Top Bottom Area code Phone number Thickness/ 2.WELL INFORMATION: :7. CASING: Depth Diameter Weight Material WELL CONSTRUCTION PERMIT# TopC, _0 BottomO•S Ft. ::k" •01fl 04c, OTHER ASSOCIATED PERMIT#(if applicable) :Top Bottom Ft. SITE WELL ID#(if applicable) :Top Bottom Ft. 3.WELL USE(Check One Box)Monitoring Municipal/Public❑ ;8. GROUT: Depth Material Method IndustriallCommercial❑ Agricultural❑ Recovery❑Injection❑ Top_; Bottom 7-) Ft. ,2e n-e- T,�1/ �O Irrigation❑ Other El (list use) Top •s Bottom 11 Ft, r,�er o'le DATE DRILLED 1Top Bottom Ft. 4.WELL LOCATION: 9. SCREEN: Depth Diameter Slot Size Material ' Pt1G �T� :Top Bottom Ft. a In. ••IQ In. (Street Name,Numbers,Community,Subdivision,Lot No.,Parcel,Zip Code) :Top Bottom Ft. In. In. CITY: 1 CJCLe .L COUNTY Top Bottom Ft. in. in. ' TOPOGRAPHIC/LAND SETTING: (check appropriate box) ❑Slope ❑Valley ❑Flat ❑Ridge ❑Other : 10.SANDIGRAVEL PACK: Depth Size Material LATITUDE 3S °3U '3L9 "DMS OR 3x.xxxxxxxxx DD -- D� 'Top 7F,S— Bottom_SrXFL-4V!2 �n(� LONGITUDE 8b "5S' q<1847 "DMS OR 7x.xxxxxxxXX DD :Top Bottom Ft. ' Latitude/longitude source: [SPS []Topographic map :Top Bottom Ft. (location of well must be shown on a USGS topo map andattached to this form if not using GPS) : 11.DRILLING LOG 5.FACILITY(Name of the business where the well is located.) : Top Bottom Formation Description Facility Name Facility #(it applicable) _ �s � Dc l,� As / _ Street Address City or T wn State Zip Code J ' Contact Name J Mailing Address / City or Town State Zip Code 12.REMARKS: `u —1 IQ I. Area code Phone number r 6.WELL DETAILS: M /O D 1 DO HEREBY CERTIFY THAT THIS WELL WAS CONSTRUCTED IN ACCORDANCE WITH W :15A NCAC 2C,WELL CONSTRUCTION STANDARDS,AND THAT A COPY OF THIS a. TOTAL DEPTH: es-- S EErypROVIDEDTOTHE WELL OWNER. S RECORD � b. DOES WELL REPLACE EXISTING WELL? YES❑ NO 6 flA l 1� J` :SIGNATURE OF CERTIFIED VVELL CONTRACTOR TE c. WATER LEVEL Below Top of Casing: ;Ij) -?3 FT. R�Ll— 11� W )�� (Use"+"if Above Top of Casing) PRINTED NAME OF PERS CONSTRUCTING THE WELL Form GW-1b Submit the original.to tho:piutsion,pf IaiioT Quad VA '101 t t o.' Aft' 7nfQttr'totioll'i M9t•.r Rev.11108 1617 Mail Service Center—Raleigfi,.NC 3ywir- p�tag, i90�y$34b I NONRESIDENTIAL ON RESIDENTIAL WELL CONSTRUCTION RECORD North Carolina Department of Environment and Natural Resources-Division of Water Quality WELL CONTRACTOR CERTIFICATION# Yr7l ' 1.WELL CONTRACTOR: I d. TOP OF CASING IS r FT.Above Land Surface* y r`1s `Top of casing terminated at/or below land surface may require Well Contractor(Individual)Name a variance in accordance with 15A NCAC 2C.0118. 1 A I= DRILLING SERVICES, LLC :e. YIELD(gpm):T AY-gft METHOD OF TEST4� Well Contractor Company Name TWO United Way f. DISINFECTION:Type_" Amount Street Address g. WATER ZONES(depth): Greenville SC 29607 Top Bottom Top Bottom ' City or Town Stale Zip Code Top Bottom Top Bottom 864 288-1986 :Top Bottom Top Bottom Area code Phone number Thickness/ 2.WELL INFORMATION: :7. CASING: Depth Diameter Weight Material 1 WELL CONSTRUCTION PERMIT# ;Top D Bottom Ft, 0�1 01b p4c, OTHER ASSOCIATED PERMIT#(if applicable) Top Bottom Ft. ' SITE WELL ID#(if applicable) :Top Bottom Ft. 9.WELL USE(Check One Box)Monitoring Municipal/Public 0 8- GROUT. Depth Material Method Industrial/Commercial❑ Agricultural 0 Recovery❑ Injection❑ Top D' Bottom N' Ft. &,-PnlT:iniC Irrigation[] Other❑ (list use) :Top 35 Bottom 3a Ft. ��BtYti1 DATE DRILLED 7-JO-140 Top Bottom Ft. 4.WELL LOCATION: :9. SCREEN: Depth Diameter Slot Size Material Top .77' Bottom , Ft. 2'In. i0 in. (Street Name,Numbers,Community,Subdivision,Lot No.,Parcel,Zip Code) :Top Bottom Ft. In. in. CITY .moi COUNTY C t�.��nir :Top Bottom Ft. In. in. ' TOPOGRAPHIC/LAND SETTING: (check appropriate box) ❑Slope ❑Valley ❑Flat []Ridge 00ther :10.SAND/GRAVEL PACK: LATITUDE �JS_'�(y 'y-lc(t)O"DMS OR 3X.XXXXXXXXX DD :Top J�1 Bottom Ss, Ft. '47Depth SMater'al LONGITUDE 80 "SIR -1W)L61 "DMS OR 7X.XXXXXXXXX DD I Top Bottom Ft. ' Latitude/longitude source: IFPS OTopographic map :Top Bottom Ft. (location of well must be shown on a USGS topo map andattached to this form if not using GPS) 11.GRILLING LOG S.FACILITY(Name of the business where the well is located.) : Top Bottom Formation Descdpllon Facility Name Facility ID#(if applicable) _!_ S_Sr.nU�%M. _ ' Street Address / City or Town `i State Zip Code Contact Name 1 Mailing Address ! City or Town State Zip Code :12.REMARKS: Area code Phone number ` 6.WELL DETAILS:/-r /! 'I DO HEREBY CERTIFY THAT THIS WELL WAS CONSTRUCTED IN ACCORDANCE WITH J 1 :15A NCAC 2C,WELL CONSTRUCTION STANDARDS,AND THAT A COPY OF THIS a. TOTAL DEPTH: :RECORD H6S BEEN PROVIDED TO THE WELL OWNER. b. DOES WELL REPLACE EXISTING WELL? YES❑ NO F � 'SIGNAT RE OF CERTIFIED AELL CONTRACTOR DATE I c. WATER LEVEL Below Top of Casing: FT. (Use"+"if Above Top of Casing) :PRINTED NAME OF PER!SON CONSTRUCTING THE WELL Form GW-1 b Submit the original to the 3i9t lon;pf yY it yl( h1t tf At";InfOrmation Mgt., Rev.11/08 1617 Mail Service Center MOO-, l 17I = �e Q�3 i8 ,r X300 ' NONRESIDENTIAL ONRESIDENTIAL WELL CONSTRUCTION RECORD North Carolina Department of Environment and Natural Resources-Division of Water Quality `'ar,w ,�• WELL CONTRACTOR CERTIFICATION# .3L5-7/ 1.WELL TOR:RA CON Cr �CONTRACTOR:��,,/ :d. TOP OF CASING IS 3 FT.Above Land Surface- Abe ( "Top of casing terminated at/or below land surface may require Well Contractor(Individual)Name a variance in accordance with 15A NCAC 2C.0118. ' A E DRILLING SERVICES. LLC :e. YIELD(gpm): 44�e —METHOD OF TEST Well Contractor Company Name :f. DISINFECTION:Type /Vl� Amount Two United Way Street Address ;g. WATER ZONES(depth): ' Greenville SC 29607 Top Bottom Top Bottom City or Town State Zip Code Top Bottom Top Bottom 8( 64 ) 288-1986 Top Bottom Top Bottom Area code Phone number' /� Thicknessf 2.WELL INFORMATION:/1w– 11 Q :7. CASING: Depth Diameter Weight Material WELL CONSTRUCTION PERMIT# ;Top_JD Bottom CSS. + Ft. a,' O10 Yc� OTHER ASSOCIATED PERMIT#(if applicable) :Top Bolcom Ft. ' SITE WELL ID#(if applicable) :Top Bottom Ft. 3.WELL USE(Check One Box)Monitoring MunicipallPublic❑ :8. GROUT: Depth 1 Material Method Industrial/Commercial p Agricultural C1ElRecovery❑Injection Top_��Bottom 'q1S FL�� aim Ft. t�C(1 I2 mi t?, Irdgation❑ Other❑ (list use) :Top Bottom DATE DRILLED DRILLED Top Bottom Ft. 4.WELL LOCATION: 8. SCREEN: Depth Diameter Slot Size Material Top W�o Bottom 916 Ft. a�� In. .JO in. 1A) (Street Name,Numbers,Community,Subdivision,Lot No..Parcel,Zip Code) :Top Bottom Ft. In. in. CITY: lUL2 U— COUNTY_C4 TL– �.�UYc :Top Bottom Ft. in. in. TOPOGRAPHIC t LAND SETTING: (check appropriate box) ' ❑Slope ❑Valley ❑Flat ❑Ridge ❑Other :10.SAND/GRAVEL PACK: LATITUDE 3S °3'q1$Z 1 "DMS OR 3X.XxxxXXXXx pp Depth 9 Size Materi LONGITUDE "5g '714130 "DMS OR 7x.xxxxxxxxx DO Top . Bottom �6, Ft. � k�� Top Bottom Ft. Latitudeflongilude source: [SPS OTopographic map :Top Bottom Ft. (location of well must be shown on a USGS topo map andattached to this form it not using GPS) 11.DRILLING LOG 5.FACILITY(Name' ofthebusiness where the well is located.) : Top Bottom Formation DescriptionMI-5AGI ,STt*G_✓)'i 5& 1{r�n / � �P,-CttL I�UG�aULIJw Fility Name Facility ID#(if applicable) �I I �• a13oW ME i,>av /570 ! ' Street Address / City or Towf State Zip Code J LAli,�AyitT` ! ' Contact Name / Mailing Address J City or Town State Zip Code 12.REMARKS: Area code Phone number B.WELL DETAILS: M �`D I DO HEREBY CERTIFY THAT THIS WELL WAS CONSTRUCTED IN ACCORDANCE WITH ' 11' , : 15A NCAC 2C,WELL CONSTRUCTION STANDARDS,AND THAT A COPY OF THIS RECORD HAZBN PROVIDE TOTHEWELLOWNER.a. TOTAL DEPTH: 9G al b. DOES WELL REPLACE EXISTING WELL? YES❑ NO;k :SSTUERTIFIED WELL CONTRACTOR DATE A E c. WATER LEVEL Below Top of Casing:_4 .440 FT. -�--� Tks EL It (Use"+"if Above Top of Casing) :PRINTED NAME OF PERS N CONSTRUCTING THE WELL , Form GW-lb the original tothe� r � Attn:Information Mgt., � t [ Q Rev.11/08 1617 Mail Service-Centerlei1/+l1 .+•S�Aipo� NONRESIDENTIAL WELL CONSTRUCTION RECORD ' North Carolina Department of Environment and Natural Resources-Division of Water Quality •d,, •,,• WELL CONTRACTOR CERTIFICATION# 1.WELL CONT T R: d. TOP OF CASING IS FT.Above Land Surface- Au jC //{� (/2�i�L "Top of casing terminated at/or below land surface may require Well Contractor(Individual)Name a variance in accordance with 15A NCAC 2C.0118. A E DRILLING SERVICES. LLQ 'e. YIELD(gpm): _ �METHOD OF TEST Well Contractor Company Name TWO United Way f. DISINFECTION:Type 4111Amount_ Street Address :g. WATER ZONES(depth): ' Greenville SC 29607 Top Bottom Top Bottom City or Town State Zip Code :Top Bottom Top Bottom $( 64 ) 288-1986 :Top Bottom Top Bottom Area code Phone number Thickness/ 2.WELL INFORMATION: '7. CASING: Depth Diameter Weight Material WELL CONSTRUCTION PERMIT# JopQ_Bottom �I Ft. C.' OTHER ASSOCIATED PERMIT#(if applicable) :Top Bottom Ft. ' SITE WELL ID#(Inapplicable) :Top Bottom Ft. 3.WELL USE(Check One Box)Monitoring�x Municipal/Public(2 :8. GROUT: Depth MaterialL Method TopD• Bottom 3, Ft.. Industrial/Commercial El Agricultural D Recovery❑injection p Irrigation❑ Other❑ (list use) :Top 6 - Bottom:_Ft. � 7-cPmiP' DATE DRILLED 9-y m/ Top Bottom Ft. 4.WELL LOCATION: :9. SCREEN: Depth Diameter Slot Size Werial 4c t'�Yst� �t$1• :Top_ 7, Bottom eQ' Ft. 7 in. JD In. fJvC (Street Name,Numbers,Community,Subdivision,Lot No.,Parcel,Zip Code) :Top Bottom Ft. in. in. CITY: 1UQ � COUNTY PLL :Top Bottom Ft. In. in. ' TOPOGRAPHIC I LAND SETTING: (check appropriate box) OSlope ❑Vailev ❑Flat ❑Ridge ❑Other :10.SANDIGRAVEL PACK: LATITUDE °3iQ' �a� Depth Size Material `�"DMS OR 3X.xxxxxxxxx DD :Top _BottamAQ Ft. �ri7 LONGITUDE "DMS OR 7x.XXxXXXXXX DO :Top Bottom Ft. ' Latitudellongitude source: M3PS Dropographic map :Top Bottom Ft. (location of well must be shown on a USGS topo map andattached to this form if not using GPS) : 11.DRILLING LOG S.FACILITY(Name of the business where the well Is located.) : Top Bottom < Formation Description 1tt1�2.oLATiI f-1) Fav Facility Name Facility ID#(if applicable) I 83"o &W IVL 84h w4� l ' Street AddreSZ7- City or Town State Zip Code / ' Contact Name 1 Mailing Address / City or Town State Zip Code 12.REMARKS: Area code Phone number 6.WELL DETAILS: I DO HEREBY CERTIFY THAT THIS WELL WAS CONSTRUCTED IN ACCORDANCE WITH:15A NCAC 2C,WELL CONSTRUCTION STANDARDS,AND THAT A COPY OF THIS yQ� : a. TOTAL DEPTH:_ RECORD BEEN OVIDEDTOTH WELL OWNER. I! c n b. DOES WELL REPLACE EXISTING WELL? (YES❑ NO :SIGNATURE F CERTIFIED WELL CONTRACTOR DATE t/ c. WATER LEVEL Below Top of Casing: 1'1 ?�rFT. (Use°+"if Above Top of Casing) :PRINTED NAME OF PERS N CONSTRUCTING THE WELL Form GW-1 b Submit the original to,thla ',tlsiora ��r ` tA(it#Ilni 3c1 dais Attnl Intormatlo Msx, Rev.11108 1617 Mail Service Center R Heigh,�t1 7 $ �NQ (919, >�07.6306' ; .�srAr�o NONRESIDENTIAL WELL CONSTRUCTION RECORD North Carolina Department of Environment and Natural Resources-Division of Water Quality WELL CONTRACTOR CERTIFICATION# 3571 ' 1.WELL CONTRACTOR: J �d. TOP OF CASING IS FT.Above Land Surface' 'Top of casing terminated atior below land surface may require Well Contractor(Individual)Name a variance in accordance with 15A NCAC 2C.0118- A 01f8.A E DRILLING SERVICES. LLC :e. YIELD(gpm): N/fi METHOD OF TEST lf,111 Well Contractor Company Name 1 TWO United Way :f. DISINFECTION:Type yip Amount Street Address ;g. WATER ZONES(depth): Greenville SC 29607 Top Bottom Top Bottom City or Town State Zip Code Top Bottom Top Bottom 8( 64 ) 288-1986 :Top Bottom Top Bottom Area code Phone number Thickness/ 2.WELL INFORMATION: :7. CASING: Depth Diameter Weight Material WELL CONSTRUCTION PERMIT# ;Top Bottom 110Ft. ars O tib p'(c�, OTHER ASSOCIATED PERMIT#(if applicable) :Top Bottom Ft. ' SITE WELL 10#(if applicable) :Top Bottom Fl. 3.WELL USE(Check One Box)Monitoring pi-MunicipaltPublic❑ 8. GROUT: Depth Material Method Industrial/Commercial C] Agricultural C3 Recovery[I Injection C3 TOP 0' Bottom 16C Ft. S.GMGA7 �ll Ari ' Irrigation❑ Other❑ (list use) :Top SS •b Bottom SU Ft. nib {emc DATE DRILLED Top Bottom Ft. 4.WELL LOCATION: :9. SCREEN: Depth Diameter Slot Size Material ' .Top 9a, Bottom_ Ft.� in. /1)� In. Pv� , (Street Name,Numbers,Community,Subdivision,Lot No.,Parcel,Zip Code) :Top Bottom Ft. in. In. CITY: COUNTY Top Bottom Ft. In. in. TOPOGRAPHIC/LAND SETTING: (check appropriate box) ' ❑Slope ❑Valley ❑Flat ❑Ridge ❑Other : 10.SANDIGRAVELPACK: Depth Size Material LATITUDE 35 DMS OR 3X.XXXXxXXXx DD Top M-,�Bottom�d, Ft.� Sano LONGITUDE '66 °Sb'3IR 8 d "DMS OR 7X.XXXXXXXXX DO :Top Bottom Ft. Latitude/longitude source: M3PS aopographic map :Top Bottom Ft. (location of weil must be shown on a USGS topo map andattached to this form if not using GPS) 11.DRILLING LOG 5.FACILITY(Name of the business where the well is located.) : Top Bottom Formation Description Facility Name11 Facility ID#(if applicable) 9- _l1 [��ti 6U.21) �a.f! /y. H,lJ1Lr1QY ZSO J Street Address City or Town State Zip Code J ' Contact Name 1 Mailing Address / ' City or Town State Zip Code 12.REMARKS: 471 q Area code Phone number 6.WELL DETAILS:q1 U)^ D I DO HEREBY CERTIFY THAT THIS WELL WAS CONSTRUCTED IN ACCORDANCE WITH 15A NCAC 2C,WELL CONSTRUCTION STANDARDS,AND THAT A COPY OF THIS a. TOTAL DEPTH: 106` RECORD HAS BEEN PROVIDED TOTHE WELL OWNER. b. DOES WELL REPLACE EXISTING WELL? YES❑ NO fY :SIG14AMRL OF CERTI DWELL CONTRAC fOR DATE v ' c. WATER LEVEL Below Top of Casing: G'l'_FT. F 1j �4C�i Lj�� (Use"+"if Above Top of Casing) :PRINTED NAME OF PERSO COf7STR TING THE WELL Form GW-1 b Submit the origin alAo this 01yWon of Water qualitMo,, Rev.11/08 1017 Main Service Ce[jt1�6,,NC'27,099-101', 4'horie NQ (9'i);'9Q74' jk d�SfATpu r NONRESIDENTIAL ONRESIDENTIAL WELL CONSTRUCTION RECORD ' North Carolina Department of Environment and Natural Resources-Division of Water Quality Q ,g• WELI,CONTRACTOR CERTIFICATION# 171 1.WELL C NTRAC�TOR: :d. TOP OF CASING IS FT.Above Land Surface' /'� f/fG.,i/r `Top of casing terminated at/or below land surface may require Well Contractor(Individual)Name a variance in accordance with 15A NCAC 2C.0118. ' A E DRILLING SERVICES, LLC :e. YIELD(gpm): ll#- METHOD OF TEST—,I///7 Well Contractor Company Name TWO United Way f. DISINFECTION:Type /W?;! AmountIW/� Street Address :g. WATER ZONES(depth): ' Greenville SC 29607 Top Bottom Top Bottom City or Town State Zip Code ;Top Bottom Top Bottom 8( 64 ) 288-1986 :Top Bottom Top Bottom Area code Phone number Thtckness/ ' 2.WELL INFORMATION: :7. CASING: Depth Diameter Weight Material WELL CONSTRUCTION PERMIT# Top 0 Bottom Ft. a OTHER ASSOCIATED PERMIT#(if applicable) :Top Bottom Ft. SITE WELL ID#(if applicable) :Top Bottom Ft. 3.WELL USE(Check One Box)MonitoringA Municipal/Public❑ :8. GROUT: Depth Material Method _1 Industrial/Commercial ElAgricultural❑ Recovery❑Injection❑ Topes BottomFt. lem�� Irrigation❑ Other❑ (list use) :Top o� Bottom I Ft. t f- 1 DATE DRILLED 844-10 Top Bottom Fl. 4.WELL LOCATION: [ :9. SCREEN: Depth Diameter Slot Size Material ' , 1`Po�ZSrtM� JT�sCtr�J :Top ,'Bottomy IV Ft.,�in. Ad In. AIC,_ (Street Name,Numbers,Community,Subdivision,Lot No.,Parcel,Zip Code) :Top Boltom Ft. in. in. CITY:7y� COUNTY :Top Bottom Ft. In. in. TOPOGRAPHIC f LAND SETTING: (check appropriate box) WSlope ❑Valley ❑Flat EfRidge ❑Other : 10.SAND/GRAVEL PACK: q"DMS OR 3x.xxxxxxxxx DO Depth Size Material LATITUDE 3S ' D JC :Top 7' .��;Ft. _ .Xin LONGITUDE FsJ `Sg '4a�Qln DMS OR 7x.xxxxxxxxx DD :Top Bottom Ft. ' LatitudeAongitude source: M3PS QTopographic map :TopBottom Ft. (location of well must be shown on a USGS topo map andattached to this form if not using GPS) : 11.DRILLING LOG S.FACILITY(Name/of the/business where the well is located.) : Top Bottom Formation Description ' 1!(B!-�hl.'// �TP11r►1 STG�io n �_/ �R y5}YfttoUtL� (1tX�3uf�-Deal Facility Name Facility ID#(if applicable) / 8121) Street Ad4ress ' ♦ / City or Ton State Zip Code ! ' Contact Name / Mailing Address / City or Town State Zip Code 12.REMARKS: Area code Phone number 1 6.WELL DETAILS:/n f,J J I DO HEREBY CERTIFY THAT THIS WELL WAS CONSTRUCTED IN ACCORDANCE WITH ('t :15A NCAC 2C,WELL CONSTRUCTION STANDARDS,AND THAT A COPY OF THIS 7. TOTAL DEPTH: + :RECORD HAS BEEN PROVIDED TO THE WELL OWNER. 7 ID b. DOES WELL REPLACE EXISTING WELL? YES❑ NO �� SIGNATU E 0� F CERTIFIED WELL CONTRAL�OR +DATE ' C. WATER LEVEL Below Top of Casing:_5-30 FT, (Use"+"if Above Top of Casing) :PRINTED NAME OF PES CONSTRUCTING THE WELL Form GW-Ib SOrnit the original to the DivisloA pf Water Quail tA(f�hi 1 A t�aYS Attn1'InWrfriAt.ion Mgt„ Rev.11108 1017 Mail Service Center-Raleigh,Ji 17699-9617 r %h!' j �� Q7- 300' , NONRESIDENTIAL WELL CONSTRUCTION RECORD North Carolina Department of Environment and Natural Resources-Division of Water Quality •,, WELL CONTRACTOR CERTIFICATION#_&7 1.WELL 1��CONTRACTOR:� d. TOP OF CASING IS Y, FT.Above Land Surface- I-bey me-Gar(I_- 'Top of casing terminated atior below land surface may require Well Contractor(Individual)Name a variance in accordance wlth 15A NCAC 2C.0118. A E DRILLING SERVICES. LLC :e. YIELD(gpm): METHOD OF TEST ' Well Contractor Company Name TWO United Way f. DISINFECTION:Type /-�i z Amount Street Address ;g. WATER ZONES(depth): ' Greenville SC 29607 :Top Bottom Top Bottom City or Town State Zip Code :Top Bottom Top Bottom— (864 ottom $t 64 ) 2$$-19$6 :Top Bottom Top Bottom Area code Phone number Thickness/ ' 2.WELL INFORMATION: :7. CASING: Depth,, Diameter Weight Material WELL CONSTRUCTION PERMIT# Jop 0 Bottom A41.(PFt. Irl Old Pile- OTHER ASSOCIATED PERMIT#(inapplicable) :Top Bottom Ft. t SITE WELL ID#(If applicable) :Top Bottom Ft. 3.WELL USE(Check One Box)Monitoring❑ Municipal/Public❑ 8. GROUT: Depth Material,} �Method Industrial/Commercial❑ Agricultural❑ Recovery Injection D Top_ Bottom .3p•�kt. C��e•" ` ///.rri Irrigation❑ Other❑ (list use) Top L4 Bottom Ft. IP e! tj'.I- --Tret-i e— DATE DRILLED .9-L-10 -Top Bottom Ft. 4.WELL LOCATION: ( :9. SCREEN: Depth Diameter Slot Size Material' :Top. Bottom_�r Ft. 2 in. !O in. Sc�+.y0 A/c, (Street Name,Numbers,Community,Subdivision,Lot No.,Parcel,Zip Code) :Top Bottom Ft. in. In. CITY: 7rcez!},, _ COUNTY_LAC:�� :Top Bottom Ft. In. in. ' TOPOGRAPHIC l LAND SETTING: (check appropriate box) OSlope ❑Valley C]Flat ❑Ridge ❑Other :10.SAND/GRAVEL PACK: Depth Size Material � LATITUDE °3(2 '5 O`p1"DMS OR 3X.XxxXXXXXX DD :Top I&``Bottom 3 44'Ft._#7/ Sgnd LONGITUDE °5g � {�� 'DMS OR 7X.Xxxxxxxxx DO :Top Bottom Ft. Latitudellongitude source: WPS aopographic map Top Bottom Ft. (location of well must be shown on a USGS topo map andattached to this form if not using GPS) 11.DRILLING LOG 6.FACILITY'Name of the business where)the well is located.) Top Bottom Formation Description �QlSh� Sham S}a4i 'm x-11 Sp ��xc atk_�QUP�Ic�_1 Facility Nam .r Facility ID#/L(if applicable)( ' Street Address Terre 1 1U,( aS�osa f City or Town Slate Zip Code / ' Contact Name / Mailing Address / ' City or Town Stale Zip Code : 12.REMARKS: Area code PhoneKimber 6.WELL DETAILS: /I k/-aO •I DO HEREBY CERTIFY THAT THIS WELL WAS CONSTRUCTED IN ACCORDANCE WITH •15A NCAC 2C,WELL CONSTRUCTION STANDARDS,AND THAT A COPY OF THIS 1 :REC AS BEEN PROVIDED TO THE WELL OWNER, a. TOTAL DEPTH:_ � � •� b. DOES WELL REPLACE EXISTING WELL? YES❑ NO 7 :SI N TURE F CERTiFI WELL CONTRACTOR— DATE c. WATER LEVEL Below Top of Casing: 3. 59 _FT. lie�/11 t(! ,i,(— i (Use"+"if Above Top of Casing) :PRINTED NAME �O[F,PERSON CONSTRUCTING THE WELL ' Submit the original to.#h,e pittision,of Water Quail. M ay , AttnsYn atioq M,' t„ Form GW-1b 1617 Mail Service Center+- Rev.1 t/08 fl� t '2789-1517 i1a; I$ 30b dp.stA�o ~~r NONRESIDENTIAL ONRESIDENTIAL WELL CONSTRUCTION RECORD North Carolina Department of Environment and Natural Resources-Division of Water Quality `•ora,;or• WELL CONTRACTOR CERTIFICATION# 145 1.WELL CONTRACTOR: :d. TOP OF CASING IS FT.Above Land Surface" /�br /�—`(tea F it "Top of casing terminated aUor below land surface may require Well Contractor(Individual)Name a variance in accordance with 15A NCAC 2C.0118. A E DRILLING SERVICES. LLC e. YIELD(gpm): 4///�' METHOD OF TEST Well Contractor Company Name Two United Way :f. DISINFECTION:Type ��/� Amount Street Address ;g. WATER ZONES(depth): Greenville SC 29607 ;Top Bottom Top Bottom City or Town State Zip Code Top Bottom Top Bottom 8( 64 ) 288-1986 :Top Bottom Top Bottom Area code Phone number Thickness/ 2.WELL INFORMATION: :7. CASING: Depth Diameter Weight Material WELL CONSTRUCTION PERMIT# :Top Bottom Ft. Z �C OTHER ASSOCIATED PERMIT#(if applicable) :Top Bottom Ft. ' SITE WELL ID#(if applicable) :Top Bottom Ft. 3.WELL USE(Check One Box)Monitoring YMunicipal/Public❑ :8. GROUT: Depth Material Method lndustriallCommercial❑ Agricultural❑ Recovery❑ Injection p Topes Bottom Ft.1'er-2+11 T••� ' Irrigation❑ Other El (list use) Top 53•!�' Bottom Ft. tk TlCmiel DATE DRILLED Top Bottom Ft. 4.WELL LOCATION: :9. SCREEN: Depth Diameter Slot Size Material SyrPcL� pr :Top_,SYL Bottom 6A�r Ft. ZIn. -/0 In. PyG. (Street Name.Numbers,Community,Subdivision,Lot No.,Parcel,Zip Code) :TOp Bottom Fl. in. in. CITY: COUNTY ;Top Bottom Ft. In. in. TOPOGRAPHIC I LAND SETTING: (check appropriate box) Slope ❑Valley ❑Flat ❑Ridge []Other 10.SANDIGRAVEL PACK: .Depth , Slze Material LATITUDE 35 °3(0' l b"DMS OR 3X.XXXXXXXXX DD :Top 1"3 S Bottom LD./ Ft.--9.2- �n LONGITUDE °58' ,1,;?e9,"DMS OR 7X.XXXXXXXXx DD Tap Bottom Ft. Latitude/longitude source: [JQPS Dropographic map Top Bottom Ft. (location of well must be shown on a USGS topo map andattached to this than if not using GPS) 11.DRILLING LOG S.FACILITY(Name of the business where the well Is located.) : Top Bottom Formatlon Description Facility Name ![ Facility ID#(if applicable) SS / fa D C5�nr n. , _ "C?5T ' StreetAdd ss / City or TowK State Zip Code / Contact Name / f Mailing Address / ' City or Town State Zip Code 12.REMARKS: ( 401 419, -1 b 2.2. Area code Phone number 6.WELL DETAILS:1)1W-1q6 /�/r{'W—1`J/,/ D •100 HEREBY CERTIFY THAT THIS WELL WAS CONSTRUCTED IN ACCORDANCE WITH 15A NCAC 2C.WELL CONSTRUCTION STANDARDS,AND THAT A COPY OF THIS :RECO D HAS BEEN PROVIDED TO THE WELL OWNER. a. TOTAL DEPTH: (a /�a�0 ,I , -Y-Iv b. DOES WELL REPLACE EXISTING WELL? YES❑ NO& :SIGNATURE OF CERT1FIED WELL CONTRACTOR DATE c. WATER LEVEL Below Top of Casing: 3L'9 FT, (Use"+"if Above Top of Casing) PRINTED NAME OF PERSON CONSTRUCTING THE WELL ' Submit the original to the pi9ision of1Nater Quality within 3Q days. Attic:Infor[rtatlon Form GW-1 b Mgt., Rev.t voa 1617 Mail Service Center-NaleiOh,NC`27fl)9-1-617: hone N4 H9)6-074300' �( NONRESIDENTIAL WELL CONSTRUCTION RECORD North Carolina Department of Environment and Natural Resources-Division of Water Quality �5 •,� ,�• WELL CONTRACTOR CERTIFICATION# SW 1.WELL CONTRAC,rPR: :d. TOP OF CASING IS�_FT.Above Land Surface' ?5%e n� 1.1,9.. 'Top of casing terminated aUor below land surface may require Well Contractor(Individual)Name a variance In accordance with 15A NCAC 2C.01 18. A E DRILLING SERVICES LLC e. YIELD(gpm):_AMETHOD OF TEST / — 1? Well Contractor Company Name TWO United Way f. DISINFECTION:Type_ _ Amount IV Street Address :g. WATER ZONES(depth). Greenville SC 29607 Top Bottom Top Bottom City or Town State Zip Code Top Bottom Top Bottom— (864 ottom 8( 64 ) 288-1986 Top Bottom Top Bottom Area code Phone number Thickness/ 2.WELL INFORMATION: :7. CASING: Depth Diameter Weight Material WELL CONSTRUCTION PERMIT# Top_ Bottom Ft. a 1 •010 Pvc OTHER ASSOCIATED PERMIT#(if applicable) :Top Bottom Ft. SITE WELL ID#(if applicable) :Top Bottom Ft. 3.WELL USE(Check One Box)Monitoring I (Municipal/Public❑ •8. GROUT: Depth Material Method Industnal/Commercial❑ Agricultural❑ Recovery El Injection❑ •Top 0' Bottom Z r Ft. Irrigation[] Other❑ (list use) :Top QW Bottom a s, Ft. +Unit If�mi e DATE DRILLED Top Bottom Ft. 4,WELL LOCATION: :9. SCREEN: Depth U Diameter Slot Size Matate'rial Top a�i Bottom 7�i Ft. Z` in. .�D In. ,vG (Street Name,Numbers,Community,Su ivision,Lot No.,Parcel,Zip Code) :Top Bottom Ft. In. in. CITY.—U��LL.L— COUNTY 'R ;Top Bottom Ft. in. in. TOPOGRAPHIC/LAND SETTING: (check appropriate box) ❑Slope ❑Valley ❑Flat ❑Ridge ❑Other 10.SAND/GRAVEL PACK: Depth Size Material LATITUDE 35 DMS OR 3X.xxxxxxxxx DD LONGITUDE � ° r�,8_',�{79 "DMS OR 7x.)ocXXXxxXX DD ;Top �r Bottom_ Ft. :Top Bottom Ft. Latitude/longitude source: 03PS Qropographic map :Top Bottom Ft. (location of well must be shown on a USGS Popo map andattached to this toms if not using GPS) :11.DRILLING LOG 6.FACILITY'Name ofthebusiness where the well is located.) : Top Bottom Formation Description //!G/S/lCt�! J�G/►2 )lG 1'��n : —�_/� �f.>i�1..��nr Ot)�ik7At�rl.1 Facility Name Facility ID#(if applicable) / Street Address City orTownState Zip Code / Contact Name / Malling Address / ' City or Town State Zip Code 12.REMARKS: tvlq� -r toga- Area code Phone number ) 6.WELL DETAIL$: Mi,V /yk� 'I DO HEREBY CERTIFY THAT THIS WELL WAS CONSTRUCTED IN ACCORDANCE WITH —,1� 15A NCAC 2C,WELL CONSTRUCTION STANDARDS,AND THAT A COPY OF THIS `rl a. TOTAL DEPTH: r :RECORDHl�SEN PROVIDED TO THE WELL OWNER. F-14'1(2 b. DOES WELL REPLACE EXISTING WELL?- YES❑ NO I :SIGNATURE OF CERTIFIED ELL CONTRAS DATE c. WATER LEVEL Below Top of Casing: •?gyp _FT. t11 1 G 1 > ) (Use"+"if Above Top of Casing) I :PRINTED NAME OF PERSON CONSTRUCTING THE WELL ' Form GW-1 b 5ubmit.the origtnat tp the btXislon,pf)Nater Quali k11 -Aftp1 InfarmaticIn Mgt., Rev.11/08 + + , 1617 Mali Service Center Ra1et �tFICe"37fP.9BQ7 � � 1' Ash Basin Monitoring Well Installation Report August 26,2010 Marshall Steam Station Terrell,Catawba County,North Carolina MACTEC Project 6228-10-5284 APPENDIX D MONITORING WELL DEVELOPMENT RECORDS i i 1 MACTEC MACTEC ENGINEERING AND CONSULTING,INC. MONITORING WELL SAMPLING FIELD DATA WORKSHEET MACTEC PROJECT NUMBER 6228-10-5284 MONITORING WELL NUMBER MW-14D SITE NAME Duke Marshall Steam Station DATE TIME OF SAMPLE N/A ' FIELD PERSONNEL Mark Filardi WEATHER CONDITIONS ' TOTAL WELL DEPTH(TWD) 62.85 measured ell tag/drillers log-circle one) SCREENED INTERVAL 55-60 bas MEASURING POINT FOR DEPTH Top of casing DEPTH TO GROUNDWATER(DGW) 36.98 LENGTH OF WATER COLUMN(LWC)=TWD-DGW= 25.87 CASING DIAMETER 2 IN. ONE STANDING WELL VOLUME= 4.22 gal. (NOTE%z"=0.0102G/FT: N"=0.023 G/FT: 1"=0.041 G/FT:2"=0.163 G/FT: 4"=0.653 G/FT: 6"= 1.46 G/FT) THREE STANDING WELL VOLUMES= 12.65 FIVE STANDING WELL VOLUMES= 21.10 METHOD OF WELL EVACUATION: BAIZE /PUMP/ THER: TYPE TOTAL VOLUME OF WATER REMOVED: 70 GAL. ' WELL TYPE: FLUSH MOUNT/ OVE GRAD COMMENTS LOCKING CAP YES X NO No sample collected/nurged for ' PROTECTIVE POST/ABUTMENT YES NO X development only NONPOTABLE LABEL YES X NO ID PLATE YES X NO WELL INTEGRITY SATISFACTORY YES X NO WELL YIELD LOW MODERATE HIGH X Temp Cond. Dis.02 Turbidity ORP Time Volume Pg (°C) (µS/cm) (mg/L) (NTU) (mV) Notes 1 30 5.68 18.00 .682 0.10 234 35 5.66 18.10 .685 0.03 115 40 5.65 18.10 .687 0.03 90 45 5.65 18.50 .688 0.02 90 50 5.65 18.50 .690 002 87 55 5.59 18.20 55 Meter Malfunction 60 5.57 16.30 .709 0.02 44 65 5.58 17.10 .727 0.01 21 70 5.62 17.20 .734 0.01 14 MACTEC ' MACTEC ENGINEERING AND CONSULTING, INC. MONITORING WELL SAMPLING FIELD DATA WORKSHEET MACTEC PROJECT NUMBER 6228-10-5284 MONITORING WELL NUMBER MW-13S SITE NAME Duke Marshall Steam Station DATE TIME OF SAMPLE N/A FIELD PERSONNEL Mark Filardi WEATHER CONDITIONS ' TOTAL WELL DEPTH(TWD) 21.12 FTQAS=G g/drillers log—circle one) SCREENEDINTERVAL 3-18 bgs. POINT FOR DEPTH To of casing 1 DEPTH TO GROUNDWATER(DGW) 5.70 LENGTH OF WATER COLUMN(LWC)=TWD—DGW= 15.42 CASING DIAMETER 2 IN. ONE STANDING WELL VOLUME= 2.51 gal. (NOTE%Z"=0.0102G/FT: 3/,"=0.023 G/FT: 1"=0.041 G/FT:2"=0.163 G/FT: 4"=0.653 GIFT: 6"= 1.46 G/FT) THREE STANDING WELL VOLUMES= 7.54 FIVE STANDING WELL VOLUMES= 12.55 METHOD OF WELL EVACUATION: BAILS PUMP OTHER: TYPE TOTAL VOLUME OF WATER REMOVED: 60 GAL. WELL TYPE: FLUSH MOUNT ABOVE GRADE COMMENTS LOCKING CAP YES X NO No sample collected/purged for I PROTECTIVE POST/ABUTMENT YES NO X development only NONPOTABLE LABEL YES X NO ID PLATE YES X NO WELL INTEGRITY SATISFACTORY YES X NO WELL YIELD LOW MODERATE HIGH X Temp Cond. Dis.02 Turbidity ORP Time Volume pR ("C) (µS/cm) (mg/L) (NTU) (mom Notes 1 35 5.96 19.70 .200 10.56 -10 Turbidity meter 45 6.27 19.00 .098 10.89 -10 Malfunction 50 6.49 18.60 .091 10.91 -10 55 6.52 18.40 .090 10.77 -10 60 6.54 18.30 .089 10.83 -10 1 1 MACTEC MACTEC ENGINEERING AND CONSULTING, INC. MONITORING WELL SAMPLING FIELD DATA WORKSHEET MACTEC PROJECT NUMBER 6228-10-5284 MONITORING WELL NUMBER MW-13D SITE NAME Duke Marshall Steam Station DATE TIME OF SAMPLE N/A 1 FIELD PERSONNEL Mark Filardi WEATHER CONDITIONS TOTAL WELL DEPTH(TWD) 48.61 FT. meas well tag/drillers log-circle one) SCREENED INTERVAL 41.5-46.5 bgs EASURING POINT FOR DEPTH Top of Casing ' DEPTH TO GROUNDWATER(DGW) 3.59 LENGTH OF WATER COLUMN(LWC)=TWD-DGW= 45.02 CASING DIAMETER 2 IN. ONE STANDING WELL VOLUME= 7.34 gal. (NOTE%a"=0.0102G/FT: Y4"=0.023 G/FT: 1"=0.041 G/FT:2"=0.163 G/FT: 4"=0.653 G/FT: 6"= 1.46 G/FT) THREE STANDING WELL VOLUMES= 22.01 _FIVE STANDING WELL VOLUMES= 36.70 tMETHOD OF WELL EVACUATION: BAILERPUMP OTHER: TYPE TOTAL VOLUME OF WATER REMOVED: 85 GAL. ' WELL TYPE: FLUSH MOUNT<E�3? COMMENTS LOCKING CAP NO No sample collected/purged for PROTECTIVE POST/ABUTMENT YES NO X development only NONPOTABLE LABEL YES X NO ID PLATE YES X NO ' WELL INTEGRITY SATISFACTORY YES X NO WELL YIELD LOW MODERATE HIGH X Time Volume pH Temp Cond. Dis.02 Turbidity ORP Notes (C) (µS/cm) (mg/L) (NTU) (mV) 1 45 6.76 18.60 .098 -- 182 50 6.72 17.60 .098 12.03 202 55 6.61 17.40 .093 -- 140 60 6.60 17.60 .093 11.65 272 65 - -- - -- -- j70 6.51 17.10 .092 11.81 30 75 6.54 17.10 .092 11.58 77 1 80 6.55 17.20 1 .091 11.29 68 85 6.55 17.00 .091 11.52 9 i 1 ArMACTEC MACTEC ENGINEERING AND CONSULTING,INC. MONITORING WELL SAMPLING FIELD DATA WORKSHEET 1 MACTEC PROJECT NUMBER 6228-10-5284 MONITORING WELL NUMBER MW-12S SITE NAME Duke Marshall Steam Station DATE TIME OF SAMPLE N/A FIELD PERSONNEL Mark Filardi WEATHER CONDITIONS TOTAL WELL DEPTH(TWD) 25.32 (measureR L11ag/drillers log—circle one) SCREENEDINTERVAL 7-22 G POINT FOR DEPTH Top of casing DEPTH TO GROUNDWATER(DGW) 14.28 LENGTH OF WATER COLUMN(LWC)=TWD—DGW= 11.04 CASING DIAMETER 2 IN. ONE STANDING WELL VOLUME= 1.80 gal. (NOTE 1/2"=0.0102G/FT: %"=0.023 G/FT: 1"=0.041GiFT:2"=0.163 G/FT: 4"=0.653 G/FT: 6"= 1.46 G/FT) ' THREE STANDING WELL VOLUMES= 5.40 FIVE STANDING WELL VOLUMES= 9.00 METHOD OF WELL EVACUATION: BAILER(PUMP OTHER: TYPE TOTAL VOLUME OF WATER REMOVED: GAL. ' WELL TYPE: FLUSH MOUNT/ OVE GRADE COMMENTS LOCKING CAP X NO No sample collected/Waed for I PROTECTIVE POST/ABUTMENT YES NO X development only NONPOTABLE LABEL YES X NO ID PLATE YES X NO ' WELL INTEGRITY SATISFACTORY YES X NO WELL YIELD LOW MODERATE HIGH X Temp Cond. Dis.02 Turbidity ORP Time Volume pH CC) (µS/cm) (mg/L) (NTU) (mV) Notes 1 140 i 1 ArMACTEC MACTEC ENGINEERING AND CONSULTING,INC. MONITORING WELL SAMPLING FIELD DATA WORKSHEET ' MACTEC PROJECT NUMBER 6228-10-5284 MONITORING WELL NUMBER MW-12D SITE NAME Duke Marshall Steam Station DATE TIME OF SAMPLE N/A FIELD PERSONNEL Mark Filardi WEATHER CONDITIONS TOTAL WELL DEPTH(TWD) 98.59 F (measured ell tag/drillers log-circle one) SCREENED INTERVAL 90-95 bgs MEASURING POINT FOR DEPTH Top of casing DEPTH TO GROUNDWATER(DGW) 15.21 LENGTH OF WATER COLUMN(LWC)=TWD-DGW= 83.38 CASING DIAMETER 2 IN. ONE STANDING WELL VOLUME= 13.59 gal. (NOTE%2"=0.0102G/FT: N"=0.023 G/FT: 1"=0.041 G/FT:2"=0.163 G/FT: 4"=0.653 G/FT: 6"= 1.46 G/FT) THREE STANDING WELL VOLUMES= 40.77 FIVE STANDING WELL VOLUMES= 67.95 METHOD OF WELL EVACUATION: BAILS /PUMP OTHER: TYPE TOTAL VOLUME OF WATER REMOVED: 85 GAL. WELL TYPE: FLUSH MOUNT OVE GRAD COMMENTS LOCKING CAP X NO No sample collected/purged for ' PROTECTIVE POST/ABUTMENT YES NO X development only NONPOTABLE LABEL YES X NO 1 ID PLATE YES X NO WELL INTEGRITY SATISFACTORY YES X NO WELL YIELD LOW MODERATE HIGH X ' Time Volume PH Temp Cond. Dis.02 Turbidity ORP Notes (C) (AS/cm) (mom) (NTU) (mv) 25 5.97 19.60 .090 12.84 123 Pumped Dry Pumped Dry Before 30 5.88 18.70 .052 12.81 848 35-gal 35 5.84 18.90 .043 11.64 121 Pumped Dry 40 5.81 17.60 .038 12.35 179 ' 45 5.74 17.30 .037 12.35 232 50 5.69 17.60 .033 0.00 83 55 5.65 18.60 .032 0.00 114 60 5.67 20.00 .032 0.00 14 65 5.69 18.00 .031 0.00 70 70 5.58 19.30 .029 0.00 28 75 5.61 19.20 .029 0.01 49 80 5.67 18.10 .029 0.01 23 85 5.58 17.80 .028 0.00 10 f MACTEC MACTEC ENGINEERING AND CONSULTING, INC. MONITORING WELL SAMPLING FIELD DATA WORKSHEET MACTEC PROJECT NUMBER 6228-10-5284 MONITORING WELL NUMBER MW-11S SITE NAME Duke Marshall Steam Station DATE TIME OF SAMPLE N/A 1 FIELD PERSONNEL Mark Filardi WEATHER CONDITIONS TOTAL WELL DEPTH(TWD) 54.38 measure well tag/drillers log-circle one) SCREENED INTERVAL 37-52 bgs MEASURING POINT FOR DEPTH Tot)of casing I DEPTH TO GROUNDWATER(DGW) 43.77 LENGTH OF WATER COLUMN(LWC)=TWD-DGW= 10.61 CASING DIAMETER 2 IN. ONE STANDING WELL VOLUME= 1.73 gal. (NOTE%z"=0.0102G/FT: Y4"=0.023 G/FT: 1"--0.041 G/FT:2"=0.163 GIFT: 4"=0.653 G/FT: 6"= 1.46 G/FT) 1 THREE STANDING WELL VOLUMES= 5.19 FIVE STANDING WELL VOLUMES= 8.65 METHOD OF WELL EVACUATION: BAIL /PUMP THER: TYPE TOTAL VOLUME OF WATER REMOVED: 60 GAL. ' WELL TYPE: FLUSH MOUNTE��x COMMENTS LOCKING CAP NO No sample collected/purged for PROTECTIVE POST/ABUTMENT YES X NO development only NONPOTABLE LABEL YES X NO ID PLATE YES X NO ' WELL INTEGRITY SATISFACTORY YES X NO WELL YIELD LOW MODERATE HIGH X Temp Cond. Dis.O= Turbidity ORP Time Volume pH Temp (µS/cm) (mg/L) (NTU) (mV) Notes 1 25 7.11 19.21 .087 .02 230 30 6.77 18.50 .068 .04 63 I 35 6.60 17.90 .060 .04 20 40 6.66 18.30 .058 .04 10 45 6.57 17.90 .055 .04 9 50 6.54 18.00 .053 .04 4 55 6.41 18.00 .050 .03 2 ' 60 6.40 17.30 .048 .04 2 MACTEC ' MACTEC ENGINEERING AND CONSULTING,INC. MONITORING WELL SAMPLING FIELD DATA WORKSHEET 1 MACTEC PROJECT NUMBER 6228-10-5284 MONITORING WELL NUMBER MW-11D SITE NAME Duke Marshall Steam Station DATE TIME OF SAMPLE N/A FIELD PERSONNEL Mark Filardi WEATHER CONDITIONS TOTAL WELL DEPTH(TWD) 93.32 FT. meas /well tag/drillers log—circle one) SCREENED INTERVAL 85.5-90.5 bas URING POINT FOR DEPTH Top of casing ' DEPTH TO GROUNDWATER(DGW) 43.40' LENGTH OF WATER COLUMN(LWC)=TWD—DGW= 49.92' CASING DIAMETER 2 IN. ONE STANDING WELL VOLUME= 8.14 gal. (NOTE%2"=0.0102G/FT: 3/,"=0.023 G/FT: 1"=0.041G/FT:2"=0.163 G/FT: 4"=0.653 G/FT: 6"= 1.46 G/FT) THREE STANDING WELL VOLUMES= 24.41 FIVE STANDING WELL VOLUMES= 40.70 METHOD OF WELL EVACUATION: BAILER<D OTHER: TYPE TOTAL VOLUME OF WATER REMOVED: 60 GAL. WELL TYPE: FLUSH MOUNT OVE GRAD COMMENTS LOCKING CAP X NO No sample collected/purged for ' PROTECTIVE POST/ABUTMENT YES X NO development only NONPOTABLE LABEL YES X NO IDPLATE YES X NO ' WELL INTEGRITY SATISFACTORY YES X NO WELL YIELD LOW MODERATE X HIGH tTemp Cond. Dis.02 Turbidity ORP Time Volume pH CC) (µS/cm) (mg/L) (NM (mom Notes ' 60 7.84 18.90 .071 .04 4.80 OMACTEC MACTEC ENGINEERING AND CONSULTING,INC. MONITORING WELL SAMPLING FIELD DATA WORKSHEET 1 MACTEC PROJECT NUMBER 6228-10-5284 MONITORING WELL NUMBER MW-10S SITE NAME Duke Marshall Steam Station DATE TIME OF SAMPLE N/A 1 FIELD PERSONNEL Mark Filardi WEATHER CONDITIONS TOTAL WELL DEPTH(TWD) 29.44 FT.0(�/well tag/drillers log—circle one) SCREENED INTERVAL 12-27 bias MEASURING POINT FOR DEPTH top of casing ' DEPTH TO GROUNDWATER(DGW) 16.64 below TOC LENGTH OF WATER COLUMN(LWC)=TWD—DGW= 12.80 CASING DIAMETER 2 IN. IONE STANDING WELL VOLUME= 2.09 gal. (NOTE %"=0.0102G/FT: N"=0.023 G/FT: I"=0.041 G/FT:2"=0.163 G/FT: 4"=0.653 G/FT: 6"= 1.46 G/FT) THREE STANDING WELL VOLUMES= 6.26 FIVE STANDING WELL VOLUMES= 10.45 METHOD OF WELL EVACUATION: BAILER UMP OTHER: TYPE TOTAL VOLUME OF WATER REMOVE] • 60 GAL. ' WELL TYPE: FLUSH MOUNT/ OVE GRADE COMMENTS LOCKING CAP X NO No sample collected/Raged for ' PROTECTIVE POST!ABUTMENT YES NO X development only NONPOTABLE LABEL YES X NO ID PLATE YES X NO WELL INTEGRITY SATISFACTORY YES X NO WELL YIELD LOW MODERATE HIGH X ' Temp Cond. Dis.02 Turbidity ORP Time Volume pd (°C) (µS/cm) (mg/L) (NTU) (mom Notes 1 40 6.13 19.40 0.163 0.01 14 45 6.09 18.20 .067 0.01 3 ' 50 6.11 18.00 .057 0.01 1 55 5.96 17.20 .051 0.01 1 60 5.97 17.50 .048 0.01 1 1 1 MACTEC MACTEC ENGINEERING AND CONSULTING, INC. MONITORING WELL SAMPLING FIELD DATA WORKSHEET 1 MACTEC PROJECT NUMBER 6228-10-5284 MONITORING WELL NUMBER MW-IOD SITE NAME Duke Marshall Steam Station DATE TIME OF SAMPLE N/A FIELD PERSONNEL Mark Filardi WEATHER CONDITIONS TOTAL WELL DEPTH(TWD) 87.69 (measured well tag/drillers log-circle one) SCREENED INTERVAL 80.4-85.4 bgs MEASURING POINT FOR DEPTH Top of casing DEPTH TO GROUNDWATER(DGW) 16.23 LENGTH OF WATER COLUMN(LWC)=TWD-DGW= 71.46 CASING DIAMETER 2 IN. ' ONE STANDING WELL VOLUME= 11.65 gal. (NOTE 1/2"=0.0102G/FT: Y4"=0.023 G/FT: 1"=0.041G/FT:2"=0.163 G/FT: 4"=0.653 GIFT: 6"= 1.46 G/FT) THREE STANDING WELL VOLUMES 39.94 FIVE STANDING WELL VOLUMES= 58.25 METHOD OF WELL EVACUATION: BAILER(9/OTHER: TYPE TOTAL VOLUME OF WATER REMO 80 GAL. ' WELL TYPE: FLUSH MOUNT ABOVE GPDX COMMENTS LOCKING CAP NO No sample collected/puMged for ' PROTECTIVE POST/ABUTMENT YES NO X development only NONPOTABLE LABEL YES X NO ID PLATE YES X NO WELL INTEGRITY SATISFACTORY YES X NO WELL YIELD LOW MODERATE HIGH X Temp Cond. Dis.02 Turbidity ORP Time Volume pH (°C) (µS/cm) (mg/L) (NTU) (mom Notes I30 6.82 20.10 .090 11.38 320 35 6.80 19.70 .082 11.38 183 ' 40 6.73 19.60 .077 11.38 172 45 6.63 18.70 .073 0.03 144 ' 50 6.63 19.00 .071 0.02 124 55 6.63 18.70 .070 0.05 140 60 6.98 18.30 .107 11.28 90 ' 65 6.78 17.80 .078 .003 58 70 6.62 17.70 .068 11.96 5 75 6.65 18.00 .065 0.04 2 80 6.62 17.60 .065 11.59 5 1 MACTEC MACTEC ENGINEERING AND CONSULTING, INC. MONITORING WELL SAMPLING FIELD DATA WORKSHEET 1 MACTEC PROJECT NUMBER 6228-10-5284 MONITORING WELL NUMBER MW-14S SITE NAME Duke Marshall Steam Station DATE TIME OF SAMPLE N/A FIELD PERSONNEL Mark Filardi WEATHER CONDITIONS TOTAL WELL DEPTH(TWD) 47.13 FT (measured well tag/drillers log-circle one) SCREENED INTERVAL 28-43 bgs ASURING POINT FOR DEPTH Top of casine DEPTH TO GROUNDWATER(DGW) 36.36 LENGTH OF WATER COLUMN(LWC)=TWD-DGW= 10.77 CASING DIAMETER 2 IN. ONE STANDING WELL VOLUME= 1.76 gal. (NOTE%:"=0.0102G/FT: Y4"=0.023 G/FT: 1"=0.041 G/FT:2"=0.163 G/FT: 4"=0.653 G/FT: 6"= 1.46 G/FT) ' THREE STANDING WELL VOLUMES= 5.27 FIVE STANDING WELL VOLUMES= 8.80 METHOD OF WELL EVACUATION: BAILER e OTHER: TYPE TOTAL VOLUME OF WATER REMO 90 GAL. ' WELL TYPE: FLUSH MOUNT ABOVE GRADE COMMENTS LOCKING CAP X NO No sample collected/purggd for ' PROTECTIVE POST/ABUTMENT YES NO X development only NONPOTABLE LABEL YES X NO ID PLATE YES X NO WELL INTEGRITY SATISFACTORY YES X NO WELL YIELD LOW MODERATE HIGH X ' Temp Cond. Dis.0, Turbidity ORP Time Volume PH (°C) (µS/cm) (mg/L) (NTU) (mV) Notes 40 5.96 18.50 .839 13.17 538 45 5.64 17.70 .857 12.55 138 ' 50 5.59 17.60 .855 .03 100 55 5.60 17.50 .866 .01 117 ' 60 5.55 17.50 .870 .00 27 65 5.56 17.50 0.91 12.35 27 DO malfunction 70 5.60 17.50 0.92 11.50 20 75 5.50 1 16.60 0.92 .02 20 80 5.49 17.00 0.93 .02 250 85 5.52 17.60 0.92 15.97 10 90 5.47 17.60 0.93 12.30 23 Ash Basin Monitoring Well Installation Report August 26,2010 Marshall Steam Station Terrell, Catawba County,North Carolina MACTEC Project 6228-10-5284 ' APPENDIX E PHOTOGRAPHS OF COMPLETED WELL PAIRS 1 Photo •. � ��'r'} �- a _ ;� ..tom_ ♦ .� .. Jwr . _........�,�-- Photo •. t - - Photo •. 1MW-14D(Right) r Photo •. • ' Photo 5: Well pair MW-I OS (Right)and MW-I OD Ash Basin Monitoring Well Installation Report August 26,2010 Marshall Steam Station Terrell,Catawba County,North Carolina MACTEC Project 6228-10-5284 APPENDIX F SLUG TEST DATA 1 r t 1 1 1. ❑❑CIO ❑❑❑❑❑❑❑ ❑ ❑ ❑ ❑ ❑ ❑ ❑ ❑ ❑ ❑ ❑ ❑ rt- 0.1 ❑ ❑ ❑ c E U (II Q .a O E 1 O C 0.01 f0 I-- i 0.001 0. 200. 400. 600. 800. 1000. Time (sec) ' RISING HEAD TEST PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-14S ' Test Date: 8/16/2010 AQUIFER DATA ' Saturated Thickness: 10.77 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-14S) ' Initial Displacement: 1.06 ft Static Water Column Height: 10.77 ft Total Well Penetration Depth: 10.77 ft Screen Length: 10.77 ft Casing Radius: 0.0833 ft Well Radius: 0.26 ft ' Gravel Pack Porosity: 0.28 SOLUTION ' Aquifer Model: Unconfined Solution Method: Dagan K = 0.0008911 cm/sec y0 = 0.5161 ft ' 10. c CD E 1. m a LA °°° ° °°°°° ° ° ° ° ° ° ° ° ° ° 0.1 ° ° ° ° ° 0. 200. 400. 600. 800. 1000. Time (sec) RISING HEAD TEST ' PROJECT INFORMATION Company: MACTEC Client: Duke Energy ' Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-14S Test Date: 8/16/2010 AQUIFER DATA 1 Saturated Thickness: 10.77 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA (MW-14S) Initial Displacement: 1.06 ft Static Water Column Height: 10.77 ft Total Well Penetration Depth: 10.77 ft Screen Length: 10.77 ft Casing Radius: 0.0833 ft Well Radius: 0.26 ft Gravel Pack Porosity: 0.28 SOLUTION Aquifer Model: Unconfined Solution Method: Bouwer-Rice K = 0.0009566 cm/sec y0 = 0.6086 ft l i ' 10. 1. c a� E a� f0 a 0.1 ° ° ° ° j 0.01 0. 140. 280. 420. 560. 700. Time (sec) RISING HEAD TEST PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-14D Test Date: 8/16/2010 AQUIFER DATA ' Saturated Thickness: 25.87 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA (MW-14D) Initial Displacement: 1.111 ft Static Water Column Height: 25.87 ft Total Well Penetration Depth: 25.87 ft Screen Length: 5. ft Casing Radius: 0.0833 ft Well Radius: 0.157 ft 1 Gravel Pack Porosity: 0.28 SOLUTION Aquifer Model: Unconfined Solution Method: Hvorslev K = 0.0006479 cm/sec y0 = 0.8376 ft t 10. t 1. tc Q E -- U (a a D 0.113 ° ° ° 13 i t 0.01 0. 140. 280. 420. 560. 700. Time (sec) ' RISING HEAD TEST PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-14D tTest Date: 8/16/2010 AQUIFER DATA tSaturated Thickness: 25.87 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-14D) Initial Displacement: 1.111 ft Static Water Column Height: 25.87 ft Total Well Penetration Depth: 25.87 ft Screen Length: 5. ft Casing Radius: 0.0833 ft Well Radius: 0.157 ft Gravel Pack Porosity: 0.28 SOLUTION Aquifer Model: Unconfined Solution Method: Bouwer-Rice K = 0.0006015 cm/sec y0 = 0.9218 ft t 1. ❑ c ° 00000000 ❑ E 0.1 ❑ 0 13 ° ' ❑ ❑ ❑ ❑ ❑ CL 0.01 I 0. 400. 800. 1.2E+3 1.6E+3 2.0E+3 Time (sec) 1 RISING HEAD TEST PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-13S 1 Test Date: 8/16/2010 AQUIFER DATA 1 Saturated Thickness: 15.42 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-13S) Initial Displacement: 0.954 ft Static Water Column Height: 15.42 ft Total Well Penetration Depth: 15.42 ft Screen Length: 15. ft Casing Radius: 0.0833 ft Well Radius: 0.26 ft Gravel Pack Porosity: 0.28 SOLUTION Aquifer Model: Unconfined Solution Method: Hvorslev K = 0.0002725 cm/sec y0 = 0.4048 ft 1 1 1. 1 °°° °°°°°°°° ° w- ° 0.1 ° ° ° C ° ° ° ° CD CE aD U CL 1 0 ° E 1 ° 0.01 12 0.001 I 0. 400. 800. 1.2E+3 1.6E+3 2.0E+3 Time (sec) RISING HEAD TEST 1PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-09-5100 Location: Marshall Steam Station Test Well: MW-13S 1 Test Date: 8/16/2010 AQUIFER DATA Saturated Thickness: 15.42 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA (MW-13S) Initial Displacement: 0.954 ft Static Water Column Height: 15.42 ft Total Well Penetration Depth: 15.42 ft Screen Length: 15. ft Casing Radius: 0.0833 ft Well Radius: 0.0833 ft Gravel Pack Porosity: 0.28 SOLUTION Aquifer Model: Unconfined Solution Method: Dagan K = 7.376E-5 cm/sec y0 = 0.4439 ft 1 1. 1 � �. ❑❑ ❑ c ° ❑❑°❑ ❑ ❑° ° ❑ ° ❑ aE ❑i 0.1 ❑ ° ❑ ❑ f� CL N 1 1 0.01 0. 400. 800. 1.2E+3 1.6E+3 2.0E+3 Time (sec) ' RISING HEAD TEST 1PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-13S Test Date: 8/16/2010 AQUIFER DATA 1 Saturated Thickness: 15.42 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-13S) Initial Displacement: 0.954 ft Static Water Column Height: 15.42 ft Total Well Penetration Depth: 15.42 ft Screen Length: 15. ft Casing Radius: 0.0833 ft Well Radius: 0.26 ft Gravel Pack Porosity: 0.28 SOLUTION Aquifer Model: Unconfined Solution Method: Bouwer-Rice K = 0.0002399 cm/sec y0 = 0.5024 ft 1 1. c CD 0.1 1 U O ° ❑ 0 ❑ ° ❑ ❑ iEl ❑ 1 ° 0.01 ' 0. 400. 800. 1.2E+3 1.6E+3 2.0E+3 Time (sec) RISING HEAD TEST PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-13D Test Date: 8/16/2010 AQUIFER DATA Saturated Thickness: 45.02 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-13D) 1 Initial Displacement: 0.837 ft Static Water Column Height: 45.02 ft Total Well Penetration Depth: 45.02 ft Screen Length: 5. ft Casing Radius: 0.0833 ft Well Radius: 0.157 ft Gravel Pack Porosity: 0.28 SOLUTION Aquifer Model: Unconfined Solution Method: Hvorslev K = 0.0007045 cm/sec y0 = 0.5309 ft 1 1. i 0.1 � 1 C CL ° o ° i ° °°°° ° ° ° ° 1 ° ° ° 1 ° 0.01 ' 0. 400. 800. 1.2E+3 1.6E+3 2.0E+3 Time (sec) 1 RISING HEAD TEST PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-13D Test Date: 8/16/2010 AQUIFER DATA ISaturated Thickness: 45.02 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA (MW-13D) Initial Displacement: 0.837 ft Static Water Column Height: 45.02 ft Total Well Penetration Depth: 45.02 ft Screen Length: 5. ft Casing Radius: 0.0833 ft Well Radius: 0.157 ft iGravel Pack Porosity: 0.28 SOLUTION Aquifer Model: Unconfined Solution Method: Bouwer-Rice K = 0.0007923 cm/sec y0 = 0.6391 ft 1 10. 1. Ic a� E 1 � U tC CL _T) ' ° °O° °O❑❑❑ ❑ ❑ ° 1 0.01 ' 0. 400. 800. 1.2E+3 1.6E+3 2.0E+3 Time (sec) ' RISING HEAD TEST PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-12S Test Date: 8/16/2010 AQUIFER DATA Saturated Thickness: 11.04 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-12S) 1 Initial Displacement: 1.257 ft Static Water Column Height: 11.04 ft Total Well Penetration Depth: 11.04 ft Screen Length: 11.04 ft Casing Radius: 0.0833 ft Well Radius: 0.26 ft 1 Gravel Pack Porosity: 0.28 SOLUTION Aquifer Model: Unconfined Solution Method: Hvorslev K = 0.001445 cm/sec y0 = 0.3676 ft 0.1 � ❑❑❑❑❑❑°❑❑ ❑ ❑ ❑ I E ° ❑ U ❑ fC a N v m E 1 0.01 ca i 1 0.001 1 0. 400. 800. 1.2E+3 1.6E+3 2.0E+3 Time (sec) ' RISING HEAD TEST PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-12S 1 Test Date: 8/16/2010 AQUIFER DATA ' Saturated Thickness: 11.04 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA (MW-12S) ' Initial Displacement: 1.257 ft Static Water Column Height: 11.04 ft Total Well Penetration Depth: 11.04 ft Screen Length: 11.04 ft Casing Radius: 0.0833 ft Well Radius: 0.26 ft Gravel Pack Porosity: 0.28 SOLUTION ' Aquifer Model: Unconfined Solution Method: Dagan K = 0.001787 cm/sec y0 = 0.4844 ft ' 10. 1 1. C a� E U N Q _Ln 0 �O❑ ❑ 0.1 00❑ ° ❑ ❑ ° ❑ ❑ 0.01 0. 400. 800. 1.2E+3 1.6E+3 2.0E+3 Time (sec) ' RISING HEAD TEST PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-12S Test Date: 8/16/2010 AQUIFER DATA ' Saturated Thickness: 11.04 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA (MW-12S) ' Initial Displacement: 1.257 ft Static Water Column Height: 11.04 ft Total Well Penetration Depth: 11.04 ft Screen Length: 11.04 ft Casing Radius: 0.0833 ft Well Radius: 0.26 ft ' Gravel Pack Porosity: 0.28 SOLUTION 1 Aquifer Model: Unconfined Solution Method: Bouwer-Rice K = 0.001557 cm/sec y0 = 0.4443 ft 1 c m E ' o m o N_ 1 1 0.1 ' 0. 400. 800. 1.2E+3 1.6E+3 2.0E+3 Time (sec) RISING HEAD TEST 1PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-12D ' Test Date: 8/16/2010 AQUIFER DATA Saturated Thickness: 83.38 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-12D) ' Initial Displacement: 1. ft Static Water Column Height: 83.38 ft Total Well Penetration Depth: 83.38 ft Screen Length: 5. ft Casing Radius: 0.0833 ft Well Radius: 0.157 ft ' Gravel Pack Porosity: 0.28 SOLUTION Aquifer Model: Unconfined Solution Method: Hvorslev K = 0.0001302 cm/sec y0 = 0.8428 ft I 1. ° ° c a� U fC � a o 1 0.1 ' 0. 400. 800. 1.2E+3 1.6E+3 2.0E+3 Time (sec) ' RISING HEAD TEST 1PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-12D ' Test Date: 8/16/2010 AQUIFER DATA ' Saturated Thickness: 83.38 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-12D) ' Initial Displacement: 1. ft Static Water Column Height: 83.38 ft Total Well Penetration Depth: 83.38 ft Screen Length: 5. ft Casing Radius: 0.0833 ft Well Radius: 0.157 ft Gravel Pack Porosity: 0.28 ?ECEIVED/DEN DWR SOLUTION OCT 1 5 201 ' Aquifer Model: Unconfined Solution Method: Bouwer-Rice a water Quality K = 0.0001336 cm/sec y0 = 0.8583 ft Permitting Seco n ❑ ❑ 0 ❑ ❑ c� a� Eb n 0.1 CP, ❑ N ❑ ❑ ❑ ❑ ❑❑ (0 ❑ E ❑ ° ❑ ❑ ❑ ❑ Z ° ❑ ❑ ❑ ❑ 0.01 ' 0. 180. 360. 540. 720. 900. Time (sec) ' RISING HEAD TEST ' PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-11S ' Test Date: 8/16/2010 AQUIFER DATA ' Saturated Thickness: 10.61 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-11S) ' Initial Displacement: 0.955 ft Static Water Column Height: 10.61 ft Total Well Penetration Depth: 10.61 ft Screen Length: 10.61 ft Casing Radius: 0.0833 ft Well Radius: 0.26 ft Gravel Pack Porosity: 0.28 SOLUTION ' Aquifer Model: Unconfined Solution Method: Hvorslev K = 0.002047 cm/sec y0 = 0.3804 ft 1 ° 1 0.1 °° ° ° E ° °° °°° E ° ° ° ° ° ° ° m ° ° ° Q ° a� E 1 O 0.01 c� 1 0.001 ' 0. 180. 360. 540. 720. 900. Time (sec) ' RISING HEAD TEST PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-11S ' Test Date: 8/16/2010 AQUIFER DATA ' Saturated Thickness: 10.61 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-11S) ' Initial Displacement: 0.955 ft Static Water Column Height: 10.61 ft Total Well Penetration Depth: 10.61 ft Screen Length: 10.61 ft Casing Radius: 0.0833 ft Well Radius: 0.26 ft ' Gravel Pack Porosity: 0.28 SOLUTION ' Aquifer Model: Unconfined Solution Method: Dagan K = 0.001285 cm/sec y0 = 0.387 ft ❑ ❑ 0 (C � N Eb 0.1 OCP 0, N ❑ ❑ ❑ N ❑ ❑ ° ❑ ❑ ❑ ❑ o ❑ ❑ ❑ ❑ ❑ ❑ ❑ Z 1 i 0.01 ' 0. 180. 360. 540. 720. 900. Time (sec) ' RISING HEAD TEST ' PROJECT INFORMATION Company: MACTEC Client: Duke Energy ' Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-11S ' Test Date: 8/16/2010 AQUIFER DATA ' Saturated Thickness: 10.61 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-11 S) Initial Displacement: 0.955 ft Static Water Column Height: 10.61 ft Total Well Penetration Depth: 10.61 ft Screen Length: 10.61 ft Casing Radius: 0.0833 ft Well Radius: 0.26 ft Gravel Pack Porosity: 0.28 SOLUTION ' Aquifer Model: Unconfined Solution Method: Bouwer-Rice K = 0.00154 cm/sec y0 = 0.4687 ft 1 1 0.1 ° aD E o Z 1 1 0.01 ' 0. 1.4E+3 2.8E+3 4.2E+3 5.6E+3 7.0E+3 Time (sec) RISING HEAD TEST ' PROJECT INFORMATION Company: MACTEC Client: Duke Energy ' Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-11D ' Test Date: 8/16/2010 AQUIFER DATA ' Saturated Thickness: 49.92 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-11 D) ' Initial Displacement: 2.627 ft Static Water Column Height: 49.92 ft Total Well Penetration Depth: 49.92 ft Screen Length: 5. ft Casing Radius: 0.0833 ft Well Radius: 0.157 ft Gravel Pack Porosity: 0.28 SOLUTION ' Aquifer Model: Unconfined Solution Method: Hvorslev K = 3.448E-5 cm/sec y0 = 1.08 ft 1 1 1 ° ami ° ° ° -0 0.1 13° N E L 1 0 Z 1 0.01 t 0. 1.4E+3 2.8E+3 4.2E+3 5.6E+3 7.0E+3 Time (sec) ' RISING HEAD TEST ' PROJECT INFORMATION Company: MACTEC Client: Duke Energy ' Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-11D ' Test Date: 8/16/2010 AQUIFER DATA ' Saturated Thickness: 49.92 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-11 D) ' Initial Displacement: 2.627 ft Static Water Column Height: 49.92 ft Total Well Penetration Depth: 49.92 ft Screen Length: 5. ft Casing Radius: 0.0833 ft Well Radius: 0.157 ft ' Gravel Pack Porosity: 0.28 SOLUTION ' Aquifer Model: Unconfined Solution Method: Bouwer-Rice K = 3.428E-5 cm/sec y0 = 1.1 ft 1 ' 10. 1. 1 c m aEi U fC Q to ❑ 0.1 ❑ ❑❑ ❑ ❑ 0 ❑ ❑ ❑ ❑ ❑ ❑ ❑ 0.01 1 0. 160. 320. 480. 640. 800. Time (sec) ' RISING HEAD TEST PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-10S ' Test Date: 8/16/2010 AQUIFER DATA ' Saturated Thickness: 12.8 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-10S) ' Initial Displacement: 1.506 ft Static Water Column Height: 12.8 ft Total Well Penetration Depth: 12.8 ft Screen Length: 12.8 ft Casing Radius: 0.0833 ft Well Radius: 0.26 ft ' Gravel Pack Porosity: 0.28 SOLUTION Aquifer Model: Unconfined Solution Method: Hvorslev K = 0.001361 cm/sec y0 = 0.7673 ft 1. 1 � _ c 0.1 ❑ 113 E ° U ❑❑ ❑ fD 0 (3 C, ❑ CL 13 ° ❑ ❑ N E 1 0.01 f6 L 1 0.001 ' 0. 160. 320. 480. 640. 800. Time (sec) RISING HEAD TEST PROJECT INFORMATION Company: MACTEC Client: Duke Energy 1 Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-10S Test Date: 8/16/2010 AQUIFER DATA 1 Saturated Thickness: 12.8 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-10S) 1 Initial Displacement: 1.506 ft Static Water Column Height: 12.8 ft Total Well Penetration Depth: 12.8 ft Screen Length: 12.8 ft Casing Radius: 0.0833 ft Well Radius: 0.26 ft 1 Gravel Pack Porosity: 0.28 SOLUTION 1 Aquifer Model: Unconfined Solution Method: Dagan K = 0.0009221 cm/sec y0 = 0.7748 ft 1 ' 10. 1. c a� E U f0 CL to ❑ 0.1 ° ❑ ❑ ❑ ❑ ❑ ° ❑ 0.01 ' 0. 160. 320. 480. 640. 800. Time (sec) 1 RISING HEAD TEST ' PROJECT INFORMATION Company: MACTEC Client: Duke Energy ' Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-10S Test Date: 8/16/2010 AQUIFER DATA 1 Saturated Thickness: 12.8 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-10S) Initial Displacement: 1.506 ft Static Water Column Height: 12.8 ft Total Well Penetration Depth: 12.8 ft Screen Length: 12.8 ft Casing Radius: 0.0833 ft Well Radius: 0.26 ft ' Gravel Pack Porosity: 0.28 SOLUTION ' Aquifer Model: Unconfined Solution Method: Bouwer-Rice K = 0.000749 cm/sec y0 = 0.7498 ft ' 10. c a� 1. co CL Mn D ❑ ❑ ❑ ❑ 1 0.1 0. 400. 800. 1.2E+3 1.6E+3 2.0E+3 Time (sec) 1 RISING HEAD TEST PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-10D Test Date: 8/16/2010 AQUIFER DATA Saturated Thickness: 71.46 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-10D) ' Initial Displacement: 1.148 ft Static Water Column Height: 71.46 ft Total Well Penetration Depth: 87.69 ft Screen Length: 5. ft Casing Radius: 0.0833 ft Well Radius: 0.157 ft ' Gravel Pack Porosity: 0.28 SOLUTION ' Aquifer Model: Unconfined Solution Method: Hvorslev K = 0.0001192 cm/sec y0 = 0.856 ft 1 ' 10. c m (D 1. i CIO U CL M ❑ ❑ ❑ ❑ 0.1 0. 400. 800. 1.2E+3 1.6E+3 2.0E+3 Time (sec) RISING HEAD TEST PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-10D ' Test Date: 8/16/2010 AQUIFER DATA Saturated Thickness: 71.46 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA (MW-10D) 1 Initial Displacement: 1.148 ft Static Water Column Height: 71.46 ft Total Well Penetration Depth: 87.69 ft Screen Length: 5. ft Casing Radius: 0.0833 ft Well Radius: 0.157 ft ' Gravel Pack Porosity: 0.28 SOLUTION 1 Aquifer Model: Unconfined Solution Method: Bouwer-Rice K = 0.0001129 cm/sec y0 = 0.8209 ft 10. Ic a� E 1. U f0 CL M ❑ ❑ ❑ 1 ❑ ❑❑❑ ° ❑ ❑ ❑ ❑ ❑ ❑ ❑1 1 ❑ 0.1 ' 0. 200. 400. 600. 800. 1000. Time (sec) 1 RISING HEAD TEST PROJECT INFORMATION Company: MACTEC Client: Duke Energy Project: 6228-10-5284 Location: Marshall Steam Station Test Well: MW-14S Test Date: 8/16/2010 AQUIFER DATA ' Saturated Thickness: 10.77 ft Anisotropy Ratio (Kz/Kr): 1. WELL DATA(MW-14S) 1 Initial Displacement: 1.06 ft Static Water Column Height: 10.77 ft Total Well Penetration Depth: 10.77 ft Screen Length: 10.77 ft Casing Radius: 0.0833 ft Well Radius: 0.26 ft Gravel Pack Porosity: 0.28 SOLUTION ' Aquifer Model: Unconfined Solution Method: Hvorslev K = 0.001007 cm/sec y0 = 0.4034 ft ' Appendix B - Permit Condition A(11 ) Attachment ' XX, Version 1 .1 , June 15, 2011 A. (6)GROUNDWATER MONITORING WELL CONSTRUCTION AND SAMPLING I 1. The permittee shall conduct groundwater monitoring as may be required to determine the compliance of this NPDES permitted facility with the current groundwater Standards found under 15A NCAC 2L.0200 ' 2. WELL CONSTRUCTION. Within 120 days of permit issuance, monitoring wells, as proposed on Attachment XX,shall be installed to monitor groundwater quality. a. Monitoring wells shall be constructed in accordance with 15A NCAC 02C .0108 ' (Standards of Construction for Wells Other than Water Supply) and any other jurisdictional laws and regulations pertaining to well construction. The general locations for all monitoring wells are indicated on Attachment XX. b. Within 30 days of completion of well construction, a completed Well Construction Record (Form GW-1) must be submitted for each monitoring well to Division of Water Quality, Aquifer Protection Section, 1636 Mail Service Center, Raleigh, NC 27699-1636. C. The Mooresville Regional Office, telephone number (704) 663-1699, shall approve the location of new monitoring wells prior to installation. The regional office shall be notified at least 48 hours prior to the construction of any ' monitoring well and such notification to the Aquifer Protection Section's regional supervisor shall be made from 8:00 a.m. until 5:00 p.m. on Monday through Friday,excluding State Holidays. ' d. Within 60 days of completion of the monitoring wells, the Permittee shall submit two original copies of a site map with a scale no greater than 1-inch equals 500 feet. At a minimum, the map shall include the following ' information: L The location and identity of each monitoring well. ii. The location of major components of the waste disposal system. iii. The location of property boundaries within 500 feet of the disposal a yeas. iv. The latitude and longitude of the established horizontal control monument. V. The elevation of the top of the well casing (i.e., measuring point) relative to a common datum. vi. The depth of water below the measuring point at the time the measuring point is established. vii. The location of compliance and review boundaries. viii. The date the map is prepared and/or revised. ix. Topographic contours in no more than ten(10)foot intervals e. The above information should be overlaid on the most recent aerial photograph taken of the site. Control monuments shall be installed in such a manner and ' made of such materials that the monument will not be destroyed due to activities taking place on the property. The map and any supporting documentation shall be sent to the Division of Water Quality,Aquifer Protection Section, 1636 Mail Service Center, Raleigh,NC 27699-1636. f. The well(s) must be constructed by a North Carolina Certified Well Contractor, the property owner, or the property lessee according to General Statutes 87- 98.4. If the construction is not performed by a certified well contractor, the ' property owner or lessee, provided they are a natural person, must physically perform the actual well construction activities. NC0004987—Marshall Steam Station Groundwater Monitoring Plan Page ] of4 6/15!11 g. The monitoring wells shall be regularly maintained. Such maintenance shall ' include ensuring that the well caps are rust-free and locked at all times, the outer casing is upright and undamaged,and the well does not serve as a conduit for contamination. 3. GROUNDWATER SAMPLING AND COMPLIANCE. Monitoring wells shall be sampled after construction and thereafter at the frequencies and for the parameters as specified in Attachment XX. All maps, well construction forms, well abandonment forms and ' monitoring data shall refer to the permit number and the well nomenclature as provided on Attachment XX. a. Per 15A NCAC 02H .0800, a Division certified laboratory shall conduct all ' laboratory analyses for the required effluent, groundwater or surface water parameters. b. The measurement of water levels shall be made prior to purging the wells. The depth to water in each well shall be measured from the surveyed point on the ' top of the casing. The measurement of pH shall be made after purging and prior to sampling for the remaining parameters. C. The measuring points (top of well casing) of all monitoring wells shall be ' surveyed to provide the relative elevation of the measuring point for each monitoring well. The measuring points (top of casing) of all monitoring wells shall be surveyed relative to a common datum. ' d. For monitoring wells that are not located at the Compliance Boundary, the Compliance Monitoring Form (GW-59CCR) is not required. However, predictive calculations or modeling shall be submitted to the Regional Office annually (i.e. 1 12 months after permit issuance) demonstrating groundwater quality standards at the Compliance Boundary. e. Two copies of the monitoring well sampling shall be submitted on a Compliance ' Monitoring Form (GW-59CCR), and received no later than the last working day of the month following the sampling month. Copies of the laboratory analyses shall be kept on site, and made available upon request. The Compliance Monitoring Form (GW-59CCR) shall include this permit number and the appropriate well identification number. All information shall be submitted to the following address: Division of Water Quality Information Processing Unit 1617 Mail Service Center Raleigh, North Carolina 27699-1617 f. For groundwater samples that exceed the ground water quality standards in ' 15A NCAC 02L.0202,the Regional Office shall be contacted within 30 days after submission of the groundwater monitoring report; an evaluation may be required to determine the impact of the waste disposal activities. Failure to do so may subject the permittee to a Notice of Violation,fines,and/or penalties. ' NC0004987 Marshall Steam Station Groundwater Monitoring Plan Page 2 of 4 6-15 11 1 1 4. COMPLIANCE BOUNDARY. The compliance boundary for the disposal system shall be specified in accordance with 15A NCAC 02L .0107(a). This disposal system was individually permitted prior to December 30, 1983; therefore, the compliance boundary is established at either 500 feet from the effluent disposal area, or at the property 1 boundary, whichever is closest to the effluent disposal area. An exceedance of groundwater standards at or beyond the compliance boundary is subject to remediation action according to 15A NCAC 02L.0106(c)as well as enforcement actions in accordance ' with North Carolina General Statute 143-215.6A through 143-215.6C. � i 1 1 1 1 r 1 1 NC0004987-Marshall Steam Station Groundwater Monitoring Plan Page 3 of 4 6 15 11 1 1 ATTACHMENT XX— GROUNDWATER MONITORING PLAN Permit Number: NC0004987 Version 1.1 WELL PARAMETER DESCRIPTION FREQUENCY ' NOMENCLATURE Monitoring Wells: Antimony Chromium Nickel Thallium MW4,MW-4D,MW-10S, Arsenic Copper Nitrate Water Level 1 MW- 101),MW-11S,MW- Barium Iron pH Zinc February,June, 111),MW-12S,MWA 21), Boron Lead Selenium October MW-13S,MW-13D,MW- Cadmium Manganese Sulfate 14S,MW-34D Chloride Mercury TDS Note 1: For locations of monitoring wells,see attached map. ' Note 2: Monitoring revisions may be considered,as applicable, if there are no significant detections prior to permit renewal. i 1 1 ' NC0004987—Marshall Steam Station Groundwater Monitoring Plan Page 4 of 4 6 15111 µe- jl • V ��80�9899868� •� ` n COOMBE { tQ I � Appendix C - Monitoring Well Locations 1 � 1 0"411-377814 Marsha//Steam Station Monitoring We//Locations Description Northing Eastina Elevation Description Elevatiom TOP OF PVC MW4D 686715.82 1414462.36 866.74 MAG NAIL SET MW4D 863.38 ' TOP OF PVC MW-4S 686723.33 1414467.78 866.42 MAG NAIL SET MW-4S 864.26 TOP OF PVC MW-61D 682253.49 1417831.24 791.19 MAG NAIL SET MW-61) 788.16 TOP OF PVC MW-6S 682250.04 1417836.99 790.35 MAG NAIL SET MW-6S 787.47 ' TOP OF PVC MW-6 685227.06 1414674.45 919.65 MAG NAIL SET MW-6 917.18 TOP OF PVC MW-71) 681379.43 1417631.76 776.85 MAG NAIL SET MW-7D 773.04 TOP OF PVC MW-7S 681375.90 1417629.95 775.99 MAG NAIL SET MW-7S 773.11 TOP OF PVC MW-7 685380.11 1414418.05 859.16 MAG NAIL SET MW-7 856.56 TOP OF PVC MW-8D 680944.28 1417513.62 775.18 MAG NAIL SET MW-8D 771.42 TOP OF PVC MW-8S 680948.92 1417509.83 775.34 MAG NAIL SET MW-8S 771.65 ' TOP OF PVC MW-9D 680637.88 1417358.10 777.38 MAG NAIL SET MW-9D 774.35 TOP OF PVC MW-9S 680639.63 1417349.54 777.34 MAG NAIL SET MW-9S 774.28 TOP OF PVC MW-101) 681327.13 1418119.07 772.04 MAG NAIL SET MW-101) 770.00 TOP OF PVC MW-10S 681328.43 1418114.26 772.05 MAG NAIL SET MW-10S 769.75 TOP OF PVC MW-11D 682060.69 1411710.71 884.67 MAG NAIL SET MW-11D 882.12 TOP OF PVC MW-I IS 682062.41 1411706.21 884.99 MAG NAIL SET MW-11S 882.29 ' TOP OF PVC MW-12D 683409.20 1410712.50 871.88 MAG NAIL SET MW-12D 869.37 TOP OF PVC MW-12S 683414.08 1410714.04 871.86 MAG NAIL SET MW-12S 869.23 TOP OF PVC MW-13D 685017.16 1410464.23 847.05 MAG NAIL SET MW-13D 844.53 ' TOP OF PVC MW-13S 685021.83 1410462.33 847.49 MAG NAIL SET MW-13S 845.06 TOP OF PVC MW-14D 683626.47 1416999.23 811.43 MAG NAIL SET MW-14D 808.67 TOP OF PVC MW-14S 683629.12 1416995.37 811.29 MAG NAIL SET MW-14S 808.37 Notel:Coordinates shown are based on the North Carolina State Plane Coordinate System ' Note2: Horizontal Datum of NC Grid NAD 1983(NSRS 2007) Note3: Elevations shown are referenced to the NAVD 88 vertical datum Note4:Coordinates and elevations shown are in U.S.Survey Foot ' Note5: Coordinates and elevations shown only for as-built wells as requested by NCDENR Note6: Mag nails set in concrete base of each well for future elevation checks Note7:Survey information provided by Duke Energy 1 1