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Home My WebLink AboutSW_F_6204-MSWLF-1995_20081112_G-O5 (J Pic-� CC-j�p RUE. Uwharrie Regional MSW Landfill Design Hydrogeologic Report, Phase 4 LIST OF APPENDICES -MN o rle May 15, 2008 BLE Project Number J07-1002-74 Appendix A. Drilling and Sampling Procedures B. Field Logs of Borings C. Soil Test Boring/Rock Coring Records and Well Diagrams D. Piezometer Installation Procedures E. Precipitation and Groundwater Level Data & Charts F. Slug Test Procedures and Results G. Soil Laboratory Test Procedures H. Soil Laboratory Test Results I. Fracture Trace Analysis Data J. Surface Geophysical Methods and Data v IRLE C. Uwharrie Regional MSW Landfill May 15, 2008 Design Hydrogeologic Report, Phase 4 BLE Project Number J07-1002-74 REPORT CROSS-REFERENCE INDEX OF APPLICABLE NORTH CAROLINA STATE REGULATIONS 15A NCAC 13B .1623 (b) Design Hydrogeologic Report Requirements STATE REGULATIONS LOCATION IN REPORT b 1 A Sections 3.5.2.1, 3.6.3; Table 2; Figures 7, 10; Appendix E (b) (1) (B) Section 3.5; Tables 2, 3, 6, 7; Figures 6, 9, 10, 11; Appendices D, E, F (b) (2 A From 15A NCAC 13B .1623(a (a) (4) (A) Sections 2.1, 3.4.1; Appendices A, B, C (a) (4) (B) Sections 2.3, 3.4.4; Tables 4, 5; Appendices G, H a (4) (C) Sections 3.4.1, 3.4.4; Tables 4, 5; Appendices B, C, H (a) (4) (D) Sections 3.4; Tables 4, 5; Appendices B, C (a) (4) (E) Sections 3.4.4, 3.5.5; Tables 3, 4, 7; Appendices F, H a 5 Sections 2.4, 2.5, 3.4.2, 3.4.3; Figure 8; Appendices I, J (a) (6) Figure 6 a 7 (A) Table 2 (a) (7) (B) Table 2; Appendix E a) (7) (C) Section 3.5.2.2; Table 2; Figure 11; Appendix E (a) (7) (D) Sections 3.2, 3.5.2, 3.5.3, 3.5.4 (a) (8) Sections 3.5.5, 3.5.6; Tables 3, 6, 7; Figures 6, 9; Appendix F a (9) Figures 9, 10, 11 (a) (10 Figure 5 (a) (11) Appendices B, C (a) (12) Sections 3.3, 3.4.2, 3.4.3; Figure 8; Appendices I, J b 2 (B) Sections 3.4, 3.5, 4. 1; Tables 2, 3, 6, 7; Figures 6, 7, 8, 9, 10 (b) (2) (C) Sections 3.0, 4.1.2; Tables 2, 3, 6, 7; Figures 6, 7, 8, 9, 10 (b) (2) (D) Sections 2.1, 3.4.1.3, 3.4.2; Figure 7; Appendices B, C, I b (2) (E Figure 11 (b) (2) F) Figure 7 (b) (2) (G) Figure 6 b 2 H Section 3.5; Tables 2, 3, 6, 7; Figures 6, 8, 9, 10 (b) 2) (1) Section 2.2 (b) (3 (A) Section 4.1, 4.3; Figure 5 b (3) (B Section 4.2, 4.3; Figure 5 (b) (3) (C) I Signature page vi NIL VG. Uwharrie Regional MSW Landfill Design Hydrogeologic Report, Phase 4 May 15, 2008 BLE Project Number J07-1002-74 The vertical gradients observed at the site are typical for unconfined aquifers in the Piedmont. Groundwater recharge occurs in the upland areas in Phase 4, as well as west and south of Phase 4. Discharge occurs to Rocky Creek located north of Proposed Cell No. 14, and to the drainage feature east of Proposed Cell No. 13. 3.6 GEOTECHNICAL CONSIDERATIONS An evaluation of the potential impact from faults, seismic zones and unstable areas, as required by 15A NCAC 13B.1622, was previously prepared for the current landfill site and documented as part of the Site Hydrogeologic Report dated September 9, 1993 (LAW Job Number 2490472802). These items are briefly reviewed below to provide a background for our geotechnical evaluation. 3.6.1 Fault Areas No Holocene faults are located within 200 feet of the subject site (Horton and Zullo, 1991). 3.6.2 Seismic Impact Zones According to the definition of seismic impact zones in 15A NCAC 13B.1622 (5), this site is in a seismic impact zone. The maximum horizontal acceleration expressed as a percentage of the earth's gravity (g) in rock is 0.13g with a 2% probability of being exceeded in 50 years (equal to 10% probability in 250 years; Frankel and others, 2002). Design of the landfill should consider the seismic conditions; however, the magnitude of acceleration should not significantly impact the planned construction. In addition, BLE will perform seismic stability analysis for the design of Cells No. 13 and 14 at a later date once design grades have been prepared. 3.6.3 Unstable Areas An unstable area according to 15A NCAC 13B.1622 (6) is defined as a location that is susceptible to natural or human induced events or forces capable of impairing the integrity of some or all of the landfill structural components responsible for preventing releases from a landfill. Unstable areas could include poor foundation conditions, areas susceptible to mass movements, and karst terrains. Site and subsurface data obtained was evaluated to determine if unstable site areas exist. The site is not in a karst area. No unstable conditions were present. Subgrade settlements resulting from the proposed landfill loading will be well within tolerable limits. BLE will evaluate specific settlement and slope stability conditions for the Cells No. 13 and 14 area at a later date once landfill design grades have been prepared. 3.6.4 Permeability of Potential On -Site Soils for Liner and Cover Construction The permeability of selected potential on -site borrow soils were determined as indicated in Section 3.4.4.2 titled Laboratory Testing Results. Five bag samples of near surface soil were collected. The samples were compacted at varying percents of the Standard Proctor maximum dry density, and at varying moisture contents of the Standard Proctor optimum moisture content. Hydraulic conductivity values ranged from 7.4 x 10-8 to 4.6 x 10-7 cm/sec. The near surface soils at the site consist of three general soil types based on topographic position. The near surface soils in the higher elevation areas, including the upper portions of the hill side- 3-13 IBLE , Uwharrie Regional MSW Landfill May 15, 2008 Design Hydrogeologic Report, Phase 4 BLE Project Number A7-1002-74 slopes, consist of reddish -brown silty clay and clayey silt. These soils generally transition to light brown clayey silt along the lower elevations of the hill side -slopes. In the lowest elevations of the site, along the surface water drainage features, the aforementioned soils transition into gray sandy silt to silty sand. The red -brown silty clay and clayey silts along the higher portions of the site present the most favorable materials for use as compacted clay liner, soil liner, or closure cap soils. The plasticity of these soils fall generally along the "A" line. The silty clay soils are found immediately below the topsoil in limited quantity. More abundant clayey silts lie below the clay. Where encountered, these soils range in thickness from three to eighteen feet. Therefore, soils that could be used as compacted soil liner can be found over the majority of the site exclusive of the drainage fractures and lower elevation portions. During site clearing and stripping activities, these soils should be carefully delineated and stockpiled for later use. The in situ moistures of the silty clay will vary based on recent rainfall; however, they should be found at moisture contents within a few points of the standard Proctor optimum moisture content. Some modification of moisture will be required during soil liner or cap construction. 3.6.5 Excavation Excavation of the residual soils can be accomplished using conventional earth moving equipment. Historical excavation of the site has typically employed track excavators, dozers, and trucks. Some excavation has been performed using tractor scrapers. An estimated top of rock (auger refusal) contour map was developed as Figure 7 which is based on auger refusal depths in the soil borings drilled at this site. Materials sufficiently hard to cause refusal to the mechanical drill augers may result from continuous bedrock, boulders, lenses, ledges, or layers of relatively hard rock or residual soil. Coring was performed at five locations in the Phase 4 area where refusal to augering occurred. Continuous rock was found with varying recovery and Rock Quality Designation (RQD) as discussed above in Section 3.4.1.3. Due to its typically varying surface, the actual occurrence of hard rock during site grading may vary somewhat from that presented in Figure 7. There is usually no sharp distinction between soil and rock in residual soil areas as at this site. Typically, the degree of weathering simply decreases with greater depth until solid rock is eventually reached. The partially weathered rock, as well as the soil above, may also contain boulders, lenses or ledges of hard rock. The presence of scattered cobble size rock material in the residual surface soils was noted in the cleared fields. The mechanical auger used in this exploration could penetrate some of the partially weathered rock of the transitional zone. The ease of excavation will depend on the geologic structure of the material itself, such as the direction of bedding, planes or weakness and spacing between discontinuities. Weathered rock or rock that cannot be penetrated by the mechanical drill auger will likely require heavy excavating equipment with ripping tools or other methods for removal, if desired. 3.6.6 Engineered Fill The residual soils that will be excavated from the cell areas to achieve the design subgrade elevations are suitable for use as structural fill. Some moisture modification (wetting or drying) may be required depending on the particular area of excavation. Conventional compaction equipment and methods should be appropriate. 3-14 IRLE C. Uwharrie Regional MSW Landfill May 15, 2008 Design Hydrogeologic Report, Phase 4 BLE Project Number J07-1002-74 Fill used for raising site grades should be uniformly compacted to at least 95 percent of the standard Proctor maximum dry density (ASTM D 698). Partially weathered rock may be mixed with the soil borrow materials provided it can be broken down by the excavation and compaction equipment into particles with a maximum dimension of 6 inches. Larger boulders or rock pieces may be used in the lower portions of the deeper fills if the boulders are placed individually and soil compacted around and over each boulder. Sufficient quantities of soil should be mixed with the partially weathered rock so that voids do not result between the pieces of partially weathered rock and the fill meets the compaction requirements. Before filling operations begin, representative samples of each proposed fill materials should be collected and tested to determine the compaction and classification characteristics. The maximum dry density and optimum moisture content should be determined. Once compaction begins, a sufficient number of density tests should be performed to measure the degree of compaction being obtained. Earthwork cut or fill slopes can be constructed as steep as 2H:1 V (horizontal:vertical). Structural fill slopes at the 2H:1 V inclination should initially be constructed at two to three feet beyond the design slope due to difficulty of compacting the edge of slopes, then trimmed to final grade leaving the exposed face well compacted. Relatively flat slopes, on the order of 3H:1 V or flatter, can be compacted in place without overfilling. Cut and fill slope surfaces outside the cell area should be protected from erosion by grassing or other means. Where the cell embankment is to be constructed on natural slopes steeper than 4H:1 V, we recommend that the fill soils be keyed into the slopes using horizontal benches to facilitate placement and compaction of structural fill and to prevent formation of a potential slip surface. The surface of compacted subgrade soils can deteriorate and lose its support capabilities when exposed to environmental changes and construction activity. Deterioration can occur in the form of freezing, formation of erosion gullies, extreme drying, exposure for a long period of time, or rutting by construction traffic. We recommend that if the fill soils within the cell become deteriorated or softened, they be proofrolled, scarified and recompacted (and additional fill placed, if necessary) prior to construction of the compacted soil liner. Additionally, any excavations through the cell embankments (such as leachate collection line trenches) should be properly backfilled in compacted lifts. Recompaction of subgrade surfaces and compaction of backfll should be checked with a sufficient number of density tests to determine if adequate compaction is being achieved. 3-15 NILE_ Uwharrie Regional MSW Landfill May 15, 2008 Design Hydrogeologic Report, Phase 4 BLE Project Number J07-1002-74 5.0 CONCLUSIONS The proposed Phase 4 landfill cell locations (Cells No. 13 and 14) are on the upland and intermediate elevation areas west and south of existing Phase 3. The Phase 4 area's subsurface geology and hydrogeology are typical of Piedmont terrain in North Carolina. No unusual or unexpected geologic features were observed in the Phase 4 area. Groundwater flow in the Phase 4 area is northward and eastward. The northward flow discharges to Rocky Creek, and the eastward flow discharges to a tributary of Rocky Creek. Other than these natural features, there are no groundwater receptors to this landfill phase. New and existing groundwater and surface water sampling locations were selected to effectively monitor the existing Phases (1, 2, and 3) and proposed Phase 4 cell areas. Two existing (GW-18 and GW-19) and one proposed well (GW-21) locations downgradient of Phase 4 were selected based on the location of landfill sumps and areas of convergent groundwater flow. New monitoring well GW-21 will be installed in association with Cell No. 13 construction in Phase 4. Once GW-21 is constructed, the landfill's water quality monitoring system will include nineteen groundwater monitoring wells and three surface water sampling locations. The site is favorable for landfill development considering geotechnical aspects. The site is in a seismic impact zone, but the landfill structural components can be designed using conventional construction to resist the seismic magnitude. The existing residuum will form a stable foundation for the landfill. Anticipated subgrade total and differential settlements of the completed waste cells are expected to be well within acceptable limits of the structural components and leachate collection system of a MSW landfill. The on -site residual soils are suitable for use as structural fill. The residual soils and the planned new engineered fill will form stable slopes and provide acceptable base liner interface friction. Low permeability surficial soils that could be used to construct a base soil liner or final cover cap (K 5 1.0 x 10-5 cm/sec) are present on site in limited quantities. Careful selection and use of these clayey soils will be required during waste cell development. BLE will evaluate settlement and slope stability conditions for the Cells No. 13 and 14 area at a later date once landfill design grades have been prepared. This Design Hydrogeologic Report was prepared to satisfy the requirements specified in the North Carolina Title 15A NCAC 13B .1623 (b). Based on the results of field and laboratory testing, it is our opinion that the study area is geologically, hydrogeologically, and geotechnically suitable for municipal solid waste landfill cell development. This Design Hydrogeologic Report, while specifically addressing Phase 4, also considers the potential expanded landfill footprint and grades shown in the Facility Plan. The final top of clay grades in each cell will be developed at a later time. •0• 5-1