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Home My WebLink AboutPN74813 Parachute Rigging Facility - PN 74813 PARACHUTE RIGGING FACILITY - STORMWATER REPORT 04FEB2019 Stormwater Report October 29, 2018 *** ***FOR OFFICIAL USE ONLY Wilmington District prepared for Parachute Rigging Facility Fort Bragg, Cumberland County, North Carolina Mason & Hanger Page - i - TABLE OF CONTENTS SECTION PAGE GENERAL ....................................................................................................................................... 1 METHODOLOGY .............................................................................................................................. 1 EXISTING CONDITIONS .................................................................................................................... 2 PROPOSED CONDITIONS ................................................................................................................. 2 STORMWATER MANAGEMENT .......................................................................................................... 3 NCDEQ MINIMUM DESIGN CRITERIA FOR BIORETENTION CELLS. .................................................... 6 OUTLET PROTECTION ..................................................................................................................... 8 WATER QUALITY ............................................................................................................................. 8 SEDIMENTATION AND EROSION CONTROL ........................................................................................ 8 TABLES Table 1 RAINFALL DATA. ......................................................................................................... 2 Table 2 BIORETENTION AREAS PREDEVELOPED RUNOFF ......................................................... 3 Table 3 BIORETENTION AREAS POSTDEVELOPED RUNOFF ....................................................... 3 Table 4 95TH PERCENTILE AND 1” FIRST FLUSH BIORETENTION VOLUMES ................................. 5 Table 5 PROVIDED BIORETENTION STORAGE VOLUME ............................................................. 5 Table 6 BIORETENTION SURFACE VOLUME AND AREAS ............................................................ 5 FIGURES Figure 1 NCDEQ SUMMARY OF STORMWATER CALCULATIONS..………………..…………………………1 Figure 2 BIORETENTION BASIN. ……………………………………………………………………………….6 APPENDIX Appendix A USGS PROJECT LOCATION MAP ............................................................................. a.1 Appendix B PREDEVELOPMENT MAP .......................................................................................... a.2 Appendix C POSTDEELOPMENT MAP .......................................................................................... a.3 Appendix D EISA 438 CALCULATIONS ........................................................................................ a.4 Appendix E STORMWATER CALCULATIONS…………………………………………….... ................ a.5 Appendix F NRCS CUMBERLAND COUNTY SOIL SURVEY MAP .................................................... a.6 Appendix G SUBSURFACE EXPLORATION AND GEOTECHNICAL ENGINEERING REPORT ................. a.7 Appendix H BIORETENTION CELL SUPPLEMENT .......................................................................... a.8 Appendix I OUTLET PROTECTION CALCULATIONS ...................................................................... a.9 Appendix J SKIMMER SEDIMENTATION BASIN CALCULATIONS ................................................... a.10 Parachute Rigging Facility Fort Bragg, Cumberland County, North Carolina Mason & Hanger Page 1 of 8 GENERAL INFORMATION The project is located within the Fort Bragg Army Installation. The site is part of the development of Patriot Point, and is located within or near multiple projects either developed or to be developed. The site is currently primarily undeveloped and covered with native vegetation. Limited abandoned access roads, both dirt and asphalt, are within the site which led to previously removed ammunition supply structures. The site is bound on the north by undeveloped wooded area and to the south by Urban Freedom Parkway. The eastern boundary of the site is undeveloped. The western boundary is primarily undeveloped, but scheduled to be developed within the next 12-18 months. The project consists of one (1) new one story building totaling approximately 84,500 SF and associated site work including access drives. Privately owned vehicle (POV) parking is not included in the project at this time. The total disturbed site area within the limits of construction is approximately 12.12 acres. Total site acreage (drainage area) is approximately 17.94 acres. The site prior to construction is undeveloped, consisting of a combination of open area and sparse vegetation. Vegetation consists primarily of brush, with a limited number of deciduous trees 8 to 12 inches in diameter. Limited asphalt pavement is required to be removed. No existing structures are on- site. The topography slopes generally towards the south, with an elevation range of approximately 11 feet. Drainage currently flows to an existing bioretention area, discharging ultimately to an existing 48” RCP pipe which diverts the water to the north of the site. The soils consists primarily silty sands in the upper 3 to 4 feet with clayey sands and sandy clays beneath. All drainage areas for the project are in the watershed of Stewarts Creek, Stream Index 18-31-24-5-4, Classification C: Aquatic Life, Secondary Recreation, Freshwater, in the Cape Fear River Basin. METHODOLOGY Per the North Carolina Department of Environmental Quality (NCDEQ), the approved methods used in stormwater calculations are as shown in Figure 1. Figure 1 - Ref: NCDEQ Stormwater BMP Manual All methodology used to determine both peak flow and storm event volumes follows the guidelines set by the Corp of Engineers Wilmington District and NCDEQ. As the project is a federal project which exceeds 5,000 square feet of footprint, Section 438 of the Energy Independence and Security Act or 2007 (EISA 438) mandates the use of site planning, design, construction, and maintenance strategies for the property to maintain or restore, to the maximum extent technically feasible, the predevelopment hydrology of the property. Parachute Rigging Facility Fort Bragg, Cumberland County, North Carolina Mason & Hanger Page 2 of 8 EXISTING CONDITIONS The existing site where the training facility and associated supporting infrastructure is to be constructed is approximately 11.76 acres. The site, prior to construction, is primarily undeveloped, consisting of a combination of open area and limited vegetation. Vegetation consists primarily of limited clusters of deciduous trees 8 to 12 inches in diameter. The topography slopes generally towards the south to an existing bioretention basin, with an elevation range of approximately 11 feet. The bioretention basin consists of a network of drainage pipes within a layer of water storage media. The drainage pipes would serve only to drain the area when infiltration is not possible due to high volumes of runoff. The outfall structure of the basin discharges to an existing 48” RCP pipe which diverts the excess water to the north of the site. The soils consists primarily silty sands in the upper 3 to 4 feet with clayey sands and sandy clays beneath. Due to the sandy nature of the existing soils, most first flush drainage permeates into the ground. For purposed of drainage calculations, the open site area is considered in fair to good condition. No existing structures exist on-site. The site was previously part of an ammunition supply point. The storage buildings have been previously removed. Limited asphalt and dirt paved roads lead to where the structures used to reside. For the purpose of the stormwater calculations, the entire drainage area to the existing bioretention basin will be analyzed. The entire construction site lies within this drainage area. The full drainage area is approximately 17.94 acres. Included in this area is runoff from parts of Urban Freedom Parkway which abuts the site. No existing structures exist within the drainage area. Limited asphalt roads which led to previously demolished ammunition supply structures cross the drainage area. A Subsurface Exploration Report has been performed by Building & Earth, completed August 22, 2018. This report is included in Appendix G. To calculate storm data, 24hr rainfall data to use for design was provided for by Fort Bragg. The rainfall data used are given in Table 1. For stormwater design, the 10yr event will be used. For temporary erosion control measures during construction, the 2yr event will be used. TABLE 1 RAINFALL DATA STORM EVENT 24HR RAINFALL DATA (IN) 1YR 3.03 2YR 3.67 5YR 4.71 10YR 5.4 25YR 6.5 50YR 7.3 100YR 8.2 WinTR55 Small Watershed Hydrology software, developed for the USDA, was utilized to calculate the peak runoff for both predevelopment and post development runoff. This software has been used in the past for other projects located at Fort Bragg and for NCDEQ, and is an approved method for stormwater calculations. The composite runoff curve number calculations for each area were entered into WinTR55 and the results are shown in the appendix and on the plan drawings. Parachute Rigging Facility Fort Bragg, Cumberland County, North Carolina Mason & Hanger Page 3 of 8 PROPOSED CONDITIONS To better control runoff at the source, and to better calculate strormwater runoff for drainage structures, the developed site was separated into 2 separate subbasins. A temporary diversion ditch will be constructed at the onset of construction to divert most of the offsite water to a skimmer sediment basin located on the northern portion of the site. An additional skimmer sediment basin will be constructed at the southern portion of the site. Each of these basins will receive runoff from less than 10 acres. The existing bioretention basin will be left in place. Stormwater runoff from the east of the site will be diverted to the southern skimmer basin, as this runoff may contain construction induced sediment. Stormwater runoff from the west of the site will continue to flow to the bioretention basin. Clean water flow from each of the sediment basins will be routed to the existing 48” outfall pipe which runs through the site, maintaining the existing point of discharge. Post construction, each of these skimmer sediment ponds will be converted to bioretention areas. The post-developed composite weighted CN calculations for each subbasin used in WinTR-55 as well as post-developed peak flows are shown in the appendix for the pipe networks, in Tables 2 and 3, and on the plan drawings. In general, the existing area is poorly grassed/brush area, which exhibits high rates of runoff. The proposed conditions include landscaping, primarily in the form of sod. The contractor is required to establish 100% groundcover within 1 year of construction. As such, the over CN for the proposed site does not differ much if any from the existing conditions. For design of all stormwater structures, AutoDesk Civil3D 2017 was utilized. As the total length of each structure is relatively small and each contributing drainage area has a time of concentration (Tc) overall less than 8 minutes to the inlet, it was assumed that each inlet on the system would receive the peak flow input at the same time. This results in a “worst case” scenario for the stormwater system, and ensures an adequate design for the 10yr storm event. Pipe sizes were calculated using the software, with minimum pipe sizes directed by UFC 3-201-01 Civil Engineering. The results of the stormwater structure designs are included in the appendices including HGL calculations. TABLE 2 PRE-DEVELOPED COMPOSITE RUNOFF CURVE NUMBER CALCULATIONS AND PEAK FLOW DRAINAGE AREA AREA (AC) WEIGHTED CN Q1 (CFS) Q10 (CFS) Q25 (CFS) Bioretention Area 1 8.85 78 7.05 22.63 30.70 Bioretention Area 2 2.96 62 2.03 7.04 9.69 TABLE 3 POST-DEVELOPED COMPOSITE RUNOFF CURVE NUMBER CALCULATIONS AND PEAK FLOW DRAINAGE AREA AREA (AC) WEIGHTED CN Q1 (CFS) Q10 (CFS) Q25 (CFS) Bioretention Area 1 8.85 81 7.05 22.63 30.70 Bioretention Area 2 2.96 72 2.36 7.57 10.28 STORMWATER MANAGEMENT As the project is a Federal facility over 5,000 square feet, the stormwater requirements of EISA Section 438 (Title 42, US Code, Section 17094) must be met. In accordance with the Department of Defense memo dated January 19, 2010 entitled DoD Implementation of Storm Water Requirements under Section 438 of the Energy Independence and Security Act (EISA) the designer of record shall implement the procedures for complying with EISA 438 as outlined in the EPA Technical Guidance on Implementing the Parachute Rigging Facility Fort Bragg, Cumberland County, North Carolina Mason & Hanger Page 4 of 8 Stormwater Runoff Requirements for Federal Projects under Section 438 of the Energy Independence and Security Act. The EPA Guidance manual prescribes two options to comply with the EISA 438 mandate. Option 1 is to retain and infiltrate the 95th percentile storm event onsite. Option 2 allows site-specific hydrologic analysis to determine the types of stormwater practices necessary to preserve predevelopment runoff conditions. Option 2 is provided for situations where pre-development conditions can be maintained by retaining less than the 95th percentile storm event, or where site-specific parameters dictate a prescriptive methodology be used or Option 1 is not protective enough, for example at the headwater of an impaired stream. For this project, Option 1 was selected. To be in compliance with EISA 438, based upon Option 1 of the EPA Technical Guidance document, the total volume of runoff from the 95th percentile storm event must be captured and infiltrated on-site. The method to determine this volume is based upon guidance from the EPA document. The 95th percentile storm event for the project area is equivalent to 1.8” of rainfall, as provided by the Fort Bragg Installation Design Guide. Criteria used for determination of total stormwater runoff to capture and infiltrate, the following criteria was used: Hydrologic Soil Group B, average Maximum Infiltration Rate of 15 inches per hour or as determined by the percolation testing, Minimum Infiltration Rate of 0.1 inches per hour, a Decay Factor or 2 per hour and Pervious Depression Storage of 0.2 inches. To provide for this storage, a total of 2 infiltration areas have been designed to help infiltrate the runoff closest to the source. Each of these areas are bioretention area consisting of a volume of ponding storage, a section of engineered fill to promote infiltration and sediment removal, and a layer of open graded aggregate to provide for the storage (see Figure 2). All drainage for the construction portion of the site is routed to an infiltration area. The design of the bioretention areas is based upon design criteria from Sustainable Landscape Systems for Managing Storm Water 2nd Edition, developed by Ohio State University Extension. The bioretention areas are designed to infiltrate the 95th percentile storm event as close as practical to the origin of the drainage. All drainage enters the bioretention areas via surface flow, or via stormwater collection pipes with the outlet at the top of the pond area, allowing for sediment to be removed via infiltration. The storage required for each area and the amount of storage provided for infiltration is shown on the plans. Storage is provided in the above ground ponding (maximum 12”), media and the open graded aggregate (minimum 2 feet). The bioretention basin design is similar and meets the Minimum Design Criteria (MDC) required for NCDEQ C-2 Bioretention Cell, revised January 19, 2018. To determine the storage volume to meet EISA 438, the Army LID Planning and Cost Tool was compared against what was calculated via the Direct Determination method. The database determines the volume required to be stored and infiltrated onside in order to meet EISA 438. The Army LID Planning and Cost Tool was developed to MILCON standards for projects within the jurisdiction of the Army. As such, the volumes determined using the Army LID Planning and Cost Tool are used for the design of the bioretention basins. Although the database was used to determine volume required, it was not used to design the bioretention areas. See below for the design of the bioretention area. The Army LID Planning and Cost Tool looks as the pre-developed and post-developed areas to calculate the storage volume requirements. WinTR-55 was utilized to calculate pre and post developed composite runoff curve numbers and peak flows for the areas draining to each bioretention area. The pre-developed composite weighted CN and peak flows for each bioretention area can be found in the appendix. A map of the post development drainage areas can be found in Appendix C. In addition, the volume required for the first flush, or 1” rainfall event, as required by NCDEQ was calculated. This would equate to the minimum required volume to store to meet NCDEQ requirements. This volume is required to be stored in a ponding volume. For EISA 438, the volume required was calculated via the Army LID Planning and Cost Tool. For bioretention areas where an underdrain is provided, the volume provided in the open aggregate is counted towards the storage. Where underdrains are not provided, the ponding and volume stored within the soil and aggregate is counted. Parachute Rigging Facility Fort Bragg, Cumberland County, North Carolina Mason & Hanger Page 5 of 8 TABLE 4 95TH PERCENTILE AND 1” FIRST FLUSH BIORETENTION VOLUMES DRAINAGE AREA VOLUME REQUIRED EISA438 (CF) VOLUME REQUIRED NCDEQ (CF) STORAGE PROVIDED EISA438 (CF) PONDING VOLUME PROVIDED (CF) Bioretention Area 1 3,380 4,005 3,396 6,900 Bioretention Area 2 1,758 2,067 4,060 3,750 TABLE 5 PROVIDED BIORETENTION STORAGE VOLUMES BIORETENTION AREA PONDING DEPTH PROVIDED (IN) PONDING VOLUME (CF) STORAGE VOLUME IN SOIL (CF) 10% VOIDS DEPTH OF AGGREGATE (FT) 40% VOIDS STORAGE VOLUME IN AGGREGATE (CF) Bioretention Area 1 9 6,900 1,150 2.0 7,360 Bioretention Area 2 9 3,750 625 2.0 4,000 For all storm events greater than the 95th percentile event, and for other events where the infiltration areas cannot sufficiently handle the storm event, excess runoff is bypassed directly to the outfall area. As the open aggregate fills with water, when the level reaches the bottom of the perforated pipe, drainage enters the pipe and is carried to either the next infiltration area, or to the outfall. In addition, if there is excess ponding due to either the saturation of the engineered fill or a large storm event, water is collected through the grate in the riser structure. This prevents flooding in areas surrounding the bioretention basins as the top of the grate is set at an elevation below the surrounding grade. Although the design of the bioretention areas are not completely compatible with the Bioretention Cell Supplement form provided by NCDEQ, this form has been completed for the drainage areas and included in the appendix. TABLE 6 BIORETENTION SURFACE VOLUME AND AREAS INFILTRATION AREA SURFACE AREA REQUIRED (SF) NCDEQ SURFACE VOLUME PROVIDED (CF) SURFACE AREA PROVIDED (SF) Bioretention Area 1 5,340 6,900 9,200 Bioretention Area 2 2,756 3,750 5,000 Parachute Rigging Facility Fort Bragg, Cumberland County, North Carolina Mason & Hanger Page 6 of 8 Figure 2 - Bioretention Basin Seasonal high water table (SHWT) depths was determined in conjunction with the geotechnical report. SHWT depths were found to be a minimum of 12’ below grade. As the 95th percentile storm event is being captured and infiltrated on-site and all excess storm drainage is routed to outlet structures with appropriate energy dissipation, this meets LEED 6.1 Stormwater Design Quantity Control requirements. The existing site has less than 50% impervious surface, and the bioretention/infiltration of the 95th percentile storm meets the quantity control requirements. For any underdrains installed within the bioretention area, cleanouts are provided in addition to the riser pipes to facilitate cleanout. It is the user’s desire to utilize sod in lieu of vegetation to facilitate maintenance reduce the risk of floating debris from entering into and clogging the system. No water supply wells are within 100’ of the project site. No surface waters are within 30’ of the project site. No Class SA waters are within 50’ of the project site. NCDEQ Minimum Design Criteria for Bioretention Cells The Minimum Design Criteria (MDC) for bioretention cells for NCDEQ is as described below. These criteria are taken from the NCDEQ Stormwater Design Manual Section C-2. Bioretention Cell Revised 1-10-2018. MDC 1: Separation from the SHWT The lowest point of all bioretention cells are a minimum of 2 feet above the SHWT. Depths to the SHWT are greater than 120” below the surface. Parachute Rigging Facility Fort Bragg, Cumberland County, North Carolina Mason & Hanger Page 7 of 8 MDC 2: Maximum Ponding Depth for Design Volume Ponding depths for both of the bioretention areas is 9”. MDC 3: Peak Attenuation Volume Each bioretention area is designed to store the required volume to meet EISA 438, which is greater than the first flush volume. At volumes above this storm event, primary outlet structure is placed (9 inches above planting surface). This additional ponding volume would not necessarily be considered to store the peak attenuation volume, however it acts as a measure of safety for the areas and is a maximum of 24” above the planting surface to the emergency spillway. The emergency spillway is designed for each bioretention basin to handle the entire flow from the 100- year storm event in case of failure of the primary outfall and storage within each basin. MDC 4: Underdrain Infiltration testing was done in conjunction with design at each bioretention basin. As the Ksat values attained are less than 2” per hour, underdrains are installed in both basins. At least one underdrain pipe per 1,000 square feet of area is provided, spaced at no greater than 10’. The underdrain pipes are sized to handle the infiltration rate of the engineered soil for the times that the internal water storage zone has reached capacity. MDC 5: Media Depth All bioretention areas are grassed cells, without trees and shrubs. The media depth in both bioretention areas is 30” as both include underdrains. MDC 6: Media Mix The planting media consists of 85% sands (by volume), 10% fines (by volume) and 5% organics (by volume). MDC 7: Media P-Index The P-Index for the soil media is 10. MDC 8: No Mechanical Compaction The soil media will not be mechanically compacted. MDC 9: Maintenance of Media An in-lieu of O&M agreement with Fort Bragg DPW has been signed and provided for the bioretention areas. Parachute Rigging Facility Fort Bragg, Cumberland County, North Carolina Mason & Hanger Page 8 of 8 MDC 10: Planting Plan In accordance with the plans and specifications, the grassed cells shall achieve 100 percent cover during the 1 year establishment period. Plants chosen for the cells are in accordance with the Fort Bragg Installation Design Guide. MDC 11: Mulch All bioretention areas will be sodded. Hardwood mulch is not desired or allowed by the user due to maintenance issues. Hardwood mulch tends to float in ponding situations and can clog the overflow structures. MDC 12: Clean-Out Pipes Clean-out pipes are provided in both bioretention areas. The cleanouts are PVC pipes with glued clean- out fittings with screw type caps that extend at least 2 feet above the surface of the bed. No flexible pipe is allowed. OUTLET PROTECTION All excess stormwater from the infiltration areas, as well as outlet structures for stormwater routed around the project site and will be connected directly to the 48” storm conveyance pipe running from the south west to the northeast of the site. This pipe was previously designed and installed for the express purpose of excess storm water routing for this project and other projects within the area. Outlet protection will be provided in accordance with guidance from Chapter 8.06 Design of Riprap Outlet Protection of the North Carolina Division of Environmental Quality Erosion and Sediment Control Planning and Design Manual for all pipes and headwalls within the project. Calculations for the outlet protection are shown in the appendix. WATER QUALITY To ensure the removal of Total Suspended Solids (TSS), all runoff is directed to the infiltration areas via either sheet flow or via storm collection pipes with their outlets at the top of the bioretention basins (protected with energy dissipaters). This includes runoff from all parking areas and roof drainage structures. This makes certain that the storm events up to the 95Th percentile event (and first flush for larger events) will have the runoff filtered through a minimum the vegetative strip and a minimum of 24” of engineered soil. Additionally, in bioretention areas that do not have landscape rock, an 8” rock filter strip is included as recommended by NCDEQ for pretreatment at bioretention basins. In addition, a non-woven geotextile fabric is placed above both the gravel section of the bioretention basin and the perforated collection pipe to keep sediment and other fines from infiltrating the storage area. It is generally accepted that bioretention basins of this type will remove between 80-90% of TSS along with the removal of heavy metals. This design has previously been used on projects at Fort Bragg and has been approved by NCDEQ for TSS removal requirements. This method will also meet LEED 6.2 Stormwater Quality Control requirements. EROSION AND SEDIMENTATION CONTROL Separate erosion and sedimentation control during construction plans have been developed for submittal to NCDEQ for permit requirements. The permit, CUMBE-2019-068, has been approved. Calculations used for sizing skimmer sedimentation basins is included with this report. Parachute Rigging Facility Fort Bragg, Cumberland County, North Carolina Mason & Hanger Page - a.1 - APPENDIX A USGS PROJECT LOCATION MAP Parachute Rigging Facility Fort Bragg, Cumberland County, North Carolina Mason & Hanger Page - a.2 - APPENDIX B PREDEVELOPMENT MAP URBAN FREEDOM WAY ASPHALT ELEVATION: 261.30' E: 1989897.14 N: 485522.55 RB&C #11 CONC TIMBER PILE 96" CHAIN LINK FENCE WITH 3 STRAND BARBED WIRE 96" CHAIN LINK FENCE WITH 3 STRAND BARBED WIRE BOTTOM BOX=250.78' TOP=260.43' BOTTOM BOX=252.49' TOP=262.22' BOTTOM BOX=257.22' TOP=266.87' BOTTOM BOX=260.94' TOP=270.57' ASPHALT ASPHALT URBAN FREEDOM WAY ASPHALT ASPHALT POND RETENTION STORMWATER AND HAND HOLE ON CONC PAD EJB METER BOXESUNKNOWNMETER BOXESUNKNOWNCONC CONC CONC CONC GUARD SHACK 1 STORY WOODS 6" 8" 24" 6" 6" 6" 15"13" 24" 11"O 20" 12"16" 14" 15" 15"O 15" 14"O 9"O 20" 8" 14" 15" 15"6"O 6"C 22" WOODS 36" 32"O 6"D 24"PE 7"O 7"O 12"O9" 6"6" 6"7"42"PE 24"PE 11"O 24"PE 24"PE 6"D 22"PE 21"PE 6"O 6"C WOODS WOODS 24"O 22"O 24"O INV.OUT=250.82' (NE) INV.IN=250.86' (S) INV.IN=252.48' (W) TOP=259.04' INV.OUT=253.82' (E) TOP=257.70' OUTFALL STRUCTURE INV.OUT=251.49' (N) INV.IN=252.38' (W) TOP=259.05' INV.OUT=250.22' (NE) INV.IN=250.27' (SW) TOP=260.07' INV.OUT=249.32' (NE) INV.IN=249.35' (SW) TOP=265.10' INV.OUT OFF-SITE INV.IN=245.34' (S) TOP=256.56' INV.OUT=247.15' (N) INV.IN=247.29' (SE) TOP=264.90' INV.OUT=248.12' (NW) INV.IN=248.24' (SW) TOP=265.44' RAP RIP RAP RIP RIP RAP RIP RAP 256B STREET (ABANDONED)S 257 257 257257257TRANSFORMER PAD ASPHALT ASPHALT ASPHALT ASPHALT ASPHALT ASPHALT ASPHALT ASPHALT ASPHALT 258 258258 258 258258258258258 D STREET (ABANDONED) MCINTYRE TRAIL (ABANDONED)259259259259 259 259259 259259259259259259 2 59259 259 259 259259S S48" RCP15" RCP 48" RCP260260260260 260 260260260 260 260 260 260260260260260260260 260260 260260260260260260260260260SWALE S SWALE T261261261261261261261 261261261 261 261 261261261261261261261 261 261261261 261 261261 261 261261261 261261261261261 261261 2612612 6 2 262 262262 262262262 262 262262262262262262262262262262262262262 262 262 262 262 262 262 262 262262262262262262262262262262 262262262262262 262 262 262262262262 262262262262262T D STR E E T (A BA N DO N E D )8" PVC6" C PP48" RCP48" RCPT 263263 263263263 263 263263263263263263263263263263263263263 263 263 263 263 263 263263263263263263263263263 263 263263263263 263263263EJB WV WV FH WVWV FH INV.OUT=251.42' TOP=263.44' BOTTOM BOX=253.31' TOP=262.99' TMH BARBED WIRE WITH 3 STRAND 84" CHAIN LINK FENCE P264 264264 264 26426426426 4264264264264264 264 264 264 264 264 264 264 264264 264264264264 264264264264264 264264 264264 2648" HDPES 265265 2652652 6 5 265 2652652652652652 6 52652 652 65 265265265265265265265 265 265 265 265265 265 265 2652652 6 5 265265265265265265265265265 265265 26526548" RCP48" RCP S48" RCP96" C H A IN LIN K FEN C E W ITH 3 STR A N D BA R B ED W IR ES BEYOND SURVEY LIMITSBEYOND SURVEY LIMITS INV.OUT=259.62' (SE) INV.IN=259.83' (NE) TOP=264.22'96" C H A IN L IN K FE NC E W ITH 3 ST R AND BA R B ED W IR E INV.=263.07' INV.=262.80' INV.=265.59' INV.=265.71' 6" CPP INV.OUT=252.38' (W) INV.IN=252.52' (E) TOP=257.26'2" FORCE MAIN WITH 8" CPP15" RCP 8" HDPE10" PVC 8" PVC INV.OUT=263.16' (SW) INV.IN=263.52' (NE) TOP=267.02' 266 266266266266266266266266266266 266 266266266 266266 266 266 266 266 266266 266266 266 266266266 266266 2 6 6 266 266266266266266266266266266 266266266 266 266266 URBAN FREEDOM WAYT267267267 267 26 7267267267267 267 267 267 267267267 267 267267267 267 267 267267267267 267267267267267267267267267 267267267 267 267 WITH 3 STRAND BARBED WIRE96" CHAIN LINK FENCE G RA V EL RO AD 96" CHAIN LINK FENCE WITH 3 STRAND BARBED WIRE GATE 268268268268268268268268268 268 268 268 268 268 268 268 2 68268 268268268268268268 268268268268268268 268 268268 2682 6 8 268 BARBED WIRE WITH 3 STRAND 96" CHAIN LINK FENCE GATE 269269269 269 269 269 269 269269269269269 269269269 26927 0270270 270270 270 270270GRAVEL ROADG RAVEL ROADGATE GRAVEL DRIVE GRAVEL DRIVE GRAVEL GRAVEL LOT WATER TANK POLE W/LIGHTPOLE W/LIGHT POLE W/LIGHT CONC PAD SHELTER OVER GENERAL INSTRUCTION COMPOUNDGRAVEL ROADGRAVEL ROADT271271 27127127196" CHAI N LI NK FENCE WI TH 3 STRAND BARBED W I RE96" CHAI N LI NK FENCE WI TH 3 STRAND BARBED WI RE72" C HAI N LI NK FE NCE WIT H 3 ST R AND B AR BE D WIR E 72" C HAI N LI NK FE NC E WIT H 3 ST R AND B AR BE D WIR E 2 7 2272272272 272 272 12" BLOCK WALL72" CHAIN LINK FENCE WITH 3 STRAND BARBED WIRETO TORA BORA BLVDTO AFRICAN LION BLVD U.S. ARMY CORPS OF ENGINEERS$FILES$ANSI DCHECKED BY:DRAWN BY:ISSUE DATE:XXXXXX-XX-X-XXXXSHEET ID FILENAME:B C D E F G 2 3 4 5 6 7 8 9 10 SOLICITATION NO.:DESIGNED BY:1 A MARKSIZE:SUBMITTED BY:DATECONTRACT NO.:®of Engineers US Army Corps CATEGORY CODEDESCRIPTIONP:\Projects\016801\03 CAD_BIM\_Sheets\05_Civil\BPRF_CG750.dgn10-SEP-201813:24 XXX-XX-XXR. BOSTONW912PM-18-C-001469 DARLINGTON AVENUEWILMINGTON DISTRICTWILMINGTON, NORTH CAROLINAFORT BRAGG, NORTH CAROLINASPECIAL OPERATIONS FORCES (SOF)PARACHUTE RIGGING FACILITYPN 74813SEPTEMBER 2018FAST TRACK SUBMITTAL GRAPHIC SCALE: 1"=60'-0" 180'120'60'030'60' N GEOGRAPHIC COORDINATE DATA HORIZONTAL DATUM: NORTH CAROLINA STATE PLANE, NAD83. VERTICAL DATUM: NAVD88. UNITS OF MEASURE: U.S. SURVEY FEET. COORDINATES SHOWN IN FORMAT OF EASTING, NORTHING AND ELEVATION.CG750S.HAGGARDPRE DEVELOPED HYDROLOGYS.CURRYM.MEYERQ100: 88.31 Q25: 62.22 Q10: 45.86 Q2: 22.06 Q1: 14.28 PEAK FLOW (CFS) WEIGHTED CN: 72 DRAINAGEAREA: 17.94 ACRES PREDEVELOPED EXISTING 48" RCP WITH OVERFLOW CONNETED TO EXISTING BIORETENTION AREA ALL DRAINAGE FLOWS TO Parachute Rigging Facility Fort Bragg, Cumberland County, North Carolina Mason & Hanger Page - a.3 - APPENDIX C POSTDEVELOPMENT MAP CONC TIMBER PILE 96" CHAIN LINK FENCE WITH 3 STRAND BARBED WIRE 96" CHAIN LINK FENCE WITH 3 STRAND BARBED WIRE BOTTOM BOX=250.78' TOP=260.43' BOTTOM BOX=252.49' TOP=262.22' BOTTOM BOX=257.22' TOP=266.87' BOTTOM BOX=260.94' TOP=270.57' ASPHALT ASPHALT URBAN FREEDOM WAY ASPHALT ASPHALT POND RETENTION STORMWATER AND HAND HOLE ON CONC PAD EJB CONC CONC CONC CONC ELEVATION=262.4' BORE HOLE ELEVATION=262.1' BORE HOLE ELEVATION=267.3' BORE HOLE ELEVATION=262.2' BORE HOLE E L E V A T IO N =264.6' BO R E H O L E ELEVATION=261.2' BORE HOLE ELEVATION=260.2' BORE HOLE ELEVATION=260.4' BORE HOLE GUARD SHACK 1 STORY WOODS 6" 8" 24" 6" 6" 6" 15"13" 24" 11"O 20" 12"16" 14" 15" 15"O 15" 14"O 9"O 20" 8" 14" 15" 15"6"O 6"C 22" WOODS URBAN FREEDOM WAY ASPHALT ELEVATION: 261.30' E: 1989897.14 N: 485522.55 RB&C #11 CI-2 CI-3 CI-1 CB-5 CB-4 CB-3 CB-2 CB-1 SDMH-2 CI-7 CI-6 CI-5 CI-4 CI-8 CI-9 CI-10 HW-3 TR-3TR-2TR-1HW-4 HW-5TR-4GI-1 SANWWWWFH WWW WSAN WWSD SDS DSDSDS DSDSDSDSDSDSDSD SDSDSDRDRDRDRDRDSD1 5" 1 5" 1 5"15"18"15"15"24"18"1 5 " 1 5" 1 5"15"6"10"6"6" 6" 6" 12" HW-6 SDMH-3 SDSD15"15"10"SDMH-4 6" 6" SD SSMH SSMH HW-8 HW-7 18" 18"GG GGGPIVFH FH SD SD SD 6"RD10"6"6"RDRD6" 1 2" RD 6" 10" 6"COCOCOCOCORDRDRD6"6"6"6" 1 0" MH-1 SD SANSANSAN SANSSMHSSMH SSMH S A N SANS ANSSMH 30"FDC8"8"8"8"8" 8"8"2"2"6"FWFW10"CO6"6"6"COS D2 4" GI-3GI-4GI-58"8"SDMH-6 SDMH-5 SDMH-7 SD24"CI-12 CI-11 SD 24" S D1 8" SDMH-8 SD15"S D1 5"18"12"15"8"8"8"8"8"8"8"CO CO CO CO CO CO CO CO CO CO 8"SD18"24"SDMH-912"GI-1A 8"8"8"8"8"COCO CO CO CO 6"6"6"6"RDRD RDCOCO6" 6" INV.OUT=250.82' (NE) INV.IN=250.86' (S) INV.IN=252.48' (W) TOP=259.04' INV.OUT=253.82' (E) TOP=257.70' OUTFALL STRUCTURE INV.OUT=251.49' (N) INV.IN=252.38' (W) TOP=259.05' INV.OUT=250.22' (NE) INV.IN=250.27' (SW) TOP=260.07' INV.OUT=249.32' (NE) INV.IN=249.35' (SW) TOP=265.10' INV.OUT OFF-SITE INV.IN=245.34' (S) TOP=256.56' INV.OUT=247.15' (N) INV.IN=247.29' (SE) TOP=264.90' INV.OUT=248.12' (NW) INV.IN=248.24' (SW) TOP=265.44' RAP RIP RAP RIP RIP RAP RIP RAP 256 SD 30" SD 30"B STREET (ABANDONED)S 257 257 257257257ASPHALT ASPHALT ASPHALT ASPHALT ASPHALT 6' TEMPORARY CONSTRUCTION CHAIN LINK FENCE TRANSFORMER PADTRANSFORMER PAD 258 258258 258 258258258258258 D STREET (ABANDONED) MCINTYRE TRAIL (ABANDONED) 259 259 259 259 259 259259 259259259259259259 25 9259 259 259 259259S S48" RCP15" RCP 48" RCP 260 260 260 260 260 260260260 260 260 260 260260260260260260260 260260 260260260260260260260260260 SWALESWALE S SWALESWALE T 261 261 261 261 261261261 261 261 261261261261261261261 261 261261261 261 261261 261 261261261 261261261261261 2612 61261261261261261 262 262262 262 2 62262262262262262262262262262 262 262 262 262 262 262 262 262262 262 262 262 262262262262262 262262262262262 262 262 262262262262 2 622622622622622 6 2 262 262262 262262262 T 8" PVC6" CPP48" RCP48" RCPT 263263263263263263263263 263263 263263 263 263 263 263 263 263 263 263 263 263263263263263 263 263263263263 263263263263263 263263263 263 263BOTTOM BOX=253.31' TOP=262.99' TMH EJB WV WV FH WVWV FH INV.OUT=251.42' TOP=263.44' BOTTOM BOX=253.31' TOP=262.99' TMH P 264264264264 2 64264264264 2 64 264 264 264 264 264 264 264264 264 264264 264 264264264264264 264264 264264 264264264264 264 2648" HDPES 265 2652652652652652 6526526526 5265265265265265265265 265 265 265 265265 265 265 265 265 2 6 5 265 265 265265265265265265265 265265 265265 265265 265 2652 6 5 265265 2652652 6 5 48" RCP48" RCP S48" RCPS BEYOND SURVEY LIMITSBEYOND SURVEY LIMITS INV.OUT=259.62' (SE) INV.IN=259.83' (NE) TOP=264.22' INV.=263.07' INV.=262.80' INV.=265.59' INV.=265.71' 6" CPP INV.OUT=252.38' (W) INV.IN=252.52' (E) TOP=257.26'2" FORCE MAIN WITH 8" CPP15" RCP 10" PVC 8" HDPE8" PVC INV.OUT=263.16' (SW) INV.IN=263.52' (NE) TOP=267.02'266266266266266266266266266 266 266266266 266266 266 266 266 266 266266 266266 266 266266266 266266 2 6 6 266 2 6 6 266266266266266266266 266 266266266 266 266266 266 266URBAN FREEDOM WAYT267267267 267 26 7267267 2 67267 267 267 267 267267267 267 267267267267 267 267 267267267 267267267267267267267267267 267 267267 267 267 GATE 268 268 268268268268268268268 268 268 268 268 268 2 68 268268 268 268268268268268268 26826826826 8268 268 268 268 268 268 2 6 8 268 BARBED WIRE WITH 3 STRAND 96" CHAIN LINK FENCE GATE 269269269 269 269 269 269 269269269269269 269269269 269270270270 270270 270 270270GRAVEL ROADGATE GRAVEL DRIVE GRAVEL DRIVE GRAVEL GRAVEL LOT WATER TANK POLE W/LIGHT POLE W/LIGHT POLE W/LIGHT CONC PAD SHELTER OVER GENERAL INSTRUCTION COMPOUNDGRAVEL ROADT271271 27127127196" CHAI N LI NK FENCE WI TH 3 STRAND BARBED WI RE72" C HAI N LI NK FE NCE WIT H 3 ST R AND B AR BE D WIR E 72" C HAI N LI NK FE NCE WIT H 3 ST R AND B AR B E D WIRE27 2 272272272 272 272 12" BLOCK WALL72" CHAIN LINK FENCE WITH 3 STRAND BARBED WIRETO TORA BORA BLVDTO AFRICAN LION BLVD U.S. ARMY CORPS OF ENGINEERSBPRF_CG751.dgnANSI DCHECKED BY:DRAWN BY:ISSUE DATE:SHEET ID FILENAME:B C D E F G 2 3 4 5 6 7 8 9 10 DESIGNED BY:1 A MARKSIZE:SUBMITTED BY:DATECONTRACT NO.:®of Engineers US Army Corps CATEGORY CODEDESCRIPTIONP:\Projects\016801\03 CAD_BIM\_Sheets\05_Civil\BPRF_CG751.dgn04-FEB-201915:19 XXX-XX-XXR. BOSTONW912PM-18-C-001469 DARLINGTON AVENUEWILMINGTON DISTRICTWILMINGTON, NORTH CAROLINAFORT BRAGG, NORTH CAROLINASPECIAL OPERATIONS FORCES (SOF)PARACHUTE RIGGING FACILITYPN 74813DECEMBER 2018FAST TRACK SUBMITTAL SN2 SN7 SN1 SN8 SN3 SN4 SN6SN5 SN11 SN10 SN12 SN9 SN13 SN14 FF EL 266.00'BIO-RETENTION EXISTING #1 BIO-RETENTION #2 BIO-RETENTION 2 6 0 2 6 0 2602602602 6 1261 261 2612612622622 6 2262 2622622622622 6 3 263 263263263263 2632632632 6 3 263263 2 6 4 264264264264 264 2642642 6 4264264264 264264264264264264 FACILITYPARACHUTE RIGGING2 6 5265 265265265 2652 6 5 265 2652652652652652652 6 5 2 6 5 2652652 6 4 2662 6 9 GRAPHIC SCALE: 1"=60'-0" 180'120'60'030'60' N GEOGRAPHIC COORDINATE DATA HORIZONTAL DATUM: NORTH CAROLINA STATE PLANE, NAD83. VERTICAL DATUM: NAVD88. UNITS OF MEASURE: U.S. SURVEY FEET. COORDINATES SHOWN IN FORMAT OF EASTING, NORTHING AND ELEVATION.CG751S.HAGGARDPOST DEVELOPED HYDROLOGYS.CURRYM.MEYERBASIN 1 BASIN 2 AS ORIGINAL FLOW PATH OUTLET TO SAME 42" RCP PIPE BIORETENTION BASIN 2 OVERFLOW Q100: 14.59 Q25: 10.28 Q10: 7.57 Q2: 3.64 Q1: 2.36 PEAK FLOW (CFS) WEIGHTED CN: 72 DRAINAGE AREA: 2.96 ACRES BIO-RETENTION BASIN 2: Q100: 43.57 Q25: 30.70 Q10: 22.63 Q2: 10.88 Q1: 7.05 PEAK FLOW (CFS) WEIGHTED CN: 81 DRAINAGE AREA: 8.85 ACRES :BIO-RETENTION BASIN 1 POST DEVELOPED: Parachute Rigging Facility Fort Bragg, Cumberland County, North Carolina Mason & Hanger Page - a.6 - APPENDIX F NRCS CUMBERLAND COUNTY SOIL SURVEY MAP United States Department of Agriculture A product of the National Cooperative Soil Survey, a joint effort of the United States Department of Agriculture and other Federal agencies, State agencies including the Agricultural Experiment Stations, and local participants Custom Soil Resource Report for Cumberland County, North Carolina Natural Resources Conservation Service September 6, 2018 Preface Soil surveys contain information that affects land use planning in survey areas. They highlight soil limitations that affect various land uses and provide information about the properties of the soils in the survey areas. Soil surveys are designed for many different users, including farmers, ranchers, foresters, agronomists, urban planners, community officials, engineers, developers, builders, and home buyers. Also, conservationists, teachers, students, and specialists in recreation, waste disposal, and pollution control can use the surveys to help them understand, protect, or enhance the environment. Various land use regulations of Federal, State, and local governments may impose special restrictions on land use or land treatment. Soil surveys identify soil properties that are used in making various land use or land treatment decisions. The information is intended to help the land users identify and reduce the effects of soil limitations on various land uses. The landowner or user is responsible for identifying and complying with existing laws and regulations. Although soil survey information can be used for general farm, local, and wider area planning, onsite investigation is needed to supplement this information in some cases. Examples include soil quality assessments (http://www.nrcs.usda.gov/wps/ portal/nrcs/main/soils/health/) and certain conservation and engineering applications. For more detailed information, contact your local USDA Service Center (https://offices.sc.egov.usda.gov/locator/app?agency=nrcs) or your NRCS State Soil Scientist (http://www.nrcs.usda.gov/wps/portal/nrcs/detail/soils/contactus/? cid=nrcs142p2_053951). Great differences in soil properties can occur within short distances. Some soils are seasonally wet or subject to flooding. Some are too unstable to be used as a foundation for buildings or roads. Clayey or wet soils are poorly suited to use as septic tank absorption fields. A high water table makes a soil poorly suited to basements or underground installations. The National Cooperative Soil Survey is a joint effort of the United States Department of Agriculture and other Federal agencies, State agencies including the Agricultural Experiment Stations, and local agencies. The Natural Resources Conservation Service (NRCS) has leadership for the Federal part of the National Cooperative Soil Survey. Information about soils is updated periodically. Updated information is available through the NRCS Web Soil Survey, the site for official soil survey information. The U.S. Department of Agriculture (USDA) prohibits discrimination in all its programs and activities on the basis of race, color, national origin, age, disability, and where applicable, sex, marital status, familial status, parental status, religion, sexual orientation, genetic information, political beliefs, reprisal, or because all or a part of an individual's income is derived from any public assistance program. (Not all prohibited bases apply to all programs.) Persons with disabilities who require 2 alternative means for communication of program information (Braille, large print, audiotape, etc.) should contact USDA's TARGET Center at (202) 720-2600 (voice and TDD). To file a complaint of discrimination, write to USDA, Director, Office of Civil Rights, 1400 Independence Avenue, S.W., Washington, D.C. 20250-9410 or call (800) 795-3272 (voice) or (202) 720-6382 (TDD). USDA is an equal opportunity provider and employer. 3 Contents Preface....................................................................................................................2 How Soil Surveys Are Made..................................................................................5 Soil Map..................................................................................................................8 Soil Map................................................................................................................9 Legend................................................................................................................10 Map Unit Legend................................................................................................11 Map Unit Descriptions.........................................................................................11 Cumberland County, North Carolina...............................................................13 BaD—Blaney loamy sand, 8 to 15 percent slopes......................................13 FaB—Faceville loamy sand, 2 to 6 percent slopes.....................................14 Soil Information for All Uses...............................................................................15 Soil Reports........................................................................................................15 Soil Physical Properties..................................................................................15 Engineering Properties (Parachute Rigging)...............................................15 References............................................................................................................19 4 How Soil Surveys Are Made Soil surveys are made to provide information about the soils and miscellaneous areas in a specific area. They include a description of the soils and miscellaneous areas and their location on the landscape and tables that show soil properties and limitations affecting various uses. Soil scientists observed the steepness, length, and shape of the slopes; the general pattern of drainage; the kinds of crops and native plants; and the kinds of bedrock. They observed and described many soil profiles. A soil profile is the sequence of natural layers, or horizons, in a soil. The profile extends from the surface down into the unconsolidated material in which the soil formed or from the surface down to bedrock. The unconsolidated material is devoid of roots and other living organisms and has not been changed by other biological activity. Currently, soils are mapped according to the boundaries of major land resource areas (MLRAs). MLRAs are geographically associated land resource units that share common characteristics related to physiography, geology, climate, water resources, soils, biological resources, and land uses (USDA, 2006). Soil survey areas typically consist of parts of one or more MLRA. The soils and miscellaneous areas in a survey area occur in an orderly pattern that is related to the geology, landforms, relief, climate, and natural vegetation of the area. Each kind of soil and miscellaneous area is associated with a particular kind of landform or with a segment of the landform. By observing the soils and miscellaneous areas in the survey area and relating their position to specific segments of the landform, a soil scientist develops a concept, or model, of how they were formed. Thus, during mapping, this model enables the soil scientist to predict with a considerable degree of accuracy the kind of soil or miscellaneous area at a specific location on the landscape. Commonly, individual soils on the landscape merge into one another as their characteristics gradually change. To construct an accurate soil map, however, soil scientists must determine the boundaries between the soils. They can observe only a limited number of soil profiles. Nevertheless, these observations, supplemented by an understanding of the soil-vegetation-landscape relationship, are sufficient to verify predictions of the kinds of soil in an area and to determine the boundaries. Soil scientists recorded the characteristics of the soil profiles that they studied. They noted soil color, texture, size and shape of soil aggregates, kind and amount of rock fragments, distribution of plant roots, reaction, and other features that enable them to identify soils. After describing the soils in the survey area and determining their properties, the soil scientists assigned the soils to taxonomic classes (units). Taxonomic classes are concepts. Each taxonomic class has a set of soil characteristics with precisely defined limits. The classes are used as a basis for comparison to classify soils systematically. Soil taxonomy, the system of taxonomic classification used in the United States, is based mainly on the kind and character of soil properties and the arrangement of horizons within the profile. After the soil 5 scientists classified and named the soils in the survey area, they compared the individual soils with similar soils in the same taxonomic class in other areas so that they could confirm data and assemble additional data based on experience and research. The objective of soil mapping is not to delineate pure map unit components; the objective is to separate the landscape into landforms or landform segments that have similar use and management requirements. Each map unit is defined by a unique combination of soil components and/or miscellaneous areas in predictable proportions. Some components may be highly contrasting to the other components of the map unit. The presence of minor components in a map unit in no way diminishes the usefulness or accuracy of the data. The delineation of such landforms and landform segments on the map provides sufficient information for the development of resource plans. If intensive use of small areas is planned, onsite investigation is needed to define and locate the soils and miscellaneous areas. Soil scientists make many field observations in the process of producing a soil map. The frequency of observation is dependent upon several factors, including scale of mapping, intensity of mapping, design of map units, complexity of the landscape, and experience of the soil scientist. Observations are made to test and refine the soil-landscape model and predictions and to verify the classification of the soils at specific locations. Once the soil-landscape model is refined, a significantly smaller number of measurements of individual soil properties are made and recorded. These measurements may include field measurements, such as those for color, depth to bedrock, and texture, and laboratory measurements, such as those for content of sand, silt, clay, salt, and other components. Properties of each soil typically vary from one point to another across the landscape. Observations for map unit components are aggregated to develop ranges of characteristics for the components. The aggregated values are presented. Direct measurements do not exist for every property presented for every map unit component. Values for some properties are estimated from combinations of other properties. While a soil survey is in progress, samples of some of the soils in the area generally are collected for laboratory analyses and for engineering tests. Soil scientists interpret the data from these analyses and tests as well as the field-observed characteristics and the soil properties to determine the expected behavior of the soils under different uses. Interpretations for all of the soils are field tested through observation of the soils in different uses and under different levels of management. Some interpretations are modified to fit local conditions, and some new interpretations are developed to meet local needs. Data are assembled from other sources, such as research information, production records, and field experience of specialists. For example, data on crop yields under defined levels of management are assembled from farm records and from field or plot experiments on the same kinds of soil. Predictions about soil behavior are based not only on soil properties but also on such variables as climate and biological activity. Soil conditions are predictable over long periods of time, but they are not predictable from year to year. For example, soil scientists can predict with a fairly high degree of accuracy that a given soil will have a high water table within certain depths in most years, but they cannot predict that a high water table will always be at a specific level in the soil on a specific date. After soil scientists located and identified the significant natural bodies of soil in the survey area, they drew the boundaries of these bodies on aerial photographs and Custom Soil Resource Report 6 identified each as a specific map unit. Aerial photographs show trees, buildings, fields, roads, and rivers, all of which help in locating boundaries accurately. Custom Soil Resource Report 7 Soil Map The soil map section includes the soil map for the defined area of interest, a list of soil map units on the map and extent of each map unit, and cartographic symbols displayed on the map. Also presented are various metadata about data used to produce the map, and a description of each soil map unit. 8 9 Custom Soil Resource Report Soil Map 38840903884140388419038842403884290388434038843903884090388414038841903884240388429038843403884390679310 679360 679410 679460 679510 679560 679610 679660 679710 679760 679810 679310 679360 679410 679460 679510 679560 679610 679660 679710 679760 679810 35° 5' 11'' N 79° 1' 59'' W35° 5' 11'' N79° 1' 38'' W35° 5' 0'' N 79° 1' 59'' W35° 5' 0'' N 79° 1' 38'' WN Map projection: Web Mercator Corner coordinates: WGS84 Edge tics: UTM Zone 17N WGS84 0 100 200 400 600 Feet 0 35 70 140 210 Meters Map Scale: 1:2,390 if printed on A landscape (11" x 8.5") sheet. Soil Map may not be valid at this scale. MAP LEGEND MAP INFORMATION Area of Interest (AOI) Area of Interest (AOI) Soils Soil Map Unit Polygons Soil Map Unit Lines Soil Map Unit Points Special Point Features Blowout Borrow Pit Clay Spot Closed Depression Gravel Pit Gravelly Spot Landfill Lava Flow Marsh or swamp Mine or Quarry Miscellaneous Water Perennial Water Rock Outcrop Saline Spot Sandy Spot Severely Eroded Spot Sinkhole Slide or Slip Sodic Spot Spoil Area Stony Spot Very Stony Spot Wet Spot Other Special Line Features Water Features Streams and Canals Transportation Rails Interstate Highways US Routes Major Roads Local Roads Background Aerial Photography The soil surveys that comprise your AOI were mapped at 1:24,000. Warning: Soil Map may not be valid at this scale. Enlargement of maps beyond the scale of mapping can cause misunderstanding of the detail of mapping and accuracy of soil line placement. The maps do not show the small areas of contrasting soils that could have been shown at a more detailed scale. Please rely on the bar scale on each map sheet for map measurements. Source of Map: Natural Resources Conservation Service Web Soil Survey URL: Coordinate System: Web Mercator (EPSG:3857) Maps from the Web Soil Survey are based on the Web Mercator projection, which preserves direction and shape but distorts distance and area. A projection that preserves area, such as the Albers equal-area conic projection, should be used if more accurate calculations of distance or area are required. This product is generated from the USDA-NRCS certified data as of the version date(s) listed below. Soil Survey Area: Cumberland County, North Carolina Survey Area Data: Version 18, Sep 26, 2017 Soil map units are labeled (as space allows) for map scales 1:50,000 or larger. Date(s) aerial images were photographed: Aug 13, 2014—Feb 4, 2017 The orthophoto or other base map on which the soil lines were compiled and digitized probably differs from the background imagery displayed on these maps. As a result, some minor shifting of map unit boundaries may be evident. Custom Soil Resource Report 10 Map Unit Legend Map Unit Symbol Map Unit Name Acres in AOI Percent of AOI BaD Blaney loamy sand, 8 to 15 percent slopes 0.0 0.1% FaB Faceville loamy sand, 2 to 6 percent slopes 16.6 99.9% Totals for Area of Interest 16.6 100.0% Map Unit Descriptions The map units delineated on the detailed soil maps in a soil survey represent the soils or miscellaneous areas in the survey area. The map unit descriptions, along with the maps, can be used to determine the composition and properties of a unit. A map unit delineation on a soil map represents an area dominated by one or more major kinds of soil or miscellaneous areas. A map unit is identified and named according to the taxonomic classification of the dominant soils. Within a taxonomic class there are precisely defined limits for the properties of the soils. On the landscape, however, the soils are natural phenomena, and they have the characteristic variability of all natural phenomena. Thus, the range of some observed properties may extend beyond the limits defined for a taxonomic class. Areas of soils of a single taxonomic class rarely, if ever, can be mapped without including areas of other taxonomic classes. Consequently, every map unit is made up of the soils or miscellaneous areas for which it is named and some minor components that belong to taxonomic classes other than those of the major soils. Most minor soils have properties similar to those of the dominant soil or soils in the map unit, and thus they do not affect use and management. These are called noncontrasting, or similar, components. They may or may not be mentioned in a particular map unit description. Other minor components, however, have properties and behavioral characteristics divergent enough to affect use or to require different management. These are called contrasting, or dissimilar, components. They generally are in small areas and could not be mapped separately because of the scale used. Some small areas of strongly contrasting soils or miscellaneous areas are identified by a special symbol on the maps. If included in the database for a given area, the contrasting minor components are identified in the map unit descriptions along with some characteristics of each. A few areas of minor components may not have been observed, and consequently they are not mentioned in the descriptions, especially where the pattern was so complex that it was impractical to make enough observations to identify all the soils and miscellaneous areas on the landscape. The presence of minor components in a map unit in no way diminishes the usefulness or accuracy of the data. The objective of mapping is not to delineate pure taxonomic classes but rather to separate the landscape into landforms or landform segments that have similar use and management requirements. The delineation of such segments on the map provides sufficient information for the development of resource plans. If intensive use of small areas is planned, however, Custom Soil Resource Report 11 onsite investigation is needed to define and locate the soils and miscellaneous areas. An identifying symbol precedes the map unit name in the map unit descriptions. Each description includes general facts about the unit and gives important soil properties and qualities. Soils that have profiles that are almost alike make up a soil series. Except for differences in texture of the surface layer, all the soils of a series have major horizons that are similar in composition, thickness, and arrangement. Soils of one series can differ in texture of the surface layer, slope, stoniness, salinity, degree of erosion, and other characteristics that affect their use. On the basis of such differences, a soil series is divided into soil phases. Most of the areas shown on the detailed soil maps are phases of soil series. The name of a soil phase commonly indicates a feature that affects use or management. For example, Alpha silt loam, 0 to 2 percent slopes, is a phase of the Alpha series. Some map units are made up of two or more major soils or miscellaneous areas. These map units are complexes, associations, or undifferentiated groups. A complex consists of two or more soils or miscellaneous areas in such an intricate pattern or in such small areas that they cannot be shown separately on the maps. The pattern and proportion of the soils or miscellaneous areas are somewhat similar in all areas. Alpha-Beta complex, 0 to 6 percent slopes, is an example. An association is made up of two or more geographically associated soils or miscellaneous areas that are shown as one unit on the maps. Because of present or anticipated uses of the map units in the survey area, it was not considered practical or necessary to map the soils or miscellaneous areas separately. The pattern and relative proportion of the soils or miscellaneous areas are somewhat similar. Alpha-Beta association, 0 to 2 percent slopes, is an example. An undifferentiated group is made up of two or more soils or miscellaneous areas that could be mapped individually but are mapped as one unit because similar interpretations can be made for use and management. The pattern and proportion of the soils or miscellaneous areas in a mapped area are not uniform. An area can be made up of only one of the major soils or miscellaneous areas, or it can be made up of all of them. Alpha and Beta soils, 0 to 2 percent slopes, is an example. Some surveys include miscellaneous areas. Such areas have little or no soil material and support little or no vegetation. Rock outcrop is an example. Custom Soil Resource Report 12 Cumberland County, North Carolina BaD—Blaney loamy sand, 8 to 15 percent slopes Map Unit Setting National map unit symbol: w6z3 Elevation: 160 to 660 feet Mean annual precipitation: 38 to 52 inches Mean annual air temperature: 61 to 70 degrees F Frost-free period: 210 to 245 days Farmland classification: Farmland of statewide importance Map Unit Composition Blaney and similar soils: 85 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Blaney Setting Landform: Low hills Landform position (two-dimensional): Shoulder Landform position (three-dimensional): Crest Down-slope shape: Convex Across-slope shape: Convex Parent material: Sandy and loamy marine deposits Typical profile A - 0 to 4 inches: loamy sand E - 4 to 25 inches: loamy sand Bt - 25 to 62 inches: sandy clay loam C - 62 to 80 inches: loamy coarse sand Properties and qualities Slope: 8 to 15 percent Depth to restrictive feature: More than 80 inches Natural drainage class: Well drained Runoff class: Medium Capacity of the most limiting layer to transmit water (Ksat): Moderately high (0.20 to 0.57 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water storage in profile: Low (about 4.0 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 3e Hydrologic Soil Group: C Ecological site: Loamy Backslope Woodland - PROVISIONAL (F137XY006GA) Hydric soil rating: No Custom Soil Resource Report 13 FaB—Faceville loamy sand, 2 to 6 percent slopes Map Unit Setting National map unit symbol: w70c Elevation: 80 to 330 feet Mean annual precipitation: 38 to 55 inches Mean annual air temperature: 59 to 70 degrees F Frost-free period: 210 to 265 days Farmland classification: All areas are prime farmland Map Unit Composition Faceville and similar soils: 80 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Faceville Setting Landform: Ridges on marine terraces, broad interstream divides on marine terraces Landform position (two-dimensional): Shoulder, summit Landform position (three-dimensional): Crest Down-slope shape: Convex Across-slope shape: Convex Parent material: Clayey marine deposits Typical profile Ap - 0 to 7 inches: loamy sand E - 7 to 17 inches: loamy sand Bt - 17 to 80 inches: clay Properties and qualities Slope: 2 to 6 percent Depth to restrictive feature: More than 80 inches Natural drainage class: Well drained Runoff class: Low Capacity of the most limiting layer to transmit water (Ksat): Moderately high to high (0.57 to 1.98 in/hr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Available water storage in profile: Moderate (about 7.8 inches) Interpretive groups Land capability classification (irrigated): None specified Land capability classification (nonirrigated): 2e Hydrologic Soil Group: B Hydric soil rating: No Custom Soil Resource Report 14 Soil Information for All Uses Soil Reports The Soil Reports section includes various formatted tabular and narrative reports (tables) containing data for each selected soil map unit and each component of each unit. No aggregation of data has occurred as is done in reports in the Soil Properties and Qualities and Suitabilities and Limitations sections. The reports contain soil interpretive information as well as basic soil properties and qualities. A description of each report (table) is included. Soil Physical Properties This folder contains a collection of tabular reports that present soil physical properties. The reports (tables) include all selected map units and components for each map unit. Soil physical properties are measured or inferred from direct observations in the field or laboratory. Examples of soil physical properties include percent clay, organic matter, saturated hydraulic conductivity, available water capacity, and bulk density. Engineering Properties (Parachute Rigging) This table gives the engineering classifications and the range of engineering properties for the layers of each soil in the survey area. Hydrologic soil group is a group of soils having similar runoff potential under similar storm and cover conditions. The criteria for determining Hydrologic soil group is found in the National Engineering Handbook, Chapter 7 issued May 2007(http:// directives.sc.egov.usda.gov/OpenNonWebContent.aspx?content=17757.wba). Listing HSGs by soil map unit component and not by soil series is a new concept for the engineers. Past engineering references contained lists of HSGs by soil series. Soil series are continually being defined and redefined, and the list of soil series names changes so frequently as to make the task of maintaining a single national list virtually impossible. Therefore, the criteria is now used to calculate the HSG using the component soil properties and no such national series lists will be maintained. All such references are obsolete and their use should be discontinued. Soil properties that influence runoff potential are those that influence the minimum rate of infiltration for a bare soil after prolonged wetting and when not frozen. These properties are depth to a seasonal high water table, saturated hydraulic conductivity after prolonged wetting, and depth to a layer with a very slow water transmission 15 rate. Changes in soil properties caused by land management or climate changes also cause the hydrologic soil group to change. The influence of ground cover is treated independently. There are four hydrologic soil groups, A, B, C, and D, and three dual groups, A/D, B/D, and C/D. In the dual groups, the first letter is for drained areas and the second letter is for undrained areas. The four hydrologic soil groups are described in the following paragraphs: Group A. Soils having a high infiltration rate (low runoff potential) when thoroughly wet. These consist mainly of deep, well drained to excessively drained sands or gravelly sands. These soils have a high rate of water transmission. Group B. Soils having a moderate infiltration rate when thoroughly wet. These consist chiefly of moderately deep or deep, moderately well drained or well drained soils that have moderately fine texture to moderately coarse texture. These soils have a moderate rate of water transmission. Group C. Soils having a slow infiltration rate when thoroughly wet. These consist chiefly of soils having a layer that impedes the downward movement of water or soils of moderately fine texture or fine texture. These soils have a slow rate of water transmission. Group D. Soils having a very slow infiltration rate (high runoff potential) when thoroughly wet. These consist chiefly of clays that have a high shrink-swell potential, soils that have a high water table, soils that have a claypan or clay layer at or near the surface, and soils that are shallow over nearly impervious material. These soils have a very slow rate of water transmission. Depth to the upper and lower boundaries of each layer is indicated. Texture is given in the standard terms used by the U.S. Department of Agriculture. These terms are defined according to percentages of sand, silt, and clay in the fraction of the soil that is less than 2 millimeters in diameter. "Loam," for example, is soil that is 7 to 27 percent clay, 28 to 50 percent silt, and less than 52 percent sand. If the content of particles coarser than sand is 15 percent or more, an appropriate modifier is added, for example, "gravelly." Classification of the soils is determined according to the Unified soil classification system (ASTM, 2005) and the system adopted by the American Association of State Highway and Transportation Officials (AASHTO, 2004). The Unified system classifies soils according to properties that affect their use as construction material. Soils are classified according to particle-size distribution of the fraction less than 3 inches in diameter and according to plasticity index, liquid limit, and organic matter content. Sandy and gravelly soils are identified as GW, GP, GM, GC, SW, SP, SM, and SC; silty and clayey soils as ML, CL, OL, MH, CH, and OH; and highly organic soils as PT. Soils exhibiting engineering properties of two groups can have a dual classification, for example, CL-ML. The AASHTO system classifies soils according to those properties that affect roadway construction and maintenance. In this system, the fraction of a mineral soil that is less than 3 inches in diameter is classified in one of seven groups from A-1 through A-7 on the basis of particle-size distribution, liquid limit, and plasticity index. Soils in group A-1 are coarse grained and low in content of fines (silt and clay). At the other extreme, soils in group A-7 are fine grained. Highly organic soils are classified in group A-8 on the basis of visual inspection. If laboratory data are available, the A-1, A-2, and A-7 groups are further classified as A-1-a, A-1-b, A-2-4, A-2-5, A-2-6, A-2-7, A-7-5, or A-7-6. As an additional refinement, the suitability of a soil as subgrade material can be indicated by a group Custom Soil Resource Report 16 index number. Group index numbers range from 0 for the best subgrade material to 20 or higher for the poorest. Percentage of rock fragments larger than 10 inches in diameter and 3 to 10 inches in diameter are indicated as a percentage of the total soil on a dry-weight basis. The percentages are estimates determined mainly by converting volume percentage in the field to weight percentage. Three values are provided to identify the expected Low (L), Representative Value (R), and High (H). Percentage (of soil particles) passing designated sieves is the percentage of the soil fraction less than 3 inches in diameter based on an ovendry weight. The sieves, numbers 4, 10, 40, and 200 (USA Standard Series), have openings of 4.76, 2.00, 0.420, and 0.074 millimeters, respectively. Estimates are based on laboratory tests of soils sampled in the survey area and in nearby areas and on estimates made in the field. Three values are provided to identify the expected Low (L), Representative Value (R), and High (H). Liquid limit and plasticity index (Atterberg limits) indicate the plasticity characteristics of a soil. The estimates are based on test data from the survey area or from nearby areas and on field examination. Three values are provided to identify the expected Low (L), Representative Value (R), and High (H). References: American Association of State Highway and Transportation Officials (AASHTO). 2004. Standard specifications for transportation materials and methods of sampling and testing. 24th edition. American Society for Testing and Materials (ASTM). 2005. Standard classification of soils for engineering purposes. ASTM Standard D2487-00. Custom Soil Resource Report 17 Absence of an entry indicates that the data were not estimated. The asterisk '*' denotes the representative texture; other possible textures follow the dash. The criteria for determining the hydrologic soil group for individual soil components is found in the National Engineering Handbook, Chapter 7 issued May 2007(http://directives.sc.egov.usda.gov/ OpenNonWebContent.aspx?content=17757.wba). Three values are provided to identify the expected Low (L), Representative Value (R), and High (H). Engineering Properties–Cumberland County, North Carolina Map unit symbol and soil name Pct. of map unit Hydrolo gic group Depth USDA texture Classification Pct Fragments Percentage passing sieve number—Liquid limit Plasticit y index Unified AASHTO >10 inches 3-10 inches 4 10 40 200 In L-R-H L-R-H L-R-H L-R-H L-R-H L-R-H L-R-H L-R-H BaD—Blaney loamy sand, 8 to 15 percent slopes Blaney 85 C 0-4 Loamy sand SM A-2-4 0- 0- 0 0- 0- 0 95-96-1 00 89-93-1 00 66-72- 82 18-23- 28 9-12 -14 NP 4-25 Loamy sand SM A-2-4 0- 0- 0 0- 0- 0 95-96-1 00 89-93-1 00 66-72- 82 18-23- 28 9-12 -14 NP 25-62 Sandy clay loam, sandy loam SC, SC- SM, SM A-4, A-6 0- 0- 0 0- 0- 0 95-97-1 00 86-92-1 00 68-80- 95 36-47- 59 0-20 -40 NP-10-2 0 62-80 Sandy loam, sandy clay loam, loamy sand, loamy coarse sand SC, SC- SM, SM A-1-b, A-2-4, A-4, A-6 0- 0- 0 0- 0- 0 95-97-1 00 86-92-1 00 45-51- 73 17-21- 39 0-10 -36 NP-0 -14 FaB—Faceville loamy sand, 2 to 6 percent slopes Faceville 80 B 0-7 Loamy sand SM A-2-4 0- 0- 0 0- 0- 0 91-95-1 00 76-87-1 00 58-69- 84 21-27- 35 9-12 -14 NP 7-17 Loamy sand SM A-2-4 0- 0- 0 0- 0- 0 91-95-1 00 76-87-1 00 58-69- 84 21-27- 35 9-12 -14 NP 17-80 Clay loam, clay, sandy clay CH, CL A-7-6, A-6 0- 0- 0 0- 0- 0 98-98-1 00 93-94-1 00 79-90-1 00 63-74- 88 25-39 -52 11-18-2 5 Custom Soil Resource Report 18 References American Association of State Highway and Transportation Officials (AASHTO). 2004. Standard specifications for transportation materials and methods of sampling and testing. 24th edition. American Society for Testing and Materials (ASTM). 2005. Standard classification of soils for engineering purposes. ASTM Standard D2487-00. Cowardin, L.M., V. Carter, F.C. Golet, and E.T. LaRoe. 1979. Classification of wetlands and deep-water habitats of the United States. U.S. Fish and Wildlife Service FWS/OBS-79/31. Federal Register. July 13, 1994. Changes in hydric soils of the United States. Federal Register. September 18, 2002. Hydric soils of the United States. Hurt, G.W., and L.M. Vasilas, editors. Version 6.0, 2006. Field indicators of hydric soils in the United States. National Research Council. 1995. Wetlands: Characteristics and boundaries. Soil Survey Division Staff. 1993. Soil survey manual. Soil Conservation Service. U.S. Department of Agriculture Handbook 18. http://www.nrcs.usda.gov/wps/portal/ nrcs/detail/national/soils/?cid=nrcs142p2_054262 Soil Survey Staff. 1999. Soil taxonomy: A basic system of soil classification for making and interpreting soil surveys. 2nd edition. Natural Resources Conservation Service, U.S. Department of Agriculture Handbook 436. http:// www.nrcs.usda.gov/wps/portal/nrcs/detail/national/soils/?cid=nrcs142p2_053577 Soil Survey Staff. 2010. Keys to soil taxonomy. 11th edition. U.S. Department of Agriculture, Natural Resources Conservation Service. http:// www.nrcs.usda.gov/wps/portal/nrcs/detail/national/soils/?cid=nrcs142p2_053580 Tiner, R.W., Jr. 1985. Wetlands of Delaware. U.S. Fish and Wildlife Service and Delaware Department of Natural Resources and Environmental Control, Wetlands Section. United States Army Corps of Engineers, Environmental Laboratory. 1987. Corps of Engineers wetlands delineation manual. Waterways Experiment Station Technical Report Y-87-1. United States Department of Agriculture, Natural Resources Conservation Service. National forestry manual. http://www.nrcs.usda.gov/wps/portal/nrcs/detail/soils/ home/?cid=nrcs142p2_053374 United States Department of Agriculture, Natural Resources Conservation Service. National range and pasture handbook. http://www.nrcs.usda.gov/wps/portal/nrcs/ detail/national/landuse/rangepasture/?cid=stelprdb1043084 19 United States Department of Agriculture, Natural Resources Conservation Service. National soil survey handbook, title 430-VI. http://www.nrcs.usda.gov/wps/portal/ nrcs/detail/soils/scientists/?cid=nrcs142p2_054242 United States Department of Agriculture, Natural Resources Conservation Service. 2006. Land resource regions and major land resource areas of the United States, the Caribbean, and the Pacific Basin. U.S. Department of Agriculture Handbook 296. http://www.nrcs.usda.gov/wps/portal/nrcs/detail/national/soils/? cid=nrcs142p2_053624 United States Department of Agriculture, Soil Conservation Service. 1961. Land capability classification. U.S. Department of Agriculture Handbook 210. http:// www.nrcs.usda.gov/Internet/FSE_DOCUMENTS/nrcs142p2_052290.pdf Custom Soil Resource Report 20 Parachute Rigging Facility Fort Bragg, Cumberland County, North Carolina Mason & Hanger Page - a.7 - APPENDIX G SUBSURFACE EXPLORATION AND GEOTECHNICAL ENGINEERING REPORT REPORT OF SUBSURFACE INVESTIGATION AND GEOTECHNICAL EVALUATION SOF Parachute Rigging Facility FORT BRAGG, NORTH CAROLINA BUILDING & EARTH PROJECT NUMBER RD180419 PREPARED FOR: ACC CONSTRUCTION COMPANY, INC. AUGUST 22, 2018 610 Spring Branch Road Dunn, North Carolina Ph: (910) 292-2085 www.BuildingAndEarth.com Birmingham, AL  Auburn, AL  Huntsville, AL  Montgomery, AL  Mobile, AL Tuscaloosa, AL  Columbus, GA  Louisville, KY  Raleigh, NC  Dunn, NC Jacksonville, NC  Springdale, AR  Little Rock, AR  Tulsa, OK  Oklahoma City, OK  Durant, OK August 22, 2018 ACC Construction Company 635 NW Frontage Road Augusta, GA 30907 Attention: Mr. Mason McKnight, IV Subject: Report of Subsurface Exploration and Geotechnical Evaluation SOF Parachute Rigging Facility Ft. Bragg, North Carolina Building & Earth Project No: RD180419 Mr. McKnight: Building & Earth Sciences, LLP has completed the authorized subsurface exploration and geotechnical engineering evaluation for the Ft. Bragg, SOF Parachute Rigging Facility located within the Yarborough Complex of Fort Bragg, North Carolina. The purpose of this exploration and evaluation was to determine general subsurface conditions at the site and to address applicable geotechnical aspects of the proposed construction and site development. The recommendations in this report are based on a physical reconnaissance of the site and observation and classification of samples obtained from twelve (12) soil test borings conducted at the site by Building & Earth Sciences, and thirteen (13) prior borings drilled by USACE for the preparation of the RFP. Confirmation of the anticipated subsurface conditions during construction is an essential part of geotechnical services. We appreciate the opportunity to provide consultation services for the proposed project. If you have any questions regarding the information in this report or need any additional information, please call us. Respectfully Submitted, BUILDING & EARTH SCIENCES, LLP Engineering Firm F-1081 Kurt. A. Miller, PE C. Mark Nolen, PE Raleigh Branch Manager Senior Vice President Page | i Table of Contents 1.0 PROJECT & SITE DESCRIPTION ........................................................................................................................... 1 2.0 SCOPE OF SERVICES ............................................................................................................................................... 3 3.0 GEOTECHNICAL SITE CHARACTERIZATION ................................................................................................... 4 3.1 GEOLOGY .................................................................................................................................................................. 5 3.2 EXISTING SURFACE CONDITIONS ........................................................................................................................... 5 3.3 SUBSURFACE CONDITIONS ..................................................................................................................................... 6 TOPSOIL ............................................................................................................................................................ 7 SILTY SAND (SM) ............................................................................................................................................ 7 CLAYEY SAND OR SANDY CLAY (SC OR CL) ................................................................................................ 7 AUGER REFUSAL ............................................................................................................................................... 7 GROUNDWATER ............................................................................................................................................... 8 SEISMIC SITE CLASSIFICATION ........................................................................................................................ 8 3.4 SEASONAL HIGH WATER TABLE AND INFILTRATION TESTING ........................................................................... 8 4.0 SITE DEVELOPMENT CONSIDERATIONS ......................................................................................................... 9 4.1 INITIAL SITE PREPARATION ..................................................................................................................................... 9 4.2 SUBGRADE EVALUATION ...................................................................................................................................... 10 4.3 MOISTURE SENSITIVE SOILS ................................................................................................................................ 11 4.4 UNDERCUTTING OR STABILIZATION OF LOW CONSISTENCY SOILS ................................................................ 11 4.5 STRUCTURAL FILL .................................................................................................................................................. 12 4.6 EXCAVATION CONSIDERATIONS .......................................................................................................................... 13 GROUNDWATER ............................................................................................................................................ 13 4.7 UTILITY TRENCH BACKFILL ................................................................................................................................... 13 4.8 LANDSCAPING AND DRAINAGE CONSIDERATION ............................................................................................ 13 4.9 WET WEATHER CONSTRUCTION ......................................................................................................................... 14 5.0 FOUNDATION RECOMMENDATIONS ............................................................................................................ 14 5.1 SHALLOW FOUNDATIONS .................................................................................................................................... 14 6.0 FLOOR SLABS .......................................................................................................................................................... 16 7.0 PAVEMENT CONSIDERATIONS ......................................................................................................................... 16 7.1 FLEXIBLE PAVEMENT ............................................................................................................................................. 17 7.2 RIGID PAVEMENT .................................................................................................................................................. 18 8.0 SUBGRADE REHABILITATION ............................................................................................................................ 18 9.0 CONSTRUCTION MONITORING ....................................................................................................................... 19 APPENDIX Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 1 1.0 PROJECT & SITE DESCRIPTION The subject site is located in the Yarborough Complex of Fort Bragg, on the north side of Urban Freedom Way, west of Tora Bora Road. Information relative to the proposed site and the proposed development is listed in Table 1 below. Photographs depicting the current site condition are presented on the following page. Development Item Detail Description General Site Size (Ac.) Approximately 12 Acres Existing Development Vacant, partially wooded land Vegetation Grass with some trees and shrubs Slopes No Retaining Walls No Drainage Appears poorly drained, standing water onsite Cuts & Fills Up to 4 feet of fill Proposed Buildings No. of Bldgs 1 Square Ft. 84,500 Stories 1 Construction Pre-fabricated steel frame Column Loads 125 kips Wall Loads 4 klf Preferred Foundation Conventional shallow spread Preferred Slab Concrete slab-on-grade Pavements Traffic Provided Standard Duty Yes, Flexible Heavy Duty Yes, Rigid and Flexible Table 1: Project and Site Description Reference: RFP Documents – SOF parachute Rigging Facility at Fort Bragg, North Carolina Notes: 1. If actual loading conditions exceed our anticipated loads, Building & Earth Sciences should be allowed to review the proposed structural design and its effects on our recommendations for foundation design. 2. Since information on final grades was not provided for this site, assumptions have been made regarding grades for the purpose of this report. Therefore, it will be essential for Building & Earth to review the final grading plans, when they become available, and be contracted to provide supplemental recommendations prior to starting construction. Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 2 Figure 1: Looking Northeast across site from boring B-01 Figure 2: Looking west from NE boundary Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 3 2.0 SCOPE OF SERVICES The authorized subsurface exploration was performed on July 31 and August 1, 2018 in general conformance with our proposal RD20008, dated January 16, 2018. Occasionally some modification of the scope outlined in our proposal is required to provide for proper evaluation of the encountered subsurface conditions. The proposal included a base bid for the Building & Main Site, and an option for 160 POV Parking Lot. Both the base bid and option were performed for this study. The purpose of the geotechnical exploration was to determine general subsurface conditions at specific boring locations and to gather data on which to base a geotechnical evaluation with respect to the proposed construction. The subsurface exploration for this project consisted of twelve (12) soil test borings. The site was drilled using a Geoprobe drill rig equipped with an automatic hammer. In addition to SPT sampling, our testing also included dilatometer testing in general accordance with ASTM D6635. This method of testing in-situ soil advances a flat plate dilatometer into the soil profile using the downward pressure from a truck mounted drill rig. At selected depths, the dilatometer is expanded into the soil mass and is able to provide information regarding penetration resistance, lateral stress and deformation modulus of the soil. Using empirical data this dilatometer information can better predict soil strength parameters that are used in the settlement analysis. The intent of this additional testing was to be better evaluate the settlement potential of the soils within the upper 10 to 15 feet of the soil profile. The soil boring locations were determined in the field by a representative of our staff by measuring from existing site features. As such, the boring locations shown on the Boring Location Plan attached to this report should be considered approximate. The soil samples recovered during our site investigation were visually classified and specific samples were selected by the project engineer for laboratory analysis. The laboratory analysis consisted of: Test ASTM No. of Tests Natural Moisture Content D2216 5 Atterberg Limits D4318 5 Material Finer Than No. 200 Sieve by Washing D1140 5 Modified Proctor with California Bearing ratio D1557/D1883 1 Table 2: Scope of Laboratory Tests Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 4 The results of the laboratory analysis are presented on the enclosed Boring Logs and in tabular form in the Appendix of this report. Descriptions of the laboratory tests that were performed are also included in the Appendix. The information gathered from the exploration was evaluated to determine a suitable foundation type for the proposed structure. The information was also evaluated to help determine if any special subgrade preparation procedures will be required during the earthwork phase of the project. The results of the work are presented within this report that addresses:  Summary of existing surface conditions.  A description of the subsurface conditions encountered at the exploration locations.  Site preparation considerations including material types to be expected during foundation construction and mass grading as well as recommendations regarding handling and treatment of unsuitable soils, if encountered.  Compaction requirements and recommended criteria to establish suitable surfaces for structural backfill.  Subsurface soil logs that detail properties of the materials encountered with soil classifications and depth to bedrock (if encountered).  Presentation of laboratory test results.  Recommendations for foundation and pavement design.  Plans and maps showing the location of the project and our onsite work. 3.0 GEOTECHNICAL SITE CHARACTERIZATION The following discussion is intended to create a general understanding of the site from a geotechnical engineering perspective. It is not intended to be a discussion of every potential geotechnical issue that may arise, nor to provide every possible interpretation of the conditions identified. The following conditions and subsequent recommendations are based on the assumption that significant changes in subsurface conditions do not occur between boreholes. However, anomalous conditions can occur due to variations in existing fill that may be present at the site, or the geologic conditions at the site, and it will be necessary to evaluate the assumed conditions during site grading and foundation installation. Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 5 3.1 GEOLOGY Situated near the western boundary of the North Carolina Coastal Plain physiographic province, published geologic maps indicate that the subject site is underlain by cretaceous aged soil deposits associated with the Middendorf and Cape Fear geologic formations. These formations are generally composed of sandstone and mudstone. The Soil Survey of Cumberland and Hoke Counties, North Carolina (USDA Soil Conservation Service) describes the area as characterized by deep sedimentary soils, ranging in depth from about 200 to about 400 feet in depth. 3.2 EXISTING SURFACE CONDITIONS The Parachute Rigging Facility site is described as fairly level and at the time of our site reconnaissance, the site was very wet, and there were large areas of shallow standing water across the site. Surface elevations range from approximately 260 to 270 ft. MSL. With a proposed finished floor elevation at about 266 feet, up to three to four feet of cut and fill will be required to achieve finished grades. The site has been used in the past as part of an ammunitions storage area, and there are fenced compounds and asphalt roadways that traverse the site. From a review of historical aerial photographs on Google Earth, a small storage building with a loop road may have been located on the eastern portion of the site. This building is able to be seen in the photographs before 2012. Storm drainage has been installed along Urban Freedom Way, and temporary storm basins are also present. Ground cover is generally grass, with some trees and shrubs that will require removal as part of site preparation operations. The remaining trees are along old “D” Street. Below is an aerial photograph of the site as it appears at the time of the 2/2018 aerial photograph. Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 6 Figure 3: Google Earth Aerial Photograph with Approximate Site Boundary 3.3 SUBSURFACE CONDITIONS A generalized stratification summary has been prepared using data from the soil test borings drilled by Building & Earth and is presented in the table below. The stratification depicts the general soil conditions and strata types encountered during our field investigation. Stratum No. Typical Thickness Description Consistency 1 3 to 12 inches Topsoil N.A. 2 1.2 to 2.7 ft. Silty Sand Very loose to loose 3 12.4 to 23.3+ Clayey Sand and Sandy Clay Loose to medium dense, and Soft to Hard Table 3: Stratification Summary Subsurface soil profiles have also been prepared based on the data obtained at the specific boring locations. The subsurface soil profiles are presented in the Appendix. For specific details on the information obtained from individual soil borings, please refer to the Boring Logs included in the Appendix. The elevations of the borings indicated in this report, and shown on the boring logs, were provided by Joyner Kersey, a local survey firm. Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 7 TOPSOIL Topsoil encountered on site ranged from about 3 to 12 inches, with an average about 5 to 6 inches. No testing has been performed to verify these soils meet the requirements of “topsoil”. Topsoil depths reported on the boring logs should only be considered an estimate and topsoil thickness may vary in unexplored portions of the site. SILTY SAND (SM) Soils described as silty sand (SM) were observed in 8 of the 12 borings. The silty sand material extends from below the topsoil to depths up to 3 feet below the surface. This material was not observed in borings B-102, P-101, P-102 or P-107. This soil is further describes as very loose to loose, and occasionally medium dense red to brown, and moist to dry. N-values range from 2 to 10 blows per foot, with values in the range 4 to 6 blows per foot considered representative. Atterberg limits and wash 200 grain size testing was performed on a sample collected from the depth interval 0.0 to 1.5 ft. in boring B-101. The testing indicates a liquid limit of 14, a plasticity index of 1, and 30.4 percent of the material passes a # 200 sieve. These data correspond to an ASTM classification Silty Sand (SM). CLAYEY SAND OR SANDY CLAY (SC OR CL) Below the silty sand layer, and below the topsoil in test borings B-102, P-101, P-102 and P-107, soils described as sandy clay (CL) and clayey sand (SC) were encountered. This layer also included inconsistent layers of silty sand (SM). This material is poorly layered in the test borings, resulting in significant variation with respect to classification and consistency. This soil is further described as very loose to medium dense, and occasionally medium dense red to brown, and moist to dry. N-values range from 2 to 10 blows per foot, with values in the range 4 to 6 blows per foot considered representative. Atterberg limits and wash 200 grain size testing was performed on representative samples collected from this layer. The testing indicates a fines content of 35 to 45 percent, and liquid limits ranging from 14 to 47, and a plastic index of 16 to 18. AUGER REFUSAL Auger refusal is the drilling depth at which the borehole can no longer be advanced using soil drilling procedures. Auger refusal can occur on hard soil, boulders, buried debris or bedrock. Coring is required to sample the material below auger refusal. Auger refusal was not encountered in borings drilled for this study. Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 8 GROUNDWATER At the time of drilling, groundwater was not observed in the test borings. Water levels reported are accurate only for the time and date that the borings were drilled. Long term monitoring of the boreholes was not included as part of our subsurface exploration. The borings were backfilled the same day that they were drilled. SEISMIC SITE CLASSIFICATION The seismic survey was not complete at the time this report was issued. The seismic survey will be completed and reported as an addendum to this report. 3.4 SEASONAL HIGH WATER TABLE AND INFILTRATION TESTING In order to measure the depth to the Season High Water Table (SHWT), Mr. Mike Eaker, a North Carolina Licensed Soil Scientist with Southeastern Soil & Environmental Associates, Inc., under contract to Building & Earth Sciences, performed the field measurements and provided a letter summarizing his work. Mr. Eaker’s report details the procedures used in his field evaluation, the results of his soil observations, the depth to SHWT, and the depth to observed water at each test location. Mr. Eaker’s report is included in the Appendix. Once the SHWT was measured, infiltration testing was performed as shown on the provided plans from Stantec. The results of the testing are included in the Appendix of this report. The flow of the near-surface soils has been approximated using the concepts presented in Bernoulli’s Equation for steady state flow and Darcy’s Law for fluid flow through a porous media. Additionally, our Ksat values were calculated using the Glover solution, which is dependent on the geometry of the borehole and the hydraulic head. To develop our results, Building & Earth has measured the saturated flow rate (Ksat) for the soils at the site using accepted test methods and equipment in general accordance with ASTM D5126 {4.1.6} (Standard Guide for Comparison of Field Methods for Determining Hydraulic Conductivity in the Vadose Zone). Ultimately, the drainage of the basins will be a function of the saturated flow rate of the soils, the surface area of the basin geometry, and the pressure differential (hydraulic head) induced by the storm water levels in the pond. In order to determine the appropriate Ksat for the soils in the basin, a small diameter bore hole was advanced to a pre-determined depth of interest. At this depth, a constant head (pressure) was established and maintained. Once our measurements approached a stabilized flow rate, our test was terminated. Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 9 4.0 SITE DEVELOPMENT CONSIDERATIONS Since information on final grades was not provided for this site, assumptions have been made regarding grades for the purpose of this report. Therefore, it will be essential for Building & Earth to review the final grading plans, when they become available, and be contracted to provide supplemental recommendations prior to starting construction. Based on surface elevations at the boring sites and upon USGS topographic data, we anticipate cuts and fills in the range of about 3 to 4 feet will be required to prepare the site for the building pad and pavement areas. Based on our evaluation of the subsurface soil information, and the anticipated foundation loads, it appears that construction with a conventional spread foundation system is feasible. The site development recommendations outlined below are intended for development of the site to support construction with a conventional spread foundation system. If a different type of foundation system is preferred, Building & Earth should be allowed to review the site development recommendations to verify that they are appropriate for the preferred foundation system. The primary geotechnical concerns for this project are: ◾ Relatively soft and loose soils at the project surface, extending to depths generally 2 feet, and in some cases up to 8 feet below the surface (B-105, RFP B-03 and RFP B-05). ◾ Fill placement ◾ Moisture sensitive soils. Recommendations addressing the site conditions are presented in the following sections. 4.1 INITIAL SITE PREPARATION All trees, roots, topsoil and deleterious materials should be removed from the proposed construction areas. Approximately 5 to 6 inches of topsoil were observed in the borings, with up to 12 inches observed in one of the borings. A geotechnical engineer should observe stripping and grubbing operations to evaluate that all unsuitable materials are removed from areas to receive buildings and pavements. Because of the past use of the site, buried structures could be encountered such as foundations, utility lines, septic tanks, etc. If encountered, they should be removed and backfilled in accordance with requirements outlined in the Structural Fill section of this report. Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 10 Standing water was observed on the site during the evaluation. Due to the moisture sensitive nature of the on-site soils, positive drainage and temporary dewatering methods (as discussed in Section 4.3) is important to help avoid degradation and softening of the soils. Materials disturbed during clearing operations should be stabilized in place or, if necessary, undercut to undisturbed materials and backfilled with properly compacted, approved structural fill. During site preparation activities, the contractor should identify borrow source materials that will be used as structural fill and provide samples to the testing laboratory so that conformance to the Structural Fill requirements outlined below and appropriate moisture-density relationship curves can be determined. 4.2 SUBGRADE EVALUATION We recommend that the project geotechnical engineer or a qualified representative evaluate the subgrade after the site is prepared. Some unsuitable or unstable areas may be present in unexplored areas of the site, and relatively soft or loose soils were noted within the upper 2 to 3 feet of all the borings, occasionally extending to depths up to 8 feet below the surface. All areas that will require fill or that will support structures should be carefully proofrolled with a heavy (40,000 # minimum), rubber-tired vehicle at the following times. ◾ After an area has been stripped, and undercut if required, prior to the placement of any fill. ◾ After grading an area to the finished subgrade elevation in a building or pavement area. ◾ After areas have been exposed to any precipitation, and/or have been exposed for more than 48 hours. Some instability may exist during construction, depending on climatic and other factors immediately preceding and during construction. If any soft or otherwise unsuitable soils are identified during the proofrolling process, they must be undercut or stabilized prior to fill placement, pavement construction, or floor slab construction. All unsuitable material identified during the construction shall be removed and replaced in accordance with the Structural Fill section of this report. Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 11 4.3 MOISTURE SENSITIVE SOILS Moisture sensitive silty sands (SM), clayey sands (SC) and sandy clays (CL) were encountered across the site during the subsurface exploration. These soils will degrade if allowed to become saturated. Therefore, not allowing water to pond by maintaining positive drainage and temporary dewatering methods (if required) is important to help avoid degradation and softening of the soils. The contractor should anticipate some difficulty during the earthwork phase of this project if moisture levels are moderate to high during construction. Increased moisture levels will soften the subgrade and the soils may become unstable under the influence of construction traffic. Accordingly, construction during wet weather conditions should be avoided, as this could result in soft and unstable soil conditions that would require ground modification, such as in place stabilization or undercutting. 4.4 UNDERCUTTING OR STABILIZATION OF LOW CONSISTENCY SOILS Low consistency soils (N≤6) were encountered in all of the borings within the building footprint in the upper 2 to 3 feet. Soft or loose soils, extending to depths of about 6 to 8 feet, were encountered in borings B-105, RFP B-03, and RFP B-05. The near-surface low consistency soils encountered within the building footprint should be undercut to a stable, suitable subgrade. Although it may be possible to stabilize some of the surficial soils in-place, it appears undercuts on the order of 2 to 3 feet can be anticipated within the building pad. The undercutting should extend laterally at least 5 feet outside building and parking lot footprints. Deeper undercuts may be required beneath foundations in isolated areas, which is discussed further in Section 5.0. Where soft or loose surficial soils can be stabilized in place, it is recommended these materials be densified using a heavy (10-ton minimum), smooth-drum vibratory roller. A rolling pattern should be determined during densification operations that will result in a sufficiently stable subgrade. Undercut depths within the planned pavement areas will be highly dependent upon final grades and subgrade evaluation results. Undercutting should extend laterally at least 3 feet outside of the edge of pavement. In pavement areas, it may be possible to reduce undercutting or stabilize the soft soils in place. Typical stabilization methods vary widely and include modification of the soft soils with the addition of shot rock or No. 2 stone, as well as utilization of geogrids and graded aggregates. The design of a specific stabilization method is beyond the scope of this investigation but can be provided by Building & Earth as an additional service if desired. Any undercutting Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 12 or stabilization performed in pavement areas should be conducted under the observation of the geotechnical engineer or his representative. Some unsuitable or unstable areas may be present in unexplored areas of the site. Once the known undercut is complete, the areas planned for construction should be proofrolled in order to identify any additional soft soils requiring removal. Undercut soils should be replaced with structural fill. Clean, non-organic, non-saturated soils taken from the undercut area can be re-used as structural fill. The placement procedure, compaction and composition of the structural fill must meet the requirements of the Structural Fill section of this report. 4.5 STRUCTURAL FILL Requirements for structural fill on this project are as follows: Soil Type USCS Classification Property Requirements Placement Location Sand and Gravel GW, GP, GM, SW, SP, SM or combinations Maximum 2” particle size Pavement subgrades, building pads where the material can be confined. Clay CL, SC, GC LL<50, PI<25, d>100 pcf All areas Clay CH LL>50, PI>25, d>100 pcf Not recommended for use Silt ML (with no sand), MH N/A Not recommended for use On-site soils CL, SC, SM LL<50, PI<25, d>100 pcf All Areas Table 5: Structural Fill Requirements Notes: 1. LL indicates the soil Liquid Limit; PI indicates the soil Plasticity Index; d indicates the maximum dry density as defined by the density standard outlined in the table below. 2. Laboratory testing of the soils proposed for fill must be performed in order to verify their conformance with the above recommendations. 3. Any fill to be placed at the site should be reviewed by the geotechnical engineer. Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 13 Placement requirements for structural fill are as follows: Specification Requirement Lift Thickness 8” loose, 6” compacted Density 92 Percent maximum per ASTM D-1557 all structural area below 24 inches 95 percent maximum per ASTM D-1557, all structural areas, top 24 inches Moisture +/- 3.0 Percentage Points ASTM D-1557 Optimum Density Testing Frequency 1 test per 2,500 S.F. Minimum 2 tests per lift Table 6: Structural Fill Placement Requirements 4.6 EXCAVATION CONSIDERATIONS All excavations performed at the site should follow OSHA guidelines for temporary excavations. Excavated soils should be stockpiled according to OSHA regulations to limit the potential cave-in of soils. GROUNDWATER Groundwater was not encountered in the test borings. However, groundwater could be encountered during construction, particularly during undercutting operations. It should be noted that fluctuations in the water level could occur due to seasonal variations in rainfall. The contractor must be prepared to remove groundwater seepage from excavations if encountered during construction. Excavations extending below groundwater levels will require dewatering systems (such as well points, sump pumps or trench drains). The contractor should evaluate the most economical and practical dewatering method. 4.7 UTILITY TRENCH BACKFILL All utility trenches must be backfilled and compacted in the manner specified above for structural fill. It may be necessary to reduce the lift thickness to 4 to 6 inches to achieve compaction using hand-operated equipment. 4.8 LANDSCAPING AND DRAINAGE CONSIDERATION The potential for soil moisture fluctuations within building areas and pavement subgrades should be reduced to lessen the potential of subgrade movement. Site grading should include positive drainage away from buildings and pavements. Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 14 Excessive irrigation of landscaping poses a risk of saturating and softening soils below shallow footings and pavements, which could result in settlement of footings and premature failure of pavements. 4.9 WET WEATHER CONSTRUCTION During rainy periods, additional effort will be required to properly prepare the site and establish/maintain an acceptable subgrade. The difficulty will increase in areas where clay or silty soils are exposed at the subgrade elevation. Likewise, rainwater may become perched on the silty and higher consistency soils encountered below the surficial layers, which could require additional dewatering efforts not needed during dry conditions. Grading contractors typically postpone grading operations during wet weather to wait for conditions that are more favorable. Contractors can typically disk or aerate the upper soils to promote drying during intermittent periods of favorable weather. When deadlines restrict postponement of grading operations, additional measures such as undercutting and replacing saturated soils or stabilization can be utilized to facilitate placement of additional fill material. 5.0 FOUNDATION RECOMMENDATIONS It is our understanding that individual column loads will be 125 kips, and that wall loads will be about 4 kips per lineal foot. Our geotechnical analysis and recommendations are based upon these loading magnitudes. If these assumptions concerning structural loading are incorrect, our office should be contacted, such that our recommendations can be reviewed. 5.1 SHALLOW FOUNDATIONS Based on the conditions encountered during our field investigation and after our site preparation and grading recommendations are implemented, the proposed structure can be supported on conventional shallow foundations designed using an allowable soil bearing capacity of 2,500 psf. Even though computed footing dimensions may be less, column footings should be at least 24 inches wide and strip footings should be at least 18 inches wide. These dimensions facilitate hand cleaning of footing subgrades disturbed by the excavation process and the placement of reinforcing steel. They also reduce the potential for localized punching shear failure. All exterior footings should bear at least 24 inches below the adjacent exterior grade. Total settlement of footings designed and constructed as recommended above should be 1 inch or less. Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 15 Soft and loose soils were encountered at and below anticipated footing depth in borings B-105, RFP B-03, and RFP B-05. It’s possible these conditions will be encountered in other, unexplored areas of the building; therefore, verification of bearing capacity will be critical. We recommend that hand rod probing and dynamic cone penetrometer (DCP) testing in accordance with ASTM STP-399 be performed for all foundation excavations. Hand rod probing should be performed for 100 percent of the excavations, and DCP testing should be performed for at least 30 percent of the interior column footings, and for each 50-foot increment of wall footings. In the event that loose/soft soils are encountered during footing inspections, undercutting and/or stabilization recommendations will be determined based on the results of these tests. The contractor should be prepared to undercut these soils to the recommended depth and backfill with NCDOT washed No. 57 stone. The washed No. 57 stone should be wrapped in filter fabric if groundwater (perched or otherwise) is encountered. The following items should be considered during the preparation of construction documents and foundation installation: ◾ The geotechnical engineer of record should observe the exposed foundation bearing surfaces prior to concrete placement to verify that the conditions anticipated during the subsurface exploration are encountered. ◾ All bearing surfaces must be free of soft or loose soil prior to placing concrete. ◾ Concrete should be placed the same day the excavations are completed and bearing materials verified by the engineer. If the excavations are left open for an extended period, or if the bearing surfaces are disturbed after the initial observation, then the bearing surfaces should be reevaluated prior to concrete placement. ◾ Water should not be allowed to pond in foundation excavations prior to concrete placement or above the concrete after the foundation is completed. ◾ Wherever possible, the foundation concrete should be placed “neat”, using the sides of the excavations as forms. Where this is not possible, the excavations created by forming the foundations must be backfilled with suitable structural fill and properly compacted. ◾ The building pad should be sloped to drain away from the building foundations. ◾ Roof drains should be routed away from the foundation soils. Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 16 6.0 FLOOR SLABS Site development recommendations presented in this report should be followed to provide for subgrade conditions suitable for support of grade supported slabs. Floor slabs will be supported on either stable, natural subgrade or on compacted structural fill. Floor slabs for the proposed building should be supported on a minimum four (4) inches thick compacted layer of free-draining, granular material, such as AASHTO No. 610 or 57 stone. The purpose of this layer is to serve as a leveling cou rse and act as a capillary break for moisture migration through the subgrade soil. With addition of the granular material, an effective modulus of subgrade reaction of 150 pci can be used in the design of grade supported building floor slabs. Depending on the proposed floor covering, consideration should be given to the use of a polyethylene vapor barrier. The slabs should be appropriately reinforced (if required) to support the proposed loads. 7.0 PAVEMENT CONSIDERATIONS Based on the materials encountered at the boring locations and after our recommendations for site preparation are implemented, pavements at the subject site may be designed based on a California Bearing Ratio (CBR) of five (5) percent. Note that CBR testing was performed, and under ideal circumstances, the subgrade soils can be compacted to achieve a considerably higher CBR value. However, for the purposes of this final geotechnical report, a CBR of 5% was used to evaluate the required pavement thicknesses. Pavement design has been performed to address parameters appearing in 3.6 of Section 01 11 02 of the RFP documents. This document references the 2012 edition of the North Carolina Department of Transportation Standard Specifications for Roads and Structures, Department of Defense document UFC 3-250-01 Pavement Design for Roads and Parking Areas, and Ft. Bragg Installation Requirements. Pavement analysis and design has been completed using the U.S. Army COE PCASE 2.09.05 pavement design program. Traffic loads, as required in the proposal documents, appear in Table 6, below. Design and analysis are based on the provided traffic loading over a 25-year design life. Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 17 Type Vehicle Passes per Life Span Standard Duty Flexible Pavement Heavy Duty Rigid Pavement HS20 Trucks 5-Axle (72,000 # Vehicle Wt.) 0 18,250 CMP 60 Fork Lift (10,000# Vehicle Wt.) 0 1,300 HMMWV 1.25-Ton Carrier (10,000# Vehicle Wt.) 4,562,500 4,562,500 P-23 Crash Truck (Fire Truck) (77,880 # Vehicle Wt.) 0 1,300 Truck – 3-Axle (66,000# Vehicle Wt.) 0 1,300 Table 7: Provided Traffic Volume It is the owner’s responsibility to evaluate whether or not the traffic volumes shown above are in line with those expected. If the owner would like Building & Earth to assess other likely traffic volumes, we will gladly review other options. Note: All subgrade, base and pavement construction operations should meet minimum requirements of the NCDOT Standard Specifications for Road and Bridge Construction. The applicable sections of the specifications are identified as follows: Material Specification Section Portland Cement Concrete Pavement 710 Bituminous Asphalt Wearing Layer 610 Bituminous Asphalt Binder Layer 610 Mineral Aggregate Base Materials 520 Soil 500 Table 8: NCDOT Specification Sections 7.1 FLEXIBLE PAVEMENT The asphalt pavement section described herein was evaluated using the pavement design program PCASE 2.09.05 described above. The minimum required pavement section was evaluated and found to be acceptable. This section is summarized below in Table 9. Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 18 Minimum Design Thickness (in) Material Standard Duty 2 Asphalt 6 Unbound Crushed Stone Base Table 9: Asphalt Pavement Recommendations 7.2 RIGID PAVEMENT The following rigid pavement sections is that appearing in the project documents as a minimum acceptable section. Analysis confirms this section is suitable for support of the heavy-duty traffic summarized in Table 6. This section was analyzed for suitability based upon the traffic loading and other parameters tabulated above. Minimum Design Thickness (in) Material Heavy Duty 6.0 Portland Cement Concrete, (S’c) of 650 psi 6.0 Crushed Stone Base Table 10: Rigid Pavement Recommendations The concrete should be protected against moisture loss, rapid temperature fluctuations, and construction traffic for several days after placement. All pavements should be sloped for positive drainage. We recommended that the pavements be reinforced to hold any cracks that might develop tightly together and restrain their growth. All pavement components must be placed and compacted in accordance with the applicable sections of the North Carolina Standard Specifications for Road and Bridge Construction. All subgrade, base and pavement construction operations should meet minimum requirements of this document. 8.0 SUBGRADE REHABILITATION The subgrade soils often become disturbed during the period between initial site grading and construction of surface improvements. The amount and depth of disturbance will vary with soil type, weather conditions, construction traffic, and drainage. The engineer should evaluate the subgrade soil during final grading and prior to stone placement to verify that the subgrade is suitable to receive pavement base or floor slabs. The final evaluation may include proofrolling or density tests. Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 19 Subgrade rehabilitation can become a point of controversy when different contractors are responsible for mass and final grading. The construction documents should specifically state which contractor will be responsible for maintaining and rehabilitating the subgrade. Rehabilitation may include wetting, mixing, and re-compacting soils that have dried excessively or drying soils that have become wet. 9.0 CONSTRUCTION MONITORING Field verification of site conditions is an essential part of the services provided by the geotechnical consultant. In order to confirm our recommendations, it will be necessary for Building & Earth personnel to make periodic visits to the site during site grading. Typical construction monitoring services are listed below. ◾ Site stripping and subgrade evaluation ◾ Placement of controlled, engineered fill ◾ Foundation bearing surfaces, reinforcing steel and concrete ◾ Structural framing ◾ Pavement subgrade and crushed stone base installation ◾ All other items subject to IBC Special Inspections 10.0 CLOSING AND LIMITATIONS This report was prepared for ACC Construction Company, for specific application to the SOF Parachute Rigging Facility located within Fort Bragg, North Carolina. The information in this report is not transferable. This report should not be used for a different development on the same property without first being evaluated by the engineer. The recommendations in this report were based on the information obtained from our field exploration and laboratory analysis. The data collected is representative of the locations tested. Variations are likely to occur at other locations throughout the site. Engineering judgment was applied in regards to conditions between borings. It will be necessary to confirm the anticipated subsurface conditions during construction. This report has been prepared in accordance with generally accepted standards of geotechnical engineering practice. No other warranty is expressed or implied. In the event that changes are made, or anticipated to be made, to the nature, design, or location of the project as outlined in this report, Building & Earth must be informed of the changes and given the opportunity to either verify or modify the conclusions of this report in writing, or the recommendations of this report will no longer be valid. Subsurface Exploration and Geotechnical Evaluation, SOF Parachute Rigging Facility Project No: RD180419, August 22, 2018 Page | 20 The scope of services for this project did not include any environmental assessment of the site or identification of pollutants or hazardous materials or conditions. If the owner is concerned about environmental issues Building & Earth would be happy to provide an additional scope of services to address those concerns. This report is intended for use during design and preparation of specifications and may not address all conditions at the site during construction. Contractors reviewing this information should acknowledge that this document is for design information only. An article published by the Geoprofessional Business Association (GBA), titled Important Information About Your Geotechnical Report, has been included in the Appendix. We encourage all individuals to become familiar with the article to help manage risk. Appendix Table of Contents GEOTECHNICAL INVESTIGATION METHODOLOGIES ........................................................................................... 1 DRILLING PROCEDURES – STANDARD PENETRATION TEST (ASTM D1586) ........................... 1 BULK SAMPLING ............................................................................................................................................... 1 BORING LOG DESCRIPTION ............................................................................................................................................ 2 DEPTH AND ELEVATION ................................................................................................................................ 2 SAMPLE TYPE ..................................................................................................................................................... 2 SAMPLE NUMBER ............................................................................................................................................. 2 BLOWS PER INCREMENT, REC%, RQD% ................................................................................................. 2 SOIL DATA ........................................................................................................................................................... 2 SOIL DESCRIPTION .......................................................................................................................................... 3 GRAPHIC .............................................................................................................................................................. 3 REMARKS ............................................................................................................................................................. 3 SOIL CLASSIFICATION METHODOLOGY..................................................................................................................... 4 KEY TO LOGS ......................................................................................................................................................................... 6 KEY TO HATCHES ................................................................................................................................................................ 8 BORING LOCATION PLAN ............................................................................................................................................... 9 SUBSURFACE SOIL PROFILES ........................................................................................................................................ 10 BORING LOGS ..................................................................................................................................................................... 11 RFP BORING LOGS ............................................................................................................................................................ 12 LABORATORY TEST PROCEDURES .............................................................................................................................. 13 DESCRIPTION OF SOILS (VISUAL-MANUAL PROCEDURE) (ASTM D2488) ............................. 13 NATURAL MOISTURE CONTENT (ASTM D2216) ............................................................................... 13 ATTERBERG LIMITS (ASTM D4318) .......................................................................................................... 13 MATERIAL FINER THAN NO. 200 SIEVE BY WASHING (ASTM D1140) ..................................... 13 MODIFIED PROCTOR COMPACTION TEST (ASTM D1557) ............................................................ 13 LABORATORY CALIFORNIA BEARING RATIO (ASTM D1883) ....................................................... 14 LABORATORY TEST RESULTS ..................................................................................................................... 14 Table A-1: General Soil Classification Test Results ....................................................................... 14 SEASONAL HIGH WATER TABLE REPORT ................................................................................................................ 15 INFILTRATION TESTING .................................................................................................................................................. 16 GEOTECHNICAL CALCULATION SAMPLES .............................................................................................................. 17 IMPORTANT INFORMATION ABOUT THIS GEOTECHNICAL-ENGINEERING REPORT ............................ 18 GEOTECHNICAL INVESTIGATION METHODOLOGIES The subsurface exploration, which is the basis of the recommendations of this report, has been performed in accordance with industry standards. Detailed methodologies employed in the investigation are presented in the following sections. DRILLING PROCEDURES – STANDARD PENETRATION TEST (ASTM D1586) At each boring location, soil samples were obtained at standard sampling intervals with a split-spoon sampler. The borehole was first advanced to the sample depth by augering and the sampling tools were placed in the open hole. The sampler was then driven 18 inches into the ground with a 140-pound automatic hammer free-falling 30 inches. The number of blows required to drive the sampler each 6-inch increment was recorded. The initial increment is considered the “seating” blows, where the sampler penetrates loose or disturbed soil in the bottom of the borehole. The blows required to penetrate the final two (2) increments are added together and are referred to as the Standard Penetration Test (SPT) N-value. The N-value, when properly evaluated, gives an indication of the soil’s strength and ability to support structural loads. Many factors can affect the SPT N-value, so this result cannot be used exclusively to evaluate soil conditions. The SPT testing was performed using a drill rig equipped with an automatic hammer. Automatic hammers mechanically control the height of the hammer drop, and doing so, deliver higher energy efficiency (90 to 99 % efficiency) than manual hammers (60 % efficiency) which are dropped using a manually operated rope and cathead system. Because historic data correlations were developed based on use of a manual hammer, it is necessary to adjust the N-values obtained using an automatic hammer to make these correlations valid. Therefore, an energy correction factor of 1.3 was applied to the recorded field N-values from the automatic hammer for the purpose of our evaluation. The N-values discussed or mentioned in this report and shown on the boring logs are recorded field values. Samples retrieved from the boring locations were labeled and stored in plastic bags at the jobsite before being transported to our laboratory for analysis. The project engineer prepared Boring Logs summarizing the subsurface conditions at the boring locations. BULK SAMPLING Bulk sample are obtained for the evaluation of the compaction characteristics of the site soils and for determination of the California Bearing Ratio (CBR). The bulk samples are obtained from manual excavations, backhoe test pits, or from auger cutting. Similar soils are normally combined to provide samples of adequate size for compaction or CBR testing. BORING LOG DESCRIPTION Building & Earth Sciences, Inc. used the gINT software program to prepare the attached boring logs. The gINT program provides the flexibility to custom design the boring logs to include the pertinent information from the subsurface exploration and results of our laboratory analysis. The soil and laboratory information included on our logs is summarized below: DEPTH AND ELEVATION The depth below the ground surface and the corresponding elevation are shown in the first two columns. SAMPLE TYPE The method used to collect the sample is shown. The typical sampling methods include Split Spoon Sampling, Shelby Tube Sampling, Grab Samples, and Rock Core. A key is provided at the bottom of the log showing the graphic symbol for each sample type. SAMPLE NUMBER Each sample collected is numbered sequentially. BLOWS PER INCREMENT, REC%, RQD% When Standard Split Spoon sampling is used, the blows required to drive the sampler each 6- inch increment are recorded and shown in column 5. When rock core is obtained the recovery ration (REC%) and Rock Quality Designation (RQD%) is recorded. SOIL DATA Column 6 is a graphic representation of four different soil parameters. Each of the parameters use the same graph, however, the values of the graph subdivisions vary with each parameter. Each parameter presented on column 6 is summarized below:  N-value- The Standard Penetration Test N-value, obtained by adding the number of blows required to drive the sampler the final 12 inches, is recorded. The graph labels range from 0 to 50.  Qu – Unconfined Compressive Strength estimate from the Pocket Penetrometer test in tons per square foot (tsf). The graph labels range from 0 to 5 tsf.  Atterberg Limits – The Atterberg Limits are plotted with the plastic limit to the left, and liquid limit to the right, connected by a horizontal line. The difference in the plastic and liquid limits is referred to as the Plasticity Index. The Atterberg Limits test results are also included in the Remarks column on the far right of the boring log. The Atterberg Limits graph labels range from 0 to 100%.  Moisture – The Natural Moisture Content of the soil sample as determined in our laboratory. SOIL DESCRIPTION The soil description prepared in accordance with ASTM D2488, Visual Description of Soil Samples. The Munsel Color chart is used to determine the soil color. Strata changes are indicated by a solid line, with the depth of the change indicated on the left side of the line and the elevation of the change indicated on the right side of the line. If subtle changes within a soil type occur, a broken line is used. The Boring Termination or Auger Refusal depth is shown as a solid line at the bottom of the boring. GRAPHIC The graphic representation of the soil type is shown. The graphic used for each soil type is related to the Unified Soil Classification chart. A chart showing the graphic associated with each soil classification is included. REMARKS Remarks regarding borehole observations, and additional information regarding the laboratory results and groundwater observations. SOIL CLASSIFICATION METHODOLOGY Major Divisions Symbols Group Name & Typical Description Lithology Group Coarse Grained Soils More than 50% of material is larger than No. 200 sieve size Gravel and Gravelly Soils More than 50% of coarse fraction is larger than No. 4 sieve Clean Gravels (Less than 5% fines) GW Well-graded gravels, gravel – sand mixtures, little or no fines GP Poorly-graded gravels, gravel – sand mixtures, little or no fines Gravels with Fines (More than 12% fines) GM Silty gravels, gravel – sand – silt mixtures GC Clayey gravels, gravel – sand – clay mixtures Sand and Sandy Soils More than 50% of coarse fraction is smaller than No. 4 sieve Clean Sands (Less than 5% fines) SW Well-graded sands, gravelly sands, little or no fines SP Poorly-graded sands, gravelly sands, little or no fines Sands with Fines (More than 12% fines) SM Silty sands, sand – silt mixtures SC Clayey sands, sand – clay mixtures Fine Grained Soils More than 50% of material is smaller than No. 200 sieve size Silts and Clays Liquid Limit less than 50 Inorganic ML Inorganic silts and very find sands, rock flour, silty or clayey fine sands or clayey silt with slight plasticity CL Inorganic clays of low to medium plasticity, gravelly clays, sandy clays, silty clays, lean clays Organic OL Organic silts and organic silty clays of low plasticity Silts and Clays Liquid Limit greater than 50 sieve Inorganic MH Inorganic silts, micaceous or diatomaceous fine sand, or silty soils CH Inorganic clays of high plasticity Organic OH Organic clays of medium to high plasticity, organic silts Highly Organic Soils PT Peat, humus, swamp soils with high organic contents Table 1: Soil Classification Chart (based on ASTM D2487) SOIL CLASSIFICATION METHODOLOGY * - Modified based on 80% hammer efficiency Building & Earth Sciences classifies soil in general accordance with the Unified Soil Classification System (USCS) presented in ASTM D2487. Table 1 and Figure 1 exemplify the general guidance of the USCS. Soil consistencies and relative densities are presented in general accordance with Terzaghi, Peck, & Mesri’s (1996) method, as shown on Table 2, when quantitative field and/or laboratory data is available. Table 2 includes Consistency and Relative Density correlations with N-values obtained using either a manual hammer (60 percent efficiency) or automatic hammer (90 percent efficiency). The Blows Per Increment and SPT N-values displayed on the boring logs are the unaltered values measured in the field. When field and/or laboratory data is not available, we may classify soil in general accordance with the Visual Manual Procedure presented in ASTM D2488. Non-cohesive: Coarse-Grained Soil Cohesive: Fine-Grained Soil SPT Penetration (blows/foot) Relative Density SPT Penetration (blows/foot) Consistency Estimated Range of Unconfined Compressive Strength (tsf) Automatic Hammer* Manual Hammer Automatic Hammer* Manual Hammer < 2 < 2 Very Soft < 0.25 0 - 3 0 - 4 Very Loose 2 - 3 2 - 4 Soft 0.25 – 0.50 3 - 8 4 - 10 Loose 3 - 6 4 - 8 Medium Stiff 0.50 – 1.00 8 - 23 10 - 30 Medium Dense 6 - 12 8 - 15 Stiff 1.00 – 2.00 23 - 38 30 - 50 Dense 12 - 23 15 - 30 Very Stiff 2.00 – 4.00 > 38 > 50 Very Dense > 23 > 30 Hard > 4.00 Table 2: Soil Consistency and Relative Density (based on Terzaghi, Peck & Mesri, 1996) 0 10 20 30 40 50 60 0 102030405060708090100Plasticity Index (PI)Liquid Limit (LL) CH or OH MH or OH CL or OL ML or OLCL-ML7 4 Figure 1: Plasticity Chart (based on ASTM D2487) KEY TO LOGS Standard Penetration Test ASTM D1586 or AASHTO T-206 Dynamic Cone Penetrometer (Sower DCP) ASTM STP-399 Soil Particle Size U.S. Standard Boulders Larger than 300 mm N.A. Cobbles 300 mm to 75 mm N.A. Shelby Tube Sampler ASTM D1587 No Sample Recovery Gravel 75 mm to 4.75 mm 3-inch to #4 sieve Coarse 75 mm to 19 mm 3-inch to ¾-inch sieve Fine 19 mm to 4.75 mm ¾-inch to #4 sieve Rock Core Sample ASTM D2113 Groundwater at Time of Drilling Sand 4.75 mm to 0.075 mm #4 to #200 Sieve Coarse 4.75 mm to 2 mm #4 to #10 Sieve Medium 2 mm to 0.425 mm #10 to #40 Sieve Auger Cuttings Groundwater as Indicated Fine 0.425 mm to 0.075 mm #40 to #200 Sieve Fines Less than 0.075 mm Passing #200 Sieve Silt Less than 5 µm N.A. Clay Less than 2 µm N.A. Table 1: Symbol Legend Table 2: Standard Sieve Sizes Standard Penetration Test Resistance calculated using ASTM D1586 or AASHTO T- 206. Calculated as sum of original, field recorded values. A measure of a soil’s plasticity characteristics in general accordance with ASTM D4318. The soil Plasticity Index (PI) is representative of this characteristic and is bracketed by the Liquid Limit (LL) and the Plastic Limit (PL). Unconfined compressive strength, typically estimated from a pocket penetrometer. Results are presented in tons per square foot (tsf). Percent natural moisture content in general accordance with ASTM D2216. Table 3: Soil Data Hollow Stem Auger Flights on the outside of the shaft advance soil cuttings to the surface. The hollow stem allows sampling through the middle of the auger flights. Descriptor Meaning Mud Rotary / Wash Bore A cutting head advances the boring and discharges a drilling fluid to support the borehole and circulate cuttings to the surface. Trace Likely less than 5% Solid Flight Auger Flights on the outside bring soil cuttings to the surface. Solid stem requires removal from borehole during sampling. Few 5 to 10% Little 15 to 25% Hand Auger Cylindrical bucket (typically 3-inch diameter and 8 inches long) attached to a metal rod and turned by human force. Some 30 to 45% Mostly 50 to 100% Table 4: Soil Drilling Methods Table 5: Descriptors KEY TO LOGS Manual Hammer The operator tightens and loosens the rope around a rotating drum assembly to lift and drop a sliding, 140-pound hammer falling 30 inches. Automatic Trip Hammer An automatic mechanism is used to lift and drop a sliding, 140-pound hammer falling 30 inches. Dynamic Cone Penetrometer (Sower DCP) ASTM STP-399 Uses a 15-pound steel mass falling 20 inches to strike an anvil and cause penetration of a 1.5-inch diameter cone seated in the bottom of a hand augered borehole. The blows required to drive the embedded cone a depth of 1-3/4 inches have been correlated by others to N-values derived from the Standard Penetration Test (SPT). Table 6: Sampling Methods Non-plastic A 1/8-inch thread cannot be rolled at any water content. Low The thread can barely be rolled and the lump cannot be formed when drier than the plastic limit. Medium The thread is easy to roll and not much time is required to reach the plastic limit. The thread cannot be re-rolled after reaching the plastic limit. The lump crumbles when drier than the plastic limit. High It takes considerable time rolling and kneading to reach the plastic limit. The thread can be re-rolled several times after reaching the plastic limit. The lump can be formed without crumbling when drier than the plastic limit. Table 7: Plasticity Dry Absence of moisture, dusty, dry to the touch. Moist Damp but no visible water. Wet Visible free water, usually soil is below water table. Table 8: Moisture Condition Stratified Alternating layers of varying material or color with layers at least ½ inch thick. Laminated Alternating layers of varying material or color with layers less than ¼ inch thick. Fissured Breaks along definite planes of fracture with little resistance to fracturing. Slickensides Fracture planes appear polished or glossy, sometimes striated. Blocky Cohesive soil that can be broken down into small angular lumps which resist further breakdown. Lensed Inclusion of small pockets of different soils, such as small lenses of sand scattered through a mass of clay. Homogeneous Same color and appearance throughout. Table 9: Structure KEY TO HATCHES Hatch Description Hatch Description Hatch Description GW - Well-graded gravels, gravel – sand mixtures, little or no fines Asphalt Clay with Gravel GP - Poorly-graded gravels, gravel – sand mixtures, little or no fines Aggregate Base Sand with Gravel GM - Silty gravels, gravel – sand – silt mixtures Topsoil Silt with Gravel GC - Clayey gravels, gravel – sand – clay mixtures Concrete Gravel with Sand SW - Well-graded sands, gravelly sands, little or no fines Coal Gravel with Clay SP - Poorly-graded sands, gravelly sands, little or no fines CL-ML - Silty Clay Gravel with Silt SM - Silty sands, sand – silt mixtures Sandy Clay Limestone SC - Clayey sands, sand – clay mixtures Clayey Chert Chalk ML - Inorganic silts and very find sands, rock flour, silty or clayey fine sands or clayey silt with slight plasticity Low and High Plasticity Clay Siltstone CL - Inorganic clays of low to medium plasticity, gravelly clays, sandy clays, silty clays, lean clays Low Plasticity Silt and Clay Till OL - Organic silts and organic silty clays of low plasticity High Plasticity Silt and Clay Sandy Clay with Cobbles and Boulders MH - Inorganic silts, micaceous or diatomaceous fine sand, or silty soils Fill Sandstone with Shale CH - Inorganic clays of high plasticity Weathered Rock Coral OH - Organic clays of medium to high plasticity, organic silts Sandstone Boulders and Cobbles PT - Peat, humus, swamp soils with high organic contents Shale Soil and Weathered Rock Table 1: Key to Hatches Used for Boring Logs and Soil Profiles BORING LOCATION PLAN Boring Location Map BES Project #: RD180419 Address: Urban Freedom Way Drawing Source: RFP Drawing City: Fort Bragg, NC Client: ACC Construction Company Figure 1 Project: SOF Parachute Rigging Facility N 200 100 0 Building Boring Location Approximate Scale (feet) Storm Basin Boring Pavement Boring Location B-101 S-101 P-101 SUBSURFACE SOIL PROFILES 235 240 245 250 255 260 265 270 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 235 240 245 250 255 260 265 270 BT=25.0 6 5 8 11 15 44 7 13 27 B-101 NNQu BT=25.0 2 8 12 13 20 26 13 13 13 B-103 NNQu BT=25.0 7 10 7 3 34 30 14 20 34 B-105 NNQu Site Map Scale 1 inch equals 0 feetExplanation BT=Boring Termination AR=Auger Refusal PPqu=Unconfined compressive strength estimate from pocket penetrometer test (tsf) X ELEVATION (feet)JOB NUMBER PLATE NUMBER 8/22/18 Water Level Reading at time of drilling. Section Name A-A' Subsurface Profile DISTANCE ALONG PROFILE (feet) 610 Spring Branch Road Dunn, NC 28334 Parachute Rigging Facility Fort Bragg, NC DATE Plate A-1 Topsoil USCS Silty Sand USCS Low Plasticity Clay USCS Clayey Sand RD180419 A' Water Level Reading after drilling. Building & EarthSciences, Inc. A Horizontal Scale (feet) X N=Standard Penetration Test N-Value Vertical Exaggeration: 0x ALDOT PROFILE RECOVERED FILE - RD180419 - CONTINUOUS.GPJ BESI.GDT 8/22/180 1 B-101 B-103 B-105 ________FFE=266.0'___________________________________________________________________________ 238 240 242 244 246 248 250 252 254 256 258 260 262 264 266 268 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 238 240 242 244 246 248 250 252 254 256 258 260 262 264 266 268 BT=25.0 7 9 5 12 11 26 31 8 21 B-102 NNQu BT=25.0 2 8 12 13 20 26 13 13 13 B-103 NNQu BT=25.0 4 4 5 5 7 9 22 13 17 B-104 NNQu Site Map Scale 1 inch equals 0 feetExplanation BT=Boring Termination AR=Auger Refusal PPqu=Unconfined compressive strength estimate from pocket penetrometer test (tsf) X ELEVATION (feet)JOB NUMBER PLATE NUMBER 8/22/18 Water Level Reading at time of drilling. Section Name A-A' Subsurface Profile DISTANCE ALONG PROFILE (feet) 610 Spring Branch Road Dunn, NC 28334 Parachute Rigging Facility Fort Bragg, NC DATE Plate A-1 Topsoil USCS Clayey Sand USCS Low Plasticity Clay USCS Silty Sand RD180419 A' Water Level Reading after drilling. Building & EarthSciences, Inc. A Horizontal Scale (feet) X N=Standard Penetration Test N-Value Vertical Exaggeration: 0x ALDOT PROFILE RECOVERED FILE - RD180419 - CONTINUOUS.GPJ BESI.GDT 8/22/180 0 B-102 B-103 B-104 ___________FFE=266.0'_____________________________________________________________________ 256 258 260 262 264 266 268 270 272 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 256 258 260 262 264 266 268 270 272 BT=10.0 2 7 12 12 12 P-105 NNQu BT=10.0 5 14 25 20 11 P-106 NNQu BT=10.0 6 7 18 20 14 P-107 NNQu Site Map Scale 1 inch equals 0 feetExplanation BT=Boring Termination AR=Auger Refusal PPqu=Unconfined compressive strength estimate from pocket penetrometer test (tsf) X ELEVATION (feet)JOB NUMBER PLATE NUMBER 8/22/18 Water Level Reading at time of drilling. Section Name A-A' Subsurface Profile DISTANCE ALONG PROFILE (feet) 610 Spring Branch Road Dunn, NC 28334 Parachute Rigging Facility Fort Bragg, NC DATE Plate A-1 Topsoil USCS Silty Sand USCS Low Plasticity Clay USCS Clayey Sand RD180419 A' Water Level Reading after drilling. Building & EarthSciences, Inc. A Horizontal Scale (feet) X N=Standard Penetration Test N-Value Vertical Exaggeration: 0x ALDOT PROFILE RECOVERED FILE - RD180419 - CONTINUOUS.GPJ BESI.GDT 8/22/180 0 P-105 P-106 P-107 BORING LOGS 1 2 3 4 5 6 7 8 9 Topsoil (approximately 5 inches) SILTY SAND (SM): loose, brown, fine to medium sand, moist SANDY CLAY (CL): medium stiff, red, fine to medium sand, moist - stiff CLAYEY SAND (SC): medium dense, orange/red, fine to medium sand, moist - very dense SILTY SAND (SM): loose, orange, fine to medium sand, moist - medium dense, yellow/orange (Coastal Plain) Boring terminated at 25 feet. Sample 1 % Passing #200 seive: 30.4 Liquid Limit (LL): 14 Plastic Limit (PL): 13 Plasticity Index (PI): 1 No groundwater encountered at the time of drilling, or after 24 hrs Boring backfilled on 08/16/18 266.6 265.1 260.1 252.7 242.1 0.4 2.0 7.0 14.4 25.0 2-2-4-4 2-2-3-4 1-3-5-8 1-3-8-17 1-1-14-15 14-29-15-18 1-1-6 5-6-7 6-12-15 GROUNDWATER LEVEL IN THE BOREHOLE UNCONFINED COMPRESSIVE STRENGTH ESTIMATE FROM POCKET PENETROMETER TEST SOIL DESCRIPTION REMARKS Huntsville, AL Columbus, GA Designation: B-101 Sheet 1 of 1 N-Value 20 40 60 80 Date Drilled: 7/31/18 10 20 30 40 Qu (tsf) N-VALUE % MOISTURE Qu Project Location: Fort Bragg, NC 10 20 30 40 Birmingham, AL GRAPHICProject Name: Parachute Rigging Facility SAMPLE NO.UNDISTURBED RECOVERY ROCK QUALITY DESIGNATION LOG OF BORING 610 Spring Branch Road Dunn, NC 28334 Office: (910) 292-2085 205-836-6300 Fax: (910) 292-2087 205-836-9007 www.BuildingAndEarth.com 1 2 3 4 Savannah, GA Raleigh, NC Tulsa, OK Springdale, AR Shreveport, LA Louisville, KY Niceville, FL 1 2 3 4 Atterberg Limits Qu (tsf) Drilling Method: Hollow Stem Auger Surface Elevation: 267.05 REMARKS Hammer Type: Automatic DEPTH (ft)DEPTH (ft)SAMPLE TYPEGRAPHIC5 10 15 20 25 STANDARD PENETRATION RESISTANCE (AASHTO T-206) PERCENT NATURAL MOISTURE CONTENT SOIL DESCRIPTION N-Value Atterberg Limits Equipment Used: Geoprobe Weather Conditions: rain, 85F Drill Crew: A.Baker/J.Johnson Logged By: MLumpkinBoring Location: NW Corner of Building Auburn, AL Project Number: RD180419 Split SpoonBLOWSPER INCREMENTREC RQD UDELEVATION (ft)265 260 255 250 245 240 % Moisture 20 40 60 80 SAMPLE TYPE LOG OF BORING 1 CONTINUOUS RECOVERED FILE - RD180419 - CONTINUOUS.GPJ BESI.GDT 8/21/18 1 2 3 4 5 6 7 8 9 Topsoil (approximately 3 inches) CLAYEY SAND (SC): loose, brown, fine to medium sand, moist - medium dense SANDY CLAY (CL): medium stiff, red, fine to medium sand, moist - stiff, orange - hard CLAYEY SAND (SC): loose, orange, fine to medium sand, moist SILTY SAND (SM): medium dense, orange, fine to medium sand, moist (Coastal Plain) Boring terminated at 25 feet. No groundwater encountered at the time of drilling, or after 24 hrs Boring backfilled on 08/16/18 267.0 263.6 252.8 243.3 242.3 0.3 3.7 14.5 24.0 25.0 3-3-4-7 4-4-5-6 1-1-4-7 1-4-8-12 2-3-8-16 8-12-14-17 3-14-17 3-3-5 2-6-15 GROUNDWATER LEVEL IN THE BOREHOLE UNCONFINED COMPRESSIVE STRENGTH ESTIMATE FROM POCKET PENETROMETER TEST SOIL DESCRIPTION REMARKS Huntsville, AL Columbus, GA Designation: B-102 Sheet 1 of 1 N-Value 20 40 60 80 Date Drilled: 7/31/18 10 20 30 40 Qu (tsf) N-VALUE % MOISTURE Qu Project Location: Fort Bragg, NC 10 20 30 40 Birmingham, AL GRAPHICProject Name: Parachute Rigging Facility SAMPLE NO.UNDISTURBED RECOVERY ROCK QUALITY DESIGNATION LOG OF BORING 610 Spring Branch Road Dunn, NC 28334 Office: (910) 292-2085 205-836-6300 Fax: (910) 292-2087 205-836-9007 www.BuildingAndEarth.com 1 2 3 4 Savannah, GA Raleigh, NC Tulsa, OK Springdale, AR Shreveport, LA Louisville, KY Niceville, FL 1 2 3 4 Atterberg Limits Qu (tsf) Drilling Method: Hollow Stem Auger Surface Elevation: 267.25 REMARKS Hammer Type: Automatic DEPTH (ft)DEPTH (ft)SAMPLE TYPEGRAPHIC5 10 15 20 25 STANDARD PENETRATION RESISTANCE (AASHTO T-206) PERCENT NATURAL MOISTURE CONTENT SOIL DESCRIPTION N-Value Atterberg Limits Equipment Used: Geoprobe Weather Conditions: rain, 85F Drill Crew: A.Baker/J.Johnson Logged By: MLumpkinBoring Location: NE Corner of Building Auburn, AL Project Number: RD180419 Split SpoonBLOWSPER INCREMENTREC RQD UDELEVATION (ft)265 260 255 250 245 240 % Moisture 20 40 60 80 SAMPLE TYPE LOG OF BORING 1 CONTINUOUS RECOVERED FILE - RD180419 - CONTINUOUS.GPJ BESI.GDT 8/21/18 1 2 3 4 5 6 7 8 9 Topsoil (approximately 6 inches) SILTY SAND (SM): very loose, brown, fine to medium sand, moist SANDY CLAY (CL): stiff, brown/red, fine to medium sand, moist - very stiff SILTY SAND (SM): medium dense, brown/orange, fine to medium sand, moist - dense - medium dense, light brown (Coastal Plain) Boring terminated at 25 feet. Sample 5 % Passing #200 seive: 25.9 Liquid Limit (LL): 47 Plastic Limit (PL): 29 Plasticity Index (PI): 18 No groundwater encountered at the time of drilling, or after 24 hrs Boring backfilled on 08/16/18 265.3 264.1 257.8 240.8 0.5 1.7 8.0 25.0 1-1-1-1 3-4-4-4 3-5-7-8 3-5-8-11 5-9-11-14 5-11-15-15 3-4-9 3-5-8 3-5-8 GROUNDWATER LEVEL IN THE BOREHOLE UNCONFINED COMPRESSIVE STRENGTH ESTIMATE FROM POCKET PENETROMETER TEST SOIL DESCRIPTION REMARKS Huntsville, AL Columbus, GA Designation: B-103 Sheet 1 of 1 N-Value 20 40 60 80 Date Drilled: 7/31/18 10 20 30 40 Qu (tsf) N-VALUE % MOISTURE Qu Project Location: Fort Bragg, NC 10 20 30 40 Birmingham, AL GRAPHICProject Name: Parachute Rigging Facility SAMPLE NO.UNDISTURBED RECOVERY ROCK QUALITY DESIGNATION LOG OF BORING 610 Spring Branch Road Dunn, NC 28334 Office: (910) 292-2085 205-836-6300 Fax: (910) 292-2087 205-836-9007 www.BuildingAndEarth.com 1 2 3 4 Savannah, GA Raleigh, NC Tulsa, OK Springdale, AR Shreveport, LA Louisville, KY Niceville, FL 1 2 3 4 Atterberg Limits Qu (tsf) Drilling Method: Hollow Stem Auger Surface Elevation: 265.83 REMARKS Hammer Type: Automatic DEPTH (ft)DEPTH (ft)SAMPLE TYPEGRAPHIC5 10 15 20 25 STANDARD PENETRATION RESISTANCE (AASHTO T-206) PERCENT NATURAL MOISTURE CONTENT SOIL DESCRIPTION N-Value Atterberg Limits Equipment Used: Geoprobe Weather Conditions: rain, 85F Drill Crew: A.Baker/J.Johnson Logged By: MLumpkinBoring Location: Center of Building Auburn, AL Project Number: RD180419 Split SpoonBLOWSPER INCREMENTREC RQD UDELEVATION (ft)265 260 255 250 245 240 % Moisture 20 40 60 80 SAMPLE TYPE LOG OF BORING 1 CONTINUOUS RECOVERED FILE - RD180419 - CONTINUOUS.GPJ BESI.GDT 8/21/18 1 2 3 4 5 6 7 8 9 Topsoil (approximately 12 inches) SILTY SAND (SM): loose, light brown, fine to medium sand, moist SANDY CLAY (CL): medium stiff, red/brown, fine to medium sand, moist - stiff CLAYEY SAND (SC): medium dense, orange, fine to medium sand, moist SILTY SAND (SM): medium dense, orange, fine to medium sand, moist (Coastal Plain) Boring terminated at 25 feet. No groundwater encountered at the time of drilling, or after 24 hrs Boring backfilled on 08/16/18 262.9 261.7 250.4 245.2 238.9 1.0 2.2 13.5 18.7 25.0 1-2-2-2 1-2-2-2 1-2-3-5 1-2-3-4 1-3-4-5 2-4-5-6 5-11-11 4-5-8 8-8-9 GROUNDWATER LEVEL IN THE BOREHOLE UNCONFINED COMPRESSIVE STRENGTH ESTIMATE FROM POCKET PENETROMETER TEST SOIL DESCRIPTION REMARKS Huntsville, AL Columbus, GA Designation: B-104 Sheet 1 of 1 N-Value 20 40 60 80 Date Drilled: 7/31/18 10 20 30 40 Qu (tsf) N-VALUE % MOISTURE Qu Project Location: Fort Bragg, NC 10 20 30 40 Birmingham, AL GRAPHICProject Name: Parachute Rigging Facility SAMPLE NO.UNDISTURBED RECOVERY ROCK QUALITY DESIGNATION LOG OF BORING 610 Spring Branch Road Dunn, NC 28334 Office: (910) 292-2085 205-836-6300 Fax: (910) 292-2087 205-836-9007 www.BuildingAndEarth.com 1 2 3 4 Savannah, GA Raleigh, NC Tulsa, OK Springdale, AR Shreveport, LA Louisville, KY Niceville, FL 1 2 3 4 Atterberg Limits Qu (tsf) Drilling Method: Hollow Stem Auger Surface Elevation: 263.94 REMARKS Hammer Type: Automatic DEPTH (ft)DEPTH (ft)SAMPLE TYPEGRAPHIC5 10 15 20 25 STANDARD PENETRATION RESISTANCE (AASHTO T-206) PERCENT NATURAL MOISTURE CONTENT SOIL DESCRIPTION N-Value Atterberg Limits Equipment Used: Geoprobe Weather Conditions: rain, 85F Drill Crew: A.Baker/J.Johnson Logged By: MLumpkinBoring Location: SW Corner of Tower Auburn, AL Project Number: RD180419 Split SpoonBLOWSPER INCREMENTREC RQD UDELEVATION (ft)260 255 250 245 240 235 % Moisture 20 40 60 80 SAMPLE TYPE LOG OF BORING 1 CONTINUOUS RECOVERED FILE - RD180419 - CONTINUOUS.GPJ BESI.GDT 8/21/18 1 2 3 4 5 6 7 8 9 Topsoil (approximately 3 inches) SILTY SAND (SM): loose, red tan, moist, fine to medium sand, moist CLAYEY SAND (SC): medium dense, orange/brown, fine to medium sand, wet - loose SILTY SAND (SM): dense, red/orange, fine to medium sand, moist - medium dense SANDY CLAY (CL): very stiff, orange, fine to medium sand, moist SILTY SAND (SM): medium dense, orange,fine to coarse sand, moist SANDY CLAY (CL), hard, light brown/orange, fine to medium sand, moist (Coastal Plain) Boring terminated at 25 feet. Sample 3 % Passing #200 seive: 45.7 Liquid Limit (LL): 43 Plastic Limit (PL): 26 Plasticity Index (PI): 17 No groundwater encountered at the time of drilling, or after 24 hrs Boring backfilled on 08/16/18 262.7 260.0 254.7 248.4 243.7 239.4 238.0 0.3 3.0 8.3 14.6 19.3 23.6 25.0 3-2-5-4 5-5-5-4 2-3-4-7 1-1-2-3 1-8-26-22 16-14-16-16 6-6-8 3-8-12 8-11-23 GROUNDWATER LEVEL IN THE BOREHOLE UNCONFINED COMPRESSIVE STRENGTH ESTIMATE FROM POCKET PENETROMETER TEST SOIL DESCRIPTION REMARKS Huntsville, AL Columbus, GA Designation: B-105 Sheet 1 of 1 N-Value 20 40 60 80 Date Drilled: 7/31/18 10 20 30 40 Qu (tsf) N-VALUE % MOISTURE Qu Project Location: Fort Bragg, NC 10 20 30 40 Birmingham, AL GRAPHICProject Name: Parachute Rigging Facility SAMPLE NO.UNDISTURBED RECOVERY ROCK QUALITY DESIGNATION LOG OF BORING 610 Spring Branch Road Dunn, NC 28334 Office: (910) 292-2085 205-836-6300 Fax: (910) 292-2087 205-836-9007 www.BuildingAndEarth.com 1 2 3 4 Savannah, GA Raleigh, NC Tulsa, OK Springdale, AR Shreveport, LA Louisville, KY Niceville, FL 1 2 3 4 Atterberg Limits Qu (tsf) Drilling Method: Hollow Stem Auger Surface Elevation: 262.95 REMARKS Hammer Type: Automatic DEPTH (ft)DEPTH (ft)SAMPLE TYPEGRAPHIC5 10 15 20 25 STANDARD PENETRATION RESISTANCE (AASHTO T-206) PERCENT NATURAL MOISTURE CONTENT SOIL DESCRIPTION N-Value Atterberg Limits Equipment Used: Geoprobe Weather Conditions: rain, 85F Drill Crew: A.Baker/J.Johnson Logged By: MLumpkinBoring Location: SE Corner of Building Auburn, AL Project Number: RD180419 Split SpoonBLOWSPER INCREMENTREC RQD UDELEVATION (ft)260 255 250 245 240 235 % Moisture 20 40 60 80 SAMPLE TYPE LOG OF BORING 1 CONTINUOUS RECOVERED FILE - RD180419 - CONTINUOUS.GPJ BESI.GDT 8/21/18 1 2 3 4 5 Topsoil (approximately 3 inches) SANDY CLAY (CL): medium stiff, orange, fine to medium sand, moist - very stiff - stiff (Coastal Plain) Boring terminated at 10 feet. No groundwater encountered at the time of drilling, or after 24 hrs Boring bacfilled on 08/16/18 264.4 254.6 0.3 10.0 2-2-2-3 2-2-4-4 2-2-3-5 4-6-10-10 2-4-7-12 GROUNDWATER LEVEL IN THE BOREHOLE UNCONFINED COMPRESSIVE STRENGTH ESTIMATE FROM POCKET PENETROMETER TEST SOIL DESCRIPTION REMARKS Huntsville, AL Columbus, GA Designation: P-101 Sheet 1 of 1 N-Value 20 40 60 80 Date Drilled: 7/31/18 10 20 30 40 Qu (tsf) N-VALUE % MOISTURE Qu Project Location: Fort Bragg, NC 10 20 30 40 Birmingham, AL GRAPHICProject Name: Parachute Rigging Facility SAMPLE NO.UNDISTURBED RECOVERY ROCK QUALITY DESIGNATION LOG OF BORING 610 Spring Branch Road Dunn, NC 28334 Office: (910) 292-2085 205-836-6300 Fax: (910) 292-2087 205-836-9007 www.BuildingAndEarth.com 1 2 3 4 Savannah, GA Raleigh, NC Tulsa, OK Springdale, AR Shreveport, LA Louisville, KY Niceville, FL 1 2 3 4 Atterberg Limits Qu (tsf) Drilling Method: Hollow Stem Auger Surface Elevation: 264.64 REMARKS Hammer Type: Automatic DEPTH (ft)DEPTH (ft)SAMPLE TYPEGRAPHIC5 10 STANDARD PENETRATION RESISTANCE (AASHTO T-206) PERCENT NATURAL MOISTURE CONTENT SOIL DESCRIPTION N-Value Atterberg Limits Equipment Used: Geoprobe Weather Conditions: rain, 85F Drill Crew: A.Baker/J.Johnson Logged By: MLumpkinBoring Location: NE Parking Lot next to building Auburn, AL Project Number: RD180419 Split SpoonBLOWSPER INCREMENTREC RQD UDELEVATION (ft)260 255 250 % Moisture 20 40 60 80 SAMPLE TYPE LOG OF BORING 1 CONTINUOUS RECOVERED FILE - RD180419 - CONTINUOUS.GPJ BESI.GDT 8/21/18 1 2 3 4 5 Topsoil (approximately 3 inches) CLAYEY SAND (SC): loose, orange, fine to medium sand, moist - medium dense (Coastal Plain) Boring terminated at 10 feet. Sample 1 % Passing #200 seive: 35.4 Liquid Limit (LL): 37 Plastic Limit (PL): 21 Plasticity Index (PI): 16 No groundwater encountered at the time of drilling, or after 24 hrs Boring backfilled on 08/16/18 261.3 251.5 0.3 10.0 4-4-4-5 4-4-4-5 4-4-4-10 4-5-8-19 2-4-6-9 GROUNDWATER LEVEL IN THE BOREHOLE UNCONFINED COMPRESSIVE STRENGTH ESTIMATE FROM POCKET PENETROMETER TEST SOIL DESCRIPTION REMARKS Huntsville, AL Columbus, GA Designation: P-102 Sheet 1 of 1 N-Value 20 40 60 80 Date Drilled: 7/31/18 10 20 30 40 Qu (tsf) N-VALUE % MOISTURE Qu Project Location: Fort Bragg, NC 10 20 30 40 Birmingham, AL GRAPHICProject Name: Parachute Rigging Facility SAMPLE NO.UNDISTURBED RECOVERY ROCK QUALITY DESIGNATION LOG OF BORING 610 Spring Branch Road Dunn, NC 28334 Office: (910) 292-2085 205-836-6300 Fax: (910) 292-2087 205-836-9007 www.BuildingAndEarth.com 1 2 3 4 Savannah, GA Raleigh, NC Tulsa, OK Springdale, AR Shreveport, LA Louisville, KY Niceville, FL 1 2 3 4 Atterberg Limits Qu (tsf) Drilling Method: Hollow Stem Auger Surface Elevation: 261.50 REMARKS Hammer Type: Automatic DEPTH (ft)DEPTH (ft)SAMPLE TYPEGRAPHIC5 10 STANDARD PENETRATION RESISTANCE (AASHTO T-206) PERCENT NATURAL MOISTURE CONTENT SOIL DESCRIPTION N-Value Atterberg Limits Equipment Used: Geoprobe Weather Conditions: rain, 85F Drill Crew: A.Baker/J.Johnson Logged By: MLumpkinBoring Location: SE Parking Lot next to building Auburn, AL Project Number: RD180419 Split SpoonBLOWSPER INCREMENTREC RQD UDELEVATION (ft)260 255 250 % Moisture 20 40 60 80 SAMPLE TYPE LOG OF BORING 1 CONTINUOUS RECOVERED FILE - RD180419 - CONTINUOUS.GPJ BESI.GDT 8/21/18 1 2 3 4 5 Topsoil (Approximately 6 inches) SILTY SAND (SM): loose, light brown, fine to medium sand, moist CLAYEY SAND (SC): very loose, red-brown, fine to medium sand, moist - loose - medium desne (Coastal Plain) Boring Terminated at 10 feet No groundwater encountered at the time of drilling, or after 24 hrs Boring backfilled on 08/16/18 258.5 257.0 249.0 0.5 2.0 10.0 1-1-3-1 1-1-2-3 1-1-1-2 3-3-4-5 4-4-7-8 GROUNDWATER LEVEL IN THE BOREHOLE UNCONFINED COMPRESSIVE STRENGTH ESTIMATE FROM POCKET PENETROMETER TEST SOIL DESCRIPTION REMARKS Huntsville, AL Columbus, GA Designation: P-103 Sheet 1 of 1 N-Value 20 40 60 80 Date Drilled: 7/31/18 10 20 30 40 Qu (tsf) N-VALUE % MOISTURE Qu Project Location: Fort Bragg, NC 10 20 30 40 Birmingham, AL GRAPHICProject Name: Parachute Rigging Facility SAMPLE NO.UNDISTURBED RECOVERY ROCK QUALITY DESIGNATION LOG OF BORING 610 Spring Branch Road Dunn, NC 28334 Office: (910) 292-2085 205-836-6300 Fax: (910) 292-2087 205-836-9007 www.BuildingAndEarth.com 1 2 3 4 Savannah, GA Raleigh, NC Tulsa, OK Springdale, AR Shreveport, LA Louisville, KY Niceville, FL 1 2 3 4 Atterberg Limits Qu (tsf) Drilling Method: Hollow Stem Auger Surface Elevation: 259.03 REMARKS Hammer Type: Automatic DEPTH (ft)DEPTH (ft)SAMPLE TYPEGRAPHIC5 10 STANDARD PENETRATION RESISTANCE (AASHTO T-206) PERCENT NATURAL MOISTURE CONTENT SOIL DESCRIPTION N-Value Atterberg Limits Equipment Used: Geoprobe Weather Conditions: rain, 85F Drill Crew: A.Baker/J.Johnson Logged By: MLumpkinBoring Location: South Parking Lot next to building Auburn, AL Project Number: RD180419 Split SpoonBLOWSPER INCREMENTREC RQD UDELEVATION (ft)255 250 245 % Moisture 20 40 60 80 SAMPLE TYPE LOG OF BORING 1 CONTINUOUS RECOVERED FILE - RD180419 - CONTINUOUS.GPJ BESI.GDT 8/21/18 1 2 3 4 5 Topsoil (approximately 6 inches) SILTY SAND (SM): loose, light brown, fine to medium sand, wet SANDY CLAY (CL): stiff, brown/red, fine to medium sand, moist - soft - stiff CLAYEY SAND (SC): medium dense, orange, fine to medium sand, moist (Coastal Plain) Boring terminated at 10 feet. No groundwater encountered at the time of drilling, or after 24 hrs Boring backfilled on 08/16/18 263.4 261.9 254.9 253.9 0.5 2.0 9.0 10.0 1-2-2-2 3-3-4-5 1-1-2-3 3-3-5-6 1-3-6-9 GROUNDWATER LEVEL IN THE BOREHOLE UNCONFINED COMPRESSIVE STRENGTH ESTIMATE FROM POCKET PENETROMETER TEST SOIL DESCRIPTION REMARKS Huntsville, AL Columbus, GA Designation: P-104 Sheet 1 of 1 N-Value 20 40 60 80 Date Drilled: 8/1/18 10 20 30 40 Qu (tsf) N-VALUE % MOISTURE Qu Project Location: Fort Bragg, NC 10 20 30 40 Birmingham, AL GRAPHICProject Name: Parachute Rigging Facility SAMPLE NO.UNDISTURBED RECOVERY ROCK QUALITY DESIGNATION LOG OF BORING 610 Spring Branch Road Dunn, NC 28334 Office: (910) 292-2085 205-836-6300 Fax: (910) 292-2087 205-836-9007 www.BuildingAndEarth.com 1 2 3 4 Savannah, GA Raleigh, NC Tulsa, OK Springdale, AR Shreveport, LA Louisville, KY Niceville, FL 1 2 3 4 Atterberg Limits Qu (tsf) Drilling Method: Hollow Stem Auger Surface Elevation: 263.94 REMARKS Hammer Type: Automatic DEPTH (ft)DEPTH (ft)SAMPLE TYPEGRAPHIC5 10 STANDARD PENETRATION RESISTANCE (AASHTO T-206) PERCENT NATURAL MOISTURE CONTENT SOIL DESCRIPTION N-Value Atterberg Limits Equipment Used: Geoprobe Weather Conditions: rain, 85F Drill Crew: A.Baker/J.Johnson Logged By: MLumpkinBoring Location: West Parking Lot next to building Auburn, AL Project Number: RD180419 Split SpoonBLOWSPER INCREMENTREC RQD UDELEVATION (ft)260 255 250 % Moisture 20 40 60 80 SAMPLE TYPE LOG OF BORING 1 CONTINUOUS RECOVERED FILE - RD180419 - CONTINUOUS.GPJ BESI.GDT 8/21/18 1 2 3 4 5 Topsoil (approximately 6 inches) SILTY SAND (SM): very loose, light brown, fine to medium sand, wet SANDY CLAY (CL): stiff, red/brown, fine to medium sand, wet - red CLAYEY SAND (SC): medium dense, red, fine to medium sand, moist (Coastal Plain) Boring terminated at 10 feet. No groundwater encountered at the time of drilling, or after 24 hrs Boring backfilled on 08/16/18 266.0 264.5 258.5 256.5 0.5 2.0 8.0 10.0 1-1-1-1 2-3-4-6 3-4-8-10 5-6-6-9 1-3-9-13 GROUNDWATER LEVEL IN THE BOREHOLE UNCONFINED COMPRESSIVE STRENGTH ESTIMATE FROM POCKET PENETROMETER TEST SOIL DESCRIPTION REMARKS Huntsville, AL Columbus, GA Designation: P-105 Sheet 1 of 1 N-Value 20 40 60 80 Date Drilled: 8/1/18 10 20 30 40 Qu (tsf) N-VALUE % MOISTURE Qu Project Location: Fort Bragg, NC 10 20 30 40 Birmingham, AL GRAPHICProject Name: Parachute Rigging Facility SAMPLE NO.UNDISTURBED RECOVERY ROCK QUALITY DESIGNATION LOG OF BORING 610 Spring Branch Road Dunn, NC 28334 Office: (910) 292-2085 205-836-6300 Fax: (910) 292-2087 205-836-9007 www.BuildingAndEarth.com 1 2 3 4 Savannah, GA Raleigh, NC Tulsa, OK Springdale, AR Shreveport, LA Louisville, KY Niceville, FL 1 2 3 4 Atterberg Limits Qu (tsf) Drilling Method: Hollow Stem Auger Surface Elevation: 266.50 REMARKS Hammer Type: Automatic DEPTH (ft)DEPTH (ft)SAMPLE TYPEGRAPHIC5 10 STANDARD PENETRATION RESISTANCE (AASHTO T-206) PERCENT NATURAL MOISTURE CONTENT SOIL DESCRIPTION N-Value Atterberg Limits Equipment Used: Geoprobe Weather Conditions: rain, 85F Drill Crew: A.Baker/J.Johnson Logged By: MLumpkinBoring Location: SW Parking Lot Auburn, AL Project Number: RD180419 Split SpoonBLOWSPER INCREMENTREC RQD UDELEVATION (ft)265 260 255 % Moisture 20 40 60 80 SAMPLE TYPE LOG OF BORING 1 CONTINUOUS RECOVERED FILE - RD180419 - CONTINUOUS.GPJ BESI.GDT 8/21/18 1 2 3 4 5 Topsoil (approximately 6 inches) SILTY SAND (SM): loose, light brown, fine to medium sand, moist CLAY WITH SAND (CL): very stiff, red/brown, fine to medium sand, moist - hard - very stiff CLAYEY SAND (SC): medium dense, orange, fine to medium sand, moist (Coastal Plain) Boring terminated at 10 feet. No groundwater encountered at the time of drilling, or after 24 hrs Boring backfilled on 08/16/18 267.1 265.6 258.6 257.6 0.5 2.0 9.0 10.0 2-2-3-3 3-4-10-13 4-11-14-15 4-9-11-13 2-2-9-17 GROUNDWATER LEVEL IN THE BOREHOLE UNCONFINED COMPRESSIVE STRENGTH ESTIMATE FROM POCKET PENETROMETER TEST SOIL DESCRIPTION REMARKS Huntsville, AL Columbus, GA Designation: P-106 Sheet 1 of 1 N-Value 20 40 60 80 Date Drilled: 8/1/18 10 20 30 40 Qu (tsf) N-VALUE % MOISTURE Qu Project Location: Fort Bragg, NC 10 20 30 40 Birmingham, AL GRAPHICProject Name: Parachute Rigging Facility SAMPLE NO.UNDISTURBED RECOVERY ROCK QUALITY DESIGNATION LOG OF BORING 610 Spring Branch Road Dunn, NC 28334 Office: (910) 292-2085 205-836-6300 Fax: (910) 292-2087 205-836-9007 www.BuildingAndEarth.com 1 2 3 4 Savannah, GA Raleigh, NC Tulsa, OK Springdale, AR Shreveport, LA Louisville, KY Niceville, FL 1 2 3 4 Atterberg Limits Qu (tsf) Drilling Method: Hollow Stem Auger Surface Elevation: 267.56 REMARKS Hammer Type: Automatic DEPTH (ft)DEPTH (ft)SAMPLE TYPEGRAPHIC5 10 STANDARD PENETRATION RESISTANCE (AASHTO T-206) PERCENT NATURAL MOISTURE CONTENT SOIL DESCRIPTION N-Value Atterberg Limits Equipment Used: Geoprobe Weather Conditions: rain, 85F Drill Crew: A.Baker/J.Johnson Logged By: MLumpkinBoring Location: Center of Parking Lot Auburn, AL Project Number: RD180419 Split SpoonBLOWSPER INCREMENTREC RQD UDELEVATION (ft)265 260 255 % Moisture 20 40 60 80 SAMPLE TYPE LOG OF BORING 1 CONTINUOUS RECOVERED FILE - RD180419 - CONTINUOUS.GPJ BESI.GDT 8/21/18 1 2 3 4 5 Topsoil (approximately 6 inches) SANDY CLAY (CL): medium stiff, red/brown, fine to medium sand, moist -stiff -very stiff CLAYEY SAND (SC): medium dense, red, fine to medium sand, moist (Coastal Plain) Boring terminated at 10 feet. No groundwater encountered at the time of drilling, or after 24 hrs Boring backfilled on 08/16/18 270.1 261.6 260.6 0.5 9.0 10.0 2-3-3-4 2-3-4-5 4-8-10-12 4-9-11-14 2-5-9-11 GROUNDWATER LEVEL IN THE BOREHOLE UNCONFINED COMPRESSIVE STRENGTH ESTIMATE FROM POCKET PENETROMETER TEST SOIL DESCRIPTION REMARKS Huntsville, AL Columbus, GA Designation: P-107 Sheet 1 of 1 N-Value 20 40 60 80 Date Drilled: 8/1/18 10 20 30 40 Qu (tsf) N-VALUE % MOISTURE Qu Project Location: Fort Bragg, NC 10 20 30 40 Birmingham, AL GRAPHICProject Name: Parachute Rigging Facility SAMPLE NO.UNDISTURBED RECOVERY ROCK QUALITY DESIGNATION LOG OF BORING 610 Spring Branch Road Dunn, NC 28334 Office: (910) 292-2085 205-836-6300 Fax: (910) 292-2087 205-836-9007 www.BuildingAndEarth.com 1 2 3 4 Savannah, GA Raleigh, NC Tulsa, OK Springdale, AR Shreveport, LA Louisville, KY Niceville, FL 1 2 3 4 Atterberg Limits Qu (tsf) Drilling Method: Hollow Stem Auger Surface Elevation: 270.62 REMARKS Hammer Type: Automatic DEPTH (ft)DEPTH (ft)SAMPLE TYPEGRAPHIC5 10 STANDARD PENETRATION RESISTANCE (AASHTO T-206) PERCENT NATURAL MOISTURE CONTENT SOIL DESCRIPTION N-Value Atterberg Limits Equipment Used: Geoprobe Weather Conditions: rain, 85F Drill Crew: A.Baker/J.Johnson Logged By: MLumpkinBoring Location: NE Parking Lot Auburn, AL Project Number: RD180419 Split SpoonBLOWSPER INCREMENTREC RQD UDELEVATION (ft)270 265 260 % Moisture 20 40 60 80 SAMPLE TYPE LOG OF BORING 1 CONTINUOUS RECOVERED FILE - RD180419 - CONTINUOUS.GPJ BESI.GDT 8/21/18 M(ksf)c(psf)Phi(degrees)Soil TypeDepthB101B102B104B105SE-Corner Depth B101 B102 B104 B105 SE-Corner Depth B101 B102 B104 B105 SE-Corner Depth B101 B102 B104 B105 SE-Corner1---------1770 674 1 ---------------1 ---------46.5 37.6 1 ---------Silty Sand Sand 2 ---------------2 ---------------2 ---------------2 ---------------3 922 1448 496 1480 869 3 ---------2270 ---3 ---43.4 ---------3 Sandy Silt Silty Sand Sandy Silt Silt Sandy Silt48635484138525644144813797122173---4 ---------------4 Silt Clayey Silt Silt Clayey Silt Sandy Silt5938110644263973652042------1114 1298 5 ---------------5 Silt Sandy Silt Sandy Silt Silt Silt 6 1130 1301 1375 559 822 6 2515 ------1335 1315 6 ------40.0 ------6 Silt Sandy Silt Silty Sand Clayey Silt Silt 7 ---1187 1221 839 7 ---------1801 7 ------------7 ---Sandy Silt Sandy Silt Silt 8 1263 682 8 4168 3566 8 ------8 Silty Clay Silty ClaySummary of Results B101 B102 B104 B105 SE-CornerEff. Depth Id kd Su(psf)Phi M(ksf)Eff. Depth Id kd Su(psf)Phi M(ksf)Eff. Depth Id kd Su(psf)Phi M(ksf)Eff. Depth Id kd Su(psf)Phi M(ksf)Eff. Depth Id kd Su(psf)Phi M(ksf)1 ---------------1 ---------------1 ---------------1 2.4 45.9 ---46.5 1770 1 17.2 5.4 ---37.6 6742---------------2 ---------------2 ---------------2 ---------------2 ---------------3 1.3 19.0 ------922 3 1.9 19.8 ---43.4 1448 3 1.2 12.6 ------496 3 1.1 29.9 2270 ---1480 3 1.3 18.6 ------86941.1 16.7 1448 ---863 4 0.7 15.9 1379 ---548 4 1.1 9.7 712 ---413 4 0.7 23.1 2173 ---852 4 1.4 10.6 ------56450.8 18.5 2042 ---938 5 1.7 11.9 ------1106 5 1.5 7.0 ------442 5 1.1 11.4 1114 ---639 5 1.0 13.2 1298 ---73660.8 18.7 2515 ---1130 6 1.6 12.3 ------1301 6 2.7 9.0 ---40.0 1375 6 0.8 11.4 1335 ---559 6 1.2 11.5 1315 ---8227---------------7 1.3 11.9 ------1187 7 1.5 11.5 ------1221 7 0.9 13.1 1801 ---83980.5 22.2 4168 ---1263 8 0.3 19.7 3566 ---682 Summary of Results DILATOMETER TEST RESULTS Project Name:Fort Bragg Parachute Facility Project Number:1180593EA Date:8/1/2018 B101- North Corner Water Depth 20 ft 0 2 4 6 8 10 12 14 16 18 20 0 2 4 6 Depth (ft)Id Silty Sand0 2 4 6 8 10 12 14 16 18 20 0 250 500 750 1000 1250 Modulus (ksf)ClaySiltSand0 2 4 6 8 10 12 14 16 18 20 0 250 500 750 1000 1250 Su (psf) 0 2 4 6 8 10 12 14 16 18 20 25º30º35º40º45º Friction Angle (deg) DILATOMETER TEST RESULTS Project Name:Fort Bragg Parachute Facility Project Number:1180593EA Date:8/1/2018 B102 - East Corner Water Depth 20 ft 0 2 4 6 8 10 12 14 16 18 20 0 2 4 6 Depth (ft)Id Silty Sand0 2 4 6 8 10 12 14 16 18 20 0 250 500 750 1000 1250 Modulus (ksf)ClaySiltSand0 2 4 6 8 10 12 14 16 18 20 0 250 500 750 1000 1250 Su (psf) 0 2 4 6 8 10 12 14 16 18 20 25º30º35º40º45º Friction Angle (deg) DILATOMETER TEST RESULTS Project Name:Fort Bragg Parachute Facility Project Number:1180593EA Date:8/1/2018 B104 - Tower Water Depth 20 ft 0 2 4 6 8 10 12 14 16 18 20 0 2 4 6 Depth (ft)Id Silty Sand0 2 4 6 8 10 12 14 16 18 20 0 250 500 750 1000 1250 Modulus (ksf)ClaySiltSand0 2 4 6 8 10 12 14 16 18 20 0 250 500 750 1000 1250 Su (psf) 0 2 4 6 8 10 12 14 16 18 20 25º30º35º40º45º Friction Angle (deg) DILATOMETER TEST RESULTS Project Name:Fort Bragg Parachute Facility Project Number:1180593EA Date:8/1/2018 B105 - South Corner Water Depth 20 ft 0 2 4 6 8 10 12 14 16 18 20 0 2 4 6 Depth (ft)Id Silty Sand0 2 4 6 8 10 12 14 16 18 20 0 250 500 750 1000 1250 Modulus (ksf)ClaySiltSand0 2 4 6 8 10 12 14 16 18 20 0 250 500 750 1000 1250 Su (psf) 0 2 4 6 8 10 12 14 16 18 20 25º30º35º40º45º Friction Angle (deg) DILATOMETER TEST RESULTS Project Name:Fort Bragg Parachute Facility Project Number:1180593EA Date:8/1/2018 SE-Corner Water Depth 20 ft 0 2 4 6 8 10 12 14 16 18 20 0 2 4 6 Depth (ft)Id Silty Sand0 2 4 6 8 10 12 14 16 18 20 0 250 500 750 1000 1250 Modulus (ksf)ClaySiltSand0 2 4 6 8 10 12 14 16 18 20 0 250 500 750 1000 1250 Su (psf) 0 2 4 6 8 10 12 14 16 18 20 25º30º35º40º45º Friction Angle (deg) Job Name : Fort Bragg Parachute Facility GeoTech Job No. : 1180593EA FIGURE 5 Date : 8/1/2018 0 2 4 6 8 10 12 14 16 18 20 0 250 500 750 1,000 DEPTH (ft)M (ksf) MODULUS vs DEPTH B101 B102 B104 B105 SE-Corner Job Name : Fort Bragg Parachute Facility GeoTech Job No. : 1180593EA FIGURE 6 Date : 8/1/2018 0 2 4 6 8 10 12 14 16 18 20 0 250 500 750 1,000 Depth (ft)COHESION (psf) C (psf) vs DEPTH B101 B102 B104 B105 SE-Corner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brief description of the laboratory tests performed is provided in the following sections. DESCRIPTION OF SOILS (VISUAL-MANUAL PROCEDURE) (ASTM D2488) The soil samples were visually examined by our engineer and soil descriptions were provided. Representative samples were then selected and tested in accordance with the aforementioned laboratory-testing program to determine soil classifications and engineering properties. This data was used to correlate our visual descriptions with the Unified Soil Classification System (USCS). NATURAL MOISTURE CONTENT (ASTM D2216) Natural moisture contents (M%) were determined on selected samples. The natural moisture content is the ratio, expressed as a percentage, of the weight of water in a given amount of soil to the weight of solid particles. ATTERBERG LIMITS (ASTM D4318) The Atterberg Limits test was performed to evaluate the soil’s plasticity characteristics. The soil Plasticity Index (PI) is representative of this characteristic and is bracketed by the Liquid Limit (LL) and the Plastic Limit (PL). The Liquid Limit is the moisture content at which the soil will flow as a heavy viscous fluid. The Plastic Limit is the moisture content at which the soil is between “plastic” and the semi-solid stage. The Plasticity Index (PI = LL - PL) is a frequently used indicator for a soil’s potential for volume change. Typically, a soil’s potential for volume change increases with higher plasticity indices. MATERIAL FINER THAN NO. 200 SIEVE BY WASHING (ASTM D1140) Grain-size tests were performed to determine the partial soil particle size distribution. The amount of material finer than the openings on the No. 200 sieve (0.075 mm) was determined by washing soil over the No. 200 sieve. The results of wash #200 tests are presented on the boring logs included in this report and in the table of laboratory test results. MODIFIED PROCTOR COMPACTION TEST (ASTM D1557) Modified Proctor compaction tests were performed to determine the maximum dry density and optimum moisture content for the soil, for use as a comparative basis during fill placement. The Modified Proctor test consists of the compaction of soil with known moisture content into a steel mold of fixed height and diameter. The soil is compacted in the mold in five lifts of equal volume using a 10 lb. manual hammer with an 18-inch free fall, to produce a consistent compactive effort. The test procedure is repeated on samples at several different moisture contents until a curve showing the relationship between moisture content and dry density of the soil is established. From this curve, the maximum dry density (peak density value) and optimum moisture content (moisture content correlating to the maximum dry density) are obtained. LABORATORY CALIFORNIA BEARING RATIO (ASTM D1883) The California Bearing Ratio, usually abbreviated CBR, is a punching shear test. The CBR value is a semi-empirical index of the soil’s strength and deflection characteristics and has been correlated with pavement performance to establish design curves for pavement thickness. The tests were performed on six-inch diameter, five-inch thick disks of compacted soil, confined in steel cylinders. The specimens were soaked for at least 96 hours prior to testing. A piston, approximately two inches in diameter, was forced into the soaked soil at a standard rate to determine the soil’s resistance to penetration. The CBR value is the ratio, expressed as a percentage, of the actual load required to produce a 0.1-inch deflection to that required for the same deflection in a certain standard crushed stone. LABORATORY TEST RESULTS The results of the laboratory testing are presented in the following tables. Boring or Test Pit Location Sample Depth (ft) LL PL PI % Passing #200 Sieve Moisture Content (%) B-101 0-2.0 14 13 1 30.4 10.2 B-103 8.0-10.0 47 29 18 25.9 11.8 B-105 4.0-6.0 43 26 17 45.7 21.3 P-102 0-2.0 37 21 16 35.4 20.8 P-106 2.0-4.0 56 37 19 60.5 28.4 Table A-1: General Soil Classification Test Results Soils with a Liquid Limit (LL) greater than 50 and Plasticity Index (PI) greater than 25 usually exhibit significant volume change with varying moisture content and are considered to be highly plastic. Soils with a LOI value greater than 3 percent are usually not suitable for supporting building and pavement sections. Checked By: John Dailly 08-10-18 (no specification provided) PL=LL=PI= D90=D85=D60= D50=D30=D15= D10=Cu=Cc= USCS=AASHTO= * Red Brown clayey sand .75 .375 #4 #10 #20 #40 #100 #200 100.0 99.7 99.4 98.7 92.9 77.9 46.3 35.4 21 37 16 0.7100 0.5575 0.2422 0.1738 SC A-2-6(1) ACC Construction Company, Inc. SOF Parachute Rigging Facility (GEO) Fort Bragg, NC RD180419 Material Description Atterberg Limits Coefficients Classification Remarks Location: P-102, S-1 Sample Number: 18-3054-01 Depth: 0-2.5'Date: Client: Project: Project No:Figure SIEVE PERCENT SPEC.*PASS? SIZE FINER PERCENT (X=NO)PERCENT FINER0 10 20 30 40 50 60 70 80 90 100 PERCENT COARSER100 90 80 70 60 50 40 30 20 10 0 GRAIN SIZE - mm. 0.0010.010.1110 % +3"Coarse % Gravel Fine Coarse Medium % Sand Fine Silt % Fines Clay 0.0 0.0 0.6 0.7 20.8 42.5 35.43 in.2 in.1½ in.1 in.¾ in.½ in.3/8 in.#4#10#20#30#40#60#100#140#200Particle Size Distribution Report Checked By: John Dailly COMPACTION TEST REPORT Dry density, pcf118 120 122 124 126 128 Water content, % 8 9 10 11 12 13 14 10.6%, 125.5 pcf ZAV for Sp.G. = 2.65 Test specification:ASTM D 1557-12 Method A Modified 0-2.5'SC A-2-6(1)20.8 37 16 0.6 35.4 Red Brown clayey sand RD180419 ACC Construction Company, Inc. Elev/Classification Nat.Sp.G.LL PI % >% < Depth USCS AASHTO Moist.#4 No.200 TEST RESULTS MATERIAL DESCRIPTION Project No.Client:Remarks: Project: Location: P-102, S-1 Sample Number: 18-3054-01 Figure Maximum dry density = 125.5 pcf Optimum moisture = 10.6 % SOF Parachute Rigging Facility (GEO) Fort Bragg, NC 2200 Westinghouse Blvd., Suite 103 • Raleigh, NC 27604 • Phone (919) 876-0405 • Fax (919) 876-0460 • www.geotechnics.net DCN: Data Transmittal Letter Date: 1/28/05 Rev.: 1 August 13, 2018 Project No R-2018-224-001 Mr. Kurt Miller Building & Earth Sciences, LLC 610 Spring Branch Road Dunn, NC 28334 Transmittal Laboratory Test Results RD180419 SOF Parachute Rigging Facility (Fort Bragg, NC) Please find attached the laboratory test results for the above referenced project. The tests were outlined on the Project Verification Form that was transmitted to your firm prior to the testing. The testing was performed in general accordance with the methods listed on the enclosed data sheets. The test results are believed to be representative of the samples that were submitted for testing and are indicative only of the specimens which were evaluated. We have no direct knowledge of the origin of the samples and imply no position with regard to the nature of the test results, i.e. pass/fail and no claims as to the suitability of the material for its intended use. The test data and all associated project information provided shall be held in strict confidence and disclosed to other parties only with authorization by our Client. The test data submitted herein is considered integral with this report and is not to be reproduced except in whole and only with the authorization of the Client and Geotechnics. The remaining sample materials for this project will be retained for a minimum of 90 days as directed by the Geotechnics’ Quality Program. We are pleased to provide these testing services. Should you have any questions or if we may be of further assistance, please contact our office. Respectively submitted, Geotechnics, Inc. Michael P. Smith Regional Manager We understand that you have a choice in your laboratory services and we thank you for choosing Geotechnics. 2200 Westinghouse Blvd., Suite 103 • Raleigh, NC 27604 • Phone (919) 876-0405 • Fax (919) 876-0460 • www.geotechnics.net SINGLE POINT CBR TEST ASTM D 1883-16 Client Building & Earth Sciences, Inc.Boring No.P-102 Client Reference RD180419 SOF Parachute Rigging Fac. Depth(ft.)N/A Project No.R-2018-224-001 Sample No.18-3054-01 Lab ID R-2018-224-001-001 Visual Description RED/BROWN SANDY CLAY Test Type MODIFIED Molding Method C Density Before After Mold ID R433 Measurement Soaking Soaking Wt. of Mold (gm.)4233 Wt. Mold & WS (gm.)8921.2 8966.7 Mold Volume (cc)2121 Wt. WS (gm.)4688.2 4734 Surcharge (lbs.)10 Sample Volume (cc)2121 2124 Piston Area (in2)3 Wet Density (gm./cc) 2.21 2.23 Sample Height 4.58 Wet Density (pcf) 137.9 139.1 Sample Conditions Soaked Blows per Layer 45 Dry Density (pcf) 125.4 125.2 Dry Density (gm./cc) 2.01 2.01 Water As Begining After Before After Top 1" Contents Rec'd Compaction Compaction Soaking Soaking After Soak Tare No.815 819 NA 304 318 Wt. of T+WS (gm.) 335.39 452 NA 685.84 553.22 Wt. of T+DS (gm.) 323.34 422.6 NA 628.57 497.69 Wt of Tare (gm.) 136.11 129.16 NA 110.64 86.5 Moisture Content(%) 6.4 10.0 NA 10.0 11.1 13.5 Piston Penetration Displacement Load Stress Swell (in.)(lbs.)(psi.)Measurement 0 5.40 1.8 Elapsed Dial Percent 0.025 401.52 133.8 Time Gauge Swell 0.050 888.83 296.3 (hrs) (Div) 0.075 1233.04 411.0 0.100 1488.70 496.2 0.00 453 0.00% 0.125 1691.55 563.8 4.00 458 0.11% 0.150 1853.92 618.0 19.00 460 0.15% 0.175 1995.63 665.2 43.00 460 0.15% 0.200 2124.47 708.2 0.250 2363.01 787.7 0.300 2590.40 863.5 0.350 2809.34 936.4 0.400 3030.30 1010.1 0.450 3242.72 1080.9 0.500 3498.00 1166.0 0.550 3716.00 1238.7 0.600 3963.00 1321.0 1Division = 0.001 in. Tested By SFS Date 8/8/18 Checked By MPS Date 8/13/18 page 1 of 2 DCN: CT-S27 REVSI0N: 5 DATE: 11/15/05Z:\2018 PROJECTS\BUILDING & EARTH SCIENCES\2018-224 BUILDING & EARTH - SOF PARACHUTE\[2018-224-001-001 1CBR TESTNET.xls]SHEET1 2200 Westinghouse Blvd., Suite 103 • Raleigh, NC 27604 • Phone (919) 876-0405 • Fax (919) 876-0460 • www.geotechnics.net SINGLE POINT CBR TEST ASTM D 1883-16 Client Building & Earth Sciences, Inc. Boring No.P-102 Client Reference RD180419 SOF Parachute RiggingDepth(ft.)N/A Project No.R-2018-224-001 Sample No. 18-3054-01 Lab ID R-2018-224-001-001 Visual Description RED/BROWN SANDY CLAY CBR VALUE (0.1") 49.6 % CBR VALUE (0.2") 47.2 % CORRECTED CBR VALUE (0.1") 51.0 % CORRECTED CBR VALUE (0.2") 47.7 % Tested By SFS Date 8/8/18 Approved By MPS Date 8/13/18 page 2 of 2 DCN: CT-S27 REVSI0N: 5 DATE: 11/15/052018 PROJECTS\BUILDING & EARTH SCIENCES\2018-224 BUILDING & EARTH - SOF PARACHUTE\[2018-224-001-001 1CBR TESTNET.xls]SHEET1 0.0 200.0 400.0 600.0 800.0 1000.0 1200.0 1400.0 0.000 0.100 0.200 0.300 0.400 0.500 0.600 0.700Penetration Stress (psi)Penetration (in) Penetration Stress vs. Penetration 3DJH_$ 6($621$/+,*+:$7(57$%/(5(3257 3DJH_$ ,1),/75$7,217(67,1* o Liquid Used: Depth of Water Table: Water Temp ( ºF): ºF Test Location: Depth of Observed Water inches Flow rate used: Hole Diameter: inches Start Saturation: Water Head: inches Hole Radius: Hole Depth: inches S 15 :55 E 16 :01 S 16 :01 E 16 :04 S 16 :04 E 16 :07 S 16 :07 E 16 :10 S 16 :10 E 16 :13 S 16 :13 E 16 :16 S E S E S E S E S E S E S E S E Stabilized Ksat in/hr 0.14 CCHP - 1 13 14 12 11 10 9 8 7 0.148/16 8.20.35 11.1 20 5868/16 0.05 70.795 70.79 0.148/16 11.10.30 14.0 20 58 8/16 0.05 0.148/16 14.00.25 16.9 20 5848/16 0.05 82.993 70.79 0.168/16 16.90.20 20.3 20 68 8/16 0.05 0.188/16 20.30.15 24.0 20 7428/16 0.05 124.491 90.32 0.258/16 24.00.10 34.2 20 204 8/16 0.10 Remarks: Weather conditions, etc.Reading Tube Flow Flow cm³ Flow Rate in³/hr Ksat in/hr 1.200 120 Test Data Trial #Date Time Elapsed Time (hrs) Δ | Total Flow Readings Saturated Conductivity 15:45 13.25 Storage Tube 5L 2 On 105.000 Sight Tube 1L 1 On 20.000 S-101 NA Constants: Capacity Liquid Containers 20 2.4 setting Rate cm³/cm Test Constants Municipal Water >120" 71 5 Technician: Brad Carlson Date: 8/16/2018 Client Name: ACC Construction Company Report Number: 1 Compact Constant Head Permeameter - ASTM D-5126 {4.1.6} In-situ Field Saturated Conductivity of Soils in the Vadose Zone via Amoozemeter Project Name: SOF Parachute Rigging Facility Project Number: RD180419 of Liquid Used: Depth of Water Table: Water Temp ( ºF): ºF Test Location: Depth of Observed Water inches Flow rate used: Hole Diameter: inches Start Saturation: Water Head: inches Hole Radius: Hole Depth: inches S 14 :55 E 14 :59 S 14 :59 E 15 :03 S 15 :03 E 15 :07 S 15 :07 E 15 :11 S 15 :11 E 15 :15 S 15 :15 E 15 :19 S E S E S E S E S E S E S E S E Stabilized Ksat in/hr 0.12 CCHP - 2 13 14 12 11 10 9 8 7 0.128/16 13.00.40 16.5 20 7068/16 0.07 64.075 64.07 0.128/16 16.50.33 20.0 20 70 8/16 0.07 0.128/16 20.00.27 23.5 20 7048/16 0.07 69.573 64.07 0.138/16 23.50.20 27.3 20 76 8/16 0.07 0.138/16 27.30.13 31.0 20 7428/16 0.07 82.381 67.74 0.15 Run less than 24" above SHWT8/16 31.00.07 35.5 20 90 8/16 0.07 Remarks: Weather conditions, etc.Reading Tube Flow Flow cm³ Flow Rate in³/hr Ksat in/hr 1.200 96 Test Data Trial #Date Time Elapsed Time (hrs) Δ | Total Flow Readings Saturated Conductivity 14:50 13.75 Storage Tube 5L 2 On 105.000 Sight Tube 1L 1 On 20.000 S-102 NA Constants: Capacity Liquid Containers 20 2.4 setting Rate cm³/cm Test Constants Municipal Water 111" 71 5 Technician: Brad Carlson Date: 8/16/2018 Client Name: ACC Construction Company Report Number: 5 Compact Constant Head Permeameter - ASTM D-5126 {4.1.6} In-situ Field Saturated Conductivity of Soils in the Vadose Zone via Amoozemeter Project Name: SOF Parachute Rigging Facility Project Number: RD180419 of Liquid Used: Depth of Water Table: Water Temp ( ºF): ºF Test Location: Depth of Observed Water inches Flow rate used: Hole Diameter: inches Start Saturation: Water Head: inches Hole Radius: Hole Depth: inches S 10 :53 E 10 :57 S 10 :57 E 11 :05 S 11 :05 E 11 :10 S 11 :10 E 11 :20 S 11 :20 E 11 :33 S 11 :33 E 11 :36 S 11 :36 E 11 :39 S E S E S E S E S E S E S E Stabilized Ksat in/hr 0.14 CCHP - 3 13 14 12 11 10 9 8 24.417 0.148/16 12.40.77 13.4 20 20 8/16 0.05 0.148/16 13.40.72 14.4 20 2068/16 0.05 24.795 24.41 0.148/16 14.40.67 18.8 20 88 8/16 0.22 0.148/16 18.80.45 22.3 20 7048/16 0.17 33.693 25.63 0.198/16 22.30.28 24.6 20 46 8/16 0.08 0.278/16 24.60.20 29.9 20 10628/16 0.13 56.751 48.51 0.328/16 29.90.07 33.0 20 62 8/16 0.07 Remarks: Weather conditions, etc.Reading Tube Flow Flow cm³ Flow Rate in³/hr Ksat in/hr 1.200 60 Test Data Trial #Date Time Elapsed Time (hrs) Δ | Total Flow Readings Saturated Conductivity 10:50 6.75 Storage Tube 5L 2 On 105.000 Sight Tube 1L 1 On 20.000 S-103 NA Constants: Capacity Liquid Containers 20 2.4 setting Rate cm³/cm Test Constants Municipal Water >120 71 5 Technician: Brad Carlson Date: 8/16/2018 Client Name: ACC Construction Company Report Number: 3 Compact Constant Head Permeameter - ASTM D-5126 {4.1.6} In-situ Field Saturated Conductivity of Soils in the Vadose Zone via Amoozemeter Project Name: SOF Parachute Rigging Facility Project Number: RD180419 of Liquid Used: Depth of Water Table: Water Temp ( ºF): ºF Test Location: Depth of Observed Water inches Flow rate used: Hole Diameter: inches Start Saturation: Water Head: inches Hole Radius: Hole Depth: inches S 12 :27 E 12 :30 S 12 :30 E 12 :33 S 12 :33 E 12 :36 S 12 :36 E 12 :39 S 12 :39 E 12 :42 S 12 :42 E 12 :45 S 12 :45 E 12 :48 S 12 :48 E 12 :51 S 12 :51 E 12 :54 S 12 :54 E 12 :57 S 12 :57 E 13 :00 S E S E S E Stabilized Ksat in/hr 0.07 CCHP - 4 13 14 12 43.9411 0.078/16 10.40.55 12.2 20 36 8/16 0.05 0.078/16 12.20.50 14.0 20 36108/16 0.05 43.949 43.94 0.078/16 14.00.45 15.8 20 36 8/16 0.05 0.088/16 15.80.40 17.9 20 4288/16 0.05 48.827 51.26 0.088/16 17.90.35 19.9 20 40 8/16 0.05 0.088/16 19.90.30 22.0 20 4268/16 0.05 46.385 51.26 0.088/16 22.00.25 23.9 20 38 8/16 0.05 0.098/16 23.90.20 26.1 20 4448/16 0.05 46.383 53.70 0.088/16 26.10.15 28.0 20 38 8/16 0.05 0.098/16 28.00.10 30.3 20 4628/16 0.05 61.021 56.14 0.108/16 30.30.05 32.8 20 50 8/16 0.05 Remarks: Weather conditions, etc.Reading Tube Flow Flow cm³ Flow Rate in³/hr Ksat in/hr 1.200 108 Test Data Trial #Date Time Elapsed Time (hrs) Δ | Total Flow Readings Saturated Conductivity 12:21 15 Storage Tube 5L 2 On 105.000 Sight Tube 1L 1 On 20.000 S-104 NA Constants: Capacity Liquid Containers 20 2.4 setting Rate cm³/cm Test Constants Municipal Water >120 71 5 Technician: Brad Carlson Date: 8/16/2018 Client Name: ACC Construction Company Report Number: 4 Compact Constant Head Permeameter - ASTM D-5126 {4.1.6} In-situ Field Saturated Conductivity of Soils in the Vadose Zone via Amoozemeter Project Name: SOF Parachute Rigging Facility Project Number: RD180419 of Liquid Used: Depth of Water Table: Water Temp ( ºF): ºF Test Location: Depth of Observed Water inches Flow rate used: Hole Diameter: inches Start Saturation: Water Head: inches Hole Radius: Hole Depth: inches S 13 :45 E 13 :48 S 13 :48 E 13 :51 S 13 :51 E 13 :54 S 13 :54 E 13 :57 S 13 :57 E 14 :00 S 14 :00 E 14 :03 S 14 :03 E 14 :06 S 14 :06 E 14 :09 S E S E S E S E S E S E Stabilized Ksat in/hr 0.10 CCHP - 5 13 14 12 11 10 9 0.108/16 19.20.40 21.1 20 3888/16 0.05 46.387 46.38 0.108/16 21.10.35 23.0 20 38 8/16 0.05 0.108/16 23.00.30 24.9 20 3868/16 0.05 51.265 46.38 0.118/16 24.90.25 27.0 20 42 8/16 0.05 0.118/16 27.00.20 29.0 20 4048/16 0.05 53.703 48.82 0.128/16 29.00.15 31.2 20 44 8/16 0.05 0.158/16 31.20.10 34.0 20 5628/16 0.05 95.201 68.35 0.218/16 34.00.05 37.9 20 78 8/16 0.05 Remarks: Weather conditions, etc.Reading Tube Flow Flow cm³ Flow Rate in³/hr Ksat in/hr 1.200 120 Test Data Trial #Date Time Elapsed Time (hrs) Δ | Total Flow Readings Saturated Conductivity 13:40 12.5 Storage Tube 5L 2 On 105.000 Sight Tube 1L 1 On 20.000 S-105 NA Constants: Capacity Liquid Containers 20 2.4 setting Rate cm³/cm Test Constants Municipal Water >120 71 5 Technician: Brad Carlson Date: 8/16/2018 Client Name: ACC Construction Company Report Number: 5 Compact Constant Head Permeameter - ASTM D-5126 {4.1.6} In-situ Field Saturated Conductivity of Soils in the Vadose Zone via Amoozemeter Project Name: SOF Parachute Rigging Facility Project Number: RD180419 3DJH_$ *(27(&+1,&$/&$/&8/$7,216$03/(6 Settle3D Analysis Information Parachute Facility Project Settings B-101Document Name Parachute FacilityProject Title Settlement B-101Analysis JRJAuthor Building & EarthCompany 8/16/2018, 1:33:53 PMDate Created BoussinesqStress Computation Method 0.9Minimum settlement ratio for subgrade modulus Use average properties to calculate layered stresses Improve consolidation accuracy Ignore negative effective stresses in settlement calculations Stage Settings NameStage # Stage 11 Loads 1. Rectangular Load: "7' SQ Column" 7 ftLength 7 ftWidth 0 degreesRotation angle FlexibleLoad Type 49 ft2Area of Load 2.5 ksfLoad 0 ftDepth Stage 1Installation Stage Coordinates Y [ft]X [ft] 10.1866.924 10.18613.924 17.18613.924 17.1866.924 Parachute Facility: Page 1 of 4 SETTLE3D 4.015 B-101.s3z Building & Earth 8/16/2018, 1:33:53 PM 2. Rectangular Load: "Continuous Footing" 30 ftLength 2 ftWidth 0 degreesRotation angle FlexibleLoad Type 60 ft2Area of Load 2.5 ksfLoad 0 ftDepth Stage 1Installation Stage Coordinates Y [ft]X [ft] -7.56-4.348 -7.5625.652 -5.5625.652 -5.56-4.348 Empirical Results 7' SQ Column NoModified Schmertmann NoConsider Time Dependent Settlement Sat. Unit Weight [kips/ft3]Unit Weight [kips/ft3]Es [ksf]Thickness [ft]Schmertmann Method 0.1150.19221Layer 1 0.1150.19221Layer 2 0.1150.18631Layer 3 0.1150.19381Layer 4 0.1150.111301Layer 5 0.1150.1126310Layer 6 Settlement Results Schmertmann [in] 0.114627Stage 1 Continuous Footing NoModified Schmertmann NoConsider Time Dependent Settlement Sat. Unit Weight [kips/ft3]Unit Weight [kips/ft3]Es [ksf]Thickness [ft]Schmertmann Method 0.0180.14961Layer 1 0.0180.14961Layer 2 0.0180.14961Layer 3 0.0180.14131Layer 4 0.0180.14421Layer 5 0.0180.1137510Layer 6 Parachute Facility: Page 2 of 4 SETTLE3D 4.015 B-101.s3z Building & Earth 8/16/2018, 1:33:53 PM Settlement Results Schmertmann [in] 0.0737962Stage 1 Soil Layers Depth [ft]Thickness [ft]TypeLayer # 01Soil Property 11 11Soil Property 22 23Soil Property 33 54Soil Property 44 94Soil Property 55 134Soil Property 16 Parachute Facility: Page 3 of 4 SETTLE3D 4.015 B-101.s3z Building & Earth 8/16/2018, 1:33:53 PM Soil Properties Soil Property 4Soil Property 3Soil Property 2Soil Property 1Property ____________Color 0.1150.1150.1150.115Unit Weight [kips/ft3] 0.1150.1150.1150.115Saturated Unit Weight [kips/ft3] 1111K0 EnabledEnabledEnabledEnabledPrimary Consolidation Non-LinearNon-LinearNon-LinearNon-LinearMaterial Type 0.30.30.30.3Cc 0.10.10.10.1Cr 1.11.11.11.1e0 1111OCR 0000Undrained Su A [kips/ft2] 0.20.20.20.2Undrained Su S 0.80.80.80.8Undrained Su m 0000Piezo Line ID Soil Property 5Property ___Color 0.115Unit Weight [kips/ft3] 0.115Saturated Unit Weight [kips/ft3] 1K0 EnabledPrimary Consolidation Non-LinearMaterial Type 0.3Cc 0.1Cr 1.1e0 1OCR 0Undrained Su A [kips/ft2] 0.2Undrained Su S 0.8Undrained Su m 0Piezo Line ID Groundwater Piezometric LinesGroundwater method 0.0624 kips/ft3Water Unit Weight Parachute Facility: Page 4 of 4 SETTLE3D 4.015 B-101.s3z Building & Earth 8/16/2018, 1:33:53 PM Continuous FootingSchmertmann: 0.07 in7' SQ ColumnSchmertmann: 0.11 in7' SQ ColumnSchmertmann: 0.11 inContinuous FootingSchmertmann: 0.07 in3020100-10-100102030Analysis DescriptionSettlement B-101CompanyBuilding & EarthDrawn ByJRJFile NameB-101.s3zDate8/16/2018, 1:33:53 PMProjectParachute FacilitySETTLE3D 4.015 Pavement Design ReportU.S. Army Corps of EngineersPCASE Version 2.09.05Date : 8/20/2018Design Name : LD FLEXDesign Type : RoadsPavement Type : FlexibleRoad Type : Parking AreaTerrain Type : FlatAnalysis Type : CBRDepth of Frost (in) : 0Wander Width (in) : 33.35Layer InformationLayer Type Material Type Frost Code AnalysisNon frost Design Thickness (in)Reduced Subgrade Strength (in)Limited Subgrade Penetration (in)CBR StrengthAsphalt Asphalt NFS Compute 2 0 0 0BaseUnbound Crushed StoneNFS Manual 6 0 0 100Natural Subgrade Cohesive Cut NFS Manual 0 0 0 5Traffic InformationPattern Name : LIGHT DUTYVehicles Weight (lb)Passes per Life SpanEquivalent PassesM1114, HMMWV, UPARMORED, 4X410000 4562500 4562500M1114, HMMWV, UPARMORED, 4X410000 4562500PCASE Equivalent Single Axle Loads377 Pavement Thickness ReportU.S. Army Corps of EngineersPCASE Version 2.09.05Date : 8/20/2018Design Name : HD RIGIDDesign Type : RoadsPavement Type : RigidRoad Type : Parking AreaTerrain Type : FlatAnalysis Type : KDepth of Frost (in) : 0Wander Width (in) : 33.35% Load Transfer : 25Effective K (pci) : 130Reduced Sub Effective K (pci) : 0Joint Spacing : 10 to 15 ftDowel Spacing : 12.00 inDowel Length : 16.00 inDowel Diameter: .75 inLayer InformationLayer Type Material Type Frost CodeFlexural Strength (psi)% SteelAnalysisNon frost Design Thickness (in)Reduced Subgrade Strength (in)Limited Subgrade Penetration (in)K Strength (pci)PCC N/A NFS 650 0 Compute 7.88 0 0 0Stabilized Base Stab-GW,GP,GM, NFS 0 0 Manual 8 0 0 0Natural Subgrade Cohesive Cut NFS 0 0 Manual 0 0 0 130Traffic InformationPattern Name : HEAVY DURYVehicles Weight (lb)Passes per Life SpanEquivalent PassesAXLE, 18 KIP 72000 18250 18250CMP 60 FORKLIFT 10000 1300 1M998, HMMWV, 1.25-TON CARRIER, 4X410000 4562500 1P-23 CRASH TRUCK (FIRE TRUCK)77880 1300 1TRUCK, 3 AXLE 66000 1300 1AXLE, 18 KIP 72000 18254PCASE Equivalent Single Axle Loads5.762E+15 3DJH_$ ,03257$17,1)250$7,21$%2877+,6*(27(&+1,&$/ (1*,1((5,1*5(3257 3DJH_$ Parachute Rigging Facility Fort Bragg, Cumberland County, North Carolina Mason & Hanger Page - a.8 - APPENDIX H NCDEQ BIORETENTION CELL SUPPLEMENT FORMS Discrete SCS Curve Number Method (NCDEQ Stormwater BMP Manual 3.3.2) Location:Bioretention Area 1 Date:1/7/2019 Soil Group:C Predevelopment BUA Developed BUA Area 0.93 acres Area 2.52 acres Area 40,511 sf Area 109,984 sf CN*98 CN*98 S 0.20 S 0.20 ia 0.04 in ia 0.04 in P 1 in P 1 in Q 0.79 in Q 0.79 in V 2,670 cf V 7,249 cf Predevelopment Open Area Developed Open Area Area 7.92 acres Area 6.33 acres Area 345,209 sf Area 275,736 sf CN*76 CN*74 S 3.16 S 3.51 ia 0.63 in ia 0.70 in P 1 in P 1 in Q 0.04 in Q 0.02 in V 1,107 cf V 533 cf Area 8.85 acres Area 8.85 acres Total 3,777 cf Total 7,782 cf Storage Required 4,005 cf Surface Area 9,200 sf Riser 9 in Storage Provided 6,900 cf Note: Runnoff depth for CN <= 70 set to 0.00 for 1.0" rainfall event based upon TR55 Urban Hydrology for Small Watersheds Table 2-1 *Composite CN calculated using Army LID Planning and Cost Tool Developed by USACE Baltimore District and USACE ERDC Discrete SCS Curve Number Method (NCDEQ Stormwater BMP Manual 3.3.2) Location:Bioretention Area 2 Date:1/7/2019 Soil Group:B Predevelopment BUA Developed BUA Area 0.13 acres Area 0.85 acres Area 5,663 sf Area 37,026 sf CN*98 CN*98 S 0.20 S 0.20 ia 0.04 in ia 0.04 in P 1 in P 1 in Q 0.79 in Q 0.79 in V 373 cf V 2,440 cf Predevelopment Open Area Developed Open Area Area 2.83 acres Area 2.11 acres Area 123,275 sf Area 91,912 sf CN*60 CN*61 S 6.67 S 6.39 ia 1.33 in ia 1.28 in P 1 in P 1 in Q 0.00 in Q 0.00 in V 0 cf V 0 cf Area 2.96 acres Area 2.96 acres Total 373 cf Total 2,440 cf Storage Required 2,067 cf Surface Area 5,000 sf Riser 9 in Storage Provided 3,750 cf Note: Runnoff depth for CN <= 70 set to 0.00 for 1.0" rainfall event based upon TR55 Urban Hydrology for Small Watersheds Table 2-1 *Composite CN calculated using Army LID Planning and Cost Tool Developed by USACE Baltimore District and USACE ERDC QuantityInfiltration SystemBioretention Cell 2Wet PondStormwater WetlandPermeable PavementSand FilterRainwater HarvestingGreen RoofLevel Spreader-Filter StripDisconnected Impervious SurfaceTreatment SwaleDry PondApplicant:Name and Title:Organization:Street address:City, State, Zip:Phone number(s):Email:DesignerCertification Statement:Signature of DesignerDateEmail:Bldg 3-1333 Butner RdFort Bragg, NC 28310(910) 396-2301Company:Contact:Mailing Address:City, State, Zip:Project Name:AddressCity / TownFort Bragg DPWLee WardSOF Parachute Rigging FacilityFort BraggSUPPLEMENT-EZ FORM COVER PAGESealviolations as well as a report being made to my professional board. - that the information provided in the form is, to the best of my knowledge - that the engineering plans, specifications, operation and maintenancethe information provided here.I am aware that there are significant penalties for submitting falseinformation including the possibility of fines and imprisonment for knowing and belief, true, accurate, and complete; andagreements and other supporting information are consistent with I certify, under penalty of law: that this Supplement-EZ form and all supportinginformation were prepared under my direction or supervision; Designer information for this project:Location(s)Please indicate the types, quantities and locations of SCMs that will be used on this project:mike.mayer@masonandhanger.comPhone number(s):Mike Mayer, Civil EngineerMason & Hanger300 W Vine St Suite 1300Lexington, KY 40507859-280-3557lee.p.ward.civ@mail.milCover Page13:48 PM 2/4/2019 BIORETENTION CELL1Drainage area number1Total coastal wetlands area (sq ft) sf - Parking / driveway (sq ft)52134 sfTotal surface water area (sq ft) sf - Sidewalk (sq ft)1850 sfTotal drainage area (sq ft)385720 sf - Roof (sq ft)56000 sfBUA associated with existing development (sq ft)40511 sf - Roadway (sq ft) sfProposed new BUA (sq ft)109984 sf - Other, please specify in the comment box below (sq ft) sfPercent BUA of drainage area29%Total BUA (sq ft)109984 sfDesign rainfall depth (in)1.0 inMinimum volume required (cu ft)4005 cfDesign volume of SCM (cu ft)6900 cf#1 Is the SCM sized to treat the SW from all surfaces at build-out?Yes#7 If applicable, with the SCM be cleaned out after construction?Yes#2 Is the SCM located on or near contaminated soils?No#8 Does the mainetenance access comply with General MDC (8)?Yes#3 What are the side slopes of the SCM (H:V)?3:1#9 Does the drainage easement comply with General MDC (9)?Yes#3 Does the SCM have retaining walls, gabion walls or other engineered side slopes? No#10 If the SCM is on a single family lot, does the plat comply with General MDC (10)?Yes#4 Are the inlets, outlets, and receiving stream protected from erosion (10-year storm)? Yes#11 Is there an O&M Agreement that complies with General MDC (11)?Yes#5 Is there a a bypass for flows in excess of the design flow?Yes#12 Is there an O&M Plan that complies with General MDC (12)?Yes#6 What is the method for dewatering the SCM for maintenance?Other#13 Was the SCM designed by an NC licensed professional?Yes#1 SHWT elevation (fmsl)248 ft #6 Percentage of medium to coarse washed sand by volume 85%#1 Bottom of the bioretention cell (fmsl)250 ft #6 Percentage of fines (silt and clay) by volume10%#1 Distance from bottom to SHWT (feet)2 ft #6 Percentage of organic matter by volume 5%#2 Surface area of the bioretention cell (square feet)9200 sf#6 Type of organic materialEngineered Fill#2 Design volume of the bioretention cell (cubic feet)6900 cf#7 Phosphorus Index (P-Index) of media (unitless) 10#2 Ponding depth of the design storm (inches)9 in#8 Will compaction be avoided during construction?Yes#3 Is the bioretention cell used for peak attenuation?No#9 Will cell be maintained to a one inch/hour standard?Yes#3 Depth of peak attenuation over planting surface (in) in #10 Describe the planting plan:#3 Height of peak attenuation outlet above the planting surface (in) in#4 Infiltration rate of the in situ soil (inch/hour).1 in/hr#4 Diameter of the underdrain pipes (if applicable)8 in#4 Does the design include Internal Water Storage (IWS)?Yes #11 Depth of mulch, if applicable (inches) in#4 if so, elevation of the top of the IWS (fmsl)252 ft #11 Type of mulch, if applicablena#4 Elevation of the planting surface (fmsl)256 ft #12 How many clean out pipes are being installed?10#5 Will the cell contain trees and shrubs?No#12 Briefly describe the pretreatment that will be used:#5 Media depth (inches)30 inTHE DRAINAGE AREABIORETENTION CELL MDC FROM 02H .10522.0 feet of open graded aggregate being provided under engineered fill/media depth in order to provide additional storage volume within cell to meet requirements for EISA 438. The engineered fill will infiltrate at approximately 2in/hr (maintained at min 1in/hr), which will eliminate the surface ponded volume within 24 hours, to the storage within the IWS for ultimate infiltration. Additionally, behive grated catch basins are provided as first-line overflow, above required storage volume, but not for peak attenuation volume. Maximum depth of storage of cell to emergency overflow is 12". Emergency overflow weir designed for 100yr storm event. Project based entirely within Fort Bragg (US Gov't property). No easements required. User requires no hardwood mulch due to maintenance issues.Break down of BUA in the drainage area (both new and existing):COMPLIANCE WITH THE APPLICABLE STORMWATER PROGRAMStormwater program(s) that apply (please specify):EISA 438, ARMY LID, FORT BRAGG IDGGENERAL MDC FROM 02H .1050ADDITIONAL INFORMATIONPlease use this space to provide any additional information about this bioretention cell that you think is relevant to the review:Contractor to provide landscape establishment to achieve 100% coverage throughout site in 12 months. Sod is desired by the user for cell. User requires no hardwood mulch within cell.Minimum 3' sod strip. All outlet headwalls to cell have rip-rap outlet protection per NCDEQ requirements.SOF Parachute Rigging FacilityBioretention110:58 AM 2/5/2019 BIORETENTION CELLSOF Parachute Rigging Facility2Drainage area number2Total coastal wetlands area (sq ft) sf - Parking / driveway (sq ft)6356 sfTotal surface water area (sq ft) sf - Sidewalk (sq ft)1250 sfTotal drainage area (sq ft)128938 sf - Roof (sq ft)29420 sfBUA associated with existing development (sq ft)5663 sf - Roadway (sq ft) sfProposed new BUA (sq ft)37026 sf - Other, please specify in the comment box below (sq ft) sfPercent BUA of drainage area29%Total BUA (sq ft)37026 sfDesign rainfall depth (in)1.0 inMinimum volume required (cu ft)2067 cfDesign volume of SCM (cu ft)3750 cf#1 Is the SCM sized to treat the SW from all surfaces at build-out?Yes#7 If applicable, with the SCM be cleaned out after construction?Yes#2 Is the SCM located on or near contaminated soils?No#8 Does the mainetenance access comply with General MDC (8)?Yes#3 What are the side slopes of the SCM (H:V)?3:1#9 Does the drainage easement comply with General MDC (9)?Yes#3 Does the SCM have retaining walls, gabion walls or other engineered side slopes? No#10 If the SCM is on a single family lot, does the plat comply with General MDC (10)?Yes#4 Are the inlets, outlets, and receiving stream protected from erosion (10-year storm)? Yes#11 Is there an O&M Agreement that complies with General MDC (11)?Yes#5 Is there a a bypass for flows in excess of the design flow?Yes#12 Is there an O&M Plan that complies with General MDC (12)?Yes#6 What is the method for dewatering the SCM for maintenance?Other#13 Was the SCM designed by an NC licensed professional?Yes#1 SHWT elevation (fmsl)249 ft #6 Percentage of medium to coarse washed sand by volume 85%#1 Bottom of the bioretention cell (fmsl)254 ft #6 Percentage of fines (silt and clay) by volume10%#1 Distance from bottom to SHWT (feet)5 ft #6 Percentage of organic matter by volume 5%#2 Surface area of the bioretention cell (square feet)5000 sf#6 Type of organic materialEngineered Fill#2 Design volume of the bioretention cell (cubic feet)3750 cf#7 Phosphorus Index (P-Index) of media (unitless) 10#2 Ponding depth of the design storm (inches)9 in#8 Will compaction be avoided during construction?Yes#3 Is the bioretention cell used for peak attenuation?No#9 Will cell be maintained to a one inch/hour standard?Yes#3 Depth of peak attenuation over planting surface (in) in #10 Describe the planting plan:#3 Height of peak attenuation outlet above the planting surface (in) in#4 Infiltration rate of the in situ soil (inch/hour).1 in/hr#4 Diameter of the underdrain pipes (if applicable)8 in#4 Does the design include Internal Water Storage (IWS)?Yes #11 Depth of mulch, if applicable (inches) in#4 if so, elevation of the top of the IWS (fmsl)256 ft #11 Type of mulch, if applicablena#4 Elevation of the planting surface (fmsl)260 ft #12 How many clean out pipes are being installed?5#5 Will the cell contain trees and shrubs?No#12 Briefly describe the pretreatment that will be used:#5 Media depth (inches)30 in2.0 feet of open graded aggregate being provided under engineered fill/media depth in order to provide additional storage volume within cell to meet requirements for EISA 438. The engineered fill will infiltrate at approximately 2in/hr (maintained at min 1in/hr), which will eliminate the surface ponded volume within 24 hours, to the storage within the IWS for ultimate infiltration. Additionally, behive grated catch basins are provided as first-line overflow, above required storage volume, but not for peak attenuation volume. Maximum depth of storage of cell to emergency overflow is 12". Emergency overflow weir designed for 100yr storm event. Project based entirely within Fort Bragg (US Gov't property). No easements required. User requires no hardwood mulch due to maintenance issues.GENERAL MDC FROM 02H .1050Contractor to provide landscape establishment to achieve 100% coverage throughout site in 12 months. Sod is desired by the user for cell. User requires no hardwood mulch within cell.Minimum 3' sod strip. All outlet headwalls to cell have rip-rap outlet protection per NCDEQ requirements.ADDITIONAL INFORMATIONTHE DRAINAGE AREABIORETENTION CELL MDC FROM 02H .1052Break down of BUA in the drainage area (both new and existing):COMPLIANCE WITH THE APPLICABLE STORMWATER PROGRAMStormwater program(s) that apply (please specify):EISA 438, ARMY LID, FORT BRAGG IDGPlease use this space to provide any additional information about this bioretention cell that you think is relevant to the review:Bioretention24:24 PM 2/4/2019 Fort Bragg Parachute Rigging Facility PN74813 Bioretention Cell #1 Underdrain Calculations 1/31/2019 By M. Mayer Engineered Fill Permeability (K)2 in/hr Surface Area (A)9200 ft2 Maximum Ponding Depth (C H)3.25 ft Depth of media (C L)2.5 ft Flow (Qi)0.55 cfs Apply 10x Factor of Safety (Q)5.50 cfs Roughness Factor (n)0.01 Internal Slope (s)0.005 Darcy's Equation Diameter of Single Pipe (d)15.09 in Diameter Underdrain Pipes 8 in Equavalent Number Required 6 Number Underdrain Pipes Provided 10 NCDEQ Stormwater BMP Manual Common BMP Design Elements, July 2007 5.7 Underdrain Systems Fort Bragg Parachute Rigging Facility PN74813 Bioretention Cell #2 Underdrain Calculations 2/1/2019 By M. Mayer Engineered Fill Permeability (K)2 in/hr Surface Area (A)5000 ft2 Maximum Ponding Depth (C H)3.25 ft Depth of media (C L)2.5 ft Flow (Qi)0.30 cfs Apply 10x Factor of Safety (Q)2.99 cfs Roughness Factor (n)0.01 Internal Slope (s)0.005 Darcy's Equation Diameter of Single Pipe (d)12.01 in Diameter Underdrain Pipes 8 in Equavalent Number Required 3 Number Underdrain Pipes Provided 5 NCDEQ Stormwater BMP Manual Common BMP Design Elements, July 2007 5.7 Underdrain Systems Parachute Rigging Facility Fort Bragg, Cumberland County, North Carolina Mason & Hanger Page - a.9 - APPENDIX I OUTLET PROTECTION CALCULATIONS User Input Data Calculated Value Reference Data Designed By:FMM Date:10/29/2018 Checked By:Date: Company: Project Name:Parachute Rigging Project No.: Site Location (City/Town)Fort Bragg Culvert Id.HW2 Total Drainage Area (acres)3.24 Rational Method for Flow Outlet pipe diameter, Do (in.)30 Tailwater depth (in.) 15 Minimum/Maximum tailwater? Max TW (Fig. 8.06b) Discharge (cfs)14.62 Velocity (ft./s)5.81 Minimum TW Maximum TW Figure 8.06a Figure 8.06b Riprap d50, (ft.)0.5 0.5 Minimum apron length, La (ft.)12 Apron width at pipe outlet (ft.) 7.5 7.5 Apron shape TRAPEZOID Apron width at outlet end (ft.) 2.5 7.3 Minimum TW Maximum TW Max Stone Diameter, dmax (ft.) 0.75 0.75 Minimum TW Maximum TW Apron Thickness(ft.) 1.125 1.125 User Input Data Calculated Value Reference Data Designed By:FMM Date:9/25/2018 Checked By: Date: Company: Project Name:Parachute Rigging Project No.: Site Location (City/Town)Fort Bragg Culvert Id.HW3 Total Drainage Area (acres)0.41 Rational Method for Flow Outlet pipe diameter, Do (in.)15 Tailwater depth (in.) 5.76 Minimum/Maximum tailwater? Min TW (Fig. 8.06a) Discharge (cfs) 1.95 Velocity (ft./s) 4.43 Minimum TW Maximum TW Figure 8.06a Figure 8.06b Riprap d50, (ft.)0.5 0.5 Minimum apron length, La (ft.)8 8 Apron width at pipe outlet (ft.) 3.75 3.75 Apron shape TRAPEZOID TRAPEZOID Apron width at outlet end (ft.) 9.25 4.45 Minimum TW Maximum TW Max Stone Diameter, dmax (ft.) 0.75 0.75 Minimum TW Maximum TW Apron Thickness(ft.) 1.125 1.125 User Input Data Calculated Value Reference Data Designed By:FMM Date:9/25/2018 Checked By: Date: Company: Project Name:Parachute Rigging Project No.: Site Location (City/Town)Fort Bragg Culvert Id.HW5 Total Drainage Area (acres)0.41 Rational Method for Flow Outlet pipe diameter, Do (in.)15 Tailwater depth (in.) 5.8 Minimum/Maximum tailwater? Min TW (Fig. 8.06a) Discharge (cfs) 1.56 Velocity (ft./s) 3.59 Minimum TW Maximum TW Figure 8.06a Figure 8.06b Riprap d50, (ft.)0.5 0.5 Minimum apron length, La (ft.)8 8 Apron width at pipe outlet (ft.) 3.75 3.75 Apron shape TRAPEZOID TRAPEZOID Apron width at outlet end (ft.) 9.25 4.45 Minimum TW Maximum TW Max Stone Diameter, dmax (ft.) 0.75 0.75 Minimum TW Maximum TW Apron Thickness(ft.) 1.125 1.125 User Input Data Calculated Value Reference Data Designed By:FMM Date:9/25/2018 Checked By: Date: Company: Project Name:Parachute Rigging Project No.: Site Location (City/Town)Fort Bragg Culvert Id.HW6 Total Drainage Area (acres)0.38 Rational Method for Flow Outlet pipe diameter, Do (in.)15 Tailwater depth (in.) 7 Minimum/Maximum tailwater? Min TW (Fig. 8.06a) Discharge (cfs) 2.81 Velocity (ft./s) 4.62 Minimum TW Maximum TW Figure 8.06a Figure 8.06b Riprap d50, (ft.)0.5 0.5 Minimum apron length, La (ft.)8 8 Apron width at pipe outlet (ft.) 3.75 3.75 Apron shape TRAPEZOID TRAPEZOID Apron width at outlet end (ft.) 9.25 4.45 Minimum TW Maximum TW Max Stone Diameter, dmax (ft.) 0.75 0.75 Minimum TW Maximum TW Apron Thickness(ft.) 1.125 1.125 User Input Data Calculated Value Reference Data Designed By:FMM Date:9/25/2018 Checked By: Date: Company: Project Name:Parachute Rigging Project No.: Site Location (City/Town)Fort Bragg Culvert Id.HW8 Total Drainage Area (acres)0.38 Rational Method for Flow Outlet pipe diameter, Do (in.)15 Tailwater depth (in.) 10.7 Minimum/Maximum tailwater? Max TW (Fig. 8.06b) Discharge (cfs) 4.26 Velocity (ft./s) 4.55 Minimum TW Maximum TW Figure 8.06a Figure 8.06b Riprap d50, (ft.)0.5 0.5 Minimum apron length, La (ft.)8 Apron width at pipe outlet (ft.) 3.75 3.75 Apron shape TRAPEZOID Apron width at outlet end (ft.) 1.25 4.45 Minimum TW Maximum TW Max Stone Diameter, dmax (ft.) 0.75 0.75 Minimum TW Maximum TW Apron Thickness(ft.) 1.125 1.125