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Home My WebLink AboutSW6201101_MWD Facility Geotechnical Report - Building & Earth_20201130Sta me 44 y� REPORT OF SUBSURFACE EXPLORATION AND GEOTECHNICAL EVALUATION MILITARY WORKING DOG FACILITY (PN 92426) FORT BRAGG, NORTH CAROLINA BUILDING & EARTH PROJECT NO.: RD190229 PREPARED FOR: Stantec MAY 21, 2019 BUILDING & EARTH Geotechnical, Environmental, and Materials Engineers BUILDING & EARTH Geotechnical, Environmental, and Materials Engineers May 21, 2019 Stantec 801 Jones Franklin Road, Suite 300 Raleigh, North Carolina 27606-3394 Attention: Mr. Dan Saltsman, PE 2664 Timber Drive, Suite 128 Garner, North Carolina 27529 Ph: (910) 292 - 2085 www.BuildingAndEarth.com Subject: Report of Subsurface Exploration and Geotechnical Evaluation Military Working Dog Facility (PN 92426) SOTF Compound, Fort Bragg, North Carolina Building & Earth Project No: RD190229 Dear Mr. Saltsman: Building & Earth Sciences, LLP has completed the authorized subsurface exploration and geotechnical engineering evaluation for the Military Working Dog Facility located near Lamont Road in 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 ten (10) soil test borings conducted at the site. 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. North Carolina Engineering License Number F-7087 Cgg4 Q+ ESS1� �j G . -rw -YI/ — Nathan Anderson, E.I.T. -Kurt A. Miller, 'R�yr�',a� C. Mark Nolen, P.E. Staff Professional Regional Vice P d�pt •r� y Senior Vice President 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 Table Of COr1Ler1L 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.....................................................................................................................................5 3.3,1 TOPSOIL............................................................................................................................................................6 3.3,2 CLAYEY SAND (SC) OR SILTY CLAYEY SAND(SC-SM)...............................................................................6 3.3.3 POORLY GRADED SAND WITH SILT(SP-SM)..............................................................................................6 3.3,4 SILTY SAND (SM)............................................................................................................................................6 3.3.5 FAT CLAY(CH).................................................................................................................................................7 3.3,6 AUGER REFUSAL...............................................................................................................................................7 3.3,7 GROUNDWATER...............................................................................................................................................7 3.3.8 SEASONAL HIGH WATER TABLE AND INFILTRATION TESTING...................................................................8 4.0 SITE DEVELOPMENT CONSIDERATIONS..............................................................................................................................8 4.1 INITIAL SITE PREPARATION.....................................................................................................................................9 4.2 SUBGRADE EVALUATION.........................................................................................................................................9 4.3 MOISTURE SENSITIVE SOILS................................................................................................................................ 10 4.4 UNDERCUTTING OF LOW CONSISTENCY SOILS................................................................................................. 10 4.5 EVALUATION OF HIGHLY PLASTIC SOILS............................................................................................................ 11 4.6 STRUCTURAL FILL.................................................................................................................................................. 11 4.7 EXCAVATION CONSIDERATIONS.......................................................................................................................... 12 4.7.1 GROUNDWATER............................................................................................................................................ 12 4.8 UTILITY TRENCH BACKFILL................................................................................................................................... 12 4.9 LANDSCAPING AND DRAINAGE CONSIDERATION............................................................................................ 13 4.10 WET WEATHER CONSTRUCTION...................................................................................................................... 13 5.0 FOUNDATION RECOMMENDATIONS.................................................................................................................................13 5.1 SHALLOW FOUNDATIONS.................................................................................................................................... 14 6.0 FLOOR SLABS................................................................................................................................................................................15 7.0 PAVEMENT CONSIDERATIONS..............................................................................................................................................16 7.1 FLEXIBLE PAVEMENT............................................................................................................................................. 17 7.2 GRAVEL PAVEMENT.............................................................................................................................................. 17 8.0 SUBGRADE REHABILITATION.................................................................................................................................................17 9.0 CONSTRUCTION MONITORING............................................................................................................................................18 10.0 CLOSING AND LIMITATIONS...............................................................................................................................................18 APPENDIX Page I i Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 1.0 PROJECT & SITE DESCRIPTION Proposed for construction is a new Military Working Dog Training Facility (PN 92426) located on the Ft. Bragg Army Base, North Carolina. The training building will be approximately 19,500 square feet, one story in height and of pre-engineered metal construction. The building will house kennels, a veterinary clinic, surgery rooms, educational spaces, and an administrative area. Foundation loads are not available at this writing. Additional information regarding the project is summarized below in Table 1. A site aerial photograph and a site diagram follow the table. Size (Ac.) Existing Development Vegetation General Site Slopes Retaining Walls Drainage Cuts & Fills' No. of Bldgs Square Ft. Stories Proposed Construction Buildings Column Loads' Wall Loads' Preferred Foundation Preferred Slab Traffic Pavements Standard Duty <1 acre Immediate area undeveloped — Existing structures surround site Trees and grass No No Fairly well drained :-6 ft. of Fill, :-3 ft. of Cut (Assumed) 1 19,500 SF 1 Pre-engineered metal construction <<<50 kips (Assumed) i<<<? Of (Assumed) Conventional shallow spread Concrete slab-on-gra Not Provided Yes, Flexible and Gravel Heavy Duty I Yes, Flexible Table 1: Project and Site Description Reference: 1. MWD Facility "Notational Site Plan", RFP Document W912HN-15-D-0070 2. Stantec RFP Information, D. Saltsman (71312079) Notes: 1. If actual loading conditions exceed anticipated loads, Building & Earth Sciences should be allowed to review the proposed structural design and its effects on our recommendations for foundation design. Page 11 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 2. Since a final grading plan 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 plan, when it becomes available, and be contracted to provide supplemental recommendations prior to starting construction 's ExIST, 5 Figure 1: Aerial Image DepJi�cting Site Location (Google Earth) tir�t�fiSE'ri'f y l T p v it 26'3,3' jr KSCW7E 31C ++��I'�,,�_�_• yy '1F % \tom ��, 1•N{jog 1,0 } t 4- +. ; + + ° 1 �,, - + Figure 2: Site Plan (Provided by Stantec - Undated) Page 12 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 2.0 SCOPE OF SERVICES The authorized subsurface exploration was performed on April 30, 2019 in conformance with Building & Earth proposal RD21034, dated January 20, 2019, and in accordance with Stantec's Task Order referencing the project. The purpose of the geotechnical exploration has been to assess 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 ten (10) soil test borings. The site was drilled using a CME 550 ATV drilling rig equipped with a manual hammer. Soil boring sites were field located by a representative of our staff using Google Earth imagery. Boring locations were selected, and the selected sites approved by the client before drilling. Boring positions appearing on the attached Boring Location Plan should be considered approximate. Soil samples recovered during our site investigation were visually classified and specific samples were selected by the project engineer for laboratory analysis. The laboratory analyses consisted of: Natural Moisture Content Atterberg Limits D2216 1 12 D4318 1 8 Material Finer Than No. 200 Sieve by Washing D1140 8 Modified Proctor Compaction Test D1557 1 Laboratory California Bearing Ratio D1883 1 Sieve Analysis D6913 1 Table 2: Scope of Laboratory Tests Results of the laboratory analyses are presented on the enclosed Boring Logs and in tabular form in the report Appendix. Descriptions of tests performed for this study are also included in the Appendix. 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 project earthworks phase. Page 13 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 Results of the work presented in this report address: Summary of existing surface conditions. A description of the subsurface conditions encountered at the boring locations. Site preparation considerations including material types to be expected during 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. Boring logs detailing the materials encountered with soil classifications, penetration values, and groundwater levels (if measured). Presentation of laboratory test results. Recommendations for foundation design, pavement design, and slab -on -grade recommendations. Depth to SHWT and Infiltration Rates to be used in the design of storm water basins. Presentation of the estimated settlement. Supporting geotechnical calculations. ■ Plans and maps showing the location of the project and our onsite work. 3.0 GEOTECHNICAL SITE CHARACTERIZATION The following paragraphs are intended to provide a general characterization of the site from a geotechnical engineering perspective. It is not of the intention of this report to address every potential geotechnical issue that may arise, nor to provide every possible interpretation of conditions encountered. The following condition description and subsequent geotechnical 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 due to variations in site geologic conditions. It will be necessary to evaluate the assumed conditions during site grading and foundation installation. Page 14 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 3.1 GEOLOGY Situated on the boundary of the North Carolina Coastal Plain and Piedmont physiographic provinces, published geologic maps indicate the site is underlain by cretaceous aged soil deposits associated with the Middendorf and Pinehurst geologic formations. These formations are generally composed of very deep (over 100 ft.) unconsolidated sand, sandstone, clay, and mudstone. 3.2 EXISTING SURFALL %,uNDITI0IN5 The proposed new Military Working Dog Facility is located near Lamont Road on the Fort Bragg army base. The project site is currently undeveloped, but existing structures surround the general project area. According to an undated, unnamed topographic survey and site plan provided by Stantec, the site generally slopes downward in an easterly direction, from an elevation of approximately 285 to 270 feet. Ground cover consists of trees and grass. 3.3 SUBSURFACE CONDITIONS A generalized stratification summary has been prepared using data from the soil test borings and is presented in the table below. The stratification depicts general soil conditions and strata types encountered during our field investigation. 1 3 — 7 in. Topsoil N/A 2A 213 3 4 5.5 — 13.5 ft. 5.5 ft. 6.5 — 14+ ft. 4.1 ft. Clayey Sand (SC) or Silty Clayey Sand (SC-SM) Poorly Graded Sand with Silt (SP-SM) Silty Sand (SM) Fat Clay (CH) Loose to Dense Loose Loose to Medium Dense Very Stiff Table 3: Stratification Summary Subsurface soil profiles, presented in the Appendix, have also been prepared based on data obtained at the specific boring locations. For specific details on the information obtained from individual soil borings, please refer to the Boring Logs included in the Appendix. Ground surface elevations reported on the boring logs were estimated from contours appearing on the referenced topographic survey and site plan provided by Stantec. Page 15 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 3.3.1 TOPSOIL Topsoil depths observed in the test borings range from 3 to 7 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 areas of the site. -i,2 CLAYEY SAND (SC) OR SILTY CLAYEY SAND (SC-SM) Soils described as Clayey Sand (SC) or Silty Clayey Sand (SC-SM) were observed in all the test borings beginning just below the topsoil and extending to depths of about 5.5 to 13.5 feet below the surface. SPT N-values in this soil layer range from 6 to 47, with values in the range of 7 to 11 considered representative in the upper 3 feet, and 25+ blows per foot considered representative below 3 feet. Soils of this stratum are further described as loose to dense, reddish brown to reddish yellow, fine to medium grained, and moist. Laboratory classification testing was performed on Samples 3 and 5 collected from respective depth intervals 4 to 6 and 8 to 10 feet in B-08. The testing indicates liquid limits of 23 to 40, plasticity indices of 4 to 16, and a 16.3 to 24.8 percent fines (passing US Standard #200 Sieve) content. This testing corresponds to USCS SC (Clayey Sand) or SC-SM (Silty Clayey Sand) classifications. 3.3.3 POORLY GRADED SAND WITH SILT (SP-SM) In boring B-06, a Poorly Graded Sand with Silt (SP-SM) soil layer was observed below the topsoil, and above the SC layer, extending to a depth of approximately 6.0 feet. This soil type was not observed in the other nine test borings. This material is further described as loose, brown to light brown, and moist. SPT-N values in this material range from 5 to 9. Wash 200 grain size testing was performed on Sample 2 collected from B-06. Results of the testing indicate 10.2 percent passing the #200 sieve, with the fine fraction non -plastic. These data correspond to a SP-SM (Poorly Graded Sand with Silt) USCS classification. 3.3.4 SILTY SAND SM Soils described as Silty Sand (SM) were observed in all the test borings beginning just below the SC layer and extending to the boring termination depths. An interval of Fat Clay (CH) (see report section 3.3.5 below) was observed in boring B-09 through the approximate interval 19.5 to 23.5 feet. SPT N-values in this soil layer range from 6 to 28, with values in the range of 13 to 19 considered representative. Page 16 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 Soils of this stratum are further described as loose to medium dense, brown to reddish yellow, fine to medium grained, and moist to wet. Laboratory classification testing performed on 4 samples of this material indicates a liquid limit in the range 21 to 25, a plasticity index in the range 1 to 3, and fines (passing US Standard #200 Sieve) content in the range 14.6 to 21.8 percent. This testing corresponds to a USCS SM (Silty Sand) classification. 3.3.5 FAT CLAY (CH) A Fat Clay (CH) soil layer was observed in B-09, extending through the approximate depth interval 19.5 to 23.5 feet. This soil type was not observed in the other nine test borings. The fat clay soils are described as very stiff, gray, and moist. On SPT test in this material indicates a 17 bpf N-value. Wash 200 grain size testing was performed on Sample 8 from B-09 indicating 93.3 percent passing the #200 sieve. Atterberg limits testing indicates a liquid limit of 94 and a plasticity index of 47. These data correspond to a CH (Fat Clay) USCS classification. ..6 AUGER kEFUSAL Auger refusal is the drilling depth at which a 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 materials below auger refusal. Auger refusal was not encountered in borings drilled for this study. 3.3.7 GROUNDWATER At the time of drilling, groundwater (perched or otherwise) was encountered in borings B-07 through B-10, and was not observed in the remaining borings. Water levels reported are accurate only for the time and date 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. Groundwater data is included in the following table. :. B-01 Dry N/A Boring B-06 Dry N/A B-02 Dry N/A B-07 18.5 259.5 B-03 Dry N/A B-08 18.0 258.0 B-04 Dry N/A B-09 23.5 255.5 B-05 Dry N/A B-10 23.5 252.5 Table 4: Approximate Groundwater Depth/Elevation Page 17 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 3.3.8 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. As requested, Building & Earth performed infiltration testing on the project site once the SHWT was measured. 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. Our testing was performed on May 2, 2019 at the locations shown on the Boring Location map, and identified as 1-02 and 1-03. Based on the results of our testing, the soils at the site have a stabilized Ksat drainage rate of 0.22 to 1.25 inches per hour. The data sheet for infiltration testing is included in the Appendix of this report. 4.0 SITE DEVELOPMENT CONSIDERATIONS A grading plan was not available at the time of this report preparation. A finished floor elevation of 280 ft. has been assumed for purposes of this study. Based on the referenced topographic survey and site plan information, we anticipate up to 6 feet of fill and 3 feet of cut will be required to reach finished grades. When a grading plan is finalized, Building & Earth should be allowed to review the plan and its effects on our recommendations. Based on our evaluation of the subsurface soil information, and anticipated foundation loads, it appears that building support with a conventional shallow spread foundation system is feasible. Site development recommendations presented below are intended for development of the site to support construction with a shallow spread 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. Page 18 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 The primary geotechnical concerns for this project are: Moisture sensitive soils encountered across the site. Proper placement of fill to achieve final grades. Low consistency soils (N-value <_6), extending to depths of about 1 to 4 feet below the surface in borings B-06 and B-09. 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 6 inches of topsoil were observed in the borings. A geotechnical engineer should observe stripping and grubbing operations to evaluate that all unsuitable materials are removed from locations for proposed construction. 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. ,.Z 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. 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. Page 19 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 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. 1.3 MOISTURE SENSITIVE SOILS Moisture sensitive clayey sands (SC) and poorly graded sands with silt (SP-SM) 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 UNULKLU i i GNU Ur ww wNsis i ENCY SOILS Low consistency soils (N<_6) were encountered in borings B-06 and B-09, within the building footprint, in the upper 1 to 4 feet below present grades. Low consistency soils should be undercut to a stable, suitable subgrade or stabilized in place as part of the initial site preparation activities. 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. If in -place stabilization is not viable, the material should be undercut and replaced with compaction, or stabilized using mechanical means. Undercutting will be highly dependent upon final grades. Any undercutting or backfill performed within the building footprint 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 further evaluated in accordance with the Subgrade Evaluation section in order to identify any additional soft soils requiring removal. Page 110 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 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. 1.5 EVALUATION OF HIGHLY PLASTIC SOILS Based on the laboratory test results, highly plastic clay (CH) was encountered in building boring B-09 through a depth interval of about 19.5 to 23.5 feet below the surface. Therefore, it appears this material will be ±20 feet below finished grade and will not pose an issue to site grading or foundation installation. If this material were to be encountered in unexplored areas during site grading or in foundation excavations, we recommend it be removed to a minimum 3.0 feet depth below finished floor elevation and 5 feet laterally beyond building footprints. Any undercutting required to maintain at this depth should be backfilled in accordance with the Structural Fill report section below. The undercutting should be conducted under the observation of the geotechnical engineer or his representative. 4.6 STRUCTURAL FILL Requirements for structural fill on this project are as follows: Sand and Gravel SW, SP, SM or combinations Clay CL, SC, GC Clay CH Silt ML, MH Maximum 2" particle size LL<50, PI <25, yd> 100 pcf LL>50, PI>25, yd>100 pcf N/A Areas where the material can be confined. All areas Not recommended for use Not recommended for use On -site SC, SC-SM, SM, ' SC, SM, SC-SM, SP-SM: Areas where soils SP-SM, CH Maximum 2" particle size material can be confined. CH: Not recommended for use. Table 5: Structural Fill Requirements Notes: 1. All structural fill should be free of vegetation, topsoil, and any other deleterious materials. The organic content of materials to be used for fill should be less than 3 percent. 2. LL indicates the soil Liquid Limit; PI indicates the soil Plasticity Index; yd indicates the maximum dry density as defined by the density standard outlined in the table below. Page 111 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 3. Laboratory testing of the soils proposed for fill must be performed in order to verify their conformance with the above recommendations. 4. Any fill to be placed at the site should be reviewed by the geotechnical engineer. Placement requirements for structural fill are as follows: Lift Thickness 8" loose, 6" compacted � Density 92 Percent maximum per ASTM D-1557 all structural areas 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 1 test per 2,500 S.F. Minimum 2 tests per lift Frequency Table 6: Structural Fill Placement Requirements 4.7 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 encountered at depths of approximately 18 to 23.5 feet in four of the ten borings. Based on this data, it is unlikely that groundwater will be encountered during site construction. However, 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. 4.8 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. Page 112 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 4.9 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. 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. 4.10 WET WEATHER CONSTRUCTION Excessive movement of construction equipment across the site during wet weather may result in ruts, which will collect rainwater, prolonging the time required to dry the subgrade soils. 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 higher consistency soils encountered below the surface across the site, 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 Specific structural loading conditions were not provided for this study; however, based on our experience with similar projects, we anticipate individual column loads will be less than 50 kips and wall loads will be less than 2 kips per linear foot. If these assumptions concerning structural loading are incorrect, our office should be contacted, such that our recommendations can be reviewed. Page 113 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 5.1 SHALLOW FOUNDATIONS Based on 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 a 2,000 psf allowable soil bearing capacity. We recommend 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 footings. Soils not meeting the 2,000 psf allowable capacity recommendation should be undercut and backfilled with structural fill. Undercut depths may vary depending upon conditions observed during construction and final grading plans. 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 bearing surface disturbed by the excavation process and 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 foundations designed and constructed as recommended above should be 1 inch or less. Settlement calculations were performed in accordance with Schmertmann's Method for calculating settlement in non -cohesive soils (1978). These calculations can be found in the Appendix section of the report. The following items should be considered during the preparation of construction documents and during foundation installation: The geotechnical engineer of record should observe exposed foundation bearing surfaces prior to concrete placement to verify 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 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. Page 114 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 Water should not be allowed to pond in foundation excavations prior to concrete placement or above the concrete after the foundation is completed. Foundation concrete should not be placed over saturated or frozen ground. 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. ■ Foundation concrete should not be place over saturated or frozen ground. 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. We recommend floor slabs for the proposed structures be supported on a minimum four - inch layer of 1/2-inch up to 11/2-inch, free -draining, gap -graded gravel, such as AASHTO No. 57 stone, with no more than 5 percent passing the ASTM No. 200 sieve. The purpose of this layer is to help distribute concentrated loads and act as a capillary break for moisture migration through the subgrade soil. This gravel material should be consolidated in -place with vibratory equipment. With the gravel material, such as AASHTO No. 57 stone, a modulus of subgrade reaction of 125 pci is recommended for use in the design of grade -supported slabs. We recommend a minimum 10-mil thick vapor retarder meeting ASTM E 1745, Class C requirements be placed directly below the slab -on -grade floors. A higher quality vapor retarder (Class A or B) may be used if desired to further inhibit the migration of moisture through the slab -on -grade and should be evaluated based on the floor covering and use. The vapor retarder should extend to the edge of the slab -on -grade floors and should be sealed at all seams and penetrations. The slab should be appropriately reinforced (if required) to support the proposed loads. Page 115 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 7.0 PAVEMENT CONSIDERATIONS It is our understanding that a parking lot will be constructed for the Military Working Dog Facility with approximately 30 parking spaces. As requested, both flexible and gravel pavement recommendations have been included in the following sections. Based on the materials encountered at the boring locations and after our recommendations for site preparation are implemented, site pavements may be designed based on a California Bearing Ratio (CBR) of 10. CBR testing has been completed on the subject site, and results can be found in the "Laboratory Testing" section of the appendix. Pavement analysis and design has been completed using the U.S. Army COE PCASE 2.09.05 pavement design program. Assumed traffic loads can be found in table 6 below. Design and analysis are based on the provided traffic loading over a 25-year design life. Car— Passenger 1,825,000 1,825,000 2,737,500 Truck — 2 Axle, 6 Tire -- -- 27,375 Truck — 3 Axle -- -- 19,714 Truck — 4 Axle -- -- I 21,434 Table 7: Assumed Traffic Volume J 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 Roads and Structures. The applicable sections of the specifications are identified as follows: Bituminous Asphalt Wearing Layer Division 6 Bituminous Asphalt Binder Layer Division 6 Mineral Aggregate Base Materials Div. 5, Section 520 Table 8: NCDOT Specification Sections Page 116 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 7.1 FLEXIBLE PAVEMENT The following flexible pavement sections were analyzed for suitability based upon the traffic loading and other parameters tabulated above. .e Table 9: Flexible Pavement Recommendations Asphalt Stabilized Base 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. 7.2 GRAVEL PAVEMENT The following gravel pavement sections are based on the design parameters presented a bove: 6.0 ABC Stone (Aggregate Base Course) Table 10: Gravel Pavement Recommendations It is our understanding that a new gravel parking lot option will be considered for the project site. Building & Earth recommends pavement section consisting of at least 6 inches of North Carolina Department of Transportation (NCDOT) compliant ABC Stone on stabilized subbase. 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. Page 117 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 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 ■ All other items subject to IBC Special Inspections 10.0 CLOSING AND LIMITATIONS This report was prepared for Stantec, for specific application to the Military Working Dog Training Facility located in 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. Page 118 Subsurface Exploration and Geotechnical Evaluation, Military Working Dog Facility, Fort Bragg, North Carolina Project No: RD190229, May 21, 2019 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 Geotechnica( Report, has been included in the Appendix. We encourage all individuals to become familiar with the article to help manage risk. Page 119 Appendix Table of Contents GEOTECHNICAL INVESTIGATION METHODOLOGIES........................................................................................... 1 DRILLING PROCEDURES —STANDARD PENETRATION TEST (ASTM D1586)........................... 1 BORING LOG DESCRIPTION............................................................................................................................................2 DEPTH AND ELEVATION................................................................................................................................ 2 SAMPLETYPE.....................................................................................................................................................2 SAMPLENUMBER.............................................................................................................................................2 BLOWS PER INCREMENT, REC%, RQD%................................................................................................. 2 SOILDATA...........................................................................................................................................................2 SOIL DESCRIPTION.......................................................................................................................................... 3 GRAPHIC.............................................................................................................................................................. 3 REMARKS............................................................................................................................................................. 3 SOIL CLASSIFICATION METHODOLOGY.....................................................................................................................4 KEYTO LOGS......................................................................................................................................................................... 5 KEYTO HATCHES................................................................................................................................................................7 BORING LOCATION PLAN............................................................................................................................................... 8 SUBSURFACE SOIL PROFILES..........................................................................................................................................9 BORINGLOGS.....................................................................................................................................................................10 INFILTRATION DATA........................................................................................................................................................11 SEASONAL HIGH WATER TABLE DATA.....................................................................................................................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.....................................................................................................................15 Table A-1: General Soil Classification Test Results.......................................................................15 IMPORTANT INFORMATION ABOUT THIS GEOTECHNICAL-ENGINEERING REPORT ............................16 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 D 7586) 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 manual 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. 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. 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. 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. • 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%. — The Natural Moisture Content of the soil sample as determined in our laboratory. Page I A-2 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. HLMAHK. Remarks regarding borehole observations, and additional information regarding the laboratory results and groundwater observations. Page I A-3 Geocechnical, Environmental, and Materials Engineers Coarse Grained Soils More than 50% of material is larger than No. 200 sieve size Fine Grained Soils More than 50% of material is smaller than No. 200 sieve size Gravel and Gravelly Soils More than 50% of coarse fraction is larger than No. 4 sieve Sand and Sandy Soils More than 50% of coarse fraction is smaller than No. 4 sieve Silts and Clays Liquid Limit less than 50 Silts and Clays Liquid Limit greater than 50 sieve SOIL CLASSIFICATION METHODOLOGY 1 � Im / � Im 91166 S• 6', Gw Well -graded gravels, gravel — sand mixtures, little or Clean Gravels , no fines (Less than 5% fines) 0 0� oo °� Id Poorly -graded gravels, gravel — sand mixtures, little D� pFGP 0 or no fines a L C GM Silty gravels, gravel —sand —silt mixtures Gravels with Fines (More than 72% fines) GC Clayey gravels, gravel —sand —clay mixtures Clean Sands SW Well -graded sands, gravelly sands, little or no fines (Less than 5% fines) Sp Poorly -graded sands, gravelly sands, little or no fines Sands with Fines SM Silty sands, sand —silt mixtures (More than 72% fines) Inorganic Organic Inorganic Organic Highly Organic Soils SC Clayey sands, sand — clay mixtures Inorganic silts and very find sands, rock flour, silty or ML clayey fine sands or clayey silt with slight plasticity Inorganic clays of low to medium plasticity, gravelly clays, sandy clays, silty clays, lean clays jCL Organic silts and organic silty clays of low plasticity — — — — — — _ OL MH IInorganic silts, micaceous or diatomaceous fine sand, or silty soils CH I Inorganic clays of high plasticity OH IOrganic clays of medium to high plasticity, organic silts „ PT Peat humus, swamp soils with high organic L� r � r • r contents .1 11 %% 11 14 fr 11 Page I A-4 Geotechnica1, Environmental, and Materials Engineers 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. SOIL CLASSIFICATION METHODOLOGY 60 oe 50 J� CH or OH a X 40 v 30 P a✓ CL or OL 20 a 10 MH orOH 4 CL M MLorOL 0 0 10 20 30 40 50 60 70 80 90 100 Liquid Limit (LL) Non -cohesive: Coarse -Grained Soil Cohesive: Fine -Grained Soil SPT Penetration Estimated Range of SPT Penetration (blows/foot) Unconfined Compressive Consistency (blows/foot) Relative Automatic Manual Strength (tsf) Density Hammer* Hammer Automatic Manual < 2 < 2 Very Soft < 0.25 Hammer* Hammer 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 15 - 30 Stiff Very Stiff 1.00 — 2.00 2.00 — 4.00 > 4.00 23 - 38 30- 50 Dense 12 -23 Very Dense > 23 > 38 > 50 > 30 Hard * - Modified based on 80% hammer efficiency Page I A-5 Geocechnical, Environmental, and Materials Engineers Standard Dynamic Cone Penetration Test Penetrometer ASTM D1586 or (Sower DCP) AASHTO T-206 ASTM STP-399 Shelby Tube Sampler No Sample O ASTM D1587 Recovery Rock Core Sample -v Groundwater at ASTM D2113 - Time of Drilling Auger Cuttings Groundwater as Indicated KEY TO LOGS Soil Particle Size U.S. Standard Boulders Larger than 300 mm N.A. Cobbles 300 mm to 75 mm N.A. Gravel 75 mm to 4.75 mm 3-inch to #4 sieve Coarse 75 mm to 19 mm 3-inch to 3/4-inch sieve Fine 19 mm to 4.75 mm 3/4-inch to #4 sieve 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 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 pm N.A. Clay Less than 2 pm N.A. Table•. • Sieve Sizes Standard Penetration Test Resistance A measure of a soil's plasticity characteristics in N-Value Atterberg general accordance with ASTM D4318. The soil calculated using ASTM D1586 or AASHTO T- Limits Plasticity Index (PI) is representative of this ❑ 206. Calculated as sum of original, field i characteristic and is bracketed by the Liquid Limit (LL) recorded values. PL LL and the Plastic Limit (PL). Qu Unconfined compressive strength, typically P 9 tYP Y 35 Moisture percent natural moisture content in general estimated from a pocket penetrometer. Results are presented in tons per square foot (tsf). accordance with ASTM D2216. 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. Mud Rotary / A cutting head advances the boring and discharges a drilling fluid to Wash Bore support the borehole and circulate cuttings to the surface. Solid Flight Auger Flights on the outside bring soil cuttings to the surface. Solid stem requires removal from borehole during sampling. Hand Auger Cylindrical bucket (typically 3-inch diameter and 8 inches long) attached to a metal rod and turned by human force. Descriptor Meaning Trace Likely less than 5% Few 5 to 10% Little 15 to 25% Some 30 to 45% Mostly 50 to 100% . •le 5: Descripto Page I A-6 BUILDING KEY TO LOGS G eatec h n ical, Environmental, and Materials Engineers 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. Uses a 15-pound steel mass falling 20 inches to strike an anvil and cause penetration Dynamic Cone Penetrometer of a 1.5-inch diameter cone seated in the bottom of a hand augered borehole. The (Sower DCP) ASTM STP-399 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). 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. The thread is easy to roll and not much time is required to reach the plastic limit. The Medium thread cannot be re -rolled after reaching the plastic limit. The lump crumbles when drier than the plastic limit. _ _ It takes considerable time rolling and kneading to reach the plastic limit The thread High can be re -rolled several times after reaching the plastic limit. The lump can be formed without crumblina when drier than the plastic limit. 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. Stratified Alternating layers of varying material or color with layers at least 1/2 inch thick. Laminated Alternating layers of varying material or color with layers less than 1/4 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. .. - Page I A-7 BUILDING &EARTH Geocechnlcal. Environmental, and Materials Engineers IMP IM /W `� �■ �`� GW - Well -graded gravels, gravel — sand + + mixtures, little or no fines ya° '0 GP - Poorly -graded gravels, gravel — sand o O a b mixtures, little or no fines v � °o a - GM - Silty gravels, gravel — sand — silt O� mixtures GC - Clayey gravels, gravel — sand — clay mixtures SW - Well -graded sands, gravelly sands, little or no fines SP - Poorly -graded sands, gravelly sands, little or no fines ' SM - Silty sands, sand — silt mixtures F SC - Clayey sands, sand — clay mixtures 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 days, si!ty clays, lean clays OL - Organic silts and organic silty clays of low plasticity MH - Inorganic silts, micaceous or diatomaceous fine sand, or silty soils CH - Inorganic clays of high plasticity OH - Organic clays of medium to high plasticity, organic silts PT - Peat, humus, swamp soils with high organic contents W0--9,Q Asphalt P,� aim °" `` a •.'a "fi}a Concrete �:•8': d :.'A'•..: a ::�': s KEY TO HATCHES Clay with Gravel a• • Q '•'Qa• • Q .{ Sand with Gravel Silt with Gravel r' &�� Gravel with Sand .� b. all •� Gravel with Clay � S s Gravel with Silt Limestone Chalk Low and Plasticity . , . Till 0 Cobbles and Boulders ��♦ Sandstone with Shale Weathered ., . . Sandstone Boulders and Cobbles o• do• Soil and Weathered Shale n '� Rock V Page I A-8 BORING LOCATION PLAN Page I A-9 ��, � t � � L. f J•� '% � ' �..� � � I� J f f i r r lI ' • � / f � � r O • J ("--r err,/f-' rrJ f -'' �'l;i J ,. r �r I•�`i'if - �,�"/�-�• Gl C m L r6 O !4p wlwl CN ' C U N LL "0 r8 cm i V LT u L ru jk O i+ + Jy + ;J r r $ y 3w r J v �A v �- LL AA a CAUJ to v O Ll A rig, . i F Ur YflIA cl o r c �,% ❑� � � r co ■ A SUBSURFACE SOIL PROFILES Page I A-10 W v km 1 {j LL c i H N oa 0 W Q w I 0 b ' 1 o N C z T o = a y ml H Vi Q U- O co O O m 7 Q b � O c ai I v R � � � 7•� Z I LU Y 1 m O m m a .5 c = O y w I n �LL N N E LL L. c v 1 m O v p Z � m I I � O Z m c[ I v E o v v M. s v O o o v v v E v o 1 0 N v N E- v O .O .� Ul Ol Ol Ul ^ J Q aci E v K K a Y c w m° o v v -6 u II Q a J > 1 m o E 0 0 v v o = v > 01 a 01 Z D �1 II a y N 01 01 E1 H i0 1 cI 0 N1 c � m d1 rn1 O Y ai cu V V DI > >a I 01 O I V1 0 W N1 V V I LLIco _� V V I Z N EI ro O ro N o Y cI W1 �Y o 3 U 0 O c O N �a°v � I I 1 I Z m m m m �n O ro N m O to N I I I 0 m� I 0 ` 1 �- Z Z m N N m ro m N m� o COO N N N N N (}aa}) NOIlVAII3 N N N rn 6l/£l/S fd9'1NI5snonNIlNOD6ZZ0614?J M3N 3TJMJd � d _ : ` 0 ° / 3 �\ @) § 2 ■a\2 .� 2 _ = Ea— )az I�§ � % ® �b r _ .E ». ^ oƒ N■- / o - �f 4 t .M j - z L\ j m § 2 3 > / !)f/ >�\)/_ \�\VE - :c /)/-uwo j _ /ƒ\o o _ ;\23±!! o- o) _ )tt--, \\`)) , \ ># � ff] ul m I u 0 ) : �: ` / J � j 2 py No Azn mmmr ae:mmmm6EE06ra mN 3,m+ BORING LOGS Page I A-11 Geotechnical, Environmental, and Materials Engineers PROJECT NAME: Military Working Dog Facility @ SOTF PROJECT NUMBER: RD190229 DRILLING METHOD: Hollow Stem Auger EQUIPMENT USED: CME 550 ATV HAMMER TYPE: Manual BORING LOCATION: South Parking Lot Entrance LOG OF BORING Designation: B-01 Sheet 1 of 1 610 Spring Branch Road Dunn, NC 28334 Office: (919) 292-2085 Fax: (205) 836-9007 www.BuildingAndEarth.com LOCATION: Fort Bragg, North Carolina DATE DRILLED: 4/30/19 WEATHER: 69 degrees, sunny ELEVATION: 274.0 DRILL CREW: J&L Drilling LOGGED BY: M. Lumpkin ❑ N-Value ❑ a p z O Q w w w J a zz J 0- < `^ H n w w 2 Z 10 20 30 40 Q m Q SOIL DESCRIPTION V _ l7 REMARKS A Qu (tsf) A 1 2 3 4 1 Atterberg Limits I 20 40 60 80 • % Moisture • 20 40 60 80 1 4-4-6-5 .. .:..:..:..:..:..:. Sample 1 M: . / 12 2 0.6 TOPSOIL: (Approximately 7") 273.4 CLAYEY SAND (SC): medium dense, red dish brown, fine to medium grained, moist 2 8-19-22-31 ..:..:..:... :..:..:..:. dense, reddish -yellow 270 5 3 18-24-23-2 4 16-24-16-3 ..:..:.....:..:..:..:..:..:.. 7.8 266.2 ' 265 5 11-1z-11-1s ":' 8 f t cave-in at 7 ee after pulling augers SILTY SAND (SM): medium dense,Boring reddish -yellow, fine to medium grained, moist 10 10.0 264.0 (COASTAL PLAIN) Boring Terminated at 10 feet. 260 15 255 20 250 Groundwater not encountered at time of 25 drilling. ............................ Borehole backfilled on date drilled unless otherwise noted. 245 Consistency/Relative Density based on correction factor for Manual hammer. SAMPLE TYPE N Split Spoon N-VALUE STANDARD PENETRATION RESISTANCE (AASHTO T-206) REC RECOVERY LL: LIQUID LIMIT M: NATURAL MOISTURE CONTENT % MOISTURE PERCENT NATURAL MOISTURE CONTENT RQD ROCK QUALITY DESIGNATION PL: PLASTIC LIMIT F: PERCENT PASSING NO. 200 SIEVE SZ GROUNDWATER LEVEL IN THE BOREHOLE AT TIME OF DRILLING UD UNDISTURBED PI: PLASTICITY INDEX 1 STABILIZED GROUNDWATER LEVEL Qu POCKET PENETROMETER UNCONFINED COMPRESSIVE STRENGTH Birmingham, AL • Auburn, AL • Huntsville, AL • Montgomery, AL • Mobile, AL • Tuscaloosa, AL Columbus, GA • Louisville, KY • Raleigh, NC • Dunn, NC • Jacksonville, NC Springdale, AR 9 Little Rock, AR 9 Tulsa, OK 9 Oklahoma City, OK 9 Durant, OK Geotechnical, Environmental, and Materials Engineers PROJECT NAME: Military Working Dog Facility @ SOTF PROJECT NUMBER: RD190229 DRILLING METHOD: Hollow Stem Auger EQUIPMENT USED: CME 550 ATV HAMMER TYPE: Manual BORING LOCATION: North Parking Lot Entrance LOG OF BORING Designation: B-02 Sheet 1 of 1 610 Spring Branch Road Dunn, NC 28334 Office: (919) 292-2085 Fax: (205) 836-9007 www.BuildingAndEarth.com LOCATION: Fort Bragg, North Carolina DATE DRILLED: 4/29/19 WEATHER: 69 degrees, sunny ELEVATION: 269.0 DRILL CREW: J&L Drilling LOGGED BY: M. Lumpkin ❑ N-Value ❑ a p z O Q w w w J a zz J 0- < `^ H n w w 2 Z 10 20 30 40 Q m Q SOIL DESCRIPTION V _ l7 REMARKS A Qu (tsf) A 1 2 3 4 1 Atterberg Limits I 20 40 60 80 • % Moisture • 20 40 60 80 TOPSOIL: (Approximately 3") 1 9-11-9-12 ...................:.. I en CLAYEY SAND (SC): med�um d se, reddish -yellow, fine to medium grained, moist 2 13-16-13-1 ..:..: :..:..:..:..:..:..:.. 265-X 5 3 12-12-13-1 4 14-16-18-1 ..:..:..: :..:..:..:..:. dense 10 260 X 5 12-9-9-8 • . . . . . . . . Sample 5 111 M: % medium dense 10.0 259.0': (COASTAL PLAIN) Bo cave in at 8 ring c 6 feet after pulling augers Boring Terminated at 10 feet. 255 15 250 20 245 Groundwater not encountered at time of 25 drilling. ............................ Borehole backfilled on date drilled unless otherwise noted. 240 Consistency/Relative Density based on correction factor for Manual hammer. SAMPLE TYPE N Split Spoon N-VALUE STANDARD PENETRATION RESISTANCE (AASHTO T-206) REC RECOVERY LL: LIQUID LIMIT M: NATURAL MOISTURE CONTENT % MOISTURE PERCENT NATURAL MOISTURE CONTENT RQD ROCK QUALITY DESIGNATION PL: PLASTIC LIMIT F: PERCENT PASSING NO. 200 SIEVE SZ GROUNDWATER LEVEL IN THE BOREHOLE AT TIME OF DRILLING UD UNDISTURBED PI: PLASTICITY INDEX 1 STABILIZED GROUNDWATER LEVEL Qu POCKET PENETROMETER UNCONFINED COMPRESSIVE STRENGTH Birmingham, AL • Auburn, AL • Huntsville, AL • Montgomery, AL • Mobile, AL • Tuscaloosa, AL Columbus, GA • Louisville, KY • Raleigh, NC • Dunn, NC • Jacksonville, NC Springdale, AR 9 Little Rock, AR 9 Tulsa, OK 9 Oklahoma City, OK 9 Durant, OK Geotechnical, Environmental, and Materials Engineers PROJECT NAME: Military Working Dog Facility @ SOTF PROJECT NUMBER: RD190229 DRILLING METHOD: Hollow Stem Auger EQUIPMENT USED: CME 550 ATV HAMMER TYPE: Manual BORING LOCATION: South Parking Lot LOG OF BORING Designation: B-03 Sheet 1 of 1 610 Spring Branch Road Dunn, NC 28334 Office: (919) 292-2085 Fax: (205) 836-9007 www.BuildingAndEarth.com LOCATION: Fort Bragg, North Carolina DATE DRILLED: 4/30/19 WEATHER: 69 degrees, sunny ELEVATION: 276.0 DRILL CREW: J&L Drilling LOGGED BY: M. Lumpkin ❑ N-Value ❑ w H w 10 20 30 40 V A Qu (tsf) A z zz n Q O J J w 2 1 2 3 4 SOIL DESCRIPTION _ REMARKS 1 Atterberg Limits I a Q a 0- m p w < Z 20 40 60 80 Q l7 • % Moisture • w `^ 20 40 60 80 TOPSOIL: (Approximately 6") i CLAYEY SAND (SC): medium dense, se, 275 1 3-7-8-8 ..: ............... reddish -yellow, fine to medium grained, moist 2 8-23-17-24 ..:..:..: :..:..:..:..:. dense 5 3 15-19-21-2 Sample 3 M: 13.1 % 270 4 15-9-9-12 ":""':":":":":":":" 7.4 medium dense 268.E:'. SILTY SAND (SM): medium dense, light Boring caved -in at 7.5 feet brown, fine to medium grained, moist ,. .: .. after pulling augers 5 9-10-10-14 ..:. .:..:..:..:..:..:..:.. 10 10.0 266.0 (COASTAL PLAIN) Boring Terminated at 10 feet 265 15 260 20 255 ..:..:..:..:..:..:..:..:..:. Groundwater not encountered at time of 25 drilling. 250 Borehole backfilled on date drilled unless otherwise noted. Consistency/Relative Density based on correction factor for Manual hammer. SAMPLE TYPE N Split Spoon N-VALUE STANDARD PENETRATION RESISTANCE (AASHTO T-206) REC RECOVERY LL: LIQUID LIMIT M: NATURAL MOISTURE CONTENT % MOISTURE PERCENT NATURAL MOISTURE CONTENT RQD ROCK QUALITY DESIGNATION PL: PLASTIC LIMIT F: PERCENT PASSING NO. 200 SIEVE SZ GROUNDWATER LEVEL IN THE BOREHOLE AT TIME OF DRILLING UD UNDISTURBED PI: PLASTICITY INDEX 1 STABILIZED GROUNDWATER LEVEL Qu POCKET PENETROMETER UNCONFINED COMPRESSIVE STRENGTH Birmingham, AL • Auburn, AL • Huntsville, AL • Montgomery, AL • Mobile, AL • Tuscaloosa, AL Columbus, GA • Louisville, KY • Raleigh, NC • Dunn, NC • Jacksonville, NC Springdale, AR 9 Little Rock, AR 9 Tulsa, OK 9 Oklahoma City, OK 9 Durant, OK Geotechnical, Environmental, and Materials Engineers PROJECT NAME: Military Working Dog Facility @ SOTF PROJECT NUMBER: RD190229 DRILLING METHOD: Hollow Stem Auger EQUIPMENT USED: CME 550 ATV HAMMER TYPE: Manual BORING LOCATION: North Parking Lot LOG OF BORING Designation: B-04 Sheet 1 of 1 610 Spring Branch Road Dunn, NC 28334 Office: (919) 292-2085 Fax: (205) 836-9007 www.BuildingAndEarth.com LOCATION: Fort Bragg, North Carolina DATE DRILLED: 4/29/19 WEATHER: 69 degrees, sunny ELEVATION: 270.0 DRILL CREW: J&L Drilling LOGGED BY: M. Lumpkin ❑ N-Value ❑ a p z O Q w w w J a zz J 0- < `^ H n w w 2 Z 10 20 30 40 Q m Q SOIL DESCRIPTION V _ l7 REMARKS A Qu (tsf) A 1 2 3 4 1 Atterberg Limits I 20 40 60 80 • % Moisture • 20 40 60 80 - 21 TOPSOIL: (Approximately 6") '� '' '�� e i CLAYEY SAND (SC): medium m dense, reddish X 1 4-6-5-7 brown, fine to medium grained, moist 2 4-4-4-5 .....:..:..:..:..:..:..:. loose 5 265 3 5-6-5-4 medium dense 6.0 264.0 SILTY SAND (SM): loose, reddish -yellow, fine to medium grained, moist 4 3-3-3-8 Sample 4 M: 5 .5 o 5 4-6-8-7 medium dense Boring caved -in at 9 feet 10 260 10.0 260.0 (COASTAL PLAIN) :: ' after pulling augers Boring Terminated at 10 feet. 15 255 20 250 ..:..:..:..:..:..:..:..:..:. Groundwater not encountered at time of 25 245 drilling. ............................ Borehole backfilled on date drilled unless otherwise noted. Consistency/Relative Density based on correction factor for Manual hammer. SAMPLE TYPE N Split Spoon N-VALUE STANDARD PENETRATION RESISTANCE (AASHTO T-206) REC RECOVERY LL: LIQUID LIMIT M: NATURAL MOISTURE CONTENT % MOISTURE PERCENT NATURAL MOISTURE CONTENT RQD ROCK QUALITY DESIGNATION PL: PLASTIC LIMIT F: PERCENT PASSING NO. 200 SIEVE SZ GROUNDWATER LEVEL IN THE BOREHOLE AT TIME OF DRILLING UD UNDISTURBED PI: PLASTICITY INDEX 1 STABILIZED GROUNDWATER LEVEL Qu POCKET PENETROMETER UNCONFINED COMPRESSIVE STRENGTH Birmingham, AL • Auburn, AL • Huntsville, AL • Montgomery, AL • Mobile, AL • Tuscaloosa, AL Columbus, GA • Louisville, KY • Raleigh, NC • Dunn, NC • Jacksonville, NC Springdale, AR 9 Little Rock, AR 9 Tulsa, OK 9 Oklahoma City, OK 9 Durant, OK Geotechnical, Environmental, and Materials Engineers PROJECT NAME: Military Working Dog Facility @ SOTF PROJECT NUMBER: RD190229 DRILLING METHOD: Hollow Stem Auger EQUIPMENT USED: CME 550 ATV HAMMER TYPE: Manual BORING LOCATION: South East Corner Builidng Pad LOG OF BORING Designation: B-05 Sheet 1 of 1 610 Spring Branch Road Dunn, NC 28334 Office: (919) 292-2085 Fax: (205) 836-9007 www.BuildingAndEarth.com LOCATION: Fort Bragg, North Carolina DATE DRILLED: 4/30/19 WEATHER: 69 degrees, sunny ELEVATION: 279.5 DRILL CREW: J&L Drilling LOGGED BY: M. Lumpkin ❑ N-Value ❑ w H w 10 20 30 40 V A Qu (tsf) A z zz n Q O J J w 2 1 2 3 4 SOIL DESCRIPTION _ REMARKS 1 Atterberg Limits I a Q a 0- m p w < Z 20 40 60 80 Q l7 • % Moisture • w `^ 20 40 60 80 _X TOPSOIL: (Approximately 6") '� ' �� CLAYEY SAND (SC): medium d dense, 1 14-10-8-8 ... ............... reddish -yellow, fine to medium grained, moist _X 2 5-6-6-8 .....:..:..:..:..:..:..:..:.. 275-X 5 3 3-4-7-9 4 8-21-23-30 ........: ......... dense _X 6 0-16-20-2 .......... ................ 270 10 - _X 6 16-23-22-2 ..:..:..:..: :..:..:..:..:.. ' Sample 7 13.5 266.0 LL:25 7 PL: 22 SILTY SAND (SM). medium dense, light brown, 265 11-11-12 0 PI: 3 fine to medium grained, moist 15 M: 12.4% F: 20.3 % 260 8 11-12-14 ..:..: .:..:..:..:..:..:. Boring caved -in at 19.4 feet 20 after pulling augers 9 ..:..:. :..:..:..:..:. Groundwater not 255 13-13-1a 25.0 254.5 :': encountered at time of 25 (COASTAL PLAIN) drilling. Boring Terminated at 25 feet. ..:..:..:..:..:..:..:..:..:. Borehole backfilled on date drilled unless otherwise noted. Consistency/Relative Density based on correction factor 250 for Manual hammer. SAMPLE TYPE N Split Spoon N-VALUE STANDARD PENETRATION RESISTANCE (AASHTO T-206) REC RECOVERY LL: LIQUID LIMIT M: NATURAL MOISTURE CONTENT % MOISTURE PERCENT NATURAL MOISTURE CONTENT RQD ROCK QUALITY DESIGNATION PL: PLASTIC LIMIT F: PERCENT PASSING NO. 200 SIEVE SZ GROUNDWATER LEVEL IN THE BOREHOLE AT TIME OF DRILLING UD UNDISTURBED PI: PLASTICITY INDEX 1 STABILIZED GROUNDWATER LEVEL Qu POCKET PENETROMETER UNCONFINED COMPRESSIVE STRENGTH Birmingham, AL • Auburn, AL • Huntsville, AL • Montgomery, AL • Mobile, AL • Tuscaloosa, AL Columbus, GA • Louisville, KY • Raleigh, NC • Dunn, NC • Jacksonville, NC Springdale, AR 9 Little Rock, AR 9 Tulsa, OK 9 Oklahoma City, OK 9 Durant, OK Geotechnical, Environmental, and Materials Engineers PROJECT NAME: Military Working Dog Facility @ SOTF PROJECT NUMBER: RD190229 DRILLING METHOD: Hollow Stem Auger EQUIPMENT USED: CME 550 ATV HAMMER TYPE: Manual BORING LOCATION: South West Corner Building Pad LOG OF BORING Designation: B-06 Sheet 1 of 1 610 Spring Branch Road Dunn, NC 28334 Office: (919) 292-2085 Fax: (205) 836-9007 www.BuildingAndEarth.com LOCATION: Fort Bragg, North Carolina DATE DRILLED: 4/29/19 WEATHER: 69 degrees, sunny ELEVATION: 283.0 DRILL CREW: J&L Drilling LOGGED BY: M. Lumpkin ❑ N-Value ❑ w H w 10 20 30 40 V A Qu (tsf) A z zz n Q O J J w 2 1 2 3 4 SOIL DESCRIPTION _ REMARKS 1 Atterberg Limits I a Q a 0- m p w < Z 20 40 60 80 Q l7 • % Moisture • w `^ 20 40 60 80 TOPSOIL: (Approximately 6") POORLY GRADED SAND WITH SILT (SP SM): 1 3-2-3-4 .................. Sample 2 loose, brown, fine to medium grained, moist LL: NP 280 2 3-3-3-3 P L: NP PI: NP M: 5.1 F: 10.2% 5 3 s-s-e-s light brown ..... ....................... 6.0 277.0 CLAYEY SAND (SC): medium dense, 4 9-12-14-18 ":":""':":":":":":" brown, fine to medium grained, moist 275 _X 5 11-16-20-2 dense, reddish -yellow 10 6 12-21-22-23 ..:..:..:..: :..:..:..:..:.. :.. 270 7 14-13-15 ..:..:. :..:..:..:..:..:..: medium dense 15 265 18.5 264.5:. SILTY SAND (SM): medium dense, ..:..:..:..:..:..:..:. 8 10-e-10 reddish -yellow, fine to medium grained, moist 20 Boring caved -in at 20.5 feet after pulling augers 260 g ..:. :..:..:..:..:..:..:..:. Groundwater not e-8-11 25.0 258.0 ::: encountered at time of 25 (COASTAL PLAIN) drilling. Boring Terminated at 25 feet. ..:..:..:..:..:..:..:..:..:. Borehole backfilled on date drilled unless otherwise noted. Consistency/Relative Density based on correction factor for Manual hammer. SAMPLE TYPE N Split Spoon N-VALUE STANDARD PENETRATION RESISTANCE (AASHTO T-206) REC RECOVERY LL: LIQUID LIMIT M: NATURAL MOISTURE CONTENT % MOISTURE PERCENT NATURAL MOISTURE CONTENT RQD ROCK QUALITY DESIGNATION PL: PLASTIC LIMIT F: PERCENT PASSING NO. 200 SIEVE SZ GROUNDWATER LEVEL IN THE BOREHOLE AT TIME OF DRILLING UD UNDISTURBED PI: PLASTICITY INDEX 1 STABILIZED GROUNDWATER LEVEL Qu POCKET PENETROMETER UNCONFINED COMPRESSIVE STRENGTH Birmingham, AL • Auburn, AL • Huntsville, AL • Montgomery, AL • Mobile, AL • Tuscaloosa, AL Columbus, GA • Louisville, KY • Raleigh, NC • Dunn, NC • Jacksonville, NC Springdale, AR 9 Little Rock, AR 9 Tulsa, OK 9 Oklahoma City, OK 9 Durant, OK Geotechnical, Environmental, and Materials Engineers PROJECT NAME: Military Working Dog Facility @ SOTF PROJECT NUMBER: RD190229 DRILLING METHOD: Hollow Stem Auger EQUIPMENT USED: CME 550 ATV HAMMER TYPE: Manual BORING LOCATION: South Center Building Pad LOG OF BORING Designation: B-07 Sheet 1 of 1 610 Spring Branch Road Dunn, NC 28334 Office: (919) 292-2085 Fax: (205) 836-9007 www.BuildingAndEarth.com LOCATION: Fort Bragg, North Carolina DATE DRILLED: 4/29/19 WEATHER: 69 degrees, sunny ELEVATION: 278.0 DRILL CREW: J&L Drilling LOGGED BY: M. Lumpkin ❑ N-Value ❑ w H w 10 20 30 40 V A Qu (tsf) A z zz n Q O J J w 2 1 2 3 4 SOIL DESCRIPTION _ REMARKS 1 Atterberg Limits I a Q a 0- m p w < Z 20 40 60 80 Q l7 • % Moisture • w `^ 20 40 60 80 TOPSOIL: (Approximately 6") CLAYEY SAND (SC)brown, loose, b , fine to 1 3-3-5-4 medium grained, moist 275 2 3-8-17-15 medium dense 5 3 10-15-18-2 dense, reddish -yellow 4 12-16-15-1 ..:..:. .:..:..:..:..:..:.. ','. 270 8.2 269.8 SILTY SAND (SM): medium dense reddish sh 5 9-9-7-9 yellow, fine to medium grained, moist e w, f m ra d, 10 Sample 6 LL:22 _X 6 8767 .. .R.:..:..:..:..:..:..: PL:20 PI:2 M: 10.4% F: 14.6% 265 7 8-5-7 .. ..:..:..:..:..:..:..:..:.. 15 260 ft GW encountered at 18.5 . brown, et light wn, w t time of drilling a d Il ng 8 6_g_7 20 Boring caved -in at 18.5 feet after pulling augers 255 ........ 9 3-6-12 ................. :..:..:..:.. 25 25.0 253.0 (COASTAL PLAIN) Boring Terminated at 25 feet. ..:..:..:..:..:..:..:..:..:. Borehole backfilled on date drilled unless otherwise noted. Consistency/Relative Density based on correction factor for Manual hammer. SAMPLE TYPE N Split Spoon N-VALUE STANDARD PENETRATION RESISTANCE (AASHTO T-206) REC RECOVERY LL: LIQUID LIMIT M: NATURAL MOISTURE CONTENT % MOISTURE PERCENT NATURAL MOISTURE CONTENT RQD ROCK QUALITY DESIGNATION PL: PLASTIC LIMIT F: PERCENT PASSING NO. 200 SIEVE SZ GROUNDWATER LEVEL IN THE BOREHOLE AT TIME OF DRILLING UD UNDISTURBED PI: PLASTICITY INDEX 1 STABILIZED GROUNDWATER LEVEL Qu POCKET PENETROMETER UNCONFINED COMPRESSIVE STRENGTH Birmingham, AL • Auburn, AL • Huntsville, AL • Montgomery, AL • Mobile, AL • Tuscaloosa, AL Columbus, GA • Louisville, KY • Raleigh, NC • Dunn, NC • Jacksonville, NC Springdale, AR 9 Little Rock, AR 9 Tulsa, OK 9 Oklahoma City, OK 9 Durant, OK Geotechnical, Environmental, and Materials Engineers PROJECT NAME: Military Working Dog Facility @ SOTF PROJECT NUMBER: RD190229 DRILLING METHOD: Hollow Stem Auger EQUIPMENT USED: CME 550 ATV HAMMER TYPE: Manual BORING LOCATION: North Center Building Pad LOG OF BORING Designation: B-08 Sheet 1 of 1 610 Spring Branch Road Dunn, NC 28334 Office: (919) 292-2085 Fax: (205) 836-9007 www.BuildingAndEarth.com LOCATION: Fort Bragg, North Carolina DATE DRILLED: 4/29/19 WEATHER: 69 degrees, sunny ELEVATION: 276.0 DRILL CREW: J&L Drilling LOGGED BY: M. Lumpkin ❑ N-Value ❑ w H w 10 20 30 40 V A Qu (tsf) A z zz n Q O J J w 2 1 2 3 4 SOIL DESCRIPTION _ REMARKS 1 Atterberg Limits I a Q a 0- m p w < Z 20 40 60 80 Q l7 • % Moisture • w `^ 20 40 60 80 TOPSOIL: (Approximately 6") I CLAYEY SAND (SC): medium dense, se, 275 1 4-6-7-11 ..: ............... reddish -brown, fine to medium grained, moist 2 6-4-4-4 ..... :..:..:..:..:..:..:..:.. loose Sample 3 ILL: 40 5 3 4-3-4-3 PL:24 PI:16 270 M: 12.7% 24 8 / F: . o _X 4 :..:..:..:..:..:..:..:..:.. 7.0 269.0. SILTY CLAYEY SAND (SC SM): loose, 3-3-3-4 Sample 5 f m ra d, reddish-yellow,ine to medium grained, moist LL:23 5 '................ P L: 19 6-5-3-4 PI: 4 10 M: 9.7 % F: 16.3% 265 6 6-9-5-3 11.0 265.0 SILTY SAND (SM): medium dense, light brownt d , fine o me ium grained, moist 6-6-5 15 260 .................:..:.. _ � GW encountered at 18 ft. at time of drilling $ 8-7 $ te, w white, et Boring caved -in at 1 86 feet 20 after pulling augers 255 9 13-15-14 light brown '.'. 25 25.0 251.0 '.' (COASTAL PLAIN) Boring Terminated at 25 feet n T 250 Borehole backfilled on date drilled unless otherwise noted. Consistency/Relative Density based on correction factor for Manual hammer. SAMPLE TYPE N Split Spoon N-VALUE STANDARD PENETRATION RESISTANCE (AASHTO T-206) REC RECOVERY LL: LIQUID LIMIT M: NATURAL MOISTURE CONTENT % MOISTURE PERCENT NATURAL MOISTURE CONTENT RQD ROCK QUALITY DESIGNATION PL: PLASTIC LIMIT F: PERCENT PASSING NO. 200 SIEVE SZ GROUNDWATER LEVEL IN THE BOREHOLE AT TIME OF DRILLING UD UNDISTURBED PI: PLASTICITY INDEX 1 STABILIZED GROUNDWATER LEVEL Qu POCKET PENETROMETER UNCONFINED COMPRESSIVE STRENGTH Birmingham, AL • Auburn, AL • Huntsville, AL • Montgomery, AL • Mobile, AL • Tuscaloosa, AL Columbus, GA • Louisville, KY • Raleigh, NC • Dunn, NC • Jacksonville, NC Springdale, AR 9 Little Rock, AR 9 Tulsa, OK 9 Oklahoma City, OK 9 Durant, OK Geotechnical, Environmental, and Materials Engineers PROJECT NAME: Military Working Dog Facility @ SOTF PROJECT NUMBER: RD190229 DRILLING METHOD: Hollow Stem Auger EQUIPMENT USED: CME 550 ATV HAMMER TYPE: Manual BORING LOCATION: North West Corner Building Pad LOG OF BORING Designation: B-09 Sheet 1 of 1 610 Spring Branch Road Dunn, NC 28334 Office: (919) 292-2085 Fax: (205) 836-9007 www.BuildingAndEarth.com LOCATION: Fort Bragg, North Carolina DATE DRILLED: 4/29/19 WEATHER: 69 degrees, sunny ELEVATION: 279.0 DRILL CREW: J&L Drilling LOGGED BY: M. Lumpkin ❑ N-Value ❑ w H w 10 20 30 40 V A Qu (tsf) A z zz n Q O J J w 2 1 2 3 4 SOIL DESCRIPTION _ REMARKS 1 Atterberg Limits I a Q a 0- m p w < Z 20 40 60 80 Q l7 • % Moisture • w `^ 20 40 60 80 TOPSOIL: (Approximately 6") CLAYEY SAND (SC): loose, red -yellow, f me to 1 3-3-3-5 ...:..:..:..:..:..:.... .....:..:..:..:..:........ medium grained, moist 2 11-13-19-21 ..:..:..:.....:..:..:..:..:.. dense 275 5 3 13-13-11-1 medium dense Sample 4 6.0 273.0 LL: 23 SILTY SAND (SM): medium dense, light brown, 4 6-6-6-9 " :1 PL :22 PI: 1 fine to medium grained, moist M: 12.7% F: 21.8 % 270 5 8-9-11-10 ............................. 10 _X 6 7-9-10-12 :. ...................... ' 265 7 9-9-11 15 .................:..:.. Sample 8 LL:83 260 8 9-8-16 ....................... • PL. 36 PI: 47 19.4 259.6 :..' .'.' HIGH PLASTICITY CLAY (CH): very stiff, 20 M: 29.6% Boring caved -in at 20 feet F: 93.3% gray, moist after pulling augers 23.5 Q255.5 SILTY SAND (SM): dense, light brown, fine to 255 GW encountered at 23.5 ft. 9 11-n-16 medium grained, wet 25.0 254.0 :. at time of drilling g 25 (COASTAL PLAIN) Boring Terminated at 25 feet. ..:..:..:..:..:..:..:..:..:. Borehole backfilled on date drilled unless otherwise noted. Consistency/Relative Density 250 based on correction factor for Manual hammer. SAMPLE TYPE N Split Spoon N-VALUE STANDARD PENETRATION RESISTANCE (AASHTO T-206) REC RECOVERY LL: LIQUID LIMIT M: NATURAL MOISTURE CONTENT % MOISTURE PERCENT NATURAL MOISTURE CONTENT RQD ROCK QUALITY DESIGNATION PL: PLASTIC LIMIT F: PERCENT PASSING NO. 200 SIEVE SZ GROUNDWATER LEVEL IN THE BOREHOLE AT TIME OF DRILLING UD UNDISTURBED PI: PLASTICITY INDEX 1 STABILIZED GROUNDWATER LEVEL Qu POCKET PENETROMETER UNCONFINED COMPRESSIVE STRENGTH Birmingham, AL • Auburn, AL • Huntsville, AL • Montgomery, AL • Mobile, AL • Tuscaloosa, AL Columbus, GA • Louisville, KY • Raleigh, NC • Dunn, NC • Jacksonville, NC Springdale, AR 9 Little Rock, AR 9 Tulsa, OK 9 Oklahoma City, OK 9 Durant, OK Geotechnical, Environmental, and Materials Engineers PROJECT NAME: Military Working Dog Facility @ SOTF PROJECT NUMBER: RD190229 DRILLING METHOD: Hollow Stem Auger EQUIPMENT USED: CME 550 ATV HAMMER TYPE: Manual BORING LOCATION: North East Corner Building Pad LOG OF BORING Designation: B-10 Sheet 1 of 1 610 Spring Branch Road Dunn, NC 28334 Office: (919) 292-2085 Fax: (205) 836-9007 www.BuildingAndEarth.com LOCATION: Fort Bragg, North Carolina DATE DRILLED: 4/29/19 WEATHER: 69 degrees, sunny ELEVATION: 276.0 DRILL CREW: J&L Drilling LOGGED BY: M. Lumpkin ❑ N-Value ❑ w H w 10 20 30 40 V A Qu (tsf) A z zz n Q O J J w 2 1 2 3 4 SOIL DESCRIPTION _ REMARKS 1 Atterberg Limits I a Q a 0- m p w < Z 20 40 60 80 Q l7 • % Moisture • w `^ 20 40 60 80 TOPSOIL: (Approximately 6" d CLAYEY SAND (SC): loose, reddish brown, 275 1 1-2-5-10 ........ fine to medium grained, moist 2 13-18-21-23 ..:..:..:.....:..:..:..:. dense 5 3 12-17-22-2 reddish yellow 270 _X 4 8-12-13-14 ..:..: :..:..:..:..:..: medium dense 5 14-15-15-1 ..:..:. .:..:..:..:..:..:. dense 10 265 14.0 262.0 7 8-10-13 SILTY SAND (SM): medium dense, reddish 15 yellow, fine to medium grained, moist 260 8 11-15-15 20 Boring caved -in at 20 feet after fter pulling augers ..:..:..:..:..:..:..:..:. Sample 9 � LL: 21 GW encountered at 23.5 ft. X 9 7-9-11 p I: 18 wet at time of drilling 25 . . . . . . . . . M:21.9% 25.0 251.0.:: '. F: 16.1 % (COASTAL PLAIN) Boring Terminated at 25 feet. 250 Borehole backfilled on date drilled unless otherwise noted. Consistency/Relative Density based on correction factor for Manual hammer. SAMPLE TYPE N Split Spoon N-VALUE STANDARD PENETRATION RESISTANCE (AASHTO T-206) REC RECOVERY LL: LIQUID LIMIT M: NATURAL MOISTURE CONTENT % MOISTURE PERCENT NATURAL MOISTURE CONTENT RQD ROCK QUALITY DESIGNATION PL: PLASTIC LIMIT F: PERCENT PASSING NO. 200 SIEVE SZ GROUNDWATER LEVEL IN THE BOREHOLE AT TIME OF DRILLING UD UNDISTURBED PI: PLASTICITY INDEX 1 STABILIZED GROUNDWATER LEVEL Qu POCKET PENETROMETER UNCONFINED COMPRESSIVE STRENGTH Birmingham, AL • Auburn, AL • Huntsville, AL • Montgomery, AL • Mobile, AL • Tuscaloosa, AL Columbus, GA • Louisville, KY • Raleigh, NC • Dunn, NC • Jacksonville, NC Springdale, AR 9 Little Rock, AR 9 Tulsa, OK 9 Oklahoma City, OK 9 Durant, OK INFILTRATION DATA Page I A-12 Project Name: MWD Facility @ SOTF Client Name: Stantec Technician: Monique Lumpkin Test Constants Liquid Used: Municipal Water Test Location: 1-02 Geotechnical, Environmental, and Materials Engineers Depth of Water Table: Constants: Capacity LiquidContainers setting Rate cm'/cm Sight Tube 1 L n 27979-- Storage Tube 5L n 5. Flow rate use Project Number: RD190229 Report Number: 1 of Date: 5/2/2019 N/A Water Temp (IF): Depth of Observed Water d: 105 Hole Diameter: 2 rr or N/A inches 3 inches Start Saturation: 9:04 Water Head: 5.4 inches Hole Radius: 1.500 Hole Depth: 45 inches Test Data MEN Elapsed Time (hrs) A I Total Flow Readings Flow Kate in'/hr Conductivity Stabilized Kat in /hr Project Name: MWD Facility @ SOTF Client Name: Stantec Technician: Monique Lumpkin Test Constants Liquid Used: Municipal Water Test Location: 1-03 Geotechnical, Environmental, and Materials Engineers Depth of Water Table: Constants: Capacity LiquidContainers setting Rate cm'/cm Sight Tube 1 L n 27979-- Storage Tube 5L n 5. Flow rate use Project Number: RD190229 Report Number: 2 of Date: 5/2/2019 N/A Water Temp (IF): Depth of Observed Water d: 105 Hole Diameter: 2 cr or N/A inches 3 inches Start Saturation: 10:07 Water Head: 11.75 inches Hole Radius: 1.500 Hole Depth: 54 inches I-est Vata Date Time Elapsed Time (hrs) A Total Flow Readings Flow Kate in3/hr Conductivity Remarks: Weather conditions, etc. Reading Flow cm3 Ksat In/hr 1 S 5/2 10 :07 0.02 0.02 48.0 105 105 384.45 0.83 E 5/2 10:08 47.0 2 S 5/2 10 :08 0.02 0.03 47.0 105 105 384.45 0.83 E 5/2 10:09 46.0 3 S 5/2 10 :09 0.02 0.05 46.0 105 157.5 576.67 1.25 E 5/2 10 :10 44.5 4 S 5/2 10 :10 0.02 0.07 44.5 105 105 384.45 0.83 E 5/2 10:11 43.5 5 S 5/2 10 :11 0.02 0.08 43.5 105 157.5 576.67 1.25 E 5/2 10 :12 42.0 6 S 5/2 10 :12 0 02 0.10105 157.5 576.67 1.25 E 5/2 10:13 N 7E S 5/2 10 :13 0 02 0.12105 157.5 576.67 1.25 5/2 10:14 8 S E 9 S E 10 S E 11 S E 12 S E 13 S E 14 S Stabilized Ksatln/hr 1.25 1-03 SEASONAL HIGH WATER TABLE DATA Page I A-13 Southeastern Soil & Environmental Associates, Inc. P.O. Box 9321 Fayetteville, NC 28311 Phone/Fax (910) 822-4540 Email mike@southeasternsoil.com May 16, 2019 Mr. Kurt Miller, PE Building and Earth Sciences, LLP 610 Spring Branch Road Dunn, NC 28334 Re: Seasonal High -Water Table (SHWT) evaluation for potential stormwater retention/treatment areas, BES Project ## RD 1902129, MWD Facility @ SOTF off Lamont Road, Fort Bragg, North Carolina Dear Mr. Miller, An evaluation of soil properties on a portion of the aforementioned property has been conducted at your request. A map showing the test locations is attached. The purpose of the investigation was to determine seasonal soil water table depths for use in stormwater retention/treatment design. Soils at the test site appear to be most similar to the Blaney soil series (see attached boring logs). Three borings were advanced to a depth of at least 8.0 feet below the soil surface. Seasonal High -Water Table (SHWT) as determined by evidence of colors of chroma 2 or less was encountered at varying deaths (greater than 72 inches) below the existing ground surface. The attached chart shows each boring with SHWT depths. I trust this is the information you require at this time. Sincerely, XV, 4 6 5 � _0 Mike Eaker President SOIL ic"' 7r_L D. SOIUSITE EVALUATION • SOIL PHYSICAL ANALYSIS • LAND USE/SUBDIVISION PLANNING • WETLANDS GROUNDWATER DRAINAGE/MOUNDING • SURFACE/SUBSURFACE WASTE TREATMENT SYSTEMS, EVALUATION & DESIGN Southeastern Soil & Environmental Associates, Inc. P.O. Sox 9321 Fayetteville, NC 28311 Phone/Fax (910) 822-4540 Email mike@southeasternsoil.com SHWT depths, MWD Facility@SOTF, off Lamont Road, Fort Bragg, NC BORING SHWT DEPTH (inches) Observed Water inches I-01 >72 None I-02 106 86 I-03 84 72 Observed water is related to temporary lateral water (not SHWT). SOIL/SITE EVALUATION • SOIL PHYSICAL ANALYSIS • LAND USE/SUBDIVISION PLANNING • WETLANDS GROUNDWATER DRAINAGE/MOUNDING • SURFACE/SUBSURFACE WASTE TREATMENT SYSTEMS, EVALUATION & DESIGN Southeastern Soil & Environmental Associates, Inc. P.O. Box 9321 Fayetteville, NC 23311 Phone/Fax (910) 822-4540 Email mike@southeasternsoil.com Soil Boring Log (Boring 1-01), MWD Facility @ SOTF, off Lamont Road, Fort Bragg, NC This map unit consists of well drained soils on uplands_ These soils formed in loamy and sandy sediments. Slopes range from 2 to 8 percent. A - 0 to 2 inches; brown (IOYR 4/2) loamy sand; weak fine granular structure; very friable; many fine roots; abrupt smooth boundary. E - 2 to 14 inches; yellowish brown (IOYR 5/6) loamy sand; approximately 10 percent clean sand; single grained; loose; very friable; abrupt smooth boundary. Bt - 14 to 42 inches; yellowish red (5YR 5/8) sandy loam to sandy clay loam; moderate medium to weak fine subangular blocky structure; friable to firm; gradual wavy boundary. BC - 42 to 50 inches; mixed mottled yellowish red (5YR 5/8) and red (2.5YR 4/8) sandy clay loam to clay loam; weak fine subangular blocky structure; friable; gradual diffuse boundary. C - 50 to 72 inches; mixed mottled yellowish red (5YR 5/8) and red (2.5YR 4/8) sandy loam.; weak fine subangular blocky structure; very friable. SHWT > 72 inches SOIL/SITE EVALUATION • SOIL PHYSICAL ANALYSIS - LAND USE/SUBDIVISION PLANNING • WETLANDS GROUNDWATER DRAINAGE/MOUNDING • SURFACE/SUBSURFACE WASTE TREATMENT SYSTEMS, EVALUATION & DESIGN Southeastern Soil & Environmental Associates, Inc. P.O. Box 9321 Fayetteville, NC 28311 Phone/Fax (910) 822-4540 Email mike@southeasternsoll.com Soil Boring Log (Boring I-02), MWD Facility @ SOTF, off Lamont Road, Fort Bragg, NC This map unit consists of well drained soils on uplands. These soils formed in loamy and sandy sediments. Slopes range from 2 to 8 percent. A - 0 to 2 inches; brown (10YR 4/2) loamy sand; weak fine granular structure; very friable; many fine roots; abrupt smooth boundary. E - 2 to 34 inches; strong brown (7.5YR 5/6) loamy sand; single grained; loose; very friable; abrupt smooth boundary. Bt - 34 to 56 inches; yellowish red (5YR 4/6) sandy loam to sandy clay loam; moderate medium to weak fine subangular blocky structure; friable to firm; gradual wavy boundary. C 1 - 56 to 106 inches; strong brown (7.5YR 5/8) to yellowish brown (10YR 5/8) sandy loam; weak fine subangular blocky structure; friable; gradual diffuse boundary. C2 - 106 to 118 inches; yellowish brown (10YR 5/4) sandy loam; many medium prominent (10YR 7/2) mottles; massive structure; very friable. SHWT @ 106 inches (10YR 7/2) SOIL/SITE EVALUATION - SOIL PHYSICAL ANALYSIS - LAND USEISUBDIV00N PLANNING - WETLANDS GROUNDWATER DRAINAGE/MOUNDING - SURFACE/SUBSURFACE WASTE TREATMENT SYSTEMS, EVALUATION & DESIGN Southeastern Soil & Environmental Associates, Inc. P.O. Box 9321 Fayetteville, NC 28311 Phone/Fax (910) 822-4540 Email mike @southeasternsoil.com Soil Boring Log (Boring 1-03), MWD Facility @ SOTF, off Lamont Road, Fort Bragg, NC This map unit consists of well drained soils on uplands. These soils formed in loamy and sandy sediments. Slopes range from 2 to 8 percent. A - 0 to 10 inches; dark gray (IOYR 4/1) loamy sand; weak fine granular structure; very friable; many fine roots; abrupt smooth boundary. E - 10 to 49 inches; strong brown (7.5YR 5/6) to yellowish brown (10YR 5/6) coarse sand; single grained; loose; very friable; gradual diffuse smooth boundary. Bt - 49 to 84 inches; strong brown (7.5YR 5/6) to yellowish brown (IOYR 5/6) sandy loam; weak fine granular structure; very friable; gradual diffuse boundary. C - 84 to 98 inches; gray (IOYR 5/1) coarse sand; single grained; loose; very friable. SHWT @ 84 inches (10YR 5/1) SOIUSITE EVALUATION • SOIL PHYSICAL ANALYSIS • LAND USE/SUBDIVISION PLANNING • WETLANDS GROUNDWATER DRAINAGE/MOUNDING • SURFACE/SUBSURFACE WASTE TREATMENT SYSTEMS, EVALUATION & DESIGN fM 60 r n m 0 A 0 w 0 ,1 ro �-Ln n l�1 LOU' .ate-, ryCb >TI �.%+7'p f, ocrk r ; cn- jp > O E7 - �y t M14 m +� M :# a OCVI r^� � N as p' N w 5s a LABORATORY TEST PROCEDURES A 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 D 1140) 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 D 7557) 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 D 7883) 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. ample Boring or Test Pit SDh e t Location a p) LL PL pl % Passing Moisture #200 Sieve Content (%) 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. Schmertmann Settlement Analysis Job No.: RD190229 Job Name: Military Working Dog Training Facility Calculations based on Boring No: Footing Size, B 6 ft Bearing Pressure,p 2000 psf Soil Unit Wt. 115 pcf Bearing Depth, Fd 2 ft B-06 (Worst Case Scenario) I Notes C1= 0.94 C2 = 1.60 t = 100 years Settlement Estimate Using N for the layer Top of Layer (ft) *Btm of Layer (ft) dz (inches) N count (bpf) Es (tsf) Zc (inches) Zc (ft) Iz Iz*dz/Es (in/tsf) 1 2 12 5 4 20 18 1.5 -0.100 -0.060 2 3 12 6 4 24 30 2.5 0.100 0.050 3 4 12 9 4 36 42 3.5 0.300 0.100 4 12 96 26 4 104 96 8 0.400 0.369 Sum = 0.459 Total Estimated Settlement by Schmertmann = 0.69 in Estimated Potential Settlement = 1 0.35 in (Schmertmann is typically reduced by a factor of 2) Bearing Capacity of Shallow Foundations Using Bowles' Equations - Foundation Analysis and Design, 5 ed. For footing (width, greater than 4 ft.: l4) l8 B 11z J kips QQ = K = allowable soil bearing capacity, in i z Qa = \4� \7 7 1� = 2.05 ksf = 2,050 psf z� 2,000 psf allowable bearing capacity 1.11 where: N=7 K = 1.11 B=6ft. D=2ft. May 14, 2019 Project No R-2019-137-001 Mr. Kurt Miller Building & Earth Sciences, LLC 610 Spring Branch Road Dunn, NC 28334 eotechnics geotechnicaI & geosynthetit testing Transmittal Laboratory Test Results MWD Facility - Fort Bracm, 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. /4.;. "l* � - Michael P. Smith Regional Manager We understand that you have a choice in your laboratory services and we thank you for choosing Geotechnics. DCN. Data Tranandttal Letter Date: I128105 Rev.: I 2200 Westinghouse Blvd., Suite 103 • Raleigh, NC 27604 • Phone (919) 876-0405 • Fax (919) 876-0460 • www.geotechnics.net eotechnics geotechnical & geosynthetic testing SINGLE POINT CBR TEST ASTM D 1883-16 Client Building & Earth Sciences, Inc. Boring No. B-08 Client Reference MWD Facility - Fort Brag, NC Depth(ft.) 1-5 Project No. R-2019-137-001 Sample No. 19-0091-01 Lab ID R-2019-137-001-001 Visual Description BROWN SAND Test Type MODIFIED Molding Method C Density Before After Mold ID R433 Measurement Soaking Soaking Wt. of Mold (gm.) 4225.4 Wt. Mold & WS (gm.) 8526.1 8592.9 Mold Volume (cc) 2121 Wt. WS (gm.) 4300.7 4368 Surcharge (lbs.) 10 Sample Volume (cc) 2121 2121 Piston Area (in2) 3 Wet Density (gm./cc) 2.03 2.06 Sample Height 4.58 Wet Density (pcf) 126.5 128.5 Sample Conditions Soaked Blows per Layer 60 Dry Density (pcf) 115.3 115.2 Dry Density (gm./cc) 1.85 1.85 Water As Begining After Before After Top 1" Contents Rec'd Compaction Compaction Soaking Soaking After Soak Tare No. 851 NA SS-1 AF-05 SS-6 Wt. of T+WS (gm.) 289.62 NA 465.44 1218.49 698.37 Wt. of T+DS (gm.) 282.91 NA 433.08 1116.18 630.07 Wt of Tare (gm.) 139.89 NA 100.27 228.44 100.9 Moisture Content(%) 4.7 NA 9.7 9.7 11.5 12.9 Piston Penetration Displacement Load Stress Swell (in.) (lbs.) (psi.) Measurement 0 9.41 3.1 Elapsed Dial Percent 0.025 196.31 65.4 Time Gauge Swell 0.050 444.35 148.1 (hrs) (Div) 0.075 682.74 227.6 0.100 939.00 313.0 0.00 131 0.00% 0.125 1135.76 378.6 20.50 131 0.00% 0.150 1268.57 422.9 98.00 132 0.02% 0.175 1347.24 449.1 0.200 1371.65 457.2 0.250 1357.24 452.4 0.300 1342.22 447.4 0.350 1329.76 443.3 0.400 1325.44 441.8 0.450 1332.84 444.3 0.500 1303.39 434.5 0.550 1271.68 423.9 0.600 1266.75 422.3 1Division = 0.001 in. Tested By SFS Date 519119 Checked By GEM Date 5/14/19 page 1 of 2 DCN: CT-S27 REVSION: 5 DATE: 11/15/05 Z: 12019 PROJECTSWILDING & EARTH12019-137 B&E - MWD FACILITYI[2019-137-001-001 1CBR TESTNET.xis]SHEET1 2200 Westinghouse Blvd., Suite 103 • Raleigh, NC 27604 • Phone (919) 876-0405 • Fax (919) 876-0460 • www.geotechnics.net Client Client Reference Project No. Lab ID 450.0 400.0 350.0 a 300.0 a a L 250.0 c 0 L c 200.0 N a 150.0 M 1.1919 eotechnics geotechnical & geosynthetic testing SINGLE POINT CBR TEST ASTM D 1883-16 Building & Earth Sciences, Inc. Boring No. MWD Facility - Fort Brag, NC Depth(ft.) R-2019-137-001 Sample No. R-2019-137-001-001 Visual Description B-08 1-5 19-0091-01 BROWN SAND CBR VALUE (0.1") 31.3 % CBR VALUE (0.2") 30.5 % CORRECTED CBR VALUE (0.1") 32.8 % CORRECTED CBR VALUE (0.2") 30.5 % Penetration Stress vs. Penetration 1 0.0 0.000 0.100 0.200 0.300 0.400 0.500 0.600 0.700 Penetration (in) Tested By SFS Date 519119 Approved By MPS Date 5/14/19 page 2 of 2 DCN: CT-S27 REVSION: 5 DATE: 11/15/05 Z12019 PROJECTSIBUILDING & EARTH12019-137 B&E - MWD FACILITY[2019-137-001-001 1CBR TESTNET.xls]SHEET1 2200 Westinghouse Blvd., Suite 103 • Raleigh, NC 27604 • Phone (919) 876-0405 • Fax (919) 876-0460 • www.geotechnics.net ±U2e#aor ====-I m I = § & < g m /�ƒ0)co & 2 y - } - < \ c > / Cl) GGGGGG�� ®eeeee>= _ � _ _ Ln o )�n®2at § /0F %a\ E _ / k7 40- � \ �\ 3 \ � |C) \ J ,o 0 0 W�RmKwmmmo IN IT o 3 3 /@ S S a J J = §> g g w \ j \ 2 2 0 0 LLJ £ kGS \ \ \ \ /mCL j \ \ _ E c \ c � 5 E § ƒ �� 0 / S // S k 2_ 4 k 0 \ 0 \ G = E /e z a a = _ § _ ƒ / / \ 3 3 Cl) 0)k = \ co co -0k / J 3 £ \ / / 7 << z / e Q Q Cl) < 0 _ 0LO �- =c0) a22/ \\0 @ &' c \ a o > g 5*&% E E m 2 < }\a 5 j#235c�G > § g < z / w = /��_ Cl) % e 3i e < \ c > / G G G G G G�� ®eeeee>= _ _ _ D o t 0 %� 3 0 LL § /@ % a » � ® a 0 E _ / <-F 40- 3 \ � | \ 2 , o 0 .or_jmmmr_- ■ � o E o / § / 7 } _/ / \k / Cl) _ E e \ § E % r \ E \ \ \ £ \ ° \ � e \ \ \ \ 1- IIJ = _ _ _ |\ F}0 �- =c0) a22/ \\§/ @ &' c \ a o > g 5*&% E E m 2 < }\a 5 ±U2e#aor ====-I m \/\< C) \ / \ � \ \ \ \ G G G G G G�� ®eeeee>= = D o t - c e- �n(iƒ\ (/ ®<_0 & cam/ (3) m Jo- £ \ 3 \ -i |) \ J ,o 0 0 I� \ } �/ ) ±� £ _ Cl) Cl) Cl) E E e z \ § % r \ c E \ 5 = = = J 0 k q / - Co \ < # \ \ � e rITITIT w — CO a 1- CO 1- IT LO wo== a=ae S r r r rwww »corm rwww \- =0000 =0000 =0000 =moor amfa ƒ / /f 2! 2 LU Cl) 0 _ 100 90 80 70 iY W 60 Z LL Z 50 W U IY W 40 0_ 30 20 10 Particle Size Distribution Report _ o00 77\ M N \` � 3k 3k 3k 3k 3k 3k 3k 3k 10 1 0.1 0.01 0.001 % +3" % Gravel % Sand % Fines Coarse Fine Coarse Medium Fine Silt 0.0 0.1 0.1 1.6 40.7 45.1 12.4 SIEVE SIZE PERCENT FINER SPEC." PERCENT PASS? (X=NO) 1 100.0 .75 99.9 .375 99.9 #4 99.8 #10 98.2 #20 85.1 #40 57.5 #60 32.3 #140 15.2 #200 12.4 (no specification provided) Location: B-08 Sample Number: 19-0091-01 Depth: 1-5' Material Description Brown silty sand Atterberg Limits PL= NP LL= NP P1= NP 0 10 20 30 40 50 60 70 80 90 100 Coefficients D90= 1.0375 D85= 0.8482 D60= 0.4475 D50= 0.3661 D30= 0.2349 D15= 0.1032 Dip= CU= Cc= Classification USCS= SM AASHTO= A-2-4(0) Remarks As -received water content=5.3% Date: 05-08-19 Client: Stantec, Inc. BUILDING & EARTH Project: MWD Facility (GEO) Fort Bragg, NC Project No: RD190229 Figure Checked By: John Dailly COMPACTION TEST REPORT 126 124 9.3% 122.5 c 122 U Q T .N C N ZAV for p` Sp.G. _ 120 2.65 118 116 2 4 6 8 10 12 14 Water content, % Test specification: ASTM D 1557-12 Method A Modified Elev/ Depth Classification Nat. Moist. Sp.G. LL PI % > #4 % < No.200 USCS AASHTO 1-5' SM A-2-4(0) 5.3 NP NP 0.2 12.4 TEST RESULTS MATERIAL DESCRIPTION Maximum dry density = 122.5 pcf Optimum moisture = 9.3 % Brown silty sand Project No. RD190229 Client: Stantec, Inc. Project: MWD Facility (GEO) Fort Bragg, NC Date: 05-08-19 O Location: B-08 Sample Number: 19-0091-01 Remarks: Figure BUILDING & EARTH Checked By: John Dailly r- Geotechnical-Engineering Report --) Geotechnical Services Are Performed for Specific Purposes, Persons, and Projects Geotechnical engineers structure their services to meet the specific needs of their clients. A geotechnical-engineering study conducted for a civil engineer may not fulfill the needs of a constructor a construction contractor or even another civil engineer. Because each geotechnical- engineering study is unique, each geotechnical-engineering report is unique, prepared solely for the client. No one except you should rely on this geotechnical-engineering report without first conferring with the geotechnical engineer who prepared it. And no one — not even you — should apply this report for any purpose or project except the one originally contemplated. Read the Full Report Serious problems have occurred because those relying on a geotechnical-engineering report did not read it all. Do not rely on an executive summary. Do not read selected elements only. Geotechnical Engineers Base Each Report on a Unique Set of Project -Specific Factors Geotechnical engineers consider many unique, project -specific factors when establishing the scope of a study. Typical factors include: the client's goals, objectives, and risk -management preferences; the general nature of the structure involved, its size, and configuration; the location of the structure on the site; and other planned or existing site improvements, such as access roads, parking lots, and underground utilities. Unless the geotechnical engineer who conducted the study specifically indicates otherwise, do not rely on a geotechnical-engineering report that was: • not prepared for you; • not prepared for your project; • not prepared for the specific site explored; or • completed before important project changes were made. Typical changes that can erode the reliability of an existing geotechnical-engineering report include those that affect: • the function of the proposed structure, as when it's changed from a parking garage to an office building, or from a light - industrial plant to a refrigerated warehouse; • the elevation, configuration, location, orientation, or weight of the proposed structure; • the composition of the design team; or • project ownership. As a general rule, always inform your geotechnical engineer of project changes —even minor ones —and request an assessment of their impact. Geotechnical engineers cannot accept responsibility or liability for problems that occur because their reports do not consider developments of which they were not informed. Subsurface Conditions Can Change A geotechnical-engineering report is based on conditions that existed at the time the geotechnical engineer performed the study. Do not rely on a geotechnical-engineering report whose adequacy may have been affected by: the passage of time; man-made events, such as construction on or adjacent to the site; or natural events, such as floods, droughts, earthquakes, or groundwater fluctuations. Contact the geotechnical engineer before applying this report to determine if it is still reliable. A minor amount of additional testing or analysis could prevent major problems. Most Geotechnical Findings Are Professional Opinions Site exploration identifies subsurface conditions only at those points where subsurface tests are conducted or samples are taken. Geotechnical engineers review field and laboratory data and then apply their professional judgment to render an opinion about subsurface conditions throughout the site. Actual subsurface conditions may differ — sometimes significantly — from those indicated in your report. Retaining the geotechnical engineer who developed your report to provide geotechnical-construction observation is the most effective method of managing the risks associated with unanticipated conditions. A Report's Recommendations Are Not Final Do not overrely on the confirmation -dependent recommendations included in your report. Confirmation - dependent recommendations are not final, because geotechnical engineers develop them principally from judgment and opinion. Geotechnical engineers can finalize their recommendations only by observing actual subsurface conditions revealed during construction. The geotechnical engineer who developed your report cannot assume responsibility or liability for the report's confirmation -dependent recommendations if that engineer does not perform the geotechnical-construction observation required to confirm the recommendations' applicability. A Geotechnical-Engineering Report Is Subject to Misinterpretation Other design -team members' misinterpretation of geotechnical-engineering reports has resulted in costly Page I A-17 problems. Confront that risk by having your geotechnical engineer confer with appropriate members of the design team after submitting the report. Also retain your geotechnical engineer to review pertinent elements of the design team's plans and specifications. Constructors can also misinterpret a geotechnical-engineering report. Confront that risk by having your geotechnical engineer participate in prebid and preconstruction conferences, and by providing geotechnical construction observation. Do Not Redraw the Engineer's Logs Geotechnical engineers prepare final boring and testing logs based upon their interpretation of field logs and laboratory data. To prevent errors or omissions, the logs included in a geotechnical-engineering report should never be redrawn for inclusion in architectural or other design drawings. Only photographic or electronic reproduction is acceptable, but recognize that separating logs from the report can elevate risk. Give Constructors a Complete Report and Guidance Some owners and design professionals mistakenly believe they can make constructors liable for unanticipated subsurface conditions by limiting what they provide for bid preparation. To help prevent costly problems, give constructors the complete geotechnical-engineering report, but preface it with a clearly written letter of transmittal. In that letter, advise constructors that the report was not prepared for purposes of bid development and that the report's accuracy is limited; encourage them to confer with the geotechnical engineer who prepared the report (a modest fee may be required) and/ or to conduct additional study to obtain the specific types of information they need or prefer. A prebid conference can also be valuable. Be sure constructors have sufficient time to perform additional study. Only then might you be in a position to give constructors the best information available to you, while requiring them to at least share some of the financial responsibilities stemming from unanticipated conditions. Read Responsibility Provisions Closely Some clients, design professionals, and constructors fail to recognize that geotechnical engineering is far less exact than other engineering disciplines. This lack of understanding has created unrealistic expectations that have led to disappointments, claims, and disputes. To help reduce the risk of such outcomes, geotechnical engineers commonly include a variety of explanatory provisions in their reports. Sometimes labeled "limitations," many of these provisions indicate where geotechnical engineers' responsibilities begin and end, to help others recognize their own responsibilities and risks. Read these provisions closely. Ask questions. Your geotechnical engineer should respond fully and frankly. Environmental Concerns Are Not Covered The equipment, techniques, and personnel used to perform an environmental study differ significantly from those used to perform ageotechnical study. For that reason, a geotechnical- engineering report does not usually relate any environmental findings, conclusions, or recommendations; e.g., about the likelihood of encountering underground storage tanks or regulated contaminants. Unanticipated environmental problems have led to numerous project failures. If you have not yet obtained your own environmental information, ask your geotechnical consultant for risk -management guidance. Do not rely on an environmental report prepared for someone else. Obtain Professional Assistance To Deal with Mold Diverse strategies can be applied during building design, construction, operation, and maintenance to prevent significant amounts of mold from growing on indoor surfaces. To be effective, all such strategies should be devised for the express purpose of mold prevention, integrated into a comprehensive plan, and executed with diligent oversight by a professional mold -prevention consultant. Because just a small amount of water or moisture can lead to the development of severe mold infestations, many mold- prevention strategies focus on keeping building surfaces dry. While groundwater, water infiltration, and similar issues may have been addressed as part of the geotechnical- engineering study whose findings are conveyed in this report, the geotechnical engineer in charge of this project is not a mold prevention consultant; none of the services performed in connection with the geotechnical engineer's study were designed or conducted for the purpose of mold prevention. Proper implementation of the recommendations conveyed in this report will not of itself be sufficient to prevent mold from growing in or on the structure involved. Rely, on Your GBC-Member Geotechnical Engineer for Additional Assistance Membership in the Geotechnical Business Council of the Geoprofessional Business Association exposes geotechnical engineers to a wide array of risk -confrontation techniques that can be of genuine benefit for everyone involved with a construction project. Confer with you GBC-Member geotechnical engineer for more information. FTMWA GEOTECHNICAL BUSINESS COUNCIL ,GH4C1&= ofdw GeoprofessionWBusinwAs dadon 8811 Colesville Road/Suite G106, Silver Spring, MD 20910 Telephone.301/565-2733 Facsimile:301/589-2017 e-mail; info@geoprofessional.org www.geoprofessionatorg Copyright 201: by Geoprofessional Business Association (GBA). Duplication, reproduction, or copying of this document, or its contents, in whole or in part, by any means whatsoever, is strictly prohibited, except with GBA's specific written permission. Excerpting, quoting, or otherwise extracting wording from this document is permitted only with the express written permission of GBA, and only for purposes of scholarly research or book review- Only members of GBA may use this document as a complement to or as an element of a geotechnical-engineering report. Any other firm, individual, or other entity that so uses this document without being a CBA member could be commiting negligent or intentional (fraudulent) misrepresentation. Page I A-18