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Home My WebLink AboutTelecommunications Reliability Facility - Fort Bragg - (1) Telecommunications Reliability Facility Geotechnical FinalSUBSURFACE EXPLORATION AND GEOTECHNICAL RECOMMENDATIONS REPORT Telecommunications Reliability Facility, FY 17, PN 81894 Fort Bragg, North Carolina By: Chris Norton, P.E., Civil Engineer Geotechnical and Dam Safety Section U.S. Army Corps of Engineers, Wilmington District December 2017 This report was prepared by the Wilmington District of the U.S. Army Corps of Engineers. The initials or signatures and registration designation of individuals appear on these documents within the scope of their employment as required by Engineer Regulation 1110-1-8152 Date: 21 December 2017 _______________________________ Christopher A. Norton, P.E. Civil Engineer CESAW-ECP-EG Geotechnical and Dam Safety Section _______________________________ Jason Inskeep, E.I. Civil Engineer CESAW-ECP-EG Geotechnical and Dam Safety Section NORTON.CHRIST OPHER.ALLEN.14 58028903 Digitally signed by NORTON.CHRISTOPHER.ALLEN.1458028903 DN: c=US, o=U.S. Government, ou=DoD, ou=PKI, ou=USA, cn=NORTON.CHRISTOPHER.ALLEN.1458028 903 Date: 2017.12.21 12:42:29 -05'00' INSKEEP.JASON.ALEX ANDER.1288384173 Digitally signed by INSKEEP.JASON.ALEXANDER.1288384173 DN: c=US, o=U.S. Government, ou=DoD, ou=PKI, ou=USA, cn=INSKEEP.JASON.ALEXANDER.1288384173 Date: 2017.12.21 12:44:08 -05'00' TABLE OF CONTENTS 1. PURPOSE .................................................................................................................................................. 1 2. QUALIFICATION OF REPORT ..................................................................................................................... 1 3. PROJECT DESCRIPTION ............................................................................................................................. 1 4. EXPLORATION PROCEDURES .................................................................................................................... 1 Site Reconnaissance ................................................................................................................................. 1 Soil Borings and DCP Testing ................................................................................................................... 2 Soil Infiltration Testing ............................................................................................................................. 2 5. SITE AND SUBSURFACE CONDITIONS ....................................................................................................... 3 Site Conditions ......................................................................................................................................... 3 Regional and Site Geology ....................................................................................................................... 3 Subsurface Conditions ............................................................................................................................. 4 Groundwater Conditions ......................................................................................................................... 4 6. ENGINEERING EVALUATIONS AND RECOMMENDATIONS ....................................................................... 5 General .................................................................................................................................................... 5 Geotechnical Investigations ..................................................................................................................... 5 Excavation, Grading, and Fill ................................................................................................................... 5 Damp-proofing and Water-proofing ....................................................................................................... 5 Presumptive Load-Bearing Values of Soils ............................................................................................... 5 Foundations ............................................................................................................................................. 6 Shallow Foundations ................................................................................................................................ 6 Frost Susceptibility ................................................................................................................................... 6 Seismic Site Classification ........................................................................................................................ 7 Liquefaction ............................................................................................................................................. 7 ATTACHMENT A: 35% Design Submittal – Site Plan ATTACHMENT B: Boring, DCP, and Infiltration Testing Location Plan ATTACHMENT C: Soil Test Boring Logs ATTACHMENT D: CBR and UBC Tabulations ATTACHMENT E: Infiltration Test Tabulations ATTACHMENT F: Michigan Method – Soil Infiltration Testing 1. PURPOSE The purpose of this “Subsurface Exploration and Geotechnical Recommendations Report” is to present the findings and evaluation of subsurface data collected on 25 and 26 September, 2017, at the proposed Telecommunications Reliability Facility site. This report provides a general overview of the site and subsurface conditions encountered within the proposed footprint of the components in the 35 percent design submittal, which was provided to the Wilmington District on 13 July, 2017 (Attachment A). The proposed components consist of two infiltration basins and a one-story building. The building will be founded on a shallow slab-on-grade concrete foundation. Preliminary engineering evaluations and recommendations are also provided with respect to the geotechnical design and construction of the project. 2. QUALIFICATION OF REPORT The subsurface investigation was conducted to determine soil and groundwater conditions and was not intended to serve as an assessment of site wetlands,environmental, or contaminant conditions. The Architect-Engineer’s (A-E) team should include a Registered Professional Engineer, henceforth referred to as Engineer, with an appropriate amount of experience in geotechnical engineering design. The Engineer should be able to interpret this report, make a determination if a more extensive subsurface investigation is required, and develop foundation and earthwork design parameters. Any additional subsurface investigations and laboratory analyses conducted to better characterize the site and to develop the final design should be performed under the direction of an Engineer with an appropriate amount of experience in geotechnical engineering design. 3. PROJECT DESCRIPTION The proposed 35 percent design site layout plan can be seen in Attachment A, and consists of a single story concrete slab-on-grade building and two infiltration basins. The project is located within the southwest corner of the Special Operations Training Facility (SOTF) compound, just west of the Antenna Field. The proposed building location is an open grassy area between an existing barbed-wire fence to the east and the existing wood-line to the west. A gravel parking lot will be constructed along the southern side of the building, adjacent to the sidewalk. Two infiltration basins will be used for drainage, one near the northwest corner of the proposed building, and one southeast of the proposed building on the other side of the existing barbed-wire fence. A new security fence will be placed around the proposed building connecting it to the rest of the SOTF compound. Please review Attachment A for more details. 4. EXPLORATION PROCEDURES Site Reconnaissance Before the field investigation was performed, the proposed project site(s) and surrounding areas were visually inspected. The observations were used in planning the subsurface exploration, in determining areas of special interest, and in relating site conditions to known geologic conditions in the area. 1 Soil Borings and DCP Testing Subsurface conditions within the proposed building footprint were evaluated by five soil test Hand Auger (HA) borings labeled TEL-HA-17-01 through TEL-HA-17-05, and five companion Dynamic Cone Penetrometer (DCP) tests labeled TEL-DCP-17-01 through TEL-DCP-17-05. The borings were taken to a depth of approximately 7 feet Below Ground Surface (BGS), and the companion DCP tests were conducted to approximately 6.5 feet BGS. The HA borings and DCP testing were conducted to visually classify materials and to estimate engineering properties of the material, respectively. The classifications and engineering properties may be used in the evaluation and design of the proposed project. North Carolina State Plane Coordinates (NAD83 - U.S. Survey Feet) and elevations (NAVD88) of borings/companion DCP tests are indicated in Attachments B and C. State Plane Coordinates were established by a hand-held mapping grade GPS unit, and should be considered approximate. The HA borings were conducted in accordance with American Standard Test Method (ASTM) D1452, with equipment consisting of 5-foot steel rod sections and a 3.25-inch outside diameter steel barrel sampler. The DCP used for this investigation conforms to ASTM D6951, and consists of a 17.6-lb hammer that is dropped (free fall) a distance of 22.6 inches, impacting an anvil attached to the drive rod. The impact drives a 60° cone, attached to the end of the drive rod, into the material of interest. One impact is equivalent to one “blow count”. The number of blow counts per inch of penetration is recorded (number blow counts)/(inch of penetration). The blow counts are then used to calculate the California Bearing Ratio (CBR) for each inch of strata. The CBR is a comparison of the penetration resistance of a soil to the penetration into a standard crushed stone sample. Penetration resistance, when properly evaluated, is an index of the soil’s strength, density, and foundation support capability. Equations used to calculate the CBR are described in ASTM D6951. A correlation between the CBR and Ultimate Bearing Capacity (UBC) has been developed by the U.S. Army Corps of Engineers (USACE). The derivation of the correlation equation can be found in the research paper titled “Evaluation of In-Situ Pavement Layers with the Dynamic Cone Penetrometer (DCP)”, Jeb S. Tingle, et al. The Engineer should note that the UBC equation does not account for the Ground Water Table (GWT). Soil classifications are shown on the soil test boring logs in Attachment C, and were determined in the field by an Engineer. Soil samples were classified in accordance with ASTM D2488 (Visual-Manual Procedure for Descriptions of Soils). The soil descriptions and classifications are based on visual examination only; no lab analyses were conducted. CBR and UBC tabulations are included in Attachment D of this report. Soil Infiltration Testing Soil infiltration tests were performed at two locations (TEL-INF-17-1 and TEL-INF-17-2). Boring logs for these tests are located in Attachment C. These locations were selected based on the A-E’s proposed location of the infiltration basins. Testing was conducted using a modified version of the “Percolation Test”; the percolation test procedure “Michigan Method” can be seen in Attachment F. A boring for each test was conducted by hand auger to the approximate elevation of the basin invert. The invert elevation for both basins was provided by the A-E, and required a 4 foot boring for TEL-INF-17-1 and a 5 foot boring for TEL-INF-17-2. For general awareness, topographic contour lines and a typical drawing of the basins can be seen in Attachment A. The testing varied from the procedure in Attachment F by utilization of a 3-inch diameter 2 PVC pipe that was inserted to the bottom of the bored hole and approximately 6 inches below the basin invert. The primary purposes of the pipe was to prevent hole collapse and limit horizontal infiltration as much as possible. After the PVC pipe was inserted, a 6 inch layer of pea gravel was placed at the bottom of the pipe to increase soil stability. By inserting the pipe 6 inches below the basin invert, we made the assumption that the rates recorded were vertical infiltration rates, i.e. the water level outside of the PVC pipe remained at the bottom of the pipe, thus eliminating horizontal infiltration. In reality, this assumption is not entirely correct since more than likely the actual outside water level was at some point above the bottom of the pipe, thus some horizontal infiltration is inevitable. As a worst case scenario, a scenario in which the water level inside the PVC pipe and the water level outside the pipe came to equilibrium thus mimicking the actual percolation test, we applied the percolation test reduction factor seen in Attachment F to the assumed vertical infiltration rates. In addition, it was assumed that the soil at the invert of the basin was undisturbed, and therefore the measured infiltration rates are those of the undisturbed soil. In reality, the soil structure was disturbed when the PVC pipe was inserted 6 inches below the basin invert. The tests were initiated by filling water to the top of pipe, then measuring from the top of pipe to the water surface at fifteen (15) minute intervals for four hours, adding water as needed. The drop in water surface over the timed interval was used to determine the rates in inches per hour. The tip of the pipe was considered to be in the vadose zone and did not intercept the GWT for the tests. The depth of the existing GWT was not identified during the site investigation and it is assumed that there are no confining soil layers that restrict flow from the proposed infiltration basins to the GWT. 5. SITE AND SUBSURFACE CONDITIONS Site Conditions Significant grading and earthwork will be needed to construct the project. At the time of investigation, the area of the new building was open and grassy and located between a chain-link barbed wire fence along the western portion of the SOTF compound, and a dense stand of pine trees to the east of the proposed building. The area had a moderate slope from the wood-line downhill to the fence. The surface soils consisted of a loose Silty Sand (SM) with a high infiltration capacity. The two proposed infiltration basins are located to the northwest and southeast of the proposed building. The northwest basin is within the wood-line, and will require tree removal to construct. The surface soils within the proposed area of this basin consist of loose SM with a high infiltration capacity. The southeast basin is within the fenced part of the SOTF compound. The ground surface within the proposed area of this basin consists of moderately compact SM with a high infiltration capacity. No abnormal site conditions were noted. Regional and Site Geology Fort Bragg is situated in the “sand hills” area of the Coastal Plain physiographic province of North Carolina. The Coastal Plain extends westward from the Atlantic Ocean to the Fall Line, a distance of about 130 miles. The Fall Line is the boundary between the Coastal Plain and the Piedmont physiographic provinces. 3 Geologic units in the area, ranging from oldest to youngest, include the Carolina Slate Belt rocks, which are the basement rocks, the Cape Fear Formation, and the Middendorf Formation. The Cape Fear and Middendorf Formations overlie the basement rock and are part of the generally southeastward-dipping and thickening wedge of sediments that constitute the Atlantic Coastal Plain deposits. The Middendorf Formation is exposed at land surface throughout the area. The formation is composed of tan, cross- bedded, medium and fine-grained, micaceous quartz sand and clayey sand interbedded with clay or sandy clay lenses or layers. Layers of hematite-cemented sandstone occur locally throughout the Middendorf Formation as do thin layers of hard kaolin and kaolin-cemented sandstone. Below the water table, these units are generally friable or plastic. In places, the Middendorf Formation is mottled orange, gray, and tan color with streaks and laminae of red and purple hematite and manganese oxide stains. Subsurface Conditions Soil test borings TEL-HA-17-1 through TEL-HA-17-5 indicate a stratigraphy consisting of Poorly Graded Sand (SP), Poorly Graded Sand with Silt (SP-SM), Poorly Graded Sand with Clay (SP-SC), and Clayey Sand (SC). Lean Clay (CL), and Fat Clay (CH) were not encountered during this investigation. Soil test boring logs are located in Attachment C. DCP tests TEL-DCP-17-1 through TEL-DCP-17-5 indicate a range of CBRs and associated UBCs from 1.7 percent (762 psf) to 16.9 percent (3578 psf), as indicated in Attachment D, CBR and UBC Tabulations. Lower strength material was encountered within the middle portion of all tests. DCP tests TEL-DCP-17-1 and TEL-DCP-17-2 indicate particularly low strength soils (less than 1000-psf) below a depth of 25 inches. Please refer to Attachment D for a detailed profile of CBR and UBC values for all tests. Infiltration test data can be seen in Attachment E. Testing indicates a minimum infiltration rate of approximately 1.49 inches per hour for TEL-INF-17-1 and 1.43 inches per hour for TEL-INF-17-2. Attachment E can be reviewed for detailed infiltration testing data. The above subsurface description is of a generalized nature to highlight the major subsurface stratification features and material characteristics. The soil test boring logs should be reviewed for specific information at individual boring locations. The stratifications shown on the soil test boring logs represent the conditions at the actual boring locations only. Variations should be expected between boring locations. The stratification lines shown on the soil test boring logs represent the approximate boundaries between the subsurface materials; the actual transitions are typically more gradual. Groundwater Conditions Neither the apparent GWT nor the Seasonal High Water Table (SHWT) were located at any point during this site investigation. Due to the prevalence of SC and SP-SC at the project site and the general area, perched water conditions could be encountered before, during, or after construction. A perched-water condition occurs when water seeping downward is blocked by a low permeability soil layer, such as SC or CL, and saturates the more permeable soil above it. The true GWT can be several to many feet below the perched-water level. It should be noted that the GWT may vary during periods of prolonged drought and excessive rainfall, as well as seasonally. Therefore, fluctuations in the GWT should be anticipated with changing climatic and rainfall conditions. 4 6. ENGINEERING EVALUATIONS AND RECOMMENDATIONS General Chapters 16, 17, 18, and 33 of the International Building Code (IBC) 2012, adopted and modified by the Unified Facilities Criteria (UFC) 3-220-01 of 2012, are the primary design standards referenced for these recommendations. The following evaluations and recommendations are based on the information available on the proposed structures, observations made at the project site, interpretation of the data obtained from the soil test borings and associated DCP testing, and previous experience with soils and subsurface conditions similar to those encountered at the site. Geotechnical Investigations A preliminary geotechnical investigation was conducted at the proposed project site by the Wilmington District, and the results are discussed in this report. This investigation may not meet all requirements set forth in Section 1803, IBC 2012, adopted and modified by Section 2-3.3, UFC 3-220-01, and this report should be evaluated accordingly. Excavation, Grading, and Fill It is recommended that the Engineer adhere to the requirements set forth in Section 1804, IBC 2012, adopted and modified by Section 2-3.4, UFC 3-220-01. Where shallow foundations will bear on compacted fill material, the compacted fill should comply with the criteria set forth in Section 1804.5, IBC 2012. Where shallow foundations will bear on Controlled Low-Strength Material (CLSM), the CLSM should comply with the criteria set forth in Section 1804.6, IBC 2012. Damp-proofing and Water-proofing It is recommended that the Engineer adhere to the requirements set forth in Section 1805, IBC 2012, adopted and modified by Section 2-3.5, UFC 3-220-01. This may include additional investigation(s) to verify the depth of the GWT or SHWT per Section 1803.5.4, IBC 2012, adopted and modified by Section 2-3.3.4 of UFC 3-220-01. Presumptive Load-Bearing Values of Soils It is recommended that the Engineer adhere to the requirements set forth in Section 1806, IBC 2012, adopted and modified by Section 2-3.6, UFC 3-220-01. As described above, soils with UBC’s less than 2000 psf were encountered at all locations and various depths within the proposed building footprint. It is recommended that the Engineer review these conditions and make a determination if improvement of subgrade materials is necessary, and if so, the type of improvements needed and to what depth the improvements are needed. The Engineer should evaluate this geotechnical investigation report, and determine if an additional geotechnical investigation is required to confirm the load bearing values indicated in this report. The Engineer should also use the Factors of Safety (FS) shown in Tables 2-2 and 2-3, UFC 3-220-01, when 5 developing the net allowable bearing capacities that will be used for design. All bearing capacities provided in Attachment D are Ultimate Bearing Capacities (UBC), and should be reduced to Allowable Bearing Capacities upon selection of the appropriate FS. Foundations It is recommended that foundations be designed and constructed in accordance with Sections 1808.2 through 1808.9, IBC 2012, adopted and modified by Section 2-3.8, UFC 3-220-01. The foundation should be designed such that the net allowable bearing capacity of the soil is not exceeded, and that total and differential settlement is limited to acceptable values. The net allowable bearing capacity should be evaluated by the Engineer. Acceptable settlement values can be found in Section 2-3.8.1, UFC 3-220-01. The foundation should be designed for the most unfavorable effects due to the combinations of loads specified in Chapter 16, IBC 2012. The Engineer should also consider possible future events such as dewatering and flooding due to storms. Expansive soils are not believed to exist at the site, however, the Engineer should make this determination and adhere to Section 1808.6, IBC 2012, adopted and modified by Section 2-3.8.4, UFC 3- 220-01, should expansive soils be determined to exist at the site. Shallow Foundations It is recommended that shallow foundations be designed and constructed in accordance with Sections 1809.2 through 1809.13, IBC 2012, adopted and modified by Section 2-3.9, UFC 3-220-01. Shallow foundations should be built on undisturbed soil, compacted fill material, or CLSM in accordance with Section 1809.2, IBC 2012. Fill material and CLSM should meet the criteria discussed in “Excavation, Grading, and Fill” of this report. For excavations, it is recommended that the top 12 inches of finished subgrade be compacted to 95 percent of maximum dry density per ASTM D698. For fill, it is recommended that material be placed in 6-inch lifts and compacted to 95 percent of maximum dry density per ASTM D698. Fill material should not be placed over wet or frozen areas. Fill material should be placed adjacent to structures, such as footings, after the structures have been completed and accepted, and should be compacted as to avoid loading upon or against the structure. Footings should be constructed at a minimum depth of 18 inches below the finished ground surface. Spacing between footings should be at least 1.5 times the width of the larger foundation to minimize any reduction in bearing capacity due to overlapping zones of influence. The minimum width of footings should be 12 inches. Frost Susceptibility Frost susceptible soils are defined in American Society of Civil Engineers (ASCE) 32, and consist of soil with greater than 6 percent by mass passing the #200 sieve in accordance with ASTM D422. Lab analyses of collected samples were not conducted as part of this geotechnical investigation. Due to the suspected clay content encountered in the soil test borings, it is recommended that the Engineer determine if frost susceptible soils exist at the site, and if so, protect the foundation and other permanent supports by one 6 or more of the following methods indicated in Section 1809.5, IBC 2012, adopted and modified by Section 2-3.9, UFC 3-220-01. Seismic Site Classification This geotechnical investigation is inadequate to provide the Seismic Site Classification (SSC) for the proposed building site. It is recommended that the Engineer adhere to Section 1613.3.2, IBC 2012, adopted and modified by Section 2-1.1.2, UFC 3-220-01, in order to verify the SSC. The SSC is designated as A, B, C, D, E, or F in accordance with Chapter 20 of ASCE 7-10. The building official may provide an assumed SSC, however, if one is not provided, and the soil properties are not known in sufficient detail to verify the SSC, an SSC of D may be assumed for preliminary purposes. For design purposes, the Engineer should verify the SSC by performing at least one boring to a depth of 100 feet or refusal (defined as N>100 blows per foot), or other method as determined by the building official. Liquefaction This geotechnical investigation is inadequate to provide an assessment of liquefaction potential. It is recommended that the Engineer adhere to Section 1613, IBC 2012, adopted and modified by Section 2- 1.1, UFC 3-220-01, regarding the assessment of liquefaction potential. 7 ATTACHMENT A 35% Design Submittal – Site Plan Description DateRev. RALEIGH, NC 27606-3394 (919) 851-6866 (919) 851-7024 FAX LICENSE # F-0672FOR OFFICIAL USE ONLYFOR OFFICIAL USE ONLYTELECOMMUNICATIONS RELIABILITY FACILITY, SOTF AS SHOWN35% SUBMITTALNOT FORCONSTRUCTION13 JULY 2017 PN-81894 U.S. ARMY CORPS OF ENGINEERS 69 DARLINGTON AVE WILMINGTON DISTRICT WILMINGTON, NORTH CAROLINA US Army Corpsof EngineersEROSION AND SEDIMENT CONTROL PLANSCALE: 1"=10'CG101EROSION AND SEDIMENT CONTROL PLAN010'10'30'1"=10'TPTPSFSFLODLODWWATTACHMENT A ATTACHMENT A ATTACHMENT B Boring, DCP, and Infiltration Testing Location Plan TEL-HA-17-5 TEL-HA-17-1 TEL-HA-17-4 TEL-HA-17-3 TEL-HA-17-2 TEL-INF-17-1 TEL-INF-17-2 !? !? !? !? !? !? !? Telecommunications Reliability Facility Ft. Bragg - PN 81894Data Source: CESAW, Stantec2013 Digital Orthphotography:OACSIM IGI&S Map Date: 10/23/2017 Ü !?Hand Auger/Dynamic Cone Penetrometer Borings !?Infilitration Test 0 25 5012.5 Feet Overlay is based on the 35% plans and specs. Site layout was confirmed by Project Management on 17 August 2017. Coordinates are in North Carolina State Plane Feet (NAD83). Bore_Label X YTEL-HA-17-2 1976375.201 510312.589TEL-HA-17-3 1976395.341 510266.341TEL-HA-17-4 1976350.661 510297.77TEL-HA-17-1 1976376.47 510254.971TEL-HA-17-5 1976373.629 510283.223TEL-INF-17-2 1976320.206 510300.049TEL-INF-17-1 1976473.464 510188.499 ATTACHMENT B ATTACHMENT C Soil Test Boring Logs 321.6 319.1 317.6 314.6 321.6 Chris Norton and Jason Inskeep COMPLETED Chris Norton, P.E., Civil Engineer VERTICAL 18. SIGNATURE AND TITLE OF INSPECTOR 9. COORDINATE SYSTEM SHEET INCLINED HORIZONTAL 3. DRILLING AGENCY 2. HOLE NUMBER 13. TOTAL NUMBER CORE BOXES Fort Bragg, NC OF Hand Auger INSTALLATION 15. DATE BORING 17. TOTAL CORE RECOVERY FOR BORING --- DISTURBED12. TOTAL SAMPLES 0 3 1. PROJECT NAD83SOTF Telecommunications Reliability Facility 6. THICKNESS OF OVERBURDEN 7. DEPTH DRILLED INTO ROCK 8. TOTAL DEPTH OF BORING STARTED South Atlantic Division USACE, Wilmington District VERTICAL UNDISTURBED 5. DIRECTION OF BORING 9/27/17 SHEETS 4. NAME OF DRILLER BEARINGDEG FROM VERTICAL DIVISION Date Drafted:10/1/2017 Reviewed By:Chris Norton, P.E. Date Checked:10/19/2017 VERSION:Draft TEL-HA-17-1 Drafted By:Jason Inskeep, E.I.T. Boring was acquired with a Hand Auger (HA). 3" 1 NAVD88 LOCATION COORDINATES 16. ELEVATION TOP OF BORING 14. ELEVATION GROUND WATER DRILLING LOG 9/27/17 1 N 510254.13 E 1976376.47 0 11. MANUFACTURER'S DESIGNATION OF DRILL 10. SIZE AND TYPE OF BIT 7.0-ft GWT not encountered Boring Designation TEL-HA-17-1 SHEET 1 of 1 Boring Designation TEL-HA-17-1 OCT 2013 SAW FORM 1836-A (SOIL BORING) REMARKS (Drilling time, water loss, depth of weathering, etc., if significant) g LEGEND c Wilmington District Geotechnical and Dam Safety Section SCALE (feet) b 0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0 ELEV (feet) a Poorly Graded Sand with Silt (SP-SM), brown, non-plastic, some rootlets Poorly Graded Sand with Clay (SP-SC), orange to brown, fine to medium grained Poorly Graded Sand (SP), orange to brown and tan, fine to medium grained BOTTOM OF BOREHOLE AT 7.0 ft SOILS ARE FIELD VISUALLY CLASSIFIED IN ACCORDANCE WITH THE UNIFIED SOIL CLASSIFICATION SYSTEM FIELD CLASSIFICATION OF MATERIALS (Description) d BOX OR SAMPLE # f 1-ft 3-ft 4.5-ft 0.5-ft 2.5-ft 4-ft S-1 S-2 S-3 ATTACHMENT C 319.7 317.7 313.2 312.7 319.7 Chris Norton and Jason Inskeep COMPLETED Chris Norton, P.E., Civil Engineer VERTICAL 18. SIGNATURE AND TITLE OF INSPECTOR 9. COORDINATE SYSTEM SHEET INCLINED HORIZONTAL 3. DRILLING AGENCY 2. HOLE NUMBER 13. TOTAL NUMBER CORE BOXES Fort Bragg, NC OF Hand Auger INSTALLATION 15. DATE BORING 17. TOTAL CORE RECOVERY FOR BORING --- DISTURBED12. TOTAL SAMPLES 0 3 1. PROJECT NAD83SOTF Telecommunications Reliability Facility 6. THICKNESS OF OVERBURDEN 7. DEPTH DRILLED INTO ROCK 8. TOTAL DEPTH OF BORING STARTED South Atlantic Division USACE, Wilmington District VERTICAL UNDISTURBED 5. DIRECTION OF BORING 9/27/17 SHEETS 4. NAME OF DRILLER BEARINGDEG FROM VERTICAL DIVISION Date Drafted:10/1/2017 Reviewed By:Chris Norton, P.E. Date Checked:10/19/2017 VERSION:Draft TEL-HA-17-2 Drafted By:Jason Inskeep, E.I.T. Boring was acquired with a Hand Auger (HA). 3" 1 NAVD88 LOCATION COORDINATES 16. ELEVATION TOP OF BORING 14. ELEVATION GROUND WATER DRILLING LOG 9/27/17 1 N 510312.589 E 1976375.201 0 11. MANUFACTURER'S DESIGNATION OF DRILL 10. SIZE AND TYPE OF BIT 7.0-ft GWT not encountered Boring Designation TEL-HA-17-2 SHEET 1 of 1 Boring Designation TEL-HA-17-2 OCT 2013 SAW FORM 1836-A (SOIL BORING) REMARKS (Drilling time, water loss, depth of weathering, etc., if significant) g LEGEND c Wilmington District Geotechnical and Dam Safety Section SCALE (feet) b 0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0 ELEV (feet) a Poorly Graded Sand with Silt (SP-SM), brown, fine to medium grained, non-plastic, rootlets Poorly Graded Sand with Clay (SP-SC), orange to brown, fine to medium grained Poorly Graded Sand with Clay (SP-SC), orange to brown, fine to medium grained BOTTOM OF BOREHOLE AT 7.0 ft SOILS ARE FIELD VISUALLY CLASSIFIED IN ACCORDANCE WITH THE UNIFIED SOIL CLASSIFICATION SYSTEM FIELD CLASSIFICATION OF MATERIALS (Description) d BOX OR SAMPLE # f 1-ft 2.5-ft 7-ft 0.5-ft 2-ft 6.5-ft S-1 S-2 S-3 ATTACHMENT C 319.9 319.4 314.9 313.4 312.4 319.9 Chris Norton and Jason Inskeep COMPLETED Chris Norton, P.E., Civil Engineer VERTICAL 18. SIGNATURE AND TITLE OF INSPECTOR 9. COORDINATE SYSTEM SHEET INCLINED HORIZONTAL 3. DRILLING AGENCY 2. HOLE NUMBER 13. TOTAL NUMBER CORE BOXES Fort Bragg, NC OF Hand Auger INSTALLATION 15. DATE BORING 17. TOTAL CORE RECOVERY FOR BORING --- DISTURBED12. TOTAL SAMPLES 0 4 1. PROJECT NAD83SOTF Telecommunications Reliability Facility 6. THICKNESS OF OVERBURDEN 7. DEPTH DRILLED INTO ROCK 8. TOTAL DEPTH OF BORING STARTED South Atlantic Division USACE, Wilmington District VERTICAL UNDISTURBED 5. DIRECTION OF BORING 9/27/17 SHEETS 4. NAME OF DRILLER BEARINGDEG FROM VERTICAL DIVISION Date Drafted:10/1/2017 Reviewed By:Chris Norton, P.E. Date Checked:10/19/2017 VERSION:Draft TEL-HA-17-3 Drafted By:Jason Inskeep, E.I.T. Boring was acquired with a Hand Auger (HA). 3" 1 NAVD88 LOCATION COORDINATES 16. ELEVATION TOP OF BORING 14. ELEVATION GROUND WATER DRILLING LOG 9/27/17 1 N 510266.341 E 1976395.341 0 11. MANUFACTURER'S DESIGNATION OF DRILL 10. SIZE AND TYPE OF BIT 7.5-ft GWT not encountered Boring Designation TEL-HA-17-3 SHEET 1 of 1 Boring Designation TEL-HA-17-3 OCT 2013 SAW FORM 1836-A (SOIL BORING) REMARKS (Drilling time, water loss, depth of weathering, etc., if significant) g LEGEND c Wilmington District Geotechnical and Dam Safety Section SCALE (feet) b 0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0 ELEV (feet) a Poorly Graded Sand with Silt (SP-SM), brown, fine to medium grained, non-plastic, rootlets Poorly Graded Sand with Clay (SP-SC), orange to brown, fine to medium grained Poorly Graded Sand with Clay (SP-SC), orange to brown, fine to medium grained Poorly Graded Sand with Clay (SP-SC), orange to brown, fine to medium grained BOTTOM OF BOREHOLE AT 7.5 ft SOILS ARE FIELD VISUALLY CLASSIFIED IN ACCORDANCE WITH THE UNIFIED SOIL CLASSIFICATION SYSTEM FIELD CLASSIFICATION OF MATERIALS (Description) d BOX OR SAMPLE # f 1-ft 2.5-ft 5.5-ft 7.5-ft 0.5-ft 2-ft 5-ft 7-ft S-1 S-2 S-3 S-4 ATTACHMENT C 321.5 319.5 317.0 315.0 314.5 321.5 Chris Norton and Jason Inskeep COMPLETED Chris Norton, P.E., Civil Engineer VERTICAL 18. SIGNATURE AND TITLE OF INSPECTOR 9. COORDINATE SYSTEM SHEET INCLINED HORIZONTAL 3. DRILLING AGENCY 2. HOLE NUMBER 13. TOTAL NUMBER CORE BOXES Fort Bragg, NC OF Hand Auger INSTALLATION 15. DATE BORING 17. TOTAL CORE RECOVERY FOR BORING --- DISTURBED12. TOTAL SAMPLES 0 4 1. PROJECT NAD83SOTF Telecommunications Reliability Facility 6. THICKNESS OF OVERBURDEN 7. DEPTH DRILLED INTO ROCK 8. TOTAL DEPTH OF BORING STARTED South Atlantic Division USACE, Wilmington District VERTICAL UNDISTURBED 5. DIRECTION OF BORING 9/27/17 SHEETS 4. NAME OF DRILLER BEARINGDEG FROM VERTICAL DIVISION Date Drafted:10/1/2017 Reviewed By:Chris Norton, P.E. Date Checked:10/19/2017 VERSION:Draft TEL-HA-17-4 Drafted By:Jason Inskeep, E.I.T. Boring was acquired with a Hand Auger (HA). 3" 1 NAVD88 LOCATION COORDINATES 16. ELEVATION TOP OF BORING 14. ELEVATION GROUND WATER DRILLING LOG 9/27/17 1 N 510297.77 E 1976350.661 0 11. MANUFACTURER'S DESIGNATION OF DRILL 10. SIZE AND TYPE OF BIT 7.0-ft GWT not encountered Boring Designation TEL-HA-17-4 SHEET 1 of 1 Boring Designation TEL-HA-17-4 OCT 2013 SAW FORM 1836-A (SOIL BORING) REMARKS (Drilling time, water loss, depth of weathering, etc., if significant) g LEGEND c Wilmington District Geotechnical and Dam Safety Section SCALE (feet) b 0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0 ELEV (feet) a Poorly Graded Sand with Silt (SP-SM), brown, fine to medium grained, non-plastic, rootlets Poorly Graded Sand with Clay (SP-SC), brown, fine to medium grained Poorly Graded Sand with Clay (SP-SC), brown, fine to medium grained Poorly Graded Sand (SP), orange to brown, fine grained BOTTOM OF BOREHOLE AT 7.0 ft SOILS ARE FIELD VISUALLY CLASSIFIED IN ACCORDANCE WITH THE UNIFIED SOIL CLASSIFICATION SYSTEM FIELD CLASSIFICATION OF MATERIALS (Description) d BOX OR SAMPLE # f 1-ft 2.5-ft 5-ft 7-ft 0.5-ft 2-ft 4.5-ft 6.5-ft S-1 S-2 S-3 S-4 ATTACHMENT C 320.8 318.8 316.8 315.8 313.8 320.8 Chris Norton and Jason Inskeep COMPLETED Chris Norton, P.E., Civil Engineer VERTICAL 18. SIGNATURE AND TITLE OF INSPECTOR 9. COORDINATE SYSTEM SHEET INCLINED HORIZONTAL 3. DRILLING AGENCY 2. HOLE NUMBER 13. TOTAL NUMBER CORE BOXES Fort Bragg, NC OF Hand Auger INSTALLATION 15. DATE BORING 17. TOTAL CORE RECOVERY FOR BORING --- DISTURBED12. TOTAL SAMPLES 0 4 1. PROJECT NAD83SOTF Telecommunications Reliability Facility 6. THICKNESS OF OVERBURDEN 7. DEPTH DRILLED INTO ROCK 8. TOTAL DEPTH OF BORING STARTED South Atlantic Division USACE, Wilmington District VERTICAL UNDISTURBED 5. DIRECTION OF BORING 9/27/17 SHEETS 4. NAME OF DRILLER BEARINGDEG FROM VERTICAL DIVISION Date Drafted:10/1/2017 Reviewed By:Chris Norton, P.E. Date Checked:10/19/2017 VERSION:Draft TEL-HA-17-5 Drafted By:Jason Inskeep, E.I.T. Boring was acquired with a Hand Auger (HA). Elevation Top of Boring estimated using existing topographic survey contours. Please see Attachment B. 3" 1 NAVD88 LOCATION COORDINATES 16. ELEVATION TOP OF BORING 14. ELEVATION GROUND WATER DRILLING LOG 9/27/17 1 N 510283.22 E 1976373.63 0 11. MANUFACTURER'S DESIGNATION OF DRILL 10. SIZE AND TYPE OF BIT 7.0-ft GWT not encountered Boring Designation TEL-HA-17-5 SHEET 1 of 1 Boring Designation TEL-HA-17-5 OCT 2013 SAW FORM 1836-A (SOIL BORING) REMARKS (Drilling time, water loss, depth of weathering, etc., if significant) g LEGEND c Wilmington District Geotechnical and Dam Safety Section SCALE (feet) b 0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0 ELEV (feet) a Poorly Graded Sand with Silt (SP-SM), brown, fine to medium grained, non-plastic, little organics Clayey Sand (SC), orange to brown, fine grained Poorly Graded Sand with Clay (SP-SC), orange to brown, fine grained Poorly Graded Sand (SP), orange to brown, fine grained BOTTOM OF BOREHOLE AT 7.0 ft SOILS ARE FIELD VISUALLY CLASSIFIED IN ACCORDANCE WITH THE UNIFIED SOIL CLASSIFICATION SYSTEM FIELD CLASSIFICATION OF MATERIALS (Description) d BOX OR SAMPLE # f 1-ft 2.5-ft 4.5-ft 5.5-ft 0.5-ft 2-ft 4-ft 5-ft S-1 S-2 S-3 S-4 ATTACHMENT C 317.4 315.4 314.4 313.4 317.4 Chris Norton and Jason Inskeep COMPLETED Chris Norton, P.E., Civil Engineer VERTICAL 18. SIGNATURE AND TITLE OF INSPECTOR 9. COORDINATE SYSTEM SHEET INCLINED HORIZONTAL 3. DRILLING AGENCY 2. HOLE NUMBER 13. TOTAL NUMBER CORE BOXES Fort Bragg, NC OF Hand Auger INSTALLATION 15. DATE BORING 17. TOTAL CORE RECOVERY FOR BORING --- DISTURBED12. TOTAL SAMPLES 0 0 1. PROJECT NAD83SOTF Telecommunications Reliability Facility 6. THICKNESS OF OVERBURDEN 7. DEPTH DRILLED INTO ROCK 8. TOTAL DEPTH OF BORING STARTED South Atlantic Division USACE, Wilmington District VERTICAL UNDISTURBED 5. DIRECTION OF BORING 9/28/17 SHEETS 4. NAME OF DRILLER BEARINGDEG FROM VERTICAL DIVISION Date Drafted:10/1/2017 Reviewed By:Chris Norton, P.E. Date Checked:10/19/2017 VERSION:Draft TEL-INF-17-1 Drafted By:Jason Inskeep, E.I.T. Boring was acquired with a Hand Auger (HA). Elevation Top of Boring estimated using existing topographic survey contours. Please see Attachment B. 3" 1 NAVD88 LOCATION COORDINATES 16. ELEVATION TOP OF BORING 14. ELEVATION GROUND WATER DRILLING LOG 9/28/17 1 N 510188.5 E 1976473.46 0 11. MANUFACTURER'S DESIGNATION OF DRILL 10. SIZE AND TYPE OF BIT 4.0-ft GWT not encountered Boring Designation TEL-INF-17-1 SHEET 1 of 1 Boring Designation TEL-INF-17-1 OCT 2013 SAW FORM 1836-A (SOIL BORING) REMARKS (Drilling time, water loss, depth of weathering, etc., if significant) g LEGEND c Wilmington District Geotechnical and Dam Safety Section SCALE (feet) b 0.0 1.0 2.0 3.0 4.0 ELEV (feet) a Poorly Graded Sand with Silt (SP-SM), brown, fine to medium grained, non-plastic, some small rock Clayey Sand (SC), orange to brown, fine to medium grained Poorly Graded Sand with Clay (SP-SC), fine to medium grained BOTTOM OF BOREHOLE AT 4.0 ft SOILS ARE FIELD VISUALLY CLASSIFIED IN ACCORDANCE WITH THE UNIFIED SOIL CLASSIFICATION SYSTEM FIELD CLASSIFICATION OF MATERIALS (Description) d BOX OR SAMPLE # f ATTACHMENT C 321.6 320.6 318.1 316.6 321.6 Chris Norton and Jason Inskeep COMPLETED Chris Norton, P.E., Civil Engineer VERTICAL 18. SIGNATURE AND TITLE OF INSPECTOR 9. COORDINATE SYSTEM SHEET INCLINED HORIZONTAL 3. DRILLING AGENCY 2. HOLE NUMBER 13. TOTAL NUMBER CORE BOXES Fort Bragg, NC OF Hand Auger INSTALLATION 15. DATE BORING 17. TOTAL CORE RECOVERY FOR BORING --- DISTURBED12. TOTAL SAMPLES 0 0 1. PROJECT NAD83SOTF Telecommunications Reliability Facility 6. THICKNESS OF OVERBURDEN 7. DEPTH DRILLED INTO ROCK 8. TOTAL DEPTH OF BORING STARTED South Atlantic Division USACE, Wilmington District VERTICAL UNDISTURBED 5. DIRECTION OF BORING 9/28/17 SHEETS 4. NAME OF DRILLER BEARINGDEG FROM VERTICAL DIVISION Date Drafted:10/1/2017 Reviewed By:Chris Norton, P.E. Date Checked:10/19/2017 VERSION:Draft TEL-INF-17-2 Drafted By:Jason Inskeep, E.I.T. Boring was acquired with a Hand Auger (HA). Elevation Top of Boring estimated using existing topographic survey contours. Please see Attachment B. 3" 1 NAVD88 LOCATION COORDINATES 16. ELEVATION TOP OF BORING 14. ELEVATION GROUND WATER DRILLING LOG 9/28/17 1 N 510300.05 E 1976320.21 0 11. MANUFACTURER'S DESIGNATION OF DRILL 10. SIZE AND TYPE OF BIT 5.0-ft GWT not encountered Boring Designation TEL-INF-17-2 SHEET 1 of 1 Boring Designation TEL-INF-17-2 OCT 2013 SAW FORM 1836-A (SOIL BORING) REMARKS (Drilling time, water loss, depth of weathering, etc., if significant) g LEGEND c Wilmington District Geotechnical and Dam Safety Section SCALE (feet) b 0.0 1.0 2.0 3.0 4.0 5.0 ELEV (feet) a Poorly Graded Sand with Silt (SP-SM), brown to tan, fine to medium grained Poorly Graded Sand with Clay (SP-SC), brown to orange, fine to medium grained Poorly Graded Sand (SP), brown to orange, fine to medium grained BOTTOM OF BOREHOLE AT 5.0 ft SOILS ARE FIELD VISUALLY CLASSIFIED IN ACCORDANCE WITH THE UNIFIED SOIL CLASSIFICATION SYSTEM FIELD CLASSIFICATION OF MATERIALS (Description) d BOX OR SAMPLE # f ATTACHMENT C ATTACHMENT D CBR and UBC Tabulations Boring ID:Boring ID:Boring ID: TOH Elev.TOH Elev.TOH Elev. Northing Northing Northing Easting Easting Easting NAVD 88 CBR Ultimate NAVD 88 CBR Ultimate NAVD 88 CBR Ultimate Elevation Bearing Elevation Bearing Elevation Bearing Depth Depth Capacity Capacity Capacity (in)(ft)(ft)(%)(psf)(ft)(%)(psf)(ft)(%)(psf) 1 0.08 321.52 7.8 2137 319.62 5.6 1725 319.82 5.6 1725 2 0.17 321.43 7.8 2137 319.53 5.6 1725 319.73 5.6 1725 3 0.25 321.35 7.8 2137 319.45 7.8 2137 319.65 7.8 2137 4 0.33 321.27 16.9 3578 319.37 7.8 2137 319.57 7.8 2137 5 0.42 321.18 12.3 2889 319.28 7.8 2137 319.48 7.8 2137 6 0.50 321.10 12.3 2889 319.20 7.8 2137 319.40 7.8 2137 7 0.58 321.02 7.8 2137 319.12 7.8 2137 319.32 7.8 2137 8 0.67 320.93 7.8 2137 319.03 7.8 2137 319.23 7.8 2137 9 0.75 320.85 16.9 3578 318.95 7.8 2137 319.15 16.9 3578 10 0.83 320.77 7.8 2137 318.87 7.8 2137 319.07 7.8 2137 11 0.92 320.68 7.8 2137 318.78 7.8 2137 318.98 7.8 2137 12 1.00 320.60 7.8 2137 318.70 7.8 2137 318.90 7.8 2137 13 1.08 320.52 7.8 2137 318.62 10.0 2522 318.82 7.8 2137 14 1.17 320.43 7.8 2137 318.53 7.8 2137 318.73 7.8 2137 15 1.25 320.35 7.8 2137 318.45 7.8 2137 318.65 7.8 2137 16 1.33 320.27 7.8 2137 318.37 7.8 2137 318.57 7.8 2137 17 1.42 320.18 7.8 2137 318.28 7.8 2137 318.48 7.8 2137 18 1.50 320.10 7.8 2137 318.20 7.8 2137 318.40 7.8 2137 19 1.58 320.02 7.8 2137 318.12 5.6 1725 318.32 7.8 2137 20 1.67 319.93 7.8 2137 318.03 5.6 1725 318.23 7.8 2137 21 1.75 319.85 7.8 2137 317.95 5.6 1725 318.15 7.8 2137 22 1.83 319.77 7.8 2137 317.87 5.6 1725 318.07 7.8 2137 23 1.92 319.68 7.8 2137 317.78 5.6 1725 317.98 5.6 1725 24 2.00 319.60 3.6 1276 317.70 5.6 1725 317.90 5.6 1725 25 2.08 319.52 3.6 1276 317.62 5.6 1725 317.82 5.6 1725 26 2.17 319.43 317.53 3.6 1276 317.73 5.6 1725 27 2.25 319.35 317.45 3.6 1276 317.65 5.6 1725 28 2.33 319.27 317.37 2.3 937 317.57 5.6 1725 29 2.42 319.18 317.28 2.3 937 317.48 30 2.50 319.10 317.20 2.3 937 317.40 31 2.58 319.02 317.12 2.3 937 317.32 3.6 1276 32 2.67 318.93 1.7 762 317.03 2.3 937 317.23 3.6 1276 33 2.75 318.85 1.7 762 316.95 2.3 937 317.15 3.6 1276 34 2.83 318.77 1.7 762 316.87 2.3 937 317.07 3.6 1276 Notes: Top of Hole (TOH) depth is 0; Horizontal Datum is NC State Plane (US Survey Feet); Vertical Datum is NAVD88; DCP conforms to ASTM D6951; CBR per ASTM D6951; Ultimate Bearing Capacity correlation per "Evaluation of In Situ Pavemement Layers with the Dynamic Cone Penetrometer (DCP)", Jeb S. Tingle, et. al. 510254.97 1976376.47 510266.34 1976395.34 510312.59 1976375.20 321.6 319.7 319.9 TEL-DCP-17-2 TEL-DCP-17-3TEL-DCP-17-1 ATTACHMENT D Boring ID:Boring ID:Boring ID: TOH Elev.TOH Elev.TOH Elev. Northing Northing Northing Easting Easting Easting NAVD 88 CBR Ultimate NAVD 88 CBR Ultimate NAVD 88 CBR Ultimate Elevation Bearing Elevation Bearing Elevation Bearing Depth Depth Capacity Capacity Capacity (in)(ft)(ft)(%)(psf)(ft)(%)(psf)(ft)(%)(psf) 35 2.92 318.68 3.6 1276 316.78 2.3 937 316.98 3.6 1276 36 3.00 318.60 3.6 1276 316.70 2.3 937 316.90 3.6 1276 37 3.08 318.52 5.6 1725 316.62 3.6 1276 316.82 3.6 1276 38 3.17 318.43 5.6 1725 316.53 3.6 1276 316.73 3.6 1276 39 3.25 318.35 3.6 1276 316.45 2.3 937 316.65 3.6 1276 40 3.33 318.27 3.6 1276 316.37 2.3 937 316.57 3.6 1276 41 3.42 318.18 3.6 1276 316.28 2.3 937 316.48 3.6 1276 42 3.50 318.10 3.6 1276 316.20 2.3 937 316.40 3.6 1276 43 3.58 318.02 3.6 1276 316.12 2.3 937 316.32 3.6 1276 44 3.67 317.93 3.6 1276 316.03 2.3 937 316.23 3.6 1276 45 3.75 317.85 3.6 1276 315.95 3.6 1276 316.15 3.6 1276 46 3.83 317.77 3.6 1276 315.87 3.6 1276 316.07 3.6 1276 47 3.92 317.68 3.6 1276 315.78 2.3 937 315.98 3.6 1276 48 4.00 317.60 3.6 1276 315.70 2.3 937 315.90 3.6 1276 49 4.08 317.52 3.6 1276 315.62 2.3 937 315.82 5.6 1725 50 4.17 317.43 3.6 1276 315.53 2.3 937 315.73 5.6 1725 51 4.25 317.35 3.6 1276 315.45 2.3 937 315.65 5.6 1725 52 4.33 317.27 3.6 1276 315.37 2.3 937 315.57 5.6 1725 53 4.42 317.18 3.6 1276 315.28 3.6 1276 315.48 5.6 1725 54 4.50 317.10 3.6 1276 315.20 3.6 1276 315.40 5.6 1725 55 4.58 317.02 3.6 1276 315.12 3.6 1276 315.32 5.6 1725 56 4.67 316.93 3.6 1276 315.03 3.6 1276 315.23 5.6 1725 57 4.75 316.85 3.6 1276 314.95 3.6 1276 315.15 5.6 1725 58 4.83 316.77 5.6 1725 314.87 3.6 1276 315.07 5.6 1725 59 4.92 316.68 5.6 1725 314.78 3.6 1276 314.98 7.8 2137 60 5.00 316.60 3.6 1276 314.70 3.6 1276 314.90 7.8 2137 61 5.08 316.52 3.6 1276 314.62 3.6 1276 314.82 5.6 1725 62 5.17 316.43 3.6 1276 314.53 3.6 1276 314.73 5.6 1725 63 5.25 316.35 3.6 1276 314.45 5.6 1725 314.65 5.6 1725 64 5.33 316.27 5.6 1725 314.37 5.6 1725 314.57 5.6 1725 65 5.42 316.18 5.6 1725 314.28 5.6 1725 314.48 7.8 2137 66 5.50 316.10 5.6 1725 314.20 5.6 1725 314.40 7.8 2137 67 5.58 316.02 5.6 1725 314.12 5.6 1725 314.32 7.8 2137 68 5.67 315.93 5.6 1725 314.03 5.6 1725 314.23 7.8 2137 321.6 319.7 319.9 510254.97 510312.59 510266.34 1976376.47 1976375.20 1976395.34 Notes: Top of Hole (TOH) depth is 0; Horizontal Datum is NC State Plane (US Survey Feet); Vertical Datum is NAVD88; DCP conforms to ASTM D6951; CBR per ASTM D6951; Ultimate Bearing Capacity correlation per "Evaluation of In Situ Pavemement Layers with the Dynamic Cone Penetrometer (DCP)", Jeb S. Tingle, et. al. TEL-DCP-17-1 TEL-DCP-17-2 TEL-DCP-17-3 ATTACHMENT D Boring ID:Boring ID:Boring ID: TOH Elev.TOH Elev.TOH Elev. Northing Northing Northing Easting Easting Easting NAVD 88 CBR Ultimate NAVD 88 CBR Ultimate NAVD 88 CBR Ultimate Elevation Bearing Elevation Bearing Elevation Bearing Depth Depth Capacity Capacity Capacity (in)(ft)(ft)(%)(psf)(ft)(%)(psf)(ft)(%)(psf) 69 5.75 315.85 5.6 1725 313.95 3.6 1276 314.15 7.8 2137 70 5.83 315.77 5.6 1725 313.87 3.6 1276 314.07 7.8 2137 71 5.92 315.68 5.6 1725 313.78 5.6 1725 313.98 7.8 2137 72 6.00 315.60 7.8 2137 313.70 5.6 1725 313.90 7.8 2137 73 6.08 315.52 7.8 2137 313.62 5.6 1725 313.82 7.8 2137 74 6.17 315.43 7.8 2137 313.53 5.6 1725 313.73 7.8 2137 75 6.25 315.35 7.8 2137 313.45 5.6 1725 313.65 5.6 1725 76 6.33 315.27 313.37 5.6 1725 313.57 5.6 1725 77 6.42 315.18 313.28 5.6 1725 313.48 5.6 1725 321.6 319.7 319.9 510254.97 510312.59 510266.34 1976376.47 1976375.20 1976395.34 Notes: Top of Hole (TOH) depth is 0; Horizontal Datum is NC State Plane (US Survey Feet); Vertical Datum is NAVD88; DCP conforms to ASTM D6951; CBR per ASTM D6951; Ultimate Bearing Capacity correlation per "Evaluation of In Situ Pavemement Layers with the Dynamic Cone Penetrometer (DCP)", Jeb S. Tingle, et. al. TEL-DCP-17-1 TEL-DCP-17-2 TEL-DCP-17-3 ATTACHMENT D Boring ID:Boring ID: TOH Elev.TOH Elev. Northing Northing Easting Easting NAVD 88 CBR Ultimate NAVD 88 CBR Ultimate Elevation Bearing Elevation Bearing Depth Depth Capacity Capacity (in)(ft)(ft)(%)(psf)(ft)(%)(psf) 1 0.08 321.42 3.6 1276 320.72 3.6 1276 2 0.17 321.33 3.6 1276 320.63 3.6 1276 3 0.25 321.25 5.6 1725 320.55 7.8 2137 4 0.33 321.17 5.6 1725 320.47 7.8 2137 5 0.42 321.08 7.8 2137 320.38 10.0 2522 6 0.50 321.00 7.8 2137 320.30 16.9 3578 7 0.58 320.92 7.8 2137 320.22 16.9 3578 8 0.67 320.83 7.8 2137 320.13 7.8 2137 9 0.75 320.75 16.9 3578 320.05 16.9 3578 10 0.83 320.67 7.8 2137 319.97 16.9 3578 11 0.92 320.58 7.8 2137 319.88 7.8 2137 12 1.00 320.50 7.8 2137 319.80 16.9 3578 13 1.08 320.42 7.8 2137 319.72 7.8 2137 14 1.17 320.33 7.8 2137 319.63 7.8 2137 15 1.25 320.25 7.8 2137 319.55 16.9 3578 16 1.33 320.17 7.8 2137 319.47 7.8 2137 17 1.42 320.08 7.8 2137 319.38 7.8 2137 18 1.50 320.00 7.8 2137 319.30 7.8 2137 19 1.58 319.92 7.8 2137 319.22 7.8 2137 20 1.67 319.83 5.6 1725 319.13 7.8 2137 21 1.75 319.75 5.6 1725 319.05 7.8 2137 22 1.83 319.67 5.6 1725 318.97 5.6 1725 23 1.92 319.58 5.6 1725 318.88 3.6 1276 24 2.00 319.50 5.6 1725 318.80 3.6 1276 25 2.08 319.42 5.6 1725 318.72 3.6 1276 26 2.17 319.33 5.6 1725 318.63 3.6 1276 27 2.25 319.25 5.6 1725 318.55 5.6 1725 28 2.33 319.17 5.6 1725 318.47 5.6 1725 29 2.42 319.08 5.6 1725 318.38 5.6 1725 30 2.50 319.00 5.6 1725 318.30 5.6 1725 31 2.58 318.92 3.6 1276 318.22 3.6 1276 32 2.67 318.83 3.6 1276 318.13 3.6 1276 33 2.75 318.75 3.6 1276 318.05 3.6 1276 34 2.83 318.67 3.6 1276 317.97 3.6 1276 321.5 320.8 Notes: Top of Hole (TOH) depth is 0; Horizontal Datum is NC State Plane (US Survey Feet); Vertical Datum is NAVD88; DCP conforms to ASTM D6951; CBR per ASTM D6951; Ultimate Bearing Capacity correlation per "Evaluation of In Situ Pavemement Layers with the Dynamic Cone Penetrometer (DCP)", Jeb S. Tingle, et. al. 510283.22 1976373.63 510297.77 1976350.66 TEL-DCP-17-4 TEL-DCP-17-5 ATTACHMENT D Boring ID:Boring ID: TOH Elev.TOH Elev. Northing Northing Easting Easting NAVD 88 CBR Ultimate NAVD 88 CBR Ultimate Elevation Bearing Elevation Bearing Depth Depth Capacity Capacity (in)(ft)(ft)(%)(psf)(ft)(%)(psf) 35 2.92 318.58 3.6 1276 317.88 3.6 1276 36 3.00 318.50 3.6 1276 317.80 3.6 1276 37 3.08 318.42 3.6 1276 317.72 3.6 1276 38 3.17 318.33 3.6 1276 317.63 3.6 1276 39 3.25 318.25 3.6 1276 317.55 3.6 1276 40 3.33 318.17 3.6 1276 317.47 3.6 1276 41 3.42 318.08 3.6 1276 317.38 3.6 1276 42 3.50 318.00 3.6 1276 317.30 3.6 1276 43 3.58 317.92 3.6 1276 317.22 3.6 1276 44 3.67 317.83 3.6 1276 317.13 3.6 1276 45 3.75 317.75 3.6 1276 317.05 3.6 1276 46 3.83 317.67 3.6 1276 316.97 3.6 1276 47 3.92 317.58 3.6 1276 316.88 3.6 1276 48 4.00 317.50 3.6 1276 316.80 3.6 1276 49 4.08 317.42 3.6 1276 316.72 3.6 1276 50 4.17 317.33 3.6 1276 316.63 3.6 1276 51 4.25 317.25 3.6 1276 316.55 3.6 1276 52 4.33 317.17 3.6 1276 316.47 3.6 1276 53 4.42 317.08 3.6 1276 316.38 5.6 1725 54 4.50 317.00 3.6 1276 316.30 5.6 1725 55 4.58 316.92 3.6 1276 316.22 5.6 1725 56 4.67 316.83 3.6 1276 316.13 5.6 1725 57 4.75 316.75 5.6 1725 316.05 3.6 1276 58 4.83 316.67 3.6 1276 315.97 3.6 1276 59 4.92 316.58 3.6 1276 315.88 5.6 1725 60 5.00 316.50 7.8 2137 315.80 5.6 1725 61 5.08 316.42 5.6 1725 315.72 3.6 1276 62 5.17 316.33 5.6 1725 315.63 3.6 1276 63 5.25 316.25 5.6 1725 315.55 5.6 1725 64 5.33 316.17 5.6 1725 315.47 5.6 1725 65 5.42 316.08 7.8 2137 315.38 5.6 1725 66 5.50 316.00 5.6 1725 315.30 5.6 1725 67 5.58 315.92 5.6 1725 315.22 5.6 1725 68 5.67 315.83 5.6 1725 315.13 5.6 1725 TEL-DCP-17-4 TEL-DCP-17-5 321.5 320.8 510297.77 510283.22 1976350.66 1976373.63 Notes: Top of Hole (TOH) depth is 0; Horizontal Datum is NC State Plane (US Survey Feet); Vertical Datum is NAVD88; DCP conforms to ASTM D6951; CBR per ASTM D6951; Ultimate Bearing Capacity correlation per "Evaluation of In Situ Pavemement Layers with the Dynamic Cone Penetrometer (DCP)", Jeb S. Tingle, et. al. ATTACHMENT D Boring ID:Boring ID: TOH Elev.TOH Elev. Northing Northing Easting Easting NAVD 88 CBR Ultimate NAVD 88 CBR Ultimate Elevation Bearing Elevation Bearing Depth Depth Capacity Capacity (in)(ft)(ft)(%)(psf)(ft)(%)(psf) 69 5.75 315.75 5.6 1725 315.05 5.6 1725 70 5.83 315.67 5.6 1725 314.97 5.6 1725 71 5.92 315.58 5.6 1725 314.88 5.6 1725 72 6.00 315.50 5.6 1725 314.80 5.6 1725 73 6.08 315.42 5.6 1725 314.72 7.8 2137 74 6.17 315.33 7.8 2137 314.63 7.8 2137 75 6.25 315.25 7.8 2137 314.55 5.6 1725 76 6.33 315.17 7.8 2137 314.47 5.6 1725 77 6.42 315.08 7.8 2137 314.38 5.6 1725 TEL-DCP-17-4 TEL-DCP-17-5 Notes: Top of Hole (TOH) depth is 0; Horizontal Datum is NC State Plane (US Survey Feet); Vertical Datum is NAVD88; DCP conforms to ASTM D6951; CBR per ASTM D6951; Ultimate Bearing Capacity correlation per "Evaluation of In Situ Pavemement Layers with the Dynamic Cone Penetrometer (DCP)", Jeb S. Tingle, et. al. 321.5 320.8 510297.77 510283.22 1976350.66 1976373.63 ATTACHMENT D ATTACHMENT E Infiltration Test Tabulations (in)(in)(in)(in/hr)(in/hr) TEL-INF-17-1 9:00 9:15 15 48.00 35.00 13.00 52.00 1.81 9:15 9:30 15 35.00 23.50 11.50 46.00 2.24 9:30 9:45 15 48.00 34.00 14.00 56.00 1.98 1976473.46 N 9:45 10:00 15 34.00 22.50 11.50 46.00 2.32 510188.5 W 10:00 10:15 15 34.50 23.50 11.00 44.00 2.16 10:15 10:30 15 23.50 15.50 8.00 32.00 2.29 10:30 10:45 15 24.50 16.50 8.00 32.00 2.18 10:45 11:00 15 31.25 22.50 8.75 35.00 1.85 11:00 11:15 15 22.50 16.00 6.50 26.00 1.88 11:15 11:30 15 30.50 23.25 7.25 29.00 1.53 11:30 11:45 15 23.25 16.50 6.75 27.00 1.89 11:45 12:00 15 32.50 25.00 7.50 30.00 1.49 12:00 12:15 15 25.00 17.50 7.50 30.00 1.98 12:15 12:30 15 27.00 20.00 7.00 28.00 1.68 (in)(in)(in)(in/hr)(in/hr) TEL-INF-17-2 9:00 9:15 15 60.00 45.44 14.56 58.25 1.61 9:15 9:30 15 45.44 32.13 13.31 53.25 1.98 9:30 9:45 15 60.00 43.06 16.94 67.75 1.92 1976320.21 N 9:45 10:00 15 43.06 31.06 12.00 48.00 1.87 510300.05 W 10:00 10:15 15 60.00 44.75 15.25 61.00 1.70 10:15 10:30 15 44.75 32.63 12.13 48.50 1.81 10:30 10:45 15 60.00 44.69 15.31 61.25 1.71 10:45 11:00 15 44.69 34.31 10.38 41.50 1.52 11:00 11:15 15 34.31 25.69 8.63 34.50 1.64 11:15 11:30 15 60.00 45.06 14.94 59.75 1.66 11:30 11:45 15 45.06 35.13 9.94 39.75 1.43 11:45 12:00 15 35.13 26.44 8.69 34.75 1.61 12:00 12:15 15 60.00 45.13 14.88 59.50 1.65 12:15 12:30 15 45.13 34.06 11.06 44.25 1.62 12:45 13:00 15 34.06 25.44 8.63 34.50 1.66 Notes: 3. The test borings do not extend to the GWT. 4. Depth of the GWT and SHWT are unknown. 7. Percolation rates consist of the total drop in head divided by the elapsed time (in/hr). 8. Infiltration rates consists of the percolation rate divided by a reduction factor (in/hr). This reduction factor is calculated according the the formula in Attachment F (Michigan Method). These rates are considered to be a conservative estimate of the true infiltration rate. Please refer to the report for a thorough explanation of methodology and assumptions. Percolation and Infiltration Rates Infiltration RatesStartEnd Elapsed Time (min) Observation Time Head at Beginning of Observation Time Head at End of Observation Time Total Head Loss over Time Interval Percolation Rate Elapsed Time (min) 6. The distance from the top of the pipe to the basin invert (including pea gravel) was approximately 48 inches for TEL-INF-17-1 and 60 inches for TEL-INF-17- 1. The results of this test are not a direct reflection of the permeability (k) and are not a substitute for normal laboratory permeability testing. Infiltration RatesStartEnd 2. It is assumed that no conditions, such as a confining soil layer, exist at this site which would prevent vertical infiltration to the GWT. 5. A PVC pipe was driven approximately 6 inches below the basin invert in an attempt to force pure vertical infiltration during the test. More than likely, this only prevented horizontal infiltration to an extent, with an unknown amount of horizontal infiltration taking place during the test. Therefore, a conservative assumption was made that full horizontal infiltration took place (the water outside the pipe was in equilibrium with water inside the pipe), and the numbers acquired during the test were in fact percolation rates. These rates are shown in the pecolation column above. These values were corrected to infiltration rates using the procedure outlined in Attachment F of this report. Predicted infiltration rates can be seen in the last column in the tables above. Observation Time Head at Beginning of Observation Time Head at End of Observation Time Total Head Loss over Time Interval Percolation Rate ATTACHMENT E ATTACHMENT F Michigan Method – Soil Infiltration Testing ATTACHMENT F Appendix E Soil Infiltration Testing Protocol Purpose of this Protocol The soil infiltration testing protocol describes evaluation and field testing procedures to determine if infiltration BMPs are suitable at a site, as well as to obtain the required data for infiltration BMP design. When to Conduct Testing The Site Design Process for LID, outlined in Chapter 5 of this manual, describes a process for site development and application of nonstructural and structural BMPs. It is recommended that soil evaluation and investigation be conducted following development of a concept plan or early in the development of a preliminary plan. Who Should Conduct Testing Soil evaluation and investigation may be conducted by soil scientists, local health department sanitarians, design engineers, professional geologists, and other qualified professionals and technicians. The stormwater designer is strongly encouraged to directly observe the testing process to obtain a first-hand understanding of site conditions. Importance of Stormwater BMP Areas Sites are often defined as unsuitable for infiltration BMPs and soil-based BMPs due to proposed grade changes (excessive cut or fill) or lack of suitable areas. Many sites will be constrained and unsuitable for infil- tration BMPs. However, if suitable areas exist, these areas should be identified early in the design process and should not be subject to a building program that precludes infiltration BMPs. Full build-out of site areas otherwise deemed to be suitable for infiltration should not provide an exemption or waiver for adequate storm- water volume control or groundwater recharge. Safety As with all field work and testing, attention to all appli- cable Occupational Safety and Health Administration (OSHA) regulations and local guidelines related to earthwork and excavation is required. Digging and excavation should never be conducted without adequate notification through the Michigan One Call system (Miss Dig www.missdig.net or 1-800-482-7171 ). Exca- vations should never be left unsecured and unmarked, and all applicable authorities should be notified prior to any work. Infiltration Testing: A Multi-Step Process Infiltration testing is a four-step process to obtain the necessary data for the design of the storm water manage- ment plan. The four steps include: 1. Background evaluation • Based on available published and site specific data • Includes consideration of proposed development plan Used to identify potential BMP locations and testing locations • Prior to field work (desktop) 2. Test pit (deep hole) observations • Includes multiple testing locations • Provides an understanding of sub-surface conditions • Identifies limiting conditions 3. Infiltration testing • Must be conducted onsite • Different testing methods available 4. Design considerations • Determine suitable infiltration rate for design calculations • Consider BMP drawdown • Consider peak rate attenuation ATTACHMENT F Step 1. Background evaluation Prior to performing testing and developing a detailed site plan, existing conditions at the site should be inven- toried and mapped including, but not limited to: • Existing mapped soils and USDA Hydrologic Soil Group classifications. • Existing geology, including depth to bedrock, karst conditions, or other features of note. • Existing streams (perennial and intermittent, including intermittent swales), water bodies, wetlands, hydric soils, floodplains, alluvial soils, stream classifications, headwaters, and first order streams. • Existing topography, slope, drainage patterns, and watershed boundaries. • Existing land use conditions. • Other natural or man-made features or conditions that may impact design, such as past uses of site, existing nearby structures (buildings, walls), abandoned wells, etc. • A concept plan or preliminary layout plan for development should be evaluated, including: 0 Preliminary grading plan and areas of cut and fill, o Location of all existing and proposed water supply sources and wells, o Location of all former, existing, and proposed onsite wastewater systems, 0 Location of other features of note such as utility rights-of-way, water and sewer lines, etc., o Existing data such as structural borings, and o Proposed location of development features (buildings, roads, utilities, walls, etc.). In Step 1, the designer should determine the potential location of infiltration BMPs. The approximate location of these BMPs should be on the proposed development plan and serve as the basis for the location and number of tests to be performed onsite. Important: If the proposed development is located on areas that may otherwise be a suitable BMP location, or if the proposed grading plan is such that potential BMP locations are eliminated, the designer is strongly encouraged to revisit the proposed layout and grading plan and adjust the development plan as necessary. Full build-out of areas suitable for infiltration BMPs should not preclude the use of BMPs for runoff volume reduc- tion and groundwater recharge. Step 2. Test pits (deep holes) A test pit (deep hole) allows visual observation of the soil horizons and overall soil conditions both hori- zontally and vertically in that portion of the site. An extensive number of test pit observations can be made across a site at a relatively low cost and in a short time period. The use of soil borings as a substitute for test pits is strongly discouraged, as visual observation is narrowly limited in a soil boring and the soil horizons cannot be observed in-situ, but must be observed from the extracted borings. A test pit (deep hole) consists of a backhoe-excavated trench, 2Y2-3 feet wide, to a depth of 6-7Y2 feet, or until bedrock or fully saturated conditions are encountered. The trench should be benched at a depth of 2-3 feet for access and/or infiltration testing. At each test pit, the following conditions are to be noted and described. Depth measurements should be described as depth below the ground surface: • Soil horizons (upper and lower boundary), • Soil texture, structure, and color for each horizon, • Color patterns (mottling) and observed depth, • Depth to water table, • Depth to bedrock, • Observance of pores or roots (size, depth), • Estimated type and percent coarse fragments, • Hardpan or limiting layers, • Strike and dip of horizons (especially lateral direction of flow at limiting layers), and • Additional comments or observations. The Sample Soil Log Form at the end of this protocol may be used for documenting each test pit. At the designer's discretion, soil samples may be collected at various horizons for additional analysis. Following testing, the test pits should be refilled with the original soil and the topsoil replaced. A test pit should never be accessed if soil conditions are unsuitable or unstable for safe entry, or if site constraints preclude entry. OSHA regulations should always be observed. LID Manual fol' Michigan -Appendix E Page 438 ATTACHMENT F It is important that the test pit provide information related to conditions at the bottom of the proposed infiltration BMP. If the BMP depth will be greater than 90 inches below existing grade, deeper excavation of the test pit will be required. The designer is cautioned regarding the proposal of systems that are significantly deeper than the existing topography, as the suitability for infiltration is likely to decrease. The design engineer is encouraged to consider reducing grading and earth- work as needed to reduce site disturbance and provide greater opportunity for stormwater management. The number of test pits varies depending on site condi- tions and the proposed development plan. General guidelines are as follows: • For single-family residential subdivisions with on-lot infiltration BMPs, one test pit per lot is recommended, preferably within 100 feet of the proposed BMP area. • For multi-family and high-density residential developments, one test pit per BMP area or acre is recommended. • For large infiltration areas (basins, commercial, institutional, industrial, and other proposed land uses), multiple test pits should be evenly distributed at the rate of four to six pits per acre of BMP area. The recommendations above are guidelines. Additional tests should be conducted if local conditions indicate significant variability in soil types, geology, water table levels, depth and type of bedrock, topography, etc. Simi- larly, uniform site conditions may indicate that fewer test pits are required. Excessive testing and disturbance of the site prior to construction is not recommended. Step 3. Infiltration tests A variety of field tests exists for determining the infil- tration capacity of a soil. Laboratory tests are not recommended, as a homogeneous laboratory sample does not represent field conditions. Infiltration te~ts should be conducted in the field. Infiltration tests should not be conducted in the rain, within 24 hours of significant rainfall events (>0.5 inches), or when the temperature is below freezing. At least one test should be conducted at the proposed bottom elevation of an infiltration BMP, and a mini- mum of two tests per test pit are recommended. Based on observed field conditions, the designer may elect to modify the proposed bottom elevation of a BMP. Person- nel conducting infiltration tests should be prepared to adjust test locations and depths depending on observed conditions. Methodologies discussed in this protocol include: • Double-ring infiltrometer tests. • Percolation tests (such as for onsite wastewater systems). There are differences between the two methods. A double-ring infiltrometer test estimates the vertical movement of water through the bottom of the test area. The outer ring helps to reduce the lateral movement of water in the soil from the inner ring. A percolation test allows water movement through both the bottom and sides of the test area. For this reason, the measured rate of water level drop in a percolation test must be adjusted to represent the discharge that is occurring on both the bottom and sides of the percolation test hole. Other testing methodologies and standards that are available but not discussed in detail in this protocol include (but are not limited to): • Constant head double-ring infiltrometer. • Testing as described in the Maryland Stormwater Manual, Appendix D .1, using five-inch diameter casing. • ASTM 2003 Volume 4.08, Soil and Rock (I): Designation D 3385-03, Standard Test Method for Infiltration Rate of Soils in Field Using a Double- Ring Infiltrometer. • ASTM 2002 Volume 4.09, Soil and Rock (II): Designation D 5093-90, Standard Test Method for Field Measurement of Infiltration Rate Using a Double-Ring Infiltrometer with a Sealed-Inner Ring. • Guelph permeameter. • Constant head permeameter (Amoozemeter). LID Manual for Michigan -Appendix E Page 439 ATTACHMENT F Methodology for double-ring infiltrometer field test A double-ring infiltrometer consists of two concentric metal rings. The rings are driven into the ground and filled with water. The outer ring helps to prevent diver- gent flow. The drop-in water level or volume in the inner ring is used to calculate an infiltration rate. The infiltration rate is the amount of water per surface area and time unit which penetrates the soils. The diameter of the inner ring should be approximately 50-70 percent of the diameter of the outer ring, with a minimum inner ring size of four inches. Double-ring infiltrometer test- ing equipment designed specifically for that purpose may be purchased. However, field testing for storm- water BMP design may also be conducted with readily available materials. Equipment for double-ring infiltrometer test: Two concentric cylinder rings six inches or greater in height. Inner ring diameter equal to 50-70 percent of outer ring diameter (i.e., an eight-inch ring and a 12-inch ring). Material typically available at a hardware store may be acceptable. Water supply, • Stopwatch or timer, • Ruler or metal measuring tape, • Flat wooden board for driving cylinders uniformly into soil, • Rubber mallet, and • Log sheets for recording data. Procedure for double-ring infiltrometer test • Prepare level testing area. • Place outer ring in place; place flat board on ring and drive ring into soil to a minimum depth of two inches. • Place inner ring in center of outer ring; place flat board on ring and drive ring into soil a minimum of two inches. The bottom rim of both rings should be at the same level. • The test area should be presoaked immediately prior to testing. Fill both rings with water to water level indicator mark or rim at 30-minute intervals for one hour. The minimum water depth should be four inches. The drop in the water level during the last 30 minutes of the presoaking period should be applied to the following standard to determine the time interval between readings: 0 If water level drop is two inches or more, use IO-minute measurement intervals. 0 If water level drop is less than two inches, use 30-minute measurement intervals. • Obtain a reading of the drop in water level in the center ring at appropriate time intervals. After each reading, refill both rings to water level indicator mark or rim. Measurement to the water level in the center ring should be made from a fixed reference point and should continue at the interval determined until a minimum of eight readings are completed or until a stabilized rate of drop is obtained, whichever occurs first. A stabilized rate of drop means a difference of 14 inch or less of drop between the highest and lowest readings of four consecutive readings. • The drop that occurs in the center ring during the final period or the average stabilized rate, expressed as inches per hour, should represent the infiltration rate for that test location. Methodology for percolation test Equipment for percolation test • Post hole digger or auger, • Water supply, • Stopwatch or timer, • Ruler or metal measuring tape, • Log sheets for recording data, • Knife blade or sharp-pointed instrument (for soil scarification), • Course sand or fine gravel, and • Object for fixed-reference point during measurement (nail, toothpick, etc.). LlD Manual for Michigan -Appendix E Page 440 ATTACHMENT F Procedure for percolation test This percolation test methodology is based largely on the criteria for onsite sewage investigation of soils. A 24-hour pre-soak is generally not required as infiltra- tion systems, unlike wastewater systems, will not be continuously saturated. • Prepare level testing area. • Prepare hole having a uniform diameter of 6-10 inches and a depth of 8-12 inches. The bottom and sides of the hole should be scarified with a knife blade or sharp-pointed instrument to completely remove any smeared soil surfaces and to provide a natural soil interface into which water may percolate. Loose material should be removed from the hole. • (Optional) Two inches of coarse sand or fine gravel may be placed in the bottom of the hole to protect the soil from scouring and clogging of the pores. • Test holes should be presoaked immediately prior to testing. Water should be placed in the hole to a minimum depth of six inches over the bottom and readjusted every 30 minutes for one hour. • The drop in the water level during the last 30 minutes of the final presoaking period should be applied to the following standard to determine the time interval between readings for each percolation hole: 0 If water remains in the hole, the interval for readings during the percolation test should be 30 minutes. 0 If no water remains in the hole, the interval for readings during the percolation test may be reduced to 10 minutes. • After the final presoaking period, water in the hole should again be adjusted to a minimum depth of six inches and readjusted when necessary after each reading. A nail or marker should be placed at a fixed reference point to indicate the water refill level. The water level depth and hole diameter should be recorded. • Measurement to the water level in the individual percolation holes should be made from a fixed reference point and should continue at the interval determined from the previous step for each individual percolation hole until a minimum of eight readings are completed or until a stabilized rate of drop is obtained, whichever occurs first. A stabilized rate of drop means a difference of V<i inch or less of drop between the highest and lowest readings of four consecutive readings. • The drop that occurs in the percolation hole during the final period, expressed as inches per hour, should represent the percolation rate for that test location. • The average measured rate must be adjusted to account for the discharge of water from both the sides and bottom of the hole and to develop a representative infiltration rate. The average/ final percolation rate should be adjusted for each percolation test according to the following formula: Infiltration Rate= (Percolation Rate)/(Reduction Factor) Where the Reduction Factor is given by**: With: R _ 2d1 -D,d + 1 !-DIA d 1 =Initial Water Depth (in.) D,d =Average/Final Water Level Drop (in.) DIA= Diameter of the Percolation Hole (in.) The percolation rate is simply divided by the reduc- tion factor as calculated above or shown in Table E.1 below to yield the representative infiltration rate. In most cases, the reduction factor varies from about two to four depending on the percolation hole dimensions and water level drop -wider and shallower tests have lower reduction factors because proportionately less water exfiltrates through the sides. ** The area reduction factor accounts for the exfiltra- tion occurring through the sides of percolation hole. It assumes that the percolation rate is affected by the depth of water in the hole and that the percolating suiface of the hole is in uniform soil. If there are significant problems with either of these assumptions then other adjustments may be necessary. LID Manual for Michigan -Append.ix E Page 441 ATTACHMENT F Step 4. Use design considerations provided in the infiltration BMP. Table E.1 Sample Percolation Rate Adjustments 6 8 6 10 6 8 8 10 6 8 10 10 0.1 3.0 0.5 2.9 2.5 2.6 0.1 3.7 0.5 3.6 2.5 3.3 0.1 4.3 0.5 4.3 2.5 3.9 0.1 2.5 0.5 2.4 2.5 2:r 0.1 3.0 0.5 2.9 2.5 2.7 0.1 3.5 0.5 3.4 2.5 3.2 0.1 2.2 0.5 2.2 2.5 2.0 0.1 2.6 0.5 2.6 2.5 2.4 0.1 3.0 0.5 3.0 2.5 2.8 LID Manual for Michigan -Appendix E Page 442 ATTACHMENT F Additional Potential Testing -Bulk Density Bulk density tests measure the level of compaction of a soil, which is an indicator of a soil's ability to absorb rain- fall. Developed and urbanized sites often have very high bulk densities and, therefore, possess limited ability to absorb rainfall (and have high rates of stormwater runoff). Vegetative and soil improvement programs can lower the soil bulk density and improve the site's ability to absorb rainfall and reduce runoff. Macropores occur primarily in the upper soil horizons and are formed by plant roots (both living and decaying), soil fauna such as insects, the weathering processes caused by movement of water, the freeze-thaw cycle, soil shrinkage due to desiccation of clays, chemical processes, and other mechanisms. These macropores provide an important mechanism for infiltration prior to development, extending vertically and horizontally for considerable distances. It is the intent of good engineering and design practice to maintain these macropores when installing infiltration BMPs as much as possible. Bulk density tests can help determine the relative compaction of soils before and after site disturbance and/or restoration and should be used at the discretion of the designer/reviewer. Soi/ Test Pit Lag Sheet Project: Name: Location: Test Pit# Horizon Depth (In.) Color REDOX FEATURES Abundance Few ........ < 2% Common .. 2-20% Many ...... > 20% Contrast faint Red ox Features hue & chroma of matrix and redox are closely related. distinct matrix & redox features vary 1 -2 units of hue and several unites of chroma & value. prominent Matrix & redox features Texture vary several units in hue, value & chroma HORIZONS 0 -organic layers of decaying plant and animal tissue (must be greater than 12- 18% organic carbon, excluding live roots). A (topsoil) -mineral horizon at or near the surface in which an accumulation of humified organic matter is mixed with the mineral material. Date: Soil Series: Other: Notes Boundary (if applicable) COARSE FRAGMENTS(% of profile) 15-35% 35-65% >65% gravelly very gravelly extremely gravelly channery very channery extremely channery cobbly very cobbly extremely cobbly flaggy very flaggy extremely flaggy stony very stony extremely stony BOUNDARY Distinctness abrupt ... < 1" (thick) gradual .. 2.5 -5" c/ear ..... 1 -2.5" diffuse .... > 5 Topography smooth -boundary is nearly level wavy-pockets with width > than depth irregular -pockets with depth > than width B (subsoil) -mineral horizon with evidence of pedogenesis or llluviation (movement into the horizon). C (substratum) -the un-weathered geologic material the soil formed in. Shows little or no sign of soil formation. E -mineral horizon which the main feature is loss of silicate clay, iron, aluminum. Must be underlain by a B {alluvial) horizon. l...ilD Manual fo11Michigan -Appendix B Page 443 ATTACHMENT F