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Home My WebLink AboutRS_Geotechnical_Engineering_Report_Migizi_080518_v1.pdf Geotechnical Engineering Report Washington State Auto Dealers Association 621 SW Grady Way Renton, Washington 98057 May 18, 2018 prepared for: Sitts & Hill Engineers, Inc. Attention: Kathy Hargrave 4815 Center Street Tacoma, Washington 98409 prepared by: Migizi Group, Inc. PO Box 44840 Tacoma, Washington 98448 (253) 537-9400 MGI Project P1258-T18 i TABLE OF CONTENTS Page No. 1.0 SITE AND PROJECT DESCRIPTION............................................................................................... 1 2.0 EXPLORATORY METHODS ............................................................................................................. 2 2.1 Test Pit Procedures ................................................................................................................ 2 3.0 SITE CONDITIONS ............................................................................................................................ 3 3.1 Surface Conditions ................................................................................................................. 3 3.2 Soil Conditions ....................................................................................................................... 3 3.3 Groundwater Conditions ...................................................................................................... 3 3.4 Seismic Conditions ................................................................................................................. 4 3.5 Liquefaction Potential ............................................................................................................ 4 4.0 CONCLUSIONS AND RECOMMENDATIONS ............................................................................ 4 4.1 Site Preparation ...................................................................................................................... 5 4.2 Asphalt Pavement .................................................................................................................. 7 4.3 Structural Fill .......................................................................................................................... 8 5.0 RECOMMENDED ADDITIONAL SERVICES ................................................................................ 9 6.0 CLOSURE ........................................................................................................................................... 10 List of Tables Table 1. Approximate Locations and Depths of Explorations ............................................................................. 2 List of Figures Figure 1. Topographic and Location Map Figure 2. Site and Exploration Plan APPENDIX A Soil Classification Chart and Key to Test Data .................................................................................................. A-1 Logs of Test Pits TP-1 through TP-3 .......................................................................................................... A-2…A-4 Page 1 of 10 MIGIZI GROUP, INC. PO Box 44840 PHONE (253) 537-9400 Tacoma, Washington 98448 FAX (253) 537-9401 May 18, 2018 Sitts & Hill Engineers, Inc. 4815 Center Street Tacoma, Washington 98409 Attention: Kathy Hargrave Subject: Geotechnical Engineering Report Washington State Auto Dealers Association 621 SW Grady Way Renton, Washington 98057 MGI Project P1258-T18 Dear Ms. Hargrave: Migizi Group, Inc. (MGI) is pleased to submit this report describing the results of our geotechnical engineering evaluation for a proposed asphalt parking lot expansion to be located in a vacant lot immediately south of the existing parking lot for the Washington State Auto Dealers Association (WSADA) building in Renton, Washington. A previous Geotechnical Letter Report was prepared for the existing facilities by E3RA, Inc. dated April 4, 2012. This report has been prepared for the exclusive use of Sitts & Hill Engineers, Inc., and their consultants, for specific application to this project, in accordance with generally accepted geotechnical engineering practice. 1.0 SITE AND PROJECT DESCRIPTION The project site is located along the south side of SW Grady Way in a commercial area just north of I-405 in Renton, Washington, as shown on the enclosed Topographic and Location Map (Figure 1). The project area is rectangularly-shaped, encompassing a total area of 0.33-acres. The site is undeveloped and lies in the ancestral floodplain of the Black and Green Rivers before the partial draining of Lake Washington in 1916. The site is bordered by SW 12th St to the south, asphalt parking lots to the north and east, and Bell Electronics to the west. It is our understanding that the project area will be stripped, paved, and connected to the existing WSADA parking area to the north. The new parking lot will be at or near existing grade. Sitts & Hill Engineers, Inc. – WSADA, 621 SW Grady Way, Renton, WA May 18, 2018 Geotechnical Engineering Report P1258-T18 Migizi Group, Inc. Page 2 of 10 2.0 EXPLORATORY METHODS We explored surface and subsurface conditions at the project site on April 27, 2018. Our exploration and evaluation program comprised the following elements: • Surface reconnaissance of the site; • Three test pit explorations (designated TP-1, TP-2, and TP-3) advanced on April 27, 2018; and • A review of published geologic and seismologic maps and literature. Table 1 summarizes the approximate functional locations and termination depths of our subsurface explorations, and Figure 2 depicts their approximate relative locations. The following sections describe the procedures used for excavation of the test pits. TABLE 1 APPROXIMATE LOCATIONS AND DEPTHS OF EXPLORATIONS Exploration Functional Location Termination Depth (feet) TP-1 TP-2 TP-3 Roughly central to the western third of the property Roughly the middle-most point of the property Roughly central to the eastern third of the property 10 3 10 The specific numbers and locations of our explorations were selected in relation to the existing site features, under the constraints of surface access, underground utility conflicts, and budget considerations. It should be realized that the explorations performed and utilized for this evaluation reveal subsurface conditions only at discrete locations across the project site and that actual conditions in other areas could vary. Furthermore, the nature and extent of any such variations would not become evident until additional explorations are performed or until construction activities have begun. If significant variations are observed at that time, we may need to modify our conclusions and recommendations contained in this report to reflect the actual site conditions. 2.1 Test Pit Procedures Our exploratory test pits were excavated with a rubber-tracked mini-excavator operated by an excavation contractor under subcontract to MGI. An engineering geologist from our firm observed the test pit excavations, collected soil samples, and logged the subsurface conditions. The enclosed test pit logs indicate the vertical sequence of soils and materials encountered in our test pits, based on our field classifications. Where a soil contact was observed to be gradational or undulating, our logs indicate the average contact depth. We estimated the relative density and consistency of the in-situ soils by means of the excavation characteristics and the stability of the test pit sidewalls. Our logs also indicate the approximate depths of any sidewall caving or groundwater seepage observed in the test pits. The soils were classified visually in general accordance with the system described in Figure A-1, which includes a key to the exploration logs. Summary logs of our explorations are included as Figure A-2 through A-4. Sitts & Hill Engineers, Inc. – WSADA, 621 SW Grady Way, Renton, WA May 18, 2018 Geotechnical Engineering Report P1258-T18 Migizi Group, Inc. Page 3 of 10 3.0 SITE CONDITIONS The following sections present our observations, measurements, findings, and interpretations regarding surface, soil, groundwater, and infiltration conditions. 3.1 Surface Conditions As previously indicated, the project site consists of a rectangularly-shaped, 0.33-acre commercial property situated near the intersection of I-405 and WA-167 in Renton. The property lies in the ancestral floodplain of the Black and Green Rivers before the partial draining of Lake Washington in 1916. The site is undeveloped and topographically flat, with the exception of a dry, empty pit in the southeastern corner of the property approximately 4 feet deep and 20 feet in length. Site vegetation is limited to sparse grass and spiky bushes lining the edges of the property, in addition to a line of deciduous and evergreen trees on the eastern boundary near an existing parking lot. No hydrologic features were observed on site, such as seeps, springs, ponds and streams. 3.2 Soil Conditions We observed subgrade conditions in three test pits across the property. These explorations revealed structural fill and construction-related debris such as concrete, asphalt, and brick in a dense condition down to approximately 2½ to 4½ feet below the surface. This material overlies dense native alluvial flood plain deposits comprised of fine sand, silty sand, silt and gravel. Native soils were all poorly consolidated and oversaturated. While excavating TP-2, a block of concrete prevented further excavation beyond 3 feet deep and the test pit was terminated. In the Geologic Map of the Renton Quadrangle, King County, Washington, as prepared by the Department of the Interior United States Geological Survey (USGS) (1965), the project site is mapped as containing Qaw, or Quaternary Alluvium associated with the flood plains of the White and Green Rivers. The upper part of these deposits are mostly clayey silt and fine sand, locally peaty, being 10 to 20 feet thick near Kent, thickening to 30 to 40 feet near Tukwila. The lower part of these deposits are mostly medium and coarse sand and can reach thicknesses of up to 75 feet. The National Cooperative Soil Survey (NCSS) for the King County Area classifies soils onsite as Ur-Urban Land, surrounded by minor soil units of sand and silt loam. This soil series reportedly formed along alluvial flood plains and is comprised of sandy loam, silt loam, silty clay loam and sand. Our subsurface explorations generally correspond with the site classifications prepared by the USGS and NCSS. The enclosed exploration logs (Appendix A) provide a detailed description of the soil strata encountered in our subsurface explorations. 3.3 Groundwater Conditions We encountered groundwater seepage in two of our three subsurface explorations, at a depth of 4 to 4½ feet below existing grade. Given the fact that our explorations were performed just outside of Sitts & Hill Engineers, Inc. – WSADA, 621 SW Grady Way, Renton, WA May 18, 2018 Geotechnical Engineering Report P1258-T18 Migizi Group, Inc. Page 4 of 10 what is generally considered the rainy season (November 1 to March 31), we do not anticipate that groundwater will rise much higher than that which we observed. Groundwater levels will fluctuate with localized geology and precipitation. 3.4 Seismic Conditions Based on our analysis of subsurface exploration logs and our review of published geologic maps, we interpret the onsite soil conditions to generally correspond with site class E, as defined by Table 30.2-1 in ASCE 7, per the 2015 International Building Code (IBC). Using 2015 IBC information on the USGS Design Summary Report website, Risk Category I/II/III seismic parameters for the site are as follows: Ss = 1.442 g SMS = 1.298 g SDS = 0.865 g S1 = 0.538 g SM1 = 1.292 g SD1 = 0.862 g Using the 2015 IBC information, MCER Response Spectrum Graph on the USGS Design Summary Report website, Risk Category I/II/III, Sa at a period of 0.2 seconds is 1.30 g and Sa at a period of 1.0 seconds is 1.30 g. The Design Response Spectrum Graph from the same website, using the same IBC information and Risk Category, Sa at a period of 0.2 seconds is 0.86 g and Sa at a period of 1.0 seconds is 0.86 g. 3.5 Liquefaction Potential Liquefaction is a sudden increase in pore water pressure and a sudden loss of soil shear strength caused by shear strains, as could result from an earthquake. Research has shown that saturated, loose, fine to medium sands with a fines (silt and clay) content less than about 20 percent are most susceptible to liquefaction. Poorly consolidated soils encountered below the water table (a depth of 4 to 4½ feet) present a moderate to severe risk for soil liquefaction. Recommendations for pavement section design and construction contained within this report helps mitigate some of this risk, but the risk for soil liquefaction and resultant post-construction settlement should still be considered moderate across the project area in the instance of a large-scale seismic event. 4.0 CONCLUSIONS AND RECOMMENDATIONS It is our understanding that the project area will be stripped, paved, and connected to the existing WSADA parking area to the north. The new parking lot will be at or near existing grade. We offer these recommendations: • Feasibility: Based on our field explorations, research, and evaluations, the proposed pavements appear feasible from a geotechnical standpoint. • Pavement Sections: We recommend a conventional pavement section comprised of an asphalt concrete pavement over a crushed rock base course over a properly prepared (compacted) subgrade or a granular subbase. Sitts & Hill Engineers, Inc. – WSADA, 621 SW Grady Way, Renton, WA May 18, 2018 Geotechnical Engineering Report P1258-T18 Migizi Group, Inc. Page 5 of 10 All soil subgrades should be thoroughly compacted, then proof-rolled with a loaded dump truck or heavy compactor. Any localized zones of yielding subgrade disclosed during this proof-rolling operation should be over excavated to an additional maximum depth of 12 inches and replaced with a suitable structural fill material. The following sections of this report present our specific geotechnical conclusions and recommendations concerning site preparation, spread footings, slab-on-grade floors, asphalt pavement, and structural fill. The Washington State Department of Transportation (WSDOT) Standard Specifications and Standard Plans cited herein refer to WSDOT publications M41-10, Standard Specifications for Road, Bridge, and Municipal Construction, and M21-01, Standard Plans for Road, Bridge, and Municipal Construction, respectively. 4.1 Site Preparation Preparation of the project site should involve erosion control, temporary drainage, clearing, stripping, excavations, cutting, subgrade compaction, and filling. Erosion Control: Before new construction begins, an appropriate erosion control system should be installed. This system should collect and filter all surface water runoff through silt fencing. We anticipate a system of berms and drainage ditches around construction areas will provide an adequate collection system. Silt fencing fabric should meet the requirements of WSDOT Standard Specification 9-33.2 Table 3. In addition, silt fencing should embed a minimum of 6 inches below existing grade. An erosion control system requires occasional observation and maintenance. Specifically, holes in the filter and areas where the filter has shifted above ground surface should be replaced or repaired as soon as they are identified. Temporary Drainage: We recommend intercepting and diverting any potential sources of surface or near-surface water within the construction zones before stripping begins. Because the selection of an appropriate drainage system will depend on the water quantity, season, weather conditions, construction sequence, and contractor's methods, final decisions regarding drainage systems are best made in the field at the time of construction. Based on our current understanding of the construction plans, surface and subsurface conditions, we anticipate that curbs, berms, or ditches placed around the work areas will adequately intercept surface water runoff. Clearing and Stripping: After surface and near-surface water sources have been controlled, sod, topsoil, and root-rich soil should be stripped from the site. The proposed work area is currently paved and no stripping will be necessary. Site Excavations: Based on our explorations, we expect that excavations will encounter loose/soft to medium dense/stiff silty, sandy alluvial soils which can be easily excavated using standard excavation equipment. Sitts & Hill Engineers, Inc. – WSADA, 621 SW Grady Way, Renton, WA May 18, 2018 Geotechnical Engineering Report P1258-T18 Migizi Group, Inc. Page 6 of 10 Dewatering: We encountered groundwater seepage in two of three of our explorations at a depth of 4 to 4½ feet below existing grade. Given the fact that our explorations were performed just outside of what is generally considered the rainy season (November 1 to March 31), we do not anticipate that groundwater will rise much higher than that which we observed. If groundwater is encountered in shallower excavations, we anticipate that an internal system of ditches, sumpholes, and pumps will be adequate to temporarily dewater most excavations. For deeper excavations well below the water table, expensive dewatering equipment, such as well points, may need to be utilized in order to adequately dewater excavations. Temporary Cut Slopes: All temporary soil slopes associated with site cutting or excavations should be adequately inclined to prevent sloughing and collapse. Temporary cut slopes in site soils should be no steeper than 1½H:1V, and should conform to Washington Industrial Safety and Health Act (WISHA) regulations. Subgrade Compaction: Exposed subgrades for the foundations of the planned additions should be compacted to a firm, unyielding state before new concrete or fill soils are placed. Any localized zones of looser granular soils observed within a subgrade should be compacted to a density commensurate with the surrounding soils. In contrast, any organic, soft, or pumping soils observed within a subgrade should be overexcavated and replaced with a suitable structural fill material. Site Filling: Our conclusions regarding the reuse of onsite soils and our comments regarding wet- weather filling are presented subsequently. Regardless of soil type, all fill should be placed and compacted according to our recommendations presented in the Structural Fill section of this report. Specifically, building pad fill soil should be compacted to a uniform density of at least 95 percent (based on ASTM:D-1557). Onsite Soils: We offer the following evaluation of these onsite soils in relation to potential use as structural fill: • Fill: The fill that overlies the site contains construction debris and some organic material, so is not reusable as structural fill. If areas of debris and organic-free fill are encountered during the construction process and are thought to be reusable, we recommend that MGI evaluate their potential for reuse. • Alluvial Silt and Silty Sand: The alluvial silty sand that underlies the site is very moisture sensitive and will be difficult or impossible to reuse during most weather conditions. The majority of this soil type is currently above the optimum moisture content and will not compact adequately unless extensively aerated. • Alluvial Fine to Medium Sand with Gravel: Where encountered, and if properly segregated from its siltier counterpart, the clean native fine sands are a possible source of structural fill. This material type is relatively impervious to moisture content variations and can be reused in most weather conditions. Sitts & Hill Engineers, Inc. – WSADA, 621 SW Grady Way, Renton, WA May 18, 2018 Geotechnical Engineering Report P1258-T18 Migizi Group, Inc. Page 7 of 10 Permanent Slopes: All permanent cut slopes and fill slopes should be adequately inclined to reduce long-term raveling, sloughing, and erosion. We generally recommend that no permanent slopes be steeper than 2H:1V. For all soil types, the use of flatter slopes (such as 2½H:1V) would further reduce long-term erosion and facilitate revegetation. Slope Protection: We recommend that a permanent berm, swale, or curb be constructed along the top edge of all permanent slopes to intercept surface flow. Also, a hardy vegetative groundcover should be established as soon as feasible, to further protect the slopes from runoff water erosion. Alternatively, permanent slopes could be armored with quarry spalls or a geosynthetic erosion mat. 4.2 Asphalt Pavement Since asphalt pavements will be used across much of the project site, we offer the following comments and recommendations for pavement design and construction. Subgrade Preparation: We recommend a conventional pavement section comprised of an asphalt concrete pavement over a crushed rock base course over a properly prepared (compacted) subgrade or a granular subbase. All soil subgrades should be thoroughly compacted, then proof-rolled with a loaded dump truck or heavy compactor. Any localized zones of yielding subgrade disclosed during this proof-rolling operation should be over excavated to an additional maximum depth of 12 inches and replaced with a suitable structural fill material. All structural fill should be compacted according to our recommendations given in the Structural Fill section. Specifically, the upper 2 feet of soils underlying pavement section should be compacted to at least 95 percent (based on ASTM D-1557), and all soils below 2 feet should be compacted to at least 90 percent. Pavement Materials: For the base course, we recommend using imported crushed rock, such as "Crushed Surfacing Top Course” per WSDOT Standard Specification 9-03.9(3). If a subbase course is needed, we recommend using imported, clean, well-graded sand and gravel such as “Ballast” or “Gravel Borrow” per WSDOT Standard Specifications 9-03.9(1) and 9-03.14, respectively. Conventional Asphalt Sections: A conventional pavement section typically comprises an asphalt concrete pavement over a crushed rock base course. We recommend using the following conventional pavement sections: Minimum Thickness Section Automobile Parking Areas Driveways and Areas Subject to Truck Traffic Asphalt Concrete Pavement 2 inches 3 inches Crushed Rock Base 4 inches 6 inches Compaction and Observation: All subbase and base course material should be compacted to at least 95 percent of the Modified Proctor maximum dry density (ASTM D-1557), and all asphalt concrete should be compacted to at least 92 percent of the Rice value (ASTM D-2041). We recommend that an MGI representative be retained to observe the compaction of each course before any overlying Sitts & Hill Engineers, Inc. – WSADA, 621 SW Grady Way, Renton, WA May 18, 2018 Geotechnical Engineering Report P1258-T18 Migizi Group, Inc. Page 8 of 10 layer is placed. For the subbase and pavement course, compaction is best observed by means of frequent density testing. For the base course, methodology observations and hand-probing are more appropriate than density testing. Pavement Life and Maintenance: No asphalt pavement is maintenance-free. The above described pavement sections present our minimum recommendations for an average level of performance during a 20-year design life, therefore, an average level of maintenance will likely be required. Furthermore, a 20-year pavement life typically assumes that an overlay will be placed after about 10 years. Thicker asphalt and/or thicker base and subbase courses would offer better long-term performance but would cost more initially; thinner courses would be more susceptible to “alligator” cracking and other failure modes. As such, pavement design can be considered a compromise between a high initial cost and low maintenance costs versus a low initial cost and higher maintenance costs. 4.3 Structural Fill The term "structural fill" refers to any material placed under foundations, retaining walls, slab-on- grade floors, sidewalks, pavements, and other structures. Our comments, conclusions, and recommendations concerning structural fill are presented in the following paragraphs. Materials: Typical structural fill materials include clean sand, gravel, pea gravel, washed rock, crushed rock, well-graded mixtures of sand and gravel (commonly called "gravel borrow" or "pit- run"), and miscellaneous mixtures of silt, sand, and gravel. Recycled asphalt, concrete, and glass, which are derived from pulverizing the parent materials, are also potentially useful as structural fill in certain applications. Soils used for structural fill should not contain any organic matter or debris, nor any individual particles greater than about 6 inches in diameter. Fill Placement: Clean sand, gravel, crushed rock, soil mixtures, and recycled materials should be placed in horizontal lifts not exceeding 8 inches in loose thickness, and each lift should be thoroughly compacted with a mechanical compactor. Compaction Criteria: Using the Modified Proctor test (ASTM:D-1557) as a standard, we recommend that structural fill used for various onsite applications be compacted to the following minimum densities: Fill Application Minimum Compaction Asphalt pavement base Asphalt pavement subgrade (upper 2 feet) Asphalt pavement subgrade (below 2 feet) 95 percent 95 percent 90 percent Sitts & Hill Engineers, Inc. – WSADA, 621 SW Grady Way, Renton, WA May 18, 2018 Geotechnical Engineering Report P1258-T18 Migizi Group, Inc. Page 9 of 10 Subgrade Observation and Compaction Testing: Regardless of material or location, all structural fill should be placed over firm, unyielding subgrades prepared in accordance with the Site Preparation section of this report. The condition of all subgrades should be observed by geotechnical personnel before filling or construction begins. Also, fill soil compaction should be verified by means of in-place density tests performed during fill placement so that adequacy of soil compaction efforts may be evaluated as earthwork progresses. Soil Moisture Considerations: The suitability of soils used for structural fill depends primarily on their grain-size distribution and moisture content when they are placed. As the "fines" content (that soil fraction passing the U.S. No. 200 Sieve) increases, soils become more sensitive to small changes in moisture content. Soils containing more than about 5 percent fines (by weight) cannot be consistently compacted to a firm, unyielding condition when the moisture content is more than 2 percentage points above or below optimum. For fill placement during wet-weather site work, we recommend using "clean" fill, which refers to soils that have a fines content of 5 percent or less (by weight) based on the soil fraction passing the U.S. No. 4 Sieve. 5.0 RECOMMENDED ADDITIONAL SERVICES Because the future performance and integrity of the structural elements will depend largely on proper site preparation, drainage, fill placement, and construction procedures, monitoring and testing by experienced geotechnical personnel should be considered an integral part of the construction process. Subsequently, we recommend that MGI be retained to provide the following post-report services: • Review all construction plans and specifications to verify that our design criteria presented in this report have been properly integrated into the design; • Prepare a letter summarizing all review comments (if required); • Check all completed subgrades for footings and slab-on-grade floors before concrete is poured, in order to verify their bearing capacity; and • Prepare a post-construction letter summarizing all field observations, inspections, and test results (if required). APPROXIMATE SITE LOCATION P.O. Box 44840 Tacoma, WA 98448 Location Job Number Figure DateTitle 621 SW Grady Way Renton, Washington Topographic and Location Map 1 05/16/18 P1258-T18 APPENDIX A SOIL CLASSIFICATION CHART AND KEY TO TEST DATA LOGS OF TEST PITS CLAYEY GRAVELS, POORLY GRADED GRAVEL-SAND-CLAY MIXTURES SILTS AND CLAYSCOARSE GRAINED SOILSMore than Half > #200 sieveLIQUID LIMIT LESS THAN 50 LIQUID LIMIT GREATER THAN 50 CLEAN GRAVELS WITH LITTLE OR NO FINES GRAVELS WITH OVER 15% FINES CLEAN SANDS WITH LITTLE OR NO FINES MORE THAN HALF COARSE FRACTION IS SMALLER THAN NO. 4 SIEVE MORE THAN HALF COARSE FRACTION IS LARGER THAN NO. 4 SIEVE INORGANIC SILTS, MICACEOUS OR DIATOMACIOUS FINE SANDY OR SILTY SOILS, ELASTIC SILTS ORGANIC CLAYS AND ORGANIC SILTY CLAYS OF LOW PLASTICITY OH INORGANIC SILTS AND VERY FINE SANDS, ROCK FLOUR, SILTY OR CLAYEY FINE SANDS, OR CLAYEY SILTS WITH SLIGHT PLASTICITY CH SILTY GRAVELS, POORLY GRADED GRAVEL-SAND-SILT MIXTURES SANDS SILTS AND CLAYS Figure A-1 INORGANIC CLAYS OF LOW TO MEDIUM PLASTICITY, GRAVELLY CLAYS, SANDY CLAYS, SILTY CLAYS, LEAN CLAYS R-Value Sieve Analysis Swell Test Cyclic Triaxial Unconsolidated Undrained Triaxial Torvane Shear Unconfined Compression (Shear Strength, ksf) Wash Analysis (with % Passing No. 200 Sieve) Water Level at Time of Drilling Water Level after Drilling(with date measured) RV SA SW TC TX TV UC (1.2) WA (20) Modified California Split Spoon Pushed Shelby Tube Auger Cuttings Grab Sample Sample Attempt with No Recovery Chemical Analysis Consolidation Compaction Direct Shear Permeability Pocket Penetrometer CA CN CP DS PM PP PtHIGHLY ORGANIC SOILS TYPICAL NAMES GRAVELS ORGANIC CLAYS OF MEDIUM TO HIGH PLASTICITY, ORGANIC SILTS WELL GRADED GRAVELS, GRAVEL-SAND MIXTURES MAJOR DIVISIONS PEAT AND OTHER HIGHLY ORGANIC SOILS WELL GRADED SANDS, GRAVELLY SANDS POORLY GRADED SANDS, GRAVELLY SANDS SILTY SANDS, POORLY GRADED SAND-SILT MIXTURES CLAYEY SANDS, POORLY GRADED SAND-CLAY MIXTURES POORLY GRADED GRAVELS, GRAVEL-SAND MIXTURES SOIL CLASSIFICATION CHART AND KEY TO TEST DATA GW GP GM GC SW SP SM SC ML FINE GRAINED SOILSMore than Half < #200 sieveLGD A NNNN02 GINT US LAB.GPJ 11/4/05INORGANIC CLAYS OF HIGH PLASTICITY, FAT CLAYS CL OL MH SANDS WITH OVER 15% FINES GB S-1 GP- GM SM SP ML 0.5 2.5 4.0 10.0 (GP-GM) Gray/brown gravel with silt and sand (dense, moist) (Fill) (SM) Gray silty sand with gravel and concrete/asphalt/brick debris (dense, moist) (Fill) (SP) Blue/gray fine to medium sand with gravel (medium dense, moist) (Alluvium) (ML) Blue/gray silt (very soft, wet) (Alluvium) Moderate caving observed from 4 to 10 feet Moderate groundwater seepage observed at 4 feet The depths on the test pit logs are based on an average of measurements across the test pit and should be considered accurate to 0.5 foot. Bottom of test pit at 10.0 feet. NOTES LOGGED BY ZLL EXCAVATION METHOD Rubber Tracked Mini Excavator EXCAVATION CONTRACTOR Paulman GROUND WATER LEVELS: CHECKED BY JEB DATE STARTED 4/27/18 COMPLETED 4/27/18 AT TIME OF EXCAVATION 4.00 ft Moderate seepage AT END OF EXCAVATION --- AFTER EXCAVATION --- TEST PIT SIZEGROUND ELEVATION SAMPLE TYPENUMBERDEPTH(ft)0.0 2.5 5.0 7.5 10.0 PAGE 1 OF 1 Figure A-2 TEST PIT NUMBER TP-1 CLIENT Sitts & Hill Engineers, Inc. PROJECT NUMBER P1258-T18 PROJECT NAME Washington State Auto Dealers Association PROJECT LOCATION 621 SW Grady Way, Renton, WA COPY OF GENERAL BH / TP LOGS - FIGURE.GDT - 5/16/18 11:29 - C:\USERS\JESSICA\DESKTOP\TEST PITS AND BORINGS - GINT\P1258-T18\P1258-T18 TEST PITS.GPJMigizi Group, Inc. PO Box 44840 Tacoma, WA 98448 Telephone: 253-537-9400 Fax: 253-537-9401 U.S.C.S.GRAPHICLOGMATERIAL DESCRIPTION GP- GM SM 0.8 3.0 (GP-GM) Gray/brown gravel with silt and sand (dense, moist) (Fill) (SM) Gray silty sand with gravel and concrete/asphalt/brick debris (dense, moist) (Fill) Refusal at a depth of 3 feet atop a large section of concrete No caving observed No groundwater seepage observed The depths on the test pit logs are based on an average of measurements across the test pit and should be considered accurate to 0.5 foot. Bottom of test pit at 3.0 feet. NOTES LOGGED BY ZLL EXCAVATION METHOD Rubber Tracked Mini Excavator EXCAVATION CONTRACTOR Paulman GROUND WATER LEVELS: CHECKED BY JEB DATE STARTED 4/27/18 COMPLETED 4/27/18 AT TIME OF EXCAVATION --- AT END OF EXCAVATION --- AFTER EXCAVATION --- TEST PIT SIZEGROUND ELEVATION SAMPLE TYPENUMBERDEPTH(ft)0.0 2.5 PAGE 1 OF 1 Figure A-3 TEST PIT NUMBER TP-2 CLIENT Sitts & Hill Engineers, Inc. PROJECT NUMBER P1258-T18 PROJECT NAME Washington State Auto Dealers Association PROJECT LOCATION 621 SW Grady Way, Renton, WA COPY OF GENERAL BH / TP LOGS - FIGURE.GDT - 5/16/18 11:29 - C:\USERS\JESSICA\DESKTOP\TEST PITS AND BORINGS - GINT\P1258-T18\P1258-T18 TEST PITS.GPJMigizi Group, Inc. PO Box 44840 Tacoma, WA 98448 Telephone: 253-537-9400 Fax: 253-537-9401 U.S.C.S.GRAPHICLOGMATERIAL DESCRIPTION GP- GM SM SM ML 1.0 3.5 4.5 10.0 (GP-GM) Gray/brown gravel with silt and sand (dense, moist) (Fill) (SM) Gray silty sand with gravel and concrete/asphalt/brick debris (dense, moist) (Fill) (SM) Gray silty sand with gravel, wood, glass, plastic and other detritus (loose, wet) (Fill) (ML) Blue/gray mottled silt (very soft, wet) (Alluvium) Moderate caving observed from 4.5 to 10 feet Moderate groundwater seepage observed at 4.5 feet The depths on the test pit logs are based on an average of measurements across the test pit and should be considered accurate to 0.5 foot. Bottom of test pit at 10.0 feet. NOTES LOGGED BY ZLL EXCAVATION METHOD Rubber Tracked Mini Excavator EXCAVATION CONTRACTOR Paulman GROUND WATER LEVELS: CHECKED BY JEB DATE STARTED 4/27/18 COMPLETED 4/27/18 AT TIME OF EXCAVATION 4.50 ft Moderate seepage AT END OF EXCAVATION --- AFTER EXCAVATION --- TEST PIT SIZEGROUND ELEVATION SAMPLE TYPENUMBERDEPTH(ft)0.0 2.5 5.0 7.5 10.0 PAGE 1 OF 1 Figure A-4 TEST PIT NUMBER TP-3 CLIENT Sitts & Hill Engineers, Inc. PROJECT NUMBER P1258-T18 PROJECT NAME Washington State Auto Dealers Association PROJECT LOCATION 621 SW Grady Way, Renton, WA COPY OF GENERAL BH / TP LOGS - FIGURE.GDT - 5/16/18 11:29 - C:\USERS\JESSICA\DESKTOP\TEST PITS AND BORINGS - GINT\P1258-T18\P1258-T18 TEST PITS.GPJMigizi Group, Inc. PO Box 44840 Tacoma, WA 98448 Telephone: 253-537-9400 Fax: 253-537-9401 U.S.C.S.GRAPHICLOGMATERIAL DESCRIPTION