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HomeMy WebLinkAboutR_Geotechnical_Report_230126_v1Geotechnical Engineering Services 901 South Grady Way Renton, Washington for Velmeir Acquisition Services, L.L.C. January 26, 2023 Geotechnical Engineering Services 901 South Grady Way Renton, Washington for Velmeir Acquisition Services, L.L.C. January 26, 2023 17425 NE Union Hill Road, Suite 250 Redmond, Washington 98052 425.861.6000 Geotechnical Engineering Services 901 South Grady Way Renton, Washington File No. 22042-005-00 January 26, 2023 Prepared for: Velmeir Acquisition Services, L.L.C. 5757 West Maple Road, Suite 800 West Bloomfield, Michigan 48322 Attention: Stephen J. Bock Prepared by: GeoEngineers, Inc. 17425 NE Union Hill Road, Suite 250 Redmond, Washington 98052 425.861.6000 Michael A. Gray, PE Senior Geotechnical Engineer Lyle J. Stone, PE Associate Geotechnical Engineer MAG:LJS:nld Disclaimer: Any electronic form, facsimile or hard copy of the original document (email, text, table, and/or figure), if provided, and any attachments are only a copy of the original document. The original document is stored by GeoEngineers, Inc. and will serve as the official document of record. January 26, 2023 | Page i File No. 22042-005-00 Table of Contents 1.0 INTRODUCTION ............................................................................................................................................. 1 2.0 PROJECT DESCRIPTION ................................................................................................................................ 1 3.0 SUBSURFACE EXPLORATIONS .................................................................................................................... 1 4.0 SITE CONDITIONS .......................................................................................................................................... 1 4.1. Surface Conditions ...................................................................................................................................... 1 4.2. Subsurface Soil Conditions ........................................................................................................................ 2 4.3. Groundwater Conditions ............................................................................................................................. 2 5.0 ENVIRONMENTALLY CRITICAL AREAS ........................................................................................................ 2 5.1. Seismic Hazard Area ................................................................................................................................... 3 5.2. Wellhead Protection Area ........................................................................................................................... 3 6.0 CONCLUSIONS AND RECOMMENDATIONS ................................................................................................. 3 6.1. Summary ..................................................................................................................................................... 3 6.2. Earthquake Engineering ............................................................................................................................. 4 6.2.1. Liquefaction ................................................................................................................................... 4 6.2.2. Lateral Spreading .......................................................................................................................... 4 6.2.3. 2018 IBC Seismic Design Information ......................................................................................... 4 6.3. Temporary Dewatering ................................................................................................................................ 5 6.4. Excavation Support ..................................................................................................................................... 5 6.4.1. Excavation Considerations ............................................................................................................ 6 6.4.2. Temporary Cut Slopes ................................................................................................................... 6 6.5. Foundation Support .................................................................................................................................... 7 6.6. Deep Foundations ....................................................................................................................................... 7 6.6.1. Augercast Piles .............................................................................................................................. 7 6.6.1. Pin Piles .......................................................................................................................................... 9 6.7. Shallow Foundations ................................................................................................................................. 10 6.8. Ground Improvement ................................................................................................................................ 10 6.8.2. Foundation Support with Ground Improvement ........................................................................ 12 6.8.3. Foundation Support Without Ground Improvement .................................................................. 13 6.8.4. Construction Considerations ...................................................................................................... 13 6.9. Slab-on-Grade Floors ................................................................................................................................ 14 6.9.1. Subgrade Preparation ................................................................................................................. 14 6.9.2. Design Parameters ...................................................................................................................... 14 6.9.3. Below-Slab Drainage ................................................................................................................... 14 6.10. Below-Grade Walls .......................................................................................................................... 14 6.10.1. Other Cast-in-Place Walls ............................................................................................................ 15 6.10.2. Drainage ....................................................................................................................................... 15 6.11. Earthwork ........................................................................................................................................ 15 6.11.1. Subgrade Preparation ................................................................................................................. 15 6.11.2. Structural Fill................................................................................................................................ 15 6.12. Infiltration Feasibility ...................................................................................................................... 17 6.13. Recommended Additional Geotechnical Services ........................................................................ 18 January 26, 2023 | Page ii File No. 22042-005-00 7.0 LIMITATIONS ............................................................................................................................................... 18 8.0 REFERENCES .............................................................................................................................................. 18 LIST OF FIGURES Figure 1. Vicinity Map Figure 2. Site Plan APPENDICES Appendix A. Cone Penetration Tests Report Appendix B. Boring Logs from Previous Studies Appendix C. Report Limitations and Guidelines for Use January 26, 2023 | Page 1 File No. 22042-005-00 1.0 INTRODUCTION This report summarizes the results of GeoEngineers’ geotechnical engineering services for the 901 South Grady Way project in Seattle, Washington. The project site is located to the southeast of the intersection of South Grady Way and Talbot Road South in the location of the decommissioned fueling station for the previously occupied Sam’s Club. The large retail building to the east is currently occupied by Home Depot. The site is shown relative to surrounding physical features on the Vicinity Map (Figure 1) and the Site Plan (Figure 2). The NAVD88 datum was used to reference elevations in this report. The purpose of this report is to provide preliminary geotechnical engineering conclusions and recommendations for the design and construction of the planned development. GeoEngineers’ geotechnical engineering services have been completed in general accordance with our signed proposal executed October 17, 2022. 2.0 PROJECT DESCRIPTION The project includes the redevelopment of the site with a single-story medical facility constructed at grade. The building is located well inside the property line so excavations for foundations are anticipated to be completed using temporary cut slopes. Foundation support is anticipated to consist of either deep foundations or shallow foundations and will be dependent on the required performance of the building during a seismic event. 3.0 SUBSURFACE EXPLORATIONS The subsurface conditions at the site were evaluated by completing two cone penetration tests (CPTs). The CPT explorations, GEI-1 and GEI-2, were each advanced to depths of approximately 58 and 59.2 feet, respectively, below existing site grades. The locations of the explorations are shown on Figure 2. A description of the field exploration program and logs/plots of the CPT’s are presented in Appendix A, Cone Penetration Tests Report. The subsurface conditions at the site were also evaluated by reviewing the logs of selected explorations from previous site evaluations in the project vicinity. The approximate locations of the previous explorations are shown on Figure 2. The logs of explorations from previous projects referenced for this study are presented in Appendix B, Boring Logs from Previous Studies. 4.0 SITE CONDITIONS 4.1. Surface Conditions The planned building will be located on a new King County parcel that is comprised of portions of Nos. 915460-0010 and 202305-9007 that is located southeast of the intersection between Talbot Road South and South Grady Way. The new parcel will be approximately 1.94 acres. Existing site conditions consist of at-grade landscaping and was the location of the fueling station for the previously occupied Sam’s Club. The fueling station, including the underground storage tanks, has since been decommissioned as January 26, 2023 | Page 2 File No. 22042-005-00 documented by Terracon in their 2019 report. Existing site grades are relatively flat with the majority of existing site grades shown to vary from approximate Elevations 35 to 37 feet (NAVD88). The site survey we received shows underground gas, water, and storm drain at, or in close proximity, to the project site. We anticipate that other utilities are also located at or adjacent to the project site. 4.2. Subsurface Soil Conditions GeoEngineers’ understanding of subsurface conditions is based on completion of two CPTs and a review of previous explorations (standard penetration tests; SPT’s) completed at the project site for a previous evaluation. The soils encountered at the site were interpreted as relatively shallow fill overlying alluvium and underlain by sandstone. The approximate locations of the CPTs completed for this study, as well as the previous explorations (SPT’s), are shown on Figure 2. ■ Fill was encountered below the pavement, where encountered, or ground surface and extended to depths of up to approximately 11½ feet below site grades. The material generally consists of very loose to loose coal, wood, sandstone, and shale fill. ■ Alluvium was encountered below the fill and extended to the depths of the boring or the sandstone, where encountered. The material consisted of very loose to medium dense sand with variable silt and gravel content as well as very soft to soft silt with variable sand and gravel content. Some borings encountered organic silt or peat in limited thicknesses at depths greater than 10 feet. ■ Sandstone was indicated in one exploration below the alluvium at a depth of approximately 68 feet below existing site grades. The material had measured blow counts greater than 100 blows per inch. The boring was reported to advance two feet into the unit. 4.3. Groundwater Conditions The CPTs completed at the site encountered groundwater near approximate Elevations 22 and 24 feet (depth of between 12 and 14 feet below existing site grades). The previous explorations completed at the site encountered groundwater at the time of drilling between approximate Elevations 24 and 28.5 feet (depths of between 4.5 and 8 feet below previous site grades). Groundwater measurements were also taken in the Terracon Environmental report for two monitoring wells that encountered groundwater between depths of 7.3 and 7.7 feet below existing site grades. Groundwater levels are expected to vary with season and in response to precipitation. Based on the planned structure, we do not anticipate that structure excavations will extend deep enough to encounter the groundwater table. 5.0 ENVIRONMENTALLY CRITICAL AREAS GeoEngineers has reviewed the critical area (ECA) maps available online through the City of Renton (COR) geographic information system (GIS) website. Based on our review of the COR GIS maps, the site is located within a mapped Seismic Hazard Area and Wellhead Protection Area. January 26, 2023 | Page 3 File No. 22042-005-00 5.1. Seismic Hazard Area The entire site is mapped within a seismic hazard area. As noted above, GeoEngineers has completed explorations at the site, and reviewed previous explorations, to evaluate the risk of liquefaction. The results of the liquefaction analysis/assessment are discussed in more detail below. 5.2. Wellhead Protection Area A wellhead protection area is present across the entire project site. We understand that imported fill materials are required to be from a verifiable source in order to ensure it is clear of contaminants. The City’s grading and excavation regulations require imported fill material in excess of 100 cubic yards have a source statement certified by a qualified professional, or confirmed that the fill material was obtained from a Washington State Department of Transportation (WSDOT) approved source which would be verified during construction. We do not anticipate this volume of fill being used on the project. 6.0 CONCLUSIONS AND RECOMMENDATIONS 6.1. Summary A summary of the geotechnical considerations is provided below. The summary is presented for introductory purposes only and should be used in conjunction with the complete recommendations presented in this report. ■ The site is designated Site Class F per the 2018 International Building Code (IBC) due to the presence of potentially liquefiable soils. Recommended seismic design parameters are provided in a subsequent section. ■ We estimate that total liquefaction induced settlement could be up to 20 inches during a design level earthquake based on the subsurface conditions encountered in explorations completed/reviewed for this study. Differential settlements between similarly supported columns is estimated to be between 5 and 10 inches. ■ Temporary cut slopes are anticipated for use where foundations/structures extend below site grades. ■ Deep foundations are appropriate support options and may consist of augercast pile or small diameter pipe piles (i.e. pin piles). The deep foundations would be constructed at grade and would reduce the risk of settlement for the structure during a seismic event. The deep foundations would be required to extend to bearing soils that are located between approximately 60 and 70 feet below site grades. ■ Shallow foundations bearing on ground improvement are considered appropriate for the site. For shallow foundations bearing directly on improved ground, an allowable soil bearing pressure of 3,500 pounds per square foot (psf) may be used. We anticipate that ground improvement would need to extend 30 to 45 feet below ground surface to adequately mitigate damaging differential settlement in the design seismic case. ■ Conventional slabs-on-grade are considered appropriate for this site and should be underlain by a 6-inch-thick layer of clean crushed rock (for example, City of Seattle Mineral Aggregate Type 22). The underslab drainage system is anticipated to consist of a perimeter foundation drain. If settlement of the slabs-on-grade during a seismic event is not desired, then they can be supported on deep foundations or ground improvement. January 26, 2023 | Page 4 File No. 22042-005-00 Our specific geotechnical recommendations are presented in the following sections of this report. 6.2. Earthquake Engineering 6.2.1. Liquefaction Liquefaction refers to the condition by which vibration or shaking of the ground, usually from earthquake forces, results in the development of excess pore pressures in saturated soils with subsequent loss of strength in the deposit of soil. In general, soils that are susceptible to liquefaction include very loose to medium dense clean to silty sands and some silts that are below the water table. The evaluation of liquefaction potential is a complex procedure and is dependent on numerous site parameters, including soil grain size, soil density, site geometry, static stress, and the design ground acceleration. Typically, the liquefaction potential of a site is evaluated by comparing the cyclic stress ratio (CSR), which is the ratio of the cyclic shear stress induced by an earthquake to the initial effective overburden stress, to the cyclic resistance ratio (CRR), which is the soils resistance to liquefaction. We evaluated the liquefaction of the CPT’s using the CLIQ program and incorporated research by Cetin et al. (2009) which accounts for the depth of the liquefiable layers when estimating settlement. These methods predict the potential for up about 7 to 9 inches of free-field liquefaction induced settlement across the site for the design earthquake event. We evaluated the liquefaction of the SPT (boring B-25 from the ZZA 2002 report) based on triggering potential (Youd et al. 2001; Idriss and Boulanger 2014) and liquefaction-induced settlement (Tokimatsu and Seed 1987; Ishihara and Yoshimine 1992; Idriss and Boulanger 2014). These methods predict between approximately 11 and 20 inches of free-field liquefaction induced settlement across the site for the design earthquake event. Differential settlements at the site could be on the order of 5 and 10 inches across the site. It should be noted that the analysis we completed assumed a 2,475 return period for the structure. 6.2.2. Lateral Spreading Lateral spreading involves lateral displacement of large, surficial blocks of soil as the underlying soil layer liquefies. Lateral spreading can occur on near-level ground as blocks of surface soils are displaced relative to adjacent blocks. Lateral spreading also occurs as blocks of surface soils are displaced toward a nearby slope or free-face by movement of the underlying liquefied soil. Due to the depth of the potentially liquefiable soils and the topography in the immediate site vicinity, it is our opinion that the risk of lateral spreading occurring at the site is low. 6.2.3. 2018 IBC Seismic Design Information Based on the results of our liquefaction analyses, the site is classified as Site Class F per ASCE 7-16 Section 20.3.1. If the fundamental period of vibration of the planned structure is greater than 0.5 seconds, a site response analysis is required to determine the design acceleration parameters for the site, and GeoEngineers should be contacted to provide revised recommendations. If the fundamental period of vibration of the planned structure is less than or equal to 0.5 seconds, the exception presented in ASCE 7-16 Section 20.3 is applicable, whereby a Site Class is permitted to be determined in accordance January 26, 2023 | Page 5 File No. 22042-005-00 with Section 20.3 for the purpose of developing seismic design acceleration parameters only. All other criteria associated with Site Class F sites still apply. Based on the geotechnical explorations completed on site, we recommended Site Class D for developing seismic design parameters for structures with fundamental periods of vibration less than or equal to 0.5 seconds. Table 1 provides the preliminary seismic design parameters per ASCE 7-16 Supplement 3 Section 11.4.8. Further, per ASCE 7-16 Supplement 3 Section 11.4.8, a ground motion hazard analysis (GMHA) is required to determine the seismic design acceleration parameters for structures on Site Class D sites with S1 greater than or equal to 0.2 unless the following exception is used, which has been incorporated in the values provided in Table 1. 1. The value of the parameter SM1 determined by Eq. (11.4-2) is increased by 50 percent for all applications of SM1. The resulting value of the parameter SD1 determined by Eq. (11.4-4) shall be used for all applications of SD1. TABLE 1. 2018 IBC SEISMIC PARAMETERS 2018 IBC Parameter1 Recommended Value Site Class F Short-period Spectral Response Acceleration, SS (g) 1.432 1-Second Period Spectral Response Acceleration, S1 (g) 0.488 Short-period Site Coefficient, FA 1.00 Long-period Site Coefficient, FV 1.81 Short-period MCER spectral response acceleration adjusted for site class, SMS (g) 1.432 Long-period MCER spectral response acceleration adjusted for site class, SM1 (g) 1.326 Short-period design spectral response acceleration adjusted for site class, SDS (g) 0.955 Long-period design spectral response acceleration adjusted for site class, SD1 (g) 0.884 Notes: 1 Parameters developed for Site Class D as permitted by ASCE 716 Section 20.3.1 based on latitude 47.4746465 and longitude -122.2057309 using the Applied Technology Council (ATC) Hazards online tool (https://hazards.atcouncil.org/). 6.3. Temporary Dewatering The groundwater table in the site vicinity is anticipated to be located between approximately 5 and 10 feet below existing site grades. The regional groundwater or surface water from rain events that are likely to be encountered in excavations extending deeper than 5 feet are anticipated to be manageable by means of sumps and pumps. The flow rate will vary based on location, precipitation, season, and other factors. For excavations deeper than 10 feet below existing grades, active temporary dewatering, such as vacuum wellpoints may be required. GeoEngineers should be notified if excavations greater than 10 feet are anticipated. 6.4. Excavation Support The planned foundations are located offset from site boundaries or existing improvements and are anticipated to be completed using temporary cut slopes. Excavation considerations and temporary cut slopes are provided below. January 26, 2023 | Page 6 File No. 22042-005-00 6.4.1. Excavation Considerations The site soils may be excavated with conventional excavation equipment, such as trackhoes or dozers. The fill on site may contain foundation elements and/or utilities from previous site development, debris, rubble and/or cobbles and boulders. We recommend that procedures be identified in the project specifications for measurement and payment of work associated with obstructions. 6.4.2. Temporary Cut Slopes The stability of open-cut slopes is a function of soil type, groundwater seepage, slope inclination, slope height and nearby surface loads. The use of inadequately designed open cuts could impact the stability of adjacent work areas, could affect existing utilities and could endanger personnel. The contractor performing the work has the primary responsibility for protection of workers and adjacent improvements. In our opinion, the contractor will be in the best position to observe subsurface conditions continuously throughout the construction process and to respond to variable soil and groundwater conditions. Therefore, the contractor should have the primary responsibility for deciding whether to use open-cut slopes for much of the excavations rather than some form of temporary excavation support, and for establishing the safe inclination of the cut slope. Acceptable slope inclinations for utilities and ancillary excavations should be determined during construction. Because of the diversity of construction techniques and available shoring systems, the design of temporary cut slopes is most appropriately left to the contractor proposing to complete the installation. Temporary cut slopes and shoring must comply with the provisions of Chapter 296-155 Washington Administrative Code (WAC), Part N, “Excavation, Trenching and Shoring.” Temporary unsupported cut slopes more than 4 feet high may be inclined at 1.5H:1V (horizontal to vertical) maximum steepness within the fill soils. For open cuts at the site, we recommend that: ■ No traffic, construction equipment, stockpiles or building supplies be allowed at the top of the cut slopes within a distance of at least 5 feet from the top of the cut; ■ The cut slopes should be planned such that they do not encroach on a 1H:1V influence line projected down from the edges of nearby or planned foundation elements. ■ Exposed soil along the slope be protected from surface erosion by using waterproof tarps or plastic sheeting; ■ Construction activities be scheduled so that the length of time the temporary cut is left open is reduced to the extent practicable; ■ Erosion control measures be implemented as appropriate such that runoff from the site is reduced to the extent practicable; ■ Surface water be diverted away from the slope; and ■ The general condition of the slopes be observed periodically by the geotechnical engineer to confirm adequate stability. Water that enters the excavation must be collected and routed away from prepared subgrade areas. We expect that this may be accomplished by installing a system of drainage ditches and sumps along the toe of the cut slopes. Some sloughing and raveling of the cut slopes should be expected. Temporary covering, January 26, 2023 | Page 7 File No. 22042-005-00 such as heavy plastic sheeting with appropriate ballast, should be used to protect these slopes during periods of wet weather. Surface water runoff from above cut slopes should be prevented from flowing over the slope face by using berms, drainage ditches, swales or other appropriate methods. 6.5. Foundation Support The building foundations can be supported on either deep or shallow foundations. The determination of the foundation support option (deep or shallow) will be dependent upon the desired performance of the building during a seismic event. The followings sections provide recommendations for deep and shallow foundation support. 6.6. Deep Foundations Deep foundations are an appropriate foundation support method. The fill and alluvium soils are potentially liquefiable and deep foundations can be constructed to the sandstone, which represents a competent bearing layer. We have provided deep foundation recommendations in the following sections. 6.6.1. Augercast Piles Augercast piles are constructed using a continuous-flight, hollow-stem auger attached to a set of leads supported by a crane or installed with a fixed-mast drill rig. The first step in the pile casting process consists of drilling the auger into the ground to the specified tip elevation of the pile. Grout is then pumped through the hollow stem during steady withdrawal of the auger, replacing the soils on the flights of the auger. The final step is to install a steel reinforcing cage and typically a center bar into the column of fresh grout. One benefit of using augercast piles is that the auger provides support for the soils during the pile installation process, thus eliminating the need for temporary casing or drilling fluid. Installation of augercast piles also produces minimal ground vibrations. 6.6.1.1. Construction Considerations Given the distinct contrast in stiffness between the alluvium and the underlying sandstone and the need to develop pile capacity from the sandstone (bearing soils), it is important that the piles achieve a consistent embedment into the sandstone. In order to confirm that the piles are consistently embedded into the sandstone, we recommend that the contractor use drilling equipment capable of measuring and displaying drill pressure and crowd speed during augercast pile installation. These measurements can be used as an indication of the transition from alluvium to sandstone, which can be used to estimate pile embedment in sandstone. Production piles located in close proximity to one of the previous geotechnical borings completed at the project site and should be installed at the beginning of pile construction to calibrate the drill pressure and crowd speed requirements for the alluvium and the sandstone. This process will provide the required information to determine whether the piles have been installed to an appropriate length and will eliminate the need for static pile load testing. As is standard practice, the pile grout must be pumped under pressure through the hollow stem as the auger is withdrawn. Maintenance of adequate grout pressure at the auger tip is critical to reduce the potential for encroachment of adjacent native soils into the grout column. The rate of withdrawal of the auger must remain constant throughout the installation of the piles in order to reduce the potential for necking of the piles. Failure to maintain a constant rate of withdrawal of the auger should result in immediate rejection of that pile. Reinforcing steel for bending and uplift should be placed in the fresh grout January 26, 2023 | Page 8 File No. 22042-005-00 column as soon as possible after withdrawal of the auger. Centering devices should be used to provide concrete cover around the reinforcing steel. The contractor should adhere to a waiting period of at least 12 hours between the installation of piles spaced closer than 8 feet, center-to-center. This waiting period is necessary to avoid disturbing the curing concrete in previously cast piles. Grout pumps must be fitted with a volume-measuring device and pressure gauge so that the volume of grout placed in each pile and the pressure head maintained during pumping can be observed. A minimum grout line pressure of 100 pounds per square inch (psi) should be maintained. The rate of auger withdrawal should be controlled during grouting such that the volume of grout pumped is equal to at least 120 percent of the theoretical pile volume. A minimum head of 5 feet of grout should be maintained above the auger tip during withdrawal of the auger to maintain a full column of grout and to prevent hole collapse. A qualified geotechnical engineer should observe the drilling operations, monitor grout injection procedures, record the volume of grout placed in each pile relative to the calculated volume of the hole, and evaluate the adequacy of individual pile installations. 6.6.1.2. Axial Capacity Axial pile load capacity at this site is developed from a combination of end bearing and side resistance in the bearing soils with some additional capacity attributed to side frictional resistance in soils located above bearing soils. Uplift pile capacity will also be developed primarily from side frictional resistance in the sandstone soils. Table 2 below includes a summary of estimated allowable static and seismic capacities for an 18-inch-diameter augercast pile. TABLE 2. SUMMARY OF ESTIMATED CAPACITIES Pile Diameter (Inches) Embedment Depth into Bearing Soils Layer1 (feet) Static Conditions Seismic Conditions2 Compression (kips) Uplift (kips) Compression (kips) Uplift (kips) 18 10 370 260 310 25 Notes: 1 Full design embedment might not be achieved if massive or unfractured sandstone is encountered. 2 Seismic conditions consider the effects of liquefaction including soil strength loss and downdrag. If piles are spaced at least three pile diameters on center, as recommended, no reduction of axial capacity for group action is needed. The structural characteristics of pile materials and structural connections may impose limitations on pile capacities and should be evaluated by the structural engineer. Full length steel reinforcing will be needed for shafts subjected to uplift loads. 6.6.1.3. Lateral Capacity Lateral loads can be resisted by passive soil pressure on the vertical piles and by the passive soil pressures on the pile cap. Because of the potential separation between the pile-supported foundation components and the underlying soil from settlement, base friction along the bottom of the pile cap should not be included in calculations for lateral capacity. January 26, 2023 | Page 9 File No. 22042-005-00 Piles spaced closer than eight pile diameters apart will experience group effects that will result in a lower lateral load capacity for trailing rows of piles with respect to leading rows of piles for an equivalent deflection. We recommend that the lateral load capacity for trailing piles in a pile group spaced three pile diameters apart be reduced by a factor of 0.3. Reductions of the lateral load capacity for trailing piles at spacings greater than three pile diameters but less than eight pile diameters apart can be linearly interpolated. If lateral capacities (deflection, shear and moment versus depth) are necessary they can be prepared during the design phase. We recommend that the passive soil pressure acting on the pile cap be estimated using an equivalent fluid density of 250 pounds per cubic foot (pcf) where the soil adjacent to the foundation consists of adequately compacted structural fill. This passive resistance value includes a factor of safety of 1.5 and assumes a 4-foot-deep pile cap and a minimum lateral deflection of 1 inch to fully develop the passive resistance. Deflections that are less than 1 inch will not fully mobilize the passive resistance in the soil. 6.6.1.4. Pile Settlement We estimate that the post-construction settlement of pile foundations, designed and installed as recommended, will be on the order of ½ inch or less. Maximum differential settlement should be less than about one-half the post-construction settlement. Most of this settlement will occur rapidly as loads are applied. 6.6.1. Pin Piles Small-diameter pipe piles, also known as pin piles, may be suitable for support of the foundation loads. We recommend an allowable design load for 6- and 8-inch-diameter pipe piles driven to refusal criteria as summarized in Table 3 below. Piles should be driven no closer together than 2 feet on center. We estimate pile settlements on the order of ½ inch, occurring rapidly following load application. We recommend that the 6- and 8-inch-diameter piles be installed using an excavator-mounted pneumatic jackhammer with a hammer weight of at least 3,000 pounds. These preliminary capacities will be confirmed during design based on specific hammer weights, pile diameters, and refusal criteria. TABLE 3. PIN PILE DESIGN CRITERIA Pile Diameter1 Seconds per inch Allowable Axial Compression2 (kips) 6-inch 6 30 8-inch 10 45 Notes: 1 Installed with a 3,000-pound hydraulic hammer. 2 Includes a factor or safety of 2. Pile tip depths are typically estimated to extend to a depth of approximately 20 to 30 feet based on achieving refusal criteria through friction resistance. However, we would recommend that the piles extend to the bearing layer, located between approximately 60 and 70 feet below existing site grades. It is recommended that the pile lengths be confirmed/estimated by a specialty contractor who has experience with installing pin piles in similar soils and that driving the pin piles to bearing soils can be achieved at the project site. Steel pipe piles have a risk of corrosion and are typically galvanized as a corrosion protection January 26, 2023 | Page 10 File No. 22042-005-00 measure. Refusal criteria and pile capacities will need to be confirmed by completing a load test for each pile type used. This is discussed in more detail below. We recommend that for each proposed pile type and selected hammer, a load test pile be driven to assess the ability to meet the driving criteria recommended above. The test piles should be loaded to at least 200 percent of the allowable design load. The pile load tests should be observed by a geotechnical engineer from our firm. Pin pile load tests are typically accomplished by jacking against a large piece of construction equipment. The equipment is centered over the top of the pile and a hydraulic jack equipped with a hand-operated hydraulic pump and a pressure gauge is placed between the excavator and pile. The load is applied in increments and downward deflection measurements are recorded at each load. The load vs. deflection is plotted to determine the pile capacity and factor of safety. Lateral resistance and deflections of pile foundations are governed primarily by the soil stiffness, fixity of the top of the pile, the amount of allowable deflection, and the strength of the pile itself. We can estimate lateral capacity of the pipe piles, as well as uplift capacity should the team choose this foundation support method. Allowable pile capacities are provided for Allowable Stress Design (ASD), and the allowable capacities are for combined dead plus long-term live loads. The allowable capacities are based on the strength of the supporting soils for the depths below the existing ground surface and include a factor of safety of 2. The capacities apply to single piles. If piles are spaced at least three pile diameters on center, as recommended, no reduction of the axial capacity for group action is needed. 6.6.1.1. Vibration Considerations The upper soils at the site are relatively loose and do not transmit vibrations compared to denser/harder soils. Therefore, we anticipate negligible vibrations will be transmitted to nearby buildings and do not believe that vibration monitoring is necessary at this time. This recommendation should be revisited once the final layout of the building is completed, and or pin pile layout is known. 6.7. Shallow Foundations Shallow foundations may be suitable for the project site provided the foundations are supported on ground improvement (stone columns) or provided the foundations/structure are designed to tolerate the anticipated total/differential settlement during a seismic event. 6.8. Ground Improvement 6.8.1.1. Ground Improvement Types Based on our understanding of soil conditions at the site, the proposed improvements, and our experience with ground improvement in the project vicinity, we anticipate that stone columns or aggregate piers will likely be the most cost-effective ground improvement method for this site. Stone columns are a vibro-displacement based ground improvement method that involves driving a vibratory probe into the ground to densify the surrounding soil and reduce the potential for soil liquefaction. As the probe is removed, stone (crushed rock) is placed and compacted in the void left by the probe. Typically, a 2- to 4-foot-diameter column of stone remains. Stone columns are most effective in loose sands with few fines that will readily densify under vibratory energy. Stone columns are less effective in January 26, 2023 | Page 11 File No. 22042-005-00 fine-grained or cohesive soils where there is no densification effect, and the improvement comes only from replacing the softer soils with the stronger crushed rock. Aggregate piers are similar to stone columns in that a column of crushed rock is installed into the soft soil to densify the soil and provide soil reinforcement. The difference between aggregate piers and stone columns is the means and methods of installing the rock and the equipment used. An aggregate pier uses a vertical action ram to install and compact the crushed rock. A stone column uses horizontal vibration and fluid jetting to construct the crushed rock column. Other ground improvement methods, such as jet grout or deep soil mixing, are also feasible. These cementitious methods are generally more expensive and are not typically used in the soil types present at the site unless there are structures or other infrastructure very close to the site with significant limits to allowable vibration or other disturbance. 6.8.1.2. Ground Improvement Design Criteria The primary intent of the ground improvement design should be to mitigate the liquefaction hazard and reduced settlement below the proposed structure. The ground improvement should cover the entire building footprint and extend at least 5 feet beyond the footprint of the structure and should be included below any critical infrastructure located outside of the main structure. We recommend the design of the ground improvement, including the actual layout, length and minimum diameter of each column or pier, be provided by the contractor performing the work and be based on the final foundation plan. At a minimum, the ground improvement should extend about 30 to 45 feet below existing site grades. We recommend that the ground improvement be designed to achieve the following minimum performance criteria. This criteria must be reviewed by the structural engineer who will confirm that the criteria is acceptable. ■ Allowable soil bearing resistance of 3,500 psf with an allowable increase of one-third for transient loading conditions. ■ Total long-term static settlement of 1 inch and differential static settlement of 0.5 inch over a distance of 40 feet. ■ Differential liquefaction-induced settlement of 2 inches over a distance of 40 feet. Based on the soil conditions observed in our explorations and the preliminary performance criteria provided above, we recommend using a minimum ground improvement area replacement ratio of 12 percent for budgeting purposes. This replacement ratio can be adjusted during design after the performance criteria has been confirmed or in the field after the performance of the installation equipment and response of the soil has been observed and tested. The contractor performing the work should provide adequate verification that the specified performance criteria has been achieved after ground improvement installation. This could include modulus tests on the installed ground improvement to verify the specified bearing resistance was achieved and post-treatment cone penetrometer tests (CPTs) to verify that the specified liquefaction mitigation was achieved. Please note that pre-treatment CPT’s have already been completed for this study. January 26, 2023 | Page 12 File No. 22042-005-00 6.8.2. Foundation Support with Ground Improvement 6.8.2.1. Bearing Surface Preparation and Minimum Foundation Dimensions Once ground improvement is installed, footing excavations should expose the top of the column or pier elements and confirm their location relative to the foundation. Foundation-bearing surfaces should be thoroughly compacted to a dense, non-yielding condition. Loose or highly disturbed materials present at the base of footing excavations between ground improvement elements should be removed or compacted. The ground improvement designer may specify that a layer of compacted structural fill be placed between the top of the ground improvement elements and the bottom of foundations. Foundation bearing surfaces should not be exposed to standing water. Should water infiltrate and pool in the excavation, it should be removed before placing structural fill or reinforcing steel. We recommend a minimum width of 1.5 feet for continuous wall footings and 2 feet for isolated column footings. All exterior footing elements should be embedded at least 18 inches below the lowest adjacent external grade. Interior footings can be founded a minimum of 12 inches below the top of the floor slab. 6.8.2.2. Allowable Soil Bearing Resistance Provided ground improvement meeting the performance criteria described above is installed, foundations for the proposed structures within the ground improvement area may be designed assuming an allowable soil bearing resistance of 3,500 psf. The provided bearing pressures apply to the total of dead and long- term live loads and may be increased by one-third when considering total loads, including earthquake or wind loads. These are net bearing pressures. The weight of the footing and overlying backfill can be ignored in calculating footing sizes. The ground improvement designer must confirm that the allowable bearing pressure stated above is achievable with their proposed design. 6.8.2.3. Foundation Settlement We estimate that static settlement of footings underlain by ground improvement designed and constructed as recommended will be less than 1 inch, with differential settlements of less than ½ inch between comparably loaded isolated column footings or along 40 feet of continuous footing. Static settlement estimates are in addition to the estimated post ground improvement liquefaction settlement provided in Section 6.2 of this Report. 6.8.2.4. Lateral Resistance The ability of the soil to resist lateral loads is a function of frictional resistance, which can develop on the base of footings and slabs and passive resistance, which can develop on the face of below-grade elements of the structure as these elements tend to move into the soil. The allowable frictional resistance on the base of the footing may be computed using a coefficient of friction of 0.40 applied to the vertical dead-load forces. The allowable passive resistance on the face of the footing or other embedded foundation elements may be computed using an equivalent fluid density of 250 pcf for undisturbed site soils or structural fill extending out from the face of the foundation element a distance at least equal to two and one-half times the depth of the element. These values include a factor of safety of about 1.5. The passive earth pressure and friction components may be combined, provided that the passive component does not exceed two-thirds of the total. The passive earth pressure value is based on the assumptions that the adjacent grade is level, and that groundwater remains below the base of the footing January 26, 2023 | Page 13 File No. 22042-005-00 throughout the year. The top foot of soil should be neglected when calculating passive lateral earth pressure unless the area adjacent to the foundation is covered with pavement or a slab-on-grade. 6.8.3. Foundation Support Without Ground Improvement Improvements that can tolerate large differential settlement during a seismic event without risking life safety or resiliency objectives of the primary structure can be supported on shallow foundations without ground improvement. We recommend that foundations without ground improvement be underlain by an 18-inch-thick layer of structural fill as specified in the “Earthwork” section below. The structural fill should be compacted as described in the “Fill Placement and Compaction Criteria” section below. Foundation bearing surfaces should be thoroughly compacted to a dense, non-yielding condition. Loose or highly disturbed materials present at the base of foundation excavations should be removed or compacted. Foundation bearing surfaces should not be exposed to standing water. Should water infiltrate and pool in the excavation, it should be removed before placing structural fill or reinforcing steel. We recommend that foundations not underlain by ground improvement be proportioned using an allowable soil bearing pressure of 2,000 psf. This is a net bearing pressure; the weight of the footing and overlying backfill can be ignored in calculating footing sizes. We estimate that settlement of footings due to static loads will be less than 1 inch. Differential settlements between comparably loaded isolated column footings or along 50 feet of continuous footing is expected to be less than ½ inch under static loads. We have based our estimates on isolated column loads of 10 kips and strip footing loads of 4 kips per linear foot. If loads exceed these values, we should be contacted for revised estimates. Settlement is expected to occur rapidly as loads are applied. Increased settlement should be expected if subgrades are disturbed. These settlement values are in addition to the estimated liquefaction induced total and differential settlement values presented in Section 6.2 above. Footings not underlain by ground improvement can be designed using the same lateral resistance parameters presented above. 6.8.4. Construction Considerations We recommend that the condition of all subgrade areas be observed by GeoEngineers to evaluate whether the work is completed in accordance with our recommendations and whether the subsurface conditions are as anticipated. If soft areas are present at the footing subgrade elevation, the soft areas should be removed and replaced with approved structural fill at the direction of GeoEngineers. We recommend that the contractor consider leaving the subgrade for the foundations as much as 6 to 12 inches high, depending on soil and weather conditions, until excavation to final subgrade is required for foundation reinforcement. Leaving subgrade high will help reduce damage to the subgrade resulting from construction traffic for other activities. The foundation recommendations provided in this report are intended for design and construction of building foundations. These recommendations may not be appropriate for temporary construction elements such as tower cranes, mobile cranes, manlifts, or other equipment. A qualified geotechnical engineer should be consulted to provide foundation support recommendations for tower cranes, mobile cranes, manlifts or other temporary construction equipment, as necessary. January 26, 2023 | Page 14 File No. 22042-005-00 6.9. Slab-on-Grade Floors Slabs-on-grade with below-slab drainage are appropriate for the site. The following sections provide design recommendations for subgrade preparation, slab-on-grade design parameters, and below-slab drainage. 6.9.1. Subgrade Preparation The exposed subgrade should be evaluated after site grading is complete. Probing should be used to evaluate the subgrade. The exposed soil should be firm and unyielding, and without significant groundwater. Disturbed areas should be recompacted if possible or removed and replaced with compacted structural fill. The site should be rough graded to approximately 1 foot above slab subgrade elevation prior to foundation construction in order to protect the slab subgrade soils from deterioration from wet weather or construction traffic. After the foundations and below-slab drainage system have been constructed, the remaining soils can be removed to final subgrade elevation followed by immediate placement of the capillary break material. 6.9.2. Design Parameters Conventional slabs may be supported on-grade, provided the subgrade soils are prepared as recommended in the “Subgrade Preparation” section above. We recommend that the slab be founded on structural fill placed over the undisturbed site soils. For slabs designed as a beam on an elastic foundation, a modulus of subgrade reaction of 200 pounds per cubic inch (pci) may be used for subgrade soils prepared as recommended. We recommend that the slab-on-grade floors be underlain by a 6-inch-thick capillary break consisting of material meeting the requirements of Mineral Aggregate Type 22 (¾-inch crushed gravel), City of Seattle Standard Specification 9-03.14. Provided that loose soil is removed and the subgrade is prepared as recommended, we estimate that slabs-on-grade will not settle appreciably. 6.9.3. Below-Slab Drainage Specification of a vapor barrier requires consideration of the performance expectations of the occupied space, the type of flooring planned and other factors, and is typically completed by other members of the project team. Structural elements (such as vaults, elevator pits, stairwells, sumps, etc.) that extend greater than 4 feet below site grades should be evaluated for the installation of foundation drainage or designed for hydrostatic pressures. GeoEngineers should be contacted to review these conditions. 6.10. Below-Grade Walls We anticipate that small cast-in-place walls may be required for vaults, elevators, stairwells, sumps, etc. If so, the following may be used for design of those structures. January 26, 2023 | Page 15 File No. 22042-005-00 6.10.1. Other Cast-in-Place Walls Conventional cast-in-place walls may be necessary for retaining structures located on-site. The lateral soil pressures acting on conventional cast-in-place subsurface walls will depend on the nature, density and configuration of the soil behind the wall and the amount of lateral wall movement that can occur as backfill is placed. For walls that are free to yield at the top at least 0.1 percent of the height of the wall, soil pressures will be less than if movement is limited by such factors as wall stiffness or bracing. Assuming that the walls are backfilled and drainage is provided as outlined in the following paragraphs, we recommend that yielding walls supporting horizontal backfill be designed using an equivalent fluid density of 35 pcf (triangular distribution), while non-yielding walls supporting horizontal backfill be designed using an equivalent fluid density of 55 pcf (triangular distribution). For seismic loading conditions, a rectangular earth pressure equal to 8H psf (where H is the height of the wall in feet) should be added to the active/at-rest pressures. Other surcharge loading should be applied as appropriate. Lateral resistance for conventional cast-in-place walls can be provided by frictional resistance along the base of the wall and passive resistance in front of the wall in accordance with the “Lateral Resistance” discussion earlier in this report. The above soil pressures assume that wall drains will be installed to prevent the buildup of hydrostatic pressure behind the walls, as discussed in the paragraphs below. 6.10.2. Drainage Positive drainage should be provided behind cast-in-place retaining walls/structures by placing a minimum 2-foot-wide zone of Mineral Aggregate Type 17 (bank run gravel), City of Seattle Standard Specification 9-03.14. A perforated drainpipe should be placed near the base of the retaining wall to provide drainage. The drainpipe should be surrounded by a minimum of 6 inches of Mineral Aggregate Type 22 (¾-inch crushed gravel), City of Seattle Standard Specification 9-03.14, or an alternative approved by GeoEngineers. The Type 22 material should be wrapped with a geotextile filter fabric meeting the requirements of construction geotextile for underground drainage, WSDOT Standard Specification 9-33. The wall drainpipe should be connected to a header pipe and routed to a sump or gravity drain. Appropriate cleanouts for drainpipe maintenance should be installed. A larger-diameter pipe will allow for easier maintenance of drainage systems. As noted above, the flow rate for the planned excavation in the below-slab drainage and below-grade wall drainage systems is anticipated to be less than 5 gallons per minute (gpm). 6.11. Earthwork 6.11.1. Subgrade Preparation The exposed subgrade in structure and hardscape areas should be evaluated after site excavation is complete. Disturbed areas should be recompacted if the subgrade soil consists of granular material. If the disturbed subgrade soils consist of fine-grained soils, it will likely be necessary to remove and replace the disturbed soil with structural fill unless the soil can be adequately moisture-conditioned and recompacted. 6.11.2. Structural Fill 6.11.2.1. Materials Fill placed to for the following conditions will need to be specified as structural fill as described below: January 26, 2023 | Page 16 File No. 22042-005-00 ■ If structural fill is necessary beneath building foundations or slabs, the fill should meet the requirements of Mineral Aggregate Type 2 or Type 17 (1¼-inch minus crushed rock or bank run gravel), City of Seattle Standard Specification 9-03.10(1)A or 9-03.12, respectively. ■ Structural fill placed behind retaining walls should meet the requirements of Mineral Aggregate Type 17 (bank run gravel), City of Seattle Standard Specification 9-03.10. ■ Structural fill placed within utility trenches and below pavement and sidewalk areas should consist of controlled density fill (CDF), or fill meeting the requirements of Mineral Aggregate Type 17 (bank run gravel), City of Seattle Standard Specification 9-03.10. ■ Structural fill placed around perimeter footing drains, underslab drains, and cast-in-place wall drains should meet the requirements of Mineral Aggregate Type 22 (¾-inch crushed gravel), City of Seattle Standard Specification 9-03.9 or 9-03.10(3). ■ Structural fill placed as capillary break material should meet the requirements of Type 22 (¾-inch crushed gravel), City of Seattle Standard Specification 9-03.9 or 9-03.10(3). ■ Structural fill placed as crushed surfacing base course below pavements and sidewalks should meet the requirements of Mineral Aggregate Type 2 (1¼-inch minus crushed rock), City of Seattle Standard Specification 9-03.10(1)A. 6.11.2.2. On-site Soils The on-site soils (sand) are moisture-sensitive and generally have natural moisture contents higher than the anticipated optimum moisture content for compaction. As a result, the on-site soils will likely require moisture conditioning in order to meet the required compaction criteria during dry weather conditions and will not be suitable for reuse during wet weather. Furthermore, most of the fill soils required for the project have specific gradation requirements, and the on-site soils do not meet these gradation requirements. Because of this we recommend that the earthwork contractor plan to import backfill material for the project. If the contractor wants to use on-site soils for structural fill, GeoEngineers can evaluate the on-site soils for suitability as structural fill, as required, during construction. It may be feasible to reuse on-site soils with the addition of cement treatment. If cement treatment is considered, GeoEngineers can work with the contractor to determine the soil/cement ratio and placement procedures. 6.11.2.3. Fill Placement and Compaction Criteria Structural fill should be mechanically compacted to a firm, non-yielding condition. Structural fill should be placed in loose lifts not exceeding 12 inches in thickness when using heavy compaction equipment and 6 inches in loose thickness when using hand operated compaction equipment. The actual thickness will be dependent on the structural fill material used and the type and size of compaction equipment. Each lift should be conditioned to the proper moisture content and compacted to the specified density before placing subsequent lifts. Compaction of all structural fill at the site should be in accordance with the ASTM D1557 (modified proctor) test method. Structural fill should be compacted to the following criteria: ■ Structural fill placed in building areas (supporting slab-on-grade floors) and in pavement and sidewalk areas (including utility trench backfill) should be compacted to at least 95 percent of the maximum dry density (MDD) estimated in general accordance with ASTM D 1557. January 26, 2023 | Page 17 File No. 22042-005-00 ■ Structural fill placed against subgrade walls should be compacted to between 90 and 92 percent. Care should be taken when compacting fill against subsurface walls to avoid over-compaction and, hence overstressing the walls. We recommend that GeoEngineers be present during probing of the exposed subgrade soils for foundations and pavement areas, and during placement of structural fill. We will evaluate the adequacy of the subgrade soils and identify areas needing further work, perform in-place moisture-density tests in the fill to verify compliance with the compaction specifications, and advise on any modifications to the procedures that may be appropriate for the prevailing conditions. 6.11.2.4. Weather Considerations Disturbance of near surface soils should be expected if earthwork is completed during periods of wet weather. During dry weather, the soils will: (1) be less susceptible to disturbance; (2) provide better support for construction equipment; and (3) be more likely to meet the required compaction criteria. The wet weather season generally begins in October and continues through May in western Washington; however, periods of wet weather may occur during any month of the year. For earthwork activities during wet weather, we recommend that the following steps be taken: ■ The ground surface in and around the work area should be sloped so that surface water is directed away from the work area. ■ The ground surface should be graded such that areas of ponded water do not develop. ■ The contractor should take measures to prevent surface water from collecting in excavations and trenches. ■ Measures should be implemented to remove surface water from the work area. ■ Slopes with exposed soils should be covered with plastic sheeting or similar means. ■ The site soils should not be left uncompacted and exposed to moisture. Sealing the surficial soils by rolling with a smooth-drum roller prior to periods of precipitation will reduce the extent to which these soils become wet or unstable. ■ Construction traffic should be restricted to specific areas of the site, preferably areas that are surfaced with materials not susceptible to wet weather disturbance. ■ Construction activities should be scheduled so that the length of time that soils are left exposed to moisture is reduced to the extent practicable. 6.12. Infiltration Feasibility A summary of groundwater measurements are provided in the groundwater conditions section above. Based on discussions with the project civil engineer we understand that planned infiltration facilities would likely extend a minimum of 8 feet below existing site grades. Based on these conditions the facilities would likely extend into the groundwater or minimum separation requirements between the bottom of the infiltration facility and the groundwater elevation would not be achieved. Therefore, we do not recommend infiltration be completed at the site. January 26, 2023 | Page 18 File No. 22042-005-00 6.13. Recommended Additional Geotechnical Services The recommendations provided in this report are provided for preliminary planning and budgeting purposes. We will need to revise our recommendations as the project advances and as the design develops. GeoEngineers should be retained to review the project plans and specifications when complete to confirm that our design recommendations have been implemented as intended. During construction, GeoEngineers should evaluate foundation subgrades, evaluate structural backfill, and provide a summary letter of our construction observation services. The purposes of GeoEngineers’ construction phase services are to confirm that the subsurface conditions are consistent with those observed in the explorations and other reasons described in Appendix C, Report Limitations and Guidelines for Use. 7.0 LIMITATIONS We have prepared this report for the exclusive use of Velmeir Acquisition Services, L.L.C. and their authorized agents for the 901 South Grady Way project in Renton, Washington. Within the limitations of scope, schedule and budget, our services have been executed in accordance with generally accepted practices in the field of geotechnical engineering in this area at the time this report was prepared. No warranty or other conditions, express or implied, should be understood. Please refer to Appendix C for additional information pertaining to use of this report. 8.0 REFERENCES ASCE (2016). “SEI/ASCE 7-16, Minimum Design Loads for Buildings and Other Structures,” American Society of Civil Engineers. Cetin K.O., Bilge H.T., Wu J., Kammerer A. and Seed R.B., [2009]. “Probabilistic Models for Cyclic Straining of Saturated Clean Sands.” J. Geotech. and Geoenv. Engrg., 135[3], 371-386. City of Seattle, 2020. “Standard Specifications for Road, Bridge and Municipal Construction.” International Code Council, 2018. “International Building Code.” Idriss, I.M. and Boulanger, R.W., 2014. “CPT and SPT Based Liquefaction Triggering Procedures.” Ishihara, K., and Yoshimine, M., 1992. “Evaluation of Settlements in Sand Deposits Following Liquefaction During Earthquakes,” Soils and Foundations, 32(1), pp. 173-188. Terracon Consultants, 2019, “Underground Storage Tank Permanent Removal from Service Report.” Tokimatsu, K., and Seed, H.B., “Evaluation of Settlements in Sands Due to Earthquake Shaking,” Journal of Geotechnical Engineering, ASCE, 113(GT8), 1987, pp. 861-878. January 26, 2023 | Page 19 File No. 22042-005-00 Youd, et al., “Liquefaction Resistance of Soils: Summary Report from the 1996 NCEER and 1998 NCEER/NSF Workshops on Evaluation of Liquefaction Resistance of Soils,” Journal of Geotechnical and Geoenvironmental Engineering, ASCE, October 2001, pp. 817-833. Zipper Zeman Associates, 2002, “Subsurface Exploration and Geotechnical Engineering Evaluation, Proposed Retail Development, S. Grady Way and Talbot Road, Renton, Washington.” FIGURES 80thAveSRenton M unic i pal A irport SW Langston Rd S W 1 9 t h S t ShattuckAveSShattuckAveSS W 7 t h S tP owellAveSWSW 3rd Pl S 130 t h S t S 134th St S 1 3 2 n d S t S W 1 2 t h S t S 1 3 5th St S W S u n s etBlvd Rai ni erAveSOakesdal eAveSWS W 1 6 t h S tRe n t on Ave S ValleyFwyBoeing Longacr es Industr ial P ark TalbotRdSS W 2 7t h S t OakesdaleAveSW900 NE 4 t h S t NE 5th Pl N 4 t h S tGardenAveN MainAveSN 3 r d S t S E 160t h S tRentonAveSWellsAveSS4thStTalbotRdSS5thSt S 18th St B e a c o n Wa y S BensonRdSN 1 st S t S 2 n d S t N E 3 r d S t TalbotRdSS 3 r d S t 116thAveSEPugetDrSEBensonDrSRiver v iew Par k - RentonCedarRiver Natural Zone Cedar Riv er Park -Renton R e n t o n S E 1 6 8 t h S t S E 1 64th S t 113thAveSEBen son Rd S 116thAveSEBensonDrS1 SITE Vicinity Map Figure 1 901 South Grady Way Renton, Washington 3 A lpine Lak es Wilderness Kent Tacoma Seattle Olympia 0 2,000 Feet P:\22\22042005\GIS\2204200500_Project\2204200500_Project.aprx\2204200500_F01_VicinityMap Date Exported: 10/24/22 by maugustSource(s): • ESRI Coordinate System: NAD 1983 UTM Zone 10N Disclaimer: This figure was created for a specific purpose and project. Any use of this figure for any other project or purpose shall be at the user's sole risk and without liability to GeoEngineers. The locations of features shown may be approximate. GeoEngineers makes no warranty or representation as to the accuracy, completeness, or suitability of the figure, or data contained therein. The file containing this figure is a copy of a master document, the original of which is retained by GeoEngineers and is the official document of record. Urgent Care B-26 B-28 B-31 B-27 B-25 B-23 B-24 B-29 B-32 GEI-01 GEI-02 Figure 2 901 South Grady Way Renton, Washington Site Plan P:\22\22042005\CAD\00\Geotech Report\2204200500_F02_Site Plan.dwg F02 Date Exported:11/29/2022 5:54 PM - by Majed FadhlW E N S Notes: 1.The locations of all features shown are approximate. 2.This drawing is for information purposes. It is intended to assist in showing features discussed in an attached document. GeoEngineers, Inc. cannot guarantee the accuracy and content of electronic files. The master file is stored by GeoEngineers, Inc. and will serve as the official record of this communication. Data Source: Apex Engineering. dated 09/02/2022. & Barghausen Consulting Engineers. dated 07/28/2022. Projection: WA State Plane, North Zone, NAD83, US Foot Feet 0 Legend 60 60 Proposed Site Boundary B-23 Boring by Zipper Zeman Associates, 2002 GEI-01 Cone Penetration Test by GeoEngineers, 2022 (Current Study) APPENDICES APPENDIX A Cone Penetration Tests Report January 26, 2023 | Page A-1 File No. 22042-005-00 APPENDIX A CONE PENETRATION TESTS REPORT Subsurface soil and groundwater conditions were evaluated by completing two cone penetration tests (CPTs; GEI-1 and GEI-2). The CPTs were completed by ConeTec, Inc. on November 2, 2022. The locations of the CPTs were measured using handheld GPS equipment. The approximate CPT locations are shown on the Figure 2. CPT’s are a subsurface exploration technique in which a small-diameter steel tip with adjacent sleeve is continuously advanced with hydraulically operated equipment. Measurements of tip and sleeve resistance allow interpretation of the soil profile and the consistency of the strata penetrated. The tip resistance, friction ratio and pore water pressure are recorded on the CPT logs. The logs of the CPT probes are included in the attached report in Appendix A. The CPT soundings were backfilled in general accordance with procedures outlined by the Washington State Department of Ecology. PRESENTATION OF SITE INVESTIGATION RESULTS 901 South Grady Way Renton Prepared for: GeoEngineers, Inc ConeTec Job No: 22-59-25016 -- Project Start Date: 02-NOV-2022 Project End Date: 02-NOV-2022 Report Date: 09-NOV-2022 Prepared by: ConeTec Inc. 1237 S Director St Seattle, WA 98108 - Tel: (253) 397-4861 ConeTecWA@conetec.com www.conetec.com www.conetecdataservices.com 901 South Grady Way Renton Introduction The enclosed report presents the results of the site investigation program conducted by ConeTec Inc. for GeoEngineers, Inc. at 901 S Grady Way, Renton, WA 98057. The program consisted of cone penetration tests. Project Information Project Client GeoEngineers, Inc. Project 901 South Grady Way Renton ConeTec project number 22-59-25016 An aerial overview from Google Earth including the CPTu test locations is presented below. Rig Description Deployment System Test Type C23-25Ton Truck Rig Integrated Push Cylinders CPTu 901 South Grady Way Renton Coordinates Test Type Collection Method EPSG Number CPTu Consumer grade GPS 4326 Cone Penetrometers Used for this Project Cone Description Cone Number Cross Sectional Area (cm2) Sleeve Area (cm2) Tip Capacity (bar) Sleeve Capacity (bar) Pore Pressure Capacity (bar) EC870: T1500F15U35 870 15.0 225 1500 15 35 Cone 870 was used for all CPTu soundings Cone Penetration Test (CPTu) Depth reference Depths are referenced to the existing ground surface at the time of each test. Tip and sleeve data offset 0.1 meter This has been accounted for in the CPT data files. Additional plots • Advanced plots with Ic, Su, phi and N(60)/N1(60) • Soil Behaviour Type (SBT) scatter plots Calculated Geotechnical Parameter Tables Additional information The Normalized Soil Behaviour Type Chart based on Qtn (SBT Qtn) (Robertson, 2009) was used to classify the soil for this project. A detailed set of calculated CPTu parameters have been generated and are provided in Excel format files in the release folder. The CPTu parameter calculations are based on values of corrected tip resistance (qt) sleeve friction (fs) and pore pressure (u2). Effective stresses are calculated based on unit weights that have been assigned to the individual soil behaviour type zones and the assumed equilibrium pore pressure profile. 901 South Grady Way Renton Limitations This report has been prepared for the exclusive use of GeoEngineers, Inc. (Client) for the project titled “901 South Grady Way Renton”. The report’s contents may not be relied upon by any other party without the express written permission of ConeTec Inc. (ConeTec). ConeTec has provided site investigation services, prepared the factual data reporting and provided geotechnical parameter calculations consistent with current best practices. No other warranty, expressed or implied, is made. The information presented in the report document and the accompanying data set pertain to the specific project, site conditions and objectives described to ConeTec by the Client. In order to properly understand the factual data, assumptions and calculations, reference must be made to the documents provided and their accompanying data sets, in their entirety. CONE PENETRATION TEST - eSeries Cone penetration tests (CPTu) are conducted using an integrated electronic piezocone penetrometer and data acquisition system manufactured by Adara Systems Ltd., a subsidiary of ConeTec. ConeTec’s piezocone penetrometers are compression type designs in which the tip and friction sleeve load cells are independent and have separate load capacities. The piezocones use strain gauged load cells for tip and sleeve friction and a strain gauged diaphragm type transducer for recording pore pressure. The piezocones also have a platinum resistive temperature device (RTD) for monitoring the temperature of the sensors, an accelerometer type dual axis inclinometer and two geophone sensors for recording seismic signals. All signals are amplified and measured with minimum sixteen-bit resolution down hole within the cone body, and the signals are sent to the surface using a high bandwidth, error corrected digital interface through a shielded cable. ConeTec penetrometers are manufactured with various tip, friction and pore pressure capacities in both 10 cm2 and 15 cm2 tip base area configurations in order to maximize signal resolution for various soil conditions. The specific piezocone used for each test is described in the CPT summary table presented in the first appendix. The 15 cm2 penetrometers do not require friction reducers as they have a diameter larger than the deployment rods. The 10 cm2 piezocones use a friction reducer consisting of a rod adapter extension behind the main cone body with an enlarged cross sectional area (typically 44 millimeters diameter over a length of 32 millimeters with tapered leading and trailing edges) located at a distance of 585 millimeters above the cone tip. The penetrometers are designed with equal end area friction sleeves, a net end area ratio of 0.8 and cone tips with a 60 degree apex angle. All ConeTec piezocones can record pore pressure at various locations. Unless otherwise noted, the pore pressure filter is located directly behind the cone tip in the “u2” position (ASTM Type 2). The filter is six millimeters thick, made of porous plastic (polyethylene) having an average pore size of 125 microns (90 - 160 microns). The function of the filter is to allow rapid movements of extremely small volumes of water needed to activate the pressure transducer while preventing soil ingress or blockage. The piezocone penetrometers are manufactured with dimensions, tolerances and sensor characteristics that are in general accordance with the current ASTM D5778 standard. ConeTec’s calibration criteria also meets or exceeds those of the current ASTM D5778 standard. An illustration of the piezocone penetrometer is presented in Figure CPTu. CONE PENETRATION TEST - eSeries Figure CPTu. Piezocone Penetrometer (15 cm2) The ConeTec data acquisition systems consist of a Windows based computer and a signal interface box and power supply. The signal interface combines depth increment signals, seismic trigger signals and the downhole digital data. This combined data is then sent to the Windows based computer for collection and presentation. The data is recorded at fixed depth increments using a depth wheel attached to the push cylinders or by using a spring loaded rubber depth wheel that is held against the cone rods. The typical recording interval is 2.5 centimeters; custom recording intervals are possible. The system displays the CPTu data in real time and records the following parameters to a storage media during penetration: • Depth • Uncorrected tip resistance (qc) • Sleeve friction (fs) • Dynamic pore pressure (u) • Additional sensors such as resistivity, passive gamma, ultra violet induced fluorescence, if applicable CONE PENETRATION TEST - eSeries All testing is performed in accordance to ConeTec’s CPTu operating procedures which are in general accordance with the current ASTM D5778 standard. Prior to the start of a CPTu sounding a suitable cone is selected, the cone and data acquisition system are powered on, the pore pressure system is saturated with silicone oil and the baseline readings are recorded with the cone hanging freely in a vertical position. The CPTu is conducted at a steady rate of two centimeters per second, within acceptable tolerances. Typically one meter length rods with an outer diameter of 1.5 inches (38.1 millimeters) are added to advance the cone to the sounding termination depth. After cone retraction final baselines are recorded. Additional information pertaining to ConeTec’s cone penetration testing procedures: • Each filter is saturated in silicone oil under vacuum pressure prior to use • Baseline readings are compared to previous readings • Soundings are terminated at the client’s target depth or at a depth where an obstruction is encountered, excessive rod flex occurs, excessive inclination occurs, equipment damage is likely to take place, or a dangerous working environment arises • Differences between initial and final baselines are calculated to ensure zero load offsets have not occurred and to ensure compliance with ASTM standards The interpretation of piezocone data for this report is based on the corrected tip resistance (qt), sleeve friction (fs) and pore water pressure (u). The interpretation of soil type is based on the correlations developed by Robertson et al. (1986) and Robertson (1990, 2009). It should be noted that it is not always possible to accurately identify a soil behavior type based on these parameters. In these situations, experience, judgment and an assessment of other parameters may be used to infer soil behavior type. The recorded tip resistance (qc) is the total force acting on the piezocone tip divided by its base area. The tip resistance is corrected for pore pressure effects and termed corrected tip resistance (qt) according to the following expression presented in Robertson et al. (1986): qt = qc + (1-a) • u2 where: qt is the corrected tip resistance qc is the recorded tip resistance u2 is the recorded dynamic pore pressure behind the tip (u2 position) a is the Net Area Ratio for the piezocone (0.8 for ConeTec probes) The sleeve friction (fs) is the frictional force on the sleeve divided by its surface area. As all ConeTec piezocones have equal end area friction sleeves, pore pressure corrections to the sleeve data are not required. The dynamic pore pressure (u) is a measure of the pore pressures generated during cone penetration. To record equilibrium pore pressure, the penetration must be stopped to allow the dynamic pore pressures to stabilize. The rate at which this occurs is predominantly a function of the permeability of the soil and the diameter of the cone. CONE PENETRATION TEST - eSeries The friction ratio (Rf) is a calculated parameter. It is defined as the ratio of sleeve friction to the tip resistance expressed as a percentage. Generally, saturated cohesive soils have low tip resistance, high friction ratios and generate large excess pore water pressures. Cohesionless soils have higher tip resistances, lower friction ratios and do not generate significant excess pore water pressure. A summary of the CPTu soundings along with test details and individual plots are provided in the appendices. A set of files with calculated geotechnical parameters were generated for each sounding based on published correlations and are provided in Excel format in the data release folder. Information regarding the methods used is also included in the data release folder. For additional information on CPTu interpretations and calculated geotechnical parameters, refer to Robertson et al. (1986), Lunne et al. (1997), Robertson (2009), Mayne (2013, 2014) and Mayne and Peuchen (2012). PORE PRESSURE DISSIPATION TEST The cone penetration test is halted at specific depths to carry out pore pressure dissipation (PPD) tests, shown in Figure PPD-1. For each dissipation test the cone and rods are decoupled from the rig and the data acquisition system measures and records the variation of the pore pressure (u) with time (t). Figure PPD-1. Pore pressure dissipation test setup Pore pressure dissipation data can be interpreted to provide estimates of ground water conditions, permeability, consolidation characteristics and soil behavior. The typical shapes of dissipation curves shown in Figure PPD-2 are very useful in assessing soil type, drainage, in situ pore pressure and soil properties. A flat curve that stabilizes quickly is typical of a freely draining sand. Undrained soils such as clays will typically show positive excess pore pressure and have long dissipation times. Dilative soils will often exhibit dynamic pore pressures below equilibrium that then rise over time. Overconsolidated fine-grained soils will often exhibit an initial dilatory response where there is an initial rise in pore pressure before reaching a peak and dissipating. Figure PPD-2. Pore pressure dissipation curve examples PORE PRESSURE DISSIPATION TEST In order to interpret the equilibrium pore pressure (ueq) and the apparent phreatic surface, the pore pressure should be monitored until such time as there is no variation in pore pressure with time as shown for each curve in Figure PPD-2. In fine grained deposits the point at which 100% of the excess pore pressure has dissipated is known as t100. In some cases this can take an excessive amount of time and it may be impractical to take the dissipation to t100. A theoretical analysis of pore pressure dissipations by Teh and Houlsby (1991) showed that a single curve relating degree of dissipation versus theoretical time factor (T*) may be used to calculate the coefficient of consolidation (ch) at various degrees of dissipation resulting in the expression for ch shown below. ch = T*∙a2 ∙√Ir t Where: T* is the dimensionless time factor (Table Time Factor) a is the radius of the cone Ir is the rigidity index t is the time at the degree of consolidation Table Time Factor. T* versus degree of dissipation (Teh and Houlsby (1991)) Degree of Dissipation (%) 20 30 40 50 60 70 80 T* (u2) 0.038 0.078 0.142 0.245 0.439 0.804 1.60 The coefficient of consolidation is typically analyzed using the time (t50) corresponding to a degree of dissipation of 50% (u50). In order to determine t50, dissipation tests must be taken to a pressure less than u50. The u50 value is half way between the initial maximum pore pressure and the equilibrium pore pressure value, known as u100. To estimate u50, both the initial maximum pore pressure and u100 must be known or estimated. Other degrees of dissipations may be considered, particularly for extremely long dissipations. At any specific degree of dissipation the equilibrium pore pressure (u at t100) must be estimated at the depth of interest. The equilibrium value may be determined from one or more sources such as measuring the value directly (u100), estimating it from other dissipations in the same profile, estimating the phreatic surface and assuming hydrostatic conditions, from nearby soundings, from client provided information, from site observations and/or past experience, or from other site instrumentation. For calculations of ch (Teh and Houlsby (1991)), t50 values are estimated from the corresponding pore pressure dissipation curve and a rigidity index (Ir) is assumed. For curves having an initial dilatory response in which an initial rise in pore pressure occurs before reaching a peak, the relative time from the peak value is used in determining t50. In cases where the time to peak is excessive, t50 values are not calculated. Due to possible inherent uncertainties in estimating Ir, the equilibrium pore pressure and the effect of an initial dilatory response on calculating t50, other methods should be applied to confirm the results for ch. PORE PRESSURE DISSIPATION TEST Additional published methods for estimating the coefficient of consolidation from a piezocone test are described in Burns and Mayne (1998, 2002), Jones and Van Zyl (1981), Robertson et al. (1992) and Sully et al. (1999). A summary of the pore pressure dissipation tests and dissipation plots are presented in the relevant appendix. REFERENCES ASTM D5778-12, 2012, "Standard Test Method for Performing Electronic Friction Cone and Piezocone Penetration Testing of Soils", ASTM International, West Conshohocken, PA. DOI: 10.1520/D5778-12. Burns, S.E. and Mayne, P.W., 1998, “Monotonic and dilatory pore pressure decay during piezocone tests”, Canadian Geotechnical Journal 26 (4): 1063-1073. DOI: 1063-1073/T98-062. Burns, S.E. and Mayne, P.W., 2002, “Analytical cavity expansion-critical state model cone dissipation in fine-grained soils”, Soils & Foundations, Vol. 42(2): 131-137. Jones, G.A. and Van Zyl, D.J.A., 1981, “The piezometer probe: a useful investigation tool”, Proceedings, 10th International Conference on Soil Mechanics and Foundation Engineering, Vol. 3, Stockholm: 489-495. Lunne, T., Robertson, P.K. and Powell, J. J. M., 1997, “Cone Penetration Testing in Geotechnical Practice”, Blackie Academic and Professional. Mayne, P.W., 2013, “Evaluating yield stress of soils from laboratory consolidation and in-situ cone penetration tests”, Sound Geotechnical Research to Practice (Holtz Volume) GSP 230, ASCE, Reston/VA: 406-420. DOI: 10.1061/9780784412770.027. Mayne, P.W. and Peuchen, J., 2012, “Unit weight trends with cone resistance in soft to firm clays”, Geotechnical and Geophysical Site Characterization 4, Vol. 1 (Proc. ISC-4, Pernambuco), CRC Press, London: 903-910. Mayne, P.W., 2014, “Interpretation of geotechnical parameters from seismic piezocone tests”, CPT’14 Keynote Address, Las Vegas, NV, May 2014. Robertson, P.K., Campanella, R.G., Gillespie, D. and Greig, J., 1986, “Use of Piezometer Cone Data”, Proceedings of InSitu 86, ASCE Specialty Conference, Blacksburg, Virginia. Robertson, P.K., 1990, “Soil Classification Using the Cone Penetration Test”, Canadian Geotechnical Journal, Volume 27: 151-158. DOI: 10.1139/T90-014. Robertson, P.K., Sully, J.P., Woeller, D.J., Lunne, T., Powell, J.J.M. and Gillespie, D.G., 1992, “Estimating coefficient of consolidation from piezocone tests”, Canadian Geotechnical Journal, 29(4): 539-550. DOI: 10.1139/T92-061. Robertson, P.K., 2009, “Interpretation of cone penetration tests – a unified approach”, Canadian Geotechnical Journal, Volume 46: 1337-1355. DOI: 10.1139/T09-065. Sully, J.P., Robertson, P.K., Campanella, R.G. and Woeller, D.J., 1999, “An approach to evaluation of field CPTU dissipation data in overconsolidated fine-grained soils”, Canadian Geotechnical Journal, 36(2): 369- 381. DOI: 10.1139/T98-105. Teh, C.I., and Houlsby, G.T., 1991, “An analytical study of the cone penetration test in clay”, Geotechnique, 41(1): 17-34. DOI: 10.1680/geot.1991.41.1.17. APPENDICES The appendices listed below are included in the report: • Cone Penetration Test Summary and Standard Cone Penetration Test Plots • Advanced Cone Penetration Test Plots with Ic, Su(Nkt), Phi and N(60)Ic/N1(60)Ic • Soil Behavior Type (SBT) Scatter Plots • Pore Pressure Dissipation Summary and Pore Pressure Dissipation Plots Cone Penetration Test Summary and Standard Cone Penetration Test Plots Job No:22-59-25016 Client:GeoEngineers, Inc. Project:901 South Grady Way Renton Start Date:02-Nov-2022 End Date:02-Nov-2022 CONE PENETRATION TEST SUMMARY Sounding ID File Name Date Cone Assumed 1 Phreatic Surface (ft) Final Depth (ft) Latitude2 (deg) Longitude2 (deg) GEI-01 22-59-25016_CP01 02-Nov-2022 EC870: T1500F15U35 14.0 58.0 47.47182 -122.20735 GEI-02 22-59-25016_CP02 02-Nov-2022 EC870: T1500F15U35 12.7 59.2 47.47144 -122.20719 Totals 2 soundings 117.2 1. Phreatic surface based on pore pressure dissipation test unless otherwise noted. Hydrostatic profile applied to interpretation tables 2. Coordinates were collected using a handheld GPS - WGS 84 Lat/Long Sheet 1 of 1 0 100 200 300 0 5 10 15 20 25 30 35 40 45 50 55 60 65 qt (tsf)Depth (feet)0.0 1.0 2.0 3.0 fs (tsf) 0.0 2.5 5.0 7.5 Rf (%) 0 50 100 1500 u (ft) 0 3 6 9 SBT Qtn GeoEngineers Job No: 22-59-25016 Date: 2022-11-02 14:56 Site: 901 South Grady Way Renton Sounding: GEI-01 Cone: 870:T1500F15U35 Max Depth: 17.675 m / 57.99 ft Depth Inc: 0.025 m / 0.082 ft Avg Int: Every Point File: 22-59-25016_CP01.COR Unit Wt: SBTQtn (PKR2009) SBT: Robertson, 2009 and 2010 Coords: Lat: 47.47182 Long: -122.20735 Undefined Sand Mixtures Sand Mixtures Silt Mixtures Clays Clays Clays Silt Mixtures Silt Mixtures Silt Mixtures Silt Mixtures Silt Mixtures Silt Mixtures Silt Mixtures Clays Silt Mixtures Silt Mixtures Clays Silt Mixtures Silt Mixtures Sands Sand Mixtures Clays Silt Mixtures Sands Sand Mixtures Sands Sand Mixtures Sands Sand Mixtures Silt Mixtures Sand Mixtures Silt Mixtures Clays Organic Soils Silt Mixtures Sand Mixtures Silt Mixtures Sands Sand Mixtures Sand Mixtures Silt Mixtures Silt Mixtures Silt Mixtures Sands Undefined 10.0 Ueq(ft) Refusal Refusal Refusal Refusal Equilibrium Pore Pressure (Ueq)Assumed Ueq Dissipation, Ueq achieved Dissipation, Ueq not achieved Hydrostatic Line The reported coordinates were acquired from hand-held GPS equipment and are only approximate locations. The coordinates should not be used for design purposes. Prepunch Prepunch Prepunch Prepunch 0 100 200 300 0 5 10 15 20 25 30 35 40 45 50 55 60 65 qt (tsf)Depth (feet)0.0 1.0 2.0 3.0 fs (tsf) 0.0 2.5 5.0 7.5 Rf (%) 0 50 100 1500 u (ft) 0 3 6 9 SBT Qtn GeoEngineers Job No: 22-59-25016 Date: 2022-11-02 13:45 Site: 901 South Grady Way Renton Sounding: GEI-02 Cone: 870:T1500F15U35 Max Depth: 18.050 m / 59.22 ft Depth Inc: 0.025 m / 0.082 ft Avg Int: Every Point File: 22-59-25016_CP02.COR Unit Wt: SBTQtn (PKR2009) SBT: Robertson, 2009 and 2010 Coords: Lat: 47.47143 Long: -122.20718 Undefined Sand Mixtures Undefined Sands Sand Mixtures Clays Silt Mixtures Silt Mixtures Clays Clays Sand Mixtures Silt Mixtures Sands Sand Mixtures Silt Mixtures Silt Mixtures Sands Clays Sand Mixtures Silt Mixtures Clays Sand Mixtures Sands Sand Mixtures Silt Mixtures Clays Sand Mixtures Sand Mixtures Sand Mixtures Clays Clays Clays Silt Mixtures Sand Mixtures Sands Sand Mixtures Sands Sand Mixtures Sand Mixtures Sands Sand Mixtures Sands Sand Mixtures 11.1 Ueq(ft) Refusal Refusal Refusal Refusal Equilibrium Pore Pressure (Ueq)Assumed Ueq Dissipation, Ueq achieved Dissipation, Ueq not achieved Hydrostatic Line The reported coordinates were acquired from hand-held GPS equipment and are only approximate locations. The coordinates should not be used for design purposes. Prepunch Prepunch Prepunch Prepunch Prepunch Prepunch Prepunch Prepunch Advanced Cone Penetration Test Plots with Ic, Su, Phi and N(60)/N1(60) 0 100 200 300 0 5 10 15 20 25 30 35 40 45 50 55 60 65 qt (tsf)Depth (feet)0 50 100 1500 u (ft) 1.0 2.0 3.0 4.0 Ic (PKR 2009) 0.0 1.0 2.0 3.0 4.0 Su (Nkt) (tsf) 20 30 40 50 60 Phi (deg) 0 10 20 30 40 50 N60 (Ic RW1998) (bpf) GeoEngineers Job No: 22-59-25016 Date: 2022-11-02 14:56 Site: 901 South Grady Way Renton Sounding: GEI-01 Cone: 870:T1500F15U35 Max Depth: 17.675 m / 57.99 ft Depth Inc: 0.025 m / 0.082 ft Avg Int: Every Point File: 22-59-25016_CP01.COR Unit Wt: SBTQtn (PKR2009) Su Nkt: 15.0 SBT: Robertson, 2009 and 2010 Coords: Lat: 47.47182 Long: -122.20735 10.0 Ueq(ft) Refusal Refusal Refusal Refusal Refusal Refusal Equilibrium Pore Pressure (Ueq)Assumed Ueq Dissipation, Ueq achieved Dissipation, Ueq not achieved Hydrostatic Line N1(60) (bpf) The reported coordinates were acquired from hand-held GPS equipment and are only approximate locations. The coordinates should not be used for design purposes. Prepunch Prepunch Prepunch Prepunch Prepunch Prepunch 0 100 200 300 0 5 10 15 20 25 30 35 40 45 50 55 60 65 qt (tsf)Depth (feet)0 50 100 1500 u (ft) 1.0 2.0 3.0 4.0 Ic (PKR 2009) 0.0 1.0 2.0 3.0 4.0 Su (Nkt) (tsf) 20 30 40 50 60 Phi (deg) 0 10 20 30 40 50 N60 (Ic RW1998) (bpf) GeoEngineers Job No: 22-59-25016 Date: 2022-11-02 13:45 Site: 901 South Grady Way Renton Sounding: GEI-02 Cone: 870:T1500F15U35 Max Depth: 18.050 m / 59.22 ft Depth Inc: 0.025 m / 0.082 ft Avg Int: Every Point File: 22-59-25016_CP02.COR Unit Wt: SBTQtn (PKR2009) Su Nkt: 15.0 SBT: Robertson, 2009 and 2010 Coords: Lat: 47.47143 Long: -122.20718 11.1 Ueq(ft) Refusal Refusal Refusal Refusal Refusal Refusal Equilibrium Pore Pressure (Ueq)Assumed Ueq Dissipation, Ueq achieved Dissipation, Ueq not achieved Hydrostatic Line N1(60) (bpf) The reported coordinates were acquired from hand-held GPS equipment and are only approximate locations. The coordinates should not be used for design purposes. Prepunch Prepunch Prepunch Prepunch Prepunch Prepunch Prepunch Prepunch Prepunch Prepunch Prepunch Prepunch Soil Behavior Type (SBT) Scatter Plots GeoEngineers Job No: 22-59-25016 Date: 2022-11-02 14:56 Site: 901 South Grady Way Renton Sounding: GEI-01 Cone: 870:T1500F15U35 Legend Sensitive, Fine Grained Organic Soils Clays Silt Mixtures Sand Mixtures Sands Gravelly Sand to Sand Stiff Sand to Clayey Sand Very Stiff Fine Grained Depth Ranges >0.0 to 7.5 ft >7.5 to 15.0 ft >15.0 to 22.5 ft >22.5 to 30.0 ft >30.0 to 37.5 ft >37.5 to 45.0 ft >45.0 to 52.5 ft >52.5 to 60.0 ft >60.0 to 67.5 ft >67.5 to 75.0 ft >75.0 ft 1 2 3 4 5 6 7 8 9 Qtn,cs = 70 Ic = 2.6 0.10 1.0 10.0 1.0 10.0 100 1000 Fr (%)QtnQtn Chart (PKR 2009) Legend Sensitive Fines Organic Soil Clay Silty Clay Clayey Silt Silt Sandy Silt Silty Sand/Sand Sand Gravelly Sand Stiff Fine Grained Cemented Sand 1 2 3 4 5 6 7 8 9 10 11 12 0.0 2.0 4.0 6.0 8.0 1.0 10.0 100 1000 Rf(%)qt (bar)Standard SBT Chart (UBC 1986) Legend CCS (Cont. sensitive clay like) CC (Cont. clay like) TC (Cont. transitional) SC (Cont. sand like) CD (Dil. clay like) TD (Dil. transitional) SD (Dil. sand like) CCS CC TC SC CD TD SD 0.10 1.0 10.0 1.0 10.0 100 1000 Fr (%)QtnModified SBTn (PKR 2016) GeoEngineers Job No: 22-59-25016 Date: 2022-11-02 13:45 Site: 901 South Grady Way Renton Sounding: GEI-02 Cone: 870:T1500F15U35 Legend Sensitive, Fine Grained Organic Soils Clays Silt Mixtures Sand Mixtures Sands Gravelly Sand to Sand Stiff Sand to Clayey Sand Very Stiff Fine Grained Depth Ranges >0.0 to 7.5 ft >7.5 to 15.0 ft >15.0 to 22.5 ft >22.5 to 30.0 ft >30.0 to 37.5 ft >37.5 to 45.0 ft >45.0 to 52.5 ft >52.5 to 60.0 ft >60.0 to 67.5 ft >67.5 to 75.0 ft >75.0 ft 1 2 3 4 5 6 7 8 9 Qtn,cs = 70 Ic = 2.6 0.10 1.0 10.0 1.0 10.0 100 1000 Fr (%)QtnQtn Chart (PKR 2009) Legend Sensitive Fines Organic Soil Clay Silty Clay Clayey Silt Silt Sandy Silt Silty Sand/Sand Sand Gravelly Sand Stiff Fine Grained Cemented Sand 1 2 3 4 5 6 7 8 9 10 11 12 0.0 2.0 4.0 6.0 8.0 1.0 10.0 100 1000 Rf(%)qt (bar)Standard SBT Chart (UBC 1986) Legend CCS (Cont. sensitive clay like) CC (Cont. clay like) TC (Cont. transitional) SC (Cont. sand like) CD (Dil. clay like) TD (Dil. transitional) SD (Dil. sand like) CCS CC TC SC CD TD SD 0.10 1.0 10.0 1.0 10.0 100 1000 Fr (%)QtnModified SBTn (PKR 2016) Pore Pressure Dissipation Summary and Pore Pressure Dissipation Plots Job No:22-59-25016 Client:GeoEngineers, Inc. Project:901 South Grady Way Renton Start Date:02-Nov-2022 End Date:02-Nov-2022 CPTu PORE PRESSURE DISSIPATION SUMMARY Sounding ID File Name Cone Area (cm2) Duration (s) Test Depth (ft) Estimated Equilibrium Pore Pressure Ueq (ft) Calculated Phreatic Surface (ft) GEI-01 22-59-25016_CP01 15.0 330.0 24.0 10.0 14.0 GEI-02 22-59-25016_CP02 15.0 350.0 23.8 11.1 12.7 Total Duration 11.3 min Sheet 1 of 1 0 100 200 300 400 0.0 10.0 20.0 0.0 -10.0 -20.0 Time (s)Pore Pressure (ft)GeoEngineers Job No:22-59-25016 Date:11/02/2022 14:56 Site:901 South Grady Way Renton Sounding:GEI-01 Cone:870:T1500F15U35 Area=15 cm² Trace Summary: Filename:22-59-25016_CP01.ppd2 Depth:7.325 m / 24.032 ft Duration:330.0 s u Min:-13.6 ft u Max:10.1 ft u Final:10.1 ft WT: 4.267 m / 13.999 ft Ueq:10.0 ft 0 100 200 300 400 0.0 5.0 10.0 15.0 20.0 Time (s)Pore Pressure (ft)GeoEngineers Job No:22-59-25016 Date:11/02/2022 13:45 Site:901 South Grady Way Renton Sounding:GEI-02 Cone:870:T1500F15U35 Area=15 cm² Trace Summary: Filename:22-59-25016_CP02.ppd2 Depth:7.250 m / 23.786 ft Duration:350.0 s u Min:1.4 ft u Max:13.2 ft u Final:11.1 ft WT: 3.869 m / 12.693 ft Ueq:11.1 ft APPENDIX B Boring Logs from Previous Studies January 26, 2023 | Page B-1 File No. 22042-005-00 APPENDIX B BORING LOGS FROM PREVIOUS STUDIES Included in this section are logs from previous studies completed in the immediate vicinity of the project site. ■ The logs of nine borings (B-23 through B-29, B-31, and B-32) completed by Zipper Zeman Associates in 2002 for the Renton Retail project. r FIELD EXPLORATION PROCEDURES AND LOGS J-1470 Our field exploration program for this project included 43 borings and 3 cone penetrometer probes advanced between September 19, 2002 and October 10, 2002. The approximate exploration locations are shown on Figure 1, the Site and Exploration Plan. Exploration locations were determined by measuring distances from existing site features with a tape relative to an undated Draft Grading and Drainage Plan prepared by PacLand. As such, the exploration locations should be considered accurate to the degree implied by the measurement method. The following sections describe our procedures associated with the explorarion. Descriptive logs of the explorations are enclosed in this appendix. Soil Boring Procedures Our exploratory borings were advanced using track- and truck-mounted drill rigs operated by an independent drilling firm working under subcontract to our firm. The borings were completed utilizing hollow-stem auger and mud rotary drilling methods. An experienced geotechnical engineer from our firm continuously observed the borings logged the subsurface conditions encountered, and obtained representative soil samples. All samples were stored in moisture-tight containers and transported to our laboratory for further visual classification andF,` testing. After each boring was completed, the borehole was bacicfilled with soil cuttings and bentonite clay. r Throughout the drilling operation, soil samples were obtained at 2.5- to 5-foot depth intervals by means of the Standard Penetration Test(ASTM: D-1586). This testing and sampling procedure consists of driving a standard 2-inch outside diameter steel split spoon sampler 18 inches into the soil with a 140-pound hammer free falling 30 inches. The number of blows required to drive the sampler through each 6-inch interval is recorded, and the total number of blows struck during the final 12 inches is recorded as the Standard Penetration Resistance, or s blow count" (N value). If a total of 50 blows is struck within any 6-inch interval, the driving is stopped and the blow count is recorded as 50 blows for the actual penetration distance. The resulting Standard Penetration Resistance values indicate the relative density of granular soils and the relative consistency of cohesive soils. Undisturbed samples were obtained by pushing a 3-inch outside diameter, seamless steel I Shelby tube into the soil using the hydraulic system on the drill rig in accordance with ASTM:D- 1587. Since the thin wall tube is pushed rather than driven, the sample obtained is considered to r be relatively undisturbed. The samples were classified in the field by examining the ends of the tube prior to sealing with plastic caps. The samples were then transported to our laboratory where they were extruded for further classification and laboratory testing. The enclosed boring logs describe the vertical sequence of soils and materials encountered in each boring, based primarily upon our field classifications and supported by our subsequent laboratory examination and testing. Where a soil conta.ct was observed to be gradational, our logs indicate the average contact depth. Where a soil type changed between sample intervals, we inferred the contact depth. Our logs also graphically indicate the blow T" count, sample type, sample number, and approximate depth of each soil sample obtained from the boring, as well as any laboratory tests performed on these soil samples. If any groundwater was encountered in a borehole, the approximate groundwater depth, and date of observation, is FIELD EXPLORATION PROCEDURES AlV'D LOGS J-1470 Our field explorarion program for this project included 43 borings advanced between October September 19, 2002 and October 10, 2002. The approxunate exploration locations are shown on Figure 1, the Site and Exploration Plan. Exploration locations were deternuned by measuring distances from exisring site features with a tape relative to an undated Draft Grading and Drainage Plan prepared by PacLand. As such, the exploration locations should be considered accurate to the degree implied by the measurement method. The following sections describe our procedures associated with the exploration. Descriptive logs of the explorations are enclosed in this appendix. Soil Boring Procedures Our exploratory borings were advanced using track- and truck-mounted drill rigs operated by an independent drilling firm working under subcontract to our firm. The borings were completed utilizing hollow-stem auger and mud rotary drilling methods. An experienced geotechnical engineer from our firm continuously observed the borings logged the subsurface conditions encountered, and obtained representative soil samples. All samples were stored in moisture-tight containers and transported to our laboratory for further visual classification and testing. After each boring was completed, the borehole was backfilled with soil cuttings and bentonite clay. Throughout the drilling operation, soil samples were obtained at 2.5- to 5-foot depth intervals by means of the Standard Penetration Test(ASTM: D-1586). This testing and sampling procedure consists of driving a standard 2-inch outside diameter steel split spoon sampler 18 inches into the soil with a 140-pound hammer free falling 30 inches. The number of blows required to drive the sampler through each 6-inch interval is recorded, and the total number of blows struck during the final 12 inches is recorded as the Standard Penetration Resistance, or blow count" (N value). If a total of 50 blows is struck within any 6-inch interval, the driving is stopped and the blow count is recorded as 50 blows for the actual penetration distance. The resulting Standard Penetration Resistance values indicate the relative density of granular soils and the relative consistency of cohesive soils. Undisturbed samples were obtained by pushing a 3-inch outside diameter, seamless steel Shelby tube into the soil using the hydraulic system on the drill rig in accordance with ASTM:D- 1 87. Since the thin wall tube is pushed rather than driven, the sample obtained is considered to be relatively undisturbed. The samples were classified in the field by examining the ends of the tube prior to sealing with plastic caps. The samples were then transported to our laboratory where they were extruded for further classification and laboratory testing. The enclosed boring logs describe the vertical sequence of soils and materials encountered in each boring, based primarily upon our field classifications and supported by our subsequent laboratory examination and testing. Where a soil contact was observed to be gradational, our logs indicate the average contact depth. Where a soil type changed between sample intervals, we inferred the contact depth. Our logs also graphically indicate the blow count, sample type, sample nurnber, and approximate depth of each soil sample obtained from the boring, as well as any laboratory tests performed on these soil samples. If any groundwater was encountered in a borehole, the appro cimate groundwater depth, and date of observation, is I depicted on the log. Groundwater depth estimates are typically based on the moisture content of soil samples, the wetted portion of the drilling rods, the water level measured in the borehole after the auger has been extracted. The boring logs presented in this appendix are based upon the drilling action, observation of the samples secured, laboratory test results, and field logs. The various types of soils are indicated as well as the depth where the soils or characteristics of the soils changed. It should be noted that these changes may have been gradual, and if the changes occurred between samples intervals, they were inferred. Electric Cone Penetrometer Probes A local exploration company under subcontract to our firm performed three electric cone penetrorneter probes for this project on Septernber 26, 2002. The descriptive soil interpretations presented on the cone penetrometer probe logs have been developed by using this classification chart as a guideline. It consists of a steel cone that is hydraulically pushed into the ground at up to 40,000 pounds of pressure. Sensors on the tip of the cone collect data. Standard cone penetrometers collect information to classify soil type by using sensors that measure cone-tip pressure and friction. The detailed interpretive logs of the static cone penetrometer probes accomplished for this study are presented subsequently. PROJECT:Renton Retail JOB NO. J-1470 BORING B-23 PAGE 1 OF Location: Renton,WA Approximate Elevation: 34.5 feet Soil Description Penetration Resistance y am a m c 0 Standard Blows per foot Other o v v Z C7 Z F- 0 10 20 30 40 1.5±inches ASPHALT above 3 inches medium dense,damp,brown,gravelty SAND above loose, L _ _ _ _' _ 1 '_ _ " moist,black,pinic,and red,silty SAND with trace GRAVEL(coal a d shale fragments) f T T T __ __ S_ 1- - ,- - - ; ;-- ; -- ; - - ; -- ; - - ,o nnc 5 SZ s nnc Very loose,wet,black,pink,red,silty SAND(coal and __ _ qTp _ _ _ shale fragments) S-3 MC 3 3 MC r- Q Very soft,wet,gray,SILT and fine sandy SILT i , ; ; ; ' ; ; ;2 Boringcompletedat11.5feetonS/25/02. Groundwater encountered at approximately 7.5 feet at time of drilling. r ' _r" r ' _ * ' 15 i- -;-- -- ; - -;--'-- - - --- -- r --;- -; - - ; -- r--r-- : - -,--,-- A. Z i , , , , , , 25 Explanation o o Zo so ao so Monitoring Well Key I 2-inch O.D.split spoon sample Moisture Content 0 Clean Sand 3-inch I.D Shelby.tube sample Cuttings Plastie Limit Naturel Liquid Limit No Recovery Bentonite Grout Groundwater level at time of drilling ATD or date of ineasurement B Screened Casing Zipper Zeman Associates,Inc.BORING LOG Figure A-1 Geotechnical8 Environmental Consultants Date Drilled:9125l02 Logged By:DCW PROJECT: Renton Retail JOB NO. J-1470 BORING B-24 PAGE 1 OF Location: Renton,WA Approximate Elevation: 34 feet Soii Description L Penetration Resistance a x y Q- °'a a m Standard Biows per foot Other j H o Nl v Z C9 Z I°i 0 70 20 30 40 4±inches ASPHALT above 4.5±inches medium dense,damp,brown,graveliy SAND above very loose, --_—____ moist,grading to wet,Wack and reddish orange,silty SAND(coal and sedimentary rocfc fragments-fill) w r ' ' r ' 'r' _ ____' , ___'' 7 '_ S i--; - - , _ . ; __ 3 MC 5 S-2 3 MC r - - ; -- ,- - ----1 --;-- -- aTo ---- - --- - - •--•- • -•- --- -- 3_3 2 MC Very soft,wet,gray,SILT and sandy SILT r 10 S Boringcompletedat11.5feeton9/25/02. 1- ---- Groundwater encountered at approximately 6.5 feet at time of drilfing. r _ 'r' ' r''T'''_ ' 5 i , . . r.-, Z f_ f _ _ ! __ _ _T__T __T_ _ T_____ I ' ' ' I Explanation o o Zo so ao. so I Monitoring Well Key 2-inch O.D.split spoon sample 0 Clean Sand Moisture Content 3-inch I.D Shetby tube sample Cuttings Plastic Limit Natural Liquid Limk No Recovery Bentonite Grout Groundwater level at time of drilling ATD or date of ineasurement Screened Casing Zipper Zeman Associates,Inc.BORING LOG Figure A-1 Geotechnical&Environmental Consultants Date Drilled:9J25IO2 Logged By: DCW PROJECT: Renton Retail JOB NO. J-1470 BORING 8-25 PAGE 1 OF 3 Location: Renton,WA Approximate Elevation: 33 feet Soii Description Penetration Resistance t aa a 3 ; c Q F z Standard Blows perfoot Other Z 0 10 20 30 40 inc es asp a over in es oose,mois, ar brown,silry,graveliy SAND(Fiq) r- f _' f_ _ _ _ _ i __ i_ _ _ , _ Loose,mast,black,COALTAILINGS(Fill) S-1 6 5 Very loose,moist,black,COAL TAILINGS(Fill)5-z 3 i- - - ; - . - -;-- --; , -- -- ATD g_g 5 Soft,wet,dark brown,ORGANIC SILT with sorne sand 1 O interbedded with gray,SAND with some s lt and gravel G S-4 7 GSA Loose,saturated,gray SAND with some gravel and _ Vacesilt i . i r ' ' r' 'r ' ' r''r'' r''t' 'i 15 Loose,wet,gray,silty SAND with some organics,Vace S-5 M'' 8 2U0 gravel interbedded with sandy SILT i - ;- - ; ' "; '" ; ''; "';' '; '-'- - 20 Grades to medium dense S-6 11 GSA i . , --' - - r-- , -- - - ,--, -- r - 25 Explanation o o zo so ao so Monitoring Well Key f ` I 2-inch O.D.spiit spoon sample Clean Sand Moistu e Content 3-inch I.D Shelby tube sample CUttiflg5 Plastic Limit Natural Liquid Limit No Recovery Bentonite Grout Groundwater level at time of drilling AT°or date of ineasurement 8 Screened Casing Zipper Zeman Associates,tnc.BORING LOG Figure A-1 Geotechnical 8 Environmental Consultants Date Drilled:9/24l02 Logged By CRT PROJECT: Renton Retail JOB NO. J-1470 BORING B-25 PAGE 2 OF 3 Location: Renton,WA Approximate Elevation: 33 feet Soil Description m Penetration Resistance r aa aa :; 0 c Q N N Z SWndard Blows per foot Other > m 0 10 20 30 40 Z Medium dense to dense,wet,gray,gravelly SAND to S_ sandy GRAVEL with some silt,Vace organics c_- f __ i _T __T__T_ __ __ T` r i 30 s-s 2a z 35 s-s 20 1- - - L - - -1 - -i-- 1- --- j i . i i i . i i i i i r ' ' r _' r ' ' r " _r_ ' t' 'r'' '''r 40 Loose to medium dense,wet,gray,silty SAND with 5-10 11 some gravel with interbedded PEAT(3') k r - - --r -- r --r- - --- ---- -- 6 i , i i . i 45 Medium dense to dense,wet,gray,gravelly SAND with S-11 37 I somesiltandtraceorganics 1 '' L" 1''' '' Medium dense,wet,gray,silty SAND with some gravel and peaty organics(1^,i -- f '- f ' ' I- 'T'T''T' 'T''?' ' 50 Explanation o io zo so ao so Monito ing Well Key I2-inch O.D.split spoon sample 0 Clean Sand MOiSture Content 3-inch I.D Shelby tube sample Cuttings plastic Limit Natural uquw um c No Recovery Bentonite Grout Groundwater level at time of drilling ATD or date of ineasurement B Screened Casing Zipper Zeman Associates,Inc.BORING LOG Figure A-1 Geotechnical8 Environmental Consultants Date Drilled:9124/02 Logged By:CRT PROJECT:Renton Retaii JOB NO. J-1470 BORING 8-25 PAGE 3 OF 3 Location: Renton,WA Approximate Elevation: 33 feet Soil Description Penetration Resistance y c ` 0 caaa °: Q N Z Standard Blaws per foot Other 0 10 20 30 40 Z Medium dense,wet,gray,silty SAND with some grevel 12 zo and peaty organics(t") t 1- -1 -- i i i i . I f _T _ i __ 1 _ T _ T T t t__ _ i__a__1__ __ . I nmm i i i i 55 Medium dense,wet,gray,silty,fine SAND S-13 17 g;z 60 Loose,wet,gray,silty SAND interbedded with sandy _— S-14 9 SILT i--1- -'-- i i i i T_ _ i __1__ L_' 1 _ _ __ L_l__ 1__ __ _' 65 Medium dense,saturated,gray,silty SAND interbedded __^ 5-15 20 withsandySlLT Very dense,damp,light gray,silty SANDSTONE 70 oar Boring completed at 70 feet on 9l24/02 S-16 Groundwater seepage observed at 6.5 feet at time of driliing 1 ' - ' t ' '- -, -- f_t _ _ _ _ __T_ T_ _ T ' __ 75 Explanation o 0 2o ao ao so Monitoring Wetl Key I F : I 2-inch O.D.split spoon sample Moisture Content Clean Sand 3-inch I.D Shelby tube sampie Cuttings Plastie Limit Natural Uquid L(mit No Recovery Bent nite Grout Groundwater levei at time of drilling f.... ATD or date of ineasurement 8 Screened Casing Zipper Zeman Associates, Inc.BOR NG LOG Figure A-1 Geotechnical& Environmental Consultants Date Drilied: 9/2M02 Lagged By: CRT PROJECT:Renton Retail JOB NO. J-1470 BORING B-26 PAGE 1 OF Location: Renton,WA Approximate Elevation: 32 feet Soil Description Penetration Resistance i = ` fl' a a- w m 0 16 Standard Bbws per foot Other j y G tn V Z C7 Z H 0 10 20 30 40 50 urface grave over medium dense,moist,brown,silry, sandy GRAVEL(RII) T _ ' ' t_T_ _ T__ i_ ' Loose,moist,black,silty SAND,COAL TAILINGS, some organic wood dabris(Fill) S 11 5 Very loose,moist,block,silty SAND with COAL S-2 3 TAILINGS wootl debris and organics(F11) Very soft,wet,black,organic SILT with some wood — - MC=1az% iragments 3 ATD . - I - - --' -- ' -- ' - - , -- - -- 1 ATT Very soft,wet to saturated,greenish ray,sandy SILT S-4 1 MC with some day interbedded with silty SAND t-- - , w i _- _ _ t T _T_ T_ i __ i r i i i L L 1 1 1 1 1 15 Ve soft,wet,bro ra ,sil SAND interbedded with M tt676 Y 9 Y tY S-5 2 200W siItySANDa dPEAT(4") 20 Medium dense,wet,gray,sitry SAND with some brow organics and Vace gravel S-6 16 Boring completed at 21.5 feet on 9/26/02 Groundwater seepage observed at B feet at time of driiling 1 - -; -- --- ; - , -'-- T _ __ T__7 _ __ 25 Explanation o o 2o so ao so I Monitoring Well Key 2-inch O.D.split spoon sample Moisture Content Clean Sand 3-inch!.D Shelby tube sample Cuttings Plastic Limit Naturel Liquid Limft No Recovery Bentonite Grout Groundwater level at time of drilling ATD or date of ineasurement B Screened Casing Zipper Zeman Associates,Inc.BORING LOG Figure A-1 Geotechnicai&Environmental Consultants Date Drilled: 9126102 Logged By: CRT PROJECT:Renton Retail JOB NO. J-1470 BORING B-27 PAGE 1 OF Location: Renton,WA Approximate Elevation: 31 feet Soil Description Penetration Resistance H m °' m = ctaaa :: Q.3 0 1° Standard Blows per foot Other y o f 2 C7 Z 1 0 10 20 30 40 Medium dense gradi g to very loose,moist grading to wet(below 4.5 feet),brown,gray,and black,grevelly, s'silty SAND(Fill) k r - - r - - r - - *- - - -' -t-- a'' ' "'a'"1'' S-1 16 MC r - - ; - - r - - r - -r -- i --,-- ; ,-- 5 ATD - -` -- ` -- ` - - `--` - - '--'- - ' -- '-- S-z r- - r - - r•- ; - , - 3 MC Soft to very soft,wet,gray,SILT with interbeds of saturated,greenish-gray,fine to medium SAND, irtegular horizons of fibrous wganics up to 0.25 inches hick S_3 3 10 s-a Boringcompletedat11.5feeton9/25/02. 1-- '- -1-- - i_ Groundwater encountered at approximately 4.5 feet at timeofdriilin9 15 20 i ; - T_ _ i_ _ _ ' __l'_ GJ Expianation o 0 20 3 ao so Monitoring Well Key I2-inch O.D.split spoon sample Clean Sand Moisture Content 3-inch I.D Shelby tube sample Cuttings plastie Umit Natural uquia um c No Recovery Bentonite Grout Groundwater level at time of driiling ATD or date of ineasurement E Screened Casing Zipper Zeman Associates,Inc.BORlNG LOG Figure A-1 Geotechnical& Environmental Consuftants Date Drilled:9/25l02 Logged By:DCW PROJECT: Renton Retail JOB NO. J-1470 BORING B-28 PAGE 1 OF Location: Renton,WA Approximate Elevation: 32.5 feet Soil Description m 6 Penetration Resistance y L aa a y 0 3 c a Standard Blows per foot Other j y C t/ t/ Z C7 3 Z H 0 10 20 30 40 Loose to medium dense,damp,brown,gravelly SAND Fillj r'' ' ' r'" r''T"'r'_i'_t"' Medium stiff to soft,moist to wet,dark brown,sandy SILT with some fine organics(FI1) S-t 1 5 MC 5 S'2 1 -- ;- !- -; -r -- 1 -- - ' _ 3 MC qTp Very soft.wet.9raY.SILT with some wood fiber g g 1 MC horizons 10 2 Boringcompletedat11.5feeton9l25/02. i --1 - - = - - Groundwater encountered at approximately 7.5 feet at v time of drilling. r '' r' ' r ' " r ''T ''T' " . t ' 15 20 L - '- - '- i -- i f T ' T_'T_T_ 1 1 __ 25 Explanation o o Zo so ao so Monitoring Well Key I2-inch O.D.split spoon sample Clean Sand MolstU e Content 3-inch I.D Shelby tube sample Cuttings Plastic Limit Natural Llqutd Llmlt No Recovery Bentonite Grout Groundwater level at time of drilling ATo or date of ineasurement B Screened Casing Zipper Zeman Associates,Inc.BORING LOG Figure A-1 Geotechnical 8 Environmental Consultants Date Drilled:9/25102 Logged By: DCW PROJECT:Renton Retail JOB NO. J-1470 BORING B-29 PAGE 1 OF Location: Renton,WA Approximate Elevation: 33 feet Soil Description Penetration Resistance yma orG1 0 3 =Q m O. = 41 m a i° Standard Btows per foot Other y o V7 fn Z (7 3 Z H 0 10 20 30 40 3.5±inches ASPHALT above 4±of inedium dense, damp,brown,gravelly SAND above very loose,moist, _____________ i _ _ _ _ __ _: __ black,silty SAND(coal fragments)with scattered horizons of brown,gravelly SAND(FiA) r -- ------- - - - - s-' 3 MC 5 s-z L - -; - ` -. -;- -.- _ , _ _ Mc A - - - -- - - - - -- - • - ; - -• -- -- Very loose,saturated,gray,fine SAND with some sitty zones and scattered fibrous organics r-- --; -'; '' , ' -- - -; - S'3 1 MC 10 Bonngcompletedat11.5feeton9/25/02. Groundwater e countered at approximately 7.0 feet at time of drilling. r- - r--r - -r-- r' -T-'1 ' 5 i i 2 i , , , - -- r --*--r - -r-- r -1- -t -- 25 Explanation o o zo so ao 50 Monitoring Well Key I2-inch O.D.split spoon sample Clean Sand Moisture Content 3-inch t.D Shelby tube sample Cuttings Plasdc Llmit Natural Liquid Um(t No Recovery Bentonite . Grout Groundwater level at time of drilling ATD or date of ineasurement B Screened Casing Zipper Zeman Associates,Inc.BORING LOG Figure A-1 Geotechnical 8 Environmental Consultants Date Drilled:9/25102 Logged By: DCW PROJECT: Renton Retail JOB NO. J-1470 BORING B-30 PAGE 1 OF Location: Renton,WA Approximate Elevation: 34 feet Soil Description D Penetration Resistance y r m d - m a r a a °' °; Qy y Z Siandard Blows perfoot Other Z 0 10 20 30 40 Medium dense,damp,brown,gravelly SAND(Fill) i r-- r''r- -r- -r -- 't'-T'- -' Very loose,mast grading to saturated,black,red,and beige,silty SAND and sandy SILT(coal fragments-filq S-1 M 5856 3 MC 5 S-2 A. ; -- ;- - - - ;- - i -- ; -- - - ,MF-59x 2 MC r-- ; -- --r -;- ;- ;-- g'3 MC=58% 1 MC Very stiff,wet,gray,SILT with trace fine SAND and fibrous organics S-4 0 Boringcompletedat11.5feeton9/25/02. 1--, -- , Groundwater encountered at approximately 5.5 feet at time of drilling. r'-r--r--r"r- , -T-- r--1- 1 - 1 -- a '' -' '- '- -- 15 20 1 - -L -- i- -1- - r __ f __ ' T _ _T__T''T'_ _ ' 2g Explanation o o Zo so ao so I Monitoring Well Key 2-inch O.D.split spoon sample Clean Sand Moisture Content 3-inch I.D Shelby tube sample Cuttings Plastie Lfmft Naturel Uquld Limit No Recovery Bentonite Grout Groundwater level at time of drilling aro or date of ineasurement B Screened Casing Zipper Zeman Associates,Inc.BORING LOG Figure A-1 Geotechnical 8 Environmental Consultants Date Drilled:9/25IO2 Logged By:DCW PROJECT:Renton Retail JOB NO. J-1470 BORING B-31 PAGE 1 OF 1 Location: Renton,WA Approximate Elevation: 32 feet Soii Description Penetration Reslstance c y a a °. :' o N Z Standard Bbws per foot Other j FZ 0 10 20 30 40 Medium dense grading to very loose,damp to moist, brown and dark gray,silty SAND with trace gravel(Fill) —_-----_ r - -- - -, -- - -r- -,--.--, - - r- S i -- 3 MC 5 ---------------------------------------------- Verysoft.wet,darkbrownandgray,SlLTwithsome -- --- fine sand and organic material interbeds S-2 i ; ; ; i ; ; 1 0 MC r-- ATD Loose to very loose,saturated,grey,fine SANO with some fine and fibrous organics S-3 5 MC 10 4 Boring completed at 11.5 feet on 8/25/02. L _ _L__1__1. _ l __ Groundwater encountered at approximately 7.5 feet at time of drilling. w- - r ''r'' r "'r ' 'r' 'r' , _' T' '' ' 15 20 1- -1 --i- -1 - - T ' 'T_ _ T _ _T_' 1 25 Explanation o o zo so ao so Monitoring Well Key I2-inch O.D.split spoon sample Clean Sand Moisture Content 3-inch I.D Shelby tube sample Cuttings plastic limit Nawr Uquid Ltmit No Recovery Bentonite Grout Groundwater level at time of drilling ATD or date of ineasurement B Screened Casing Zipper Zeman Associates,Inc.BORING LOG Figure A-1 Geotechnlcal&Environmental Consultants Date Drtlled:9/25l02 Logged By:DCW PROJECT:Renton Retail JOB NO. J-1470 BORING B-32 PAGE 1 OF Location: Renton,WA Approximate Elevation: 33 feet Soil Description Penetration Resistance x mm d °' ` Y a °. Q y y Z Standard Blaws perfoot Other FZ 0 10 20 30 40 Medium dense,damp,brown,silty,gravelly SAND(FII) T _ _'._i' _T__T. 'i'_ " Medium stiff,moist to wet,black and brown,silty SAND _ _ coal fragments-fill) S , t- - - - - - - -: , ,5 200 1 - -; - - ; - - r- -r - - , -,--,-- 5 ATD Very loose,wet,black,SAND with some fine roots and g_2 MC=5i9 Z MC wood fibers(coal fragments-fill) r - -r--r - - r ; - ; - - ; --;- ; - Very loose,saturated,gray-brown,fine SAND S'3 4 MC 10 s-a 3 Boring completed at 11.5 feet on 9/25l02. L_' L_ '1' 1' "1 '_ f'''Groundwater encountered at approximately 4.5 feet at Gme of drilling. w- r"" r'" r "r "r'_r_' '1"7 ' 2 L , f ' ' T ' _T_ _ _T'-T__l __ 25 Explanation o io zo ao ao so Monitoring Well Key I2-inch O.D.split spoon sample Clean Sand MoiStu e Content 3-inch I.D Shelby tube sample Cuttings Plastie LimR Na uroi Liquid Limit No Recavery Bentonite Grout Groundwater level at time of drilling aro or date of ineasurement B Screened Casing Zipper Zeman Associates,inc.BORING LOG Figure A-'1 Geotechnical&Environmental Consultants Date Drilled:9125/02 Logged By:CRT APPENDIX C Report Limitations and Guidelines for Use January 26, 2023 | Page C-1 File No. 22042-005-00 APPENDIX C REPORT LIMITATIONS AND GUIDELINES FOR USE 1 This appendix provides information to help you manage your risks with respect to the use of this report. Geotechnical Services Are Performed for Specific Purposes, Persons and Projects This report has been prepared for the exclusive use of Velmeir Acquisition Services, L.L.C. This report is not intended for use by others, and the information contained herein is not applicable to other sites. GeoEngineers structures our services to meet the specific needs of our clients. For example, a geotechnical or geologic study conducted for a civil engineer or architect may not fulfill the needs of a construction contractor or even another civil engineer or architect that are involved in the same project. Because each geotechnical or geologic study is unique, each geotechnical engineering or geologic report is unique, prepared solely for the specific client and project site. Our report is prepared for the exclusive use of our Client. No other party may rely on the product of our services unless we agree in advance to such reliance in writing. This is to provide our firm with reasonable protection against open-ended liability claims by third parties with whom there would otherwise be no contractual limits to their actions. Within the limitations of scope, schedule and budget, our services have been executed in accordance with our Agreement with the Client and generally accepted geotechnical practices in this area at the time this report was prepared. This report should not be applied for any purpose or project except the one originally contemplated. A Geotechnical Engineering or Geologic Report Is Based on a Unique Set of Project-specific Factors This report has been prepared for the 901 South Grady Way project in Renton, Washington. GeoEngineers considered a number of unique, project-specific factors when establishing the scope of services for this project and report. Unless GeoEngineers specifically indicates otherwise, do not rely on this report if it was: ■ Not prepared for you, ■ Not prepared for your project, ■ Not prepared for the specific site explored, or ■ Completed before important project changes were made. For example, changes that can affect the applicability of this report include those that affect: ■ The function of the proposed structure; ■ Elevation, configuration, location, orientation or weight of the proposed structure; ■ Composition of the design team; or ■ Project ownership. 1 Developed based on material provided by ASFE, Professional Firms Practicing in the Geosciences; www.asfe.org. January 26, 2023 | Page C-2 File No. 22042-005-00 If important changes are made after the date of this report, GeoEngineers should be given the opportunity to review our interpretations and recommendations and provide written modifications or confirmation, as appropriate. Subsurface Conditions Can Change This geotechnical or geologic report is based on conditions that existed at the time the study was performed. The findings and conclusions of this report may be affected by the passage of time, by manmade events such as construction on or adjacent to the site, or by natural events such as floods, earthquakes, slope instability or groundwater fluctuations. Always contact GeoEngineers before applying a report to determine if it remains applicable. Most Geotechnical and Geologic Findings Are Professional Opinions Our interpretations of subsurface conditions are based on field observations from widely spaced sampling locations at the site. Site exploration identifies subsurface conditions only at those points where subsurface tests are conducted or samples are taken. GeoEngineers reviewed field and laboratory data and then applied our professional judgment to render an opinion about subsurface conditions throughout the site. Actual subsurface conditions may differ, sometimes significantly, from those indicated in this report. Our report, conclusions and interpretations should not be construed as a warranty of the subsurface conditions. Geotechnical Engineering Report Recommendations Are Not Final Do not over-rely on the preliminary construction recommendations included in this report. These recommendations are not final, because they were developed principally from GeoEngineers’ professional judgment and opinion. GeoEngineers’ recommendations can be finalized only by observing actual subsurface conditions revealed during construction. GeoEngineers cannot assume responsibility or liability for this report's recommendations if we do not perform construction observation. Sufficient monitoring, testing and consultation by GeoEngineers should be provided during construction to confirm that the conditions encountered are consistent with those indicated by the explorations, to provide recommendations for design changes should the conditions revealed during the work differ from those anticipated, and to evaluate whether or not earthwork activities are completed in accordance with our recommendations. Retaining GeoEngineers for construction observation for this project is the most effective method of managing the risks associated with unanticipated conditions. A Geotechnical Engineering or Geologic Report Could Be Subject to Misinterpretation Misinterpretation of this report by other design team members can result in costly problems. You could lower that risk by having GeoEngineers confer with appropriate members of the design team after submitting the report. Also retain GeoEngineers to review pertinent elements of the design team's plans and specifications. Contractors can also misinterpret a geotechnical engineering or geologic report. Reduce that risk by having GeoEngineers participate in pre-bid and preconstruction conferences, and by providing construction observation. January 26, 2023 | Page C-3 File No. 22042-005-00 Do Not Redraw the Exploration Logs Geotechnical engineers and geologists prepare final boring and testing logs based upon their interpretation of field logs and laboratory data. To prevent errors or omissions, the logs included in a geotechnical engineering or geologic report should never be redrawn for inclusion in architectural or other design drawings. Only photographic or electronic reproduction is acceptable, but recognize that separating logs from the report can elevate risk. Give Contractors a Complete Report and Guidance Some owners and design professionals believe they can make contractors liable for unanticipated subsurface conditions by limiting what they provide for bid preparation. To help prevent costly problems, give contractors the complete geotechnical engineering or geologic report, but preface it with a clearly written letter of transmittal. In that letter, advise contractors that the report was not prepared for purposes of bid development and that the report's accuracy is limited; encourage them to confer with GeoEngineers and/or to conduct additional study to obtain the specific types of information they need or prefer. A pre-bid conference can also be valuable. Be sure contractors have sufficient time to perform additional study. Only then might an owner be in a position to give contractors the best information available, while requiring them to at least share the financial responsibilities stemming from unanticipated conditions. Further, a contingency for unanticipated conditions should be included in your project budget and schedule. Contractors Are Responsible for Site Safety on Their Own Construction Projects Our geotechnical recommendations are not intended to direct the contractor’s procedures, methods, schedule or management of the work site. The contractor is solely responsible for job site safety and for managing construction operations to minimize risks to on-site personnel and to adjacent properties. Read These Provisions Closely Some clients, design professionals and contractors may not recognize that the geoscience practices (geotechnical engineering or geology) are far less exact than other engineering and natural science disciplines. This lack of understanding can create unrealistic expectations that could lead to disappointments, claims and disputes. GeoEngineers includes these explanatory “limitations” provisions in our reports to help reduce such risks. Please confer with GeoEngineers if you are unclear how these “Report Limitations and Guidelines for Use” apply to your project or site. Geotechnical, Geologic and Environmental Reports Should Not Be Interchanged The equipment, techniques and personnel used to perform an environmental study differ significantly from those used to perform a geotechnical or geologic study and vice versa. For that reason, a geotechnical engineering or geologic report does not usually relate any environmental findings, conclusions or recommendations; e.g., about the likelihood of encountering underground storage tanks or regulated contaminants. Similarly, environmental reports are not used to address geotechnical or geologic concerns regarding a specific project. January 26, 2023 | Page C-4 File No. 22042-005-00 Biological Pollutants GeoEngineers’ Scope of Work specifically excludes the investigation, detection, prevention or assessment of the presence of Biological Pollutants. Accordingly, this report does not include any interpretations, recommendations, findings, or conclusions regarding the detecting, assessing, preventing or abating of Biological Pollutants and no conclusions or inferences should be drawn regarding Biological Pollutants, as they may relate to this project. The term “Biological Pollutants” includes, but is not limited to, molds, fungi, spores, bacteria, and viruses, and/or any of their byproducts. If Client desires these specialized services, they should be obtained from a consultant who offers services in this specialized field.