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05 Quality Geo NW - Geotechnical Services Report_20251112
1 10/3/2025 (revised 11/12/2025) LDC Attn: Ross Jarvis, P.E. 2800 Forest Hill Dr SE Olympia, WA 98501 Subject: Geotechnical Services Report Yelm Veterans Memorial Park - Geotechnical Investigation 15425 WA-507, Yelm, WA 98597 Project Number: QG25-134 Dear Client, At your request, Quality Geo NW, PLLC (QG) has completed a soils investigation of the above- referenced project. The investigation was performed in accordance with our proposal for professional services. We would be pleased to continue our role as your geotechnical consultant of record during the project planning and construction phases, as local inspection firms have not been found to be as familiar or reliably experienced with geotechnical design. This may include soil subgrade inspections, periodic review of special inspection reports, or supplemental recommendations if changes occur during construction. We will happily meet with you at your convenience to discuss these and other additional Time & Materials services. We thank you for the opportunity to be of service on this project and trust this report satisfies your project needs currently. QG wishes you the best while completing the project. Respectfully Submitted, Quality Geo NW, PLLC Luke Preston McCann, L.E.G. Ray Gean II Owner + Principal Staff Geologist/Project Manager Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 2 SOILS REPORT YELM VETERANS MEMORIAL PARK GEOTECHNICAL INVESTIGATION 15425 WA-507 YELM, WA 98597 LDC Attn: Ross Jarvis, P.E. 2800 Forest Hill Dr SE Olympia, WA 98501 Prepared by: Approved by: Jason Cross, G.I.T. Luke Preston McCann, L.E.G. Staff Geologist Principal Licensed Engineering Geologist Quality Geo NW, PLLC Geotechnical Investigation & Engineering Consultation Phone: 360-878-9705| Web: qualitygeonw.com Mail: 4631 Whitman Ln SE, Ste D, Lacey, WA 98513 10/3/2025 (revised 11/12/2025) QG Project # QG25-134 Copyright © 2025 Quality Geo NW, PLLC All Rights Reserved. 10/3/2025 (revised 11/12/2025) Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 3 TABLE OF CONTENTS 1.0 INTRODUCTION ............................................................................................................... 4 1.1 PROJECT DESCRIPTION ............................................................................................................................ 4 1.2 FIELD WORK ................................................................................................................................................ 4 2.0 EXISTING SITE CONDITIONS ........................................................................................ 5 2.1 AREA GEOLOGY ......................................................................................................................................... 5 2.2 SITE & SURFACE CONDITIONS ............................................................................................................... 5 2.3 SOIL LOG ...................................................................................................................................................... 6 2.4 SURFACE WATER AND GROUNDWATER CONDITIONS .................................................................... 6 3.0 GEOTECHNICAL RECOMMENDATIONS .................................................................... 7 3.1 SHALLOW FOUNDATION RECOMMENDATIONS ................................................................................ 7 3.1.1 BUILDING SLAB ON GRADE FLOOR ............................................................................................ 8 3.2 LATERAL SOIL & CONCRETE FOUNDATION CONSIDERATIONS .................................................... 9 3.3 SEISMIC DESIGN PARAMETERS AND LIQUEFACTION .................................................................... 10 3.4 INFILTRATION RATE DETERMINATION ............................................................................................. 11 3.4.1 GRADATION ANALYSIS METHODS & RESULTS .......................................................................11 3.4.2 TREATMENT POTENTIAL ..............................................................................................................13 3.5 DRAINAGE RECOMMENDATIONS ........................................................................................................ 13 3.6 IMPERVIOUS PAVEMENT CONSIDERATIONS .................................................................................... 14 3.6.1 RIGID CONCRETE PAVEMENT AND FLATWORKS ..................................................................15 3.6.2 CBR SELECTION ..............................................................................................................................16 4.0 CONSTRUCTION RECOMMENDATIONS .................................................................. 17 4.1 EARTHWORK ............................................................................................................................................. 17 4.1.1 GRADING & EXCAVATION.............................................................................................................17 4.1.2 SUBGRADE EVALUATION & PREPARATION .............................................................................17 4.1.3 SITE PREPARATION, EROSION CONTROLL, WET WEATHER ...............................................17 4.2 STRUCTURAL FILL MATERIALS AND COMPACTION ...................................................................... 18 4.2.1 MATERIALS .......................................................................................................................................18 4.2.2 FILL PLACEMENT AND COMPACTION ......................................................................................19 4.3 TEMPORARY EXCAVATIONS AND TRENCHES ................................................................................. 19 5.0 SPECIAL INSPECTION .................................................................................................. 21 6.0 LIMITATIONS ................................................................................................................. 22 Region & Vicinity Maps ................................................................................................................23 Exploration Map .............................................................................................................................24 Exploration Logs ............................................................................................................................25 Laboratory Results..........................................................................................................................30 Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 4 1.0 INTRODUCTION This report presents the findings and recommendations of Quality Geo NW’s (QG) soil investigation conducted in support of new site surface improvements. 1.1 PROJECT DESCRIPTION QG understands the project entails the construction of a new memorial park within a residentially developed site. QG has been contracted to perform a soils investigation of the proposed site to provide development, infiltration potential, earthwork development and foundation recommendations. 1.2 FIELD WORK Site exploration activities were performed on 9/3/2025. Exploration locations were marked in the field by a QG Staff Geologist with respect to the map provided and cleared for public conductible utilities. Our exploration locations were selected by a QG Staff Geologist prior to fieldwork to provide safest access to relevant soil conditions. The geologist directed the advancement of 4 excavated test pits (TP). The test pits were advanced within the vicinity of the anticipated development footprint areas, to maximum depths of 7.75 feet below present grade (BPG) in general accordance with the specified contract depth and equipment capabilities. During explorations QG logged and field classified each soil horizon encountered in accordance with the Unified Soil Classification System (USCS). Representative soil samples were collected from each unit, identified according to boring location and depth, placed in plastic bags to protect against moisture loss, and were transported to the soil laboratory for supplemental classification and other tests. QG advanced 1 Kessler Dynamic Cone Penetrometer (K-DCP) test at a representative location within the vicinity of the proposed development and as conditions permitted. The penetrometer test was terminated upon reaching the equipment’s maximum practical extent. During penetrometer advancement, blow counts were recorded in 50-mm increments as a 17.6-pound weight was dropped 22 inches. Blow counts were then converted to resistance (kg/cm2), standard penetration blow counts (N-values), and corresponding soil consistency, with complete results shown on the attached logs. Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 5 2.0 EXISTING SITE CONDITIONS 2.1 AREA GEOLOGY QG reviewed available map publications to assess known geologic conditions and hazards present at the site location. The Washington Geologic Information Portal (WGIP), maintained by the Department of Natural Resources Division of Geology and Earth Resources, provides 1:100,000- scale geologic mapping of the region. Geology of the site consists of Pleistocene continental glacial drift (Qgog). The Qgog soil on site is typically summarized as, “Recessional and proglacial, stratified pebble, cobble, and boulder gravel deposited in meltwater streams and their deltas; locally contains ice-contact deposits.” The WGIP Map also offers layers of mapped geohazard conditions within the state. According to the regional-scale interactive map, no known geohazards are mapped for the site. The United States Department of Agriculture portal (USDA) provides a soil mapping of the region. The soil within the parcel is mapped as Spanaway gravelly sandy loam (110) in the center and southwest corner of the site, and Spanaway stony sandy loam (112, 113) in the southern portion and northeast corner of the site. Spanaway gravelly sandy loam formed as terraces and outwash plains derived from volcanic ash over gravelly outwash. The soils are described as gravelly sandy loam from 0 to 15 inches, very gravelly loam from 15 to 20 inches, and extremely gravelly sand from 20 to 60 inches. Depth to restrictive feature is more than 80 inches. Capacity of most limiting layer to transmit water (ksat) is listed as high (1.98 to 5.95 in/hr). Depth to water table is more than 80 inches. Spanaway stony sandy loam formed as terraces and outwash plains derived from volcanic ash over gravelly outwash. The soils are described as stony sandy loam from 0 to 16 inches, very gravelly sandy loam from 16 to 22 inches, and extremely gravelly sand from 22 to 60 inches. Depth to restrictive feature is more than 80 inches. Capacity of most limiting layer to transmit water (ksat) is listed as high (1.98 to 5.95 in/hr). Depth to water table is more than 80 inches. 2.2 SITE & SURFACE CONDITIONS The project site comprises 2 parcels that roughly form a triangle. The parcel that has residential development features two homes, and vegetation consists of grass with some trees and bushes. The parcel that has no development features Mill Pond, which surrounded by trees, bushes, blackberries, and water grass. To the north and east is a golf course. To the east and south are residential homes. To the west is the St Columban Catholic Church. Surface water on site only consists of Mill Pond. Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 6 2.3 SOIL LOG Site soil conditions were consistent across the property within all test pits. Representative lab samples were taken from TP-3 and TP-4. Soils conditions from TP-4 were as follows: • 0.0’ to 5.0’ – Silty Gravel with Sand (GM) The brown silty gravel with sand soil had organics in the form of roots, abundant rounded cobbles up to approximately 18 inches in diameter. The soil was dry and no mottling was observed. The soil was in dense condition. • 5.0’ to 6.5’ – Silty Gravel with Sand (GM) The grayish brown to tan silty gravel with sand soil had organics in the form of roots, abundant rounded cobbles up to approximately 18 inches in diameter. The soil was dry, and no mottling was observed. The soil was in dense condition. This soil layer experienced frequent caving. No groundwater was observed in any of the test pits. 2.4 SURFACE WATER AND GROUNDWATER CONDITIONS No active surface water features are present on site. During our test pit explorations, a groundwater table was not encountered. Based on well logs made publicly available by the WA Department of Ecology, the regional groundwater table is reported to exist approximately 40 feet beneath the surface on site. However, the presence of Mill Pond indicates the presence of a perched water table at the surface elevation of the pond. Groundwater elevations for this project site should be based on this perched water table. QG’s scope of work did not include determination or monitoring of seasonal groundwater elevation variations, formal documentation of wet season site conditions, or conclusive measurement of groundwater elevations at depths past the extent feasible for explorations at the time of the field explorations. Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 7 3.0 GEOTECHNICAL RECOMMENDATIONS 3.1 SHALLOW FOUNDATION RECOMMENDATIONS Assuming site preparation is completed as described below, we recommend the following: • Subgrade Preparation QG recommends excavating and clearing any loose or organic cover soils, including the thin overriding layer of topsoil where necessary, from areas of proposed pavement construction, down to firm bearing conditions and benching the final bottom of subgrade elevation flat. Excavations should be performed with a smooth blade bucket to limit disturbance of subgrade soils. Vibratory compaction methods shall be used to densify the underlying non-organic native soils. After excavations have been completed to the planned subgrade elevations, but before placing fill or structural elements, the exposed subgrade should be evaluated under the periodic guidance of a QG representative. Any areas that are identified as being soft or yielding during subgrade evaluation should be brought to the attention of the geotechnical engineer. Where over excavation is performed below a structure, the over excavation area should extend beyond the outside of the footing a distance equal to the depth of the over excavation below the footing. The over-excavated areas should be backfilled with properly compacted structural fill. The proposed buildings may utilize either stepped or continuous footings with slab-on-grade elements. For continuous footing elements, upon reaching bearing strata, we recommend benching foundation lines flat. Continuous perimeter and strip foundations may be stepped as needed to accommodate variations in final subgrade level. We also recommend maximum steps of 18 inches with spacing of at least 5 feet be constructed unless specified otherwise by the design engineer. Structural fill may then be placed as needed to reestablish final foundation grade. • Allowable Bearing Capacity: Up to 1,500 pounds per square foot (psf) for foundations placed on compacted native soil or approved, granular, and compacted structural fill in accordance with the recommendations of Section 4.2. Bearing capacities, at or below 1,500 psf may eliminate the need for additional inspection requirements if approved by the county. The allowable bearing capacity may be increased by 1/3 for transient loading due to wind and seismic events. • Minimum Footing Depth: For a shallow perimeter and spread footing system, all exterior footings shall be embedded a minimum of 18 inches and all interior footings shall be embedded a minimum of 12 inches below the lowest adjacent finished grade, but not less than the depth required by design. However, all footings must also penetrate to the prescribed bearing stratum cited above. Minimum depths are Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 8 referenced per IBC requirements for frost protection; other design concerns may dictate greater values be applied. • Minimum Footing Width: Footings should be proportioned to meet the stated bearing capacity and/or the IBC 2021 (or current) minimum requirements. For a shallow perimeter and spread footing system, continuous strip footings should be a minimum of 16 inches wide and interior or isolated column footings should be a minimum of 24 inches wide. • Estimated Settlements: All concrete settles after placement. We estimate that the maximum settlements will be on the order of 0.5 inch, or less, with a differential settlement of ½ inch, or less, over 50 linear feet. Settlement is anticipated to occur soon after the load is applied during construction. 3.1.1 BUILDING SLAB ON GRADE FLOOR QG anticipates that slab-on-grade floors are planned for the interior of the proposed building. Based on typical construction practices, we assume finished slab grade will be similar to or marginally above present grade for the below recommendations. If floor grades are planned to be substantially raised or lowered from existing grade, QG should be contacted to provide revised or alternative recommendations. • Capillary Break: A capillary break will be helpful to maintain a dry slab floor and reduce the potential for floor damage resulting from shallow perched water inundation. To provide a capillary moisture break, a 6-inch thick, properly compacted granular mat consisting of open-graded, free-draining angular aggregate is recommended below floor slabs. To provide additional slab structural support, or to substitute for a structural fill base pad where specified, QG recommends the capillary break should consist of crushed rock all passing the 1-inch sieve and no more than 3 percent (by weight) passing the U.S. No. #4 sieve, compacted in accordance with Section 4.2.2 of this report. • Vapor Barrier: A vapor retarding membrane such as 10 mil polyethylene film should be placed beneath all floor slabs to prevent transmission of moisture where floor coverings may be affected. Care should be taken during construction not to puncture or damage the membrane. To protect the membrane, a layer of sand no more than 2 inches thick may be placed over the membrane if desired. If excessive relict organic fill material is discovered at any location, additional sealant or more industrial gas barriers may be required to prevent off-gassing of decaying material from infiltrating the new Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 9 structure. These measures shall be determined by the structural engineer to meet local code requirements as necessary. • Structural Design Considerations: QG assumes the design and specifications of slabs will be assessed by the project design engineer. We suggest a minimum unreinforced concrete structural section of 4.0 inches be considered to help protect against cracking and localized settlement, especially where larger equipment or localized loads are anticipated. It is generally recommended that any floor slabs and annular exterior concrete paving subject to vehicular loading be designed to incorporate reinforcing. Additionally, some level of reinforcing, such as a wire mesh may be desirable to prolong slab life due to the overwhelming presence of such poor underlying soils. It should be noted that QG does not express any guarantee or warranty for proposed slab sections. 3.2 LATERAL SOIL & CONCRETE FOUNDATION CONSIDERATIONS The results of QG’s investigation indicate shallow and deep subsurface conditions at the proposed building areas consist of silty gravel with sand and poorly graded sand with silt and gravel at depth. The finished grade is assumed to be similar to the existing grade. In general, native soils may be considered suitable for use as backfill against new in-ground structures or direct bearing on a case- by-case basis. QG understands that the building structures may likely incorporate continuous perimeter grade beams as well as isolated footings, incorporating soil amendment as determined by the structural design team. For lateral support of these structures, the following soil parameters should be considered regarding any structural fill against these features (ignoring the upper 18 inches, due to freeze/thaw softening, unless covered in concrete or asphalt). Table 1. Lateral Earth Pressures Soil Type Active Pressure (PSF*H) At-Rest Pressure (PSF*H) Seismic Surcharge (PSF*H) Grade Beam Passive Equivalent Fluid Weight (PCF) Grade Beam Coefficient of Friction Existing GM Soils 40 60 13 203* 0.35** Existing SP-SM Soils 30 60 11 203* 0.38** New Structural Fill 35 55 10 200 0.35 *Factor of Safety: 2.0 **Factor of Safety: 1.5 All concrete foundation elements may bear directly on compacted native soils or approved, imported, granular, structural fill per the requirements of Section 4.2 Structural Fill Materials and Compaction. To ensure adequate friction, no fabric shall be placed between the structural fill and native soils when placed under primary building foundations & grade beams. Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 10 3.3 SEISMIC DESIGN PARAMETERS AND LIQUEFACTION According to the Liquefaction Susceptibility layer of the Washington Geologic Information Portal the site is identified as having very low susceptibility. This is generally consistent with the findings of QG’s investigation to date. Liquefaction is a phenomenon typically associated with a subsurface profile of relatively loose, cohesionless soils saturated by groundwater. Under seismic shaking the pore pressure can exceed the soil’s shear resistance and the soil ‘liquefies’, which may result in excessive differential settlements that are damaging to structures and disruptive to exterior improvements. The Washington Interactive Geologic Map - Seismic Site Class Map classifies the project regional vicinity as Site Class C. The USGS Seismic Design Map Tool was used to determine seismic design coefficients and spectral response accelerations assuming Site Soil Class D, representing a stiff or dense soil profile (upper 100 feet) as soil borings did not reach 100 feet in depth. Parameters in Table 2 were calculated using 2014 USGS hazard data and ASCE 7-22 was referenced for site Peak Ground Acceleration. For ASCE 7-16, we have identified the site as Site Class D. Table 2. Seismic Design Parameters Seismic Design Category D D-Default D Default Reference ASCE 7-16 ASCE 7-16 ASCE 7-22 ASCE 7-22 Risk Category II II II II MCER ground motion (period=0.2s) SS 1.288 1.288 1.47 1.47 MCER ground motion (period=1.0s) S1 0.466 0.466 0.43 0.43 Site-modified spectral acceleration value SMS 1.288 1.545 1.61 1.61 Site-modified spectral acceleration value SM1 NULL NULL 0.94 0.94 Numeric seismic design value at 0.2s SA SDS 0.858 1.03 1.07 1.07 Numeric seismic design value at 1.0s SA SD1 NULL NULL 0.63 0.63 Site modified peak ground acceleration PGAM 0.563 0.614 0.62 0.62 Long-period transition period TL 16 16 16 16 Shear wave velocity at 30 meters depth VS30 NULL NULL 260 260 Site amplification factor at 0.2s Fa 1 1.2 NULL NULL Site amplification factor at 1.0s Fv NULL NULL NULL NULL Based on the findings of this study, the site is generally considered to have a very low risk of liquefaction-induced settlement. Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 11 3.4 INFILTRATION RATE DETERMINATION QG understands the design of on-site stormwater controls are pending the results of this study to confirm design parameters and interpreted depths to perched seasonal groundwater and restrictive soil features. 3.4.1 GRADATION ANALYSIS METHODS & RESULTS During test pit excavations for general site investigation, QG collected representative samples of native soil deposits among potential infiltration strata and depths. Representative soil samples were selected from native soils within TP-3 and TP-4 to characterize the local infiltration conditions. We understand the project will be subject to infiltration design based on the Stormwater Management Manual for Western Washington (SWMMWW). For initial site infiltration characterization within the scope of this study, laboratory gradation analyses were completed including sieve and hydrometer tests for stormwater design characterization and rate determination to supplement field observations. Results of laboratory testing in terms of rate calculation are summarized below. Laboratory results were interpreted to recommended design inputs in accordance with methods of the Washing Department of Ecology Stormwater Management Manual for Western Washington (SWMMWW). Gradation results were applied to the Massmann (2003) equation (1) to calculate Ksat representing the initial saturated hydraulic conductivity. (1) log10(Ksat) = -1.57 + 1.90*D10 + 0.015*D60 - 0.013*D90 - 2.08*ff Corrected Ksat values presented below are a product of the initial Ksat and correction factor CFT. For a generalized site-wide design situation, we have applied a site variability factor of CFv = 0.7 along with typical values of CFt = 0.4 (for the Grain Size Method) and CFm = 0.9 (assuming standard influent control). (2) CFT = CFv x CFt x CFm = 0.7 x 0.4 x 0.9 = 0.25 Results were cross-referenced with test pit logs to determine the validity and suitability of unique materials as an infiltration receptor. Additional reduction factors were applied for practical rate determination based on our professional judgement. Table 3. Results Of Massmann Analysis TP # Sample Depth (BPG) Unit Extent (ft) Soil Type D10 D60 D90 Fines (%) Ksat (in/hr) Corrected Ksat (in/hr) LT Design Infiltration Rate(in/hr) Cation Exchange Capacity (meq/100g) Organic Content % 1, 3 2.5 0.0 to 7.25 GM 0.023 19.76 42.02 24.9 7.20 1.81 1.81 8.4 3.3 2, 4 3.0 0.0 to 5.0 GM 0.022 13.31 40.03 24.6 6.18 1.56 1.56 10.2 4.4 Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 12 Lab sample soils from TP-3 and TP-4 were observed across the project site, including at TP-1 and TP-2. The gravelly soils on site were observed to generally exhibit moderate fines content and generally no oxidation. In-ground infiltration structures are required to maintain a minimum of 5-feet separation from restrictive soil & groundwater features. No groundwater was encountered within our explorations down to 7.75 feet below grade. Nearby public well logs report groundwater to be approximately 40 feet beneath the surface. However, the presence of Mill Pond suggests that a perched water table may exist at the surface elevation of the pond. At this time, QG does not recommend seasonal groundwater monitoring or mounding analysis, however the city may deem one or both necessary for this project. QG has preemptively installed a single monitoring portal at TP-3 within the proposed infiltration facility on site. Due to the seasonable water table of the pond, the presence of weathered glacial till in TP-2, and generally dense, silty conditions of the soils on site, the site does not appear to be adequate for deep infiltration techniques and should be avoided if possible. At TP-1 and across the site, QG recommends the designer pursue shallow infiltration structures instead, such as shallow infiltration trenches, bio swales, wet ponds, rain gardens, pervious pavements, etc. For shallow infiltration features utilizing treatment media, we recommend a maximum design rate of up to 1.00 inches/hour be considered, which is typically suitable for most shallow infiltration features. These rates are considered applicable to all areas for the subject site at the specified depths. For in-ground facilities, a minimum of 5 feet of separation is generally required between the base of any gallery or drywell and any confining unit or water table. This separation can be reduced if justified by adequate soil analysis. Soil testing results showed that existing soils are adequately conductive for in-ground infiltration. QG recommends a minimum of 3 feet separation must be maintained between the base of any in-ground facilities and groundwater. In general, the results of QG’s investigation indicate site soil conditions are feasible for conventional on-site infiltration design. The required separation appears generally achievable across the site. Alternatively, a detention or wet pond can be used instead of infiltration. However, if a detention pond is pursued, the elevation of the groundwater in the area must be considered and if a wet pond is pursued, it may not be possible to make it impermeable due to hydrostatic pressure against the pond liner. QG recommends the facility designer review these results and stated assumptions per reference literature to ensure applicability with the proposed development, level of anticipated controls, and QG recommends the facility designer review these results and stated assumptions per reference literature to ensure applicability with the proposed development, level of anticipated controls, and long- term maintenance plan. The designer may make reasonable adjustments to correction factors Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 13 and the resulting design values based on these criteria to ensure design and operational intent is met. We recommend that we be contacted if substantial changes to rate determination are considered. 3.4.2 TREATMENT POTENTIAL Depending on stormwater and runoff sources, some stormwater features, such as rain gardens or pervious pavements may require treatment. Stormwater facilities utilizing native soils as treatment media typically require Cation Exchange Capacities (CEC) of greater than 5 milliequivalents per 100 grams (meq/100g) and organic contents greater than 1% (this may vary depending on local code). Native soils across the site and at all test pit locations meet and exceed the minimum requirements. 3.5 DRAINAGE RECOMMENDATIONS QG recommends proper drainage controls for stormwater runoff during and after site development to protect the site. The ground surface adjacent to structures should be sloped to drain away at a 5% minimum to prevent ponding of water adjacent to them. Foundations shall incorporate a wraparound footing drain composed of imported clean granular drain rock. There shall be a perforated drainpipe connected around the perimeter of the footing drain (within the rock) graded to gravity drain to an outfall pipe, to allow any accumulated water to be released to an approved drainage feature or location. The outfall point must be lower in elevation than the lowest point of possible water accumulation in the mat fill, so as to allow any captured water within the mat or crawlspace to completely drain away from the building footprint preventing standing water from accumulating. QG recommends all stormwater catchments (new or existing) be tightlined (piped) away from structures to an existing catch basin, stormwater system, established channel, or approved outfall to be released using appropriate energy-dissipating features at the outfall to minimize point erosion. Roof and footing drains should be tightlined separately or should be gathered in an appropriately sized catch basin structure and redistributed collectively. If storm drains are incorporated for impervious flatworks (driveways, sidewalks, etc.) collected waters should also be discharged according to the above recommendations. Appropriate measures should be taken by the site designer to consider and allow for an adequate emergency outfall location in the event of a future record stormwater fall that cannot be anticipated. QG does not recommend dispersion of collected stormwater directly downhill from (or adjacent to) the house, as increased runoff or localized stormwater inundation can negatively impact long-term erosional and global slope stability. With county/city approval, an outfall to Mill Pond may be considered for reasonable quantities of stormwater, so long as appropriate energy reducing features are established at the outfall, such as fabric and quarry spalls, or other approved methods, to prevent erosion. Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 14 3.6 IMPERVIOUS PAVEMENT CONSIDERATIONS QG anticipates most pavements will be constructed of flexible Hot Mix Asphalt surfacing, with thickened sections for anticipated heavy load areas. The main entrance/exit drive will likely experience different traffic volumes than the far end of the pavement areas. As a result, consideration could be given to increasing the pavement section in the main entrance/exit drive. Pavement sections presented in the above table should not be used for areas which experience repeated truck traffic/parking, equipment or truck parking areas, entrances and exit aprons, or contain trash dumpster loading zones. In these areas, a Portland Cement Concrete (PCC) pavement should be used, as opposed to HMA. QG recommends incorporating geogrid at subgrade level to reduce the need for thicker sections of base aggregate and prevent accelerated degradation of the pavement section. Revised pavement sections were derived assuming the incorporation of commonly available Tensar Technology TriAx TX160 geogrid, representing a standard level of geotextile application, or an equivalent product. Geogrid materials shall be placed in accordance with the manufacturer’s recommended instructions. The following table summarizes the proposed new minimum pavement sections. Table 5. Summary of Minimum Flexible Pavement Sections *Tensar Technology – TriAx TX160 geogrid placed directly above subgrade per the manufacturer’s specifications, or an approved alternative. Existing soils at the new bottom subgrade level should be graded level with minimal disturbance, in an effort to prevent degradation. Smooth bladed equipment should be used for final grading. For any saturated, organic rich, or deteriorated soils encountered, unsuitable soils shall be removed and replaced with approved compacted imported structural fill. This will provide an even surface for paving application that will also serve as additional support to the flexible pavement sections that can increase design life and reduce repair regularity in the long term. One of the important considerations in designing a high quality and durable pavement is providing adequate drainage. Design of drainage for the proposed pavement section is outside of QG’s scope of work at this time. It is important that bird baths (leeching basins) and surface waves are not created during construction of the HMA layer. A proper slope should also be allowed, and drainage should be provided along the edges of pavements and around catch basins to prevent accumulation of free water within the base course, which otherwise may result in subgrade softening and pavement deterioration under exposure and repeated traffic conditions. Scenario Pavement CSTC Gravel Base Geogrid* Heavy Pavement Section 3 inches 2 inches 6 inches Yes Car Access and Parking 2 inches 2 inches 4 inches Yes Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 15 All pavements require regular maintenance and repair to maintain the serviceability of the pavement. These repairs and maintenance are due to normal wear and tear of the pavement surface and are required to extend the serviceability life of the pavement. However, after 10 years of service, a normal pavement structure is likely to deteriorate to a point where pavement rehabilitation may be required to maintain the serviceability. The deterioration is more likely if the pavement is constructed over poor subgrade soils or in area of higher traffic volumes. These calculated sections should be considered preliminary until verifying the parameters, traffic loading, and assumed grading are applicable to final project design. We recommend pavement sections be reviewed by the civil designer, who may apply an alternative section for final project use based on the conditions reported herein and final design and construction preferences. 3.6.1 RIGID CONCRETE PAVEMENT AND FLATWORKS Rigid pavement components are commonly utilized for portions of accesses and ancillary exterior improvements. The project civil designer may re-evaluate the below general recommendations for pavement thicknesses and base sections, if necessary, to ensure proper application to a given structure and use. QG recommends that we be contacted for further consultation if the below sections are proposed to be reduced. Concrete driveway aprons and curb alignments, if utilized, should consist of a minimum 6-inch thickness of unreinforced concrete pavement over structural base fill. Base thickness should correspond to related location and anticipated traffic loading. For light traffic areas, a 6-inch minimum base thickness (total 12-inch section) can be applied. For heavy traffic zones, we recommend allotting a 12- inch minimum base section beneath the pavement, or the incorporation of reinforcing steel in the concrete. For other paved areas which experience repeated truck traffic, equipment or truck parking areas, entrances and exit aprons, or contain trash dumpster loading zones, a Portland Cement Concrete (PCC) pavement should be used. The PCC layer thickness is recommended to be 8.0 inches with a minimum of 6.0 inches thick crushed stone base course over geogrid but may be modified depending on the final design. The reinforcement details for PCC layers should be designed by the project design engineer as the project conditions dictate. Concrete sidewalks, walkways and patios if present may consist of a minimum 4-inch section of plain concrete (unreinforced) installed over a 6-inch minimum compacted base of crushed rock. At locations where grade has been raised with structural fill, a 4-inch minimum crushed rock section may be used. Flatworks should employ frequent joint controls to limit cracking potential. Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 16 Specifications for concrete aprons and flatworks can be predetermined by the local municipality and may conflict with the above. In this case, we recommend either adhering to the more stringent option, or contacting QG for clarification. 3.6.2 CBR SELECTION QG collected additional field data towards pavement design using Kessler DCP equipment, yielding data correlative with California Bearing Ratio (CBR) values at locations distributed among proposed parking areas and along proposed driveway lane alignments. KDCP logs are attached in Appendix D. KDCP results concur with field observations that soil consistencies of silty gravel and sand. Blow counts within the proposed parking lot (KDCP-1) indicate very dense soil conditions. The recorded CBR values include values as high as over 100.0. A conservative selection of average CBR for the proposed parking lot is around 60.0. In our opinion, this value is representative of the dense silty gravel with sand soil found on site. QG recommends applying a bulk CBR value for pavement design (CBR = 60.0). This is assigned assuming finished pavement grades for roads and parking areas will be similar to or nominally higher than existing grade, and that stripping depths will be to include topsoils and unsuitably soft subgrades. Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 17 4.0 CONSTRUCTION RECOMMENDATIONS 4.1 EARTHWORK 4.1.1 GRADING & EXCAVATION A grading plan was not available to QG at the time of this report. However, based on provided conceptual plans, this study assumes finished site grade will approximate current grade. Therefore, depths referred to in this report are considered roughly equivalent to final depths. Excavations can generally be performed with conventional earthmoving equipment such as bulldozers, scrapers, and excavators. 4.1.2 SUBGRADE EVALUATION & PREPARATION After excavations have been completed to the planned subgrade elevations, but before placing fill or structural elements, the exposed subgrade should be evaluated under the part-time observation and guidance of a QG representative. The special inspection firm should continuously evaluate all backfilling. Any areas that are identified as being soft or yielding during subgrade evaluation should be over excavated to a firm and unyielding condition or to the depth determined by the geotechnical engineer. Where over excavation is performed below a structure, the over excavation area should extend beyond the outside of the footing a distance equal to the depth of the over excavation below the footing. The over-excavated areas should be backfilled with properly compacted structural fill. 4.1.3 SITE PREPARATION, EROSION CONTROLL, WET WEATHER Any silty or organic rich native soils may be moisture-sensitive and become soft and difficult to traverse with construction equipment when wet. During wet weather, the contractor should take measures to protect any exposed soil subgrades, limit construction traffic during earthwork activities, and limit machine use only to areas undergoing active preparation. Once the geotechnical engineer has approved the subgrade, further measures should be implemented to prevent degradation or disturbance of the subgrade. These measures could include, but are not limited to, placing a layer of crushed rock or lean concrete on the exposed subgrade, or covering the exposed subgrade with a plastic tarp and keeping construction traffic off the subgrade. Once the subgrade has been approved, any disturbance because the subgrade was not protected should be repaired by the contractor at no cost to the owner. During wet weather, earthen berms or other methods should be used to prevent runoff from draining into excavations. All runoffs should be collected and disposed of properly. Measures may also be Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 18 required to reduce the moisture content of on-site soils in the event of wet weather. These measures can include, but are not limited to, air drying and soil amendment, etc. QG recommends earthwork activities take place during the summer dry season. 4.2 STRUCTURAL FILL MATERIALS AND COMPACTION 4.2.1 MATERIALS All material placed below structures or pavement areas should be considered structural fill. Excavated native soils may be considered suitable for reuse as structural fill on a case-by-case basis. Imported material can also be used as structural fill. Care should be taken by the earthwork contractor during grading to avoid contaminating stockpiled soils that are planned for reuse as structural fill with native organic materials. Frozen soil is not suitable for use as structural fill. Fill material may not be placed on frozen soil. Structural fill material shall be free of deleterious materials, have a maximum particle size of 4 inches, and be compactable to the required compaction level. Imported structural fill material should conform to the WSDOT manual Section 9-03.14(1) Gravel Borrow, or an approved alternative import material. Controlled-density fill (CDF) or lean mix concrete can be used as an alternative to structural fill materials, except in areas where free-draining materials are required or specified. Imported materials utilized for trench back fill shall conform to Section 9-03.19, Trench Backfill, of the most recent edition (at the time of construction) of the State of Washington Department of Transportation Standard Specifications for Road, Bridge, and Municipal Construction (WSDOT Standard Specifications). Imported materials utilize as grade fill beneath roads shall conform to WSDOT Section 9-03.10, Gravel Base. Pipe bedding material should conform to the manufacturer’s recommendations and be worked around the pipe to provide uniform support. Cobbles exposed in the bottom of utility excavations should be covered with pipe bedding or removed to avoid inducing concentrated stresses on the pipe. Soils with fines content near or greater than 10% fines content may likely be moisture sensitive and become difficult to use during wet weather. Care should be taken by the earthwork contractor during grading to avoid contaminating stockpiled soils that are planned for reuse as structural fill with native organic materials. The contractor should submit samples of each of the required earthwork materials to the materials testing lab for evaluation and approval prior to delivery to the site. The samples should be submitted at least 5 days prior to their delivery and sufficiently in advance of the work to allow the contractor to identify alternative sources if the material proves unsatisfactory. Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 19 4.2.2 FILL PLACEMENT AND COMPACTION For lateral and bearing support, structural fill placement below footings shall extend at minimum a distance past each edge of the base of the footing equal to the depth of structural fill placed below the footing [i.e. extending at least a 1H:1V past both the interior and the exterior of the concrete footing]. Prior to placement and compaction, structural fill should be moisture conditioned to within 3 percent of its optimum moisture content. Loose lifts of structural fill shall not exceed 12 inches in thickness. All structural fill shall be compacted to a firm and unyielding condition and to a minimum percent compaction based on its modified Proctor maximum dry density as determined per ASTM D1557. Structural fill placed beneath each of the following shall be compacted to the indicated percent compaction: • Foundation and Floor Slab Subgrades: 95 Percent • Pavement Subgrades & wall backfill (upper 2 feet): 95 Percent • Pavement Subgrades & wall backfill (below 2 feet): 90 Percent • Utility Trenches (upper 4 feet): 95 Percent • Utility Trenches (below 4 feet): 90 Percent A sufficient number of tests should be performed to verify the compaction of each lift. The number of tests required will vary depending on the fill material, its moisture condition and the equipment being used. Initially, more frequent tests will be required while the contractor establishes the means and methods required to achieve proper compaction. Jetting or flooding is not a substitute for mechanical compaction and should not be allowed. 4.3 TEMPORARY EXCAVATIONS AND TRENCHES All excavations and trenches must comply with applicable local, state, and federal safety regulations. Construction site safety is the sole responsibility of the Contractor, who shall also be solely responsible for the means, methods, and sequencing of construction operations. We are providing soil type information solely as a service to our client for planning purposes. Under no circumstances should the information be interpreted to mean that QG is assuming responsibility for construction site safety or the Contractor’s activities; such responsibility is not being implied and should not be inferred. The contractor shall be responsible for the safety of personnel working in utility trenches. Given that steep excavations in native soils may be prone to caving, we recommend all utility trenches, but particularly those greater than 4 feet in depth, be supported in accordance with state and federal safety regulations. Heavy construction equipment, building materials, excavated soil, and vehicular traffic should not be allowed near the top of any excavation. Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 20 Temporary excavations and trenches should be protected from the elements by covering them with plastic sheeting or some other similar impermeable material. Sheeting sections should overlap by at least 12 inches and be tightly secured with sandbags, tires, staking, or other means to prevent wind from exposing the soils under the sheeting. Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 21 5.0 SPECIAL INSPECTION The recommendations made in this report assume that an adequate program of tests and observations will be made throughout construction to verify compliance with these recommendations. Testing and observations performed during construction should include, but not necessarily be limited to, the following: • Geotechnical plan review and engineering consultation as needed prior to construction phase, • Observations and testing during site preparation, earthwork, structural fill, and pavement section placement, • Consultation on temporary excavation cutslopes and shoring if needed, • Consultation as necessary during construction. QG recommends that we be retained for construction phase soils testing and periodic earthwork observation in accordance with the local code requirements. We also strongly recommend that QG be retained as the project Geotechnical Engineering Firm of Record (GER) during the construction of this project to perform periodic supplementary geotechnical observations and review the special inspectors reports during construction. Our knowledge of the project site and the design recommendations contained herein will be of great benefit in the event that difficulties arise and either modifications or additional geotechnical engineering recommendations are required or desired. We can also, in a timely fashion observe the actual soil conditions encountered during construction, evaluate the applicability of the recommendations presented in this report to the soil conditions encountered, and recommend appropriate changes in design or construction procedures if conditions differ from those described herein. We would be pleased to meet with you at your convenience to discuss the Time & Materials scope and cost for these services. Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 22 6.0 LIMITATIONS Upon acceptance and use of this report, and its interpretations and recommendations, the user shall agree to indemnify and hold harmless QG, including its owners, employees and subcontractors, from any adverse effects resulting from development and occupation of the subject site. Ultimately, it is the owner’s choice to develop and live in such an area of possible geohazards (which exist in perpetuity across the earth in one form or another), and therefore the future consequences, both anticipated and unknown, are solely the responsibility of the owner. By using this report for development of the subject property, the owner must accept and understand that it is not possible to fully anticipate all inherent risks of development. The recommendations provided above are intended to reduce (but may not eliminate) such risks. This report does not represent a construction specification or engineered plan and shall not be used or referenced as such. The information included in this report should be considered supplemental to the requirements contained in the project plans & specifications and should be read in conjunction with the above referenced information. The selected recommendations presented in this report are intended to inform only the specific corresponding subjects. All other requirements of the above- mentioned items remain valid, unless otherwise specified. Recommendations contained in this report are based on our understanding of the proposed development and construction activities, field observations and explorations, and laboratory test results. It is possible that soil and groundwater conditions could vary and differ between or beyond the points explored. If soil or groundwater conditions are encountered during construction that differ from those described herein, or If the scope of the proposed construction changes from that described in this report, QG should be notified immediately in order to review and provide supplemental recommendations. The findings of this study are limited by the level of scope applied. We have prepared this report in substantial accordance with the generally accepted geotechnical engineering practice as it exists in the subject region. No warranty, expressed or implied, is made. The recommendations provided in this report assume that an adequate program of tests and observations will be conducted by a WABO approved special inspection firm during the construction phase in order to evaluate compliance with our recommendations. This report may be used only by the Client and their design consultants and only for the purposes stated within a reasonable time from its issuance, but in no event later than 18 months from the date of the report. It is the Client's responsibility to ensure that the Designer, Contractor, Subcontractors, etc. are made aware of this report in its entirety. Note that if another firm assumes Geotechnical Engineer of Record responsibilities, they need to review this report and either concur with the findings, conclusions, and recommendations or provide alternate findings, conclusions and recommendation. Land or facility use, on- and off-site conditions, regulations, or other factors may change over time, and additional work may be required. Based on the intended use of the report, QG may recommend that additional work be performed and that an updated report be issued. Non-compliance with any of these requirements by the Client or anyone else will release QG from any liability resulting from the use of this report. The Client, the design consultants, and any unauthorized party, agree to defend, indemnify, and hold harmless QG from any claim or liability associated with such unauthorized use or non-compliance. We recommend that QG be given the opportunity to review the final project plans and specifications to evaluate if our recommendations have been properly interpreted. We assume no responsibility for misinterpretation of our recommendations. Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 23 Region & Vicinity Maps REGION VICINITY Quality Geo NW, PLLC Site Region Yelm Veterans Memorial Park Geo Figure 1 Source: Google Imagery, 2025 Scale & Locations are approx. Not for Construction Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 24 Exploration Map 125 0 SCALE (FEET) Quality Geo NW, PLLC Site Map Yelm Veterans Memorial Park Geo Figure 2 Source: Thurston Co. GIS, 2025 Scale & Locations are approx. Not for Construction Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 25 Exploration Logs Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 26 Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 27 Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 28 Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 29 Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 30 Laboratory Results Yelm Veterans Memorial Park Geo - Soils Report Quality Geo NW, PLLC 10/3/2025 (revised 11/12 /2025) Project # QG25-134 31