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Home My WebLink AboutGeotech Repot_05042021MONTANA | WASHINGTON | IDAHO | NORTH DAKOTA | PENNSYLVANIA JOB NO. 21-006-001 FEBRUARY 2021 REPORT OF GEOTECHNICAL INVESTIGATION CLIENT ENGINEER L’Heureux, Page, Werner Mr. Timothy Peterson, AIA 15 Fifth St S Great Falls, MT 59401 Email: timothyp@lpwarchitecture.com Ahren Hastings, PE ahren.hastings@tdhengineering.com REPORT OF GEOTECHNICAL INVESTIGATION PROJECT NAME PROJECT LOCATION 406.586.0277 tdhengineering.com 234 East Babcock, Suite 3 Bozeman, MT 59715 TRADITIONS TOWNHOMES BOZEMAN, MONTANA Geotechnical Report Traditions Townhomes Table of Contents Bozeman, Montana i Table of Contents 1.0 EXECUTIVE SUMMARY .................................................................................................... 1 2.0 INTRODUCTION .................................................................................................................. 3 2.1 Purpose and Scope....................................................................................................... 3 2.2 Project Description ........................................................................................................ 3 3.0 SITE CONDITIONS.............................................................................................................. 3 3.1 Geology and Physiography .......................................................................................... 3 3.2 Subsurface Conditions ................................................................................................. 3 3.2.1 Soils .......................................................................................................................... 3 3.2.2 Ground Water ......................................................................................................... 4 4.0 ENGINEERING ANALYSIS ................................................................................................. 5 4.1 Introduction ..................................................................................................................... 5 4.2 Site Grading and Excavations ..................................................................................... 5 4.3 Conventional Shallow Foundations on Structural Fill .............................................. 5 4.4 Building Slab-on-Grade and Exterior Flatwork ......................................................... 6 5.0 RECOMMENDATIONS ....................................................................................................... 7 5.1 Site Grading and Excavations ..................................................................................... 7 5.2 Conventional Shallow Foundations ............................................................................ 8 5.3 Foundation and Retaining Walls ................................................................................. 9 5.4 Exterior Concrete Flatwork ........................................................................................ 11 5.5 Interior Concrete Floor Slabs ...................................... 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Bookmark not defined. 5.7 Continuing Services .................................................................................................... 11 6.0 SUMMARY OF FIELD AND LABORATORY STUDIES ............................................... 13 6.1 Preliminary Field Explorations ................................................................................... 13 6.2 Laboratory Testing ...................................................................................................... 13 7.0 LIMITATIONS ..................................................................................................................... 14 Geotechnical Report Traditions Townhomes Appendix Bozeman, Montana ii APPENDIX  Test Pit Location Map (Figure 1)  Logs of Exploratory Test Pits (Figures 2 through 5)  Laboratory Test Data (Figures 6 through 8)  Soil Classification and Sampling Terminology for Engineering Purposes  Classification of Soils for Engineering Purposes Geotechnical Report Traditions Townhomes Executive Summary Bozeman, Montana Page 1 GEOTECHNICAL REPORT TRADITIONS TOWNHOMES BOZEMAN, MONTANA 1.0 EXECUTIVE SUMMARY A geotechnical investigation was performed for the proposed new Traditions Townhomes, located at the intersection of Durston Road and Rosa Way in Bozeman, Montana, on January 15, 2021. Subsurface soil conditions consist of lean clay overlying native poorly-graded gravel with sand and clay. In all test pits a surficial layer of topsoil classifying as lean clay with elevated organics was encountered. The topsoil and majority of the lean clay was frozen at the time of our investigation. Ground water was observed in all test pits at depths ranging from 5.0 to 6.5 feet below existing site grade. This area is known for high ground water which could rise or fluctuate seasonally; thus, ground water should be expected in excavations for the building and associated utilities at certain times of the year. Based on the findings of our preliminary field investigation and experience in this area, the seismic site class for this site is D. The risk of seismically induced liquefaction is considered low and does not warrant additional consideration. The primary geotechnical concern regarding this project is the presence of weak surficial lean clay and relatively high ground water. Based on the site conditions encountered, it is our opinion that the clay soils are not suitable for the support of the planned structure due to the weak nature and presence of organics. Objectionable settlement is expected for foundations and slabs supported on the weak clay material. The recommended bearing stratum for this project is the native gravel which was encountered in all four test pits at a depths between 2.1 to 3.5 feet. Our recommendation is to completely remove the topsoil and clay to the underlying native gravel and replace this zone with compacted structural fill up to the desired building foundation. This approach may require over- excavation beneath conventional foundation and slab systems. The amount of over-excavation will vary depend on site grading and the finished floor elevation. Geotechnical Report Traditions Townhomes Introduction Bozeman, Montana Page 3 2.0 INTRODUCTION 2.1 Purpose and Scope This report presents the results of our geotechnical investigation for the proposed new Traditions Townhomes, located at the intersection of Durston Road and Rosa Way in Bozeman, Montana. The purpose of this preliminary study was to determine the general surface and subsurface conditions across the existing site for use by the owner and design team in site planning and design for the buildings. This report describes the field work and laboratory analyses conducted for the site investigation, the surface and subsurface conditions encountered, and presents our engineering assessment and design recommendations. The site investigation was performed on January 15, 2021 and consisted of four test pits excavated across the proposed project area. Excavation depths ranged from 7.4 to 8.2 feet below existing site grades. Samples from the investigation were returned to our Great Falls laboratory for testing. Laboratory testing was performed on selected soil samples to obtain engineering properties of the subsurface materials. 2.2 Project Description We understand the proposed project includes construction of a two-story, five-plex townhome apartment building and associated site improvements on Lots 4A, 4B, 4C, 4D and 4E, Block 1, Traditions Subdivision-Phase 1, Bozeman, Montana. Based on the “Preliminary Not For Construction” Building Drawings dated November 3, 2020, we understand that both a conventional shallow spread footing foundation with a crawlspace and thickened-edge slab-on-grade system are being considered for this project. Due to known high ground water in the area and know n issues with water accumulations in crawlspaces, we highly recommend that slab-on-grade construction be utilized in this area. Structural loads had not been provided for the structure at the time of this report. Our preliminary analysis assumes the building will be loaded typical of residential construction. Our understanding is that asphalt pavement will not be a part of this project and has been excluded from our analysis. Geotechnical Report Traditions Townhomes Site Conditions Bozeman, Montana Page 3 3.0 SITE CONDITIONS 3.1 Geology and Physiography The site is geologically characterized as gravel (Qgr) and upper Tertiary Sediments (Tsu). The gravel areas shown on the geologic map below are generally comprised of variable deposits ranging from pebble to boulder size including sand, silt, and clay. They are dominantly associated with alluvial terrace, abandoned channel and floodplain, remnant alluvial fan, and local glacial outwash. The sections denoted Tsu are Upper Tertiary Sediments or sedimentary rock comprised of conglomerate, tuffaceous sandstone and siltstone, marlstone, and equivalent sediment and ash beds. Geologic Map of Montana, Edition 1.0 (2007) Montana Bureau of Mines & Geology Based on the subsurface conditions encountered and our experience in the area, the site falls under seismic Site Class D. The structural engineer should utilize the site classification above to determine the appropriate seismic design data for use on this project in accordance with current applicable building codes in use by the City of Bozeman at the time of design. The likelihood of seismically-induced soil liquefaction is low and does not warrant additional evaluation. 3.2 Subsurface Conditions 3.2.1 Soils The subsurface soil conditions appear to be relatively consistent based on our exploratory excavations and soil sampling. In general, the subsurface soil conditions encountered within the test pits consist of approximately 0.4 to 0.6 feet of surficial topsoil, visually classified as lean clay which contains organic material. This is underlain by native lean clay ranging in Geotechnical Report Traditions Townhomes Site Conditions Bozeman, Montana Page 4 thickness of 1.6 to 3.1 feet. Native poorly-graded gravel with sand was encountered in all test pits at depths of 5.0 to 6.5 feet below existing ground, and similar gravels extend to depths of at least 8.2 feet, the maximum depth investigated. The subsurface soils are described in detail on the enclosed test pit logs and are summarized below. The stratification lines shown on the logs represent approximate boundaries between soil types, and the actual in situ transition may be gradual vertically or discontinuous laterally. TOPSOIL The topsoil was visually classified as lean clay and was observed to be frozen and considered relatively stiff based on difficulty with excavating the material. Generally organics were observed in varying amounts at our test pit locations. LEAN CLAY Lean Clay was encountered in all test pits between the surficial topsoil and the underlying native gravel. The clay is considered stiff and was predominantly frozen during excavation. A sample of the material contained 3 percent gravel, 7.8 percent sand, and 89.2 percent fines (clay and silt). The lean clay was found to have a liquid limit of 43, a plastic limit of 23 percent, and a plasticity index of 20 percent based on Atterberg Limits result. The natural moisture contents varied from 14.4 to 19.8 percent and averaged 18.0 percent. POORLY-GRADED GRAVEL WITH SAND AND CLAY Native poorly-graded gravel with sand and clay was encountered in all test pits beneath the surficial clay and extends to depths of at least 8.2 feet. The native gravels are considered relatively dense based on the effort required during excavation. A sample of the material contained 59.3 percent gravel, 22.3 percent sand, and 5.8 percent fines (silt and clay). The natural moisture contents varied from 2.6 to 5.8 percent and averaged 4.2 percent. 3.2.2 Ground Water Ground water was encountered in all four test pits at depths ranging from 5.0 to 6.5 feet below existing ground surface. Numerous factors contribute to seasonal ground water occurrences and fluctuations, and the evaluation of such factors is beyond the scope of this report. This area is known for high ground water and should be expected in excavations for the building and associated utilities at certain times of the year. A monitoring well was installed in TP-1 for future ground water monitoring. Geotechnical Report Traditions Townhomes Engineering Analysis Bozeman, Montana Page 5 4.0 ENGINEERING ANALYSIS 4.1 Introduction The primary geotechnical concern regarding this project is the presence of weak surficial lean clay and high ground water. The native clays were frozen and generally considered stiff based on the difficulty of excavation. However, during spring conditions similar clays are generally very soft and highly compressible leading to concerns with settlement. Due to the shallow ground water and the potential for seasonal fluctuations the use of a crawlspace is not advised for this project. This option carries an elevated risk of water accumulation within the below grade space which can lead to mold and other health risks. Conventional foundation drain systems utilizing mechanical pumping systems, such as would be required due to the flat terrain, are not intended for permanent ground water control and will not resolve the ground water issues. 4.2 Site Grading and Excavations The ground surface at the proposed site is consistent and can be described as relatively flat. The majority of the site appears to be lower than the surrounding curb level indicating that fill may be necessary to build up the site during construction. Based on our field work, variable clay thicknesses overlying native poorly-graded gravel with sandy and clay will be encountered in excavations across the site. Depending on the time of year, ground water should be anticipated in all utility and foundation excavations. 4.3 Conventional Shallow Foundations on Structural Fill The existing clay soils encountered across the site are not suitable to support foundation loads due to their relatively weak strength and the resulting risk of settlement. It is recommended that the native clays be completely removed down to the underlying native gravel and replaced with compacted structural fill to the desired foundation elevation beneath all conventional footing and stem wall or thickened-edge foundation systems. This depth of over-excavation and resulting structural fill thickness will depend on the finished floor elevation and foundation system selected for the proposed building. Transferring foundation loads directly to the native gravel through compacted structural fill will minimize total and differential settlement risk. Based on this construction methodology, our experience, and using an allowable bearing pressure of 3,000 pounds per square foot, we estimate the total settlement for footings will be less than ¾-inch. Differential settlement across the building should be on the order of one-half this magnitude. 4.4 Foundation Walls Foundation walls associated with a crawlspace configuration, if used, will be subjected to horizontal loading due to lateral earth pressures. The lateral earth pressures are a function of the natural and backfill soil types and acceptable wall movements, which affect soil strain to mobilize the shear Geotechnical Report Traditions Townhomes Engineering Analysis Bozeman, Montana Page 6 strength of the soil. More soil movement is required to develop greater internal shear strength and lower the lateral pressure on the wall. To fully mobilize strength and reduce lateral pressures, soil strain and allowable wall rotation must be greater for clay soils than for cohesionless, granular soils. The lowest lateral earth pressure against walls for a given soil type is the active condition and develops when wall movements occur. Passive earth pressures are developed when the wall is forced into the soil, such as at the base of a wall on the side opposite the retained earth side. When no soil strain is allowed by the wall, this is the "at-rest" condition, which creates pressures having magnitudes between the passive and active conditions. The distribution of the lateral earth pressures on the structure depends on soil type and wall movements or deflections. In most cases, a triangular pressure distribution is satisfactory for design and is usually represented as an equivalent fluid unit weight. Design parameters are given in the recommendations section of this report. 4.5 Building Slab-on-Grade In our opinion, the use of slab-on-grade construction is best suited to this site and the shallow ground water conditions; however, the clay soils present on site are not suitable to support these systems directly. Therefore, it will be necessary to improve the underslab conditions by removing the surficial clay soils down to native gravel and replacing this zone with compacted structural fill up to the planned bottom of slab elevation. This can result in a significant amount of soil removal and imported gravel depending on the final site grading and finished floor elevation; however, this method of construction will help control the potential for slab displacements, optimize slab performance, and control issues related to the shallow ground water condition in the area. 4.6 Exterior Concrete Flatwork Exterior flatwork is generally more tolerable to vertical movement and can be repaired or replaced more economically than interior slab systems. Thus, it is common for exterior flatwork applications to utilize conventional construction consisting of a limited base course layer (four to six inches) beneath the concrete surfacing. Similar construction is anticipated for this project assuming the Owner understands and is willing to accept the risks and resulting need for future maintenance. Exterior flatwork on this site will be exposed to greater risk as a result of the lean clay which is compressible and highly frost susceptible. Should the Owner desire a higher level of performance, improvements beneath exterior flatwork systems can be considered. The cost of improving the subgrade below exterior flatwork can be substantial and generally consist of thicker base course sections and possible geogrid improvements to help reduce the overall risk to within the desired level. Optimal performance is realized when the clay soils are completely removed and replaced with compacted structural fill as is recommended beneath interior slab systems. Geotechnical Report Traditions Townhomes Recommendations Bozeman, Montana Page 7 5.0 RECOMMENDATIONS 5.1 Site Grading and Excavations 1. All topsoil and organic material should be removed from the proposed building and any areas to receive site grading fill. Additionally, the existing native lean clay should be completely removed from beneath all planned building foundations and interior slab-on-grade systems. 2. All fill and backfill should be non-expansive, free of organics and debris and should be approved by the project geotechnical engineer. The on-site soils, exclusive of topsoil, are suitable for use as exterior backfill and general site grading fill on this project. All fill should be placed in uniform lifts not exceeding 8 inches in thickness for fine- grained soils and not exceeding 12 inches for granular soils. All materials compacted using hand compaction methods or small walk-behind units should utilize a maximum lift thickness of 6 inches to ensure adequate compaction throughout the lift. All fill and backfill shall be moisture conditioned to near the optimum moisture content and compacted to the following percentages of the maximum dry density determined by a standard proctor test which is outlined by ASTM D698 or equivalent (e.g. ASTM D4253-D4254). On-site moisture conditioning should be anticipated for any fine-grained clay or silt soils to be utilized as fill or backfill as these materials are likely to exhibit excessively high moisture contents to be properly compacted. a) Below Foundations or Spread Footings ...................................... 98% b) Below Interior Slab-on-Grade Construction ................................. 98% c) Exterior Backfill, Crawlspace Infill, & Exterior Flatwork ............... 95% d) General Landscaping or Nonstructural Areas ............................. 92% e) Site Utility Trench Backfill, To Within 2 Feet of Surface ............. 95% For your consideration, verification of compaction requires laboratory proctor tests to be performed on a representative sample of the soil prior to construction. These tests can require up to one week to complete (depending on laboratory backlog) and this should be considered when coordinating the construction schedule to ensure that delays in construction or additional testing expense is not required due to laboratory processing times or rush processing fees. 3. Imported structural fill, when required, should be non-expansive, free of organics and debris, and conform to the material requirements outlined in Section 02234 of the Montana Public Works Standard Specifications (MPWSS). All gradations outlined in this standard are acceptable for use on this project; however, conventional proctor methods (outlined in ASTM D698) shall not be used for any materials containing less Geotechnical Report Traditions Townhomes Recommendations Bozeman, Montana Page 8 than 70 percent passing the ¾-inch sieve. Conventional proctor methods are not suitable for these types of materials, and the field compaction value must be determined using a relative density test outlined in ASTM D4253-4254. 4. Develop and maintain site grades which will rapidly drain surface and roof runoff away from foundation and subgrade soils; both during and after construction. The final site grading shall conform to the grading plan, prepared by others to satisfy the minimum requirements of the applicable building codes. 5. It is the responsibility of the Contractor to provide safe working conditions in connection with underground excavations. Temporary construction excavations greater than four feet in depth, which workers will enter, will be governed by OSHA guidelines given in 29 CFR, Part 1926. The soil conditions on site can change due to changes in soils moisture or disturbances to the site prior to construction. Thus, the contractor is responsible to provide an OSHA knowledgeable individual during all excavation activities to regularly assess the soil conditions and ensure that all necessary safety precautions are implemented and followed. 5.2 Conventional Shallow Foundations The design and construction criteria below should be observed for conventional shallow foundation systems including thickened-edge slab options. The construction details should be considered when preparing the project documents. 6. Both interior and exterior footings should bear on properly compacted native poorly- graded gravel with sand and clay or structural fill extending to native gravels and should be designed for a maximum allowable soil bearing pressure of 3,000 psf provided settlements as outlined in the Engineering Analysis are acceptable. The limits of over-excavation and replacement, when needed, should extend at least 18 inches beyond the outer faces of the footing in all directions. 7. Soils disturbed below the planned depths of footing excavations should either be re- compacted or be replaced with suitable compacted backfill approved by the geotechnical engineer. 8. Footings shall be sized to satisfy the minimum requirements of the applicable building codes while not exceeding the maximum allowable bearing pressure provided in Item 6 above. 9. Exterior footings and footings beneath unheated areas should be placed at least 48 inches below finished exterior grade for frost protection. For shallow thickened-edge slabs, use of rigid board, extruded polystyrene insulation (XEPS) is recommended to provide adequate frost protection. One inch of XEPS is approximately equivalent to 1 foot of soil cover. Geotechnical Report Traditions Townhomes Recommendations Bozeman, Montana Page 9 10. The bottom of the footing excavations should be free of cobbles and boulders to avoid stress concentrations acting on the base of the footings. If the native gravels cannot be rolled smooth, the use of a thin cushion course between the native gravels and the footings should be considered. Cushion course gravels should conform to the material requirements of MPWSS Section 02235 and be compacted to requirements of Item 2a above. 11. Lateral loads are resisted by sliding friction between the footing base and the supporting soil and by lateral pressure against the footings opposing movement. For design purposes, a friction coefficient of 0.45 and a lateral resistance pressure of 200 psf per foot of depth are appropriate for footing bearing on properly compacted native gravel or structural fill and backfilled with compacted native soils. 12. A representative of the project geotechnical engineer should be retained to observe all footing excavations prior to the placement of concrete formwork in order to document that native gravels have been encountered beneath all foundation elements and to conduct compaction testing to verify compliance with Item 2a during subgrade preparation. 5.3 Foundation Walls The design and construction criteria presented below should be observed for foundation walls if a crawlspace configuration is selected for this project. The construction details should be considered when preparing the project documents. 13. Foundation stem walls which are laterally supported and can be expected to undergo only a slight amount of deflection should be designed for a lateral earth pressure computed on the basis of an equivalent fluid unit weight of 60 pcf for exterior backfill consisting of properly compacted native soils. 14. When a crawlspace configuration is utilized, fill should be placed and compacted (Item 2c) on the interior of the crawlspace to an elevation equal to the top of the exterior footings. This fill is intended to provide lateral support to the wall during exterior backfill and help control the potential for water accumulation in the crawlspace associated with exterior sources. 15. Backfill should be selected, placed, and compacted per Item 2c above. Care should be taken not to over-compact the backfill since this could cause excessive lateral pressure on the walls. Only hand-operated compaction equipment should be used within 5 feet of foundation walls. 16. Exterior footing drains are required to remove ground water seepage and infiltrated surface runoff away from foundation soils when a crawlspace configuration is Geotechnical Report Traditions Townhomes Recommendations Bozeman, Montana Page 10 utilized. This will be a critical component to help control the potential for water accumulation within the crawlspace but the inclusion of a foundation drain alone will not prevent water accumulations from occurring. We highly advise against the use of a crawlspace for this project due to the inherent ground water issues and associated risks which can pose health concerns to future tenants should mold or other moisture related issues develop. If a crawlspace is used, the preferred system would be directly connected to the storm water system to eliminate the need for mechanical pumps, which can fail and operate with restrictions increasing the potential for water accumulations on site such as this where the system may be operating to lower the ground water table on site. 5.4 Building Slab-on-Grade 17. As discussed in the engineering analysis section above, the native clay soils are not considered suitable to support interior building slabs and should be completely removed down to the surface of the native gravels and replaced with properly compacted structural fill back to the design slab elevation. A thin cushion course of finer graded gravel is permissible directly beneath the slab-on-grade construction as needed for plumbing installation or as a leveling material. 18. Structural fill materials should conform to the gradation shown in Item 3 above. Cushion course materials utilized beneath interior and exterior slab-on-grade applications should conform to the requirements outlined in Section 02235 of the Montana Public Works Standard Specifications (MPWSS). All gradation outlined in this specification are acceptable for this application. Prior to placing the cushion course, the upper six inches of subgrade (exterior) or underlying structural fill should be compacted per Item 2 above. As an alternative, a clean crushed chips material has been utilized on previous projects in lieu of conventional base course materials. This product is acceptable for use on this project but should be compacted using at least three passes of a smooth bottom vibratory plate following installation and we advise thicknesses not exceed six inches. 19. Concrete floor slabs should be designed using a modulus of vertical subgrade reaction no greater than 300 pci when designed and constructed as recommended in Item 17 above. 20. Geotechnically, an underslab vapor barrier is recommended for this project due to the shallow ground water table and the potential for moisture transmission through the building slab. We recommend a minimum 10-mil vapor barrier which is taped and sealed at all joints be utilized unless otherwise specified by the architect or structural engineer. Geotechnical Report Traditions Townhomes Recommendations Bozeman, Montana Page 11 5.5 Exterior Concrete Flatwork 21. For normally loaded, exterior concrete flatwork, the native lean clay soils may pose some risk to the performance of these features due to the potential compressive properties. Conventional construction consisting of approximately four to six inches of free-draining, crushed gravel placed beneath the concrete and compacted to the requirements of Item 2c above is considered suitable provided the Owner is aware of and willing to accept the risks associated with this construction method. The magnitude of displacement will vary depending the depth of the clay soils or fill in that location as well as drainage conditions, irrigation locations, slab loading conditions, and other factors. Slab movements could result in the need for more frequent repair or replacement of the exterior concrete if they become too great. 22. If the Owner desires to reduce the risk of movements beneath exterior slab systems and improve anticipated performance a variety of measures are possible and these can be discussed with the design team. Mitigative efforts can range from the use of a greater base course thickness to the complete removal and replacement of the problematic soil. The various options need to be considered by the Owner based on the expected performance and related construction cost so they can select the most appropriate system for their project. 5.6 Continuing Services Three additional elements of geotechnical engineering service are important to the successful completion of this project. 23. Consultation between the geotechnical engineer and the design professionals during the design phases is highly recommended. This is important to ensure that the intentions of our recommendations are incorporated into the design, and that any changes in the design concept consider the geotechnical limitations dictated by the on-site subsurface soil and ground water conditions. 24. Observation, monitoring, and testing during construction is required to document the successful completion of all earthwork and foundation phases. A geotechnical engineer from our firm should be retained to observe the excavation, earthwork, and foundation phases of the work to determine that subsurface conditions are compatible with those used in the analysis and design. If construction services are performed by someone other than our firm, the entities performing these services must be directed to contact us immediately upon changes in subsurface conditions so we may re-evaluate our recommendations in a timely manner. 25. During site grading, placement of all fill and backfill should be observed and tested to confirm that the specified density has been achieved. We recommend that the Geotechnical Report Traditions Townhomes Recommendations Bozeman, Montana Page 12 Owner maintain control of the construction quality control by retaining the services of an experienced construction materials testing laboratory. We are available to provide construction inspection services as well as materials testing of compacted soils and the placement of Portland cement concrete and asphalt. In the absence of project specific testing frequencies, TD&H recommends the following minimum testing frequencies be used: Compaction Testing Beneath Column Footings 1 Test per Footing per Lift Beneath Wall Footings 1 Test per 50 LF of Wall per Lift Beneath Slabs 1 Test per 1,500 SF per Lift Foundation Backfill 1 Test per 100 LF of Wall per Lift LF = Lineal Feet SF = Square Feet Geotechnical Report Traditions Townhomes Summary of Field and Laboratory Studies Bozeman, Montana Page 13 6.0 SUMMARY OF FIELD AND LABORATORY STUDIES 6.1 Field Explorations The geotechnical investigation was performed on January 15, 2021 and consisted of four test pits excavated to depths ranging from 7.4 to 8.2 feet across the property. The approximate location of each test pit is shown on Figure 1. The test pits were excavated by Earth Surgeons using a Komatsu 88 excavator. The subsurface exploration and sampling methods used are indicated on the attached test pit logs. The test pits were logged by Mr. Ahren Hastings, PE of TD&H Engineering. During excavation, composite samples of the subsurface materials were collected from the excavation spoils at distinct changes in the subsurface stratigraphy. Logs of all test pits, which include soil descriptions and sample depths, are presented on Figures 2 through 5. During excavation of TP-1, a perforated pipe was installed vertically and backfilled with excavation spoils to be utilized in any future ground water monitoring. 6.2 Laboratory Testing Samples obtained during the field exploration were returned to our materials laboratory where they were observed and visually classified in general accordance with ASTM D2487, which is based on the Unified Soil Classification System. Representative samples were selected for testing to determine the engineering and physical properties of the soils in general accordance with ASTM or other approved procedures. Tests Conducted: To determine: Natural Moisture Content Representative moisture content of soil at the time of sampling. Grain-Size Distribution Particle size distribution of soil constituents describing the percentages of clay/silt, sand and gravel. Atterberg Limits A method of describing the effect of varying water content on the consistency and behavior of fine-grained soils. The laboratory testing program for this project consisted of eight moisture-visual analyses, two sieve (grain-size distribution) analyses, and one Atterberg Limits analysis. The results of the water content analyses are presented on the test pit logs, Figures 2 through 5. The grain-size distribution curve and Atterberg Limits results are presented on Figures 6 through 8. Geotechnical Report Traditions Townhomes Limitations Bozeman, Montana Page 14 7.0 LIMITATIONS This report has been prepared in accordance with generally accepted geotechnical engineering practices in this area for use by the client for design purposes. The findings, analyses, and recommendations contained in this report reflect our professional opinion regarding potential impacts the subsurface conditions may have on the proposed project and are based on site conditions encountered. Our analysis assumes that the results of the exploratory test pits are representative of the subsurface conditions throughout the site, that is, that the subsurface conditions everywhere are not significantly different from those disclosed by the subsurface study. Unanticipated soil conditions are commonly encountered and cannot be fully determined by a limited number of test pits and laboratory analyses. Such unexpected conditions frequently require that some additional expenditures be made to obtain a properly constructed project. Therefore, some contingency fund is recommended to accommodate such potential extra costs. The recommendations contained within this report are based on the subsurface conditions observed in the test pits and are subject to change pending observation of the actual subsurface conditions encountered during construction. TD&H cannot assume responsibility or liability for the recommendations provided if we are not provided the opportunity to perform limited construction inspection and confirm the engineering assumptions made during our analysis. A representative of TD&H should be retained to observe all construction activities associated with subgrade preparation, foundations, and other geotechnical aspects of the project to ensure the conditions encountered are consistent with our assumptions. Unforeseen conditions or undisclosed changes to the project parameters or site conditions may warrant modification to the project recommendations. Long delays between the geotechnical investigation and the start of construction increase the potential for changes to the site and subsurface conditions which could impact the applicability of the recommendations provided. If site conditions have changed because of natural causes or construction operations at or adjacent to the site, TD&H should be retained to review the contents of this report to determine the applicability of the conclusions and recommendations provide considering the time lapse or changed conditions. Misinterpretation of the geotechnical information by other design team members is possible and can result in costly issues during construction and with the final product. Our geotechnical engineers are available upon request to review those portions of the plans and specifications which pertain to earthwork and foundations to determine if they are consistent with our recommendations and to suggest necessary modifications as warranted. This service was not included in the original geotechnical scope of the project and will require additional fees for the time required for specification and plan document review and comment. In addition, TD&H should be involved throughout the construction process to observe construction, particularly the placement and compaction of all fill, preparation of all foundations, and all other geotechnical aspects. Retaining the geotechnical engineer who prepared your geotechnical report to provide construction observation is the most effective method of managing the risks associated with unanticipated conditions. Geotechnical Report Traditions Townhomes Limitations Bozeman, Montana Page 15 This report was prepared for the exclusive use of the owner and architect and/or engineer in the design of the subject facility. It should be made available to prospective contractors and/or the contractor for information on factual data only and not as a warranty of subsurface conditions such as those interpreted from the test pit logs and presented in discussions of subsurface conditions included in this report. Prepared by: Reviewed by: Ahren Hastings, PE Craig Nadeau PE Geotechnical Engineer Geotechnical Manager TD&H ENGINEERING TD&H ENGINEERING J:\2021\21-006 Traditions Townhomes\GEOTECH\Traditions Townhomes Geotech FINAL.doc QUALITY CHECK:DESIGNED BY:DRAWN BY:CAD NO.JOB NO.DATE:21-006 FIG-1MONTANAWASHINGTONIDAHOGREAT FALLS-BOZEMAN-KALISPELL-SHELBYLEWISTONSPOKANEEngineeringtdhengineering.comNORTH DAKOTAWATFORD CITY1FIGURE21-0061.31.2021ACHAPPROXIMATE TEST PIT LOCATIONSBOZEMAN, MONTANATRADITIONS TOWNHOMES GEOTECHNICAL INVESTIGATION Log of Test Pit TP-1 Figure No. Sheet of 2 1 1LOGGRAPHIC01020304050 0 0 10 30 40 5020SAMPLEDEPTHWATERGROUNDSOIL DESCRIPTION LEGEND DEPTH(FEET)Traditions Townhomes Geotechnical Investigation THOMAS, DEAN & HOSKINS, INC.ENGINEERING CONSULTANTS January 15, 2021 21-006(FEET)1 8 12 Ground Water EncounteredDuring ExcavationAPPROXIMATE SURFACE ELEVATION: SURFACE: Logged By: Ahren Hastings, P.E.Excavated By:Earth Surgeons Komatsu 88 4 6 10 14 16 CLAY 2 3 5 7 9 11 13 15 Bottom of Test Pit GRAVEL CLAY Log of Test Pit TP-2 Figure No. Sheet of 3 1 1LOGGRAPHIC01020304050 0 0 10 30 40 5020SAMPLEDEPTHWATERGROUNDSOIL DESCRIPTION LEGEND DEPTH(FEET)Traditions Townhomes Geotechnical Investigation THOMAS, DEAN & HOSKINS, INC.ENGINEERING CONSULTANTS January 15, 2021 21-006(FEET)1 8 12Ground Water EncounteredDuring ExcavationAPPROXIMATE SURFACE ELEVATION: SURFACE: Logged By: Ahren Hastings, P.E.Excavated By:Earth Surgeons Komatsu 88 4 6 10 14 16 CLAY 2 3 5 7 9 11 13 15 Bottom of Test Pit GRAVEL CLAY Log of Test Pit TP-3 Figure No. Sheet of 4 1 1LOGGRAPHIC01020304050 0 0 10 30 40 5020SAMPLEDEPTHWATERGROUNDSOIL DESCRIPTION LEGEND DEPTH(FEET)Traditions Townhomes Geotechnical Investigation THOMAS, DEAN & HOSKINS, INC.ENGINEERING CONSULTANTS January 15, 2021 21-006(FEET)1 8 12Ground Water EncounteredDuring ExcavationAPPROXIMATE SURFACE ELEVATION: SURFACE: Logged By: Ahren Hastings, P.E.Excavated By:Earth Surgeons Komatsu 88 4 6 10 14 16 CLAY 2 3 5 7 9 11 13 15 Bottom of Test Pit GRAVEL CLAY Log of Test Pit TP-4 Figure No. Sheet of 5 1 1LOGGRAPHIC01020304050 0 0 10 30 40 5020SAMPLEDEPTHWATERGROUNDSOIL DESCRIPTION LEGEND DEPTH(FEET)Traditions Townhomes Geotechnical Investigation THOMAS, DEAN & HOSKINS, INC.ENGINEERING CONSULTANTS January 15, 2021 21-006(FEET)1 8 12Ground Water EncounteredDuring ExcavationAPPROXIMATE SURFACE ELEVATION: SURFACE: Logged By: Ahren Hastings, P.E.Excavated By:Earth Surgeons Komatsu 88 4 6 10 14 16 CLAY 2 3 5 7 9 11 13 15 Bottom of Test Pit GRAVEL CLAY Tested By: BC Checked By: LIQUID AND PLASTIC LIMITS TEST REPORT PLASTICITY INDEX0 10 20 30 40 50 60 LIQUID LIMIT 0 10 20 30 40 50 60 70 80 90 100 110 CL-ML C L o r O L C H o r O H ML or OL MH or OH Dashed line indicates the approximate upper limit boundary for natural soils 47 WATER CONTENT42.4 42.8 43.2 43.6 44 44.4 44.8 45.2 45.6 46 46.4 NUMBER OF BLOWS 5 6 7 8 9 10 20 25 30 40 MATERIAL DESCRIPTION LL PL PI %<#40 %<#200 USCS Project No. Client:Remarks: Project: Location: TP-3 Sample Number: A-22731 Depth: 2.0 ft Figure Lean CLAY 43 23 20 CL 21-006-001 LPW Report No. A-22731-207 Date: 1-28-2021Traditions Subdivision 5-Plex Bozeman, Montana 6 Tested By: WJC Checked By: 1-30-2021 (no specification provided) PL= LL= PI= D90= D85= D60= D50= D30= D15= D10= Cu= Cc= USCS= AASHTO= * Poorly-Graded GRAVEL with Silt and Sand (Visual) 6" 4" 3" 2.5" 2" 1.5" 1" 3/4" 1/2" 3/8" #4 #10 #20 #40 #60 #80 #100 #200 100.0 96.8 87.4 77.4 70.5 65.3 54.9 48.6 40.5 36.4 28.1 20.7 15.1 11.1 8.9 7.8 7.2 5.8 80.5163 72.9042 30.7716 20.3480 5.6570 0.8349 0.3284 93.70 3.17 GP-GM Report No. A-22730-206X LPW Traditions Subdivision 5-Plex Bozeman, Montana 21-006-001 Material Description Atterberg Limits Coefficients Classification Remarks Location: TP-2 Sample Number: A-22730 Depth: 4.0 - 5.0 ft Date: Client: Project: Project No:Figure SIEVE PERCENT SPEC. *PASS? SIZE FINER PERCENT (X=NO)PERCENT FINER0 10 20 30 40 50 60 70 80 90 100 GRAIN SIZE - mm. 0.00010.0010.010.1110100 % +3"Coarse % Gravel Fine Coarse Medium % Sand Fine Silt % Fines Clay 12.6 38.8 20.5 7.4 9.6 5.3 5.86 in.3 in.2 in.1½ in.1 in.¾ in.½ in.3/8 in.#4#10#20#30#40#60#100#140#200Particle Size Distribution Report 7 Tested By: WJC Checked By: 1-30-2021 (no specification provided) PL= LL= PI= D90= D85= D60= D50= D30= D15= D10= Cu= Cc= USCS= AASHTO= * Lean CLAY 1/2" 3/8" #4 #10 #20 #40 #60 #80 #100 #200 100.0 98.8 97.0 95.9 95.0 94.0 93.2 92.6 92.0 89.2 0.0904 CL Report No. A-22726-206 LPW Traditions Subdivision 5-Plex Bozeman, Montana 21-006-001 Material Description Atterberg Limits Coefficients Classification Remarks Location: TP-1 Sample Number: A-22726 Depth: 2.0 ft Date: Client: Project: Project No:Figure SIEVE PERCENT SPEC. *PASS? SIZE FINER PERCENT (X=NO)PERCENT FINER0 10 20 30 40 50 60 70 80 90 100 GRAIN SIZE - mm. 0.00010.0010.010.1110100 % +3"Coarse % Gravel Fine Coarse Medium % Sand Fine Silt % Fines Clay 0.0 0.0 3.0 1.1 1.9 4.8 89.26 in.3 in.2 in.1½ in.1 in.¾ in.½ in.3/8 in.#4#10#20#30#40#60#100#140#200Particle Size Distribution Report 8 Great Falls, Kalispell, Bozeman, Montana Spokane, Washington, Lewiston, Idaho THOMAS, DEAN & HOSKINSEngineering Consultants SOIL CLASSIFICATION AND SAMPLING TERMINOLOGY FOR ENGINEERING PURPOSES 12" 3" 3/4" No.4 No.10 No.40 No.200 <No.200 SILTS & CLAYSBOULDERSCOBBLESGRAVELSSANDS PARTICLE SIZE RANGE (Distinguished By Atterberg Limits)FineCoarse FineMediumCoarse Sieve Openings (Inches)Standard Sieve Sizes CL - Lean CLAY ML - SILT OL - Organic SILT/CLAY CH - Fat CLAY MH - Elastic SILT OH - Organic SILT/CLAY SW - Well-graded SAND SP - Poorly-graded SAND SM - Silty SAND SC - Clayey SAND GW - Well-graded GRAVEL GP - Poorly-graded GRAVEL GM - Silty GRAVEL GC - Clayey GRAVEL * Based on Sampler-Hammer Ratio of 8.929 E-06 ft/lbf and 4.185 E-05 ft^2/lbf for granular and cohesive soils, respectively (Terzaghi) STANDARD PENETRATION TEST (ASTM D1586) RELATIVE DENSITY*RELATIVE CONSISTENCY* Granular, Noncohesive (Gravels, Sands, & Silts)Fine-Grained, Cohesive (Clays) Very Loose Loose Medium Dense Dense Very Dense Very Soft Soft Firm Stiff Very Stiff Hard 0-2 3-4 5-8 9-15 15-30 +30 0-4 5-10 11-30 31-50 +50 Standard Penetration Test (blows/foot) Standard Penetration Test (blows/foot) PLASTICITY CHART 0 10 16 20 30 40 50 60 70 80 90 100 110 60 50 40 30 20 107 4 C L or O LC H or O H ML or OL MH or OH CL-ML "U - LIN E""A - LIN E"LIQUID LIMIT (LL)PLASTICITY INDEX (PI)For classification of fine-grained soils and thefine-grained fraction of coarse-grained soils. Equation of "A"-line Horizontal at PI = 4 to LL = 25.5, then PI = 0.73 (LL-20) Equation of "U"-line Vertical at LL = 16 to PI = 7, then PI = 0.9 (LL-8) Great Falls, Kalispell, Bozeman, Montana Spokane, Washington, Lewiston, Idaho THOMAS, DEAN & HOSKINSEngineering Consultants ASTM D2487 CLASSIFICATION OF SOILS FOR ENGINEERING PURPOSES Flow Chart For Classifying Coarse-Grained Soils (More Than 50 % Retained On The No. 200 Sieve) Flow Chart For Classifying Fine-Grained Soils ( 50 % Or More Passes The No. 200 Sieve) <5% fines 5-12% fines >12% fines <5% fines 5-12% fines >12% fines Well-graded GRAVELWell-graded GRAVEL with sandPoorly-graded GRAVELPoorly-graded GRAVEL with sand Well-graded GRAVEL with silt Well-graded GRAVEL with silt and sandWell-graded GRAVEL with clay (or silty clay)Well-graded GRAVEL with clay and sand (or silty clay and sand) Poorly-graded GRAVEL with silt Poorly-graded GRAVEL with silt and sand Poorly-graded GRAVEL with clay (or silty clay)Poorly-graded GRAVEL with clay and sand (or silty clay and sand) Silty GRAVELSilty GRAVEL with sandClayey GRAVELClayey GRAVEL with sandSilty, clayey GRAVEL Silty, clayey GRAVEL with sand Well-graded SAND Well-graded SAND with gravel Poorly-graded SANDPoorly-graded SAND with gravel Well-graded SAND with silt Well-graded SAND with silt and gravel Well-graded SAND with clay (or silty clay)Well-graded SAND with clay and gravel (or silty clay and gravel) Poorly-graded SAND with siltPoorly-graded SAND with silt and gravelPoorly-graded SAND with clay (or silty clay) Poorly-graded SAND with clay and gravel (or silty clay and gravel) Silty SANDSilty SAND with gravelClayey SAND Clayey SAND with gravel Silty, clayey SAND Silty, clayey SAND with gravel <15% sand>15% sand <15% sand >15% sand <15% sand>15% sand <15% sand >15% sand <15% sand>15% sand<15% sand>15% sand <15% sand>15% sand<15% sand>15% sand<15% sand >15% sand <15% gravel >15% gravel <15% gravel>15% gravel <15% gravel>15% gravel<15% gravel>15% gravel <15% gravel >15% gravel<15% gravel>15% gravel <15% gravel >15% gravel<15% gravel>15% gravel<15% gravel>15% gravel Lean CLAYLean CLAY with sandLean CLAY with gravelSandy lean CLAY Sandy lean CLAY with gravel Gravelly lean CLAY Gravelly lean CLAY with sand Silty CLAY Silty CLAY with sand Silty CLAY with gravel Sandy silty CLAYSandy silty CLAY with gravelGravelly silty CLAYGravelly silty CLAY with sand SILT SILT with sandSILT with gravelSandy SILTSandy SILT with gravel Gravelly SILT Gravelly SILT with sand Fat CLAYFat CLAY with sand Fat CLAY with gravel Sandy fat CLAYSandy fat CLAY with gravelGravelly fat CLAYGravelly fat CLAY with sand Elastic SILT Elastic SILT with sand Elastic SILT with gravelSandy elastic SILTSandy elastic SILT with gravelGravelly elastic SILT Gravelly elastic SILT with sand %sand > %gravel %sand < %gravel <15% gravel>15% gravel<15% sand>15% sand %sand > %gravel %sand < %gravel<15% gravel>15% gravel<15% sand >15% sand %sand > %gravel%sand < %gravel <15% gravel>15% gravel<15% sand>15% sand %sand > %gravel%sand < %gravel<15% gravel>15% gravel<15% sand >15% sand %sand > %gravel %sand < %gravel <15% gravel>15% gravel<15% sand>15% sand fines=ML or MH fines=CL or CH (or CL-ML) fines=ML or MH fines=CL or CH (or CL-ML) fines=ML or MH fines=CL or CH fines=CL-ML fines=ML or MH fines=CL or CH (or CL-ML) fines=ML or MH fines=CL or CH (or CL-ML) fines= ML or MH fines=CL or CH fines=CL-ML <30% plus No. 200 >30% plus No. 200 <30% plus No. 200 >30% plus No. 200 <30% plus No. 200 >30% plus No. 200 <30% plus No. 200 >30% plus No.200 <30% plus No. 200 >30% plus No. 200 Cu>4 and 1<Cc<3 Cu<4 and/or 1>Cc>3 Cu>4 and 1<Cc<3 Cu<4 and/or 1>Cc>3 Cu>6 and 1<Cc<3 Cu<6 and/or 1>Cc>3 Cu>6 and 1<Cc<3 Cu<6 and/or 1>Cc>3 CL CL-ML ML CH MH PI>7 and plotson or above"A" - line 4<PI<7 andplots on or above"A" - line PI<4 or plotsbelow "A" - line PI plots on orabove "A" - line PI plots below"A" - line GRAVEL%gravel > %sand SAND%sand >%gravel LL>50(inorganic) LL<50(inorganic) GW GP GW-GM GW-GC GP-GM GP-GC GM GC GC-GM SW SP SW-SM SW-SC SP-SM SP-SC SM SC SC-SM <15% plus No. 20015-29% plus No. 200 %sand > %gravel %sand < %gravel <15% plus No. 200 15-29% plus No. 200 %sand > %gravel %sand < %gravel <15% plus No. 200 15-29% plus No. 200 %sand > %gravel %sand < %gravel <15% plus No. 20015-29% plus No. 200 %sand > %gravel %sand < %gravel <15% plus No. 20015-29% plus No. 200 %sand > %gravel %sand < %gravel