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Home My WebLink AboutTract Map 3883 Lot 292 Geotechnical Study�En�EN COITION 41625 Enterprise Gale South, B-z,Tbmecula California 92590 t 951-296.351 1 - Fax 951.196.3711 www.engencorp.com Geotechnica! Feasibility Study Lindsey Residence Calle Tiara, Temecula, California APN: 919-249-911 Project Number: 4134GFS January 22, 2915 Prepared for: Jeff Lindsey - Post Office Box 1943 Temecula, California 92593 Lindsey Residence- Job Number: 4134GFS 1.0 EXECUTIVE SUMMARY....................................................................................................................................1 2.0 SITE/PROJECT DESCRIPTION .......................................................................................................... .................2 2.1 SITE DESCRIPTION: ................................................................................................................................................. 2 2.2 PROJECT DESCRIPTION: ...................................................................... 2.3 SCOPE OF WORK: ................................................................................................................................................... 2 2.4 FIELD STUDY: ......................................................................................................................................................... 2 3.0 FINDINGS........................................................................................................................................................3 3.1 SITE REVIEW: ................................................................................................... ..................................................... 3 3.2 SUBSURFACE SOIL PROFILE: ...................................................................................................................................... 3 3.3 TRANSITION AREAS: ................................................................................................................................................ 3 4.0 LABORATORY TESTING....................................................................................................................................4 4.1 GENERAL: ............................................................................................................................................................. 4 4.2 CLASSIFICATION: .................................................................................................................................................... 4 4.3 MAXIMUM ❑RY DENSITY/OPTIMUM MOISTURE CONTENT RELATIONSHIP TEST: ................................................................ 4 4.4 EXPANSION TEST: ........................................................................................................................................... 4 4.5 SOLUBLE SULFATES: ................................................................................................................................................ 4 4.6 ❑IRECT SHEAR TEST: ............................................................................................................................................... 5 5.0 GEOLOGY AND SEISMICITY.............................................................................................................................5 5.1 GEOLOGIC SETTING: ............................................................................................................................................... 5 5.2 SEISMIC HAZARDS: ................................................................................................................................................. 5 5.3 SEISMIC DESIGN PARAMETERS: ................................................................................................................................. 6 5.4 SURFACE FAULT RUPTURE: ....................................................................................................................................... 6 5.5 LIQUEFACTION: ...................................................................................................................................................... 6 5.6 SEISMICALLY INDUCED LANDSLIDING:......................................................................................................................... 6 5.7 SEISMICALLY INDUCED FLOODING, 5£1CHES:................................................................................................................ 6 E.0 EARTH MATERIALS..........................................................................................................................................6 6.1 UNDOCUMENTED FILL: ............................................................................................................................................ 6 6.2 COLLUVIUM/RESIDUAL SOILS(C[2AL):....................................................................................................................... 6 6.3 ALLUVIUM(QAL):.................................................................................................................................................. 7 6.4 PAUBA FORMATION BEDROCK(QPS):........................................................................................................................ 7 7.0 CONCLUSIONS AND RECOMMENDATIONS......................................................................................................7 7.1 EARTHWORK RECOMMENDATIONS (ALL AREAS).......................................................................................................... 7 7.2 SOIL EXPANSION POTENTIAL: .................................................................................................................................... 7 7.3 SOIL CORROSIVE POTENTIAL: ..................................................................................................................................... 7 8.0 SLOPE STABILITY (GENERAL}:..........................................................................................................................7 8.1 EXISTING SLOPES: ................................................................................................................................................... 7 8.2 FOUNDATION DESIGN RECOMMENDATIONS: ............................................................................................................... 8 8.3 FOUNDATION SIZE: .................................................................................................................................................. 8 8.4 DEPTH OF EMBEDMENT: .......................................................................................................................................... 8 8.5 BEARING CAPACITY: ................................................................................................................................................ 8 8.6 SETTLEMENT: ........................................................................................................................................................ 8 8.7 LATERAL CAPACITY: ................................................................................................................................................ 9 8.8 SLAB -ON -GRADE RECOMMENDATIONS:...................................................................................................................... 9 8.9 EXTERIOR SLABS: ................................................................................................................................................... 9 8.10 RETAINING WALL RECOMMENDATIONS.................................................................................................................... 10 8.11 EARTH PRESSURES: ............................................................................................... I ............................................... 10 8.12 RETAINING WALL DESIGN: ..................................................................................................................................... 10 8.13 SUBDRAIN:.........................................................................................................................................................10 EnGEN Corporation Lindsey Residence- Job Number: 4134GFS 8.14 BACKFILL:................................................................................................................................. ...11 8.15 UTILITY TRENCH RECOMMENDATIONS:..................................................................................................................... 11 8.16 FINISH LOT DRAINAGE RECOMMENDATIONS: ............................................................................................................. 11 8.17 PLANTER RECOMMENDATIONS: ............................................................................................................ 12 8.18 SUPPLEMENTAL CONSTRUCTION OBSERVATIONS AND TESTING: .................................................................................... 12 9.4 PLAN REVIEW: .............................................................................................................................................. 12 9.1 PRE -BID CONFERENCE: ................................................................................................................................... 12 9.2 PRE -CONSTRUCTION CONFERENCE: ......................................................................................................................... 13 10.0 CLOSURE.......................................................................................................................................................13 APPENDICES: APPENDIX 1 - GENERAL TECHNICAL REFERENCES APPENDIX 2 - LA130RATORY TEST RESULTS APPENDIX 3 - EXPLORATORY TEST PIT LOGS APPENDIX 4- PLATE 1 - GEOTECHNICAL FEASIBILITY STUDY SITE PLAN APPENDIX 5- PLATE 2 - CROSS SECTION EnGEN Corporation January 22, 2015 Mr. Jeff Lindsey Post Office Box 1943 Temecula, California 92593 Subject: Geotechnical Feasibility Study AP 919-240-011, CaIle Tiara, Temecula, California Project Number: 4134GFS References: 1) Topographic Map Site Plan, provided by client, undated. Dear Mr. Lindsey: In accordance with your request and signed authorization, a representative of this firm has visited the subject site on March 26, 2014 to visually observe the surface conditions of the subject site, perform subsurface exploration and testing and collect samples of representative site earth materials. Laboratory testing was performed on these samples. Recommendations for grading operations and preliminary foundation design are provided in the subsequent sections of this report. 1.0 EXECUTIVE SUMMARY + Feasibility for development: It is the opinion of this firm that the proposed improvements are feasible from a geotechnical standpoint, provided that the recommendations presented in this report are incorporated in the design and construction of the project. Unsuitable Soils: A portion of the soils along the outer edges of the proposed building pad is comprised of undocumented fill underlain by Pauba Formation Bedrock, (see Plate 1). There was no record found for the site grading at the City of Temecula or the Riverside County Building Departments. Based on available historical aerial photographs of the site, the grading appears to have taken place prior to 1996. Field tests taken during this study revealed less than 90% relative compaction in the undocumented fill. As such, these materials are unsuitable for structural support and should not be relied upon from a design engineering standpoint. It is also recommended that the undocumented fill be removed to expose competent native ground prior to placement of footings. • Foundation System: It is represented the site will not be graded and that it is the intention to construct the proposed residential structure on a stepped and/or pier foundation system. Footings and/or piers should be founded into competent unweathered bedrock. More detailed recommendations can be found under Section 8.2 of this report. ■ Expansive Soils: Areas to receive concrete slabs will be supported on soils that have a Low expansion potential. Minimum slab design recommendations are provided under Section 8.8, Foundation Design Recommendations% page 9 of this report: I 'm41625 Enter rise Circle South B-2 Temecula California 92590 951.296.351 I Fax: 951.296.371 I ' `k`'i p :.:, :; a, Jeff Lindsey — Linssey Residence Project Number: 4134GF5 January 2015 Page 2 2.0 SITEIPROJECT DESCRIPTION 2.1 Site Description: The subject property is an irregular shaped approximately .8 acre parcel of undeveloped land located east of Calle Tiara, in the City of Temecula, California. Vertical topographic relief across the site is approximately 31 feet with overall site drainage toward the east. At the time the field study was conducted, the site was covered with a light growth of native grasses and weeds. 2.2 Project Description: It is represented that future development of the subject property will be a single-family wood or steel -framed residential structure founded on a combination of stepped and/or pier foundations. The purpose of this study is to evaluate the site geotechnical conditions relative to the proposed development and to provide recommendation for site earthwork and minimum foundation design recommendations base on soil conditions that will be supporting the proposed structure. 2.3 Scope of Work: The scope included: 1) site reconnaissance and geologic mapping, 2) subsurface exploration and field testing, 3) sampling and laboratory testing of on -site materials, 4) engineering analysis of field and laboratory data, and 5) preparation of this report. 2.4 Field Study: Field reconnaissance, geologic mapping and subsurface exploration was conducted on March 26th 2014. The purpose of the subsurface exploration was to assess the underlying earth materials' existing condition and geotechnical properties as well as the presence of historical groundwater conditions that might affect the geotechnical integrity of the proposed improvements. Four (4) exploratory backhoe test pits were excavated within the proposed improvement areas of the subject site. Soils encountered consisted of colluvium/residual soils, undocumented fill and Pauba Formation Bedrock, (see Exploratory Backhoe Logs in the Appendix). The exploratory test pits were excavated utilizing a rubber -tired backhoe equipped with a 24-inch bucket. Bulk samples were collected from selected depth intervals and in -place density tests were performed in the upper 4-feet of each Exploratory Test Pit. Representative soil samples were subsequently returned to this firm's soils laboratory for verification of field classifications and testing. Selected samples were tested for maximum density, USCS classification, shear strength, and expansion. In addition, soil samples were visually inspected for evidence of corrosive properties that would dictate a formal corrosive analysis of materials that will be in direct contact with the proposed concrete within the improvement areas. The approximate location of the exploratory test pits are denoted on the Geotechnical Feasibility Study Site Plan, (Plate 1 and Plate 2). 2.4.1 Exploratory Test Pit Backfill Compaction: The exploratory test pits were backfilled with loose soil cuttings after completion of logging, testing and sampling operations. No compaction efforts were applied during the backfill operations, and EnGEN Corporation Jeff Lindsey -- i_insdey Residence Project Number: 4134GF5 January 2015 Page 3 tests were not performed to determine the compaction of the backfilled material. The exploratory test pit backfill should be removed and re -compacted during site development to verify as meeting a minimum density of the surrounding earth materials. 3.0 FINDINGS 3.1 Site Review: The subject site is essentially an undeveloped lot. The natural topographic relief across the subject lot is to the east at variable gradients averaging approximately 12 to 15 percent. The site has been previously graded resulting in a level building pad adjacent to and east of Calle Tiara. There was no grading plan available or documentation of the previous grading operations at the subject site. As a result, a subsurface exploration and testing program was developed in order to assess the condition of the graded area for the proposed development. The site is not located within a State designated Alquist-Priolo Zone. 3.2 Subsurface Soil Profile: Based on our site study, the majority of the pad area is comprised of Pauba Formation Bedrock (mapped as Qps, see Plate 1 and Plate 2) and artificial fill (mapped as Af, see Plate 1 and Plate 2) underlain by Pauba Formation Bedrock. Table 1 - Earth Materials Earth Materials Range of Depth Condition Colluvial Deposits Several Inches to +3' Porous, loose Undocumented Fill From 2 to greater than 10 feet Moist, loose Pauba Formation Bedrock See Plate 1 & Appendix C Dense to very dense A thin mantle of colluvium covers the natural slopes throughout the site and overlies the Pauba Formation Bedrock in the higher elevations (see Plate 1 and Plate 2). Undocumented fill was encountered within the proposed improvement areas which ranged in depth from 3 feet to the maximum depth explored. Pauba Formation Bedrock underlies the soils deposits throughout the subject site. The exploratory test pit logs of earth materials encountered during the subsurface exploration are included in the Appendix. Further discussion of the on -site earth material is presented in § 4.3 of this report. 3.3 Transition Areas: Because no grading is proposed for the subject site, once the undocumented fill has been removed from the pad area, there will be no transitions between undocumented fill and the natural bedrock formation. Because the proposed structure will be founded in unweathered Pauba Formation Bedrock with a stepped and/or pier foundation system, there is no corrective grading recommended for site preparation? Should the foundation design change from that planned this time, EnGEN should be notified so that supplemental recommendations can be given. EnGEN Corporation Jeff Lindsey — Linsdey Residence Project Number: 4134GFS January 2015 Page 4 4.0 LABORATORY TESTING 4.1 General: The results of laboratory tests performed on samples of earth material obtained during the site visit are presented in the attached Appendix. Following is a listing and brief explanation of the laboratory tests performed. The samples obtained during the field study will be discarded 30 days after the date of this report. This office should be notified immediately if retention of samples will be needed beyond 30 days. 4.2 Classification: The field classification of soil materials encountered during our site visit were verified in the laboratory in general accordance with the Unified Soils Classification System, ASTM D 2488-00, Standard Practice for Determination and Identification of Soils (Visual -Manual Procedures). The final classification is shown in the Moisture Density Test Report presented in the Appendix, 4.3 Maximum Dry Density/Optimum Moisture Content Relationship Test: Maximum dry density/optimum moisture content relationship determinations were performed on samples of near -surface earth material in general accordance with ASTM 1557-02 procedures using a 4.0-inch diameter mold. Samples were prepared at various moisture contents and compacted in five (5) layers using a 10-pound weight dropping 18-inches and with 25 blows per layer. A plot of the compacted dry density versus the moisture content of the specimens is constructed and the maximum dry density and optimum moisture content determined from the plot. The plot is shown in the Moisture Density Test Report presented in the Appendix. 4.4 Expansion Test: Laboratory expansion tests were performed on samples of near -surface earth material in general accordance with CBC 18-2. In this testing procedure, a remolded sample is compacted in two (2) layers in a 4.0-inch diameter mold to a total compacted thickness of approximately 1.0-inch by using a 5.5-pound weight dropping 12-inches and with 15 blows per layer. The sample should be compacted at a saturation between 49 and 51 percent. After remolding, the sample is confined under a pressure of 144 pounds per square foot (psf) and allowed to soak for 24 hours. The resulting volume change due to the increase in moisture content within the sample is recorded and the Expansion Index (EI) calculated. 4.5 Soluble Sulfates: Soils are not always tested for Soluble Sulfates depending on the type of material encountered. Sandy soils low in organic content are considered to be low in soluble sulfates and do not possess corrosive characteristics. Clayey earth materials and soils containing a high degree of organic material are typically identified as having soluble sulfates and corrosive properties. Should these types of soils be encountered, corrosive testing will be performed. There were no samples obtained during this study that contained high concentrations of clays or organic material, EnGEN Corporation Jeff Lindsey — Linsdey Residence Project Number: 41 34GFs January 2015 Page 5 therefore corrosive testing of the soils was not deemed necessary and Type II Concrete can be used for the foundation system. 4.6 Direct Shear Test: Direct shear tests were performed on select samples of near -surface earth material in general accordance with ASTM D 3080-03 procedures. The shear machine is of the constant strain type. The shear machine is designed to receive a 1.0-inch high, 2.42-inch diameter ring sample. Specimens from the sample were sheared at various pressures normal to the face of the specimens. The specimens were tested in a submerged condition. The maximum shear stresses were plotted versus the normal confining stresses to determine the shear strength (cohesion and angle of internal friction). 5.0 GEOLOGY AND SEISMICITY 5.1 Geologic Setting: The site is located in the Northern Peninsular Range on the southern sector of the structural unit known as the Perris Block, The Perris Block is bounded on the northeast by the San Jacinto Fault Zone, on the southwest by the Elsinore Fault Zone, and on the north by the Cucamonga Fault Zone. The southern boundary of the Perris Block is not as distinct, but is believed to coincide with a complex group of faults trending southeast from the Murrieta, California area (Kennedy, 1977). The Peninsular Range is characterized by large Mesozoic age intrusive rock masses flanked by volcanic, metasedimentary, and sedimentary rocks. Various thicknesses of colluvial/alluvial sediments derived from the erosion of the elevated portions of the region fill the low-lying areas. The earth materials encountered on the subject site are described in more detail in subsequent sections of this report. 5.2 Seismic Hazards: Because the proposed development is located in tectonicalIy active southern California, it will likely experience some effects from earthquakes. The type or severity of seismic hazards affecting the site is mainly dependent upon the distance to the causative fault, the intensity of the seismic event, and the soil characteristics. The seismic hazard may be primary, such as surface rupture and/or ground shaking, or secondary, such as liquefaction or dynamic settlement. The following is a site - specific discussion about ground motion parameters, earthquake induced settlement hazards, and liquefaction. The purpose of this analysis is to identity potential seismic hazards and propose mitigations, if necessary, to an acceptable level of risk. The following seismic hazards discussion is guided by CBC (2010). EnGEN Corporation Jeff Lindsey— Linsdey Residence Project Number: 4134GFS January2015 Page 6 5.3 Seismic Design Parameters: The 2013 California Building Code (CBC) seismic design parameters for the subject site are as follows: Description Design Parameters Site Latitude: 33.53331ON Site Longitude: -117.11544°W Site Class: D Spectral Response (Short): 0.2 sec — Ss': 1.819 Spectral Response — (1-Second): j 1.0 sec — Si: 0.724 Short Period Site Coefficient: Fa: 1.0 1-Second Period Site Coefficient: Fv: 1.5 Adjusted Spectral Res onse: Short Period - 0.2 sec — Sms: 1.819 Adjusted Spectral Response: One Sec — Sm1:1.086 Design Spectral Response: j Short Period 0.2 sec -- Sds: 1.213 Design Spectral Response: One Sec 1.0 sec -- Shc: 0.724 5.4 Surface Fault Rupture: No known active faults exist on the subject site. Accordingly, the potential for fault surface rupture on the site is considered unlikely. 5.5 Liquefaction: Based on the nature and density of the granitic bedrock formation, and the assumed depth to groundwater the potential for hazards associated with liquefaction are considered low. 5.6 Seismically Induced Landsliding: Due to the density and coarse -grained nature of the bedrock at the subject site, the probability of seismically induced landsliding is considered low. Undocumented fill should be removed from the site to prevent landsliding during a seismic event. 5.7 Seismically Induced Flooding, Seiches: Due to the lack of a large body of water located above the subject site, the possibility of seismically induced flooding or seiches is considered low. Due to the large distance of the project site to the Pacific Ocean, the possibility for seismically induced tsunamis to impact the site is considered nil. 6.0 EARTH MATERIALS 6.1 Undocumented Fill: Undocumented fill has been identified within a portion of the existing graded pad area and mapped as "Af" on Plate 1. 6.2 Coll uviumfResiduaI Soils (CQal): Based on the subsurface exploration conducted for this study, colluvial material and residual soils (unmapped) cover the majority of the near surface soil profile across the natural slopes on the subject site. EnGEN Corporation Jeff Lindsey — Linddey Residence Project Number: 4134GFS January 2015 Page 7 6.3 Alluvium (Qal): Alluvium was observed and mapped near the easterly property boundary in the shallow surface ravine draining in a general northeasterly direction, (See Plate 1). The alluvium is not within the proposed development area and will not impact the proposed development of the site from a geotechnical standpoint. 6.4 Pauba Formation Bedrock (Qps): The subject site has been mapped within the geologic bedrock formation commonly referred to as the Pauba Formation. The Pauba Formation Bedrock is a sandstone formation comprised of a mixture of silty sands, clayey sands and gravelly clean sands that is partially weathered near the surface and becomes dense to very dense at a depth of 2 to 3 feet. 7.0 CONCLUSIONS AND RECOMMENDATIONS 7.1 Earthwork Recommendations (All Areas) It is represented that other than removal of the undocumented fill, no grading is proposed for this project. However, should the planned grading of the subject site change from that represented herein, this office should be notified so that supplemental recommendations may be given. 7.2 Soil Expansion Potential: Preliminary Expansion Index testing was performed, yielding an El of 16.8. This is classified as a very low expansion potential. Import soils or soils used near finish grade may have a different El. 7.3 Soil Corrosive Potential: After a physical examination of the earth materials anticipated to be in contact with the footings of the proposed structure, it is this firm's opinion that the earth materials encountered on the subject site d❑ not possess corrosive properties normally requiring special concrete mix designs. Consequently, normal Type 11 cement may be used in concrete that will come in contactwith native soils. Final determination for soil corrosiveness should be determined upon achieving final grade elevations and samples taken considered to be representative of those that will be in contact with the proposed footings. 8.0 SLOPE STABILITY (GENERAL): 8.1 Existing Slopes: It is our opinion that the existing slopes, are stable in their current inclination with the exception of the undocumented fill (see Plate 1 and Plate 2). Due to the loose condition of the undocumented fill within the pad area, it is recommended that the undocumented fill be removed to expose the Pauba Formation Bedrock underlying it. It is our opinion that slopes comprised of the Pauba Formation Bedrock will be grossly stable at an inclination of 2:1. EnGEN Corporation Jeff Lindsey -- Lrnsdey Residence Project Number: 4134GFS January2015 Page 8 8.2 Foundation Design Recommendations: JFoundations for the proposed structures may _consist of conventional column footings and continuous wall footings founded in the Pauba Formation Bedrock. The recommendations J presented in the subsequent paragraphs for foundation design and construction are based on g eofe chnical characteristics and upon a very low expansion index potential for the supporting soils and should not preclude more restrictive structural requirements. The Structural Engineer for the project should determine the actual footing width and depth in accordance with the latest edition of the California Building Code to resist design vertical, horizontal, and uplift forces and should 1 either verify or amend the design based on final expansion testing at the completion of grading, if J necessary. 8.3 Foundation Size: Continuous footings should have a minimum width of 12-inches. Continuous footings should be continuously reinforced with a minimum of two (2) No. 4 steel reinforcing bar located near the top and two (2) No. 4 steel reinforcing bars located near the bottom of the footings to minimize the effects of slight differential movements which may occur due to minor variations in the engineering characteristics or seasonal moisture change in the supporting soils. Column footings should have a minimum width of 18-inches by 18-inches and be suitably reinforced, based on structural requirements. A grade beam, founded at the same depths and reinforced the same as the adjacent footings, should be provided across doorway and garage entrances. 8.4 Depth of Embedment: Exterior and interior footings founded in native soils should extend to a minimum depth of 12- inches for single story structures and 18-inches for two story structures below lowest adjacent finish grade. 8.5 Bearing Capacity: Provided the footings are founded within unweathered Pauba Formation Bedrock, minimum footing width, and minimum depth of embedment for footings are incorporated into the project design and construction, the allowable bearing value for design of continuous and column footings, for the residential structure for the total dead plus frequently -applied live loads, is 2,500 psf when founded on unweathered Pauba Formation Bedrock. The allowable bearing value has a Factor of Safety of at least 3.0 and may be increased by 33.3 percent for short durations of live and/or dynamic loading such as wind or seismic forces. 8.6 Settlement: Footings designed according to the recommended bearing values and the maximum assumed wail and column loads are not expected to exceed a maximum settlement of 0.75-inch or a EnGEN Corporation Jeff Lindsey — Unsdey Residence Project Number: 4134GP5 January2015 Page 9 differential settlement of 0.50-inch over a distance of 40-feet in unweathered bedrock material under static load conditions. 8.7 Lateral Capacity: Additional foundation design parameters for the residence based on compacted fill for resistance to static lateral forces, are as follows: Allowable Lateral Pressure (Equivalent Fluid Pressure), Passive Case: Unweathered Bedrock — 200 pcf Allowable Coefficient of Friction: Engineered - 0.35 Lateral load resistance may be developed by a combination of friction acting on the base of foundations and slabs and passive earth pressure developed on the sides of the footings and stem walls below grade when in contact with undisturbed, native material. The above values are allowable design values and may be used in combination without reduction in evaluating the resistance to lateral loads. The allowable values may be increased by 33.3 percent for short durations of live and/or dynamic loading, such as wind or seismic forces. For the calculation of passive earth resistance, the upper 1.0-foot of material should be neglected unless confined by a concrete slab or pavement. The maximum recommended allowable passive pressure is 5.0 times the recommended design value. 8.8 Slab -on -Grade Recommendations: The recommendations for concrete slabs, both interior and exterior, excluding PCC pavement, are based upon the anticipated building usage and upon a very low expansion potential for the supporting material as determined by Chapter 18 of the California Building Code. Concrete slabs should be designed to minimize cracking as a result of shrinkage. Joints (isolation, contraction, and construction) should be placed in accordance with the American Concrete Institute (ACI) guidelines. Special precautions should be taken during placement and curing of all concrete slabs. Excessive slump (high water/cement ratio) of the concrete and/or improper curing procedures used during either hot or cold weather conditions could result in excessive shrinkage, cracking, or curling in the slabs. It is recommended that all concrete proportioning, placement, and curing be performed in accordance with ACI recommendations and procedures. Slab -on - grade reinforcement and thickness should be provided by the structural engineer based on structural considerations, but as a minimum, it is recommended that concrete floor slabs be at least 4-inches in actual thickness and reinforced with at least No. 3 reinforcing bars placed 18- inches on center, both ways, placed at mid -height of the slab cross-section. 8.9 Exterior Slabs: All exterior concrete slabs cast on finish subgrade (patios, sidewalks, etc., with the exception of PCC pavement) should be a minimum of 4-inches nominal in thickness. Reinforcing in the slabs and the use of a compacted sand or gravel base beneath the slabs should be according to the EnGEN Corporation Jeff Lindsey — Linsdey Residence Project Number: 4134GFS January 2015 Page 10 current local standards. Subgrade soils should be moisture conditioned to at least optimum moisture content to a depth of 12-inches immediately before placing the concrete. 8.10 Retaining Wall Recommendations 8.11 Earth Pressures: Retaining walls backfilled with non -expansive granular soil (EI=O) or very low expansive potential materials (Expanslon Index of 20 or less) within a zone extending upward and away from the heel of the footing at a slope of 0.5:1 (horizontal to vertical) or flatter can be designed to resist the following static lateral soil pressures: Condition Level 6ackfill 2:1 Slope Active 35 pcf 56 pcf At Rest 65 pcf -- Further expansion testing of potential backfill material should be performed at the time of retaining wall construction to determine suitability. Walls that are free to deflect 0.01 radian at the top may be designed for the above -recommended active condition. Walls that need to be restricted from this amount of movement should be assumed rigid and designed for the at -rest condition. The above values assume well -drained backfill and no buildup of hydrostatic pressure. Surcharge loads, dead and/or live, acting on the backfill behind the wall should also be considered in the design. 8.12 Retaining Wall Design: Retaining wall footings should be founded to the same depths into firm, competent, undisturbed, unweathered bedrock as standard foundations and may be designed for an allowable bearing value of 2,500 psf (as long as the resultant force is located in the middle one-third of the footing), and with an allowable static lateral bearing pressure of 200 psflft and allowable sliding resistance coefficient of friction of 0.35. When using the allowable lateral pressure and allowable sliding resistance, a Factor of Safety of 1.5 should be achieved. 8.13 Subdrain: A subdrain system should be constructed behind and at the base of retaining walls equal to or in excess of 4-feet in height to allow drainage and to prevent the buildup of excessive hydrostatic pressures. Gravel galleries and/or filter rock, if not properly designed and graded for the on -site and/or import materials, should be enclosed in a geotextile fabric such as Mirafi 140N, Supac 4NP, or a suitable substitute in order to prevent infiltration of fines and clogging of the system. The perforated pipes should be at least 4.0-inches in diameter. Pipe perforations should be placed downward. Gravel filters should have volume of at least 1.0 cubic foot per lineal foot of pipe. For retaining walls with an overall height of less than 4-feet, subdrains may include weep holes with a continuous gravel gallery, perforated pipe surrounded by filter rock, or some other approved EnGEN Corporation Jeff Lindsey -- Linddey Residence Project Number: 4134GFS January 2015 Page 11 system. Subdrains should maintain a positive flow gradient and have outlets that drain in a non - erosive manner. 8.14 Backfill: Backfill directly behind retaining walls (if backfill width is less than 3 feet) may consist of 0.5 to 0.75-inch diameter, rounded to subrounded gravel enclosed in a geotextile fabric such as Mirafi 140N, Supac 4NP, or a suitable substitute or a clean sand (Sand Equivalent Value greater than 50) water jetted into place to obtain proper compaction. If water jetting is used, the subdrain system should be in place. Even if water jetting is used, the sand should be densified to a minimum of 90 percent relative compaction. If the specified density is not obtained by water jetting, mechanical methods will be required. If other types of soil or gravel are used for backfill, mechanical compaction methods will be required to obtain a relative compaction of at least 90 percent of maximum dry density. Backfill directly behind retaining walls should not be compacted by wheel, track or other rolling by heavy construction equipment unless the wall is designed for the surcharge loading. If gravel, clean sand or other imported backfill is used behind retaining walls, the upper 18-inches of backfill in unpaved areas should consist of typical on -site material compacted to a minimum of 90 percent relative compaction in order to prevent the influx of surface runoff into the granular backfill and into the subdrain system. Maximum dry density and optimum moisture content for backfill materials should be determined in accordance with ASTM D 1557-02 procedures. 8.15 Utility Trench Recommendations: Utility trenches within the zone of influence of foundations or under building floor slabs, hardscape, and/or pavement areas should be backfilled with properly compacted soil. It is recommended that all utility trenches excavated to depths of 5.0-feet or deeper be cut back to an inclination not steeper than 1:1 (horizontal to vertical) or be adequately shored during construction. Where interior or exterior utility trenches are proposed parallel and/or perpendicular to any building footing, the bottom of the trench should not be located below a 1:1 plane projected downward from the outside bottom edge of the adjacent footing unless the utility lines are designed for the footing surcharge loads. Backfill material should be placed in a lift thickness appropriate for the type of backfill material and compaction equipment used. Backfill material should be compacted to a minimum of 90 percent relative compaction by mechanical means. Jetting of the backfill material will not be considered a satisfactory method for compaction. Maximum dry density and optimum moisture content for backfill material should be determined according to ASTM D 1557- 02 procedures. 8.15 Finish Lot Drainage Recommendations: Finish lot surface gradients in unpaved areas should be provided next to tops of slopes and buildings to direct surface water away from foundations and slabs and from flowing over the tops EnGEN Corporation i Jeff Lindsey -- Lindsey Residence Project Number; 4134GF5 January 2015 Page 12 of slopes. The surface water should be directed toward suitable drainage facilities. Ponding of surface water should not be allowed next to structures or on pavements. In unpaved areas, a minimum positive gradient of 2.0 percent away from the structures and tops of slopes for a minimum distance of 3.0-feet and a minimum of 1.0 percent pad drainage off the property in a non -erosive manner should be provided. 8.17 Planter Recommendations: Planters around the perimeter of the structure should be designed with proper surface slope to ensure that adequate drainage is maintained and minimal irrigation water is allowed to percolate into the soils underlying the building. 8.18 Supplemental Construction Observations and Testing: Any subsequent grading for development of the subject property should be performed under engineering observation and testing performed by EnGEN Corporation. Subsequent grading includes, but is not limited to, any additional overexcavation of cut and/or cut/fill transitions, fill placement, and excavation of temporary and permanent cut and fill slopes. In addition, EnGEN Corporation should observe all foundation excavations. Observations should be made prior to installation of concrete forms and/or reinforcing steel to verify and/or modify, if necessary, the conclusions and recommendations in this report. Observations of overexcavation cuts, fill placement, finish grading, utility or other trench backfill, pavement subgrade and base course, retaining wall backfill, slab pre -saturation, or other earthwork completed for the development of subject property should be performed by EnGEN Corporation. If any of the observations and testing to verify site geotechnical conditions are not performed by EnGEN Corporation, liability for the safety and performance of the development is limited to the actual portions of the project observed and/or tested by EnGEN Corporation. 9.0 PLAN REVIEW: Subsequent to formulation of final plans and specifications for the project but before bids for construction are requested, grading and foundation plans for the proposed development should be reviewed by EnGEN Corporation to verify compatibility with site geotechnical conditions and conformance with the recommendations contained in this report. If EnGEN Corporation is not accorded the opportunity to make the recommended review, we will assume no responsibility for misinterpretation of the recommendations presented in this report. 9.1 Pre -Bid Conference: It is recommended that a pre -bid conference be held with the owner or an authorized representative, the Project Architect, the Project Civil Engineer, the Project Geotechnical Engineer and the proposed contractors present. This conference will provide continuity in the bidding EnGEN Corporation Jeff Lindsey — Linddey Residence Project Number: 4134GF5 January 2015 Page 13 process and clarify questions relative to the supplemental grading and construction requirements of the project. 9.2 Pre -Construction Conference: Before the start of any construction, a conference should be held with the owner or an authorized ' representative, the contractor, the Project Architect, the Project Civil Engineer, and the Project Geotechnical Engineer present. The purpose of this meeting should be to clarify questions relating to the intent of the supplemental grading recommendations and to verify that the project specifications comply with the recommendations of this geotechnical engineering report. Any j special grading procedures and/or difficulties proposed by the contractor can also be discussed at that time. 10.0 CLOSURE This report has been prepared for use by the parties or project named or described in this document. It may or may not contain sufficient information for other parties or purposes. In the event that changes in the assumed nature, design, or location of the proposed structure and/or project as described in this report, are planned, the conclusions and recommendations contained in this report will not be considered valid unless the changes are reviewed and the conclusions and recommendations of this report are modified or verified in writing. This study was conducted in general accordance with the applicable standards of our profession and the accepted soil and foundation engineering principles and practices at the time this report was prepared. No other warranty, implied or expressed beyond the representations of this report, is made. Although every effort has been made to obtain information regarding the geotechnical and subsurface conditions of the site, limitations exist with respect to the knowledge of unknown regional or localized off -site have an impact at the site. The recommendations resented in this report are conditions that may h p p valid as of the date of the report. However, changes in the conditions of a property can occur with the passage of time, whether they are due to natural processes or to the works of man on this and/or adjacent properties. if conditions are observed or information becomes available during the design and construction process that are not reflected in this report, EnGEN Corporation should be notified so that supplemental evaluations can be performed and the conclusions and recommendations presented in this report can be modified or verified in writing. Changes in applicable or appropriate standards of care or practice occur, whether they result from legislation or the broadening of knowledge and experience. Accordingly, the conclusions and recommendations presented in this report may be invalidated, wholly or in part, by changes outside of the control of EnGEN Corporation which occur in the future. EnGEN Corporation Jeff Lindsey-- Linsdey Residence Project Number: 4134GFS January 2015 Page 14 Thank you for the opportunity to provide ❑ur services. Often, because of design and construction details which occur on a project, questions arise concerning the geotechnical conditions on the site. If we can be of further service or should you have questions regarding this report, please do not hesitate to contact this office at your convenience. Because of our involvement in the project to date, we would be pleased to discuss engineering testing and observation services that may be applicable on the project. Respectfully submitted, EnGEN Corporation qH.ne im ge, Pr' as ❑rn atene, P ' cipa REPA 46729, Pr ' anager Project eotechni al Engineer, GE 162 HWBIOB.ch Distribution: (2) Addressee QQ,�,oFESSIoly LU No. 162 M �1 V Al� of caO�o�`�� EnGEN Corporation Lindsey Residence— Job Number: 4134GF5 Appendix I - General Technical References I. California Building Code, 2013, State of California, California Code of Regulations, Title 24, 2013 2. 0, California Building Code. 3. California Division of Mines and Geology, 1997, Guidelines for Evaluating and Mitigating Seismic Hazards in California, Special Publication 117. 4. California Geological Survey, 2002, California Geomorphic Provinces: CDMG, Note 36. 5. Hart, Earl W., and Bryant, William A., Revised 2007, Fault -Rupture Hazard Zones in California, Alquist-Prioio Earthquake Fault Zoning Act with Index to Earthquake Fault Zone Maps: State of California, Department of Conservation, Division of Mines and Geology, Special Publication 42. 6. Kennedy, M.P., 1977, Recency and Character of Faulting Along the Elsinore Fault Zone in Southern Riverside County, California: California Division of Mines and Geology, Special Report 131, 12 p., 1 Plate, Scale 1:24,000. 7. Mann, J.F., Jr., October 1955, Geology of a Portion of the Elsinore Fault Zone, California: State of California, Department of Natural Resources, Division of Mines, Special Report 43. 8. Michael P Kennedy and D.M. Morton, Geologic Map of the Murrieta 7.5 Quadrangle, California, Version 1.0, Scale 1:24,000, Digital Database by Rachel Alvarez and Morton, dated 2008. 9. County of Riverside, 2000, Transportation and Land Management Agency, Technical Guidelines for Review of Geotechnical and Geologic Reports. 10. Riverside County Planning Department, January 1983, Riverside County Comprehensive General Plan - County Seismic Hazards Map, Scale 1 Inch = 2 Miles. 11. Riverside County Land Information System: http:tlwww3.tlma.co.riverside.ca.us/pa/rclis/ 12. Guidelines for Evaluating and Mitigating Seismic Hazards in California (SCEC), 2008, California Geologic Survey (CGS), Special Publication 117A. 13. Southern California Earthquake Data Center (SCEDC), 2014, Southern California Earthquake Data Center Website, http://www.scecdc.scec.org. 14. U.S. Seismic Design Maps Web Application, United States Geologic Survey Website (http://geohazards.usgs.govldesignmaps/us/application.php), Earthquake Hazards Program, Seismic Design Maps for Engineers, 2014. EnGEN Corporation Lindsey Residence— Job Number: 4134GFS Appendix 2 - Laboratory Test Results EnGEN Corporation COMPACTION TEST REPORT 115 114 113 c� a v 112 NN- 111 - 1 r 110 4.5 5 7.5 9 10.5 12 13.5 Water content, % Test specification: ASTM D 1557-00 Method A Modified Elevl Classification Nat. Depth USCS AASHTO Moist. Sp.G. SM 3.5 TEST RESULTS Maximum dry density W 113.4 pcf Optimum moisture = 8.7 % Project No. 4134-GFS Client: Jeff Lindsey Project: Lindsey Residence o Location: TP1 @ 0-5 Sample Number: A-1 ■ EnGEN Tested By: DJ Checked By: PB AV for )p.G. - :.30 LL Pl ❑♦a ❑/a c #4 No.200 MATERIAL DESCRIPTION SAND TAN Remarks: SAMPLE# A -I SAMPLED BY PBIDJ Figure COMPACTION TEST REPORT Water content, % Test specification: ASTM D 1557-00 Method A Modified Elevl Classification Nat, Depth USCS AASHTQ Moist. Sp.G SM 9.3 TEST RESULTS Maximum dry density = 121.2 pcf Optimum moisture = 12.4 % Project No. 4134-GFS Client: Jeff Lindsey Project: Lindsey Residence o Location: TP2 @ 0-5 Sample Number: A-2 LEnGE--N ■ Corporation Tested By: DJ Checked By: PB AV for p. G. = .68 LL Pl % 7 % C #4 1 No.2QQ MATERIAL DESCRIPTION SILTY SAND BROWN Remarks: SAMPLE# A-2 SAMPLED BY PB/DJ Figure COMPACTION TEST REPORT 124 123 ,} 122 U 121 120 119 i_ I I i I I I I I I I I.,, I ,._ I I 1 1 7 8.5 10 11.5 Water content, % Test specification: ASTM D 1557-00 Method A Modified 13 14.5 16 AV for 3p.G. - L68 Elect Depth Classification Nat. Moist. S G. p� LL PI % > #4 % r No.200 USCS AASHTO SM 8.2 TEST RESULTS MATERIAL DESCRIPTION Maximum dry density — 122.6 pcf SILTY SAND WITRACE CLAY, LIGHT BltoWN Optimum moisture = 11.8 % Project No. 4134-GFS Client: Jeff Lindsey Remarks: Project: Lindsey Residence SAMPLE# A-3 SAMPLED BY PB ❑ Location: TP3 @ 0-5 Sample Number: A-3 SAMPLED ON 3-28-14 ■ IL EnGEN -J Figure Tested By: PB 300C f 2000 f 4- uj N CL Q N N N N Qi (D 1000 5CU LL 0 3000 2500 2000 N CL N U) 1500 L c� m 1000 500 0L_I I I I I I I I I II I M I I I I I 0 5 10 15 20 Strain, % Sample Type: BULK Description: SILTY SAND WITRACE CLAY, LIGHT BROWN Specific Gravity= 2.62 Remarks: SAMPLE# A-3 SAMPLED BY PBIDJ -1 Figure ---- •rrr VVVV VVLV Normal Stress, psf Sample No. Water Content, % Dry Density, pcf 3 2 Saturation, % Void Ratio Diameter, in. 2 Hei ht, in. Water Content, % Dry Density, pcf w Saturation, % Q Void Ratio Diameter, in. Height, in. Normal Stress, psf Fail. Stress, psf Strain, % Ult. Stress, psf Strain, % Strain rate, i n./min. 1 2 3 12.9 12.9 NIA 113.3 113.3 NIA 75.8 75.8 NIA 0.4442 0.4442 NIA .2.42 2.42 2.42 1.00 1.00 1.00 NIA NIA NIA 1000 2000 3000 871 1731 2396 2.9 3.7 9.5 773 1614 2162 6.6 9.5 12.8 0.10 0.10 0.10 Client: Jeff Lindsey Project: Lindsey Residence Location: TP3 @ 0-5 Sample Number: A-3 Proj. No.: 4134-GFS Date Sampled: DIRECT SHEAR TEST REPORT EnGEN Corporation UBC Laboratory Expansion Test Results 2014 Job Number: 4134-GFS Job Name: Lindsey Residence Location: Calle Tiara Sample Source: TP2 @a 0-5 Sampled by: PBIDJ Lab Technician: PB Sample Descr: Silty Sand, Brown Wet Compacted Wt.: 615.8 Pin Wt b 197 1 Net Wet Wt.: 418.7 Wet Density: 126.4 Wet Soil: 223.5 Dry Soil: 202.6 Initial Moisture (%): 10.3% Initial Dry Density: 114.6 % Saturation: 59.3% Final Wt. & Ring Wt.: 643.3 Net Final Wt.: 446.2 Dry Wt.: 379.9 Loss: 66.3 Expansion Index: 25 Net Dry Wt.: 379.9 Final Density: 113.2 Adjusted Index: 30.2 Saturated Moisture: 17.4/Q (UBC 18-2) J EnGEN Corporation 41625 Enterprise Circle,"B-2" , Temecula, CA 92590 Office: 951.296.3511 • Fax: 951.296.3711 WebSite: www.engencorp.com UBC Laboratory Expansion Test Results Job Number: 4134-GFS Job Name: Lindsey Residence Location: Caile Tiara Sample Source: TP3@ 0-5' Sampled by: PB1DJ Lab Technician: DJ Sample Descr: Silty Sand, Light -Brown Wet Compacted Wt.: 607.5 Ring Wt.: 197.1 Dial Change Time Net Wet Wt.: 410.4 • Reading 1: 0.100 NIA 3:25 Wet Density: 123.9 Reading 2: 0.103 0.003 3:40 Wet Soil: 233.1 Reading 3: 0.106 0.006 3:55 Dry Soil: 212.1 Reading 4: 0.109 0.009 4-Apr Initial Moisture °/°}: 9.9% Initial Dry Density: 112.8 % Saturation: 54.1 % Final Wt. & Ring Wt.: 631.9 Net Final Wt., 434.8 Dry Wt.: 373.8 Loss: 61.0 Expansion Index' 9 Net Dry Wt.: 373.8 Final Density: 111.4 Adjusted Index: 10.8 Saturated Moisture: 16.3% {UBC 18-2} EnCEN Corporation 41625 Enterprise Circle,"B-2" , Temecula, CA 92590 Office: 951.296.3511 Fax: 961.296.3711 WebSite: www.engencorp.com Lindsey Residence- Job Number: 4134GFS Appendix 3 - Exploratory Test Pit Logs EnGEN Corporation TEST PIT LOG Test Pit No.: TP1 PROJECT PROJECT NO. Lindsey Residence 4134GFS CLIENT DATE Jeff Lindse 03/26/14 LOCATION ELEV. West Side of Existing Pad Area see Plate 1 1250 EXCAVATION METHOD LOGGER Wheel -Mounted Backhoe with a 24-Inch Bucket. HWB DEPTH TO -Water: nla When checked: Caving: z U 0~ Z) o �� o w `'�- IL ¢ � V DESCRIPTION a `�� Q p � �x LL, �• c U Lij " Sand, trace silt, loose, moist, light brown, (Residual Soil/ Colluvium). 1.5 1'MN SP- •rxrM Gravelly, coarse to fine sand with silt, and some clay, dense, :�rfl •�x�,.r SMBrown-Pauba moist, Formation Bedrock (Qps). 4%11.1 3'af3f AM •rxi+:i 4.5 4FF3.E sa:rrr mf •rxi�•c 7'Fr�Z :�rFr.E a�rrr E •ra:rx r �:HrFi 4XCfr •rx[�:r fi 3:eFii 7 9 BOTTOM OF EXCAVATION @ 6'. NO GROUNDWATER ENCOUNTERED AND NO CONDITIONS OBSERVED THAT WOULD INDICATED HIGH GROUNDWATER CONDITION. 3.9 1 8.7 1 113.41 105.41 92.9 1 Nuke 10.3 112.4 1 121.21 112.1 1 92.5 1 Nuke Notes: EnGEN Corporation TEST PIT LOG Test Pit No.: TP2 PROJECT Lindsey Residence CLIENT Jeff Lindse r LOCATION Bottom of Undocumented Fill Slo ve EXCAVATION METHOD Wheel mounted backhoe with 24-inch bucket DEPTH TO - Waiver: nla When checked: nla z U Oz Cl-uvj ❑ESCRIF'71oN � ' ' SM Silty sand with trace clay, moist, loose, brown (UndoMmented Fill - UQ. Sp- 4',:I Gravelly, coarse to fine sand with silt, and some clay, dense, Y i .�.xr rr eI SM moist, Brown- Pauha Formation Bedrock (Qps). .+:rt7i :,ari r .i it — 3 :r Cirr ax.srr 7'errl k; _ •1:; L f L �:r•rtr :17: r M axr rr i i:irf } i a5:crr ;1 H;•j� - BOTTOM OF EXCAVATION @ 5'. NO GROUNDWATER _ ENCOUNTERED, NO INDICATIONS OF HISTORICALLY HIGH GROUND WATER CONDITIKONS OBSERVED. 991 7 PROJECT NO. 4134GFS DATE 312G114 ELEV. 1240 LOGGER HWB Caving: nla N z LU a o a LLJ� 1-0 Z Q } aUj v 5.4 1 8.7 1113.41 99.9 1 I Nuke 9.6 112.4 j 121.21 106.01 1 Nulte Notes: Top of existing pad area. Appears to be less than 2 feet of undocumented fill in this area of pad. Pauba formation underlains think layer of undocumented fill. EnGEN Corporation TEST PIT LOG Test Pit No.: TP3 PROJECT Lindsev Residence CLIENT Jeff Li LOCATION Bottom of Undocumented Fill Slope EXCAVATION METHOD Wheel mowited bac1dioe with 24-inch bucket DEPTH TO -Water. i-da When checked: ii/a !Z 0 CL C) LU DESCRIPTION LU -j (D LU Silty sand with trace clay, moist, loose, brown (Undocumented Fill - Ufl. PROJECT NO. 4 1 -')4GFS DATE 3/26/14 ELEV. 1240 LOGGER HWB Caving: ii/a rr z z 0 0 z W Uj 0 EL LLI IL 2 0 0 .-I C) Sp- Gravelly, coarse to fine sand with silt, and some clay, dense, 8.6 12.4 121.2 101.6 Nuke SM moist, Gravelly, coarse to fine sand with silt and trace clay, moist, medium dense, brown, (Uf). ,3 ti 9.6 12+4 121.2 105.7 Nuke M W313 :kr"A 4,5 ........ Pauba Formation Bedrock IN: N BOTTOM OF EXCAVATION @ 5'. NO GROUNDWATER ENCOUNTERED, NO INDICATIONS OF HISTORICALLY HIGH GROUND WATER CONDITIKONS OBSERVED. -7 Notes: Appears to be a "sliver fill with natural slope covered by undocumente fill pushed off of the top of the pad area. Undocumented fill at toe of slope is approximately 5'thick, (see Plate 1). - -- EnGEN Corporation TEST PIT LOG Test Pit No.: TP4. PROJECT PROJECT NO. Lindsey Residence 4134QFS CLIENT DATE Jeff Lindsey 3126114 LOCATION ELEV. Bottom of Undocumented Fill Sloe 1236 EXCAVATION METHOD LOGGER Wheel mounted backhoe with 24-inch bucket HWB DEPTH TO -Water: nla When checked: n/a Caving: nla 2 �� U 5 co DESCRIPTION z N ❑ o o �aa } � N~a a ao IC1 aLU ui P � 0 o 0 SM Silty sand with trace clay, moist, loose, brown (Undocumented 12.7 12.4 121.2 102.8 Nuke Fill - U0. 9 Pauba Formation Bedrock 19.8 12.4 121.2 101.8 Nuke 3 BOTTOM OF EXCAVATION a7 3'. NO GROUNDWATER ENCOUNTERED, NO INDICATIONS OF HISTORICALLY HIGH GROUND WATER CONDITIKONS OBSERVED. 4 6 7 Notes: Appears to be a "sliver fill with natural slope covered by undocumente fill pushed off of the top of the pad area. Undocumented fill at toe of slope is approximately2' thick, (see Plate 1). EnGEN Corporation Lindsey Residence- Job Number: 4134GF5 Appendix 4- Plate 7 - Geotechnical Feasibility Study Site Plan EnGEN Corporation GRAPHIC SCALE o sa ao so 120 ISO Ipsw0l pia 01, q `Q,ey ptd elena 4 De\ Re e Ra Sotana Way VICINITY MAP Not to Scale M a PLATE 1 LEGEND TP-11 ® = Approximate Location of Test Pits = Soil Sample Approximate Boundary of Geologic Contact A = Approximate Location of Geologic Cross -Section A = Colluvium overlying Pauba Formation = Pauba Formation Bedrock = Undocumented Fill GEOTECHNICALFEASIBILITY STUDY SITE PLAN I 41625 Enterprise Circle South, B-2 • Temecula, California 92590 - 951. 296.3511 • Fax; 951. 296-3711 • www.engencorp.com Lindsey Residence- Job Number: 4134GFS Appendix 5- Plate 2 — Cross Section EnGEN Corporation 1340 1320 1300 1280 1260 1240 1220 1200 iIDid 1160 PLATE 2 GEOLOGIC CROSS-SECTION A -A' 1"=2V' 0 90 20 +40 60 So J 1"=20' A caire Tara Approximate boundary Access Road between bedrock & Existing Pad ndocumented fill . . . . . . ,p%leCg`U'f_ , . Existing ps . . �R-�. ;; �2. Slope >.... s • Qp$ •TPA. A' ...•.• ... .......................................... zP'.'.L��s. . Cross Section 20 40 60 80 100 120 140 160 180 200 En EN 1340 1320 1300 1280 1260 1240 iPill 1200 1160 PLATE 2 GEOLOGIC CROSS-SECTION A -A' 1" = 209 0 10 20 40 60 80 1. a 20' A Cade Tiara Approximate boundary Access Road • . . between bedrock & • . Existing Pad ndocumented fill . t°c Existing : (, �s : • • : 2:1 Slope ,�. • `::. :" � ;.: ......'.'.'.'.'.'.'.'.'. .'. TP.3.'.' Cross Section 20 40 60 80 100 120 140 160 180 200 En ON