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Home My WebLink AboutGeotech Investigation I I I I I I I I I I I I I I I I I I I LEIGHTON AND ASSOCIA TES, INC. Geotechnical and Environmental Engineering Consultants GEOTECHNICAL INVESTIGATION, PROPOSED RANCHO ROSES, TENTATIVE TRACT 28309, NICHOLAS ROAD, CITY OF TEMECULA, RIVERSIDE COUNTY, CALIFORNIA January 2, 1996 Project No. 11950364-001 Prepared For: REALTY MANAGEMENT ADVISORS 4350 La Jolla Village Drive, Suite 300 San Diego, California 92122 3934 MURPHY CANYON ROAD, SUITE B20S, SAN DIEGO, CA 92123 ~ (619) 292-8030. (800) 447-2626 FAX (619) 292-0771 I I I I I I I I I I I I I I I I I I I LEIGHTON AND ASSOCIA TES, INC. Geotechnical and Environmental Engineering Consultants January 2, 1996 Project No. 11950364-001 To: Realty Management Advisors 4350 La Jolla Village Drive, Suite 300 San Diego, California 92122 Attention: Mr. Bill Kennedy Subject: Geotechnical Investigation, Proposed Rancho Roses, Tentative Tract 28309, Nicolas Road, City of Temecula, Riverside County, California In accordance with your request and authorization, Leighton and Associates, Inc. has performed a geotechnical investigation for the proposed above-referenced site. The accompanying report presents a summary of our investigation and provides conclusions and recommendations relative to the proposed site development. Based on the results of our investigation and review of the current project plan prepared by Robert Bein, William Frost and Associates, the proposed residential development is considered feasible from a geotechnical standpoint provided the recommendations outlined in this report are implemented during site grading and construction. If you have any questions regarding this report, please do not hesitate to contact this office. We appreciate this opportunity to be of service. Respectfully submitted, LEIGHfON AND ASSOCIATES, INC. ~~~ Associate agist Josep G. Fra~52 . tor of Engineering . KAB/MB/JGF/keb . Distribution: (4) Addressee 3934 MURPHY CANYON ROAD, SUITE B20S, SAN DIEGO, CA 92123 z.. (619) 292-8030 . (800) 447-2626 FAX (619) 292-0771 I I I I I I I I I I I I I I I I I I I 11950364-001 TABLE OF CONTENTS : Section Pa~e 11.0 INTRODUCTION .................................................... 1 1.1 Purpose and Scope ................................................. 1 1.2 Site Location and Description. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 1.3 Proposed Development. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 2.0 SUBSURFACE INVESTIGATION AND LABORATORY TESTING ............ 2 2.1 Subsurface Investigation ............................................. 2 2.2 Laboratory Testing ................................................. 2 :3.0 SUMMARY OF GEOTECHNICAL CONDmONS .......................... 3 3.1 Regional Geologic Setting. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 3.2 Site Geology ...................................................... 3 3.2.1 Fill Soils .................................................... 3 3.2.2 Alluvial Soils. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 3.3 Ground Water. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 4.0 FAULTING AND SEISMICITY ......................................... 5 4.1 Faulting.... . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 4.2 Seismicity ........................................................ 5 4.2.1 Lurching.................................................... 6 4.2.2 Liquefaction and Dynamic Settlement . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 4.2.3 Subsidence and Fissuring ....................................... 6 5.0 CONCLUSIONS...................................................... 7 5.1 Seismicity ........................................................ 7 5.2 Excavatability ..................................................... 7 5.3 Fill Suitability ..................................................... 7 5.4 Ground'Water. . . . . . . . . . .. . . . .. . . . . . .. . . .. .. .. .. . .. . . . . . . . . . . . . .. . . 7 - i - ~ WORTON AND ASSOCIATES, INC. I I I I I I I I I I I I I I I I I I I 11950364-001 TABLE OF CONTENTS (Continued) Section Pal!e 6.0 RECOMMENDATIONS ............................................... 8 6.1 General Earthwork ................................................. 8 6.1.1 .Site Preparation .............................................. 8 6.1.2 .Removals and Excavations ...................................... 8 6.1.3 ,Structural Fills ............................................... 8 6.1.4 Trench Backfill . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 6.2 Control of Ground Water and Surface Water ............................. 9 6.2.1 'Surface Drainage and Erosion. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 6.3 Foundation Design ................................................. 9 6.4 Floor Slabs ....................................................... 10 6.5 Settlement. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. 10 6.6 Lateral Earth Pressures and Resistance. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. 11 6.7 Preliminary Pavement Design ......................................... 12 7.0 CONSTRUCTION OBSERVATION AND PLAN REVIEW . . . . . . . . . . . . . . . . . . .. 13 Accompanying Figures and Appendices , Fil!Ures Figure 1 - Site Location Map .. . . .. .. . .. . .. . . . .. . . .. . . . .. .. .. . . . . .. .. . . Rear of Text ; Plates , Plate 1 - Geotechnical Map ............................................. In Pocket , Aooendices , Appendix A - References , Appendix B - Boring Logs , Appendix C - Laboratory Testing Procedures and Results , Appendix D - General Earthwork and Grading Specifications - 1 - A. IE/ORTON AltO ASSOCIArES. /IIC. I I I I I I I I I I I I I I I I I I I 11950364-001 1.0 INTRODUCTION 1.1 Puroose and Scope This report presents the results of Leighton and Associates, Inc.'s (Leighton) geotechnical investigation of the proposed Rancho Roses, Tentative Tract 28309, Nicolas Road in the City of Temecula, California. The purpose of our investigation was to identify and evaluate the pertinent geotechnical conditions present at the site and to provide geotechnical conclusions and recommendations relative to the proposed development. Our scope of services included: . Review of referenced documents and maps (Appendix A). . Site reconnaissance. . Subsurface exploration, consisting of the excavation, logging and sampling of five smaII- diameter borings on the site. Logs of these borings are presented in Appendix B. . Laboratory testing of representative soil samples obtained from the subsurface exploration program. Results of these tests are presented in Appendix C and on the boring logs (Appendix B). . Compilation and analysis of the geotechnical data obtained from our background studies, field investigation and laboratory testing. . Preparation of this report presenting our findings, conclusions and recommendations regarding the proposed development. 11.2 Site Location and Description The site is located on Nicolas Road approximately 1 mile east of the intersection of Nicholas Road and Winchester Road in Temecula, California (Figure 1 - Site Location Map). The subject site is currently a vacant dirt lot covering approximately 11.4 acres. Several vacant structures, including greenhouse-type structures, and a large section of asphalt and concrete were being demolished near the southwest comer of the property during this investigation. Current site elevation ranges from approximately 1,119 feet mean sea level (msl) at the southwest corner of the site to 1,127 feet msl at the southeast corner of the lot. 1.3 ProlJQsed Development The proposed development consists of a residential development with associated streets, hardscapes,:and landscaping. We anticipate minor cuts and fills to create the desired building pads and str~t elevations. . Develop~ent plans depict~g the anticipated .wading configuration j were not avaIlable at the time of thIS report preparatIon. , vr1t; Ct-' 0 ~ f7 ~'V I ";liD/- . ...../' ~- I. ft., y",,,, . -7 f:1.j(ft,,-,, y:;;...:...:.'. .- -- - 1 - 11-- "" ~ -.:> IEI6RTON AJIJI ASSOCIATES, INC. I I I I I I I I I I I I I. I I I I I I 11950364-001 2.0 SUBSURFACE INVESTIGATION AND LABORATORY TESTING 2.1 Subsurface Investil!ation Our subsurface investigation consisted of the excavation of five 8-inch-diameter, hollow-stem auger borings to depths between 21 to 41 feet below the existing ground surface. The purpose of these excavations was to evaluate the engineering characteristics of the onsite soils relative to the proposed development. The borings were logged by a geologist from our firm. Representative relatively undisturbed and bulk samples were collected during drilling for laboratory testing. The approximate locations <if the borings are shown on Plate 1. Logs of borings are presented in Appendix B. Subsequent to logging, the borings were backfilled with borehole cuttings. Some settlement of the boring backfill soils should be expected with time. 2.2 Laboratorv Testing Representative samples were tested for the following parameters: in-situ moisture content and density, expansion potential, and consolidation. The results of our laboratory testing along with a summary of the testing procedures are presented in Appendix C. In-situ moisture and density test results are presented on the boring logs (Appendix B). -2- ~ IE/OIfTlJIIAIIDASSl/C/ATES,/IIC. I I I I I I I I I I I I I I I I I I I 11950364-001 3.0 SUMMARY OF GEOTECHNICAL CONDmONS '3.1 Relrional Geologic Settinl! The site is located in the Peninsular Range Geomorphic Province of California. The Peninsular Ranges are characterized by steep, elongated valleys that trend northwestward. More specifically, the property is located adjacent to a fault-controlled, down-dropped graben known as the Elsinore Trough. This graben is believed to contain as much as 3,000 feet of alluvium which has accumulated since Miocene time. The Elsinore Trough is bounded on the northeast by the Wildomar fault and on the southwest by the Willard fault. These faults are part of the Elsinore fault zone which extends from the San Gabriel River Valley southeasterly to the United States/Mexico border. The Wildomar fault is considered active, and the Willard fault is considered to be potentially active. . The Santa Ana Mountains lie along the western side of the Elsinore fault zone and the Perris Block is located along the eastern side of the fault zone. The mountain ranges are underlain by Pre-Cretaceous metasedimentary and metavolcanic rocks and Cretaceous plutonic rocks on the Southern California batholith. Tertiary and Quaternary rocks are generally comprised of non-marine sediments consisting of sandstones, mudstones, conglomerates and occasional volcanic units. 13.2 Site Geolol!V Based on our subsurface exploration and review of our referenced reports (Appendix A), the site is apparently underlain by fill soils which are, in turn, underlain by a thick sequence of alluvial soils with bedrock material at depth. A brief description of the onsite units encountered during our subsurface investigation is presented below. 3.2.1 Fill Soils Fill soils onsite were encountered to depths ranging from 3 to 8 feet below the existing ground surface in our borings. These soils were described as brown, damp to moist, sandy silt to silty sand with scattered construction debris. Expansion index testing of a representative sample of the fill soils indicates a low expansion potential (UBC index = 34). The fill soils were evaluated to be relatively dry in the upper portions and relatively competent and suitable for support of the proposed development below the upper 3 feet. -3- '1 UIOHTDII AND ASSOCIArES. INC. I I I I I I I I I I I I I I I I I I I 11950364-001 3.2.2 Alluvial Soils Alluvial soils were encountered below the fill soils (at a depth of 3 to 8 feet) to the total depth explored (41 feet). These soils were descnbed as light brown, damp, medium dense, sandy clay to medium dense, clayey sand with layers of medium dense, fine to medium sand. The alluvial soils are also relatively competent and suitable for the support of fill and/or structural loads. Our laboratory testing indicated a low potential for hydroconsolidation, which could be further reduced by remedial measures during grading (see Section 6.1). 3.3 Ground Water Ground water was not observed at the time of drilling. Ground water is not anticipated to be a constraint to the proposed at-grade construction. However, ground-water depths and locaIized seepage can be expected to fluctuate in response to rainfall, irrigation and broken water lines. - 4- II ~ - ~ lEIORTON AND ASSOCIATES, INC. I I I I I I I I I I I I I I I I I I I 11950364-001 4.0 FAULTING AND SEISMICITY A.l Faultinl! Our discussion of faults on the site is prefaced with a discussion of California legislation and policies concerning the classification and land-use criteria associated with faults. By definition of the California Mining and Geology Board, an active fault is a fault which has had surface displacement within Holocene time (approximately the last 11,000 years). The State Geologist has defined a potentiallv active fault as any fault considered to have been active during Quaternary time (the last 2,000,000 years). This definition is used in delineating Special Studies Zones as mandated by the Alquist-Priolo Geologic Hazards Zones Act of 1972, and as subsequently revised in 1975, 1985, 1990, and 1992. The intent of this act is to assure that unwise urban development, and certain inhabitable structures, do not occur across the traces of active faults. The subject site is not included within any special study zones as created by the Alquist-Priolo Act. A review of available geologic literature pertaining to the subject site (Appendix A) indicates that there are no known active faults crossing the property. The nearest known active regional fault is the, Elsinore fault zone located approximately 3.1 miles southwest of the site. 14.2 Seismicity The subject site can be considered to lie within a seismically active region, as can all of southern California A maximum probable earthquake is the maximum expectable earthquake produced from a causative fault during a loo-year interval. The Elsinore fault zone is considered to have the most significant affect at the site from a design standpoint. A maximum probable earthquake of Richter Magnitude 6.75 is expected to produce a peak horizontal ground acceleration of approximately O.5g at the site. The effect of seismic shaking may be mitigated by adhering to the Uniform Building Code (UBC) and state-of-the-art seismic design parameters of the Structural Engineers Association of California This site is located within UBC Seismic Zone 4. Secondary effects associated with severe ground shaking, following a relatively large earthquake on a regional fault which may affect the site, include ground lurching, soil liquefaction and dynamic settlement. These secondary effects of seismic shaking are discussed in the following sections. -5- q UIGHTON AND ASSOCIATES, INC. I I I I I I I I I I I I I I I I I I I 11950364-001 4.2.1 Lurchinl! Soil lurching refers to the rolling motion on the surface due to the passage of seismic surface waves. Effects of this nature are not considered significant on sites (such as the subject site) where the thickness of soft sediments does not vary appreciably under structures. 4.2.2 Liquefaction and Dvnamic Settlement Liquefaction is a phenomenon in which soils lose shear strength for short periods of time during an earthquake, which may result in a very large total and/or differential settlements for structures founded on liquefying soils. In order for the potential effects of liquefaction to be manifested at the ground surface, the soils generally have to be granular, loose to medium dense, saturated relativelv near the !!fOund surface. and must be subjected to a sufficient magnitude and duration of shaking. The subject site is located in an area delineated by the County of Riverside as an area of potential liquefaction. However, liquefaction is not considered likely to occur in clayey alluvial materials, dense formational materials or properly compacted fill soils. It is our opinion that (due to the depth to ground water) adverse liquefaction and associated dynamic settlement to surface structures due to a design earthquake event are unlikely at this site. It should be recognized, however, that many of the parameters used in liquefaction evaluation are subjective and open to interpretation. It should also be understood that much of southern California is an area of moderate to high seismic risk and it is not generally considered economically feasible to build structures totally resistant to earthquake-related hazards. However, current state-{)f-the-art standards for design and construction are intended to reduce the potential for major structural damage at this time. 4.2.3 Subsidence and FlSSurinl! The subject site lies relatively adjacent to a region which has been delineated by the Riverside County Planning Department to have the potential for differential settlement or subsidence and associated surface fissuring. It is our opinion given that no active faults are known to transect the subject site and that the site is underlain by fill soils over a relatively uniform deposit of competent alluvial soils, that the potential for differential settlement and/or subsidence at the site due to the design earthquake event is considered low. -6- \0 1El6IITIIII AND ASSOCIATES, INC. I I I I I I I I I I I I I I I I I I I 11950364-001 5.0 CONCLUSIONS Based on the results of our preliminary geotechnical investigation of the site, it is our opinion that the proposed development is feasible from a geotechnical standpoint provided the recommendations ,contained herein are incorporated in the project design. The following is a summary of the geotechnical factors which may affect development of the site. 5.1 Seismicitv Active faults are not known to exist on or in the immediate vicinity of the site. The maximum anticipated ground acceleration on the site due to a maximum orobable earthquake on the Elsinore fault zone is estimated to be approximately O.5g. , 5;2 Excavatabilitv We anticipate that excavations of the surficial soils could generally be accomplished with conventional earthwork equipment in good working condition. , 5.3 Fill Suitability The existing onsite soils appear to be suitable material for structural fill provided they are relatively fr= of rock fragments larger than 6 inches in maximum dimensions, organic material and/or deleterious debris. Oversize material, if encountered, should be exported oflSite. , 5.4 Ground Water Ground water was not encountered in any of the borings during our investigation. Ground water is not anticipated to have a significant adverse effect on the proposed at-grade construction. - 7 - II ~ - \\ IEIfIHrDII AND ASSOClArES. INC. I I I I I I I I I I I I I I I I I I I 11950364-001 6.0 RECOMMENDATIONS 6.1 General Earthwork Earthwork should be performed in accordance with the General Earthwork and Grading Specifications in Appendix D, and the following recommendations. The recommendations contained~ in Appendix D are general grading specifications provided for typical grading projects and may not be strictly applicable to this project. The specific recommendations contained in the text of this report supersede the general recommendations in Appendix D. The contract between the developer and earthwork contractor should be worded such that it is the responsibility of the contractor to place the fill properly and in accordance with the recommendations of this report and the specifications in Appendix D, not withstanding the testing and observation of the geotechnical consultant. 6.1.1 Site Preparation Prior to grading, the site should be cleared of existing structures, surface and subsurface obstructions (including any existing buried electrical, storm drain, water, sewer pipes and/or septic systems which are to be abandoned), existing asphalt, pavement, deleterious debris, and landscape vegetation. Vegetation, oversize material and debris should be disposed of offsite. Holes resulting from removal of buried obstructions which extend below finished site grades should be filled with properly compacted soil 6.1.2 Removals and Excavations Landscaping topsoil, loose, dry soils and existing asphalt should be removed below and within 5 feet (measured horizontally) of the pro structure or proposed fill areas, and all settlement-sensitive structures.__' I . e . i'lIDd\iteoomj'i1mftlm'depthasheuld W..!!RIlr&lximatel~_~"'~I~~: " ;;su , .a< ..J;)r,.(lIQ~_rQll&bEgmde elevations and may be loca1Iy deeper based on actual conditions eneowffetOO- during grading. After removals, the base of removals should be thoroughly moistened with a water truck until the moisture penetration has reached a depth of 3 feet from the base of the removals. We anticipate that excavations may be accomplished using standard, heavy-duty grading and excavation equipment. All excavations should be in accordance with Cal-OSHA regulations. 6.1.3 Structural Fills The onsite soils are generally suitable for use as compacted fill, provided they are free of organic materials and debris, asphalt concrete, and material larger than 6 inches. The compacted fill soils should be brought to at least 1 percent above the optimum -8- \~ IEI6Jffl/N AND ASSDCIATES, IIIC. I I I I I I I I I I I I I I I I I I I 11950364-001 moisture content, and recompacted to at least 90 percent relative compaction. The optimum lift thickness to produce a uniformly compacted fill will depend on the type and size of compaction equipment used. In general, fill should be placed in uniform lifts not exceeding 8 inches in thickness. Fill soils should be placed a minimum of 90 percent relative compaction, at least 1 percent above optimum moisture content based on ASTM D1557-91. == ;iItiil~ie::~ti~~~~wials~~h~.Q per " ,. -- '8'=-2). . ~ ,. ....,,.~._,. 6.1.4 Trench Backfill The onsite soils may generally be suitable as trench backfill provided they are screened of rocks and other material over 6 inches in diameter and organic matter. Trench backfill should be compacted in uniform lifts (not exceeding 8 inches in compacted thickness) by mechanical means to at least 90 percent relative compaction (ASTM D1557-91). ,6.2 Control of Ground Water and Surface Water Our experience indicates that surface or near-surface ground-water conditions can develop in areas where ground-water conditions did not exist prior to site development, especially in areas where a substantial increase in surface-water infIltration results from landscape irrigation. Drainage devices for reduction of water accumulation can be recommended if these conditions are observed. We recommend that landscape irrigation be kept to the minimum necessary to maintain plant vigor. 6.2.1 Surface Drainal!e and Erosion Surface drainage should be controlled at all times. Positive surface drainage should be provided to direct surface water away from the structures, toward the street or suitable drainage facilities. Ponding of water should be avoided adjacent to structures. '6.3 Foundation Desil!D We assume that the structures will be underlain by soils of low expansion potential (less than 50 per UBC 18-2). Footings bearing in properly compacted fill should extend a minimum of 12 inches (for one-story structures) or 18 inches (for two-story structures) below the lowest adjacent grade. At this depth, footings may be designed using an allowable soil-bearing value of 2,000 pounds per square foot (psf). This value may be increased by one-third for loads of short duration, including wind or seismic forces. Footings should be reinforced with four No. -9- I~ LEI6RTON AND ASSDCIA TES, INC. I I I I I I I I I I I I I I I I I I I 11950364-001 4 rebars, two near the top and two near the bottom of the footing. The footings should have a minimum 7-foot setback (measured horizontally) from the base of the footing to daylight. 6.4 Floor Slabs All slabs should have a minimum thickness of 4 inches. Reinforcement should consist of No. 3 bars at 18 inches on center (each way) or No.4 bars at 24 inches on center (each way). We emphasize that it is the responsibility of the contractor to ensure that the slab reinforcement is placed at midheight of the slab. Slabs should be underlain by a 2-inch layer of clean sand (sand equivalent greater than 30) to aid in concrete curing, which is underlain by a 6-mil (or heavier) moisture barrier, which is in turn underlain by 2 inches of clean sand to act as a capillary break. All penetrations through the moisture barrier and all laps should be sealed. Our experience indicates that use of reinforcement in slabs and foundations can generally reduce the potential for drying and shrinkage cracking. However, some cracking should be expected as the concrete cures. Minor cracking is considered normal; however, it is often aggravated by a high water/cement ratio, high concrete temperature at the time of placement, small nominal aggregate size, and rapid moisture loss due to hot, dry and/or windy weather conditions during placement and curing. Cracking due to temperature and moisture fluctuations can also be expected. The use of low slump concrete (not exceeding 4 inches at the time ,of placement) can reduce the potential for shrinkage cracking. To reduce the potential for moisture migration through the concrete to have a detrimental affect on floor coverings, we recommend that the floor coverings contractor test the moisture-vapor flux rate prior to attempting application of moisture-sensitive floorings. "Breathable" floor coverings should be considered if the vapor flux rates are high. Floor covering manufacturers should be consulted, for specific recommendations. If tile or other crack-sensitive flooring is planned, a slipsheet should be used. Flexible joint material should be used where crack-sensitive flooring overlies concrete joints. 6.5 Settlement The recommended allowable bearing capacity is generally based on a total allowable settlement of 3/4 inch. Actual settlement can be estimated on the basis that settlement is roughly proportional to the net contact bearing pressure. Since settlements are a function of footing size and contact bearing pressure, some differential settlement can be expected between adjacent columns or waIls where a large differential loading condition exists. However, for most cases, differential settlements are considered unlikely to exceed 1/2 inch. With increased footing depth/width ratios, differential settlements should be less. -ro- ~ UI6IITIIII AND ASSl/CIATES. INC. I I I I U U I I I I I I I I I I I I I 11950364-001 6.6 Lateral Earth Pressures and Resistance Embedded structural walls should be designed for lateral earth pressures exerted on them. The magnitude of these pressures depends on the amount of deformation that the wall can withstand ,under load. If the wall can yield enough to mobilize the full shear strength of the soil, it can be designed for "active" pressure. If the wall cannot yield under the applied load, the shear strength of the soil cannot be mobilized and the earth pressure will be higher. Such walls should be designed for "at rest" conditions. If a structure moves toward the soils, the resulting resistance developed by the soil is the "passive" resistance. For design purposes, the recommended equivalent fluid pressure in each case for walls founded above the static ground-water table and backfilled with soils of very low to low expansion potential are provided below. All backfill soils should have an expansion potential of 50 or less (per UBC 18-2). Equivalent Fluid Weight (pet) Condition Level Active 35 At-Rest 55 Passive 350 (Maximum of 3 kst) The above values assume very low to low expansion potential backfill and free-draining conditions. If conditions other than these covered herein are anticipated, the equivalent fluid pressure values should be provided on an individual case basis by the geotechnical engineer. A surcharge load for a restrained or unrestrained wall resulting from automobile traffic may be assumed to be equivalent to a uniform pressure of 75 psf which is in addition to the equivalent fluid pressures given above. All retaining wall structures should be provided with appropriate drainage and waterproofing. Typical retaining wall drainage design is illustrated in Appendix D. Wall backfill should be compacted by mechanical methods to at least 95 percent relative compaction (based on ASTM Test Method D1557-91). Wall footings design and setbacks should be performed in accordance with the previous foundation design recommendations and reinforced in accordance with structural considerations. Soil resistance developed against lateral structural movement can be obtained from the passive pressure value provided above. Further, for sliding resistance, a friction coefficient of 0.35 may be used atthe concrete and soil interface. These values may be increased by one-third when considering loads of short duration, including wind or seismic loads. The total resistance may be taken as the sum of the frictional and passive resistance provided that the passive portion does not exceed two-thirds the total resistance. - 11 - ~~ LElOHTON AND ASSDCIArES, INC. I !I I I I I I I I I I I I I I I I I I 6.7 11950364-001 f ki r bYlt, , 1.16, l Of 1:\'" ~!. I()/): ,'t' ".1'1 l l' "',' " , I 1Pllrl Our ev~l~~tion ,?f th~ onsi~l":S they _ ~. a~, allfe.~l':;if>prox!m~tely ~! UtillZlDg thIS, With a . <<~0iliii1i _ . .. !i2@j~J; streets, a prel1lD1nary pavement section of~~.Oaineh,,< (lf~a<ghal~ll0nllrete_(lVer 5.0 inches (for a traffic index of 5.0) o~or a traffic index of 5.5) of4il~aggregmJ;;sQlllIe should be anticipated. The final pavement section should be based on R-value samples obtained near the finish grade during earthwork operations. Preliminarv Pavement Desil!D , U' I.'; \1" - 12- ,Co IE/OHTDN AND ASSOCIATES, INC. II I I I I I I I I I I I I I I I I I I 11950364-001 7.0 CONSTRUCTION OBSERVATION AND PLAN REVIEW The recommendations provided in this report are based on subsurface conditions disclosed by field reconnaissance and widely spaced exploratory borings. The interpolated subsurface conditions should be checked in the field during construction by a representative of Leighton. We recommend that onsite excavations be observed during grading by a representative from Leighton. Construction observation and field density testing of compacted fIll should be performed by a Leighton representative so that construction is in accordance with the recommendations of this report and requirements of the City of Temecula and the County of Riverside. Revisions to the grading and/or building plans should be reviewed by this office prior to construction. -13- 11 LE/BHTDII AND ASSOCIATES, INC. I I I I I I I I I I I I I I I I I I SITE LOCATION MAP t -N- ~ !BASE MAP: U.S.G.S. 7.5 min. Murrieta and Bachelor Mtn. Topographic Quadrangles I Project No. 11950364-001 RANCHO ROSES Scale 1-/24,000' [1][I] Engr.lGeol. JGF/MB I'@> Drafted By KAB '042 889 Nicolas Rd., Temecula Date 12/22/95 Figure No. 1 I I I I I I il II I I I I I 'I , i,l ' , i il il il I I 11950364-001 APPENDIX A References Albee, AL, and Smith, J.L, 1966, Earthquake Characteristics and Fault Activity in Southern California, in Lung, R and Proctor, R, ed., Engineering Geology in Southern California, Association of Engineering Geologists, Special Publication, dated October 1966. Bolt, B.A, 1973, Duration of Strong Ground Motion, Proc. Fifth World Conference on Earthquake Engineering, Rome, Paper No. 292, pp. 1394-1313, dated June 1973. Bonilla, M.J., 1970, Surface Faulting and Related Effects, in Wiegel, R, ed., Earthquake Engineering, New Jersey, Prentice-Hall, Inc., pp. 47-74. California, State of, Department of Transportation, 1988a, Standard Specifications, dated January 1988. , 1988b, Highway Design Manual, 4th Ed., dated August 5, 1988. GreensfeIder, RW., 1974, Maximum Credible Rock Accelerations from Earthquakes in California, California Division of Mines and Geology, Map Sheet 23. Hart, E.W., 1992, Fault-Rupture Hazard Zones in California, Alquist-Priolo Special Studies Zones Act of 1972, with Index to Special Study Zones Maps: Department of Conservation, Division of Mines land Geology, Special Publication 42. Ishihara, K., 1985, "Stability of Natural Deposits During Earthquakes", Proc. of the Eleventh International Conference on Soil Mechanics and Foundation Engineering, AA Belkema Publishers, Rotterdam, Netherlands. Jennings, C.W., 1992, Fault Activity Map of California: California Division of Mines and Geology, DMG Open-File Report 92-03. Lamar, D.L, Merifield, P.M., and Proctor, RJ., 1973, Earthquake Recurrence Intervals on Major Faults in Southern California, in Moran, D.R, Slosson, J.R, Stone, RD., Yelverston, C.A, eds., 1973, Geology Seismicity, and Environmental Impact: Association of Engineering Geologists, Special Publication. Robert Bein, William Frost, Inc., 1983 (Revised 1988), Riverside County Comprehensive General Plan Seismic-Geologic Map, Compiled by Riverside County Planning Department, dated January 1983 (revised April 1988). Schnabel, B., and Seed, J.B., 1973, Accelerations in Rock for Earthquakes in the Western United States, Bulletin of the Seismological Society of America, V. 63, No.2, pp. 501-516. A-l \~ .. I I I i I I I I I I I I ;1 , 'I 'I !I il Iii il 11950364-001 APPENDIX A (Continued) Seed, H.B., Idriss, I.M., and Kiefer, F.W., 1969, Characteristics of Rock Motions During Earthquakes, Journal of Soil Mechanics and Foundation Division, ASCE, V. 95, No. SM5, Proc. Paper 6783, pp. 119-1218. A-l 2-0 I GEOTECHNICAL BORING LOG KEY I Dale Prdject , Drilling Co. Hole Diameter Elevation Top of Hole +1- Drive Weight ft. Ref or Datum " ~ ,j.~ .. .. "x .- .. . ..0 ..~ t.'"' ..lI! 30 1:'" ".. olL. "I: -u ..U u. -to eQ. .!41 -II) 10.. '"' 0" " '-::i Q. t. J:15 ell'"' e u Sheet -L of -L. Project No. Type of Rig KEY TO BORING LOG GRAPHICS I I Drop I I: o~ .I;~ u .-.. .. +-ieu ..... .I; III .. ~iQl Q." Q.o .. .... .....J 0 ~0 e~ t. z l!) '" '0 0 ~ . . " .. '" .. . . . - ~ 15 . o z .. Q. E .. II) I I in. GEOTECHNICAL DESCRIPTION Logged By Sampled By CL CH Inorganic clay or low to medium plasticity, gravelly clay, sandy clay. silty clay; lean clay Inorganic clay of high plasticity; rat clay OL-OH Organic clay, silt or silty day..clayey silt mixtures ML Inorganic silt: very fine sand: silty or clayey fine sand; clayey silt with low plasticity I MH Inorganic silt: diatomaceous fine sandy or silty soils; clastic silt C~ML l...ow plasticity clay to silt mixture ML-SM Sandy silt to silty sand mixture CL-SC Sandy day to clayey sand mixture SCSM aayey sand to silty sand mixture SW Well graded sand; gravelly sand. little or no fines I I v 'l J .. . .. . ... . .. . ... . 10 I J.,. ~: '.'-.J ' ~.^-....~ ) \). ( 0' I I 15 !I 6 2~ ~ ~~ il !20 0 0 . _ D - '\ ' I... - I 'I \'" < 'll'l- il ~-- 'I !I - - SP Poorly graded sandi gravelly sand, little or no finel Silty sand; poorly graded sand.ilt mixture SM sc OW OP OM OC Oaycy sand: poorly graded sand.day mixtu... Wen graded gravel: gravel-cand mixtu....lillle or no fines Poorly graded gravel: gravel-cand mixtu.... liltle or no r.... Silty gravel: gravel-cand-<ill mixtu... Clayey gravel: gravel....d.day mixtu... Sandstone Siltstone Oaystone Breccia (angular gravel and cobbles or matrix~pported conpomerate) Conglomerale (rounded gravel and cobble, cla5l-oupported) Igneous granitic or granitic type rock Metavolcanic or metamorphic rock Artificial or man.made fill Asphaltic concrete Portland Cement Concrete :1 5Q5A( ll/n) LEIGHTON & ASSOCIATES ~\ ~I )1 ~. I I '. . I I I I I il il il il il I I GEOTECHNICAL BORING LOG B-1 Daie Project Drilling Co. Hole Diameter EIeyation Top of Hole 11-20-95 8 In. + /- 1,122 ft. Kennedy Properties Bal'JlOS DrlllInll Service Drive Weight Ref. or Datum Sheet -L Project No. Type of Rig of-L 4950364-001 Hollow-Stem Aauer Drop 30 in. 140 DOnnds mean sea level . :II ~ '~ C 0 +- +- Q,I':-: '" . GEOTECHNICAL DESCRIPTION 0" s:" 0 z ..0 - I..~ "'rn .-+- '" ....... "'.. .. . .... ++- S:lll GI 01 :00 c.... -u ~: 0.01 0.0 +- 0lJ.. 010 "tic u. 01 ..oJ 0 co. ,2j.... 0. -I.. ._01 _rn !v I.. Z ccOl ~ 0" Logged By KAB ' ~ CD E :II E:c -::i .. a.. 111 rn I.. 0 o~ Sampled By KAB c u rn 0 8M ARTIFICIAL FlU. ',' - @O': Brown, dry, medium dense, silty fine to coarse SAND - , ' 1 42 112.5 4.2 - :e-: ' ' -&.1- -OUATERNARYMf.~UM---------------------- , "" 2 36 104.7 4.0 @4'; Brown liilty fine to medium SAND; slightly damp, medium dense, slighly 5- porous , . , . - ',' 3 19 111.4 3.2 @ 6': Tan, slightly damp, loo6c, medium to COlIIIC SAND '- , . , - ',' 4 11 106.1 3.4 @ 8': As at 6 feet , -:- '.' ' . 10- '. , 5 16 117.5 7.1 @ 10': Tan, damp, loo6c, medium to COlIIIC SAND with scattered pebbles '- , , , . - " . . '. -'- ' . , . L~ '. % 6 34 123.2 113 SM/SC @ 15': Tan to olive-gay, damp, medium de...; sUghtly clayey, fme to COlIIIC - ~ SAND with scattered ~Ic-Qzed clasts ~ @ 15.5': Dtiller Iq'Orl..U tly tighter drilling - - ~ - ~ /.,' ,20 :~ . 7 30 107.5 6,0 8M @ 20': Light tan, damp 10 moist, medium dense, silty fme to COlIIIC SAND - Total Depth c 21 Feet No Ground Water Encountered at TJDlc of Drilling - Backfilled on November 20, 1995 - ,25- - - - - 505A(1"n) LEIGHTON & ASSOCIATES ~'J.,. I Date Project Drilling .Ql. Hole Diameter Elevation Top of Hole I I I I I I I I I I I I il il il il il il 505A(11/77) 11.20-95 GEOTECHNICAL BORING LOG B-2 " 01'." J:~: U :;:+- , +- Q,I; J:lll ..Ill !.:'!' 0.0 >11I .....J ~~ r.. ,~ (!) LIJ . o , '. '- : - ' - ':. '-::::.. 5- '- '. - -: : ,-:' -::. . 10-: : -: :.:.. -. _:: : -:: : '. lS-: :.: -: :': ,-: '. -:: : '. ~: : 20--;--::: . . . '. '-.:.: .:. : -:;. . -: -: lS-:,,: :.. - - ... - 8 in. +/- .. III .... o z . o Z III 0. e .. UI 1 ,Bag-2 @4'-6' Kennedy Properties Bal'llOS DrllliDl! Service Drive Weight ft. Ref. or Datum Sheet ---L- Project No. Type of Rig 140 Dounds mean sea level of-L 49S031iWOl HoUow-Stem Aauer Drop 30 in. :Jl " ,,;" .... .... 1lIl': .- .. . ..0 .." r..~ ..II! ,,0 "0+- ".... -u 0"- IlIU -:;;" u . -r.. co. ._11I _U1 "'Ill ~ 0.... a. :Jl E:" -::i r.. 0 rll~ c u SM GEOTECHNICAL DESCRIPTION Logged By Sampled By KAB KAB ARTIF'lr.IAL FIll. @ 0': Tan, dry. tOO6C, medium to coarse SAND with scattered construction debris n t05.9 9.5 - SM - -OUAWRNARY-Aii:ti\iiUM - -- -- - - - - - - - - - - -- -- - -- @ 3': Light brown to tan, damp, medium densej slightly clayey, silty rme SAND 3 20 113.5 10.6 4 lS 105.9 5.2 5 21 106.7 7.9 6 16 107.8 6.8 7 28 111.4 7.1 8 @ 6': Ught blOMl to tan, damp, medium dc.... s1igbtly clayey, silty fme SAND @ 9': Tan, damp, medium dense, fine to coarse SANDj slightly silty @ 12': As at 9 feet; moi&:t to wet @ 12': Tan, medium 10 coarse SAND @ 20': As aIlS reel 18 61.4 66.1 ML @lS': UghtblOMl,moist,61ilf,sligbllyclayeySlLT @ 28': Slightly looser drilling tq><>rled LEIGHTON & ASSOCIATES ~ I 'I I I I I I I I I I I I I I I I I I GEOTECHNICAL BORING LOG B-2 Date Project Drilling Co. Hole Diameter Elevation Top of Hole 11.20-95 8 in. +/- Kennedy Properties BaI'Re5 DrillinR Service Drive Weight ft. Ref or Datum Sheet -----L- Project No. Type of Rig of -----L- 495OJ6.W01 Holiow-Stem ARuer Drop 30 in. :l\ ~ ,j,~ C 0 .... .... mX GEOTECHNICAL DESCRIPTION o~ 0 .- "' " i.c:~ "' z ",0 "'~ t.~ ..~ :;:+- !~lU .clll ClI ClI :>0 c... ".... -u ..W ll.0 .... OLL ClIO ....c u " >ClI :(UG.I ....J 0 - Cll. "'ClI ll. -t. _fIl .!~ :C,~ t. z lllCll ~ .-.... Logged By KAB (!) E :l\ Oc ._~ lI.I .. 0.. t. :1:0 cll~ fIl C u Sampled By KAB ,. 30 9 50/4" 116.8 21.8 ML OUArnRNARY AU~lMUM fC..ontinued) - @ 30': Light brown, damp, dense to very dense, SILT - - @ 33': Looser drilling rq>ortcd - 135- . - I - @ 37': Tight drilling rq>ortcd . . - - . 40- 10 50/4" 109.0 16.7 ML @ 40': Brown, damp, dense to very dense, slightly clayey SILT - Total Depth = 41 Feet No Ground Water Encountered at TlMC of Drilling Backfilled on November 20, 1995 - - 45- - - - - '50- - - - - 55- ,- - ,- - 140 BOunds mean sea level 505A(11/n) LEIGHTON & ASSOCIATES '2A I 'I I I I I I I I I I I I GEOTECHNICAL BORING LOG B-3 Date Project Dri1lingCo. Hole Diameter Elevation Top of Hole 11-20-95 81D. +/- 1.124 Kennedy Properties BaI'ROS DriiiinK Service Drive Weight Ref. or Datum Sheet ---1..-. Project No. Type of Rig of ---1..-. 4950364-001 Hoiiow-Stem A2uer Drop 30 in. I I I I I ~. . ;,l ^ v. " c: 0 +- +- cuX GEOTECHNICAL DESCRIPTION .~':'\ U .- "' . ,~~ "' z ",0 ",,, LV .."! +-+- ; +i cu .c0l II II ;)0 C:'" ::l+- -u ..II a. II a.o +- ou. IIU tic: u . >11 II... .....J 0 a. -L ea. ._11 Ul !:t ,q"" L Z e 1011 v o+- - Logged By KAB l!l ;,l .-::i ILl .. 0. L E:C: Ul 0 ell v Sampled By KAB e u 0 8M ARTIFICIAL FlU. ',' -' ..' @ 0': Tan, dry, loose, medium to coarse SAND witb scattered debris " - @ 2': Brown, dry, medium dense, silty fme to coarse SAND 1 24 112.9 2.7 - ' , ' - : :,: ' ' 2 24 108.8 2,6 @4': Brown, damp, medium dense, fme to medium SAND , S ,~ -sM'- -OifArnRNARY-Al.f.tMtlM - - - - - - - - - - - - - - - - - - - - -- ',' - ' , ' " , 3 15 lOS.9 4.0 @ 6': Tan, damp, loose, silty, medium to coarse SAND - :-: , ' - :: : 4 16 lOS.0 2.8 @ 8': As at 6 reet . - ',' i 1,10-': :.: ' ' S 20 107.4 2.7 @ 10': As at 8 reet; slightly silty medium to coa.... SAND ! -. ': , '. _: :,: ' ' . . - ".' ! " _: :.: ' ' , ',' 15-: :': ' ' 6 36 107.1 6.9 @ 1S': TaD, slightly damp, medium dense, silty fine to coarse SAND . _: :,: . ! -: :': '. '. . -: :-: ' ' . ',' -: :': 120-: :: '. 7 29 112.5 18.2 @20': Ol.ive-gray, damp, medium dense, silty fine SAND - Total Deptb = 21 Feet No Ground Water Encountered at Tune of Drilling - BacldUlcd on November 20, 1995 - 25- - - - - ft 140 PODnds mean sea level 505A(111771 LEIGHTON & ASSOCIATES t:S I I I I I I I I I I I I I I I I I I I 5051.<11/77> GEOTECHNICAL BORING LOG B-4 Date Project Drilling Co. Hole Diameter Elevation Top of Hole 11-20-95 8 in. +/- 1,124 ft. Kennedy Properties Bal1le8 Drillinl( Service Drive Weight Ref. or Datum Sheet -L Project No. Type of Rig of-L 49S0364-OO1 HoIlow-Stem Aauer Drop 30 in. :1\ ~ .~ C 0 .... .... Qlx '" . GEOTECHNICAL DESCRIPTION o~ .t:.~ U Z ",0 .- l..~ "'Ill :;:+- '" "'~ ".... III . ........ .t:.0l QI QI 30 C'" -u IlIll1 IiCU 0.0 .... OlL QlU tic u . >llI QIQI IlI...J 0 - co. 0. -l.. .-QI _Ill .!:t c'" l.. Z lDQI ~ 0.... Logged By KAB ,~ t!) E :1\ '-:i III c.. E:c LU III l.. 0 rll~ c u Sampled By KAB 0 SM ARTIFICIAl. Fill. -: @ 0': Tllll, dl}', Ioooe, silty fme to coarse SAND with scattered construction deb.. -: :. ',". -:: : 1 34 122.1 11.1 @3': Dark brown, damp, medium dense, silty fme to coarse SAND -: '-:.'.: ',' . 5-': :.: , -: .' . 2 22 120.1 14.5 @ 6': As at Heel _: . . - :-:- -S"M- ()UATRR~RyAill~I]M---------------------- . -' :. '. , 3 37 116.9 12.1 @ 9': Light to medium brown, mottled, damp, medium dense, silty fme SAND 10- : .' . -:. : . -: ,'. . . :':',-: 4 46 117.3 9.4 SM @ 12': Light brown to brown, damp, medium dense, silty fine SAND - ,'. . . -: 15-: . " ,'. . 5 46 116.1 11.2 @ 15': As al12 fee~ fine to medium SAND . -: . - .:: . @17': Loooc: drilling rq><loed -' :':',": '. - : '. 20- : ' " :':':": 6 16 99.8 18.0 @ 20': OIiYc-gray 10 Ughl gray, damp, Ioooe, silty fine SAND , " - Total Depth = 21 Feel No Ground Waler Encountered al Tune of Drilling - Backftlled on November 20, 1995 - ,25- - - - - , 140 BOunds mean sea level LEIGHTON & ASSOCIATES '2Jp I I I I. I I I I I I I I I I I I I I "I GEOTECHNICAL BORING LOG B-5 Date Project Drilling Co. Hole Diameter Elevation Top of Hole 11.20.95 8 in. +/- 1,120 Kennedy Properties BarRes DrilliDR: Service Drive Weight ft. Ref. or Datum Sheet -----1- Project No. Type of Rig of -----1- 49503~1 HolIow-Stem As!ner Drop 30 in. 140 ponnds mean sea level ci :ll " '" <= -+- -+- cu~ '" . GEOTECHNICAL DESCRIPTION 0" ;.(~ 0 z ,"0 .- l.~ '"Ul :;+- .- '" ,"" "-+- .. . ,+: cu J:lll .. .. ;:)0 <=... -u .... 0... 0.0 -+- 0"- ..0 'ti<= u . >01 ..... ....J 0 0. -l. co. .-.. _Ul .!0 c~ l. z e lO.. ~ o-+- Logged By KAB '" .. a.. :ll >:<= '-::i lIJ Ul l. 0 cll~ Sampled By KAB c u 0 8M ARTIFICIAL FlU. : -: @O': Brown, dry, lOO6C, silty. fme to coarse SAND " - t 76 127.t 5.9 @2': Dark brown, damp, dense, silty rille SAND " - : Bag-2 @3'-4' - " : 3 62 127.0 8.9 @4': As at 2 feet medium dense 5- : - ....:: :~. 4 15 t13.5 7.1 -S~r OUA~~IDMRYML~UM---------------------- - : @6': Tan, damp, loose to medium dense, silty fine SAND - : '. 5 46 t09.0 7.6 @8': As al 6 feel -: 10- : 6 27 ltS.8 5.2 @10': Ughl brown to lighl gray al top, medium dense, silty fine SAND '. -: '. -: . -. @13': Driller rqx>rts Ioo6er malcrial -: : : 15-' '. 7 27 t06.9 t2.3 @15': Tan, damp, medium dense, silty fme to coarse SAND : -: '. -: : -: '. -: : : , 20~: . '. 8 22 N.R. @20': Olive-gray, damp, medium dense, silty fine SAND - Total Depth = 21 Feel No Ground Water Encountered at TIme of Drilling . - Backfilled on November 20, 1995 , - . '15- - - - - SOSAf t1/n) LEIGHTON & ASSOCIATES 2-1 I I I I I I I I I I I I I I I I I I I 11950364-001 APPENDIX C Laboratorv Testinl! Procedures and Test Results I Consolidation Tests: Consolidation tests were performed on selected, relatively undisturbed ring , samples. Samples were, placed in a consolidometer and loads were applied in geometric progression. , The percent consolidation for each load cycle was recorded as the ratio of the amount of vertical , compression to the original 1-inch height. The consolidation pressure curves are presented in the I test data. I Expansion IndexTests:, The expansion potential of selected materials was evaluated by the Expansion I Index Test, U.B.C. Standard No. 18-2. Specimens are molded under a given compactive energy to ,approximately the optimum moisture content and approximately 50 percent saturation or I approximately 90, percent relative compaction. The prepared 1-inch thick by 4-inch diameter ; specimens are loaded to an equivalent 144 psf surcharge and are inundated with tap water until , volumetric equilibrium is reached. The results of these tests are presented in the table below: . Sample Location Compacted Dry Expansion Expansion Sample Description Density (pet) Index Potential ! B-5, 3'-4' SM 108.2 34 Luw : Moisture and Density Determination Tests: Moisture content and dry density determinations were 'performed on relatively undisturbed samples obtained from the test borings. The results of these : tests are presented in the boring logs. Where applicable, only moisture content was determined from '"undisturbed" or disturbed samples. C-2 Z~ I I I I I I I I I I I I I I I I I I I o ~ 1 "'-. ~ "- "" ~ '" 'I 10 2 3 4 5 6 7 8 9 10 11 12 0.1 VERTICAL STRESS (ksf) Test Method: ASTM 02435-90 . Before Adding Water . After Adding Water Boring No. Sample No. Depth (feet) Soli Type B-1 3 6.0 SM Dry Density (pet) 108.4 Moisture Content (%): Before 3.2 After 15.2 Type of Sample Undisturbed CONSOLIDATION - PRESSURIE CURVE - ProJect No. 4950364-001 ProJect Name KennedY ProDertles Date 12/26/95 Figure No. ~ m[TI z.q I I I !I I I I I II I I I I I I I I I I o - -- i'1 ') ""~ '" ~ " 't 2 3 4 5 6 7 8 9 10 11 12 0.1 10 VERTICAL STRESS (ksf) Test Method: ASTM 02435-90 . Before Adding Water . After Adding Water Boring No. Sample No. Depth (feet) Soli Type B-1 4 8.0 SM Dry Density (pel) 104.2 Moisture Content (%): Before 3.4 After 18.4 Type of Sample Undisturbed CONSOLIDATION - PRESSURE CURVE - Project No, 4950384-001 Project Name KennedY ProDertles _ Date 12/26/95 Figure No. ~_ CfJ[TI '!P I II I I I I I I I I I I I I I I I I I o -- --- ---.... ~ " ~ " 'I 2 3 4 5 6 7 8 9 10 11 12 0,1 10 VERTICAL STRESS (ksf) Test Method: ASTM 02435-90 . Before Adding Water . After Adding Water Boring No. Sample No. Depth (feet) Sol/Type B-2 1 3.0 SM Dry Density (pel) 106,8 Moisture Content (%): Before 9,5 After 19.3 Type of Sample Undisturbed CONSOLIDATION - PRESSURE CURVE - Project No, 4950364-001 Project Name Kennedv ProDerties Date 12/26/95 Figure No. ~ [fjITJ 1J\ I I I I I I I I I I I I I I I I I I I I o ~ ~ " "" - 2 3 4 5 6 7 8 9 10 11 12 0.1 10 VERTICAL STRESS (ksf) Test Method: ASTM 02435-90 . Before Adding Water . After Adding Water Boring No. Sample No. Depth (feet) Soil Type B-2 6 15.0 SM Dry Density (pel) 99.7 Moisture Content (%): Before 6.6 After 20.6 Type of Sample Undisturbed CONSOLIDATION - PRESSURE CURVE - Project No. 4950364-001 Project Name KennedY Properties Date 12/26/95 Figure No. ....!...- mDJ 31- I I I I I I I I I I I I I I I I I I I o 1 I ~ -....... ~ "- 'I 2 3 4 5 6 7 8 9 10 11 12 0.1 10 VERTICAL STRESS (ksf) Test Method: ASTM 02435-90 . Before Adding Water . After Adding Water Boring No. Sample No. Depth (feet) Soil Type B-2 8 25,0 ML Dry Density (pel) 60.4 Moisture Content (%): Before 86.1 After 70.0 Type of Sample Undisturbed CONSOLIDATION - PRESSURE CURVE - Project No. 4950364-001 Project Name Kennedv Properties Date 12/26/95 Figure No, ~ []fj[I] JP I ..... ~ ~ " ~ '. I : I I I I I I I I I I I I I I I I I I o 2 3 4 5 6 7 8 9 10 11 12 0.1 10 VERTICAL STRESS (ksf) Test Method: ASTM 02435-90 . Before Adding Water . After Adding Water Boring No. Sample No. Depth (feet) Soil Type Type of Sample CONSOLIDATION - PRESSURE CURVE - 8-3 3 6.0 8M Dry Density (pel) 105.0 Moisture Content <%): Before 4.0 After 19.1 Undisturbed Project No. 4950364-001 Project Name KennedY ProDertles Date 12/26/95 Figure No. -"-- mITJ '3A I i I I I I I I I I I I I I I I I I I I 1 ... "- "- "t \, \ 1\ \ \ 1\ 1\ o 2 3 4 5 6 7 8 9 10 11 12 0.1 10 1 VERTICAL STRESS (ksf) Test Method: ASTM 02435-90 . Before Adding Water . After Adding Water Boring No. Sample No. Depth (feet) Soli Type B-4 6 20.0 8M Dry Density (pet) 109,6 Moisture Content (%): Before 12. 7 After 15.2 Type of Sample Undisturbed CONSOLIDATION - PRES.SURE CURVE - Project No. 4950364-001 Project Name Kennedv ProDertles Date 12/26/95 Figure No, ..2-- [fjOJ ~ I I I I I I I I I I I I I I I I I I I LEIGHTON AND ASSOCIATES, INC. GENERAL EARTHWORK AND GRADING SPECIFICATIONS FOR ROUGH GRADING 1.0 General 1.1 Intent: These General Earthwork and Grading Specifications are for the grading and earthwork shown on the approved grading plan(s) and/or indicated in the geotechnical report( s). These Specifications are a part of the recommendations contained in the geotechnical report(s). In case of conflict, the specific recommendations in the geotechnical report shall supersede these more general Specifications. Observations of the earthwork by the project Geotechnical Consultant during the course of grading may result in new or revised recommendations that could supersede these specifications or the recommendations in the geotechnical report( s). 1.2 'The Geotechnical Consultant of Record: Prior to commencement of work, the owner shall employ the Geotechnical Consultant of Record (Geotechnical Consultant). The Geotechnical Consultants shall be responsible for reviewing the approved geotechnical report(s) and accepting the adequacy of the preliminary geotechnical findings, conclusions, and recommendations prior to the commencement of the grading. Prior to commencement of grading, the Geotechnical Consultant shall review the "work plan" prepared by the Earthwork Contractor (Contractor) and schedule sufficient personnel to perform the appropriate level of observation, mapping, and compaction testing. During the grading and earthwork operations, the Geotechnical Consultant shall observe, map, and document the subsurface exposures to verify the geotechnical design assumptions. If the observed conditions are found to be significantly different than the interpreted assumptions during the design phase, the Geotechnical Consultant shall inform the owner, recommend appropriate changes in design to accommodate the observed conditions, and notify the review agency where required. Subsurface areas to be geotechnically observed, mapped, elevations recorded, and/or tested include natural ground after it has been cleared for receiving fill but before fill is placed, bottoms of all "remedial removal" areas, all key bottoms, and benches made on sloping ground to receive fill. The Geotechnical Consultant shall observe the moisture-conditioning and processing of the subgrade and fill materials and perform relative compaction testing of fill to determine the attained level of compaction. The Geotechnical Consultant shall provide the test results to the owner and the Contractor on a routine and frequent basis. 1.3 The Earthwork Contractor: The Earthwork Contractor (Contractor) shall be qualified, experienced, and knowledgeable in earthwork logistics, preparation and processing of ground to receive fill, moisture-conditioning and processing of fill, and compacting fill. The Contractor shall review and accept the plans, geotechnical report(s), and these Specifications prior to commencement of grading. The ,3030.1QSi4 3~ ~ I I I I I I I I I I I I I I I I I I I I:.eighton and Associates, Inc. GENERAL EARTHWORK AND GRADING SPECIFICATIONS Page 2 of 6 Contractor shall be solely responsible for performing the grading in accordance with the plans and specifications. The Contractor shall prepare and submit to the owner and the Geotechnical Consultant a work plan that indicates the sequence of earthwork grading, the number of "spreads" of work and the estimated quantities of daily earthwork contemplated for the site prior to commencement of grading. The Contractor shall inform the owner and the Geotechnical Consultant of changes in work schedules and updates to the work plan at least 24 hours in advance of such changes so that appropriate observations and tests can be planned and accomplished. The Contractor shall not assume, that the Geotechnical Consultant is aware of all grading operations. The Contractor shall have the sole responsibility to provide adequate equipment and methods to accomplish the earthwork in accordance with the applicable grading codes and agency ordinances, these Specifications, and the recommendations in the approved geotechnical report( s) and grading plan( s). If, in the opinion of the Geotechnical Consultant, unsatisfactory conditions, such as unsuitable soil, improper moisture condition, inadequate compaction, insufficient buttress key size, adverse weather, etc., are resulting in a quality of work less than required in these specifications, the Geotechnical Consultant shall reject the work and may recommend to the owner that construction be stopped until the conditions are rectified. ,2.0 Prenaration of Areas to be Filled 2.1 C1earinl! and Grubbing: Vegetation, such as brush, grass, roots, and other deleterious material shall be sufficiently removed and properly disposed of in a method acceptable to the owner, governing agencies, and the Geotechnical Consultant. The Geotechnical Consultant shall evaluate the extent of these removals depending on specific site conditions. Earth fill material shall not contain more than 1 percent of organic materials (by volume). No fill lift shall contain more than 5 percent of organic matter. Nesting of the organic materials shall not be allowed. If potentially hazardous materials are encountered, the Contractor shall stop work in the affected area, and a hazardous material specialist shall be informed immediately for proper evaluation and handling of these materials prior to continuing to work in that area As presently defined by the State of California, most refined petroleum products (gasoline, diesel fuel, motor oil, grease, coolant, etc.) have chemical constituents that are considered to be hazardous waste. As such, the indiscriminate dumping or spillage of these fluids onto the ground may constitute a misdemeanor, punishable by fines and/or imprisonment, and shall not be allowed. 13030.1094 ~\ I I I I I I I I I I I I I I : I , i i. I I I }~ I I I I I I I I I I I I I I I I I I I Leighton and Associates, Inc. GENERAL EARTIlWORK AND GRADING SPECIFICATIONS Page 3 of 6 2.2 Processin~: Existing ground that has been declared satisfactory for support of fill by the Geotechnical Consultant shall be scarified to a minimum depth of 6 inches. Existing ground that is not satisfactory shall be overexcavated as specified in the following section. Scarification shall continue until soils are broken down and free of large clay lumps or clods and the working surface is reasonably uniform, flat, and free of uneven features that would inhibit uniform compaction. 2.3 Overexcavation: In addition to removals and overexcavations recommended in the approved geotechnical report(s) and the grading plan, soft, loose, dry, saturated, spongy, organic-rich, highly fractured or otherwise unsuitable ground shall be overexcavated to competent ground as evaluated by the Geotechnical Consultant during grading. 2.4 Benchinl!: Where fills are to be placed on ground with slopes steeper than 5:1 (horizontal to vertical units), the ground shall be stepped or benched. Please see the Standard Details for a graphic illustration. The lowest bench or key shall be a minimum of 15 feet wide and at least 2 feet deep, into competent material as evaluatlold by the Geotechnical Consultant. Other benches shall be excavated a minimum height of 4 feet into competent material or as otherwise recommended by the Geotechnical Consultant. Fill placed on ground sloping flatter than 5:1 shall also be benched or otherwise overexcavated to provide a flat subgrade for the filL 2.5 Evaluation/Acceptance of Fill Areas: All areas to receive fill, including removal and processed areas, key bottoms, and benches, shall be observed, mapped, elevations recorded, and/or tested prior to being accepted by the Geotechnical Consultant as suitable to receive fill. The Contractor shall obtain a written acceptance from the Geotechnical Consultant prior to fill placement. A licensed surveyor shall provide the survey control for determining elevations of processed areas, keys, and benches. , 3.0 Fill Material 3.1 General: Material to be used as fill shall be essentially free of organic matter and other deleterious substances evaluated and accepted by the Geotechnical Consultant prior to placement. Soils of poor quality, such as those with unacceptable gradation, high expansion potential, or low strength shall be placed in areas acceptable to the Geotechnical Consultant or mixed with other soils to achieve satisfactory fill material 3.2 Oversize: Oversize material defmed as rock, or other irreducible material with a maximum dimension greater than 8 inches, shall not be buried or placed in fill unless location, materials, and placement methods are specifically accepted by the Geotechnical Consultant. Placement operations shall be such that nesting of oversized material does not occur and such that oversize material is completely surrounded by compacted or densified filL Oversize material shall not be placed within 10 vertical feet of finish grade or within 2 feet of future utilities or underground construction. !3030.10';l4 ~" I I I I I I I I I I I I I I I I I I I Leighton and Associates, Inc. GENERAL EARTIIWORK AND GRADING SPECIFICATIONS Page 4 of 6 3.3 Imoort: If importing of fill material is required for grading, proposed import material shall meet the requirements of Section 3.1. The potential import source shall be given to the Geotechnical Consultant at least 48 hours (2 working days) before importing begins so that its suitability can be determined and appropriate tests performed. 4.0 Fill Placement and Compaction 4.1 Hill Lavers: Approved fill material shall be placed in areas prepared to receive fill (per Section 3.0) in near-horizontal layers not exceeding 8 inches in loose thickness. The Geotechnical Consultant may accept thicker layers if testing indicates the grading procedures can adequately compact the thicker layers. Each layer shall be spread evenly and mixed thoroughly to attain relative uniformity of material and moisture throughout. 4.2 Hill Moisture Conditiouinl!: Fill soils shall be watered, dried back, blended, and/or mixed, as necessary to attain a relatively uniform moisture content at or slightly over optimum. Maximum density and optimum soil moisture content tests shall be performed in accordance with the American Society of Testing and Materials (ASTM Test Method D1557-91). 4.3 GomDaction of Fill: After each layer has been moisture-conditioned, mixed, and evenly spread, it shall be uniformly compacted to not less than 90 percent of maximum dry density (ASTM Test Method 01557-91). Compaction equipment shall be adequately sized and be either specifically designed for soil compaction or of proven reliability to efficiently achieve the specified level of compaction with uniformity. 4.4 GomDaction of Fill Slooes: In addition to normal compaction procedures specified above, compaction of slopes shall be accomplished by backrolling of slopes with sheepsfoot rollers at increments of 3 to 4 feet in fill elevation, or by other methods producing satisfactory results acceptable to the Geotechnical Consultant. Upon completion of grading, relative compaction of the fill, out to the slope face, shall be at least 90 percent of maximum density per ASTM Test Method 01557-91. 4.5 GomDaction Testin~: Field tests for moisture content and relative compaction of the fill soils, shall be performed by the Geotechnical Consultant. Location and frequency of tests shall be at the Consultant's discretion based on field conditions encountered. Gompaction test locations will not necessarily be selected on a random basis. Test locations shall be selected to verify adequacy of compaction levels in areas that are judged to be prone to inadequate compaction (such as close to slope faces and at the fill!bedrock benches). 3QlO.l094 A,o I I I I I I I I I I II I I I I I I I I Leighton and A&sociates, Ine. GENERAL EARTIlWORK AND GRADING SPECIFICATIONS Page 5 of 6 4.6 FreQuencv of ComDaction Testing: Tests shall be taken at intervals not exceeding 2 feet in vertical rise and/or 1,000 cubic yards of compacted fill soils embankment. In addition, as a guideline, at least one test shall be taken on slope faces for each 5,000 square feet of slope face and/or each 10 feet of vertical height of slope. The Contractor shall assure that fill construction is such that the testing schedule can be accomplished by the Geotechnical Consultant. The Contractor shall stop or slow down the earthwork construction if these minimum standards are not met. 4.7 Compaction Test Locations: The Geotechnical Consultant shall document the approximate elevation and horizontal coordinates of each test location. The Contractor shall coordinate with the project surveyor to assure that sufficient grade stakes are established so that the Geotechnical Consultant can determine the test locations with sufficient accuracy. At a minimum, two grade stakes within a horizontal distance of 100 feet and vertically less than 5 feet apart from potential test locations shall be provided. . 5.0 Subdrain, Installation Subdrain I systems shall be installed in accordance with the approved geotechnical report( s), the grading plan, and the Standard Details. The Geotechnical Consultant may recommend additional subdrains and/or changes in subdrain extent, location, grade, or material depending on conditions encountered during grading. All subdrains shall be surveyed by a land surveyor/civil engineer for line and grade after installation and prior to burial Sufficient time should be allowed by the Contractor for these surveys. .6.0 Excavation Excavations, as. well as over-excavation for remedial purposes, shall be evaluated by the Geotechnical Cpnsultant during grading. Remedial removal depths shown on geotechnical plans are estimates only. The actual extent of removal shall be determined by the Geotechnical Consultant based on the field evaluation of exposed conditions during grading. Where fiIl-over ,.cut slopes are to be graded, the cut portion of the slope shall be made, evaluated, and accepted by the Geotechnical Consnltant prior to placement of materials for construction of the fill portion of the slope, unless otherwise recommended by the Geotechnical Consultant. 7.0 Trench Backfills 7.1 The Contractor shall follow all OHSA and Cal/OSHA requirements for safety of trench excavations. 30J0.1194 ~\ I I I I I I I I I I I I I I I I I I I Leighton and Associates, Inc. GENERAL EARTIfWORK AND GRADING SPECIFlCATIONS Page 6 of 6 7,2 All bedding ,and backfill of utility trenches shall be done in accordance with the applicable provisions of Standard Specifications of Public Works Construction. Bedding material shall have a Sand Equivalent greater than 30 (SE>30). The bedding shall be placed to 1 foot over the top of the conduit and densified by jetting. BackfiII shall be placed and densified to a minimum of 90 percent of maximum from 1 foot above the top of the conduit to the surface. 7.3 The jetting of the bedding around the conduits shall be observed by the Geotechnical Consultant. 7.4 The Geotechnical Consultant shall test the trench backfill for relative compaction. At least one test should be made for every 300 feet of trench and 2 feet of filL 7.5 Lift thickness of trench backfill shall not exceed those allowed in the Standard Specifications of Public Works Construction unless the Contractor can demonstrate to the Geotechnical Consultant that the fill lift can be compacted to the minimum relative compaction by his alternative equipment and method. JQlO.I094 A,t-- I I I I I I I I I I I I I I I I I I I REMOVE UNSUITABlE MATERIAL BENCH HEIGHT IIENCHIIG BHALI. BE DONE WHEN SLOPES ANGLE IS EQUAL TO OR OREAlER THAN 5:1 MINIMUM BENCH HEIOHT BHALI. BE 4 FEET MINIMUM F1l.L WImI BHALI. BE 8 FEET NATURAL GROUND 4' TYPICAL BENCH LBENCH HEIGHT 2' MIN. KEY DEPTH ~ MIN.-;-- 1--'5~ MIN.---1 LOWEST BENCH (KEY) -- - NATURAL GROUND ~ - --- --- -'2% MIN._- 1--'8' MIN. ~ LOWEST BENc;:j! Z'MIN. KEY DEPTH ~ CUT fACE BHALI. BE CONSTJ:lUClB) PRIOR TO FU PlACEMENT TO ASSURE ADEQUATE 0E0L00lC CONDlTIONS CUT FACE TO BE CONSTRUCTED PRIOR ./' TO AU. PlACEMENT ,/" ,/" ,/ PROJECTED PLANE lTO 1 ,MAxIMUM FROM Toe OF SLOPE TO APPROIIED OAOUNO Z'MIN. KEY DEPTH ~, FlU SLOPE REMOVE UNSUITABLE MATERIAL FIU-oVER-CUT SLOPE ~ CUT -oVER-FIU SLOPE For Subdrains See Standard Detail C A?? KEYING ,AND BENCHING GENERAL EARTHWORK AND GRADING m[I]!, SPECIFICAnONS U STANDARD DETAILS A 4185 I I I I I I I ,I il ! I : I , , I I I I I I I I - FINISH GRADE --------- -------------------. --------- -------------------- ---------- -------------------. _~-==_==-=-=~~-=-::iO'-M1N.::::-=-::::COMPACTED-Fiu::::-::=-~ SLOPE _-..=__-_-_-_-_-_-__::...-_-_-_-~-------------..=-----------------_-__::...-: FACE _-_-_-_-_--=-_-_-_-_-_-_-_--=-_- ----------::...-:...-------------------------: ---:::-=-=~-=-=-'""2--EO-~-::::::::::-=-..=----n---------Q-----= ----:..-------::::::-::z:~-' ---------------- ------------------ ---:: _-_-:...;.:-:-:-:-:-:-r-_-:---___-:-:-:-:-:-:~-____-:-:-:~~-::~-:__-_-~. ---------------,r----------------..=------------------=-----------------------:..--- -------~-----U----------~------ -----------=-------n--------:..-------:. ------- _-=~~~:~==3=Z=:~===-..=---===:==~=--~-- =====~=~==l--::...-~==~====:=-- ------~- -------------A' MIN --~15' MIN ,- --..=-------:..-:-. , -----~..=- -------_-:..---------..=-_----~--_.:....-:..- ----_..:.-- -----. -~------------~-- ------- -----. =:-::::-:-:-:-:-==-LE-------::--' ~~::::==~~:- :: -===j::=:=====j::=====:====~~-:-- -------- ---- --------~- ------=-..=---..=-..=-..=--=---- ~====:~==-~-:-O=-V=E-=R-S=-IZE=-=~= =================:==================:::;-:-:::::---=- - - JETTED OR FLOODED =-=-==--::?~===::WINDROW' :..-=-=-=-=-=-=-=-=-=-:-=-:...,.-----...:::--- GRANULAR MATERIAL -------- .-------- o Oversize rock Is larger than 8 inches 'in largest dimension. o Excavate a trench in the compacted fill deep enough to, bury all the rock. o BackflII with granular $Oil jetted or flooded In place to fill all the voids. ., Do not bury rock, within 10 feet of finish grade. ., Wmdrow ct burled rock shall be paraJIeI to the linished,sIope fiR. ELEVATION A-A' PROFILE ALONG WINDROW _A - - _ -_ - - - .... JETTED OR FLOODED GRANULAR MATERIAL ~ OVERSIZE ROCK. DISPOSAL GENERAL EARTHWORK AND GRADING [l][I], SPECIFICATIONS ~ U STANDARD DETAILS B 4/1l5 II I I ,I I I I I I I I I I I I I I I I BENCHING NATURAL Y GROUND '" ~ - ~ - -------- ----------------- - ---'------------------------------ - .- - ---------------------------- - - . -: COMPACTED FILL :...----- --------- ~-:--------------------~--~--- --~~-------------------~-~~ - ---~-....-~--~:~==-===-=~:::"=::::"=:::~:-::~-7- - - .- ----------------- =-:-:-:s;;:-:-:-:-:::-:-::-:-:~~~:--:- ~ ~~ _ oo:~ cooQ .......... '\ \ \ REMOVE UNSUITABLE MATERIAL CALTRANS CLASS II PERMEABLE OR #2 ROCK (9FT.'IFT.) WRAPPED IN FILTER FABRIC FILTER FABRIC (MlRAFl14O OR.... . APPROVED '-COLLECTOR PIPE SHALl. EQUIVALENl) BE MINIMUM" DIAMETER SCHEDULE 40 PVC PERFORATED CANYON SUBDRAIN OUTLET DETAIL PIPE. SEE STANDARD DETAIL D FOR PIPE SPECIFICATION PERFORATED PIPE 6"+ MIN. ~20'iMIN.~ NON~ERFORATED 5' MIN. 6"+ MIN. FILTER FABRIC (MIRAFl140 OR APPROVED EQUIVALENT) DESIGN FINISHED GRADE #2 ROCK WRAPPED IN FILTER FABRIC OR CALTRANS ClASS II PERMEABLE. ",. b.",i> CANYON SUBDRAINS GENERAL EARTHWORK AND GRADING m[TI SPECIFICATIONS U STANDARD DETAILS C ~ I I I I I I I I , I I I II I I I I I I I I \15' MI~'I OUTlET PIPES 4'.' NON-PERFORATED PIPE, 100' MAX. O.C. HORIZONTAllY, 30' ,MAX. O,C. VERTICAllY ------------- - - -_-:...-----_-::...---=----:...-----;: / -- -----------~- \ --- ------------- ---- ---------- ---- ---------- ----- ---------- ~~,.. _-C-={~j&~-~~~~~~ ~/ \ ~ .--=------------=----=----~7:7:-:-:r: . -......... \ 2' ~IN, 1:-~-----1~,2:.:.IN.-~-~-1 / ~VER~ FROM THE TOP KEY WIDTH POSITIVE SEAL \HOG RING TIED EVERY 6 FEET SHOULD BE y:: \ PROVIDED AT \ FILlER FABRIC THE JO~ ./' -.: (MIRAFI140 OR S" At .. APPROVED OUTlET PIPE INi; EQUIVALENl) (NON.PERFORAlEDI----:.-;..... J \ T -CONNECTION FOR CALTRANS CLASS II COLlECTOR PIPE TO PERMEABLE OR #2 ROCK OUTlET PIPE (3FT.'IFT.) WRAPPED IN ' / FILlER FABRIC ~ .] SUBDRAlN INSTALlATION - Subdraln collector pipe shall be Installed with pedoratlons down or, , unless lllherwIse designated by the geotechnical consullanl. Outlet pipes shaft be non-perforated I pipe. The subdraIn pipe shaB have at Ieasl 8 perforations uniformly spaced per fool. Perforation shall I be W to W I drilled holes are used. All subdraln pipes shall have a gradient at 1easl2% towards the , outlet. ., SUBDRAlN PIPE - Subdraln pipe shall be ASTM 02751, SDR 23,5 or ASTM 01527, Schedule 40, or , ASTM D3034, SDR 23.5. Schedule 40 Polyvinyl Chloride Plastic (PVC) pipe. . , All 0UlIel pipe shall ~ placed In a trench no wider than twice the subdraln pipe. Pipe shall be in soli , 01 SE >30 jetted or flooded In place except for the outside 5 feet which shall be native soil backfill. * BUTIRESS OR REPLACEMENT FILL SUBDRAINS . GENERAL EARTHWORK AND GRADING m[IJi SPECIFICATIONS U STANDARD DETAILS D 4/Il!5 I :1 I 'I I I I I II I 'I I II I I I I I I I I CUT AND CUT-FILL LOT REMOVE UNSUITABLE GROUND -- ....... - ....... ....... - - -:::-':~':COMPACTiD-F1U.:--------2-~-----=---------- , .: ~ ---------~~-------_:.=-- " :::=~=~--J=----::::-=-=-=-=-=-=-7=~---=-:-= ..... -- ----- --~- ._--------~-- -=-------------~.:_----- / OVEREXCAVATION AND RECOMPACT UNWEATHERED BEDROCK OR ~ MATERIAl APPROVED BY ~ THE GEOTECHNICAl CONSULTANT SIDE HILL FILL FOR CUT PAD NATURAL _ - GROUND,) .- .- - .- - - .- .- ....... .- .- .- .- ....... ....... OVEREXCAVATE ......- AND RECOMPACT 7 ~ (REPLACEMENT FI ~_- -::-=-::-=-=-=-~=-- .... \ . . . . . . . . . . . . . . . . .. -- -----~ OVERBURDEN ------ ., ~-=-:;-- PAD OVEREXCAVATION AND OR UNSUITABLE _-_-=-_ --- _-==___-.......-.:_ -- RECOMPAC110N SHALl BE MATERIAL: PERFORMED IF SPECIFIED BY THE GEOTECHNICAL BENCHING CONSULTANT SEE STANDARD DETAIL FOR SUBDRAlN DETAIL WHEN REQUIRED BY GEOTECHNICAL CONSULTANT .- FINISHED CUT PAD II FEET MIN. UNWEATHERED BEDROCK OR ~ MATERIAl APPROVED BY THE ----.s-- GEOTECHNICAl CONSULTANT A.~ 'TRANSITION LOT FILLS AND SIDE HILL FILLS GENERAL EARTHWORK AND GRADING [fj[IJ SPECIFICATIONS U STANDARD DETAILS E 41'1I5 I I I I I I I I I I I I I I I I I ,I I RETAINING WALL DRAINAGE DETAIL RE'FAINING WALL WALL' WATERPROOFING PER ARCHITECT'S SPECIFICA TIONS FINISH GRADE SOIL BACKFILL, COMPACTED TO 90 PERCENT RELATIVE COMPACTlON* --- -~------ -------------- -- --------- ------------. --- -------- ------------ --- -------- ----------- iii~~iiiiiii ~l~l;I~:V -I 'oh"":1 -0.-0.-0.-_-0.-_-_""' o~.. ... ~ I :=-:::-:::-==::::" 106' MIN. c ~~~~~-=- FILTER FABRIC ENVELOPE OVERLAP ____" ( I' '0' :=-:=-:=-== MIRAFI 140N OR APPROVED , ____ EQUIV ALENT) ** o o 0 (I ---- 10 1: MIN. I 0 . . . ' I. 0 :0 ,0 I :f:f:f:f . . ---- o =_-:.: 3/4'-1-112' CLEAN GRA VEL ** 4',(MIN.) DIAMETER PERFORATED pvc PIPE (SCHEDULE 40 OR EQUIVALENT) WITH PERFORATIONS ORIENTED DOWN AS DEPICTED MINIMUM 1 PERCENT GRADIENT TO SUITABLE OUTLET -------- --------------------- ------------------------------ ------------------------------ ------------------------------ --':-::::f~~~~~~~f~~:~~~:I~J~~~~~~~ W ALL FOOTING m -= NOT TO SCALE SPECIFICATIONS:FOR CALTRANS :CLASS 2 PERMEABLE MATERIAL U.S. Standard Sieve Size % Passinq 1" 100 3/4" 90-100 3/8" 40-100 No.4 25-40 No. 8 18-33 No. 30 5-15 No. 50 0-7 No. 200 0-3 ,sand Equivalent>75 COMPETENT BEDROCK OR MATERIAL AS EVALUATED BY THE GEOTECHNICAL CONSULT ANT *BASED ON ASTM 01667 * * IF CAL TRANS CLASS 2 PERMEABLE MATERIAL (SEE GRADATION TO LEFT) IS USED IN PLACE OF 3/4'-1-1/2' GRAVEL, FILTER FABRIC MAY BE DELETED. CAL TRANS CLASS 2 PERMEABLE 1\0- MATERIAL SHOULD BE COMPACTED TO 90 "VJ PERCENT RELATIVE COMPACTION * NOTE:COMPOSITE DRAINAGE PRODUCTS SUCH AS WiRADRAIN OR J-DRAIN MAY BE USED AS AN ALTERNAllVE TO GRAVEL OR CLASS 2.INSTALLAllON SHOULD BE PERFORtJED IN ACCORDANCE WITH MANUFACTURER'S SPEClACAllONS.