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Home My WebLink About3843; El Camino Real Water Pipeline; El Camino Real Water Pipeline; 2002-09-16^B5H?== Leighton and Associates A GTG Company GEOTECHNICAL CONSULTANTS n m GEOTECHNICAL INVESTIGATION, PROPOSED EL CAMINO REAL WATER PIPELINE, CARLSBAD, CALIFORNIA September 16, 2002 Project No. 040752-001 Prepared For: KENNEDY JENKS & ASSOCIATES, INC. 16855 West Bernardo Drive, Suite 360 Encinitas, California 92024 3934 Murphy Canyon Road, #8205, San Diego, CA 92123-4425 (858) 292-8030 • FAX (858) 292-0771 • www.leightongeo.com =^ Leighton and Associates A GTG Company GEOTECHNICAL CONSULTANTS September 16,2002 Project No. 040752-001 To: Kennedy Jenks & Associates 16855 West Bernardo Drive, Suite 360 San Diego, California 92127 Attention: Mr. Ray Montoya Subject: Geotechnical Investigation, Proposed El Camino Real Water Pipeline, Carlsbad, California In accordance with your request and authorization, we have performed a geotechnical investigation for the proposed pipeline on El Camino Real between Cougar Drive and Faraday Avenue in Carlsbad, California. The accompanying report presents a summary of our investigation and provides conclusions and recommendations relative to the proposed. Based on the results of our investigation and review of the conceptual project plan prepared by the Kennedy Jenks & Associates (Kennedy Jenks, 2002), the proposed improvements are considered feasible from a geotechnical standpoint provided the recommendations outlined in this report are implemented during project design and construction. If you have any questions regarding our report, please contact this office. We appreciate this opportunity to be of service. Respectfully submitted, LEIGHTON AND ASSOCIATES, INC. William D. Olson, RCE 45283 Senior Project Engineer Distribution: (6) Addressee Michael R. Stewart, CEG 1349 VicePresident/PrincipalGeologist ENGINEERING GEOLOGIST 3934 Murphy Canyon Road, #B205, San Diego, CA 92123-4425 (858) 292-8030 • FAX (858) 292-0771 • www.leightongeo.com 040752-001 TABLE OF CONTENTS Section Page 1.0 INTRODUCTION 1 1.1 PURPOSE AND SCOPE 1 1.2 SITE DESCRIPTION 1 1.3 PROPOSED IMPROVEMENTS 3 2.0 SUBSURFACE EXPLORATION AND LABORATORY TESTING 4 2.1 SUBSURFACE EXPLORATION 4 2.2 LABORATORY TESTING 4 3.0 SUMMARY OF GEOLOGIC CONDITIONS 5 3.1 REGIONAL GEOLOGY 5 3.2 SITE-SPECIFIC GEOLOGY 5 3.2.1 Undocumented Artificial Fill (Afu) 5 3.2.2 Point Loma Formation (kp) 5 3.3 SURFACE AND GROUND WATER 6 3.4 SOIL COMPRESSIBILITY 6 3.5 EXPANSION POTENTIAL 6 3.6 GEOCHEMICALCONSIDERATIONS 6 4.0 FAULTING AND SEISMICITY 7 4.1 FAULTING 7 4.2 SEISMICITY 7 4.2.1 Lurching and Shallow Ground. 8 4.2.2 LiquefactionandDynamic Settlement 9 5.0 CONCLUSIONS 10 5.1 CONCLUSIONS 10 6.0 RECOMMENDATIONS 11 6.1 EARTHWORK 11 6.1.1 Site Preparation 11 6.1.2 Excavations and Shoring 11 6.1.3 Removals 72 6.1.4 Pipe Bedding and Pipe Zone Backfill 72 6.7.5 Trench Zone 72 6.1.6 Excavatability 13 6.1.7 Lateral Earth Pressures 13 6.2 PRELIMINARY PAVEMENT DESIGN 14 6.3 EXISTING UTILITIES AND IMPROVEMENTS 15 6.4 TRENCH RESURFACING 15 7.0 CONSTRUCTION OBSERVATION AND PLAN REVIEW 16 8.0 LIMITATIONS 17 040129-001 TABLE OF CONTENTS (Continued) FIGURE FIGURE 1 - SITE LOCATION MAP - PAGE 2 TABLES TABLE 1 - SEISMIC PARAMETERS FOR ACTIVE FAULTS - PAGE 8 TABLE 2 - GENERALIZED RIPPABILITY CHARACTERISTICS - PAGE 13 TABLE 3 - STATIC EQUIVALENT FLUID WEIGHT (PCF) - PAGE 13 TABLE 4 - RECOMMENDED PAVEMENT SECTION UTILIZING CLASS 2 AGGREGATE BASE - PAGE 14 PLATE PLATE 1 - GEOTECHNICAL MAP - IN POCKET APPENDICES APPENDIX A - REFERENCES APPENDIX B - BORING LOGS APPENDIX C - LABORATORY TESTING PROCEDURES APPENDIX D - SEISMIC ANALYSIS APPENDIX E - GENERAL EARTHWORK AND GRADING SPECIFICATIONS FOR ROUGH GRADING 040752-001 1.0 INTRODUCTION 1.1 Purpose and Scope This report presents the results of our geotechnical investigation of the proposed El Camino Real water pipeline located in the City of Carlsbad, California (Site Location Map, Figure 1). 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 construction. Our scope of services included: • Review of the referenced documents and maps (Appendix A). • A geotechnical reconnaissance of the site. • Coordination with Underground Services Alert and City of Carlsbad representatives. • Acquisition of City of Carlsbad permits for underground excavations in the public right-of- way. • Preparation and implementation of traffic control plans. • Excavation of 6 exploratory borings using a small diameter hollow-stem auger rig to depths of 2 to 15.5feetbgs. • Geologic logging of the borings (Appendix B). • Laboratory testing of representative samples obtained from the subsurface exploration. Results of these tests are presented in Appendix C of this report and on the borings logs (Appendix B). • Geotechnical analysis of data obtained. • Preparation of this report presenting our findings, conclusions, and recommendations regarding the proposed improvements. 1.2 Site Description The proposed pipeline, approximately 2,000 feet long, will be located beneath the existing eastern northbound lanes of El Camino Real from Faraday Avenue (Station 19+75) to Cougar Drive (Station 2+75). Topographically, El Camino Real slopes down northward from Faraday Avenue (approximately elevation 320 feet mean sea level) to Cougar Drive approximately elevation 265 feet mean sea level). m i PROJECT SITE NORTH BASE MAP: 2003 Digital Edition Thomas Guide, San Diego County NOT TO SCALE Kennedy/Jenks El Camino Real Water Main Between Cougar Drive and Faraday Avenue San Diego, California SITE LOCATION MAP Project No. 040752-001 Date Sept. 2002 Figure No. 1 040752-001 1.3 Proposed Improvements Based on our review of the proposed project plans and conversations with Kennedy Jenks, we understand the proposed pipeline will vary in depth from approximately feet 5 to 9 feet below the existing ground surface (bgs), and consist of a Ductile Iron Pipe (DIP) pipe with diameters of 16 inches and 24 inches. Installation of the pipeline will be primarily a cut-and-cover construction method. In addition, we understand that the proposed pipeline will be connected to existing pipelines located at Faraday Avenue and Cougar Drive. -3- 040752-001 2.0 SUBSURFACE EXPLORATION AND LABORATORY TESTING 2.1 Subsurface Exploration Our subsurface exploration consisted of the excavating six 8-inch diameter hollow-stem auger borings (B-l through B-6) to depths ranging from 2 to 15.5 feet bgs. The purpose of these exploration excavations was to evaluate the engineering characteristics of the onsite soils relative to the proposed 24-inch pipeline. Prior to excavation of the borings, location and identification of nearby underground utilities were coordinated with Underground Service Alert. The borings were logged by representatives from our firm. Relatively undisturbed drive samples and bulk disturbed samples were collected during drilling for laboratory testing. The approximate locations of the borings are shown on Geotechnical Map, Plate 1 . After logging, the borings were backfilled with bentonite and native soils, and pavement was restored with 6-inches of concrete overlay by 2 inches of asphalt. Logs of borings are presented in Appendix B of this report. 2.2 Laboratory Testing Selected samples were tested for expansion potential, moisture content, dry density, R- Value, and geochemical properties (i.e., pH, Resistivity, Chloride, and Sulfate Content). The results of our laboratory testing along with a summary of the testing procedures are presented in Appendix C of this report. In-situ moisture and density test results are presented on the borings logs (Appendix B). -4- 040752-001 3.0 SUMMARY OF GEOLOGIC CONDITIONS 3.1 Regional Geology The site is located within the coastal subprovince of the Peninsular Ranges Geomorphic Province, near the western edge of the southern California batholith. The topography at the edge of the batholith changes from the rugged landforms developed on the batholith to the more subdued landforms which typify the softer sedimentary formations of the coastal plain such as are present on the site. Specifically, the site is underlain by Point Loma Formation and surficially underlain by Undocumented Artificial Fill. Subsequent to the deposition of these units, erosion and regional tectonic uplift created the valleys and ridges of the area. Human influences, recent weathering and erosional processes have produced the Quaternary and recent surficial units including undocumented fill soils, which mantle the formational and bedrock materials along the proposed pipeline alignment. 3.2 Site-Specific Geology Formational and bedrock materials including Point Loma Formation and a surficial unit consisting undocumented fill soils were encountered during our investigation of the site. Brief descriptions of the geologic units encountered are provided below. 3.2.1 Undocumented Artificial Fill (Afu) Undocumented artificial fill placed during the construction of El Camino Real was encountered. Since no documentation of the placement and compaction of the existing fill were available, we have designated these fills as undocumented at this time. As encountered during our investigation, the artificial fill materials generally consist of brown to dark brown and gray-brown, damp to moist, dense to hard, fine to clayey sand and sandy clay. This material generally exists within graded portions of El Camino Real between Station 7+00 and Station 14+75. Artificial fill material was encountered in Borings B-1, B- 4, and B-5 to depths ranging from 1.5 to 13 feet bgs (Appendix B). 3.2.2 Point Loma Formation (kp) The Point Loma Formation underlies the entire site of the proposed pipeline alignment. As encountered during our investigation, this sedimentary formation primarily consists of moderately to well cemented, light brown to olive-brown, and orange brown, very dense to hard, very fine silty sandstone with clay to very fine sandy siltstone with clay. Occasional cemented interbeds and hard concretionary layers can be observed in adjacent road cuts and may be encountered within this unit. This material was encountered in Borings B-l, B-3, B-4, B-5, and B-6 at depths ranging from 2 to 15.5 feet bgs (Appendix B). -5- 040752-001 3.3 Surface and Ground Water During our field investigation, ground water was not encountered in any of our exploratory borings, nor was surface water observed in the adjacent drainages. However, seasonal fluctuations of surface water and ground water should be expected. It is our opinion that ground water related problems should be minor provided the recommendations in this report are incorporated into the design and construction of the project. 3.4 Soil Compressibility Based on our field exploration and observations, the soils encountered are predominantly sands, clays, and silts. In general, undocumented fill soils located at the central portion of the alignment (approximately Station 7+00 to 14+75) appear to be moist and relatively well compacted. However, localized porous zones were noted which may be relatively compressible. 3.5 Expansion Potential The test results indicate the on site soils have a medium expansion potential (per UBC Table 1 8-1- B). In addition, the siltstone and claystone materials of the Point Loma Formation may have a medium to high expansion potential. 3.6 Geochemical Considerations We have performed geochemical testing for soluble sulfate, chloride, pH and minimum resistivity on representative soils (Appendix C). The chloride content indicates a threshold affect on exposed steel or concrete. The soluble sulfate testing indicates a negligible soluble sulfate content in the onsite soils. The results of the minimum resistivity and pH testing indicate a very high to high potential for corrosion to buried uncoated metal materials. A corrosion engineer should be consulted regarding the type of protection needed for buried metal materials. m m i -6- 040752-001 4.0 FAULTING AND SEISMICITY ~ 4.1 Faulting Our discussion of faults on the site is prefaced with a discussion of California legislation and state "•" policies concerning the classification and land-use criteria associated with faults. By definition of m the California Mining and Geology Board, an active fault is a fault which has had surface displacement within Holocene time (about the last 11,000 years). The State Geologist has defined a m potentially active fault as any fault considered to have been active during Quaternary time (last gj 1,600,000 years). This definition is used in delineating Earthquake Fault Zones as mandated by the Alquist-Priolo Geologic Hazards Zones Act of 1972 and as most recently revised in 1997. The HI intent of this act is to regulate development near active faults so as to mitigate the hazards of ^ surface fault rupture" (Hart, 1997). Based on our review of the Fault-Rupture Hazard Zones, the site is not located within any Fault-Rupture Hazard Zones as created by the Alquist-Priolo Act m (Hart, 1997). l^lj San Diego, like the rest of southern California, is seismically active as a result of being located near ^ the active margin between the North American and Pacific tectonic plates. The principal source of seismic activity is movement along the northwest-trending regional fault zones such as the San "" Andreas, San Jacinto and Elsinore Faults Zones, as well as along less active faults such as the Rose Canyon Fault Zone. Seismic activity is also possible (although less likely) along unnamed inactive faults mapped on the City of Carlsbad Geotechnical Hazard Analyses and Mapping Study «• (Leighton,1992). ""* Our review of geologic literature pertaining to the site area indicates that there are known major m active faults in the immediate vicinity of the site (Jennings, 1994). Based on our review, unnamed faults were mapped central and northern portion of the proposed alignment through the El Camino ** Real (Leighton, 1992). Approximate location of these faults are presented on Geotechnical Map M (Plate 1). The nearest known active fault is the Rose Canyon Fault Zone located offshore approximately 6.8 miles west of the site. 4.2 Seismicitv — The site can be considered to lie within a seismically active region, as can all of Southern California. Table 1 (below) indicates potential seismic events that could be produced by the n maximum moment magnitude earthquake. A maximum moment magnitude earthquake is the maximum expectable earthquake given the presently known tectonic framework. Site-specific seismic parameters included in Table 1 are the distances to the causative faults, earthquake magnitudes, and expected ground accelerations (Appendix D). M -7- m 040752-001 ill m Table 1 Seismic Parameters for Active Faults (Blake, 2000) Potential Causative Fault Rose Canyon (offshore) Newport-Inglewood (Offshore) Elsinore- Julian Distance from Fault to Site (Miles) 6.8 8.8 22.3 Maximum Moment Magnitude 7.0 6.9 7.1 Peak Horizontal Ground Acceleration (g) 0.374 0.299 0.17 As indicated in Table 1, the Rose Canyon Fault is the 'active' fault considered having the most significant effect at the site from a design standpoint. A maximum moment magnitude earthquake of moment magnitude 7.0 on the fault could produce an estimated peak horizontal ground acceleration 0.374g at the site. The Rose Canyon Fault is considered a Type B seismic source according to Table 16-Uofthe 1997 Uniform Building code (ICBO, 1997). The effect of seismic shaking may be mitigated by adhering to the Uniform Building code or state-of-the-art seismic design parameters of the Structural Engineers Association of California. The soil parameters in accordance with UBC 1997 and other guidelines, are as follows: Soil Profile Types = Sc, (Table 16-J, 1997 UBC) Seismic Zone = 4 (Figure 16-2, 1997 UBC) Seismic Source Type = B (Table 16-U, 1997 UBC) Na= 1.0 (Table 16-S, 1997 UBC) Nv = 1.0 (Table 16-T, 1997 UBC) Secondary effects that can be associated with severe ground shaking following a relatively large earthquake which include shallow ground rupture, soil liquefaction and dynamic settlement. These secondary effects of seismic shaking are discussed in the following sections. 4.2.1 Lurching and Shallow Ground Soil lurching refers to the rolling motion on the ground surface by the passage of seismic surface waves. Effects of this nature are likely to be most severe where the thickness of soft sediments vary appreciably under structures. The potential for lurching can be mitigated if the potentially compressible soils present on the site are properly compacted in accordance with the recommendations of this report (Section 6.0). Breaking of the ground because of faulting is not likely to occur on site due to the absence of known active faults on the site. Cracking due to shaking from distant seismic events is not considered a significant hazard, although it is a possibility at any site. H m m i 040752-001 4.2.2 Liquefaction and Dynamic Settlement Liquefaction is a seismic phenomenon in which loose, saturated, fine-grained granular soils behave similarly to a fluid when subjected to high-intensity ground shaking. Liquefaction occurs when three general conditions exist: 1) shallow-groundwater; 2) low density non- cohesive soils; and 3) high-intensity ground motion. Based on absence of aforementioned characteristics along proposed pipeline, the potential for liquefaction is considered unlikely. m ma -9- 040752-001 5.0 CONCLUSIONS 5.1 Conclusions Based on our geotechnical investigation, it is our opinion that the development of the site is feasible from a geotechnical standpoint. There appear to be no significant geotechnical constraints on the site that cannot be mitigated by proper planning, design, and sound construction practices. Our recommendations for proper site development are presented in the following sections. The following items discuss the major conclusions based on our site investigation. • The soils encountered were generally evaluated to have favorable load-settlement characteristics at the depth of the pipe. However, localized zones of potentially compressible fill materials are anticipated in the central portion of the alignment from Stations 7+00 and 14+50. • Shallow excavations of the onsite materials may generally be accomplished with conventional heavy-duty earthwork equipment. Heavy ripping or breaking will likely be required where cemented and concretionary lenses are encountered in deeper excavations. Our preliminary interpretation of rippability with respect to geologic unit is provided in Section 6.1.6 of this report. • Ground water is not anticipated on the proposed pipeline alignment on El Camino Real. • The peak horizontal ground acceleration on the site due to the maximum credible earthquake is postulated to be 0.374g. • The test results indicate on site soils have a medium expansion potential. • Soluble Sulfate content tests indicate the soils possess negligible concentrations of soluble sulfates (per U.B.C. Table 19-A-4). Chloride content indicates a threshold affect on exposed steel. Minimum resistivity and pH testing indicate high to very high potential for corrosion. A corrosion engineer should be consulted regarding the type of protection needed for buried metal materials. m ti -10- m m 040752-001 6.0 RECOMMENDATIONS 6.1 Earthwork Grading and earthwork should be performed in accordance with the following recommendations and the General Earthwork and Grading Specifications for Rough Grading included as Appendix E. 6.1.1 Site Preparation Site preparation is anticipated to include demolition pavement and buried obstructions. Voids resulting from removal of buried obstructions that extend below finished pipeline grades should be backfilled with properly compacted fill soils. Utilities should be properly abandoned in accordance with appropriate local codes. All grading should be performed under the testing and observation of a qualified geotechnical consultant. 6.1.2 Excavations and Shoring Based on our observations during subsurface investigation and results of laboratory tests, shallow excavations of the onsite materials may generally be accomplished with conventional heavy-duty earthwork equipment. Heavy ripping or breaking will likely be required where cemented and concretionary lenses are encountered in deeper excavations. Our preliminary interpretation of excavatability characteristics of onsite material is provided in Section 6.1 .6 of this report All excavation should comply with OSHA requirements. For preliminary planning, sloping of surficial fill soils at 1 to 1 (horizontal to vertical) may be assumed. Loose and/or saturated artificial fill, if present on site, may cave during trenching operations. Special care should be taken for excavation near existing improvements and, to verify that the integrity of the existing improvements will not be impacted. For shored excavations, the geotechnical consultant should review the contractors proposed shoring design. We anticipate that scattered amounts of oversize material may be generated during excavation of localized cemented lenses within the formational unit. Recommendations for treatment of oversize material are included in the attached General Earthwork and Grading Specifications for Rough Grading (Appendix E). In general, oversize material should be hauled off site. ma -11- 040752-001 6.1.3 Removals Removal depths should be evaluated by a qualified geotechnical consultant during excavation. Significant removals of compressible material are not anticipated, and should generally be limited to within 2 feet of the bottom of the proposed pipeline. We do anticipate that potentially compressible soils will generally be encountered in the undocumented fill located at the central portion of the alignment. Compressible soils beneath the proposed Pipeline alignment should be removed to a minimum depth of 2 feet below the bottom of the proposed Pipeline line. The bottom of the excavation should be overlain with Mirafi 600x (or equivalent) and removed soil should be replaced with 2 feet of crushed aggregate prior to additional fill placement or the construction of improvements. 6.1.4 Pipe Bedding and Pipe Zone Backfill Pipe bedding should extend to a depth of at least 6 inches below the pipe and the pipe zone backfill should extend from the top of the bedding to a height of at least 12 inches over the top of the pipe. In addition, there should be a range of 6 to 12 inches of pipe zone backfill material on either side of the pipe. The bedding and pipe zone material may consist of compacted free draining sand, gravel or crushed rock (SE >30) in accordance with Appendix E of this report and the City of Carlsbad specifications. The bedding layer should be supported on firm, competent material, as determined by the Geotechnical Consultant and provisions of the above reference. Disturbed or loose materials at excavation bottom should be removed to expose firm native material. We anticipate that firm soil conditions exist at proposed invert depths, although some soft and/or loose soils may be encountered, as discussed above. Removals should be performed as previously described in Section 6.1.3 of this report and in accordance with the recommendations made during the course of excavation. 6.1.5 Trench Zone The onsite soils are generally suitable for reuse as compacted structural fill provided they are free of oversize material, organic materials, and debris. Saturated soils should be dried back and/or replaced with import soils. The optimum lift thickness required 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. Materials greater than 6 inches in maximum dimension should not be utilized in fills. Fill soils (onsite and import) should be placed near or above optimum moisture content and compacted to a minimum of 90 percent relative compaction (based on ASTM Test Method D1557). Placement and compaction of fill should be performed in accordance -12- 040752-001 with local grading ordinances under the observation and testing of a qualified geotechnical consultant. Densification by water jetting within the trench zone is not recommended. 6.1.6 Excavatability Based on our preliminary findings and our experience with the following geologic units, the following is our preliminary interpretation of excavatability with respect to geologic unit: Table 2 Generalized Excavation Characteristics Geologic Unit Artificial Fill Point Loma Formation General Excavation Characteristic Easy ripping, localized debris, oversize material may be encountered Generally excavated with standard construction equipment, localized cemented zones may prove to be difficult with localized breaking required "Difficult ripping" refers to rocks, in which it becomes difficult to achieve tooth penetration, sharply reducing ripping production. Localized ripping or breaking may be necessary in order to maintain a desired ripping production rate. We also note that concrete was encountered at shallow depths in Boring B-2 and B-3. The actual extent of this concrete was not determined by our study. m m mi 6.1.7 Lateral Earth Pressures For design purposes, the following lateral earth pressure values for level or sloping backfill are recommended for walls backfilled with on-site soils or approved granular material of very low to low expansion potential. Table 3 Static Equivalent Fluid Weight (pcf) Conditions Active At-Rest Passive Level 35 55 350 (Maximum of 3 ksf) 2:1 Slope 55 65 150 (sloping down) -13- 040752-001 m m m m Unrestrained (yielding) cantilever walls up to 10 feet in height should be designed for an active equivalent pressure value provided above. In the design of walls restrained from movement at the top (nonyielding) such as basement walls, the at-rest pressures should be used. If conditions other than those 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 pressure given above. For other uniform surcharge loads, a uniform pressure equal to 0.35q should be applied to the wall (where q is the surcharge pressure in psf). The wall pressures assume walls are backfilled with free draining materials and water is not allowed to accommodate behind walls. Wall backfill should be compacted by mechanical methods to at least 90 percent relative compaction (based on ASTM D1557). Wall footings should be designed in accordance with the foundation design recommendations and reinforced in accordance with structural considerations. For all retaining walls, we recommend a minimum horizontal distance from the outside base of the footing to daylight of 10 feet. Lateral soil resistance developed against lateral structural movement can be obtained from the passive pressure value provided above. Further, for sliding resistance, the friction coefficient of 0.3 may be used at the 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 of the total resistance. The geotechnical consultant should approve any backfill materials that will be utilized prior to the backfill placement operations. It is the contractor's responsibility to provide representative samples of the selected backfill material. 6.2 Preliminary Pavement Design Since an evaluation of the characteristics of the actual soils at pavement subgrade cannot be made at this time, we have provided the following range of pavement sections to be used for planning purposes only. Based on laboratory test R-Value and the City of Carlsbad's minimum section thickness requirements, a preliminary pavement section is presented in Table 3. m Table 4 Recommended Pavement Section Utilizing Class 2 Aggregate Base Location El Camino Real (Station No. 13+00) Traffic Index 8.5 Design R-Value 16 Asphalt Concrete Thickness (in inches) 5 Class 2 Aggregate Base Thickness (in inches) 17 -14- 040752-001 6.3 Existing Utilities and Improvements The proposed pipeline improvements are located near and cross several existing utilities. The contractor should exercise care to not disturb these utilities and or support them during construction. Compacting backfill above the pipe zone may be detrimental to surrounding utilities, we recommend a lean 1-sack cement sand slurry mix be used for backfilling operations. These areas should be limited to a zone between two pipes and not exceeding two feet on either side of the crossing. 6.4 Trench Resurfacing Trench resurfacing should be performed in accordance with San Diego Regional Standard Drawing No. G-24 and G-25 and the City of Carlsbad requirements. mi -15- 040752-001 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. All construction should be performed under the observation and testing of the Geotechnical Consultant at the following stages: • During trench excavation; • During placement of bedding and backfill; • During pavement capping; and • When any unusual or unexpected geotechnical conditions are encountered. The final Pipeline improvement plans should implement the recommendations presented in this report and should be reviewed by the project geotechnical consultant. m m -16- 040752-001 8.0 LIMITATIONS The conclusions and recommendations in this report are based in part upon data that were obtained from a limited number of observations, site visits, excavations, samples, and tests, such information is by necessity incomplete. The nature of many sites is such that differing geotechnical or geological conditions can occur within small distances and under varying climatic conditions. Changes in subsurface conditions can and do occur over time. Therefore, the findings, conclusions, and recommendations presented in this report can be relied upon only if Leighton has the opportunity to observe the subsurface conditions during grading and construction of the project, in order to confirm that our preliminary findings are representative for the site. m m -17- •I i 040752-001 APPENDIX A REFERENCES Blake, 2000, EQFAULT, Version 3.00. Boore, D.M., Joyner, W.B., and Fumal T.E., 1997, Equations for Estimating Horizontal Response Spectra and Peak Acceleration from Western North American Earthquakes: a Summary of Recent Work, Seismological Research Letters, v.68, No 1. Carlsbad, City of, 1996, Standards for Design and Construction of Public Works Improvements in the City of Carlsbad, California, Project No. 05332-12-01, dated April 20, 1993, revised December 10, 1996. CDMG, 1996, Probabilistic Seismic Hazard Assessment for the State of California, Open-File Report, 96-08. , 1996, Probabilistic Seismic Hazard Assessment for the State of California, Open File Report 96-706. Kennedy Jenks & Associates, 2002, El Camino Real, Water Main Preliminary Design Plan, undated. Hart, E.N., 1997, Fault-Rupture Hazard Zones in California, Alquist-Priolo Earthquake Fault Zoning with Index to special Study Zone Maps: Department of Conservation, Division of Mines and Geology, Special Publications42. International Conference of Building Officials, 1997, Uniform Building Code. Jennings, CW, 1994, Fault Activity Map of California, California Division Mines and Geology, Scale 1:750,000. Leighton and Associates, 1992, City of Carlsbad Geotechnical Hazards Analysis and Mapping Study, 48 Sheets, dated November, 1992. NCEER, 1997, Proceeding of the NCEER Workshop on Evaluation of Liquefaction Resistance of Soils, December 31,1997, NO. 97-0022. San Diego County Department of Public Works, 1992, San Diego Area Regional Standard Drawings, dated May, 1992. Tan, Siangs S. and Kennedy, Michael P., 1996, Geology Map of the Oceanside, San Luis Rey, and San Marcos Quadrangles, San Diego County, California A-l 040752-001 APPENDIX A (Continued) REFERENCES Tokimatu and Seed, 1986, Evaluation of Settlement in Sands due to Earthquake Shaking, JGE, Vol. 113, No. 8, August, 1987. Treiman, J.A., 1993, The Rose Canyon Fault zone, Southern California: California Division of Mines and Geology, Open-File Report 93-02,45 p. AERIAL PHOTOGRAPHS Date 4-11-53 Source USDA Scale 1:2000 Flight AXN-8M Photo Nos. 70 and 71 A-2 GEOTECHNICAL BORING LOG KEY Date Project Sheet 1 of 1 ct ngCo. Diameter LtionTopofHole +/- KEY TO BORING LOG GRAPHICS Drive Weight ft. Ref. or Datum Project No. Type of Rig Drop in.Elevation(feet) 1II o — 25 — in — o .CO)Q_O L //// f$fa A A A iA A A AA A A V / 7. y/. % i'/y /•/y./// ° r\f~-~~) ^> Co • . 3 \> ^ %%/. . . ±U^l-"~ EI-I-I-: <? /\ 0 /- Wsx \ x /- VV^Notes 1///$• /// ^^/^^J •&&&Q 6 <u 0. ruCO GRO TAI 01 CL SPT SAMPI CAL SAMPI ND WA ,EATT 3RILLI 31 c£0) OQ a t_a E .E TER [ME <G Moisture 1Content ('/.)V O)• C/3 CL CH OL-OH ML MH CL-ML ML-SM CL-SC SC-SM SW SP SM SC GW GP GM GC GEOTECHNICAL DESCRIPTION Logged By Sampled By Inorganic clay of low to medium plasticity; gravelly clay; sandy clay; silty clay; lean clay Inorganic clay or high plasticity; fat clay Organic clay, silt or silty clay-clayey silt mixtures Inorganic silt; very fine sand; silty or clayey fine sand; clayey silt with low plasticity Inorganic silt; diatomaceous fine sandy or silty soils; elastic silt Low plasticity clay to silt mixture Sandy silt to silty sand mixture Sandy clay to clayey sand mixture Clayey sand to silty sand mixture Well graded sand; gravelly sand, little or no fines Poorly graded sand; gravelly sand, little or no fines Silty sand; poorly graded sand-silt mixture Clayey sand; poorly graded sand; clay mixture Well graded gravel; gravel-sand mixture, little or no fines Poorly graded gravel; gravel-sand mixture, little or no fines Silty gravel; gravel-sand-silt mixture Clayey gravel; gravel-sand-clay mixture Sandstone Siltstone Claystone Breccia (angular gravel and cobbles or matrix-support conglomerate) Conglomerate (rounded gravel and cobble clast-supported) Igneous granitic or granitic type rock Metavolcanic or metamorphic rock Artificial or man-made fill Asphaltic concrete Portland cement concrete - 505A(11/77)LEIGHTON & ASSOCIATES Date Project Drilling Co. 8-21-02 GEOTECHNICAL BORING LOG B-l Kennedy Jenk/ECR Sheet 1 of 1 Project No. 040752-001 Cal Pac Drilling Type of Rig Hollow-Stem Auger Hole Diameter 8 in. Drive Weight 140 pounds Drop 30 in. Elevation Top of Hole +/- 308 ft. Ref. or Datum Mean Sea Level c '^_+- ><J!0)^ Ul 305- 300- 295- 290- 285- 280- f »<u,J!O^ - — 5 — 10 — 15 — - 20 — - 25 — - 10 _ ; //// u 0(0 CD | 1ri 0)o_J •>^« a' <U oz o <U Q. CO Bag-1 @2'-5' . '1 3 I 1 4 1 -i- 1° ~~ / 1" 55 70 31 Ct-QJ Ua a.-j,^t_ Q 100.3 £_^ ^ ._ OJ °"c^~ oo 24.5 *~ GCJ CO co^ ML CL ML GEOTECHNICAL DESCRIPTION Logged By MDJ Sampled By MDJ @0-8": Asphaltic Concrete @ 8"-16": Aggregate Base ARTIFICIAL FILL (Undocumented') ( Afu) @ 16": Sandy clayey SILT: Brown to gray-brown, damp to moist, dense - @ 5': Sandy CLAY: Brown, moist, hard; porous, possible topsoil derived fill CRETACEOUS POINT LOMA FORMATION @ 8': Very fine sandy SILTSTONE with clay: Orange-brown, damp, hard @ 10': Very fine sandy SILTSTONE with clay: Orange-brown, damp, hard Total Depth = 1 1 Feet No ground water encountered at time of drilling Backfilled on 8/2 1/02 - - - - - - 505A(11/77)LEIGHTON & ASSOCIATES GEOTECHNICAL BORING LOG B-2 Date — Project 8-21-02 ct ng Co. Diameter 8 in. ition Top of Hole +/- 315 Kennedy Jenk/ECR Cal Pac Drilling Drive Weight ft. Ref. or Datum Sheet 1 Project No. Type of Rig 140 pounds Mean Sea Level of 1 040752-001 Hollow-Stem Auger Drop 30 in.Elevation(feet) |315- 310- 305- 300- 295- 290- ?8<i-Depth 1(feet) 1u .CO)Q.Ofd_i CD &0)+-o P"- 5 — 10 — 15 — 20 — 25 — 10 lsla d 01 Q. 01CO Bag-1 @7"-2' 38 0^ <QOJQ. 31•(- in^CH-OJ UQ Q.\^D) Q MoistureContent (*) |w^ > u^— V> '53CO GEOTECHNICAL DESCRIPTION Logged By MDJ Sampled By MDJ @ 0-7": Asphaltic Concrete @7"-2': Aggregate Base @ 2': Encountered concrete, possible storm drain or slurry, practical refusal Total Depth = 2.5 Feet No ground water encountered at time of drilling Backfilled on 8/21/02 - - - - - 505A(11/77)LEIGHTON & ASSOCIATES GEOTECHNICAL BORING LOG B-3 Date 8-21-02 Project Drilling Co. Hole Diameter 8 in. Elevation Top of Hole +/- 315 Kennedy Jenk/ECR Cal Pac Drilling Drive Weight ft. Ref. or Datum Sheet 1 of 1 Project No. 040752-001 Type of Rig Hollow-Stem Auger 140 pounds Drop 30 in. Mean Sea Level Elevation(feet) |315- 310- 305- 300- 295- 290- •785-'Depth(feet) 1o .CO)Q.On)_i cs NotesM - - 5~ 10 — 15 20 — ^c in — >.'-": 6z <u Q. (00) sl 0^ cofea. JP-i- tn^ CM- QJ Ua a. \-S 3) Q MoistureContent (/O<n~ S" "^_to "5303 GEOTECHNICAL DESCRIPTION Logged By MDJ Sampled By MDJ @ 0-8": Asphalt Concrete @8"-2': Class 2 Aggregate Base \@ 2': Encountered concrete, practical refusal 7 Total Depth = 2 Feet No ground water encountered at time of drilling Backfilled on 8/21/02 - - - - - 505AC11/77)LEIGHTON & ASSOCIATES Date 8-21-02 Project Drilling Co. GEOTECHNICAL BORING LOG B-4 Kennedy Jenk/ECR Sheet 1 of 1 Project No. 040752-001 Cal Pac Drilling Type of Rig Hollow-Stem Auger Hole Diameter Sin. Drive Weight 140 pounds Drop 30 in. Elevation Top of Hole +/- 303 ft. Ref. or Datum Mean Sea Level c «8 ju£ LU 300- 295- 285- 280- 275- ?«(UfjTQw - 5 — - 10 — - 15 — - 20 — - 25 — - O Qffl£_O •^^0 ~ / / '4. -: 0)O1 •^" f > 0% 01-1-0z 6 0> O) 1I 1 Bag-2 1 3 | 4 I '1 6 1 •+- §£ CD QJ 29 1 21 28 24 1 50/1" S CH-OI Oa a. 3) a 98.9 99.6 93.8 QJ-5 ^ " (U °"£ o 24.2 14.0 25.2 j»2 o". *z • ww CL ML CL SM GEOTECHNICAL DESCRIPTION Logged By MDJ Sampled By MDJ @ 0-8.5": Asphalt Concrete @ 8.5"-2': Aggregate Base ARTIFICIAL FILL (Undocumented) (Afu) @ 2': Sandy silty CLAY: Orange-brown to brown, moist, very stiff @ 5': Clayey SILT with clay: Orange-brown, moist, very stiff @ 7.5': Silty CLAY: Brown, moist, very stiff @ 10': Silty CLAY: Brown to black, moist, very stiff; slighdy porous, possible topsoil CRETACEOUS POINT LOMA FORMATION @ 13': Silty SANDSTONE: Light brown, damp, very dense @ 15': Well-cemented layer or concretion ~\@ 15': Two ring sluff, two rings formation f \Practical refusal at 15.5' Total Depth = 15.5 Feet No ground water encountered at time of drilling Backfilled: 8/12/02 - - - - 505A(11/77)LEIGHTON & ASSOCIATES GEOTECHNICAL BORING LOG B-5 Date 8-21-02 Project Drilling Co. Hole Diameter 8 in. Elevation Top of Hole +/- 296 Kennedy Jenk/ECR Cal Pac Drilling Drive Weight ft. Ref. or Datum Sheet 1 of 1 Project No. 040752-001 Type of Rig Hollow-Stem Auger 140 pounds Drop 30 in. Mean Sea Level o^ ;SIs LU 295- 290- 285- 280- 275- 270- •£*-1! „- - - 5 — — - 15 — - 20 - 25 - 10 0 .CO)CLO(0 _l CD •i'•'"'" " °o " » //// //// //// %/ W/ Ifl0)-1-o o QJ Q.£ CO 1 1 1 Bag-2 1 @2'-4f 1 3 | 4 1 f +- ~~ (_ 44 1 38 98 ^+• CH-OI OQ Q. a 95.9 /^ t-^*^ii o 25.5 I/I ^^ (f\ f* fl -^CO^ CL ML GEOTECHNICAL DESCRIPTION Logged By MDJ Sampled By MDJ @ 0-7.5": Asphalt Concrete @ 7.5"-2.5': Aggregate Base - ARTIFICIAL FILL (Undocumented") (Ami @ 2.5': Silty CLAY with sand: Brown, moist, hard - @ 5': Silty CLAY with sand: Brown, moist, hard - CRETACEOUS POINT LOMA FORMATION @ 7': Clayey SILTSTONE with very fine SAND: Green, damp, hard; fracture infilled with calcium carbonate Total Depth = 9 Feet No ground water encountered at time of drilling Backfilled on 8/21/02 - - - - - - - - 505AO1/77)LEIGHTON & ASSOCIATES GEOTECHNICAL BORING LOG B-6 Date 8-21-02 Project Drilling Co. Hole Diameter 8 in. Elevation Top of Hole +/- 279 Kennedy Jenk/ECR Cal Pac Drilling Drive Weight ft. Ref. or Datum Sheet 1 of 1 Project No. 040752-001 Type of Rig Hollow-Stem Auger 140 pounds Drop 30 in. Mean Sea Level c "8"^(y LU 275- 270- 265- 260- 255 250- £«01 (jrQ^ "1 J C _ - — 10 — - 15 — - 20 — - 25 — - in j | D • .' - J I p D | ^P c T 0)o_] •0 C in01 oz r-- 6 01 Q. (/) 1 [ 1 1 Bag-2 1 @2'-5' [ 3 1 : '1r -H g£ ( f\u_ 70 1 88 : 98 j 3» ci01 OO Q. 31C-o 102.0 C.^^- ._ 01o"^E oo 23.0 W- uu! ~ • cn^ SM/ML ML ML GEOTECHNICAL DESCRIPTION Logged By MDJ Sampled By MDJ @0-7": Asphalt Concrete @ 7"-2': Aggregate Base CRETACEOUS POINT LOMA FORMATION @ 2.0': Silty very fine SANDSTONE with clay to very fine sandy SILTSTONE with clay: Orange-brown, damp, very dense to hard; iron-oxided stained ~ @ 5': Very fine sandy SILTSTONE with clay: Orange-brown to brown, damp, hard @ 6.5': Cemented layer - @ 10': Very fine sandy SILTSTONE: Orange-brown, damp, dense; iron-oxided \ stained f Total Depth = 10.5 Feet No ground water encountered at time of drilling Backfilled on 8/21/02 - - - - - - - 505A(11/77)LEIGHTON & ASSOCIATES m m 040752-001 APPENDIX C Laboratory Testing Procedures and Test Results Chloride Content: Chloride content was tested in accordance with Caltrans Test Method CT422. The results are presented below: Sample Location B-l @ 2-5 Feet B-4 @ 2.5-5 Feet B-5 @ 2-4 Feet B-6 @ 2-5 Feet Chloride Content, ppm 213 141 139 206 Chloride Attack Potential* Threshold Threshold Threshold Threshold *per City of San Diego Program Guidelines for Design Consultant, 1992. m m m m Expansion Index Tests: The expansion potential of selected materials was evaluated by the Expansion Index Test, U.B.C. Standard No. 18-2 and/or ASTM Test Method 4829. Specimens are molded under a given compactive energy to approximately the optimum moisture content and approximately 50 percent saturation or 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 B-4 @ 2.5-5 Feet Sample Description Gray-olive sandy lean CLAY Compacted Dry Density (pcf) 99.6 Expansion Index 70 Expansion Potential Medium m Moisture and Density Determination Tests: Moisture content (ASTM Test Method D2216) and dry density determinations were performed on relatively undisturbed ring samples obtained from the test borings and/or trenches. The results of these tests are presented in the boring and/or trench logs. Where applicable, only the moisture content was determined from disturbed samples. mm m ij^i C-l 040752-001 Laboratory Testing Procedures and Test Results (Continued) Minimum Resistivity and pH Tests: Minimum resistivity and pH tests were performed in general accordance with Caltrans Test Method CT643 for Steel or CT532 for concrete and standard geochemical methods. The results are presented in the table below: Sample Location B-l@ 2-5 Feet B-4 @ 2.5-5 Feet B-5 @ 2-4 Feet B-6 @ 2-5 Feet Sample Description Gray-olive sandy lean CLAY Gray-olive sandy lean CLAY Gray-olive lean CLAY Gray-olive lean CLAY with sand pH 8.11 8.25 8.05 7.92 Minimum Resistivity (ohms-cm) 1786 962 893 756 "R"-Value: The resistance "R"-value was determined by the California Materials Method CT301 for base, subbase, and basement soils. The samples were prepared and exudation pressure and "R"-value determined. The graphically determined "R"-value at exudation pressure of 300 psi is reported. Sample Number B- 1,2-5 Feet Sample Description Olive sandy lean CLAY R-Value 16 Soluble Sulfates: The soluble sulfate contents of selected samples were determined by standard geochemical methods (Caltrans Test Method CT417). The test results are presented in the table below: Sample Location B-l@ 2-5 Feet B-4 @ 2.5-5 Feet B-5 @ 2-4 Feet B-6 @ 2-5 Feet Sample Description Gray-olive sandy lean CLAY Gray-olive sandy lean CLAY Gray-olive sandy lean CLAY Gray-olive lean CLAY with sand Sulfate Content (%) <0.015 <0.06 0.015 <0.015 Potential Degree of Sulfate Attack* Negligible Negligible Negligible Negligible * Based on the 1997 edition of the Uniform Building Code, Table No. 19-A-4, prepared by the International Conference of Building Officials (ICBO, 1997). C-2 EQFAULT Version 3.00 DETERMINISTIC ESTIMATION OF PEAK ACCELERATION FROM DIGITIZED FAULTS JOB NUMBER: 040785-001 DATE: 08-30-2002 JOB NAME: EL CAMINO REAL @ COUGAR DRIVE CALCULATION NAME: Analysis FAULT-DATA-FILE NAME: C:\Program Files\EQFAULTl\CdmgfIte (Modified RCFZ).dat SITE COORDINATES: SITE LATITUDE: 33.1415 SITE LONGITUDE: 117.2775 SEARCH RADIUS: 100 mi ATTENUATION RELATION: 13) Boore et al. (1997) Horiz. - Vs = 750 m/s UNCERTAINTY (M=Median, S=Sigma): M Number of Sigmas: 0.0 DISTANCE MEASURE: cd_2drp SCOND: 0 Basement Depth: 5.00 km Campbell SSR: Campbell SHR: COMPUTE PEAK HORIZONTAL ACCELERATION FAULT-DATA FILE USED: C:\Program Files\EQFAULT1\CdmgfIte (Modified RCFZ).dat MINIMUM DEPTH VALUE (km): 0.0 EQFAULT SUMMARY DETERMINISTIC SITE PARAMETERS Page 1 ABBREVIATED FAULT NAME ROSE CANYON NEWPORT-INGLEWOOD (Offshore) ELSINORE-JULIAN ELSINORE-TEMECULA CORONADO BANK ELSINORE-GLEN IVY PALOS VERDES EARTHQUAKE VALLEY SAN JACINTO-ANZA SAN JACINTO-SAN JACINTO VALLEY CHINO-CENTRAL AVE . (Elsinore) NEWPORT-INGLEWOOD (L. A. Basin) SAN JACINTO-COYOTE CREEK WHITTIER ELSINORE-COYOTE MOUNTAIN COMPTON THRUST SAN JACINTO-SAN BERNARDINO ELYSIAN PARK THRUST SAN JACINTO - BORREGO SAN ANDREAS - San Bernardino SAN ANDREAS - Southern SAN JOSE PINTO MOUNTAIN SAN ANDREAS - Coachella CUCAMONGA SIERRA MADRE NORTH FRONTAL FAULT ZONE (West) BURNT MTN. CLEGHORN EUREKA PEAK SUPERSTITION MTN. (San Jacinto) NORTH FRONTAL FAULT ZONE (East) SAN ANDREAS - 1857 Rupture SAN ANDREAS - Mojave RAYMOND CLAMSHELL-SAWPIT ELMORE RANCH SUPERSTITION HILLS (San Jacinto) VERDUGO LACUNA SALADA APPROXIMATE DISTANCE mi ( km ) 6. 8. 22. 22. 22. 34. 39. 40. 45. 46. 49. 49. 49. 53. 54. 59. 60. 61. 62. 64. 64. 70. 71. 71. 72. 72. 75. 76. 78. 78. 79. 79. 82. 82. 82. 82. 82. 83. 85. 85. 8( 8( 3( 3( 9( 9( 5( 4( 2( 3( 2( 3( 6( 4( 4( 0( 5( 2( 8( 2( 2( 2( 0( 4{ 6( 9( 9( 2( 3{ 9( K 5( K K 4( 5( 7( 8( K 7( 10. 14. 35. 35. 36. 56. 63. 65. 72. 74. 79. 79. 79. 86. 87. 94. 97. 98. 101. 103. 103. 113. 114. 114. 116. 117. 122. 122. 126. 127. 127. 127. 132. 132. 132. 132. 133. 134. 137. 137. 9) 2) 9) 9) 8) 1) 5) 0) 7) 5) 2) 4) 8) 0) 5) 9) 3) 5) 1) 4) 4) 0) 3) 9) 8) 3) 2) 6) 0) 0) 3) 9) 1) ESTIMATED MAX.EARTHQUAKE EVENT MAXIMUM | PEAK EARTHQUAKE SITE MAG. (Mw) | ACCEL, g 7. 6. 7. 6. 7. 6. 7. 6. 7. 6. 6. 6. 6. 6. 6. 6. 6. 6. 6. 7. 7. 6. 7. 7. 7. 7. 7. 6. 6. 6. 6. 6 . 7 . 1) 7. 6) 6. 7) 6. 1) 6. 8) 6. 0) 6. 9) 7. 1 0 | 0 9 | 0 1 1 0 8 | 0 4 | 0 8 | 0 1 0 5 0 2 0 9 0 7 0 9 0 8 8 8 7 7 6 3 4 5 0 1 0 0 0 4 5 4 6 7 8 1 5 5 6 6 7 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 .222 .178 .100 .086 .115 .061 .065 .046 .062 .052 .054 .049 .046 .044 .043 .049 .038 .046 .035 .049 .052 .037 .039 .041 .047 .047 .045 .027 .028 .026 .029 EST. SITE INTENSITY MOD . MERC . IX VIII VII VII VII VI VI VI VI VI VI VI VI VI VI VI V VI V VI VI V V V VI VI VI V V V v .037 V .053 VI .037 V .033 V .032 | V .028 | V .028 V .035 V .034 V DETERMINISTIC SITE PARAMETERS Page 2 ABBREVIATED FAULT NAME LANDERS HOLLYWOOD HELENDALE - S. LOCKHARDT LENWOOD-LOCKHART-OLD WOMAN SPRGS BRAWLEY SEISMIC ZONE SANTA MONICA EMERSON So. - COPPER MTN . JOHNSON VALLEY (Northern) MALIBU COAST SIERRA MADRE (San Fernando) NORTHRIDGE (E. Oak Ridge) SAN GABRIEL a PPPOVriv^TA TIT?r\L r C\\J A J. i*.Ln j. Hi DISTANCE mi 86.4 ( 87. 2( 88. 2( 91. 7( 92. 0( 92. 2 ( 94. 3( 94.4 ( 95. 1( 98.1 ( 98.7 ( 99.9 ( (km) 139.0) 140.3) 141.9) 147.5) 148.0) 148.4) 151.8) 152.0) 153.1) 157.9) 158.8) 160.7) ESTIMATED MAX. EARTHQUAKE EVENT MAXIMUM EARTHQUAKE MAG. (Mw) 7.3 6.4 7.1 7.3 6.4 6.6 6.9 6.7 6.7 6.7 6.9 7.0 PEAK SITE ACCEL, g 0.039 0.030 0.035 0.038 0.023 0.031 0.030 0.027 0.032 0.032 0.035 0.030 t*-JfJr-*-****-*-*-J EST. SITE INTENSITY MOD. MERC. V V V V IV V V V V V V V t-TtTt--t-t-Jr-Jr-Jr-it4- -END OF SEARCH- THE ROSE CANYON 52 FAULTS FOUND WITHIN THE SPECIFIED SEARCH RADIUS. FAULT IS CLOSEST TO THE SITE. IT IS ABOUT 6.8 MILES (10.9 km) AWAY. LARGEST MAXIMUM-EARTHQUAKE SITE ACCELERATION: 0.2222 g * EQFAULT * * * * Version 3.00 ** * *********************** DETERMINISTIC ESTIMATION OF PEAK ACCELERATION FROM DIGITIZED FAULTS JOB NUMBER: 040785-001 DATE: 08-30-2002 JOB NAME: EL CAMINO REAL @ COUGAR DRIVE CALCULATION NAME: Analysis FAULT-DATA-FILE NAME: C:\Program Files\EQFAULTl\CdmgfIte (Modified RCFZ).dat SITE COORDINATES: SITE LATITUDE: 33.1415 SITE LONGITUDE: 117.2775 SEARCH RADIUS: 100 mi ATTENUATION RELATION: 13) Boore et al. (1997) Horiz. - Vs = 750 m/s UNCERTAINTY (M=Median, S=Sigma): S Number of Sigmas: 1.0 DISTANCE MEASURE: cd_2drp SCOND: 0 Basement Depth: 5.00 km Campbell SSR: Campbell SHR: COMPUTE PEAK HORIZONTAL ACCELERATION FAULT-DATA FILE USED: C:\Program Files\EQFAULT1\CdmgfIte (Modified RCFZJ.dat MINIMUM DEPTH VALUE (km): 0.0 c L C C I z c c c c c E C EQFAULT DETERMINISTIC SUMMARY SITE PARAMETERS Page 1 ABBREVIATED FAULT NAME ROSE CANYON NEWPORT-INGLEWOOD (Offshore) ELSINORE-JULIAN ELSINORE-TEMECULA CORONADO BANK ELSINORE-GLEN IVY PALOS VERDE S EARTHQUAKE VALLEY SAN JACINTO-ANZA SAN JACINTO-SAN JACINTO VALLEY CHINO-CENTRAL AVE . (Elsinore) NEWPORT-INGLEWOOD (L. A. Basin) SAN JACINTO-COYOTE CREEK WHITTIER ELSINORE-COYOTE MOUNTAIN COMPTON THRUST SAN JACINTO-SAN BERNARDINO ELYS IAN PARK THRUST SAN JACINTO - BORREGO SAN ANDREAS - San Bernardino SAN ANDREAS - Southern SAN JOSE PINTO MOUNTAIN SAN ANDREAS - Coachella CUCAMONGA SIERRA MADRE NORTH FRONTAL FAULT ZONE (West) BURNT MTN. APPROXIMATE DISTANCE mi 6.8( 8.8( 22. 3( 22. 3( 22. 9( 34. 9 ( 39. 5( 40.4 ( 45.2 ( 46. 3( 49. 2( 49. 3( 49. 6( 53.4 ( 54.4 ( 59. 0( 60. 5( 61. 2( 62. 8 ( 64. 2( 64. 2( 70. 2( 71. 0( 71.4 ( 72. 6( 72. 9( 75. 9( 76. 2( CLEGHORN 78.3( EUREKA PEAK 78.9( SUPERSTITION MTN. (San Jacinto) 79. 1( NORTH FRONTAL FAULT ZONE (East) 79.5( SAN ANDREAS - 1857 Rupture 82. 1 ( SAN ANDREAS - Mojave 82.1( RAYMOND 82.4( CLAMSHELL-SAWPIT 82. 5 ( ELMORE RANCH 82.7 ( SUPERSTITION HILLS (San Jacinto) 83. 8 ( VERDUGO I 85.1( LACUNA SALADA I 85.7( (km) 10. 14. 35. 35. 36. 56. 63. 65. 72. 74. 79. 79. 79. 86. 87. 94. 97. 98. 101. 103. 103. 113. 114. 114. 116. 117. 122. 122. 126. 127. •127. 127. 132. 132. 132. 132. 133. 134. 137. 137. 9) 2) 9) 9) 8) 1) 5) 0) 7) 5) 2) 4) 8) 0) 5) 9) 3) 5) 1) 4) 4) 0) 3) 9) 8) 3) 2) 6) 0) 0) 3) 9) 1) 1) 6) 7) 1) 8) 0) 9) ESTIMATED MAX. EARTHQUAKE EVENT MAXIMUM EARTHQUAKE MAG. (Mw) 7.0 6.9 7.1 6.8 7.4 6.8 7.1 6.5 7.2 6.9 6.7 6.9 6.8 6.8 6.8 6.8 6.7 6.7 6.6 7.3 7.4 6.5 7.0 7.1 7.0 7.0 7.0 6.4 6.5 6.4 6.6 6.7 7.8 7.1 6.5 6.5 6.6 6.6 6.7 7.0 PEAK SITE ACCEL, g 0.374 0.299 0.169 0.144 0.194 0.103 0.109 0.078 0.104 0.087 0.091 0.083 0.078 0.074 0.073 0.083 0.064 0.077 0.058 0.083 0.088 0.062 0.066 0.069 0.079 0.078 0.076 0.045 0.047 0.044 0.049 0.062 0.089 0.062 0.055 0.055 0.047 0.047 0.059 0.057 EST. SITE INTENSITY MOD . MERC . IX IX VIII VIII VIII VII VII VII VII VII VII VII VII VII VII VII VI VII VI VII VII VI VI VI VII VII VII VI VI VI VI VI VII VI VI VI VI VI VI VI I I DETERMINISTIC SITE PARAMETERS Page 2 ABBREVIATED FAULT NAME LANDERS HOLLYWOOD HELENDALE - S. LOCKHARDT LENWOOD-LOCKHART-OLD WOMAN SPRGS BRAWLEY SEISMIC ZONE SANTA MONICA EMERSON So. - COPPER MTN . JOHNSON VALLEY (Northern) MALIBU COAST SIERRA MADRE (San Fernando) NORTHRIDGE (E. Oak Ridge) SAN GABRIEL APPROXIMATE DISTANCE mi ( km ) 86. 4( 139.0) 87. 2( 140.3) 88. 2( 141.9) 91. 7( 147.5) 92. 0( 148.0) 92. 2( 148.4) 94. 3( 151.8) 94. 4( 152.0) 95. 1( 153.1) 98. 1( 157.9) 98. 7( 158.8) 99.9 ( 160.7) ESTIMATED MAX. EARTHQUAKE EVENT MAXIMUM EARTHQUAKE MAG. (Mw) 7.3 6.4 7.1 7.3 6.4 6.6 6.9 6.7 6.7 6.7 6.9 7.0 t**********v PEAK SITE ACCEL, g 0.066 0.050 0.059 0.063 0.039 0.053 0.050 0.045 0.054 0.053 0.059 0.050 t**********v EST. SITE INTENSITY MOD. MERC. VI VI VI VI V VI VI VI VI VI VI VI t********* -END OF SEARCH- THE ROSE CANYON 52 FAULTS FOUND WITHIN THE SPECIFIED SEARCH RADIUS. FAULT IS CLOSEST TO THE SITE. IT IS ABOUT 6.8 MILES (10.9 km) AWAY. LARGEST MAXIMUM-EARTHQUAKE SITE ACCELERATION: 0.3737 g CALIFORNIA FAULT MAP EL CAMINO REAL (5) COUGAR DRIVE -25-- -50-- -75-- -100-- -125 -- 150 175 200 225 250 275 300 325 350 Leightonand Associates, Inc. GENERAL EARTHWORK AND GRADING SPECIFICATIONS Page 1 of 6 LEIGHTONAND 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-conditioningand process ing 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. 3030.1094 Leightonand Associates, Inc. GENERAL EARTHWORK AND GRADING SPECIFICATIONS Page 2 of 6 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 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 Preparation of Areas to be Filled 2.1 Clearing 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. 3030.1094 Leightonand Associates, Inc. GENERAL EARTHWORK AND GRADING SPECIFICATIONS Page 3 of 6 2.2 Processing: 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 Benching: 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 evaluated 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 defined 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. 3030.1094 Leighton and Associates, Inc. GENERAL EARTHWORK AND GRADING SPECIFICATIONS Page 4 of 6 3.3 Import: 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 Fill Layers: 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 Fill Moisture Conditioning: 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 Compaction 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 Dl 557-91). 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 Compaction of Fill Slopes: 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 Dl 557-91. 4.5 Compaction Testing: 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. Compaction 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). 3030.1094 Leightonand Associates, Inc. GENERAL EARTHWORK AND GRADING SPECIFICATIONS Page 5 of 6 4.6 Frequency of Compaction 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 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 Consultant 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 fill-over-cut slopes are to be graded, the cut portion of the slope shall be made, evaluated, and accepted by the Geotechnical Consultant prior to placement of materials for construction of the fill portion of the slope, unless otherwise recommended by the Geotechnical Consultant. 3030.1094 Leighton and Associates, Inc. GENERAL EARTHWORK AND GRADING SPECIFICATIONS Page 6 of 6 7.0 Trench Backfills 7.1 The Contractor shall follow all OHSA and Cal/OSHA requirements for safety of trench excavations. 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. Backfill 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. 3030.1094 PROJECTED PLANE 1 TO 1 MAXIMUM FROM TOE OF 8LOPE TO APPROVED GROUND NATURAL GROUND FILL SLOPE REMOVE UNSUITABLE MATERIAL BENCH HEIGHT V MIN. KEY DEPTH LOWEST BENCH (KEY) NATURAL GROUND 4' TYPICAL ' I—BENCH HEIGHT FILL-OVER-CUT SLOPE REMOVE UNSUITABLE MATERIAL CUT FACE SHALL BE CONSTRUCTED PRIOR TO FILL PLACEMENT TO ASSURE ADEQUATE OEOLOOe CONDITIONS CUT FACE TO BE CONSTRUCTED PRIOR TO FILL PLACEMENTv OVERBUILT AND TRIM BACK PROJECTED PLANE 1 TO 1 MAXIMUM FROM TOE OF SLOPE TO APPROVED GROUND DESIGN SLOPE REMOVE NSUITABLE MATERIAL CUT-OVER-FILL SLOPE For Subdrains See Standard Detail C BENCH HEIGHT 2f MIN.—' KEY DEPTH LOWEST BENCH (KEY) BENCHING SHALL BE DONE WHEN SLOPES ANGLE IS EQUAL TO OR GREATER THAN 5:1 MINIMUM BENCH HEIGHT SHALL BE 4 FEET MINIMUM FILL WIDTH SHALL BE 9 FEET KEYING AND BENCHING GENERAL EARTHWORK AND GRADING SPECIFICATIONS STANDARD DETAILS A uu REV. 4/11/96 FINISH GRADE SLOPE FACE ™_m^n^r^iO' MIN.irtr-_r:COMPACTED FILL JETTED OR FLOODED GRANULAR MATERIAL • Oversize rock is larger than 8 Inches in largest dimension. • Excavate a trench in the compacted fill deep enough to bury all the rock. • Backfill with granular soil jetted or flooded in place to fill all the voids. • Do not bury rock within 10 feet of finish grade. • Windrow of burled rock shaH be parallel to the finished slope fill.ELEVATION PROFILE ALONG WINDROW A-A' JETTED OR FLOODED GRANULAR MATERIAL OVERSIZE ROCK DISPOSAL GENERAL EARTHWORK AND GRADING SPECIFICATIONS STANDARD DETAILS B T 4/95 NATURAL GROUND BENCHING REMOVE UNSUITABLE MATERIAL - COMPACTED FILL 2" MIN. OVERLAP FROM THE TOP HOG RING TIED EVERY 6 FEET CALTRANS CLASS II PERMEABLE OR #2 ROCK' (9FT.3/FT.) WRAPPED IN FILTER FABRIC FILTER FABRIC (MIRAF1140 OR APPROVED EQUIVALENT) CANYON SUBDRAIN OUTLET DETAIL PERFORATED PIPE 6'* MIN. V\COLLECTOR PIPE SHALL BE MINIMUM 6* DIAMETER SCHEDULE 40 PVC PERFORATED PIPE. SEE STANDARD DETAIL D FOR PIPE SPECIFICATION DESIGN FINISHED GRADE 20' MIN- FILTER FABRIC (MIRAFI 140 OR APPROVED EQUIVALENT) .NON-PERFORATED. MIN. 5' MIN X #2 ROCK WRAPPED IN FILTER TABRIC OR CALTRANS CLASS II PERMEABLE. CANYON SUBDRAINS GENERAL EARTHWORK AND GRADING SPECIFICATIONS STANDARD DETAILS C LU 4/95 OUTLET PIPES 4'* NON-PERFORATED PIPE, 100' MAX. O.C. HORIZONTALLY, 30' MAX. O.C. VERTICALLY BACKCUT 1:1 OR FLATTER 2' MIN. POSITIVE SEAL SHOULD BE PROVIDED AT THE JOI 12* MIN. OVERLAP FROM THE TOP HOG RING TIED EVERY 6 FEET VI OUTLET PIPE (NON-PERFORATED) CALTRANS CLASS II PERMEABLE OR #2 ROCK (3FT.3/FT.) WRAPPED IN FILTER FABRIC FILTER FABRIC (MIRAF1 140 OR APPROVED EQUIVALENT) ECTIONT-CONNECTION FOR COLLECTOR PIPE TO OUTLET PIPE • SUBDRAIN INSTALLATION - Subdrain collector pipe shall be installed with perforations down or, unless otherwise designated by the geotechnical consultant Outlet pipes shad be non-perforated pipe. The subdrain pipe shall have at least 8 perforations uniformly spaced per foot. Perforation shad be Vt to Vi1 if drilled holes are used. All subdrain pipes shall have a gradient at least 2% towards the outlet • SUBDRAIN PIPE - Subdrain pipe shall be ASTM D2751, SDR 23.5 or ASTM D1527, Schedule 40, or ASTM D3034, SDR 23.5, Schedule 40 Polyvinyl Chloride Plastic (PVC) pipe. • All outlet pipe shall be placed in a trench no wider than twice the subdrain pipe. Pipe shall be in soil of SE>30 jetted or flooded in place except for the outside 5 feet which shall be native soil backfill. BUTTRESS OR REPLACEMENT FILL SUBDRAINS GENERAL EARTHWORK AND GRADING SPECIFICATIONS STANDARD DETAILS D LU 4/95