The URL can be used to link to this page

Home My WebLink AboutSDP 2018-0020; 540 CHESTNUT AVE; GEOTECHNICAL INVESTIGATION PROPOSED RESIDENTIAL DEVELOPMENT 540 CHESTNUT AVENUE CARLSBAD, CA; 2020-02-25'5~ \7 . CTEL~,,, Construction Testing & Engineering, Inc. Inspection I leshng I Geotechnical I Environmental & Construction Engineering I Civil Engineering I Surveying RECORD COPY GEOTECHNICAL INVESTIGATION _______ I0'2a PROPOSED RESIDENTIAL DEVELOPM Initial Date 540 CHESTNUT AVENUE CARLSBAD, CALIFORNIA Prepared for: BG CONSOLIDATED, LLC C/O: DAVID CARRON 110 COPPERWOOD WAY SUITE P OCEANSIDE, CALIFORNIA 92056 Prepared by: CONSTRUCTION TESTING & ENGINEERING, INC. 1441 MONTIEL ROAD, SUITE 115 ESCONDIDO, CALIFORNIA 92026 kE CEIVED MAR 18 ZOZO LAND DEVELOPMENT ENGINEERING CTE JOB NO.: 10-13921S FEBRUARY 25, 2020 1441 Montiel Road, Suite 115 1 Escondido, CA 92026 1 Ph (760) 746-4955 1 Fax (760) 746-9806 1 www.cte-inc.net TABLE OF CONTENTS 1.0 INTRODUCTION AND SCOPE OF SERVICES ...................................................................1 1.1 Introduction...................................................................................................................1 1.2 Scope of Services..........................................................................................................1 2.0 SITE DESCRIPTION...............................................................................................................1 3.0 FIELD INVESTIGATION AND LABORATORY TESTING................................................2 3.1 Field Investigation........................................................................................................2 3.2 Laboratory Testing........................................................................................................3 4.0 GEOLOGY...............................................................................................................................3 4.1 General Setting .............................................................................................................3 4.2 Geologic Conditions .....................................................................................................3 4.2.1 Quaternary Undocumented Fill .....................................................................4 4.2.2 Residual Soil..................................................................................................4 4.2.3 Quaternary Old Paralic Deposits ...................................................................4 4.3 Groundwater Conditions...............................................................................................5 4.4 Geologic Hazards..........................................................................................................5 4.4.1 Surface Fault Rupture....................................................................................5 4.4.2 Local and Regional Faulting..........................................................................6 4.4.3 Liquefaction and Seismic Settlement Evaluation..........................................7 4.4.4 Tsunamis and Seiche Evaluation...................................................................8 4.4.5 Landsliding ....................................................................................................8 4.4.6 Compressible and Expansive Soils................................................................8 4.4.7 Corrosive Soils...............................................................................................9 5.0 CONCLUSIONS AND RECOMMENDATIONS .................................................................10 5.1 General........................................................................................................................10 5.2 Site Preparation...........................................................................................................10 5.3 Site Excavation...........................................................................................................12 5.4 Fill Placement and Compaction..................................................................................12 5.5 Fill Materials...............................................................................................................12 5.6 Temporary Construction Slopes .................................................................................13 5.7 Foundations and Slab Recommendations...................................................................14 5.7.1 Foundations..................................................................................................14 5.7.2 Foundation Settlement ............. . ................................................................... 16 5.7.3 Foundation Setback......................................................................................16 5.7.4 Interior Concrete Slabs ................................................................................16 5.8 Seismic Design Criteria..............................................................................................17 5.9 Lateral Resistance and Earth Pressures ......................................................................18 5.10 Exterior Flatwork......................................................................................................20 5.11 Vehicular Pavement..................................................................................................21 5.12 Drainage....................................................................................................................22 5.13 Slopes........................................................................................................................22 5.14 Controlled Low Strength Materials (CLSM)............................................................23 5.15 Plan Review .............................................................................................................. 24 5.16 Construction Observation.........................................................................................24 6.0 LIMITATIONS OF INVESTIGATION.................................................................................25 I FIGURES FIGURE 1 FIGURE 2 FIGURE 3 FIGURE 4 SITE LOCATION MAP GEOLOGIC/ EXPLORATION LOCATION MAP REGIONAL FAULT AND SEISMICITY MAP RETAINING WALL DRAINAGE DETAIL APPENDICES APPENDIX A APPENDIX B APPENDIX C APPENDIX D REFERENCES FIELD EXPLORATION METHODS AND BORING LOGS LABORATORY METHODS AND RESULTS STANDARD GRADING SPECIFICATIONS Geotechnical Investigation Page 1 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S 1.0 INTRODUCTION AND SCOPE OF SERVICES 1.1 Introduction Construction Testing and Engineering, Inc. (CTE) has completed a geotechnical investigation and report providing conclusions and recommendations for the proposed improvements at the subject site in Carlsbad, California. It is understood that the proposed improvements are to consist of three single-story structures with associated flatwork, utilities, landscaping and other minor improvements. CTE has performed this work in general accordance with the terms of proposal 034019S dated September 1, 2017. Preliminary geotechnical recommendations for excavations, fill placement, and foundation design for the proposed improvements are presented herein. 1.2 Scope of Services The scope of services provided included: Review of readily available geologic and soils reports. Coordination of USA mark-out and location. Excavation of exploratory borings and soil sampling utilizing limited-access manually operated drilling equipment Laboratory testing of selected soil samples. Description of the site geology and evaluation of potential geologic hazards. Engineering and geologic analysis. Preparation of this preliminary geotechnical report. 2.0 SITE DESCRIPTION The subject site is located at 540 Chestnut Avenue in Carlsbad, California (Figure 1). The site is bounded by Chestnut Avenue to the southeast, Tyler Street to the southwest, Roosevelt Street to the \ESC_SERVERWrojects\10-13000 to 10-13999 Projects\I0-13921S'.Rpt_Geotechnical.doc Geotechnical Investigation Page 2 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S northeast, and a residence to the northwest. The site layout is illustrated on Figure 2. The improvement area is currently an undeveloped lot with utilities. Based on reconnaissance and review of topography, the improvement area gradually descends to the southwest with elevations ranging from approximately 50 feet above mean sea level (msl) in the northeast to approximately 47 feet to the southwest. 3.0 FIELD INVESTIGATION AND LABORATORY TESTING 3.1 Field Investigation CTE performed the subsurface investigation on January 16, 2020 to evaluate underlying soil conditions. This fieldwork consisted of a site reconnaissance, and the excavation of two exploratory soil borings in representative areas. The borings were advanced with a limited-access manually operated auger that extended to a maximum explored depth of approximately 10.0 feet below ground surface (bgs). Bulk samples were collected from the cuttings. Approximate locations of the soil borings are shown on the attached Figure 2. Soils were logged in the field by a CTE Engineering Geologist, and were visually classified in general accordance with the Unified Soil Classification System. The field descriptions have been modified, where appropriate, to reflect laboratory test results. Boring logs, including descriptions of the soils encountered, are included in Appendix B. The approximate locations of the borings are presented on Figure 2. \\ESC_SERVER\Projects\10-I3000 to 10-13999 Projects\l0-13921SRpt_GeotechnicaI.doc Geotechnical Investigation Page 3 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S 3.2 Laboratory Testing Laboratory tests were conducted on selected soil samples for classification purposes, and to evaluate physical properties and engineering characteristics. Laboratory tests included: Expansion Index, Grain Size Analysis, and Chemical Characteristics. Test descriptions and laboratory test results are included in Appendix C. 4.0 GEOLOGY 4.1 General Setting Carlsbad is located within the Peninsular Ranges physiographic province that is characterized by northwest-trending mountain ranges, intervening valleys, and predominantly northwest trending regional faults. The greater San Diego Region can be further subdivided into the coastal plain area, a central mountain—valley area and the eastern mountain valley area. The project site is located within the coastal plain area that is characterized by Cretaceous, Tertiary, and Quaternary sedimentary deposits that onlap an eroded basement surface consisting of Jurassic and Cretaceous crystalline rocks. 4.2 Geologic Conditions Based on the regional geologic map prepared by Kennedy and Tan (2007), the near surface geologic unit that underlies the site consists of Quaternary Old Paralic Deposits, Unit 6-7. Based on recent explorations, Quaternary Undocumented Fill and Residual Soil were observed overlying the Old Paralic Deposits. Based on nearby sea cliff exposures, regional geologic map relationships, previous soil borings and known subsurface conditions in the site vicinity, we anticipate the Old Paralic \E5C_SERVERProjects\10-13000 to 10-13999 Projects\ 10- 1392 1 5'Rpt_Geotechnical.doc Geotechnical Investigation Page 4 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S Deposits are underlain by dense to very dense Eocene Santiago Formation materials at a depth of generally less than 40 feet beneath the site. Descriptions of the geologic and soil units encountered during the investigation are presented below. 4.2.1 Quaternary Undocumented Fill Where observed, the Undocumented Fill generally consists of loose, dark brown to reddish brown, silty fine to medium grained sand. Fills were observed to a maximum depth of approximately 3.3 feet bgs, although isolated areas of deeper fill may be encountered throughout the site during grading and construction. 4.2.2 Residual Soil Where observed, the Residual Soil generally consists of medium dense, dark brown, silty fine to medium grained sand. Exploratory excavations encountered Residual Soil to a maximum depth of approximately 4.5 feet (bgs). This unit is relatively thin and blankets the underlying Old Paralic Deposits. 4.2.3 Quaternary Old Paralic Deposits Quaternary Old Paralic Deposits were observed in both the borings. Where observed, these materials generally consist of medium dense, reddish brown, silty fme to medium grained sandstone that was encountered to the maximum explored depth. As indicated, the site area is underlain at depth by dense Eocene deposits. \ESC_SERVERWrojects\I 0-13000 to 10-13999 Projects\10-13921 S'Rpt_Geotechnical.doc Geotechnical Investigation Page 5 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S 4.3 Groundwater Conditions Groundwater was not observed in the recent site explorations, however, seepage was encountered at an approximate depth of 15 feet bgs at a nearby project on Pine Avenue. While groundwater conditions may vary, especially following periods of sustained precipitation or irrigation, it is not generally anticipated to adversely affect shallow construction activities or the completed improvements, if proper site drainage is designed, installed, and maintained as per the recommendations of the project civil engineer of record. If deeper excavations are proposed, groundwater may be encountered and would need to be addressed. 4.4 Geologic Hazards Geologic hazards considered to have potential impacts to site development were evaluated based on field observations, literature review, and laboratory test results. The following paragraphs discuss geologic hazards considered and associated potential risk to the site. 4.4.1 Surface Fault Rupture In accordance with the Aiquist-Priolo Earthquake Fault Zoning Act, (ACT), the State of California established Earthquake Fault Zones around known active faults. The purpose of the ACT is to regulate the development of structures intended for human occupancy near active fault traces in order to mitigate hazards associated with surface fault rupture. According to the California Geological Survey (Special Publication 42, Revised 2018), a fault that has had surface displacement within the last 11,700 years is defined as a Holocene- active fault and is either already zoned or pending zonation in accordance with the ACT. \\ESC_5ERVERProjects\10-13000 to 10-13999 Projects10-1392 15Rpt_Geotechnica1.doc Geotechnical Investigation Page 6 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S There are several other definitions of fault activity that are used to regulate dams, power plants, and other critical facilities, and some agencies designate faults that are documented as older than Holocene (last 11,700 years) and younger than late Quaternary (1.6 million years) as potentially active faults that are subject to local jurisdictional regulations. Based on the site reconnaissance and review of referenced literature, the site is not located within a local or State-designated Earthquake Fault Zone, no known active fault traces underlie or project toward the site, and no known potentially active fault traces project toward the site. Therefore fault surface rupture potential is considered to be low at the subject site. 4.4.2 Local and Regional Faulting The United States Geological Survey (USGS), with support of State Geological Surveys, and reviewed published work by various researchers, have developed a Quaternary Fault and Fold Database of faults and associated folds that are believed to be sources of earthquakes with magnitudes greater than 6.0 that have occurred during the Quaternary (the past 1.6 million years). The faults and folds within the database have been categorized into four Classes (Class A-D) based on the level of evidence confirming that a Quaternary fault is of tectonic origin and whether the structure is exposed for mapping or inferred from fault related deformational features. Class A faults have been mapped and categorized based on age of documented activity ranging from Historical faults (activity within last 150 years), Latest Quaternary faults (activity within last 15,000 years), Late Quaternary (activity within last 130,000 years), to Middle to late Quaternary (activity within last 1.6 million years). The \ESC_SERVERWrojects\I 0-13000 to 10-13999 Projects\ 10- 1392 1 SRpt_GeotechnicaI.doc Geotechnical Investigation Page 7 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S Class A faults are considered to have the highest potential to generate earthquakes and/or surface rupture, and the earthquake and surface rupture potential generally increases from oldest to youngest. The evidence for Quaternary deformation and/or tectonic activity progressively decreases for Class B and Class C faults. When geologic evidence indicates that a fault is not of tectonic origin it is considered to be a Class D structure. Such evidence includes joints, fractures, landslides, or erosional and fluvial scarps that resemble fault features, but demonstrate a non-tectonic origin. The nearest known Class A fault is the Newport-Inglewood-Rose Canyon fault zone (<1.6 million years), which is approximately 3.5 kilometers west of the site. The attached Figure 3 shows regional faults and seismicity with respect to the site. 4.4.3 Liquefaction and Seismic Settlement Evaluation Liquefaction occurs when saturated fine-grained sands or silts lose their physical strengths during earthquake-induced shaking and behave like a liquid. This is due to loss of point-to-point grain contact and transfer of normal stress to the pore water. Liquefaction potential varies with water level, soil type, material gradation, relative density, and probable intensity and duration of ground shaking. Seismic settlement can occur with or without liquefaction; it results from densification of loose soils. The site is underlain at shallow depths by medium dense Old Paralic Deposits. Based on the noted subsurface conditions, the potential for liquefaction or significant seismic settlement at the site is considered to be low. \\ESC_SERVERProjects\I 0-13000 to 10-13999 Projects\10-13921S\Rpt_Geotechnical.doc Geotechnical Investigation Page 8 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S 4.4.4 Tsunamis and Seiche Evaluation According to https://www.conservation.ca.gov/cgs/tsunanii/maps/san-diego the site is not located within a tsunami inundation zone based on its distance from the Pacific Ocean and elevation above sea level. Damage resulting from oscillatory waves (seiches) is considered unlikely due to the absence of large nearby confined bodies of water. 4.4.5 Landsliding According to mapping by Tan (1995), the site is considered "Marginally Susceptible" to landsliding, and no landslides are mapped in the site area. In addition, evidence of landslides or landslide potential was not observed during the field exploration at the relatively flat-lying site. Based on these findings, landsliding is not considered to be a significant geologic hazard at the subject site. 4.4.6 Compressible and Expansive Soils The near surface Undocumented Fill and Residual Soil encountered at the site are considered to be potentially compressible in their current condition. Therefore, it is recommended that these soils be overexcavated and properly compacted beneath proposed improvement areas as recommended herein and as determined to be necessary during construction. Based on the field data, site observations, and CTE's experience with similar soils in the vicinity of the site, medium dense native soils underlying the site are not considered to be subject to significant compressibility under the anticipated loads. \\ESC_SERVER\Projects\10-13000 to 10-13999 Projects\10. 1392 IS\Rpt_Geotechnical.doc Geotechnical Investigation Page 9 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S Based on the generally granular nature of the subgrade materials, soils at the site are anticipated to exhibit Very Low expansion potential (Expansion Index of 20 or less). Therefore, expansive soils are generally not anticipated to present significant adverse impacts to site development. Additional evaluation of near-surface soils should be performed based on field observations during grading and excavation activities. 4.4.7 Corrosive Soils Soil environments detrimental to concrete generally have elevated levels of soluble sulfates and/or pH levels less than 5.5. According to the American Concrete Institute (ACI) Table 318 4.3.1, specific guidelines have been provided for concrete where concentrations of soluble sulfate (SO4) in soil exceed 0.10 percent by weight. These guidelines include low water: cement ratios, increased compressive strength, and specific cement type requirements. A minimum resistivity value less than approximately 5,000 ohm-cm and/or soluble chloride levels in excess of 200 ppm generally indicate a corrosive environment for buried metallic utilities and untreated conduits. Based on representative area conditions, near-surface soils at the site are generally anticipated to present a negligible corrosion potential for Portland cement concrete. It is also interpreted that the site soils will have a low corrosive potential to buried metallic improvements. However, it would likely be prudent for buried utilities to utilize plastic piping and/or conduits, where feasible. However, CTE does not practice corrosion engineering. Therefore, if corrosion of improvements is of more significant concern, a \'ESC_SERVER'.Projects\10-I3000 to 10-13999 Projects\10- 139215\Rpt_Geotechnical.doc Geotechnical Investigation Page 10 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S qualified corrosion engineer could be consulted. Verification of corrosivity should be performed based on the results of the site specific testing. 5.0 CONCLUSIONS AND RECOMMENDATIONS 5.1 General CTE concludes that the proposed improvements on the site are feasible from a geotechnical standpoint, provided the preliminary recommendations in this report are incorporated into the design and construction of the project. Recommendations for the proposed earthwork and improvements are included in the following sections and Appendix D. However, recommendations in the text of this report supersede those presented in Appendix D should conflicts exist. These preliminary recommendations should either be confirmed as appropriate or updated following demolition of existing improvements and observations during site preparation. 5.2 Site Preparation Prior to grading, the site should be cleared of any existing construction debris and vegetation, not suitable for structural backfill and be properly disposed of offsite. Based on the presence of disturbed near surface soils overexcavation in areas to receive structures should extend to a minimum depth of two feet below proposed foundations or to the depth of competent Old Paralic Deposits, whichever is deeper. Overexcavation should extend laterally at least five feet beyond the limits of the proposed improvements, where feasible. \\ESC_SERVER\Projects\10-13000 to 10-13999 Projccts\ 10-13921S\Rpt_Geotechnical.doc Geotechnical Investigation Page 11 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S For other proposed improvements, such as pavement and hardscape areas, existing soils should be excavated to the depth of two feet below proposed grades, or to the depth of competent underlying materials, whichever is greater. If encountered, existing below-ground utilities should be redirected around proposed structures. Existing utilities at an elevation to extend through the proposed footings should generally be sleeved and caulked to minimize the potential for moisture migration below the building slabs. Abandoned pipes exposed by grading should be securely capped or filled with minimum two-sack cement/sand slurry to help prevent moisture from migrating beneath foundation and slab soils. Overexcavations adjacent to existing structures and property limits should generally not extend below a 1:1 plane extended down from the bottom of the existing footings or as recommended during grading based on the exposed conditions. Depending on the depth and proximity of the existing building footings, alternating slot excavations could be required in localized areas during earthwork. A CTE representative should observe the exposed ground surface prior to placement of compacted fill to document and verify the competency of the encountered subgrade materials. If unsuitable material is exposed at the base of excavations additional removals may be recommended. After approval by this office, the exposed subgrades to receive fill should be scarified a minimum of nine inches, moisture conditioned, and properly compacted prior to additional compacted fill placement. \ESC_SERVER\Projects\10-13000 to 10-13999 Projects\l0-139215Rpt_Geotechnical.doc Geotechnical Investigation Page 12 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921 S 5.3 Site Excavation Based on CTE's observations, shallow excavations at the site should be feasible using well- maintained heavy-duty construction equipment run by experienced operators. However, excavations within the Old Paralic Deposits could encounter zones that are sensitive to caving and/or erosion, and may not effectively remain standing vertical or near-vertical, even at shallow or minor heights and for short periods of time. 5.4 Fill Placement and Compaction Following the recommended overexcavation of loose or disturbed soils, the areas to receive fills should be scarified approximately nine inches, moisture conditioned, and properly compacted. Fill and backfill should be compacted to a minimum relative compaction of 90 percent at above optimum moisture content, as evaluated by ASTM D 1557. The optimum lift thickness for fill soil depends on the type of compaction equipment used. Generally, backfill should be placed in uniform, horizontal lifts not exceeding eight inches in loose thickness. Fill placement and compaction should be conducted in conformance with local ordinances, and should be observed and tested by a CTE geotechnical representative. 5.5 Fill Materials Properly moisture-conditioned very low to low expansion potential soils derived from the on-site excavations are considered suitable for reuse on the site as compacted fill. If used, these materials should be screened of organics and materials generally greater than three inches in maximum dimension. Irreducible materials greater than three inches in maximum dimension should generally \WSC_SERVER\Projccts\10-13000 to 10-13999 Projects\ 10- 1392 1 S\Rpt_Geotechnical.doc Geotechnical Investigation Page 13 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10- 13 92iS not be used in shallow fills (within three feet of proposed grades). In utility trenches, adequate bedding should surround pipes. Imported fill beneath structures, flatwork, and pavements should have an Expansion Index of 20 or less (ASTM D 4829). Proposed import fill soils for use in structural or slope areas should be evaluated by the geotechnical engineer before being transported to the site. If retaining walls are proposed, backfill located within a 45-degree wedge extending up from the heel of the wall should consist of soil having an Expansion Index of 20 or less (ASTM D 4829) with less than 30 percent passing the No. 200 sieve. The upper 12 to 18 inches of wall backfill should consist of lower permeability soils, in order to reduce surface water infiltration behind walls. The project structural engineer and/or architect should detail proper wall backdrains, including gravel drain zones, fills, filter fabric, and perforated drain pipes. However, a conceptual wall backdrain detail, which may be suitable for use at the site, is provided as Figure 4. 5.6 Temporary Construction Slopes The following recommended slopes should be relatively stable against deep-seated failure, but may experience localized sloughing. On-site soils are considered Type B and Type C soils with recommended slope ratios as set forth in Table 5.6. E5C_5ERVERWrojects\10-13000 to 10-13999 Projects\10-13921S'Rpt_Geotechnical.doc Geotechnical Investigation Page 14 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S - TABLE 5.6 RECOMMENDED TEMPORARY SLOPE RATIOS SOIL TYPE SLOPE RATIO MAXIMUM HEIGHT (Horizontal: vertical) B (Old Paralic Deposits) 1:1 (OR FLATTER) 5 Feet C (Undocumented Fill and 1.5:1 (OR FLATTER) 5 Feet Residual Soil) Actual field conditions and soil type designations must be verified by a "competent person" while excavations exist, according to Cal-OSHA regulations. In addition, the above sloping recommendations do not allow for surcharge loading at the top of slopes by vehicular traffic, equipment or materials. Appropriate surcharge setbacks must be maintained from the top of all unshored slopes. 5.7 Foundations and Slab Recommendations The following recommendations are for preliminary design purposes only. These foundation recommendations should be re-evaluated after review of the project grading and foundation plans, and after completion of rough grading of the building pad areas. Upon completion of rough pad grading, Expansion Index of near surface soils should be verified, and these recommendations should be updated, if necessary. 5.7.1 Foundations Foundation recommendations presented herein are based on the anticipated very low to low expansion potential of site soils (Expansion Index of 50 or less). \ESC_SERVER\Projects\I 0-13000 to 10-13999 Projects\10-13921 S\Rpt_Geotechnical.doc Geotechnical Investigation Page 15 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S Following the recommended preparatory grading, continuous and isolated spread footings are anticipated to be suitable for use at this site. Foundation dimensions and reinforcement should be based on allowable bearing values of 2,000 pounds per square foot (psf) for minimum 15-inch wide footings embedded a minimum of 18-inches below lowest adjacent subgrade elevation. Isolated footings should be at least 24 inches in minimum dimension. The allowable bearing value may be increased by one-third for short-duration loading, which includes the effects of wind or seismic forces. Based on the recommended preparatory grading, it is anticipated that all footings will be founded entirely in properly compacted fill materials. Footings should not span cut to fill interfaces. Minimum reinforcement for continuous footings should consist of four No. 5 reinforcing bars; two placed near the top and two placed near the bottom, or as per the project structural engineer. The structural engineer should design isolated footing reinforcement. An uncorrected subgrade modulus of 130 pounds per cubic inch is considered suitable for elastic foundation design. The structural engineer should provide recommendations for reinforcement of any spread footings and footings with pipe penetrations. Footing excavations should generally be maintained above optimum moisture content until concrete placement. \ESC_SERVERProjects\10613000 to 10-13999 Projects\10-13921S'tRpt_Geotechnical.doc Geotechnical Investigation Page 16 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S 5.7.2 Foundation Settlement The maximum total static settlement is expected to be on the order of one inch and the maximum differential settlement is expected to be on the order of 0.5 inch over a distance of 40 feet. Due to the generally dense nature of underlying materials, dynamic settlement is not expected to adversely affect the proposed buildings. 5.7.3 Foundation Setback Footings for structures should be designed such that the horizontal distance from the face of adjacent slopes to the outer edge of the footing is at least 10 feet.. In addition, footings should bear beneath a 1:1 plane extended up from the nearest bottom edge of adjacent trenches and/or excavations. Deepening of affected footings may be a suitable means of attaining the prescribed setbacks. 5.7.4 Interior Concrete Slabs Lightly loaded concrete slabs should be a minimum of 4.5 inches thick. Minimum slab reinforcement should consist of #4 reinforcing bars placed on maximum 18-inch centers, each way, at or above mid-slab height, but with proper cover. More stringent recommendations per the project structural engineer could be provided. In moisture-sensitive floor areas, a suitable vapor retarder of at least 15-mil thickness (with all laps or penetrations sealed or taped) overlying a four-inch layer of consolidated aggregate base or gravel (with SE of 30 or more) should be installed. An optional maximum two-inch layer of similar material may be placed above the vapor retarder to help protect the \\ESC_SERVER'tProjects\10- 13000 to 10.13999 Projects\l0-13921SRpt_GeotechnicaI.doc Geotechnical Investigation Page 17 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S membrane during steel and concrete placement. This recommended protection is generally considered typical in the industry. If proposed floor areas or coverings are considered especially sensitive to moisture emissions, additional recommendations from a specialty consultant could be obtained. CTE is not an expert at preventing moisture penetration through slabs. A qualified architect or other experienced professional should be contacted if moisture penetration is a more significant concern. Slabs subjected to heavier loads may require thicker slab sections and/or increased reinforcement. A 110-pci subgrade modulus is considered suitable for elastic design of minimally embedded improvements such as slabs-on-grade. Subgrade materials should be maintained or brought to a minimum of two percent or greater above optimum moisture content until slab underlayment and concrete are placed. 5.8 Seismic Design Criteria The seismic ground motion values listed in the table below were derived in accordance with the ASCE 7-16 Standard that is incorporated into the 2019 California Building Code. This was accomplished by establishing the Site Class based on the underlying soil properties at the site, and calculating site coefficients and parameters using the using the SEAOC-OSHPD U.S. Seismic Design Maps application. Seismic ground motion values are based on the approximate site coordinates of 33.1556° latitude and -117.3446° longitude. These values are intended for the design of structures to resist the effects of earthquake ground motions. \\ESC_SERVERProjects\10-1 3000 to 10-13999 Projects\10-13921SRpt_Geotechnica1.doc Geotechnical Investigation Page 18 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S TABLE 5.8 . SEISMIC GROUND MOTION VALUES (CODE-BASED)• - - PARAMETER - - 2019 CBC AND ASCE 7-16. VALUE 2019 CBC/ASCE 7-16 REFERENCE Site Class C ASCE 16, Chapter 20 Mapped Spectral Response 1.081 Figure 1613.2.1 (1) Acceleration Parameter, S Mapped Spectral Response 0.391 Figure 1613.2.1 (2) Acceleration Parameter, S1 Seismic Coefficient, F. 1.2 Table 1613.2.3 (1) Seismic Coefficient, F 1.5 Table 1613.2.3 (2) MCE Spectral Response 1.298 Section 16 13.2.3 Acceleration Parameter, SMS MCE Spectral Response 0.586 Section 1613.2.3 Acceleration Parameter, SMI Design Spectral Response 0.865 Section 1613.2.5(l) Acceleration, Parameter SDS Design Spectral Response 0.391 Section 16 13.2.5 (2) Acceleration, Parameter 5D1 Peak Ground Acceleration PGAM 0.573 ASCE 16, Section 11.8.3 5.9 Lateral Resistance and Earth Pressures Lateral loads acting against structures may be resisted by friction between the footings and the supporting soil or passive pressure acting against structures. If frictional resistance is used, allowable coefficients of friction of 0.30 (total frictional resistance equals the coefficient of friction multiplied by the dead load) for concrete cast directly against compacted fill is recommended. A design passive resistance value of 250 pounds per square foot per foot of depth (with a maximum value of 2,000 pounds per square foot) may be used. The allowable lateral resistance can be taken as the sum of the frictional resistance and the passive resistance, provided the passive resistance does not exceed two-thirds of the total allowable resistance. \ESC_SERVERProjects\10-13000 to 10-13999 Projects\10-13921 S\Rpt_Geotechnical.doc Geotechnical Investigation Page 19 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. lo-13921S If proposed, retaining walls backfihled using granular soils may be designed using the equivalent fluid unit weights given in Table 5.9 below. TABLE 5.9 EQUIVALENT FLUID UNIT WEIGHTS (Gh) (pounds per cubic foot) SLOPE BACKFILL WALL TYPE LEVEL BACKFILL 2:1 (HORIZONTAL: VERTICAL) CANTILEVER WALL 35 55 (YIELDING) RESTRAINED WALL 55 65 Lateral pressures on cantilever retaining walls (yielding walls) over six feet high due to earthquake motions may be calculated based on work by Seed and Whitman (1970). The total lateral earth pressure against a properly drained and backfilled cantilever retaining wall above the groundwater level can be expressed as: PAE = PA + APAE For non-yielding (or "restrained") walls, the total lateral earth pressure may be similarly calculated based on work by Wood (1973): PKE = PK + APKE Where PA/b = Static Active Earth Pressure = GhH2/2 PK/b = Static Restrained Wall Earth Pressure = GhH2/2 APAFJb = Dynamic Active Earth Pressure Increment = (3/8) kh yH2/2 APKE/b = Dynamic Restrained Earth Pressure Increment = kh yH2/2 b = unit length of wall (usually 1 foot) kh = 2/3 PGA.. (PGAm given previously Table 5.8) \\ESC_SERVERProjects\10-13000 to 10-13999 Projects\ 10- 13921 S'.Rpt_Geotechnical.doc Geotechnical Investigation Page 20 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S Oh = Equivalent Fluid Unit Weight (given previously Table 5.9) H = Total Height of the retained soil = Total Unit Weight of Soil 135 pounds per cubic foot The static and increment of dynamic earth pressure in both cases may be applied with a line of action located at H/3 above the bottom of the wall (SEAOC, 2013). These values assume non-expansive backfill and free-draining conditions. Measures should be taken to prevent moisture buildup behind all retaining walls. Drainage measures should include free- draining backfill materials and sloped, perforated drains. These drains should discharge to an appropriate off-site location. Figure 4 shows a conceptual wall backdrain detail that may be suitable for walls at the subject site. Any waterproofing should be as specified by the project architect. 5.10 Exterior Flatwork Flatwork should be installed with crack-control joints at appropriate spacing as designed by the project architect to reduce the potential for cracking in exterior flatwork caused by minor movement of subgrade soils and concrete shrinkage. Additionally, it is recommended that flatwork be installed with at least number 4 reinforcing bars at 24-inch centers, each way, at or above mid-height of slab, but with proper concrete cover, or with other reinforcement per the applicable project designer. Flatwork that should be installed with crack control joints, includes driveways, sidewalks, and architectural features. All subgrades should be prepared according to the earthwork recommendations previously given before placing concrete. Positive drainage should be established and maintained next to all flatwork. Subgrade materials should be maintained at a minimum of two percent above optimum moisture content before concrete placement. \\ESC_SERVER'Projects\l 0-13000 to 10-13999 Projects\ 10- 1392 1 SRpt_Geotechnica1.doc Geotechnical Investigation Page 21 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S 5.11 Vehicular Pavement The proposed improvements include paved vehicle drive and parking areas. Presented in Table 5.11 are preliminary pavement sections utilizing estimated Resistance "R" Value and traffic index. The upper 12 inches of subgrade and all base materials should be compacted to 95% relative compaction in accordance with ASTM D1557, and at a minimum of two percent above optimum moisture content. TABLE 5.11 RECOMMENDED PAVEMENT THICKNESS Traffic Area Assumed Preliminary Asphalt Pavements Portland Cement Traffic Index Subgrade Concrete AC Class II "R"-Value Thickness Aggregate Base Pavements, on (inches) Thickness Subgrade Soils (inches) (inches) Automobile 5.0 30+ 3.0 6.0 6.5 Parking Areas * Caltrans class 2 aggregate base ** Concrete should have a modulus of rupture of at least 600 psi During or following rough site grading, CTE recommends laboratory testing at-grade soils for as- graded "R"-Value. Asphalt paved areas should be designed, constructed, and maintained in accordance with the recommendations of the Asphalt Institute, or other widely recognized authority. Concrete paved areas should be designed and constructed in accordance with the recommendations of the American Concrete Institute or other widely recognized authority, particularly with regard to thickened edges, \E5C_SERVERProjects\10-13000 to 10-13999 Projects\10-139215Rpt_Geotechnica1.doc Geotechnical Investigation Page 22 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S joints, and drainage. The Standard Specifications for Public Works construction ("Greenbook") or Caltrans Standard Specifications may be referenced for pavement materials specifications. 5.12 Drainage Surface runoff should be collected and directed away from improvements by means of appropriate erosion-reducing devices and positive drainage should be established around the proposed improvements. Positive drainage should be directed away from improvements at a gradient of at least two percent for a distance of at least five feet. However, the project civil engineers should evaluate the on-site drainage and make necessary provisions to keep surface water from affecting the site. Generally, CTE recommends against allowing water to infiltrate building pads or adjacent to slopes. CTE understands that some agencies are encouraging the use of storm-water cleansing devices. Use of such devices tends to increase the possibility of adverse effects associated with high groundwater including slope instability and liquefaction. 5.13 Slopes The site is generally flat and no significant slopes were observed. Based on anticipated soil strength characteristics, fill slopes if proposed, should be constructed at slope ratios of 2:1 (horizontal: vertical) or flatter. These fill slope inclinations should exhibit factors of safety greater than 1.5. \\ESC_SERVER\Projects\l 0-13000 to 10-13999 Projects\ 10- 1392 1 SRpt_Geotechnica1.doc Geotechnical Investigation Page 23 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S Although properly constructed slopes on this site should be grossly stable, the soils will be somewhat erodible. Therefore, runoff water should not be permitted to drain over the edges of slopes unless that water is confined to properly designed and constructed drainage facilities. Erosion-resistant vegetation should be maintained on the face of all slopes. Typically, soils along the top portion of a fill slope face will creep laterally. CTE recommends against building distress-sensitive hardscape improvements within five feet of slope crests. 5.14 Controlled Low Strength Materials (CLSM) Controlled Low Strength Materials (CLSM) may be used in lieu of compacted soils below foundations, within building pads, and/or adjacent to retaining walls or other structures, provided the appropriate following recommendations are also incorporated. Minimum overexcavation depths recommended herein beneath bottom of footings, slabs, flatwork, and other areas may be applicable beneath CLSM if/where CLSM is to be used, and excavation bottoms should be observed by CTE prior to placement of CLSM. Prior to CLSM placement, the excavation should be free of debris, loose soil materials, and water. Once specific areas to utilize CLSM have been determined, CTE should review the locations to determine if additional recommendations are appropriate. CLSM should consist of a minimum three-sack cement/sand slurry with a minimum 28-day compressive strength of 100 psi (or equal to or greater than the maximum allowable short term soil bearing pressure provided herein, whichever is higher) as determined by ASTM D4832. If re- excavation is anticipated, the compressive strength of CLSM should generally be limited to a maximum of 150 psi per ACI 229R-99. Where re-excavation is required, two-sack cement/sand \\ESC_SERVERProjects10-13000 to 10-13999 Projects\10-1392 1 S\Rpt_Geotechnical.doc Geotechnical Investigation Page 24 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S slurry may be used to help limit the compressive strength. The allowable soils bearing pressure and coefficient of friction provided herein should still govern foundation design. CLSM may not be used in lieu of structural concrete where required by the structural engineer. 5.15 Plan Review CTE should be authorized to review the project grading and foundation plans prior to commencement of earthwork in order to provide additional recommendations, if necessary. 5.16 Construction Observation The recommendations provided in this report are based on preliminary design information for the proposed construction and the subsurface conditions observed in the soil borings. The interpolated subsurface conditions should be checked by CTE during construction with respect to anticipated conditions. Upon completion of precise grading, if necessary, soil samples will be collected to evaluate as-built Expansion Index. Foundation recommendations may be revised upon completion of grading, and as-built laboratory tests results. Additionally, soil samples should be taken in pavement subgrade areas upon rough grading to refme pavement recommendations as necessary. Recommendations provided in this report are based on the understanding that CTE will provide the observation and testing services for the project. All earthwork should be observed and tested in accordance with recommendations contained within this report. CTE should evaluate footing excavations before reinforcing steel placement. \ESC_SERVERWrojects\10-13000 to 10-13999 Projects\10- 13921 SRpt_GeotechnicaI.doc Geotechnical Investigation Page 25 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S 6.0 LIMITATIONS OF INVESTIGATION The field evaluation, laboratory testing and geotechnical analysis presented in this report have been conducted according to current engineering practice and the standard of care exercised by reputable geotechnical consultants performing similar tasks in this area. No other warranty, expressed or implied, is made regarding the conclusions, recommendations and opinions expressed in this report. Variations may exist and conditions not observed or described in this report may be encountered during construction. This report is prepared for the project as described. It is not prepared for any other property or party. The recommendations provided herein have been developed in order to reduce the post-construction movement of site improvements. However, even with the design and construction recommendations presented herein, some post-construction movement and associated distress may occur. The findings of this report are valid as of the present date. However, changes in the conditions of a property can occur with the passage of time, whether they are due to natural processes or the works of man on this or adjacent properties. In addition, changes in applicable or appropriate standards may occur, whether they result from legislation or the broadening of knowledge. Accordingly, the findings of this report may be invalidated wholly or partially by changes outside CTE's involvement. Therefore, this report is subject to review and should not be relied upon after a period of three years. E5C_5ERVER\Projects\10-13000 to 10-13999 Projects\ 10- 13921 SRpt_Geotechnica1.doc ((C No.1890 cERliFlED..% OGNEERING cEOLOQST*\F 5 /.1/,1 Geotechnical Investigation Page 26 Proposed Residential Improvements 540 Chestnut Avenue February 25, 2020 CTE Job No. 10-13921S CTE's conclusions and recommendations are based on an analysis of the observed conditions. If conditions different from those described in this report are encountered, CTE should be notified and additional recommendations, if required, will be provided subject to CTE remaining as authorized geotechnical consultant of record. This report is for use of the project as described. It should not be utilized for any other project. CTE's conclusions and recommendations are based on an analysis of the observed conditions. If conditions different from those described in this report are encountered during construction, this office should be notified and additional recommendations, if required, will be provided. CTE appreciate this opportunity to be of service on this project. If you have any questions regarding this report, please do not hesitate to contact the undersigned. Respectfully submitted, CONSTRUCTION TESTING & ENGINEERING, INC. ESSI (N:266 Dan T. Math, GE #2665 12/3h/ ) Principal Engineer 4 Aaron J. BLy, CEG 1101 #2603 Ii Project Geologist N~4,~,Z—FC~XVV DTM/JFL/AJB :ack Jay F. Lynch, CEG #1890 Principal Engineering Geologist No.2603 CERTIFIED ENGINEERING \\ESC_SERVER\Projects\1O-13000 to 10-13999 Projects10-13921 S\Rpt_Geotechnical.doc st Western Plus aci View L. Dns Bistro (y. \ - I e - - - A V -- p / o i d -el 4- :- df 01 OA Ca -: ts\10-1 3000 to 10-13999 Projects \10-139215\Figure 2. 12 0 6 12 Fill \ LEGEND 095 / 1 Inch • a. 49 " --- HISTORIC FAULT DISPLACEMENT (LAST 200 YEARS) _- 0 -. t ____--------•--• HOLOCENE FAULT DISPLACEMENT (DURING PAST 11,700 YEARS) Ee 46 LATE QUATERNARY FAULT DISPLACMENT (DURING PAST 700,000 YEARS) < - QUATERNARY FAULT DISPLACEMENT (AGE UNDIFFERENTIATED) \ . go, PREQUATERNARY FAULT DISPLACEMENT (OLDER THAN 1 6 MILLION YEARS) '1,1 It g 93 40 t! J73 1800- 1869- 1932- PERIOD 1868 1931 2010 CREEp" ' 1 7.0 1r: 6569 0 0 - __ \ _/ IQ ) 05.0-5.40 0 / - / \ ( LAST TWO DIGITS OF M>6 5 EARTHQUAKE YEAR ' S 5- - \ - . AJIROXIMA'I',1 ° SIll I OC A 1I( ) N ( 9 p \ / 1 JJ-4 N P- - - - •. - 99 fu 7 Do t I ITO ( \\\ \ \CREEP I , I . - : , '' , 5C7 5. if 95 - 0 171A S S NOTES: FAULT ACTIVITY MAP OF CALIFORNIA, 2010, CALIFORNIA GEOLOGIC DATA MAP SERIES MAP NO. 6; REGIONAL FAULT AND SEISMICITY MAP CTE X N1O139215 EPICENTERS OF AND AREAS DAMAGED BY M>5 CALIFORNIA EARTHQUAKES, 1800-1999 ADAPTED \\ Construction Testing & Engineering, Inc. AFTER TOPPOZADA, BRANUM, PETERSEN, HAILSTORM, CRAMER, AND REICHLE, 2000, CTE Tf ' PROPOSED RESIDENTIAL DEVELOPMENT 1 inch = 12 miles CDHG MAP SHEET 49 i1VL_,. 1441 Montiel Rd Ste 115, Escondido, CA 92026 Ph (760)746-4955 540 CHESTNUT AVENUE DATE REFERENCE FOR ADDITIONAL EXPLANATION; MODIFIED WITH CISN AND USGS SEISMIC MAPS CARLSBAD, CALIFORNIA 2/20 3 12" TO 18" OF LOWER PERMEABILITY NATIVE MATERIAL COMPACTED TO 90% RELATIVE COMPACTION RETAINING W FINISH GRADE I, V I ,4 I. L I& • 44 I' o' > I& S Ill b4 p a. * p Afy p > & S • &p p••• > C • p 90 ACTION I ij INGTOBE ARCHITECT 4DIA. PERFORATED PVC IPE (SCHEDULE 40 OR EQUIVALENT). MINIMUM 1% GRADIENT TO SUITABLE OUTLET WALL FOOTING APPENDIX A REFERENCES REFERENCES American Society for Civil Engineers, 2016, "Minimum Design Loads for Buildings and Other Structures," ASCE/SEI 7-16. ASTM, 2002, "Test Method for Laboratory Compaction Characteristics of Soil Using Modified Effort," Volume 04.08 Blake, T.F., 2000, "EQFAULT," Version 3.00b, Thomas F. Blake Computer Services and Software. California Building Code, 2019, "California Code of Regulations, Title 24, Part 2, Volume 2 of 2," California Building Standards Commission, published by ICBO, June. California Division of Mines and Geology, CD 2000-003 "Digital Images of Official Maps of Alquist-Priolo Earthquake Fault Zones of California, Southern Region," compiled by Martin and Ross. California Emergency Management Agency/California Geological Survey, "Tsunami Inundation Maps for Emergency Planning." Hart, Earl W., Revised 1994, Revised 2018, "Fault-Rupture Hazard Zones in California, Alquist Priolo, Special Studies Zones Act of 1972," California Division of Mines and Geology, Special Publication 42. Jennings, Charles W., 1994, "Fault Activity Map of California and Adjacent Areas" with Locations and Ages of Recent Volcanic Eruptions. Kennedy, M.P. and Tan, S.S., 2007, "Geologic Map of the Oceanside 30'x 60' Quadrangle, California", California Geological Survey, Map No. 2. Reichie, M., Bodin, P., and Brune, J., 1985, The June 1985 San Diego Bay Earthquake swarm [abs]: EOS, v. 66, no. 46, p.952. Seed, H.B., and R.V. Whitman, 1970, "Design of Earth Retaining Structures for Dynamic Loads," in Proceedings, ASCE Specialty Conference on Lateral Stresses in the Ground and Design of Earth-Retaining Structures, pp. 103-147, Ithaca, New York: Cornell University. Tan, S. S., and Giffen, D. G., 1995, "Landslide Hazards in the Northern Part of the San Diego Metropolitan Area, San Diego County, California: Oceanside and San Luis Rey Quadrangles, Landslide Hazard Identification Map No. 35", California Department of Conservation, Division of Mines and Geology, Open-File Report 95-04, State of California, Division of Mines and Geology, Sacramento, California. Wood, J.H. 1973, Earthquake-Induced Soil Pressures on Structures, Report EERL 73-05. Pasadena: California Institute of Technology. APPENDIX B EXPLORATION LOGS Construction Testing & Engineering, Inc. CrE imè. 1441 MontielRd Ste 115,Escondido, CA 92026 Ph (760) 746-4955 DEFINITION OF TERMS PRIMARY DIVISIONS SYMBOLS SECONDARY DIVISIONS GRAVELS CLEAN 4 (3W WELL GRADED GRAVELS, GRAVEL-SAND MIXTURES MORE THAN GRAVELS LITTLE OR NO FINES -.—L .z; GP POORLY GRADED GRAVELS OR GRAVEL SAND MIXTURES, Z HALF OF <5% FINES —' u COARSE LITTLE OF NO FINES GRAVELS GM SILTY GRAVELS, GRAVEL-SAN D-SILT MIXTURES, Oo -w N LL. FRACTION IS —J W co LARGER THAN NO.4 SIEVE WITH FINES NON-PLASTIC FINES . GC , CLAYEY GRAVELS, GRAVEL-SAND-CLAY MIXTURES, Z W PLASTIC FINES SANDS CLEAN :::: w .:C WELL GRADED SANDS, GRAVELLY SANDS, LITTLE OR NO W <c'i 0 MORE THAN HALF OF SANDS <5% FINES FINES - -. SP POORLY GRADED SANDS, GRAVELLY SANDS, LITTLE OR <O WZ02 COARSE NO FINES I(Il SILTY SANDS, SAND-SILT MIXTURES, NON-PLASTIC FINES o FRACTION IS SMALLER THAN NO.4 SIEVE SANDS WITH FINES , sc CLAYEY SANDS, SAND-CLAY MIXTURES, PLASTIC FINES W I I 1I,1,1.I1k I ML I I I INORGANIC SILTS, VERY FINE SANDS, ROCK FLOUR, SILTY SILTS AND CLAYS OR CLAYEY FINE SANDS, SLIGHTLY PLASTIC CLAYEY SILTS J.J.I..4J.I / CL INORGANIC CLAYS OF LOW TO MEDIUM PLASTICITY, -JO...j U) u- - Iij LIQUID LIMIT IS (I)> LESS THAN 50 / GRAVELLY, SANDY, SILTS OR LEAN CLAYS 1 iuIi ORGANIC SILTS AND ORGANIC CLAYS OF LOW PLASTICITY ZZ Lh O I U) 1h (MH II INORGANIC SILTS, MICACEOUS OR DIATOMACEOUS FINE ° w SILTS AND CLAYS SANDY OR SILTY SOILS. ELASTIC SILTS INORGANIC CLAYS OF HIGH PLASTICITY, FAT CLAYS wck: W Z z o z LIQUID LIMIT IS GREATER THAN 50 ORGANIC CLAYS OF MEDIUM TO HIGH PLASTICITY, ORGANIC SILTY CLAYS HIGHLY ORGANIC SOILS PEAT AND OTHER HIGHLY ORGANIC SOILS GRAIN SIZES BOULDERS COBBLES GRAVEL I SAND I I SILTS AND CLAYS COARSE I FINE I COARSE I MEDIUM I FINE 12" 3" 3/4" 4 10 40 200 CLEAR SQUARE SIEVE OPENING U.S. STANDARD SIEVE SIZE ADDITIONAL TESTS (OTHER THAN TEST PIT AND BORING LOG COLUMN HEADINGS) MAX- Maximum Dry Density PM- Permeability PP- Pocket Penetrometer OS- Grain Size Distribution SG- Specific Gravity WA- Wash Analysis SE- Sand Equivalent HA- Hydrometer Analysis DS- Direct Shear El- Expansion Index AL- Atterberg Limits UC- Unconfined Compression CHM- Sulfate and Chloride RV- R-Value MD- Moisture/Density Content, pH, Resistivity CN- Consolidation M- Moisture COR — Corrosivity CP- Collapse Potential SC- Swell Compression SD- Sample Disturbed HC- Hydrocollapse 01- Organic Impurities REM- Remolded FIGURE:I BL1 Construction Testing & Engineering, Inc. CTEi . 1441 Montiel Rd Ste 115, Escondido, CA 92026 Ph (760) 746-4955 PROJECT: DRILLER: SHEET: of CTE JOB NO: DRILL METHOD: DRILLING DATE: LOGGED BY: SAMPLE METHOD: ELEVATION: .2 E 0. I ' !° BORING LEGEND Laboratory Tests (I) 0 — .9 . • DESCRIPTION - - - Block or Chunk Sample - - - - - - - - Bulk Sample .5- - - - - - - Standard Penetration Test 10 - - - Modified Split-Barrel Drive Sampler (Cal Sampler) - - - - [ - - Thin Walled Army Corp. of Engineers Sample - - - 15 - - Groundwater Table - - ------------------------------------------------------------------------- - Soil Type or Classification Change 20 - Formation Change [(Approximate boundaries Queried (?)1 Quotes are placed around classifications where the soils 25 exist in situ as bedrock FIGURE: I BL2 Testing & Engineering, Inc. C Construction 1441 Montiel Rd Ste 115, Escondido, CA 92026 Ph (760) 746-4955 PROJECT: PROPOSED RESIDENTAL DEVELOPMENT DRILLER: BAJA EXPLORATION SHEET: 1 of CTE JOB NO: 540 CHESTNUT AVENUE DRILL METHOD: HOLLOW-STEM AUGER DRILLING DATE: 1/1612020 LOGGED BY: MB SAMPLE METHOD: RING, SET and BULK ELEVATION: -49 FEET -' - E I BORING: B-i Laboratory Tests '' • CL . a DESCRIPTION - - - - - QUATERNARY UNDOCUMENTED FILL: - Loose, moist, dark brown, silty fine to medium grained SAND. Becomes reddish brown - SM RESIDUAL SOIL: - Medium dense, moist, dark brown, silty fine to medium grained "SM' ', SAND. oxidized, massive. - GS QUATERNARY OLD PARALIC DEPOSITS: - Medium dense, moist, reddish brown, silty fine to medium grained SAND, oxidized, massive. - Fine gravel Medium dense, moist, reddish gray, poorly graded fine grained - SAND with silt, friable. - - - - - Total Depth: 10' No Groundwater Encountered -13 -26 -25 — — I B- 1 Construction Testing & Engineering, Inc. CTEI . 1441 Montiel Rd Ste 115, Escondido, CA 92026 Ph (760) 746-4955 PROJECT: PROPOSED RESIDENTAL DEVELOPMENT DRILLER: BAJA EXPLORATION SHEET: 1 of CTE JOB NO: 540 CHESTNUT AVENUE DRILL METHOD: HOLLOW-STEM AUGER DRILLING DATE: 1/16/2020 LOGGED BY: KB SAMPLE METHOD: RING, SPT and BULK ELEVATION: -49 FEET .3 B-2 I BORING: Laboratory Tests 'M to 2 U Q FQ 6 Vi a 0 DESCRIPTION - - - - - RESIDUAL SOIL: - Loose to medium dense, moist, dark brown, silty fine to medium cirained SAND. "SM" QUATERNARY OLD PARALIC DEPOSITS: - Medium dense, moist, reddish brown, silty fine to medium grained - SAND, oxidized, massive. El, CFIM - Total Depth: 5' No Groundwater Encountered -15 25 I B-2 APPENDIX C LABORATORY METHODS AND RESULTS LABORATORY METHODS AND RESULTS Laboratory Testing Program Laboratory tests were performed on representative soil samples to detect their relative engineering properties. . Tests were performed following test methods of the American Society for Testing Materials or other accepted standards. The following presents a brief description of the various test methods used. - Classification Soils were classified visually according to the Unified Soil Classification System. Visual classifications were supplemented by laboratory testing of selected samples according to ASTM D2487. The soil classifications are shown on the Exploration Logs in Appendix B. Expansion Index Expansion testing was performed on selected samples of the matrix of the on-site soils according to ASTM D 4829. Particle-Size Analysis Particle-size analyses were performed on selected representative samples according to ASTM D 422. Chemical Analysis Soil materials were collected with sterile sampling equipment and tested for Sulfate and Chloride content, pH, Corrosivity, and Resistivity. Construction Testing & Engineering, Inc. 1441 Montiel Rd Ste 115, Escondido, CA 92026 Ph (760) 746-4955 EXPANSION INDEX TEST ASTMD 4829 LOCATION DEPTH EXPANSION INDEX EXPANSION (feet) POTENTIAL B-2 0-5 0 VERY LOW SULFATE LOCATION DEPTH RESULTS (feet) ppm B-2 0-5 20.9 CHLORIDE LOCATION DEPTH RESULTS (feet) ppm B-2 0-5 2.7 ml LOCATION DEPTH RESULTS (feet) B-2 0-5 7.57 RESISTIVITY CALIFORNIA TEST 424 LOCATION DEPTH RESULTS (feet) ohms-cm B-2 0-5 23700 LABORATORY SUMMARY CIE JOB NO. 10-13921S .1JIIUhIIOIIIIIIiiiiIII 11111111 11111111 r.j111111_11111111_IIIIIlI_11111111_11111111 11111111 IliliHi ihuul 11111111 11111111 E'iuhhh'_11111111_11111111_11111111_11111111 111111 11111111 IIIIIIII 11111111 11111111 __ _____ ____ 11111111_11111111_IIIUhIi 11111111_11111111 JIIIIIII 11111111 HIIIIIILIIIIIIIl 11111111 J01'hl_11111111 11111111__1111111_11111111 11111111 11111111 1i11111 11111111 11111111 11111111 11111111 1111111$ 11111111 11111111 .fl;li[sILTh41 PARTICLE SIZE ANALYSIS Construction Testing & Engineer in g, Inc. 1441 Montiel Rd Ste 115, [.i Escondido,__ Appendix D Page D-1 Standard Specifications for Grading Section 1 - General Construction Testing & Engineering, Inc. presents the following standard recommendations for grading and other associated operations on construction projects. These guidelines should be considered a portion of the project specifications. Recommendations contained in the body of the previously presented soils report shall supersede the recommendations and or requirements as specified herein. The project geotechnical consultant shall interpret disputes arising out of interpretation of the recommendations contained in the soils report or specifications contained herein. Section 2 - Responsibilities of Project Personnel The geotechnical consultant should provide observation and testing services sufficient to general conformance with project specifications and standard grading practices. The geotechnical consultant should report any deviations to the client or his authorized representative. The Client should be chiefly responsible for all aspects of the project. He or his authorized representative has the responsibility of reviewing the findings and recommendations of the geotechnical consultant. He shall authorize or cause to have authorized the Contractor and/or other consultants to perform work and/or provide services. During grading the Client or his authorized representative should remain on-site or should remain reasonably accessible to all concerned parties in order to make decisions necessary to maintain the flow of the project. The Contractor is responsible for the safety of the project and satisfactory completion of all grading and other associated operations on construction projects, including, but not limited to, earth work in accordance with the project plans, specifications and controlling agency requirements. Section 3 - Preconstruction Meeting A preconstruction site meeting should be arranged by the owner and/or client and should include the grading contractor, design engineer, geotechnical consultant, owner's representative and representatives of the appropriate governing authorities. Section 4- Site Preparation The client or contractor should obtain the required approvals from the controlling authorities for the project prior, during and/or after demolition, site preparation and removals, etc. The appropriate approvals should be obtained prior to proceeding with grading operations. STANDARD SPECIFICATIONS OF GRADING Page 1 of 26 Appendix D Page D-2 Standard Specifications for Grading Clearing and grubbing should consist of the removal of vegetation such as brush, grass, woods, stumps, trees, root of trees and otherwise deleterious natural materials from the areas to be graded. Clearing and grubbing should extend to the outside of all proposed excavation and fill areas. Demolition should include removal of buildings, structures, foundations, reservoirs, utilities (including underground pipelines, septic tanks, leach fields, seepage pits, cisterns, mining shafts, tunnels, etc.) and other man-made surface and subsurface improvements from the areas to be graded. Demolition of utilities should include proper capping and/or rerouting pipelines at the project perimeter and cutoff and capping of wells in accordance with the requirements of the governing authorities and the recommendations of the geotechnical consultant at the time of demolition. Trees, plants or man-made improvements not planned to be removed or demolished should be protected by the contractor from damage or injury. Debris generated during clearing, grubbing and/or demolition operations should be wasted from areas to be graded and disposed off-site. Clearing, grubbing and demolition operations should be performed under the observation of the geotechnical consultant. Section 5 - Site Protection Protection of the site during the period of grading should be the responsibility of the contractor. Unless other provisions are made in writing and agreed upon among the concerned parties, completion of a portion of the project should not be considered to preclude that portion or adjacent areas from the requirements for site protection until such time as the entire project is complete as identified by the geotechnical consultant, the client and the regulating agencies. Precautions should be taken during the performance of site clearing, excavations and grading to protect the work site from flooding, ponding or inundation by poor or improper surface drainage. Temporary provisions should be made during the rainy season to adequately direct surface drainage away from and off the work site. Where low areas cannot be avoided, pumps should be kept on hand to continually remove water during periods of rainfall. Rain related damage should be considered to include, but may not be limited to, erosion, silting, saturation, swelling, structural distress and other adverse conditions as determined by the geotechnical consultant. Soil adversely affected should be classified as unsuitable materials and should be subject to overexcavation and replacement with compacted fill or other remedial grading as recommended by the geotechnical consultant. STANDARD SPECIFICATIONS OF GRADING Page 2 of 26 Appendix D Page D-3 Standard Specifications for Grading The contractor should be responsible for the stability of all temporary excavations. Recommendations by the geotechnical consultant pertaining to temporary excavations (e.g., backcuts) are made in consideration of stability of the completed project and, therefore, should not be considered to preclude the responsibilities of the contractor. Recommendations by the geotechnical consultant should not be considered to preclude requirements that are more restrictive by the regulating agencies. The contractor should provide during periods of extensive rainfall plastic sheeting to prevent unprotected slopes from becoming saturated and unstable. When deemed appropriate by the geotechnical consultant or governing agencies the contractor shall install checkdams, desilting basins, sand bags or other drainage control measures. In relatively level areas and/or slope areas, where saturated soil and/or erosion gullies exist to depths of greater than 1.0 foot; they should be overexcavated and replaced as compacted fill in accordance with the applicable specifications. Where affected materials exist to depths of 1.0 foot or less below proposed finished grade, remedial grading by moisture conditioning in-place, followed by thorough recompaction in accordance with the applicable grading guidelines herein may be attempted. If the desired results are not achieved, all affected materials should be overexcavated and replaced as compacted fill in accordance with the slope repair recommendations herein. If field conditions dictate, the geotechnical consultant may recommend other slope repair procedures. Section 6- Excavations 6.1 Unsuitable Materials Materials that are unsuitable should be excavated under observation and recommendations of the geotechnical consultant. Unsuitable materials include, but may not be limited to, dry, loose, soft, wet, organic compressible natural soils and fractured, weathered, soft bedrock and nonengineered or otherwise deleterious fill materials. Material identified by the geotechnical consultant as unsatisfactory due to its moisture conditions should be overexcavated; moisture conditioned as needed, to a uniform at or above optimum moisture condition before placement as compacted fill. If during the course of grading adverse geotechnical conditions are exposed which were not anticipated in the preliminary soil report as determined by the geotechnical consultant additional exploration, analysis, and treatment of these problems may be recommended. STANDARD SPECIFICATIONS OF GRADING Page 3 of 26 Appendix D Page D-4 Standard Specifications for Grading 6.2 Cut Slopes Unless otherwise recommended by the geotechnical consultant and approved by the regulating agencies, permanent cut slopes should not be steeper than 2:1 (horizontal: vertical). The geotechnical consultant should observe cut slope excavation and if these excavations expose loose cohesionless, significantly fractured or otherwise unsuitable material, the materials should be overexcavated and replaced with a compacted stabilization fill. If encountered specific cross section details should be obtained from the Geotechnical Consultant. When extensive cut slopes are excavated or these cut slopes are made in the direction of the prevailing drainage, a non-erodible diversion swale (brow ditch) should be provided at the top of the slope. 6.3 Pad Areas All lot pad areas, including side yard terrace containing both cut and fill materials, transitions, located less than 3 feet deep should be overexcavated to a depth of 3 feet and replaced with a uniform compacted fill blanket of 3 feet. Actual depth of overexcavation may vary and should be delineated by the geotechnical consultant during grading, especially where deep or drastic transitions are present. For pad areas created above cut or natural slopes, positive drainage should be established away from the top-of-slope. This may be accomplished utilizing a berm drainage swale and/or an appropriate pad gradient. A gradient in soil areas away from the top-of-slopes of 2 percent or greater is recommended. Section 7 - Compacted Fill All fill materials should have fill quality, placement, conditioning and compaction as specified below or as approved by the geotechnical consultant. 7.1 Fill Material Quality Excavated on-site or import materials which are acceptable to the geotechnical consultant may be utilized as compacted fill, provided trash, vegetation and other deleterious materials are removed prior to placement. All import materials anticipated for use on-site should be sampled tested and approved prior to and placement is in conformance with the requirements outlined. STANDARD SPECIFICATIONS OF GRADING Page 4 of 26 Appendix D Page D-5 Standard Specifications for Grading Rocks 12 inches in maximum and smaller may be utilized within compacted fill provided sufficient fill material is placed and thoroughly compacted over and around all rock to effectively fill rock voids. The amount of rock should not exceed 40 percent by dry weight passing the 3/4-inch sieve. The geotechnical consultant may vary those requirements as field conditions dictate. Where rocks greater than 12 inches but less than four feet of maximum dimension are generated during grading, or otherwise desired to be placed within an engineered fill, special handling in accordance with the recommendations below. Rocks greater than four feet should be broken down or disposed off-site. 7.2 Placement of Fill Prior to placement of fill material, the geotechnical consultant should observe and approve the area to receive fill. After observation and approval, the exposed ground surface should be scarified to a depth of 6 to 8 inches. The scarified material should be conditioned (i.e. moisture added or air dried by continued discing) to achieve a moisture content at or slightly above optimum moisture conditions and compacted to a minimum of 90 percent of the maximum density or as otherwise recommended in the soils report or by appropriate government agencies. Compacted fill should then be placed in thin horizontal lifts not exceeding eight inches in loose thickness prior to compaction. Each lift should be moisture conditioned as needed, thoroughly blended to achieve a consistent moisture content at or slightly above optimum and thoroughly compacted by mechanical methods to a minimum of 90 percent of laboratory maximum dry density. Each lift should be treated in a like manner until the desired finished grades are achieved. The contractor should have suitable and sufficient mechanical compaction equipment and watering apparatus on the job site to handle the amount of fill being placed in consideration of moisture retention properties of the materials and weather conditions. When placing fill in horizontal lifts adjacent to areas sloping steeper than 5:1 (horizontal: vertical), horizontal keys and vertical benches should be excavated into the adjacent slope area. Keying and benching should be sufficient to provide at least six-foot wide benches and a minimum of four feet of vertical bench height within the firm natural ground, firm bedrock or engineered compacted fill. No compacted fill should be placed in an area after keying and benching until the geotechnical consultant has reviewed the area. Material generated by the benching operation should be moved sufficiently away from STANDARD SPECIFICATIONS OF GRADING Page 5 of 26 Appendix D Page D-6 Standard Specifications for Grading the bench area to allow for the recommended review of the horizontal bench prior to placement of fill. Within a single fill area where grading procedures dictate two or more separate fills, temporary slopes (false slopes) may be created. When placing fill adjacent to a false slope, benching should be conducted in the same manner as above described. At least a 3-foot vertical bench should be established within the firm core of adjacent approved compacted fill prior to placement of additional fill. Benching should proceed in at least 3-foot vertical increments until the desired finished grades are achieved. Prior to placement of additional compacted fill following an overnight or other grading delay, the exposed surface or previously compacted fill should be processed by scarification, moisture conditioning as needed to at or slightly above optimum moisture content, thoroughly blended and recompacted to a minimum of 90 percent of laboratory maximum thy density. Where unsuitable materials exist to depths of greater than one foot, the unsuitable materials should be over-excavated. Following a period of flooding, rainfall or overwatering by other means, no additional fill should be placed until damage assessments have been made and remedial grading performed as described herein. Rocks 12 inch in maximum dimension and smaller may be utilized in the compacted fill provided the fill is placed and thoroughly compacted over and around all rock. No oversize material should be used within 3 feet of finished pad grade and within 1 foot of other compacted fill areas. Rocks 12 inches up to four feet maximum dimension should be placed below the upper 10 feet of any fill and should not be closer than 15 feet to any slope face. These recommendations could vary as locations of improvements dictate. Where practical, oversized material should not be placed below areas where structures or deep utilities are proposed. Oversized material should be placed in windrows on a clean, overexcavated or unyielding compacted fill or firm natural ground surface. Select native or imported granular soil (S.E. 30 or higher) should be placed and thoroughly flooded over and around all windrowed rock, such that voids are filled. Windrows of oversized material should be staggered so those successive strata of oversized material are not in the same vertical plane. It may be possible to dispose of individual larger rock as field conditions dictate and as recommended by the geotechnical consultant at the time of placement. STANDARD SPECIFICATIONS OF GRADING Page 6 of 26 Appendix D Page D-7 Standard Specifications for Grading The contractor should assist the geotechnical consultant and/or his representative by digging test pits for removal determinations and/or for testing compacted fill. The contractor should provide this work at no additional cost to the owner or contractor's client. Fill should be tested by the geotechnical consultant for compliance with the recommended relative compaction and moisture conditions. Field density testing should conform to ASTM Method of Test D 1556-00, D 2922-04. Tests should be conducted at a minimum of approximately two vertical feet or approximately 1,000 to 2,000 cubic yards of fill placed. Actual test intervals may vary as field conditions dictate. Fill found not to be in conformance with the grading recommendations should be removed or otherwise handled as recommended by the geotechnical consultant. 7.3 Fill Slopes Unless otherwise recommended by the geotechnical consultant and approved by the regulating agencies, permanent fill slopes should not be steeper than 2:1 (horizontal: vertical). Except as specifically recommended in these grading guidelines compacted fill slopes should be over-built two to five feet and cut back to grade, exposing the firm, compacted fill inner core. The actual amount of overbuilding may vary as field conditions dictate. If the desired results are not achieved, the existing slopes should be overexcavated and reconstructed under the guidelines of the geotechnical consultant. The degree of overbuilding shall be increased until the desired compacted slope surface condition is achieved. Care should be taken by the contractor to provide thorough mechanical compaction to the outer edge of the overbuilt slope surface. At the discretion of the geotechnical consultant, slope face compaction may be attempted by conventional construction procedures including backrolling. The procedure must create a firmly compacted material throughout the entire depth of the slope face to the surface of the previously compacted firm fill intercore. During grading operations, care should be taken to extend compactive effort to the outer edge of the slope. Each lift should extend horizontally to the desired finished slope surface or more as needed to ultimately established desired grades. Grade during construction should not be allowed to roll off at the edge of the slope. It may be helpful to elevate slightly the outer edge of the slope. Slough resulting from the placement of individual lifts should not be allowed to drift down over previous lifts. At intervals not STANDARD SPECIFICATIONS OF GRADING. Page 7 of 26 Appendix D Page D-8 Standard Specifications for Grading exceeding four feet in vertical slope height or the capability of available equipment, whichever is less, fill slopes should be thoroughly dozer trackrolled. For pad areas above fill slopes, positive drainage should be established away from the top-of-slope. This may be accomplished using a berm and pad gradient of at least two percent. Section 8 - Trench Backfill Utility and/or other excavation of trench backfill should, unless otherwise recommended, be compacted by mechanical means. Unless otherwise recommended, the degree of compaction should be a minimum of 90 percent of the laboratory maximum density. Within slab areas, but outside the influence of foundations, trenches up to one foot wide and two feet deep may be backfilled with sand and consolidated by jetting, flooding or by mechanical means. If on-site materials are utilized, they should be wheel-rolled, tamped or otherwise compacted to a firm condition. For minor interior trenches, density testing may be deleted or spot testing may be elected if deemed necessary, based on review of backfill operations during construction. If utility contractors indicate that it is undesirable to use compaction equipment in close proximity to a buried conduit, the contractor may elect the utilization of light weight mechanical compaction equipment and/or shading of the conduit with clean, granular material, which should be thoroughly jetted in-place above the conduit, prior to initiating mechanical compaction procedures. Other methods of utility trench compaction may also be appropriate, upon review of the geotechnical consultant at the time of construction. In cases where clean granular materials are proposed for use in lieu of native materials or where flooding or jetting is proposed, the procedures should be considered subject to review by the geotechnical consultant. Clean granular backfill and/or bedding are not recommended in slope areas. Section 9 - Drainage Where deemed appropriate by the geotechnical consultant, canyon subdrain systems should be installed in accordance with CTE's recommendations during grading. Typical subdrains for compacted fill buttresses, slope stabilization or sidehill masses, should be installed in accordance with the specifications. STANDARD SPECIFICATIONS OF GRADING Page 8 of 26 Appendix D Page D-9 Standard Specifications for Grading Roof, pad and slope drainage should be directed away from slopes and areas of structures to suitable disposal areas via non-erodible devices (i.e., gutters, downspouts, and concrete swales). For drainage in extensively landscaped areas near structures, (i.e., within four feet) a minimum of 5 percent gradient away from the structure should be maintained. Pad drainage of at least 2 percent should be maintained over the remainder of the site. Drainage patterns established at the time of fine grading should be maintained throughout the life of the project. Property owners should be made aware that altering drainage patterns could be detrimental to slope stability and foundation performance. Section 10 - Slope Maintenance 10.1 - Landscape Plants To enhance surficial slope stability, slope planting should be accomplished at the completion of grading. Slope planting should consist of deep-rooting vegetation requiring little watering. Plants native to the southern California area and plants relative to native plants are generally desirable. Plants native to other semi-arid and and areas may also be appropriate. A Landscape Architect should be the best party to consult regarding actual types of plants and planting configuration. 10.2 - Irrigation Irrigation pipes should be anchored to slope faces, not placed in trenches excavated into slope faces. Slope irrigation should be minimized. If automatic timing devices are utilized on irrigation systems, provisions should be made for interrupting normal irrigation during periods of rainfall. 10.3 - Repair As a precautionary measure, plastic sheeting should be readily available, or kept on hand, to protect all slope areas from saturation by periods of heavy or prolonged rainfall. This measure is strongly recommended, beginning with the period prior to landscape planting. If slope failures occur, the geotechnical consultant should be contacted for a field review of site conditions and development of recommendations for evaluation and repair. If slope failures occur as a result of exposure to period of heavy rainfall, the failure areas and currently unaffected areas should be covered with plastic sheeting to protect against additional saturation. STANDARD SPECIFICATIONS OF GRADING Page 9 of 26 Appendix D Page D-1O Standard Specifications for Grading. In the accompanying Standard Details, appropriate repair procedures are illustrated for superficial slope failures (i.e., occurring typically within the outer one foot to three feet of a slope face). STANDARD SPECIFICATIONS OF GRADING Page 10 of 26 BENCHING FILL OVER NATURAL SURFACE OF FIRM EARTH MATERIAL FILL SLOPE MIN M TLJ 10, TYPICAL 15' MIN. (INCLINED 2% MIN. INTO SLOPE) BENCHING FILL OVER CUT SURFACE OF FIRM EARTH MATERIAL FINISH FILL SLOPE FINISH CUT SLOPE 2% MIN 10, TYPICAL 15' MIN OR STABILITY EQUIVALENT PER SOIL ENGINEERING (INCLINED 2% MIN. INTO SLOPE) NOT TO SCALE BENCHING FOR COMPACTED FILL DETAIL STANDARD SPECIFICATIONS FOR GRADING Page 11 0f26 TOE OF SLOPE SHOWN ON GRADING PLAN FILL -. • 1Jç4' .01 10' TYPICAL BENCH WIDTH VARIES COMPETENT EARTH MATERIAL At 2% MIN MINIMUM _/ " 15' MINIMUM BASE KEY WIDTH DOWNSLOPE KEY DEPTH TYPICAL BENCH HEIGHT PROVIDE BACKDRAIN AS REQUIRED PER RECOMMENDATIONS OF SOILS ENGINEER DURING GRADING WHERE NATURAL SLOPE GRADIENT IS 5:1 OR LESS, BENCHING IS NOT NECESSARY. FILL IS NOT TO BE PLACED ON COMPRESSIBLE OR UNSUITABLE MATERIAL. NOT TO SCALE FILL SLOPE ABOVE NATURAL GROUND DETAIL STANDARD SPECIFICATIONS FOR GRADING Page 12 of 26 REMOVE ALL TOPSOIL, COLLUVIUM, AND CREEP MATERIAL FROM TRANSITION CUT/FILL CONTACT SHOWN ON GRADING PLAN FILL cn -I Z 0 CUT/FILL CONTACT SHOWN - an ON "AS-BUILT" C 'TYPICAL Cl) - 3 C) - NATURAL o TOPOGRAPHY - 2% MIN 10' TYPICAL CA)> z 15' MINIMUM 0) Ci') CUT SLOPE* BEDROCK OR APPROVED m 0 FOUNDATION MATERIAL C) > C Z *NOTE: CUT SLOPE PORTION SHOULD BE C) MADE PRIOR TO PLACEMENT OF FILL NOT TO SCALE FILL SLOPE ABOVE CUT SLOPE DETAIL j— SURFACE OF I COMPETENT MATERIAL ----------------- - ,1 COMPACTED FILL TYPICAL BENCHING REMOVE UNSUITABLE MATERIAL SEE DETAIL BELOW INCLINE TOWARD DRAIN AT 2% GRADIENT MINIMUM DETAIL MINIMUM 9 FT3 PER LINEAR FOOT MINIMUM 4" DIAMETER APPROVED OF APPROVED FILTER MATERIAL PERFORATED PIPE (PERFORATIONS DOWN) 6" FILTER MATERIAL BEDDING 14" MINIMUM CALTRANS CLASS 2 PERMEABLE MATERIAL FILTER MATERIAL TO MEET FOLLOWING SPECIFICATION OR APPROVED EQUAL: SIEVE SIZE PERCENTAGE PASSING 1" 100 3,4" 90-100 3%is 40-100 NO.4 25-40 NO.8 18-33 NO. 30 5-15 NO. 50 0-7 NO. 200 APPROVED PIPE TO BE SCHEDULE 40 POLY-VINYL-CHLORIDE (P.V.C.) OR APPROVED EQUAL. MINIMUM CRUSH STRENGTH 1000 psi PIPE DIAMETER TO MEET THE FOLLOWING CRITERIA, SUBJECT TO FIELD REVIEW BASED ON ACTUAL GEOTECHNICAL CONDITIONS ENCOUNTERED DURING GRADING LENGTH OF RUN PIPE DIAMETER INITIAL 500' 4" 500' TO 1500' 6" > 1500' 8" 0-3 NOT TO SCALE TYPICAL CANYON SUBDRAIN DETAIL STANDARD SPECIFICATIONS FOR GRADING Page 14 of 26 CANYON SUBDRAIN DETAILS ,- SURFACE OF / COMPETENT MATERIAL __)j COMPACTED FILL TYPICAL BENCHING '% '°•° Ole REMOVE UNSUITABLE MATERIAL SEE DETAILS BELOW INCLINE TOWARD DRAIN AT 2% GRADIENT MINIMUM TRENCH DETAILS 6" MINIMUM OVERLAP OPTIONAL V-DITCH DETAIL - MINIMUM 9 FPPER LINEAR FOOT OF APPROVED DRAIN MATERIAL MIRAFI 140N FABRIC OR APPROVED EQUAL MIRAFI 140N FABRIC OR APPROVED EQUAL 6" MINIMUM OVERLAP MINIMUM 24" MINIMUM 9 FT PER LINEAR FOOT OF APPROVED DRAIN MATERIAL 60° TO 90° APPROVED PIPE TO BE SCHEDULE 40 POLY- VINYLCHLORIDE (P.V.C.) OR APPROVED EQUAL. MINIMUM CRUSH STRENGTH 1000 PSI. DRAIN MATERIAL TO MEET FOLLOWING SPECIFICATION OR APPROVED EQUAL: SIEVE SIZE PERCENTAGE PASSING PIPE DIAMETER TO MEET THE FOLLOWING CRITERIA, SUBJECT TO FIELD REVIEW BASED ON ACTUAL GEOTECHNICAL CONDITIONS ENCOUNTERED DURING GRADING 1 Y2" 88-100 1" 5-40 3/411 0-17 0-7 NO. 200 0-3 LENGTH OF RUN INITIAL 500' 500' TO 1500' > 1500' NOT TO SCALE PIPE DIAMETER 4,' 6" 8" GEOFABRIC SUBDRAIN STANDARD SPECIFICATIONS FOR GRADING Page 15 of 26 FRONT VIEW ----- CONCRETE ,. 6" Mm. CUT-OFF WALL : •'.. ' • L L 'j) SUBDRAIN PIPE 6" Mm. 24" Mm. -I 6" Mm. SIDE VIEW 12" Mm. 6" Min. CONCRETE CUT-OFF WALL I_6"Mm. Q SOILD SUBDRAIN PIPE " PERFORATED SUBDRAIN PIPE NOT TO SCALE RECOMMENDED SUBDRAIN CUT-OFF WALL STANDARD SPECIFICATIONS FOR GRADING Page 16 of 26 FRONT VIEW . !0 _'. _ .. . .. . .. A ,. 24" Min. A • p. • - ._ ._ - I' •% % A -• - V . - V• ¼b..%b 'b. ' A • %.• 24" Mm. SUBDRAIN OUTLET PIPE (MINIMUM 4" DIAMETER) SIDE VIEW ALL BACKFILL SHOULD BE COMPACTED IN CONFORMANCE WITH PROJECT SPECIFICATIONS. COMPACTION EFFORT SHOULD NOT DAMAGE STRUCTURE CONCRETE HEADWALL - -. ''_. _V .'V . - 24" Mm. NOTE: HEADWALL SHOULD OUTLET AT TOE OF SLOPE OR INTO CONTROLLED SURFACE DRAINAGE DEVICE ALL DISCHARGE SHOULD BE CONTROLLED THIS DETAIL IS A MINIMUM DESIGN AND MAY BE MODIFIED DEPENDING UPON ENCOUNTERED CONDITIONS AND LOCAL REQUIREMENTS NOT TO SCALE TYPICAL SUBDRAIN OUTLET HEADWALL DETAIL STANDARD SPECIFICATIONS FOR GRADING Page 17 of 26 4" DIAMETER PERFORATED PIPE BACKDRAIN 4" DIAMETER NON-PERFORATED PIPE LATERAL DRAIN 15' MINIMUM SLOPE PER PLAN 2.0% FILTER MATERIAL - BENCHING H12 t2IMi M - lEfli: I I-r-rrI I ITIr AN ADDITIONAL BACKDRAIN AT MID-SLOPE WILL BE REQUIRED FOR SLOPE IN EXCESS OF 40 FEET HIGH. KEY-DIMENSION PER SOILS ENGINEER (GENERALLY 1/2 SLOPE HEIGHT, 15' MINIMUM) DIMENSIONS ARE MINIMUM RECOMMENDED NOT TO SCALE TYPICAL SLOPE STABILIZATION FILL DETAIL STANDARD SPECIFICATIONS FOR GRADING Page 18 of 26 15' MINIMUM 4" DIAMETER PERFORATED PIPE BACKDRAIN 4" DIAMETER NON-PERFORATED PIPE LATERAL DRAIN - - SLOPE PER PLAN 20% IH 1 FILTER MATERIAL = .1 BENCHING 1' 2'MI 2% MIN -HI I II I Ii I I-i 1 17 -- iii ADDITIONAL BACKDRAIN AT MID-SLOPE WILL BE REQUIRED k FOR SLOPE IN EXCESS OF 40 FEET HIGH. KEY-DIMENSION PER SOILS ENGINEER DIMENSIONS ARE MINIMUM RECOMMENDED NOT TO SCALE TYPICAL BUTTRESS FILL DETAIL STANDARD SPECIFICATIONS FOR GRADING Page 19 of 26 FINAL LIMIT OF DAYLIGHT EXCAVATION LINE FINISH PAD OVEREXCAVATE 3' AND REPLACE WITH COMPACTED FILL OVEREXCAVATE 20' MAXIMUM 2 COMPETENT BEDROCK kTAIIl 2' MINIMUM\ \ L. TYPICAL BENCHING OVERBURDEN \ \.._. LOCATION OF BACKDRAIN AND (CREEP-PRONE) \ OUTLETS PER SOILS ENGINEER \ AND/OR ENGINEERING GEOLOGIST \ DURING GRADING. MINIMUM 2% \ FLOW GRADIENT TO DISCHARGE \ LOCATION. EQUIPMENT WIDTH (MINIMUM 15') NOT TO SCALE DAYLIGHT SHEAR KEY DETAIL STANDARD SPECIFICATIONS FOR GRADING Page 20 of 26 NATURAL GROUND PROPOSED GRADING 01 / \ / / \- _i_/ / II, / 15/ -, 1.5 ly / COMPACTED FILL "WI' _ PROVIDE BACKDRAIN, PER BACKDRAIN DETAIL. AN ADDITIONAL BACKDRAIN AT MID-SLOPE WILL BE REQUIRED FOR BACK BASE WIDTH "W" DETERMINED SLOPES IN EXCESS OF BY SOILS ENGINEER 40 FEET HIGH. LOCATIONS OF BACKDRAINS AND OUTLETS PER SOILS ENGINEER AND/OR ENGINEERING GEOLOGIST DURING GRADING. MINIMUM 2% FLOW GRADIENT TO DISCHARGE LOCATION. NOT TO SCALE TYPICAL SHEAR KEY DETAIL STANDARD SPECIFICATIONS FOR GRADING Page 21 of 26 FINISH SURFACE SLOPE 3 FT3 MINIMUM PER LINEAR FOOT APPROVED FILTER ROCK* CONCRETE COLLAR PLACED NEAT COMPACTED FILL A 4" MINIMUM DIAMETER SOLID OUTLET PIPE SPACED PER SOIL ENGINEER REQUIREMENTS DURING GRADING TYPICAL BENCHING - 4" MINIMUM APPROVED PERFORATED PIPE** (PERFORATIONS DOWN) MINIMUM 2% GRADIENT TO OUTLET BENCH INCLINED TOWARD DRAIN DETAIL A-A TEMPORARY FILL LEVEL MINIMUM MINIMUM 4N DIAMETER APPROVED 12" COVE .L [// SOLID OUTLET PIPE ç MINIMUM *FILTER ROCK TO MEET FOLLOWING **APPROVED PIPE TYPE: SPECIFICATIONS OR APPROVED EQUAL: SCHEDULE 40 POLYVINYL CHLORIDE SIEVE SIZE PERCENTAGE PASSING (P.V.C.) OR APPROVED EQUAL. 1. 100 MINIMUM CRUSH STRENGTH 1000 PSI 90-100 40-100 NO.4 25-40 NO. 30 5-15 NO. 50 0-7 NO. 200 0-3 NOT TO SCALE TYPICAL BACKDRAIN DETAIL STANDARD SPECIFICATIONS FOR GRADING Page 22 of 26 FINISH SURFACE SLOPE MINIMUM 3 FT PER LINEAR FOOT OPEN GRADED AGGREGATE* TAPE AND SEAL AT COVER CONCRETE COLLAR PLACED NEAT COMPACTED FILL A MINIMUM 4" DIAMETER SOLID OUTLET PIPE SPACED PER SOIL ENGINEER REQUIREMENTS TYPICAL BENCHING II '- MIRAFI 140N FABRIC OR APPROVED EQUAL 4" MINIMUM APPROVED PERFORATED PIPE (PERFORATIONS DOWN) MINIMUM 2% GRADIENT TO OUTLET BENCH INCLINED TOWARD DRAIN DETAIL A-A TEMPORARY FILL LEVEL MINIMUM 12" COVER BACKFILL MINIMUM 4" DIAMETER APPROVED SOLID OUTLET PIPE 12" *NOTE: AGGREGATE TO MEET FOLLOWING SPECIFICATIONS OR APPROVED EQUAL: SIEVE SIZE PERCENTAGE PASSING 100 1" 5-40 3/4k 0-17 0-7 NOT TO SCALE NO. 200 0-3 BACKDRAIN DETAIL (GEOFRABIC) STANDARD SPECIFICATIONS FOR GRADING Page 23 of 26 FILL SLOPE CLEAR ZONE —/ I xcccr SOIL SHALL BE PUSHED OVER I EQUIPMENT WIDTH ROCKS AND FLOODED INTO I / VOIDS. COMPACT AROUND AND OVER STACK BOULDERS END TO END. DO NOT PILE UPON EACH OTHER. ' 10'] FILL SLOPE J, 10' MIN STAGGER ROWS 15' / O,MPT NOT TO SCALE ROCK DISPOSAL DETAIL STANDARD SPECIFICATIONS FOR GRADING Page 24 of 26 1 FINISHED GRADE BUILDING I NO OVERSIZE, AREA FOR 10' FOUNDATION, UTILITIES, SLOPE FACE AND SWIMMING POOLS STREET 0 15' WINDROW _J 5' MINIMUM OR BELOW DEPTH OF DEEPEST UTILITY TRENCH (WHICHEVER GREATER) TYPICAL WINDROW DETAIL (EDGE VIEW) j- GRANULAR SOIL FLOODED I TO FILL VOIDS HORIZONTALLY PLACED COMPACTION FILL PROFILE VIEW NOT TO SCALE ROCK DISPOSAL DETAIL STANDARD SPECIFICATIONS FOR GRADING Page 25 of 26 GENERAL GRADING RECOMMENDATIONS CUT LOT -ORIGINAL GROUND - TOPSOIL, COLLUVIUM AND WEATHERED BEDROCK 5' MIN 3' MIN OVEREXCAVATE UNWEATHERED BEDROCK AND REGRADE CUT/FILL LOT (TRANSITION) ORIGINAL .0101 .01 GROUND -.-----.-- MIN COMPACTED FILL 3' MIN -.--- - TOPSOIL, COLLUVIUM -AND WEATHERED BEDROCK .00 .00 - 0 UNWEATHERED BEDROCK NOT TO SCALE OVEREXCAVATE AND REGRADE TRANSITION LOT DETAIL STANDARD SPECIFICATIONS FOR GRADING Page 26 of 26