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Home My WebLink AboutCDP 2020-0017; SAREM RESIDENCE; PRELIMINARY GEOTECHNICAL EVALUATION PROPOSED TWO STORY RESIDENCE; 2020-05-11PRELIMINARY GEOTECHNICAL EVALUATION PROPOSED TWO-STORY RESIDENCE, 4005 SKYLINE ROAD, APN 207-072-17-00 CITY OF CARLSBAD, SAN DIEGO COUNTY, CALIFORNIA MR. SCOTT SAREM May 11, 2020 J.N. 20-155 ENGINEERS + GEOLOGISTS + ENVIRONMENTAL SCIENTISTS Offices Strategically Positioned Throughout Southern California RIVERSIDE COUNTY OFFICE 40880 County Center Drive, Suite M, CA 92591 T: 951.253.4458 For more information visit us online at www.petra-inc.com May 11, 2020 J.N. 20-155 MR. SCOTT SAREM 6684 Lemon Leaf Drive Carlsbad, California 920011 Subject: Preliminary Geotechnical Evaluation, Proposed Two-Story Residence, 4005 Skyline Road, APN 207-072-17-00, City of Carlsbad, San Diego County, California Dear Mr. Sarem: Petra Geosciences, Inc. (Petra) is submitting herewith our preliminary geotechnical evaluation report for the proposed construction of a two-story residence within the subject site. This work was performed in accordance with the scope of work outlined in our Proposal No. 20-155P, dated March 5, 2020. This report presents the results of our field investigation, laboratory testing, and our engineering and geologic judgment, opinions, conclusions, and recommendations pertaining to the geotechnical design aspects of the proposed development. It has been a pleasure to be of service to you on this project. If you have any questions regarding the contents of this report or require additional information, please do not hesitate to contact us. Respectfully submitted, PETRA GEOSCIENCES, INC. Jim Larwood, CEG Principal Geologist MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 TABLE OF CONTENTS Page PURPOSE AND SCOPE OF SERVICES ..................................................................................................................... 1 LOCATION AND SITE DESCRIPTION ..................................................................................................................... 1 PROPOSED CONSTRUCTION AND GRADING ...................................................................................................... 2 FIELD EXPLORATION ............................................................................................................................................... 2 Laboratory Testing .............................................................................................................................................3 FINDINGS .................................................................................................................................................................... 3 Regional and Local Geology ..............................................................................................................................3 Subsurface Soil Conditions ................................................................................................................................3 Groundwater .......................................................................................................................................................4 Faulting ..............................................................................................................................................................4 Secondary Seismic Effects .................................................................................................................................5 CONCLUSIONS AND RECOMMENDATIONS ........................................................................................................ 5 General Feasibility ...................................................................................................................................................5 Grading Plan Review ...............................................................................................................................................6 Earthwork and Grading ............................................................................................................................................6 General Specifications .......................................................................................................................................6 Geotechnical Observations and Testing During Grading ...................................................................................6 Site Clearing .......................................................................................................................................................6 Existing Septic System .......................................................................................................................................6 Ground Preparation – Building Pad Area ...........................................................................................................7 Ground Preparation – Driveway and Hardscape Areas ......................................................................................7 Excavation Characteristics .................................................................................................................................8 Stability of Temporary Excavation Sidewalls ....................................................................................................8 Benching ............................................................................................................................................................8 Fill Placement ....................................................................................................................................................9 Imported Soils ....................................................................................................................................................9 Slope Construction ...................................................................................................................................................9 Fill Slopes ..........................................................................................................................................................9 Cut Slopes ..........................................................................................................................................................9 PRELIMINARY FOUNDATION DESIGN CONSIDERATIONS ............................................................................ 10 Seismic Design Parameters .............................................................................................................................. 10 Discussion - General ........................................................................................................................................ 12 Allowable Soil Bearing Capacities................................................................................................................... 13 Continuous Footings ........................................................................................................................................ 13 Estimated Footing Settlement .......................................................................................................................... 13 Lateral Resistance ............................................................................................................................................ 13 Guidelines for Slab-on-Ground Foundation Design and Construction .................................................................. 14 Conventional Slab-on-Grade System ............................................................................................................... 14 Foundation Excavation Observations ............................................................................................................... 16 General Corrosivity Screening ............................................................................................................................... 17 Retaining Wall Design and Construction Considerations ...................................................................................... 18 Active and At-Rest Earth Pressures ................................................................................................................. 18 Backdrains ........................................................................................................................................................ 19 Waterproofing .................................................................................................................................................. 19 Wall Backfill .................................................................................................................................................... 20 Geotechnical Observation and Testing ............................................................................................................. 20 Masonry Block Walls (Non-Retaining) ................................................................................................................. 21 Planter Walls .......................................................................................................................................................... 21 Swimming Pool and Spa Recommendations ......................................................................................................... 21 Allowable Bearing, Settlement, and Lateral Earth Pressures ........................................................................... 21 MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 TABLE OF CONTENTS Page Temporary Access Ramps ................................................................................................................................ 22 Plumbing Fixtures ............................................................................................................................................ 22 Pool and Spa Decking ...................................................................................................................................... 22 Post-Grading Considerations ................................................................................................................................. 22 Utility Trenches ................................................................................................................................................ 22 Site Drainage .................................................................................................................................................... 23 Exterior Concrete Flatwork .................................................................................................................................... 23 General ............................................................................................................................................................. 23 Thickness and Joint Spacing ............................................................................................................................ 24 Reinforcement .................................................................................................................................................. 24 Edge Beams (Optional) .................................................................................................................................... 24 Subgrade Preparation ....................................................................................................................................... 25 Drainage ........................................................................................................................................................... 25 Tree Wells ........................................................................................................................................................ 25 GRADING PLAN REVIEW AND FUTURE IMPROVEMENTS ............................................................................. 26 REPORT LIMITATIONS ........................................................................................................................................... 26 REFERENCES ............................................................................................................................................................ 28 ATTACHMENTS FIGURES RW-1 through RW-3 FIGURE 1 – SITE LOCATION MAP FIGURE 2 - GEOTECHNICAL MAP PLATE A-1– LOGS OF TEST PITS APPENDIX A – LABORATORY TEST PROCEDURES / LABORATORY DATA SUMMARY APPENDIX B – SEISMIC DESIGN PARAMETERS APPENDIX C – STANDARD EARTHWORK CONSTRUCTION PRELIMINARY GEOTECHNICAL EVALUATION PROPOSED TWO-STORY RESIDENCE, 4005 SKYLINE ROAD, APN 207-072-17-00 CITY OF CARLSBAD, SAN DIEGO COUNTY, CALIFORNIA PURPOSE AND SCOPE OF SERVICES Petra Geosciences, Inc. (Petra) is presenting herein the results of our geotechnical evaluation for the subject property. The purposes of this investigation are to obtain information regarding surface and subsurface geologic conditions within the general project area, evaluate the engineering properties of the onsite soil materials and to provide conclusions as to the feasibility of the proposed improvements and recommendations for site remedial grading, as well as the design and construction of the proposed residence and site improvements. To accomplish these objectives, our scope of services includes the following: 1. Review of available published and unpublished literature and maps pertaining to regional faulting, seismic hazards and soil and geologic conditions within and adjacent to the site that could have an impact on the proposed development. 2. Excavating, sampling, and logging four (4) exploratory test pits to depths ranging from 3 to 6 feet below the ground surface within portions of the site (Plates A-1 and A-2). 3. Performing laboratory testing on representative samples of earth materials obtained from the test pits to determine their engineering properties. 4. Engineering and geologic analyses of the field and laboratory data as they pertain to the proposed construction. 5. Preparation of this report presenting our findings, conclusions and recommendations for site grading and design of building foundation systems. LOCATION AND SITE DESCRIPTION The 0.59-acre site is located on the western side of Skyline Road, approximately 750 feet north of Tamarack Avenue in the city of Carlsbad. The property is identified as San Diego County Assessor Parcel Number (APN) APN 207-072-17-00. The general location of the site is shown on Figure 1. The narrow, semi- rectangular-shaped lot is bounded on the north, west and south by single-family residential homes and Skyline Road to the east. The lot slopes downward at a gentle gradient from Skyline Road, towards the rear of the lot to the west. Elevations of the site ranges from approximately 307 feet above mean sea level (msl) at the east side to 277 feet msl along the west property boundary for an overall topographic relief of 30 feet. The subject lot is occupied by a one-story home with perimeter fencing, wood deck off the rear of the house and, possibly, a backyard septic system. A water meter box and gas service are located at the south side of the driveway. Overhead electrical enters the site from a power pole at the north end of the driveway. The majority of the front yard is landscaped, whereas the backyard is generally covered by grasses and some succulents. An elevated swimming pool is located near the northern property line. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 2 PROPOSED CONSTRUCTION AND GRADING Based on the architectural site plan prepared by B+D Studio (B+D) dated February 28, 2020, it is our understanding that the proposed development will consist of a split-level two-story residence, attached garage and a connecting deck. To accommodate the split level, interior retaining walls from 1.5 feet up to 5 feet in height are proposed. Appurtenant improvements are expected to include a paved driveway, below- ground utilities, hardscape flatwork and landscaping. It is anticipated that the residence will be of typical wood-frame construction with concrete slabs constructed on-grade. For this type of construction, it is anticipated that relatively light foundation loads will be imposed on the subgrade soils. We understand that grading plans have not yet been developed for the site. Based on site plans provided by B+D, finish floor elevations are proposed at 299.0, 300.5 and 305.5 feet msl within the house and attached garage. Given the floor elevations of the proposed residence, earthwork within the site is generally expected to entail cuts and/or fills ranging from approximately 1 to 5 feet from existing grades. It should be noted, however, that remedial grading (i.e., removal and re- compaction of existing unsuitable surficial soils) will entail deeper cuts from existing grades as recommended in subsequent sections of this report. Other proposed site improvements may include swimming pool, spa, patio, barbeque pit, concrete flatwork, and landscaping. Recommendations for site grading, and for the design and construction of building foundations, are presented in the “Conclusions and Recommendations” section of this report. FIELD EXPLORATION Our subsurface exploration was performed on April 15, 2020 and consisted of the excavation of four exploratory test pits (TP-1 to TP-4) with a mini-excavator to depths ranging from 3 to 6 feet below the existing ground surface (bgs). The locations of our test pits are shown on the Geotechnical Map, Figure 2. Test pit logs are included as Plates A-1 and A-2. General descriptions of the soil materials encountered are provided in the Subsurface Soil Conditions section. Earth materials encountered in each of the exploratory test pits were field classified and logged in accordance with Unified Soil Classification System (USCS) procedures. In addition, our subsurface exploration included the collection of bulk samples of the subsurface soils for laboratory testing purposes and in-situ density testing using a nuclear gauge. The samples were placed in sealed bags and transported to our laboratory for testing. The test pits were loosely backfilled with the excavated soil cuttings. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 3 Laboratory Testing To evaluate the engineering properties of the onsite soils, several laboratory tests were performed on selected samples considered representative of the materials encountered during our exploration. Laboratory tests included the determination of expansion potential, soluble sulfate and chloride content, soil pH, minimum resistivity, and maximum dry density. A description of laboratory test methods and test data is provided in Appendix A. FINDINGS Regional and Local Geology The site is located in the Peninsular Ranges Geomorphic Province of California. The Peninsular Range Province is characterized by northwest trending mountain ranges separated by a series of subparallel fault zones associated with the San Andreas Fault System. The mountain ranges consist generally of Cretaceous igneous rocks of the Southern California Batholith and Jurassic meta-sediments and meta-volcanics. Younger sediments flank the mountain ranges to the southwest along the coastal plain. The sediments flanking the mountains along the coastal plain consist of Tertiary and Quaternary marine, non-marine and lagoonal deposits, with several local areas deformed by tectonics. The subject site is situated near the top of the easterly flank of an elevated terrace running parallel to the Pacific Ocean, north of the Agua Hedionda Lagoon. Regional geologic mapping by Kennedy and Tan (2005) shows the site is underlain by middle to early Pleistocene-age very old paralic deposits generally of playa, lacustrine and estuarine depositional environment (map symbol: Qvol). Underlying Qvol are well indurated Tertiary-aged sandstone, conglomerate and siltstone bedrock belonging to the Santiago Formation (map symbol: Tss). Subsurface Soil Conditions Undocumented artificial fill (map symbol: afu) and topsoil, consisting of loose, moist to wet, dark brown silty fine to medium grained sand with some organics, was encountered in each test pit to a depth of up to approximately 2 feet bgs. Qvol (referred to herein as terrace deposits) was observed in each test pit, consisting of massively bedded, reddish brown with some iron oxide staining, moist to wet, dense to very dense, weathered to slightly weathered fine- to coarse-grained sandstone. The clay content of the sandstone increased with depth to the maximum depth of the test pits, up to 6 ft bgs. Evidence of existing septic leach lines was encountered within the test pits TP-2 and TP-4. The leach lines, where encountered, were characterized by north-south trending clay pipe encapsulated by 1- to 3-inch MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 4 diameter, rounded gravel. The pipe was about 2 to 2.5 feet bgs. Some water was seen in the gravel and pipe. Each line of pipe appeared to be laterally separated 10 feet. The clay pipe connections were found to be loosely attached to allow for seepage. The assumed septic tank may be located beneath the cluster of succulents along the northwest side of the exiting building but was not confirmed. The approximate location of leach lines and septic tank are shown on Figure 2. It is important to understand that during the previous week before conducting this investigation, the Carlsbad area experienced a record amount of rainfall of about 6 inches. The soil at the site is relatively permeable and allowed the rainfall to infiltrate into the underlying soils. When reviewing the moisture descriptions above, one must understand that this rainfall presented a wet condition that may not be representative of normal conditions. Groundwater Groundwater was not encountered in our field exploration to the maximum depth explored of 6 feet. Regional groundwater is not expected to be within 50 feet of the ground surface along the upper portions of this local elevated terrace. Groundwater is not expected to impact future site grading. However, seepage from the septic leach field was observed coming from clay pipe and gravel. Faulting Based on our review of the referenced geologic maps and literature, no active faults are known to project near or through the property. Furthermore, the site does not lie within the boundaries of an “Earthquake Fault Zone” as defined by the State of California in the Alquist-Priolo Earthquake Fault Zoning Act (Bryant, 2007; CGS, 2018). The Alquist-Priolo Earthquake Fault Zoning Act (AP Act) defines an active fault as one that “has had surface displacement within Holocene time (about the last 11,000 years).” The main objective of the AP Act is to prevent the construction of dwellings on top of active faults that could displace the ground surface resulting in loss of life and property. However, it should be noted that according to the USGS Unified Hazard Tool website and/or 2010 CGS Fault Activity Map of California, the Newport-Inglewood-Rose Canyon Fault, located approximately 5.8 miles (9.3 kilometers) west of the site, would probably generate the most severe site ground motions and, therefore, is the majority contributor to the deterministic minimum component of the ground motion models. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 5 Secondary Seismic Effects The site and immediate area exhibit very gentle sloping that is not prone to landsliding, nor were surficial features indicative of slope instability noted during our field reconnaissance. Additionally, the site is not mapped within a zone of marginal landslide susceptibly (Tan, S. S., 1995) and no landslide are mapped within the surrounding area. Secondary effects of seismic activity normally considered as possible hazards to a site include several types of ground failure. Various general types of ground failures, which might occur as a consequence of severe ground shaking at the site, include ground subsidence, liquefaction, ground lurching and lateral spreading. The probability of occurrence of each type of ground failure depends on the severity of the earthquake, distance from faults, topography, subsoil, and groundwater conditions, in addition to other factors. Based on the site conditions and gentle topography across the site, significant ground lurching, and lateral spreading are considered unlikely at the site. Due to the overall density of the very old paralic deposits encountered onsite, the potential for ground subsidence due to seismic shaking and liquefaction is anticipated to be very low. Seismically induced flooding that might be considered a potential hazard to a site normally includes flooding due to tsunami or seiche (i.e., a wave-like oscillation of the surface of water in an enclosed basin) that may be initiated by a strong earthquake or failure of a major reservoir or retention structure upstream of the site. The potential for either seiche inundation or flooding due to a tsunami is considered negligible at the site due to the elevation above both the Pacific Ocean and the nearby lagoon. CONCLUSIONS AND RECOMMENDATIONS General Feasibility From a soils engineering and engineering geologic point of view, the subject property is considered suitable for the proposed development, provided that the following conclusions and recommendations are incorporated into the design criteria and project specifications. Based on our geotechnical investigation of the site, it is our opinion the building site is free of hazard from landslide, liquefaction, settlement, and slippage, and will remain so provided that the recommendations of this report are incorporated into the design criteria and project specifications. Furthermore, it is our opinion that the proposed grading and construction will not adversely affect the geologic stability of adjoining properties in an adverse manner provided that the grading and construction are performed in accordance with current standards of practice, all applicable grading ordinances and the recommendations presented in this report. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 6 Grading Plan Review This report has been prepared based on a provided architectural site plan. The final site grades and the future grading plans should be reviewed by the geotechnical consultant. As such, additional recommendations and/or modification of the grading recommendations provided herein may be necessary if significant graded slopes or retaining walls are proposed. Earthwork and Grading General Specifications All earthwork and grading should be performed in accordance with all applicable requirements of the grading and excavation codes of the City of Carlsbad, and in compliance with all applicable provisions of the 2019 California Building Code (CBC). Grading should also be performed in accordance with the recommendations provided in this report. Geotechnical Observations and Testing During Grading Exposed bottom surfaces in the building over-excavation areas should be observed and approved by a representative of the geotechnical consultant prior to placing fill. In addition, a representative of the geotechnical consultant should be present onsite during grading operations to observe proper placement and adequate compaction of all fills, as well as to document compliance with the other recommendations presented herein. Site Clearing Site clearing operations should include the removal of all existing vegetation, septic system and any improvements. During site grading, laborers should be provided to clear from fill soils any roots, trash, debris, or other deleterious materials as encountered. The project geotechnical consultant should be notified at the appropriate times to observe general clearing operations. If any unusual soil conditions or buried structures are encountered during demolition operations - or grading that is not described or anticipated herein, the project geotechnical consultant should be contacted immediately for corrective recommendations. Existing Septic System Based on our investigation, it is likely that there is a septic tank and leach field in the back yard of the existing residence. Removal of the entire septic system is required and should consist of complete removal of the leach lines, plumbing and septic tank. The excavated areas should be backfilled with compacted fill, MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 7 placed under full-time geotechnical observation and testing. It is recommended that the septic removal and disposal be conducted in accordance with current local, state and federal disposal regulations. Ground Preparation – Building Pad Area Our subsurface evaluation found that the subject site is underlain by approximately 1 to 2.5 feet of undocumented artificial fill, topsoil and weathered terrace deposits, which in turn is underlain by medium dense to dense terrace deposits. Therefore, in order to mitigate possible distress to the proposed building footings and floor slabs due to the effects of potential adverse settlement, it is recommended that all building pad soils should be over-excavated to at least 3 feet below finish pad grade to expose competent native terrace deposit soils as observed and approved by a representative of Petra. In order to provide both vertical and lateral support of the footings, the horizontal limits of over-excavation and re-compaction should extend to a minimum distance of 5 feet beyond the perimeter edges of the footings including any footings supporting overhead canopies or structures connected to the buildings. It must be emphasized that the depths of remedial grading as provided above are estimates only and are based on conditions encountered at the exploratory test pit locations. Subsurface conditions can and usually do vary between points of exploration and for this reason, the actual removal depths will have to be determined based on in-grading observations and testing performed by a representative of the project geotechnical consultant. Remedial grading and ground preparation should be performed prior to placing any new fills. After completion of over-excavation and prior to fill placement, the exposed native bottom surfaces should be scarified to a minimum depth of 12 inches, moisture-conditioned as necessary to achieve at least two percent above optimum, and then mechanically re-compacted to a relative compaction of 95 percent or more, referenced to ASTM D1557. Additional compacted (engineered) fill to be placed to achieve pad grade shall be compacted to 95 percent relative compaction or more. Ground Preparation – Driveway and Hardscape Areas Within the paved driveway or exterior hardscape areas, exposed soils should be over-excavated to a minimum depth of 1 foot below existing grades as observed by the geotechnical consultant; and the exposed ground surface should be scarified to a depth of at least 12 inches, moisture-conditioned as necessary to achieve at or slightly above optimum moisture conditions, and then re-compacted in-place to a minimum relative compaction of 90 percent. The horizontal limits of over-excavation should extend to a minimum horizontal distance of 5 feet beyond the perimeter of the proposed improvements, where possible. Where MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 8 removals are limited by property lines, the removals should be performed within 3 feet from the property lines. Excavation Characteristics Based on the results of our subsurface evaluation, observed soils within the site are expected to be readily excavatable with conventional earthmoving equipment. Stability of Temporary Excavation Sidewalls During site grading, a temporary excavation with sidewalls approximately 5 feet in height may be created during construction to obtain the split pad configurations for the proposed residence. Based on the physical characteristics of the onsite materials, 5 feet of the sidewalls exposing competent material may be tentatively planned at a vertical gradient. However, should these sidewalls exceed this height, the lower 5 feet may be cut vertical and the upper portions above a height of 5 feet should be cut back at a maximum gradient of 1:1, horizontal to vertical, or flatter. Temporary slopes excavated at the above slope configurations are expected to remain stable during construction; however, the temporary excavations should be observed by a representative of Petra for any evidence of potential instability. Depending on the results of these observations, revised slope configurations may be necessary. Other factors which should be considered with respect to the stability of temporary slopes include construction traffic and storage of materials on or near the tops of the slopes, construction scheduling, presence of nearby walls or structures, and weather conditions at the time of construction. All applicable requirements of the California Construction and General Industry Safety Orders, the Occupational Safety and Health Act of 1970, and the Construction Safety Act should also be followed. No temporary excavations along the property lines should be left open without proper protections to mitigate safety hazards. The grading contractor is solely responsible for ensuring the safety of construction personnel and the general public, and for appointing a designated “Competent Person” to observe and classify temporary excavation sidewalls pursuant to 29 CFR Part 1926 (OSHA Safety and Health Regulations for Construction). Benching Compacted fills placed on the natural ground surface inclining at 5:1 (h:v) or steeper should be placed on a series of level benches excavated into competent terrace deposits. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 9 Fill Placement Fill materials for the building pad should be placed in approximately 6- to 8-inch thick loose lifts, watered or air-dried as necessary to achieve a moisture content of at least 2 percent above the optimum moisture condition, and then compacted in-place to a minimum relative compaction of 95 percent. Fill to be placed in hardscape areas or driveways should be compacted to no less than 90 percent relative compaction. The laboratory maximum dry density and optimum moisture content for each change in soil type should be determined in accordance with ASTM D1557. Imported Soils If imported soils are required to complete the planned grading, these soils should consist of clean materials devoid of rock exceeding a maximum dimension of 3 inches, organics, trash, and other deleterious materials. To avoid making revisions to the foundation design, imported soils should also exhibit a very low expansion potential (Expansion Index 0-20). Prospective import soils should be observed at the source, tested, and approved by the geotechnical consultant prior to importing the soils to the site. It is recommended that the project environmental consultant should also be notified so that they can confirm the suitability of the proposed import material from an environmental standpoint. Slope Construction Fill Slopes For fill slopes exceeding 5 feet in height, if planned, a fill key excavated a depth of 2 feet or more into competent terrace deposits is recommended at the base of the fill slope. The width of the fill key should equal to one-half the slope height or 15 feet, whichever is greater, sloping downward from the toe of the slope to the heel of the key by approximately 1 foot. To obtain proper compaction to the face of fill slopes, low-height fill slopes should be overfilled during construction and then trimmed-back to the compacted inner core. Cut Slopes Although cut slopes are not anticipated, observations during grading of individual cut slopes by the project engineering geologist to document favorable geologic structure or soil conditions of the exposed conditions is recommended. Although not anticipated, if cohesionless sandy soil materials are observed, the cut slopes in question may require stabilization by means of a compacted stabilization fill. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 10 PRELIMINARY FOUNDATION DESIGN CONSIDERATIONS Seismic Design Parameters Earthquake loads on earthen structures and buildings are a function of ground acceleration which may be determined from the site-specific ground motion analysis. Alternatively, a design response spectrum can be developed for certain sites based on the code guidelines. To provide the design team with the parameters necessary to construct the design acceleration response spectrum for this project, we used two computer applications. Specifically, the first computer application, which was jointly developed by Structural Engineering Association of California (SEAOC) and California’s Office of Statewide Health Planning and Development (OSHPD), the SEA/OSHPD Seismic Design Maps Tool website, https://seismicmaps.org, is used to calculate the ground motion parameters. The second computer application, the United Stated Geological Survey (USGS) Unified Hazard Tool website, https://earthquake.usgs.gov/hazards/interactive/, is used to estimate the earthquake magnitude and the distance to surface projection of the fault. To run the above computer applications, site latitude and longitude, seismic risk category and knowledge of site class are required. The site class definition depends on the direct measurement and the ASCE 7-16 recommended procedure for calculating average small-strain shear wave velocity, Vs30, within the upper 30 meters (approximately 100 feet) of site soils. A seismic risk category of II was assigned to the proposed building in accordance with 2019 CBC, Table 1604.5. No shear wave velocity measurement was performed at the site, however, the subsurface materials at the site appears to exhibit the characteristics of stiff soils condition for Site Class D designation. Therefore, an average shear wave velocity of 600 to 1,200 feet per second for the upper 100 feet was assigned to the site based on engineering judgment and geophysical experience. As such, in accordance with ASCE 7-16, Table 20.3-1, Site Class D (D- Default as per SEA/OSHPD software) has been assigned to the subject site. The following table, Table 1, provides parameters required to construct the seismic response coefficient, Cs, curve based on ASCE 7-16, Article 12.8 guidelines. A printout of the computer output is attached in Appendix B. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 11 TABLE 1 Seismic Design Parameters Ground Motion Parameters Specific Reference Parameter Value Unit Site Latitude (North) - 33.1568 ° Site Longitude (West) - -117.3206 ° Site Class Definition Section 1613.2.2 (1), Chapter 20 (2) D-Default (4) - Assumed Seismic Risk Category Table 1604.5 (1) II - Mw - Earthquake Magnitude USGS Unified Hazard Tool (3) 6.9 (3) - R – Distance to Surface Projection of Fault USGS Unified Hazard Tool (3) 9.3 (3) km Ss - Mapped Spectral Response Acceleration Short Period (0.2 second) Figure 1613.2.1(1) (1) 1.017 (4) g S1 - Mapped Spectral Response Acceleration Long Period (1.0 second) Figure 1613.2.1(2) (1) 0.37 (4) g Fa – Short Period (0.2 second) Site Coefficient Table 1613.2.3(1) (1) 1.2 (4) - Fv – Long Period (1.0 second) Site Coefficient Table 1613.2.3(2) (1) Null (4) - SMS – MCER Spectral Response Acceleration Parameter Adjusted for Site Class Effect (0.2 second) Equation 16-36 (1) 1.221 (4) g SM1 - MCER Spectral Response Acceleration Parameter Adjusted for Site Class Effect (1.0 second) Equation 16-37 (1) Null (4) g SDS - Design Spectral Response Acceleration at 0.2-s Equation 16-38 (1) 0.814 (4) g SD1 - Design Spectral Response Acceleration at 1-s Equation 16-39 (1) Null (4) g To = 0.2 SD1/ SDS Section 11.4.6 (2) Null s Ts = SD1/ SDS Section 11.4.6 (2) Null s TL - Long Period Transition Period Figure 22-14 (2) 8 (4) s PGA - Peak Ground Acceleration at MCEG (*) Figure 22-9 (2) 0.446 g FPGA - Site Coefficient Adjusted for Site Class Effect (2) Table 11.8-1 (2) 1.1 (4) - PGAM –Peak Ground Acceleration (2) Adjusted for Site Class Effect Equation 11.8-1 (2) 0.535 (4) g Design PGA ≈ (⅔ PGAM) - Slope Stability (†) Similar to Eqs. 16-38 & 16-39 (2) 0.357 g Design PGA ≈ (0.4 SDS) – Short Retaining Walls (‡) Equation 11.4-5 (2) 0.326 g CRS - Short Period Risk Coefficient Figure 22-18A (2) 0.898 (4) - CR1 - Long Period Risk Coefficient Figure 22-19A (2) 0.909 (4) - SDC - Seismic Design Category (§) Section 1613.2.5 (1) Null (4) - References: (1) California Building Code (CBC), 2019, California Code of Regulations, Title 24, Part 2, Volume I and II. (2) American Society of Civil Engineers/Structural Engineering Institute (ASCE/SEI), 2016, Minimum Design Loads and Associated Criteria for Buildings and Other Structures, Standards 7-16. (3) USGS Unified Hazard Tool - https://earthquake.usgs.gov/hazards/interactive/ (4) SEI/OSHPD Seismic Design Map Application – https://seismicmaps.org Related References: Federal Emergency Management Agency (FEMA), 2015, NEHERP (National Earthquake Hazards Reduction Program) Recommended Seismic Provision for New Building and Other Structures (FEMA P-1050). Notes: * PGA Calculated at the MCE return period of 2475 years (2 percent chance of exceedance in 50 years). † PGA Calculated at the Design Level of ⅔ of MCE; approximately equivalent to a return period of 475 years (10 percent chance of exceedance in 50 years). ‡ PGA Calculated for short, stubby retaining walls with an infinitesimal (zero) fundamental period. § The designation provided herein may be superseded by the structural engineer in accordance with Section 1613.2.5.1, if applicable. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 12 Discussion - General Owing to the characteristics of the subsurface soils, as defined by Site Class D-Default designation, and proximity of the site to the sources of major ground shaking, the site is expected to experience strong ground shaking during its anticipated life span. Under these circumstances, where the code-specified design response spectrum may not adequately characterize site response, the 2019 CBC typically requires a site- specific seismic response analysis to be performed. This requirement is signified/identified by the “null” values that are output using SEA/OSHPD software in determination of short period, but mostly, in determination of long period seismic parameters, see Table 1. For conditions where a “null” value is reported for the site, a variety of design approaches are permitted by 2019 CBC and ASCE 7-16 in lieu of a site-specific seismic hazard analysis. For any specific site, these alternative design approaches, which include Equivalent Lateral Force (ELF) procedure, Modal Response Spectrum Analysis (MRSA) procedure, Linear Response History Analysis (LRHA) procedure and Simplified Design procedure, among other methods, are expected to provide results that may or may not be more economical than those that are obtained if a site-specific seismic hazards analysis is performed. These design approaches and their limitations should be evaluated by the project structural engineer. Discussion – Seismic Design Category Please note that the Seismic Design Category, SDC, is also designated as “null” in Table 1. For Risk Category I, II or III structures, where the mapped spectral response acceleration parameter at 1 – second period, S1, is less than 0.75, the 2019 CBC, Section 1613.2.5.1 allows that seismic design category to be determined from Table 1613.2.5(1) alone provided that all 4 requirements concerning fundamental period of structure, story drift, seismic response coefficient, and relative rigidity of the diaphragms are met. Our interpretation of ASCE 7-16 is that for conditions where one or more of these 4 conditions are not met, seismic design category should be assigned based on: 1) 2019 CBC, Table 1613.2.5(1), 2) structure’s risk category and 3) the value of SDS, at the discretion of the project structural engineer. Discussion – Equivalent Lateral Force Method As stated herein, the subject site is considered to be within a Site Class D-Default. A site-specific ground motion hazard analysis is not required for structures on Site Class D-Default with S1 > 0.2 provided that the Seismic Response Coefficient, Cs, is determined in accordance with ASCE 7-16, Article 12.8 and structural design is performed in accordance with Equivalent Lateral Force (ELF) procedure. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 13 Allowable Soil Bearing Capacities Pad Footings An allowable soil bearing capacity of 2,000 pounds per square foot may be utilized for design of isolated 24-inch-square footings founded at a minimum depth of 12 inches below the lowest adjacent final grade for pad footings that are not a part of the slab system and are used for support of such features as roof overhang, second-story decks, patio covers, etc. This value may be increased by 20 percent for each additional foot of depth and by 10 percent for each additional foot of width, to a maximum value of 3,000 pounds per square foot. The recommended allowable bearing value includes both dead and live loads and may be increased by one-third for short duration wind and seismic forces. Continuous Footings An allowable soil bearing capacity of 2,000 pounds per square foot may be utilized for design of continuous footings founded at a minimum depth of 12 inches below the lowest adjacent final grade. This value may be increased by 20 percent for each additional foot of depth and by 10 percent for each additional foot of width, to a maximum value of 3,000 pounds per square foot. The recommended allowable bearing value includes both dead and live loads and may be increased by one-third for short duration wind and seismic forces. Estimated Footing Settlement Based on the allowable bearing values provided above, total static settlement of the footings under the anticipated loads is expected to be on the order of 0.75 inch or less. Differential settlement is expected to be less than 0.5 inch over a horizontal span of 30 feet. Most of the settlement is likely to take place as footing loads are applied or shortly thereafter. Lateral Resistance A passive earth pressure of 300 pounds per square foot per foot of depth, to a maximum value of 2,000 pounds per square foot, may be used to determine lateral bearing resistance for footings. In addition, a coefficient of friction of 0.30 times the dead load forces may be used between concrete and the supporting soils to determine lateral sliding resistance. The above values may be increased by one-third when designing for transient wind or seismic forces. It should be noted that the above values are based on the condition where footings are cast in direct contact with compacted fill or competent native soils. In cases where the footing sides are formed, all backfill placed against the footings upon removal of forms should be compacted to at least 90 percent of the applicable maximum dry density. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 14 Guidelines for Slab-on-Ground Foundation Design and Construction The results of our laboratory tests performed on representative samples of near-surface soils within the site during our investigation indicate that these materials predominantly exhibit expansion indices that are less than 20. As indicated in Section 1803.5.3 of 2019 California Building Code (2019 CBC), these soils are considered non-expansive and, as such, the design of slabs on-grade is considered to be exempt from the procedures outlined in Sections 1808.6.2 of the 2019 CBC and may be performed using any method deemed rational and appropriate by the project structural engineer. However, the following minimum recommendations are presented herein for conditions where the project design team may require geotechnical engineering guidelines for design and construction of footings and slabs on-grade the project site. The design and construction guidelines that follow are based on the above soil conditions and may be considered for reducing the effects of variability in fabric, composition and, therefore, the detrimental behavior of the site soils such as excessive short- and long-term total and differential heave or settlement. These guidelines have been developed on the basis of the previous experience of this firm on projects with similar soil conditions. Although construction performed in accordance with these guidelines has been found to reduce post-construction movement and/or distress, they generally do not positively eliminate all potential effects of variability in soils characteristics and future heave or settlement. It should also be noted that the suggestions for dimension and reinforcement provided herein are performance-based and intended only as preliminary guidelines to achieve adequate performance under the anticipated soil conditions. However, they should not be construed as replacement for structural engineering analyses, experience, and judgment. The project structural engineer, architect and/or civil engineer should make appropriate adjustments to slab and footing dimensions, and reinforcement type, size and spacing to account for internal concrete forces (e.g., thermal, shrinkage and expansion) as well as external forces (e.g., applied loads) as deemed necessary. Consideration should also be given to minimum design criteria as dictated by local building code requirements. Conventional Slab-on-Grade System Given the expansion index of less than 20, as generally exhibited by onsite soils, we recommend that footings and floor slabs be designed and constructed in accordance with the following minimum criteria. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 15 Footings 1. Exterior continuous footings supporting one- and two-story structures should be founded at a minimum depth of 12 inches below the lowest adjacent final grade, respectively. Interior continuous footings may be founded at a minimum depth of 10 inches below the top of the adjacent finish floor slabs. 2. In accordance with Table 1809.7 of 2019 CBC for light-frame construction, all continuous footings should have minimum widths of 12 inches for one- and two-story construction. We recommend all continuous footings should be reinforced with a minimum of two No. 4 bars, one top and one bottom. 3. A minimum 12-inch-wide grade beam founded at the same depth as adjacent footings should be provided across garage entrances or similar openings (such as large doors or bay windows). The grade beam should be reinforced with a similar manner as provided above. 4. Interior isolated pad footings, if required, should be a minimum of 24 inches square and founded at a minimum depth of 12 inches below the bottoms of the adjacent floor slabs for one- and two-story buildings. Pad footings should be reinforced with No. 4 bars spaced a maximum of 18 inches on centers, both ways, placed near the bottoms of the footings. 5. Exterior isolated pad footings intended for support of roof overhangs such as second-story decks, patio covers, and similar construction should be a minimum of 24 inches square and founded at a minimum depth of 18 inches below the lowest adjacent final grade. The pad footings should be reinforced with No. 4 bars spaced a maximum of 18 inches on centers, both ways, placed near the bottoms of the footings. Exterior isolated pad footings may need to be connected to adjacent pad and/or continuous footings via tie beams at the discretion of the project structural engineer. 6. The minimum footing dimensions and reinforcement recommended herein may be modified (increased or decreased subject to the constraints of Chapter 18 of the 2019 CBC) by the structural engineer responsible for foundation design based on his/her calculations, engineering experience and judgment. Building Floor Slabs 1. Concrete floor slabs should be a minimum 4 inches thick and reinforced with No. 3 bars spaced a maximum of 24 inches on centers, both ways. Alternatively, the structural engineer may recommend the use of prefabricated welded wire mesh for slab reinforcement. For this condition, the welded wire mesh should be of sheet type (not rolled) and should consist of 6x6/W2.9xW2.9 WWF (per the Wire Reinforcement Institute, WRI, designation) or stronger. All slab reinforcement should be properly supported to ensure the desired placement near mid-depth. Care should be exercised to prevent warping of the welded wire mesh between the chairs in order to ensure its placement at the desired mid-slab position. Slab dimension, reinforcement type, size and spacing need to account for internal concrete forces (e.g., thermal, shrinkage and expansion) as well as external forces (e.g., applied loads), as deemed necessary. 2. Living area concrete floor slabs and areas to receive moisture sensitive floor covering should be underlain with a moisture vapor retarder consisting of a minimum 10-mil-thick polyethylene or polyolefin membrane that meets the minimum requirements of ASTM E96 and ASTM E1745 for vapor retarders (such as Husky Yellow Guard®, Stego® Wrap, or equivalent). All laps within the membrane should be sealed, and at least 2 inches of clean sand should be placed over the membrane to promote uniform curing of the concrete. To reduce the potential for punctures, the membrane should be placed MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 16 on a pad surface that has been graded smooth without any sharp protrusions. If a smooth surface cannot be achieved by grading, consideration should be given to lowering the pad finished grade an additional inch and then placing a 1-inch-thick leveling course of sand across the pad surface prior to the placement of the membrane. At the present time, some slab designers, geotechnical professionals, and concrete experts view the sand layer below the slab (blotting sand) as a place for entrapment of excess moisture that could adversely impact moisture-sensitive floor coverings. As a preventive measure, the potential for moisture intrusion into the concrete slab could be reduced if the concrete is placed directly on the vapor retarder. However, if this sand layer is omitted, appropriate curing methods must be implemented to ensure that the concrete slab cures uniformly. A qualified materials engineer with experience in slab design and construction should provide recommendations for alternative methods of curing and supervise the construction process to ensure uniform slab curing. Additional steps would also need to be taken to prevent puncturing of the vapor retarder during concrete placement. 3. Garage floor slabs should be a minimum 4 inches thick and reinforced in a similar manner as living area floor slabs. Garage slabs should also be poured separately from adjacent wall footings with a positive separation maintained using ¾-inch-minimum felt expansion joint material. To control the propagation of shrinkage cracks, garage floor slabs should be quartered with weakened plane joints. Consideration should be given to placement of a moisture vapor retarder below the garage slab, similar to that provided in Item 2 above, should the garage slab be overlain with moisture sensitive floor covering. 4. Presaturation of the subgrade below floor slabs will not be required; however, prior to placing concrete, the subgrade below all dwelling and garage floor slab areas should be thoroughly moistened to achieve a moisture content that is at least equal to or slightly greater than optimum moisture content. This moisture content should penetrate to a minimum depth of 12 inches below the bottoms of the slabs. 5. The minimum dimensions and reinforcement recommended herein for building floor slabs may be modified (increased or decreased subject to the constraints of Chapter 18 of the 2019 CBC) by the structural engineer responsible for foundation design based on his/her calculations, engineering experience and judgment. Foundation Excavation Observations Foundation excavations should be observed by a representative of this firm to document that they have been excavated into competent bearing soils prior to the placement of forms, reinforcement, or concrete. The excavations should be trimmed neat, level, and square. All loose, sloughed or moisture-softened soils and/or any construction debris should be removed prior to placing of concrete. Excavated soils derived from footing and/or utility trenches should not be placed in building slab-on-grade areas or exterior concrete flatwork areas unless the soils are compacted to at least 90 percent of maximum dry density. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 17 General Corrosivity Screening As a screening level study, limited chemical and electrical tests were performed on a single sample considered representative of the onsite soils to identify potential corrosive characteristics of these soils. The common indicators associated with soil corrosivity include water-soluble sulfate and chloride levels, pH (a measure of acidity), and minimum electrical resistivity. Test methodology and results are presented in Appendix B. It should be noted that Petra does not practice corrosion engineering; therefore, the test results, opinion and engineering judgment provided herein should be considered as general guidelines only. Additional analyses would be warranted, especially, for cases where buried metallic building materials (such as copper and cast or ductile iron pipes) in contact with site soils are planned for the project. In many cases, the project geotechnical engineer may not be informed of these choices. Therefore, for conditions where such elements are considered, we recommend that other, relevant project design professionals (e.g., the architect, landscape architect, civil and/or structural engineer) also consider recommending a qualified corrosion engineer to conduct additional sampling and testing of near-surface soils during the final stages of site grading to provide a complete assessment of soil corrosivity. Recommendations to mitigate the detrimental effects of corrosive soils on buried metallic and other building materials that may be exposed to corrosive soils should be provided by the corrosion engineer as deemed appropriate. In general, a soil’s water-soluble sulfate levels and pH relate to the potential for concrete degradation; water-soluble chlorides in soils impact ferrous metals embedded or encased in concrete, e.g., reinforcing steel; and electrical resistivity is a measure of a soil’s corrosion potential to a variety of buried metals used in the building industry, such as copper tubing and cast or ductile iron pipes. Table 2, below, presents a single value of individual test results with an interpretation of current code indicators and guidelines that are commonly used in this industry. The table includes the code-related classifications of the soils as they relate to the various tests, as well as a general recommendation for possible mitigation measures in view of the potential adverse impact on various components of the proposed structures in direct contact with site soils. The guidelines provided herein should be evaluated and confirmed, or modified, in their entirety by the project structural engineer, corrosion engineer and/or the contractor responsible for concrete placement for structural concrete used in exterior and interior footings, interior slabs on-ground, garage slabs, wall foundations and concrete exposed to weather such as driveways, patios, porches, walkways, ramps, steps, curbs, etc. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 18 TABLE 2 Soil Corrosivity Screening Results Test Test Results Classification General Recommendations Soluble Sulfates (Cal 417) 0.0015 percent S01 Type II cement; min. f’c= 2,500 psi; no water/cement ratio restrictions pH (Cal 643) 7.67 Slightly Alkaline No special recommendations Soluble Chloride (Cal 422) 108 ppm C12 C24 Residence: No special recommendations Pools/Decking: water/cement ratio 0.40, f’c = 5,000 psi Resistivity (Cal 643) 8,700 ohm-cm Moderately Corrosive3 Protective wrapping/coating of buried pipes; corrosion resistant materials Consult corrosion engineer Notes: 1. ACI 318-14, Section 19.3 2. ACI 318-14, Section 19.3 3. Pierre R. Roberge, “Handbook of Corrosion Engineering” 4. Exposure classification C2 applies specifically to swimming pools and appurtenant concrete elements Retaining Wall Design and Construction Considerations Provided herein are geotechnical design and construction recommendations for building and exterior retaining walls. Footings for retaining walls may be designed in accordance with the bearing and lateral resistance values provided previously for building footings; however, when calculating passive resistance, the resistance of the upper 6 inches of the soils should be ignored in areas where the footings will not be covered with concrete flatwork, or where the thickness of soil cover over the top of the footing is less than 12 inches. Active and At-Rest Earth Pressures Active and at-rest earth pressures to be utilized for design of any retaining walls to be constructed within the will be dependent on whether on-site soils or imported granular materials are used for backfill. For this reason, active and at-rest earth pressures are provided below for both conditions. 1. On-Site Soils Used for Backfill If on-site soils are used as backfill, active earth pressures equivalent to fluids having densities of 35 and 51 pounds per cubic foot should be used for design of cantilevered walls retaining a level backfill and ascending 2:1 backfill, respectively. For walls that are restrained at the top, at-rest earth pressures of 53 and 78 pounds per cubic foot (equivalent fluid pressures) should be used. The above values are for retaining walls that have been supplied with a proper subdrain system (see Figure RW-1). All walls should be designed to support any adjacent structural surcharge loads imposed by other nearby walls or footings in addition to the above recommended active and at-rest earth pressures. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 19 2. Imported Sand, Pea Gravel or Rock Used for Wall Backfill Where imported clean sand exhibiting a sand equivalent value (SE) of 30 or greater, or pea gravel or crushed rock are be used for wall backfill, the lateral earth pressures may be reduced provided these granular backfill materials extend behind the walls to a minimum horizontal distance equal to one-half the wall height. In addition, the sand, pea gravel or rock backfill materials should extend behind the walls to a minimum horizontal distance of 2 feet at the base of the wall or to a horizontal distance equal to the heel width of the footing, whichever is greater (see Figures RW-2 and RW-3). For the above conditions, cantilevered walls retaining a level backfill and ascending 2:1 backfill may be designed to resist active earth pressures equivalent to fluids having densities of 30 and 41 pounds per cubic foot, respectively. For walls that are restrained at the top, at-rest earth pressures equivalent to fluids having densities of 45 and 62 pounds per cubic foot are recommended for design of restrained walls supporting a level backfill and ascending 2:1 backfill, respectively. These values are also for retaining walls supplied with a proper subdrain system. Furthermore, as with native soil backfill, the walls should be designed to support any adjacent structural surcharge loads imposed by other nearby walls or footings in addition to the recommended active and at-rest earth pressures. Backdrains A perforated pipe and gravel backdrain should be installed behind all basement and retaining walls to prevent entrapment of water in the backfill (Appendix C). Perforated pipe should consist of 4-inch- minimum diameter PVC Schedule 40, or SDR-35, with the perforations laid down. The pipe should be encased in a 1-foot-wide column of ¾-inch to 1½-inch open-graded gravel. If on-site soils are used as backfill, the open-graded gravel should extend above the wall footings to a minimum height equal to one- third the wall height or to a minimum height of 1.5 feet above the footing, whichever is greater. If imported sand, pea gravel, or crushed rock is used as backfill, subdrain details (Appendix C) should be utilized. The open-graded gravel should be completely wrapped in filter fabric consisting of Mirafi 140N or equivalent. Solid outlet pipes should be connected to the subdrains and then routed to a suitable area for discharge of accumulated water. If a limited area exists behind the walls for installation of a pipe and gravel subdrain, a geotextile drain mat such as Mirafi Miradrain, or equivalent, can be used in lieu of drainage gravel. The drain mat should extend the full height and lengths of the walls and the filter fabric side of the drain mat should be placed up against the backcut. The perforated pipe drain line placed at the bottom of the drain mat should consist of 4-inch minimum diameter PVC Schedule 40 or SDR-35. The filter fabric on the drain mat should be peeled back and then wrapped around the drain line. Waterproofing The backfilled portions of retaining walls should be coated with an approved waterproofing compound or covered with a similar material to inhibit migration of moisture through the walls. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 20 Wall Backfill Recommended active and at-rest earth pressures for design of retaining walls are based on the physical and mechanical properties of the on-site soil materials. On-site soil materials may be difficult to compact when placed in the relatively confined areas located between the walls and temporary backcut slopes. Therefore, to facilitate compaction of the backfill, consideration should be given to using pea gravel or crushed rock behind the proposed retaining walls. For this condition, the reduced active and at-rest pressures provided previously for sand, pea gravel, or crushed rock backfill may be considered in wall design provided they are installed as shown (Appendix C). Where the onsite soils materials or imported sand (with a Sand Equivalent of 30 or greater) are used as backfill behind the proposed retaining walls, the backfill materials should be placed in approximately 6- to 8-inch-thick maximum lifts, watered as necessary to achieve near optimum moisture conditions, and then mechanically compacted in place to a minimum relative compaction of 90 percent. Flooding or jetting of the backfill materials should be avoided. A representative of the project geotechnical consultant should observe the backfill procedures and test the wall backfill to verify adequate compaction. If imported pea gravel or rock is used for backfill, the gravel should be placed in approximately 2- to 3- foot-thick lifts, thoroughly wetted but not flooded, and then mechanically tamped or vibrated into place. A representative of the project geotechnical consultant should observe the backfill procedures and probe the backfill to determine that an adequate degree of compaction is achieved. To reduce the potential for the direct infiltration of surface water into the backfill, imported sand, gravel, or rock backfill should be capped with at least 12 to 18 inches of on-site soil. Filter fabric such as Mirafi 140N or equivalent, should be placed between the soil and the imported gravel or rock to prevent fines from penetrating into the backfill. If a thicker cap is desired (for planting or other reasons), consultation with the project structural engineer may be required to ascertain if the wall design is appropriate for the additional lateral pressure that a thicker cap of native material may impose. Geotechnical Observation and Testing All grading and construction phases associated with retaining wall construction, including backcut excavations, observation of the footing and pier excavations, installation of the subdrainage systems, and placement of backfill should be provided by a representative of the project geotechnical consultant. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 21 Masonry Block Walls (Non-Retaining) Footings for free-standing (non-retaining) masonry block walls may be designed in accordance with the bearing and lateral resistance values provided previously for building footings. However, as a minimum, the wall footings should be embedded at a minimum depth of 12 inches below the lowest adjacent final grade. The footings should also be reinforced with a minimum of two No. 4 bars, one top and one bottom. In order to reduce the potential for unsightly cracking related to the possible effects of differential settlement and/or expansion, positive separations (construction joints) should also be provided in the block walls at each corner and at horizontal intervals of approximately 20 to 25 feet. The separations should be provided in the blocks and not extend through the footings. The footings should be poured monolithically with continuous rebars to serve as effective “grade beams” below the walls. Planter Walls Low-height planter walls should be supported by continuous concrete footings constructed in accordance with the recommendations presented previously for masonry block wall footings. Swimming Pool and Spa Recommendations Allowable Bearing, Settlement, and Lateral Earth Pressures The pool and spa shells may be designed using an allowable bearing value of 1,000 pounds per square foot. It is anticipated that the swimming pool and spa will be located within an area that is underlain by competent terrace deposits. If it in fact the shells span a transition between engineered fill and competent terrace deposits, the pool and spa shells should be deepened to competent terrace deposits. Based on this condition, total settlement and associated differential of the shell can be expected on the order of less than ¼ of an inch. Pool and spa walls should be designed assuming that an earth pressure equivalent to a fluid having a density of 53 pounds per cubic foot is acting on the outer surface of the walls. Pool and spa walls should also be designed to resist lateral surcharge pressures imposed by any adjacent footings or structures in addition to the above lateral earth pressure. Care should be taken while excavating the pool and spa bottoms to prevent disturbance of the terrace deposits exposed at grade in the pool and spa bottoms. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 22 Temporary Access Ramps It is essential that all backfill placed within temporary access ramps extending into the pool and spa excavations be compacted and tested. This is intended to reduce excessive settlement of the backfill and subsequent damage to concrete decking or other structures placed on the backfill. Plumbing Fixtures Leakage from the pool/spa or from any of the appurtenant plumbing could create adverse saturated conditions of the surrounding subgrade soils. Localized areas of over-saturation can lead to differential settlement of the subgrade soils and subsequent shifting of concrete flatwork. Therefore, it is essential that all plumbing and pool fixtures be absolutely leak-free. For similar reasons, drainage from deck areas should be directed to local area drains designed to carry runoff water to a suitable discharge point. Pool and Spa Decking Pool and spa decking should be constructed in accordance with the recommendations presented in the “Exterior Concrete Flatwork” section of this report. Post-Grading Considerations Utility Trenches All utility trench backfill should be compacted to a minimum relative compaction of 90 percent. Due to the nature of the onsite earth materials, flooding and jetting techniques should be avoided. Therefore, trench backfill materials should be placed in lifts no greater than approximately 12 inches in thickness, watered or air-dried as necessary to achieve near optimum moisture conditions, and then mechanically compacted in place to a minimum relative compaction of 90 percent. A representative of the project geotechnical consultant should probe and test the backfills to verify adequate compaction. As an alternative for shallow trenches where pipe or utility lines may be damaged by mechanical compaction equipment, such as under building floor slabs, imported clean sand having a sand equivalent (SE) value of 30 or greater may be utilized. The sand backfill materials should be watered to achieve near optimum moisture conditions and then tamped into place. No specific relative compaction will be required; however, observation, probing, and if deemed necessary, testing should be performed by a representative of the project geotechnical consultant to verify an adequate degree of compaction. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 23 If clean, imported sand is to be used for backfill of exterior utility trenches, it is recommended that the upper 12 inches of trench backfill materials consist of properly compacted onsite soil materials. This is to mitigate infiltration of irrigation and rainwater into granular trench backfill materials. Where an exterior and/or interior utility trench is proposed in a direction parallel to a building footing, the bottom of the trench should not extend below a 1:1 (horizontal to vertical) plane projected downward from the bottom edge of the adjacent footing. Where this condition occurs, the adjacent footing should be deepened or the utility constructed and the trench backfilled and compacted prior to footing construction. Where utility trenches cross under a building footing, these trenches should be backfilled with on-site soils at the point where the trench crosses under the footing to reduce the potential for water to migrate under the floor slabs. Site Drainage Positive surface drainage systems consisting of a combination of sloped concrete flatwork, swales and possibly subsurface area drains (if needed) should be provided around the building and within the planter areas to collect and direct all surface waters to an appropriate drainage facility as determined by the project civil engineer. The ground surfaces of planter and landscape areas that are located within 10 feet of building foundations should be sloped at a minimum gradient of 5 percent away from the foundations and towards the nearest area drains. The ground surface of planter and landscape areas that are located more than 10 feet away from building foundations may be sloped at a minimum gradient of 2 percent away from the foundations and towards the nearest area drains. Concrete flatwork surfaces that are located within 10 feet of building foundations should be inclined at a minimum gradient of one percent away from the building foundations and towards the nearest area drains. Concrete flatwork surfaces that are located more than 10 feet away from building foundations may be sloped at a minimum gradient of 1 percent towards the nearest area drains. Surface waters should not be allowed to collect or pond against building foundations and within the level areas of the site. All drainage devices should be properly maintained throughout the lifetime of the development. Future changes to site improvements, or planting and watering practices, should not be allowed to cause over-saturation of site soils adjacent to the structures. Exterior Concrete Flatwork General Near-surface compacted fill soils within the site are expected to exhibit very low expansion potential. Therefore, we recommend that all exterior concrete flatwork such as sidewalks, patio slabs, large decorative MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 24 slabs, concrete subslabs that will be covered with decorative pavers, private and/or public vehicular driveways and/or access roads within and adjacent to the site be designed by the project architect and/or structural engineer with consideration given to mitigating the potential cracking and uplift that can develop in soils exhibiting expansion index values that fall in the very low category. The guidelines that follow should be considered as minimums and are subject to review and revision by the project architect, structural engineer and/or landscape consultant as deemed appropriate. Thickness and Joint Spacing To reduce the potential of unsightly cracking, concrete walkways, patio-type slabs, large decorative slabs and concrete subslabs to be covered with decorative pavers should be at least 4 inches thick and provided with construction joints or expansion joints every 6 feet or less. Private driveways that will be designed for the use of passenger cars for access to private garages should also be at least 5 inches thick and provided with construction joints or expansion joints every 10 feet or less. Reinforcement All concrete flatwork having their largest plan-view panel dimension exceeding 5 feet should be reinforced with a minimum of No. 3 bars spaced 24 inches on centers, both ways. Alternatively, the slab reinforcement may consist of welded wire mesh of the sheet type (not rolled) with 6x6/W1.4xW1.4 WWF designation in accordance with the Wire Reinforcement Institute (WRI). The reinforcement should be properly positioned near the middle of the slabs. The reinforcement recommendations provided herein are intended as guidelines to achieve adequate performance for anticipated soil conditions. The project architect, civil and/or structural engineer should make appropriate adjustments in reinforcement type, size and spacing to account for concrete internal (e.g., shrinkage and thermal) and external (e.g., applied loads) forces as deemed necessary. Edge Beams (Optional) Where the outer edges of concrete flatwork are to be bordered by landscaping, it is recommended that consideration be given to the use of edge beams (thickened edges) to prevent excessive infiltration and accumulation of water under the slabs. Edge beams, if used, should be 6 to 8 inches wide, extend 8 inches below the tops of the finish slab surfaces. Edge beams are not mandatory; however, their inclusion in flatwork construction adjacent to landscaped areas is intended to reduce the potential for vertical and MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 25 horizontal movement and subsequent cracking of the flatwork related to uplift forces that can develop in expansive soils. Subgrade Preparation Compaction To reduce the potential for distress to concrete flatwork, the subgrade soils below concrete flatwork areas to a minimum depth of 12 inches (or deeper, as either prescribed elsewhere in this report or determined in the field) should be moisture conditioned to at least equal to, or slightly greater than, the optimum moisture content and then compacted to a minimum relative compaction of 90 percent. Pre-Moistening As a further measure to reduce the potential for concrete flatwork cracking, subgrade soils should be thoroughly moistened prior to placing concrete. The moisture content of the soils should be at least 1.2 times the optimum moisture content and penetrate to a minimum depth of 12 inches into the subgrade. Flooding or ponding of the subgrade is not recommended to achieve the above moisture conditions since this method would likely require construction of numerous earth berms to contain the water. Therefore, moisture conditioning should be achieved with a light spray applied to the subgrade over a period of few days just prior to pouring concrete. Pre-watering of the soils is intended to promote uniform curing of the concrete, reduce the development of shrinkage cracks, and reduce the potential for differential expansion pressure on freshly poured flatwork. A representative of the project geotechnical consultant should observe and verify the density and moisture content of the soils, and the depth of moisture penetration prior to pouring concrete. Drainage Drainage from patios and other flatwork areas should be directed to local area drains and/or graded earth swales designed to carry runoff water to the adjacent streets or other approved drainage structures. The concrete flatwork should be sloped at a minimum gradient of one percent, or as prescribed by project civil engineer or local codes, away from building foundations, retaining walls, masonry garden walls and slope areas. Tree Wells Tree wells are not recommended in concrete flatwork areas since they introduce excessive water into the subgrade soils and allow root invasion, both of which can cause heaving and cracking of the flatwork. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 26 GRADING PLAN REVIEW AND FUTURE IMPROVEMENTS Petra should review the site grading plans when they become available and issue an addendum letter to this report if necessary. If additional improvements are considered in the future, our firm should be notified so that we may provide design recommendations to mitigate movement, settlement and/or tilting of the structures. Potential problems can develop when drainage is altered in any way such as placement of fill and construction of new walkways, patios, landscape walls, or planters. Therefore, it is recommended that we be engaged to review the final design drawings, specifications, and grading plan prior to any new construction. If we are not provided the opportunity to review these documents with respect to the geotechnical aspects of new construction and grading, it should not be assumed that the recommendations provided herein are wholly or in part applicable to the proposed construction. REPORT LIMITATIONS This report is based on the proposed project and geotechnical data as described herein. The materials encountered on the project site and utilized in our laboratory investigation are believed representative of the project area, and the conclusions and recommendations contained in this report are presented on that basis. However, soil materials and moisture conditions can vary in characteristics between points of exploration, both laterally and vertically, and those variations could affect the conclusions and recommendations contained herein. As such, observation and testing by a geotechnical consultant during the grading and construction phases of the project are essential to confirming the basis of this report. This report has been prepared consistent with that level of care being provided by other professionals providing similar services at the same locale and time period. The contents of this report are professional opinions and as such, are not to be considered a guarantee or warranty. This report should be reviewed and updated after a period of one year or if the project concept changes from that described herein. The information contained herein has not been prepared for use by parties or projects other than those named or described herein. This report may not contain sufficient information for other parties or other purposes. This report is subject to review by the controlling authorities for this project. MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 27 Should you have any questions, please do not hesitate to call. Respectfully submitted, PETRA GEOSCIENCES, INC. 5/11/2020 Jim Larwood Grayson R. Walker Principal Geologist Principal Engineer CEG 1897 GE 871 JL/GRW/lv W:\2020-2025\2020\100\20-155 Scott Sarem (4005 Skyline Road, Carlsbad)\Reports\20-155 110 Prelim Geotechnical Report.docx \ MR. SCOTT SAREM May 11, 2020 4005 Skyline Road. / Carlsbad J.N. 20-155 Page 28 REFERENCES American Concrete Institute, 2014, Building Code Requirements for Structural Concrete (ACI 318-14) and Commentary. Bryant, W.A., and Hart, E.W., 2007, Fault-Rupture Hazard Zones in California, Alquist-Priolo Earthquake Fault Zoning Act with Index to Earthquake Fault Zones Maps, California Geological Survey, Special Publication 42. California Department of Water Resources, 2018, Water Data Library, http://www.water.ca.gov/waterdatalibrary/ accessed September. California Geological Survey, 2010, ‘Fault Activity Map of California, Geologic Data Map No. 6, http://maps.conservation.ca.gov/cgs/fam/. ______, 2018, Earthquake Fault Zones, A Guide for Government Agencies, Property Owners/Developers, and Geoscience Practitioners for Assessing Fault Rupture Hazards in California, Special Publication 42. Google Earth™ 2020, by Google Earth, Inc., http://www.google.com/earth/index.html, accessed May. International Building Code, 2013, 2015, 2016, 2019 California Building Code, California Code of Regulations, Title 24, Part 2, Volume 2 of 2, Based on the 2019 International Building Code, California Building Standards Commission. Jennings, C.W. and Bryant, W.A., 2010, Fault Activity Map of California: California Geological Survey, Geologic Data Map No. 6. Kennedy, M.P. and Tan, S.S, 2007, Geologic map of the Oceanside 30’ x 60’ quadrangle, California, United States Geological Survey. Macrostrat, Creative Commons Attribution 4.0, 2020, accessed May. https://macrostrat.org/map/ San Diego County Regional Standards Committee, 2108, Regional Standard Drawing Book, 2018 Edition. http://www.regional-stds.com/home/book/drawings SEAOC & OSHPD Seismic Design Maps Web Application – https://seismicmaps.org/ Tan, S. S., 1995, Landslide Hazards in the Northern Part of the San Diego Metropolitan Area, San Diego County, California, Relative Landslide Susceptibility and Landslide Distribution Map, Plate A, California Division of Mines and Geology Open-File Report 95-04. Tan, S.S., and Kennedy, M.P., 1996, Geologic maps of the northwestern part of San Diego County, California: California Division of Mines and Geology, Open File Report 96-02. United States Geological Survey (USGS), 2014, Unified Hazard Tool v4.0x, https://earthquake.usgs.gov/hazards/interactive/ FIGURES H PETRA NATIVE SOIL BACKFILL / ~ ~ _}Sloped= g: surtace .. Compacted on-site soil r;:;O" • :; : ,,,, ~ Fi~ter_fabric (shoui~ consist of : ~o (/ ~ M1raf1 140N or eqwvalent) ~ 4 inch perforated pipe. Perforated pipe should consist of 4" diameter ABS SDR-35 or PVC Schedule 40 or approved equivalent with the · perforations laid down. Pipe should be laid on . at least 2 inches of open-graded gravel. * Vertical height (h) and slope angle of backcut per soils report. Based on geologic conditions, configuration of backcut may require revisions (i.e. reduced vertical height, revised slope angle, etc.) RETAINING WALL BACKFILL AND SUBDRAIN DETAILS FIGURE RW-1 H PETR IMPORTED SAND BACKFILL Waterproofing compound .-:-,:/{::}:(~ stall subdrain system :}\-:/:~:\{: cubic toot per toot min. of s14" -1 112" -/•:_:,::..-.:-:.-·./.-pen graded gravel wrapped in filter · ... _.:_.·.:::·-:::· ·· bric. Filter fabric (should consist of · Mirafi 140N or equivalent). 4 inch perforated pipe. Perforated pipe should consist of 4" diameter ABS SDR-35 or PVC Schedule 40 or approved equivalent with the · perforations laid down. Pipe should be laid on .· at least 2 inches of open-graded gravel. * At base of wall, the non-expansive backfill materials should extend to a min. distance of 2' or to a horizontal distance equal to the heel width of the footing, whichever is greater. RETAINING WALL BACKFILL AND SUBDRAIN DETAILS FIGURE RW-2 IMPORTED GRAVEL OR CRUSHED ROCK BACKFILL H PETR Non-expansive imported ·· gravel or crushed rock Install filter fabric (Mirafi 140N or equal) to prevent migration of fines into backfill. . 4 inch perforated pipe. Perforated pipe should · consist of 4" diameter ABS SDR-35 or PVC . Schedule 40 or approved equivalent with the perforations laid down. If pea gravel used, pipe should be encased in 1 cubic foot per · foot min. of 3/4" -1 i/2" open-graded gravel wrapped in filter fabric (Mirafi 140N or equal) Pipe should be laid on at least 2 inches of gravel. * At base of wail, the non-expansive backfill materials should extend to a min. distance of 2' or to a horizontal distance equal to the heel width of the footing, whichever is greater. RETAINING WALL BACKFILL AND SUBDRAIN DETAILS FIGURE RW-3 Scale: 1” = 2,000’ Base Map: Portion of USGS San Luis Rey Quadrangle 7.5-Minute Topographic Series, 2018 N 41880 County Center Drive, Suite M Temecula, California 92591 PHONE: (951) 600-9271COSTA MESA TEMECULA VALENCIA PALM DESERT CORONA SAN DIEGO SITE LOCATION MAP 4005 Skyline Road Carlsbad, California DATE: May 2020 J.N.: 20- 155 Figure 1 PETRA GEOSCIENCES, INC. SITE GEOTECHNICAL MAP 40880 County Center Drive, Suite M Temecula, California 92591 PHONE: (951) 600-9271 COSTA MESA TEMECULA VALENCIA PALM DESERT CORONA SAN DIEGO 4005 Skyline Road Carlsbad, California DATE: May 2020 J.N.: 20-155 Figure 2 N PETRA GEOSCIENCES, INC.EXPLANATION Artificial Fill, undocumented Very Old Paralic Deposits, Circled Where Buried Approximate Location Of Exploratory Test Pit TD = Total Depth Qvol afu EXPLANATION Compacted Artificial Fill (GMU, 2006) Topanga Formation, Circled Where Buried Geologic Contact, Dotted Where Buried (GMU, 2006) Bedding Attitude (GMU, 2006) Vertical Bedding Attitude (GMU, 2006) Approximate Location Of Exploratory Boring TD = Total Depth Geologic Cross Section B-3 TD=26.5’ Tt Qafc BB’ 34 EXPLANATION Compacted Artificial Fill (GMU, 2006) Topanga Formation, Circled Where Buried Geologic Contact, Dotted Where Buried (GMU, 2006) Bedding Attitude (GMU, 2006) Vertical Bedding Attitude (GMU, 2006) B-3 TD=26.5’ Tt Qafc B B’ 34 Approximate Elevation of Fill to Bedrock Contact (Current Investigation, at Exploration Point) Approximate Elevation of Fill to Bedrock Conract (GMU, 2006) Approximate Location Of Exploratory Boring TD = Total Depth Geologic Cross Section 647 688 0 4020 Scale: 1” = 20’ Proposed Pool Existing Pool Existing Residence Tvs HA-3 TD=2.4’ HA-1 TD=8’ HA-2 TD=8’ af Qes B-1 TD=67.5’ B-2 TD=26.5’ B-3 TD=26.5’ B-4 TD=26.5’ 365365TP-1 TD=5’ TP-2 TD=5’ Qyf af B-1 TD=5’ B-2 TD=21.5’ B-3 TD=61.5’ N CPT-1 TD=55’ B-1 TD=51.5’ P-1 TD=5’ Qomf Tm Tt Ta B-2TD=21.5’TsoafTsoaf Base Map Reference: B + D Studio Preliminary Site Plan, sheet C-1, dated February 28, 2020 TP-4 TD=6’ N TP-3 TD=3.5’ TP-4 TD=6’ TP-1 TD=5.2’ TP-2 TD=4’ possible septic lines possible septic tank afu afu ?? ? ? ? ?? ? afu Qvol Qvol Qvol PLATE A-1 LOGS OF TEST PITS LOGS OF TEST PITS PETRA GEOSCIENCES, INC. 4/15/2020 J.N. 20-155 Plate A-1 TEST PIT NUMBER DEPTH (ft) DESCRIPTION TP-1 0 - 1 Undocumented Artificial Fill (afu): Dark brown, Silty SAND (SM), fine to coarse grained, moist to wet; loose; abundant roots. 1 – 3.5 WEATHERED SANDSTONE (Qvol): Light reddish brown, fine to coarse grained with some clay, wet, dense; 3.5 – 4.5 SANDSTONE (Qvol): Becomes medium red brown 4.5 – 5.2 Becomes very dense Total Depth 5.2 ft, no groundwater encountered; practical refusal on dense material. TP-2 0 – 2.5 Undocumented Artificial Fill (afu): Medium brown, Silty SAND (SM), fine to coarse grained, moist to wet; loose; abundant roots. 2.5 Top of suspected leach line at west side of trench. 4 to 6-inch diameter clay pipe, loosely fitted, trending north-south, encased in 1 to 2-inch diameter gravel; no odors, observed to be clean water. 2.5 - 4 SANDSTONE (Qvol): reddish brown, fine to coarse grained with some clay, moist, dense; sone iron-oxide staining. Total Depth 4 ft, no groundwater encountered; seepage from suspected leach line pipe; practical refusal on dense material. TP-3 0 - 1 Undocumented Artificial Fill (afu): Dark brown, Silty SAND (SM), fine to coarse grained, moist to wet; loose; abundant roots. 1 – 2.5 WEATHERED SANDSTONE (Qvol): Weathered reddish brown, fine to coarse grained with some clay, moist to wet, dense; 3.5 SANDSTONE (Qvol): Becomes very dense Total Depth 3.5 ft, no groundwater encountered; practical refusal on dense material. TP-4 0 – 2 Undocumented Artificial Fill (afu): Dark brown, Silty SAND (SM), fine to coarse grained, moist to wet; loose; abundant roots. 2 Top of suspected leach line at west side of trench. 4 to 6-inch diameter clay pipe, loosely fitted, trending north-south, encased in 1 to 2-inch diameter gravel; no odors, no water in pipe. 2 - 4 SANDSTONE (Qvol): reddish brown, fine to coarse grained, moist, dense; sone iron-oxide staining. 4 - 6 Becomes mottled with light gray and some clay. Total Depth 6 ft, no groundwater encountered; practical refusal on dense material. APPENDIX A LABORATORY TEST PROCEDURES LABORATORY DATA SUMMARY PETRA GEOSCIENCES, INC. Laboratory Address: 1251 W. Pomona Road, Unit 103, Corona, CA, 92882 J.N. 20-155 PLATE A-1 LABORATORY TEST PROCEDURES Soil Classification Soil materials encountered within the property were classified and described in accordance with the Unified Soil Classification System and in general accordance with the current version of Test Method ASTM D 2488. The assigned group symbols are presented on Plate A-1. Laboratory Maximum Dry Unit Weight and Optimum Moisture Content The maximum dry unit weight and optimum moisture content of the on-site soils were determined for a selected bulk sample in accordance with current version of Method B of ASTM D 1557. The results of these tests are presented on Plate B-1. Expansion Index An expansion index test was performed on a selected bulk sample of the on-site soils in accordance with the current version of Test Method ASTM D 4829. The test results are presented on Plate A-1. Corrosivity Screening Chemical and electrical analyses were performed on a selected bulk sample of onsite soils to determine soluble sulfate content, chloride content, pH (acidity) and minimum electrical resistivity. These tests were performed in accordance with the current versions of California Test Method Nos. CTM 417, CTM 422 and CTM 643, respectively. The results of these tests are included on Plate A-1. PETRA GEOSCIENCES, INC. Laboratory Address: 1251 W. Pomona Road, Unit 103, Corona, CA, 92882 J.N. 20-155 PLATE A-1 LABORATORY DATA SUMMARY* Test Pit Number Sample Depth (ft) Soil Description Max. Dry Density 1 (pcf) Optimum Moisture1 (%) Expansion Index2 CBC Soil Classification3 Atterberg Limits4 Sulfate Content5 (%) Chloride Content6 (ppm) pH7 Minimum Resistivity7 (ohm-cm) LL PL PI TP-1 2.6 Silty/fine to coarse grained Sand with trace of clay (SM) 135.0 8.5 0 Very Low - - - 0.0015 108 7.67 8,700 Test Procedures: 1 Per ASTM Test Method D 1557 5 Per Caltrans Test Method 417 2 Per ASTM Test Method D 4829 6 Per Caltrans Test Method 422 3 Per ASTM Test Method D 4829 Table 1, Per CBC 2016 7 Per Caltrans Test Method 643 4 Per ASTM Test Method D 4318 8 Per ASTM Test Method D 1140 APPENDIX B SEISMIC DESIGN PARAMETERS 20-155 4005 Skyline Rd, Carlsbad, CA 92008, USA Latitude, Longitude: 33.1568136, -117.3205812 Date 5/6/2020, 4:32:17 PM Design Code Reference Document ASCE7-16 Risk Category II Site Class D - Default (See Section 11.4.3) Type Value Description SS 1.017 MCER ground motion. (for 0.2 second period) S1 0.37 MCER ground motion. (for 1.0s period) SMS 1.221 Site-modified spectral acceleration value SM1 null -See Section 11.4.8 Site-modified spectral acceleration value SDS 0.814 Numeric seismic design value at 0.2 second SA SD1 null -See Section 11.4.8 Numeric seismic design value at 1.0 second SA Type Value Description SDC null -See Section 11.4.8 Seismic design category Fa 1.2 Site amplification factor at 0.2 second Fv null -See Section 11.4.8 Site amplification factor at 1.0 second PGA 0.446 MCEG peak ground acceleration FPGA 1.2 Site amplification factor at PGA PGAM 0.535 Site modified peak ground acceleration TL 8 Long-period transition period in seconds SsRT 1.017 Probabilistic risk-targeted ground motion. (0.2 second) SsUH 1.133 Factored uniform-hazard (2% probability of exceedance in 50 years) spectral acceleration SsD 1.5 Factored deterministic acceleration value. (0.2 second) S1RT 0.37 Probabilistic risk-targeted ground motion. (1.0 second) S1UH 0.408 Factored uniform-hazard (2% probability of exceedance in 50 years) spectral acceleration. S1D 0.6 Factored deterministic acceleration value. (1.0 second) PGAd 0.503 Factored deterministic acceleration value. (Peak Ground Acceleration) CRS 0.898 Mapped value of the risk coefficient at short periods CR1 0.909 Mapped value of the risk coefficient at a period of 1 s DISCLAIMER While the information presented on this website is believed to be correct, SEAOC /OSHPD and its sponsors and contributors assume no responsibility or liability for its accuracy. The material presented in this web application should not be used or relied upon for any specific application without competent examination and verification of its accuracy, suitability and applicability by engineers or other licensed professionals. SEAOC / OSHPD do not intend that the use of this information replace the sound judgment of such competent professionals, having experience and knowledge in the field of practice, nor to substitute for the standard of care required of such professionals in interpreting and applying the results of the seismic data provided by this website. Users of the information from this website assume all liability arising from such use. Use of the output of this website does not imply approval by the governing building code bodies responsible for building code approval and interpretation for the building site described by latitude/longitude location in the search results of this website. APPENDIX C STANDARD GRADING SPECIFICATIONS STANDARD GRADING SPECIFICATIONS Page 1 These specifications present the usual and minimum requirements for projects on which Petra Geosciences, Inc. (Petra) is the geotechnical consultant. No deviation from these specifications will be allowed, except where specifically superseded in the preliminary geology and soils report, or in other written communication signed by the Soils Engineer and Engineering Geologist of record (Geotechnical Consultant). I. GENERAL A. The Geotechnical Consultant is the Owner's or Builder's representative on the project. For the purpose of these specifications, participation by the Geotechnical Consultant includes that observation performed by any person or persons employed by, and responsible to, the licensed Soils Engineer and Engineering Geologist signing the soils report. B. The contractor should prepare and submit to the Owner and Geotechnical Consultant a work plan that indicates the sequence of earthwork grading, the number of "spreads" and the estimated quantities of daily earthwork to be performed prior to the commencement of grading. This work plan should be reviewed by the Geotechnical Consultant to schedule personnel to perform the appropriate level of observation, mapping, and compaction testing as necessary. C. All clearing, site preparation, or earthwork performed on the project shall be conducted by the Contractor in accordance with the recommendations presented in the geotechnical report and under the observation of the Geotechnical Consultant. D. It is the Contractor's responsibility to prepare the ground surface to receive the fills to the satisfaction of the Geotechnical Consultant and to place, spread, mix, water, and compact the fill in accordance with the specifications of the Geotechnical Consultant. The Contractor shall also remove all material considered unsatisfactory by the Geotechnical Consultant. E. It is the Contractor's responsibility to have suitable and sufficient compaction equipment on the job site to handle the amount of fill being placed. If necessary, excavation equipment will be shut down to permit completion of compaction to project specifications. Sufficient watering apparatus will also be provided by the Contractor, with due consideration for the fill material, rate of placement, and time of year. F. After completion of grading a report will be submitted by the Geotechnical Consultant. II. SITE PREPARATION A. Clearing and Grubbing 1. All vegetation such as trees, brush, grass, roots, and deleterious material shall be disposed of offsite. This removal shall be concluded prior to placing fill. 2. Any underground structures such as cesspools, cisterns, mining shafts, tunnels, septic tanks, wells, pipe lines, etc., are to be removed or treated in a manner prescribed by the Geotechnical Consultant. STANDARD GRADING SPECIFICATIONS Page 2 III. FILL AREA PREPARATION A. Remedial Removals/Overexcavations 1. Remedial removals, as well as overexcavation for remedial purposes, shall be evaluated by the Geotechnical Consultant. Remedial removal depths presented in the geotechnical report and shown on the geotechnical plans are estimates only. The actual extent of removal should be determined by the Geotechnical Consultant based on the conditions exposed during grading. All soft, loose, dry, saturated, spongy, organic-rich, highly fractured or otherwise unsuitable ground shall be overexcavated to competent ground as determined by the Geotechnical Consultant. 2. Soil, alluvium, or bedrock materials determined by the Soils Engineer as being unsuitable for placement in compacted fills shall be removed from the site. Any material incorporated as a part of a compacted fill must be approved by the Geotechnical Consultant. 3. Should potentially hazardous materials be encountered, the Contractor should stop work in the affected area. An environmental consultant specializing in hazardous materials should be notified immediately for evaluation and handling of these materials prior to continuing work in the affected area. B. Evaluation/Acceptance of Fill Areas All areas to receive fill, including removal and processed areas, key bottoms, and benches, shall be observed, mapped, elevations recorded, and/or tested prior to being accepted by the Geotechnical Consultant as suitable to receive fill. The contractor shall obtain a written acceptance from the Geotechnical Consultant prior to fill placement. A licensed surveyor shall provide sufficient survey control for determining locations and elevations of processed areas, keys, and benches. C. Processing After the ground surface to receive fill has been declared satisfactory for support of fill by the Geotechnical Consultant, it shall be scarified to a minimum depth of 6 inches and until the ground surface is uniform and free from ruts, hollows, hummocks, or other uneven features which may prevent uniform compaction. The scarified ground surface shall then be brought to optimum moisture, mixed as required, and compacted to a minimum relative compaction of 90 percent. D. Subdrains Subdrainage devices shall be constructed in compliance with the ordinances of the controlling governmental agency, and/or with the recommendations of the Geotechnical Consultant. (Typical Canyon Subdrain details are given on Plate SG-1). E. Cut/Fill & Deep Fill/Shallow Fill Transitions In order to provide uniform bearing conditions in cut/fill and deep fill/shallow fill transition lots, the cut and shallow fill portions of the lot should be overexcavated to the depths and the horizontal limits discussed in the approved geotechnical report and replaced with compacted fill. (Typical details are given on Plate SG-7.) STANDARD GRADING SPECIFICATIONS Page 3 IV. COMPACTED FILL MATERIAL A. General Materials excavated on the property may be utilized in the fill, provided each material has been determined to be suitable by the Geotechnical Consultant. Material to be used for fill shall be essentially free of organic material and other deleterious substances. Roots, tree branches, and other matter missed during clearing shall be removed from the fill as recommended by the Geotechnical Consultant. Material that is spongy, subject to decay, or otherwise considered unsuitable shall not be used in the compacted fill. Soils of poor quality, such as those with unacceptable gradation, high expansion potential, or low strength shall be placed in areas acceptable to the Geotechnical Consultant or mixed with other soils to achieve satisfactory fill material. B. Oversize Materials Oversize material defined as rock, or other irreducible material with a maximum dimension greater than 12 inches in diameter, shall be taken offsite or placed in accordance with the recommendations of the Geotechnical Consultant in areas designated as suitable for rock disposal (Typical details for Rock Disposal are given on Plate SG-4). Rock fragments less than 12 inches in diameter may be utilized in the fill provided, they are not nested or placed in concentrated pockets; they are surrounded by compacted fine grained soil material and the distribution of rocks is approved by the Geotechnical Consultant. C. Laboratory Testing Representative samples of materials to be utilized as compacted fill shall be analyzed by the labora- tory of the Geotechnical Consultant to determine their physical properties. If any material other than that previously tested is encountered during grading, the appropriate analysis of this material shall be conducted by the Geotechnical Consultant as soon as possible. D. Import If importing of fill material is required for grading, proposed import material should meet the requirements of the previous section. The import source shall be given to the Geotechnical Consultant at least 2 working days prior to importing so that appropriate tests can be performed and its suitability determined. V. FILL PLACEMENT AND COMPACTION A. Fill Layers Material used in the compacting process shall be evenly spread, watered, processed, and compacted in thin lifts not to exceed 6 inches in thickness to obtain a uniformly dense layer. The fill shall be placed and compacted on a horizontal plane, unless otherwise approved by the Geotechnical Consultant. STANDARD GRADING SPECIFICATIONS Page 4 B. Moisture Conditioning Fill soils shall be watered, dried back, blended, and/or mixed, as necessary to attain a relatively uniform moisture content at or slightly above optimum moisture content. C. Compaction Each layer shall be compacted to 90 percent of the maximum density in compliance with the testing method specified by the controlling governmental agency. (In general, ASTM D 1557-02, will be used.) If compaction to a lesser percentage is authorized by the controlling governmental agency because of a specific land use or expansive soils condition, the area to received fill compacted to less than 90 percent shall either be delineated on the grading plan or appropriate reference made to the area in the soils report. D. Failing Areas If the moisture content or relative density varies from that required by the Geotechnical Consultant, the Contractor shall rework the fill until it is approved by the Geotechnical Consultant. E. Benching All fills shall be keyed and benched through all topsoil, colluvium, alluvium or creep material, into sound bedrock or firm material where the slope receiving fill exceeds a ratio of 5 horizontal to 1 vertical, in accordance with the recommendations of the Geotechnical Consultant. VI. SLOPES A. Fill Slopes The contractor will be required to obtain a minimum relative compaction of 90 percent out to the finish slope face of fill slopes, buttresses, and stabilization fills. This may be achieved by either overbuilding the slope and cutting back to the compacted core, or by direct compaction of the slope face with suitable equipment, or by any other procedure that produces the required compaction. B. Side Hill Fills The key for side hill fills shall be a minimum of 15 feet within bedrock or firm materials, unless otherwise specified in the soils report. (See detail on Plate SG-5.) C. Fill-Over-Cut Slopes Fill-over-cut slopes shall be properly keyed through topsoil, colluvium or creep material into rock or firm materials, and the transition shall be stripped of all soils prior to placing fill. (see detail on Plate SG-6). STANDARD GRADING SPECIFICATIONS Page 5 D. Landscaping All fill slopes should be planted or protected from erosion by other methods specified in the soils report. E. Cut Slopes 1. The Geotechnical Consultant should observe all cut slopes at vertical intervals not exceeding 10 feet. 2. If any conditions not anticipated in the preliminary report such as perched water, seepage, lenticular or confined strata of a potentially adverse nature, unfavorably inclined bedding, joints or fault planes are encountered during grading, these conditions shall be evaluated by the Geotechnical Consultant, and recommendations shall be made to treat these problems (Typical details for stabilization of a portion of a cut slope are given in Plates SG-2 and SG- 3.). 3. Cut slopes that face in the same direction as the prevailing drainage shall be protected from slope wash by a non-erodible interceptor swale placed at the top of the slope. 4. Unless otherwise specified in the soils and geological report, no cut slopes shall be excavated higher or steeper than that allowed by the ordinances of controlling governmental agencies. 5. Drainage terraces shall be constructed in compliance with the ordinances of controlling governmental agencies, or with the recommendations of the Geotechnical Consultant. VII. GRADING OBSERVATION A. General All cleanouts, processed ground to receive fill, key excavations, subdrains, and rock disposals must be observed and approved by the Geotechnical Consultant prior to placing any fill. It shall be the Contractor's responsibility to notify the Geotechnical Consultant when such areas are ready. B. Compaction Testing Observation of the fill placement shall be provided by the Geotechnical Consultant during the progress of grading. Location and frequency of tests shall be at the Consultants discretion based on field conditions encountered. Compaction test locations will not necessarily be selected on a random basis. Test locations may be selected to verify adequacy of compaction levels in areas that are judged to be susceptible to inadequate compaction. C. Frequency of Compaction Testing In general, density tests should be made at intervals not exceeding 2 feet of fill height or every 1000 cubic yards of fill placed. This criteria will vary depending on soil conditions and the size of the job. In any event, an adequate number of field density tests shall be made to verify that the required compaction is being achieved. STANDARD GRADING SPECIFICATIONS Page 6 VIII. CONSTRUCTION CONSIDERATIONS A. Erosion control measures, when necessary, shall be provided by the Contractor during grading and prior to the completion and construction of permanent drainage controls. B. Upon completion of grading and termination of observations by the Geotechnical Consultant, no further filling or excavating, including that necessary for footings, foundations, large tree wells, retaining walls, or other features shall be performed without the approval of the Geotechnical Consultant. C. Care shall be taken by the Contractor during final grading to preserve any berms, drainage terraces, interceptor swales, or other devices of permanent nature on or adjacent to the property. S:\!BOILERS-WORK\REPORT INSERTS\STANDARD GRADING SPECS DEPTH AND BEDDING MAY VARY WITH PIPE AND LOAD CHARACTERISTICS. (3' TYPICAL) PROPOSED COMPACTED FILL REMOVE UNSUITABLE MATERIAL c;~;,~ENTNAT1~~so1L: · ·. ORBEDROCKMATERIALS · AS DETERMINED BY THE · . GEOTECHN/CAL . . . · CONSUL TANT . . ALTERNATE SUBDRAIN SYSTEM - . · MINIMUM OF 9 CUBIC FEET PER < LINEAL FOOT OF CLASS 2 FILTER .. MATERIAL. SEE PLATE SG-3 FOR . CLASS 2 FILTER MATERIAL ·SPECIFICATIONS. CLASS 2 MATERIAL OOES NOT NEED TO BE ENCASED IN FILTER FABRIC. MINIMUM 6-INCH DIAMETER PVC SCHEDULE 40, OR ABS SDR-35 WITH A MINIMUM OF EIGHT 1/4-INCH DIAMETER PERFORATIONS PER LINEAL FOOT IN BOTTOM HALF OF PIPE. PIPE TO BE LAID WITH PERFORATIONS FACING DOWN. NQJES: 1. FOR CONTINUOUS RUNS IN EXCESS OF 500 FEET USE 8-INCH DIAMETER PIPE. 2. FINAL 20 FEET OF PIPE AT OUTLET SHALL BE NON-PERFORATED AND BACKFILLED WITH FINE-GRAINED MATERIAL. ·PETRA CANYON SUBDRA1N DETAtl PLATESG-1 ROUGH GRADING CONSTRUCTION. PROVIDE GRATES TO PREVENT RODENT NESTING. PROPOSED GRADE OVEREXCAVATE PAD AS RECOMMENDED BY GEOTECHNICAL CONSULT ANT OUTLETS TO BE SPACED AT 100' MAX. INTERVALS.\ EXTEND 12" BEYOND FACE OF SLOPE AT TIME OF ,__..._ _________________ .,__,. ",' , ,,·. -.. ,·,, •' "• ',·,,,•· ,' ' 2' Mir{ t<EY bEPTH ir-fr6 d6~PETEN'r BEDROCK OR COMPETENT SOIL MATERIALS AS DETERMINED BY THE GEOTECHNICAL CONSUL TANT N.QIES: .,..,.,.........,.,.. 1; 30' MAXIMUM VERTICAL SPACING BETWEEN SUBDRAIN SYSTEMS. i,. ,',.,'. ,·,, .,,• ·.·· , .··•• •• .. TYPl~A~-~~NCHl~(i ·--. 2. tOO' MAXIMUM HORIZONTAL DISTANCE BETWEEN NON-PERFORATED OUTLET PIPES. (See Below) 3. MINIMUM GRADIENT OF 2% FOR ALL PERFORATED AND NON-PERFORATED PIPE. SECTION A-A (PERFORATED PIPE PROFILE) ---------100' max.--------1--< ---50'-------I•-< ---50'------ \ OUTLET PIPE (TYPICAL) PETRA \I -~ PERFORATED PIPE (lYPICAL) BUTTRESS OR STABILIZATION FILL DETAIL :::D g< \ OUTLET PIPE (TYPICAL) PLATESG.;2 .. ··.•.····· .• ·• . APPROVEDFILTERMATERIAL(OPEN-', : . ·. . ., ·• , : GRADED GRAVEL WRAPPED IN FILTER , ) ... · .. ·.,. ;··.·.·.·. -: ... :.;. /· ~ FABRIC OR CLASS 2 FILTER MATERIAL). ; !, ·• •· : f-'/.'.,, .:· -.. -._:·.:·.:·.:·.: 5 CUBIC FEET OF CLASS 2 FILTER · ~}'' .:· .. \··.::.:·.:·.:·. MATERIAL WITHOUT FILTER FABRIC SLOPE FACE f!:~========::!i=:::::::=::::::===:;::::::::=:::::;;;;;;;;;~ 12" min. 1 . [& ......... • ............. , , ...... · ... • .. .. .. MIRAFI 140N OR EQUIVALENT, AND ' ··.:·.;-;·.:· .. '.:·.:· .. ,,\ ... :·.:·.:· .. '.:·.:·, ··:·.:·;·.. SHOULD BE LAPPED A MINIMUM OF ·. . ::··/·.:·-::··~-::•·::-.::-·::-.::i:-\·\·•::·/•:::\ .. 12 INCHES ·: ;A-INbH NO~-PEJ·;6il+~·b::·~i;{:/::-:· .... 4-INCH PERFORATED PIPE WITH MINIMUM 2% GRADE TO OUTLET. PERFORATIONS DOWN. MINIMUM 2% GRADE TO OUTLET PIPE. ;~~~;*J•s~fil__APPROVED ON-SITE MATERIAL PER SOILS ENGINEER ~~{~fl COMPACTED TO A MINIMUM OF 90% MAXIMUM DENSITY. f"<,"""'"5j . 4-INCH NON-PERFORATED PIPE . ,: ,::; ''1,. SECTION B-B (OUTLET PIPE) PIPE SPECIFICATIONS: 1. 4-INCH MINIMUM DIAMETER, PVC SCHEDULE 40 OR ABS SDR-35. 2. FOR PERFORATED PIPE, MINIMUM 8 PERFORATIONS PER FOOT ON BOTTOM HALF OF PIPE. FILTER MATERIAL/FABRIC SPECIFICATIONS: OPEN-GRADED GRAVEL ENCASED IN FILTER FABRIC. (MIRAFI 140N OR EQUIVALENT) OPEN-GRADED GRAVEL SIEVE SIZE 11/2-JNCH 1-INCH 3/4-INCH 3/8-INCH No. 200 PERCENT PASSING 88-100 5-40 0-17 0-7 0-3 ALTERNATE: CLASS 2 PERMEABLE FIL TEA MATERIAL PER CAL TRANS STANDARD SPECIFICATION 68-1.025. CLASS 2 FILTER MATERIAL SIEY'.E SIZE PERCENT PASSING 1-INCH 100 3/4-INCH 90-100 3/8-INCH 40-100 No.4 25-40 No.8 18 -33 No. -30 5-15 No. -50 0-7 No. 200 0-3 PETRA BUTTRESS OR STABILIZATION FILL SUBDRAIN PLATESG-3 10' l FINISHED GRADE CLEAR AREA FOR FOUNDATIONS, UTILITIES AND SWIMMING POOLS SLOPE FACE STREET WINDROW COMPACTED FILL .. --::~\\\),......- TYPICAL WINDROW DETAIL (END VIEW) GRANULAR SOIL JETTED OR FLOODED TO FILL VOIDS . ,-'' '_, 5' OR MIN. OF 2' BELOW DEPTH OF DEEPEST UTILITY TRENCH, WHICHEVER IS GREATER K----------15'MIN.----------+i TYPICAL WINDROW DETAIL (PROFILE VIEW) N.QIE: OVERSIZE ROCK IS DEFINED AS CLASTS HAVING A MAXIMUM DIMENSION OF 12" OR LARGER PETRA TYPICAL ROCK DISPOSAL DETAIL PLATESG-4 TOE OF SLOPE AS SHOWN ON GRADING PLAN REMOVE MATERIAL i:'f[L • I<... · 15' MINIMUM_.i _____ .,.. .. · . KEYWIDTH 2' MIN. KEY DEPTH INTO COMP~EN·T. · BEDROCK OR SOIL MATERIALS AS . DETERMINED BY THE GEOTECHNICAL .. CONSULT ANT . ~: Ai TYP;CAL ' ··•• -~~.<l-·· ·.··.· .. ·c6tviPEreJT BEDROCK OR so1L ,,.{4.fERIALS ·. · . AS DETERMINED BY THE ... ·.··.· .. GEOTECHNICALCONSULTANT .. . . . iri H◊~ifo~ALW1DtH · ACE TO BENCH / BACKCUT 1. WHERE NATURAL SLOPE GRADIENT IS 5:1 OR LESS, BENCHING IS NOT NECESSARY; HOWEVER, FILL IS NOTTO BE PLACED ON COMPRESSIBLE OR UNSUITABLE MATERIAL. 2. SOILS ENGINEER TO DETERMINE IF SUBDRAIN IS REQUIRED. PETRA FILL SLOPE ABOVE NATURAL SLOPE PLATE SG-5 PROPOSED GRADE ------ ,, ·. ::.;,~: CUT I FILL CONTACT SHOWN ON GRADING PLAN SHOWN ON AS-BUILT REMOVE UNSUITABLE MATERIAL NATURAL GROUND SURFACE PETRA ,· :coMPETENT BEDROCKOR SOIL MATERiALB .. AS DETERMINED BY THE _·.·• GEOTECHN/CAL CONSUL TANT•-. ' .·.,, '• , .· .. ,· MAINTAIN 15' MIN. HORIZONTAL WIDTH · .. FROM SLOPE FACE TO BENCH/ BACKCUT TION OF SUBDRAIN TO BE DETERMINED EOTECHNICAL CONSUL TANT. ED, SEE PLATES SG-2 AND SG-3 ETAILS. . ·"0THE cut PORTION OF THE SLOPE SHOULD BE EXCAVATED . · ... · .. .. ··. . .AND EVALUATED BY THE ENGINEERING GEOLOGIST PRIOR· ·. ··<TO CONSTRUCTING THE FILL PORTION OF THE SLOPE. . FILL SLOPE ABOVE CUT SLOPE PLATE SG-6 ORIGINAL GROUND SURFACE C.UTLOT UNSUITABLE MATERIAL EXPOSED IN PORTION OF CUT PAD --r I I ---------------.. ----------- . . . ci:JMPETeiT BEDRdcK dR s6iL M;iE~1Ais · • · -.· -· . · AS DETERMINED BY THE · . . .. . •. ·. GEOTECHNICAL CONSUL TANT·· .. ·· CUT-FILL TRANSITION LOT ----------------r ORIGINAL GROUND SURFACE MAXIMUM FILL THICKNESS (F) DEPTH OF OVEREXCAVATJON (D) FOOTING DEPTH TO 3 FEET . . . . . . . . . EQUAL DEPTH 3 TO 6 FEET . . . . . . . . . . . . . . . . . . . . . . 3 FEET GREATER THAN 6 FEET.. . . . . . . . . . . . 1/2 THE THICKNESS OF DEEPEST FILL PLACED WITHIN THE "FILL" PORTION (F) TO 15 FEET MAXIMUM PETRA CUT LOTS AND CUT-FILL TRANSITION LOTS PLATE SG-7 PROPOSED 2:1 FILL SLOPE EXISTING GROUND SURFACE ~ ···~ .. ~·, ~--·,.••~·-~-~--··· ~,~~-~ . . / . TYPICAL BENCHING INTO . > -COMPETENT BEDROCK OR . .· . , . , , . , . , . _SOIL MATERIALS AS ,. , .:15' MINIMUM KEY ,• · DETERMINED BY THE . -. EMBEDDED A MINIMUM OF 2' . GEOTECHNICAL CONSUL TANT ·, ' . INTO COMPETENT BEDROCK . "-OR SOIL MATERIALS AS DETERMINED BY THE .. \GEOTECHNICAL CONSULTANT D = RECOMMENDED DEPTH OF REMOVAL PER GEOTECHNICAL REPORT PETRA TYPICAL REMOVALS BEYOND TOE OF PROPOSED FILL SLOPE PLATE SG-8 PROPOSED CUT LOT NOTE: / EXISTING GROUND SURFACE / PROPOSED DAYLIGHT CUT RECONSTRUCT AT 2:1 OR FLATTER 1. "D" SHALL BE 10 FEET MINIMUM OR AS DETERMINED BY SOILS ENGINEER. .PETRA SHEAR KEY ON DAYLIGHT CUT LOTS PLATE SG-9