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Home My WebLink About215 Riverside_ Soils Report engineering M geotechnical applications consultants GEOTECHNICAL INVESTIGATION FOR PROPOSED COMMERCIAL DEVELOPMENT LOCATED AT 215 RIVERSIDE AVENUE NEWPORT BEACH, CALIFORNIA Presented to: Laidlaw Schultz Architects 3111 Second Avenue Corona Del Mar, CA 92625 Attention: Scott Laidlaw, Principal cc: Mobilitie, LLC Attention: Kathy Wongsatittham Prepared by: EGA CONSULTANTS, Inc. 375-C Monte Vista Avenue Costa Mesa, California 92627 ph (949) 642-9309 fax (949) 642-1290 November 5, 2018 Project No. SL148.1 375-C Monte Vista Avenue • Costa Mesa, CA 92627 • (949) 642-9309 • FAX (949) 642-1290 engineering / geotechnical November 5, 2018 applications consultants Project No. SL148.1 Site: Proposed Commercial Development at 215 Riverside Avenue Newport Beach—California Executive Summary Based on our geotechnical study of the site, our review of available reports and literature and our experience, it is our opinion that the proposed mixed-use development is feasible from a geotechnical standpoint. There appear to be no significant geotechnical constraints on-site that cannot be mitigated by proper planning, design, and utilization of sound construction practices. The engineering properties of the soil and native materials, and surface drainage offer favorable conditions for site re-development. The following key elements are conclusions confirmed from this investigation: • A review of available geologic records indicates that no active faults cross the subject property. • The site is located in the seismically active Southern California area, and within 2 kilometers of the Type B Newport-Inglewood Fault. As such, the proposed development shall be designed in accordance with seismic considerations specified in the 2016 California Building Code (CBC) and the City of Newport Beach requirements. • Foundation specifications herein include added provisions for potential liquefaction on-site per City policy CBC 1803.11-12. SUMMARY OF RECOMMENDATIONS Design Item Recommendations Foundations: Footing Bearing Pressure: 2,000 psf- building, continuous; 2,500 psf-columns Passive Lateral Resistence: 250 psf per foot Perimeter Footing Widths: min. 15 inches with two No. 5 bars top and bottom Perimeter Footing Depths: min. 24 inches below lowest adjacent grade Coefficient of Friction: 0.30 Mat Slab (Optional): min. 12 inches with thickened edges (+ 6 inches) with no. 5 bars @ 12" o.c. each way, top and bottom Soil Expansion: Non-Expansive Terrace Deposits Soil Sulfate Content: Negligible Building Pad Removals: min. 3 ft. overexcavation, with 5 ft. envelope where feasible Sandy Soil Max. Density: 119.0 pcf @ 10.5 % Opt. Moisture Building Slab: * Concrete slabs cast against properly compacted fill materials shall be a minimum of 5 inches thick (actual) and reinforced with No. 4 rebar at 12 inches on center in both directions. * Dowel all footings to slabs with No. 4 bars at 24 inches on center. * Concrete building slabs shall be underlain by 2 inches clean sand, underlain by a min. 15 mil Stego Wrap (visqueen vapor barrier), with all laps sealed, underlain by 4 inches of %-inch gravel (capillary break). Seismic Values : Site Class Definition (Table 1613.5.2) D Mapped Spectral Response Acceleration at 0.2s Period, SS 1.700 g Mapped Spectral Response Acceleration at 1s Period, S, 0.627 g Short Period Site Coefficient at 0.2 Period, Fa 1.00 Long Period Site Coefficient at 1s Period, F, 1.50 Adjusted Spectral Response Acceleration at 0.2s Period, SMs 1.700 g Adjusted Spectral Response Acceleration at 1s Period, SM, 0.941 g Design Spectral Response Acceleration at 0.2s Period, SpS 1.133 g Design Spectral Response Acceleration at 1s Period, Sp, 0.627 g PGAm = 0.696 g 3 7 5-C Monte Vista Avenue • Costa Mesa, CA 92627 • (949) 642-9309 • FAX (949) 642-1290 engineering geotechnical applications consultants November 5, 2018 Project No. SL148.1 Laidlaw Schultz Architects 3111 Second Avenue Corona Del Mar, CA 92625 Attention: Scott Laidlaw, Principal Subject: GEOTECHNICAL INVESTIGATION FOR PROPOSED COMMERCIAL DEVELOPMENT LOCATED AT 215 RIVERSIDE AVENUE NEWPORT BEACH, CALIFORNIA Dear Scott, In accordance with your request we have completed our Geotechnical Investigation of the above referenced site. This investigation was performed to determine the site soil conditions and to provide geotechnical parameters for the proposed re-grading and construction at the subject lot. It is our understanding that the proposed residential re-development shall include the demolition of the existing structures, and the construction of a new commercial development and associated improvements. This opportunity to be of service is appreciated. If you have any questions, please call. Very truly yours, EGA Consultants, Inc. 1roFIR r� DAVID A. WORTHINGTON CEG 2124 PAUL DURAND RCE 58 64,11. Principal Engineering Geologist Sr. Project Engineer '` Or De wor: IyoCG�nq �4 �ALIF0R Copies: (5) Addressee 375-C Monte Vista Avenue • Costa Mesa, CA 92627 • (949) 642-9309 • FAX (949) 642-1290 November 5, 2018 Project No. SL148.1 GEOTECHNICAL INVESTIGATION FOR PROPOSED COMMERCIAL DEVELOPMENT LOCATED AT 215 RIVERSIDE AVENUE NEWPORT BEACH, CALIFORNIA INTRODUCTION In response to your request and in accordance with the City of Newport Beach Building Department requirements, we have completed a preliminary geotechnical investigation at the subject site located at 215 Riverside Avenue, in the City of Newport Beach, State of California (see Site Location Map, Figure 1). The purpose of our investigation was to evaluate the existing geotechnical conditions at the subject site and provide recommendations and geotechnical parameters for site re- development, earthwork, and foundation design for the proposed re-construction. We were also requested to evaluate the potential for on-site geotechnical hazards. This report presents the results of our findings, as well as our conclusions and recommendations. SCOPE OF STUDY The scope of our investigation included the following tasks: • Review of readily available published and unpublished reports; • Geologic reconnaissance and mapping; • Excavation and sampling of three (3) exploratory boring to a total depth of 17 feet below existing grade (b.g.); • Advancement of four (4) continuous Cone Penetration Test (CPT) soundings to a maximum depth of 50 feet below grade (results of the CPT soundings are included herein); • Laboratory testing of representative samples obtained from the exploratory borings; • Engineering and geologic analysis including seismicity coefficients in accordance with the 2016 California Building Code (CBC); • Seismic and Liquefaction analysis and settlement computations (in accordance with California Geological Survey, SP 117A); • Preparation of this report presenting our findings, conclusions, and recommendations. GENERAL SITE CONDITIONS The subject property is a semi-rectangular shaped parcel located at 215 Riverside Avenue in the City of Newport Beach, County of Orange, California (see Site Location Map, Figure 1). The lot dimensions are provided on Plot Plan, Figure, 2, with approximate lot area of 19,000 square feet. For the purpose of clarity in this report, the lot is bound by Avon Street to the south, by Riverside Avenue to the east, by residential homes to the north, and by Cliff Drive Park to the west. The nearest cross street is Avon Street. The lot is located on the mainland side of Pacific Coast Highway. Channel waters of the Newport Bay are approximately 850 feet to the south, and the Pacific Ocean is located approximately 4,350 feet southwest of the site (see Site Location Map, Figure 1). The subject property consists of a relatively flat, terraced lot with a gradual 2.5:1 slope in the north of the property, up to the adjacent residential homes. Currently, the lot is occupied by a office-retail business situated on a graded level pad. All structures are supported on continuous perimeter footings with slab-on-grade floors (see Plot Plan, Figure 2). The site is legally described as Parcels D and 3 of PMB 237/35-36, in the City of Newport Beach, County of Orange, California (APN 049-103-17). PROPOSED COMMERCIAL-OFFICE USE RE-DEVELOPMENT The precise grading plan is not available at this time. However, based on our review of the preliminary plans by Laidlaw Schultz Architects, the proposed scope of work includes the demolition of the existing structures, and the construction of a two-story 2,500 sq. ft. commercial office building and a 50-space parking area with associated improvements and retaining walls. We assume that the proposed buildings will consist of wood-frame and masonry block construction or building materials of similar type and load. The building foundations will consist of a combination of isolated and continuous spread footings. Loads on the footings are unknown, but are expected to be less than 2,500 and 2,000 pounds per square foot on the isolated and continuous footings, respectively. If actual loads exceed these assumed values, we should be contacted to evaluate whether revisions of this report are necessary. It is our understanding that the grade of the sites are not expected to vary significantly, with maximum regrades consisting of approximately 1 to Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No.S1_148.1 November 5,2018 3 2 feet in the building areas. Based on NAVD88, the lowest site elevation is approximately 17 feet above MSL. Based on the preliminary plans, the proposed finish floor elevation shall be 9+ ft. above mean sea level (MSL) to conform with City and United States FEMA flood elevation requirements. Note: The precise determination, measuring, and documenting of the site elevations, hub locations, property boundaries, etc., is the responsibility of the project licensed land surveyor. SUBSURFACE EXPLORATION Our subsurface exploration consisted of the excavation of three (3) exploratory boring (B-1, B-2, and B-3) to a maximum depth of 17 feet below grade (b.g.) and four (4) CPT probes (CPT-1, CPT-2, CPT-3, and CPT-4) to a depth of 50 ft. b.g. (continuous soil profile). Prior to drilling, the underground detection and markup service (Underground Service Alert of Southern California) was ordered and completed under DigAlert Confirmation No. A182531182-OOA. Representative bulk and relatively undisturbed soil samples were obtained for labora- tory testing. Geologic/CPT logs of the soil boring/probes are included in Appendix A. The borings were continuously logged by a registered geologist from our firm who obtained soil samples for geotechnical laboratory analysis. The approximate locations of the borings are shown on Figure 2, Plot Plan. Geotechnical soil samples were obtained using a modified California sampler filled with 2 3/8 inch diameter, 1-inch tall brass rings. Bulk samples were obtained by collecting representative bore hole cuttings. Locations of geotechnical samples and other data are presented on the boring logs in Appendix A. The soils were visually classified according to the Unified Soil Classification System. Classifications are shown on the boring logs included in Appendix A. LABORATORY TESTING Laboratory testing was performed on representative soil samples obtained during our subsurface exploration. The following tests were performed: Dry Density and Moisture Content (ASTM: D 2216) Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No.SL148.1 November 5.2018 4 Maximum Dry Density and Optimum Moisture Content (ASTM: D 1557) Wet (Submerged) Density (ASTM: D 1557) Direct Shear (ASTM D 3080) Expansion Index (ASTM D 4829) Sulfate Content (ACI 318-14, CA 417) Soil Classification (ASTM D 2487) All laboratory testing was performed by our sub-contractor, G3SoilWorks, Inc., of Costa Mesa, California. Geotechnical test results are included in Appendix B, herein. SOIL AND GEOLOGIC CONDITIONS The site soil and geologic conditions are as follows. Seepage and Groundwater Seepage or surface water ponding was not noted on the subject site at the time of our study. Groundwater was not encountered in our test excavations. According to the Orange County Water District (OCWD), there are no water wells located within the general vicinity of the subject property. Our data indicates that perched groundwater subject to tidal fluctuations is encountered in the region, but was not present on site at the time of our test excavations. Channel waters of the Newport Bay are approximately 850 feet to the south, and the Pacific Ocean is located approximately 4,350 feet southwest of the site (see Site Location Map, Figure 1). A tidal chart during the week of September 28, 2018, presented as Figure 4, herein. Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No.SL148.1 November 5,2018 Geologic Setting Regionally, the site is located within the western boundary of the Coastal Plain of Orange County. The Coastal Plain lies within the southwest portion of the Los Angeles Basin and consists of semi-consolidated marine and non-marine deposits ranging in age from Miocene to recent. The western boundary of the Coastal Plain, in which the site is located, is referred to as the Tustin Plain. It is bound by the Santa Ana Mountains to the northeast and the San Joaquin Hills to the southeast. Based on available geologic maps the site is underlain by a thin mantle of residual soils and/or engineered fill. The shallow soil layer is underlain by older terrace deposits (Qtm) which are described as silty sands and with trace clays (see reference No. 2). The competent terrace deposits are underlain by bedrock of the Monterey Formation (Tm). Roadside exposures of massive bedrock of the Monterey Formation (Tm) are visible on the inland side of the Pacific Coast Highway less than '/2 kilometers northwest and southeast of the site (Banning Ranch and Dover Shores bluffs). A Geologic Map is presented as Figure 3, herein (reference: Morton, D.M., and Miller, F.K., 2006). Faulting A review of available geologic records indicates that no active faults cross the subject property (Figure No. 3 and reference No. 2). S isrnICIty The seismic hazards most likely to impact the subject site is ground shaking following a large earthquake on the Newport-Inglewood (onshore), Palos Verdes (offshore), Whittier-Elsinore, or Cucamonga. The fault distances, probable magnitudes, and horizontal accelerations are listed as follows: FAULT DISTANCE FROM MAXIMUM CREDIBLE MAXIMUM (Seismic SUBJECT SITE EARTHQUAKE HORIZONTAL Source Type) (Kilometers) MAGNITUDE ROCK ACCELERATION Newport- 2 kilometers southwest 7.2 0.69 g's Inglewood (B) Palos Verdes 16 kilometers 7.1 0.38 g's (B) southwest Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No.SL148.1 November 5,2018 6 Chino-Cental 40 kilometers northeast 6.7 0.14 g's Avenue (B) Elsinore (B) 37 kilometers northeast 6.8 0.16 g's Cucamonga 50 kilometers north- 7.0 0.14 g's (A) northeast The maximum anticipated bedrock acceleration on the site is estimated to be less than 0.69, based on a maximum probable earthquake on the Newport- Inglewood Fault. The site is underlain by fill and estuarine sands. For design purposes, two-thirds of the maximum anticipated bedrock acceleration may be assumed for the repeatable ground acceleration. The effects of seismic shaking can be mitigated by adhering to the 2016 California Building Code or the standards of care established by the Structural Engineers Association of California. With respect to this hazard, the site is comparable to others in this general area in similar geologic settings. The grading specifications and guidelines outlined in Appendix C of the referenced report are in part, intended to mitigate seismic shaking. These guidelines conform to the industry standard of care and from a geotechnical standpoint, no additional measures are warranted. Based on our review of the "Seismic Zone Map," published by the California Department of Mines and Geology in conjunction with Special Publication 117, there are no earthquake landslide zones on or adjacent to the site. The proposed development shall be designed in accordance with seismic considerations contained in the 2016 CBC and the City of Newport Beach requirements. Based on Chapter 16 of the 2016 CBC and on Maps of Known Active Near- Source Zones in California and Adjacent Portions of Nevada (ASCE 7 Standard), the following parameters may be considered: 2016 CBC Seismic Design Parameters SITE ADDRESS: 215 Riverside Avenue,Newport Beach, CA Site Latitude(Decimal Degrees) 33.6219 Site Longitude(Decimal Degrees) -117.92365 Site Class Definition D Mapped Spectral Response Acceleration at 0.2s Period, SS 1.700 g Mapped Spectral Response Acceleration at is Period, S, 0.627 g Short Period Site Coefficient at 0.2 Period,Fa 1,00 Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No. SL148.1 _ November 5,2018 Long Period Site Coefficient at Is Period,Fv 1.50 Adjusted Spectral Response Acceleration at 0.2s Period, SMs 1.700 g Adjusted Spectral Response Acceleration at is Period, S,, 0.941 g Design Spectral Response Acceleration at 0.2s Period, SDS 1.133 g Design Spectral Response Acceleration at Is Period SD, 0.627 g In accordance with the USGS Design Maps, and assuming Site Class "D", the mean peak ground acceleration (PGAm) per USGS is 0.696 g. The stated PGAm is based on a 2% probability of exceedance in a 50 year span (see copies of the USGS Design Maps Detailed Report, Appendix D, herein). Other Geologic Hazards Other geologic hazards such as landsliding, or expansive soils, do not appear to be evident at the subject site. FINDINGS Subsurface Soils As encountered in our test borings, the site is underlain by, fill and native materials as follows: Fill A Fill soils were encountered in a depth of approximately 2'/2 to 3 feet b.g. The fill soils consist generally of grayish brown, dry to damp, loose to medium dense, silty sand with clay and gravel. The expansion potential of the fill soils was tested (in accordance with ASTM D 4829) and is determined to be non-expansive (E.I. = 0) when exposed to an increase in moisture content. Based on the laboratory results dated October 16, 2018, the site maximum dry density is 119.0 pcf at an optimum moisture content of 10.5 % (per ASTM D 1557). The sulfate content of the on site soils were determined to be negligible, Class [SO]. The complete laboratory reports are presented in Appendix B, herein. Native - Terrace Deposits Qtm Underlying the fill materials are Quaternary-age terrace deposits as encountered in each of the test borings (B-1 through B-3 and CPT-1 Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No.SL148.1 November 5,2018 through CPT-4) to the maximum depths explored (17 ft b.g.). The native soils consist generally of gray brown, dry to moist, medium dense, non- cemented, fine- to medium-grained, micaceous sand with silt layers which becomes less weathered with depth. Monterey Formation Tm Though not encountered in any of the three hand-augered test borings, the terrace deposits on the subject site are underlain by deposits of the Miocene age Monterey Formation. Bedrock exposures are visible in the rear yard and park of the natural slopes ascending to Cliff Drive. This correlates with the high blow count data from our CPT probe advanced on October 26, 2018 (see continuous log in Appendix A, herein). Bedrock materials consist generally of marine siltstone and sandstone, siliceous and diatomaceous, and dense to very dense. The bedrock is moderately weathered becoming less weathered with depth. Based on the extrapolation of data and geologic maps (Figure 3 of the soils report), the geologic structure of the bedrock (bedding) dips at gentle angles (horizontal to 10 degrees) to the north and west. This structural orientation is considered to be neutral to favorable with respect to the gross stability of the rear and surrounding slopes underlain with bedrock. LIQUEFACTION ANALYSIS Per 5P1I AJ Liquefaction of soils can be caused by strong vibratory motion in response to earthquakes. Both research and historical data indicate that loose, granular sandy soils are susceptible to liquefaction, while the stability of rock, gravels, clays, and silts are not significantly affected by vibratory motion. Liquefaction is generally known to occur only in saturated or near saturated granular soils. The site is underlain by fill/estuarine sands, old paralic deposits, and bedrock of the Monterey Formation. It is our understanding that the current City policy, has assigned a seismic settlement potential of one (1.0) inch in the upper ten feet, and three (3.0) inches for soil depths of ten to fifty feet. In the event settlement values exceed these threshold values, then additional analysis and/or additional mitigation is required. The CPT testing was performed in accordance with the "Standard Test Method for Performing Electronic Friction Cone and Piezocone Penetration Testing of Soils," (ASTM D5778-12). The seismically induced settlement for the proposed structure was evaluated based on the "Soil Liquefaction During Earthquakes" by Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No,SL148.1 November 5,2018 I.M. Idriss and R.W. Boulanger, dated September 8, 2008. The analysis was provided by the 10-feet deep 4 " diameter hand-auger borings, and a 50+ feet deep 1.7" diameter CPT probe advanced on October 26, 2018. The exploratory boring and probe locations are shown in the Plot Plan, Figure 2, herein. The soil borings were continuously logged by a certified engineering geologist of our firm. The computations and results of our Liquefaction Analysis, based on CPT blow counts of Boring CPT-1, are attached in Appendix E, herein. The seismically induced settlement analysis was evaluated based on methods published in the references Nos. "a" through "j" (see "Associated References", herein). The liquefaction and seismic settlement calculations indicate seismic settlement (includes dry and saturated sands) in the upper 50 feet is less than 2.0 inches and less than 1.0 inch in the upper 10 feet. Hence, shallow mitigation methods for liquefaction may be implemented per City Code Policy (No. CBC 1803.5.11- 2 last revised 7/3/2014). Based on our liquefaction analysis, and in accordance with the City of Newport Beach Policy No. CBC 1803.5.11-12 (NBMC, Chapter 15), we recommend the following mitigative methods to minimize the effects of shallow liquefaction: 1. Tie all pad footings with grade beams. 2. All footings should be a minimum of 24 inches deep, below grade. 3. Continuous footings should be reinforced with two No. 5 rebar (two at the top and two at the bottom). 4. Concrete slabs cast against properly compacted fill materials shall be a minimum of 5 inches thick (actual) and reinforced with No. 4 rebar at 12 inches on center in both directions. The reinforcement shall be supported on chairs to insure positioning of the reinforcement at mid-center in the slab. 5. Dowel all footings to slabs with No. 4 bars at 24 inches on center. The foundation specifications outlined above will act to decrease the potential settlement due to liquefaction and/or seismically induced lateral deformation to tolerable amounts. If the above specifications are incorporated, the proposed structure shall be stable and adequate for the intended uses and the proposed construction will not adversely impact the subject or adjacent properties. Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No.SL148.1 November 5,2018 10 Other Geologic Hazards Other geologic hazards such as landsliding, or expansive soils, do not appear to be evident at the subject site. CONCLUSIONS Based on our geotechnical study of the site, our review of available reports and literature and our experience, it is our opinion that the proposed improvements at the site are feasible from a geotechnical standpoint. There appear to be no significant geotechnical constraints on-site that cannot be mitigated by proper planning, design, and utilization of sound construction practices. The engineering properties of the soil and native materials, and the surface drainage offer favorable conditions for site re- development. RECOMMENDATIONS The following sections discuss the principle geotechnical concerns which should be considered for proper site re-development. Earthwork Grading and earthwork should be performed in accordance with the following recommendations and the General Earthwork and Grading Guidelines included in Appendix C. It is our understanding that the majority of grading will be limited to the re-grading of the building pad for the proposed construction. In general, it is anticipated that the removal of the upper 3 feet within the building footprint (slab-on-grade portion) will require removal and recompaction to prepare the site for construction. The removals should be accomplished so that all fill and backfill existing as part of the previous site use and demolition operations are removed. Where feasible, the limits of the pad fill shall be defined by a five (5) feet envelope encompassing the building footprint. Care should be taken to protect the adjacent property improvements. A minimum one foot thick fill blanket should be placed throughout the exterior improvements (approaches, hardscape, etc.). The fill blanket will be achieved by re-working (scarifying) the upper 12 inches of the existing grade. Water via a 2-inch hose shall be vigorously induced during the pad grading operations. Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No.SL148.1 November 5,2018 11 Site Preparation Prior to earthwork or construction operations, the site should be cleared of surface structures and subsurface obstructions and stripped of any vegetation in the areas proposed for development. Removed vegetation and debris should then be disposed of off-site. A minimum of 3 feet of the soils below existing grade will require removal and recompaction in the areas to receive building pad fill. Following removal, the excavated surface should be inspected by the soils engineer or his designated representative prior to the placement of any fill in footing trenches. Holes or pockets of undocumented fill resulting from removal of buried obstructions discovered during this inspection should be filled with suitable compacted fill. Fills The on-site soils are suitable for reuse as compacted fill, provided they are free of organic materials, debris, and materials larger than six (6) inches in diameter. After removal of any loose, compressible soils, all areas to receive fill and/or other surface improvements should be scarified to a minimum depth of 12 inches, brought to at least 2 percent over optimum moisture conditions and compacted to at least 90 percent relative compaction (based on ASTM: D 1557). If necessary, import soils for near-surface fills should be predominately granular, possess a very low expansion potential, and be approved by the geotechnical engineer. Lift thicknesses will be dependent on the size and type of equipment used. In general, fill should be placed in uniform lifts not exceeding 8 inches. Placement and compaction of fill should be in accordance with local grading ordinances under the observation and testing of the geotechnical consultant. We recommend that fill soils be placed at moisture contents at least 2 percent over optimum (based on ASTM: D 1557). We recommend that oversize materials (materials over 6 inches) should they be encountered, be stockpiled and removed from the site. Trench Backfill The on-site soils may be used as trench backfill provided they are screened of rock sizes over 6 inches in dimension and organic matter. Trench backfill should be compacted in uniform lifts (not exceeding 8 inches in compacted thickness) by mechanical means to at least 90 percent relative compaction (ASTM: D 1557). Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No.SL148.1 November 5,2018 Geotechnical Parameters The following Geotechnical parameters may used in the design of the proposed structure (also, see "Liquefaction Analysis" section, above): Foundation Design Structures on properly compacted fill may be supported by conventional, continuous or isolated spread footings. All footings should be a minimum of 24 inches deep (measured in the field below lowest adjacent grade). Footing widths shall me an minimum 15 inches for interior cross beams and 18 inches for perimeter footings. As stated above, additionally, to further reduce the effects of the thin zones of potentially liquefiable soils, the building slab shall include 15" wide by 24" deep interior grade beams to be reinforced with two No. 5 rebars (two at the top and two at the bottom). The cross beam locations shall be determined by the structural engineer. At this depth (24 inches) footings founded in fill materials may be designed for an allowable bearing value of 2,000 and 2,500 psf (for dead-plus-live load) for continuous wall and isolated spread footings, respectively. These values may be increased by one-third for loads of short duration, including wind or seismic forces. Reinforcement requirements may be increased if recommended by the project structural engineer. In no case should they be decreased from the previous recommendations. Mat Foundation Design (Optional) Due to anticipated high tide waters and cohesionless sands during construction, a mat slab foundation system is a recommended option. Mat slabs founded in compacted fill or competent native materials may be designed for an allowable bearing value of 2,500 psf (for dead-plus-live load). These values may be increased by one-third for loads of short duration, including wind or seismic forces. The actual design of the foundation and slabs should be completed by the structural engineer. MIN_. DESIGN ITEM RECOMMENDATIONS Mat foundations: allowable bearing pressure 2,500 psf passive lateral resistence: 250 psf per foot mat slab thickness: min. 12 inches with thickened edges (+ 6 inches) steel reinforcement: no. 5 bars @ 12" o.c. each way, top and bottom Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No SL148.1 November 5,2018 coefficient of friction: 0.30 Modulus of Subgrade Reaction: ks = 100 1 Win 3 Interior Slabs-on-grade -conventional Concrete slabs cast against properly compacted fill materials shall be a minimum of 5 inches thick (actual) and reinforced with No. 4 rebar at 18 inches on center in both directions. The slabs shall be doweled into the footings using No. 4 bars at 24 inches on center. The reinforcement shall be supported on chairs to insure positioning of the reinforcement at mid-center in the slab. , Interior slabs shall be underlain by 2 inches of clean sand over a min. 15 mil thick, puncture-resistant plastic sheeting (e.g. "Stego Wrap"), with all laps sealed, over 4 inches of% -inch gravel (see "Capillary Break" specifications, below). Some slab cracking due to shrinkage should be anticipated. The potential for the slab cracking may be reduced by careful control of water/cement ratios. The contractor should take appropriate curing precautions during the pouring of concrete in hot weather to minimize cracking of slabs. We recommend that a slipsheet (or equivalent) be utilized if crack-sensitive flooring is planned directly on concrete slabs. All slabs should be designed in accordance with structural considerations. Cement Type for Concrete in Contact with On-Site Earth Materials Concrete mix design should be based on sulfate testing with Section 1904.2 of the 2016 CBC. Preliminary laboratory testing indicates the site soils possess negligible sulfate exposure. In the event import soils are used, the soils shall be tested for sulfate content and the associated recommendation shall be implemented as follows: ACI 318 BUILDING CODE -Table 19.3.1.1 REQUIREMENTS FOR CONCRETE EXPOSED TO SULFATE-CONTAINING SOLUTIONS Sulfate Water soluble Sulfate(SO4)in Cement Type Maximum water- Minimum fc', Exposure sulfate(SO4)in soil water, ppm cementitious material normal-weight [SO] percent by weight ratio, by weight, normal and light weight weight concrete concrete,psi Negligible 0.00 < SO4<0.10 0 < SO4<150 [Si] Moderate 0.10<SO4<0.20 150<SO4<1500 II,IP(MS), 050 4000 [32] IS(MS),P(MS) I(PM)(MS), I(SM)(MS) Severe 0 20 <_ SO4<2.00 1500<SO4< V 0.45 4500 [S3] 10,000 Very Severe SO4>2.00 SO4> 10,000 V plus 0.45 4500 [S4] I I pozzalan Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No.SL148.1 November 5,2018 As a conservative approach, we recommend cement with a minimum strength f'c of 3,000 psi be used for concrete in contact with on-site earth materials. Settlement Utilizing the design recommendations presented herein, we anticipate that the majority of any post-grading settlement will occur during construction activities. We estimate that the total settlement for the proposed structure will be on the order of 1 inch. Differential settlement is not expected to exceed 1 inch in 30 feet. These settlement values are expected to be within tolerable limits for properly designed and constructed foundations. Lateral Load Resistance Footings founded in fill materials may be designed for a passive lateral bearing pressure of 250 pounds per square foot per foot of depth. A coefficient of friction against sliding between concrete and soil of 0.30 may be assumed. Capillafy Break Below Interior Slabs In accordance with the 2016 California Green Building Standards Code Section 4.505.2.1, we provide the following building specification for the subject site (living area and garages slabs): Concrete building slabs shall be directly underlain by a min. 2 inches of clean/washed sand, underlain by a min.15 mil-thick moisture barrier (e.g. "Stego Wrap"), with all laps sealed, underlain by 4 inches of% -inch gravel. The above specification meets or exceeds the Section 4.505.2.1 requirement. We do not advise placing sand directly on the gravel layer as this would reverse the effects of vapor retardation (due to siltation of fines). A/C Pavement Subbase Asphaltic concrete (AC) and Class II rock base should conform to, and be placed in accordance with the latest revision of the California Department of Transportation Standard Specifications. We assume that Class II base with a minimum R-value of 78 will be used; as follows: Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No S1_148.1 November 5,2018 RECOMMENDED MINIMUM DESIGN SECTIONS LOCATION DESIGN TRAFFIC ASPHALTIC CLASS II INDEX CONCRETE AGGREGATE BASE Car Traffic, Parking 4.0-5.0 3 5' 4.0" Areas Heavy Truck Traffic 5.0-6.0 4.5" &0" Aisles Trash Pads 5.0-6.0 6.0" (Concrete) 6,0" Truck Dock or 5.0-6.0 6.0" (Concrete) 6.0" Truck Pads The minimum section of 6 inches concrete over 6 inches Class II Base Material applies to the site approaches. If off-site (surrounding roadways) work is anticipated, the Minimum Design Section shall conform with either the County or Caltrans specifications, depending on jurisdiction. Prior to placing pavement sections, the subbase soil should have a relative compaction of at least 90 percent, based on ASTM: D 1557. We also recommend that the base course be compacted to a minimum of 95 percent relative compaction (based on ASTM: D 1557-13). If pavement areas are planned adjacent to landscaped areas, we recommend that the amount of irrigation be kept to a minimum to reduce the possible adverse effects of water on pavement subgrade. Retaining Wall Design Since the grading plan is not yet available, the limits of the retaining walls are not known at this time. However, based on the preliminary architectural renderings, all retaining and landscape wall footings will be embedded into competent native materials. The following equivalent fluid pressures may be used in the design of the site retaining walls assuming free draining conditions (select granular backfill): E uivalent Fluid Pressure Condition Level Active Pressures 40 pcf At-Rest Pressures 55 pcf For the soldier pile caisson locations along confined areas (side yards and slopes), the following recommended equivalent fluid pressures may be used in the site retaining wall design assuming backfill using on-site soils (based on triangular distribution): Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No. SL148.1 November 5.2018 16 Equivalent Fluid Pressure Condition Level Active Pressures 65 pcf At-Rest Pressures 90 pcf Depending on whether the wall is restrained (rigid) or unrestrained (free to deflect), an additional uniform lateral pressure equal to 50 or 33 percent, respectively, of the anticipated maximum surcharge load located within a distance equal to the height of the wall should be used in design. This office shall be contacted to provide additional recommendations if actual conditions are different than those assumed above. Lateral Pressure - New Retaining Walls founded in competent native materials A passive earth pressure of 300 pounds per square foot per foot of depth, to a maximum value of 3,000 pounds per square foot, may be used to determine lateral bearing resistance for footings founded in terrace deposits or bedrock. 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. However, the lateral sliding resistance should not exceed one-half the dead load. An increase of one-third of the above values may also be used when designing for short duration wind and seismic forces. The above lateral resistance values are based on footing placed directly against competent native materials. In cases where footing sides are formed, all backfill placed against the footings should be compacted to at least 90 percent of the applicable maximum dry density value. Passive pressure is used to compute lateral soil resistance developed against lateral soil movement. Further, for sliding resistance, a friction coefficient of 0.30 may be used at the concrete and soil interface. These lateral and frictional resistance values represent ultimate values, so appropriate safety factors for wall design should be applied by the structural engineer. Settlement Utilizing the design recommendations presented herein, the total settlement of the building slabs/foundations is expected to be less than 1 inch. The differential settlement between adjacent footings is expected to be less than 1/4 inch over a horizontal span of 40 feet. It is anticipated that the majority of the footing settlements will occur during construction or shortly thereafter as building loads are applied. Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No SL148.1 November 5,2018 Retaining_Wall Backfill Material It is recommended that a minimum 2-foot thick layer of free-draining granular material (less than 5 % passing the No. 200 sieve) be placed against the back face of the retaining walls. This material should be approved by the geotechnical engineer. This layer of granular material should be separated from the adjacent soils using a suitable geotextile fabric. If the layer of free-draining material is not covered by an impermeable surface, such as a structure or pavement, a 12-inch thick layer of a low permeability soil should be placed over the backfill to reduce surface water migration to the underlying soils. All retaining wall backfill should be placed and compacted under engineering controlled conditions in the necessary layer thickness to ensure a minimum in- place density of 90 percent of the maximum dry density as determined by the Modified Proctor test (ASTM D1557). Care should be taken to avoid over- compaction of the soils behind the retaining walls, and the use of heavy compaction equipment should be avoided. Retaining Wall Back Drains The retaining walls shall be provided with water proofing in accordance with the architects recommendations and be free draining. Back drains shall be installed to collect and divert migrating groundwater. As a minimum, the wall may be drained by placing a 4-inch diameter pipe perforated (faced down) PVC Schedule 40 pipe or approved equivalent, located behind the base of the wall. The pipe shall be covered by 3/-inch crushed rock at a rate of not less than 2 sq. ft. per linear ft. of pipe surrounded in turn by geofabric such as Supac 4NP or equivalent. All wall backfill shall be compacted to a minimum 90 percent relative compaction in accordance with ASTM D-1557. Wall back drains shall outlet separately and not be combined with area drains. This office shall be contacted to provide additional recommendations if actual conditions are different than those assumed above. During construction, drainage devices shall be inspected by a representative of EGA Consultants. SHORING INSTALLATION RECOMMENDATIONS Since the grading plan is not yet available, the limits of the retaining walls and associate shoring are not known at this time. However, based on our review of preliminary architectural renderings, we understand that permanent and/or temporary shoring is proposed along portions of the each side yard and the base of the ascending slope at the rear of the property. The approximate limits of the recommended caisson layout shall be presented when the building footprints and retaining walls have been Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No.SL148.1 November 5,2018 18 determined. It is our understanding that the shoring will be designed having a combination of temporary and permanent shoring segments, based on the project locations and proposed elements. It is our understanding that the shoring system will consist of steel "H" beam soldier piles and either wood or steel sheet lagging. The steel "H" beam soldier piles should be installed within pre-drilled holes. The soldier piles should not be driven or vibrated into place due to the possible damage that could occur to nearby structures. Once a soldier pile boring is advanced to its recommended depth, a steel soldier pile should be place within the boring and the boring then backfilled. The borings should be backfilled with concrete up to the elevation of the excavation bottom. Above the excavation bottom, the borings may be filled with 2-sack slurry. Due to the anticipated moderate exposure to sulfates, Type II cement should be used in the concrete. In addition, the maximum water-cement ratio should not exceed 0.50 and the minimum concrete compressive strength should not be less than 3,000 pounds per square inch. The drill holes for the steel "H" piles should be sufficiently large to allow concrete backfilling around piles to be performed as effectively as possible. Any voids left between the "H" pile and the sides of the holes are expected to reduce the lateral capacity of the soldier pile. In order to provide adequate space for concrete slurry backfilling, we recommend that the web height of the steel "H" pile be at least 10 inches from the diameter of the hole. The concrete and slurry should be placed into the soldier pile excavation from the bottom up using a pump and tremie pipe. The bottom of the tremie pipe should be kept at least 2 to 3 feet below the level of the rising concrete or slurry. The concrete should be thoroughly vibrated to remove any entrapped air. The soil and water mixture dispersed by the concrete and slurry should be pumped into a suitable disposal container. After the soldier piles have been placed, the excavation of the lower pads may begin. If concrete and slurry is used for backfill, these materials should be allowed to cure prior to lower excavations. Care should be taken to ensure that the lagging drops down as the excavation advances. Any gaps in the lagging could cause undermining of the adjacent structures. To prevent caving of the sidewalls, the lagging elements should be forced down either behind the soldier piles or at an appropriate place within the flanges of the "H" and through the existing soils. The slurry materials that were placed within the soldier pile borings may be broken an removed during the lagging process. The lagging elements should not be driven or vibrated into place due to the possible damage that could occur to nearby structures. It should be noted that the shoring should be designed for a minimum safety factor of 1.2 and that the lateral deformation of the ground surface should be controlled by structural design in order to protect the adjacent structures. The shoring should be designed to support the surcharge of any adjacent structures in addition to the earth Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No.SL148.1 November 5,2018 pressures exerted by the native backfill soils. Recommended design values with respect to distribution of earth pressures on shoring elements are presented below. The contractor shall verify the locations of all existing underground utilities prior to commencing the drilling and excavating. Backfill shall be of compacted spoils or slurry, No vibratory equipment or hammering shall be utilized in the shoring installation. Each caisson boring shall be a min. 24-inches in diameter, embedded a min. 15 ft. into competent bedrock material. Based on this we assume caissons shall be a minimum 15 feet length at the near-street elevations, and staggered up to 30 feet along the rear row of caissons (all depths below lowest adjacent grade). Caissons may be designated for both end bearing and friction. Caissons may be designed for an allowable bearing capacity of 4,000 psf and a skin friction of 400 psf (neglect the upper 2 feet of old fill). The bearing value may be increased by 1/3 for wind and seismic forces. The point of fixity of 5 feet below finish grade shall be applied. Channel drains, miradrain, and bentonitic waterproofing shall be installed at each shoring bay (between every caisson). All drains shall be gravity-fed to a suitable outlet. The geotechnical consultant should be present during the excavation and shoring phases of the project to observe the soil conditions and make additional recommendations if necessary. Each borehole bottom shall be free of debris and approved by the geotechnical consultant. Active Earth Pressures For cantilever shoring beams, an active earth pressure (equivalent fluid pressure) of 40 pounds per cubic foot may be considered for the on-site fill and the native soils. It should be noted that under this condition, the movement of shoring H-beams are not restrained so that the soil internal strength can be fully mobilized. Active Pressure 40 pcf The active pressure may be approximated by a rectangular soil pressure distribution with the pressure per foot of width equal to 23H, where H is equal to the depth of the excavation being shored. At-Rest Earth Pressure If movement of the shoring, H-beams are restrained at the top, then an at-rest earth pressure of 55 pounds per cubic foot should be used in design. Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No.SU 48.1 November 5,2018 Passive Resistance A passive earth pressure increasing at a rate of 400 pounds per square foot per foot of width of a shoring H-beam, per foot of depth, to a maximum value of 4,000 pounds per square foot may be used to determine lateral resistance for H- beams. The passive resistance should be ignored for the upper 2 feet of the H- beams embedded below the lowest cut grade. Active Pressure: 40 pcf At-Rest Pressure: 55 pcf Seismic Earth Pressure and Kh In accordance with Section 1803.5.12 of the 2016 CBC, for design purposes, a seismic earth pressure of 20 pcf (equivalent fluid pressure) may be used for the retaining wall design. This pressure is additional to the static earth pressures and should be considered as the resultant force acting at 1/3 height of the retaining wall (reference: Mononobe-Okabe equation and Atik & Sitar). For a complete listing of the resources used, please see Reference Nos. 12 through 15, herein. Assuming level backfill conditions with density of backfill a minimum 110 pcf, the seismic element coefficient Kh = 0.28 (reduction factor = 0.35). Spacing and Depth of H-beams The minimum clear spacing between the H-beams should be three effective H- beam diameters, sidewall to sidewall. The maximum clear spacing between H- beams should not exceed five effective H-beam diameters, sidewall to sidewall. The embedment depths of the H-beams will likely vary depending on the retained height of the proposed shoring system along its alignment. The structural engineer should determine the final depths based on our recommendations presented herein. However, the H-beams should be embedded, at a minimum, five effective diameters into the underlying competent native deposits. The geotechnical consultant should be present during the excavation and shoring phases of the project to observe the soil conditions and make additional recommendations if necessary. Waterproofing If applicable, lower pad or basement wall/slabs shall be waterproofed in accordance with the 2016 CBC. Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No.SL148.1 November 5.2018 The retaining/shotcrete walls shall be sealed and waterproofed using the miradrain and miraclay (i.e. Grace 3000) waterproofing system, or equivalent. Joint in the membrane shall be lapped and sealed in an approved manner. Protection board shall be used to protect the membrane during and after backfilling. Joints in walls and floors, and between the wall and floor, and penetrations of the wall and floor shall be made watertight using suitable methods and materials (i.e. bentonite "WaterStops", or "Mira-Stop"). Exterior Slabs-on-grade (Hardscape) Concrete slabs cast against properly compacted fill materials shall be a minimum of 4 inches thick (actual) and reinforced with No. 3 rebar at 18 inches on center in both directions. The reinforcement shall be supported on chairs to insure positioning of the reinforcement at mid-center in the slab. Control joints should be provided at a maximum spacing of 8 feet on center in two directions for slabs and at 6 feet on center for sidewalks. Control joints are intended to direct cracking. Expansion or felt joints should be used at the interface of exterior slabs on grade and any fixed structures to permit relative movement. Some slab cracking due to shrinkage should be anticipated. The potential for the slab cracking may be reduced by careful control of water/cement ratios. The contractor should take appropriate curing precautions during the pouring of concrete in hot weather to minimize cracking of slabs. New Fences/Garden Walls New fences or garden wall footings, if any, should be founded a minimum of 18- inches into approved firm materials. To reduce the potential for unsightly cracks due to expansion forces, we recommend inclusion of construction joints at 8-ft to 15-ft intervals. Surface Drainage Surface drainage shall be controlled at all times. Positive surface drainage should be provided to direct surface water away from structures and toward the street or suitable drainage facilities. Ponding of water should be avoided adjacent to the structures. Recommended minimum gradient is 2 percent for unpaved areas and one percent for concrete/paved areas. Roof gutter discharge should be directed away from the building areas through solid PVC pipes to suitable discharge points. Area drains should be provided for planter areas and drainage shall be directed away from the top of slopes. Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No.SL148.1 November 5,2018 PRE-CONSTRUCTION MEETING It is recommended that no clearing of the site or any grading operation be performed without the presence of a representative of this office. An on site pre-grading meeting should be arranged between the soils engineer and the grading contractor prior to any construction. GEOTECHNICAL OBSERVATION AND TESTING DURING CONSTRUCTION We recommend that a qualified geotechnical consultant be retained to provide geotechnical engineering services,including geotechnical observation/testing,during the construction phase of the project.This is to verify the compliance with the design, specifications and or recommendations, and to allow design changes in the event that subsurface conditions differ from those anticipated. Geotechnical observations/testing should be performed at the following stages: • During ANY grading operations, including excavation, removal, filling, compaction, and backfilling, etc. • After excavations for footings/grade beams and/or drilling for soldier piles/caissons, if any to verify the adequacy of underlying materials. • After pre-soaking of new slab sub-grade earth materials and placement of capillary break, plastic membrane, prior to pouring concrete. • During backfill of drainage and utility line trenches, to verify proper compaction. • When/if any unusual geotechnical conditions are encountered. • Prior to slab pours to ensure proper subgrade compaction and moisture barriers. During/after installation of water proofing for retaining/basement walls, if any prior to installation of sub-drain/backfilling. • During/after installation of retaining wall sub-drain, prior to backfilling. • During compaction of retaining wall backfill materials to verify proper compaction. • During backfill of drainage and utility line trenches, to verify proper compaction. • When/if any unusual geotechnical conditions are encountered. • Prior to slab pours to ensure proper subgrade compaction and moisture barriers Please schedule an inspection with the geotechnical consultant prior to the pouring of all interior and exterior slabs. LIMITATIONS The geotechnical services described herein have been conducted in a manner consistent with the level of care and skill ordinarily exercised by members of the geotechnical engineering profession practicing contemporaneously under similar conditions in the subject locality. Under no circumstance is any warranty, expressed or implied, made in connection with the providing of services described herein.Data,interpretations,and recommendations presented herein are based solely on information available to this office at the time work was performed. EGA Consultants will not be responsible for other parties' interpretations or use of the information developed in this report. The interpolated subsurface conditions should be checked in the field during construction by a representative of EGA Consultants. We recommend that all foundation excavations and grading operations be observed by a representative of this firm to ensure that construction is performed in accordance with the specifications outlined in this report. We do not direct the contractor's operations, and we cannot be responsible for the safety of others. The contractor should notify the owner if he considers any of the recommended actions presented herein to be unsafe. Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No.SL148.1 November 5,2018 Associated References re. Liquefaction Arlalysis a. "Special Publication 117A: Guidelines for Evaluating and Mitigating Seismic Hazards in California,"bytheCalifornia Departmentof Conservation,California Geological Survey,dated March 13, 1997; Revised September 11, 2008. b. "Recommended Procedures for Implementation of DMG Special Publication 117 Guidelines for Analyzing and Mitigating Liquefaction Hazards in California," by G.R. Martin and M. Lew, University of Southern California Earthquake Center dated March, 1999. C. "Soil Liquefaction During Earthquakes"by I.M. Idriss and R.W. Boulanger,dated September 8, 2008. d. "Soils and Foundations, 81h Edition," by Cheng Liu and Jack B. Evett, dated August 4, 2013. e. "Evaluation of Settlement in Sands due to Earthquake Shaking" by Kahaji Tokimatsu and H Bolton Seed, Dated August 1987. f "Guidelines for Estimation of Shear Wave Velocity Profiles" By Bernard R. Wair, Jason T. Jong,Thomas Shantz Pacific Earthquake Engineering Research Center, Dated December, 2012. g "Subsurface Exploration Using the Standard Penetration Test and the Cone Penetrometer Test," by J. David Rogers, Environmental & Engineering Geoscience, pp. 161-179, dated May, 2006. h "Handbook of Geotechnical Investigation and Design Tables" By Burt G. Look, Dated 2007. I. "Use of SPT Blow Counts to Estimate Shear Strength Properties of Soils: Energy Balance Approach," by Hiroshan Hettiarachi and Timothy Brown, Journal of Geotechnical and Geoenvironmental Engineering, ASCE, pp. 830-834, dated June, 2009. j. "Standard Test Method for Performing Electronic Friction Cone and Piezocone Penetration Testing of Soils," (ASTM D5778-12), dated 2012. REFERENCES I. "USGS Topographic Map, 7.5 minute Quadrangle, Newport Beach OE S, California Quadrangle," dated 2015. 2. "Geologic Map of the San Bernardino and Santa Ana 30' X 60' Quadrangles, California," Version 1.0, compiled by Douglas M. Morton and Fred K. Miller, dated 2006. 3. "Maximum Credible Rock Acceleration from Earthquakes in California," by Roger W. Reensfelder, dated 1974. 4. Maps of Known Active Fault Near-Source Zones in California and Adjacent Portions of Nevada,"prepared by California Department of Conservation Division of Mines and Geology, published by International Conference of Building Officials, dated February, 1998. 5. "Guide for Concrete Floor and Slab Construction," by American Concrete Institute, ACI 302.1 R-04, dated 2004. 6. "California Building Code, California Code of Regulations, Title 24, Part 2," by California Building Standards Commission, 2016. 7. "Seismic Hazard Zone Report for the Newport Beach 7.5-Minute Quadrangles, Orange County, California," by the California Department of Conservation, 1997. 8. "2015 International Building Code," by the International Code Council, dated June 5, 2014. 9. "Geologic Map of California, Santa Ana Sheet," Compilation by Thomas H. Rogers, 1965, fifth printing 1985. 10. "Geologic Map of the Newport Beach 7.5' Quadrangle, Orange and San Diego Counties, California: A Digital Database, Version 1.0," by Siang S. Tan, CDMG, and USGS, dated 1999. 11. "International Building Code, 2015," by the International Code Council, dated June 5, 2014. Proposed 2-Story Commercial Office Development 215 Rivvrside Avenue,Newport Beach,CA Soils Report Project No.SL148.1 November 5,2018 24 12. "Analysis of Active Blind Thrust and Fold Hazards in the Southern Los Angeles Basin from Shallow Aquifers and Airborne Swath-Mapped DEM's, Final Technical Report, NEHRP," by Karl Meuller, Dept. of Geological Sciences, University of Colorado, dated 2004. 13. Al Atik, L., Sitar, N. "Seismic Earth Pressures on Cantilever Retaining Structures"Journal of Geotechnical and Geoenvironmental Engineering. ASCE, dated October 2010. 14. Lew, M., Sitar, N., Al Atik, L., Pourzanjani, M., Hudson, M.B. "Seismic Earth Pressures on Deep Building Basements" SEAOC 2010 Convention Proceedings. Structural Engineers Association, California, dated 2010. 15 Monobe, N. And Matsuo, M., "Experimental Investigation of Lateral Earth Pressure During Earthquakes," 1932. 16. Monobe, N. And Matsuo, M., "On Determination of Earth Pressures During Earthquakes," 1929. Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No SL148.1 November 5,2018 25 m OHMS WY .: a � ST ANChUR M4Eaer � �� PRODUCTION PIL SEVI MA£ ACi4ICE W N� J° ST ' �. `ti4 �� •gyp f V Q' � A 800 r r `L! Q��ERSZ ow cne HIED I Cq� A ��+� z PA HALYARD LNIN U CT 7e- WA HOSPITAL 3 i p j, Lyra tiAFWR N HA .SMINEr vlkw a�• � E PAR!( 0 _ 4000 SAG 1❑ f~� Dn PO m LBpq a PL 6A C6VES a IMS ~�- � s SITE �� ' SL LOCATION �� t'(} ne �4 avnr�L PL PARK lao 4 � « Samm Shw DR M �r YAW cue p �f 1 ANZA ST KI a v+ CL qy� g� Si 11AW 2 BEACH DR A�S Q 700 't I�IHA 3 BDLIVAR ST n KI PAW Jr" AV 'D7tt� e 5� CH FS VT �'I� �y SEA 400 Ux WE BALBOA CR PA ■ 31ST ST F ST BAY�$ �{ CLUBS R $ ila9 0 �lP t ST PEvMU 4 .S� REsiwr� yes~ p 4 z �C ..� � 1101E P Um .AW ti q^\, A g fs ' �s ni iVAR ST A\` S�. 4 5 S s '' '. -t N OBTAINED FROM "THE THOMAS GUIDE" THOMAS BROS. MAPS, ORANGE COUNTY RAND MCNALLY& COMPANY, DATED 2008 EGA SITE LOCATION MAP Project No: SL148.1 Consultants 215 RIVERSIDE AVENUE Date: NOV 2018 engineering geotechnical applications NEWPORT BEACH, CALIFORNIA Figure No: 1 v RIVERSIDE AVENUE U v P.L. _46_ r N F+ 7��. U n 3 �a B-1 B-2 ru EXISTING CPT-4 s STRUCTURE 0 Q Z 1 CPT-2 v W a' W EXISTING ,y PARKING LOT IL O ra QV L a ry' 0 a 0 r B-3 u c m v v 0 � Im q� CPT-3 CPT-1 LEGEND GEOTECHNICAL BORINGS BY EGA CONSULTANTS CONE PENETRATION TEST BY KEHOE TESTING AND ENGINEERING EGA PLOT PLAN Project No: SL148.1 Consultants 215 RIVERSIDE AVENUE Date: NOV 2018 NEWPORT BEACH CALIFORNIA Figure No: 2 engineering geotechnical applications , - • .'Cop J SITE ' LOCATION ort .Beach ', e s! F M � � f i A Eolian deposits(late Holocene)—Active or QoP3 6 Old paralic deposits, Units 3-6,undivided (late to recently active sand dune deposits; middle Pleistocene)—Silt, sand and cobbles on 45- unconsolidated. 55 m terraces. Marine deposits(late Holocene)—Active or Old paralic deposits(late to middle Pleistocene) Qm recently deposits;sand active beach de Do f overlain by alluvial fan deposits—Old paralic unconsolidated. deposits capped by sandy alluvial-fan deposits. Estuarine deposits(late Holocene)—Sand, silt, Capistrano Formation (early Pliocene and Cues. I and clay;unconsolidated, contains variable T0S Miocene)Siltstone facies—Siltstone and amounts of organic matter, mudstone;white to pale gray,massive to crudely f Old paralic deposits, Unit 4(late to middle bedded,friable. r C�op4 Tm ! Pleistocene)—Silt,sand and cobbles resting on 34- Monterey Formation (Miocene)—Marine siltstone 37 m Stuart Mesa terrace.Age about 200,000- and sandstone;siliceous and diatomaceous. 300,000 years. Sources: Morton,D.M.,and Miller,F.K.Preliminary Geologic map of the San Bernardino and Santa Ana 30'x 60'quadrangles,California. U.S.Geological Survey.Published 2006.1:100,000 scale. EGA GEOLOGIC MAP Project No: SL148.1 Consultants 215 RIVERSIDE AVENUE Date: NOV 2018 engineering geotechnical applications NEWPORT BEACH, CALIFORNIA Figure No: 3 Balboa Pier, Newport Beach, California Tide Chart Requested time: 2018-09-28 Fri 12:00 AM PDT Balboa Pier, Newport Beach, California 09-27 Thu 09-28 Fri 09-28 Fri 09-28 Fri 09-29 Sat 09-29 Sat 09-29 Sat 09-29 Sat .:25 PM PDT 5:15 AM PDT 11:22 AM PDT 6:16 PM PDT 12:17 AM PDT 5:46 AM PDT 12:00 PM PDT 7:17 PM PDT 7 ft 6 ft 5 ft 4 ft S ft 2 ft 1 ft 0 ft -1 ft 0 1! 12 1 2 3 4 5 6 7 8 9 10 11 12 1 2 3 4 5 6 7 8 9 10 11 12:•:I =}`' Ti !.6 7 8 9 10 11 12 1 2 3 A 5 6 3 8 9 '1 ! 1 I I r 1 I I I I I I I I ! S 1 I 1 l t ! I I l 1 Balboa Pier, Newport Beach, California 33.6000° N, 117.9000° W 2018-09-28 Fri 5:15 AM PDT 1.5 feet Low Tide 2018-09-28 Fri 6:43 AM PDT Sunrise 2018-09-28 Fri 11:22 AM PDT 5.2 feet High Tide 2018-09-28 Fri 6:16 PM PDT 0.8 feet Low Tide 2018-09-28 Fri 6:39 PM PDT Sunset 2018-09-29 Sat 12:17 AM PDT 3.9 feet High Tide snsrtnAnna 2018-09-29 Sat 5:46 AM PDT 1.9 feet Low Tide 2018-09-29 Sat 6:44 AM PDT Sunrise 'i-Pamslhlghwaybridip,,California 2018-09-29 Sat 12:00 PM PDT 5.2 feet High Tide xtuaingronaesclti coatahrenne 2018-09-29 Sat 6:38 PM PDT Sunset 2018-09-29 Sat 7:17 PM PDT 0.8feet Low Tide Santa Ana Riwr entrance kin side),California. 2018-09-30 Sun 1:30 AM PDT 3.4 feet High Tide Newport Bay Entrance,Coronadel,Nar..Collfornla 2018-09-30 Sun 6:23 AM PDT 2.4 feet Low Tide •alhepPier,Ne Fort Beach,California 2018-09-30 Sun 6:45 AM PDT Sunrise 2018-09-30 Sun 12:49 PM PDT 5.0 feet High Tide 2018-09-30 Sun 6:37 PM PDT Sunset 2018-09-30 Sun 8:36 PM PDT 0.9 feet Low Tide 2018-10-01 Mon 3:21 AM PDT 3.2 feet High Tide 2018-10-01 Mon 6:46 AM PDT Sunrise 2018-10-01 Mon 7:24 AM PDT 2.8 feet Low Tide 2018-10-01 Mon 1:59 PM PDT 4.9 feet High Tide 2018-10-01 Mon 6:35 PM PDT Sunset 2018-10-01 Mon 10:07 PM PDT 0.7 feet Low Tide 2018-10-02 Tue 2:47 AM PDT Last Quarter EGA TIDAL CHART Project No: SL148.1 Consultants 215 RIVERSIDE AVENUE Date: NOV 2018 engineering geotechnicalapplications NEWPORT BEACH, CALIFORNIA Figure No: 4 APPENDIX A GEOLOGIC LOGS and CPT Data Report by Kehoe Drilling &Testing (B-1, B-2, B-3, CPT-1, CPT-2, CPT-3, and CPT-4) UNIFIED SOIL CLASSIFICATION SYSTEM ASTM D-2457 UNIFIED SOIL CLASSIFICATION AND SYMBOL CHART LABORATORY CLASSIFICATION CRITERIA COARSE-GRAINED SOILS T (more than 501%of material is largw than No.200 sieve size.) Clean Gravels(Leas than 5%fines). D p r'� C - 60 greater than 4;C = 30 between 1 and 3 R,1 Well-graded gravels,).ravel-sand GW u D c D x D GW mixtwes,little or no fines 10 10 60 GRAVELS �� More than 50% GP Poorly-graded gravels,gravel-sand of coarse mixtures.little or no fines GP Not meeliny all gradation requirements for GW fraclion larger Gravels with fines(More than 12%fines) than No.4 f eve size I GMSilly gravels,gravel-sand-silt mixtures GM Alterberg limits below"A" f. line or P.I.less than 4 Above"A"line with P.I.between 4 and 7 are borderline cases " GC Clayey gravels•gravel-sand-clay GC Alterberg limits above"A" requiring use of dual symbols mixtures line with P.I.greater than 7 Clean 5s rids Lass Ihan D96 fines) D gn D30 Well-graded sands,gravelly sands, SW Du= D greater than 4;Cc= D ■D between 1 and 3 SW little or no fines 16 10 fiU SANDS 50%of more SP Poorly graded sands,gravelly sands, of coarse little or no fines Sp Not meeting all gradation requirements for GW Ll fraction smaller Semis n_tlti lfnss.(Mnre than 12%fines),__ than No.4 Atterber limits below"A" sieve size Sh1 Silly sands,sand-sill mixtures SM g Limits plotting In shaded zone ine or P.I.less than 4 with P.I.between 4 anti 7 are Alterberg limits above"A" borderline cases requiring use SC Clayey sands,sand-clay mixtures SC line with P.I.greater than 7 of dual symbols. FINE-GRAINED SOILS (50% or more of material is smaller than No 200 sieve size.) Determine pet'oentages of sand and gravel from graln-size curve Depending on percentage of fines(fraction smaller than No 200 Slave size), Inorganic silts and very fine sands,rock coarse-grained soils are classified as follows' SILTS ML flour,silty of clayey fine sands or clayey Less than 5 percent ....................................GW,GP.SW,SP sills with slight plasticity More then 12 percent ... GM.GC.SM..SC AND ]. .—. 5 to 12 percent...................Borderline cases requiring dual symbols CLAYS Inorganic clays of low to medium Liquid limit CL plasticity,gravelly clays,sandy clays, less than silty clays,lean clays PLASTICITY CHART 50°in — OL Organic silts and organic silly clays of 60 low plasticity e 50 Inorganic silts,micaceous or a CH MH diatornaceous fine sandy or silly soils, x 40 SILTS elastic silts u3 A LINE: AND a F'I=0 73 LL-20 CLAYS CH Inorganic clays of high plasticity..fat 30 CL MH1 Liquid limit clays 2D 50% — or greater rn OH Organic clays of medium la high g 1 p '1Z- Plasticity,organic sills a ML&OL HIGHLY 00 10 20 30 40 50 60 70 80 90 100 ORGANIC Pr Peat and other highly organic soils LIQUID LIMIT(ILL)I%) SOILS RELATtVIF DENSITY CONSISTENCY Cohesionless Blows/ft* Blows/ft** Cohesive Soils Blows/ft* Blows/ft** Sands and Silts Very loose 0-4 0-30 Very soft 0-4 0-4 Loose 4-10 30-60 Soft 2-4 4-11 Medium dense 10-30 80-200 Firm 4-8 11-50 Dense 30-50 200-400 Stiff 8-16 50-110 Very dense Over 50 Over 400 Very stiff 16-32 110-220 Hard Over 32 Over 220 * Blows/foot for a 140-pound hammer falling 30 inches to drive a 2-inch O.D.,1-3/8 inch I.D.Split Spoon sampler (Standard Penetration Test). ** Blows/foot for a 36-pound hammer falling 24 inches to drive a 3.25 O,D„2.41 I.D.Sampler(Hand Sampling).Blow count convergence to standard penetration test was done in accordance with Fig.1.24 of Foundation Engineering Handbook by H.Y.Fang,Von Nostrand Reinhold,1991. LOG OF EXPLORATORY BORING Sheet 1 of 1 .Job Number: SL148.1 Boring No: B-1 'Project: 215 Riverside Avenue, Newport Beach, CA Boring Location: See Figure 2 Commercial Site Date Started: 9/28/2018 Rig: Mob. 4" augers Date Com feted: 9/28/2018 Grnd Elev. +/-22 ft. NAVD88 Sample 'E Direct TCL ype axi Shear Thin Wall 2.5"Ring �`� a c c~ LL Tube ®Sample o w y n a o N w a H �12 Y U c L c Z Bulk m Standard Split Static Water o c E U w cn m Sample Spoon Sample = Tahte o ' _ y Z x E H 0 o o w O FILL: Gray brown, silty sand with clay and gravel, 1 SM abundant organics, loose to medium dense. I/ Encountered rock/clasts, unable to advace auger beyon 4 ft. 5 Total Depth: 4 ft. at Refusal. No Groundwater. No Caving. Backfilled and Compacted 9/28/2018. 10 15 20 25 - 30 - 35 - 40 Figure EGA Consultants A-1 LOG OF EXPLORATORY BORING Sheet 1 of 1 Job Number: SL148.1 Boring No: B-2 Project: 215 Riverside Avenue, Newport Beach, CA Boring Location: See Figure 2 Commercial Site Date Started: 9/28/2018 Rig: Mob. 4" augers Date Completed: 9/28/2018 Grnd Elev. +/- 17 ft. NAVD88 Sample Direct Type n Shear U CL w Thin Ofall 2.5"Ring w c in u~i U- T Tube ®Sample o N � � L a LU H a Y U c o $ � L o ' Bulk m Standard SpIiE Static Water o j U = U) m Sample Spoon Sample = Table � � a B T- o j o o w x O FILL: Brownish gray, silty fine to medium sand with opt r 1 sM trace clay, loose to medium dense, moist. 0 119.0 30 185 10.5% At 2.5 ft.: Becomes gray brown, silty fine to medium 15.3 107.5 Sulf sm sand, medium dense, moist to very moist. 12ppm 5 At 4.0 ft. becomes micaceous silty sand, med. 20.0 SM dense to dense, low to med. porosity. At 6 ft.: Same, moist to very moist, medium dense. 17.6 At 8 ft.: Becomes brown, silty sand with gravel very moist, dense. 25.2 10 At 10 ft.: Becomes very dense, very moist. Total Depth: 11 ft. No Groundwater. No Caving. 15 Backfilled and Compacted 9/28/2018. 20 25 30 - 35 40 - [IA-2 ure EGA Consultants LOG OF EXPLORATORY BORING Sheet 1 of 1 Job Number. SL148A Boring No: B-3 Project: 215 Riverside Avenue, Newport Beach, CA Boring Location: See Figure 2 Commercial Site Date Started: 9/2$/2018 Rig: Mob. 4" augers (Date Completed: 9/28/2018 Grnd Elev. +/-24 ft. NAVD88 Sample t Direct Type X n Shear U) Thin Wall 2.5"Ring a n Z LL T Tube Sample c c �, w c a� Y U c o 0 a H L o ' Bulk Standard Split � Static Water o 7 $ v Q U) o CO 0 Sample m Spoon Sample = Table z a E T o j o o w X O FILL: Yellowish grown,fine to medium sand with ap+ 1 sM trace silt, loose to medium dense, dry. 2.6 96.3 0 1190 30 185 10.5% Sulf SM At 3 ft-: Becomes brownish gray, fine to medium 4.7 12 ppm 5 sand with trace sift, medium dense, dry to damp. sMi At 4 ft.: Becomes mixed clay and silty sand. 3.7 Sc At 7 ft.: Becomes yellowish gray, fine to medium sM sand with silt, medium dense to dense, dry. 3.2 At 10 ft.: 'Transitions to very fine silty sand, moist, 10 medium dense to dense. 13.4 At 11 ft.:Yellowish brown,fine to medium sand with trace silt, dense, damp, low porosity. 4.9 At 14 ft,: Becomes medium to coarse sand with SIB Z trace silt, dense to very dense, dry to damp. 3.2 15 At 16 ft.: Becoming difficult to drill,very dense, medium to coarse sand with trace silt, damp. 4.0 Total Depth: 17 ft. 20 - No Groundwater. No Caving. Backfilled and Compacted 9/28/2018. 25 - 30 - 35 40 Figure EGA Consultants A-3 Y 4 N n _ V d •6'a +'r' w ,�.. gg w row � R 1f c ro pp I R R fE R q N. It R 1 f R y R R R F R O .-I F F E nh n = y,+7 g• n y, n�„�,`7�i.il•��•,�•#n .n anri y, y w�E �•n �• ,�J {V O #±- ._. ,S.�..f. '1 z.. - t-,II�. ..2 [a[te�.. „�w. U } oclu 7 W G7 U V V! [n co 16j ROO t3 04 C.I Vl M 4Y 4JN U 0 r4 o N 43 �' t. ID 19 ;, al [Ln ® ❑t aL F- co cu 'D H O ._ I J � at m .. rl v? la n .- ut - •,� � .. rJ vl ()l)4jda(3 I E , af li o .. .. — .r .. rl ••l - rV I I r, I I , , ^ .. � eta (:g)4;da fl a [[ wCL Q a 00 0 ( )4 a4 0 c Jt o . Li aai C n W0 EO pa u I, Or O cl SC� @) " 8 0 0 Q ! A._L _I ] CL j41 Id Ln w W ry Cp .. ., F G] N U ]G `oZE _ IL • r. 4� •-, ry «1 I ,:r ra ra IN rl (4)44daa Y >. 3 ` •y A• 00 d ri N � I W� r t i > > CD ly rL LL E ] E I ()4)4;daa 7 a kn kn ................ . ................ CL - ¢ a � � L a ri Q. N n C O M ()4)44da4 0` c C, m e E v - ._i........;......_�... w 7 _ LU ... .. ...... { O1 V kY U/ n L o y�� r )4�ad c F OY 1. of co o+ @) o o a aka., m � v �C Z aci Z In M m E V 14 C J W W N t e v 1-4 (:4)44da0 !h 00 Y - •i .• leer. �. ..� a : C 0 n3l'a .a a s l9 Q ni a F.rea. .. .... -.-. _ ...... .....:.. -..-...• - - - _. ... - ..; co - ... ...... ... . ... I. .........--.. .. a ui L 0 a, co v . 0 F ()4)4;daa L �• � � i 3 i I � I � � [ [ ] I [ ? -_ + it —? Ta LL .. j.. .. �_ . II t i i I [ (:4)44daa 7 _ ' w ,d lb W a a D Q m CD 16 a N a 0 CD _. � - _r .� tJ , t•, r'1 CD � )4 a(i o c r N LP -A o dti u C . a r W O E i O m N C � .. i ti ri .- ,. , ••1 �t i .- r! ul •' a O t o (�)44daa r � � Y0)) t' m _ 0 a o °a z � Z c v Q o_ co a Y o V T N 9 - - - laJ V y 4 v t v a L a LnCL a` Ifl 41 .a ~a w W N p ..... •--� U N U > N � v r-, -� ,Y •4 iV tv r, r,,I rl r, t t t r T C C 7 - (:4)4;daa V co -he ro 0 u 41 CL co (4)q4a(3 i T ry LL ............. T� k I I U. (D4)44daCl CL tunl rn M a oc� C) (:4)q-jdaCj 79 0 .......... .2 ..............I fo 'n 3 r z z 0 E ........ .... ......... ................. .................. ............... .... LU 0 E U0. .2 0 ICI L� 6 14 14 (:g)q4da.Cl 0 a 0 m yJ 3 .2 cL Z . ..... ........ .............. M N a 'd LA Ln CL LU N t F N u 7 ()4)4;da<3 215 Riverside Ave., NB, CA SL148.1 CPT-1 In situ data No Depth(ft) qc(tsf) fs(tsf) SBTn Ksbt(ft/s) Cv(ft2/s) SPT N1(60) Constrained (blows/feet) Mod.(tsf) 1 0 1.06 0.45 0 0.00E+00 0.00E+00 0 58.25 2 1 119.54 1.25 6 9.39E-05 1.88E+00 69 625.65 3 2 12.02 0.82 6 8.97E-05 2.03E+00 54 705.66 4 3 16.95 0.33 5 3.66E-06 2.66E-02 30 227.3 5 4 20.26 0.33 5 5.16E-06 3.38E-02 21 204.82 6 5 7.4 0.15 5 1.81E-06 8.58E-03 16 148.24 7 6 5.01 0.17 4 1.28E-07 2.68E-04 10 65.57 8 7 2.73 0.17 3 3.48E-08 4.97E-05 8 44.58 9 8 3.08 0.06 3 3.43E-08 4.32E-05 6 39.26 10 9 4.86 0.08 5 1.25E-05 1.59E-01 13 396.77 11 10 52.06 0.26 5 1.10E-05 2.00E-01 18 566.57 12 11 26.33 0.57 6 1.20E-04 3.18E+00 26 828.8 13 12 107 0.4 6 2.13E-04 6.41E+00 29 938.46 14 13 99.3 0.41 6 9.00E-04 2.83E+01 30 983.42 15 14 109.42 0.25 6 2.56E-04 7.56E+00 26 920.79 16 15 27.6 0.48 6 4.16E-05 1.13E+00 22 846.35 17 16 20.35 0.55 5 9.26E-07 8.46E-03 14 285.29 18 17 16.07 0.36 4 4.28E-07 3.15E-03 12 229.91 19 18 15.92 0.35 4 3.96E-07 2.70E-03 11 212.96 20 19 16.9 0.33 4 5.05E-07 3.63E-03 10 224.69 21 20 18.76 0.28 5 8.22E-07 6.67E-03 10 253.46 22 21 22.27 0.29 5 9.70E-07 8.45E-03 11 272.02 23 22 21.06 0.35 5 2.39E-06 3.20E-02 14 419.1 24 23 50.45 0.78 5 6.36E-06 2.16E-01 19 1063.2 25 24 70.93 0.95 5 1.60E-05 7.12E-01 25 1393.05 26 25 96.95 1.43 6 2.51E-05 1.16E+00 26 1441.71 27 26 77.07 0.73 6 2.24E-05 1.03E+00 25 1434.16 28 27 64.92 0.88 6 2.26E-05 9.86E-01 23 1359.21 29 28 85.36 1.02 5 1.55E-05 7.69E-01 25 1548.09 30 29 91.37 1.65 5 7.59E-06 4.12E-01 26 1694.4 31 30 56.06 1.86 5 7.30E-06 4.34E-01 27 1854.05 32 31 105.24 1.81 5 1.51E-05 9.08E-01 29 1881.83 33 32 130.39 1.27 5 1.78E-05 1.09E+00 29 1918.2 34 33 70.58 1.86 6 2.44E-05 1.51E+00 29 1934.53 35 34 125.88 1.62 5 6.25E-06 3.67E-01 24 1834.5 36 35 47.54 1.36 5 5.30E-06 1.64E-01 21 968.62 37 36 40.43 0.88 4 6.64E-07 1.11E-02 13 519.88 38 37 29.92 0.56 4 7.60E-07 1.29E-02 13 530.66 39 38 50.03 1.22 5 7.36E-06 3.76E-01 20 1594.31 40 39 139.86 1.45 6 5.16E-05 3.14E+00 28 1899.1 1 215 Riverside Ave., NB, CA SL148.1 CPT-1 41 40 178.01 1.07 6 5.79E-05 3.80E+00 30 2048.24 42 41 86.63 1,74 6 1.38E-04 9.14E+00 32 2068.04 43 42 212.21 1.09 6 7.24E-05 4.85E+00 30 2092.39 44 43 131.39 1.38 6 1.09E-04 7.21E+00 31 2071.88 45 44 114.6 1.42 6 7.06E-05 5.24E+00 32 2318.34 46 45 228.06 2.28 6 1.59E-04 1.17E+01 34 2296.31 47 46 200.45 0.83 6 4.61E-04 3.35E+01 37 2269.8 48 47 220.65 0.81 6 9.04E-04 5.87E+01 35 2025.7 49 48 233.51 1.12 6 4.89E-04 3.20E+01 33 2042.17 50 49 137.24 1.04 6 3.99E-04 2.77E+O1 34 2165.53 51 50 233.7 1.27 6 3.58E-04 2.53E+01 34 2208.12 2 APPENDIX B LABORATORY RESULTS G3SOI [Works GEOLOGY.GEOTECH .GROUNDWATER EGA Consultants October 16, 2018 375-C Monte Vista Avenue Project No. 114-523-10 Costa Mesa, California 92627 Attention: Mr. David Worthington, C.E.G. Subject: Laboratory Test Results 215 Riverside Avenue Newport Beach, California Dear Mr. Worthington: G3SoilWorks, Inc. performed the requested laboratory tests on soil specimens delivered to our office for the subject project. The results of these tests are included as an attachment to this report. We appreciate the opportunity of providing our services to you on this project. Should you have any questions, please contact the undersigned. Sincerely, G3SQiIWorks, Inc. ti J. No.GE2726 By: niel J,'Ylorilkawa, ti RGE 2726, Reg. expiry Attachment: Laboratory Test Results 350 Fischer Ave. Front 4 Costa Mesa, CA 92626 P: 714 668 5600 www.G3SoilWorks.com EGA Consultants October 16, 2018 Laboratory Test Results Project No. 114-523-10 215 Riverside Avenue Page 2 of 4 Newport Beach, California LABORATORY TEST RESULTS Summarized below are the results of requested laboratory testing on samples submitted to our office. Dry Density and Moisture Content Tabulated below are the requested results of field dry density and moisture contents of undisturbed soils samples retained in 2.42 — inch inside diameter by one-inch height rings. Moisture only results were obtained from small bulk samples. Sample Dry Density, Moisture Content, Identification pcf % B-2 @ 2.5' 107.5 15.3 B-2 @ 4.0' 20.0 B-2 @ 6.0' 17.6 B-2 @ 8.0' 25.2 B-3 @ 2.5' 96.3 2.6 B-3 @ 4.0' 4.7 B-3 @ 6.0' 3.7 B-3 @ 8.0' 3.2 B-3 @ 10.0' 13.4 B-3 @ 12.0' 4.9 B-3 @ 14.0' 3.2 B-3 @ 16.0' 4.0 Notes: (*) Denotes small bulk sample for moisture content testing only. 350 Fischer Ave. Front * Costa Mesa, CA 92626 4 P: 714 668 5600 ® www.G3SoilWorks.com EGA Consultants October 16, 2018 Laboratory Test Results Project No. 114-523-10 215 Riverside Avenue Page 3 of 4 Newport Beach, California Soil Classification Requested soil samples were classified using ASTM D2487 as a guideline and are based on visual and textural methods only. These classifications are shown below: Sample Identification Soil Description Group Symbol Silty sand with clay— gray brown, B-1 @ 0-3 SM gravel, abundant organics Silty fine to medium sand with trace B-2 @ 0-3, SM clay— brownish gray B-2 @ 4.0' Silty fine to medium sand —gray SM brown, micaceous B-2 @ 8 0' Silty sand with gravel SM B-3 @ 0-3' Fine to medium sand with trace silt— SP yellow brown B-3 @ 4.0' Fine to medium sand with trace silt— SP brownish gray B-3 @ 8.0' Fine to medium sand with trace silt— SP yellowish gray - B-3 @ 14.0' Medium to coarse sand with trace silt SP —yellowish brown Maximum Dry Density and Optimum Moisture Content Maximum dry density and optimum moisture content test was performed in accordance with ASTM: D 1557, The results are shown below: Sample Identification Maximum Dry Density Optimum Moisture (pcf) Content (%) B-2 @ 0-3' 119.0 10.5 Expansion Index A bulk soil sample was tested for expansion potential following the ASTM D-4829 Test Procedure. Test results are presented below: Sample Identification Expansion Index Expansion Potential (UBC 18-1-13) L7B-3@ 0-3' 0 Very Low 350 Fischer Ave. Front . Costa Mesa, CA 92626 ® P: 714 668 5600 a www.G3SoilWorks.com EGA Consultants October 16, 2018 Laboratory Test Results Project No. 114-523-10 215 Riverside Avenue Page 4 of 4 Newport Beach, California Sulfate Content A selected bulk sample was tested for soluble sulfate content in accordance with Hach procedure. The test result is shown below: Water Soluble Sulfate in Soil Sulfate Exposure Class Sample Identification (percentage by weight (%)) (ACI 318-14, Table 19.3.1.1) I B-3 @ 0-3' 0.0012 SO Direct Shear The results of direct shear testing (ASTM D3080) are plotted on Figure S-1. Soil specimens were soaked in a confined state and sheared under varied loads ranging from 1.0 ksf to 4.0 ksf with a direct shear machine set at a controlled rate of strain of 0.005 inch per minute. 350 Fischer Ave. Front a Costa Mesa, CA 92626 . P: 714 668 5600 - www.G3SoilWorks.com DIRECT SHEAR TEST 4,000 i.;. 3,750 4. 3,500 i •r• - 3 250 - - T T - .�.y. .t. .}• 4 i 1 .F. 3,000 2,75 0 - - .�. .}.i. i•f •1- 2,500 � _ d 2,250 U) w 2,000 U) Q 1.750 w _ - - 1.500 ;. 1,250 0 - 4 .. }. 1,000 1. ,. 750 -- - 500 4. z 250 - i ' f- 0 - 0 500 1,000 1,500 2,000 2,500 3,000 3,500 4,000 NORMAL STRESS, PSF 215 Riverside Avenue, Newport Beach COHESION 185 psf. FRICTION ANGLE 30.0 degrees symbol boring depth(ft.) symbol boring depth(ft.) FIGURE S-1 • B-2 2.5 DIRECT SHEAR TEST PN: 114-523-10 REPORT DATE: 10/16/18 350 Fischer Ave. Fio3it �^ Costa Mesa,CA 92626 3 '-.; ®1 S Phone:(714)668 5600 — www.(33S01lwoPks coin FIG. S-1 APPENDIX C GENERAL EARTHWORKS AND GRADING GUIDELINES GENERAL EARTHWORK AND GRADING GUIDELINES I. GENERAL These guidelines present general procedures and requirements for grading and earthwork including preparation of areas to be filled, placement of fill, installation of subdrains, and excavations. The recommendations contained in the geotechnical report are a part of the earthwork and grading specifications and should supersede the provisions contained herein in the case of conflict. Evaluations performed by the consultant during the course of grading may result in new recommendations which could supersede these specifications or the recommendations of the geotechnical report. II. EARTHWORK OBSERVATION AND TESTING Prior to commencement of grading, a qualified geotechnical consultant should be employed for the purpose of observing earthwork procedures and testing the fills for conformance with the recommendations of the geotechnical report and these specifications. The consultant is to provide adequate testing and observation so that he may determine that the work was accomplished as specified. It should be the responsibility of the contractor to assist the consultant and keep him apprised of work schedules and changes so that the consultant may schedule his personnel accordingly. The contractor is to provide adequate equipment and methods to accomplish the work in accordance with applicable grading codes or agency ordinances, and these specifications. If in the opinion of the consultant, unsatisfactory conditions are resulting in a quality of work less than required in these specifications, the consultant may reject the work and recommend that construction be stopped until the conditions are rectified. Maximum dry density tests used to determine the degree of compaction should Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No. SL148 1 November 5,2018 be performed in accordance with the American Society for Testing and Materials Test Method ASTM: D 1557. III. PREPARATION OF AREAS TO BE FILLED 1. Clearing and Grubbing: All brush, vegetation, and debris should be removed and otherwise disposed of. 2. Processing: The existing ground which is evaluated to be satisfactory for support of fill should be scarified to a minimum depth of 6 inches. Existing ground which is not satisfactory should be overexcavated as specified in the following section. Scarification should continue until the soils are broken down and free of large clay lumps or clods and until the working surface is reasonably uniform and free of uneven features which would inhibit uniform compaction. 3. Overexcavation: Soft, dry, spongy, or otherwise unsuitable ground, extending to such a depth that surface processing cannot adequately improve the condition, should be over excavated down to firm ground, approved by the consultant. 4. Moisture Conditioning: Over excavated and processed soils should be watered, dried-back, blended, and/or mixed, as necessary to attain a uniform moisture content near optimum. 5. Recompaction: Over excavated and processed soils which have been properly mixed and moisture-conditioned should be recompacted to a minimum relative compaction of 90 percent. 6. Benching: Where fills are to be placed on ground with slopes steeper than 5:1 (horizontal to vertical units), the ground should be benched. The lowest bench should be a minimum of 15 feet wide, and at least 2 feet deep, expose firm material, and be approved by the consultant. Other Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No. SL148.1 November 5,2018 2 benches should be excavated in firm material for a minimum width of 4 feet. Ground sloping flatter than 5:1 should be benched or otherwise over excavated when considered necessary by the consultant. 7. Approval: All areas to receive fill, including processed areas, removal areas, and toe-of-fill benches should be approved by the consultant prior to fill placement. IV. FILL MATERIAL 1. General: Material to be placed as fill should be free of organic matter and other deleterious substances, and should be approved by the consultant. Soils of poor gradation, expansion, or strength characteristics should be placed in areas designated by the consultant or mixed with other soils until suitable to serve as satisfactory fill material. 2. Oversize: Oversize material defined as rock, or other irreducible material with a maximum dimension greater than 12 inches, should not be buried or placed in fill, unless the location, materials, and disposal methods are specifically approved by the consultant. Oversize disposal operations should be such that nesting of oversize material does not occur, and such that the oversize material is completely surrounded by compacted or densified fill. Oversize material should not be placed within 10 feet vertically of finish grade or within the range of future utilities or underground construction, unless specifically approved by the consultant. 3. Import: If importing of fill material is necessary for grading, the import material should be approved by the geotechnical consultant. V. FILL PLACEMENT AND COMPACTION 1. Fill Lifts: Approved fill material should be placed in areas prepared to receive fill in near-horizontal layers not exceeding 6 inches in compacted Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No.SL148.1 November 5,2018 3 thickness. The consultant may approve thicker lifts if testing indicates the grading procedures are such that adequate compaction is being achieved with lifts of greater thickness. Each layer shall be spread evenly and should be thoroughly mixed during spreading to attain uniformity of material and moisture in each layer. 2. Fill Moisture: Fill layers at a moisture content less than optimum should be watered and mixed, and wet fill layers should be aerated by scarification or blended with drier material. Moisture-conditioning and mixing of fill layers should continue until the fill material is at a uniform moisture content at or near optimum. 3. Compaction of Fill: After each layer has been evenly spread, moisture- conditioned, and mixed, it should be uniformly compacted to not less than 90 percent of maximum dry density. Compaction equipment should be adequately sized and either specifically designed for soil compaction or of proven reliability, to efficiently achieve the specified degree of compaction. 4. Fill Slopes: Compacting of slopes should be accomplished, in addition to normal compacting procedures, by backrolling of slopes with sheepsfoot rollers at frequent increments of 2 to 3 feet in fill elevation gain, or by other methods producing satisfactory results. At the completion of grading, the relative compaction of the slope out to the slope face shall be at least 90 percent. 5. Compaction Testing: Field tests to check the fill moisture and degree of compaction will be performed by the consultant. The location and frequency of tests should be at the consultant's discretion. In general, the tests should be taken at an interval not exceeding 2 feet in vertical rise and/or 1,000 cubic yards of embankment. VI. SUBDRAIN INSTALLATION Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No SL148.1 November 5,2018 4 Subdrain systems, if required, should be installed in approved ground and should not be changed or modified without the approval of the consultant. The consultant, however, may recommend and upon approval, direct changes in subdrain line, grade, or material. VI I. EXCAVATION Excavations and cut slopes should be examined during grading. If directed by the consultant, further excavation or overexcavation and refilling of cut areas should be performed, and/or remedial grading of cut slopes performed. Where fill-over-cut slopes are to be graded, unless otherwise approved, the cut portion of the slope should be made and approved by the consultant prior to placement of materials for construction of the fill portion of the slope. Proposed 2-Story Commercial Office Development 215 Riverside Avenue,Newport Beach,CA Soils Report Project No.SL148.1 November 5,2018 5 APPENDIX D USGS Design Maps Detailed Report USGS Design Maps Summary Report User—Specified Input Report Title 215 Riverside Avenue, Newport Beach, CA Thu October 18, 2.018 04:43:26 UTC Building Code Reference Document ASCE 7-10 Standard (which utilizes USGS hazard data available in 2008) Site Coordinates 33.62190N, 117.92365°W Site Soil Classification Site Class D - "Stiff Soil" Risk Category I/II/III •�5 yA>�t. 'i' 'Fountain Valley s-APOrIk,rlE�'P� � sr'; .K •..�.. I_r.+:JShm 4±iaye+a A ryl .Huntington Beach Ile� irvil4 Costa M esa�' ` ,r 7 •. M ISslon Viejo Newport Bea k Lagunawoods. Lake For 75 t�guna Hill Aliso Viej o • 1 Laguna Beach - vim` USGS—Provided Output SS = 1.700 g SMS = 1.700 g Sus = 1.133 g S1 = 0.627 g SM1 = 0.941 g Spl = 0.627 g For information on how the SS and S1 values above have been calculated from probabilistic (risk-targeted) and deterministic ground motions in the direction of maximum horizontal response, please return to the application and select the "2009 NEHRP" building code reference document. IN[CI:H RoiponseSpe+rtrum Nslign ReipmiiseSpedrum I.+r .lid, L Ir � 137T4 f fiPel 14 1 it I fl-I? Ilivi .li.l Inn u,�l u,pi iIN li}yi U<I I,A I.k Ifri I;v �,u -. n-7 n,p nirl u l Inl I Y 14, If" 1.251 -,u Pcripld,T fu. v) PL-rhkd,T(er) For PGA,„ T1, CRs, and CR, values, please view the detailed report. Ait.hough this information is a product of the U.S. Geological Survey, we provide no warranty, expressed or implied, as to the accuracy of the data contained therein.This tool is not a substitute for technical Subject-rnatte.r knowledge. ZUSGS Design Maps Detailed Report ASCE 7-10 Standard (33.6219°N, 117.92365°W) Site Class D - "Stiff Soil", Risk Category I/II/III Section 11.4.1 — Mapped Acceleration Parameters Note: Ground motion values provided below are for the direction of maximum horizontal spectral response acceleration. They have been converted from corresponding geometric mean ground motions computed by the USGS by applying factors of 1.1 (to obtain Ss) and 1.3 (to obtain SJ. Maps in the 2010 ASCE-7 Standard are provided for Site Class B. Adjustments for other Site Classes are made, as needed, in Section 11.4.3. From Figure 22-1 Ss = 1.700 g From Figure 22-2[21 S1 = 0.627 g Section 11.4.2 — Site Class The authority having jurisdiction (not the USGS), site-specific geotechnical data, and/or the default has classified the site as Site Class D, based on the site soil properties in accordance with Chapter 20. Table 20.3-1 Site Classification Site Class VS N or W,, S. A. Hard Rock >5,000 ft/s N/A N/A B. Rock T 2,500 to 5,000 ft/s N/A N/A C. Very dense soil and soft rock 1,200 to 2,500 ft/s >50 >2,000 psf D. Stiff Soil 600 to 1,200 ft/s 15 to 50 1,000 to 2,000 psf E. Soft clay soil <600 ft/s <15 <1,000 psf Any profile with more than 10 ft of soil having the characteristics: • Plasticity index PI > 20, • Moisture content w >_ 40%, and • Undrained shear strength su < 500 psf F. Soils requiring site response See Section 20.3.1 analysis in accordance with Section 21.1 For SI: 1ft/s = 0,3048 m/s 1lb/ft2 = 0.0479 kN/m2 Section 11.4.3 - Site Coefficients and Risk-Targeted Maximum Considered Earthquake Spectral Response Acceleration Parameters Table 11.4-1: Site Coefficient Fa Site Class Mapped MCE R Spectral Response Acceleration Parameter at Short Period Ss <_ 0,25 SS = 0.50 SS = 0.75 SS = 1.00 SS >- 1.25 A 0.8 0.8 0.8 0.8 0.8 B 1,0 1.0 1.0 1,0 1.0 C 1.2 1.2 1.1 1,0 1.0 D 1.6 1.4 1.2 1.1 1.0 E 2.5 1.7 1.2 0.9 0.9 F See Section 11.4.7 of ASCE 7 Note: Use straight-line interpolation for intermediate values of SS For Site Class = D and SS = 1.700 g, Fa = 1.000 Table 11.4-2: Site Coefficient F, w Site Class Mapped MCE R Spectral Response Acceleration Parameter at 1-s Period S, 5 0.10 S, = 0.20 S, = 0.30 S, = 0.40 S, ? 0.50 A 0.8 0.8 0,8 0.8 0.8 B 1.0 1.0 1.0 1.0 1.0 C 1.7 1.6 1.5 1.4 1.3 D 2.4 2.0 1.8 1.6 1.5 E 3.5 3.2 2.8 2.4 2.4 F See Section 11,4.7 of ASCE 7 Note: Use straight-line interpolation for intermediate values of S, For Site Class = D and Sl = 0.627 g, F = 1.500 Equation (11.4-1): SMs = F,,Ss = 1.000 x 1.700 = 1.700 g Equation (11.4-2): SM1 = F,S1 = 1.500 x 0.627 = 0.941 g Section 11.4.4 — Design Spectral Acceleration Parameters Equation (11.4-3): SoS = % SMS = 2/3 x 1.700 = 1.133 g Equation (11.4-4): Spl = z/3 SMi = 2/3x 0.941 = 0.627 g Section 11.4.5 — Design Response Spectrum From Figure 22-12 E31 TL = 8 seconds Figure 11,4-1: Design Response Spectrum T<Tfl:S.=SEm(fl.4+OATITo) TosT5T,:S,=S05 ' T>TL:S,-%IT�IT' e ' T,I=0,1 1 1 Ps=b 5153 1000 ")d,7'fAoe9 Section 11.4.6 — Risk-Targeted Maximum Considered Earthquake (MCER) Response Spectrum The MCER Response Spectrum is determined by multiplying the design response spectrum above by 1.5. SACS 1 700 -- i i i 1 S il,z3�}I !II a ' I 0 1 1 1 'I's=0 554 1.000 PaW,T(w) Section 11.8.3 - Additional Geotechnical Investigation Report Requirements for Seismic Design Categories D through F From Figure 22-7141 PGA = 0.696 Equation (11.8-1): PGA, = FPGAPGA = 1.000 x 0.696 = 0.696 g Table 11.8-1: Site Coefficient F,GA Site Mapped MCE Geometric Mean Peak Ground Acceleration, PGA Class PGA << PGA = PGA = PGA = PGA >_ 0.10 0.20 0.30 0.40 0.50 A 0.8 0.8 0.6 0.8 0.8 B 1.0 1.0 1.0 1.0 1.0 C 1.2 1.2 1.1 1.0 1.0 D 1.6 1.4 1.2 1.1 1.0 E 2.5 1.7 1.2 0.9 0.9 F See Section 11.4.7 of ASCE 7 Note: Use straight-line interpolation for intermediate values of PGA For Site Class = D and PGA = 0.696 g, FPGA = 1.000 Section 21.2.1.1 - Method 1 (from Chapter 21 - Site-Specific Ground Motion Procedures for Seismic Design) From Figure 22-17151 CRs = 0.904 From Figure 22-1.8161 CRl = 0.922 Section 11.6 — Seismic Design Category Table 11.6-1 Seismic Design Category Based on Short Period f�t�sponse Acceleration Parameter RISK CATEGORY VALUE OF Sos I or II III IV SDS < 0.167g A A A 0.167g <_ Sos < 0.33g B B C 0.33g S SDS < 0.50g C C D 0.50g 6 Sos D D D For Risk Category = I and SD, = 1.133 g, Seismic Design Category = D Table 11.6-2 Seismic Design Category Based on 1-S Period Response Acceleration Parameter RISK CATEGORY VALUE OF SDI I or II III IV SDI < 0.067g A A A 0.067g <_ SDI < 0.133g B B C 0.133g <_ SDI < 0.20g C C D 0.20g <_ SDI D D D For Risk Category = I and SDI = 0.627 g, Seismic Design Category = D Note: When S, is greater than or equal to 0.75g, the Seismic Design Category is E for buildings in Risk Categories I, II, and III, and F for those in Risk Category IV, irrespective of the above. Seismic Design Category = "the more severe design category in accordance with Table 11.6-1 or 11.6-2" = D Note: See Section 11.6 for alternative approaches to calculating Seismic Design Category. References 1. Figure 22-1: https://earthquake.usgs.gov/hazards/designmaps/downloads/pdfs/2010._ASCE- 7_Figure_22-1.pdf 2. Figure 22-2: https://earthquake.usgs,gov/hazards/designmaps/downloads/pdfs/2010_ASCE- 7_Figure_22-2.pdf 3. Figure 22-12: https://earthquake.usgs,gov/hazards/designmaps/downloads/pdfs/2010_ASCE- 7_Fi g u re_22-12.pdf 4. Figure 22-7: https://earthquake.usgs,gov/hazards/designmaps/downloads/pdfs/2010_ASCE- 7_Figure_22-7.pdf 5. Figure 22-17: https://earthquake.usgs.gov/hazards/designmaps/downloads/pdfs/2010_ASCE- 7_Figure_22-17,pdf 6. Figure 22-18: https://earthquake.usgs.gov/hazards/designmaps/downloads/pdfs/2010_ASCE- 7_Figure_22-18.pdf APPENDIX E LIQUEFACTION ANALYSES/SETTLEMENT COMPUTATIONS V o6 o F o LT L N g N a v � ao m E c t v o ° o a 3 z ,o z 0 ai `n :3 0 C 4� N o 0 0 0 0 0 0 0 0 0 0 0 d' OI d' O z N D, z M O L, Ln h n n L%% n n L* r- n Ll ID Ln Ln Ln d; d' M M M M N N E ° 00 Ln d' d' d' M M M N N m 00 co O] n L, h CJ 00 L- 10 r- ID .-1 LD .-I ID r1 ID .-I LD r1 I�R �--� In o Ln O Ln O Ln O N d' T N Ln n O N Ln I, O N Ln n O N Lo n O N Ln n O N Ln a N N N N M M M M d' d' It d' Ln Ln Ln Ln �o z ID Ln 00 Ln d' M r-I o 00 L, z d' M N O OI 00 IO Ln d' T 00 L, In d r1 V M Ll ri Z r1 �q o tin O Ln O Ln O d' Cn It O d' O d' 00 M 00 M U N d' O\ Ln O z H Ll N W M ON d' O Ln 0 z H L� N 0o M CN d' O M M d' d' m Ln z L*l L" co co O, Q, O O rq .--L N M 0 LD 00 co 0 n L� M M L" 00 d' O M LD d' Ln N ON ON N H Ln O O O 00 M N CO �c O, Ln ON Ln C� ID L% ID d' M M N N M d' Ln ID O ZD M d' 00 M o0 �D Ln .-q ID M D n z N d' N .--I o O H d' T z Ln d' N .--1 .-I r-I .-1 N N N N N H -4 H H r� U Ln Ln Lo Ln co 00 00 co Ln Ln Ln In Ln Ln Lo Ln Ln Ln Ln Ln Ln Ln N Ln n n N n 0 0 0 0 cq 00 0o W co W o+ rn D+ Om M M M rn rn M 0 0 0 0 0 0 0 0 0 0 0 0 00 0 0 0 0 0 0 r-I '+ N ,� '. .� e-I '-I •-1 '-I r1 r-I ,� '-I N .-1 ,� r-I ,� ,� .--I .� ,� rl Da co 0o co co 0o co co co o co co 0o 00 0 o Go co 00 00 00 o o 00 ao w o 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Ln Ln Ln Ln Ln Ln Ln Ln Ln Ln Ln Ln Ln Ln Ln Ln Ln Ln Ln Ln Ln m Ln Ln O o Lr U OG W z O LD 0 0 0 0 0 0 0 z �o ID 0 0 0 0 0 0 0 0 0 0 0 C r-I Ln H Ln M M Ln Ln M Ln H H '-4 Ln M Ln Ln Ln Ln Ln Ln Ln M Ln z V � � •� N N N �d N N N N � N N N <C N t0 N N N p0 Ly F„ L„ C„) U V CJ V V V CJ V C� V U V U U CJ CJ U ID N D ID co Ln v h z H Hr-4 R'N O _ �� aaaaaaaa � z 03 a a a a a a a a a a a a a a a a a a \ " Ln W O Ol 'S O .-I IO 0 LA ID M tp IO OL O w ry r N .+ O `1- � � G v y S p 14 Y ° N i o M � Ln '4) 5r C •�' di L' L" O O H H N N M M d' d' Ln M ID z N L" 00 W Cl m O 0 N A. 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