HomeMy WebLinkAbout; Two Retail Structures- Pad 4 and Pad 6; Geotechnical Investigation Report; 2005-04-05I
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Geotechnical Investigation Report
Two Retail Structures - Pad 4 and Pad 6
7190 Avenida Encinas
Carlsbad, California
Prepared For:
Mr. Clint Knox
Donahue Schriber Realty Group, Inc.
200 E. Baker Street, Suite 100
Costa Mesa, California 92626
Converse Project No. 05-32123-01
April 5, 2005
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Converse Consultants
" '^^j^^r ^v®'' Years of Dedication in Geotechnicai Engineering and Environmental Sciences
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April 5, 2005
Mr. Clint Knox
Donahue Schriber Realty Group, Inc.
200 E. Baker Street, Suite 100
Costa Mesa, Caiifornia 92626
Subject: GEOTECHNICAL INVESTIGATION REPORT
Two Retail Structures - Pad 4 and Pad 6
7190 Avenida Encinas
Carlsbad, California
Con verse Project No: 05-32123-01
Dear Mr. Knox:
Presented herein are the results of the geotechnical investigation performed by
Converse Consultants (Converse) for the two proposed retail structures at Pad 4 and
Pad 6, located at 7190 Avenida Encinas in Cadsbad, Caiifornia. This work was
performed in accordance with our proposal dated March 7, 2005, and your authorization
dated March 10, 2005.
Submittal of this report completes our scope of work for this project. Plan review,
representation at meetings, consultation, performance of any further studies required by
reviewing agencies, and subsequent earthwork observation and testing services are
beyond our current scope of work and would require separate contracts.
Thank you for the opportunity of working with you on this project. If there are any
questions, please call us at 714-444-9660. We look forward to assisting you during
construction.
Yours truly,
CONVERSE CONSULTANTS
William H. Chu, G.E.
Sr. Vice President/Principal Engineer
KN/klf
Dist: Addressee (4)
185 East Paularino Avenue, Suite B, Costa Mesa, California 92626
Telephone: (714) 444-9660 • Facsimile: (714) 444-9640 • e-mail: costamesa@converseconsultants.com
Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carlsbad, Caiifomla
March 5, 2005
Page ii
PROFESSIONAL CERTIFICATION
This report has been prepared by the staff of Converse Consultants (Converse) under
the professional supervision of the individuals whose seals and signatures appear
hereon.
The findings, recommendations, specifications or professional opinions contained in this
report were prepared in accordance with generally accepted professional engineering
and engineering geologic principles and practice in this area of California. There is no
warranty, either expressed or implied.
Krishnamenon Nadaraja, P.E.
Project Engineer ^-i^VroTT'^SK
Catm-ene Glick, C^.GytH.G. \ - \
Seriior Geologist/Hyd)^geologi'?t \ '
Converse Consultants
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Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carlsbad, Califomia
March 5, 2005
Page iii
TABLE OF CONTENTS
1.0 INTRODUCTION 1
2.0 PROJECT DESCRIPTION 1
3.0 PURPOSE OF STUDY 1
4.0 FIELD EXPLORATION AND LABORATORY TESTING 2
4.1 FIELD EXPLORATION 2
4.2 LABORATORY TESTING 2
5.0 SITE AND SUBSURFACE CONDITIONS 2
5.1 SITE DESCRIPTION 2
5.2 GEOLOGIC SETTING 2
5.2.1 SITE GEOLOGY 3
5.3 SUBSURFACE CONDITIONS 3
5.4 GROUNDWATER 4
6.0 FAULTING AND SEISMICITY 4
FAULTING 4
6.2 SEISMICITY 4
6.3 SEISMIC COEFFICIENTS 4
6.4 GEOLOGIC HAZARDS DUE TO SEISMIC ACTIVITIES 5
7.0 CONCLUSIONS AND RECOMMENDATIONS 6
7.1 GENERAL 6
7.2 DISCUSSION OF FOUNDATION ALTERNATIVES 7
7.3 SITE PREPARATION AND GRADING 8
7.4 TEMPORARY CONSTRUCTION SLOPE AND SHORING 9
7.5 FOUNDATION SUPPORT 10
7.5.1 SHALLOW FOUNDATION 10
7.5.2 DRILLED PILES 11
7.5.3 GEOPIER FOUNDATION 12
7.5.4 MAT FOUNDATION 13
7.5.5 FLOOR SLABS 13
7.5.6 CONCRETE FLATWORK 14
7.6 LATERAL LOADS 14
7.7 SURFACE DRAINAGE 15
7.8 UTILITIES 15
7.9 SOIL CORROSIVITY 15
7.10 PLAN REVIEW, OBSERVATIONS AND TESTING 16
8.0 CLOSURE 16
REFERENCES 17
FIGURE
FIGURE NO. 1 - SITE AND BORING LOCATION PLAN FOLLOWS PAGE 1
APPENDICES
APPENDIX A - FIELD EXPLORATION A-1 THROUGH A-5
APPENDIX B - LABORATORY TESTING B-1 THROUGH B-8
APPENDIX C - EARTHWORK SPECIFICATIONS C-1 THROUGH C-4
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Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carlsbad, Califomia
March 5, 2005
Page 1
1.0 INTRODUCTION
This report presents the results of our geotechnical investigation performed for the two
retail structures at Pad 4 and Pad 6, located at 7190 Avenida Encinas in the City of
Carlsbad, County of San Diego, California. The location ofthe project is shown on Figure
No. 1, Site and Boring Location Plan.
2.0 PROJECT DESCRIPTION
Based on the information provided to our office, it is our understanding that the project
sites (Pad 4 and Pad 6) are for a commercial/retail center and that two (2 single-story
retail structures will be constructed. The proposed structures at building pad 4 and pad
6 will have building footpnnts of approximately 5,800 and 5,000 square feet,
respectively.
A grading plan was not available at the time of our investigation. The structures will be
built essentially on/or near the existing surface. Although it appeared that the sites were
previously graded, we were not provided documentation forthe previous development.
3.0 PURPOSE OF STUDY
The purpose of this study was to: (1) obtain information on the subsurface conditions
within the proposed development area, (2) evaluate the data, and (3) provide
conclusions and recommendations for site grading, foundation design, and construction
ofthe proposed residential development as influenced bythe subsurface conditions.
To accomplish these objectives, we:
1. Collected and reviewed available geologic, boring, earthwork information, and
available project data.
2. Prepared a field exploration program.
3. Performed a site reconnaissance and located the borings in the field.
4. Acquired permit from the San Diego County, Department of Environmental
Health, Monitoring Well Program.
5. Engaged a drilling contractor to perform test borings, and logged the borings.
6. Backfilled the boreholes with bentonite chips and grout per SAM Manual.
7. Performed laboratory tests to aid in classification of the materials sampled and to
obtain data on their engineering properties.
8. Correlated, interpreted, analyzed, and evaluated the data obtained.
9. Prepared this report to present our conclusions and recommendations.
Converse Consultants
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Existing Chevron
Gas Station
LEGEND
8-4 INDICATES NUMBER AND
APPROXIMATE LOCATION
OF BORING
APPROXIMATE SCALE
i" = 120'
SITE AND BORING LOCATION PLAN
TWO RETAIL STRUCTURES
Carlsbad, California
For: Donahue Schriber Realty Group, Inc.
Project No.
05-32123-01
^7 r^»r.w»ro« r^»r.o..l«o»to Geotechnlcal Engineering
Converse Consultants and Applied sciences
Figure No.
1
Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carisbad. California
March 5, 2005
Page 2
4.0 FIELD EXPLORATION AND LABORATORY TESTING
4.1 Field Exploration
A total of four (4) test borings ( BH-1 through BH-4) were drilled on Pad 4 and Pad 6
(two (2) borings per site) on March 25 and March 28, 2005 at the locations shown on
Figure No. 1, Site and Boring Location Plan. The borings were drilled with a hollow-
stem auger drill rig to depths ranging from 2672 to 5172 feet below the existing grade.
Logs of the subsurface conditions, as encountered in the test borings, were recorded at
the time of drilling and are presented on the boring logs included in Appendix A, Field
Exploration. Relatively undisturbed nng samples and bulk samples of subsurface
matenals were obtained at frequent intervals below the ground surface and were taken
to the laboratory for classification and testing. In addition. Photo Ionization Detector
(PID) tests were performed on the cuttings to detect potential hydrocarbon
contamination. All borings were backfilled with bentonite chips and grout at the
completion of dniling and the drilled cuttings were drummed per our proposal.
A brief descnption of the drilling and sampling operation is included in Appendix A,
Field Exploration.
4.2 Laboratory Testing
Representative soil samples were tested in the laboratory to obtain engineering
properties of the subsurface soils. Laboratory tests included unit weight, moisture
content, maximum dry density and optimum moisture content, gradation, percent
passing the No. 200 sieve, direct shear, consolidation, expansion index, and corrosivity
(sulfate and chloride content, pH and electrical resistivity). Detailed descriptions of the
laboratory tests are presented in Appendix B, Laboratory Testing along with the
tabulated test results.
Soil samples will be discarded 30 days after the date of this report, unless this office
receives a specific request to retain the samples for a longer period of time.
5.0 SITE AND SUBSURFACE CONDITIONS
5.1 Site Description
The sites will consist of Pad 4 and Pad 6 with a floor area of 5800 square feet and 5000
square feet, respectively. At the time of our field investigation, the pads were vacant.
5.2 Geologic Setting
The project site lies along the central coastal margin of the Peninsular Ranges
Geomorphic Province of California. The Peninsular Ranges province is charactenzed by
northwest trending valleys and mountain ranges, which have formed in response to the
regional tectonic forces along the boundary between the Pacific and North American
tectonic plates. The geologic structure is dominated by northwest trending right-lateral
faults, most notable, the San Andreas Fault, San Jacinto Fault, Elsinore Fault and
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Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carisbad, California
March 5, 2005
Page 3
Newport-Inglewood Fault. This Province extends southward from the Transverse
Ranges at the north end of the Los Angeles basin to the southern tip of the Baja
California peninsula.
The coastal margin of the Peninsular Ranges has undergone coastal and marine
erosion during the past one million years (Holocene and Pleistocene Epochs). Marine
erosion and wave action has cut terraces into the coastal margin. During the final
Pleistocene glacial stage (about 14 to 16 thousand years ago), the sea level was
lowered about 200-300 feet. This forced streams crossing the terraces to cut deep
gullies and canyons into the terrace platforms and readjust to the new base sea levels.
The amount of down cutting and width of the channel or valley was dependent on the
size of the stream tributary or river. As the continental ice sheets melted and the
postglacial sea levels rose, the lower ends of the channels and valleys were flooded by
the rising ocean and filled with sediments from stream deposition and shoreline
processes. The channels mouths were gradually filled along the coastline with
continental alluvial deposits to form the present day estuaries and partially filled channel
features.
The project site is not located within a currently designated State of California
Earthquake Fault-Rupture Hazard Zone. No faults with evidence of surface rupture are
known to project through or towards the project site. The site is located along the
coastal margin between the active Elsinore Fault and the offshore Newport-Inglewood
Fault.
5.2.1 Site Geology
The project site is underlain by up to 1,500 feet of Holocene, interbedded marine and
non-manne sand and gravel sediments with thin interstitial sandy- to silty clay lenses
typical of Point Loma Formation. A thick section of non-marine sedimentary rocks,
interbedded cobble, conglomerates and Sandstone lenses ranging in age from Pliocene
to Cretaceous, underties the site at depth.
The soil borings advanced for this project encountered interbedded sand and clayey
sand sequences to the extent drilled (5iy2-feet below ground surface) which are typical
ofthe Point Loma Formation sediments previously described.
5.3 Subsurface Conditions
In our recent exploration, fill was encountered up to five (5) feet and seven (7) feet in our
borings at the site for Pad 6 and Pad 4, respectively. The fill is likely to be associated with
the previous grading, however we were not provided the documentation related to the
previous development. At this time we will consider this fill as undocumented fill material
consisting of sands, clayey and silty sands. The fill materials are underlain by native soils
to the maximum explored depth of 5172 feet below existing ground surface. The native
soils are composed of mainly sands, silty and clayey sands and clay. The near surface
soils have a very low expansion potential and are not sensitive to moisture variation,
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Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carisbad, California
March 5, 2005
Page 4
5.4 Groundwater
Groundwater was encountered in all of the borings between 20 and 21 feet below the
existing ground surface at the end of drilling. Based on our review of available
groundwater data, high groundwater could be within 10 feet of the existing grade. It
should be noted that the depths to groundwater could vary depending upon season,
precipitation, and possible groundwater pumping activity in the vicinity.
6.0 FAULTING AND SEISMICITY
Faulting
Based on our review of the available information, there are no known active faults
projecting toward or extending across the project site. An active fault is defined as one
that has surface displacement within Holocene time (about the last 11,000 years). The
site is not situated within a currently designated State of California Earthquake Fault
Zone.
The nearest known active faults are the Rose Canyon fault located about 5 miles
southwest of the site. The Newport Inglewood (offshore) and Coronado Bank faults are
located approximately 6.5 miles and 21.5 miles, respectively, northwest ofthe site.
6.2 Seismicity
The site for two retail structures is situated in a seismically active region. As is the case
for most areas of southern California, ground-shaking resulting from earthquakes
associated with both nearby and more distant faults is likely to occur. During the life of
the project, seismic activity associated with active faults in the area may generate
moderate to strong ground shaking at the site.
Earthquake intensities will vary throughout southern California, depending upon the
magnitude of the earthquake, the distance from the active fault, and the type of material
underiying the site. The site will probably be subjected to at least one moderate to
severe earthquake during the next 50 years that will cause strong ground shaking.
Based on our evaluation, the site could be subjected to an average peak ground
acceleration of approximately 0.35g with a 10 percent probability of exceedance in 50
years, based on attenuation relationships by Campbell & Bozorgnia (1997), Joyner &
Boore (1997), and Sadigh et al. (1997).
6.3 Seismic Coefficients
Based on the results of our borings and laboratory testing, and in accordance with the
1997 Uniform Building Code (UBC)/2001 California Building Code (CBC), the site
should be considered as having a So soil profile. The site is located within Seismic
Zone 4 in accordance with the UBC/CBC. The following seismic coefficients are
considered appropriate for analysis:
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Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carisbad, California
March 5, 2005
Page 5
Seismic Zone Factor, Z 0.40
Soil Profile Type So
Seismic Source Type B
Seismic Coefficient, Na 1.0
Seismic Coefficient, Nv 1.2
Seismic Coefficient, Cg 0.44 Na
Seismic Coefficient, Cv 0.64 Nv
6.4 Geologic Hazards Due to Seismic Activities
Historical evidence and current technology indicate that at least one moderate to severe
earthquake will occur during the design life of the site. During a moderate to severe
earthquake occurring on the nearby faults, strong ground shaking of the project site will
probably occur. In addition to ground shaking, effects of seismic activity on a project site
may include surface fault rupture, soil liquefaction, and seismically induced differential
settlement of structures, ground lurching, land sliding, lateral spreading, earthquake-
induced flooding, seiches, and tsunamis. Results of a site-specific evaluation of each of
the above possible secondary effects are explained below:
Surface Fault Rupture
The project site is not located within a currently designated State of California
Earthquake Fault Zone. Based on our review of existing geologic information, no known
major surface fault crosses through or extends towards the site. The potential for
surface rupture resulting from the movement of a previously unrecognized fault is not
known with certainty but is considered low.
Liquefaction Potential
Soil liquefaction is a phenomenon that occurs when saturated cohesionless soil layers,
located within about 50 feet of the ground surface, lose strength during cyclic loading,
as caused by earthquakes. During the loss of strength, the soil acquires "mobility"
sufficient to permit both horizontal and vertical movements. Soils that are most
susceptible to liquefaction are clean, loose, saturated, and uniformly graded, fine-
grained sands that lie below the groundwater table within a depth usually considered to
be about 50 feet. The factors known to influence liquefaction potential include soil type
and depth, grain size, density, groundwater level, degree of saturation, and both the
intensity and duration of ground shaking.
Based on our recent subsurface exploration, the subsurface soils to a depths of about
5172 feet consist of predominantly dense to very dense sand, clayey and silty sand, and
very stiff clay. It is our opinion that the potential for liquefaction of the dense to very
dense sandy soils below historical high ground water (within 10 feet) at the site is very low.
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Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Cartsbad, Caiifornia
March 5, 2005
Page 6
Landslides
Seismically induced landslides and other slope failures are common occurrences in
areas of significant ground slopes during or soon after earthquakes. The site is
relatively flat therefore there is no potential for seismically induced landslides affecting
the site.
Lateral Spreading
Seismically induced lateral spreading involves lateral movement of earth materials due
to ground shaking. It differs from a slope failure in that ground failure involving a large
movement does not occur due to the flatter slope of the initial ground surface. Lateral
spreading is characterized by near-vertical cracks with predominantly horizontal
movement of the soil mass involved over the liquefied soils. The potential for lateral
spreading at the subject site is considered low.
Differential Settlement Due to Seismic Shaking
The potential of differential settlement due to seismic shaking exists forthe sandy layers
that are potentially liquefiable. Based on our review, site soils are not prone to
liquefaction thus, liquefaction-induced settlement and with differential seismic settlement
is very low.
Tsunamis
Tsunamis are tidal waves generated in large bodies of water by fault displacement or
major ground movement. The site is within a mile from the Pacific Ocean. Based on
the site location and elevation there is a low to moderate risk of tsunamis at this site.
Seiches
Seiches are large waves generated in enclosed bodies of water in response to ground
shaking. Based on our review, no significant dams or other enclosed bodies of water
are present in the vicinity of the site. It is our opinion that the potential for damage due
to seiches is considered low.
Earthquake-Induced Flooding
Flooding may be caused by failure of dams or other water retaining structures due to
earthquake. Based on our review, no significant dams or other enclosed bodies of
water are present in the vicinity of the site. The potential for earthquake-induced
flooding is considered low.
7.0 CONCLUSIONS AND RECOMMENDATIONS
7.1 General
Based on the results of our field and laboratory exploration, in conjunction with
engineering analysis and our experience and judgment, it is our professional opinion
that the sites for Pad 4 and Pad 6 are suitable for the proposed retail structures from a
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Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carisbad, Califomia
March 5, 2005
Page 7
geotechnical engineering standpoint provided that the recommendations presented
herein are incorporated in the design and construction of the project.
The primary geotechnical considerations for foundation design are as follows:
Undocumented Fill:
Up to a depth of 5 feet and 7 feet of fill encountered in the vicinity of Pad 6 and Pad 4,
respectively. No documentation was available at the time of this report to verify that the
fill was placed in accordance with engineering standards. Based on dry density tests,
and laboratory maximum dry density and optimum moisture content test results, the
relative compaction of the fill was found to be about 90 percent or above except for the
sample taken at 5 feet at boring BH-4. The non-uniform nature ofthe fill is considered to
have the potential to experience detrimental differential settlement.
Unless this office verifies the fill uniformity by performing a series of density tests in
selected test pits for every 15 feet grid, along with the Cone Penetrometer Testing
(CPT), the fill will be considered as undocumented fill and not acceptable for foundation
support. This potential future investigation is beyond our scope and current contract and
it is not guarantied that fill soils can be acceptable at the end ofthe investigation.
The undocumented fill material is not suitable for foundation support without some form
of ground improvement. The structures should be supported on either a shallow
foundation system founded on improved soils/engineered fill or a deep foundation.
7.2 Discussion of Foundation Alternatives
Several alternatives were evaluated for foundation support of the structures. The
selected alternatives should be based on effectiveness of the system and economics.
The alternatives are presented below:
Conventional Footing with Fill Removal and Replacement:
To minimize the potential of the structures undergoing adverse settlements due to the
non-uniformity of the near surface soils, we recommend that all fill and the upper soils
within the footprint of the proposed building be entirely removed and replaced as
compacted fill. This compacted fill should extend a minimum of two (2) feet below the
bottom of all footings and slabs. The removal and re-compaction should extend at least
five (5) feet beyond the limits of the building and appendages. The building may then be
supported on conventional shallow spread and continuous footings founded on the
compacted fill.
The removal and total replacement of the undocumented fill is feasible and typically cost
effective when fill thickness limited to be less than 8 feet.
Drilled Piles:
Drilled piles can be used as an alternate foundation system to support the proposed
structure. Drilled piles are typically not considered ideally suitable in areas with
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Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carisbad, California
March 5, 2005
Page 8
groundwater and the potential for caving soils conditions. For drilled piles to be properly
installed, the use of bentonite slurry is required to stabilize the hole below the
groundwater level. In addition, concrete should be placed by pump with the tremie
method.
Geopier Foundation System:
As an alternative, a Geopier foundation system may be used to improve and reinforce
the undocumented fill to support the slabs and footings. Geopier elements are relatively
small diameter holes and the high frequency impact energy does not cause resonant
action in soils, as does pile driving, since soils have a natural low frequency.
A Geopier foundation system is a practical refinement to the traditional over excavation
and replacement method by strengthening and selectively removing the subsoils for
settlement control and bearing capacity improvements. The Geopier support is
constructed by drilling a limited depth shaft, by removing a volume of
compressible/loose subsoil materials, then installing a bottom bulb of clean, open-
graded stone while vertically prestressing and prestraining the subsoils beneath the
bottom bulb. The Geopier shaft is built on top of the bottom bulb, using well-graded
highway base course placed in thin lifts (12 inches compacted thickness). Densification
of the bottom bulb and the shaft fill is accomplished by using the impact ramming action
of a modified hydraulic hammer/tamper. The tamper consists of a special steel alloy
shaft and a round beveled tamper head. The beveled tamper head assists in
transferring force vertically and laterally during impact densification, resulting in pushing
of aggregate against the confined walls of the cavity. In addition to increasing shear
resistance at the Geopier element perimeter, the increased horizontal stress in the
matrix soil improves the composite material and makes it stiffer.
Mat Foundation:
As an alternative to the complete removal and replacement, mat foundation in
conjunction with limited removal and re-compaction of the undocumented fill may be
used to support the structures associated with the expansion. We recommend that the
existing fill beneath the mat foundation be removed to a depth of three (3) feet and be
re-compacted. In addition, the compacted fill should be underiain by a layer of
geosynthetic fabric to provide additional tensile reinforcement. Mat foundation is a more
rigid system and is capable of spanning pockets/cavities associated with compression
of the underiying undocumented fill or seismically induced settlement.
7.3 Site Preparation and Grading
The locations of the proposed structures should be cleared of all surface items, near
surface disturbed soil, highly organic topsoil, deleterious materials, vegetation and
utilities. For structures to be supported by mat foundation, a minimum removal and re-
compaction of four (4) feet below the mat should be provided. The removal and re-
compaction should extend at least five (5) feet beyond the limits (or to the extent
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Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carisbad, California
March 5, 2005
Page 9
possible) of the foundation. For concrete flatwork, driveway, parking, and for minor non-
load bearing structures, a minimum of 12 inches of removal and re-compaction is
recommended. The actual depth of removal and re-compaction should be determined in
the field by the geotechnical engineer at the time of construction. Fill for the building
pad should not contain rocks or lumps larger than three inches.
Additional excavation may be necessary if any disturbed soil or other unsuitable
deposits are exposed. We recommend that the exposed surface be scarified to a
minimum depth of six (6) inches and be compacted to a minimum density of 90 percent
relative compaction as determined by ASTM Designation Dl 557-00.
The excavated on-site soils may be reused as compacted fill provided they are free of
deleterious substances, and are relatively free of the cobble and boulder size particles
discussed above. Any soils imported from off-site sources for use within the structure
areas and to five (5) feet beyond the building limits should be non-expansive with an
expansion index of less than 20, and be approved by the geotechnical engineer prior to
placement.
Acceptable fill material should be placed in lifts not exceeding eight (8) inches in
thickness when loose and should be properly compacted to at least 90 percent of the
maximum dry density as determined by ASTM Test Method Dl 557-00. On-site
materials should be compacted with the water content at, or within two (2) percent of the
optimum as determined from ASTM Test Method D1557-00. The placement and
compaction of all fill should be performed under the observation and testing of Converse
Consultant's representative.
Shrinkage is the loss of soil volume caused by compaction of the soil to a density
greater than before grading. For an earthwork volume estimate, a shrinkage value on
the order of 10 to 15 percent may be assumed for the near surface soils.
7.4 Temporary Construction Slope and Shoring
Based on our borings, the over excavation forthe grading operation, in our opinion, may
be accomplished with conventional excavation equipment. The excavations are not
expected to stand vertically for any extended period of time, and all excavations must
be sloped or shored. Where sufficient space is available for a sloped excavation, the
excavations in the medium dense sand deposits should be sloped no steeper than 1:1
(horizontal to vertical). The exposed slope faces should be kept moist and not allowed
to dry out. The Table No.l, Slope Ratio for Temporary Excavations may be used for
temporary open cut trenches or excavations. Temporary cuts encountering soft and wet
fine-grained soils; dry cohesionless soils or loose fill may have to be constructed at a
flatter gradient than presented below.
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Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carisbad, California
March 5, 2005
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Table No. 1, Slope Ratios for Temporary Excavations
Depth of Cut Recommended Maximum Slope (Horizontal: Vertical)^
0-3 Vertical
3-5 0.5:1 i
5-7 1:1
7-12 1.5:1
^Slope ratio assumed to be uniform from top to toe of slope.
For steeper temporary construction slopes or deeper excavations, or unsuitable soil
encountered during the excavation, shoring should be provided by the contractor, as
necessary, to protect the workers in the excavation.
Surcharge loads should not be permitted within five feet from the top of the slopes,
unless the cut is properiy shored. The contractor should be aware that neither slope
height, slope inclination, nor excavation depths should exceed those specified in local,
state or federal safety regulations, e.g. OSHA Health and Safety Standards for
Excavations, 29 CFR Part 1926, or successor regulations. Such regulations are strictly
enforced and, if violated, the owner and/or the contractor could be liable for substantial
penalties.
Construction of open cuts adjacent to existing structures, including underground pipes,
is not recommended within a 1:1 (horizontal: vertical) plane extending beyond and down
from the perimeter of the structure. Cuts that are proposed within five (5) feet of light
standards, other utilities, underground structures and pavement should be provided with
temporary shoring. For excavations extending to a depth more than 20 feet, OSHA
requires the side slopes and shoring for such excavations be designed by a
professional engineer registered in the State of California.
It is important to note that soil and groundwater conditions may vary significantly within
the footprint of the expansion. Our preliminary soil classifications are based solely on
the materials encountered at the actual boring locations. The contractor should verify
that similar conditions exist throughout the proposed area of excavation. If different
subsurface conditions are encountered at the time of construction, we recommend that
our office be contacted immediately to evaluate the conditions encountered.
7.5 Foundation Support
7.5.1 Shallow Foundation
The proposed building may be supported on continuous or isolated spread footings
founded on at least two (2) feet of compacted fill. All continuous interior and isolated
spread footings should be founded at least 24 inches below the lowest adjacent final
grade and should be at least 18 inches wide. Continuous perimeter footings should be
Converse Consultants
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Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carisbad, California
March 5, 2005
Page 11
at least 18 inches wide and 24 inches below the finished subgrade. Footing design may
be based on a maximum allowable net bearing value of 2,000 psf for continuous and
isolated spread footings. This value may be increased by 33 percent for transient wind
and seismic forces.
Based on anticipated loads, total and differential settlement of the structure designed in
accordance with the recommendations provided in this report is expected to be within
tolerable limits for this type of construction. For example, settlement of a five (5) foot
square footing is expected to be within 72 inch, with differential settiement between
footings to be within 7 inch. Most of the settlement is expected to occur during
construction.
7.5.2 Drilled Piles
Drilled pile is another alternative foundation system and the piles deriving their
capacities primarily from the native soils about 5 feet below the existing grade. We
recommend that the grade beam, footings, and slab be supported on the piles if piling is
the selected alternate. The allowable design capacities for recommended minimum pile
length of 15 feet for 18-inch and 24-inch diameter piles are 30 kips, and 40 kips
respectively.
The capacities were computed by using a safety factor of three (3) and two (2) for end
bearing and skin friction, respectively. The settlement of a single pile is expected to be
about one-fourth (7) inch. The vertical capacities above may be increased by 33
percent to resist transient downward vertical loads, such as wind forces or seismic
shaking. Pile uplift design capacities may be taken as 50 percent of the vertical
downward pile design values shown.
The center-to-center spacing between piles should not be less than three (3) times the
pile diameter. Allowable axial loads of pile groups with center-to-center pile spacing of
less than three (3) pile diameters should be determined by incorporating an efficiency
reduction factor to the allowable axial loads for single piles.
To maintain the stability of the borehole for the drilled pile, the use of bentonite slurry is
recommended below the groundwater table while advancing the excavation to the final
depth. Drilled pile excavations should be filled with concrete on the same day they are
drilled. The drilling for piles should not be performed adjacent to recently excavated or
recently poured piles until the concrete in the completed piles has been allowed to set
for several hours. In addition, the piles should also be poured in a manner that will not
result in concrete flowing into adjacent open pile excavations. Piles in groups should be
drilled and poured in an alternating sequence to minimize the potential for fresh
concrete flowing into adjacent open pile excavations.
The placement of reinforcement and concreting operations should conform to ACI and
other applicable code requirements. Concrete placement should be continuous from
the bottom to the top of the drilled pile. Concrete placement should continue after the
Converse Consultants
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Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carisbad, California
March 5, 2005
Page 12
borehole is filled until good quality concrete is evident at the top of the shaft. Concrete
should be placed through a tremie or pump system and the discharge end of the
tremie/orifice should be immersed at least 5 feet in concrete at all times after the start of
the concrete flow. In addition, the level of concrete in the tremie should be maintained
above the level of slurry in the borehole at all times to prevent slurry intrusion into the
shaft concrete.
We recommend that the installation of the drilled piles be performed with the
obsen/ation of Converse Consultants.
7.5.3 Geopier Foundation
As an alternative to the piling system, the structures associated with the expansion may
be supported on shallow footings or mat foundation founded on a Geopier foundation
system.
Geopier elements should be designed and installed by a licensed Geopier foundation
installer. The design of the Geopier system should be reviewed by Converse and
installed under our observation. The design should meet the following:
• Maximum overall post-improvement settlement = Vz inch
• Maximum post-improvement differential settlement = 7 inch per 100 feet
• Minimum composite allowable bearing pressure = 3,000 pounds per square foot
(Min F.S. = 3.0).
• Minimum Geopier diameter = two (2) feet
• Minimum Geopier length = 10 ft.
• Minimum Geopier element stiffness = 250 pci.
• Minimum uplift capacity per geopier = 40 kips
For uplift application, the geopier element should be structurally connected to the
footing by means of steel rebar.
Proof of the effectiveness of the Geopier system is typically provided by a full-scale
Geopier Modulus Load Test on site to verify design assumptions and uplift capacity.
The test provides a conservative measure of the stiffness of the Geopier element and
will help establish installation procedures forthe project.
Continuous and isolated spread footings should be founded at least 24 inches below the
lowest adjacent final grade and should be at least 24 inches wide. Footing design may
be based on a maximum composite allowable net bearing value of 3,000 psf for
continuous and isolated spread footings. This value may be increased by 33 percent for
transient wind and seismic forces. For mat foundation supported on the geopier
element, a maximum composite allowable net bearing value of 2,000 psf can be used.
In addition, a modulus of subgrade reaction between 150 to 200 pounds per square inch
per inch can be used forthe design ofthe mat.
Converse Consultants
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Geotechnical Investigation Report
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7190 Avenida Encinas
Carisbad, California
March 5, 2005
Page 13
Based on anticipated loads, total and differential settlement ofthe structure designed in
accordance with the recommendations provided in this report is expected to be within
tolerable limits for this type of construction. Most of the settlement is expected to occur
during construction.
If a Geopier system is considered, we recommend that the local Geopier installer in
southern California be contacted to review and analyze the subsurface data in this
report to provide a preliminary design, cost and time estimate.
The information forthe installer is as follows:
Geopier Foundation Company - West
570 Giotto, Irvine, CA 92614
Tel: 949-387-8863, Fax: 949-387-7772
Attn: Mr. Ken Hoevelkamp
We recommend that the Geopier installer's operations be monitored by Converse full-
time as a Quality Assurance service to supplement the installer's internal Quality
Control (QC) program. The QC program will monitor drill depths, Geopier element
lengths, average lift thicknesses, installation, aggregate quality, and densification of lifts.
These items will be documented for each Geopier element installed to provide a
complete installation report.
7.5.4 Mat Foundation
As another alternate to the piling and geopier foundation system, the structures may be
supported on a reinforced mat foundation bearing on a layer of compacted fill. The mat
may be designed for a net bearing pressure of 1,500 psf for combined dead plus live
loads with one-third increase for all loads including wind or seismic. The total static
settlements ofthe structural slab underthe anticipated structural loads and the potential
settlement due to compression of the underiying undocumented fill settlement is
estimated to be about one (1) inchs with differential settlement on the order of about 72-
inche. In addition, a modulus of subgrade reaction of between 150 pounds per square
inch per inch can be used for the design of the mat.
Mat foundation may be supported on at least three (3) feet of properiy compacted fill.
We recommend that a layer of geotextile reinforcing fabric such as Mirafi HP570 be
placed on the subgrade to provide additional tensile reinforcement against potential
compression of the underiying fill prior to replacement of the upper fill.
7.5.5 Floor Slabs
If slab is used for the building, we recommend that the slab be supported on at least
three (3) feet of properiy compacted fill or the piles or be reinforced with the Geopier
element. Slabs supported on piles or the Geopiers element must be adequately
reinforced in both directions or sectionalized with structural separations to control
cracking.
Converse Consultants
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7190 Avenida Encinas
Carisbad, California
March 5, 2005
Page 14
If migration of moisture through the slab is undesirable, we recommend that a moisture
barrier such as an 8-mil polyethylene sheet be used under new slabs. The moisture
barrier should be covered with two (2) inches of coarse sand to facilitate concrete curing
and to protect the polyethylene sheet.
Adequate provisions should be made to limit and/or prevent moisture content changes
in the subgrade beneath slabs. These include: positive drainage away from building
foundations with a minimum gradient of two (2) percent; impervious cut-off barriers
along exterior walls adjacent to landscape planters; and properiy sealed joints for
interior piping beneath interior and exterior slab areas. The cut-off barrier can consist of
"thickened edge" at least 12-inches wide along the perimeter ofthe slabs.
7.5.6 Concrete Flatwork
All exterior slabs and concrete flatwork including the sidewalks should be supported
directly on at least 12 inches of properiy compacted fill. We recommend that concrete
slabs be at least six inches thick and be properiy reinforced in accordance with the
structural requirements.
7.6 Lateral Loads
Resistance to lateral loads can be assumed to be provided by passive earth pressure
and by friction acting on structural components in permanent contact with the subgrade
soils, by the pile caps, and by the lateral resistance ofthe piles.
Passive earth pressure on the sides of footings, grade beams or pile caps may be
assumed equal to that exerted by an equivalent fluid weighing 275 pcf, subject to a
maximum pressure of 2,000 psf A coefficient of friction of 0.40 may be assumed with
dead load forces of slab-on-grade/mat in permanent contact with subgrade soils. A
friction factor of 0.3 is considered appropriate for concrete slabs underiain by a moisture
barrier. No friction is allowed for pile supported structural components, or footing
supported structural slabs.
Lateral Load design criteria for auger pressure grouted pile are presented below:
Recommended Pile Design Parameters for Lateral Loads
FIXED-HEAD DIMENSION
18-in 24-in
Maximum All. Lateral Load Capacity (kips) 21 37
Maximum Negative Moment (kip-ft) 115 250
Maximum Positive Moment (kip-ft) 36 73
Depth to Maximum Negative Moment (ft) 0 0
Depth to Maximum Positive Moment (ft) 10 12
First Point of Zero Lateral Displacement (ft) 16 18
Depths to Zero Moments (ft) 5.5 & 20 7.0 & 25
Converse Consultants
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Geotechnical Investigation Report
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7190 Avenida Encinas
Carisbad, Califomia
March 5, 2005
Page 15
7.7 Surface Drainage
Positive surface drainage should be provided adjacent to the structures to direct surface
water away from the foundations and slabs toward suitable discharge facilities. Ponding
of surface water should not be allowed adjacent to the structure or on flatwork.
Landscaped areas should be designed with a minimum slope of two (2) percent.
Desirable slopes in paved areas are at least one (1) percent.
7.8 Utilities
The on-site soils are suitable for backfill of utility trenches from one foot above the top of
the pipe to the surface, provided the material is free of organic matter and deleterious
substances.
It is anticipated that the natural soils will provide a firm foundation for site utilities. Any
soft and/or unstable material encountered at the pipe invert should be removed and
replaced with an adequate bedding material.
The on-site soils are not considered suitable for bedding or shading of utilities.
Therefore, we recommend that non-expansive granular soils with a Sand Equivalent
(SE) greater than 30 as determined by ASTM Test Method D2419-91 be imported for
that purpose. Trench backfill soils should be compacted to at least 90 percent of the
maximum dry density as determined by ASTM Test Method Dl 557-00.
7.9 Soil Corrosivity
Soluble sulfates and soil corrosivity tests were performed by EGL Inc. Test Laboratory,
Santa Fe Springs, California on selected samples of soils encountered in the borings.
The results are presented in Appendix C and summarized herein. The pH of the soils
was 6.8, which is neutral. The soil sulfates content 0.006 percentage by weight, which
is negligibly corrosive to concrete. Accordingly, Type I or II Portland cement can be
used.
The chloride content of the soil samples tested was 105 ppm, and the resistivity
(saturated) of the soil tested 2,400 ohm-cm indicate the soils are corrosive to buried
ferrous metals in contact with these soils. Therefore, corrosion mitigation measures are
considered appropriate which may include the following:
• All steel and wire concrete reinforcement should have at least three (3) inches of
concrete cover where cast against soil, unformed.
• Below-grade ferrous metals should be given a high-quality protective coating,
such as 18-mil plastic tape, extruded polyethylene, coal-tar enamel, or Portland
cement mortar.
• Below-grade metals should be electrically insulated (isolated) from above-grade
metals by means of dielectric fittings in ferrous utilities and/or exposed metal
structures breaking grade.
Converse Consultants
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Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carisbad, California
March 5, 2005
Page 16
• If a more specific recommendations are needed a Corrosion Engineer should be
contacted.
7.10 Plan Review, Observations and Testing
As the final project plans and specifications are completed, they should be fon^/arded to
Converse for review for conformance with the intent of these recommendations. All
excavation and the placement and compaction of backfill should be performed under
the observation of and testing by Converse. All structure backfill and excavations
should be obsen/ed prior to placing the bedding material to verify that pipe bedding
materials and any structures, are founded on satisfactory soils, and that the excavations
are free of loose and disturbed materials.
8.0 CLOSURE
This report has been prepared for the exclusive use of Donahue Schriber and their,
consultants to assist in the design and construction of the proposed retail structures.
Any reliance on this report by third parties shall be at third party's sole risk. Our
sen/ices have been performed in accordance with applicable state and local ordinances,
and generally accepted practices within our profession.
Converse is not responsible or liable for any claims or damages associated with
interpretation of available information provided by others. Site exploration identifies
actual soil conditions only at those points where samples are taken, when they are
taken. Data derived through sampling and analytical testing are extrapolated by
Converse employees who render an opinion about the overall soil conditions. Actual
conditions in areas not sampled may differ. In the event that changes to the property
occur, or additional, relevant information about the property is brought to our attention,
the recommendations contained in this report may not be valid unless these changes
and additional relevant information are reviewed and the recommendations ofthis report
are modified or verified in writing.
Our findings and recommendations were obtained in accordance with generally
accepted professional principles practiced in geotechnical engineering. We make no
other warranty, either express or implied.
Converse Consultants
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7190 Avenida Encinas
Carisbad, California
March 5, 2005
Page 17
REFERENCES
BLAKE, T. F., 2000, EQSEARCH, FRISKSP, Version 3.0, computer programs for
performing deterministic and historical seismic hazard analysis.
CALIFORNIA DIVISION OF MINES AND GEOLOGY (1994), Fault Activity Map of
California and Adjacent Areas, DMG Geologic Data Map No. 6.
CALIFORNIA BUILDING STANDARDS COMMISSION (2001), California Building Code
(CBC).
INTERNATIONAL CONFERENCE OF BUILDING OFFICIAL (1997), Uniform Building
Code (UBC).
NAVFAC (1986), Design Manual 7.02: Foundation and Earth Structures.
STANDARD SPECIFICATIONS FOR PUBLIC WORKS CONSTRUCTION (2003), Joint
Committee ofthe Southern California Chapter, American Public Works Association
and Southern California Districts Associated General Contractors of California.
UNITED STATES GEOLOGICAL SURVEY (USGS), 2001; Groundwater Levels for
California.
Converse Consultants
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A
P
P
E
N
D
I
X
A
APPENDIX A
FIELD EXPLORATION
Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carisbad, Califomia
March 5, 2005
Page A-1
APPENDIXA
FIELD EXPLORATION
Our field investigation included a site reconnaissance of the property and a subsurface
exploration program consisting of drilling test borings. During the site reconnaissance,
the surface conditions were noted and the locations of the test borings were
determined. The test borings were located by pacing with existing topography and
boundary features, and should be considered accurate only to the degree implied by the
method used.
The test borings were advanced using a truck-mounted rig equipped with eight-inch
diameter hollow-stem auger for soil sampling. A total of four (4) borings (BH-1 through
BH-4)were drilled on March 25 and 28, 2005 to depths ranging from 2172 and 5172 feet.
Two borings were drilled on each pad. Soils encountered in the borings were logged by
our field engineer and geologist and classified in the field by visual examination in
accordance with the Unified Soil Classification System. The field descriptions have been
modified where appropriate to reflect laboratory test results.
Relatively undisturbed ring samples and bulk samples of the subsurface soils were
obtained at frequent intervals in the borings. The relatively undisturbed samples were
obtained using a California Drive Sampler (2.4-inch inside diameter [I.D.], 3.0-inch
outside diameter [O.D.]) lined with thin sample rings, and disturbed (bulk) samples were
obtained using a split spoon sampler (178-inch I.D. and 2-inch O.D). Both sampler types
are indicated in the "drive samples" column of the boring logs as presented in this
appendix.
Resistance and Standard Penetration Test (SPT) blow counts were obtained with the
sampler by dropping a 140-pound automatic hammer through a 30-inch free fall. The
sampler was driven 18 inches, and the number of blows were recorded for each six (6)
inches of penetration. The blows per foot was recorded on the boring logs represent
the accumulated number of blows required for the last 12 inches, or shorter distance as
indicated when refusal was encountered. The Standard Penetration tests were
performed in accordance with ASTM Standard Dl 586-84 test method.
For a key to soil symbols and terminology used in the boring logs, refer to Drawing No.
A-1, Unified Soil Classification and Key to Boring Log Symbols. For logs of the borings,
see Drawing Nos. A-2 and A-5, Log of Boring.
Converse Consultants
M:\JOBFILE\2005\32\05-123 DONAHUESCHRIBER\05-32123-01-GIR.DOC
APPENDIX B
SUMMARY OF LABORATORY TEST RESULTS
SOIL CLASSIFICATION CHART
MAJOR DIVISIONS
COARSE
GRAINED
SOILS
MORE THAN 50% 01
^MTERIAL IS
LARGER THAN NO
200 SIEVE SIZE
GRAVEL
AND
GRAVELLY
SOILS
MORE THAN 50% OF
COARSE FRACTION
RETAINED ON NO 4
SIEVE
SAND
AND
SANDY
SOILS
MORE THAN 50% OF
COARSE FRACTION
PASSING ON NO. 4
SIEVE
CLEAN
GRAVELS
(LITTLE OH NO FINES) l=-r \ o U
GRAVELS
WITH
FINES
(APPRECIABLE AMOUNT OF FINES)
CLEAN
SANDS
ILITTLE OB NO FINES)
SYMBOLS
GRAPH
SANDS WITH
FINES
(APPRECIABLE AMOUNT
OF FINES)
LETTER
GW
GP
GM
TYPICAL
DESCRIPTIONS
WELL-GRACED GRAVELS,
jRAVEL - SANO MIXTURES.
LITTLE OR NO FINES
^OOHLY-GRADED GRAVELS,
GRAVEL • SAND MIXTURES, LITTLE OH NO FINES
GC
SW
SP
SM
SC
SILTY GRAVELS, GRAVEL - SANO
- SILT MIXTURES
CLAYEY GRAVELS. GRAVEL -
SAND-CUVY MIXTURES
WELL-GRADED SANDS.
GRAVELLY SANOS, LITTLE
OR NO FINES
POORLY-GRADED SANOS,
GRAVELLY SANO, LITTLE OR
NO FINES
StLTY SANOS, SANO - SILT
MIXTURES
CUYEY SANOS, SANO - CLAY
MIXTURES
ML
INORGANIC SILTS AND VERV
FINE SANOS, HOCK FLOUR,
SILTY OR CLAYEY FINE
SANOS OR CLAYEY SILTS
WITH gi ir.UT PI tgTiriTv
FINE
GRAINED
SOILS
MORE THAN 50% OF
MATERIAL IS
SMALLER THAN NO.
200 SIEVE SIZE
SILTS AND
CLAYS LIQUID LIMITLESS
THAN 50
CL
INORGANIC CLAYS OF LOW/ TO
MEDIUM PLASTICITY.
GRAVELLY CLAYS. SANOY
CLAYS, SILTY CUVYS, LEAN
CLllS
OL ORGANIC SILTS ANO ORGANIC
SILTY CUYS OF LOW
PLASTICITY
SILTS AND
CLAYS LIQUID UMIT
GREATER THAN 50
MH INORGANIC SILTS, MICACEOUS
OR DIATOMACEOUS FINE
SANO OR SILTY SOILS
CH INORGANIC CLAYS OF HIGH
PLASTICITY
OH ORGANIC CLAYS OF MEDIUM TO
HIGH PLASTICITY, ORGANIC
SILTS
HIGHLY ORGANIC SOILS PT PEAT HUMUS, SWAMP SOILS
WITH HIGH ORGANIC
CONTENTS
NOTE: DUAL SYMBOLS ARE USEO TO INDICATE BORDERLINE SOIL CLASSIFICATIONS
BORING LOG SYMBOLS
•
SAMPLE TYPE
STANDARO PENETRATION TEST
Split barrel sampler in accordance with
ASTM 0-1586-84 Standard Test Method
DRIVE SAMPLE 2.42" I D. sampler, driven
with 140 Ib weight, 30 m. drop
DRIVE SAMPLE No recovery
BULK SAMPLE
GROUNDWATER WHILE DRILLING
GROUNDWATER AFTER DRILLING
UBORATORY TESTING ABBREVIATIONS
TEST TYPE STRENGTH
(Results shown in Appendix B) Pocket Penetrometer
Direct Shear P ds Direct Shear (singli point) ds-
CLASSIFICATION Unconfined Compression
Triaxial Compression
UC
tx Plasticity pi Vane Shear vs Grain Size Analysis ma vs
Passing No. 200 Sieve wa Consolidation c Sand Equivalent se Collapse TasI col Expansion Index ei Resistance (R) Value r Compaction Curve max Chemical Anatysis ca
Hydrometer h Electrical Resistivity •r
UNIFIED SOIL CLASSIFICATION AND KEY TO BORING LOG SYMBOLS
Converse Consultants
Project Name
Two Proposed Retail Structures
7190 Avenida Encinas
Carlsbad, CA
Project No.
05-32123-01
Drawing No.
A-1
Log OT boring NO.BH-T
Dates Drilled: 3/25/2005 Logged by: CKL
Equipment: 8" HOLLOW STEM AUGER Driving Weight and Drop: 140 lbs/30 in
Ground Surface Elevation (ft): 70 Depth to Water (ft): _ 21 feet
Checked By: KN
20 -
SUMMARY OF SUBSURFACE CONDITIONS
This log is part of the report prepared by Converse for this project
and should be read together with the report. This summary applies
only at the location of the boring and at the time of drilling.
Subsurface conditions may differ at other locations and may change
at this location with the passage of time. The data presented is a
simplification of actual conditions encountered.
FILL:
CLAYEY SAND (SC): fine- to medium-grained, brown.
NATIVE:
CLAYEY SAND(SC): fine- to medium-grained, light
gray.
- gray brown
CLAY (CL): light gray.
SILTY SAND (SM): fine-grained, gray.
fine- to medium-grained
End of boring at 26.5 feet.
Groundwater encountered at 21 feet at the time of
drilling.
Boring backfilled with bentonite chips and grout.
Project Name
Converse Consultants ^rgrATirES'^"'^*""'
Carlsbad, CA
SAMPLES o o
CO
85
68
65
48
50-6"
50-6"
(50-6";
UJ
cr:
I-
O as
15
14
16
18
15
Project No,
05-32123-01
10 124
111
117
115
111
108
Q
CL
Drawing No.
A-2
Log of Boring No.BH-2
Dates Drilled: 3/25/2005 Logged by: CKL Checked By:
Equipment: 8''HOLLOW STEM AUGER Driving Weight and Drop: 140 lbs/ 30 in
Ground Surface Elevation (ft): 70 Depth to Water (ft): 20 feet
KN
SUMMARY OF SUBSURFACE CONDITIONS
This log is part of the report prepared by Converse for this project
and should be read together with the report. This summary applies
only at the location of the boring and at the time of drilling.
Subsurface conditions may differ at other locations and may change
at this location with the passage of time. The data presented is a
simplification of actual conditions encountered.
- 25
- 30 4
FILL:
SILTY SAND (SM): fine- to medium-grained, trace clay,
gray brown.
NATIVE:
SILTY SAND (SM): fine- to medium-grained, gray,
- trace clay
CLAYEY SAND(SC): fine- to medium-grained, gray
brown.
CLAY (CL): light gray.
- trace fine- grained sand
CLAYEY SAND (SC): fine-grained, light gray.
• fine- to medium-grained
Project Name
Converse Consultants ^rgrArirES^*"*^'"^
Project No.
05-32123-01
Drawing No.
A-3a
Carlsbad, CA
Log of Boring No.BH-2
Dates Drilled: 3/25/2005 Logged by: CKL
Equipment: 8" HOLLOW STEM AUGER Driving Weight and Drop: 140 lbs / 30 in
Ground Surface Elevation (ft): 70 Depth to Water (ft): 20.feet
Checked By: KN
Q.
(U
Q
Q.
SUMMARY OF SUBSURFACE CONDITIONS
This log is part of the report prepared by Converse for this project
and should be read together with the report. This summary applies
only at the location of the boring and at the time of drilling.
Subsurface conditions may differ at other locations and may change
at this location with the passage of time. The data presented is a
simplification of actual conditions encountered.
SAMPLES
UJ >
a: D
Q CQ
o o
u.
O
_j
CO
UJ
H-W
O
H
Z
D
><:x
as a
CL
- 40
45
- 50
CLAYEY SAND (SC): fine-grained, light gray.
fine- to medium-grained
fine- grained
- fine- to coarse-grained
End of boring at 51.5 feet.
Groundwater encountered at 20 feet at the time of
drilling.
Boring backfilled with bentonite chips and grout.
(50-6")
50-6"
(50-6")
50-6"
15
16
107
89
Converse Consultants
Project Name
Two Proposed Retail Structures
7190 Avenida Encinas
Carlsbad, CA
Project No.
05-32123-01
Drawing No.
A-3b
Log of Boring No.BH-3
Dates Drilled: 3/28/2005
Equipment: 8" HOLLOW STEM AUGER
Ground Surface Elevation (ft): 70
Logged by: CKL
Driving Weight and Drop: 140 lbs/30 in
Depth to Water (ft):_ _ 21 feet
Checked By: KN
Q. 0)
Q
r 5
- 15
10
- 20
25
- 30
SUMMARY OF SUBSURFACE CONDITIONS
This log is part of the report prepared by Converse for this project
and should be read together with the report. This summary applies
only at the location ofthe boring and at the time of drilling.
Subsurface conditions may differ at other locations and may change
at this location with the passage of time. The data presented is a
simplification of actual conditions encountered.
FILL :
SAND (SP): fine-grained, reddish brown.
NATIVE:
CLAYEY SAND (SC): fine- to medium-grained,
yellowish brown.
medium- to coarse-grained
fine- to medium-grained, orange brown
SILTY SAND (SM): fine-grained, tan gray.
- yellowish brown
Converse Consultants JraoSra^ESL''"^*""
Project Name
Two Proposed
7190 Avenida
Carlsbad, CA
SAMPLES; O
O
LL
cn
O
_i ca
!
UJ
IT
I-
O
45
60
85-11"
50-6"
(45)
50-6"
(50-5")
50-5"
2
>-<^^
Q S
11
14
15
15
19
Project No.
05-32123-01
10 118
111
108
108
105
105
114
106
9 a
Drawing No.
A-4a
Dates Drilled: 3/28/2005
Equipment: 8" HOLLOW STEM AUGER
Ground Surface Elevation (ft): 70
Log of Boring No.BH-3
Logged by: CKL
Driving Weight and Drop: 140 lbs/30 in
Depth to Water (ft): 21 feet
Checked By: KN
Q. 01
a
y
a
03 O)
(33
SUMMARY OF SUBSURFACE CONDITIONS
This log is part of the report prepared by Converse for this project
and should be read together with the report. This summary applies
only at the location of the boring and at the time of drilling.
Subsurface conditions may differ at other locations and may change
at this location with the passage of time. The data presented is a
simplification of actual conditions encountered.
- 40
- 45 -
50
SILTY SAND (SM): fine-grained, yellowish brown.
tan gray
SAMPLES! 1-i O I o
1 u.
CO
OQ
SAND (SP): fine-grained, tan gray.
End of boring at 51.5 feet.
Groundwater encountered at 21 feet at the time of
drilling.
Boring backfilled with bentonite chips and grout.
Converse Consultants
(50-6")
LU 01 D H
CD
2
aS
50-6"
(50-6")
50-3"
9
Q.
Project Name
Two Proposed Retail Structures
7190 Avenida Encinas
Carlsbad, CA
Project No,
05-32123-01
Drawing No.
A-4b
Dates Drilled: 3/25/2005
Equipment: 8" HOLLOW STEM AUGER
Ground Surface Elevation (ft): 70
Log of Boring No.BH-4
Logged by: CKL
Driving Weight and Drop: 140 lbs/30 in
Depth to Water (ft): 21feet
Checked By: KN
Q.
0)
Q
o x:
Q.
ra cn
63
SUMMARY OF SUBSURFACE CONDITIONS
This log is part of the report prepared by Converse for this project
and should be read together with the report. This summary applies
only at the location of the bohng and at the time of drilling.
Subsurface conditions may differ at other locations and may change
at this location with the passage of time. The data presented is a
simplification of actual conditions encountered.
SAMPLES o o
u.
cn
CQ
LU
H
cn
O aS 9
CL
- 10
15
20
25
30
FILL:
SAND (SP): fine- to medium-grained, orange brown.
NATIVE:
SAND (SP): fine- to medium-grained, tan brown.
orange brown
jr - medium- to coarse-grained
CLAYEY SAND (SC): fine- to medium-grained, brown.
fine- grained
70
83
35
40
(55)
80
(50-6")
50-6" 14
111
104
96
100
101
Project Name
Converse Consultants JraoATira^ESas'^^'^'"^^
Project No.
05-32123-01
Drawing No.
A-5a
Carlsbad, CA
Dates Drilled: 3/25/2005
Equipment: 8" HOLLOW STEM AUGER
Ground Surface Elevation (ft): 70
L-uy Ul Duniiy MO.Dn-<t
Logged by: CKL
Driving Weight and Drop: 140 lbs/ 30 in
Depth to Water (ft): 21 feet
Checked By: KN
x: a.
(S3
a
SUMMARY OF SUBSURFACE CONDITIONS
This log is part of the report prepared by Converse for this project
and should be read together with the report. This summary applies
only at the location of the boring and at the time of drilling
Subsurface conditions may differ at other locations and may chanqe
at this location with the passage of time. The data presented is a
simplification of actual conditions encountered.
y x: a ro o)
5.3
CLAYEY SAND(SC): fine- to medium-grained, brown.
End of boring at 36.5 feet.
Groundwater encountered at 20 feet at the time of
drilling.
Boring backfilled with bentonite chips and grout.
Converse Consultants
Project Name
Two Proposed Retail Structures
7190 Avenida Encinas
Carlsbad, CA
Project No.
05-32123-01
Drawing No.
A-5b
A
P
P
E
N
D
I
X
B
Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carlsbad, Califomia
March 5, 2005
Page B-1
APPENDIX B
SUMMARY OF LABORATORY TEST RESULTS
Tests were conducted in our laboratory on representative soil samples for the purpose
of classification and evaluation of their relevant physical characteristics and engineering
properties. The amount and selection of tests were based on the geotechnical
requirements of the project. Test results are presented herein and on the boring logs
(see Appendix A, Field Exploration). The following is a summary of the various
laboratory tests conducted forthis project.
Moisture Content and Dry Density
Results of moisture content and dry density tests, performed on relatively undisturbed
ring samples were used to aid in the classification of the soils and to provide
quantitative measure of the in-situ dry density. Data obtained from this test provides
qualitative information on strength and compressibility characteristics of site soils. For
test results, see the boring logs (Appendix A, Field Exploration).
Sieve Analysis
To aid in classification of the soils, mechanical grain-size analysis were performed on
two (2) representative samples. Testing was performed in accordance with the ASTM
Standard D422 method. For test results, see Drawing No. B-1, Grain Size Distribution
Results.
Amounts of Material in Soils Finer Than the No. 200 Sieve
Five (5) selected samples were tested in accordance with the ASTM Standard D1140-
92 test method to determine the amount of material finer than U.S. Standard Sieve No.
200. This information is summarized below:
Table No. B-1, Percent Finer than #200 Sieve Results
Boring No. Depth (ft) Soil Classification Percent Finer Than No.
200 Sieve {%)
*BH-1 7.5 CLAYEY SAND (SC) 29
BH-1 15 SILTY SAND (SM) 24
BH-2 20 CLAYEY SAND (SC) 15
BH-2 35 CLAYEY SAND (SC) 22
BH-3 20 CLAYEY SAND (SC) 28
BH-4 5 SAND (SP) 5
*BH-4 25 CLAYEY SAND (SC) 19
Converse Consultants
M:\JOBFiLE\2005\32\05-123 DONAHUE SCHRIBER\05-32123-01-GIR.DOC
Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carlsbad, California
March 5, 2005
Page B-2
Expansion Index Test
One (1) representative bulk sample was tested to evaluate the expansion potential of
material encountered at the site. The test was conducted in accordance with UBC/CBC
Standard. For test results, see Table No. B-2 below:
Table No. S-2, Summary of Expansion Index Test Results
Boring No. Depth
(feet) Soil Description Expansion
Index
Expansion
Potential
BH-1 0-5 CLAYEY SAND (SC) 7 Very Low
Direct Shear Tests
Three (3) direct shear tests were performed on undisturbed samples and remolded
sample to 90 percent relative compaction, at soaked moisture conditions. Each sample,
contained in three brass sampler rings, was placed, one at a time, directly into the test
apparatus and subjected to a range of normal loads appropriate for the anticipated
conditions. The sample was then sheared at a constant strain rate of 0.01 inch/minute.
Shear deformation was recorded until a maximum of about 0.25-inch shear
displacement was achieved. Peak strength was selected from the shear-stress
deformation data and plotted to determine the shear strength parameters. For test data,
including sample density and moisture content, see Drawing No. B-3 through B-5, Direct
Shear Test Results and Table No. B-3 below:
Table No. B-3, Summary of Direct Shear Test Results
Boring
No.
Depth
(feet)
Soli Classificatton Peak Strength Parameters Boring
No.
Depth
(feet)
Soli Classificatton
Friction Angle
(degrees)
Cotiesion
(psf)
BH-r 0-5 CLAYEY SAND (SC) 30 200
BH-3* 0-5 SAND (SP) 32 0
BH-4
* n 1-1 t 4. _
7.5 SAND (SP) 36 0
Consolidation Test
Data obtained from this test, performed on two (2) relatively undisturbed soil samples,
were used to evaluate the settlement characteristics of the on-site soils under load!
Preparation for this test involved trimming the sample, placing it in a one-inch-high
brass ring, and loading it into the test apparatus, which contained porous stones to
Converse Consultants
M:\JOBFILE\2005\32\05-123 DONAHUE SCHRIBER\05-32123-01-GIR.DOC
Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carlsbad, Califomia
March 5, 2005
Page B-3
accommodate drainage during testing. The sample was tested at field moisture and
submerged conditions. Normal axial loads were applied to one end ofthe sample through
the porous stones, and the resulting deflections were recorded at various times. The load
was increased after the sample reached a reasonable state of equilibrium. Normal loads
were applied at a constant load-increment ratio, successive loads being generally twice
the preceding load.
For test results, including sample density and moisture content, see Drawing No. B-6
and B-7, and Consolidation Test Results.
Soil Corrosivity
One (1) representative soil sample was tested to determine minimum electrical
resistivity, pH, and chemical content, including soluble sulfate and chloride
concentrations. The purpose of these tests is to determine the corrosion potential of site
soils when placed in contact with common construction materials. These tests were
performed by EGL Inc. Test Laboratory, Santa Fe Springs, California. For test results,
see below.
Table No. B-4, Soil Corrosivity Test Resu ts
Boring Nc/Depth pH Chloride
(ppm)
Sulfate
(% by weight)
Min. Resistivity
(as-received)
(ohm-cm)
BH-4 / 0 - 5' 6.81 105 0.006 2,400
Sample Storage
Soil samples presently stored in our laboratory will be discarded 30 days after the date
of this report, unless this office receives a specific request and a fee to retain the
samples for a longer period.
Converse Consultants
M:\JOBFILE\2005\32\05-123 DONAHUE SCHRIBER\05-321 23-01-GIR.DOC
U.S. SIEVE OPENING IN INCHES u,s, SIEVE NUMBERS HYDROMETER
6 \ 3 ^15 ' 3/4 ^^^3/8 ^ A ^ 8^° 14^^ 20 ^° 40 ^0 60 140 2°°
1 0,1
GRAIN SIZE IN MILLIMETERS
COBBLES GRAVEL SAND
0.01 0.001
SILT OR CLAY
Boring No. Depth (ft) Description LL PL PI Cc Cu
• BH-1 7.5 CLAYEY SAND (SC)
CD BH-4 25 CLAYEY SAND (SC)
Boring No. Depth (ft) D100 D60 D30 DIO %Gravel %Sand %Si t 1 °A )Clav
• BH-1 7.5 4.76 0.236 0.081 0.0 71.0 29.0
IZl BH-4 25 4.76 0.269 0.134 0.0 81.0 19.0
GRAIN SIZE DISTRIBUTION RESULTS
Converse Consultants
Project Name
Two Proposed Retail Structures
7190 Avenida Encinas
Carlsbad, CA
Project No.
05-32123-01
Drawing No.
B-1
>-
OT
Z LU Q >-
o
135
130
^ 125
120
115
110
105
100
95
90
) \\\/
Uuivub Ul 100% Sail
for Specific Gravity E
.2.65
alien
qual to:
Vv
WATER CONTENT, %
SYMBOL SAMPLE NO, DEPTH (ft) DESCRIPTION ASTM
TEST METHOD
OPTIMUM
WATER, %
MAXIMUM DRY
DENSITY, pcf
• BH-3 0-5 SAND (SP) D1557 Method A 12 124
Zl BH-1 0-5 CLAYEY SAND (SC) D1557 Method A 8 133
- MOISTURE-DENSITY RELATIONSHIP RESULTS
® Project Name Proiect No
^ li. . Two Proposed Retail structures riujcuiiNu.
Converse Consultants 7190 Avenida Encinas 05-32123-01
Carlsbad, CA
Drawing No.
B-2
4,000
3,500
3,000
i 2,500
X I-o z
UJ
OT a: < ill
X OT
2,000
1,500
1,000
500
1,000 2,000
NORMAL PRESSURE, psf
3,000 4,000
SAMPLE NO. BH-1 DEPTH (ft) 0-S
DESCRIPTION CLAYEY SAND (SC)
COHESION (psf) 200 FRICTION ANGLE (degrees): 30
MOISTURE CONTENT (%) : 14 DRY DENSITY (pcf) 120
NOTE: SAMPLES REMOLDED TO 90% RELATIVE COMPACTION
DIRECT SHEAR TEST RESULTS
Converse Consultants
Project Name
Two Proposed Retail Structures
7190 Avenida Encinas
Carlsbad, CA
Project No.
05-32123-01
Drawing No.
B-3
4,000
3,500
3,000
i 2,500
x"
o z
LU
a. Ul a. <
UJ x w
2,000
1,500
1,000
1,000 2,000
NORMAL PRESSURE, psf
3,000 4,000
SAMPLE NO. BH-3 DEPTH (ft) 0-5
DESCRIPTION SAND (SP)
COHESION (psf) 300 FRICTION ANGLE (degrees): 28
MOISTURE CONTENT (%) : 10 DRY DENSITY (pcf) 112
NOTE: SAMPLES REMOLDED TO 90% RELATIVE COMPACTION
DIRECT SHEAR TEST RESULTS
Converse Consultants
Project Name
Two Proposed Retail Structures
7190 Avenida Encinas
Carlsbad, CA
Project No. Drawing No.
05-32123-01 B-4
4,000
3,500
3,000
I 2,500
o z
Ul
^ 2,000
X OT
1,500
1,000
500
1,000 2,000
NORMAL PRESSURE, psf
3,000 4,000
SAMPLE NO. BH-4 DEPTH (ft) 7.5
DESCRIPTION SAND (SP)
COHESION (psf) 0 FRICTION ANGLE (degrees): 36
MOISTURE CONTENT (%) : 5 DRY DENSITY (pcf) 96
NOTE: PEAK STRENGTH
DIRECT SHEAR TEST RESULTS
Converse Consultants
Project Name
Two Proposed Retail Structures
7190 Avenida Encinas
Carlsbad, CA
Project No.
05-32123-01
Drawing No.
B-5
I
I
I
I
I
I
I
I
i
I
I
:
I
1
z
h-
OT
STRESS, ksf
SAMPLE NO. BH-1 DEPTH (ft) 5
DESCRIPTION : CLAYEY SAND (SC) SPECIFIC GRAVITY : 2.65
MOISTURE
CONTENT (%) DRY DENSITY
(pcf)
PERCENT
SATURATION VOID
RATIO
INITIAL 15
FINAL 17
111
115
82
100
0.467
0.416
NOTE: SOLID CIRCLE INDICATES READING AFTER ADDITION OF WATER.
CONSOLIDATION TEST RESULTS
1^
Project Name
Converse Consultants ?r9°oSS:'En:SL'*"'^^
Carlsbad, CA
Project No.
05-32123-01
Drawing No.
B-6
I
X OT
STRESS, ksf
100
SAMPLE NO. BH-3 DEPTH (ft) 7.5
DESCRIPTION : CLAYEY SAND (SC) SPECIFIC GRAVITY : 2.65
MOISTURE
CONTENT(%)
DRY DENSITY
(pcf)
PERCENT
SATURATION VOID
RATIO
INITIAL 9 108 45 0.510
FINAL 16 112 90 0.456
NOTE: SOLID CIRCLE INDICATES READING AFTER ADDITION OF WATER.
, CONSOLIDATION TEST RESULTS
Wi
1^
Project Name
Converse Consultants J^rA^rEnS'''"'"™'
Carlsbad, CA
Project No. Drawing No.
05-32123-01 B-7
I
A
P
P
E
N
0
/
f
f
I
X
C
APPENDIX C
EARTHWORK SPECIFICATIONS
^''tC/F/CAT/o/vs
3bor o,
^^^^'^ 5, 2005
Page C-1
ExcavaKoos
Preparation of p
• The
design aoH ^-'^^^^^^d in tH- s^bsurfa ° ^^'^^ C°nsu/tanf. ^^^°^'^ed.
o.3.„,„3 ^-___^-tface an.
2.
3.
3.
-t.t\-*ns to ,e "^FS
' subor.=H« • ^^"erneath o/, ^®f^oved anw feet hpw„ ^
S'x re) /of® a" area<. f structure s/ahcf '^^o^Pacted .
•-•~wnsu«a„,s —
I
1
'I
I
'I
I
2.
an°ctXt^ -ay , '"'^'^ ^.e ap^ ^'f-"?
5. 4,, "'Pac(eca;°®P/aced„„ '^'"'""al of ,H ^"'^'^ e, -S-^eee:::;---^^^^^^^ ^'^«-te,n,.,
l^X^^' ^^"'^ - appro,,, ,
^sec^ 3^'^^/ eng/^^ on~site earth ^eefeT^^^^a/
/'"""'^et' W ^"=«''aoeoos /„ """"'"a/
ptv° ^'rZ^:^^^^^^^^^^ to ,0 "^^""^"^^o •
more 'abot^f «''a« fta.„ , ' "^"^"t of „
'•--::^;r^~^^ -ent .
Cf.
3.
Geotechnical Investigation Report
Two Retail Stores - Pad 4 and Pad 6
7190 Avenida Encinas
Carlsbad, California
March 5, 2005
Page C-4
shall be moisture conditioned to within two (2) percent, and clayey soils to at
least two (2) percent above, optimum moisture content.
5. Fill exceeding five (5) feet in height shall not be placed on native slopes that are
steeper than 5 to 1 (horizontal to vertical). Where native slopes are steeper than
5 to 1, and the height of the fill is greater than five (5) feet, the fill shall be
benched Into competent materials. The height and width of the benches shall be
at least two (2) feet.
6. Representative samples of materials being used as compacted fill will be
analyzed in the laboratory by the geotechnical engineer to obtain information on
their physical properties. Maximum laboratory density of each soil type used in
the compacted fill will be determined by the ASTM D1557-00 compaction
method.
7. Fill materials shall not be placed, spread or compacted during unfavorable
weather conditions. When site grading is interrupted by heavy rain, filling
operations shall not resume until the geotechnical engineer approves the
moisture and density conditions ofthe previously placed fill.
8. It shall be the grading contractor's obligation to take all measures deemed
necessary during grading to provide erosion control devices In order to protect
slope areas and adjacent properties from storm damage and flood hazard
originating on this project. It shall be the contractor's responsibility to maintain
slopes in their as-graded form until all slopes are in satisfactory compliance with
job specifications, all berms have been properly constructed, and all associated
drainage devices meet the requirements ofthe civil engineer.
Cf .8 Observation and Testing
1. During the progress of grading, the geotechnical engineer will provide
observation ofthe fill placement operations.
2. Field density tests will be made during grading to provide an opinion on the
degree of compaction being obtained by the contractor. Where compaction less
than specified herein is indicated, additional compactive effort with adjustment of
the moisture content shall be made as necessary until the required degree of
compaction is obtained.
3. A sufficient number of field density tests will be performed to provide an opinion
to the degree of compaction achieved. In general, density tests will be performed
on each one-foot lift of fill, but not less than one for each 500 cubic yards of fill
placed.
Converse Consultants
M:\JOBFiLE\2005\32\05-123 DONAHUE SCHRIBER\05-32123-01-GIR.DOC