HomeMy WebLinkAboutCT 81-46; Carlsbad Airport Center Unit 2; Soils Report; 1988-07-29SUPPLmEnTAL
GBOTECHBICAL IAVESTIGATION
CARLSBAD AIRPORT CENTER, UNIT 2,
AND OFF-SITE FILL AREA
CARLSBAD, CALIFORUIA
PREPARED FOR
CENTRE DEVELOPMENT
21 1 1 PALOMAR AIRPORT ROAD
CARLSBAD, CALIFORNIA 92009
PREPARED BY
SAN DIEGO GEOTECHNICAL CONSULTANTS, INC.
6455 NANCY RIDGE DRIVE, SUITE 200
SAN DIEGO, CALIFORNIA 92121
JULY 29, 1988
JOB NO. 05-4879-011-00-00
LOG NO. 8-1797
.
r
Centre Development
Carlsbad, California 92009 2111 Palomar Airport Road
Attention: Mr. Joe Giedeman
7
-
Job NO. 05-4879-011-00-00 Log NO. 8-1797
SUBJECT: SUPPLEMENTAL GEOTECHNICAL INVESTIGATION
and Off-site Fill Area Carlsbad Airport Center, Unit 2,
Carlsbad, California
Gentlemen:
As requested, San Diego Geotechnical Consultants has completed a
supplemental geotechnical investigation for the proposed Unit 2
of the Carlsbad Airport Center in Carlsbad, California. Our work
also covered a limited area of offsite fill that will be graded
as part of the project. This report presents the re'sults of our
investigation, as well as our conclusions and recommendations
regarding your proposed development of this site.
In general, the development will be feasible from a geotechnical
standpoint. The major geotechnical constraints will be difficult
excavation of volcanic rock in deeper cuts, the generation of
oversize material from ripping or blasting of volcanic rock, the
and the stability of proposed cut slopes.
-
- removal of compressible alluvium and colluvium in canyon bottoms,
- We sincerely appreciate this opportunity to serve you . If you
have any questions, please call us at your convenience.
Very truly yours,
SAN DIEGO GEOTECHNICAL CONSULTANTS, INC.
c
-
- e7v1 Antho Vice President F. Bel ast, P.E.
AFB/pb
974nTRAnF PI ACF SIIITF lon SAN nlFGn CAWI~R. IRIQI~?R.I~~?. FAY.I~~~Q! 6?~-17nfi
A SUBSIDIARY OF THE IRVINE CONSULTING GROUP, INC.
TABLE OF CONTENTS
1.0 INTRODUCTION...............................................l
1.1 Authorization.........................................l
1.2 Scope of Services.....................................l
2.0 PROPOSED DEVELOPMENT.......................................2
3.0 SITE DESCRIPTION.....................................-.....2
4.0 SITE INVESTIGATION.........................................3
4.1 General...............................................3
4.2 Field Exploration.....................................4
4.3 Laboratory Testing Program.. .......................... 5
5.0 GEOTECHNICAL SETTING AND SUBSURFACE CONDITIONS.............6
5.1 Regional Geology........... ........................... 6
5.2 Geologic Units........................................6
5.2.1 Santiago Peak Volcanics (Map Symbol Jsp)..... ..6
5.2.2 Santiago Formation (Map Symbol Tsa)............7
5.2.3 Alluvium (Map Symbol Qal>......................7
5.2.5 Topsoil................................. ....... 9
5.3 Groundwater...........................................g
5.4 Geologic Structure....................................9
6.0 SEISMICITY................................................lO
6.1 Earthquake Effects...................................lO
6.1.1 Surface Fault Rupture ......................... 10
6.1.2 Earthquake Accelerations......................ll
6.1.3 Seismically Induced Slope Failures............ll
6.1.4 Seismically Induced Settlement................12
6.1.5 Liquefaction..................................l2
6.1.6 Lurching and Shallow Ground Rupture...........lZ
6.1.7 Tsunamis, Seiches, and Reservoir Failures.....l2
7.0 GEOTECHNICAL EVALUATION AND RECOMMENDATIONS...............13
7.1 General..............................................l3
7.2 Grading and Earthwork................................l4
7.2.1 General.......................................l4
7.2.2 Geotechnical Observations.....................14
7.2.3 Site Preparation .............................. 15
7.2.4 Rippability ................................... 16
7.2.5 Fill Materials................................l7
7.2.6 Fill Compaction...... ......................... 19
5.2.4 Fill...........................................8
i
TABLE OF CONTENlS
(Continued)
7.2.7 Shrinkage and Bulking ......................... 20
7.2.8 Overexcavation of Bedrock.....................20
7.2.9 Cut-Fill Transitions..........................21
7.2.10 Trench and Wall Backfill......................21
7.2.11 Off-site Fill Area.......................... ..21
7.2.12 Existing Fills................................22
7.3.1 Bedrock and Soil Characteristics..............23
7.3.3 Stabilization and Buttress Fills..............26
7.3 Slope Stability. ..................................... 23
7.3.2 Cut and Fill Slopes ........................... 24
7.3.4 Fill-over-cut Slopes .......................... 28
7.3.5 Construction Slopes ........................... 28
7.3.6 Natural Slopes. ............................... 29
7.3.7 Slope Protection and Maintenance..............30
7.4 Settlement Considerations............................30
7.5 Surface and Subgrade Drainage... ..................... 32
7.6 Foundation Recommendations.. ........................ .34
7.7 Reactive Soils.......................................35
7.8 Pavements ............................................ 35
7.9 Review of Grading Plans..............................36
8.0 LIMITATIONS OF INVESTIGATION..............................^^
Figures
1
2 3
Appendices
A B
C 1
D
ATTACWENTS
Location Map Regional Fault Map Geologic Cross-sections
References Field Exploration Program,
Boring Logs, Figures B-2 through B-11 Test Pits, Figures B-12 through B-16 Seismic Traverses, B-17 and B-18 Laboratory Testing Program, Figures C-1 through C-8 Standard Guidelines for Grading Projects
ii
Plates
1 and 2
TABLE OF CONTENTS (Continued)
Geotechnical Maps
iii
SUPPmEBrAL GEOTECHNICAL INVESTIGATION
CARLSBAD AIRPORT CENTER, UNIT 2,
CARLSBAD, CALIFORNIA
AND OFF-SITE FILL AREA
1.0 INTRODUCTION
This report presents results of a geotechnical investigation
of a proposed commercial project in Carlsbad, California.
The purpose of our investigation was to evaluate the surface
and subsurface soils and geologic conditions at the site
and, based on those conditions, to make recommendations
regarding mass grading and other geotechnical aspects of the
project. Because the project will create rough-graded lots
that will be sold and developed separately, individual
foundation investigations should be made for each lot when
precise grading plans, building locations, and loading
conditions are known. Our conclusions and recommendations
are based on analysis of the data from our field exploration
and laboratory tests, and from our experience with similar
soils and geologic conditions in this area.
1.1 Authorization
This investigation was authorized by Mr. Jim Morrissey
of Centre Development on June 21, 1988. Our scope of
services for this investigation generally conformed to
that outlined in our Proposal No. SDP8-4833, dated June
3, 1988.
1.2 Scope of Services
The scope of services for this investigation included
the following tasks:
a. Review of pertinent geotechnical literature, aerial
photographs, and an 80-scale topographic map by
Rick Engineering, Inc., dated June 7, 1988.
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Job NO. 05-4879-011-00-00
Log NO. 8-1797 Page 2
b. Geologic reconnaissance of the site;
c. Subsurface exploration consisting of four 8-inch
diameter hollow-stem auger drill holes, three
30-inch diameter bucket auger drill holes, nine
test pits, and two seismic refraction traverses;
d. Logging of the drillholes and test pits, with
collection of bulk, disturbed, and relatively
undisturbed samples for laboratory testing;
e. Laboratory testing of samples obtained during the
field exploration;
f. Geologic and engineering analysis of the field and
laboratory data to develop our conclusions and
recommendations ; and
g. Preparation of this report with its accompanying
maps, figures, and other information to present our
findings, conclusions, and recommendations.
2.0 PROPOSED DEVELOPMENT
The proposed development is divided into about 22 separate
commercial lots. We understand that the site will be rough
graded during the initial phases of mass grading, after
which each lot will be developed separately. Our review of
the grading plans indicate that cut slopes to a maximum
height of approximately 35 feet, and fill slopes to a
maximum height of approximately 65 feet are proposed.
3.0 SITE DESCRIPTION
Unit 2 of the Carlsbad Airport Center will occupy a land
parcel of irregular shape located in Carlsbad, California.
The site includes about 70 acres of hills and associated
small drainage basins located east of the existing Carlsbad
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Airport Center, Unit 1. The location and topography are
shown on the attached Location Map (Figure 1). The site is
bounded on the north and east by McClellan Palomar Airport,
on the south by Palomar Airport Road, and on the west by
Units 1 and 3 of the Carlsbad Airport Center.
Topographically, the site includes both low- and high-relief
areas. Steeply descending slopes lie near the western and
eastern boundaries. Natural slopes within the project are
approximately 1.5:l (horizonta1:vertical) or steeper on the
canyon sidewalls in the western and eastern portions of the
site. Maximum relief for the site is about 240 feet, with
elevations ranging from about 190 to 330 feet above mean sea
level. The site drains to east-west trending canyons in the
northwestern and southeastern portions of the site and to
several north-south trending tributary canyons.
Access to the site is along improved roads from the existing
Carlsbad Airport Center, Unit 1. An agricultural reservoir
presently exists near the center of the site.
4.0 SITE INVESTIGATION
4.1 General
A previous geotechnical report by H.V. Lawmaster and
Company (Reference 1) includes Unit 2. In addition,
the as-graded report for Unit 1 by Moore h Taber
(Reference 2) describes offsite grading performed in
Unit 2. We reviewed both reports as part of our work.
Before starting field work, we studied aerial photos
and topographic maps of the site to aid in determining
the locations of our subsurface explorations. This
information, combined with our field investigation,
laboratory test results, seismicity reviews, and
previous experience in the general area, forms the
I FEET
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4.2
basis for the conclusions and recommendations in this
report. The study methods used conform to generally
accepted standards of practice for geotechnical
investigations in southern California.
Field Exploration
Field work began on June 21, 1988. and was completed on
June 30, 1988. During this period, seven borings were
drilled through the surficial deposits and into the
bedrock. Nine test pits were also excavated during
this period. Two seismic traverses were performed to
evaluate rippability in the area of proposed cuts in
volcanic rock. The approximate locations of the test
pits and boreholes are shown on the Geotechnical Map
(Plate 1). These locations were made in the field by
pacing and by inspection of available maps. Locations
should not be considered more accurate than is implied
by the methods of measurement used.
The boreholes were drilled using an 8-inch diameter,
continuous-flight, hollow-stem auger drill rig and a
30-inch bucket auger drill rig. Samples were obtained
using a standard split spoon sampler and a 2.5-inch
(inside diameter) Modified California sampler. In the
hollow-stem auger drillholes, the drive weight was a
140-pound hammer falling 30 inches. The rig kelly bar
was the drive weight in the bucket auger drillholes.
For each drive sample, we recorded the number of blows
needed to drive the sampler 12 inches into the soil.
Three-inch (outside diameter) steel Shelby tubes were
also hydraulically pushed to obtain samples from the
hollow-stem auger drillholes. The test pits were
excavated by a tracked backhoe. Bulk samples only were
collected from the test pits. Each hole or pit was
backfilled upon completion of logging and sampling.
...
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Our field geologist was present to supervise drilling
and test pit excavation. Groundwater conditions were
reported as they appeared to the geologist at the time
of drilling. Each borehole and test pit was logged and
sampled for laboratory tests. These logs are attached
in Appendix B as Figures B-2 to B-16. The boundaries
shown between soil types on the logs were interpolated
between sample locations and are approximate only.
Transitions between soil types actually may be either
abrupt or gradual.
Two seismic refraction traverses were made with a Bison
1570C signal-enhancement seismograph, using a 10-pound
hammer as the energy source. Each traverse line was
100 feet long, with hammer stations at 10-foot
spacings. The velocities of compressional waves were
measured and interpreted on the basis of published
charts and local experience to estimate the rippability
characteristics of the bedrock. The results of the
seismic survey are shown on Figures B-17 and B-18 in
Appendix B.
4.3 Laboratory Testing Program
Typical samples of the earth materials found during the
field work were taken to our laboratory for testing.
The testing program included particle-size, Atterberg
limits, in-place density and water content. maximum
density, direct shear, consolidation, expansion index,
sulfate content, pH, and resistivity tests. Appendix C
contains descriptions of the test methods and summaries
of the results.
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5.0 GEOTECBNICAL SEYTING AND SUBSURFACE CONDITIONS
5.1 Regional Geolom
The site is located in the Peninsular Ranges geomorphic
province of California near the western margin of the
Southern California Batholith. Along this margin, the
terrain changes from the typically rugged landforms
developed over granitic rocks to flatter, more subdued
landforms underlain by sedimentary bedrock units of the
coastal plain. Specifically, Jurassic metavolcanics
and Eocene sedimentary rocks lie beneath the site.
Alluvial sediments are present in the canyon bottoms.
The distribution of the geologic units is shown on the
attached Geotechnical Map (Plate 1).
5.2 Geologic hits
5.2.1 Santiago Peak Volcanics (Map Symbol Jsp)
The Jurassic-age Santiago Peak Volcanics lie
under the western part of the site. This is a
series of mildly metamorphosed volcanic rocks.
Regionally, the Santiago Peak Volcanics vary in
composition from basalt to rhyolite. On the
site, they are predominantly andesite. The
Santiago Peak Volcanics are moderately to highly
jointed. Joint spacings are variable; clay
fillings are usually present. The Santiago Peak
Volcanics are weathered to depths varying from
of about two feet on top of the volcanic peaks
to about 12 feet on lower slopes. Excavation in
the Santiago Peak Volcanics will be difficult.
The highly weathered rock within about five feet
of the existing ground surface can generally be
excavated with conventional heavy earthmoving
equipment. Below that depth heavy ripping and
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blasting should be expected. Heavy ripping or
blasting will generally produce oversize
materials. The difficulty of handling and
placing these materials in fills will tend to
increase the cost of grading the site.
5.2.2 Santiago Formation (Map Symbol Tsa)
The Eocene-age Santiago Formation underlies
about two-thirds to three-fourths of the site.
As observed, the unit is massive to thick-bedded
silty to clayey sandstone with interbedded sandy
claystone and siltstone. Santiago Formation
rocks probably can be excavated by conventional
earth moving equipment. The claystones and some
siltstones are moderately to highly expansive.
5.2.3 Alluvium (Map Symbol Qal)
Alluvium is present in the east-west and north-
south trending drainage courses As mapped for
this project, the alluvium includes variable
deposits of colluvium on canyon side slopes.
Most alluvium and colluvium consists of dry to
moist, porous, soft, silty and sandy clay.
Alluvium was observed to a maximum depth of
about 20 feet at the location of the proposed
off site fill and was, on the average, about six
feet deep. As observed, the alluvium appeared
to be deepest near the center of the drainage
courses, with shallower depths observed along
the margins. The colluvium was observed to a
maximum depth of about five feet and averaged
about three feet deep on canyon side slopes.
The primary concern with regard to alluvium and
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colluvium is their potential for settlement in
response to loads imposed by fills or struc-
tures. Unacceptable settlement may occur after
construction, especially if these soils become
saturated at a later date. Recommendations to
reduce settlement potential are presented in
later sections.
5.2.4 Fill -
A small part of the site is overlain by
uncompacted fill and debris. The uncompacted
fill exists in the northern and southeastern
areas of the property. In the northern area,
the material consists of sandy clay used to
construct an agricultural reservoir. At the
southeastern edge of the site. the fill is the
result of a prior landfill operation. The fill
consists of rocky soil which may contain some
oversized materials. trash, or debris. In their
present condition, these materials are not
suitable to support either fill or structural
loads. The expansion potential of the fill
soils is expected to be low to medium. Existing
fill materials may be reused as fill material
for grading if they are properly processed
before use.
Much larger areas along Camino Vida Robles were
filled during the grading of Unit 1 in 1985 and
1986. These are mostly canyon fills with
maximum depths of 20 to more than 50 feet.
According to the as-graded soils report
(Reference 2) these were placed as engineered,
compacted fills in accordance with the local
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standards of practice for such fills. We did
not investigate or test the fill for this
report, and we relied on Reference 2 for all
information relating to the nature and quality
of the site preparation and grading.
5.2.5 Topsoil
The topsoil seen on the site consisted of loose,
dry, fine-grained silty sand. Fills or
structures should not be founded directly on
topsoil due to its limited strength and
potential for settlement and seepage. Topsoil
should have low to moderate expansion potential
and may be used in compacted fills if vegetation
and organic material is removed. The topsoil
was not mapped and is not shown on Plate 1.
5.3 Groundwater
Groundwater was found in test pits TP-1 and TP-2 and in
drillholes BW-1, BW-2 and BW-3 at the contact between
alluvium and bedrock. This is probably a localized,
"perched" water table and does not reflect the regional
water table. Groundwater conditions may fluctuate with
seasonal rainfall conditions, and will probably change
in response to development of the site.
5.4 Geologic Structure
Most of the dominant structural features in the area
are associated with pre-Tertiary folding along north-
south axes. The post-Cretaceous sequences have been
gently folded and tilted generally to the west. Dips
ranging from 4 to 15 degrees to the southwest were
measured on bedding planes in the Santiago Formation.
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Discontinuous northeast-trending faulting is associated
with the post-Cretaceous folding. Although no faults
were found within the site during our investigation,
faulting has been mapped in adjacent areas. However,
the closest known active fault is the Elsinore Fault.
about 25 miles to the northeast.
6.0 SEISICITY
As with all of southern California. this site lies in a
seismically active area. There are, however, no known
active faults either on or adjacent to the site. Figure 2
shows the known active faults and earthquake epicenters (M >
5.0) in the region and their relationship to the site.
Because the active faults lie at some distance, the seismic
risk at this site is thought. to be only low to moderate in
comparison with many other areas of southern California.
Seismic hazards at the site are the result of ground shaking
caused by earthquakes on distant, active faults. The hazard
level is sufficient to place the area in seismic risk zone 3
as defined in the Uniform Building Code. Table 1 lists the
known major active and potentially active faults within a
100-kilometer radius and the estimated bedrock accelerations
resulting from the maximum probable earthquakes on those
faults. By definition, the maximum probable earthquake is
the largest event likely to occur in a 100-year interval,
but is in no case smaller than the largest historic
earthquake (Reference 6).
6.1 Earthquake Effects
6.1.1 Surface Fault Rupture
Because active or potentially active faults do
not cross the site, the probability of surface
fault rupture is very low.
TABLK I
SEISMICITY FOR MAJOR FAULTS
MAXIMLM ESTIMATED
DISTANCE PROMJ3LE PEAKBEDROCK REPEAUBLE HIQI
FAUIX FRa4 SITE wmwu~~~1 ACCEIERATI~~ BEDROCK ACCELERATLONS~
Ia Nacion4 35 Miles SE 6.0 0.05g 0.05g
=Canyon4 10 Miles SW 6.0 0.22g 0.14g
Elsinore 25 Miles NE 7.0 0.1 7g 0.17g
Coranado Banks 40 Miles SSW 6.0 0.048 0.04g
Newport-
San Jacinto 48 Miles NE 7.5 0.089 0.08g
San Clemente 57 Miles SW 7.3 0.07g 0.07g
Inglm 40 Miles W 6.5 0.06 0.06
1.
2.
3.
4.
Values are local magnitudes. Maximun probable earthquake
estimates taken frm Seismic Safety Study for the City of
San Mego (1 974). employing the method of Banilla (1 970).
From attenuation chart in Seed and Idriss (1982).
After Ploessel h Slosson (1 974).
'Ihe earthquake capability of the Ia Nacion and Rose Canyon
Faults has not been established. Although the faults are
classed as only potentially active, they are included for
information purposes due to their proximity to the site.
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6.1.2 Earthquake Accelerations
In our opinion, based on the information now
available, the most significant event likely to
affect this project will be an earthquake on the
Elsinore Fault. While a maximum probable event
on the Rose Canyon Fault would generate high
accelerations at the site, the capability of the
Rose Canyon Fault to generate such an earthquake
has not been demonstrated. We therefore
recommend that earthquakes associated with the
Elsinore Fault be used for design and evaluation
purposes at this project.
For Elsinore events, we estimate a peak bedrock
acceleration at the site of about 0.17g for a
maximum probabie earthquake of magnitude 7.0.
We do not expect surface accelerations at this
site to differ significantly from the bedrock
accelerations. The repeatable high bedrock
acceleration is about 65 percent of the peak
acceleration and is used as a design value for
events occurring within 20 miles of a site.
Beyond 20 miles, the peak acceleration is the
recommended design value (Reference 5). Because
the Elsinore Fault is about 25 miles from the
site, we recommend use of the peak bedrock
acceleration for the structures at this site.
6.1.3 Seismically Induced Slope Failures
Seismically-induced slope failures are not
likely to occur at this site under the design
earthquake loading, provided that proper grading
and construction practices are used.
Centre Develomnent July 29, 1988'
6.1.4
6.1.5
6.1.6
6.1.7
Job NO. 05-4879-011-00-00 Log NO. 8-1797 Page 12
Seismically Induced Settlement
The bedrock under this site should not undergo
significant settlement as a result of seismic
shaking. However, the thicker alluvial soils
may experience small settlements. Any measures
taken to mitigate the compressibility of the
alluvium during grading should also decrease the
potential for seismically induced ;ettlement.
Recompaction of those soils should reduce the
potential for seismically induced settlement to
insignificant levels.
Liquefaction
Liquefaction is unlikely at this site due to the
absence of saturation, the fines present in the
soils, and the density of the soil.
Lurching and Shallow Ground Rupture
Shallow ground rupture should not be a hazard,
given the apparent absence of active faults in
the area. Ground cracking also should not be a
major hazard. However, it is possible that some
cracking may occur at any site during a major
earthquake.
Tsunamis, Seiches. and Reservoir Failures
The site is not subject to inundation by
tsunamis or seiches because of its elevation
above sea level and its distance inland from a
major body of water. No reservoirs exist that
are capable of flooding the property.
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7.0 GEOTECHNICAL EVALUATlOU AND REC(MMEIYDATI0NS
7.1 General
We did not identify any geotechnical conditions during
our investigation that would prevent development of the
Carlsbad Airport Center, Unit 2, essentially as now
planned. However, the recommendations in this report
should be followed to minimize delay, inconvenience, or
loss that might arise from the geotechnical conditions
that do exist.
To reduce the potential for damaging settlements, the
existing surficial soil, colluvium, and alluvium should
be removed prior to fill placement, and the resulting
overexcavation should be made as uniform as practical
beneath the building areas. If areas can be identified
where buildings will not be constructed, such as roads
or parking lots, it may be possible to limit removal of
alluvium to shallower depths. This determination can
be made upon review of the grading plans.
Many or most of the required excavations can be made by
conventional heavy grading equipment; however, blasting
may be necessary in volcanic rocks. Hard rock affects
grading not only as it is excavated (rippability), but
also when it is reused as fill (oversized rock disposal
or rockf ill) .
If practical, soils having significant potentials for
expansion should be buried at least five feet beneath
finish grade. The use of expansive soils at shallower
depths will require that specially designed foundations
or special site preparation be used.
Specific foundation recommendations should be made when
details of the buildings to be constructed are known.
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However, shallow footing foundations should be suitable
if (a) all footings in a building will bear entirely
on bedrock or entirely on compacted fill, (b) the pads
are overexcavated so that fills will have relatively
uniform thicknesses under individual buildings, and (c)
compressible soils are removed prior to placing fill.
The remainder of this report explains our geotechnical
recommendations in more detail. These recommendations
are based on empirical and analytical methods typical
of the state of practice in Southern California. If
these recommendations appear to not cover any specific
feature of the proposed development, please contact San
Diego Geotechnical Consultants at once for revisions or
additions to our recommendations.
7.2 Grading and Earthwork
7.2.1 General
The proposed development will use cut and fill
grading to produce building pads, slopes and
street improvements. This grading and earthwork
should be done in accordance with the "Standard
Guidelines for Grading Projects" attached to
this report as Appendix D, and with Chapter 70
of the Uniform Building Code. Where special
recommendations in the body of this report
conflict with the guidelines in Appendix D, the
recommendations in the report should govern.
7.2.2 Geotechnical Observation
San Diego Geotechnical Consultants personnel
should continuously observe the grading and
earthwork operations for this project. Such
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July 29, 1988
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observations are essential to identify field
conditions that differ from those predicted by
preliminary investigations, to adjust designs to
actual field conditions, and to determine that
the grading is in general accordance with the
recommendations of this report. Our personnel
should perform sufficient testing of fill during
grading to support the geotechnical consultant's
professional opinion as to compliance of the
fill with compaction requirements.
7.2.3 Site Preparation
The ground should be stripped and prepared to
receive fill as recommended in Appendix D. In
addition, the existing colluvium and alluvium in
building areas should be removed to the depth at
which bedrock is encountered. Removals should
extend beyond the building footprint a minimum
of five feet or to an imaginary one-to-one plane
extending down and out from the building's outer
edge, whichever is greater. Our personnel in
the field should observe the depth and lateral
extent of this removal.
In drainageways where groundwater is present,
full removal of alluvium may not be practical.
Removals in these areas should extend to depths
at which water inflows or the onset of surface
"pumping" make further removals unfeasible. The
resulting subgrade may be loose and saturated.
Such subgrades may require stabilization prior
to placing fill. A heavy geofabric intended for
stabilization use, such as Mirafi 500X, Propex
2002, or Typar 3341, should be installed on the
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exposed subgrade. The geofabric should then be
covered with a minimum of 12 inches of coarse-
grained gravel or crushed rock. If substantial
thicknesses of alluvium are left in place under
fills. settlement monuments should be installed
and monitored during fill placement.
7.2.4 Rippability
The proposed grading may involve cuts up to 35
feet high in the Santiago Peak Volcanics rock.
Excavability of this rock will probably be a
significant factor in site development. Data
from the test pits were used with the seismic
refraction data to estimate the rippability of
the rock. The velocity of a compressional wave
can be correlated to rock hardness and used as a
indicator of rock behavior during excavation.
The seismic traverses provide useful data down
to depths of about 20 to 30 feet. Figures B-16
and B-17 in Appendix B summarize the seismic
data and our interpretation of it. Reference
reports seismic data from previous studies.
From the data available, the uppermost two to
five feet in the Santiago Peak Volcanics outcrop
area appears rippable with relative ease by a
Caterpillar D-9 bulldozer fitted with a,single-
shank ripper. A layer of weathered bedrock,
rippable with moderate difficulty, exists in
places to depths of five to 15 feet below the
present ground surface. This layer is, however,
discontinuous. In many areas, the easily-ripped
surficial layer rests directly on less-weathered
rock that is rippable only with much difficulty,
..
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if at all. This layer, which lies at depths of
about four to 15 feet below the present surface,
will probably require a combination of blasting
and hard ripping. Blasting may also be needed
where solid boulders ("floaters") are found in
otherwise rippable material.
Once excavated, many of the rock fragments may
be too large for use in normal compacted soil
fills without special placement techniques (see
Appendix D) or placement as rockfill. The size
of rock fragments may be controlled somewhat by
careful design of blasting patterns.
7.2.5 Fill Materials
Any soil imported or excavated from cuts may be
reused for compacted fill if, in the opinion of
the geotechnical engineer, it is suitable for
such use. Debris and organic matter should be
removed from the soil before it is placed. The
criteria governing placement of fills depend on
the size of material present. In general, fills
can be divided into "soil", "soil-rock", and
"rock" fills :
a. "Soil" fills are fills containing no rocks
or hard lumps larger than 12 inches in
maximum dimension and containing at least 60
percent (by weight) of material passing the
314 inch U.S. Standard sieve.
b. "Soil-rock'' fills are fills that contain no
rocks larger than four feet in maximum
dimension and that have a matrix of soil
fill. Rocks larger than 12 inches may be
placed in windrows and by using the other
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techniques described in Appendix D. Some
boulders too large for windrowing will
require special handling during grading.
c. "Rock" fills are fills containing rock
fragments no larger than 2 feet in maximum
dimension, with no appreciable fine-grained
soil matrix. Rock fills require special
testing to monitor compaction as recommended
in Section 7.2.6. Cuts in Santiago Peak
Volcanics (Jsp) may quite likely generate
materials suitable for placement in rock
fills.
Fill placed within three feet of finish grade
should be select finish-grade soil that contains
no rocks or hard lumps greater than six inches
in maximum dimension. For landscaping purposes,
the uppermost four inches of fill should contain
no rocks or hard lumps greater than two inches
in maximum dimension. Soils with an expansion
index of 21 or higher should not be used within .
three feet of finish grade if practical.
Typical samples of soil to be used for soil fill
should be tested by the geotechnical engineer to
evaluate their maximum density, optimum moisture
content and, where appropriate, shear strength
and expansion characteristics. During grading
operations, the contractor may encounter soil
types other than those tested for this report.
The geotechnical engineer should be consulted to
evaluate the suitability of these soils for use
as fill and finish-grade soils. Imported soils
should, if practical, be relatively well-graded,
granular, nonexpansive soils containing small to
moderate amounts of silty and clayey fines. The
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geotechnical engineer should be contacted at
least two working days before the first use of
an imported soil to assess its desirability as a
fill soil.
7.2.6 Fill Compaction
Soil and soil-rock fills should be placed as
described in the standard guidelines of Appendix
D, except where those guidelines are superseded
by recommendations in this report. The minimum
compaction for fills is 90 percent of modified
Proctor maximum dry density (ASRI D 1557-78).
The water content at placement should be at, or
slightly above the optimum water content.
Rock fill requires special placement methods.
The general placement technique is to place a
relatively thin lift of rock, water the lift,
and then compact the lift with heavy compaction
equipment. Heavy vibratory rollers yield the
best results. The actual thickness of each lift
depends on the gradation of the rock. However,
the lifts will probably be about two to three
feet thick. After each lift has been uniformly
spread, it should be sprayed with water to wash
fines through the rock material and to lubricate
the rock mass. Water spraying should continue
throughout the compaction process. The watering
operation is essential to adequate compaction of
the fill. The volume of water used should be at
least 15 percent of the rock fill volume. At
the start of rock fill construction, a test fill
should be built so that placement and compaction
procedures can be evaluated by the geotechnical
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engineer. Once an acceptable procedure has been
established, it may be used throughout the fill.
The rock fill should be brought to finish grade
by placement of a compacted soil fill cap. This
cap should meet the criteria for finish-grade
fill stated in Section 7.2.5. The gradation of
the rock fill should be assessed during grading
by the geotechnical consultant to determine if a
filter is needed between the rock fill and the
soil cap. If needed, this filter may be either
graded aggregate or a geofabric. The purpose of
the filter is to minimize piping of the earth
fill cap into the voids within the underlying
rock fills. However. local experience indicates
that a filter may not be needed.
7.2.7 Shrinkage and Bulking
Removal and recompaction of the surficial soil,
alluvial deposits, and other cut materials will
probably result in shrinkage of about 5 to 10
percent. Bulking in dense alluvium, weathered
rock, and rippable volcanic rock can be expected
to be about 5 to 10 percent. Blasting or hard
ripping of solid rock will probably result in
bulking of 15 to 20 percent.
7.2.8 Overexcavation of Bedrock
Where bedrock is exposed at finish grade, it is
recommended that an overexcavation of at least
three feet be made, and that compacted fill be
placed up to finish grade. This will permit the
economical excavation of utility and foundation
trenches, and will improve the drainage of the
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lots. If deeper utility trenches will be cut,
the overexcavation depth should be increased
accordingly.
7.2.9 Cut-Fill Transitions
Buildings should not be located over cut/fill
transitions because of differential settlement
that may occur between bedrock and compacted
fill. In addition, large changes in fill depth
below structures may cause damaging differential
settlements. The potential for such conditions
should be evaluated during review of the grading
plans. Mitigation of differential settlements
usually includes overexcavation of the rock to
produce near-uniform fill thicknesses under the
pads, with or without special foundation design.
7.2.10 Trench and Wall Backfill
Unless we recommend otherwise in specific cases,
backfill in trenches and behind retaining walls
should be compacted to at least 90 percent of
modified Proctor maximum density (ASTM D1557).
The backfill should be placed in uniform lifts
of six to eight inches. Mechanical compactors
normally should be used to achieve the required
density; water-flooding should not be used.
When specified, strict attention should be given
to special requirements for bedding or hand
compaction around pipes and conduits.
7.2.11 Off-site Fill Area
Excess soil and rock generated from cuts will be
placed in an off-site fill. The fill area is in
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Log NO. 8-1797 Page 22
a canyon west of Carlsbad Airport Center, Unit
1, as shown on Plate 2. In general, off-site
fill should be placed in the same way, and to
the same standards, as mass fill for Unit 2.
The canyon does, however, contain at least 15
feet of uncompacted agricultural fill and 10
feet of alluvium. Both materials are highly
compressible and should be completely removed
before the off-site fill is placed.
Existing Fills
Two classes of existing fill are present on the
site. The first of these is agricultural fill,
including that placed for land-levelling and
that placed for dams and stock ponds. This fill
is entirely undocumented and is probably of poor
quality. All agricultural and undocumented fill
should be completely removed during grading.
The second class of fill is off-site fill placed
during grading of Carlsbad Airport Center, Unit
1. This fill mostly adjoins Camino Vida Roble
along the south edge of Unit 2. For the most
part, it consists of canyon fills varying from
less than 20 to more than 50 feet thick. This
fill was observed and tested by Moore h Taber of
Anaheim, California, in 1985 and 1986. Their
as-graded report (Reference 2) states that the
fill was properly placed and compacted on a
correctly prepared surface. Because San Diego
Geotechnical Consultants did not observe any of
this grading, and because our scope of services
did not include subsurface exploration of the
canyon fills, our recommendations for further
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grading rely on Moore & Taber's representations
regarding fill quality. We therefore recommend
that the surface of this fill be stripped of any
loose, dry, or otherwise unsuitable soil. The
stripped fill surface should then be scarified,
moistened, and compacted in the same way as the
native soil surface prior to receiving fill.
7.3 Slope Stability
7.3.1 Bedrock and Soil Characteristics
Slope stability conditions vary greatly over the
site. Although most of the soil and rock have
moderately high shear strength, weaker rock is
present also. This weaker rock often includes
low-strength discontinuities. Nevertheless,
both the natural and man-made slopes should be
stable over the life of the project if proper
care, prudence, and skill are applied to their
construction and maintenance. The current
absence of free groundwater over most of the
site enhances the stability of slopes. Care
should be taken, though, to prevent or minimize
the development of groundwater seepage during
the post-construction period.
Soil strength parameters used in analysis were
based on laboratory test results, on data from
other local projects, and on our experience and
judgement. For silty sandstone and similar weak
rocks (mostly Santiago Formation), a cohesion of
100 psf and an effective friction angle of 31
degrees was chosen. For clayey sandstone and
claystone, a cohesion of 400 psf and a friction
angle of 26 degrees was used. Fills built from
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mixtures of these rocks were assumed to have a
cohesion of 200 psf and a friction angle of 29
degrees. For pre-sheared clay seams in the
bedrock. a residual friction angle of 12 degrees
was assumed, with no cohesion.
Cut slopes in the Santiago Peak Volcanics were
not analyzed for stability in the usual way.
The stability of hard rock slopes is controlled
by jointing. the nature of fracture fillings,
and the prsence of seepage. Analyses based on
mass strength parameters are usually misleading
because they do not account for the geometry or
mechanisms of rock failure. Accordingly, the
stability of the rock slopes was judged on the
basis of experience and local practice.
7.3.2 Cut and Fill Slopes
The proposed fill and cut slopes will mostly be
built to maximum heights of about 40 feet. We
assume that they will be built at slope ratios
of 2.0 (horizontal) to 1.0 (vertical), will have
level surfaces behind their crests, will not be
subject to significant surcharge loads, and will
not become saturated. Under these assumptions,
the slopes may be built to the following maximum
heights :
Slope Type and Material Slope Height, Feet
Cut; Silty Sandstone (Tsa) 51
Cut; Clayey Rocks (Tsa) 83
Fill; Mixed Soils 72
These heights are based on Taylor's charts, with
static factors of 1.5. They therefore should
meet local state-of-practice standards for slope
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stability. Slopes not conforming to the stated
assumptions should be individually studied prior
to construction of the buildings. Cut slopes in
Santiago Peak Volcanic rocks should be stable to
heights of at least 35 to 40 feet. As discussed
above, though, the stability of these hard rock
slopes will depend heavily on structural factors
that must be assessed during grading.
Two atypical slopes have been planned for the
site. In the eastern part of the tract, along
Palomar Airport Road, a fill slope will rise up
to about 65 to 70 feet above the valley floor.
In its highest section. the slope gradient will
be 3:l (horizonta1:vertical). with an eight-foot
bench at a height of 40 feet. This slope should
have a factor of safety of at least 1.5, subject
to the assumptions stated above. However, the
factor of safety against a toe failure should be
reassessed during grading if high groundwater
levels will prevent full removal of alluvium or
saturate the toe.
The second atypical slope is in the eastern part
of the site, where the north property line abuts
the developed part of the airport. A planned
slope about 30 to 32 feet high will be cut down
from the property line, just below an existing
fill slope. This cut slope should be stable if
no presheared clay seams are present and if the
other assumptions stated above are met. If not,
though, mitigation measures may be needed.
Despite the overall stability of the slopes,
some erosion, ravelling, or thin surficial
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sliding may occur on otherwise stable slopes if
they are not well vegetated or maintained after
construction. Groundwater seepage, fractures
and other unfavorable geologic structures, or
variations in soil and rock properties may lower
the stability of cuts greatly. Such conditions
usually can be assessed only when soil and rock
is exposed during grading. For this reason, San
Diego Geotechnical Consultants personnel should
observe all slopes during grading to evaluate
the geologic conditions.
In particular, cut slopes in clayey rocks of the
Santiago Formation are very likely to contain
weak seams of soft, pre-sheared clay. Multiple
seams were found in our drillholes B-1 and B-3,
in the center of Unit 2 (Figure 3). Similar
conditions were reported throughout Unit 1, and
stabilization or buttress fills were constructed
on most of the larger cut slopes in that unit.
The diversity of slope heights and orientations,
and the unknown number, Location, and attitudes
of the clay seams present, require an assumption
that most cut slopes in Santiago Formation rock
will require stabilization or buttressing.
7.3.3 Stabilization and Buttress Fills
Given the information now known, stabilization
or buttress fills probably will be needed on
most of the cut slopes in Santiago Formation
rocks. Moore h Taber noted that the slopes cut
along Camino Vida Roble during the grading of
Unit 1 would need stabilization (Reference 2).
Observations in drillholes B-1 and B-3 indicate
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that almost any cut slope in the central part of
the site may need stabilization as well. Clay
seams in Santiago Formation rocks may be less
common in the east part of the site. However,
observations during grading may identify such
seams in that area as well.
For planning purposes, it should be assumed that
stabilization fills at least 15 feet wide will
be required at all significant cut slopes in the
Santiago Formation. Typical details of buttress
and stabilization fills can be found in Appendix
D. The actual size and extent of stabilization
fills and buttresses should be designed during
grading, when geologic conditions are adequately
exposed. We recommend that false cuts be used
to construct the cut slopes. so that geologic
conditions can be mapped and assessed before the
final cuts are made. If the presence or nature
of the clay seams cannot be properly assessed
from the false cuts, large-diameter boreholes
should be drilled and logged at critical points.
Careful planning and coordination between the
contractor and the geotechnical engineer will be
needed so that this work can be done without
undue expense and delay. In the case of slopes
along the north property line, very little room
exists in which to build buttresses and slope
failures might damage airport facilities. We
recommend that contingency plans for modifying
the grading in this area be made in advance, in
the event that stabilization is needed.
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7.3.4 Fill-over-cut Slopes
Where fill-over-cut slopes are proposed, the cut
portion should be finished before fill placement
begins. A keyway, at least one equipment-width
wide (about 12 to 15 feet), should be built at
the cut/fill contact. Also, a subsurface drain
should be placed along the rear of the keyway.
The drain may consist of perforated PVC pipe
surounded by gravel or crushed rock and wrapped
with geofabric. This drain should lap up onto
the rear of the keyway at least six inches above
the cut/fill contact. Alternative drain designs
should be submitted to San Diego Geotechnical
Consultants for review prior to use.
7.3.5 Construction Slopes
In the absence of surcharge loads, groundwater
seepage, or presheared clay seams, temporary
excavations and slopes may be cut to the slope
ratios and heights listed below:
Slope Ratio Height of Slope, Feet
(Horiz. :Vert .) - Fill Qal Jsp
Vertical 4 3 4 4
0.75: 1 .O 26 7 15 10
1 .oo: 1 .o 44 11 26 20
1.25: 1.0 " 20 48 --
Slopes higher than those listed above should be
built on the basis of specific recommendations
made by the geotechnical engineer.
If surcharge loads (such as equipment, material
stockpiles, or spoil banks) are placed along the
edges of excavations or slopes, the slope ratios
should be flattened from those given above. For
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planning purposes, we recommend flattening when
surcharge loads fall within a zone defined by a
1:l plane rising from the nearest bottom corner
of the excavation or slope. Contact San Diego
Geotechnical Consultants if such surcharges will
exist for specific recommendations.
Water should not be allowed to flow freely over
the tops of temporary slopes. Workmen should be
protected from the local ravelling and surficial
sliding that may still occur at the slope ratios
listed above. Temporary slopes and excavations
subjected to severe vibratory loads should be
analyzed for dynamic stability. All temporary
excavations should meet at least the minimum
requirements of applicable occupational safety
and health standards. San Diego Geotechnical
Consultants should be contacted for further
recommendations if soil conditions are found
that deviate from those assumed or if evidence
of instability appears at the site.
7.3.6 Natural Slopes
With the existing slope ratios and groundwater
conditions. the natural slopes on and near this
site presently appear stable. If drainage is
provided and the grading recommendations in this
report are observed, development of this tract
or adjoining properties should not cause these
slopes to become unstable. However, we should
review this conclusion when grading plans are
complete and during the grading operation.
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7.3.7 Slope Protection and Maintenance
Although graded slopes on this site should be
grossly stable if built in accordance with the
recommendations in this report, the soils will
be somewhat erodible. For this reason, the
finished slopes should be planted as soon as
practical after the end of construction.
Preferably, deep-rooted plants adapted to semi
arid climates should be used. In addition,
runoff water should not be permitted to drain
over the edges of slopes unless the water is
confined to properly designed and constructed
drainage facilities.
7.4 Settlement Considerations
Both the weight of the new fill and the loads imposed
by buildings and structures will produce settlement.
Some degree of settlement will occur in compacted fill
and in the underlying native soil and rock. However,
settlements within rock of the Santiago Formation and
the Santiago Peak Volcanics should be negligible. If
compressible soils are properly removed and replaced
with compacted fill, settlements within the native
materials should not be significant.
If groundwater prevents the full removal of alluvium or
other compressible soils from beneath fills, buildings
or other settlement-sensitive structures should not be
built until primary settlement of both the alluvium and
the fill is essentially complete. Settlement monuments
should be installed at the base of fills and surveyed
at intervals during and after fill placement if more
than five feet of alluvium will remain in place. San
Diego Geotechnical Consultants can then review the
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survey data to evaluate the progress of settlement.
Our experience in the area is that settlementls,
buildings or other settlement-sensitive structures
should not be built until primary settlement of both
the alluvium and the fill is essentially complete.
Settlement monuments should be installed at the base of
fills and surveyed at intervals during and after fill
placement if more than five feet of alluvium will
remain in place. San Diego Geotechnical Consultants
can then review the survey data to evaluate the
progress of settlement. Our experience in the area is
that settlement is largely complete within three to
four months after completion of the fill.
Compacted fills normally settle under their own weight
by approximately 114 percent to 112 percent of their
original height following construction. Although much
of this settlement occurs during the construction
period, the structures planned for this site should be
designed to withstand settlements of this magnitude.
Compaction of the fill at water contents above optimum
should minimize the potential for future settlements if
the fill later becomes saturated. If the settlement of
the fill under its own weight is not tolerable, the
total amount of settlement affecting structures can be
reduced by delaying construction of buildings until the
settlement is largely complete. This will require that
settlement monuments. like those described above, be
installed and monitored. Settlement monuments may also
be used if there is any question as to the ability of
the fill placed during grading of Unit 1 to support new
fill without excessive settlement.
Estimates of settlement due to building loads depends
on the design of the building and on the foundation
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system selected for use. Reliable estimates therefore
cannot be made until foundation investigations are made
for individual buildings. If designed for appropriate
bearing pressures, though, shallow foundations should
generate total and differential settlements that fall
within limits generally considered acceptable.
7.5 Surface and Subgrade Drainage
Foundation and slab performance depends greatly on how
well the runoff waters drain from the site. This is
true both during construction and over the entire life
of the structure. The ground surface around structures
should be graded so that water flows rapidly away from
the structures without ponding. The surface gradient
needed to achieve this depends on landscaping type.
Pavements or lawns within five feet of buildings should
slope away at gradients of at least 2 percent. Densely
vegetated areas should have minimum gradients of 5
percent away from buildings in the first five feet if
it is practical to do so. Terrace drains should be
constructed on fill slopes at intervals not exceeding
30 to 40 vertical feet. The benches for terrace drains
should be at least six feet wide. Drainage facilities
should be regularly maintained, cleaned, and repaired
so that they will function properly.
Planters should be built so that water from them will
not seep into the foundation areas or beneath slabs and
pavements. Maintenance personnel should be instructed
to limit irrigation to the minimum actually necessary
to properly sustain the landscaping plants. Should
excessive irrigation, waterline breaks, or unusually
high rainfall occur. saturated zones and "perched"
groundwater may develop in the soils. Consequently,
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the site should be graded so that water drains away
readily without saturating foundation or landscaping
areas. Potential water sources, such as water mains,
drains, and pools, should be frequently examined for
signs of leakage or damage. Any such leakage or damage
should be repaired promptly.
Subdrains should be installed at the base of fills
placed in drainageways or over areas of actual or
potential seepage. The general locations of subdrains
should be indicated on the grading plans. Specific
locations should be determined in the field during
grading, with installations being reviewed by San Diego
Geotechnical Consultants prior to the fill placement.
Appendix'D includes typical details of subdrains.
Subdrain pipes may be of coated metal, plastic, or
other corrosion-resistant materials. The pipe should
have adequate structural strength to withstand the
loads imposed by fills, structures, and live loads.
The recommended subdrain type consists of a perforated
pipe surrounded by free-draining gravel or crushed
rock. The rock, in turn, is wrapped with geofabric.
We recommend the following pipe sizes for the drains:
Total Run Length Pipe Diameter
0 - 400 ft. 4 in.
400 - 800 ft. 6 in.
More than 800 ft. 8 in.
About nine cubic feet of rock should be used for each
lineal foot of subdrain. The gravel or crushed rock
should be a nondegrading, durable, open-graded material
with a maximum grain diameter of 1.0 to 1.5 inches. It
should not have more than three percent (by weight) of
fines passing the No. 200 U.S. Standard sieve, as
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placed. The fines should not have a plasticity index
(ASTM D 4318-84) greater than 4.0. The geofabric
should be a high-permeability, nonwoven fabric such as
Mirafi 140N. Propex 4545, or Typar 3201. The outlets
of subdrains should be mapped at the end of grading and
accurately shown on the as-built plans. Thereafter.
the outlets should be cleaned and repaired at frequent
intervals to prevent burial or blockage.
7.6 Foundation Recommendations
Bearing capacities, foundation dimensions, pressures on
retaining walls, and other foundation recommendations
depend on structural details of the specific buildings
to be constructed and on economic and constructability
concerns. As the individual lots in Unit 2 will be
marketed for ultimate development by others, detailed
recommendations are premature at this point. Separate
foundation investigations should be made for each lot
when it is developed. The foundation recommendations
can then be guided by the specific requirements of each
building and structure.
In general, the building pads should be suitable for
the support of moderate foundation loads typical of
one- and two-story concrete tilt-up structures. The
allowable bearing capacities for conventional spread
footings and strip footings should be at least 2000
psf. Foundation costs can be minimized if (1) the lots
are capped with at least 3 feet of nonexpansive or low-
expansive soil, and (2) buildings are not located over
transitions from bedrock to fill or over areas where
large changes in fill depth occur across the building
footprint. Both of these provisions are incorporated
into the recommendations of this report.
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7.7 Reactive Soils
Based on chemical tests and our experience with similar
soils, either Type I or Type 11 Portland cement may be
used for concrete in contact with the soil. However,
the absence of water-soluble sulfates in the soil and
rock should be confirmed at the completion of grading.
7.8 Pavements
R-value tests were not made because the soil types in
the subgrades of streets and parking areas will not be
known until grading is complete. It is conservative to
assume, however, that relatively poor subgrades and
thick pavement sections will be needed. For traffic
indices of 7.0, 8.0, and 8.5 which are typical for the
street areas, the following pavement sections can be
used for planning purposes:
Traffic Index 7.0 8.0 8.5
R-value 10.0 10.0 10.0
Pavement Thickness 4" 4" 5 "
Aggregate Base 14.5" 1 8" 18"
Total Thickness 18.5" 22" 23"
These sections indicate that streets should be kept
about two feet low during rough grading to accommodate
the pavement sections. Please note that these pavement
sections may not be the final ones used and that actual
sections will vary across the site. R-value tests
should be performed after grading for final design of
pavement sections. The pavement subgrades should be
prepared as recommended in Section 7.2.3 and compacted
to at least 90 percent of the Modified Proctor maximum
dry density (ASTM D 1557-78). Aggregate base course
should conform to the CALTRANS Standard Specifications
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Job NO. 05-4879-011-00-00 Log NO. 8-1797 Page 36
for Class I1 base. and should be compacted to a minimum
relative compaction of 95 percent.
If rigid pavements are required at loading docks or
trash enclosures. we recommend a full-depth Portland
cement concrete section with a minimum thickness of six
inches. The concrete should be durable and resistant
to scaling, with a modulus of rupture equal to at least
600 pounds per square foot. We further recommend that
#3 deformed steel reinforcement bars be placed on 18-
inch centers in both directions for crack control.
Steel dowels should be installed at all cold joints,
and contraction joints should be placed at spacings of
25 feet.
7.9 Review of Grading Plans
San Diego Geotechnical Consultants should review the
grading plans for the proposed development prior to
construction. This review will allow us to assess the
compatibility of those plans with the recommendations
in this report. If the final plans differ materially
from our present understanding of the project, further
investigation and analysis or recommendations for
design changes may be necessary.
8.0 LIMITATIONS OF INVESTIGATION
Our investigation was performed using the degree of care and
skill ordinarily exercised, under similar circumstances, by
reputable soils engineers and geologists practicing in this
or similar localities. No other warranty, expressed or
implied, is made as to the conclusions and professional
advice included in this report.
Centre Development
July 29, 1988
Job NO. 05-4879-011-00-00 Log NO. 8-1797 Page 37
The samples taken and used for testing and the observations
made are believed typical of the entire project. However,
soil and geologic conditions can vary significantly between
drillholes, test pits, or other exploration locations. As
in most projects involving earthwork, the conditions
revealed by excavation during construction may vary from
those predicted in our preliminary findings. If such
changed conditions are found, they should be evaluated by
the project soils engineer and geologist. It may then be
necessary to adjust the project designs or to recommend
alternate designs.
This report is issued with the understanding that the owner,
or his representative, is responsible for bringing the
information and recommendations contained herein to the
attention of the architects and engineers involved in the
project. The owner or his representative is also
responsible for assuring that the information and
recommendations are incorporated into the plans, and that
the necessary steps are taken to see that the contractor and
subcontractors carry out the recommendations in the field.
This firm does not practice or consult in the field of
safety engineering. We do not direct the contractor's
operations, and we cannot be responsible for anyone other
than our own personnel on the jobsite. Therefore, the
safety of other persons at the jobsite is the responsibility
of the contractor. The contractor should notify the owner
promptly if he considers any of the recommendations in this
letter to be unsafe.
Our findings in this report are valid as of the date of
issue. However, changes in the condition of a site can
occur with the passage of time, due either to natural
processes or the works of man on this or adjacent
Centre Development July 29, 1988
Job NO. 05-4879-01 1-00-00 Log NO. 8-1797 Page 38
properties. In addition, changes to the applicable or
appropriate laws, regulations, and standards of practice may
occur as a result of either new legislation or the
broadening of knowledge. Our findings may be invalidated
wholly or in part by such changes, over which we have no
control. The validity of this report therefore should not
be relied upon after a period of three years without a
comprehensive review by San Diego Geotechnical Consultants.
***
- SAN DIEGO GEOTECHNICAL CONSULTANTS, INC.
- k e, d-
Patrick A. Thomas - Staff Geologist P.E. C 43422, Registration Expires: 6-30-92 C.E.G. 1355, Registration Expires: 6-30-90 Senior Engineer
"
..
No. 1355 CERTIFIED
GEOLOGIST Anthony F. Belfast, P.E. Principal Engineer ENGINEERING
PAT/RNM/AFB/rm/pb
APPEUDIX A
References
References
1. H. V. Lawmaster h Company, Inc., 1980, Preliminary
Geotechnical Investigation, Proposed Palomar Business
Park, North San Diego County, California: Unpublished
report no. 79-939416546 to Palomar Business Park, January
15, 1980 (includes grading plan review letters dated June
8. 1982 and September 27, 1982).
2. Moore h Taber, 1987, Report of Geotechnical Services,
Carlsbad Tract No. 81-46, Airport Business Center, Unit
No. 1, City of Carlsbad, California: Unpublished report
to Centre Development Company, February 25, 1987.
3. Bonilla, M. G., 1970, Surface Faulting and Related Effects, - in Wiegel, R. L. (ed.), Earthquake Engineering: Engle-
wood Cliffs, New Jersey, Prentice-Hall, p. 47-74.
4. Seed, H. B., and Idriss, I. M., 1982, Ground motions and soil
liquefaction during earthquakes, Earthquake Engineering
Research Institute, Monograph Series.
5. Ploessel, M. R., and Slosson, J. E., 1974, Repeatable high
ground accelerations from earthquakes, California
Geology, September.
6. California Division of Mines and Geology, 1975, Recommended
Guidelines for Determining the Maximum Credible and the
Maximum Probable Earthquakes: California Division of
Mines and Geology Notes, Number 43.
APPEBDIX B
Field Exploration
.. .
DEFINITION OF TERMS
SILTS AND CLAYS
LIQUID LIMIT IS
LESS THAN SO%
GRAIN SIZES
ILTS AND CLAYS SAND I QAAVEL
FINE I MEDIUM I COARSE I FINE I COARSE COBBLES BOULDERS
200 40 10 4 314' 3' 12. u.a STANDARD SERIES SIEVE CLEAR SQUARE SIEVE OPENINQE
p QROUNDWATER LEVEL AT TIME OF DRILLINQ.
QROUNDWATER LEVEL MEASURED LATER IN STANDPIPE.
LOCATION OF SAMPLE TAKEN USINQ A STANDARD SPLIT TUBE SAMPLER.
2-INCH O.D.. 1-318-lNCH I.D. DRIVEN WITH'A 14O.POUND HAMMER FALLINQ
30-INCHEB.
LOCATtQN OF SAMPLE tAKEN.USlNQ A MODIFIED CALIFORNIA SAMPLER.
3-118-INCH O.D.. WITH 2-112-INCH I.D. LINER RINQS. DRIVEN USINQ THE
WEIQHT OF KELLY BAR (LARQE DIAMETER BORINQS) OR USINQ A 140 POUND
HAMMER FALLlNQ 30-tNCHES (SMALL DIAMETER BORINQ):
LOCATION OF SAMPLE TAKEN USINQ A 3-INCH 0.0. THIN-WALLED TUBE SAMPLER
(SHELBY TUBE) HYDRAULICALLY PUSHED.
LOCATION OF BULK SAMPLE TAKEN FROM AUQER CUTTINQS.
m
LOG OF BORING NO. 1
Sheet 1 of 2
DESCRIPTION
TOPSOIL: Medium brown clayey SAND,
dry to damo. loose, fine grained
SANTIAGO FORMATION ITsak Light brown silty SANDSTONE, damp to moist,
dense, orange iron oxide staining
(mottled), fine grained, laminated,
moderately weathered, friable, N20E/2OE
@ 6' remolded clay seam about 3" thick, some caliche, clay is dark olive-gray, moist, soft to firm, NSOE/3S, wavey
@ 8' sandstone becomes light grey with
yellow sulfide stain, changes to sandy silt
CONTACT: N4OW/9S I
Olive-grey sandy CLAYSTONE, damp to
staining and yellow sulfide staining
moist, firm to stiff, orange-red iron oxide
CONTACT: N80E/10 NW 1
)ATE OBSERVED: 6-30-88 METHOD OF DRILLING: 30" Bucket A
I ELEVATIOM298.0' LOCATION: See Geotechn
0'-24':2218 1I:
i
I ! i -
"
k
- -
-
- - 1
"
n - -
R Diego Geotechnical Consultants, Inc. I B-:
Medium brown clayey SANDSTONE, damp to moist, medium dense, fine grained, some
@I 15.5 joint fracture, N25W 55 SW
gypsum in fractures
@ 19.0' Remolded clay seam about 3"
thick, olive-gray sandy clay with iron (oxide stain, N5OW 5 I
Light grey silty SANDSTONE, damp to
thin bedded to laminated, moderately moist, dense to very dense, fine grained,
@I 25' becomes medium brown to light
weathered, well indurated, sulfide staining
grey, cross laminae N90E 5 S
@ 28.5' gypsum seam, 1/2" thick, continuous, horizontal
@I 30' less brown coloration; mostly light olive-grey, cross lamiiae (sulfide and iron oxide stained) N80E 10 NW
@ 35' dark grey sandy CLAY, damp to
moist, very dense to hard, very fine ,grained, some yellow sulfide stain,
fracture N5OE 80 W. drilling becomes more unoxidized, slab fracture during drilling,
uxer
6 24'-44'31358 lb
lcal Mao
SOIL TEST
herberg Limits
5xpansion Index
LOG OF BORING NO. 1
Sheet 2 of 2
DISCRIPTION
\Minor seepage at 39'
Total Depth: 40'
Minor seepage at 39' No Caving
Geologically logged to 39'
Backfilled 6-30-88
I
umx
lical MaD
24'-44':1358 Ib
SOIL TEST
&E
00 5 LOG OF BORING NO. 2 !L Sheet 1 of 1
DESCRIPTION
moist, soft to stiff
10.0
SANTIAGO FORMATION ITsaI: Light olive-gray to medium brown sandy silty CLAYSTONE, moist, firm to Stiff,
massive, orange iron oxide staining, some
cobbles and gravel, mottled, slightly fractured - weathered to about 9'
@ 9' joint set N23W 50 N to N90W 75 SE
,CONTACT: Horizontal I
Light brown silty SANDSTONE, damp,
dense to very dense, fine grained,
fossiliferous
@ 11' fossiliferous. zone
@ 12' crossbedded sandstone dipping 5
degrees to SW, S I5 W
@ 13' clay seam horizontal
CONTACT: N60W, 15 S, gypsum filling I I
@ 16' Olive-gray sandy CLAYSTONE,
moist, stiff, some brown color
@ 20' some iron oxide and sulfide staining
and gypsum concretion
~~
]thick, gypsum at contact
@ 25' fossiliferous cemented zone about 6" I
~~ ~~~
Dark grey sandy CLAYSTONE, damp to
fracture during drilling, unoxidized, well
moist, very hard, fossiliferous, slab
indurated Drilling becomes more difficuic near
refusal
Total Depth 30'
No Water No Caving Geologically logged to 30' Backfilled 6-30-88
uger
b: 24'-44':1358 Ib.
~Cal Mao
SOIL TEST
>irect Shear, Sieve
inalysis, Atterberg
.imits
iulfate
Expansion Index
L
DATE OBSERVED: 6-30" METHOD OF DRILLING 30" Bucket A1
ELEVATION280' LOCATION See Geotechn
0'-24':2218 Ib
L
LOG OF BORING NO. 3
Sheet 1 of 1
DESCRIPTION
TOPSOIL. Medium brown to dark olive gray CLAY, damp to very moist, soft, to firm
CONTACT: gradational, caliche infilled,
N70W 10 S I
SANTIAGO FORMATION (Tsal: Light olive gray white to light brown silty
SANDSTONE, damp to moist, dense, fine
to medium grained, orange iron oxide stainiig. moderately weathered, massive,
friable, cross bedded
@ 9' cross laminae, iron oxide stained, N-S
15 E, fracture, caliche infilled, N-S 73 E
@ 14' clay seam about 2"-3" thick, caliche
infiied, slightly undulating
CONTACT: generally horizontal I
Olive-gray clayey SANDSTONE, damp to moist, very dense, fine-grained, iron oxide mottling, well indurated
@ 18' clay seam, 2"-3" thick, remolded,
wet, generally horizontal
@ 20.5' clay seam slightly remolded at
sandstone contact, horizontal
@ 23' clay bed
@ 30' gypsum concretions, dark charcoal brown with caliche infilled fractures and iron oxide borders
Total Depth 35'
Geologically Logged to 35'
No Caving No Seepage
"
user
ical Ma0 .: 24'-44':1358 lb.
SOIL TEST
Xrect Shear, Sieve lnalysis
LOGGED BY:
LOG OF BORING NO. 4
Sheet 1 of 2
DESCRIPTION
mL: Medium brown SAND, dry to damp, loose to medium dense, fine grained
DATE OBSERVED: 6-28-88 METHOD OF DRILLING: 8" Hollow SI
1 ELEVATION:= LOCATION: See Geotech 140 Ib. Ham
I
-.
ALLUVIUM lOalk Medium brown
clayey SAND, moist, stiff
Medium brown clayey SAND, damp,
medium dense, fine grained
"_"""-"""""""""
Sampler bouncing on quartz gravel clast
55"38'
tem Auzer
mer. 30" Fall nical MaD
SOIL TEST
Consolidation, Sieve
Analysis, Atterberg Limits
iANTIAGO FORMATION ITsak
- PA
DATE OBSERVED 6-28-88 METHOD OF DRILLING: 8" Hollow Stem Auger
OUND ELEVATI0N:m LOCATION: See Geotechn 140 Ib. Hammer: 30" Fall . gc I 02 LOG OF BORING NO. 4
i
- w"
. n;
i jE
I Zfi
Sheet 2 of 2
DESCRIPTION
damp to moist, very dense, fine grained, I micaceous
I Total Depth' 42'
Backfilled 6-28-88
No Water
ical Ma0
SOIL TEST
DATE OBSERVED: 6-28-88 METHOD OF DRILLING 8" Hollow
LOGGED BY:& L I
140 Ib. H
LEVATION232LT LOCATION See Geote
LOG OF BORING NO. BW-1
Sheet I of 2
DESCRIPTION
COLLUVIUM.
dry to damp, loose. fine grained . Medium brown SAND,
I
SANTIAGO FORMATION (Ts& Light
brown SANDSTONE, damp, dense, fine grained, some silt
Dark gray CLAYSTONE, damp to moist, firm to stiff
@ 36' Medium brown CLAYSTONE, moist
to wet, soft to firm
Dark grey CLAYSTONE, moist, very dense
lieno Geotechnical Consultants.
em Auger mer: 30" Fall
niCd Mao
SOIL TEST
" San
;EVATION2$0.0' LOCATION See Geote
140 Ib. Hr
LOG OF BORING NO. BW-1
Sheet 2 of 2
DESCRIPTION
Total Depth: 51' No Caving
Seepage @ 36'
Well Installed 6-28-88 by Hydrotech. All
samples by Hydrotech.
SOIL TEST
"
-
- iesro Geotechnical Consultants, Inc.
LoGGl t LOG OF BORING NO. BW-2
Sheet 1 of I
DESCRIPTION
FILL: Medium brown SAND, dry to
damp, loose, fine grained
DATE OBSERVED: 6-28-88 METHOD OF DRILLING: 8" Hollow Ste
140 Ib. Hamn
ALLUYIUM IOalk Dark brown sandy
CLAY, moist to wet, soft, strong petroleum odor
SANTIAGO FORMATION [Tsa): Olive-gray CLAYSTONE, moist, soft to
firm, some yellow staining
Total Depth 16.5
No Water Well installed 6-28-88 by Hydrotech
:m Auger lex 30" Fall
ical Ma0
SOIL TEST
DATE OBSERVED: 6-28-88 METHOD OF DRILLING 8" Holloa
140 Ib. H
LEVATION238.0' LOCATION See Geotc
LOG OF BORING NO. BW-3
Sheet 1 of 1
DESCRIPTION
____ FILL: Medium brown SAND, dry to
damp, loose, some roots and organic debris,
fine grained
ALLUVIUM (Oalk Medium gray to medium brown clayey SAND, moist, loose, some gravel, fine grained
7 'SANTIAGO FORMATION (Tsal:
Medium brown to medium grey
SANDSTONE, moist to wet, medium dense, some orange staining, fine grained
Total Depth' 15'
Water @ 11'
Well installed 6-28-88 by Hydrotech
!go Geotechnical Consultants, I
:m Auaer
ner: 30" Fall
ucal Mao
SOIL TEST
FATE OBSERVED: 6-21-88 DRILLIN& Kubota KH 170L Tracked Hoe
,OQQED BY: PAT -
LOQQED BY: QROUND E
TEST PIT NO. 1
DESCRIPTION
WWIUM (Qal) : Light brown SAND,
damp, loose, fine grained, some rip- ~
rap and debris on surface
Dark grey sandy CLAY, wet, soft, som
seepage at 2-3', strong petroleum
odor
""
. ~" .. ~
SANTIAGO FORMATION (Tsa) : Olive-gray
sandy CLAYSTONE, mist to wet, soft
to firm, some yellow-oranqe staining
"
Total Depth: 8'
No Caving
Seepage at 2'
Backfilled 6-21-88
.
son TEST
2'
, 240' 2 See Geotechnical Map LEVATION:.
01 1-01 -
TEST PIT NO. 2
ALLWIUM (Qal): Medium brown clayey
SAND, damp to wet, loose, fine
grained
Seepage at 6'-13'
SANTIAGO FORMATION (Tsa) : Olive-gray
sandy CLAYSTONE, damp, soft to firm \
Total Depth: 13'
Seepage at 6-13'
Expansion Index
Backfilled 6-21-88 Caving
00 ILOG OF TEST PIT IFlQUW%B- 12.
1
DESCRIPTION
ALLUVIUM (Qal): Medium brown silty
SAND, dry to damp. loose, some roots and organic debris, fine grained
SANTIAGO FORMATION (Tsa): Light brown
SANDSTONE, damp to moist, medium
dense to dense, fine grained, some
orange staining
Total Depth: 9'
No Water
No Caving
:a1 Map
SOIL TEST
TEST PIT NO.4
A~LWIUM (Qal): Medium brown silty
SAND, dry to damp, loose, fine
grained
SANTIAGO FORMATION (Tsa): Medium
brown silty SANDSTONE, damp, medium
dense to dense, fine grained, some
orange staining
T cal Map
Total Depth: 9.5'
NO Water
No Caving
TOPSOIL: Dark brown sandy CLAY, damp
to moist, soft
SANTIAGO FORMATION (Tsa): Light brown
silty SANDSTONE, damp to mist, . medium dense to dense, some orange
staining, fine grained
Total Depth: 9'
No Water
No Caving
OQQED BY: QROUND ELEVATION "" LOCATION: See Geotechnical Map t TEST PIT NO.&
ALLUVIUM (Qal) : Dark brown clayey
SAND, damp to wet, loose to firm,
fine grained
SANTIAGO FORMATION (Tsa): Light brown
SANDSTONE, damp to mist, dense to
very dense, fine grained, some orange
staining
Total Depth: 8'
No Water
Backfilled 6-21-88
No Caving
Maxim density,
Direct Shear,
Sieve Analysis
DATE OBSERVED: 6-21-88
6
10
16
sc
TEST PIT NO.",
son TEST
DESCRIPTION I
ALLWIUM (Qal): Medium brown sandy
CLAY, damp to mist, soft to stiff
SANTIAGO FORMATION (Tsa) : Light
brown SANDSTONE. damp, dense to very
dense, fine grained
Total Depth: 5' I
No Water
No Caving
LOQQED BY:& QROUND ELEVATION 288' f LOCATION See Geotechnical Map
I I
TEST PIT NO. 8 - - . CLAY, damp to moist, soft to firm, sc ALLWIUM (Qal): Medium brown sandy - some gravel - -
6-
- SANTIAGO FORMATION (Tsa): Light brown SM
to gray SANDSTONE, damp to moist,
dense to very dense, some orange - - staining, fine grained
IO- - - - Total Depth: 7' - No Water
16- No Caving - -
'OB N0-:05-4879-0 1 I -00-00 I LOG OF TEST PIT IF- 8-16.
WWIUM (Qal): Medium brown silty
CLAY, damp to moist, soft to film
SANTIAGO FORMATION (Tsa) : Medium
brown SANDSTONE. dam^ to mist. densc I\ to very dense, fine grained Iā
Total Depth: 6.5ā
No Water
No Caving
Backfilled 6-21-88
IVATION LOCATION:
TEST PIT NO.
0 0 h m
0 0 I F
0
c
0 t
OD
-1 14
m
3 0
m
r
a
W -1
t
W 0
<
L 0 -1 W m
r
a t
W
> 0
0 0 -1 W >
W
t
a a c
U 0 m
n L w W LL Y 2 0
c < 0. 0 -I
W
-
m
0 I-
~. a W s
APPENDIX C
Laboratory Testing Program
Laboratory Testing Program
Typical soil samples from the site were tested to determine their
engineering properties. The test methods used conform generally
to those of the American Society for Testing and Materials (ASTM)
or those of other recognized standard-setting organizations. The
following section describes the testing program.
Classification
During fieldwork, the soil and rock was classified by the Unified
Soil Classification System (visual-manual procedure) of ASTM D
2488-84. These classifications were checked and, if necessary,
modified on the basis of laboratory test results (ASTM D 2487-
85). The logs in Appendix B show the classifications.
Atterberg Limits
ASTM D 4318-84 was used to determine the liquid limit, plastic
limit. and plasticity index of three selected clayey samples.
Figure C-1 shows the results.
Particle Size Analysis
Mechanical analyses of particle-size distribution, as described
in ASTM D 422-63, were made on four selected samples. Figures C-
2 through C-5 show the results.
Direct Shear
Consolidated, drained, direct shear tests (ASTM D 3080-72) were
made on two relatively undisturbed samples of Santiago Formation
rocks from drillholes B-2 and B-3. The test results are plotted
on Figure C-6. Tests were also made on a Santiago Formation
sample from test pit TP-6 that had been remolded to 90 percent of
the modified Proctor maximum dry density. The results of these
tests are shown on Figure C-7. All three tests were made under
saturated conditions and were carried out to measure ultimate
strength values.
Laboratory Testing Program
(Continued)
Consolidation Tests
To assess its compressibility when loaded and wetted, a sample of
alluvium from drillhole B-4 was subjected to a consolidation test
(ASTM D 2435-80). Figure C-8 shows the results.
Maximum Density/Optimum Moisture Content
The moisture - density relationship for one sample of Santiago
Formation rock from test pit TP-6 was determined using AS" D
1557-78. Table C-1 lists the test results.
Expans ion
The expansion potential of two samples of Santiago Formation rock
from drillholes B-1 and B-3. and of one sample of surficial soil
from test pit TP-6, was tested using the UBC 29-2 expansion index
method. Table C-2 lists the results.
Sulfate Content
A sample of Santiago Formation rock from drillhole B-2 was tested
for water-soluble sulfate minerals with CALTRANS Method 417 (Part
I). The results are listed in Table C-3.
PLASTICITY CHART
LIQUID LIMIT (%I
UNIFIED
No. *O0 INDEX CLASS+
SYMBOL
SIEVE FlCATlON
68.0 -0.1 e CL
ATTERBERG LIMITS
IB NO: OS-4879-Ot1-00-00 DATE: FIQURE:
C- 1
- PERCENT PASSINQ
PERCENT PASSINQ
NO.: i-4879-011-00-00 PARTICLE SIZE ANALYSIS FIQURE: c-2
PERCENT PA881NQ
PERCENT PA881NO
36 NO.: 95-4870 - 011 " QO OQ PARTICLE SIZE ANALYSIS FIBURE -
PERCENT PASSINQ
PERCENT PASSINO
PERCENT PA881NQ
PERCENT PA881NQ
JOB NO.: 06-4879-011-00-00 PARTICLE SIZE ANALYSIS FIQURE: c-6
I I 1 I I 1000 2000 3000 4000 6000
NORMAL LOAD (PSn . Doa
18 NO.: - 79-~~1-~0-~0 FIQURE: SHEARING STRENGTH TEST c-6
NORMAL LOAD (PSn
OB NO.: os-4870-011 - 00 - 00 I SHEARING STRENGTH TEST FIOURE: -
INITIAL DENSITY (PCF)
10.8 INITIAL MOISTURE (%I
EXPLANATION 80.7
FIELD MOISTURE
FINAL MOISTURE (%) I 19.8
INITIAL VOID RATIO 10.710
""""" SAMPLE SATURATED
I I I REBOUND
4.0
2.0
4.0
0.0
CI s
z
c 0
P
m
10.0
g 12.0
0
20.00 I
0 a 0 0 00
2
1 1 8 000 0 00
0 0 00 ru o*o
NORMAL LOAD (PSn
DB NO.: 06-4879-011-00-00 I LOAD CONSOLIDATION TEST FIQURE: -
TABLE C-1
MAXIMUM DENSITY/OPTIMUM MOISTURE RELATIONSHIPS
(ASTM D 1557-78)
Sample Optimum Moisture Maximum Dry
Location Content (%) Density (pcf)
TP-6 @ 5.0-6.0 13.7 113.8
TABLE c-2
RESULTS OF EXPANSION TESTS
(UBC Method 29-2)
Sample
Potential Index Location
Expansion Expansion
B-1 @ 20.0"21.0'
Medium 85 TP-6 @ 1.0"2.0'
Low 24 B-2 @ 30.0'-31.0'
Low 30
TABLE C-3
RESULTS OF SOLUBLE SULFATE TESTS
(EPA 300)
Sample Location Soluble Sulfates (X)
B-2 @ 20.0'-21.0' 0.0797
APPJIHDIX D
Standard Guidelines for Grading Projects
- STANDARD GUIDELINES FOR GRADING PROJECTS
- 1. GENERAL
1.1
1.2
1.3
1.4 -
- 1.5
1.6
-
Representatives of the Geotechnical Consultant should be present on-site during grading operations in order to make observations and perform tests so that professional opinions can be developed. The opinion will address whether grading has proceeded in accordance with the Geotechnical Consultant's recommendations and applicable project specifications; if the site soil and geologic conditions are as anticipated in the preliminary investigation: and if
unexpected site conditions. Services do not include additional recommendations are warranted by any
supervision or direction of the actual work of the contractor, his employees or agents.
The guidelines contained herein and the standard details attached hereto represent this firm's standard
recommendations for grading and other associated operations on construction projects. These guidelines should be considered a portion of the report to which they are appended.
All plates attached hereto shall be considered as part of these guidelines.
without prior recommendation by the Geotechnical The Contractor should not vary from these guidelines
Consultant and the approval of the Client or his authorized representative.
These Standard Grading Guidelines and Standard Details may be modified and/or superseded by recommendations contained in the text of the preliminary geotechnical report and/or subsequent reports.
If disputes arise out of the interpretation of these grading guidelines or standard details, the Geotech- nical Consultant should determine the appropriate interpretation.
- 2. DEFINITIONS OF TERMS
2.1 ALLUVIUM -- Unconsolidated detrital deposits resulting - from flow of water, including sediments deposited in river beds, canyons, flood plains, lakes, fans at the foot of slopes and estuaries.
- Standard Guidelines for Grading Projects Page 2
2.2
2.3
2.4
2.5
2.6
2.7
2.8
2.9
2.10
2.11
2.12
AS-GRADED (AS-BUILT) -- The surface and subsurface conditions at completion of grading.
BACKCUT -- A temporary construction slope at the rear of earth retaining structures such as buttresses, shear keys, stabilization fills or retaining walls.
BACKDRAIN -- Generally a pipe and gravel or similar drainage system placed behind earth retaining structures such buttresses, stabilization fills, and retaining walls.
BEDROCK -- A more or Less solid, relatively undis- turbed rock in place either at the surface or beneath
superficial deposits of soil.
BENCH -- A relatively level step and near vertical
be placed. rise excavated into sloping ground on which fill is to
BORROW (Import) -- Any fill material hauled to the
project site from off-site areas.
BUTTRESS FILL -- A fill mass, the configuration of which is designed by engineering calculations to
retain slope conditions containing adverse geologic
minimum key width and depth and by maximum backcut features. A buttress is generally specified by
angle. A buttress normally contains a backdrainage system.
CIVIL ENGINEER -- The Registered Civil Engineer or consulting firm responsible for preparation of the grading plans, surveying and verifying as-graded topographic conditions.
COLLUVIUM -- Generally loose deposits usually found near the base of slopes and brought there chiefly by gravity through slope continuous downhill creep (also see Slope Wash).
COMPACTION -- Is the densification of a fill by mechanical means.
CONTRACTOR -- A person or company under contract or otherwise retained by the Client to perform demolation. grading and other site improvements.
." Standard Guidelines
for Grading Projects Page 3
-
2.13
2.14
2.15
2.16
2.17
2.18
2.19
2.20
2.21
2.22
2.23
DEBRIS -- All products of clearing, grubbing, demolition, contaminated soil material unsuitable for reuse as compacted fill and/or any other material so designated by the Geotechnical Consultant.
ENGINEERING GEOLOGIST -- A Geologist holding a valid
certificate of registration in the specialty of Engineering Geology.
ENGINEERED FILL -- A fill of which the Geotechnical Consultant or his representative, during grading, has made sufficient tests to enable him to conclude that the fill has been placed in substantial compliance
with the recommendations of the Geotechnical Consultant and the governing agency requirements.
result of the movement of wind, water, and/or ice. EROSION -- The wearing away of the ground surface as a
EXCAVATION -- The mechanical removal of earth materials.
EXISTING GRADE -- The ground surface configuration prior to grading.
or other similar materials placed by man. FILL -- Any deposits of soil, rock, soil-rock blends
which time the surface elevations conform to the FINISH GRADE -- The ground surface configuration at
approved plan.
GEOFABRIC -- Any engineering textile utilized in geotechnical applications including subgrade stabilization and filtering.
GEOLOGIST -- A representative of the Geotechnical Consultant educated and trained in the field of geology.
GEOTECHNICAL CONSULTANT -- The Geotechnical Engineer- ing and Engineering Geology consulting firm retained to provide technical services for the project. For the purpose of these guidelines, observations by the Geotechnical Consultant include observations by the Geotechnical Engineer, Engineering Geologist and those performed by persons employed by and responsible to the Geotechnical Consultants.
- Standard Guidelines for Grading Projects
-
Page 4
2.24
2.25
2.26
2.27
2.28
2.29
2.30
2.31
2.32
2.33
2.34
GEOTECHNICAL ENGINEER -- A licensed Civil Engineer who applies scientific methods, engineering principles and
professional experience to the acquisition, inter- pretation and use of knowledge of materials of the earth's crust for the evaluation of engineering problems. Geotechnical Engineering encompasses many of the engineering aspects of soil mechanics, rock mechanics, geology, geophysics, hydrology and related sciences.
GRADING -- Any operation consisting of excavation, filling or combinations thereof and associated operations.
LANDSLIDE DEBRIS -- Material, generally porous and of low density, produced from instability of natural of
man-made slopes.
MAXIMUM DENSITY -- Standard laboratory test for maximum dry unit weight. Unless otherwise specified,
accordance with ASTM Method of Test D1557. the maximum dry unit weight shall be determined in
OPTIMUM MOISTURE -- Test moisture content at the maximum density.
RELATIVE COMPACTION -- The degree of compaction
material as compared to the maximum dry unit weight of (expressed as a percentage) of dry unit weight of a
the material.
ROUGH GRADE -- The ground surface configuration at
which time the surface elevations approximately conform to the approved plan.
SITE -- The particular parcel of land where grading is being performed.
generally constructed by excavating a slot within a SHEAR KEY -- Similar to buttress, however, it is
natural slope in order to stabilize the upper portion of the slope without grading encroaching into the lower portion of the slope.
of which is generally specified as a ratio of SLOPE -- Is an inclined ground surface the steepness
horizonta1:vertical (e.g.. 2:l).
SLOPE WASH -- Soil and/or rock material that has been transported down a slope by mass wasting assisted by
Colluvium). runoff water not confined by channels (also see
-. Standard Guidelines for Grading Projects Page 5
2.35 -
2.36
2.37
-
2.38
2.39
2.40
2.41
-
2.42
- 2.43
SOIL -- Naturally occurring deposits of sand, silt, clay, etc., or combinations thereof.
SOIL ENGINEER -- Licensed Civil Engineer experienced
in soil mechanics (also see Geotechnical Engineer).
STABILIZATION FILL -- A fill mass, the configuration of which is typically related to slope height and is specified by the standards of practice for enhancing the stability of locally adverse conditions. A
key width and depth and by maximum backcut angle. A
stabilization fill is normally specified by minimum
stabilization fill may or may not have a backdrainage system specified.
SUBDRAIN -- Generally a pipe and gravel or similar drainage system placed beneath a fill in the alignment of canyons or former drainage channels.
during grading operations. SLOUGH -- Loose, noncompacted fill material generated
TAILINGS -- Nonengineered fill which accumulates on or adjacent to equipment haul-roads.
TERRACE -- Relatively level step constructed in the face of graded slope surface for drainage control and maintenance purposes.
TOPSOIL -- The presumably fertile upper zone of soil which is usually darker in color and loose.
WINDROW -- A string of large rock buried within engineered fill in accordance with guidelines set
forth by the Geotechnical Consultant.
3. SITE PREPARATION
3.1 Clearing and grubbing should consist of the removal of vegetation such as brush, grass, woods, stumps, trees,
materials from the areas to be graded. Clearing and roots to trees and otherwise deleterious natural
grubbing should extend to the outside of all proposed excavation and fill areas.
.- 3.2 Demolition should include removal of buildings, struc-
underground pipelines, septic tanks, leach fields,
tures, foundations, reservoirs, utilities (including
seepage pits, cisterns, mining shafts, tunnels, etc.) and other man-made surface and subsurface improvements
- Standard Guidelines for Grading Projects
-.
Page 6
from the areas to be graded. Demolition of utilities
of wells in accordance with the requirements of the
lines at the project perimeter and cutoff and capping
governing authorities and the recommendations of the Geotechnical Consultant at the time of demolition.
" should include proper capping andfor re-routing pipe-
- 3.3 Debris generated during clearing, grubbing andfor
be graded and disposed off-site. Clearing, grubbing
demolition operations should be wasted from areas to
and demolition operations should be performed under . the observation of the Geotechnical Consultant.
4. SITE PROTECTION
4.3
4.4
4.5
The Contractor should be responsible for the stability
Geotechnical Consultant pertaining to temporary of all temporary excavations. Recommendations by the
of stability of the completed project and, therefore. excavations (e.g.. backcuts) are made in consideration
should not be considered to preclude the responsibil-
Geotechnical Consultant should not be considered to ities of the Contractor. Recommendations by the
preclude more restrictive requirements by the regulating agencies.
Precautions should be taken during the performance of
work site from flooding. ponding or inundation by poor site clearing, excavations and grading to protect the
or improper surface drainage. Temporary provisions should be made during the rainy season to adequately direct surface drainage away from and off the work site.
During periods of rainfall, the Geotechnical
as to the nature of remedial or preventative work Consultant should be kept informed by the Contractor
being performed (e.g., pumping. placement of sandbags or plastic sheeting. other labor, dozing, etc.).
Following periods of rainfall. the Contractor should contact the Geotechnical Consultant and arrange a review of the site in order to visually assess rain related damage. The Geotechnical Consultant may also recommend excavations and testing in order to aid in his assessments.
Rain related damage should be considered to include, but may not be limited to, erosion, silting. saturation, swelling, structural distress and other
adverse conditions identified by the Geotechnical
- Standard Guidelines for Grading Projects
-
Page 7
Consultant. Soil adversely affected should be classified as Unsuitable Materials and should be
subject to overexcavation and replacement with compacted fill or other remedial grading as recommended by the Geotechnical Consultant.
5. EXCAVATIONS
- 5.1 UNSUITABLE MATERIALS
5.1.1 Materials which are unsuitable should be
of the Geotechnical Consultant. Unsuitable excavated under observation and recommendations
materials include, but may not be limited to, dry, loose, soft, wet, organic compressible natural soils and fractured, weathered, soft bedrock and nonengineered or otherwise deleterious fill materials.
5.1.2 Material identified by the Geotechnical Consultant as unsatisfactory due to its moisture conditions should be overexcavated.
blended to a uniform near optimum moisture watered or dried. as needed, and thoroughly
prior to placement as compacted fill. condition (as per guidelines reference 7.2.1)
5.2 CUT SLOPES
5.2.1 Unless otherwise recommended by the Geotech- nical Consultant and approved by the regulating agencies, permanent cut slopes should not be steeper than 2:l (horizonta1:vertical).
5.2.2 If excavations for cut slopes expose loose. cohesionless, significantly fractured or otherwise unsuitable material, overexcavation
with a compacted stabilization fill should be and replacement of the unsuitable materials
accomplished as recommended by the Geotechnical Consultant. Unless otherwise specified by the Geotechnical Consultant, stabilization fill construction should conform to the requirements
of the Standard Details.
5.2.3 The Geotechnical Consultant should review cut
Consultant should be notified by the contractor slopes during excavation. The Geotechnical
prior to beginning slope excavations.
- Standard Guidelines for Grading Projects Page 8
5.2.4 If, during the course of grading, adverse or
.. potentially adverse geotechnical conditions are
preliminary report, the Geotechnical Consultant encountered which were not anticipated in the
should explore, analyze and make recommen- dations to treat these problems. -
6. COMPACTED FILL _-
All fill materials should be compacted to at least 90
percent of maximum density (AS" D1557) unless otherwise recommended by the Geotechnical Consultant.
6.1 PLACEMENT
6.1.1
6.1.2
6.1.3
Prior to placement of compacted fill, the Contractor should request a review by the Geotechnical Consultant of the exposed ground surface. Unless otherwise recommended, the exposed ground surface should then be scarified (6-inches minimum), watered or dried as needed, thoroughly blended to achieve near optimum moisture conditions, then thoroughly compacted to a minimum of 90 percent of the maximum
density .
Compacted fill should be placed in thin horizontal lifts. Each lift should be watered
optimum moisture conditions then compacted by or dried as needed, blended to achieve near
mechanical methods to a minimum of 90 percent of laboratory maximum dry density. Each lift should be treated in a like manner until the desired finished grades are achieved.
When placing fill in horizontal lifts adjacent
vertical), horizontal keys and vertical benches to areas sloping steeper than 5:l (horizontal:
area. Keying and benching should be sufficient should be excavated into the adjacent slope
to provide at least 6-foot wide benches and a minimum of 4-feet of vertical bench height within the firm natural ground, firm bedrock or engineered compacted fill. No compacted fill
keying and benching until the area has been should be placed in an area subsequent to
reviewed by the Geotechnical Consultant. Material generated by the benching operation should be moved sufficiently away from the bench area to allow for the recommended review
of the horizontal bench prior to placement
- Standard Guidelines for Grading Projects Page 9
6.1.4
6.1.5
6.1.6
6.1.7
fill. Typical keying and benching details have been included within the accompanying Standard Details.
Within a single fill area where grading procedures dictate two or more separate fills, temporary slopes (false slopes) may be created. When placing fill adjacent to a false slope, benching should be conducted in the same manner as above described. At least a 3-foot vertical bench should be established within the firm core adjacent approved compacted fill prior to placement of additional fill. Benching should proceed in at least 3-foot vertical increments until the desired finished grades are achieved.
Fill should be tested for compliance with the recommended relative compaction and moisture conditions. Field density testing should conform to accepted test methods. Density testing frequency should be adequate for the geotechnical consultant to provide professional opinions regardings fill compaction and adherence to recommendations. Fill found not to be in conformance with the grading recommendation should be removed or otherwise handled as recommended by the Geotechnical
Consultant.
The Contractor should assist the Geotechnical Consultant and/or his representative by digging test pits for removal determinations andlor for testing compacted fill.
As recommended by the Geotechnical Consultant, the Contractor may need to remove grading
personnel safety is considered to be a problem. equipment from an area being tested if
6.2 MOISTURE
6.2.1 For field testing purposes "near optimum" moisture will vary with material type and other
optimum" may be specifically recommended in factors including compaction procedure. "Near
evaluated during grading. Preliminary Investigation Reports andlor may be
6.2.2 Prior to placement of additional compacted fill following an overnight or other grading delay, the exposed surface or previously compacted
- Standard Guidelines
for Grading Projects Page 10
watered or dried as needed, thoroughly blended fill should be processed by scarification,
to near-optimum moisture conditions, then recompacted to a minimum of 90 percent of laboratory maximum dry density. Where wet, dry, or other unsuitable materials exist to
materials should be overexcavated.
depths of greater than one foot, the unsuitable
- 6.2.3 Following a period of flooding, rainfall or overwatering by other means, no additional fill should be placed until damage assessments have been made and remedial grading performed as described under Section 5.6 herein.
6.3 FILL MATERIAL
6.3.1
6.3.2
6.3.3
6.3.4
Excavated on-site materials which are considered suitable to the Geotechnical Consultant may be utilized as compacted fill, provided trash, vegetation and other deleterious materials are removed prior to placement.
Where import fill materials are required for use on-site, the Geotechnical Consultant should be notified in advance of importing, in order
borrow sites. No import fill materials should to sample and test materials from proposed
be delivered for use on-site without prior sampling and testing notification by Geotechnical Consultant.
Where oversized rock or similar irreducible material is generated during grading, it is
material off-site or on-site in areas recommended, where practical, to waste such
designated as "nonstructural rock disposal
be placed with sufficient fines to fill areas". Rock placed in disposal areas should
voids. The rock should be compacted in lifts to an unyielding condition. The disposal area should be covered with at least three feet of
material. The upper three feet should be compacted fill which is free of oversized
placed in accordance with the guidelines for compacted fill herein.
Rocks 12 inches in maximum dimension and smaller may be utilized within the compacted fill, provided they are placed in such a manner
Standard Guidelines for Grading Projects Page 11
that nesting of the rock is avoided. Fill
should be placed and thoroughly compacted over
not exceed 40 percent by dry weight passing the and around all rock. The amount of rock should
3/4-inch sieve size. The 12-inch and 40 percent recommendations herein may vary as
field conditions dictate.
6.3.5 Where rocks or similar irreducible materials of greater than 12 inches but less than four feet of maximum dimension are generated during
within an engineered fill, special handling in grading, or otherwise desired to be placed
accordance with the accompanying Standard Details is recommended. Rocks greater than four feet should be broken down or disposed off-site. Rocks up to four feet maximum dimension should be placed below the upper 10 feet of any fill and should not be closer than 20-feet to any slope face. These recommen- dations could vary as locations of improvements dictate. Where practical, oversized material should not be placed below areas where structures or deep utilities are proposed. Oversized material should be placed in windrows
on a clean, overexcavated or unyielding compacted fill or firm natural ground surface. Select native or imported pranular soil (S.E. 30 or higher) should be placed and thoroughly flooded over. and around ill windrowed rock, such that voids are filled. Windrows of oversized material should be staggered so that successive strata of oversized material are not in the same vertical plane.
6.3.6 It may be possible to dispose of individual larger rock as field conditions dictate and as recommended by the Geotechnical Consultant at the time of placement.
6.3.7 The construction of a "rock fill" consisting primarily of rock fragments up to two feet in maximum dimension with little soil material may be feasible. Such material is typically generated on sites where extensive blasting is required. Recommendations fo'r construction of rock fills should be provided by the
bas is. Geotechnical Consultant on a site-specific
Standard Guidelines for Grading Projects Page 12
6.3.8 During grading operations, placing and mixing the materials from the cut and/or borrow areas may result in soil mixtures which possess unique physical properties. Testing may be required of samples obtained directly from the fill areas in order to determine conformance with the specifications. Processing of these additional samples may take two or more working
operation to other areas within the project, or
days. The Contractor may elect to move the
may continue placing compacted fill pending laboratory and field test results. Should he elect the second alternative, fill placed is done so at the Contractor's risk.
6.3.9 Any fill placed in areas not previously reviewed and evaluated by the Geotechnical Consultant may require removal and recom- paction. Determination of overexcavations should be made upon review of field conditions
by the Geotechnical Consultant.
6.4 FILL SLOPES
6.4.1 Permanent fill slopes should not be constructed
steeper than 2:l (horizontal to vertical). unless otherwise recommended by the Geotech- nical Consultant and approved by the regulating
agencies.
6.4.2 Fill slopes should be compacted in accordance with these grading guidelines and specific
compaction are typically utilized in mass report recommendations. Two methods of slope
grading, lateral over-building and cutting back, and mechanical compaction to grade (i.e. sheepsfoot roller backrolling). Constraints such as height of slope, fill soil type, access, property lines, and available equipment will influence the method of slope construction and
be notified by the contractor what method will compaction. The geotechnical consultant should
be employed prior to slope construction.
Slopes utilizing over-building and cutting back should be constructed utilizing horizontal fill lifts (reference Section 6) with compaction equipment working as close to the edge as prac- tical. The amount of lateral over-building will vary as field conditions dictiate. Compaction testing of slope faces will be required and
- Standard Guidelines
for Grading Projects Page 13
6.4.3
6.4.4
reconstruction of the slope may result if testing does not meet our recommendations.
Mechanical compaction of the slope to grade during construction should utilize two types of compactive effort. First, horizontal fill lifts should be compacted during fill placement. This equipment should provide compactive effort to the outer edge of the fill slope. Sloughing of fill soils should not be permitted to drift down the slope. Secondly, at intervals not exceeding four feet in vertical slope height or the
capability of available equipment, whichever is less, fill slopes should be backrolled with a sheepsfoot-type roller. Moisture conditions of the slope fill soils should be maintained throughout the compaction process. Generally upon slope completion, the entire slope should be compacted utilizing typical methods, (i.e. sheepsfoot rolling, bulldozer tracking, or rolling with rubber-tired heavy equipment). Slope construction grade staking should be removed as soon as possible in the slope compaction process. Final slope compaction should be performed without grade sakes on the slope face.
In order to monitor slope construction procedures, moisture and density tests will be taken at regular intervals. Failure to achieve the desired results will likely result in a recommendation by the Geotechnical Consultant to overexcavate the slope surfaces followed by reconstruction of the slopes utilizing over- filling and cutting back procedures or further
backrolling approach. Other recommendations compactive effort with the conventional
may also be provided which would be commensurate with field conditions.
Where placement of fill above a natural slope or above a cut slope is proposed, the fill
accompanying Standard Details should be slope configuration as presented in the
adopted.
For pad areas above fill slopes, positive drainage should be established away from the top-of-slope, as designed by the project civil engineer.
- Standard Guidelines
for Grading Projects Page 14
6.5 OFF-SITE FILL
6.5.1
6.5.2
6.5.3
Off-site fill should be treated in the same manner as recommended in the specifications for site preparation, excavation, drains, compaction, etc.
Off-site canyon fill should be placed in preparation for future additional fill, as
shown in the accompanying Standard Details.
Off-site fill subdrains temporarily terminated
(up canyon) should be surveyed for future relocation and connection.
6.6 TRENCH BACKFILL
6.6.1
6.6.2
6.6.3
6.6.4
Utility trench backfill should, unless other- wise recommended, be compacted by mechanical means. Unless otherwise recommended, the degree of compaction should be a minimum of 90 percent of maximum density (ASTM D1557).
Backfill of exterior and interior trenches extending below a 1:l projection from the outer edge of foundations should be mechanically compacted to a minimum of 90 percent of the laboratory maximum density.
Within slab areas, but outside the influence of foundations, trenches up to one foot wide and two feet deep may be backfilled with sand (S.E. > 30), and consolidated by jetting, flooding or by mechanical means. If on-site materials are utilized, they should be wheel-rolled, tamped
For minor interior trenches, density testing or otherwise compacted to a firm condition.
may be deleted or spot testing may be elected if deemed necessary, based on review of backfill operations during construction.
If utility contractors indicate that it is undesirable to use compaction equipment in close proximity to a buried conduit, the Contractor may elect the utilization of light weight mechanical compaction equipment and/or
material, (S.E. > 30) which should be shading of the conduit with clean, granular
thoroughly moistened in the trench, prior to
Standard Guidelines for Grading Projects Page 15
Other methods of utility trench compaction may initiating mechanical compaction procedures.
also be appropriate, upon review of the Geotechnical Consultant at the time of construction.
6.6.5 In cases where clean granular materials are
where flooding or jetting is proposed, the proposed for use in lieu of native materials or
procedures should be considered subject to review by the Geotechnical Consultant.
6.6.6 Clean granular backfill and/or bedding are not recommended in slope areas unless provisions are made for a drainage system to mitigate the potential build-up of seepage forces and piping.
7. DRAINAGE 1
7.1 Canyon subdrain systems recommended by the Geotechnical Consultant should be installed in accordance with the Standard Details.
7.2 Typical subdrains for compacted fill buttresses, slope stabilizations or sidehill masses, should be installed in accordance with the specifications of the .accompanying Standard Details.
7.3 Roof, pad and slope drainage should be directed away
via suitable devices designed by the project civil from slopes and areas of structures to disposal areas
area drains, earth swales, etc.). engineer (i.e., gutters, downspouts, concrete swales,
7.4 Drainage patterns established at the time of fine grading should be maintained throughout the life of the project. Property owners should be made aware
slope stability and foundation performance. that altering drainage patterns can be detrimental to
a. SLOPE MAINTENANCE
8.1 LANDSCAPE PLANTS
problems, slope planting should be accomplished at the In order to decrease erosion surficial slope stability
completion of grading. Slope planting should consist of deep-rooting vegetation requiring little watering. A Landscape Architect would be the test party to
configuration.
consult regarding actual types of plants and planting
-
Standard Guidelines for Grading Projects
8.2 IRRIGATION
Page 16
8.2.1 Slope irrigation should be minimized. If automatic timing devices are utilized on irrigation systems, provisions should be made for interrupting normal irrigation during periods of rainfall.
8.2.2 Property owners should be made aware that
overwatering of slopes is detrimental to slope stability and may contribute to slope seepage, erosion and siltation problems in the subdivision.
Rev 5/88
1s' MINIMUM
4. DIAMETER PERFORATED
PIPE BACKDRAIN
4' DIAMETER NON-PERFORATED
PIPE LATERAL DRAIN
ELOPE PER PLAN
BENCHINQ
1-t
PROVIDE BACK DRAIN PER BACKDRAIN
DETAIL. AN ADDITIONAL BACKDRAIN
AT MID-ELOPE WILL BE REQUIRED FOR
ELOPE IN EXCESS OF 40 FEET HIQH.
(QENERALLY 112 ELOPE HEIQHT. 1s'
KEY-DIMENSION PER SOIL8 ENQINEER
MINIMUM)
TYPICAL STABILIZATION FILL DETAIL
OB NO.: - DATE: - - .. -< JULY *-',,
FIQURE:
1
4' DIAMETER PERFORATED
PIPE BACKDRAIN \
4' DIAMETER NON-PERFORATED
PIPE LATERAL DRAIN
SLOPE PER PLAN-
BENCHINQ
\ LPROVIDE BACKDRAIN PER BACKDRAIN
DETAIL. AN ADDITIONAL BACKDRAIN
AT MID-SLOPE WILL BE REQUIRED FOR
ELOPE IN EXCESS OF 40 FEET-HIQH.
-KEY-DIMENSION PER SOILS ENQINEER
TYPICAL BUTTRESS FILL DETAIL ~ ~~ ~~
OS NO.: DATE: - 0-1 1-00*00' FIQURE: JULY" tOdM 2
r NATURAL QROUND
PROPOSED QRADINQ
"
COMPACTED FILL
PROVIDE BACKDRAIN PER
BACKDRAIN DETAIL. AN
ADDITIONAL BACKDRAIN
AT MID-SLOPE WILL BE
REQUIRED FOR BACK
SLOPES IN EXCESS OF BASE WIDTH .W. DETERMINED
40 FEET HIQH. LOCA- BY SOILS ENQINEER
AND OUTLETS PER SOILS TIONS OF BACKDRAINS
ENQINEER ANDIOR EN-
QlNEERlNQ QEOLOQIST
DURINQ QRADINQ.
)B NO.: 06-487Q-Qll - DATE: JULY 1.0881 FIGURE: 3
FINAL I
EXCA
.IM
VA
OVEREXCAVATE
Ill OF
TlON
DAYLIQHT /- FINISH PAD
DAYLIGHT SHEAR KEY DETAIL
OB no.: DATE: .. FIGURE: 06-48?@-01 ?-OO-OQ- JULY 1988.: 4
BENCHING FILL OVER NATURAL
SURFACE OF FIRM EARTH MATERIAL 7 /
-10' MIN. (INCLINED 2% MIN. INTO SLOPE)
BENCHING FILL OVER CUT
SURFACE OF FIRM
FINISH FILL SLOPE EARTH MATERIAL
TYPICAL
16' MIN. OR STABILITY EQUIVALENT PER SOIL ENQlNEERlNQ (INCLINED 2% MIN. INTO SLOPE)
BENCHING FOR COMPACTED FILL DETAIL
B NO.: DATE: Q5-48?SdWt-00-00: FIQURE: JULY 1988'1 6
" FINISH SURFACE SLOPE
- 3 FT3 MINIMUM PER LINEAL FOOT
APPROVED FILTER ROCK*
~
_-
COMPACTED FILL
-
4. MINIMUM APPROVED
PERFORATED PIPE**
(PERFORATION8 DOWN)
MINIMUM 2% QRADIENT 4. MINIMUM DIAMETER
SOLID OUTLET PIPE TO OUTLET
ENQINEER REQUIRE- DRAIN
MENTS DURINQ QRADINQ TYPICAL BENCHINQ
- SPACED PER SOIL BENCH INCLINED TOWARD
I-
DETAIL A-A
/TEMPORARY FILL LEVEL
I- - /
! COMPACTED 4. MINIMUM DIAMETER
APPROVED SOLID
1- OUTLET PIPE
~ 12' MINIMUM COVER -
.-
I i 1- 12. MINIMUM F *FILTER ROCK TO MEET FOLLOWINQ
SPECIFICATIONS OR APPROVED EQUAL
- SIEVE PERCENTAQE PASSINQ -
'APPROVED PIPE TYPE: 1' 100
SCHEDULE 40 POLYVINYL CHLORIDE
MINIMUM CRUSH STRENQTH 1000 PSI.
314. 80-100 318. 40-100
N0.4 2s-40
N0.30
N0.60
s-1s
0-7
N0.200 0-3
- (P.V.C.) OR APPROVED EQUAL.
- - TYPICAL BACKDRAIN DETAIL JOB NO.: DATE: 06-4879-011-40-0@! FIQURE: JULY t08W. 6
FINISH SURFACE SLOPE
MINIMUM 3 FT3 PER LINEAL FOOT OPEN QRADED AQQREQATE*
TAPE AND SEAL AT CONTACT
COMPACTED FILL
SUPAC 8-P FABRIC OR APPROVED EQUAL
4. MINIMUM APPROVED PERFORATED PIPE
4. MINIMUM DIAMETER (PERFORATIONS DOWN)
SOLID OUTLET PIPE MINIMUM 2% QRADIENT SPACED PER SOIL TO OUTLET
ENQINEER REQUIREMENTS
TOWARD DRAIN BENCH INCLINED
BENCHING
DETAIL A-A r TEMPORARY FILL LEVEL
I 1 /
MINIMUM BACKFILL COMPACTED
12" COVER MINIMUM 4. DIAMETER APPROVED SOLID OUTLET PIPE
ktZUd
*NOTE: AQQREQATE TO MEET FOLLOWINQ SPECIFICATIONS OR APPROVED EQUAL:
SIEVE SIZE PERCENTAQE PASSINQ
1 112' 100
1.
314' 0-17
5-40
918"
NO. 200
0-7 0-3
BACKDRAIN DETAIL (GEOFABRIC)
OB NO.: DATE: - FIQURE: - " JULY lQ88, 7
f- SURFACE OF
FIRM EARTH
MATERIAL
\ \
TYPICAL BENCHING
REMOVE UNSUITABLE
BEE DETAIL BELOW INCLINE TOWARD DRAIN
""""" \ / MINIMUM 4. DIAMETER APPROVED
PERFORATED PIPE (PERFORATIONS
DOWN)
MNIMUM e FT~PER LINEAR FOOT
)F APPROVED FILTER MATERIAL 8. FILTER MATERIAL BEDDlNa
:ILTER MATERIAL TO MEET FOLLOWINQ
IPEClFlCATlON OR APPROVED EQUAL:
llEVE SIZE
1.
314.
318'
N0.4
N0.30
NO.60
N0.200
PERCENTAQE
100
80-100
40- 100
26-40
6-15
0-7
0-3
APPROVED PIPE TO BE SCHEDULE 40
POLY-VINYL-CHLORIDE (P.V.C.) OR
APPROVED EQUAL. MINIMUM CRUSH
STRENQTH 1000 pal
PIPE DIAMETER TO MEET THE
FOLLOWINQ CRITERIA. SUBJECT TO
FIELD REVIEW BASED ON ACTUAL
QEOTECHNICAL CONDITIONS
ENCOUNTERED DURING QRADINQ
LENQTH OF RUN PIPE DIAMETER
UPPER 600' 4.
NEXT 1000' 8.
> 1600' 8.
TYPICAL CANYON SUBDRAIN DETAIL
OB NO.: os-4879-011-00-00 DATE: JULY 1988 FIQURE: 8
CANYON SUBDRAIN DETAILS
SURFACE OF
FIRM EARTH
"""" f / /
TYPICAL BENCHINQ REMOVE UNSUITABLE MATERIAL
INCLINE TOWARD DRAIN
8EE DETAIL8 BELOW
TRENCH DETAIL
8' MINIMUM OVERLAP
>
OPTIONAL V-DITCH DETAIL rMlNlMUM 0 FT3 PER LINEAL , FOOT OF APPROVED DRAIN MATERIAL
8UPAC 8-P FABRIC BUPAC 5-P FABRIC OR
APPROVED EQUAL
""" 8. MINIMUM OVERLAP
MINIMUM
MINIMUM 0 FT3 PER LINEAL FOOT
OF APPROVED DRAIN MATERIAL
8PECIFICATION OR APPROVED EQUAL:
DRAIN MATERIAL TO MEET FOLLOWINQ ADD MINIMUM 4. DIAMETER
SIEVE SIZE PERCENTAQE PA881NQ LE88 THAN 2%
APPROVED PERFORATED
PIPE WHEN QRADIENT I8
1 112' 88- 100
1.
314'
318'
N0.200
5-40
0-17
0-7
0-3
APPROVED PIPE TO BE
SCHEDULE 40 POLY-VINYL-
CHLORIDE (P.V.C.) OR
CRU8H BTRENQTH 1000 pal.
APPROVED EQUAL. MINIMUM
GEOFABRIC SUBDRAIN
OB NO.: O6-487@-0t~-80-00 . DATE: JULY teae 4 9 FIQURE:
FINAL NATURAL SLOPE
LIMITS OF FINAL EXCAVATION
TOE OF SLOPE SHOWN
ON QRADINQ PLAN
COMPETENT EARTH
MATERIAL
MINIMUM
DOWNBLOPE
KEY DEPTH PROVIDE SACKDRAIN AS
MENDATIONS OF SOILS
REQUIRED PER RECOM-
ENQINEER DURINQ QRADINQ
WHERE NATURAL SLOPE QRADIENT 18 6:1 OR LESS.
BENCHING 18 NOT NECESSARY. HOWEVER. FILL IS
NOT TO BE PLACED ON COMPRESSIBLE OR UNSUIT-
ABLE MATERIAL.
GENERAL GRADING RECOMMENDATIONS
CUT LOT
,,-"ORIQINAL
QROUND
TOPSOIL, COLLUVIUM AND
WEATHERED BEDROCK,,/..
LOVEREXCAVATE AND
UNWEATHERED BEDROCK REQRADE
CUTlFlLL LOT (TRANSITION)
LOVEREXCAVATE AND
/COLLUVIUM AND , TOPSOIL. REQRADE
WEATHERED 00 UNWEATHERED BEDROCK
BEDROCK 0
TRANSITION LOT DETAIL
DATE: OB NO.: 06-4879-011-00-00 JULY lO88: FIQURE: 12
BUILDING
FINISHED QRADE
CLEAR AREA FOR
FOUNDATION. UTILITIES.
AND SWIMMINQ POOLS
0
0
Ow0
WINDROW
So OR BELOW DEPTH OF
(WHICHEVER QREATER)
DEEPEBT UTILITY TRENCH
TYPICAL WINDROW DETAIL (EDGE VIEW)
QRANULAR SOIL FLOODED
TO FILL VOIDS
\
HORIZONTALLY PLACED
COMPACTION FILL
/ I .' / / / / / / / / /
PROFILE VIEW
ROCK DISPOSAL DETAIL
OB NO.: DATE: - ste-011-00-00 JULY leea >'>,
FIQURE: 13