HomeMy WebLinkAboutCDP 04-50; RHODES RESIDENCE; LIMITED SITE INVESTIGATION; 2005-07-20)..
EAST COUNTY SOIL CONSULTATION
AND ENGINEERING, INC.
10925 HARTLEY ROAD, SUITE "I"
SANTEE, CALIFORNIA. 92071
(619) 258-7901 .
Mr. Glenn Rhodes
1200 Chinquapin Avenue
Carlsbad, California 92008
Fax 258-7902
Subject: Limited Site Investigation
July 20, 2005
Project No. 05-1106G6
Proposed Two-Story Single Family Residence
1200 Chinquapin Avenue
City of Carlsbad, California
Dear Mr. Rhodes:
In accordance with your request, we have performed a limited
investigation of the soil qonditions at the subject site to
provide the soil engineering criteria for site grading and
recommend an appropriate foundation system for the proposed
residence .
.Our investigation has found that the site is underlain by topsoil
and colluvium to a maximum depth of approximately 3 feet below
existing grade. The colluvium is underlain by medium dense to
dense sandstone of the Terrace Deposits Formation to the explored
depth of 5.0 feet.
It is our opinion that the proposed development is feasible
provided the recommendations herein are implemented in the design
and construction.
Respectfully submitted,
Mamadou Saliou Diallo, P.E.
RCE 5-4071
MSD/md
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j
..
-RHODES PROJECT NO. 05-1106 •
SITE DESCRIPTION AND PROPOSED CONSTRUCTIO~
The subject site is located on the north side of Chinqqapin
Avenue, in the City of Carlsbad, California. The site is occupied
by a single-story house along with a 12-foot deep abandoned
seepage pit. The property slopes gently to the west. It is our
understanding that the existing house will be demolished and
.replaced with a two-story, wood-fratnec;l. single-family residence~-
. The structure will be founded on continuous footings with a slab-
on-grade floor.
FIELD INVESTIGATION
On July 8, 2005, three (3) exploratory borings were drilled to a
mc).ximum depth of approximately 5. 0 feet with a hand auger. The
approximate locations of the borings are shqwn on the attached
Plate No. 1, entitled "Location of Exploratory Borings". A
continuous log of the soils encounte·red was recorded at the time
of drilling and is shown on Plate No. 2 entitled "Summary Sheet".
The soils were visually and texturally classified according to the
filed identification procedures set forth on the attached P~ate
~o .. 3 entitled "USCS Soil Classification" ...
Following the field exploration, laboratory testing was performed
to evaluate the pertinent engineering pr6perties of the foundation
materials. The laboratory-testing ptogtam included moisture and
density, maximum density and optimum moisture content, particle
sizE; analysis and expansion index· tests. These tests were
performed in general accordance with ASTM standards. Plate No. 2
and Page L-1 rrovide a summary of the laboratory test results.
SUBGRADE CONDITIONS
Topsoil and colluvium were encountered to a maximum depth of
approximately 3 feet below existing g:i;-ade. '.I'hese soils were
composed of sand and silt mixture with a loose to medium dense
consistency and a low moisture content. Medium dense to dense
sandstone of the Terrace Deposits· Formation was underlying the
colluvium to the maximum explored depth o.f approximately 5 .. 0 feet.
EXPANSIVE SOILS
An expansion index test · was perforroed on a select sample of the
colluvium to determine volumetric change characteristics with
change in moisture content. An expansion index of 2 indicates a
very low expansion potential for the foundation soils.
3
• -RHODES PROJECT NO. 05-1106G'
. GRADING AND EARTHWORK
Site grading should begin with clearing and grubbing, e.g.· the
removal of v~getation, · topsoil and deleterious materials. All
colluvium under the proposed structure should be overexcavated,
moisture · con.di tioned within 2 perc~nt over the optimum moisture
content and compacted to a minimum of 90 percent relative
compaction (ASTM. D1557) . The overexcavation should extend to the
dense sandstone of. the Terrace Deposits Formation and at least 5
feet beyond proposed perimeter footings. Proper keying and
benching of the subgrade along the adj ac.ent slope to the east
shquld be observed during the grading operation. To prevent any
transition between cut and fill within the building pad, th~ cut
portion of the pad should be overexca,vated to a minimum depth of
three feet below finish pad grade, moisture conditioned ahd
compacted as above. The actual depth and extent of removal should
be eva.luated in the .field at the time of excavation by a
representat'ive of this firm. Grading should be performed in
accordance with the attached Appendix A.
rn addition, the abando:r;ied seepage pit should be properly cleaned
out and backfilled with compacted fill mater.ials or a concrete
slurry mix.
FOUNDATIONS AND SLABS
a. Continuous footings are suitable for use and should e·xte.nd a
minitnµrn of 18 inches for· the two-story · residence · into properly.
compacted fill soils~ These footings should be at least 15 inches
in width and reinforced with four #4 steel bars; two bars placed
near t.he top of the footings and the other two bars placed near
the bottom of the footings
b. Interior concrete floor slabs sho.uld be a minimum of 4 inches
thick. Reinforcement should consist of #3 bars placed at 16 inches
on center each way within the .middle third of the slab by
supporting the steel on chairs or concrete blocks "dobies". The
slab should be underlain· by 2 inches of clean sand· over a lO~mil
vis queen moisture barrier. The effect of concrete shrinkage will
result in cracks in virtually all copcrete slabs. To reduce the
extent of shrinkage, the concrete should be placed at a maximum of
4-inch slump. The minimum steel recommended is not intended to
prevent shrinkage cracks.
5
e. e RHODES PROJECT NO. 05-.J 106G6
c. Where moisture sensitive floor coverings are anticipated over
the slab, the 10-mil plastic moisture barrier sh6uld be underlain
by a capillary break at least 2 inches thick, consisting of coarse
sand, gravel or crushed rock not exceeding 3/4 inch in size with
rio more than 5 percent passing the #20,0 s.ieve.
d. An allowable soil bearing value of 1,725 pounds per square foot
may be used for the design of the above footings founded into the
properly compacted fill. This value may be increased by 300 psf
for each additional foot of width or depth to a maximum value of
4,500 lb/ft2 as set forth in the 1.997 Edition of the Uniform
Building Code, Table No. l&-I-~.
e. Lateral resistance to horizontal movement may be provided by
the soil passive pressure and the friction of concrete to soil. An
allowable passive pressure of 250 pounds per square foot per foot
of depth may be used. A coefficient of friction of 0.35 is
recommended. The soils passive pressure as well as the bearing
value may be increased by 1/3 for wind and seismic loading.
RETAINING WALLS
Cantilevered retaining walls should be designed for an "active"
lateral earth pressure of 35 psf/ft (35 pcf EFP) for approved
granular backfill and level backfill conditions. Where cantilevered
walls support 2:1 (hor:vert) sloping backfill, the equivalent active
fluid pressure should be increased to 45 pcf. Cant~lever walls
subject to uniform surcharge loads should be designed for an
additional uniform lateral pressure equal to· qne-third (1/3) the
anticipated surcharge pressure.
Restrained walls should be designed utilizing an "at-rest" earth
pressure of 58 psf/ft (58 pcf EFP) fbr ~pproved granular and level
backfill. Restrained walls subject to uniform surcharge loads should
be designed for an additional uniform lateral pressure equal to one-
half {1/2) the anticipated surcharge.
Retaining wall footings should be embedded a minimum of 18 inches
below the lowest adjacent grade. Retaining walls that are to be
located near the top of slopes should be designed to allow a minimum
daylight distance of 7 feet laterally from the outside edge of the
footing to the slope face.
Soil design criteria, such as bearing capacity, passive earth
pressure and sliding resistance as recommended under the Foundation
and Slab Recommendations section, may be incorporated into the
retaining wall design. The design and location of retaining walls
6
J.:'
-RHODES PROJECT NO. 05-1106,
should be reviewed by our firm for conformance with our
recommendations.
Footings should be reinforced as recommended by the structural
engineer and. appropriate back drainag~ provided to avoid excessive
hydrostatic wall pressures. As a :minimum we recornmend a fabric-
wrapped crushed rock and perforated pipe system. At least 2 cubic
feet per linear foot of free-drainage crushed rock should be
provided.
The remaining wall backfill should consist of approved granular
tnate+:ial. This fill material should be compactec:;i to a minimum
relative compaction of 90 percent as determined by ASTM D-1557 test
method. Flooding or jetting of backfill should not be permitted.
Granular backfill should be capped with a minimum 18 inches of
relatively impervious fill to seal the backfill and prevent
saturation.
It should be noted that the use of heavy compaction equipment in
close proximity to retaining structures can result in wall pressures
exceeding design values and corresponding wall movement greater than
that associated with active or at-rest conditions. In tpis regard,
the contractor should take appropriate precautions during the
backfill placement .
. SETTLEMENT
Settlement of compacted fill soils is normal and should be
anticipated. Because of the type and thickness of the fill soils
under the proposed footings and the light building loads, total
a~d differential settlement should be within acceptable limits.
TRENCH EXCAVATION AND BACKFILL
Excavations for foundation and on-site utility trenches may be
+nade vertically for shallow depths and must be either shored or
sloped at 1H: 1V for depths greater than 4 feet. Utilities should
be bedded and backfilled with clean sand or approved granular soil
to a depth of at least one foot over the pipe. This backfill
should be uniformly watered and compacted to a firm condition for
pipe support. The remainder of the backfill should be on-site
soils or non-expansive imported soils, which should be placed in
thin lifts, moisture-conditioned and compacted to at least 90%
relative compaction (ASTM D1557).
7
" _,
-RHODES PROJECT NO. 05-11061
DRAINAGE
.Adequate measures should be undertaken to properly finish grade
the site after the structure and other improvements are in place,
such that the drainage water within the site and adjacent
properties is directed away from the foundations, footings, floor
slabs and the tops of slopes via surface swales and subsurface
dtains towards the natural drainage for this area. A minimum
gradient of 1 percent is recommended in hardscape areas. For earth
areas, a minimum gradient of 5 percent away from all structures
for a distance of at least 5 feet should be provided. Earth swales
should have a minimum gradient of 2 percent. Drainage should be
di~ected to approved drainage facilities. Proper surface and
subsurface drainage will be required to minimize the potential of
water seeking the level of the bearing soils under the
foundationsi footings and floor slabs, which may otherwise result
in undermining and differential settlement of the structure and
other improvements.
FOUNDATION EXCAVATION OBSERVATION
Foundation excavations should be observed by our representative
prior to the placement of forms, reinforcement or concrete for
-conformance with the plans and specifications and the intent of the
recommendations herein.
LIMITS OF INVESTIGAT.ION
Our investigation was performed using the s.kill and degree of care
ordinarily exercised, under similar circumstance.s, 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.
This report is prepared for the sole use of our client afid may not
be assigned to others without the written consent of the client and
ECSCE, Inc.
The samples collected and used for testing, and the observations
made, are · believed representative of site conditions; however,
soil and geologic conditions can vary significantly between
borings and surface exposures. As in most major projects,
~onditions revealed by construction ~xcavations may vary with
preliminary findings. If this occurs, the changed conditions must
be evaluated by a representative of ECSCE and designs adjusted as
required or alternate desi.gns recommended.
8
--RHODES PROJSCT NO. 05-110606
This report is issued with the understanding that it is the
responsibility of the owner, or of his representative to ensure that
the information and recommendations contained herein are brought to
the attention of the project archi.tect and engineer. Appropriate
recommendations s.hould be incorporated into the structural plans.
The necessary steps should be taken to see that the contractor and
subcontractors carry out such recommendations in the field.
The findings of this report are valid as . of this present date.
However, changes in the conditions of a property can occur with the
passage of time, whether they are due to natural processes or the
works ·of man on this or adjacent properties. In addition, changes in
applicable or appropriate standards may occur from legislation or
the broadening of knowledge. Accorctingly, the findings of this
report may be invalidated wholly or partially by changes outside of
our control. Therefore, this report is subject to review and should
be updated after a period of two years.
Plates No. 1 through 3, Page L-1, References and Appendix A are
parts of this report.
Respectfully submitted,
Diallo, P.E.
9
EAST COUNTY SOIL CONSULTATION
& ENGINEERING, INC.
10925 HARTLEY RD .• SUITE I. SAN,cE, CA 9207 I
(619.) 258-7901 F:ix (6 I 9) 258-7902
--~
,, .. '
'-1--'
.,f.... ~1'rf.·
C/21/N~v'.-:Pl,V At/£. ----'---f
DEPTH
Surface
OS
3.0'
5.0'
DEPTH
Surface
0.5'
LO'
· 2.0'
3.0'
DEPTH.
· Surface
0.5'
1.5'
3.0'
-RHODES PROJECT NO. 05-1106,,.
PLATEN0.2
SUMMARY SHEET
BORINGN0.1
SOIL DESCRIPTION
TOPSOIL
brown, dry, loose, silty, fine sand with rootlets
COLLUVIUM (Qal)
brown, damp, loose to medium dense sand with silt
TERRACE DEPOSITS FORMATION (Qt)·
tan, damp, medium dense to dense, silty, fine sand
bottom of boring, no caving, no groundwater
boring·backfilled 7/8/05
BORINGN0.2
SOIL DESCRIPTION
TOPSOIL
brown, dry, loose, silty, fine sand with rootlets
COLLUVIUM (Qal)
brown, damp, loose to medium dense sand with silt
" " " " "
TERRACE DEPOSITS FORMATION (Qt)
. tan, damp, medium dense to dense, silty, fine sand
bottom of boring, no caving, no groundwater
boring backfilled 7/8/05
BORINGN0.·3
SOIL DESCRIPTION
TOPSOIL
brown, dry, loose, silty, fine sand with rootlets
COLLUVIUM (Qal)
brown, damp, loose to medium dense sand with silt
TERRACE DEPOSITS FORMATION (Qt)
· tan, damp, medium dense to dense, silty, fine sand
bottom of boring, no caving, ho groundwater
boring backfilled 7 /8/05
y M
112.3 4.6
y M
105.6 3.3
y M
4.1
. ---------.-----------------------------------.---
10
.-·.
lYIAJOR DIV.ONS ·SYMBOL -1:scR:lPTION
GW WELL GRADED GRAVELS OR GRA V~L-SAND
. . MIXTURES. LITTLE 0R NO F.INES
GRAVELS GP POORLY GRADED GRAVELS OR GRAVEL-SAND (MORETHAN½ . MIXTURES. LITTLE OR NO FINES OF COARSE
FRACTION GM SIL TY GRAVELS, GRAVEL-SAND-SILT MIXTURES >N0.4SIEVE
SIZE) COARSE GC CLAYEY GRAVELS, GRAVEL-SAND-CLAY MIXTURES GRAINED SOILS
(MORE THAN ½ OF SOIL> . SW NO. 200 SIEVE SIZE) WELL GRADED SANDS OR GRAVELLY SANDS,
LITTLE OR NO FINES
SANDS SP POORLY GRADED SANDS OR GRA YELL Y SANDS, (MORETHAN½
OF COARSE LITTLE OR NO FINES
FRACTION S:M SILT{ SANDS, SILT-SAi"lD MIXTURES <N0.4SIEVE
SIZE)
SC CLAYEY SANDS, SAND-CLAY MIXTURES
ML INORGANIC SILTS Ai'IP VERY FINE SAi"lDS, ROCK
SILTS & FLOUR, SIL TY OR CLAYEY FINE SANDS OR CLAYEY
SiLTS WITH SLIGHTPLASTICITY
CLAYS CL INORGAi"lIC CLAYS OF. LOW TO MEDIUM
LIQUID LIMIT PLASTICITY, GRAVELLY CLAYS, SAi"lDY CLAYS,
<50 SILTY CLAYS. LEAN CLAYS
FINE GRAINED OL ORGAi"lIC SILTS Ai"lD ORGAi"lIC SILTY CLAYS OF SOILS LOW PLASTICITY
(MORE THAI"-! ½ OF SOIL< l\'IlI NO. 200 SIEVE SIZE) iNORGAi"lIC'~ILTS, MICACEOUS OR DIATOMACEOUS SILTS & FINE SANDY OR SIL TY SOILS. ELASTIC SIL TS
CLAYS CH INORGANIC CLAYS OF HIGH PLASTICITY, FAT LIQUID LIMIT
>50 CLAYS
OH I ORGANIC CLAYS OF MEDIUM TO HIGH PLASTICITY,
ORGAi"lIC SIL TY CLAYS. ORGAi"lIC SIL TS
HIGHLY ORGAJ.'11:C SOILS Pt I PEAT A,"lD OTHER HIGH!. Y ORGAi"lIC SOILS
CLASSIFICATION CHART (UNIFIED SOIL CLASSIFICATION SYSTEM)
' CLASSIFICATION RANGE OF GRAIN SIZES
t;.S. STANDA,RD GRAIN SIZE IN
.SIEVE SIZE MILLIMETERS
BOULDERS I Above 12 Inches I Above305
COBBLES I .12 Inches To 3 Inches 305 To 76.2
GR,AVEL
I
3 Inches to No. 4
I
76.2 to 4.76
Coarse 3 Inches to ¾ Inch 76.2 to 19.1
Fine l/4 Inch to No. 4 19.1 to 4.76
SAND No. 4 to No. 200 4.76 to 0.074
Coarse No. 4 to No. 10 4.76 to 2.00
Medium No. 10 to No. 40 2.00 to 0.420
Ftile No. 40 to No. 200 0.420 to 0.074
SILT AND CLAY I Below No. 200 ~ Below 0.074
GRAIN SIZE CHART
EAST COUNTY SOIL CONSULTATION
AND ENGINEERING, INC.
10925 HARTLEY ROAD, SUITE "I"
SANTEE, CALIFORNIA 920il
U.S.C.S. SOIL CLASSIFICATION
70
10 I· ·1 .. I' I -e ~ ~ I I ,. s 44 I I =
~ 30 la! ·I I ;; £ :0 r I ~H.t'H
10
UQUIO UJrial r (t.:..~. ":
PLASTICITY CHART
RHODES PROJECT NO. 05~1106G6
PLATE NO. 3
JUL:Y 20, 2005
-RH0DESPROJ$CTNO. 05-11061
PAGEL-1
LABORATORY TEST RESULTS
MAXIMUM DRY DENSITY AND OPTIMUM MOISTURE CONTENT (ASTM D1557)
The maximum dry densities and optimum moisture contents of the fill materials as determined by ASTM
Dl557-91, Procedures A and B which use 25 blows of a 10 pound slide hammer falling from a height of 18
inches on each of 5 equal layers in a 4 inch diameter 1/30 cubic foot compaction cylinder and Procedure C
which uses 56 blows of a 10 pound slide hammer falling from a height of 18 inches on each of 5 equal layers
in a 6 inch diameter 1/13.3 cubic foot compaction cylinder are presented as follows:
OPTIMUM
MAXIMUM MOISTURE
SOILTYJ>E/ DRY DENSITY CONTENT
PROCEDURE DESCRIPTION (PCF) (%)
1/A TAN SILTY FINE SAND 127.0 7.8
INITIAL
MOISTURE
CONTENT{%)
8.2
l"
1/2"
3/8"
#4
#8
#16
#30
#40
#60
#100
#200
uses
EXP ANSI ON iNDEX TEST (ASTM D4829)
SATURATED
MOISTURE
CONTENT(%)
15.7
INITIAL DRY
DENSITY EXPANSION
(PCF) INDEX.
116.7 0
PARTICLE SIZE ANALYSIS (ASTM D422)
100
99
88
71
37
18
10
SP-SM
11
100
99
98
97
90
77
46
30
22
·sM
LOCATION
B-1@ 1.5'
LOCATION
B-1@ 1.5'
• RHODES PROJECT NO .. 05~1106,,
REFERENCES
1. "1997 Unifonn Building Code, Volume 2, Structural Engineering Design Provisions", Published
by International Conference of Building Officials.
2. "Maps of Known Active Fault Near-Source Zones in California and Adjacent Portions of
Nevada", Published by International Conference of Building Officials.
3. "Geologic Maps of the Northwestern Part of San Diego County, California, Plate No. 1,
Geologic Map of the Oceanside, San Luis Rey, and San Marcos 7.5' Quadrangles, San Diego
County,. California", by Siang S. Tan and Michael P. Kennedy, 1996.
12
••
EAST COUNTY SOIL CONSULTATION
AND ENGINEERING, INC.
10925 HARTLEY ROAD, SUITE I
SANTEE, CALIFORNIA 92071
(619) 258-7901
APPENDIX A
RECOMMENDED EARTHWORK SPECIFICATIONS
1. General Description
The intent of these specifications is to obtain uniformity and adequate strength in filled ground so
that the proposed structures may be safely supported. The procedures include the clearing and
. preparation of the land to be filled, processing the fill soils, the spreading, and compaction of the
filled areas to conform with the lines and grades as shown on the approved plans.
The owner shall retain a Civil Engineer qualified in sqil mechanics (herein referred to as engineer)
to inspect and test earthwork in accordance with these specifications. The engineer shall advise the
owner and grading contractor immediately if any unsatisfactory conditions are observed to exist
and shall have the authority to reject the compacted filled ground until such time that corrective
measures are taken, necessary to comply with the specifications. It shall be the sole responsibility
of the grading contractor to achieve the specified degree of compaction.
2. Preparing Areas to be Filled
(a) All brush, vegetation and any biodegradable refuse shall be removed or otherwise
disposed of so as to leave the areas to be filled free of vegetation and debris. Any uncompacted
filled ground or loose compressible natural ground shall be removed unless the report recommends
otherwise. Any buried tanks or other structures shall be removed and the depression backfilled to
the satisfaction of the engineer.
(b) The natural ground which is determined to be satisfactory for the support of the filled
ground shall then be plowed or scarified to a depth of at least 12 inches (12").
(c) · After the natural ground has been prepared, it shall then be brought to the proper
moisture content and compacted to not less than 90 percent of maximum dry dep.sity in accordance
with ASTM D1557-91.
( d) Where fills are made on slopes greater than 20 percent, horizontal benches shall be cut
into the firm natural ground. The initial bench at the toe of the fill sha:11 be at least 15 feet in width
on firm undisturbed natural ground. The width of all succeeding benches shall be at least 6 feet.
... APPENDIXA. • 2
3. Fill Materials
All material shall be approved by the engineer and shall consist of materials free from vegetable
matter, and other lumps greater than 6 inches in diameter. If, during grading operations, soils are
found which were not encountered and tested in the preliminary investigation, tests on· these soils
shall be performed to determine their physical characteristics. Any special treatment recommended
in the preliminary or subsequent soils reports not covered herein shall become an addendum to
these specifications.
4. Placing and Compacting Fill Materials
( a) When the moisture content of the fill material is below that specified, water shall be
added until the moisture content is near optimum to assure unifon:p. mixing and effective
compaction. _
(b) When the moisture content of the fill materials is above that specified, the fill material
shall be aerated by blading and scarifying or other satisfactory methods until the moisture content is
near optimum as speci~ed.
(c) After processing, the suitable fill materials shall be placed in layers which, when
compacted, shall not exceed six inches ( 6"). Each layer shall be spread evenly and shall be
thoroughly mixed during the .spreading ·insure uniformity of materials and moisture in each layer.
( d) After each layer has been placed, mixed and spread evenly, it shall be thoroughly
compacted to not less than the density set forth in paragraph 2 ( c) above. Compaction shall be
-accomplished with approval types of compaction equipment. Rolling shall be accomplished while
the fill material is at the specified moisture content. In place density tests shall be performed in
accord~ce with A.STM D1556-90.
( e) The ~urfaces of the fill slopes shall be compacted by means of sheepsfoot rollers or other
suitable equipment. Compacting operations shall be continued until the slopes are stable and until
the~e i.s no appreciable amount ofloose soil on the slopes.
5. Inspection
Bufficient inspection by our firm or the Soil's Engineer of record and/or his/her representative shall
be maintained during the filling and compacting operations so that he/she can verify that the fill
was constructed in accordance with the accepted specifications.
6. Seasonal Limits
No fill material shall be placed, spread, or rolled if weather conditions increase the moisture
content above permissible limits. When the work i~ interrupted by rain, fill operations shall not be
resumed until the moisture content and dens.ity of fill are as previously specified.
All recommendations presented in the attached report are a part of these specifications.
2