HomeMy WebLinkAboutSubsoil StudyKJ-rf $ffiiffifffiiriiå*"'
An Employcc Owncd Compony
5020 CountyRoad 154
Glenwood Springs, CO 81601
phone: (970) 945-7988
fax: (970) 945-8454
email: kaglenwood@kumarusa.com
wwwkumarusa.com
Office Locations: Denver (HQ), Parker, Colorado Springs, Fort Collins, Glenwood Springs, and Summit County, Colorado
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SUBSOIL STUDY
FOR FOT]NDATION DESIGN
PROPOSED SHOP AI\D RESIDENCE
TBD PARACHUTE/RULISON ROAI)
GARFTELD COUNTY, COLORADO
PROJECT NO.20-7-416
SEPTEMBER23,2020
PREPARED FOR:
IVIIKE PERDUE
P.O. BOX 476
PARACHUTE, COLORADO 81635
@
TABLE OF CONTENTS
PURPOSE AND SCOPE OF STUDY.....
PROPOSED CONSTRUCTION ......
SITE CONDITIONS
FIELD EXPLORATION
STIBSURFACE CONDITIONS ..
FOTINDATION BEARING CONDITIONS
DESIGN RECOMMENDATIONS ............
FOI.INDATIONS
FOUNDATION AND RETAINING WALLS
FLOOR SLABS.
TINDERDRAIN SYSTEM ..............
STIRFACE DRAINAGE
LIMITATIONS
FIGURE 1 - LOCATION OF EXPLORATORY BORINGS
FIGURE 2 - LOGS OF EXPLORATORY BORINGS
FIGURE 3 - LEGEND AND NOTES
FIGLIRES 4 and 5 - SWELL-CONSOLIDATION TEST RESULTS
FIGURES 6 and 7 - GRADATION TEST RESULTS
TABLE 1- SUMMARY OF LABORATORY TEST RESULTS
I
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Kumar & Associates. Inc. o Project No.20-7-416
PURPOSE AND SCOPE OF STUDY
This report presents the results of a subsoil study for a proposed shop and residence to be located
on Parachute/Rulison Road, Garfield County, Colorado. The project site is shown on Figure 1.
The purpose of the study was to develop recommendations for the foundation design. The study
was conducted in accordance with our proposal for geotechnical engineering services to Mike
Perdue dated July 23,2020.
A field exploration program consisting of exploratory borings was conducted to obtain
information on the subsurface conditions. Samples of the subsoils obtained durìng the field
exploration were tested in the laboratory to deter-mine their classification, compressibility or
swell and other engineering characteristics. The results of the field exploration and laboratory
testing were analyzedto develop recommendations for foundation types, depths and allowable
pressures for the proposed building foundation. T'his repoft summarizes the data obtained during
this study and presents our conclusions, design recommendations and other geotechnical
engineering considerations basecl on the proposed construction and the subsurface conditions
encountered.
PROPOSED CONSTRUCTION
The proposed residence will be a one story wood frame structure over a walkout basement with
attached garage. The shop will be a 60 by 100 foot steel frame structure. Grouncl floors are
assumed be a combination of structural over crawlspace and slab-on-grade for the residence and
slab-on-grade for the shop. Grading for the structures is assumed to be relatively rninor with cut
depths between about 2 to I0 feet. We assume relatively light foundation loadings, typical of the
proposed type of construction.
If building loadings, location or grading plans change significantly from those described above,
we should be notifiecl to re-evaluate the recomrnendations contained in this report.
SITE CONDITIONS
The subject site was yacant at the tirne of our field exploration. The ground surface is sloping
down to the north at grades of between 5 and 15 percent. There is a steep slope of up to 50o/o
grade to the northwest of the subject site. Vegetation consists of grass and sage brush with
juniper trees near the steep slope to the nofthwest.
Kumar & Associates, lnc. @ Project No. 20-7-416
¡l
F'IELD EXPLORATION
The field exploration for the project was conducted on July 30, 2020. Four exploratory borings
were drilled and two profile pits were excavated at the locations shown on Figure I to evaluate
the subsurface conditions. The borings were advanced with 4 inch diameter continuous flight
augers powered by a truck-mounted CME-458 drill rig. The borings were logged by a
representative of Kumar & Associates, Inc.
Samples of the subsoils were taken wlth I% inch and 2 inch I.D. spoon samplers. The samplers
were driven into the subsoils at various depths with blows from a 140 pound hammer falling 30
inches. This test is similar to the standard penetration test described by ASTM Method D-1586.
The penetration resistance values are an indication of the relative density or consistency of the
subsoils. Depths at which the samples were taken and the penetration resistance values are
shown on Figure 2. The samples were returned to our laboratory for review by the project
engineer and testing.
SUBSURFACE CONDITIONS
Graphic logs of the subsurface conditions encountered at the site are shown on Figure 2. The
subsoils consist of about Yz foot of topsoil overlying very stiffl, low plasticity, sandy clayey silt to
between 3 and 7lzfeet deep. Underlying the silt, silty clayey sand and gravel was encountered to
the maximum drilled depth of 21 feet. Borings I and2 encountered very stiff, high plasticity,
sandy clayey silt to between 12 and 13 feet. Drilling in the dense granular soils with auger
equipment was difficult due to the cobbles and boulders and drilling refusal was encountered in
the deposit in Borings 2 and3.
Laboratory testing performed on samples obtained from the borings included natural moisture
content, density, Atterberg limits and gradation analyses. Results of swell-consolidation testing
performed on relatively undisturbed drive samples, presented on Figures 4 and 5, indicate low to
moderate compressibility under conditions existing conditions and light loading and a low
collapse potential (settlement under constant load) to low swell potential when wetted under
constant light surcharge. Results of gradation analyses performed on small diameter drive
samples (minus I%-inch fraction) of the coarse gtanular subsoils are shown on Figures 6 and7.
The laboratory testing is summarized in Table 1.
No free water was encountered in the borings at the time of drilling and the subsoils were
slightly moist to moist.
Kumar & Associates, lnc. @ Project No,20-7-416
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F'OT]NDATION BEARING CONDITIONS
The shallow sandy clayey silt soils encountered at the site possess low bearing capacity and a
variable swell or collapse potential especially when wetted. The exposed soils in the subgrade
should be evaluated for swell potential at the time of excavation. The underlying gravel soils
possess a moderate bearing capacity and a low settlement potential. 'We anticipate the exposed
subgrade will consist of sandy silt soils. Spread footings placed on the silt soils can be used for
support of the proposed construction can be used with a risk of differential foundation movement
and possible distress, especially if the bearing soils become wetted. A lower risk option would
be to extend the bearing level down to the underlying gravel soils either through sub-excavation
to the gtavel soils and replacement with imported structural fill or a deep foundation system such
as helical piers or drilled piers.
DESIGN RECOMMEIIDATIONS
FOUNDATIONS
Considering the subsurface conditions encountered in the exploratory borings and the nature of
the proposed construction, the buildings can be founded with spread footings bearing on the
natural soils with a risk of foundation movement especially if the bearing soils become wetted.
The design and construction criteria presented below should be observed for a spread footing
foundation system.
1) Footings placed on the undisturbed natural soils should be designed for an
allowable bearing pressure of 1,500 psf. Based on experience, we expect
settlement of footings designed and constructed as discussed in this section will
be up to about 1 inch. A representative of the geotechnical engineer should
observe the exposed soils in the subgrade for swell potential at the time of
excavation. Sub-excavation of expansive soils and placement of at least 3 feet of
structural fill could be needed to mitigate moisture sensitive soils.
2) The footings should have a minimum width of 16 inches for continuous walls and
2 feet for isolated pads.
3) Exterior footings and footings beneath unheated areas should be provided with
adequate soil cover above their bearing elevation for frost protection. Placement
of foundations at least 36 inches below exterior grade is typically used in this
area.
4) Continuous foundation walls should be reinforced top and bottom to span local
anomalies such as by assuming an unsupported length of at least 12 feet.
Foundation walls acting as retaining structures should also be designed to resist
Kumar & Associates, lnc. @ Project No.20-7-416
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lateral earth pressures as discussed in the "Foundation and Retaining Walls"
section of this report.
Topsoil and any loose or disturbed soils should be removed and the footing
bearing level extended down to the natural soils. The exposed soils in footing
area should then be moistened and compacted. If water seepage is encountered,
the footing areas should be dewatered before concrete placement.
A representative of the geotechnical engineer should observe all footing
excavations prior to concrete placement to evaluate bearing conditions.
FOUNDATION AND RETAINING WALLS
Foundation walls and retaining structures which are laterally supported and can be expected to
undergo only a slight amount of deflection should be designed for a lateral earth pressr¡re
computed on the basis of an equivalent fluid unit weight of at least 55 pcf for backfill consisting
of the on-site soils. Cantilevered retaining structures which are separate from the buildings and
can be expected to deflect sufficiently to mobilize the fulI active earth pressure condition should
be designed for a lateral earth pressure computed on the basis of an equivalent fluid unit weight
of at least 45 pcf for backfill consisting of the on-site soils.
All foundation and retaining structures should be designed for appropriate hydrostatic and
surcharge pressures such as adjacent footings, traffic, construction materials and equipment. The
pressures recommended above assume drained conditions behind the walls and a horizontal
backfill surface. The buildup of water behind a wall or an upward sloping backfill surface will
increase the lateral pressure imposed on a foundation wall or retaining structure. An underdrain
should be provided to prevent hydrostatic pressure buildup behind walls.
Backfill should be placed in uniform lifts and compacted to at least 90o/o of the maxlmum
standard Proctor density at a moisture content near optimum. Backfill in pavement and walkway
areas should be compacted to at least 95To of the maximum standard Proctor density. Care
should be taken not to overcompact the backfill or use large equipment near the wall, since this
could cause excessive lateral pressure on the wall. Some settlement of deep foundation wall
backfill should be expected, even if the material is placed correctly, and could result in distress to
facilities constructed on the backfill.
The lateral resistance of foundation or retaining wall footings will be a combination of the
sliding resistance of the footing on the foundation materials and passive earth pressure against
the side of the footing. Resistance to sliding at the bottoms of the footings can be calculated
based on a coefficient of friction of 0.35. Passive pressure of compacted backfill against the
5)
6)
Kumar & Associates, Inc. @ Project No.20-7-416
5
sides of the footings can be calculated using an equivalent fluid unit weight of 325 pcf. The
coefficient of ÍLiction and passive pressure values recommended above assume ultimate soil
strength. Suitable factors of safety should be included in the design to limit the strain which will
occur at the ultimate strength, particularly in the case of passive resistance. Fill placed against
the sides of the footings to resist lateral loads should be compacted to at least 95o/o of the
maximum standard Proctor density at a moisture content near optimum.
FLOOR SLABS
The natural on-site soils, exclusive of topsoil, may be suitable to support lightly loaded slab-on-
grade construction. The exposed underslab soils should be checked for expansion potential at
the time of construction. If expansive soils are encountered, subexcavation of a few feet of soil
and replacement with imported road base may be needed. To reduce the effects of some
differential movement, floor slabs should be separated from all bearing walls and columns with
expansion joints which allow unrestrained vertical movement. Floor slab control joints should
be used to reduce damage due to shrinkage cracking. The requirements for joint spacing and
slab reinforcement should be established by the designer based on experience and the intended
slab use. A minimum 4 inch layer of free-draining gravel should be placed beneath basement
level slabs to facilitate drainage. This material should consist of minus 2-inch aggregate with at
least 50% retained on the No. 4 sieve and less than 2%ó passing the No. 200 sieve.
All fill materials for support of floor slabs should be compacted to at least 95o/o of maximum
standard Proctor density at a moisture content near optimum. Required fill can consist of
imported granular soils such as'/+-inchroad base devoid of vegetation, topsoil and oversized
rock.
LINDERDRAIN SYSTEM
Although free water was not encountered during our exploration, it has been our experience in
the area that local perched groundwater can develop during times of heavy precipitation or
seasonal runoff. Frozen ground during spring runoff can create a perched condition. We
recommend below-grade construction, such as retaining walls, crawlspace and basement areas,
be protected from wetting and hydrostatic pressure buildup by an underdrain system.
The drains should consist of drainpipe placed in the bottom of the wall backfill surrounded above
the invert level with free-draining granular material. The drain should be placed at each level of
excavation and at least 1 foot below lowest adjacent finish grade and sloped at a minimum LYo to
a suitable gravity outlet. Free-draining granular material used in the underdrain system should
contain less than 2Yopassingthe No. 200 sieve, less than 50% passing the No. 4 sieve and have a
Kumar & Associates, lnc. @ Project No.20-7-416
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maximum size of 2 inches. The drain gravel backfill should be at least lY, feet deep. An
impervious membrane such as 20 mil PVC should be placed beneath the drain gravel in a trough
shape and attached to the foundation wall with mastic to prevent wetting of the bearing soils.
SURFACE DRAINAGE
The following drainage precautions should be observed during construction and maintained at all
times after the buildings have been completed:
1) Inundation ofthe foundation excavations and underslab areas should be avoided
during construction.
2) Exterior backfill should be adjusted to near optimum moisture and compacted to
at least 95Yo of the maximum standard Proctor density in pavement and slab areas
and to at least 90Yo of the maximum standard Proctor density in landscape areas.
3) The ground surface surrounding the exterior of the building should be sloped to
drain away from the foundation in all directions. 'We recommend a minimum
slope of 12 inches in the first 10 feet in unpaved areas and a minimum slope of
3 inches in the first 10 feet in paved areas. Free-draining wall backfill should be
capped with about 2 feet of the on-site soils to reduce surface water infiltration.
4) Roof downspouts and drains should discharge well beyond the limits of all
backfill.
5) Landscaping which requires regular heavy imigation should be located at least
10 feet from foundation walls.
LIMITATIONS
This study has been conducted in accordance with generally accepted geotechnical engineering
principles and practices in this area at this time. We make no warranty either express or implied.
The conclusions and recommendations submitted in this report are based upon the data obtained
from the exploratory borings drilled at the locations indicated on Figure 1, the proposed type of
construction and our experience in the area. Our services do not include determining the
presence, prevention or possibility of mold or other biological contaminants (MOBC) developing
in the future. If the client is concerned about MOBC, then a professional in this special field of
practice should be consulted. Our findings include interpolation and extrapolation of the
subsurface conditions identified at the exploratory borings and variations in the subsurface
conditions may not become evident until excavation is performed. If conditions encountered
during construction appear different from those described in this report, we should be notified so
that re-evaluation of the recommendations may be made.
Kumar & Associates, lnc. @ Project No.20-7-416
This report has been prepared for the exclusive use by our client for design pulposes. We are not
responsible for technical interpretations by others of our information. As the project evolves, we
should provjde continued consultation and field services during construction to review and
monitor the implementation of our recommendations, and to veriff that the recommendations
have been appropriately interpreted. Significant design changes may require additional analysis
or modifications to the recommendations presented herein. We recommend on-site observation
of excavations and foundation bearing strata and testing of structural frll by a representative of
the geotechnical engineer.
Respectfully Submitted,
Kumar & Associates, Inc.
H. Parsons, E.I.
Reviewed by:
Daniel E. Hardin,
JHP/kac
Kumar & Assaçiates, lnc. o Project No.20-7-416
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O BORING 2
o PROPOSED RESIDENCE
BORING 1
PP-I I1,,-
2
BOR¡NG ,l
o
o PRoPosED
BORING 5 SHOP
NOT TO SCALE
20-7 -41 6 Kumar & Associates LOCATION OF EXPLORATORY
BORINGS AND PITS Fig. 1
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BORING 1
EL. 60.9'
BORING 2
EL. 53.4'
BORING 3
EL. 94.2'
BORING 4I'E1.91
0 1e/12 0
2s/12
WC=4.2
DD=94
-200=88
23/12
WC=5.8
DD=122
-200=89
5 1s/12
WC=14.7
DD=68
-2OO=46
21 /12
WC=6.4
DD= l 07
1e/12
WC=4.8
DD=1 03
5
26/12
WC=4.3
D0=97
f--l¡l
t¡JtL
I-F.fL
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10
57 /12
WC=5.4
*4=23
-2QO=34
LL=26
Pl=8
36/6, 5s/6
WC=7.2
50/ 1
10
t-l¡J
l"¡Jlr-
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tilô
70/ 12
WC= 14.5
DD=98 -2OQ=22
LL=29
Pl=2
15 27/6, 35/6 15
so /3 50/1
20 2050/2
25 25
PROFILE PIÏ 1 PROFILE PIT 1
0 0
t-t¡¡tJ
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LJo
5
WC=3.1
GRAVEL='l
SAND=38
SILT=50
CLAY=11
5
t--
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LL
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10 10
20-7 -416 Kumar & Associates LOGS OF EXPLORATORY
BORINGS AND PITS Fig. 2
LEGEND
TOPSOIL; SILT, SAND, CLAY, ORGANIC MATTER, SOME GRAVEL AND COBBLES,
MEDIUM DENSE, DRY TO SLIGHTLY MOIST, LIGHT BROWN.
srLr (ML);
CALCAREOU
SLIGHTLY SANDY TO SANDY, MEDIUM DENSE, SLIGHTLY MOIST, TAN, SLIGHTLY
S.
ffiS|LT (ML); SLIGHTLY SANDY TO SANDY, OCCASIONAL MEDIUM GRAVEL, MEDIUM DENSE TO
VERY DENSE, SLIGHTLY MOIST, WHITE CALICHE.
GRAVEL (GC); CLAYEY, SANDY GRAVEL AND SAND ANGULAR, VERY DENSE, SLIGHTLY
MOIST, TAN.
GRAVEL (GM); SILTY, SANDY TO VERY SANDY GRAVEL ANGULAR WITH SOME BASALT
PIECES, VERY DENSE, SLIGHTLY MOIST, TAN.
DRIVE SAMPLE, 2-INCH I.D. CALIFORNIA LINER SAMPLE.
i DRTVE SAMPLE, 1 3/3-INCH l.D. SPLIT SPOON STANDARD PENETRATION TEST
^^ /.ı DRIVE SAMPLE BLOW COUNT. INDICATES THAT 29 BLOWS OF A 14o_POUND HAMMER¿r/ t¿ FALLTNG 50 TNCHES WERE REQU|RED To DRtvE THE SAMPLER 12 tNcHES.
f nnncrrcaL AUGER REFUSAL.
NOTES
1 THE EXPLORATORY BORINGS WERE DRILLED ON JULY 30, 2O2O WITH A 4-INCH-DIAMETER
CONTINUOUS-FLIGHT POWER AUGER.
2, THE EXPLORATORY BORINGS WERE LOCATED BY THE CLIENT
5. THE ELEVATIONS OF THE EXPLORATORY BORINGS WERE MEASURED BY INSTRUMENT LEVEL AND
REFER TO THE GROUND SURFACE AT THE WESTERN MOST ENTRY GATE POST AS 1OO'
ASSUMED.
4. THE EXPLORATORY BORING LOCATIONS AND ELEVATIONS SHOULD BE CONSIDERED ACCURATE
ONLY TO THE DEGREE IMPLIED BY THE METHOD USED.
5. THE LINES BETWEEN MATERIALS SHOWN ON THE EXPLORATORY BORING LOGS REPRESENT THE
APPROXIMATE BOUNDARIES BETWEEN MATERIAL TYPES AND THE TRANSITIONS MAY BE GRADUAL.
6. GROUNDWATER WAS NOT ENCOUNTERED IN THE BORINGS AT THE TIME OF DRILLING.
7, LABORATORY TEST RESULTS:
WC = WATER CONTENT (%) (ASTM D2216);
DD = DRY DENSITY (PCT) (ISTU D2216);
+4 = PERCENTAGE RETAINED ON NO. 4 SIEVE (ASTM D6913);
-2OO= PERCENTAGE PASSING NO. 2OO SIEVE (ASTM Dl1AO);
LL = LIQUID LIMIT (ASTM 0a318);
Pl = PLASTICITY INDEX (ASTM Da318);
GRAVEL = PERCENT RETAINED ON NO. 10 SIEVE;
SAND = PERCENT PASSING No. 1 0 SIEVE AND RETAINED ON NO. 325 SIEVE;
SILT = PERCENT PASSING NO. 525 SIEVE TO PARTICLE SIZE .002MM;
CLAY = PERCENT SMALLER THAN PARTICLE SIZE .002MM.
20-7 -41 6 Kumar & Associates LEGEND AND NOTES Fig. 3
I
SAMPLE OF: Sllghtly Sondy Silt
FROM:Boringl@5'
WC = 4.3 %, DD = 97 pcf
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EXPANSION UNDER CONSTANT
PRESSURE UPON WETTING
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1.0 APPLIEO
APPLIED PRESSURE - KSF
100
-2
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SAMPLE OF: Slightly Sondy Silt with Coliche
FROM: Boring 1 @ 10'
WC = 14.5 %, DD = 98 pcf
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EXPANSION UNDER CONSTANT
PRESSURE UPON WETTING
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20-7 -41 6 Kumar & Associates SWELL-CONSOLIDATION TEST RESULTS Fig. 4
SAMPLE OF: Slightly Sondy to Sondy Silt
FROM:BoringS@5'
WC = 6.4 %, DD = 107 pcf
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EXPANSION UNDER CONSTANT
PRESSURE UPON WETTING
i:
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=U'
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t0 100
-3
f APPLIED PRESSURE - KSF
SAMPLE OF: Slightly Sondy Silt
FROM:Boring4@5'
WC = 4.8 %, DD = 103 pcf
lo tb
:
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ADDITIONAL COMPRESSION
UNDER CONSTANT PRESSURE
DUE TO WETTING
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20-7 -416 Kumar & Associates SWELL-CONSOLIDATION TEST RESULTS Fig. 5
u
f00
90
a0
70
60
50
40
30
20
to
o
10
20
ro
40
50
60
70
ao
s0
to0
=
u
2.O
IN MILLIMETERS
152
DIAMETER OF
CLAY TO SILT COEBLES
GRAVEL 23 % SAND
LIQUID LIMIT 26
SAMPLE OF: Gloyey Sond with Grovôl
43%
PLASTICITY INDEX
SILT AND CLAY 34 %
I
FROM:Borlng2Ot0'
lhalc lcsl rosulls opply only to lho
somplos whlch w€rô losled. The
l€sllng rcporl shqll nol be reproduced,
oxcÊpl ln full, wllhoul lhr wrlll.nqpprcvol of Kumor & Assocloloe, Inc.Sl.v. onolysb lggllng ls porform.d lnqccordonc€ wlth
^STM
D6915, ASTM 07928,
ASTM Cl56 ondlor ASTM 011,10.
HYDROMEIER ANALYSIS SIEVE ANALYSIS
IIVE PADINGS
Z¿ HRS 7 HRS
U.S. IANDARO SEiIES CLEAR SQUARÊ OPENII{CS
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.l-,., l, ,,,.---1,';, 1;),f ,
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SAND GRAVEL
FINE MEDIUM COARSE FINE COARSE
20-7 -416 Kumar & Associates GRADATION TEST RESULTS Fig. 6
SIEVE ANALYSISHYDROMETER ANALYSIS
24 HR, 7 HR 1 MIN.
#325
045
#140 #60 #35 #18 #10 #4 3', 5" 6" 8',100
10
;¿-
/
90
20 80
30 70
tìLIz
t-
LJÉ
Fzt!OE
l-llû
40 60
()z
Ø(n
o_
f-'z
L¡JO
E.
Lrl
o_
50 50
60 4A
70 30
80 20
90 10
100 0.001 .002 .106 .025 .500 1.00 2.00 4.75
DIAMETER OF PARTICLES IN MILLIMETERS
CLAY COBBLES
GRAVEL 1 %SAND 38 %SILT 50 %CLAY 1.1 %
USDA SOIL TYPE: Very Sandy Slightly Loam FROM: PlTl @3'-4.5'
SILT
2A-7-416 Kumar & Associates USDA GRADATION TIST RESULTS lis. 7
l(+rtiffififfiffi*iii*"'TABLE 1SUMMARY OF LABORATORY TEST RESULTSProject No.20-7-4161 ol2SOIL ÌYPESlightly Sandy SiltSlightly Sandy SiltSlightly Sandy Silt withCalicheSand and SiltClayey Sand with GravelSlightly Sandy to SandySiltSlightly Sandy to SandySiltSilty Sandy GravelSlightly Sandy Silt(ps0UNCONFINEDCOMPRESSIVESTRENGTHP/"1PTASTICINDEXI2ATTERBERG LIMITS(%tLIQUID LIMIT262946PERCENTPASSING NO.200 stEVE883489224323NATURALDRYDENSITYGRADATIONSAND$tGRAVELtf/"|94979868t22r07103tololNATURALMOISTURECONTENT4.24.314.514.75.4s.86.47.24.82%5105102/z5015SAMPLE LOCATIONDEPTHBoring/PitBoring 1Boring 2Boring 3Boring 4
l(+rtiffififfiffi*,'å--'TABLE 1SUMMARY OF LABORATORY TEST RESULTSProiect No.20-74162ol2SOIL TYPEVery Sandy SlightlyClavev SiltCLAY$t1150SILT(%)It'lrlSAND38USDA SOIL TEXTURE(%)GRAVEL1SILT&CLAY{%)SAND(%)GRADATIONGRAVEL(%)NATURALDRYDENSIÏY(pcr)NATURALMOISTURECONTENTV"l1aJDEPTH(ft)3-4%ProfilePit ISAMPLE LOCATIONPIT
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Soil Texture Calculator
Use th¡s onl¡ne tool to calculate ã s¡ngle po¡nt texture class based on percent sand, silt, and clay. Including the
optional sand fractions w¡ll ref¡ne the calculation.
Or download a Microsoft Excel Macro-enabled spreadsheet to develop total sand, silt, and clay low,
representative, and high values using an interactive texture triangle w¡th textures that toggle on and off.
Download Interact¡ve Texture Tr¡angle Excel Version (XLSM; 6.11 MB)
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