HomeMy WebLinkAboutHARMONY SAFEWAY, CENTENNIAL BANK - FDP - 33-94D - SUBMITTAL DOCUMENTS - ROUND 1 - GEOTECHNICAL (SOILS) REPORTTABLE D2
RECOMMENDED PREVENTATIVE MAINTENANCE POLICY
FOR JOINTED CONCRETE PAVEMENTS
Distress
Distress
Recommended
Distress
Distress
Recommended
Type
Severity
Maintenance
Type
Severity
Maintenance
Low
None
No
Medium
Full -Depth
Blow-up
Porished
Severity
Groove Surface
or
Concrete Patch/
Aggregate
Levels
Overlay
High
Slab Replacement
Defined
Low
Seal Cracks
No
Medium
Full -Depth
Comer
Break
Popouts
Severity
Levels
None
High
Concrete Patch
Defined
Low
Seal Cracks
No
Underseal,
Divided
Medium
Pumping
Severity
Seal cracks/joints
and
Slab
Slab
Levels
Restore
High
Replacement
Defined
Load Transfer
Low
None
Low
Seal Cracks
Medium
Full -Depth Patch
Medium
Full -Depth
Durability
Punchout
Cracking
Concrete
High
Slab Replacement
High
Patch
Low
None
Low
No
Medium
Medium
Faulting
Railroad
Crossing
Policy
for this
Grind
High
High
Project
Low
None
Scaling
Low
None
Medium
Reseal
Medium
Slab Replacement,
Joint
Seal
Map Cracking
Crazing
Joints
Full -depth Patch,
High
High
or Overlay
Low
Regrade and
No
Medium
Lane/Shoulder
Fill Shoulders
Shrinkage
Severity
None
Drop-off
to Match
Cracks
Levels
High
Lane Height
Defined
Linear Cracking
Low
Clean &
Low
None
Longitudinal,
Transverse and
Seal all Cracks
Spalling
Medium
Medium
(Comer)
Partial -Depth
High
Full -Depth Patch
High
Diagonal
Cracks
Concrete Patch
Low
None
Low
None
Large Patching
S ailin
and
Medium
Seal Cracks or
(Joint)
Medium
Partial -Depth Patch
High
High
Reconstruct Joint
Utility Cuts
Replace Patch
Low
None
Medium
Replace
Small
Patching
Patch
High
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" .. a
TABLE D7
RECOMMENDED PREVENTATIVE MAINTENANCE POLICY
FOR ASPHALT CONCRETE PAVEMENTS
Distress
Distress
Recommended
Distress
Distress
Recommended
Type
Severity
Maintenance
Type
Severity
Maintenance
Low
None
Low
None
Alligator
Cracking
Patching &
Utility Cut
Patching
Medium
Full -Depth
Asphalt Concrete
Medium
Full -Depth
Asphalt Concrete
High
Patch
High
Patch
Low
None
Low
Bleeding
Polished Aggregate
None
Medium
Surface Sanding
Medium
High
Shallow AC Patch
High
Fog Seal
Low
None
Low
Shallow AC Patch
Medium
Clean &
Seal
Medium
Full -Depth
Asphalt Concrete
Block
Cracking
Potholes
High
All Cracks
High
Patch
Bumps &
Sags
Low
None
Railroad
Crossing
Low
No Policy
for
This Project
Medium
Shallow AC Patch
Medium
High
Full -Depth Patch
High
Low
None
Low
None
Medium,_
Full -Depth
Asphalt Concrete
Medium
Shallow AC Patch
Corrugation
Rutting
High
Patch
High
Full -Depth Patch
Low
None
Low
None
Medium
Shallow AC Patch
Medium
Mill &
Depression
Shoving
Shallow AC
High
Full -Depth Patch
High
Patch
Low
None
Low
None
Edge Cracking
Medium
Seal Cracks
Slippage Cracking
Medium
Shallow
Asphalt Concrete
High
Full -Depth Patch
High
Patch
Low
Clean &
Low
None
Joint
Reflection
Seal
All Cracks
Swell
Medium
Medium
Shallow AC Patch
High
Shallow AC Patch
High
Full -Depth Patch
Low
None
Low
Lane/Shoulder
Drop -Off
Weathering
& Ravelling
Fog
Seal
Medium
Regrade
Shoulder
Medium
High
High
Low
None
Longitudinal &
Transverse
Cracking
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Medium
Clean &
Seal
All Cracks
High
REPORT TERMINOLOGY
(Based on ASTM 13653)
Expansive Potential The potential of a soil to expand (increase in volume) due to absorption of
moisture.
Finished Grade
The final grade created as a part of the project.
Footing
A portion of the foundation of a structure that transmits loads directly to the
soil.
Foundation
The lower part of a structure that transmits the loads to the soil or bedrock.
Frost Depth
The depth of which the ground becomes frozen during the winter season.
Grade Beam
A foundation element or wall, typically constructed of reinforced concrete,
used to span between other foundation elements such as drilled piers.
Groundwater
Subsurface water found in the zone of saturation of soils, or within fractures
in bedrock.
Heave
Upward movement.
Lithologic
The characteristics which describe the composition and texture of soil and
rock by observation.
Native Grade
The naturally occuring ground surface.
Native Soil
Naturally occurring on -site soil, sometimes referred to as natural soil.
Optimum Moisture
The water content at which a soil can be compacted to a maximum dry unit
Content
weight by a given compactive effort.
Perched Water
Groundwater, usually of limited area maintained above a normal water
elevation by the presence of an intervening relatively impervious continuing
stratum.
Scarify
To mechanically loosen soil or break down existing soil structure.
Settlement
Downward movement.
Skin Friction (Side
The frictional resistance developed between soil and an element of structure
Shear)
such as a drilled pier or shaft. -
Soil (earth)
Sediments or other unconsolidated accumulations of solid particles produced
by the physical and chemical disintegration of rocks, and which may or may
not contain organic matter.
Strain
The change in length per unit of length in a given direction.
Stress
The force per unit area acting within a soil mass.
Strip
To remove from present location.
Subbase
A layer of specified material in a pavement system between the subgrade and
base course.
Subgrade
The soil prepared and compacted to support a structure, slab or pavement
system.
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REPORT TERMINOLOGY
(Based on ASTM 13653)
Allowable Soil
The recommended maximum contact stress developed at the interface of the
Bearing Capacity
foundation element and the supporting material.
Alluvium
Soil, the constituents of which have been transported in suspension by flowing
water and subsequently deposited by sedimentation.
Aggregate Base
A layer of specified material placed on a subgrade or subbase usually beneath
Course
slabs or pavements.
Backfill
A specified material placed and compacted in a confined area.
Bedrock
A natural aggregate of mineral grains connected by strong and permanent
cohesive forces. Usually requires drilling, wedging, blasting or other methods of
extraordinary force for excavation.
Bench
A horizontal surface in a sloped deposit.
Caisson (Drilled pier
A concrete foundation element cast in a circular excavation which may have an
or Shaft)
enlarged base. Sometimes referred to as a cast-in=place pier or drilled shaft.
Coefficient of
A constant proportionality factor relating normal stress and the corresponding
Friction
shear stress at which sliding starts between the two surfaces.
Coluuvium
Soil, the constituents of which have been deposited chiefly by gravity such as
at the foot of a slope or cliff.
Compaction
The densification of a soil by means of mechanical manipulation.
Concrete Slab -on-
A concrete surface layer cast directly upon a base, subbase or subgrade, and
Grade
typically used as a floor system.
Differential
Unequal settlement or heave between, or within foundation elements of a
Movement
structure.
Earth Pressure
The pressure or force exerted by soil on any boundary such as a foundation
wall.
ESAL
Equivalent Single Axle Load, a criteria used to convert traffic to a uniform
standard, 0 8,000 pound axle loads).
Engineered Fill
Specified material placed and compacted to specified density and/or moisture
conditions under observations of a representative of a geotechnical engineer.
Equivalent Fluid
A hypothetical fluid having a unit weight such that it will produce a pressure
against a lateral support presumed to be equivalent to that produced by the
actual soil. This simplified approach is valid only when deformation conditions
are such that the pressure increases linearly with depth and the wall friction is
neglected.
Existing Fill (or
Materials deposited through the action of man prior to exploration of the site.
man-made rill)
Existing Grade
The ground surface at the time of field exploration.
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LABORATORY TESTS
SIGNIFICANCE AND PURPOSE
TEST
SIGNIFICANCE
PURPOSE
California
Used to evaluate the potential strength of subgrade soil,
Pavement
Bearing
subbase, and base course material, including recycled
Thickness
Ratio
materials for use in road and airfield pavements.
Design
Conso/idation
Used to develop an estimate of both the rate and amount of
Foundation
both differential and total settlement of a structure.
Design
Direct
Used to determine the consolidated drained shear strength of
Bearing Capacity,
Shear
soil or rock.
Foundation Design &
Slope Stability
Dry
Used to determine the in -place density of natural, inorganic,
Index Property
Density
fine-grained soils.
Soil Behavior
Used to measure the expansive potential of fine-grained soil
Foundation & Slab
Expansion
and to provide a basis for swell potential classification.
Design
Used for the quantitative determination of the distribution of
Soil
Gradation
particle sizes in soil.
Classification
Liquid &
Used as an integral part of engineering classification systems
Plastic Limit,
to characterize the fine-grained fraction of soils, and to
Soil
Plasticity
specify the fine-grained fraction of construction materials.
Classification
Index
Used to determine the capacity of soil or rock to conduct a
Groundwater
Permeability
liquid or gas.
Flow Analysis
Used to determine the degree of acidity or alkalinity of a soil.
Corrosion
p H
Potential
Used to indicate the relative ability of a soil medium to carry
Corrosion
Resistivity
electrical currents.
Potential
Used to evaluate the potential strength of subgrade soil,
Pavement
R-Value
subbase, and base course material, including recycled
Thickness
materials for use in road and airfield pavements.
Design
Soluble
Used to determine the quantitative amount of soluble
Corrosion
Sulphate
sulfates within a soil mass.
Potential
To obtain the approximate compressive strength of soils that
Bearing Capacity
Unconfined
possess sufficient cohesion to permit testing in the
Analysis
Compression
unconfined state.
for
Foundations
Water
Used to determine the quantitative amount of water in a soil
Index Property
Content
mass.
Soil Behavior
__ lrarracon
UNIFIED SOIL CLASSIFICATION SYSTEM
Criteria for Assigning Group Symbols and Group Names Using Laboratory Testd'
Coarse -Grained Gravels more than Clean Gravels Less Cu > 4 and 1 < Cc <3E
Soils more than 50% of coarse than 5% finesc
50% retained on fraction retained on
No. 200 sieve No. 4 sieve Cu < 4 and/or 1 > Cc > 3'
Gravels with Fines c Fines classify as ML or MH
more than 12% fines
Fines classify as CL or CH
Sands 50% or more Clean Sands Less
Cu > 6 and 1 < Cc < 3E
of coarse fraction than 5% fines'
passes No. 4 sieve
Cu < 6 and/or 1 > Cc > 3E
Sands with Fines
Fines classify as ML or MH
more than 12% fines°
Fine -Grained Soils Silts and Clays
50% or more Liquid limit less
passes the than 50
No. 200 sieve
Silts and Clays
Liquid limit 50
or more
Highly organic soils Prim
ABased on the material passing the 3-in.
(75-mm) sieve
elf field sample contained cobbles or
boulders, or both, add "with cobbles or
boulders, or both" to group name.
cGravels with 5 to 12% fines require dual
symbols:
GW-GM well -graded gravel with silt
GW-GC well -graded gravel with clay
GP -GM poorly graded gravel with silt
GP -GC poorly graded gravel with clay
°Sands with 5 to 12% fines require dual
symbols:
SW-SM well -graded sand with silt
SW -SC well -graded sand with clay
SP-SM poorly graded sand with silt
SP-SC poorly graded sand with clay
m
50
X 40
0
Z
30
U_
20
a
10
r
4
0
0
inorganic
organic
inorganic
organic
Fines Classify as CL or CH
PI > 7 and plots on or above "A line'
PI < 4 or plots below "A" line'
Liquid limit - oven dried
< 0.75
Liquid limit - not dried
PI plots on or above "A" line
PI lots below "A" line
Liquid limit - oven dried
< U.75
Liquid limit - not dried
matter, dark in color, and organic odor
(D30)9
aCu'Dse/Dio CC.(
Doo X Dso
FIf soil contains > 15% sand, add "with
sand" to group name.
olf fines classify as CL-ML, use dual symbol
GC -GM, or SC-SM.
"If fines are organic, add "with organic fines"
to group name.
'If soil contains > 15% gravel, add "with
gravel" to group name.
'If Atterberg limits plot in shaded area, soil is
a CL-ML, silty clay.
Soil Classification
Group Group Name'
GW Well -graded gravel`
GP Poodv oradad nrave
GM Silty gravel,G,H
GC
Clayey gravel"AN
SW
Wall -graded sand'
SP
Poorly graded sand'
SM
Silty sand°•"•'
SC
Clayey sando,"'
CL
Lean clay'-LM
ML
SiltK,L,M
OL
Organic clay'LLKN
Organic silt'L`"
CH
Fat clayK,L-M
MH
Elastic Silt"M
MrIT
siltKI-M•o
PT Peat
KIf soil contains 15 to 29% plus No. 200, add
.with sand" or "with gravel", whichever is
predominant.
Llf soil contains > 30% plus No. 200
predominantly sand, add "sandy" to group
name.
MY soil contains > 30% plus No. 200,
predominantly gravel, add "gravelly" to group
name.
"PI > 4 and plots on or above "A" line.
°PI < 4 or plots below "A" line.
PPI plots on or above "A" line.
'PI plots below "A" line.
For .1... Meehan of fine —,rain" coil.
and lin.jtroin.d feocllnn of team.—
1.
E,mGon of 'e'
"then �t 0..73 (L to L2La;
E,..oah of V — line
Vertical at LL " IK to
then a 0.9
OQ-
OIL
MH DR
OH
ML DR OL
10 fd 20 3o a w m 70 eo 9a too to
LIQUID LIMIT (LL)
Berracon
4'4
DRILLING AND EXPLORATION
DRILLING & SAMPLING SYMBOLS:
R : Ring Barrell - 2.42" I.D., 3" O.D., unless otherwise noted
SS : Split Spoon - 1%n I.D., 2" O.D., unless otherwise noted
PS : Piston Sample
ST : Thin -Walled Tube - 2" O.D., unless otherwise noted
WS : Wash Sample
PA : Power Auger
FT : Fish Tail Bit
HA : Hand Auger
RB : Rock Bit
DB : Diamond Bit = 4", N, B
BS : Bulk Sample
AS : Auger Sample
PM : Pressure Meter
HS : Hollow Stem Auger
DC : Dutch Cone
WB : Wash Bore
Penetration Test: Blows per foot of a 140 pound hammer falling 30 inches on a 2-inch O.D. split spoon, except where
noted.
WATER LEVEL MEASUREMENT SYMBOLS:
WL : Water Level WS : While Sampling
WCI : Wet Cave in WD : While Drilling
DCI : Dry Cave in BCR : Before Casing Removal
AB : After Boring ACR : After Casting Removal
Water levels indicated on the boring logs are the levels measured in the borings at the time indicated. In pervious soils,
the indicated levels may reflect the location of groundwater. In low permeability soils, the accurate determination of
groundwater levels is not possible with only short term observations.
DESCRIPTIVE SOIL CLASSIFICATION:
Soil Classification is based on the Unified Soil Classification system and the ASTM Designations D-2487 and D-2488.
Coarse Grained Soils have more than 50% of their dry weight retained on a #200 sieve; they are described as: boulders,
cobbles, gravel or sand. Fine Grained Soils have less than 50% of their dry weight retained on a #200 sieve; they are
described as: clays, if they are plastic, and silts if they are slightly plastic or non -plastic. Major constituents may be
added as modifiers and minor constituents may be added according to the relative proportions based on grain size. In
addition to gradation, coarse grained soils are defined on the basis of their relative in -place density and fine grained soils
on the basis of their consistency. Example: Lean clay with sand, trace gravel, stiff (CL); silty sand, trace gravel, medium
dense ISM).
CONSISTENCY OF FINE-GRAINED SOILS:
Unconfined Compressive
Strength, Ou, psf
Consistency
< 500
Very Soft
500 - 1,000
Soft
1,001 - 2,000
Medium
2,001 - 4,000
Stiff
4,001 - 8,000
Very Stiff
8,001-16,000
Very Hard
RELATIVE PROPORTIONS OF
SAND AND GRAVEL
Descriptive Term(s)
(of Components Also
Percent of
Present in Sample)
Dry Weight
Trace
< 15
With
15 - 29
Modifier
> 30
RELATIVE PROPORTIONS OF FINES
Descriptive Term(s)
(of Components Also
Percent of
Present in Sample)
Dry Weight
Trace
< 5
With
5 - 12
Modifier
> 12
RELATIVE DENSITY OF
COARSE -GRAINED SOILS:
N-Blows/ft.
Relative Density
0-3
Very Loose
4-9
Loose
10-29
Medium Dense
30-49
Dense
50-80
Very Dense
80+
Extremely Dense
GRAIN SIZE TERMINOLOGY
Major Component
of Sample
Size Range
Boulders
Over 12 in. (300mm)
Cobbles
12 in. to 3 in.
(300mm to 75mm)
Gravel
3 in. to #4 sieve
(75mm to 4.75mm)
Sand
#4 to #200 sieve
(4.75mm to 0.075mm)
Silt or Clay
Passing #200 Sieve
(0.075mm)
lrerracon
SUNMARY OF TEST RESULTS
PROJECT NO. 20965128
Boring
No.
Depth
Ft.
Moisture
%
Dry
Density
(PCF)
Compressive
Strength
(PSF)
Swell
Pressure
(PSF)
Soluble
Sulfates
%
pH
Liquid
Limit
%
Plasticity
Index
%
Group
Index
Classification
AASHTO
USCS
Resistivity
(OHM -CM)
Penetration
Blow/In.
1
.5-1.5
10
11/12
3-4
14
113
21,810
1430
.0033
4-5
12
14/12
7-8
11
117
23,850
8-9
11
19/12
14-15
22
6/12
19-20
21
18/12
2
0-1
11
10/12
1-2
15/12
4-5
13
15/12
9-10
16
11/12
Comp.
Samp.
.5.4.0
35
18
11
A-6(11); CL
3
0-1
35
20
9
A-6(9); CL
8/12
1-2
13
12/12
4-5
11
12/12
9-10
10
14/12
Irerracon
CONSULTANTS WESTERN, INC.
301 North Howes Street
Fort Collins, Colorado 80521
(970) 484-0359 FAX (970) 484-0454
CLIENT: Safeway
PROJECT: Harmony Market
LOCATION: 2 @ 0.5-4
TERRACON NO. 20965128 CLASSIFICATION: See Aft
TEST SPECIMEN NO.
1
2
3
COMPACTION PRESSURE (PSI)
100
120
140
DENSITY (PCF)
101.5
104.7
106.2
MOISTURE CONTENT (%)
22.4
21.4
20.4
EXPANSION PRESSURE
0.00
0.00
0.00
HORIZONTAL PRESSURE @ 160 PSI
139
135
130
SAMPLE HEIGHT (INCHES)
2.52
2.47
2.52
EXUDATION PRESSURE (PSI)
257.8
290.4
319.0
CORRECTED R-VALUE
9.6
12.6
15.5
UNCORRECTED R-VALUE
9.7
12.4
15.6
R-VALUE @ 300 PSI EXUDATION PRESSURE = =
100
90
80
70
w 60
a 50
40
30
20
10
0
100 200 300 400 500 600 700 800
EXUDATION PRESSURE - PSI
LOG OF BORING No. 3
Page 1 of 1
CLIENT
ARCHITECT / ENGINEER
Safeway Inc.
Concept West Architecture, Inc.
SITE Harmony Safeway Marketplace
PROJECT
Fort Collins, Colorado
Safeway Store #1552
SAMPLES
TESTS
o
o
':
o
}
U
DESCRIPTION
a:z\
M
z
HF-
w cn
H
2
2
In
W
W
W
>
i In
:3
F-
W
O
LL. CD
Z Z
[O fn W
O: F- Z
O.
I-
O.
to
U
CO
E
W
O-
O
U
3
F-O
to
H
YLL
O W
UXLL
W H H
HELL.
LD
Approx. Surface Elev.: 4975.5 ft.
WC
M
z
W
Nm
E
oa
Mu~ia
~¢_j X
",°""
0.5 6" TOPSOIL 4975.0
CL
1
SS
12"
8
13
35/20/60
SANDY LEAN CLAY
2
SS
12"
12
Brown to tan, dry to moist,
Stiff to very stiff
CL
3
SS
12"
12
10
5
4
SS
12"
14
10
10.0 4965.5
10
BOTTOM OF BORING
THE STRATIFICATION LINES REPRESENT THE APPROXIMATE BOUNDARY LINES
BETWEEN SOIL AND ROCK TYPES: IN -SITU, THE TRANSITION MAY BE GRADUAL.
WATER LEVEL OBSERVATIONS
BORING STARTED 8-20-96
�
g None W.D.=None
A B
RING COMPLETED 20_96
11rerracon
RIG CME-55
FORFMg DML
wL
Water checked 3 days A.B.
APPROVED NRS
Job N 20965128
LOG OF BORING No. 2
Page 1 of 1
CLIENT
ARCHITECT i ENGuvEER
Safeway Inc.
Concept West Architecture, Inc.
SITE Harmony Safeway Marketplace
PROJECT
Fort Collins, Colorado
Safeway Store #1552
SAMPLES
TESTS
g
\
Y
C9
J
c�
DESCRIPTION
LL
}
W
z\
W
z
H�
w cn
=
x
In
W
W
W
L U)
t—
W
❑
LLcD
zz
McnW
Wf-z
0-
F
W
m
W
O
3
to
ow
W H H
d
U
E
0-
CJ
FO
H
>lL
UWLL
Hz LL
CD
Approx. Surface Elev.: 4978.5 ft.
C3
z
W
Cn m
E
o a
� Cn 0-¢
�
" " "
0.5 6" TOPSOIL 4978.0
T $AN CLAY
CL
1
SS
12"
10
11
2
SS
12"
15
2.0 Brown, dry to moist, stiff 4976.5
35/18/72
LFAN CLAY WITH SAND AND
3
BS
GRAYEL
Red to tan, moist,
CL
4
SS
12"
15
13
Stiff to very stiff
composite sample 0 0.5' - 4.0'
S
5
SS
12"
11
16
10.0 4968.5
10
BOTTOM OF BORING
THE STRATIFICATION LINES REPRESENT THE APPROXIMATE BOUNDARY LINES
BETWEEN SOIL AND ROCK TYPES: IN -SITU, THE TRANSITION MAY BE GRADUAL.
WATER LEVEL OBSERVATIONS
r�rr icon
BORING STARTED 8-20-96
None WD
= None A B
BORING COMPLETED 8-20-96
V
RIG CME-55
FOREMAN DML
Water checked 3 days A.B.
APPROVED - — -
JOB a 20965128
LOG OF BORING No. 1 Page 1 of 1
CLIENT
ARCHITECT / ENGINEER
Safeway Inc.
Concept West Architecture, Inc.
SITE Harmony Safeway Marketplace
PROJECT
Fort Collins, Colorado
Safeway Store #1552
SAMPLES
TESTS
W
CO
x:
z
W
O.
w
>
O
U
W
z\
i N
3
FO
Nm
X
j
H
fn
H
E
}
z
O
>-LL
ona.
H
ZZ
ow
L)XLL
�u~)a.
JU)
J U)
WWLL
U))O-a.
C7
L)
2
(L
0
DESCRIPTION
Approx. Surface Elev.: 4979.0 ft.
LL
S
F
(L
C3
J
N
fA
U
^^"^"
0.5 6" TOPSOIL 4978.5
LEAN CLAY
Brown, dry to moist, stiff
CL
1
SS
12"
11
10
3.5 4975.5
1430
2
ST
12"
14
113
21810
CL
3
SS
12"
14
12
LEAN CLAY WITH SAND A_hM
GRAVEL
5
Red to tan, moist to wet
Medium to very hard
625
4
ST
12"
11
117
23850
5
SS
12"
19
11
=
10
Sz
6
SS
12"
6
22
IS
17.5 4961.5
SILTY SAND
Tan, wet, medium dense
SM
7
SS
12"
18
21
20.0 4959.0
20
BOTTOM OF BORING
THE STRATIFICATION LINES REPRESENT THE APPROXIMATE BOUNDARY LINES
BETWEEN SOIL AND ROCK TYPES: IN -SITU, THE TRANSITION MAY BE GRADUAL.
WATER LEVEL OBSERVATIONS
BORING STARTED 8-20-96
WL
14.6 W D
= 10.3 A.B.
RING COMPLETED
MAN -96
IL
11rerracon
RIGCME-55
FORD DML
`
Water checked 3 days A.B.
APPROVED NRS
JOB R 20965128
No. 3�
No. 30
C •
TBM MANHOLE AnO ! - � A R O -
RIM = ELEV. 4981.3' `e` /- j, No, 0
�No.4 No. 9-i' • No.27 N•2
5 • No.15
No� \/ " PROPOSED \ No.
SAFEWAY • No.14
\ • • No.4 BUILDING • No.10 ♦ No.28
FF=ELEV. 80.5 • No.l6
.. ,, `` • No.24
W \, , • No.3 • No.17 • No.18
j \ •No.13
Q 1, • No.11 • No.25
Q No.3
I • No.2
O I • No.1 No•2 • No. • No.19
No.2
Q i •
Lu
�II
_ J
• No.32
• No.20 • No.21
HARMONY ROAD
F-----------------------------
FIGURE 1: SITE PLAN
HARMONY SAFEWAY MARKETPLACE
FORT COLLINS, COLORADO
TCW INC. PROJECT No. 20965128
LEGEND
• BORING DRILLED IN OCTOBER 1980
BORING DRILLED IN AUGUST 1996
• No.22
Q
i G
• No.29
N
SCALE 1" = 200'
Irerracon
CONSULTANTS WESTERN. INC.
EMPIRE DIVISION
Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20965128
GENERAL COMMENTS
It is recommended that the Geotechnical Engineer be retained to provide a general review of
final design plans and specifications in order to confirm that grading and foundation
recommendations have been interpreted and implemented. In the event that any changes of
the proposed project are planned, the conclusions and recommendations contained in this
report should be reviewed and the report modified or supplemented as necessary.
The Geotechnical Engineer should also be retained to provide services during excavation,
grading, foundation and construction phases of the work. Observation of footing excavations
should be performed prior to placement of reinforcing and concrete to confirm that satisfactory
bearing materials are present and is considered a necessary part of continuing geotechnical
engineering services for the project. Construction testing, including field and laboratory
evaluation of fill, backfill, pavement materials, concrete and steel should be performed to
determine whether applicable project requirements have been met. It would be logical for
Terracon Consultants Western, Inc. to provide these additional services for continuing from
design through construction and to determine the consistency of field conditions with those
data used in our analyses.
The analyses and recommendations in this report are based in part upon data obtained from
the field exploration. The nature and extent of variations beyond the location of test borings
may not become evident until construction. If variations then appear evident, it may be
necessary to re-evaluate the recommendations of this report.
Our professional services were performed using that degree of care and skill ordinarily
exercised, under similar circumstances, by reputable geotechnical engineers practicing in this
or similar localities. No warranty, express or implied, is made. We prepared the report as an
aid in design of the proposed project. This report is not a bidding document. Any contractor
reviewing this report must draw his own conclusions regarding site conditions and specific
construction techniques to be used on this project.
This report is for the exclusive purpose of providing geotechnical engineering and/or testing
information and recommendations. The scope of services for this project does not include,
either specifically or by implication, any environmental assessment of the site or identification
of contaminated or hazardous materials or conditions. If the owner is concerned about the
potential for such contamination, other studies should be undertaken.
19
Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20965128
Additional Design and Construction Considerations
Exterior Slab Design and Construction
Exterior slabs -on -grade, exterior architectural features, and utilities founded on, or in
backfill may experience some movement due to the volume change of the backfill.
Potential movement could be reduced by:
• minimizing moisture increases in the backfill
• controlling moisture -density during placement of backfill
• using designs which allow vertical movement between the exterior features and
adjoining structural elements
• placing effective control joints on relatively close centers
• allowing vertical movements in utility connections
• Underground Utility Systems
All piping should be adequately bedded for proper load distribution. It is suggested that
/ clean, graded gravel compacted to 75 percent of Relative Density ASTM D4253 be
used as bedding. Where utilities are excavated below groundwater, temporary
dewatering will be required during excavation, pipe placement and backfilling
operations for proper construction. Utility trenches should be excavated on safe and
stable slopes in accordance with OSHA regulations as discussed above. Backfill
should consist of the on -site soils or existing bedrock. If bedrock is used, all plus 6-inch
material should be removed from it prior to its use. The pipe backfill should be
compacted to a minimum of 95 percent of Standard Proctor Density ASTM D698.
All underground piping within or near the proposed structure should be designed with
flexible couplings, so minor deviations in alignment do not result in breakage or
distress. Utility knockouts in grade beams should be oversized to accommodate
differential movements.
Corrosion Protection
Results of soluble sulfate testing indicate that ASTM Type 1-II Portland cement is
suitable for all concrete on or below grade. Foundation concrete should be designed in
accordance with the provisions of the ACI Design Manual, Section 318, Chapter 4.
18
Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20965128
Maximum Slope
Material Horizontal:Vertical
Cohesive soils (clays).................................................................................3:1
Detention pond slopes................................................................................3:1
If steeper slopes are required for site development, stability analyses should be
completed to design the grading plan.
Compliance
Performance of slabs -on -grade, foundations and pavement elements supported on
compacted fills or prepared subgrade depend upon compliance with "Earthwork"
recommendations. To assess compliance, observation and testing should be
performed under the direction of the geotechnical engineer.
Excavation and Trench Construction
Excavations into the on -site soils will encounter a variety of conditions. Excavations
into the clays can be expected to stand on relatively steep temporary slopes during
construction. However, caving soils and/or groundwater may also be encountered.
The individual contractor(s) should be made responsible for designing and constructing
stable, temporary excavations as required to maintain stability of both the excavation
sides and bottom. All excavations should be sloped or shored in the interest of safety
following local and federal regulations, including current OSHA excavation and trench
safety standards.
The soils to be penetrated by the proposed excavations may vary significantly across
the site. The preliminary soil classifications are based solely on the materials
encountered in widely spaced exploratory test borings. The contractor should verify
that similar conditions exist throughout the proposed area of excavation. If different
subsurface conditions are encountered at the time of construction, the actual conditions
should be evaluated to determine any excavation modifications necessary to maintain
safe conditions.
As a safety measure, it is recommended that all vehicles and soil piles be kept to a
minimum lateral distance from the crest of the slope equal to no less than the slope
height. The exposed slope face should be protected against the elements.
16
I
Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20965128
beneath pavement should be compacted within a moisture content range of 2
percent below to 2 percent above optimum.
5. Granular soils should be compacted within a moisture content range of 3 percent
below to 3 percent above optimum unless modified by the project geotechnical
engineer.
6. If a well defined maximum density curve cannot be generated by impact
compaction in the laboratory for any fill type, engineered fill should be compacted
to a minimum of 75 percent relative density as determined by ASTM D4253
D4254.
Shrinkage
For balancing grading plans, estimated shrink or swell of soils and bedrock when used
as compacted fill following recommendations in this report are as follows:
Material
Estimated Shrink(-) Swell (+)
Based on ASTM D698
On -site soils:
Clays.....................................................................................15 to -20%
Slopes:
1. For permanent slopes in compacted fill areas, maximum slope angles of 21/21
(horizontal to vertical) for on -site materials are recommended. If steeper slopes
are required for site development, stability analyses should be completed to design
the grading plan.
2. The face of all slopes should be compacted to the minimum specification for fill
embankments. Alternately, fill slopes can be over -built and trimmed to compacted
material.
3. For permanent slopes in cut areas, the following maximum angles are
recommended as follows:
15
Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20965128
Percent fines by weight
Gradation (ASTM C136)
6"..........................................................................................................100
3".....................................................................................................70-100
No. 4 Sieve........................................................................................50-80
No. 200 Sieve...............................................................................50 (max)
• Liquid Limit.......................................................................35 (max)
• Plasticity Index..................................................................15 (max)
• Minimum R-value.......................................................................14
6. Aggregate base should conform to Colorado Department of Transportation Class 5
or 6 specifications.
Placement and Compaction:
1. Place and compact fill in horizontal lifts, using equipment and procedures that will
produce recommended moisture contents and densities throughout the lift.
J 2. No fill should be placed over frozen ground.
3. Materials should be compacted to the following:
f iffMn
Minimum Percent Compaction
(ASTM D698)
Subgrade soils beneath fill areas.........................................................................95
On -site soils or approved imported fill:
Beneathfoundations...........................................................................98
Beneathslabs.....................................................................................95
Beneathpavements............................................................................95
Utilities.................................................................................................95
Aggregate base (beneath slabs).........................................................95
Miscellaneousbackfill.........................................................................90
4. Clay soils placed around or beneath foundations should be compacted within a
moisture content range of optimum to 2 percent above optimum. Clay soils placed
14
Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20965128
2. Depending upon depth of excavation and seasonal conditions, groundwater may
be encountered in excavations on the site. Pumping from sumps may be utilized
to control water within excavations. Well points may be required for significant
groundwater flow or where excavations penetrate groundwater to a significant
depth.
3. On -site clay soils in proposed pavement areas may pump or become unstable or
unworkable at high water contents. Workability may be improved by scarifying and
drying. Overexcavation of wet zones and replacement with granular materials may
be necessary. Lightweight excavation equipment may be required to reduce
subgrade pumping. [Minimizing construction traffic on -site is recommended.]
Use of lime, fly ash, kiln dust, cement or geotextiles could also be considered as a
stabilization technique. Laboratory evaluation is recommended to determine the
effect of chemical stabilization on subgrade soils prior to construction.
Proof -rolling of the subgrade may be required to determine stability prior to paving.
Fill Materials:
1. Clean on -site soils or approved imported materials may be used as fill material for
the following:
fj general site grading exterior slab areas
• foundation areas pavement areas
• interior floor slab areas foundation backfill
2. On -site soils are not recommended for use beneath slabs or as baci'cfili� _
3. Select granular materials should be used as backfill behind retaining walls.
4. Frozen soils should not be used as fill or backfill.
5 . Imported soils (if required) should conform to the following or be approved by the
Project Geotechnical Engineer:
13
Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20965128
the first priority when implementing a planned pavement maintenance program and provides
the highest return on investment for pavements.
Recommended preventative maintenance policies for asphalt and jointed concrete
pavements, based upon type and severity of distress, are provided in Appendix D. Prior to
implementing any maintenance, additional engineering observation is recommended to
determine the type and extent of preventative maintenance.
Earthwork
Site Clearing and Subgrade Preparation:
1. Strip and remove existing vegetation, debris, and other deleterious materials from
proposed building and pavement areas. All exposed surfaces should be free of
mounds and depressions which could prevent uniform compaction.
2. If unexpected fills or underground facilities are encountered during site clearing,
such features should be removed and the excavation thoroughly cleaned prior to
backfill placement and/or construction. All excavations should be observed by the
geotechnical engineer prior to backfill placement.
3. Stripped materials consisting of vegetation and organic materials should be wasted
from the site or used to revegetate exposed slopes after completion of grading
operations. If it is necessary to dispose of organic materials on -site, they should
be placed in non-structural areas and in fill sections not exceeding 5 feet in height.
4. The site should be initially graded to create a relatively level surface to receive fill,
and to provide for a relatively uniform thickness of fill beneath proposed building
structures.
5. All exposed areas which will receive fill, floor slabs and/or pavement, once properly
cleared and benched where necessary, should be scarified to a minimum depth of
8 inches, conditioned to near optimum moisture content, and compacted.
Excavation:
1. It is anticipated that excavations for the proposed construction can be
accomplished with conventional earthmoving equipment.
12
Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20965128
Longitudinal and transverse joints should be provided as needed in concrete pavements for
expansion/contraction and isolation. The location and extent of joints should be based upon
the final pavement geometry and should be placed (in feet) at roughly twice the slab thickness
(in inches) on center in either direction. Sawed joints should be cut within 24-hours of
concrete placement, and should be a minimum of 25% of slab thickness plus 1/4 inch. All
joints should be sealed to prevent entry of foreign material and dowelled where necessary for
load transfer.
Future performance of pavements constructed on the clay soils at this site will be dependent
upon several factors, including:
maintaining stable moisture content of the subgrade soils and
providing for a planned program of preventative maintenance.
Since the clay soils on the site have shrink/swell characteristics, pavements could crack in the
future primarily because of expansion of the soils when subjected to an increase in moisture
content to the subgrade. The cracking, while not desirable, does not necessarily constitute
structural failure of the pavement.
The performance of all pavements can be enhanced by minimizing excess moisture which can
reach the subgrade soils. The following recommendations should be considered at minimum:
• Site grading at a minimum 2% grade away from the pavements;
• Compaction of any utility trenches for landscaped areas to the same criteria as the
pavement subgrade;
• Sealing all landscaped areas in or adjacent to pavements to minimize or prevent
moisture migration to subgrade soils;
• Placing compacted backfill against the exterior side of curb and gutter; and,
• Placing curb, gutter and/or sidewalk directly on subgrade soils without the use of base
course materials.
Preventative maintenance should be planned and provided for an on -going pavement
management program in order to enhance future pavement performance. Preventative
maintenance activities are intended to slow the rate of pavement deterioration and to preserve
the pavement investment.
Preventative maintenance consists of both localized maintenance (e.g. crack sealing and
patching) and global maintenance (e.g. surface sealing). Preventative maintenance is usually
11
Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20965128
Aggregate base course (if used on the site) should consist of a blend of sand and gravel which
meets strict specifications for quality and gradation. Use of materials meeting Colorado
Department of Transportation (CDOT) Class 5 or 6 specifications is recommended for base
course. Aggregate base course should be placed in lifts not exceeding six inches and should
be compacted to a minimum of 95% Standard Proctor Density (ASTM D698).
Asphalt concrete and/or plant -mixed bituminous base course should be composed of a
mixture of aggregate, filler and additives, if required, and approved bituminous material. The
bituminous base and/or asphalt concrete should conform to approved mix designs stating the
Hveem properties, optimum asphalt content, job mix formula and recommended mixing and
placing temperatures. Aggregate used in plant -mixed bituminous base course and/or asphalt
concrete should meet particular gradations. Material meeting ColWN
Trr
ortation Grading C or CX s ecification is recommended shalt concrete.
Aggregate meeting olorado Department of ransportation Grading G or C coPrifira±inns IS
ommended for plant -mixed bituminous base c__� Mix designs should be submitted
prior to construction to verify their adequacy. Asphalt material should be placed in maximum
3-inch lifts and should be compacted to a minimum of 95% Hveem density (ASTM D1560)
(ASTM D1561).
Where rigid pavements are used, the concrete should be obtained from an approved mix
design with the following minimum properties:
• Modulus of Rupture @ 28 days.......................................................600 psi minimum
• Strength Requirements............................................................................. ASTM C94
Minimum Cement Content...............................................................6.5 sacks/cu. yd.
• Cement Type......................................................................................Type I Portland
• Entrained Air Content......................................................................................6 to 8%
• Concrete Aggregate ............................................ ASTM C33 and CDOT Section 703
Aggregate Size..................................................................................1 inch maximum
• Maximum Water Content.............................................................0.49 lb/lb of cement
• Maximum Allowable Slump............................................................................4 inches
Concrete should be deposited by truck mixers or agitators and placed a maximum of 90
minutes from the time the water is added to the mix. Other specifications outlined by the
Colorado Department of Transportation should be followed.
10
Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20965128
characteristics are considered to control the design. These characteristics, coupled with the
approximate duration of saturated subgrade conditions, results in a design drainage coefficient
of 1.0 when applying the AASHTO criteria for design.
For flexible pavement design, a terminal serviceability index of 2.0 was utilized along with an
inherent reliability of 70% and a design life of 20 years. Using the correlated design R-value of
13, appropriate ESAUday, environmental criteria and other factors, the structural numbers
(SN) of the pavement sections were determined on the basis of the 1986 AASHTO design
equation.
In addition to the flexible pavement design analyses, a rigid pavement design analysis was
completed, based upon AASHTO design procedures. Rigid pavement design is based on an
evaluation of the Modulus of Subgrade Reaction of the soils (K-value), the Modulus of Rupture
of the concrete, and other factors previously outlined. The design K-value of 100 for the
subgrade soil was determined by correlation to the laboratory tests results. A modulus of
rupture of 600 psi (working stress 488 psi) was used for pavement concrete. The rigid
pavement thicknesses for each traffic category were determined on the basis of the AASHTO
design equation.
Recommended alternatives for flexible and rigid pavements, summarized for each traffic area,
are as follows and should replace pavement recommendations discussed in the original
report:
Traffic Area;
AlEemattve
Recommended
Pavementihickl esses ilncties101
Asphait
Aggregate
Ptant'Mixed
Portland
Total
£oncrete'
:BaseCourse
Bituminous
CemenE
Surfa-XXce .>
Base
Concrete
Automobile
A
3
4
7
Parking
B
2
2'/a
4'/
C
I
5
5
Main Traffic
A
3
6
9
Corridors
B
2
3'/�
5'/2
C
6'/=
6'/
Each alternative should be investigated with respect to current material availability and
economic conditions.
Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20965128
Berm Dewatering System
To reduce the potential for surface water to enter the building subsurface adjacent to the
proposed berm, installation of a dewatering system is recommended. The dewatering system
should include a perimeter drainage system.
The drainage system should be constructed along to the north side of the building adjacent to
the berm and should consist of a properly sized perforated pipe, embedded in free -draining
gravel, placed in a trench at least 12 inches in width. The pipe should be placed a minimum of
one foot below the finished floor. The gravel should extend a minimum of 3 inches beneath
the bottom of the pipe to within 1 foot above the top of the berm above the pier. The gravel
should be covered with drainage fabric and backfilled with on -site clay material and topsoil. A
manufactured wall drain, such as Contech StripDrain, may be used in place of a conventional
pipe and gravel drainage system.
The drainage system should slope at least 1/8 inch per foot and should daylight into the
detention pond to the east or empty into a suitable outlet, such as a storm drain or sump and
pump system.
Pavement Design and Construction
Design of pavements for the project have been based on the procedures outlined in the 1986
Guideline for Design of Pavement Structures by the American Association of State Highway
and Transportation Officials (AASHTO). Pavement recommendations discussed below
reflect current standards. Areas within proposed pavements on the site will be divided into
two categories based upon anticipated traffic and usage.
Traffic criteria provided for pavement thickness designs include equivalent 18-kip single axle
loads (ESAL's) of 21,900 for automobile parking, and 87,500 for driveways and truck access.
The traffic data is based on information provided by Safeway, Inc., which includes
approximately four semi -tractor trailers and 20 delivery trucks per week.
Based upon AASHTO criteria, Colorado is located within Climatic Region VI of the United
States. This region is characterized as being dry, with hard ground freeze and spring thaw.
The spring thaw condition typically results in saturated or near -saturated subgrade soil
moisture conditions. The AASHTO criteria suggests that these moisture conditions are
prevalent for approximately 12-1/2% of the annual moisture variation cycle.
Local drainage characteristics of proposed pavement areas are considered to vary from fair to
good depending upon location on the site. For purposes of this design analysis, fair drainage
P
Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20965128
subsurface materials, a seismic site coefficient, "s" of 1.0 should be used for the design of
structures for the proposed project (1994 Uniform Building Code, Table No. 16-J).
Floor Slab Design and Construction
In general, low to moderate expansive soils or engineered fill will support the floor slab.
However, thin layers of moderate to high expansive soils were encountered at the site.
Therefore, some differential movement of a slab -on -grade floor system is possible should the
subgrade soils increase in moisture content. Such movements are normally within general
tolerance for slab -on -grade construction. To reduce potential slab movements, the subgrade
soils should be prepared as outlined in the "Earthwork" section of this report.
Additional floor slab design and construction recommendations are as follows:
• Positive separations and/or isolation joints should be provided between slabs and all
foundations, columns or utility lines to allow independent movement.
• Contraction joints should be provided in slabs to control the location and extent of
cracking. The American Concrete Institute (ACI) recommends the control joint spacing
in feet for nonstructural slabs should be 2 to 3 times the slab thickness in inches in both
directions. Maximum joint spacing of 15 to 20 feet in each direction is recommended.
Sawed or tooled joints should have a minimum depth of 25% of slab thickness plus %
inch.
• Interior trench backfill placed beneath slabs should be compacted in accordance with
recommended specifications outlined below.
• In areas subjected to normal loading, a minimum flinch layer of clean -graded gravel
should be placed beneath interior slabs. Slabs supporting heavy loading should be
underlain by a minimum 6-inch layer of crushed aggregate base course.
• If moisture sensitive floor coverings are used on interior slabs, consideration should be
given to the use of barriers to minimize potential vapor rise through the slab.
• Floor slabs should not be constructed on frozen subgrade.
• Other design and construction considerations, as outlined in the ACI Design Manual,
Section 302.1 R are recommended.
For structural design of concrete slabs -on -grade, a modulus of subgrade reaction of 100
pounds per cubic inch (pci) may be used for floors supported on existing or engineered fill
consisting of on -site soils. A modulus of 150 pci may be used for floors supported on a
minimum of 6 inches of crushed aggregate base course.
7
M
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Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20966128
Foundations and masonry walls should be reinforced as necessary to reduce the potential for
distress caused by differential foundation movement. The use of joints at openings or other
discontinuities in masonry walls is recommended.
Foundation excavations should be observed by the geotechnical engineer. If the soil
conditions encountered differ from those presented in this report, supplemental
recommendations will be required.
Lateral Earth Pressures
For soils above any free water surface, recommended equivalent fluid pressures for
unrestrained foundation elements are:
• Active:
• Cohesive soil backfill (clay)............................................................................ 45 psf/ft
• Passive:
• Cohesive soil backfill (clay).......................................................................... 350 psf/ft
• Adhesion at base of footing.................................................................................500 psf
Where the design includes restrained elements, the following equivalent fluid pressures are
recommended:
• At rest:
• Cohesive soil backfill (clay)............................................................................ 60 psf/ft
The lateral earth pressures herein are not applicable for submerged soils. Additional
recommendations may be necessary if such conditions are to be included in the design.
Fill against grade beams and retaining walls should be compacted to densities specified in
"Earthwork". Medium to high plasticity clay soils should not be used as backfill against
retaining walls. Compaction of each lift adjacent to walls should be accomplished with hand -
operated tampers or other lightweight compactors. Overcompaction may cause excessive
lateral earth pressures which could result in wall movement.
Seismic Considerations
The project site is located in Seismic Risk Zone I of the Seismic Zone Map of the United
States as indicated by the 1994 Uniform Building Code. Based upon the nature of the
lJ
A ..0
Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20965128
CONCLUSIONS AND RECOMMENDATIONS
Geotechnical Considerations
The subsurface conditions encountered during this investigation are consistent with those
described in our October 17, 1980 report. The recommendations presented in that report may
be used. For convenience, the are summarized in the following paragraphs.
The site appears suitable for the proposed construction from a geotechnical engineering point
of view. Potentially expansive soils will require particular attention in the design and
construction.
The following foundation systems were evaluated for use on the site:
• spread footings and/or grade beams bearing on undisturbed soils; and,
spread footings and/or grade beams bearing on engineered fill.
Slab -on -grade construction is considered acceptable for use, provided that design and
construction recommendations are followed.
Foundation Systems
Due to the presence of expansive soils on the site, spread footing and/or grade beam
foundations bearing upon undisturbed subsoils and/or engineered fill are recommended for
support for the proposed structure. The footings and/or grade beams may be designed for a
maximum bearing pressure of 2,000 psf. In addition, the footings should be sized to maintain
a minimum dead -load pressure of 500 psf. The design bearing pressure applies to dead loads
plus design live load conditions. The design bearing pressure may be increased by one-third
when considering total loads that include wind or seismic conditions.
Exterior footings should be placed a minimum of 30 inches below finished grade for frost
protection. Finished grade is the lowest adjacent grade for perimeter footings.
Footings should be proportioned to minimize differential foundation movement. Proportioning
on the basis of equal total settlement is recommended; however, proportioning to relative
constant dead -load pressure will also reduce differential settlement between adjacent footings.
Total settlement resulting from the assumed structural loads is estimated to be on the order of
3/4 inch. Proper drainage should be provided in the final design and during construction to
reduce the settlement potential.
5
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Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20965128
• Silty Topsoil: The area tested is overlain by a 6-inch layer of silty topsoil. The topsoil
has been penetrated by root growth and organic matter.
• Lean Clay: This stratum underlies the topsoil in Borings 1 and 2 and extends to
depths of 2 to 3Yz feet below the surface. The lean clay is dry to moist and stiff in
consistency.
• Lean Clay with Sand: A layer of lean clay with sand underlies the upper lean clay in
Borings 1 and 2 and extends to depths of 10 to 12'/ feet below the surface. The lean
clay with sand contains gravel, is moist to wet and medium to very hard in consistency.
• Sandy Lean Clay: A layer of red sandy lean clay underlies the topsoil in Boring 3 and
extends beyond the depths explored. The red sandy lean clay is dry to moist and stiff
to very stiff in consistency.
•Silty Sand: The silty sand stratum was encountered in Boring 1 at a depth of 17'/ feet
and extends beyond the depths explored. The silty sand is medium dense and wet in
situ.
Field and Laboratory Test Results
Field and laboratory test results indicate the clay soils at the site exhibit moderate to high swell
potential and moderate to high bearing characteristics.
Groundwater Conditions
Groundwater was observed in Boring 1 at an approximate depth of 14Y feet at the time of
field exploration. Borings 2 and 3 were dry at the time of drilling. When checked three days
after drilling, free groundwater was encountered in Boring 1 at an approximate depth of 10Y
feet below the surface, and Borings 2 and 3 remained dry. These observations represent only
current groundwater conditions, and may not be indicative of other times, or at other locations.
Groundwater levels can be expected to fluctuate with varying seasonal and weather
conditions.
4
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Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20966128
Groundwater measurements were made in each boring at the time of site exploration, and
three days after drilling.
Laboratory Testing
All samples retrieved during the field exploration were returned to the laboratory for
observation by the project geotechnical engineer, and were classified in accordance with the
Unified Soil Classification System described in Appendix C. At that time, the field descriptions
were confirmed or modified as necessary and an applicable laboratory testing program was
formulated to determine engineering properties of the subsurface materials. Boring logs were
prepared and are presented in Appendix A.
Selected soil samples were tested for the following engineering properties:
• Water content
• Dry density
• Consolidation
• Compressive strength
• Expansion
• Plasticity Index
• R-value
• Water soluble sulfate content
The significance and purpose of each laboratory test is described in Appendix C. Laboratory
test results are presented in Appendix B, and were used for the geotechnical engineering
analyses, and the development of foundation and earthwork recommendations. All laboratory
tests were performed in general accordance with the applicable ASTM, local or other accepted
standards.
SITE CONDITIONS
The site consists of a vacant tract of land vegetated with native grasses and weeds. A grass
berm and trees are located along the south edge of the site adjacent to Harmony Road. The
property is relatively flat and has minor drainage to the east. The site is bordered to the north
by Monte Carlo Drive, to the east by McMurray Drive, to the west by Wheaton Drive, and to
the south by Harmony Road.
SUBSURFACE CONDITIONS
Soil Conditions
The following describes the characteristics of the primary soil strata in order of increasing
depths:
3
r
Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20965128
require approximately one foot of fill below the majority of the proposed Safeway Store. A
large berm will be constructed along the north side of the proposed Safeway building. Parking
and drive areas will be constructed along the front of the proposed Safeway Store and other
building pads. A detention pond is proposed in the northeast comer of the site.
PREVIOUS REPORT
Thirty-four test borings were previously drilled at the site for a neighborhood center by Empire
Laboratories, Inc., our predecessor firm. A Report of a Geotechnical Investigation was
prepared for the site in October of 1980.
SITE EXPLORATION
The scope of the services performed for this project included site reconnaissance by an
engineering geologist, a subsurface exploration program, laboratory testing and engineering
analysis.
Field Exploration
A total of three test borings were drilled on August 20, 1996 to depths of 9 to 20 feet at the
locations shown on the Site Plan, Figure 1. One boring was drilled within the footprint of the
proposed building, and two borings were drilled in the area of proposed pavements. All
borings were advanced with a truck -mounted drilling rig, utilizing 4-inch diameter solid stem
auger.
The Borings were located in the field by pacing from property lines and/or existing site
features. Elevations were taken at each boring location by measurements with an engineer's
level from a temporary bench mark (TBM) shown on the Site Plan. The accuracy of boring
locations and elevations should only be assumed to the level implied by the methods used.
Continuous lithologic logs of each boring were recorded by the engineering geologist during
the drilling operations. At selected intervals, samples of the subsurface materials were taken
by pushing thin -walled Shelby tubes, or by driving split -spoon samplers. Representative bulk
samples of subsurface materials were obtained from pavement borings.
Penetration resistance measurements were obtained by driving the split -spoon into the
subsurface materials with a 140-pound hammer falling 30 inches. The penetration resistance
value is a useful index to the consistency, relative density or hardness of the materials
encountered.
2
SUPPLEMENTAL GEOTECHNICAL ENGINEERING REPORT
PROPOSED SAFEWAY STORE NO. 1552
HARMONY SAFEWAY MARKET PLACE
FORT COLLINS, COLORADO
Project No. 20965128
September 6, 1996
INTRODUCTION
This report contains the results of our supplemental geotechnical engineering exploration for
the proposed Safeway Store No. 1552 to be located on Harmony Road between Wheaton
Drive and McMurray Avenue in southeast Fort Collins, Colorado. The site is located in the
Southwest 1/4 of Section 31, Township 7 North, Range 68 West of the 6th Principal Meridian.
The purpose of these services is to provide additional information and geotechnical
engineering recommendations relative to:
• subsurface soil conditions
• groundwater conditions
• foundation design and construction
• lateral earth pressures
• floor slab design and construction
• pavement design and construction
• earthwork
• drainage
The conclusions and recommendations contained in this report are based upon the results of
field and laboratory testing, engineering analyses, our experience with similar soil conditions
and structures and our understanding of the proposed project.
PROPOSED CONSTRUCTION
Based on information provided by Safeway, Inc., the proposed structure will be a single -story,
slab -on -grade supermarket. Additional building pads for future construction will be built in
conjunction with the Safeway building. Parking and drive areas will be constructed for the
entire project. The finished first floor of the building will be placed at elevation 80.50. This will
Y� ,
Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20965128
TABLE OF CONTENTS (cont'd)
Page No.
GENERALCOMMENTS.....................................................................................................19
APPENDIX A
Site Plan and Boring Location Diagram
Logs of Borings
APPENDIX B
Laboratory Test Results
APPENDIX C
General Notes
APPENDIX D
Pavement Notes
IV
v
. . 1
TABLE OF CONTENTS
Page No.
Letterof Transmittal.................................................................................................................. ii
INTRODUCTION............................................................................................I....................1
PROPOSED CONSTRUCTION..........................................................................................1
PREVIOUSREPORT..........................................................................................................2
SITEEXPLORATION..........................................................................................................2
FieldExploration......................................................................................................2
LaboratoryTesting................................................................................................... 3
SITECONDITIONS.............................................................................................................3
SUBSURFACE CONDITIONS.............................................................................................3
SoilConditions......................................................................................................... 3
Field and Laboratory Test Results........................................................................... 4
Groundwater Conditions..........................................................................................4
CONCLUSIONS AND RECOMMENDATIONS.................................................................... 5
Geotechnical Considerations...................................................................................5
FoundationSystems................................................................................................5
Lateral Earth Pressures...........................................................................................6
Seismic Considerations...........................................................................................
6
Floor Slab Design and Construction........................................................................
7
BermDewatering System........................................................................................
8
Pavement Design and Construction .... ....:......... .... ...................................................
8
Earthwork................................................................................................................12
Site Clearing and Subgrade Preparation......................................................12
Excavation...................................................................................................12
FillMaterials.................................................................................................13
Placement and Compaction.........................................................................14
Shrinkage.....................................................................................................15
Slopes..........................................................................................................15
Compliance..................................................................................................16
Excavation and Trench Construction............................................................16
Drainage..................................................................................................................17
SurfaceDrainage.........................................................................................17
SubsurfaceDrainage...................................................................................17
Additional Design and Construction Considerations.................................................18
Exterior Slab Design and Construction.........................................................18
Underground Utility Systems........................................................................18
CorrosionProtection....................................................................................18
y
Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Terracon Project No. 20965128
We appreciate the opportunity to be of service to you on this phase of your project. If you have
any questions concerning this report, or if we may be of further service to you, please do not
hesitate to contact us.
Sincerely,
TERRACON CONSULTANTS WWg T€RN, INC.
Empire Division `< 1EOF PFOf o•.
ATE
Prepared by: 237g��BF9;G. Reviewed by:
i t • L111"V � inAJ.Attwooll,
i
/ �alyez "'"'•� o� �~ Wi
eil R. rod olq. SHEPP✓ c�
Senior ngineering Geologis °'9CF;s;ll�lly Office Manager
Copies to: Addressee (2)
Concept West Architecture, Inc. - Mr. Gary Harrison (2)
p0 Rf G
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3 18829
����'/iss/0NAI
September 6, 1996
Safeway, Inc.
6900 South Yosemite
Englewood, Colorado 80011
Attn: Mr. Cam Potter
Director of Denver/Phoenix Division
Re: Supplemental Geotechnical Engineering Report
Proposed Safeway Store No.1552
Harmony Safeway Market Place
Fort Collins, Colorado
Project No. 20966128
Terracon Consultants Western, Inc., Empire Division has completed a supplemental
geotechnical engineering exploration for the proposed Safeway Store to be located on Harmony
Road in southeast Fort Collins, Colorado. This study was performed in general accordance
with our proposal number D2096150 dated August 2, 1996.
The results of our engineering study, including the boring location diagram, laboratory test
results, test boring records, and the geotechnical recommendations needed to aid in the design
and construction of foundations and other earth connected phases of this project are attached.
The subsoils at the site consist of lean clay, lean clay with sand and sandy lean clay. The clay
materials recently tested are moderately to highly expansive. The soils at the site are similar to
those described in a "Report of a Geotechnical Investigation" prepared for a neighborhood
center at the site in October of 1980 by Empire Laboratories, Inc., our predecessor firm. Due to
the type of construction proposed for the site, it is recommended the structures be supported by
conventional -type spread footing and/or grade beam foundation systems. This is consistent
with the foundation recommendations previously made at the site. Further details are provided
in this report.
a
•r
SUPPLEMENTAL GEOTECHNICAL ENGINEERING REPORT
PROPOSED SAFEWAY STORE NO. 1552
HARMONY SAFEWAY MARKET PLACE
FORT COLLINS, COLORADO
PROJECT NO.20965128
September 6, 1996
Prepared for.
SAFEWAY, INC.
6900 SOUTH YOSEMITE
ENGLEWOOD, COLORADO 80112
ATTN: MR. CAM POTTER
DIRECTOR OF DENVER/PHOENIX DIVISION
Prepared by.
Terracon Consultants Western, Inc.
Empire Division
301 North Howes Street
Fort Collins, Colorado 80521
lrerracon
Supplemental Geotechnical Engineering Exploration
Safeway, Inc.
Project No. 20965128
Drainage
Surface Drainage:
1. Positive drainage should be provided during construction and maintained
throughout the life of the proposed construction. Infiltration of water into utility or
foundation excavations must be prevented during construction. Planters and other
surface features which could retain water in areas adjacent to the building or
pavements should be sealed or eliminated.
2. In areas where sidewalks or paving do not immediately adjoin the structure, we
recommend that protective slopes be provided with a minimum grade of
approximately 5 percent for at least 10 feet from perimeter walls. Backfill against
footings, exterior walls and in utility and sprinkler line trenches should be well
compacted and free of all construction debris to reduce the possibility of moisture
infiltration.
3. Downspouts, roof drains or scuppers should discharge into splash blocks or
extensions when the ground surface beneath such features is not protected by
exterior slabs or paving.
4. Sprinkler systems should not be installed within 5 feet of foundation walls.
Landscaped irrigation adjacent to the foundation system should be minimized or
eliminated.
• Subsurface Drainage
Free -draining, granular soils containing less than five percent fines (by weight) passing
a No. 200 sieve should be placed adjacent to walls which retain earth. A drainage
system consisting of either weep holes or perforated drain lines (placed near the base
of the wall) should be used to intercept and discharge water which would tend to
saturate the backfill. Where used, drain lines should be embedded in a uniformly
graded filter material and provided with adequate clean -outs for periodic maintenance.
An impervious soil should be used in the upper layer of backfill to reduce the potential
for water infiltration.
17