REVIEWED RESUB1 BLD2022-1741+GEO LETTER+4.5.2023_12.36.05_PM+3464806BLD2022-1741 RES U B REVIEWED Reviewed by
By City of Edmonds
Apr 05 2023 CITY S
IBUILDINGG DEEPARTMPARTMENT: Planning Division.
................................................
CITY OF EDMONDS
DEVELOPMENT SERVICES
DEPARTMENT
COBALT Cobalt Geosciences, LLC
G E 0 S C I E N C E S P.O. Box82243
Kenmore, Washington 98028
December 9, 2022
Updated March 3, 2023
RR Foundation Specialist
Attn: Alesha Stickles
RE: Limited Geotechnical Evaluation
Foundation Mitigation
16131 75th Place West
Edmonds, Washington
In accordance with your authorization, Cobalt Geosciences, LLC has prepared this letter to
discuss the results of our limited geotechnical evaluation at the above -referenced location.
Site and Project Description
The site is located at 16131 75th Place West in Edmonds, Washington. The site consists of one
irregularly shaped parcel (No. 005131058o11oo) with a total area of about o.16 acres.
The western portion of the property is developed with a residence and parking areas. The
remainder of the property is vegetated with grasses, bushes, shrubs, and sparse trees.
The site slopes gently downward from east to west with relief of about 15 feet. The site is
bordered to the north and east by residential properties, to the west by .75th Place West, and to the
south by 162nd Street SW.
We understand that portions of the building have settled up to 1.5 inches over time, likely
beginning after construction and potentially continuing today. The deck east of the residence has
settled more in places. The settlement is widespread.
The project includes installation of at least 8 helical anchors and 8 driven piers below the affected
foundation elements. Anchors will be attached with steel brackets and angle iron if necessary.
Anchors are anticipated to be driven to refusal below foundation elements. Lifting will not be
performed.
Area Geology
The site lies within the Puget Lowland. The lowland is part of a regional north -south trending
trough that extends from southwestern British Columbia to near Eugene, Oregon. North of
Olympia, Washington, this lowland is glacially carved, with a depositional and erosional history
including at least four separate glacial advances/retreats. The Puget Lowland is bounded to the
west by the Olympic Mountains and to the east by the Cascade Range. The lowland is filled with
glacial and non -glacial sediments consisting of interbedded gravel, sand, silt, till, and peat lenses.
The Geologic Map of the Edmonds East Quadrangle indicates that the site is underlain by
Whidbey Formation and Pre -Olympia Deposits.
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December 9, 2022
Updated March 3, 2023
Page 2 of 4
Limited Geotechnical Evaluation
These materials can include silty -sands, silts, and gravelly materials which are typically
heterogenous and can be layered. These materials generally become denser with depth below a
weathered zone.
The site is within an older landslide feature that may have areas of reactivation. We understand
that the City requires new development to have extensive geotechnical analysis, including borings
and risk assessments.
Soil & Groundwater Conditions
We advanced several shallow probes and a hand boring near foundation elements, where
accessible. The soils consisted of loose mixtures of silt, sand, and gravel which became medium
dense approximately 6 feet below grade. Groundwater could be present at shallow depths,
perched on denser and/or finer grained materials.
We reviewed numerous nearby boring and test pit logs. In general, the soils became denser with
depth and varied widely in composition.
Conclusions and Recommendation
Based on our observations, it appears likely that the settlement is likely the result of insufficient
removal of loose weathered soils prior to fill and foundation placement. Additional factors that
could contribute to the settlement include saturation of foundation soils due to downspout drain
leakage, age of foundation systems, and/or inadequately designed foundation systems for the
current loads.
The proposed mitigation utilizing helical anchors and driven piers with steel connections appears
suitable to reduce settlement and support the affected portions of the residence. Based on our
observations, we anticipate that helical anchors and piers may extend 7 to 20 feet below grade
with an average depth of 12 feet. This estimate is based on our experience with soil conditions at
similar sites in this area. Depths may vary if higher loads are required.
Statement of Risk
We understand that the site is within a known landslide feature and that the City of Edmonds
requires extensive geotechnical analysis for any new development and other specific activities. It
is our opinion that this project does not require peer review related to these hazards since the
proposed work is limited to pier installation (underpinning).
This work typically takes less than a week and requires very small excavations close to the
foundation elements which are immediately backfilled. The pier installation work will not
adversely affect any geologic hazards at the site and adjacent areas and will not increase or
decrease slope stability in the area. These piers merely provide additional support to the
foundation, transferring the loads into more competent soil deposits at depth.
Helical Piers@
Helical Piers® may be used to support the structure, where proposed and required. The Helical
Piers® could be installed using portable rotary tools, truck mounted rotary tools, backhoe
mounted rotary tools, caisson drills, or skid -steer loaders. It is important that the torque output,
rotational speed, down pressure capability, and angle control of the installation equipment is
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December 9, 2022
Updated March 3, 2023
Page 3 of 4
Limited Geotechnical Evaluation
compatible with the required foundation system. The pile installation equipment should have
adequate torque capacity to prevent refusal conditions at relatively shallower depths that are well
above recommended bearing depths or layers.
A Helical Pier® consists of an anchor (lead section) with 1, 2, 3 or more helical flights on a shaft.
The number and diameter of the helices on the anchor are dependent on the soil characteristics of
the site and the design loads to be applied to the pier. Based on these parameters the anchor helix
configuration is chosen to best fit the site conditions.
As the anchor is advanced into the soil extension sections (shaft) are placed on the lead section.
The shaft configuration is based on the design loads and anticipated installation torque.
The static compression load capacity of a Helical Pier® is the sum of all individual helix
capacities below liquefiable soils and in bearing layer. Individual helix static compression
capacity is the result of the projected area of the helix, and its bearing pressure.
It is recommended that the piers penetrate into relatively dense native soils a minimum of 5 feet,
or until refusal whichever is shallower. The bearing layer will be at variable depths below the
existing ground surface due to previously natural slope conditions (anticipated to be 7 to 20 feet).
Increased capacity can be obtained with increased penetration, and additional helical flights on
the lead section.
Helical Pier® installation should be monitored to verify installation torque, and proper
embedment into the presumed bearing layer. The Helical Pier® lengths may need to be modified
during construction if it is determined that the depth to the bearing layer varies. Helical Pier®
anchors are well suited to field adjustments as length can be varied by merely adding or deleting
extension sections (shafts) during installation.
Monitoring installation torque in the field is used to estimate the anchor compression capacity,
and also as a quality control during anchor installation, provided that the anchor is bearing in
dense or hard soils. Dependent on the pile size and the equipment used to install the anchors, an
empirical factor is multiplied by the average torque over the final 3 feet of installation to estimate
ultimate capacity.
Allowable Helical Pier Compression Capacity Pa may be estimated from the following equation
provided that the pier is in the recommended bearing soils:
Pa = Kt x T/FoS,
Where T is the applied torque, Kt is the empirical ratio factor. The following industry standards
apply to shafts with blades spaced along the shaft at 2.5 to 3.5 times the average blade diameter
on -center and meeting the manufacturer's specifications.
1.5" and 1.75" Square Shafts - Kt = 9 ft-1
2.875" O.D. Round Shafts - Kt = 9 ft-1
3.0" O.D. Round Shafts - Kt = 8 ft-1
3.5" O.D. Round Shafts - Kt = 7 ft-1
Proof testing of at least 3 percent of the helical piers in eight equal increments up to 200 percent
of the design load, if required by the permitting authority. Each load increment up to the 200
percent of design load should be held for five (5) minutes and the vertical strain monitored.
www.cobaltgeo.com (206) 331-1097
December 9, 2022
Updated March 3, 2023
Page 4 of 4
Limited Geotechnical Evaluation
If the total strain between 1 and 5 minutes is less than 0.04 inches, the helical pier may be
considered acceptable. If the recorded strain exceeds 0.04 inches, the helical pier should either be
deepened and retested or abandoned and a new helical pier shall be installed and tested.
Driven Piles
We understand that 2-7/8 inch piles may be used to support portions of the structure. These piles
will likely be advanced using a double -cylinder hydraulic system.
Piles should be advanced until working pressures are achieved that provide the specific minimum
capacities with a factor of safety of at least 2. Work will be halted if the structure experiences
uplift flexure. The working pressure for a 3.5 inch cylinder bore is 2,500 pounds per square inch
(psi), and 2,000 psi for a 4 inch diameter cylinder bore.
The required pile length in order to develop the recommended pile capacity is expected to vary
depending on the depth of dense to very dense soils below the residence. We estimate pile lengths
Of 7 to 20 feet below foundation grades, with a likely average of about 12 feet. Deeper piers may
be observed if higher loads are required/observed.
A total of 3 percent of the piles (one pile minimum) should be load tested to verify the design
capacities. All load tests shall be performed in accordance with the procedure outlined in ASTM
D1143. The maximum test load shall be 2 times the design load. Load testing may need to be
terminated if additional lifting of the structure occurs.
A representative of the geotechnical engineer shall provide full time observation of pile
installation and testing to verify the driving refusal criteria.
Closure
The information presented herein is based upon professional interpretation utilizing standard
practices and a degree of conservatism deemed proper for this project. We emphasize that this
report is valid for this project as outlined above and for the current site conditions and should not
be used for any other site. Our scope pertains to foundation mitigation only and not any
assessment of slope stability at the site or for the structure. Drilled borings and other analyses
would be required for this type of assessment.
Sincerely,
Cobalt Geosciences, LLC
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Phil Haberman, PE, LG, LEG
Principal
www.cobaltgeo.com (2o6) 331-1097
Sno. Co. GIS Image
qN
Approximate Hand W
Hg_1 Boring Location
Foundation Mitigation SITE PLAN
16131 75th Place West
Edmonds, Washington FIGURE i
Cobalt Geosciences, LLC
P.O. Box 82243
Kenmore, WA 98028
(206) 331-1097
www.cobaltgeo.com
cobaltgeoogmail.com
Cobalt Geosciences, LLC
Foundation Mitigation REPAIR P.O. Box 82243
16131 th Place West Kenmore, WA 98028
3 75 PLAN (206) 331-1097
Edmonds, Washington FIGURE 2 www.cobaltgeo.com
cobaltgeoogmail.com
Unified Soil Classification System (USCS)
MAJOR DIVISIONS SYMBOL
TYPICAL DESCRIPTION
GW
Clean Gravels
Well -graded gravels, gravels, gravel -sand mixtures, little or no fines
Gravels
(more than 50%
(less than 5% _ GP
fines)
Poorly graded gravels, gravel -sand mixtures, little or no fines
COARSE
GRAINED
SOILS
of coarse fraction
retained on No. 4
sieve)
GM
Gravels with
Fines
(more than 12% GC
fines)
Silty gravels, gravel -sand -silt mixtures
Clayey gravels, gravel -sand -clay mixtures
(more than 50%
retained on
;°e sw
Clean Sands
Well -graded sands, gravelly sands, little or no fines
No. 200 sieve)
Sands
(50% or more
of coarse fraction
(less than 5% SP
fines)
Poorly graded sand, gravelly sands, little or no fines
passes the No. 4
sieve)
sM
Sands with Fines
Silty sands, sand -silt mixtures
(more than 12% sc
fines)
Clayey sands, sand -clay mixtures
ML
Inorganic silts of low to medium plasticity, sandy silts, gravelly silts,
FINE GRAINED
SOILS
(50% or more
Silts and Clays
(liquid limit less
than 50)
Inorganic cL
or clayey silts with slight plasticity
Inorganic clays of low to medium plasticity, gravelly clays, sandy clays
silty clays, lean clays
oL
Organic
Organic silts and organic silty clays of low plasticity
passes the
MH
Inorganic silts, micaceous or diatomaceous fine sands or silty soils,
No. 200 sieve)
Silts and Clays
(liquid limit 50 or
more)
Inorganic CH
elastic silt
Inorganic clays of medium to high plasticity, sandy fat clay,
or gravelly fat clay
OH
Organic
Organic clays of medium to high plasticity, organic silts
HIGHLY ORGANIC
SOILS
primarily organic matter, dark in color, PT
and organic odor
Peat, humus, swamp soils with high organic content (ASTM D4427)
1 Classification of Soil Constituents 1
MAJOR constituents compose more than 50 percent,
by weight, of the soil. Major constituents are capitalized
(i.e., SAND).
Minor constituents compose 12 to 50 percent of the soil
and precede the major constituents (i.e., silty SAND).
Minor constituents preceded by "slightly" compose
5 to 12 percent of the soil (i.e., slightly silty SAND).
Trace constituents compose o to 5 percent of the soil
(i.e., slightly silty SAND, trace gravel).
Relative Density
(Coarse Grained Soils)
Consistency
(Fine Grained Soils)
N, SPT,
Relative
N, SPT,
Relative
Blows/FT
Density
Blows/FT
Consistency
0-4
Very loose
Under 2
Very soft
4 -10
Loose
2-4
Soft
10 - 30
Medium dense
4-8
Medium stiff
30 - 50
Dense
8 -15
Stiff
Over 50
Very dense
15 - 30
Very stiff
Over 3o
Hard
Grain Size Definitions
Description
Sieve Number and/or Size
Fines
<#200 (0.08 mm)
Sand
-Fine
#200 to #40 (0.08 to 0.4 mm)
-Medium
#40 to #10 (0.4 to 2 MM)
-Coarse
#10 to #4 (2 to 5 mm)
Gravel
-Fine
#4 to 3/4 inch (5 to 19 mm)
-Coarse
3/4 to 3 inches (19 to 76 mm)
Cobbles
3 to 12 inches (75 to 305 mm)
Boulders
>12 inches (305 mm)
Moisture Content Definitions
Dry Absence of moisture, dusty, dry to the touch
Moist Damp but no visible water
Wet Visible free water, from below water table
Cobalt Geosciences, LLC
P.O. Box 82243
Kenmore, WA98028 Soil Classification Chart Figure C1
(206) 331-1097
_ www.cobalt eg o.com
cobaltgeo(d-) gmail.com
Log of Hand Boring HB-1
Date: November 2022
Depth: 6'
Initial Groundwater: None
Contractor:
Elevation: N/A
Sample Type: Grab
Method: Hand Auger
Logged By: PH Checked By: SC
Final Groundwater: N/A
o
4
Moisture Content (%)
Plastic 1 Liquid
u-
O
U
E
3
Limit Limit
oMaterial
Description
o
SPT N-Value
C
0 10 20 30 40 5
Vegetation/Topsoil
---
----
--
---
SM
--------------------------------------------
Very loose to medium dense, silty -fine to medium grained sand
with gravel, dark yellowish brown to yellowish brown,
moist. (Fill? and Weathered Whidbey Formation?)
2
3
4
5
End of Hand Boring 6'
7
8
9
10
Cobalt Geosciences, LLC
P.O. Box 82243
Foundation Mitigation
Hand
Kenmore, WA 98028
331-iog7
3-.
161 1 th Place West
3 75
Borin(2o6) g
www.cobaltgeo.com
Edmonds, Washington
Log
cobaltgeo Cd) gmail. corn