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9202 OLYMPIC VIEW DR
PROJECT REVIEW CHECKLIST
PROJECT NAME: P PLAN CHECK #:
PROJECT ADDRESS: q2JC)2_ N �4 J-Q AA,) -Lc RECEIPT DATE: �/)Lj 01_W
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Setbacks/Variance/Setback Adjustment
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Conditional Use Permit
ADB Requirements
. . . . . . . . . .
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Other Zoning Requirements
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Underground Wiring Required
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Lot Slope 15%
SEPA Environmental Checklist/Hydraulics Permit
Tree Cutting Plan
Al 199
Plat/Subdivision Requirements
Legal Description Verification
..........
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Quit Claim/Street Dedications
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Easements - Public/Private
Engineering Storm Drain Review Fee
. . . . . . . . . .
Engineering 2.2 Inspection Fee
. . . . . . . . . . . .
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Drainage Plan (On-Site
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Setback - To of Bank, Stream, Water Courses
Setback -Storm Drain Line
Open Ditch - Existing
.... .......
Culvert Required
. ......
Culvert Size
. . . .
Shoulder Drainage/Shale Open Runoff
. .
. . . . . . . .
Catch Basin Required
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Driveway Slope & Vehicle Access
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Sidewalk Required
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Curb & Gutter Required
--- -------
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Curb Cut For Driveway Required
. . . . . . . . . . . . . . . . . . . .
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Street Paving Required
Right -Of -Way Construction Permit Required
............
Street Name Sign Required
...............
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Other Signing Required
Bond Required For Public Improvements
FEMA- .Map Ch ck/Water Table
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Side .9eAier Availability
Calculate Sewer Connection Fee If No LID #
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Create Street File
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Existing Water Main Size
Water Meter Size
Service Line Size
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Water Meter Charge Required
Hydrant Required
Hydrant Size Existing
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Fire Line Charge Required - Sprinkler
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Street Cut
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Miscellaneous
Reviewed By:
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CITY OF EDMOND SIDE SEWER PERMIT
EDMONDS
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Address of ConsP6&jt: �Awww �� DEP1
Property Legal Description (Include all easements): _
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Owner and/or Contractor:
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❑ Multi -Family (No. of Units )
❑ Commercial
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Invasion into City Right -of -Way:'®" No ❑ Yes
RW Construction Permit No.
Cross other Private Property: Er —No ❑ Yes
Attach legal description and copy of recorded easement
I certify that I have read and shall comply with all city requirements
as indicated on the back of the Permit Card.
Date
* CALL DIAL -A -DIG (1-800-424-5555) BEFORE ANY EXCAVATION
** PERMIT MUST BE POSTED ON JOB SITE **
White Copy: File Green Copy: Inspector- Buff Copy: Applicant
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17311-135th Avenue NE, A-500
Woodinville, WA 98072
(425) 486-1669 • Fax 481-2510
November 24, 1997
City of Edmonds
Planning Department
250 — 5th Avenue
Edmonds, Washington 98020
Supplemental Letter
Four Lot Short Plat
Edmonds, Washington
NCA File No. 178096
Dear Sirs:
NELSON-COUVRETTE & ASSOCIATES, INC.
CONSULTING GEOTECHNICAL ENGINEERS, GEOLOGISTS
AND ENVIRONMENTAL SCIENTISTS
Snohomish County (425) 337-1669
Wenatchee/Chelan (509) 784-2756
Fr l�,' f t KA.tiv'Y
This is a supplemental letter to our preliminary geological investigation letter for this site, dated July 11,
1996 (NCA File No 178096). The purpose of this letter is to clarify our use of the term "buffer zone" in
the Building Setback subsection of our report. We have been requested to provide this clarification by
Jeff Vehrs of the Emerald Coast Group.
In our report, we recommended a minimum building setback of 10 feet for structures on Lots 3 and 4, to
establish a "buffer zone" between dwelling areas and the slope margin. We did not intend the word
"buffer" to be used as referenced and defined by the City of Edmonds in their Development Code. We
understand that these definitions were provided in the new code which was enacted after our report was
prepared. The City of Edmonds defines "buffer" as the area immediately next to and part of a steep
slope. The buffer is intended to protect the stability of the slope. A 15-foot setback is required from the
edge of the buffer.
The topographic map provided corresponds with our field measurements taken at the time of our
explorations. The topographic map of the steep slope area shows that the slope the maximum slope
Supplemental Letter
f Edmonds Short Plat
November 24, 1997
NCA File No. 178096
Page 2
inclination is about 58 percent for a total height of 8 to 10 feet. The portion of the slope with an average
slope above 40 percent is less than 20 feet in vertical height. Therefore, this slope does not qualify as a
steep slope hazard area under the City of Edmonds Code. It is our opinion that a building setback of 10
feet from the toe of the slope is appropriate. This allows for maintenance of the area in the event a
slough event occurs. The term "buffer" used in our original report was not intended to be used as
defined in the code, but was intended to be used as a setback of the structure from the toe of the slope. In
the event that the steep slope hazard is still applied, it is our opinion that moving the buffer onto the
slope and having the standard building setback start at the toe of the slope would be appropriate.
- We trust this letter provides you with the information you requested and appreciate the opportunity to be
of continued service to you on this project. If you have any questions concerning this letter, do not
hesitate to call.
Sincerely,
NELSON-COUVRETTE & ASSOCIATES, INC.
Charles P. Couvrette, PE
Principal Engineer
LMH:CPC:nt
Three Copies Submitted
NELSON-COUVRETTE & ASSOCIATES, INC.
GEOTECHNICAL INVESTIGATION REPORT
FOUR LOT SHORT PLAT
EDMONDS, WASHINGTON
FOR
THE CITY OF EDMONDS AND
LOVELL-SAUERLAND & ASSOCIATES, INC.
C/TV
Cp*pY
NELSON-COUVRETTE & ASSOCIATES, INC.
CONSULTING GEO TECHNICAL ENGINEERS, GEOLOGISTS
AND ENVIRONMENTAL SCIENTISTS
17311.135th Avenue NE, A-500 Snohomish County (206) 337.1669
Woodinville, WA 98072
(206) 486.1669 • Fax 481-2510 Wenatchee/Chelan (509) 784.2756
July 11, 1996
City of Edmonds
Planning Department
250 - 5th Avenue
Edmonds, Washington 98020
Geotechnical Investigation Report
Four Lot Short Plat
Edmonds, Washington
NCA File No. 178096
INTRODUCTION
This report presents the results of our geotechnical investigation for the planned LSA/Echelbarger four
lot short plat in Edmonds, Washington. The site is located on the south side of Olympic View Drive near
the 9200 block. We have been retained to evaluate a critical area and provide recommendations for site
development. For our use in preparing this report, we have been provided with a copy of the plans, dated
May 1996, prepared by Lovell- Sauerland & Associates, Inc. (LSA).
The project will consist of four residential lots that will be accessed along the western property line. The
access road will have a few feet of fill with a planned rockery as high as 4 feet on the downhill side. An
existing slope will be regraded on the east side of Lot 3. A rockery 4 to 6 feet in height is planned at the
base of this slope. The excavated material from the slope regrading will be used as fill to raise the road
grades and to fill a low area on the west side of Lots 1 and 2. A steep slope located in the southeast
corner of the site is to remain undisturbed. The steep slope will be.within Lots 3 and 4, and we have
been requested to provide setbacks from the toe of slope for these lots. Existing structures will be
removed from the site during project development. The grading required to develop the lot areas will
need to be accomplished during plat development as it incorporates building and roadway areas.
.J
' Geotechnical Investigation Report
Four Lot Short Plat
NCA File No. 178096
July 11, 1996
Page 2
i
SCOPE
The purpose of this study is to explore the subsurface conditions and to provide recommendations for
project development. Specifically, our scope of services includes the following:
1. Review the geologic map for the area.
2. Explore the subsurface conditions with backhoe excavated test pits.
3. Evaluate the ground water conditions.
4. Provide recommendations for site preparation, grading and structural fill.
5. Provide recommendations for foundation design and setbacks from steep slopes.
6. Provide general information for on -site drainage considerations.
7. Prepare a written report to document our findings and recommendations.
3
j SITE CONDITIONS
Surface
The site is over 1.3 acres in size and has a residence, garage, shed, and fallout shelter. The site is
accessed in the middle of the north property line from Olympic View Drive. A couple. of short retaining
•' walls and hedges exist along side of the driveway. The site slopes generally to the northwest with a total
vertical relief of approximately 50 feet. We measured the slopes on site with a clinometer. These
measurements were compared to the site plan provided to us. Our slope angles are similar to the grades
shown on the topography map provided to us.
A steep slope exists in southeastern portion of the site. The steep slope has angles up to 30 degrees (58
percent) with a. vertical relief of approximately 15 feet. Near the top of the steep slope, the neighboring
property owner has been using the area as a garden. Debris has been placed on the steep slope, in the
approximate area shown on the site plan, creating a pile approximately 3 to 4 feet in height.
A low area exists in the northwest portion of the site. The lowest point is approximately 5 to 6 feet
below the road elevation. The area is covered with tall grass. We suspect that the area was previously
used as a borrow pit.
Vegetation consists of a few large evergreen and deciduous trees with a dense undergrowth in the
southern portion of the site. The developed portion of the site is covered with grass, trees and small
i
j
NELSON-COUVRETTE & ASSOCIATES, INC.
Geotechnical Investigation Report
Four Lot Short Plat
j NCA File No. 178096
July 11, 1996
Page 3
i underbrush or shrubs. Tall strands of hedges occur along side the existing driveway. Vegetation on the
steep slope consists of brush, bevy vines, and scattered deciduous trees. The trees on the steep slope
range up to 22 inches in diameter.
Geologic Conditions
Landforms within this region comprise a system of glacially sculptured features, which have been
exposed by post -glacial erosion. Locally, the terrain of this area is interpreted to have been glacially
modified, and to have been placed during the latest glaciation of the Puget Lowland area. Glacial ice is
thought to have last occupied the region during the late Pleistocene Epoch, some 11,000 to 13,000 years
before present. The latest glacial advance over the area is referred to as the Vashon Stade of the Fraser
Glaciation, of which the geologic materials on site are believed composed.
The general stratigraphy within this area was observed and found to consist of advance glacial outwash,
referred to as Esperance Sand (Qva/Qe). Advance outwash in this area is composed of a dense, fine
sand, with trace silt and occasional gravel, which has been overridden and compacted by the weight of
the thick glacial ice. The advance sands were observed in all of the test pits. It is not uncommon for
more gravelly and/or silty zones to occur in these deposits.
Washington by James P. Minard, published by U.S. Geological Survey in 1975, was referenced for the
geologic and soil conditions at the site. The soil unit mapped at this site is classified as a Whidbey
Formation (Qw), with glacial till (Qvt) and Esperance Sand in the near vicinity.. We did not encounter
the Qw or Qvt in the subsurface conditions of the site. The Esperance Sand deposit is the geological unit
which commonly lies between the Whidbey and till deposits.
Subsurface Conditions
The subsurface conditions at the site were explored on June 8, 1996 by excavating ten test pits with .a
tire -mounted backhoe. The depths of the backhoe test pits range from 4.0 to 7.5 feet. The approximate
locations of the test pits are shown on the Site Plan in Figure 2. A representative from our firm was
present during the explorations. He examined the soils and geologic conditions encountered and
maintained logs of the test pits. The soils were visually classified in general accordance with the Unified
j Soil Classification System, a copy of which is presented as Figure 3. The logs of the test pits are
presented in Figures 4 through 6.
,
NELSON-COUVRETTE & ASSOCIATES, INC.
i
Geotechnical Investigation Report
Four Lot Short Plat
NCA File No. 178096
July 11, 1996
Page 4
i Subsurface conditions found on site consist mostly of a fine sand with silt or trace silt that varied from
loose at the surface, to medium dense to dense with depth. We have interpreted these soils to be the
Esperance Sands. Test Pit 9, located on the east portion of Lot 2, encountered 4 feet of fill. The fill
consists of similar native material with some organics and bottles. We also expect localized fills in areas
behind structures and/or retaining walls. The site is covered with a thin layer of topsoil. The topsoil
ranged up to 0.8 feet in depth.
Hydrologic Conditions
No obvious evidence of ground water, perched ground water or outcropping ground water along the
slopes was observed within this site. The advance outwash is considered fairly permeable and water is
expected to infiltrate vertically in the deposit until it encounters a less permeable layer, such as the
Whidbey Formation. We do not know the depths of these less permeable layers. The site appears to be
well drained with the advance sands.
SENSITIVE AREA EVALUATION
Seismic Hazard
The Puget Sound Region is classified as a Zone 3 by the Uniform Building Code. Seismic considerations
for this type of site includes liquefaction potential and attenuation of ground motions by soft soil
i deposits. The liquefaction potential is highest for loose sand and silty sand with a high ground water
table: The sand deposits at the site below a few feet were at least medium dense or better. These soils
have a low potential of liquefaction. Seismically sensitive soft soils were not observed at this site.
Erosion Hazard
The erosion hazard criteria used for determination of affected areas include soil type, slope gradient,
vegetation cover, and ground water conditions. The erosion sensitivity is related to vegetative cover and
the specific surface soil types (group classification), which are related to the underlying geologic .soil
units. The soils have been classified in accordance with the Soil Conservation Service (SCS)
classification system and have been grouped with respect to the corresponding geologic unit. The
geologic unit is Esperance Sand which corresponds to the SCS classification of Everett soils. The
' erosion hazard is greatest when the on -site soils have been stripped of vegetation. Provided the surface
water flowing over the exposed sandsare properly controlled during construction, and vegetation is re-
established after development, we do not expect a significant erosion concern.
I
NELSON- COU VRETTE & ASSOCIATES, INC.
Geotechnical Investigation Report
Four Lot Short Plat
NCA File No. 178096
July 11, 1996
Page 5
-i
Landslide Hazard
An evaluation of potential landslide hazard was performed for this site. This evaluation includes soil
type, underlying stratigraphy, slope gradient, ground water conditions, and vegetation cover. The soil
conditions at the site commonly have high strengths and the slope angles are not excessively steep for
these types of soils. We also did not observe any signs of instability such as shallow or deep-seated
failures. Accordingly, it is our opinion that the native site slopes are stable and large scale failures are
not expected.. Localized slough events may occur in the steep portions depending on the area specific
conditions. These would be expected to be shallow, involving the near -surface soils. The garden debris
placed on the top of the steep slope is considered unstable may cause shallow sloughs of the steep slope.
CONCLUSIONS AND RECOMMENDATIONS
General
The site is suitable for the planned residential short plat. The underlying sand deposits have moderately
high strength, and the existing slopes are considered stable with respect to deep-seated landslides or
failures. Surficial sloughing and erosion can occur, however, we did not observe evidence of slope
failures. The risk of these sloughs can be minimized by maintaining vegetation on the slopes and
controlling any surface water that may exist. We consider that minimum setbacks from the toe of slope
are considered appropriate to reduce the risk of future effects from surface sloughing. The outwash sand
deposits should provide a good subgrade for support of the structure's foundations.
{ The soil to be used as structural fill will be obtained from the east side of Lots 1, 2 and 3. Excavating
these soils to be used as fill, will cause a portion of the trees and the existing structures to be removed
during the initial development activities. The fill soil will be placed in the roadway area and also the low
depression on the west side of Lot 1.
Building Setbacks
Uncertainties related to building along steep slopes are typically addressed by the use of building
setbacks. The purpose of the setback is to establish a "buffer zone" between the dwelling areas and the
slope margin so that ample room is allowed for normal slope regression, or if a slope failure were to
occur, the likelihood of dwelling involvement would be minimized. In a general sense, the greater the
setback, the lower the risk. From a geological standpoint, the setback dimension is usually based on the
slope's physical characteristics, e.g., slope height, surface angle, material composition, hydrology, etc.
Other factors such as historical slope activity, rate of regression, type, and desired life span of the
development are important considerations as well.
:I
NELSON-COUVRETTE & ASSOCIATES, INC.
.S
i
r (`
Geotechnical Investigation Report
Four Lot Short Plat
j NCA File No. 178096
i July 11, 1996
Page 6
Based upon our explorations, slope evaluation and observations, we recommend a minimum building
setback of 10 feet for structures on Lots 3 and 4. Setbacks are not necessary on the other lots from the
toe of the steep slope. Specifically, we recommend that the setback area not be used for placement or
storage of fill materials, including "temporary" excavation spoils from building area preparation and
excavation. The landscape debris on the upper portion of the steep slope should be removed.. The area
should be re-established with vegetation if the soil is exposed. Any development or encroachment into
the setback areas should be evaluated by a specific geotechnical evaluation and report.
Site Preparation and Grading
Site preparation and grading should consist of stripping the vegetation and topsoil layer to the planned
subgrade. The exposed surface should be compacted to a non -yielding condition using a steel -drum
vibratory compactor. The subgrade should be observed for indication of disturbance of the lower soils
both during excavation and compaction. If the subgrade shows signs of disturbance, we should be
retained to provide recommendations for repair or potentially alternate construction techniques.
The on -site soil is expected to be only somewhat moisture sensitive with a uniform grain size, and may
be difficult to work and compact during periods of wet weather. Earthwork should be suspended during
rainfall and for a period of time afterward. The actual ability to work the site during the wet time of the
year will be dependent on the performance of the soils under load when wet. These conditions should be
observed and the site work adjusted accordingly. We recommend that all soil stock piles that are
intended to be used as backfill be covered with plastic during rainy weather to help maintain a moisture
content suitable for compaction. Sometimes a layer of crushed gravel or 2- to 4-inch spalls is used to
provide wet season access and to improve pavement and foundation subgrade. The use of the gravel and
spalls should be based on conditions observed in the field.
Excavation Slopes
Temporary slopes greater than 4 feet in height should be sloped at an inclination no steeper than 1.5H:1V
for the loose to medium dense sands, and 1H:1V for dense sands for cuts up to 12 feet in height. These
slopes should be protected from rain by well secured plastic sheeting. If ground water or seepage is
encountered, we should be retained to comment on the stability of the slopes in the excavation. The
above cut slope angles should be considered preliminary in nature. The contractor should be ultimately
responsible for the stability of the cut slopes, as he is continuously at the site and can observe the
performance on a daily basis. All state and federal standards should be followed with respect to cut
slopes and workman safety.
NELSON-COUVRETTE & ASSOCIATES, INC.
a
' Geotechnical Investigation Report
Four Lot Short Plat
NCA File No. 178096
July 11, 1996
Page 7
Structural Fill
General: Fill will be placed with the current design. Fill to be placed beneath buildings, pavements or
other settlement sensitive features, should be placed as structural. fill. Structural fill, by definition, is soil
placed in`accordance with prescribed methods and standards described in this report, and is monitored by
an experienced geotechnical professional or soils technician. Field monitoring procedures would include
a representative number of in -place density tests to document the attainment of the desired degree of
relative compaction.
Materials: Imported structural fill should consist of a good quality free draining granular soil, free of
organic and other deleterious material, and be well graded to a maximum size of about 3 inches.
Imported all weather fill should contain no more than about 5 percent fines (soil finer than a U.S. No.
200 sieve) based on that fraction passing the U.S. 3/4-inch sieve.
The on -site outwash soil can be used as structural fill but these soils contain some fine-grained particles
and are considered slightly moisture sensitive. The use of the soils as fill should be limited to extended
periods of dry weather. These soils have a uniform grain size and are sometimes more difficult to
compact than well graded soils. Depending on the moisture content of the soil, adding water may be
necessary to achieve compaction. Soils with a high organic content should not be used as structural fill.
Fill Placement: Following subgrade preparation, placement of the structural fill may proceed. All
backfilling should be accomplished in 8- to 10-inch thick uniform lifts. Each lift should be spread evenly
5 and be thoroughly compacted prior to placement of subsequent lifts. All structural fill underlying
building areas, and within 2 feet of pavement subgrade, should be compacted to a minimum of 95
percent of its maximum dry density. Maximum dry density in this report refers to that density as
determined by the ASTM D 1557 compaction test procedure. Fills more than 2 feet beneath sidewalks
and pavement subgrades should be compacted to at least 90 percent of their maximum dry density. The
moisture content of the soils to be compacted should be within about 2 percent of optimum, so that a
readily compactable condition exists. It may be necessary to overexcavate and remove wet soils in cases
where drying to a compactable condition is not feasible. All compaction should be accomplished by
equipment of a type and size sufficient to attain the desired degree of compaction. Care should be taken
when compacting the soil condition near to adjacent houses. A photo documented survey of the
neighboring structures is suggested prior to any heavy equipment arriving at the site. Sometimes the use
of smaller compaction equipment and thinner lifts is better if adjacent structures are being impacted.
NELSON-COUVRETTE & ASSOCIATES, INC.
Geotechnical Investigation Report
Four Lot Short Plat
NCA File No. 178096
July 11, 1996
Page 8
Foundations
The foundations should be placed either on undisturbed medium dense or dense native sand or structural
fill extending to these soils. If footings are to bear on structural fill, the fill zone should extend outside
of the footing a distance equal to the depth of fill beneath the footing. The soil conditions should be
evaluated for appropriate density and disturbance at the time of construction. Exterior footings should
extend a minimum of 18. inches below the adjacent outside ground surface, with interior column footings
a minimum of 12 inches below the bottom of the adjacent slab. All loose or disturbed soil should be
removed from the foundation excavation prior to placing concrete. Standing water should not be allowed
to accumulate in the building pad or footing trenches.
For foundations constructed as outlined above, we recommend an allowable design bearing pressure of
not more than 2,500 pounds per square foot-(psf) be used. Higher bearing values may be available based
on specific soil conditions, footing size and settlement tolerance. This can be reviewed at the time that
the structure is designed and foundation loads are determined. A .one-third increase in the above
allowable bearing pressure may be used when considering short-term transitory wind or seismic loads.
Although structural loading information was not available at the time of this study, based on our
experience with similar structures supported on similar soil conditions and for the above allowable soil
bearing pressures, we estimate that the maximum total post -construction settlement for medium dense
sands should be 3/4 of an inch or less, and that the differential settlement across the building width
should be 1/2 inch or less. We expect larger differential settlements may occur if the building is
constructed part on fill and part on native soils.
Lateral Pressures
The lateral pressure acting on retaining walls is dependent on the nature and density of the soil behind
the wall, the amount of lateral wall movement which can occur as backfill is placed and the inclination of
the backfill. Soil pressures will be less for walls that are free to yield at the top at least one -thousandth
of the height of the wall, than if movement is limited by such factors as wall stiffness or bracing. We
recommend that yielding walls supporting horizontal backfill be .designed using an equivalent fluid
density of 35 pounds per cubic foot (pcf). Non -yielding walls should be designed using an equivalent
fluid density of 50 pcf. These lateral soil pressures do not include the effects of surcharges such as
traffic loads or other surcharge loads. Surcharge effects should be considered, if appropriate. If desired,
we can provide recommendations for surcharge loads as they become apparent.
NELSON-COUVRETTE & ASSOCIATES, INC.
Geotechnical Investigation Report
Four Lot Short Plat
NCA File No. 178096
July 11, 1996
Page 9
All backfill for subgrade walls that will, not act as structural fill should be compacted to between 90 and
92 percent of the maximum dry density as determined in accordance with ASTM D 1557. Care should
be taken to prevent the buildup of excess lateral soil pressures due to overcompaction of the backfill
behind the wall. This can be accomplished by placing the backfill within 18 to 24 inches of the wall in
lifts not exceeding 8 inches in loose thickness, and compacting this zone with hand -operated vibrating
plate compactors.
Lateral loads can be resisted by friction between the foundation and subgrade or the passive earth
pressure acting on the below -grade foundation. For the latter, the foundation must be placed "neat"
against the undisturbed soil, or backfilled with a clean, free draining, compacted structural fill. We
recommend that lateral passive resistance be calculated by using an equivalent fluid weight of 250 pcf.
An allowable coefficient of'friction between footings and the subgrade of 0.40 may be used. These
values include a factor of safety of 2.0 for lateral resistance and 1.5 for the coefficient of friction.
The wall pressures, listed above, are based on the assumption that the soil directly behind the wall is free
draining or a drainage composite is used. All of the on -site surface soils are not free draining. Some free
draining soil may exist at depth. Wall drains are discussed in the Subsurface Drainage sub -section of
this report.
Site Drainage
Surface Drainage: The finished ground surface should be graded such that storm water is directed off
of the site. Water should not be allowed to stand in any area where footings, slabs or pavements are to be
constructed. Final site grades should allow for drainage away from the building. We suggest that the
finished ground be sloped at a gradient of 3 percent minimum for a distance of at least 10 feet away from
the building. Surface water should be collected by permanent catch basins and drain lines, and be
discharged into a storm drain system.
The surficial soils are loose to medium dense, fine sand. These soil types erode easily, especially when
directly exposed to precipitation and runoff. Surface water should be diverted away from the steep to
moderate slopes. Stripped areas should be revegetated to improve the stability of the near -surface slope
soils. The vegetation should be maintained until it is established.
Subsurface Drainage: Where slabs are located below the surrounding grades, a system of perimeter
footing drains should be included in the design. The perimeter footing drains should consist of 4-inch
diameter perforated smooth -walled PVC pipe surrounded by pea gravel. The footing drains should. be
NELSON-COUVRETTE & ASSOCIATES, INC.
Geotechnical Investigation Report
Four Lot Short Plat
j NCA File No..178096
i July 11, 1996
Page 10
1 .
located at the elevation of the footing. The drains should be tightlined to the storm drain system. We do
not consider foundation drains necessary for standard foundations construction.
A drainage system should be planned behind all retaining walls. The drainage system should consist of
an 18-inch wide blanket of free draining material. Pea gravel would be a suitable material. If 0.5-inch or
larger washed rock is used, filter fabric may be required ,to surround the rock. A drainage composite
approved by geotechnical engineer could be used in place of the rock blanket. A 4-inch diameter
perforated pipe should be placed along the base of the wall within the free draining material. The drains
should be routed to an appropriate discharge point.
Slabs -on -Grade
Slabs should be supported on native subgrade soils or structural fill prepared as described in the Site
Preparation and Grading and Structural Fill sub -sections of this report. Where moisture control is
important, we recommend that the floor slabs be underlain by 6 inches of free draining granular material,
for use as a capillary break. A suitable vapor barrier, such as heavy plastic sheeting, should be placed
over the capillary break material. A 2-inch thick sand blanket may be placed over the vapor barrier to
protect it during placement of the concrete and to help the concrete cure.
Rockeries
Rockeries are used in the Puget Sound region to face stable soil exposures to reduce weathering and
slough type failures. Although it is not always common to consider a rockery as a retaining wall, in
reality, the rockery can act as a gravity wall. The problems associated with using the rockery as a
retaining wall is the quality of the rockery construction and the compacted backfill. There is some risk
associated with rockeries since the rocks are not tied together. Therefore, the methods in which they are
stacked are very important. Rockeries should be designed and constructed in accordance with
Association of Rockery Contractors (ARC) guidelines, unless otherwise recommended in this report.
Inspection of the rockery construction by the geotechnical consultant is recommended.
We consider the rockery at the base of the cut slope to be appropriate. However, we recommend that the
rock sizes be increased to H/2 instead of the H/3 as recommended in the ARC manual. We recommend
that the same standards be used for the rockery that retains the driveway fill. However, since the wall
could be exposed to unknown wheel and traffic loads, it may be prudent to design it as a reinforced soil
wall. The reinforcement could consist of either fabric or geogrid.
NELSON-COUVRETTE & ASSOCIATES, INC.
Geotechnical Investigation Report
Four Lot Short Plat
1 NCA File No. 178096
July 11, 1996
Page 11
USE OF THIS REPORT
We have prepared this report for The City of Edmonds, Lovell- Sauerland & Associates, Inc. and their
agents, for use in planning and design of this project. The data and report should be provided to
prospective contractors for their bidding or estimating purposes, but our report, conclusions and
interpretations should not be construed as a warranty of the subsurface conditions. The scope of our
services does not include services related to construction safety precautions -and our recommendations
are not intended to direct the contractor's methods, techniques, sequences or procedures, except as
specifically described in this report for consideration in design.
There are possible variations in subsurface conditions between the explorations and also with time. A
contingency for unanticipated conditions should be included in the budget and schedule. We should be
retained to provide monitoring and consultation services during construction to confirm that 'the
conditions encountered are consistent with those indicated by the explorations, to provide
recommendations for design changes should the conditions revealed during the work differ from those
anticipated, and to evaluate whether or not earthwork and foundation installation activities comply with
contract plans and specifications.
Within the limitations of scope, schedule and budget for our services, we have strived to take care that
our work has been completed in accordance with generally accepted practices followed in this area at the
time this report was prepared. No other conditions, expressed or implied, should be understood.
NELSON-COUVRETTE & ASSOCIATES, INC.
Geotechnical Investigation Report
Four Lot Short Plat
NCA File No. 178096
July 11, 1996
Page 12
We appreciate the opportunity to be of service to you. If there are any questions concerning this report
or if we can provide additional services, please call.
Sincerely,
NELSON-COUVRETTE & ASSOCIATES, INC.
C3L�
Rick B: Powell, PE
Project Engineer
EXPIRES to •l�• mot$
Charles P. Couvrette, PE.
Principal Engineer
Three Copies Submitted
Six Figures
cc: Mr. Jurgen Sauerland - Love ll-Sauerland & Associates, Inc.
NELSON-COUVRETTE & ASSOCIATES, INC.
LOG OF EXPLORATION
DEPTH
USC
SOIL DESCRIPTION
TEST PIT ONE
0.0 - 1.3
SM
DARK BROWN SILTY FINE SAND WITH ORGANICS (LOOSE TO MEDIUM DENSE,
WET) (TOPSOIL)
1.3 - 4.0
SP-SM
RED -BROWN FINE SAND WITH SILT (MEDIUM DENSE, MOIST) (WEATHERED
Qva)
4.0 - 6.5
SP-SM
GRAY -BROWN FINE SAND WITH SILT (MEDIUM DENSE TO DENSE, MOIST TO
WET) (Qva)
SAMPLE WAS COLLECTED AT 6.0 FEET
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 6.5 FEET ON 6/15/96
TEST PIT TWO
0.0 - 0.4
SM
DARK BROWN SILTY FINE SAND WITH SOME ORGANICS (LOOSE TO MEDIUM
DENSE, WET)
0.4 - 4.0
SP-SM
GRAY -BROWN FINE SAND WITH SILT AND ORGANICS (MEDIUM DENSE, MOIST
TO WET) (Qva)
SAMPLES WERE NOT COLLECTED
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 4.0 FEET ON 6/15/96
TEST PIT THREE
0.0 - 0.2
TOPSOIL
0.2 - 2.0
SP
LIGHT BROWN FINE SAND (MEDIUM DENSE TO DENSE, MOIST) IFILLI
2.0 - 3.5
SP-SM/SM
BROWN TO DARK BROWN FINE SAND WITH SILT TO SILTY FINE SAND (LOOSE
TO MEDIUM DENSE, MOIST) (OLD TOPSOIL)
3.5 - 5.0
SP
LIGHT BROWN FINE SAND (MEDIUM DENSE TO DENSE, MOIST TO WET) (Qva)
SAMPLES WERE NOT COLLECTED
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 5.0 FEET ON 6115/96
TEST PIT FOUR
0.0 - 0.2
TOPSOIL
0.2 - 2.0
SP-SM
BROWN TO DARK BROWN FINE SAND WITH SILT AND SOME ORGANICS
(MEDIUM DENSE, MOIST) (TOPSOIUQva)
2.0 - 4.0
SP
LIGHT BROWN TO BROWN FINE SAND (MEDIUM DENSE, MOIST) (Qva)
SAMPLES WERE COLLECTED AT 1.5 AND 4.0 FEET
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 4.0 FEET ON 6/15/96
NELSON-COUVRETTE & ASSOCIATES, INC.
FILE NO. 178096
FIGURE 4
;Q
(D
(D
D
0
(D
OL (n
60
C,
0
J
OL
0
0
(D
OL
CT
0
a
(D
r- Z
0 C:
0
>,
m
5;u M
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0g z
50 0
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X
En
U)
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'I*
SOIL CLASSIFICATION SYSTEM
GROUP
MAJOR DIVISIONS
SYMBOL
GROUP NAME
COARSE
GRAVEL
CLEAN GRAVEL
GW
WELL -GRADED GRAVEL, FINE TO COARSE GRAVEL
GRAVEL
GP
POORLY -GRADED GRAVEL
GRAINED
SOILS
MORE THAN50%OFCOARSE
FRACTION RETAINED ON
WITH FINES
GM
SILTY GRAVEL
NO., SIEVE
GC
CLAYEY GRAVEL
MORE THAN sm
RETAINED ON
NO.2W SIEVE
SAND
CLEAN SAND
SW
WELL -GRADED SAND, FINE TO COARSE SAND
SP
POORLY -GRADED SAND
MORE THAN s0% OF COARSE
FRACTION PASSES
NO.4 SIEVE
SAND
SM
SILTY SAND
SC
CLAYEY SAND.
WITH FINES
FINE
SILT AND CLAY
INORGANIC
ML
SILT
CL
CLAY
GRAINED
LIQUID LJMR LESS THAN 50%
ORGANIC
OL
ORGANIC SILT, ORGANIC CLAY .
SOILS
SILT AND CLAY
INORGANIC
MH
SILT OF HIGH PLASTICITY, ELASTIC SILT
CH
CLAY OF HIGH PLASTICITY, FAT CLAY
MORE THAN SO% PASSES
NO. 2W SIEVE
uOUIDuMTT50%ORMORE
ORGANIC
OH
ORGANIC CLAY, ORGANIC SILT
HIGHLY ORGANIC SOILS
PT
PEAT
NOTES:
SOIL MOISTURE MODIFIERS
1)
Field classification is based on
Dry-
Absence of moisture, dusty, dry
visual examination of soil in general
to the touch
accordance with ASTM D 2488 - 83.
Moist -
Damp, but no visible water
2)
Soil classification using laboratory
tests is based on ASTM D 2487 - 83.
Wet -
Visible free water or saturated,
usually soil is obtained from
3)
Descriptions of soil density or
below water table
consistency are based on
Interpretation of blowcount data,
visual appearance, of soils, and/or
test data.
NELSON- COUVRETTE&ASSOCIATES, INC.
SOIL
CLASSIFICATION SYSTEM
CONSULTING ENGINEERS, GEOLOGISTS
GEOTECIHNICAL
AND ENVIRONMENTAL SCIENTISTS
FIGURE 3
LOG OF EXPLORATION
DEPTH
USC
SOIL DESCRIPTION
TEST PIT ONE
0.0 -1.3
SM
DARK BROWN SILTY FINE SAND WITH ORGANICS (LOOSE TO MEDIUM DENSE,
WET) (TOPSOIL)
1.3 - 4.0
SP-SM
RED -BROWN FINE SAND WITH SILT (MEDIUM DENSE, MOIST) (WEATHERED
Ova)
4.0 - 6.5
SP-SM
GRAY -BROWN FINE SAND WITH SILT (MEDIUM DENSE TO DENSE, MOIST TO
WET) (Ova)
SAMPLE WAS COLLECTED AT 6.0 FEET
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 6.5 FEET ON 6/15/96
TEST PIT TWO
0.0 - 0.4 SM DARK BROWN SILTY FINE SAND WITH SOME ORGANICS (LOOSE TO MEDIUM
DENSE, WET)
0.4 - 4.0 SP-SM GRAY -BROWN FINE SAND WITH SILT AND ORGANICS (MEDIUM DENSE, MOIST
TO WET) (Ova)
SAMPLES WERE NOT COLLECTED
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 4.0 FEET ON 6/15/96
TEST PIT THREE
0.0 - 0.2
TOPSOIL
0.2 - 2.0
SP LIGHT BROWN FINE SAND (MEDIUM DENSE TO DENSE, MOIST) (FILL)
2.0 - 3.5
SP-SM/SM BROWN TO DARK BROWN FINE SAND WITH SILT TO SILTY FINE SAND (LOOSE
TO MEDIUM DENSE, MOIST) (OLD TOPSOIL)
3.5 - 5.0
SP LIGHT BROWN FINE SAND (MEDIUM DENSE TO DENSE, MOIST TO WET) (Ova)
SAMPLES WERE NOT COLLECTED
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 5.0 FEET ON 6/15/96
TEST PIT FOUR
0.0 - 0.2 TOPSOIL
0.2 - 2.0 SP-SM BROWN TO DARK BROWN FINE SAND WITH SILT AND SOME ORGANICS
(MEDIUM DENSE, MOIST) (TOPSOIL/Qva)
2.0 - 4.0 SP LIGHT BROWN TO BROWN FINE SAND (MEDIUM DENSE, MOIST) (Ova)
SAMPLES WERE COLLECTED AT 1.5 AND 4.0 FEET
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 4.0 FEET ON 6/15/96
NELSON-COUVRETTE & ASSOCIATES, INC.
FILE NO. 178096
FIGURE 4
LOG OF EXPLORATION
DEPTH USC SOIL DESCRIPTION
TEST PIT FIVE
0.0 - 0.4
0.4 - 4.0
TEST PIT SIX
0.0 - 0.5
0.5 - 4.0
TEST PIT SEVEN
0.0 - 0.5
0.5 - 2.0
2.0 - 7.5
TEST PIT EIGHT
0.0 - 0.4
0.4 - 3.0
3.0 - 5.5
TOPSOIL
SP LIGHT BROWN WITH SLIGHT RUST STAINING FINE SAND WITH TRACE SILT
(MEDIUM DENSE TO DENSE, MOIST) (Qva)
SAMPLES WERE NOT COLLECTED
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 4.0 FEET ON 6/15/96
TOPSOIL
SP-SM LIGHT BROWN TO BROWN FINE SAND WITH SILT (MEDIUM DENSE TO DENSE,
MOIST TO WET) (Qva)
SAMPLES WERE COLLECTED FROM 3.0 - 4.0 FEET
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 4.0 FEET ON 6/15/96
TOPSOIL
SP-SM/SM BROWN TO RED -BROWN FINE SAND WITH SILT TO SILTY FINE SAND (MEDIUM
DENSE, MOIST) (WEATHERED Qva)
SP LIGHT BROWN TO BROWN FINE SAND WITH TRACE SILT (MEDIUM DENSE TO
DENSE, MOIST) (Qva)
SAMPLE WAS COLLECTED AT 6.0 FEET
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 7.5 FEET ON 6/15196
TOPSOIL
SP-SM TAN -BROWN FINE SAND WITH SILT (MEDIUM DENSE, MOIST TO WET)
(WEATHERED Qva)
SP-SM GRAY -BROWN FINE TO MEDIUM SAND WITH SILT (MEDIUM DENSE TO DENSE,
MOIST TO WET) (Qva)
SAMPLES WERE COLLECTED FROM 4.0 - 5.0 FEET
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 5.5 FEET ON 6/15/96
NELSON-COUVRETTE & ASSOCIATES, INC.
FILE NO. 178096
FIGURE 5
LOG OF EXPLORATION
1 DEPTH USC SOIL DESCRIPTION
i
TEST PIT NINE
0.0 - 0.7 TOPSOIL
0.7 - 4.0 SM/SP-SM BROWN TO DARK BROWN SILTY FINE SAND TO FINE SAND WITH SILT,
ORGANICS AND A BOTTLE (LOOSE, MOIST) LMU
4.0 - 5.0 SP-SM BROWN FINE SAND WITH SILT (MEDIUM DENSE, MOIST) (Qva)
SAMPLES WERE NOT COLLECTED
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS. COMPLETED AT 5.0 FEET ON 6/15/96
TEST PIT TEN
0.0 - 0.8 TOPSOIL
0.8 - 4.0 SP-SM RED -BROWN TO LIGHT BROWN FINE SAND WITH SILT AND OCCASIONAL
COBBLES (MEDIUM DENSE TO DENSE, MOIST TO WET) (Qva)
SAMPLES WERE NOT COLLECTED
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 4.0 FEET ON 6/15/96
NELSON-COUVRETTE & ASSOCIATES, INC.
FILE NO. 178096
FIGURE 6
9�2o;2 o,z V. Vvie,
rAO 4.01 rs
7-X7,e%,Al
1�5 aeiz S//0 /�7— 7- 5-9 5 - P-o ,P-
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CITY C-Qpy.
05 06 98 12:42 FAX 1-425-481-6149 BDZ DEVELOPERS .-.. LSA Z 01
Sky
Valley P.O. Box 835
Monroe, WA. 98272
Testing (360) 794-4555
(206) 788-6600
December 4, 1996 DEC 1 0 1996
Project No. 6854
BDZ Developers, Inc.
19400 33rd Ave W, suite 200
Lynnwood, Wa. 98036
Reference: Olympic View S.P.
92 Ave W. & Olympic view Dr.
Edmonds, Wa.
To Whom It May Concern:
The Above referenced site was monitored by observing fill
placement arid the taking of density tests as fill was
placed and compacted. These were taken in the fill area
located in the west portion of lots 1 & 2. Results are
enclosed along with (proctor) maximum density.
we trust this information is of value and if you have any
questions please call.
incere�
Jerry Boyd
Soil Consultant
SKY VALLEY TESTING
P. O. Box 835
Monroe, WA 98212
(360) 7944555 (206) 788-6600
DAILY FIELD REPORT
Soils tab — Drainfleld Design
TRAVEUPREP. TrhfE
/ Q
JOB No. f J
fiSW� G�
Tims ON srrE
LAMES
MMOFF SrrE
FAGS OF
WEATHER
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VISrTORS
CLMWT/OWNER
REPORT SEO. NO.
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SKY VALLEY TESTING
TRAVEUPRIEF, TrME
JOB NO.
P. 0. Box 835
VRE ON srm
MILES
Monroe, WA 98272
(360) 7944555 (206) 788-6600.
TDAE OFF ME
PAGE
OF
DAILY FIELD REPORT
WEATHER
4�0057
VISITORs
CUUNT/OwKER
REPORT SEQ- NO.
Z02
Joe
0011,lvvox
JOB LOCATION
nAY OF WEEK
CONTRACTOR 64) z
FOREMAN
J IRS. CIIARGED
Test
Point
No.
Location
Fill
Depth
Ft.
Elev.
Ft.
Moisture
Content
%
Dry
Dre-rasity
Pd
Max. Dry
Density
PCf
17,Z-5
Percent
Compaction
17
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05, 06. 98 12: 42 FAX 1=425-481-6149 BDZ DE17ELOPERS 444 LSA
Z 03
SKY VALLEY TESTING
TRAVIIJPREP.TIAS / d
JOB No.
P. O. Box 835
Monroe, WA 98272
r
TIME ON SffE
Z J �
MRES
(360) 794-4555 (206) 788-6600
T EOFFSrM
PAGE
OF
DAILY FIELD PORT'
WEATHER
PW7ZZJ eZ4W /Sy/i�,VY
VISITORS
CLIENT/OWNER
REPORT SEQ. NO.
OB
JD6-/
TION
JOHZpTf�G
iIli aw 04
J)ATE
I1�(/f� I I
DAYWEEK
I
CONTRACTOR
FOREMAN
HRS. CHARGED
Test
Location
Fill
Elev.
Moisture
Dry
Max. Dry
Percent
Point
Depth
Ft,
Content.
Density
Density
Compaction
No.
Ft.
%
pcf
pcf
13
1`/
�5�--
/3: zr
/ 7
/02-5
96
NOTES:
9L
E
M6—f
41
7h�73��
'maw
- f89a.-19�0
City of Edmonds
t
+�
;r ,y
DEC 7 1995
a :
PERMIT COUNTER
-
.Y�
J
Critical Areas Checklist
The Critical Areas Checklist contained on
and submit.] KWilie"City. The City will
this form is to be filled out by- any person
, review the checklist, make a precursory site ' ...
preparing a Development Permit
• -visit, and make a determination of the
Application for the City of Edmonds prior..;;; .:
`" . subsequent steps necessary to complete_ a_
to his/her submittal of a development,; `..,:-:f
development permit application.
permit to the City.
Arth a signed copy.,of this form; the -
The purpose of the Checklist is to. enable
applicant should also submit a vicinity map
City staff to determine -whether any - • -- -----
or plot -plan for individual lots ofthe•par+cel
potential Critical Areas are or may be•with
enough detail that City staff can find-
present on the subject property: The
::and identify the subject pareel(s).i,7
information needed to complete the r ty
ad&don, the applicant shall include
Checklist should be easily available.froiii'•;` -
other pertinent information (e.g. site,:`:":; -
observations of the site or data available at
_ . •.: .
P1ax4 topography map, etc.):ur studies. • s'm
l
City Hall (Critical Areas inventories; maps,
•'
cogjunction with this Checkl stio assist
or soil surveys). :�;:A�
staff in completing their preliminary.. '. y,•
assessment of the site.
An applicant, or his/her" representative,
must fill out the checklist, sign and date it,
I have completed the attached Critical Area Checklist and attest that the answers provided are
factual, to th4est of my knowledge (fill out the appropriate column below). -^ -
Owner / Applicant: Applicant Representative:
N. V� Cu tJN b w 6 O&M Cv
Name Name
`t2c° w R 61
Street Address ' Street Address 11T
City, State, ZIP
City, State, ZIP ti,. {� p ty �Phoae
c.�, Z b 95 s� 9,Sta•
Signature Date Signature Date
_ i ,�, h }. x i`>� •!31 f � err sz � 1, i � 2 +ti Ft;d��J m.A7h y, ; ��,pa:�. .
c.•,' S t}�Jr4M.Y .ry, 4 •S'��
� It i L�ti�tt ,�, i � �a;t t� �' F^�'f-�'�p y�C , •(..r �, 'r •. �f' 't L� h .Y $
CA FILE NO.�5��
Critical Areas Checklist
Site Information`(soils/topography/hydrology/vegetation)
1. Site Address/Location: 9.20H 01 wto
lc-
-Tw► o
2. Property Tax Account Number: 5 10 ' ba - O (5 - U 00% S'r `S� �0O b" oa
3. Approximate Site Size (acres or square feet): ' S 9 oca o s J�4 a 1(,00c, CS,�S.E,- Oct -0J3 -V
4. Is this site currently developed? K yes; no.R `
If yes; how is site developed? < % vw e ' C 4 R-es c e
5. Describe the general site topography. Check all that apply.
Flat: less than 5-feet elevation change over entire site.
_. Rolling: slopeFon site generally less than 15% (a vertical rise of 10-feet over a
horizontal distance of 66-feet).
Hilly: slopes present on site of more than 15% and less than 30% ( a vertical rise
of 10-feet over a horizontal distance of 33 to 66-feet).
Steep: grades of greater than 30% present on site (a vertical rise of 10-feet over a
horizontal distance of less than 33-feet).
Other (please describe):
6. Site contains areas of year-round standing water: VL0IN ; Approx. Depth:
7. Site contains areas of seasonal standing water. 110"C ; Approx. Depth:
What season(s) of the year? �1 a
8. Site is in the floodway nd floodplain ✓W of a water course.
9. Site contains a creek or an area where water flows across the grounds surface? Flows are year-
round? h o.% Flows are seasonal? 41:5_ (What time of year? A . ).
10. Site is primarily: forested ; meadow ; shrubs ; mixed
urban. landscaped (lawn,shrubs etc) )C
11. Obvious wetland is present on site: no t4@.
R"0004% ti
9�2 D ;2
4�0100vN G- e-7—
Sr'a G�,ET-,�,vrrry�cl SA5 T7�!
-t/i = //,
Ad S B0. G1�3�9'q°v
' M Y
_ Fri_7T-=0u
7,
V-P - - -----
1
FILL_
NT L�tiE.
�UILDIN�
MAR - � 1998
GEOTECHNICAL INVESTIGATION REPORT
FOUR LOT SHORT PLAT
EDMONDS, WASHINGTON
FOR
THE CITY OF EDMONDS AND
LOVELL-SAUERLAND & ASSOCIATES, INC.
STREET FILE
I
NELSON-COUVRETTE & ASSOCIATES, INC.
CONSULTING GEOTECHNICAL ENGINEERS, GEOLOGISTS
AND ENVIRONMENTAL SCIENTISTS
17311.135th Avenue NE, A-500
Woodinville, WA 98072
(206) 486-1669 • Fax 481.2510
July 11, 1996
City of Edmonds
Planning Department
250 - 5th Avenue
Edmonds, Washington 98020
Geotechnical Investigation Report
Four Lot Short Plat
Edmonds, Washington
NCA File No. 178096
Snohomish County (206) 337.1669
Wenatchee/Chelan (509) 784.2756
INTRODUCTION
This report presents the results of our geotechnical investigation for the planned LSA/Echelbarger four
lot short plat in Edmonds, Washington. The site is located on the south side of Olympic View Drive near
the 9200 block. We have been retained to evaluate a critical area and provide recommendations for site
development. For our use in preparing this report, we have been provided with a copy of the plans, dated
May 1996, prepared by Lovell-Sauerland & Associates, Inc. (LSA).
The project will consist of four residential lots that will be accessed along the western property line. The
access road will have a few feet of fill with a planned rockery as high as 4 feet on the downhill side. An
existing slope will be regraded on the east side of Lot 3. A rockery 4 to 6 feet in height is planned at the
base of this slope. The excavated material from the slope regrading will be used as fill to raise the road
grades and to fill a low area on the west side of Lots 1 and 2. A steep slope located in the southeast
corner of the site is to remain undisturbed. The steep slope will be .within Lots 3 and 4, and we have
been requested to provide setbacks from the toe of slope for these lots. Existing structures will be
removed from the site during project development. The grading required to develop the lot areas will
need to be accomplished during plat development as it incorporates building and roadway areas.
' Geotechnical Investigation Report
Four Lot Short Plat
NCA File No. 178096
July 11, 1996
Page 2
SCOPE
The purpose of this study is to explore the subsurface conditions and to provide recommendations for
project development. Specifically, our scope of services includes the following:
1. Review the geologic map for the area.
2. Explore the subsurface conditions with backhoe excavated test pits.
3. Evaluate the ground water conditions.
4. Provide recommendations for site preparation, grading and structural fill.
5. Provide recommendations for foundation design and setbacks from steep slopes.
6. Provide general information for on -site drainage considerations.
7. Prepare a written report to document our findings and recommendations.
1
j SITE CONDITIONS
Surface
The site is over 1.3 acres in size and has a residence, garage, shed, and fallout shelter. The site is
accessed in the middle of the north property line from Olympic View Drive. A couple of short retaining
walls and hedges exist along side of the driveway. The site slopes generally to the northwest with a total
vertical relief of approximately 50 feet. We measured the slopes on site with a clinometer. These
measurements were compared to the site plan provided to us. Our slope angles are similar to the grades
shown on the topography map provided to us.
A steep slope exists in southeastern portion of the site. The steep slope has angles up to 30 degrees (58
percent) with a vertical relief of approximately J 5 feet. Near the top of the steep slope, the neighboring
property owner has been using the area as a garden. Debris has been placed on the steep slope, in the
approximate area shown on the site plan, creating a pile approximately 3 to 4 feet in height.
A low area exists in the northwest portion of the site. The lowest point is approximately 5 to 6 feet
below the road elevation. The area is covered with tall grass. We suspect that the area was previously
used as a borrow pit.
Vegetation consists of a few large evergreen and deciduous trees with a dense undergrowth in the
southern portion of the site. The developed portion of the site is covered with grass, trees and small
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NELSON-COUVRETTE & ASSOCIATES, INC.
Geotechnical Investigation Report
Four Lot Short Plat
NCA File No. 178096
July 11, 1996
Page 3
underbrush or shrubs. Tall strands of hedges occur alongside the existing driveway. Vegetation on the
steep slope consists of brush, bent' vines, and scattered deciduous trees. The trees on the steep slope
range up to 22 inches in diameter.
Geologic Conditions
Landforms within this region comprise a system of glacially sculptured features, which have been
exposed by post -glacial erosion. Locally, the terrain of this area is interpreted to have been glacially
modified, and to have been placed during the latest glaciation of the Puget Lowland area. Glacial ice is
thought to have last occupied the region during the late Pleistocene Epoch, some 11,000 to 13,000 years
before present. The latest glacial advance over the area is referred to as the Vashon Stade of the Fraser
Glaciation, of which the geologic materials on site are believed composed.
The general stratigraphy within this area was observed and found to consist of advance glacial outwash,
referred to as Esperance Sand (Qva/Qe). Advance outwash in this area is composed of a dense, fine
sand, with trace silt and occasional gravel, which has been overridden and compacted by the weight of
the thick glacial ice. The advance sands were observed in all of the test pits. It is not uncommon for
more gravelly and/or silty zones to occur in these deposits.
The Geologic Map of the Edmonds East and Edmonds West Quadrangle Snohomish and King Counties
Washington by James P. Minard, published by U.S. Geological Survey in 1975, was referenced for the
geologic and soil conditions at the site. The soil unit mapped at this site is classified as a Whidbey
Formation (Qw), with glacial till (Qvt) and Esperance Sand in the near vicinity. We did not encounter
F the Qw or Qvt in the subsurface conditions of the site. The Esperance Sand deposit is the geological unit
which commonly lies between the Whidbey and till deposits.
Subsurface Conditions
The subsurface conditions at the site were explored on June 8, 1996 by excavating ten test pits with .a
tire -mounted backhoe. The depths of the backhoe test pits range from 4.0 to 7.5 feet. The approximate
locations of the test pits are shown on the Site Plan in Figure 2. A representative from our firm was
present during the explorations. He examined the soils and geologic conditions encountered and
maintained logs of the test pits. The soils were visually classified in general accordance with the Unified
i Soil Classification System, a copy of which is presented as Figure 3. The logs of the test pits are
presented in Figures 4 through 6.
f NELSON-COUVRETTE & ASSOCIATES, INC.
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Geotechnical Investigation Report
Four Lot Short Plat
NCA File No. 178096
July 11, 1996
Page 4
i Subsurface conditions found on site consist mostly of a fine sand with silt or trace silt that varied from
loose at the surface, to medium dense to dense with depth. We have interpreted these soils to be the
Esperance Sands. Test Pit 9, located on the east portion of Lot 2, encountered 4 feet of fill. The fill
consists of similar native material with some organics and bottles. We also expect localized fills in areas
behind structures and/or retaining walls. The site is covered with a thin layer of topsoil. The topsoil
ranged up to 0.8 feet in depth.
Hydrologic Conditions
No obvious evidence of ground water, perched ground water or outcropping ground water along the
slopes was observed within this site. The advance outwash is considered fairly permeable and water is
expected to infiltrate vertically in the deposit until it encounters a less permeable layer, such as the
Whidbey Formation. We do not know the depths of these less permeable layers. The site appears to be
well drained with the advance sands.
SENSITIVE AREA EVALUATION
Seismic Hazard
The Puget Sound Region is classified as a Zone 3 by the Uniform Building Code. Seismic considerations
for this type of site includes liquefaction potential and attenuation of ground motions by soft soil
i deposits. The liquefaction potential is highest for loose sand and silty sand with a high ground water
table. The sand deposits at the site below a few feet were at least medium dense or better. These soils
have a low potential of liquefaction. Seismically sensitive soft soils were not observed at this site.
Erosion Hazard
The erosion hazard criteria used for determination of affected areas include soil type, slope gradient,
vegetation cover, and ground water conditions. The erosion sensitivity is related to vegetative cover and
the specific surface soil types (group classification); which are related to the underlying geologic soil
units. The soils have been classified in accordance with the Soil Conservation Service (SCS)
classification system and have been grouped with respect to the corresponding geologic unit. The
geologic unit is Esperance Sand which corresponds to the SCS classification of Everett soils. The
erosion hazard is greatest when the on -site soils have been stripped of vegetation. Provided the surface
water flowing over the exposed sands are properly controlled during construction, and vegetation is re-
established after development, we do not expect a significant erosion concern.
NELSON-COUVRETTE & ASSOCIATES, INC.
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' Geotechnical Investigation Report
Four Lot Short Plat
NCA File No. 178096
July 11, 1996
Page 5
i
Landslide Hazard
An evaluation of potential landslide hazard was performed for this site. This evaluation includes soil
type, underlying stratigraphy, slope gradient, ground water conditions, and vegetation cover. The soil
conditions at the site commonly have high strengths and the slope angles are not excessively steep for
these types of soils. We also did not observe any signs of instability such as shallow or deep-seated
failures. Accordingly, it is our opinion that the native site slopes are stable and large scale failures are
not expected.. Localized slough events may occur in the steep portions depending on the area specific
conditions. These would be expected to be shallow, involving the near -surface soils. The garden debris
placed on the top of the steep slope is considered unstable may cause shallow sloughs of the steep slope.
CONCLUSIONS AND RECOMMENDATIONS
General
The site is suitable for the planned residential short plat. The underlying sand deposits have moderately
high strength, and the existing slopes are considered stable with respect to deep-seated landslides or
failures. Surficial sloughing and erosion can occur, however, we did not observe evidence of slope
failures. The risk of these sloughs can be minimized by maintaining vegetation on the slopes and
controlling any surface water that may exist. We consider that minimum setbacks from the toe of slope
are considered appropriate to reduce the risk of future effects from surface sloughing. The outwash sand
deposits should provide a good subgrade for support of the structure's foundations.
The soil to be used as structural fill will be obtained from the east side of Lots 1, 2 and 3. Excavating
these soils to be used as fill, will cause a portion of the trees and the existing structures to be removed
during the initial development activities. The fill soil will be placed in the roadway area and also the low
depression on the west side of Lot 1.
' Building Setbacks
Uncertainties related to building along steep slopes are typically addressed by the use of building
setbacks. The purpose of the setback is to establish a "buffer zone" between the dwelling areas and the
slope margin so that ample room is allowed for normal slope regression, or if a slope failure were to
occur, the likelihood of dwelling involvement would be minimized. In a general sense, the greater the
setback, the lower the risk. From a geological standpoint, the setback dimension is usually based on the
slope's physical characteristics, e.g., slope height, surface angle, material composition, hydrology, etc.
Other factors such as historical slope activity, rate of regression, type, and desired life span of the
development are important considerations as well.
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NELSON-COUVRETTE & ASSOCIATES, INC.
Geotechnical Investigation Report
Four Lot Short Plat .
j NCA File No. 178096
j July 11, 1996
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Page 6
Based upon our explorations, slope evaluation and observations, we recommend a minimum building
setback of 10 feet for structures on Lots 3 and 4. Setbacks are not necessary on the other lots from the
toe of the steep slope. Specifically, we recommend that the setback area not be used for placement or
storage of fill materials, including "temporary" excavation spoils from building area preparation and
excavation. The landscape debris on the upper portion of the steep slope should be removed. The area
should be re-established with vegetation if the soil is exposed. Any development or encroachment into
the setback areas should be evaluated by a specific geotechnical evaluation and report.
Site Preparation and Grading
Site preparation and grading should consist of stripping the vegetation and topsoil layer to the planned
subgrade. The exposed surface should be compacted to a non -yielding condition using a steel -drum
vibratory compactor. The subgrade should be observed for indication of disturbance of the lower soils
both during excavation and compaction. If the subgrade shows signs of disturbance, we should be
retained to provide recommendations for repair or potentially alternate construction techniques.
The on -site soil is expected to be only somewhat moisture sensitive with a uniform grain size, and may
be difficult to work and compact during periods of wet weather. Earthwork should be suspended during
rainfall and for a period of time afterward. The actual ability to work the site during the wet time of the
year will be dependent on the performance of the soils under load when wet. These conditions should be
observed and the site work adjusted accordingly. We recommend that all soil stock piles that are
intended to be used as backfill be covered with plastic during rainy weather to help.maintain a moisture
content suitable for compaction. Sometimes a layer of crushed gravel or 2- to 4-inch spalls is used to
provide wet season access and to improve pavement and foundation subgrade. The use of the gravel and
spalls should be based on conditions observed in the field.
Excavation Slopes
Temporary slopes greater than 4 feet in height should be sloped at an inclination no steeper than 1.5H:1 V
for the loose to medium dense sands, and 1H:1V for dense sands for cuts up to 12 feet in height. These
slopes should be protected from rain by well secured plastic sheeting. If ground water or seepage is
encountered, we should be retained to comment on the stability of the slopes in the excavation. The
above cut slope angles should be considered preliminary in nature. The contractor should be ultimately
responsible for the stability of the cut slopes, as he is continuously at the site and can observe the
performance on a daily basis. All state and federal standards should be followed with respect to cut
slopes and workman safety.
NELSON-COUVRETTE & ASSOCIATES, INC.
' Geotechnical Investigation Report
Four Lot Short Plat
NCA File No. 178096
July 11, 1996
Page 7
Structural Fill
General: Fill will be placed with the current design. Fill to be placed beneath buildings, pavements or
other settlement sensitive features, should be placed as structural. fill. Structural fill, by definition, is soil
placed in accordance with prescribed methods and standards described in this report, and is monitored by
an experienced geotechnical professional or soils technician. Field monitoring procedures would include
a representative number of in -place density tests to document the attainment of the desired degree of
relative compaction.
Materials: Imported structural fill should. consist of a good quality free draining granular soil, free of
organic and other deleterious material, and be well graded to a maximum size of about 3 inches.
Imported all weather fill should contain no more than about 5 percent fines (soil finer than a U.S. No.
200 sieve) based on that fraction passing the U.S. 3/4-inch sieve.
The on -site outwash soil can be used as structural fill but these soils contain some fine-grained particles
and are considered slightly moisture sensitive. The use of the soils as fill should be limited to extended
periods of dry weather. These soils have a uniform grain size and are sometimes more difficult to
compact than well graded soils. Depending on the moisture content of the soil, adding water may be
necessary to achieve compaction. Soils with a high organic content should not be used as structural fill.
Fill Placement: Following subgrade preparation, placement of the structural fill may proceed. All
backfilling should be accomplished in 8- to 10-inch thick uniform lifts. Each lift should be spread evenly
and be thoroughly compacted prior to placement of subsequent lifts. All structural fill underlying
building areas, and within 2 feet of pavement subgrade, should. be compacted to a minimum of 95
percent of its maximum dry density. Maximum dry density in this report refers to that density as
determined by the ASTM D 1557 compaction test procedure. Fills more than 2 feet beneath sidewalks
and pavement subgrades should be compacted to at least 90 percent of their maximum dry density. The
moisture content of the soils to be compacted should be within about 2 percent of optimum, so that a
readily compactable condition exists. ' It may be necessary to overexcavate and remove wet soils in cases
where drying to a compactable condition is not feasible. All compaction should be accomplished by
equipment of a type and size sufficient to attain the desired degree of compaction. Care should be taken
when compacting the soil condition near to adjacent houses. A photo documented survey of the .
neighboring structures is suggested prior to any heavy equipment arriving at the site. Sometimes the use
of smaller compaction equipmen't and thinner lifts is better if adjacent structures are being impacted.
NELSON-COUVRETTE & ASSOCIATES, INC.
Geotechnical Investigation Report
Four Lot Short Plat
NCA File No. 178096
July l 1, 1996 .
Page 8
Foundations
The foundations should be placed either on undisturbed medium dense or dense native sand or structural
fill extending to these soils. If footings are to bear on structural fill, the -fill zone should extend outside
of the footing a distance equal to the depth of fill beneath the footing. The soil conditions should be
evaluated for appropriate density and disturbance at the time of construction. Exterior footings should
extend a minimum of 18. inches below the adjacent outside ground surface, with interior column footings
a minimum of 12 inches below the bottom of the adjacent slab. All loose or disturbed soil should be
removed from the foundation excavation prior to placing concrete. Standing water should not be allowed
to accumulate in the building pad or footing trenches.
For foundations constructed as outlined above, we recommend an allowable design bearing pressure of
not more than 2,500 pounds per square foot•(psf) be used. Higher bearing values may be available based
on specific soil conditions, footing size and settlement tolerance. This can be reviewed at the time that
the structure is designed and foundation loads are determined. A .one-third increase in the above
allowable bearing pressure may be used when considering short-term transitory wind or seismic loads.
Although structural loading information was not available at the time of this study, based on our
experience with similar structures supported on similar soil conditions and for the above allowable soil
bearing pressures, we estimate that the maximum total post -construction settlement for medium dense
sands should be 3/4 of an inch or less, and that the differential settlement across the building width
should be 1/2 inch or less. We expect larger differential settlements may occur.if the building is
constructed part on fill and part on native soils.
Lateral Pressures
The lateral pressure acting on retaining walls is dependent on the nature and density of the soil behind
the wall, the amount of lateral wall movement which can occur as backfill is placed and the inclination of
the backfill. Soil pressures will be less for walls that are free to yield at the top at least one -thousandth
of the height of the wall, than if movement is limited by such factors as wall stiffness or bracing. We
recommend that yielding walls supporting horizontal backfill be .designed using an equivalent fluid
density of 35 pounds per cubic foot (pcf). Non -yielding walls should be designed using an equivalent
fluid density of 50 pcf. These lateral soil pressures do not include the effects of surcharges such as
traffic loads or other surcharge loads. Surcharge effects should be considered, if appropriate. If desired,
we can provide recommendations for surcharge loads as they become apparent.
NELSON-COUVRETTE & ASSOCIATES, INC.
Geotechnical Investigation Report
Four Lot Short Plat
NCA File No. 178096
July 11, 1996
Page 9
All backfill for subgrade walls that will, not act as structural fill should be compacted to between 90 and
92 percent of the maximum dry density as determined in accordance with ASTM D 1557. Care should
be taken to prevent the buildup of excess lateral soil pressures due to overcompaction of the backfill
behind the wall. This can be accomplishedby placing the backfill within 18 to 24 inches of the wall in
lifts not exceeding 8 inches in loose thickness, and compacting this zone with hand -operated vibrating
plate compactors.
Lateral loads can be resisted by friction between the foundation and subgrade or the passive earth
pressure acting on the below -grade foundation. For the latter, the foundation must be placed "neat"
against the undisturbed soil, or backfilled with a clean, free draining, compacted structural fill. We
recommend that lateral passive resistance be calculated by using an equivalent fluid weight of 250 pcf.
An allowable coefficient of friction between footings and the subgrade of 0.40 may be used. These
values include a factor of safety of 2.0 for lateral resistance and 1.5 for the coefficient of friction.
The wall pressures, listed above, are based on the assumption that the soil directly behind the wall is free
draining or a drainage composite is used. All of the on. -`site surface soils are not free draining. Some free
draining soil may exist at depth. Wall drains are discussed in .the Subsurface Drainage sub -section of
this report.
Site Drainage
Surface Drainage: The finished ground surface should be graded such that storm water is directed off
of the site. Water should not be allowed to stand in any area where footings, slabs or pavements are to be
constructed. Final site grades should allow for drainage away from the building. We suggest that the
finished ground be sloped at a gradient of 3 percent minimum for a distance of at least 10 feet away from
the building. Surface water should be collected by permanent catch basins and drain lines, and be
discharged into a storm drain system.
The surficial soils are loose to medium dense, fine sand. These soil types erode easily, especially when
directly exposed to precipitation and runoff. Surface water should be diverted away from the steep to
moderate slopes. Stripped areas should be revegetated to improve the stability of the near -surface slope
soils. The vegetation should be maintained until it is established.
Subsurface Drainage: Where slabs are located below the surrounding grades, a system of perimeter
footing drains should be included in the design. The perimeter footing drains should consist of 4-inch
diameter perforated smooth -walled PVC pipe surrounded by pea gravel. The footing drains should be
NELSON-COUVRETTE & ASSOCIATES, INC.
Geotechnical Investigation Report
Four Lot Short Plat
j NCA File No..178096
i July 11, 1996
Page 10
1
located at the elevation of the footing. The drains should be tightlined to the storm drain system. We do
not consider foundation drains necessary for standard foundations construction.
A drainage system should be planned behind all retaining walls. The drainage system should consist of
an 18-inch wide blanket of free draining material. Pea gravel would be a suitable material. If 0:5-inch or
larger washed rock is used, filter fabric may be required to surround the rock. A drainage composite
approved by geotechnical engineer could be used in place of the rock blanket. A 4-inch diameter
perforated pipe should be placed along the base of the wall within the free draining material. The drains
should be routed to an appropriate discharge point.
Slabs -on -Grade
Slabs should be supported on native subgrade soils or structural fill prepared as described in the Site
Preparation and Grading and Structural Fill sub -sections of this .report. Where moisture control is
important, we recommend that the floor slabs be underlain by 6 inches of free draining granular material,
for use as a capillary break. A suitable vapor barrier, such as heavy plastic sheeting, should be placed
over the capillary break material. A 2-inch thick sand blanket may be placed over the vapor barrier to
protect it during placement of the concrete and to help the concrete cure.
Rockeries
Rockeries are used in the Puget Sound region to face stable soil exposures to reduce weathering and
slough type failures. Although it is not always common to consider a rockery as a retaining wall, in
reality, the rockery can act as a gravity wall. The problems associated with using the rockery as a
retaining wall is the quality of the rockery construction and the compacted backfill. There is some risk
associated with rockeries since the rocks are not tied together. Therefore, the methods in which they are
stacked are very important. Rockeries should be designed and constructed in accordance with
Association of Rockery Contractors (ARC) guidelines, unless otherwise recommended in this report.
Inspection of the rockery construction by the geotechnical consultant is recommended.
We consider the rockery at the base of the cut slope to be appropriate. However, we recommend that the
rock sizes be increased to H/2 instead of the 1-1/3 as recommended in the ARC manual. We recommend
that the same standards be used for the rockery that retains the driveway fill. However, since the wall
could be exposed to unknown wheel and traffic loads, it may be prudent to design it as a reinforced soil
wall. The reinforcement could consist of either fabric or geogrid.
NELSON- COU VRETTE & ASSOCIATES, INC.
Geotechnical Investigation Report
Four Lot Short Plat .
i NCA File No. 178096
i July 11, 1996
Page 11
USE OF THIS REPORT
We have prepared this report for The City of Edmonds, Lovell- Sauerland & Associates, Inc. and their
agents, for use in planning and design of this project. The data and report should be provided to
prospective contractors for their bidding or estimating purposes, but our report, conclusions and
interpretations should not be construed as a warranty of the subsurface conditions. The scope of our
services does not include services related to construction safety precautions and our recommendations
are not intended to direct the contractor's methods, techniques, sequences . or procedures, except as
specifically described in this report for consideration in design.
There are possible variations in subsurface conditions between the explorations and also with time. A
contingency for unanticipated conditions should be included in the budget and schedule. We should be
retained to provide monitoring and consultation services during construction to confirm that the
conditions encountered are consistent with those indicated by the explorations, to provide
recommendations for design changes should the conditions revealed during the work differ from those
anticipated, and to evaluate whether or not earthwork and foundation installation activities comply with
contract plans and specifications.
Within the limitations of scope, schedule and budget for our services, we have strived to take care that
our work has been completed in accordance with generally accepted practices followed in this area at the
time this report was prepared. No other conditions, expressed or implied, should be understood.
NELSON-COUVRETTE & ASSOCIATES, INC.
Geotechnical Investigation Report
Four Lot Short Plat
NCA File No. 178096.
July 11, 1996
Page 12
f We appreciate the opportunity to be of service to you. If there are any questions concerning this report
or if we can provide additional services, please call.
Sincerely,
NELSON-COUVRETTE & ASSOCIATES, INC.
C7UX
Rick B. Powell, PE
Project Engineer
EXPIRES (e . t-+. �jg
Charles P. Couvrette, PE
Principal Engineer
Three Copies Submitted
Six Figures
s
cc: Mr. Jurgen Sauerland - Lovell-Sauerland & Associates, Inc.
1
NELSON-COUVRETTE & ASSOCIATES, INC.
LOG OF EXPLORATION
DEPTH USC SOIL DESCRIPTION
TEST PIT ONE
0.0 -1.3 SM DARK BROWN SILTY FINE SAND WITH ORGANICS (LOOSE TO MEDIUM DENSE,
WET) (TOPSOIL)
1.3 - 4.0 SP-SM
RED -BROWN FINE SAND WITH SILT (MEDIUM DENSE, MOIST) (WEATHERED
ova)
4.0 - 6.5 SP-SM
GRAY -BROWN FINE SAND WITH SILT (MEDIUM DENSE TO DENSE, MOIST TO
WET) (Ova)
SAMPLE WAS COLLECTED AT 6.0 FEET
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 6.5 FEET ON 6/15/96
TEST PIT TWO
0.0 - 0.4 SM
DARK BROWN SILTY FINE SAND WITH SOME ORGANICS (LOOSE TO MEDIUM
DENSE, WET)
0.4 - 4.0 SP-SM
GRAY -BROWN FINE SAND WITH SILT AND ORGANICS (MEDIUM DENSE, MOIST
TO WET) (Ova)
SAMPLES WERE NOT COLLECTED.
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 4.0 FEET ON 6/15/96
TEST PIT THREE
0.0 - 0.2 TOPSOIL
0.2 - 2.0 SP LIGHT BROWN FINE SAND (MEDIUM DENSE TO DENSE, MOIST) IFILLI
2.0 - 3.5 SP-SM/SM BROWN TO DARK BROWN FINE SAND WITH SILT TO SILTY FINE SAND (LOOSE
TO MEDIUM DENSE, MOIST) (OLD TOPSOIL)
3.5 - 5.0 SP LIGHT BROWN FINE SAND (MEDIUM DENSE TO DENSE, MOIST TO WET) (Ova)
SAMPLES WERE NOT COLLECTED
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 5.0 FEET ON 6/15/96
TEST PIT FOUR
0.0 - 0.2 TOPSOIL
0.2 - 2.0 SP-SM BROWN TO DARK BROWN FINE SAND WITH SILT AND SOME ORGANICS
(MEDIUM DENSE, MOIST) (TOPSOIUQva)
2.0 - 4.0 SP LIGHT BROWN TO BROWN FINE SAND (MEDIUM DENSE, MOIST) (Ova)
SAMPLES WERE COLLECTED AT 1.5 AND 4.0 FEET
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 4.0 FEET ON 6/15/96
NELSON-COUVRETTE & ASSOCIATES, INC.
FILE NO. 178096
FIGURE 4
Approximzis Location of Debris
* ....... TP-8
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A
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% TP- 101
TP-5
TP-7
Al
\ \ •�l ;1 •:e�� =tit.:- \ 2 - -----
IS
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TP-2
TP-3
T 1-6
0
TP-4
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Z-
TP-1
7
- - - - - - - - - - - - - - - -
V
LEGEND
TP-
NUMBER AND APPROXIMATE
LOCATION OF TEST PITS
2 rV-T SE?XCK AT PL
NELSON- COUVRETTE &ASSOCIATES, INC.
Reference: Site Plan was created from a drawing provided by Lovell-Sauerland & Associates, Inc., CoNsuLrNa GEOTECHNIC44 ENGINEERS. GEOLOGISTS
dated May 16,1996 AND ENVIRONMENTAL SCIENTISTS
!-9
Site Plan
0 40 80
Scale 1" = 40'
FIGURE
LSA/Echelbarger 2
FILE NO. DATE
178096 June 1996
SOIL CLASSIFICATION SYSTEM
GROUP
MAJOR DIVISIONS
SYMBOL
GROUP NAME
COARSE
GRAVEL
CLEAN GRAVEL
GW
WELL -GRADED GRAVEL, FINE TO COARSE GRAVEL
GRAVEL
GP
POORLY -GRADED GRAVEL
GRAINED
SOILS
MORE TI"W%OF COARSE
FRACTIONRETANEDON
WITH FINES
GM
SILTY GRAVEL
NO.4 SIEVE
GC
CLAYEY GRAVEL
MORE THAN 5M
RETANED ON
NO.200 SIEVE
SAND
CLEAN SAND
SW
WELL -GRADED SAND, FINE TO COARSE SAND
SP
POORLY -GRADED SAND
MORE THAN 50% OF COARSE
FRAC M PASSES
NO.4 SIEVE
SAND
SM
SILTY SAND
SC
CLAYEY SAND
WITH FINES
FINE
SILT AND CLAY
INORGANIC
ML
SILT
CL
CLAY
GRAINED
uOVio IJMR LESS THAN So%
ORGANIC
OL
ORGANIC SILT, ORGANIC CLAY .
SOILS
SILT AND CLAY
INORGANIC
MH
SILT OF HIGH PLASTICITY, ELASTIC SILT
CH
CLAY OF HIGH PLASTICITY, FAT CLAY
MORE 71-AN Sax PASSES
NO. 200 SIEVE
UOM UMIT sax OR MORE
ORGANIC
OH
ORGANIC CLAY, ORGANIC SILT
HIGHLY ORGANIC SOILS
PT
PEAT
NOTES:
SOIL MOISTURE MODIFIERS
1)
Field classirication is based on
Dry -
Absence of moisture, dusty, dry
visual examination of soil In general
to the touch
accordance with ASTM D 2488 - 83.
Moist -
Damp, but no visible water
2)
Soil classification using laboratory
tests is based on ASTM D 2487 - 83.
Wet -
Visible free water or saturated,
usually soil is obtained from
3)
Descriptions of soil density or
below water table
consistency are based on
Interpretation of blowcount data,
visual appearance, of soils, and/or
test data.
NELSON-COUVRETTE & ASSOCIATES, INC.
SOIL
CLASSIFICATION SYSTEM
CONSULTING GEOTECHNICAL ENGINEERS, GEOLOGISTS
AND ENVIRONMENTAL SCIENTISTS
-
FIGURE 3
LOG OF EXPLORATION
DEPTH USC SOIL DESCRIPTION
TEST PIT ONE
0.0 -1.3 SM DARK BROWN SILTY FINE SAND WITH ORGANICS (LOOSE TO MEDIUM DENSE,
WET) (TOPSOIL)
1.3 - 4.0 SP-SM RED -BROWN FINE SAND WITH SILT (MEDIUM DENSE, MOIST) (WEATHERED
ova)
4.0 - 6.5 SP-SM GRAY -BROWN FINE SAND WITH SILT (MEDIUM DENSE TO DENSE, MOIST TO
WET) (Ova)
SAMPLE WAS COLLECTED AT 6.0 FEET
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 6.5 FEET ON 6/15/96
TEST PIT TWO
0.0 - 0.4 SM DARK BROWN SILTY FINE SAND WITH SOME ORGANICS (LOOSE TO MEDIUM
DENSE, WET)
0.4 - 4.0 SP-SM GRAY -BROWN FINE SAND WITH SILT AND ORGANICS (MEDIUM DENSE, MOIST
TO WET) (Ova)
SAMPLES WERE NOT COLLECTED
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 4.0 FEET ON 6/15/96
TEST PIT THREE
0.0 - 0.2 TOPSOIL
0.2 - 2.0 SP LIGHT BROWN FINE SAND (MEDIUM DENSE TO DENSE, MOIST) (FILL1
2.0 - 3.5 SP-SM/SM BROWN TO DARK BROWN FINE SAND WITH SILT TO SILTY FINE SAND (LOOSE
TO MEDIUM DENSE, MOIST) (OLD TOPSOIL)
3.5 - 5.0 SP LIGHT BROWN FINE SAND (MEDIUM DENSE TO DENSE, MOIST TO WET) (Ova)
SAMPLES WERE NOT COLLECTED
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 5.0 FEET ON 6/15/96
TEST PIT FOUR
0.0 - 0.2 TOPSOIL
0.2 - 2.0 SP-SM BROWN TO DARK BROWN FINE SAND WITH SILT AND SOME ORGANICS
(MEDIUM DENSE, MOIST) (TOPSOIUQva)
2.0 - 4.0 SP • LIGHT BROWN TO BROWN FINE SAND (MEDIUM DENSE, MOIST) (Ova)
SAMPLES WERE COLLECTED AT 1.5 AND 4.0 FEET
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 4.0 FEET ON 6/15/96
NELSON-COUVRETTE & ASSOCIATES, INC.
FILE NO. 178096
FIGURE 4
LOG OF EXPLORATION
DEPTH USC SOIL DESCRIPTION
TEST PIT FIVE
0.0 - 0.4
0.4 - 4.0
TEST PIT SIX
0.0 - 0.5
0.5 - 4.0
TEST PIT SEVEN
0.0 - 0.5
0.5 - 2.0
2.0 - 7.5
TEST PIT EIGHT
0.0 - 0.4
0.4 - 3.0
3.0 - 5.5
TOPSOIL
SP LIGHT BROWN WITH SLIGHT RUST STAINING FINE SAND WITH TRACE SILT
(MEDIUM DENSE TO DENSE, MOIST) (Ova)
SAMPLES WERE NOT COLLECTED
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 4.0 FEET ON 6/15/96
TOPSOIL
SP-SM LIGHT BROWN TO BROWN FINE SAND WITH SILT (MEDIUM DENSE TO DENSE,
MOIST TO WET) (Ova)
SAMPLES WERE COLLECTED FROM 3.0 - 4.0 FEET
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 4.0 FEET ON 6/15/96
TOPSOIL
SP-SM/SM BROWN TO RED -BROWN FINE SAND WITH SILT TO SILTY FINE SAND (MEDIUM
DENSE, MOIST) (WEATHERED Ova)
SP LIGHT BROWN TO BROWN FINE SAND WITH TRACE SILT (MEDIUM DENSE TO
DENSE, MOIST) (Ova)
SAMPLE WAS COLLECTED AT 6.0 FEET
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST.PIT WAS COMPLETED AT 7.5 FEET ON 6115/96
TOPSOIL
SP-SM TAN -BROWN FINE SAND WITH SILT (MEDIUM DENSE, MOIST TO WET)
(WEATHERED Ova)
SP-SM GRAY -BROWN FINE TO MEDIUM SAND WITH SILT (MEDIUM DENSE TO DENSE,
MOIST TO WET) (Ova)
SAMPLES WERE COLLECTED FROM 4.0 - 5.0 FEET
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 5.5 FEET ON 6/15/96
NELSON-COUVRETTE & ASSOCIATES, INC.
FILE NO. 178096
FIGURE 5
LOG OF EXPLORATION
DEPTH USC SOIL DESCRIPTION
TEST PIT NINE
0.0 - 0.7 TOPSOIL
0.7 - 4.0. SM/SP-SM BROWN TO DARK BROWN SILTY FINE SAND TO FINE SAND WITH SILT,
ORGANICS AND A BOTTLE (LOOSE, MOIST) Fj ILL)
4.0 - 5.0 SP-SM BROWN FINE SAND WITH SILT (MEDIUM DENSE, MOIST) (Qva)
SAMPLES WERE NOT'COLLECTED
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 5.0 FEET ON 6/15/96
TEST PIT TEN
0.0 - 0.8 TOPSOIL
0.8 - 4.0 SP-SM RED -BROWN TO LIGHT BROWN FINE SAND WITH SILT AND OCCASIONAL
COBBLES (MEDIUM DENSE TO DENSE, MOIST TO WET) (Qva)
SAMPLES WERE NOT COLLECTED
GROUND WATER SEEPAGE WAS NOT ENCOUNTERED
TEST PIT CAVING WAS NOT ENCOUNTERED
TEST PIT WAS COMPLETED AT 4.0 FEET ON 6/15/96
NELSON-COUVRETTE & ASSOCIATES, INC.
FILE NO. 178096
FIGURE 6
PLANNING DATA
NAME: & *�6m
SITE ADDRESS: /per OVp DATE: �8
ZONING: F-S I2 PLAN CHK#: 9� - 7✓
PROJECT DESCRIPTION:_�� j�f f off' 5- 95 - -20y.
CORNER LOT (Yes/No) FLAG LOT 1W (Yes/No)
SETBACKS:
Required Setbacks:
Front: �" Left Side:" ZO Right Side: Id Rear:
Actual Setbacks:
Front:�Left Side:2,1Right Side: 10 Rear . A
Street map checked for additional setback required? (Yes/No)
LEGAL NONCONFORMING LAND USE DETERMINATION ISSUED (Y/N)
LOT COVERAGE: 2/�,� e�
Maximum Allowed: o A al: A n
BUILDING HEIGHT: °
Maximum Allowed: �d'1 S Actual Hei9 ht: ktr, S
Datum Point: Na4" Datum Elevation: 17 (5, y`i
A.D.U. CREATED?: ND
SUBDIVISION: UUVWydW41i SW/- � 5-- ZO 1-
CRITICAL AREAS #: 95 � 21-
SEPA DETERMINATION: NIA
LOT AREA: `'5r 0
v
OTHER:
c:uue3spertn1trp1anaaL000
I
17311-135th Avenue NE, A-500
Woodinville, WA 98072
(425) 486-1669 • Fax 481-2510
November 24, 1997
City of Edmonds
Planning Department
250 — Sth Avenue
Edmonds, Washington 98020
Supplemental Letter
Four Lot Short Plat
Edmonds, Washington
NCA File No. 178096
Dear Sirs:
NELSON-COUVRETTE & ASSOCIATES, INC.
CONSULTING GEOTECHNICAL ENGINEERS, GEOLOGISTS
AND ENVIRONMENTAL SCIENTISTS
Snohomish County (425) 337-1669
Wenatchee/Chelan (509) 784-2756
STREET FILE
This is a supplemental letter to our preliminary geological investigation letter for this site,'dated July 11,
1996 (NCA File No 178096). The purpose of this letter is to clarify our use of the term "buffer zone" in
the Building Setback subsection of our report. We have been requested to provide this clarification by
Jeff Vehrs of the Emerald Coast Group.
In our report, we recommended a minimum building setback of 10 feet for structures on Lots 3 and 4, to
establish a "buffer zone" between dwelling areas and the slope margin. We did not intend the word
"buffer" to be used as referenced and defined by the City of Edmonds in their Development Code. We
understand that these definitions were provided in the new code which was enacted after our report was
prepared. The City of Edmonds defines "buffer" as the area immediately next to and part of a steep
slope. The buffer is intended to protect the stability of the slope. A 15-foot setback is required from the
edge of the buffer.
The topographic map provided corresponds with our field measurements taken at the time of our
explorations. The topographic map of the steep slope area shows that the slope the maximum slope
Supplemental Letter
Edmonds Short Plat
November 24, 1997
NCA File No. 178096
Page 2
inclination is about 58 percent for a total height of 8 to 10 feet. The portion of the slope with an average
slope above 40 percent is less than 20 feet in vertical height. Therefore, this slope does not qualify as a
steep slope hazard area under the City of Edmonds Code. It is our opinion that a building setback of 10
feet from the toe of the slope is appropriate. This allows for maintenance of the area in the event a
slough event occurs. The term "buffer" used in our original report was not intended to be used as
defined in the code, but was intended to be used as a setback of the structure from the toe of the slope. In
the event that the steep slope hazard is still applied, it is our opinion that moving the buffer onto the
slope and having the standard building setback start at the toe of the slope would be appropriate.
We trust this letter provides you with the information you requested and appreciate the opportunity to be
of continued service to you on this project. If you have any questions concerning this letter, do not
hesitate to call.
Sincerely,
NELSON-COUVRETTE & ASSOCIATES, INC.
Charles P. Couvrette, PE
Principal Engineer
LMH:CPC:nt
Three Copies Submitted
NELSON-COUVRETTE & ASSOCIATES, INC.
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STREET FILE
CITY OF EDMONDS
CONSTRUCTION PERMIT APPL
OWNPNAM /NE OF �ISINES
NAME
ADDRESS }
CITY
NAME
)
4.
ADDRESS q
CITY
r
USE PERMIT
ZONE ! 8y''+�/0 4
..- NUMBER L,/f�-,:f�'
TION roe i
ONENUMBER
NUMBER
W/ C-
ZIP. ITELEPHONE NUM
ST TE LICENSE NUMBER PIRA
Tom ,06, -t� f
Legal Description of Property - include all easements'
Z 0 T— r
a
Lu
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furl
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Property
Tax Account) f
ADDRESS / T
-- PIL)IC-
a
-EGAL DESCRIPTION CHECK
SUBDIVISION NO.
LID NO-
S 9t5 - zcfz
N/A
PUBLIC RIGHT OF WAY PER OFFICIAL STREET MAP.
EXISTING 10' REQUIRED DEDICATION _
TESCP Approved ❑
RW Permit Required ❑
Street Use Permit Req'd
PROPOSED F✓T �f1
Inspection Required ❑
Sidewalk Required ❑
cc
M T R SIZE
LINE SIZE
NO. OF FIXTURES
PRV REQUIRED Q
"/ „
YES NO ❑ 3
0
TEMARKS Z
till 1 Z IA1 j Z F-C,.2 (� - /= ���iI�TQ 1% Ei�GSr[ , Z
• .q%
DATED REVJEN/FD BY
VARIANCE OR CU ADB It SHORELINE q
SEPA REVIEW SIGN AREA HEIGHT
COMPLETE I EXEMPT ALLOWED I PROPOSED ALLOWED PROPOSED
EXP � - t�
LOT COVERAGE fY �JY�jfREQUIREDSETBACKS
ETBACKS (Fr.) PROPOSED SETBACKS (FT)
ALL IPROPOSED FRONTDE REAR
I//5_/J/o5-I0
Parcel Na ,, �`_^ ' t j) ! / _f _� " •-
% ( r
NRLI EW
ADDITION
REMODEL
REPAIR
❑
® RESIDENTIAL
COMMERCIAL
APT. BLDG.
j GR 'DyN
CYDS.
WOODSTOVE
♦
PLUMBING/MECH
COMPLIANCE OR
CI CHANGE OF USE
SIGN
FENCE
(x_FT►
SWIM POOL
REMARKS
CHECKED BY
TYPE
SPECIAL INSPECTOR
DEMOLISH L_j INSERT HOT TUB/SPA Z 6,77 %�L4-07'
CARPORT ROCKERY
REQUIRED ❑ YES
'M 7
`® CGARAGE RETAINING WALL/
RENEWAL REMARKS
(TYPE OF USE, BUSINESS OR ACTI •ITY) EXPLAIN:
U¢
W NUMBER
NUMBER OF
CRITICAL
O OF
R
DWELLING (
AREAS qr-
m STORIES
UNITS rrr
NUMBER 1 j
DESCRIBE W046 TO BE DONE (gTT.QCH PLq`r PLAN)
J: = "
PROGRESS INSPECTIONS PER. UBC 108
FINAL INSPECTION REQUIRED
VALUATION FEE
OCCUPANT
LOAD
PLAN CHECK FEE
-
BUILDING
HEAT SOURCE:
GLAZING
fC�1
PLUMBING
Plan Check No. o
MECHANICAL
GRADINGIFILL
This Permit covers work to be done on private properly ONLY.
Any construction on the public domain (curbs, sidewalks,
driveways, marquees, etc.) will require separate permission.
STATE SURCHARGE
Permit Application: 180 Days
Permit Limit: 1 Year - Provided Work Is Started Within 180 Days
STORM DRAINAGE FEE
i
"Applicant, on behalf of his or her spouse, heirs, assigns and
ENG. INSPECTION FEE
0—
,n
successors in interest, agrees to indemnify, defend and hold
w
harmless the City of. Edmonds, Washington, its officials,
I
employees, and agents from any and all claims for damages of
a
z
whatever nature, arising directly or indirectly from the issuance
be deemed to
PLAN CHECK DEPOSIT
q-
of this permit. Issuance of this permit shall not
�.
omodify,
waive or reduce any requirement of any city ordinance
=
nor Iimit In any way the City's ability to enforce any ordinance
TOTAL AMOUNT DUE
provision."
I hereby acknowledge tfiat I have read this application; that the
informationgiven is coirect; and that I am the owner, or the duly
ATTENTION
APPLICATION APPROVAL
authorized agent of the -owner. I agree_to comply with city and
state laws regulating construction; and in doing the work authoriz-
THIS PERMIT
AUTHORIZES
This application is not a permit until
ed thereby, no person will be employed in violation of the Labor
ONLY THE
signed by the Building Official or his/her
Code of ttte State of Washington relating to Workmen's Compensa-
WORK NOTED
Deputy; and fees are paid, and receipt is
tion Insur nce aria RCW 18.27.
INSPECTION
acknowledged in space provided.
SIGNAT7E ( WNER OR GENT) DATE S GNE
e^
DEPARTMENT
CITY OF
OFFI ?1 'S ATURE D TE
r
EDMONDS
�-
UA
CALL FOR
RELEASE6. D
ATTENTION
INSPECTION
-
IT IS UNLAWFUL TO USE OR OCCUPY A BUILDING OR STRUCTURE
UNTIL A FINAL INSPECTION HAS BEEN MADE AND APPROVAL OR
O�wO
7711
ORIGINAL — File YELLOW Inspector
A CERTIFICATE OF OCCUPANCY HAS BEEN GRANTED. UBC
—
SECTION 109
3141,
PINK — Owner GOLD — Assessor