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DEVELOPMENT ENGINEERING, PLLC
P.O. Box 446
Tacoma, WA 98401
Ph (253) 228-0513
www.de-civil.com
September 7, 2017
Schneider Homes, Inc.
6510 Southcenter Blvd #1
Tukwila, WA 98188
Attn: Mr. Harry Schneider
Geologic Assessment Report
Proposed Short Plat
7XX S 21st Street
Renton, Washington
PN: 7222000110
Job: 17-166 Schneider.GR
INTRODUCTION
This letter and design report presents the results of our subsurface explorations for the proposed short
plat to be located at 7XX S 21st Street in the City of Renton, Washington. The general location of the
site is shown on the attached Site Vicinity Map, Figure 1.
Our understanding of the project is based on our discussions with yourself, our September 4, 2017 site
visit, and our experience in the area. We understand that you are proposing to subdivide the property
into 3 lots in order to construct new residences on each of the sites. We anticipate that the proposed
residence(s) will be a constructed with conventional wood-framing, supported on spread and
continuous foundations.
SCOPE
We understand that the City of Renton is requesting a geotechnical report to address stormwater
management and other design issues related to the site development. The purpose of our services is to
evaluate the surface and subsurface conditions at the site as a basis for providing engineering
recommendations for the development of the site. Specifically, our scope of services for the project
included the following:
1. Reviewing the available geologic, hydrogeologic and geotechnical data for the site area.
2. Performing a geological reconnaissance of the site to assess the site’s soil, groundwater and
subsurface conditions.
3. Exploring shallow subsurface conditions at the site by monitoring the excavation of two test pits
across the site.
4. Evaluating the engineering characteristics of the soils encountered at the site, as appropriate.
5. Providing geotechnical recommendations for site infiltration site grading including site
preparation, subgrade reparation, fill placement criteria, suitability of on-site soils for use as
structural fill, temporary and permanent cut and fill slopes, drainage and erosion control
measures.
6. Providing site-specific seismic criteria based on the subsurface conditions encountered at the
site.
7. Preparing a written report summarizing our observations, conclusions and recommendations
along with the supporting data.
Subsurface explorations or laboratory testing were completed as part of this assessment.
17-166 Schneider.GR
September 7, 2017
Page 2
SITE CONDITIONS
Surface Conditions
The subject parcel is located at 7XX S 21st Street in the City of Renton, Washington. The site consists of
a single parcel that is rectangular in shape, approximately 290 feet in length (west to east) by 70 feet in
width (north to South) and encompasses an area of approximately 0.46 acres. The site is an existing lot
of record that is currently undeveloped and is well vegetated with trees, grasses and brush. Access to
the site will be from a private driveway from S 21st Street, see Figure 2 Site Plan.
The parcel is nearly level with a slight slope to the north, site grades are generally less than 5 percent
with less than 5 feet of elevation change across the lot. No surface water or seepage was observed on
the site at the time of our first site visit, however we did observe signs of a potentially high
groundwater in the upper soils of the site, see below for more information. No evidence of erosion,
soil movement, landslide activity or deep-seated slope instability was observed at the site or within
300 feet of the site at the time of our site visit.
Site Soils
The USDA Natural Resource Conservation Service Web Soil Survey for King County mapped the soils in
the area of the site as Beausite gravelly sandy loam (BeC). The Beausite soils are a gravelly sandy loam,
formed from glacial deposits overlying sandstone bedrock on slopes of 6 to 15 percent slope and are
listed as having a “moderate” erosion potential, see Figure 3 USDA Soil Map.
Site Geology
The Geological Map of the Renton Quadrangle, King County, Washington by D. R. Mullineaux, 1965
indicates the site is underlain by glacial till (Qvt). These glacial soils were deposited during the latest
stage of the most recent Vashon Stade of the Fraser Glaciation, approximately 12,000 to 15,000 years
ago. These soils are characterized as mix of silt, sand with gravel which were overridden by the glacial ice.
As such, these soils are generally very dense exhibiting high strength and low compressibility
characteristics. An excerpt of the above referenced map is included as Figure 4.
Based on our site observations the near surface soils at the site are most consistent with the USDA
mapped soils.
Subsurface Explorations
On September 4, 2017 we visited the site and observed the excavation of three test pits to a maximum
depth of 6 feet for the purpose of determining infiltration feasibility for the project, soil samples were
collected for later analysis in our lab. The test pits were excavated by a track mounted excavator
operated by a licensed earthwork contractor. The test pits were located in the field by our
representative by pacing from existing site features such as property corners and adjacent roadways
and fences. The approximate location of the test pits are indicated on the attached Site Plan as
Figure 2.
A geotechnical engineer from our office logged the subsurface conditions encountered in each test pit,
obtained representative soil samples, and observed pertinent site features. Representative soil
samples obtained from the test pits were placed in sealed plastic bags and taken to our laboratory for
further examination and testing, as deemed appropriate.
Based on our experience in the area and extent of our explorations in the area it is our opinion that the
soils encountered in the test pits are generally representative of the soils at the site.
17-166 Schneider.GR
September 7, 2017
Page 3
Because the soils encountered were consistent between the test sites and other exposed site soils and
the soil mapping, it is our opinion that no additional soils tests required to evaluate the subsurface
conditions at the site.
The explorations performed as part of this evaluation indicate conditions only at the specific locations
and that the actual condition in other locations could vary. Furthermore, the nature and extent of any
such variations would not become evident until additional explorations are performed or until
construction activities have begun.
Subsurface Conditions
Our test pits encountered uniform subsurface conditions that confirmed the general geological
mapping stratigraphy. The site soils generally consisted of a minimum of 24 to 36 inches of weathered
silty sand and gravel over a dense sandstone layer. Test pit #2 showed signs of a shallow fill layer
(approximately 12 to 18 inches). Based on our review of our test pits, the upper weathered site soils in
the area of development are consistent with the Beausite soils. The soils encountered were visually
classified in accordance with the Unified Soil Classification System (USCS) described on Figure 5. The
test pit logs are included as Figures 6.
Groundwater Conditions
No groundwater seepage was observed in any of the test pits. Although based on our observations we
anticipate that during periods of heavy rainfall the upper soils would become saturated. Perched
groundwater typically develops when the vertical infiltration of precipitation through a more
permeable soil is slowed at depth by a deeper, less permeable soil type. We expect that perched
groundwater will develop seasonally atop the shallow sandstone layer. Based on the observed mottling
and nature of the near surface soils, we anticipate fluctuations in the local groundwater levels will
occur in response to precipitation patterns, off-site construction activities, and site utilization.
CONCLUSIONS
Based on our site observations, subsurface explorations and engineering analysis, it is our opinion that
the proposed development is feasible from a geotechnical standpoint.
The residences may be supported on new conventional spread footings or floor slabs bearing on
competent native soils or on structural fill placed above these native soils. We understand that grading
at the site will be minimal, and will consist primarily of excavating the footings for the proposed
residence(s), site utilities, and the stormwater facilities. If grading activities will take place during the
winter season, the owner should be prepared to import free-draining granular material for use as
structural fill and backfill. Proper surface drainage and erosion control measures will reduce the risk
for future erosion at the site.
Site Preparation
Areas to be graded should be cleared of deleterious matter including any existing structures,
foundations, abandoned utility lines, debris and vegetation. The portions of the site covered with
vegetation should be stripped of any forest duff and organic-laden soils. Based on our test pits we
anticipate stripping depths to be on the order of 6 to 18 inches. These materials can be stockpiled and
later used for erosion control. Material that cannot be utilized on the site should be removed from the
site.
Where placement of fill material is required, the stripped/exposed subgrade areas should be
compacted to a firm and unyielding surface prior to placement of any fill. Excavations for debris
17-166 Schneider.GR
September 7, 2017
Page 4
removal should be backfilled with structural fill compacted to the densities described in the “Structural
Fill” section of this report.
We recommend that a member of our staff evaluate the exposed subgrade conditions after removal of
vegetation and topsoil stripping is completed and prior to placement of structural fill. The exposed
subgrade soil should be proof-rolled with heavy rubber-tired equipment during dry weather or probed
with a 1/2-inch-diameter steel rod during wet weather conditions.
Any soft, loose or otherwise unsuitable areas delineated during proof-rolling or probing should be
recompacted, if practical, or over-excavated and replaced with structural fill, based on the
recommendations of our site representative. The areas of old fill material should be evaluated during
grading operations to determine if they need mitigation; recompaction or removal.
Structural Fill
All material placed as fill associated with mass grading, as utility trench backfill, under building areas,
or under asphalt pavement should be placed as structural fill. The structural fill should be placed in
horizontal lifts of appropriate thickness to allow adequate and uniform compaction of each lift. Fill
should be compacted to at least 95 percent of MDD (maximum dry density as determined in
accordance with ASTM D-1557).
The appropriate lift thickness will depend on the fill characteristics and compaction equipment used.
We recommend that the appropriate lift thickness be evaluated by our field representative during
construction. We recommend that our representative be present during site grading activities to
observe the work and perform field density tests.
The suitability of material for use as structural fill will depend on the gradation and moisture content of
the soil. As the amount of fines (material passing US No. 200 sieve) increases, soil becomes
increasingly sensitive to small changes in moisture content and adequate compaction becomes more
difficult to achieve. During wet weather, we recommend use of well-graded sand and gravel with less
than 5 percent (by weight) passing the US No. 200 sieve based on that fraction passing the 3/4-inch
sieve, such as Gravel Backfill for Walls (9-03.12(2)). If prolonged dry weather prevails during the
earthwork and foundation installation phase of construction, higher fines content (up to 10 to
12 percent) will be acceptable. Material placed for structural fill should be free of debris, organic
matter, trash and cobbles greater than 6-inches in diameter. The moisture content of the fill material
should be adjusted as necessary for proper compaction.
Suitability of On-Site Materials as Fill
During dry weather construction, any non-organic on-site soil may be considered for use as structural
fill; provided it meets the criteria described above in the structural fill section and can be compacted as
recommended. If the soil material is over-optimum in moisture content when excavated, it will be
necessary to aerate or dry the soil prior to placement as structural fill. We generally did not observe
the site soils to be excessively moist at the time of our subsurface exploration program.
The native weathered and glacial till soils in the site generally consisted of silty gravel with fine sand.
These soils are generally comparable to “common borrow” material and will be suitable for use as
structural fill provided the moisture content is maintained within 3 percent of the optimum moisture
level. However, because of the high fines content, the till soils encountered across the site will likely
be unsuitable during extended periods of wet weather.
We recommend that completed graded-areas be restricted from traffic or protected prior to wet
weather conditions. The graded areas may be protected by paving, placing asphalt-treated base, a
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September 7, 2017
Page 5
layer of free-draining material such as pit run sand and gravel or clean crushed rock material
containing less than 5 percent fines, or some combination of the above.
Temporary Excavations
All job site safety issues and precautions are the responsibility of the contractor providing
services/work. The following cut/fill slope guidelines are provided for planning purposes only.
Temporary cut slopes will likely be necessary during grading operations or utility installation.
All excavations at the site associated with confined spaces, such as utility trenches and retaining walls,
must be completed in accordance with local, state, or federal requirements. Based on current
Washington Industrial Safety and Health Act (WISHA, WAC 296-155-66401) regulations, the shallow
upper soils on the site would be classified as Type C soils, whereas the very dense sandstone soils
would be classified as Type A soils.
According to WISHA, for temporary excavations of less than 20 feet in depth, the side slopes in Type A
soils should be laid back at a slope inclination of ¾H:1V (Horizontal: Vertical) and Type C soils should be
laid back at a slope inclination of 1½H:1V or flatter from the toe to the crest of the slope. It should be
recognized that slopes of this nature do ravel and require occasional maintenance. All exposed slope
faces should be covered with a durable reinforced plastic membrane, jute matting, or other erosion
control mats during construction to prevent slope raveling and rutting during periods of precipitation.
These guidelines assume that all surface loads are kept at a minimum distance of at least one half the
depth of the cut away from the top of the slope and that significant seepage is not present on the
slope face. Flatter cut slopes will be necessary where significant raveling or seepage occurs, or if
construction materials will be stockpiled along the slope crest.
Where it is not feasible to slope the site soils back at these inclinations, a retaining structure should be
considered. Where retaining structures are greater than 4-feet in height (bottom of footing to top of
structure) or have slopes of greater than 15 percent above them, they should be engineered.
This information is provided solely for the benefit of the owner and other design consultants, and
should not be construed to imply that Development Engineering, PLLC assumes responsibility for job
site safety. It is understood that job site safety is the sole responsibility of the project contractor.
Foundation Support
Based on the subsurface soil conditions encountered across the site, we recommend that spread
footings for the new residences be founded on dense to very dense native soils or on structural fill that
extends to suitable native soils. Given the presence of fill material on the site it is anticipated that
some footings may be located in areas where existing fill material is present. Provided the exposed
soils area evaluated and verified by a representative from our office at time of construction to be
suitable to support the design loads we do not anticipate that the presence of the fill material on site
will be a detrimental factor to the site development.
We do not recommend that footings be supported on a mix of sandstone and weathered material. If
areas of sandstone are exposed we recommend that those areas are over excavated a minimum of 12
inches and brought back to grade with structural fill.
The soil at the base of the footing excavations should be disturbed as little as possible. All loose, soft
or unsuitable material should be removed or recompacted, as appropriate. A representative from our
firm should observe the foundation excavations to determine if suitable bearing surfaces have been
prepared, particularly in the areas where the foundation will be situated on fill material.
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September 7, 2017
Page 6
We recommend a minimum width of 2 feet for isolated footings and at least 16 inches for continuous
wall footings. All footing elements should be embedded at least 18 inches below grade for frost
protection. Footings founded as described above can be designed using an allowable soil bearing
capacity of 2,000psf (pounds per square foot) for combined dead and long-term live loads. For deeper
footings supported entirely on the sandstone a bearing capacity of 5,000psf may be used. The weight
of the footing and any overlying backfill may be neglected. The allowable bearing value may be
increased by one-third for transient loads such as those induced by seismic events or wind loads.
Lateral loads may be resisted by friction on the base of footings and floor slabs and as passive pressure
on the sides of footings. We recommend that an allowable coefficient of friction of 0.40 be used to
calculate friction between the concrete and the underlying soil. Passive pressure may be determined
using an allowable equivalent fluid density of 300 pcf (pounds per cubic foot). Factors of safety have
been applied to these values.
We estimate that settlements of footings designed and constructed as recommended will be less than
1 inch, for the anticipated load conditions, with differential settlements between comparably loaded
footings of 1/2 inch or less. Most of the settlements should occur essentially as loads are being
applied. However, disturbance of the foundation subgrade during construction could result in larger
settlements than predicted.
Floor Slab Support
Slabs-on-grade, if constructed, should be supported on the medium dense native soils or on structural
fill prepared as described above. Any areas of old fill material should be evaluated during grading
activity for suitability of structural support. Areas of significant organic debris should be removed.
We recommend that floor slabs be directly underlain by a capillary break material with minimum 6-
inch thickness of coarse sand, pea gravel, or gravel containing less than 3 percent fines. The drainage
material should be placed in one lift and compacted to an unyielding condition.
A synthetic vapor barrier is recommended to control moisture migration through the slabs. This is of
particular importance where the foundation elements are underlain by the silty till, or where moisture
migration through the slab is an issue, such as where adhesives are used to anchor carpet or tile to the
slab.
A subgrade modulus of 400 kcf (kips per cubic foot) may be used for floor slab design. We estimate
that settlement of the floor slabs designed and constructed as recommended, will be 1/2 inch or less
over a span of 50 feet.
Site Drainage
All ground surfaces, pavements and sidewalks at the site should be sloped away from structures. The
lot should also be carefully graded to ensure positive drainage away from all structures and property
lines. Surface water runoff from the roof area, driveways, perimeter footing drains, and wall drains,
should be collected, tightlined, and conveyed to an appropriate discharge point.
Based on our site evaluation, it is our opinion that the infiltration of stormwater at the site not feasible
on the site. Further, based on our understanding of the current City of Renton Stormwater
Management Manual, it will likely be necessary to visit the site and perform additional explorations
and possibly at least one full scale “Pilot Infiltration Test” (PIT) between December 1 and April 30
(winter months) in order to determine seasonal groundwater levels and infiltration feasibility. Since
our field final work was done in early Suptember we recommend that we revisit our Site Drainage
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September 7, 2017
Page 7
recommendations once this additional field work is complete. For preliminary design purposes we are
not recommending that infiltration be pursued.
LID Feasibility
The following table presents our recommendations for various Best Management Practices (BMP’s) for
various Low Impact Development (LID) BMP’s.
BMP Viable Limitations or Infeasibility Criteria
Lawn and Landscape Areas
T5.13: Post Construction Soil Quality
and Depth
Yes None.
Roofs
T5.30: Full Dispersion No The site does not have sufficient dispersion area.
T5.10A: Downspout full infiltration
systems.
No Infiltration appears to be infeasible due to a high
groundwater table.
Bio Retention No This BMP also has limited feasibility for the same
general reasons as for full infiltration.
T5.10B Downspout Dispersion
systems
Limited This BMP may be feasible depending on final lot
configurations.
T5.10C Perforate stub connections Limited Similar to the infiltration systems there will be
limited depths of soil for the connection to ensure
that it is at least 1 foot above the till layers.
Other Hard Surfaces
T5.30 Full Dispersion No The site does not have sufficient dispersion area.
T5.15 Permeable Surfacing No The soils in the areas of the proposed pavement
included a very shallow groundwater depth which
does not allow for the required 12 inches of
separation between the bottom of the pavement
section and the groundwater. Further, given the
silty nature of the site soils, permeable surfacing
would not be sufficiently supported and would
likely fail in a short period of time.
Bio Retention No This BMP also has limited feasibility for the same
general reasons as for full infiltration.
T5.12: Sheet Flow Dispersion
T5.11 Concentrated flow dispersion
Limited No flooding or erosion impacts are anticipated.
However, this BMP may be feasible dependent on
the final lot configurations and the available areas
for dispersion of runoff.
LIMITATIONS
We have prepared this report for Schneider Homes, Inc, and other members of the design team for use
in evaluating a portion of this project. Subsurface conditions described herein are based on our
observations of exposed soils on the parcel. This report may be made available to regulatory agencies
or others, but this report and conclusions should not be construed as a warranty of subsurface
conditions. Subsurface conditions can vary over short distances and can change with time.
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September 7, 2017
Page 8
Within the limitations of scope, schedule and budget, our services have been executed in accordance
with generally accepted practices in this area at the time this report was prepared. No warranty,
express or implied, should be understood.
We trust this is sufficient for your current needs. Should you have any questions, or require additional
information, please contact us at your earliest convenience.
Respectfully submitted,
Development Engineering, PLLC
Glen Coad, PE
Owner
WGC
DocID:17-166 Schneider.GR
Attachments: Figure 1: Vicinity Map
Figure 2: Site Plan
Figure 3: SCS Soil Survey
Figure 4: USGS Geology Map
Figure 5: Soils Classification Chart
Figure 6: Test Pit Logs
Approximate Site Location
Not to Scale
DE-CIVIL, PLLC
P.O. Box 446
Tacoma, WA 98401
Ph (253) 228-0513
www.de-civil.com
Site Vicinity Map
Schneider SP
7XX S 21st Street
Renton County, Washington
Job No: 17-166 September 2017 Figure 1
DEVELOPMENT
ENGINEERING, PLLC
P.O. Box 446
Tacoma, WA 98401
Ph (253) 228-0513
www.de-civil.com
Approximate Test Pit Location
Site Plan
Schneider SP
7XX S 21st Street
Renton County, Washington
Job No: 17-166 September 2017 Figure 2
TP-1
TP-2
TP-3
TP-1
Approximate Site Location
Not to Scale
DE-CIVIL, PLLC
P.O. Box 446
Tacoma, WA 98401
Ph (253) 228-0513
www.de-civil.com
USDA Web Soil Survey
Schneider SP
7XX S 21st Street
Renton County, Washington
Job No: 17-166 September 2017 Figure 3
Approximate Site Location
Not to Scale
DE-CIVIL, PLLC
P.O. Box 446
Tacoma, WA 98401
Ph (253) 228-0513
www.de-civil.com
USGS Geologic Map
Schneider SP
7XX S 21st Street
Renton County, Washington
Job No: 17-166 September 2017 Figure 4
DEVELOPMENT
ENGINEERING, PLLC
P.O. Box 446
Tacoma, WA 98401
Ph (253) 228-0513
www.de-civil.com
Soil Classification Chart
Schneider SP
7XX S 21st Street
Renton County, Washington
Job No: 17-166 September 2017 Figure 5
`
Test Pit TP-1
Location: (See Figure 2)
Depth (ft.) Soil Type Description
0 – 0.5 Topsoil
0.5 – 5.0 SM Brown silty sand and gravel (cemented, dense)
5.0 – 6.0 Tan Sandstone (fractured)
Terminated at 6.0 feet below ground surface.
No caving observed. Evidence of seasonal groundwater at 6 inches.
Test Pit TP-2
Location: (See Figure 2)
Depth (ft.) Soil Type Description
0 – 1.0 Brown silty SAND with gravel Fill (asphalt and concrete debris)
1.0 – 2.5 SM Brown silty SAND w/ gravel, (weakly cemented, dense)
2.5 – 7.0 ML grey SILT w/sand & gravel, (stiff)
7.0 – 8.0 tan Sandstone (fractured)
Terminated at 8.0 feet below ground surface.
No caving observed. Evidence of seasonal groundwater at 12 inches.
Test Pit TP-3
Location: (See Figure 2)
Depth (ft.) Soil Type Description
0 – 0.5 Top soil
0.5 – 2.0 SM Brown silty SAND w/ gravel, (weakly cemented, dense)
2.0 – 4.5 ML grey SILT w/sand & gravel, (stiff)
4.5 – 6.0 tan Sandstone (fractured)
Terminated at 6.0 feet below ground surface.
No caving observed. Evidence of seasonal groundwater at 12 inches.
Logged by WGC, 9/4/17
DE-CIVIL, PLLC
P.O. Box 446
Tacoma, WA 98401
Ph (253) 228-0513
www.de-civil.com
Test Pit Logs
Schneider SP
7XX S 21st Street
Renton County, Washington
Job No: 17-166 September 2017 Figure 6