HomeMy WebLinkAboutMiscAssociated Earth Sciences, Inc.
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Serving tne Pacific Nortnwest Since 19B1
December 20,2013
Project No. TE130561A
Iossif Rozenblat
5415 NE 2"" Court
Renton, Washington 98509
Subject: Subsurface Exploration and Preliminary Geotechnical Engineering Report
Proposed Melrose Short Plat
186XX 108'" Avenue Southeast
Renton, Washington
Dear Mr. Rozenblat:
We are pleased to present these copies of our preliminary geotechnical engineering report for
the referenced project. This report summarizes the results of our subsurface exploration,
geologic hazards, and geotechnical engineering studies, and offers preliminary
recommendations for the design and development of the proposed project. At the time this
report was prepared, the site was in the planning stage and no detailed project plans had been
formulated. This report is based on a preliminary site layout plan titled "Melrose Short Plat"
by Beyler Consulting dated November 14,2013. We recommend that we be allowed to review
the recommendations contained in this report and modify them, if necessary, when a detailed
project plan has been developed.
We have enjoyed working with you on this study and are confident that the recommendations
presented in this report will aid in the successful completion of your project. If you should
have any questions, or if we can be of additional help to you, please do not hesitate to call.
Sincerely,
ASSOCIATED EARTH SCIENCES, INC.
Tacoma, Washington
~'M~rri~an, P.E.
Senior Principal Engineer
KDM/pc
TE130S6IA3
ProjcctsUOI30561\TE\WP
Kirkland
425-827-7701
• Everett • Tacoma
425-259-0522 253-722-2992
www.aesgeo.com
(jeotecfinica('Engineering
Water 'Resources
Environmenta( :Assessments
antI 'Remediation
Sustainalj(e 1Jeve(oyment Services
(jeo(ogic :Assessments
Associated Earth Sciences, Inc.
Serving the Pacific Northwest Since 19B1
Subsurface Exploration and
Preliminary Geotechnical Engineering Report
PROPOSED MELROSE SHORT PLAT
Renton, Washington
Prepared for
Iossif Rozenblat
Project No. TE130561A
December 20,2013
SUBSURFACE EXPLORATION AND PRELIMINARY
GEOTECHNICAL ENGINEERING REPORT
PROPOSED MELROSE SHORT PLAT
Renton, Washington
Prepared for:
Iossif Rozenblat
5415 NE 2"" Court
Renton, Washington 98509
Prepared lJy:
Associated Earth Sciences, Inc.
1552 Connnerce Street, Suite 102
Tacoma, Washington 98402
253-722-2992
Fax: 253-722-2993
December 20,2013
Project No. TE130561A
Proposed Me/rose Shorl Pial
Renton, Washington
Subsurface Exploration and Preliminary
Geotechnical Engineering Reporl
Project and Site Conditions
I. PROJECT AND SITE CONDITIONS
1.0 INTRODUCTION
This report presents the results of our subsurface exploration, geologic hazards, and
preliminary geotechnical engineering studies for the proposed new short plat. The site location
is shown on the "Vicinity Map,» Figure 1. The approximate locations of exploration pits
completed for this study are shown on the "Site and Exploration Plan,» Figure 2. Logs of the
subsurface explorations and copies of laboratory test results completed for this study are
included in the Appendix.
1.1 Purpose and Scope
The purpose of this study is to provide geotechnical engineering design recommendations to be
utilized in the preliminary design of the project. This study included a review of selected
available geologic literature, advancing three exploration pits and performing geologic studies
to assess the type, thickness, distribution, and physical properties of the subsurface sediments
and shallow ground water. Geotechnical engineering studies were completed to formulate
recommendations for site preparation, structural fill, pavement subgrade preparation, and
drainage. Based on exploration data contained in this report, on-site storm water infiltration
using conventional shallow infiltration strategies is not feasible in our opinion. This report
summarizes our fieldwork and offers preliminary geotechnical engineering recommendations
based on our present understanding of the project. We recommend that we be allowed to
review the recommendations presented in this report and revise them, if needed, when a
detailed project design has been developed.
1.2 Authorization
Authorization to proceed with this study was granted by means of a signed copy of our scope
of work and cost proposal dated November 7, 2013, This report has been prepared for the
exclusive use of Iossif Rozenblat and his agents for specific application to this project. Within
the limitations of scope, schedule, and budget, our services have been performed in accordance
with generally accepted geotechnical engineering practices in effect in this area at the time our
report was prepared. No other warranty, express or implied, is made.
2,0 PROJECT AND SITE DESCRIPTION
The project site is an undeveloped parcel between 18633 and 18647 108th Avenue Southeast in
Renton, Washington. The site is rectangnlar in plan view and overall site area is
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Proposed Melrose ShOJ1 Plat
Renton, Washington
Subsurface Exploration and Preliminary
Geotechnical Engineering Report
Pro;ect and Site Conditions
approximately 0.4 acres. Site topography generally slopes gently down from west to east, and
a rockery along the east edge of the site protects a grade transition of approximately 5 feet
descending from west to east. Overall vertical relief across the site is approximately 10 feet.
The site does not appear to include Geologic Hazard Areas as described in Remon Municipal
Code (RMC) Section 4-3-050 J with the exception of possible Erosion Hazard Areas. At the
time of our subsurface investigation, the site was undeveloped except for the existing rockery,
and covered with mature trees and moderately dense native understory plants.
3.0 SUBSURFACE EXPLORATION
Our subsurface exploration completed for this project included advancing three exploration
pits. The conclusions and recommendations presented in this report are based on the
explorations completed for this study. The locations and depths of the explorations were
completed within site and budget constraints.
3.1 Exploration Pits
The exploration pits were excavated using a tracked excavator. The pits permitted direct,
visual observation of subsurface conditions. Materials encountered in the exploration pits were
studied and classified in the field by geologists from our firm. All exploration pits were
backfilled after examination and logging. Selected samples were then transported to our
laboratory for further visual classification and testing, as necessary.
4.0 SUBSURFACE CONDITIONS
Subsurface conditions at the project site were inferred from the field explorations accomplished
for this study, visnal reconnaissance of the site, and review of selected applicable geologic
literature. Because of the nature of exploratory work below ground, extrapolation of
subsurface conditions between field explorations is necessary, It should be noted that differing
subsurface conditions may sometimes be present due to the random nature of deposition and
the alteration of topography by past grading and/or fIlling. The nature and extent of any
variations between the field explorations may not become fully evident until construction.
4.1 Stratigraphy
Surficial Topsoil
Exploration pits encountered surficial topsoil approximately 1 foot thick. Topsoil is not
suitable for structural support, and should be stripped from structural areas. Excavated topsoil
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Proposed Melrose Shon Plat
Renton, Washington
Subsurface Exploration and Preliminary
Geotechnical Engineering Repon
Project and Site Conditions
may be suitable for reuse in landscape areas if allowed by project specifications. Excavated
topsoil should be expected to swell 30 percent or more in volume between the in situ condition
and the loose condition after stripping.
Lodgement Till
Each of the exploration pits encountered native sediments consisting of medium dense grading
to very dense sand with varying silt and gravel content interpreted as Vashon lodgement till.
Lodgement till was deposited at the base of an active continental glacier and was compacted by
the weight of the overlying glacial ice. Lodgement till is suitable for structural support when
properly prepared. Excavated lodgement till material is suitable for use in structural fill
applications if suitable moisture conditions are achieVed prior to compaction and if such reuse
is specifically allowed by the owner and project documents. At the time of exploration, we
estimate that most or all of the lodgement till soils that we observed were above optimum
moisture content for compaction purposes, and therefore, will require drying during favorable
weather prior to compaction in structural fill applications.
Published Geologic Map
We reviewed a published geologic map of the area (Geologic Map of King County,
Washington, by Derek B. Booth, Kathy A. Troost, and Aaron P. Wisher, 2006). The
referenced map indicates that the site is expected to be underlain at shallow depths by
lodgement till.
4.2 Hydrology
No ground water seepage was observed in the subsurface explorations completed for this
study. Sites underlain by lodgement till often develop shallow "perched" ground water during
seasonal wet weather. Perched ground water occurs when vertical infiltration is impeded by
less-penrieable soil layers, resulting in horizontal flow. The quantity and duration of perched
ground water flow from an excavation will vary, depending on season, soil gradation, and
adjacent topography. Ground water conditions should be expected to vary in response to
changes in precipitation, on-and off-site land usage, and other factors.
4.3 Laboratory Testing
As a part of our investigation of the infiltration potential of the site soils, we completed one
laboratory grain-size analysis. A copy of the grain-size analysis report is included in the
Appendix.
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Proposed Melrose Short Plat
Renton, Washington
4.4 InfIltration Potential
Subsurface Exploration and Preliminary
Geotechnical Engineering Report
Project and Site Conditions
Native sediments at shallow depths below the site consist of lodgement till. The grain-size
analysis of lodgement till completed for this project identifIed 23-percent silt in the sample
selected for testing. The estimated density of the lodgement till ranged from medium dense
near the snrface to very dense at depth. Though the applicable storm water design standards
(2009 King County Surface Water Design Manual and 2010 City of Renton Addenda) do not
provide a quantitative method for estimating an infIltration rate based on grain-size testing, in
our experience the measured infIltration rate of lodgement till is very small, approaching zero.
We do not recommend that lodgement till be used as a storm water infIltration receptor. Other
best management practices (BMPs) such as splash blocks and storm water dispersion might be
feasible at the discretion of the project civil engineer. We do not recommend storm water
dispersal in close proximity to the existing rockery on the east side of the site. Ideally any
storm water dispersal that is planned on the east lot of the short plat should be positioned on
the west side of the proposed home on that lot.
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Proposed Melrose Short Pklt
Renton, Washington
Subsuiface Exploration and Preliminary
Geotechnical Engineering Report
Geologic Hazards and Mitigations
n. GEOLOGIC HAZARDS AND MITIGATIONS
The following discussion of potential geologic hazards is based on the geologic, slope, and
ground and surface water conditions, as observed and discussed herein. The discnssion will be
limited to slope stability, seismic, and erosion issues. The site does not appear to contain any
areas that meet City of Renton definitions for Geologic Hazard Areas as defined in RMC
Section 4-3-050 J with the exception of Erosion Hazard Areas. Individual geologic hazard
topics are discussed in further detail below.
5.0 SLOPE HAZARDS AND MITIGATIONS
Based on the plat map that was provided to us, it does not appear that any slopes on-site meet
City of Renton definitions for treatment as Steep Slope or Landslide Hazard critical areas in
our opinion. No detailed assessment of slope stability was prepared as part of this report and
none is warranted in our opinion.
6.0 SEISMIC HAZARDS AND MITIGATIONS
The site is underlain at shallow depths by unsaturated lodgement till. The site does not contain
areas that meet City of Renton definitions for Seismic Hazard areas in our opinion. A detailed
assessment of liquefaction risks was not completed, and none is warranted for the currently
proposed project in our opinion.
6.1 Surficial Ground Rupture
Generally, the largest earthquakes that have occnrred in the Puget Sound area are sub-crustal
events with epicenters ranging from 50 to 70 kilometers in depth. Earthquakes that are
generated at such depths usually do not result in fault rupture at the ground surface. Current
research indicates that surficial ground rupture is possible in areas close to the Seattle Fault
Zone, the closest mapped fault zone to the project. Although our current understanding of this
fault zone is limited and is an active area of research, the site lies approximately 2 miles south
of the currently mapped limits of the Seattle Fault Zone. Therefore, based on current
information, the risk of damage to planned improvements as a result of surface rupture due to
faulting is low, in our opinion.
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Proposed Melrose Short Plat
Renton, Washington
6.2 Ground Motion
Subsuiface Exploration and Preliminary
Geotechnical Engineering Report
Geologic Hazards and Mitigations
Structural design of the project should be in accordance with the 2012 International Building
Code (IBC) using Site Class C.
7.0 EROSION HAZARDS AND MITIGATIONS
The following discussion addresses Washington State Department of Ecology (Ecology)
erosion control regulations that will be applicable to the project. We anticipate that if the
project complies with Washington State requirements, it will also be acceptable with respect to
City of Renton requirements.
As of October 1, 2008, Ecology Construction Storm Water General Permit (also known as the
National Pollutant Discharge Elimination System [NPDES] permit) requires weekly Temporary
Erosion and Sedimentation Control (TESC) inspections, turbidity monitoring, and pH
monitoring for all sites 1 or more acres in size that discharge storm water to surface waters of
the state. Because the proposed project will not require disturbance of more than 1 acre, we
anticipate that these inspection and reporting requirements will not be triggered. The following
recommendations are related to general erosion potential and mitigation.
The erosion potential of the site soils is high. Maintaining cover measures atop disturbed
ground typically provides the greatest reduction to the potential generation of turbid runoff and
sediment transport. During the local wet season (October 1" through March 31"), exposed soil
should not remain uncovered for more than 2 days unless it is actively being worked.
Ground-cover measures can include erosion control matting, plastic sheeting, straw mulch,
crushed rock or recycled concrete, or mature hydroseed.
Project planning and construction should follow local standards of practice with respect to
temporary erosion and sedimentation control. BMPs should include but not be limited to:
• Provide storm drain inlet protection;
• Route surface water away from work areas;
• Keep staging areas and travel areas clean and free of track-out;
• Cover work areas and stockpiled soils when not in use;
• Complete earthwork during dry weather and site conditions, if possible.
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Proposed Melrose Short Plat
Renlon, Washington
Subsuiface Exploration and Preliminary
Geotechnical Engineering Report
Preliminary Design Recommendations
m. PRELIMINARY DESIGN RECOMMENDATIONS
8.0 INTRODUCTION
The site is underlain at shallow depths by lodgement till that is suitable for structural support
with proper preparation. Lodgement till is silty and sensitive to moisture contents above
optimum for compaction purposes. Careful preparation and protection of lodgement till
bearing surfaces will reduce the potential that remedial preparation will be needed. Aeration
and drying of excavated lodgement till sediments is expected to be needed before they can be
reused in compacted fill applications. Reuse of excavated lodgement till in structural fill
applications is permitted only if explicitly allowed by the owner and project documents.
9.0 SITE PREPARATION
Erosion and surface water control should be established around the clearing limits to satisfy
local requirements. We are not aware of any existing structures or buried utilities on-site. If
any exist they should be removed where they are located below planned construction areas.
All disturbed soils resulting from demolition activities should be removed to expose underlying
undisturbed native sediments and replaced with structural fill, as needed. All excavations
below final grade made for demolition activities should be backfilled, as needed, with
structural fill.
Existing vegetation and topsoil should be stripped, and tree stumps and roots should be
grubbed. Any materials below final grades that are disturbed by stripping and grubbing should
be removed and replaced as structural fill as defined in this report.
9.1 Site Drainage and Surface Water Control
The site should be graded to prevent water from ponding in construction areas and/or flowing
into excavations. Exposed grades should be crowned, sloped, and smooth drum-rolled at the
end of each day to facilitate drainage. Accumulated water must be removed from subgrades
and work areas immediately prior to performing further work in the area. Equipment access
may be limited, and the amount of soil rendered unfit for use as structural fill may be greatly
increased, if drainage efforts are not accomplished in a timely sequence. If an effective
drainage system is not utilized, project delays and increased costs could be incurred due to the
greater quantities of wet and unsuitable fill, or poor access and unstable conditions.
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Proposed Melrose Short Plat
Renton, Washington
9.2 Subgrade Protection
Subsurface Exploration and Preliminary
Geotechnical Engineering Report
Preliminary Design Recommendations
If construction will proceed during the winter, we recommend the use of a working surface of
sand and gravel, crushed rock, or quarry spalls to protect exposed soils, particularly in areas
supporting concentrated equipment traffic. In winter construction staging areas and areas that
will be subjected to repeated heavy loads, a minimum thickness of 12 inches of quarry spalls or
18 inches of pit run sand and gravel is recommended. If subgrade conditions are soft and silty,
a geotextile separation fabric, such as Mirafi 500X or approved equivalent, should be used
between the subgrade and the new fill.
9.3 Proof-Rolling and Subgrade Compaction
Following the recommended demolition, site stripping, and planned excavation, the stripped
sub grade within the planned building and paving areas should be compacted to 95 percent of
the modified Proctor maximum dry density and proof-rolled with heavy, rubber-tired
construction equipment, such as a fully loaded tandem-axle dump truck. Proof-rolling should
be performed prior to structural fill placement or foundation excavation. The proof-roll should
be monitored by the geotechnical engineer so that any soft or yielding subgrade soils can be
identified. Any soft/loose, yielding soils should be removed to a stable subgrade. The
sub grade should then be scarified, adjusted in moisture content, and recompacted to the
required density. Proof-rolling should only be attempted if soil moisture contents are at or
near optimum moisture content. Proof-rolling of wet subgrades could result in further
degradation. Low areas and excavations may then be raised to the planned fmished grade with
compacted structural fill. Subgrade preparation and selection, placement, and compaction of
structural fIll should be performed under engineering-controlled conditions in accordance with
the project specifications.
9.4 Overexcavation/Stabilization
Construction during extended wet weather periods could create the need to overexcavate
exposed soils if they become disturbed and cannot be recompacted due to elevated moisture
content and/or weather conditions. Even during dry weather periods, soft/wet soils, which
may need to be overexcavated, may be enconntered in some portions of the site. If
overexcavation is necessary, we recommend that overexcavation progress be observed by
Associated Earth Sciences, Inc. CAESI). Soils that have become unstable may require remedial
measures in the form of one or more of the following:
1. Drying and recompaction. Selective drying may be accomplished by scarifying or
windrowing surficial material during extended periods of dry and warm weather.
2. Removal of affected soils to expose a suitable bearing subgrade and replacement with
compacted structural fill.
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Proposed Melrose Short Plat
Renton, Washington
Subswface Exploration and Preliminary
Geotechnical Engineering Report
Preliminary Design Recommendations
3. Mechanical stabilization with a coarse-crushed aggregate compacted into the subgrade,
possibly in conjunction with a geotextile.
4. Soil/cement admixture stabilization.
9.5 Wet Weather Conditions
If construction proceeds during an extended wet-weather construction period and the
moisture-sensitive site soils become wet, they will become unstable. Therefore, the bids for site
grading operations should be based upon the time of year that construction will proceed. It is
expected that in wet conditions additional soils may need to be removed and/or other stabilization
methods used, such as a coarse crushed-rock working mat, to develop a stable condition if silty
subgrade soils are disturbed in the presence of excess moisture. The severity of construction
disturbance will be dependent, in part, on the precautions that are taken by the contractor to
protect the moislure-and disturbance-sensitive site soils. If overexcavation is necessary, it
should be confirmed through continuous observation and testing by a representative of our firm.
9.6 Temporary and Permanent Cut Slopes
In our opinion, stable construction slopes should be the responsibility of the contractor and
should be determined during construction. For estimating purposes, however, we anticipate
that temporary, unsupported cut slopes in unsaturated surficial weathered lodgement till can be
made at a maximum slope of 1.5H:IV (Horizontal:Vertical) or flatter. Temporary slopes in
unsaturated lodgement till may be planned at IH: 1 V. As is typical with earthwork operations,
some sloughing and raveling may occur, and cut slopes may have to be adjusted in the field. If
ground water seepage is encountered in cut slopes, or if surface water is not routed away from
temporary cut slope faces, flatter slopes will be required. In addition, WISHAlOSHA
regulations should be followed at all times. Permanent cut and structural fIll slopes that are not
intended to be exposed to surface water should be designed at inclinations of 2H: 1 V or flatter.
All permanent cut or fill slopes should be compacted to at least 95 percent of the modified
Proctor maximum dry density, as determined by American Society for Testing and Materials
(ASTM):D 1557, and the slopes should be protected from erosion by sheet plastic until
vegetation cover can be established during favorable weather.
9.7 Frozen Subgrades
If earthwork takes place during freezing conditions, all exposed sub grades should be allowed to
thaw and then be recompacted prior to placing subsequent lifts of structural fIll or foundation
components. Alternatively, the frozen material could be stripped from the subgrade to reveal
unfrozen soil prior to placing subsequent lifts of fill or foundation components. The frozen
soil should not be reused as structural fill until allowed to thaw and adjusted to the proper
moisture content, which may not be possible during winter months.
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Proposed Melrose Short Plat
Renton, Washington
10.0 STRUCTURAL FILL
Subsurface Exploration and Preliminary
Geotechnical Engineering Report
Preliminary Design Recommendations
All references to structural fIll in this report refer to sub grade preparation, fill type and
placement, and compaction of materials, as discussed in this section. If a percentage of
compaction is specified under another section of this report, the value given in that section
should be used.
After stripping, planned excavation, and any required overexcavation have been performed to
the satisfaction of the geotechnical engineer, the upper 12 inches of exposed ground in areas to
receive fIll should be recompacted to 90 percent of the modified Proctor maximum density
using ASTM:D 1557 as the standard. If the subgrade contains silty soils and too much
moisture, adequate recompaction may be difficult or impossible to obtain and should probably
not be attempted. In lieu of recompaction, the area to receive fill should be blanketed with
washed rock or quarry spalls to act as a capillary break between the new fill and the wet
subgrade. Where the exposed ground remains soft and further overexcavation is impractical,
placement of an engineering stabilization fabric may be necessary to prevent contamination of
the free-draining layer by silt migration from below.
After recompaction of the exposed ground is tested and approved, or a free-draining rock
course is laid, structural fill may be placed to attain desired grades. Structural fill is defined as
non-organic soil, acceptable to the geotechnical engineer, placed in maximum 8-inch loose
lifts, with each lift being compacted to 95 percent of the modified Proctor maximum density
using ASTM:D 1557 as the standard. Use of soils from the site in structural fill applications is
acceptable if the material meets the project specifications for the intended use, and if
specifically allowed by project specifications. In the case of roadway and utility trench filling,
structural fill should be placed and compacted in accordance with current City of Renton codes
and standards. The top of the compacted fill should extend horizontally outward a minimum
distance of 3 feet beyond the locations of the roadway edges before sloping down at an angle
of 2H: I V. Structural fills with sloping faces that cannot be compacted directly by a vibratory
roller should be compacted by overbuilding, then cutting back to a compacted slope core.
Track walking alone is not an effective means of compacting a structural fill slope.
The contractor should note that any proposed fill soils must be evaluated by AESI prior to their
use in fills. This would require that we have a sample of the material 72 hours in advance to
perform a Proctor test and determine its field compaction standard. Soils in which the amount
of fine-grained material (smaller than the No. 200 sieve) is greater than approximately
5 percent (measured on the minus No.4 sieve size) should be considered moisture-sensitive.
Use of moisture-sensitive soil in structural fills should be limited to favorable dry weather
conditions, and is only permitted if specifically allowed by project plans and specifications.
The native soils present on-site contained significant amounts of silt and are considered highly
moisture-sensitive. If fill is placed during wet weather or if proper compaction cannot be
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Proposed Melrose Shon Plat
Renton, Washington
Subsurface Exploration and Preliminary
Geotechnical Engineering Repon
Preliminary Design Recommendations
obtained, a select import material consisting of a clean, free-draining gravel and/or sand should
be used. Free-draining fill consists of non-organic soil with the amount of fine-grained
material limited to 5 percent by weight when measured on the minus No. 4 sieve fraction with
at least 25 percent retained on the No.4 sieve.
A representative from our firm should inspect the stripped sub grade and be present during
placement of structural fill to observe the work and perform a representative number of
in-place density tests. In this way, the adequacy of the earthwork may be evaluated as filling
progresses, and any problem areas may be corrected at that time. It is important to understand
that taking random compaction tests on a part-time basis will not assure uniformity or
acceptable performance of a filL As such, we are available to aid the owner in developing a
suitable monitoring and testing program.
11.0 FOUNDATIONS
Spread footings that are supported on structural fill or a combination of structural fill and
native lodgement till sediments may be designed witb an allowable foundation soil bearing
pressure of 2,500 pounds per square foot (psf), including both dead and live loads. Higher
foundation soil bearing pressures are possible but are not expected to be needed. An increase
of one-third may be used for short-term wind or seismic loading.
Footings should be buried at least 18 inches into the surrounding soil for frost protection.
However, all footings must penetrate to tbe prescribed bearing stratum, and no footing should
be founded in or above organic or loose soils. All footings should have a minimum width of
18 inches.
It should be noted that the area bound by lines extending downward at IH: 1 V from any footing
must not intersect another footing or intersect a filled area that has not been compacted to at
least 95 percent of ASTM:D 1557. In addition, a 1.5H:IV line extending down from any
footing must not daylight because sloughing or raveling may eventually undermine the footing.
Thus, footings should not be placed near the edge of steps or cuts in the bearing soils.
Anticipated settlement of footings founded as described above should be on the order of % inch
or less. However, disturbed soil not removed from footing excavations prior to footing
placement could result in increased settlements. All footing areas should be inspected by AESI
prior to placing concrete to verifY that the design bearing capacity of the soils has been attained
and that construction conforms to the recommendations contained in this report. Such
inspections may be required by the governing municipality. Perimeter footing drains should be
provided, as discussed under the "Drainage Considerations" section of this report.
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Proposed Melrose Short Plat
Renton, Washington
11.1 Drainage Considerations
Subsurface Exploration and Preliminary
Geotechnical Engineering Report
Preliminary Design Recommendations
Foundations should be provided with foundation drains. Drains should consist of rigid,
perforated, polyvinyl chloride (PVC) pipe surrounded by washed pea gravel. The drains
shonld be constructed with sufficient gradient to allow gravity discharge away from the
proposed buildings. No other runoff shonld be placed into the footing drain system.
12.0 FOUNDATION WALLS
All backfill behind foundation walls or around foundation units should be placed as per our
recommendations for structural fill and as described in this section of the report. Horizontally
backfilled walls, which are drained and free to yield laterally at least 0.1 percent of their
height, may be designed to resist active lateral earth pressure represented by an equivalent
fluid equal to 35 pounds per cubic foot (pct). Fully restrained, drained, horizontally
backfilled, rigid walls that cannot yield should be designed for an at-rest equivalent fluid of
50 pcf. Walls with sloping backfill up to a maximum gradient of 2H:IV should be designed
using an equivalent fluid of 55 pef for yielding conditions or 75 pcf for fully restrained
conditions. If parking areas are adjacent to walls, a surcharge equivalent to 2 feet of soil
should be added to the wall height in determining lateral design forces.
As required by the 2012 mc, retaining wall design should include a seismic surcharge
pressure in addition to the equivalent fluid pressures presented above. Considering the site
soils and the recommended wall backfill materials, we recommend a seismic surcharge
pressure of 5H and lOH psf, where H is the wall height in feet, for the "active" and "at-rest"
loading conditions, respectively. The seismic surcharge should be modeled as a rectangular
distribution with the resultant applied at the midpoint of the walls.
The lateral pressures presented above are based on the conditions of a uniform backfill
consisting of excavated on-site soils, or imported structural fill compacted to 90 percent of
ASTM:D 1557. A higher degree of compaction is not recommended, as this will increase the
pressure acting on the walls. A lower compaction may result in settlement of slab-on-grade
floors or other structures supported above the walls. Thus, the compaction level is critical and
must be tested by our firm during placement. Surcharges from adjacent footings or heavy
construction equipment must be added to the above values. Perimeter footing drains should be
provided for all retaining walls, as discussed under the "Drainage Considerations" section of
this report.
It is imperative that proper drainage be provided so that hydrostatic pressures do not develop
against the walls. This would involve installation of a minimum, 1-foot-wide blanket drain to
December 20, 2013 ASSOCIATED EAKTH SCIENCES, INC.
BWG/pc -TE13056IA3 -Projectsl20130561IIE1WP Page 15
Proposed Melrose Short Plat
Renton, Washington
Subsurface Exploration and Preliminary
Geotechnical Engineering Report
Preliminary Design Recommendations
within 1 foot of finish grade for the full wall height using imported, washed gravel against
the walls.
12.1 Passive Resistance and Friction Factors
Lateral loads can be resisted by friction between the foundation and the natural glacial soils or
supporting structural fill soils, and by passive earth pressure acting on the buried portions of
the foundations. The foundations must be backfilled with structural fill and compacted to at
least 95 percent of the maximum dry density to achieve the passive resistance provided below.
We recommend the following allowable design parameters:
• Passive equivalent fluid = 250 pef
• Coefficient of friction = 0.30
13.0 PAVEMENT RECOMMENDATIONS
Pavement areas should be prepared in accordance with the "Site Preparation" section of this
report. If the stripped native soil subgrade can be compacted to 95 percent of ASTM:D 1557
and is firm and unyielding, no additional preparation is required. Soft or yielding areas should
be overexcavated to provide a suitable subgrade and backfilled with structural fill.
The pavement sections included in this report section are for driveway and parking areas
on-site, and are not applicable to right-of-way improvements. At this time, we are not aware
of any planned right-of-way improvements; however, if any new paving of public streets is
required, we should be allowed to offer situation-specific recommendations.
Pavement areas should be prepared in accordance with the "Site Preparation" section of this
report. The exposed ground should be recompacted to 95 percent of ASTM:D 1557. If
required, structural fill may then be placed to achieve desired subbase grades. Upon
completion of the recompaction and structural fill, a pavement section consisting of 2'h inches
of asphaltic concrete pavement (ACP) underlain by 4 inches of 1 \<I-inch crushed surfacing base
course is the recommended minimum in areas of planned passenger car driving and parking.
Pavement sections for use by heavy vehicles are not expected to be needed for this project.
We can provide heavy pavement section recommendations on request. The crushed rock
course must be compacted to 95 percent of the maxinrum density, as determined by
ASTM:D 1557. All paving materials should meet gradation criteria contained in the current
Washington State Department of Transportation (WSDOT) Standard Specifications.
December 20, 2013
BWGIpc. -TE1J0561A3 -Projwsl20J30S61\TEIWP
ASSOCIATED EARI1I SCIENCES, INC
Page 16
Proposed Melrose Shan Plat
Renton, Washington
Subsurface Exploration and Preliminary
Geotechnical Engineering Report
Preliminary Design Recommendations
14.0 PROJECT DESIGN AND CONSTRUCTION MONITORING
Our report is preliminary since project plans had not been finalized at the time this report was
written. We recommend that AESI perform a geotechnical review of the plans prior to final
design completion. In this way, we can confirm that our earthwork and foundation
recommendations have been properly interpreted and implemented in the design.
We are also available to provide geotechnical engineering services during construction.
Construction monitoring services are not part of this current scope of work. If these services
are desired, please let us know, and we will prepare a cost proposal.
We have enjoyed working with you on this study and are confident that these recommendations
will aid in the successful completion of your project. If you should have any questions or
require further assistance, please do not hesitate to call.
Sincerely,
ASSOCIATED EARTH SCIENCES, INC.
Kirkland, Washington
Bruce W. GiIenzler, L.E.G.
Senior Project Geologist
Attachments: Figure 1:
Figure 2:
Appendix:
December 20, 2013
Vicinity Map
Site and Exploration Plan
Exploration Logs
Laboratory Testing Results
BWGlpc -TE]30561A3 -Projects\20/3056/11E1WP
Kurt D. Merriman, P.E.
Senior Principal Engineer
ASSOCIATED EARTH SCIENCES, INC.
Page 17
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VICINITY MAP
MELROSE SHORT PLAT
RENTON, WASHINGTON
a
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FIGURE 1
DATE 12113
PROJ_ NO_ TE130561A
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APPROXIMATE LOCATION
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~ _______ ~ _____ ~ _____ I111 ___________________ R_E_N_T_O_N_,\M __ ~_S_H_IN_G_T_O_N ____________ ~P~R~O~J.~N~O~.T~E~I~30~56~I~A __ __
APPENDIX
GC
gravel and
sand, little to
gravel
gravel with sand,
to no fines
Clayey gravel and
clayey gravel with sand
Poorly-graded sand
and sand with gravel,
little to no fines
Silty sand and
. SM silty sand with
gravel
Clayey sand and
clayey sand with gravel
---if---------l
Silt, sandy silt, gravelly silt,
ML slit with sand or gravel
medium
I pl"stl"lty;; silty, sandy, or
gravelly clay, lean clay
clay or silt of low
Terms Describing Relative Density and Consistency
Density SPT~)blows/foot
Coarse-Very Loose Oto 4
Grained Soils Loose 4to 10
Medium Dense 10 to 30
Dense 30 to 50 Test Symbols
Very Dense >50 G -Graln Size
M ~ Moisture Content
ConSistent::;' SPT(2t,lows/foot A ~ Atterberg Umlts
Fine-Very Soft o t02 C ~ Chemical
Grained Soils son 2t04 DD ~ Dry Density
Medium Stiff 4 taB K ~ Penneabiilty
Stiff B t015
Very Stiff 15 to 30
Hard >30
Descriptive Term
Boulders
Component Definitions
Size Range and Sieve Number
Larger tnan 12"
Cobbles
Gravel
Coarse Gravet
Rna Gravel
Send
Coarse Sard
Medium Send
AneSand
SOt and Clay
3' to 12"
3' to No.4 (4.75 mm)
3~ to 3/4-
3/4' to No.4 (4.75 mm)
No.4 (4.75 mm) 10 No. 200 (0.075 mm)
No.4 (4.75 mm) to No. 10 (2.00 mm)
No. 10 (2.00 mm) to No. 40 (0.425 mm)
No. 40 (0.425 mm) to No. 200 (0.075 mm)
Smaller then No. 200 (0.075 mm)
Estimated Percentage Moisture Content
Dry ~ Absence of moisture,
dusty, dry 10 the IoucIl
Slightly Moist -Perceptible
moisture
Component Percentage by
Weight
Trace
Few
UtUe
WiIh
Sampler
Type
2.0'00
Spllt-Spoon
Sampler
<5
5to 10
15 to 25
~ Non-primary coarse
constituents: .:::. 15%
-Fines content between
5% and 15%
Moist -Damp but no visible
water
Very Moist -Water visible but
not free draining
Wet· Visible free water, usually
from below water table
Symbols
BIows/6~· or
portion of 6"
I • • •
Sampler Type
Description
3.0' 00 spin-spoon Sampler
,.)
Cement grout
surface seal
Bentonite
seal
-~----"':77-:--.-::--I (SPl)
high plasticity, 3.25' 00 Spln-spoon Ring Sempler
~ Flter pack with
:. btank casing
0.-section
or gravelly c1ey, fat Bulk sample
clay with sand or gravel
~_+-________ -I Grab Sample
• 3.0' 00 thin-Wail Tube Sampler
Qncfudlng Shelby tube)
:' Screened casing
-or Hydrotlp
'. ". with liter pack
:. Endcap
Organic clay or sitt of o Portion not recovered
OH medium to high Percentage by dry weight
~-.JL_~~~_!~~' ~ _____ ~ t2) (SPl) Standard Penetration Tesl
Peat, muck and other
highly organic sQlls
(ASTM D-15B6)
13) In General Accordarce with
Standard Practice for Deoonption
1'1 Depth of ground water
:f ATD ~ At time 01 drilHng
~ Static waler _ (date)
(6) Combined uses symbols used for
flnes between 5% and 15% end ldentffication of Soils (ASTM ~24BB) I Classifications of solis in this report are based on Vhiual field amilor laboratory observations. which Include density/consistency, moIsture condltrOf\ grain size, and'
plastlctty estimates: and should not be construed to lmpJy field or laboratory lestlng unless presented herem. Vlsua1-manual and/or laboratory classification 5 methods of ASTM 0-.2487 and D-24BB were used as an Identfftcatlon guide for the Unified Sol Classtfication System.
~ l============================================
. Associated Earth Sciences, Inc. i -----------------------------------------------------------
EXPLORA liON LOG KEY FIGURE A1
LOG OF EXPLORATION PIT NO. EP-1
S This log Is part of the report rrrepared by Associated Earth Sciences, Inc. (AESI) for the named RrOject and should be
t read togetlier with that rsPQ for com;R'ate interpretation. This summary ~p!ies only to the loea Ion of this trench at the
'" time of excavation. Subsurface cond' Ions may change at this location wi the passage of time. The data presented are
0 a simplfication of actual conditions encountered.
DESCRIPTION
Topsoil
1 Vashon Lodgement ""
2
Medium dense, moist, reddish brown, fine SAND, trace medium to coarse sand, little silt, few fine to
coarse gravel; weathered (SM).
3 -
4 -
5 -Medium dense, moist to very mOist, mottled brown, fine SAND, trace medium to coarse sand, little
silt, few to little fine to coarse gravel, with layers (1 to 2 inches thick) of fine to medium sand, few to
6 -
little silt (SM).
Medium dense to dense, moist to very moist, brown, fine SAND, trace medium to coarse sand, little
7 -
silt, little fine to coarse gravel (diamict) (SM).
8 -
9 -
10 -Very dense, moist to very moist, brown, fine SAND, trace medium to coarse sand, little silt, little fine
r\to coarse gravel (diamict) (SM). r
11 -
BoHom of exploration pit at depth 10 feet
No seepage. No caving.
12 -
13 -
14 -
15 -
16 -
17 -
18 -
19 -
28 M
" ;------------------------------------------------------------------------------------
Melrose Short Plat
J
~
Logged by: LDM
Approved by:
Renton, WA
Associated Earth Sciences, Inc. Project No. TE130561 A
12/9113
-------------------------------------------------------------------------------------------------------
I
LOG OF EXPLORATION PIT NO. EP-2
. -------~
g This log is part of the report rrrepared by Associated Earth Sciences, Inc. (AESJ) for the named ftrOject and should be
£i read tqgether with that rePe;? for comftlete interpretation. This summary agplles only to the loea ion of this trench at the
"-time of excavation. Subsurface condi ions may change at this location Wit the passage of time. The data presented are <D
0 a simplfication of actual conditions encountered.
DESCRIPTION
Topsoil
1 Vashon Lodgement Till
2 -Medium dense, very moist, reddish brown, fine SAND, trace medium to coarse sand, little silt, few
fine to coarse gravel; weathered (SM).
I 3 Medium dense, moist to very mOist, mottled brown, fine SAND, trace medium to coarse sand, little ! silt, few to little fine to coarse gravel, with lenses (1 to 2 inches thick) of fine sand, little to with silt
4 (diamict); stratified (SM).
5
6 -Dense, very moist, brown to gray, fine SAND, trace medium to coarse sand, little to with silt, little
7 -fine to coarse gravel (diamicl), with layers «1 inch thick) of fine to medium sand, few silt(SM).
8 -
9 -Very dense, very moist, gray, fine SAND, trace medium to coarse sand, little silt, few fine to coarse
10 -I\gravel, with layers «1 inch thick) of fine to medium sand, few silt (SM). . r
Bottom of exploration pit at depth 9,5 feet
No seepage. No caving.
11 -
12 -
13 -
14 -
15 -
16 -
17 -
18 -
19 -
I
I
~--~2~O~-----------------------------------------------------------------------------e------------------------------------------------------------------------------------
0
1 Melrose Short Plat
• Renton, WA
Logged by: LDM
Approved by:
Associated Earth Sciences, Inc. Project No. TE130561 A
1219113 ~ -------------------------------------------------------------
~
'" o
2 -
3 -
LOG OF EXPLORATION PIT NO. EP-3
This log is part of the report prepared by Associated Earth Sciences, Inc. (AESI) for the named project and should be
read together with that repqrt for complete interpretation. This summary aoolies only to the location of this trench at the
time of excavation. Subsurface conditions may change at this location with'the passage of time. The data presented are
a slmplfication of actual conditions encounterBd.
DESCRIPTION
Topsoil
Vashon Lodgement Till
Medium dense, very moist, reddish brown, fine SAND, trace medium to coarse sand, little silt, few
fine to coarse gravel; nonstratified; weathered (SM).
Dense, moist to very moist, mottled brown, fine SAND, trace to few medium to coarse sand, little
4 -silt, little fine to coarse gravel (diamict) (SM).
5 -
6 -Dense, moist to very moist, brown to gray, fine SAND, trace medium to coarse sand, little silt, few to
little fine to coarse gravel, with layers (t to 2 inches thick) of few silt(SM). 7 -
8 -
9 -
Very dense, very moist, brown, fine SAND, trace medium to coarse sand, little silt, few fine to
10 -[\,coarse gravel, with layers (1 to 2 inches thick) of fine to medium sand, few silt (SM). r
11 -
12 -
13 -
14 -
15 -
16 -
17 -
18 -
19 -
Bottom of exploration pit at depth 10 feet
No seepage. No caving.
~--~2~O~----------------------------------------------------------------------------m-----------------------------------------------------------
" ~
Logged by: LDM
Approved by:
Melrose Short Plat
Renton, WA
Associated Earth Sciences, Inc. Project No. TE130561A
1219113
---------------------------------------------------
GRAIN SIZE ANALYSIS -MECHANICAL
Date Sampled Project Project No. Soil Description
12/1112013 Rozenblat TE130561A Sand little gravel little silt
Tested Sy Location ESIEP No lDePth
MS Onsite EP·2 2'
wt. of moisture wet sample + Tare 316. Total Sample Tare
Wt. of moisture dry Sample + Tare 286.81 Total Sample wt + tare
wt. of Tare .. Total Sample Wt 747.2
Wt. of moisture D Sample 184.77 Total Sample Dry Wt 645.2
Moisture % 16%
Sieve No. Dian (mm) Wt (! % % i
.1"'" '. ·C>.· 0.0· .
" " c u: -c
8 " ~
100
;
80
60
40
20
o
100
3"
,
US STANDARD SIEVE NOS.
314" NO.4 NO.16 NO.40 NO.200
~ .
~
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"l!
"' ,
..
"'
10 01
Gravel Sand Silt and Clay
Coarse I Fine Coarse I Medium I Fine
Grain Size, mm
ASSOCIA TED EARTH SCIENCES, INC.
911 5th Ave., Suite 100 Kirkland. WA 98033 425-827·no1 FAX425-827-5424
001
iB:
BEYLER
CONSULTING
Prepared for:
Prepared by:
Reviewed by:
CONTACT
phone: 253-380-2958
fax. 253-582-5694
landon(ci'beylerconsulting,coM
beylerconsultrng.com
OFFiCE
10314 lOOth St. SW
Lakewood, WA 98498
Plan. Design. Manage.
CIVIl. [NGIN[[RIi'.JG I L/\ND Pl/\"INING I rU,SIGUT'!
PROJ[CT MI\'-.lI\G['vI[N~ I PC:RMIT =XP[DITI~::;
MELROSE SHORT PLAT
Preliminary Drainage
Report
Jossif Rosenblat
5415 NE 2 nd Ct
Renton, WA 98509
January 24, 2014
Brandon Loucks, PE
Landon C. Beyler, P.E.
Beyler Consulting
7602 Bridgeport Way W #3d
Lakewood, WA 98499
253.301.4157
IVED
FEB 1 0 2014
CITY OF RENTON
PLANNING DIVISION
TABLE OF CONTENTS
I. PROJECT OVERVIEW •••••••..••••••••••••••••••••••••••••••••••••••••••••••••••••••• 3
Project Description ....................................................................... 3
TIR Worksheet ............................................................................. 5
II. CONDITIONS AND REQUIREMENTS SUMMARy ......................... 6
III. OFFSITE ANALYSIS ••••••••••••••••••••••••••..••••••••••••••••••••••••••••• 11 ••••••• 8
3.1.1 Task 1 -Study Area Definition and Maps ............................ 8
3.1.2 Task 2 -Resource Review ................................................ 8
3.1.3 Task 3 -Field Inspection .................................................. 9
3.1.3.1 Upstream and onsite runoff ............................................... 9
3.1.3.2 Downstream ................................................................... 9
3.1.4 Task 4 -Drainage System Description and Problem
Descriptions .............................................................................. 10
3.1.5 Task 5 -Mitigation of Existing or Potential Problems .......... 10
IV. FLOW CONTROL AND WATER QUALITY FACILITY ANALYSIS
AND DESIGN ••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••• 10
V. CONVEYANCE SYSTEM ANALYSIS AND DESIGN ...................... 14
VI. SPECIAL REPORTS AND STUDIES ........................................... 14
VII. OTHER PERMITS ••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••••• 14
VIII. CSWPPP ANALYSIS AND DESIGN ........................................... 14
IX. BOND QUANTITIES, FACILITY SUMMARIES, AND DECLARATION
OF COVENANT .•••••.•••••••••••••••••••••••••••••••••••••••••••••••••••••.•••••••••••••••••••• 14
X. OPERATION AND MAINTENANCE MANUAL .............................. 14
XI. Appendices •••.•••••.•••••.•••••...••.••.••••••••••••..••••••••••••••••••.•••••••.•••••. 15
iB:
APPENDIX A -OFFSITE STUDY MAPS
APPENDIX B -DOWNSTREAM SYSTEM TABLE AND MAPS
APPENDIX C -CSWPPP
BEYLER
I PROJECT OVERVIEW
Project Description
This project proposes to short plat a vacant parcel located in Renton Washington. The project
is located within the Renton City limits, however does not currently have an assigned address
yet (parcel #322305-9202). The current zoning of the parcel is Residential 8 indicating a
maximum density of 8 dwelling units per acre. This project proposes 2 lots on the 0.41 acre
property, each approximately 8,232 sf. The remaining area will be dedicated for future right-
of-way.
The short plat proposal includes providing 2 lots for single family residences, a shared use
driveway within a access and utility easement, frontage improvements, and appropriate
utilities. The futures houses will be permitted at a future date.
The property is adjacent to 108th Ave SE (SR 515, Principal Arterial), to the north and south
are single family residences, and to the east is a single family residence within the Vista Hills
subdivision. The project is keeping consistent with neighboring land use characteristics.
It has been requested on the preapplication memorandum, dated October 9, 2013 to provide
improvements along 108th Ave SE to meet the City's complete street standards. These
improvements include an 8-foot planting strip behind the existing curb, a 12-foot sidewalk,
and a 2-foot strip back of the sidewalk. To build this, approximately 12' of right-of-way is
proposed for dedication.
The site will be accessed off of 108th Ave SE near the southeast corner of the property. The
access way will be a 12' paved shared-use driveway within a 20' access and utility easement.
The 12' shared driveway will be approximately 80 linear feet.
This project is subject to the 2009 King County Surface Water Design Manual (King Manual)
and the City of Renton amendments to the Manual (Renton Manual). Per Figure 1.1.2.A of the
Renton Manual, the project is subject to a Full drainage review.
A subsurface exploration on the project site was conducted by Associated Earth SCiences, Inc
(AES) in December 2013. In summary, each of the exploration pits encountered native
sediments consisting of medium dense grading to very dense sand with varying silt and gravel
content (23% silt). This is interpreted as Vashon Lodgement till. AES does not recommend
infiltration as a method for managing storm water.
A field study was conducted by EnCo Environmental Corporation to locate any wetlands or
streams located on the site and determine any required buffers. Based on observation, review
of collected data, and evaluation of readily available maps, the project site does not contain
wetlands or streams at this time. The edges of wetland and streams were not identified within
200 feet of the project site.
iB:
BEYLER
1-
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PROJECT I, //
SITE r , ..
VICINITY MAP
N.T.S
t
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TIR Worksheet
TlR Worksheet will be completed during final engineering
lB:
SEYLER
Ii. CONDITIONS AND REQUIRElviENTS SUMfJiARv
(The plat conditions with responses will be placed here upon receipt of conditions)
Review of Eight Core Requirements and Five Special Requirements
The following comments are a review of the Core and Special Requirements per the 2009 Ki ng
County Surface Water Storm water Manual.
Core Requirement No.1 Discharge at the Natural Location
The site's topography suggests that stormwater runoff from the site sheets flows to the east
through the project parcel to the city drainage system in 108th Ave SE. Under developed
conditions, stormwater from the shared driveway will be directed toward 108th Ave SE to an
existing catch basin.
Core Requirement No 2 Offsite Analysis
The project proposes to discharge all stormwater to the existing conveyance system in 108th
Ave SE. A Level 1 off site analysis was conducted January 22 2014. No flooding or potential
flooding problems were identified downstream of the site. Further narrative of this analysis
can be found in Section III of this report.
Core Requirement No 3 Flow Control
Flow Control Facility (1.2.3.1.Bl:
The proposed project is located within the Flow Control Duration Standard -Matching
Forested area per the Renton Manual. This is equivalent to Conservation Flow Control in the
King Manual which matches requiring runoff from developments to be detained and released
at a rate that matches the flow duration of predeveloped rates. The above is required unless
an exception applies to the proposed site conditions.
The developed conditions of do not exceed a 0.1 ds difference in the sum of developed 100-
year peak flows for those target surfaces subject to the flow control facility requirement and
the sum of forested site conditions 100-year peak flows for the same surface areas. Thus
flow control is not required for this basin per section 1.2.3.1.B of the Renton Manual. See
Section N of this report for details and a table of the target areas.
Flow Control BMPs:
In addition to flow control facility requirements, projects subject to Core Requirement #3
must apply flow control BMPs to impervious surfaces on each individual lot. Flow control BMPs
are methods and design for dispersing, infiltrating, or otherwise reducing development
increases in runoff. However, implementation of flow control BMPs on indiVidual lot as part
of this short plat project is optional per Section 5.2.2.1 of the King Manual. The applicant has
chosen to defer implementation of flow control BMPs on the individual lots of the short plat
until the building permit is obtained for construction on each lot. Stubs for roof drain
connections will be provided as a part of this short plat.
Core Requirement No.4 Conveyance System
All new pipes systems will be designed with sufficient capacity to convey and contain at
minimum the 25-year peak flow. Conveyance design will be completed during final
engineering.
iB: -1"'-"
.. -; .~/
BEYLER
Core Requirement No.5 Erosion and Sediment Control
This development will be constructed in one phase. A CSWPPP will be prepared during final
engineering.
Core Requirement No.6 Maintenance and Operations
The maintenance and Operations Manual will be included during final engineering.
Core Requirement No.7 Financial Guarantees and Liability
Financial guarantees will be provided during final engineering.
Core Requirement No.8 Water Quality
This project falls within a Basic Water Quality treatment land use area as designated by the
Renton Manual and is not subject to Enhanced Basic WQ menu per Section 1.2.8.1.A. The
goal of Basic WQ treatment is 80% removal of total suspended solids.
The project though falls under the Pollution Generating Impervious Surface (PGIS) threshold
of 5,000 sf within a threshold discharge area. Stormwater treatment is not required for this
project. See Section IV of this report for details and a table of the target areas.
Special Requirement No.1 Other Adopted Area-Specific Requirements
This project is not in a designated Critical Drainage Area. This special requirement is not
applicable.
Special Requirement No.2 Flood Hazard Area Delineation
The project does not contain or is not adjacent to a flood hazard area for a river, stream,
lake, wetland, closed depreSSion, or marine shoreline that is within the 100-year floodplain
according to King County and FEMA.
Special Requirement No.3 Flood Protection Facilities
This project does not rely on any flood protection facility such as a levee or revetment nor
will construct a new flood protection facility.
Special Requirement No.4 Source Control
This project does not require a commercial building or commercial site development permit.
This special requirement is not applicable.
Special Requirement No.5 Oil Control
This project is not defined as a high-use site nor is a redevelopment project proposing
$100,000 or more of improvements to an existing high-use site. This special requirement is
not applicable.
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ilL OFFSlfE ANALYSIS
A preliminary off site analysis report has been prepared per Section 1.2.2, Core Requirement
#2. This is to identify and evaluate offsite flooding, erosion, and water quality problems that
may be created or aggravated by the proposed project. The primary component of this off site
analysis report is the downstream analysis. The second component of the report is to evaluate
the upstream drainage system to verify that significant flooding and erosion impact will not
occur as a result of the project.
3.1 DOWNSTREAM ANAL YSIS
The following Level 1 downstream analysis is a review of the drainage system up to a mile
downstream of the site.
3.1.1
The four tasks outlined under this review are:
Task 1 -Define and map the study area
Task 2 -Review all available information on the study area
Task 3 -Field inspect the study area
Task 4 -Drainage System Description and Problem Descriptions
Task 1 -Study Area Definition and Maps
The project is located in the King County Black River Drainage Sub-Basin within the
Duwamish-Green water resource inventory area. The drainage study area is approximately
a mile long path encompassing the site's downstream corridor. See Appendix A for maps of
the basic study area.
The site is currently vacant, surrounded by NE 203rd to the South and single family residences
to the north, east, and west.
3.1.2 Task 2 -Resource Review
The following resources have been reviewed for the downstream analysis. This is a review of
all available information on the downstream area at least a mile downstream. Sources include
the City of Renton GIS maps, King County GIS maps, geotechnical studies, wetland studies.
Sensitive Area (See Appendix A for Sensitive Area Maps)
iB:
• Erosion-Project site mapped as high erosion potential according to the
geotechnical report prepared by AES. However, the downstream path is within a
closed conveyance system.
• Seismic -None Mapped
• Landslide -None Mapped
• Coal Mine -None Mapped
• Streams and Wetlands Map -None Mapped
• Susceptible to Groundwater Contamination -Low
• 100 year flood plain -According to King County iMAP and the FEMA Flood Maps,
the 100 year flood plain is not located near the project property.
BEYLER
Drainage complaints and studies
3.1.3
King County -Relevant DNRP drainage complaints within 1 mile of the downstream
corridor within the last 10 years were searched. There are currently no
open complaints within the corridor, however 3 relevant complaints
within the last 10 years has been filed. Refer to drainage complaint map
in Appendix A for the location of this complaint. See also Task 4 of this
Downstream analysis for a description of the complaint and how it was
mitigated.
Task 3 -Field Inspection
A site visit was performed on January 22, 2012 for the purpose of analyzing the proposed
project site and its upstream and downstream corridor at least a quarter mile downstream of
the site (1,320 ftJ. The weather conditions were cloudy and partly foggy. A description of
the drainage path is described below. See Appendix B for downstream reach locations.
3.1.3.1 Upstream and onsite runoff
The project site does not appear to be subject to any significant upstream run-to the project
site.
The site's topography suggests that that stormwater sheet flows through west to the public
storm. Currently the site is heavily forested and most stormwater is absorbed into the duff
layer and does not convert to runoff.
3.1.3.2 Downstream
The following is a discussion of the downstream corridor from the discharge location of the
project. See Appendix B for a Summary of each reach including: pipe size, length, and
material as well as a map of each reach's location. City of Renton GIS information was
utilized to determine pipe size, slope, and length.
Reach 1
0-> 1,535' Storm water from the site and upstream flows is collected in an existing
catch basin near the proposed shared access entrance on 10Sth Ave SE and enters
the public storm system. From this point stormwater is conveyed in 12" Concrete
pipes north along lOSth to the limits of the field inspection analysis. The pipe slopes
range from 1% to S.5%.
See Appendix B for a Summary of each reach including: pipe size, length, and material as
well as a map of each reach's location.
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SEYLER
3.1.4 Task 4 -Drainage System Description and Problem Descriptions
The drainage system is comprised mostly an existing piped conveyance system within 10S th
Ave SE. However parcels adjacent to 10Sth Ave SE have had some complaints filed with
King County. Two existing relevant drainage complaints are listed below.
Existing drainage complaint #2006-0549:
This complaint is regarding the regional stormwater facility located at the corner of 10Sth
and SE lS2nd St. There was a complaint that the facility was not being maintained, the
vegetation was very overgrown, and there were rats. This facility has since been cleaned
and is in better working order.
Existing drainage complaint #2006-0553:
This is a Code enforcement case #E0600791 for the same issue above.
3.1.5 Task 5 -Mitigation of Existing or Potential Problems
There does not appear to be any existing or potential problems (other than standard
maintenance of the piped conveyance system) associated with the site.
IV. FLOW CONTROL AND WATER QUALITY FACILITY ANALYSIS
AND DESIGN
The stormwater flow control and water quality facilities were designed in accordance with the
2009 King County Surface Water Design Manual (King Manual) and the City of Renton
amendments to the Manual (Renton Manual).
Existing Site Hvdrology (Part A)
Existing conditions on the project site consists of a vacant 0.41 acre parcel. The project is
made up of one sub basin where the site generally slopes down from the west to east over a
relatively flat grade. The overall vertical relief of the site is approximately 5 feet. Slopes across
the site are generally less than 8 percent. At the eastern edge of the property is rock wall up
to 6' in height. The majority of the site is 4 to 6 feet above the Sidewalk and road along lOS th
Ave SE.
Currently the site is covered with a large amount of deCiduous trees, cottonwoods and alders.
Most of the trees are in poor condition.
According to the geotechnical report, the topsoil is approximately 1 foot thick. It is likely that
with the thick topsoil cover and the large tree canopy cover, most stormwater is absorbed
into the soil with very little turning into runoff.
Developed Site HYdrology (Part B)
The disturbance on Site will include construction clearing and grading, construction the shared
use driveway, aSSOCiated utilities, and eventually the two future houses. The future driveways
and rooftops have been included in the stormwater calculations. It is proposed that each
ilt
BEYLER
driveway will slope toward the shared use driveway. The shared use driveway will be graded
such that it directs runoff to a private catch basin on the shared access. It is then proposed
to connect the new CB to the existing catching in 108th Ave SE adjust to the property. A stub
for a roof drain connection has been proposed for each lot to tightline rooftop runoff to the
new catch basin in the shared driveway.
Tables 4.1 and 4.2 break down the historic and developed site conditions
TABLE 4 1 -Historic Conditions .
Sub-basin Total Area Impervious Till Grass Till Forest
sf (ae) Sf (ac) Sf (ac) sf (ac)
Site* 16,464 0 0 16J 464
TOTAL 16,464 0 0 16,464
(0.378) (0.378)
*The area reflects the site area after ROW dedication
. -TABLE 4 2 D eve ope dC d" on Ittons
Sub-basin Total Impervious Till Grass PGIS
sf (ac) Sf (ac) Sf (ac) (YIn)
Site* 16464
Shared Use 936 v
2 Houses 4500 n
Lot 1 Conc 834 y
Drive
Lot 2 Asphalt 777 y
Drive
Lot 2 Conc 783 Drive
Lawn 8634 n
TOTAL 16,464 7,830 8,634
(0.378) (0.180) (0.198)
TOTAL PGIS 3,330
(0.076)
*The area reflects the site area after ROW dedication
Performance Standards (part C)
Flow Control Facilitv (1 2.3.1.8);
The proposed project is located within the Flow Control Duration Standard -Matching
Forested area per the Renton Flow Control Application Map Dated 01/09/2014. This is
equivalent to Conservation Flow Control in the King Manual which matches requiring runoff
from developments to be detained and released at a rate that matches the flow duration of
predeveloped rates. This is for a range of predeveloped discharge rates from 50% of the 2-
year peak flow up to the full 50-year peak flow and applied to target surfaces only. The above
is required unless an exception applies to the proposed Site conditions.
The developed conditions do not exceed a 0.1 cfs difference in the sum of developed 100-
year peak flows for those target surfaces subject to the flow control facility requirement and
the sum of forested site conditions 100-year peak flows for the same surface areas. Thus
flow control is not required for this basin per section 1.2.3.1.B of the Renton Manual. Part 0
of this section for analysis output comparing the pre and post flow rates.
ill:
BEYLER
Flow Control BMPs:
In addition to flow control facility requirements, projects subject to Core Requirement #3
must apply flow control BMPs to impervious surfaces on each individual lot. Flow control BMPs
are methods and design for dispersing, infiltrating, or otherwise reducing development
increases in runoff. However, implementation of flow control BMPs on individual lot as part
of this short plat project is optional per Section 5.2.2.1 of the King Manual. The applicant has
chosen to defer implementation of flow control BMPs on the individual lots of the short plat
until the building permit is obtained for construction on each lot. Stubs for roof drain
connections will be provided as a part of this plat.
Water Qualitv
This project falls within a Basic Water Quality treatment land use area as designated by the
Renton Manual and is not subject to Enhanced Basic WQ menu per Section 1.2.B.1.A. The
goal of Basic WQ treatment is BO% removal of total suspended solids.
The project though falls under the Pollution Generating Impervious Surface (PGIS) threshold
of 5,000 sf within a threshold discharge area. See Table 4.2. Stormwater treatment is not
required for this project.
Storm water Conveyance
The conveyance system capacity standards require that new conveyance systems contain the
25-year peak flow and ensure that the lOa-year event does not create a severe flooding or
erosion problem. See Section V of this report for the conveyance analysis per Core
Requirement #4.
Flow Control Systems (Part Pl
As discussed in Section The developed conditions of do not exceed a 0.1 cfs difference in the
sum of developed lOa-year peak flows for those target surfaces subject to the flow control
facility requirement and the sum of forested site conditions lOa-year peak flows for the same
surface areas.
To compare the flow rates, the King County Runoff Time Series (KCRTS) analysis software
was used. The project is located in the SeaTac 1 region according to Figure 3.2.2.A of the
King Manual. The values in Table 4.2 were input into KCRTS and analysis results are below.
All areas are conSidered target as defined in Section 1.2.3.1.B in the Renton Manual.
Flow Frequency Analysis
[lme Serles Flle:pre.tsTI
project Locatlon:Sea-Tac
---Annual
Flow Rate
(CFS)
0.024
0.006
0.018
0.001
0.011
0.019
0.015
0.031
Peak Flow Rates---
Rank Time of peak
2
7
4
8
6
3
5
1
2/09/01 18:00
1/05/02 16:00
2/28/03 3:00
3/24/04 20:00
1/05/05 8:00
1/18/06 21:00
11/24/06 4:00
1/09/08 9:00
computed peaks
ill:
SEYLER
-----Flow Frequency Analysis-------
- -Peaks Rank Return Prob
(CFS) peri od
0.019 3 10.00 0.900
0.018 4 5.00 0.800
0.015 5 3.00 0.667
0.011 6 2.00 0.500
0.006 7 1.30 0.231
0.001 8 1.10 0.091
0.028 50.00 0.980
Flow Frequency Analysis
[lme serles F1Ie:dev.tsfj
ProJect Locatlon:sea-Tac
---Annual
Flow Rate
(CFS)
0.061
0.047
0.074
0.048
0.059
0.065
0.070
0.127
Peak Flow Rates---
Rank Time of peak
5
8
2
7
6
4
3
1
2/09/01 2:00
1/05/02 16:00
2/27/03 7:00
8/26/04 2:00
10/28/04 16:00
1/18/06 16:00
10/26/06 0:00
1/09/08 6:00
computed peaks
Flow Control BMPs
-----Flow Frequency Analysis-------
- -peaks - -Rank Return prob
~CFS) peri od
:s?K ~ ~~:gg g:3g~
0.070 3 10.00 0.900
0.065 4 5.00 0.800
0.061 5 3.00 0.667
0.059 6 2.00 0.500
0.048 7 1.30 0.231
0.047 8 1.10 0.091
0.109 50.00 0.980
The applicant has chosen to defer implementation of flow control BMPs on the individual lots
of the short plat until the building permit is obtained for construction on each lot. Stubs for
roof drain connections will be provided as a part of this plat.
Water Quality System (Part E)
The project is located within a Basic Water Quality treatment area as discussed in Part C in
this Section. The project though falls under the Pollution Generating Impervious Surface
(PGIS) threshold of 5,000 sf within a threshold discharge area. See Table 4.2. Stormwater
treatment is not required for this project.
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SEYLER
v. CONVEl'ANCE SYSTHi ANALYSIS AND DESIGN
The conveyance system will be designed per Section 3 and 4 of the King Manual. Table 3.2
of the Manual suggests that the Rational Method of analysis is required for undetained areas
for tributary areas less than 10 ac. Further analysis will be provided during final engineering.
VI. SPECIAL REPORTS AND STUDIES
Geotechnical Report
Subsurface Exploration and Preliminary Geotechnical Engineering Report,
December 20,2013; Prepared by Associated Earth Sciences Inc.
Sensitive Area Study
Wetland & Stream Assessment and Certification, November 6, 2013; Prepared
by EnCo Environmental Corporation.
VII. OTHER PERMITS
There are currently no other permits that effect the drai nage submittal or the Technical
Information Report.
VIII. CSWPPP ANALYSIS AND DESIGN
A CSWPPP will be included during final Engineering.
IX. BOND QUANTITIES, FACILITY SUMMARIES, AND
DECLARATION OF COVENANT
A completed Bond Quantities Worksheet can be made available to the County upon request.
X. OPERATION AND MAINTENANCE MANUAL
The Operations and Maintenance Manual will be submitted at a later date.
iB:
BEYLER
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XI. Append Ices
APPENDIX A -OFFSITE STUDY MAPS
Topography Map
Renton
,
+
{C12IOO8Kmog County 01
The informetion indldecl on this map has been compiled by KIng COI.rrty stat'\' rrom II II8Iiely at L'IOIJI'C89 and IS ~ect to d\ange withOut notice. King
County makes no represerUtIons or warranties, e~ or impled, 81 to accuracy, completeness, 1irneIrIeas, or rights to the use of SUCh infOrmation.
ThIs dOa.iment is not intended tor use 81 a &uI'W)' product King CounIY shall not be ~abI$ for any general, special, Indirea, iocidenIaI, or 00I'IMqU8I"Itia
damages i'IcIuding, W not Mmited to, ~ revenues or Io&t profits resutti~ rrom the use or miSuse of the infOrmation contained on this map. Any sale of
this map or Information on this map is prohibited except by written permission of King County.
Date: 12f2712013 Soutar. King County iMAP -S10rmwatef (http://www.meIrokc.govIGISliMAP)
,
110111
til King County
Drainage Complaints
SL l&iTH
Da le : IMAP-
APPENDIX B -DOWNSTREAM SYSTEM TABLE AND MAPS
Basin: DUWAMISH-GREEN
Symbol Drainage
Component Type,
Name and Size
see map Type: sheet flow, swale,
stream, channel, pipe,
pond; Size: diameter,
surface area
Reach 1 Pipe
Reach 2 Pipe
Reach 3 Pipe
Reach 4 Pipe
Reach 5 Pipe
Reach 6 Pipe
Reach 7 Pipe
OFF-SITE ANALYSIS DRAINAGE SYSTEM TABLE
SURFACE WATER DESIGN MANUAL, CORE REQUIREMENT #2
Snbbasin Name: BLACK RIVER Subbasin Number: WRIA #9
Drainage Slope Distance Existing Potential Observations of field
I
Component from site Problems Problems inspector, resource
Description discharae reviewer, or resident I
drainage basin, vegetation, % 1,.4 ml -1,320 ft. constrictions, under capacity, ponding, tributary area, likelihood of problem, !
cover, depth, type of sensitive overtopping, flooding, habitat or organism overflow pathways, potential impacts
area, volume destrudion, scouring, bank sloughing,
i sedimentation, incision, other erosion
57 LF-12" Rep 1% 57' none none
302 LF-12" Rep 4% 359' none none
145 LF-12" Rep 2.8% 504' none none
237 LF-12" Rep 3.2% 741' none none
276 LF-12" Rep 4% 1 ,017' none none
249 LF-12" Rep 8.5% 1,266' none none
269 LF-12" Rep 5% 1,535' none none
•
1/9.12009
o
1 : 1,856
155 o 77 155 Feet
C ity of RentOD F :"
Finan ce & IT Divi s ion
Downstream Map 1
Legend
City and County Boundary
Olher
[j Ci, of R,"","
Parcels
Structu re
• Catchbasm -Type 1
• Catchbasin -TypelL
• Conaele/Curb !nlet . Type 4
• Orop Inlet
• Catchbasm -Type 2 MH
Beyler Cons ulting
1212712013
• Calchbasm -Type 1
• Calchbasin -Typel L
• Concrete/C urb In let -Type 4
• Drop Inlet
Caldlbasm -Type 2 MH
c Access Riser
Utility Vault
• Claanout
• Other
, Unknown Structure
I-'~r IS ,(' , f'ra!f) -!IJJI)I'I
';" ":" ;,-y It:~. (~i~ t!,~ '.ppe9.r ~I'IS
,,'J!('
:l~;; '~ ';; "'J
'1'8)' r' , )~
In rv: '(' "ltJi
THI S MAP IS NOT TO BE USED FOR NAVIGATION
Note s
o
1: 1 ,856
155 o 77 155 Feet
C ity of Renton
Finan c e & IT Division
Downstream Map 2
Legend
City and County Boundary
0"'"
[j C,t, of Ron ton
Parcels
Structure
• Catchb85in -Type 1
• Catctlba sin -Typell
• Cooaele/Curt) Inlet -Type 4
• Or op Inlet
• CalchOaSin -Type 2 MH
Beyler Consulting
12 127/2013
• Catchba5ln • Type 1
• Catchb8Stn -TypelL
• ConcretelCurtllnlei . Type 4
• Drop Inlet
CatchbaSl n · Type 2 MH
• Access Riser
Ub li ty Vault
• Cleanout
• Other
.. Unknown Struc1ure
tlra' , utf1 I' )rr n nlf r ~r'~ 'l ,~,.
Dat "'., 'prJ" r ,,", :t1'~ 1;W;J) 'J~ r:-I
.Jt I~ er Ihe'~;:, Jei€
THIS MAP IS NOT TO BE USED FOR NAVIGATION
APPENDIX C -CSWPPP
Will be submitted at a later date.
Mr. Jossef Rozenblat
5415 NE 2nd Court
Renton WA 98509
PO Box 1212
Puyallup WA 98371
Telephone: 253.841.9710
www.encoec.com
Mr. Gerald Wasser, Associate Planner
City of Renton
1055 South Grady Way
Renton WA 98057
RE: Wetland & Stream Assessment and Certification
Jossef Rozenblat Property
November 6, 2013
Address: XXX 108th Avenue SE, Renton, King County, WA 98057
Current Land Use: Undeveloped Proposed Land Use: Residential
1.0 INTRODUCTION & SUMMARY
At the request of Mr. Landon Beyler of Beyler Consulting, LLC, EnCo Environmental Corporation
(EnCo) performed a wetland and stream assessment on the above-referenced property, herein
known as the project site. It is my understanding that the landowner may develop the project site
into a 2 lot short plat for two single family residences.
Based on observations, review of collected data, and evaluation of readily available maps the
project site does not contain wetlands or streams at this time. The edges of wetlands and streams
were not identified within 200 feet of the project site.
2.0 DESCRIPTION
The project site is located within the jurisdictional boundary of the City of Renton in King County
(FIGURE 1 -VICINITY). The lot is situated in the southwest quarter of Section 32, Township 23N,
Range 05W of the Willamette Meridian. The property consists of vacant, third grown woodland.
The lot is covered with a moderately dense stand of trees with a scrub-shrub and emergent
understory. There are no structures on the property.
The east boundary of the site is located contiguous with 108th Avenue, SE. The south, west and
north boundary of the site is located contiguous to residential properties. There are no other public
roads which lie contiguous to the site. The property consists of one separate parcel of land as
shown below.
Parcel Number Acreage Shape Length eN to S) Width eE to W)
A: 322305-9202 0.41 Rectangle 105.54' 168.06'
GIS Mapping· Site Assessment • Wetla~d. Remediation· Habitat· stormwateRECEIVED
FEB 102014
CITY OF RENTON
PLANNING DIVISION
3.0 BACKGROUND
Reportedly, a single family dwelling formerly occupied the site. The dwelling has been
demolished. A professional land survey was completed on November 1, 2013.
4.0 PURPOSE
The purpose of this report is to study and document the presence or non-presence of wetlands and
streams on and in the near vicinity to the project site for the City of Renton in support of a
proposed application for a 2 lot short plat residential development.
5.0 SCOPE OF WORK
EnCo performed the following sub tasks:
• Reviewed readily available aerial photographs, agency mapped wetlands, streams, soils, and
topography.
• Performed one site visit with the landowner or approved representative who is familiar with the
project site boundaries, current land use, proposed development, and project envelope.
• Established two (2) randomly selected test plots in representative ecological communities as
depicted on FIGURE 2 -TEST PLOT LOCATIONS.
• Determined the baseline condition of the natural features and land use.
• Determined whether or not wetlands exist on the property according to current jurisdictional
government agency methodology and within about 200 feet from the project site boundary,
proposed development, or change in land use.
• Determined whether or not streams or other regulated waterbodies exist on the property
according to currently accepted methodology and within about 200 feet from the project site
boundary, proposed development, or change in land use.
• Determined if wetlands and streams (if identified) are jurisdictional.
• Prepared a hand sketch (not to scale) of the test plots over a color aerial photograph.
• Prepared this letter on the findings with a PHOTOGRAPHIC LOG (APPENDIX B) documenting
current site conditions and the test plots.
6.0 METHODOLOGY
The critical area determination was performed using the most current edition of the City of Renton
Critical Area Ordinance. The wetland determination method followed the latest version (2008) of
the U. S. Army Corps of Engineers Wetland Delineation Manual for Western Mountains, Valleys,
and Coast Region and stream determination followed the Washington Department of Natural
Resource stream and river dassification system.
GIS Mapping· Site Assessment· Wetland' Remediation' Habitat· Stormwater
2
7.0 SCHEDULE & WEATHER CONDITIONS
The assessment was performed by Mr. Jonathan Kemp, Professional Wetland Scientist of EnCo
on November 4, 2013. The field work took about 4 hours to complete with one project wetland
scientist. The site visit was performed during the growing season and weather conditions
consisted of mostly clear skies with ambient air temperatures ranging from 44°F to 52°F. No
rainfall fell during the field work or within 48 hours. The climatic conditions are considered typical
for this time of the year.
8.0 FIELD PROCEDURES
Field procedures undertaken followed acceptable industry practices. The assessment included a
pedestrian survey over the property, starting at east end and then traveling north, west and south
along the property boundary. The survey included walking a transect through the middle of the
property.
A trenching shovel was used to dig the test holes down to at least 18 inches below the ground
surface at 2 discrete locations to study the presence or non-presence of near-surface hydric soil
indicators and to measure the presence or non-presence of the near surface ground water level.
The assessment included estimating areal cover of dominant vegetation species and looking for
indicators of flowing water, scouring, and defined channels.
The collected data and indicators were compared to the three wetland criteria and a wetland and
stream determination was made. Based on this process a final analysis was made to determine if
the area assessed contains jurisdictional wetlands or streams. These data and observations were
recorded in a field log book by the wetland scientist.
The wetland determination was made by putting equal emphasis on all three wetland indicators; 1)
hydric soil indicators, 2) dominant hydrophytic vegetation growth pattems, and 3) wetland
hydrology.
9.0 FINDINGS
The data collected at the test plots in concert with the pedestrian survey of the lot was used to
make the determinations. The project site exhibits normal circumstances for soils, vegetation, and
hydrology because these features appear to have remained stable for five years or more. The
topography is relatively flat and there are no defined depressions or scoured swales to collect,
concentrate or convey surface water.
Soils
Observed Soil
The soils observed at the test plots from the ground surface down to about 5 inches below ground
surface (bgs) consists of aerobic dark brown to brown, gravelly (rounded 1/8 th inch), silty medium
GIS Mapping· Site Assessment· Wetland· Remediation • Habitat· Stormwater
3
to fine sandy loam underlain with yellow brown gravelly (rounded 1/2 inch to 1.S inch) silty medium
sand to the bottom of the test pit at 18 inches bgs. Natural depletions were not observed from the
surface down to 18 inches bgs. The soil was slightly moist at the surface down to the bottom of
the test holes. The soil layers at P-2 are mixed and blended indicating human disturbance.
Observed soil characteristics in the test plots are presented on the data forms. The data forms are
kept in the EnCo file for future reference, if needed. A summary of the rationale for making the
upland vs. wetland determination for hydric soil indicators (if any) at plots is listed below.
Hydric Soil Indicators Identified in Test Plots
Test Black Sulfidic Loamy Redox Depleted Depleted Hydric
Plot Histic Odor Mucky Dark Matrix Below Dark Soil List
Mineral Surface
1 No No No No No No No
2 No No No No No No No
Mapped Soil
Based on interpretation of the USDA Natural Resources Conservation Service Web Soil Survey
map, the original, undisturbed, primary mapped soil series identified at the ground surface and
down to about 60 inches bgs on the project site have been mapped as indicated below.
Age -Alderwood Gravelly Sandy Loam 6"10 to 15%
The soil type mapped on 100 percent of the project site is classified as Alderwood Gravelly Sandy
Loam 6-12"10. Note: The actual slope observed at the site ranges from 0% to 6%. The Alderwood
series consists of nearly level to undulating soil and is moderately well drained while permeability
in the upper soil profile is (if disturbed), is moderately rapid to moderately slow depending upon
compaction. Roots penetrate to and tend to mat on the surface of the consolidated substratum.
Some roots enter the substratum through cracks. Water moves on top of the substratum in winter.
Available water capacity is low. Runoff is slow and the erosion hazard is slight. This soil type
formed in ancient lake moraines and till plains from basal till and volcanic ash. Alderwood soils are
not listed on the county hydriC soils list.
In a typical soil profile the surface layer from 0 to 26 inches is dark-brown (1 OYR 4/3) gravelly
sandy loam, pale brown (10YR 6/3) dry, massive, slightly hard, very friable, non-sticky, non-plastic;
many roots; medium acid with abrupt and smooth boundary. From 26 inches to 60 inches bgs the
soil consists of grayish-brown (2.SY S/2) weakly consolidated to strongly consolidated glacial till,
light brownish gray (2.SY 6/2) dry; common, medium, prominent mottles of yellowish brown (10YR
S/6) moist, massive, no roots, medium acid. The upper, very friable part of the soil extends to a
depth of 20 inches to 40 inches bgs and ranges from dark grayish brown to dark yellowish brown.
A restrictive layer of glacial till was observed at or greater than 1.S feet below ground surface in
upland test plots.
GIS Mapping· Site Assessment· Wetland· Remediation· Habitat· Stormwater
4
Vegetation
Observed vegetation species in the test plots are presented on the data forms. Dominance was
determined using the using the AGOE 50/20 rule. Hydrophytic plants are those plants listed with
indicator status of OSL, FAGW, and/or FAG. A summary of the rationale for making the upland vs.
wetland determination for hydrophytic vegetation indicators at the plots is listed in the table below.
Dominant Hydrophytic Vegetation Identified in Test Plots
Test Common Name Scientific Name Stratum Indicator
Plot Status
1,2 Big Leaf Maple Acer macrophyllum Tree FACU
1,2 Red Alder Alnus rubra Tree FAC
1 Bitter Cherry Prunus emarginata -mol/is Tree FACU
1 Beaked Hazelnut Corylus cornuta Shrub FACU
1,2 Himalayan Blackberry Rubus discolor Shrub FACU
1 Holly /lex aquifolium Shrub None
2 Hawthorne Crataegus monogyna Shrub FACU
2 Osoberry Oemleria cerasiformis Shrub FACU
2 Cut/eaf Blackberry Rubus laciniatus Shrub FACU
2 Big Leaf Maple (saplings) Acer macrophy/lum Shrub FACU
2 Thimble Berry Rubus parviflourus Shrub FAC-
1 Bracken Fern Pferidium aquilinum Herb FACU
1 Colonial Bentgrass Agrostis capillaris tenuis Herb FAC
1 Orchard Grass Oactylis glomerata Herb FACU
2 Sword Fern Polystichum munitum Herb FACU
2 Trailing Blackberry Rubus ursinus vitifolius Herb FACU
Hydrology
Observed hydrology in the test plots are presented on the data forms. A summary of the rationale
for making the upland vs. wetland determination for the wetland hydrology indicators at the test
plots is listed in the table below.
Test
Plot
1
2
Inundated Saturated Water Sediment Drainage Stained Stunted
(S1' bgs) Marks Deposits Patterns Leaves
No No No No No No
No No No No No No
GIS Mapping· Site Assessment· Wetland· Remediation· Habitat· Stormwater
5
Plants
No
No
The rationale for making the upland and wetland determination after reviewing all indicators is
summarized in the table below.
WETLAND, STREAM, & UPLAND DETERMINATION RATIONALE
Test Problematic Hydric Dominant Wetland Water Wetland
Plot Soil Hydrophytic Hydrology Level Stream
Indicators Vegetation (bgs) Upland
1 No No No No >1.5' Upland
2 No No No No >1.5' Upland
10.0 EXCLUSIONS
The work effort did not include interviewing govemment agencies, attending meetings, applying for
or obtaining permits, performing a professional land survey, resolving violations (if any), designing
or engineering any structure, or trespassing onto off-site property.
11.0 CONCLUSION
Based on observations, review of collected data, and evaluation of readily available maps the
project site does not contain wetlands or streams at this time. The edges of wetlands and streams
were not identified within 200 feet of the project site.
Sincerely,
Jonathan M. Kemp
Professional Wetland Scientist and Wildlife & Fisheries Biologist
EnCo Environmental Corporation
Sent via e-mail
RozenblaLWetland_Recon_Nov_2013
GIS Mapping· Site Assessment· Wetland • Remediation • Habitat· Stormwater
6
APPENDIX A
FIGURE 1 -VICINITY
FIGURE 2 -TEST PLOT LOCA nONS
GIS Mapping· Site Assessment· Wetland· Remediation· Habitat. Stonnwater
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Date : 911212013 Source:
FIGURE 2 -TEST PLOT LOCATIONS
King County iMAP Map
[IN 1m .... ?' :::34-",-"6+ Q ••
tQ King County
APPENDIX B
PHOTOGRAPHIC LOG
GIS Mapping· Site Assessment· Wetland· Remediation· Habitat· Stormwater
Photo 1
Facing North
Project Site
Test Plot 1
Up land Plot
East-Central
Photo 3
Facing South
Project Site
Sample Plot 1
Upland Plot
East-Central
Photo 5
Top View
Project Site
Sample Plot 1
Upland Plot
East-Central
No Water At 1.5'
)
Photo 2
Facing East
Project Site
Test Plot 1
Upland Plot
East-Central
Photo 4
Facing West
Project Site
Sample Plot 1
Upland Plot
East-Central
Appendi. B
11.4.2013 Rosenblal-Renlon·1 Page 1
Photo 6
F aci ng No rth
Pro jec t Site
Test Pl ot 2
Up tand Pl ot
So uthw est Corner
Photo 8
Fa cing South
Project Site
Test Pl ot 2
Upland Plot
Southwest Corner
Photo 10
Top Vi ew
Test Plot 2
Up land Plot
Southwest Corne r
No Water At 1,5'
Photo 7
Facing East
Pr oject Si te
Test Plo t 2
Up land Pl ot
Southwest Corne r
Photo 9
Facing West
Project Sit e
Test Plot 2
Up land Pl ot
Southwest Co rner
Appendix B
11.4,2013 Ros en bla!·Renton ·1 Page 2