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G Eu O TECH 13256 Northeast 20th Street. Suite 16
CONSULTANTS, INC. �� � 7 %
Bellevue, 98005
(425)747-5618 FAX(425)747-8561
May 20, 2015
Classico Homes Inc.
j'W JN 15193
PO Box 5012 j
Lynnwood, Washington 98046 ilEW1OPMEal
Attention: Joe Schmaus coiliv,43 via email. classicohomes@gmail.com
Subject: Transmittal Letter — Geotechnical Engineering Study
Proposed Two Single -Family Residences
532 — 71 Avenue South
Edmonds, Washington
Dear Mr. Schmaus:
We are pleased to present this geotechnical engineering report for the two residences to be
constructed in Edmonds, Washington. The scope of our services consisted of exploring site
Surface and subsurface conditions, and then developing this report to provide recommendations for
general earthwork and design criteria for foundations and retaining walls. This work was
authorized by your acceptance of our proposal dated April 24, 2015.
The attached report contains a discussion of the study and our recommendations. Please contact
us if there are any questions regarding this report, or for further assistance during the design and
construction phases of this project.
Respectfully submitted,
GEOTECH CONSULTANTS, INC.
James H. Strange, P.E.
Associate
cc: Hagge Design /associates Inc. - Tom Hagge
via email. hag et esign@msn, com
TRC/JHS: at
GEOTECH CONSULTANTS, INC.
GEOTECHNICAL ENGINEERING STUDY
Proposed Two Single -Family Residences
532 — 71 Avenue South
Edmonds, Washington
This report presents the findings and recommendations of our geotechnical engineering study for
the site of the two proposed residences to be located in Edmonds.
We were provided with a site plan, floor plans, and elevation views prepared by Hagge Design
Associates Inc., dated April 29, 2015. Based on these plans, we understand that the development
will consist of two single-family residences with two stories. The eastern residence Will have a
partial basement that daylights toward the north. One residence will be located in the eastern
portion of the site and another will be located in the southwestern portion. The north side of the
residences will be close to the top of a steep, north -facing slope, and the west side of the
southwest residence will be close to the top of a steep, west -facing slope. Both residences will
have garages that will be accessed from a driveway along the south edge of the site, and the
eastern residence will have an additional garage at its north end. The southwestern residence will
have a deck north of the residence that will extend close to the steep northern slope.
The southwest residence will be constructed close to the existing ground surface, as will the south
half of the eastern residence. The garage and basement below the northern half of the east
residence will have floor elevations 13 and 11 feet, respectively, below the floor of the main level.
If the scope of the project changes from what we have described above, we should be provided
with revised plans in order to determine if modifications to the recommendations and conclusions of
this report are warranted.
SURFACE
The Vicinity Map, Plate 1, illustrates the general location of the site in Edmonds. The site is
bordered to the east by 711 Avenue South, and is otherwise surrounded with residences. We
understand that a house formerly occupied the site but has been removed. The site appears to
have been cleared, and is vegetated with sparse field grass.
The ground surface in the southern half of the site has a high point near the center of the southern
property line, and slopes gently down from the high point toward the west to east. Near the east
edge of the site the slope steepens and declines to the adjacent roadway. A slope about 5 feet
high near the southern property, line slopes steeply down from the neighboring property to the site.
A concrete block wall faces about the west half of that steep slope, which was likely caused by an
excavation to level the subject site.
A short distance west of the southern half of the site the ground surface slopes down toward the
west, at an inclination close to 2:1 (H:V). This slope has a height of about 15 to 20 feet.
The ground surface in the northern half of the site slopes at an inclination of 1.51 (H:V) down
toward the north. This slope is about 30 feet tall. A level pad on the east side of this slope is
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accessible from the adjacent 71 Avenue South, and appears to have been graded by cutting into
the slope and filling to the north.
We did not observe `Indications of instability of the steep slopes within the site, and we unserstand
that these slopes were granted a steep exemption based on previous study at the site (by others).
SUBSURFACE
The subsurface conditions were explored by excavating six test pits at the approximate locutions
shown on the Site Exploration Plan, Plate 2. Our exploration program was based on the proposed
construction, anticipated subsurface conditions and those encountered during exploration, and the
scope of work outlined in our proposal.
The test pits were excavated on May 1, 2015 with a rubber -tracked excavator. A geotechnical
engineer from our staff observed the excavation process, logged the test pits, and obtained
representative samples of the soil encountered. "Grab" samples of selected subsurface soil were
collected from the excavator bucket. The Test Pit Logs are attached to this report as Plates 3
through 5.
Soil Conditions
Test Pits 1, 4, 5, and 6 were located on or close to the steep northern slope. These
exploration encountered similar conditions that consisted of sand with gravel that was loose
or loose to medium -dense to depths of at least 6 feet.
In Test Pits 1 and 5 the sand with gravel was medium -dense below 6 and 7.5 feet,
respectively. The loose to medium -dense soil extended to the base of Test Pits 4 and 6 at
depths of 6 and 6.5 feet.
Test Pits 2 and 3 were located in the western portion of the site, more than 15 feet from the
tops of steep slopes. These explorations revealed loose to medium -dense sand with gravel
that became medium -dense 2.5 feet below the ground surface, and continued to the
maximum explored depths of 4.5 and 6 feet.
Groundwater Conditions
No groundwater seepage was observed in the test pits. It should be noted that groundwater
levels vary seasonally with rainfall and other factors,
The stratification lines on the logs represent the approximate boundaries between soil types at the
exploration locations. The actual transition between soil types may be gradual, and subsurface
conditions can vary between exploration locations. The logs provide specific subsurface
information only at the locations tested. The relative densities and moisture descriptions indicated
on the test pit logs are interpretive descriptions based on the conditions observed, during
excavation.
The compaction of test pit backfill was not in the scope of our services. Loose soil will therefore be
found in the area of the test pits. If this presents a problem, the backfill will need to be removed
and replaced with structural fill during construction.
GEOTECH CONSULTANTS, INC.
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GENERAL
JN 15193
Page 3
THIS SECTION CONTAINS A SUMMARY OF OUR STUDY AND FINDINGS FOR THE PURPOSES OF A
GENERAL OVERVIEW ONLY. MORE SPECIFIC RECOMMENDATIONS AND CONCLUSIONS ARE
CONTAINED IN THE REMAINDER OF THIS REPORT. ANY PARTY RELYING ON THIS REPORT SHOULD
READ THE ENTIRE DOCUMENT.
The test pits conducted for this study encountered sand with gravel that was loose or loose to
medium -dense on or close to steep slopes„ and was medium -dense at shallow depths in our
explorations that were more than 15 feet from the slopes.
We recommend that the northern sides of the residences and the west side of the southwest
residence be supported by pipe piles driven to refusal. Decks that extend from the residences
toward the adjacent steep slopes should also be supported with pipe piles and be tied back to the
main foundations with continuous footings. This foundation system will provide vertical support of
the structures by transferring vertical loads past the near -surface loose soil and into the underlying
medium -dense soil, It will also avoid placing any loads from the foundations onto the slope. The
remainder of the residence structural loads can be supported with conventional footing foundations,
provided they bear on native, medium -dense native soil.
Based on the soils revealed at the site, the soils at the core of the steep slopes are granular and
medium -dense. Therefore, it is our opinion the site slopes are stable with respect to deep-seated
slope failures. However, as with any steep slope in the Puget Bound area, the site slopes do have
a potential for shallow slope failures. We expect that any failures would be shallow skin slides up
to a few feet in depth. Such shallow soil movement will not impact the residences provided pipe
piles are used to support the portions of the residences close to the steep slopes, as recommended
above. To lower the potential for shallow soil movement, no fill soils should be placed between the
proposed residences and the steep slopes, and stormwater runoff should not be directed onto
steep slopes.
Although the sandy soils that underlie the site have a fairly high permeability, in our opinion
stormwater infiltration is not feasible for the project due to the steep slopes close to the proposed
development.
The erosion control measures needed during the site development will depend heavily on the
weather conditions that are encountered. We anticipate that a silt fence will be needed around the
downslope sides of any cleared areas. Existing pavements, ground cover, and landscaping should
be left in place wherever possible to minimize the amount of exposed soil. locked staging areas
and construction access roads should be provided to reduce the amount of soil or mud carried off
the property by trucks and equipment. Wherever possible, the access roads should follow the
alignment of planned pavements. Trucks should not be allowed to drive off of the rock -covered
areas. Out slopes and soil stockpiles should be covered with plastic during wet weather, Following
clearing or rough grading„ it may be necessary to mulch or hydroseed bare areas that will not be
immediately covered with landscaping or an impervious surface. On most construction projects, it
is necessary to periodically maintain or modify temporary erosion control measures to address
specific site ,and weather conditions.
The drainage and/or waterproofing recommendations presented in this report are intended only to
prevent active seepage from flowing through concrete walls or slabs. Even in the absence of active
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seepage into and beneath structures, water vapor can migrate through walls, slabs, and floors from
the surrounding soil, and can even be transmitted from slabs and foundation walls due to the
concrete curing process. Water vapor also results from occupant uses, such as cooking and
bathing. Excessive water vapor trapped within structures can result in a variety of undesirable
conditions, Including, but not limited to, moisture problems with flooring systems„ excessively moist
air within occupied areas, and the growth of molds, fungi, and other biological organisms that may
be harmful to the health of the occupants. The designer or architect must consider the potential
vapor sources and likely occupant uses, and provide sufficient ventilation, either passive or
mechanical, to prevent a build up of excessive water vapor within the planned structure.
Geotech Consultants, Inc. should be allowed to review the final development plans to verify that the
recommendations presented in this report are adequately addressed in the design. Such a plan
review would be additional work beyond the current scope of work for this study, and it may include
revisions to our recommendations to accommodate site, development, and geotechnical
constraints that become more evident during the review process.
We recommend including this report, in its entirety, in the project contract documents. This report
should also be provided to any future property owners so they will be aware of our findings and
recommendations.
SEISMIC CONSIDERATIONS
In accordance with the International Building Code (IBC), the site soil profile within 100 feet of the
ground surface is best represented by Site Class Type C (Stiff Site Class). As noted in the BSGS
website, the mapped spectral acceleration value for a 0.2 second (Ss) and 1.0 second period (Si)
equals 1.27g and 0.50g, respectively.
The IBC states that a site-specific seismic study need not be performed provided that the peak
ground acceleration be equal to SDS/2.5, where SDs is determined in ASCD 7. It is noted that SDS is
equal to 2/3Sms. SMs equals Fe times Ss, where Fa is determined in Table 11.4-1. For our site, F.
1.0. The calculated peak ground acceleration that we utilized' for the seismic -related parameters
(earth pressures and seismic surcharges) of this report equals 0.348.
The site soils are not susceptible to seismic liquefaction because of their medium -dense nature and
the absence of near -surface groundwater.
CONVENTIONAL FOUNDATIONS
The proposed structure can be supported on conventional continuous and -
on undisturbed, medium -dense, native soil. We recommend that continuous and individual
y
•••- minimum widthsof _ • 16 inches, respectively. •••tings •••
be
bottomed at least 18 inches below the lowest adjacent finish ground surface for protection against
frost and erosion, The local building codes should be reviewed to determine if different footing
widths or embedment depths are required. Footing subg!rade!s must be cleaned of loose or
Asturbed soil prior to pouring concrete. Depending upon site and equipment constraints, this may
require removing the disturbed soil by hiand.
An allowable bearing pressure of 2,000 pounds per square foot (psf) is appropriate for footings
supported on competent native soil. A one-third increase in this design bearing pressure may be
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used when considering short-term wind or seismic loads. For the above design criteria, it is
anticipated that the total post -construction settlement of footings founded on competent native soil
will be about one -inch, with differential settlements on the order of one -half-inch in a distance of 30
feet along a continuous footing with a uniform load.
Lateral loads due to wired or seismic forces may be resisted, by friction between the foundation and
the bearing soil, or by passive earth pressure ,acting on the vertical, embedded portions of the
foundation. For the latter condition, the foundation must be either poured directly against relatively
level, undisturbed soil or be surrounded by level, well -compacted fill. We recommend using the
following ultimate values for the foundation's resistance to lateral loading:
Coefficient of Friction 0.45
Passive Earth Pressure 300 pcf
Where: pcf is Pounds per Cubic Foot, and Passive Earth
Pressure is computed using the equivalent fluid density.
If the ground in front of a foundation is loose or sloping, the passive earth pressure given above will
not be appropriate. We recommend maintaining a safety factor of at least 1.5 for the foundation's
resistance to lateral loading, when using the above ultimate values.
PIPE PILES
Three- or 4 -inch -diameter pipe piles driven with a 650- or 800- or 1,100 -pound hydraulic
jackhammer to the following final penetration rates may be assigned the following compressive
capacities,
3 inches 12 sec/inch 10 sec/inch6 sec/inch 6 tons
4 inches 20 sec/inch 15 sec/inch±7��10 sec/inch 10 tons
Note: The refusal criteria indicated in the above table ,are valid only for pipe piles that are installed
using a hydraulic impact hammer carried on leads that allow the hammer to sit on the top of the pile
during driving. If the piles are installed by alternative methods, such as a vibratory hammer or a
hammer that is hard -mounted to the installation machine, numerous load tests to 200 percent of the
design capacity would be necessary to substantiate the allowable pile load, The appropriate number of
load tests would need to be determined at the time the contractor and installiation method are chosen,
As a minimum, Schedule 40 pipe should be used. The site soils should not be highly corrosive.
Considering this, it is our opinion that standard "black" pipe can be used, and corrosion protection,
such as galvanizing, is not necessary for the pipe piles.
Smaller, 2 -inch -diameter pipe piles with less capacity can be used to support unroofed decks close
to steep slopes, A 2-inch-diamieter pipe pile driven with a minimum 90 -pound jackhammer or a
140-piound Rhino hammer to a final penetration rate of 1 -inch or less for one minute of continuous
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driving may be assigned an allowable compressive load of 2 tons. Extra -strong steel pipe should
be used for these 2 -inch piles.
We recommend a minimum pile length of 15 feet to achieve embedment into medium -dense,
native soils. This is simply a minimum length needed to develop sufficient capacity. Our
experience with installation of small -diameter pipe piles indicates that it is likely that they will be
longer than this minimum length to reach refusal.
Pile caps and grade beams should be used to transmit loads to the piles. Isolated pile caps should
include a minimum of two piles to reduce the potential for eccentric loads being applied to the piles
and any outboard deck supports on the slope side of the residences should be attached to the main
foundation with nominally reinforced footings to restrain the pile tops laterally. Subsequent sections
of pipe can be connected with slip or threaded couplers, or they can be welded together. If slip
couplers are used, they should fit snugly into the pipe sections. This may require that shims be
used or that beads of welding flux be applied to the outside of the coupler.
Lateral loads due to wind or seismic forces may be resisted by passive earth pressure acting on the
vertical, embedded portions of the foundation. For this condition, the foundation must be either
poured directly against relatively level, undisturbed soil or be surrounded by level compacted fill.
We recommend using a passive earth pressure of 250 pounds per cubic foot (pcf) for this
resistance. If the ground in front of a foundation is loose or sloping (on the downslope side of the
houses/decks), the passive earth pressure given above will not be appropriate. We recommend a
safety factor of at least 1.5 for the foundation's resistance to lateral loading, when using the above
ultimate passive value. Due to their small diameter, the lateral capacity of vertical pipe piles is
relatively small. However, if lateral resistance in addition to passive soil resistance is required, we
recommend driving battered piles in the same direction as the applied lateral load. The lateral
capacity of a battered pile is equal to one-half of the lateral component of the allowable
compressive load, with a maximum allowable lateral capacity of 1,000 pounds. The allowable
vertical capacity of battered piles does not need to be reduced if the piles are battered steeper than
1:5 (Horizontal:Vertical).
FOUNDATION AND RETAINING WALLS
Retaining walls backfilled on only one side should be designed to resist the lateral earth pressures
imposed by the soil they retain. The following recommended parameters are for walls that restrain
level backfill:
Where: pcf is Pounds per Cubic Foot, and Active and Passive
Earth Pressures are computed using the equivalent fluid
pressures.
* For a restrained wall that cannot deflect at least 0.002 times its
height, a uniform lateral pressure equal to 10 psf times the height
of the waif afwauld be added to the above active equivalent fluid
pressure.
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The design values given above do not include the effects of any hydrostatic pressures behind the
walls and assume that no surcharges, such as those caused by slopes, vehicles, or adjacent
foundations will be exerted on the walls. If these conditions exist, those pressures should be added
to the above lateral soil pressures. Where sloping backfill is desired behind the walls, we will need
to be given the wall dimensions and the slope of the backfill in order to provide the appropriate
design earth pressures. The surcharge due to traffic loads behind a wall can typically be
accounted for by adding a uniform pressure equal to 2 feet multiplied by the above active fluid
density. Heavy construction equipment should not be operated behind retaining and foundation
walls within a distance equal to the height of a wall, unless the walls are designed for the additional
lateral pressures resulting from the equipment.
The values given above are to be used to design only permanent foundation and retaining walls
that are to be backfilled, such as conventional walls constructed of reinforced concrete or masonry.
It is not appropriate to use the above earth pressures and soil unit weight to back -calculate soil
strength parameters for design of other types of retaining walls, such as soldier pile, reinforced
earth, modular or soil nail walls. We can assist with design of these types of walls, if desired. The
passive pressure given is appropriate only for a shear key poured directly against undisturbed
native soil, or for the depth of level, well -compacted fill placed in front of a retaining or foundation
wall. The values for friction and passive resistance are ultimate values and do not include a safety
factor. Restrained wall soil parameters should be utilized for a distance of 1.5 times the wall height
from corners or bends in the walls. This is intended to reduce the amount of cracking that can
occur where a wall is restrained by a corner,
The surcharge wall loads that could be imposed by the design earthquake can be modeled
by adding a uniform lateral pressure to the above -recommended active pressure. The
recommended surcharge pressure is 8H pounds per square foot (psf), where H is the
design retention height of the wall. Using this increased pressure, the safety factor against
sliding and overturning can be reduced to 1.2 for the seismic analysis.
Retajg6ga Wall Back frltl and IJLiate roo&xr
Backfill placed behind retaining or foundation walls should be coarse, free -draining
structural fill containing no organics. This backfill should contain no more than 5 percent silt
or clay particles and have no gravel greater than 4 inches in diameter. The percentage of
particles passing the No. 4 sieve should be between 25 and 70 percent. If the native sand
is used as backfill, a drainage composite similar to Miradrain 6000 should be placed against
the backfilled retaining walls. The drainage composites should be hydraulically connected
to the foundation drain system.
The purpose of these backfill requirements is to ensure that the design criteria for a
retaining wall are not exceeded because of a build-up of hydrostatic pressure behind the
wall. Also, subsurface drainage systems are not intended to handle large volumes of water
from surface runoff. The top 12 to 18 inches of the backfill should consist of a compacted,
relatively impermeable soil or topsoil, or the surface should be paved. The ground surface
must also slope away from backfilled walls to reduce the potential for surface water to
percolate into the backfill. Water percolating through pervious surfaces (pavers, gravel,
permeable pavement, etc.) must also be preventedfrom flowing toward walls or into the
backfill zone. The compacted subgrade below pervious surfaces and any associated
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drainage layer should therefore be sloped away. Alternatively, a membrane and subsurface
collection system could be provided below a pervious surface.
It is critical that the wall backfill be placed in lifts and be properly compacted, in order for the
above -recommended design earth pressures to be appropriate. The wall design criteria
assume that the backfill will be well -compacted in lifts no thicker than 12 inches. The
compaction of backfill near the walls should be accomplished with hand -operated
equipment to prevent the walls from being overloaded by the higher soil forces that occur
during compaction. The section entitled General Earthwork and Structural Fill contains
additional recommendations regarding the placement and compaction of structural fill
behind retaining and foundation walls.
The above recommendations are not intended to waterproof below -grade walls, or to
prevent the formation of mold, mildew or fungi in interior spaces. Over time, the
performance of subsurface drainage systems can degrade, subsurface groundwater flow
patterns can change, and utilities can break or develop leaks. Therefore, waterproofing
should be provided where future seepage through the walls is not acceptable. This typically
includes limiting cold joints and wall penetrations, and using bentonite panels or
membranes on the outside of the walls. There are a variety of different waterproofing
materials and systems, which should be installed by an experienced contractor familiar with
the anticipated construction and subsurface conditions. Applying a thin coat of asphalt
emulsion to the outside face of a wall is not considered waterproofing, and will only help to
reduce moisture generated from water vapor or capillary action from seeping through the
concrete. As with any project, adequate ventilation of basement and crawl space areas is
important to prevent a build up of water vapor that is commonly transmitted through
concrete walls from the surrounding soil, even when seepage is not present. This is
appropriate even when waterproofing is applied to the outside of foundation and retaining
walls. We recommend that you contact an experienced envelope consultant if detailed
recommendations or specifications related to waterproofing design, or minimizing the
potential for infestations of mold and mildew are desired.
The General, Slabs -On -Grade, and Drainage Considerations sections should be
reviewed for additional recommendations related to the control of groundwater and excess
water vapor for the anticipated construction.
SLABS -ON -GRADE
The building floors can be constructed as slabs -on -grade atop competent native soil, or on
structural fill. The subgrade soil must be in a firm, non -yielding condition at the time of slab
construction or underslab fill placement. Any soft areas encountered should be excavated and
replaced with select, imported structural fill.
Even where the exposed soils appear dry, water vapor will tend to naturally migrate upward through
the soil to the new constructed space above it. This can affect moisture -sensitive flooring, cause
imperfections or damage to the slab, or simply allow excessive water vapor into the space above
the slab. All interior slabs -on -grade should be underlain by a capillary break drainage layer
consisting of a minimum 4 -inch thickness of clean gravel or crushed rock that has a fines content
(percent passing the No. 200 sieve) of less than 3 percent and a sand content (percent passing the
No. 4 sieve) of no more than 10 percent. Pea gravel or crushed rock are typically used for this
layer.
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As noted by the American Concrete Institute (ACI) in the Guides for Concrete Floor and Slab
Structures, proper moisture protection is desirable immediately below any on -grade slab that will be
covered by tile, wood, carpet, impermeable floor coverings, or any moisture -sensitive equipment or
products. ACI also notes that vapor retarders such as 6 -mil plastic sheeting have been used in the
past, but are now recommending a minimum 10 -mil thickness for better durability and long term
performance. A vapor retarder is defined as a material with a permeance of less than 0.3 perms,
as determined by ASTM E 96. It is possible that concrete admixtures may meet this specification,
although the manufacturers of the admixtures should be consulted. Where vapor retarders are
used under slabs, their edges should overlap by at least 6 inches and be sealed with adhesive
tape. The sheeting should extend to the foundation walls for maximum vapor protection. If no
potential for vapor passage through the slab is desired, a vapor barrier should be used. A vapor
barrier, as defined by ACI, is a product with a water transmission rate of 0.01 perms when tested in
accordance with ASTM E 96. Reinforced membranes having sealed overlaps can meet this
requirement.
In the recent past, ACI (Section 4.1,6) recommended that a minimum of 4 inches of well -graded
compactible granular material, such as a 5/8 -inch -minus crushed rock pavement base, be placed
over the vapor retarder or barrier for their protection, and as a "blotter" to aid in the curing of the
concrete slab. Sand was not recommended by ACI for this purpose, However, the use of material
over the vapor retarder, is controversial as noted in current ACI literature because of the potential
that the protection/blotter material can become wet between the time of its placement and the
installation of the slab. If the material is wet prior to slab placement, which is always possible in the
Puget Sound area, it could cause vapor transmission to occur up through the slab in the future,
essentially destroying the purpose of the vapor barrier/retarder. Therefore, if there is a potential
that the protection/blotter material will become wet before the slab is installed, ACI now
recommends that no protection/blotter material be used. However, ACI then recommends that,
because there is a potential for slab curl due to the loss of the blotter material, joint spacing in the
slab be reduced, a low shrinkage concrete mixture be used, and "other measures" (steel
reinforcing, etc.) be used. ASTM E-1643-96 "Standard practice for Installation of Water Vapor
Retarders Used in Contact with Earth or Granular Fill Under Concrete Slabs" generally agrees with
the recent ACI literature.
We recommend that the contractor, the project materials engineer, and the owner discuss these
issues and review recent ACI literature and ASTM E-1643 for installation guidelines and guidance
on the use of the protection/blotter material.
The General, Permanent Foundation and Retaining Walls, and Drainage Considerations
sections should be reviewed for additional recommendations related to the control of groundwater
and excess water vapor for the anticipated construction,
EXCAVATIONS AND SLOPES
Excavation slopes should not exceed the limits specified in local, state, and national government
safety regulations, Temporary cuts to a depth of about 4 feet may be attempted vertically in
unsaturated soil, if there are no indications of slope instability, However, vertical cuts should not be
made near property, boundaries, or existing utilities and structures, Based upon Washington
Administrative Code (WAC) 296, Part N, the soil at the subject site would generally be classified as
Type B. Therefore, temporary cut slopes greater than 4 feet in height should not be excavated at
an inclination steeper than 1: 1 (Horizontal:Vertical), extend'ing continuously between the top and
the bottom of
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The above -recommended temporary slope inclination is based on the conditions exposed in our
explorations, and on what has been successful at other sites with similar soil conditions. It is
possible that variations in soil and groundwater conditions will require modifications to the
inclination at which temporary slopes can stand. Temporary cuts are those that will remain
unsupported for a relatively short duration to allow for the construction of foundations, retaining
walls, or utilities. Temporary cut slopes should be protected with plastic sheeting during wet
weather, It is also important that surface runoff be directed away from the top of temporary slope
cuts. Cut slopes should also be backfilled or retained as soon as possible to reduce the potential
for instability. Please note that sand or loose soil can cave suddenly and without warning.
Excavation, foundation, and utility contractors should be made especially aware of this potential
danger, These recommendations may need to be modified if the area near the potential cuts has
been disturbed in the past by utility installation, or if settlement -sensitive utilities are located nearby.
All permanent cuts into native soil should be inclined no steeper than 2:1 (H:V). Water should not
be allowed to flow uncontrolled over the top of any temporary or permanent slope. All permanently
exposed slopes should be seeded with an appropriate species of vegetation to reduce erosion and
improve the stability of the surficial layer of soil, Topsoil is often placed on regraded slopes to
promote growth of vegetation. Proper preparation of the regraded surface, and use of appropriate
topsoil is necessary to prevent the topsoil from sliding off the slope. This is most likely to occur
following extended wet weather if a silty topsoil is used. On steeper slopes, it may be necessary to
"track walk" the slope or cut small grooves across the slope prior to placing the topsoil.
DRAINAGE CONSIDERATIONS
Footing drains should be used where: (1) crawl' spaces or basements will be below a structure; (2)
a slab is below the outside grade; or, () the outside grade does not slope downward from a
building. Drains should also be placed at the base of all earth -retaining walls. These drains should
be surrounded by at least 6 inches of 1 -inch -minus, washed rock that is encircled' with non -woven,
geotextile filter fabric (Mirafi 140N, Supac 4NP, or similar material). At its highest point, a
perforated pipe invert should be at least 6 inches below the bottom of a slab floor or the level of a
crawl space. The discharge pipe for subsurface drains should be sloped for flow to the outlet point..
Roof and surface water drains must not discharge into the foundation drain system, A typical drain
detail is attached to this report as Plate 6. For the best long-term performance„ perforated PVC
pipe is recommended for all subsurface drains.
As a minimum, a vapor retarder, as defined in the Slabs -Om -Grade section, should be provided in
any crawl space area to limit the transmission of water vapor from the underlying soils. Crawl space
grades are sometimes left near the elevation of the bottom of the footings. As a result, an outlet
drain is recommended for all crawl spaces to prevent an accumulation of any water that may
bypass the footing drains. Providing even a few inches of free draining gravel' underneath the
vapor retarder limits the potential for seepage to build up on top of the vapor retarder.
No groundwater was observed during our field work. If seepage is encountered in an excavation, it
should be drained from the site by directing it through drainage ditches, perforated pipe, or French
GEOTECH CONSULTANTS, INC.
Classico Homes Inc. JN 15193
May 20, 2015 Page 11
drains, or by pumping it from sumps interconnected by shallow connector trenches at the bottom of
the excavation.
The excavation and site should be graded so that surface water is directed off the site and away
from the tops of slopes. Water should not be allowed to stand in any area where foundations,
slabs, or pavements are to be constructed. Final site grading in areas adjacent to buildings should
slope away at least 2 percent, except where the area is paved. Surface drains should be provided
where necessary to prevent ponding of water behind foundation or retaining walls. A discussion of
grading and drainage related to pervious surfaces near walls and structures is contained in the
Foundation and Retaining Walls section. Water from roof, storm water, and foundation drains
should not be discharged onto slopes; it should be tightlined to a suitable outfall located away from
any slopes.
GENERAL EARTHWORK AND STRUCTURAL FILL
All building and pavement areas should be stripped of surface vegetation, topsoil, organic soil, and
other deleterious material. The stripped or removed materials should not be mixed with any
materials to be used as structural fill, but they could be used in non-structural areas, such as
landscape beds.
Structural fill is defined as any fill, including utility backfill, placed under, or close to, a building,
behind permanent retaining or foundation walls, or in other areas where the underlying soil needs
to support loads. All structural fill should be placed in horizontal lifts with a moisture content at, or
near, the optimum moisture content. The optimum moisture content is that moisture content that
results in the greatest compacted dry density. The moisture content of fill is very important and
must be closely controlled during the filling and compaction process.
Fills placed on sloping ground should be keyed into the competent native soils. This is typically
accomplished by placing and compacting the structural fill on level benches that are cut into the
competent soils. The allowable thickness of the fill lift will depend on the material type selected, the
compaction equipment used, and the number of passes made to compact the lift. The loose lift
thickness should not exceed 12 inches. We recommend testing the fill as it is placed. If the fill is
not sufficiently compacted, it can be recompacted before another lift is placed. This eliminates the
need to remove the fill to achieve the required compaction. The following table presents
recommended relative compactions for structural fill:
Where: Minimum Relative Compaction Is the ratio, expressed In
percentages, of the compacted dry density to the maximum dry
density, as determined in accordance with ASTM Test
Designation D 1557-91 (Modified Proctor).
GEOTECH CONSULTANTS, INC.
Classico Homes Inc. JN 15193
May 20, 2015 Page 12
Structural fill that will be placed in wet weather should consist of a coarse, granular soil with a silt or
clay content of no more than 5 percent. The percentage of particles passing the No. 200 sieve
should be measured from that portion of soil passing the three -quarter -inch sieve.
LIMITATIONS
The conclusions and recommendations contained in this report are based on site conditions as
they existed at the time of our exploration and assume that the soil and groundwater conditions
encountered in the test pits are representative of subsurface conditions on the site. If the
subsurface conditions encountered during construction are significantly different from those
observed in our explorations, we should be advised at once so that we can review these conditions
and reconsider our recommendations where necessary. Unanticipated conditions are commonly
encountered on construction sites and cannot be fully anticipated by merely taking samples in test
pits. Subsurface conditions can also vary between exploration locations. Such unexpected
conditions frequently require making additional expenditures to attain a properly constructed
project. It is recommended that the owner consider providing a contingency fund to accommodate
such potential extra costs and risks. This is a standard recommendation for all projects.
The recommendations presented in this report are directed toward the protection of only the
proposed structures from damage due to slope movement. Predicting the future behavior of steep
slopes and the potential effects of development on their stability is an inexact and imperfect
science that is currently based mostly on the past behavior of slopes with similar characteristics.
Landslides and soil movement can occur on steep slopes before, during, or after the development
of property. At additional cost, we can provide recommendations for reducing the risk of future
movement on the steep slopes, which could involve regrading the slopes or installing subsurface
drains or costly retaining structures, The owner of any property containing, or located close to
steep slopes must ultimately accept the possibility that some slope movement could occur,
resulting in possible loss of ground or damage to the facilities around the proposed building
residences.
This report has been prepared for the exclusive use of Classico Homes Inc. and its representatives
for specific application to this project and site. Our conclusions and recommendations are
professional opinions derived in accordance with our understanding of current local standards of
practice, and within the scope of our services. No warranty is expressed or implied. The scope of
our services does not include services related to construction safety precautions, and our
recommendations are not intended to direct the contractor's methods, techniques, sequences, or
procedures, except as specifically, described in our report for consideration in design. Our services
also do not include assessing or minimizing the potential for biological hazards, such as mold,
bacteria, mildew and fungi in either the existing or proposed site development.
ADDITIONAL„..... SERVICES
Oeotech Consultants, Inc. should be retained to provide geotechnical consultation, testing, and
observation services during construction. This is to confirm that subsurface conditions are
consistent with those indicated by our exploration, to evaluate whether earthwork and foundation
construction activities comply with the general intent of the recommendations presented in this
report, and to provide suggestions for design changes in the event subsurface conditions differ
from those anticipated prior to the start of construction. However, our work would not include the
GEOTECH CONSULTANTS, INC.
Classico Homes Inc.
May 20, 2015
JN 15193
Page 13
supervision or direction of the actual work of the contractor and its employees or agents. Also, job
and site safety, and dimensional measurements, will be the responsibility of the contractor.
During the construction phase, we will provide geotechnical observation and testing services when
requested by you or your representatives. Please be aware that we can only document site work
we actually observe. It is still the responsibility of your contractor or on-site construction team to
verify that our recommendations are being followed, whether we are present at the site or not.
The following plates are attached to complete this report:
Plate 1 Vicinity Map
Plate 2 Site Exploration Plan
Plates 3 - 5 Test Pit Logs
Plate 6 Typical Footing Drain Detail
We appreciate the opportunity to be of service on this project. Please contact us if you have any
questions, or if we can be of further assistance.
TRC/JHS:at
Respectfully submitted,
GEOTECH CONSULTANTS, INC.
James H. Strange, Jr., RE,
Associate
GEOTECH CONSULTANTS, INC.
GEOT'ECH.
CONSULTANTS, MC.
(Source: M Owft Mapft64 2013)
VICINITY MAP
532 - 7th Avenue South
Edmonds, Washington
Job No: Date: Plate:
15193 1 May 2015
TP -4
Nem 2 S TOR Y
Rew NOE
w T
TP -3
CNIST&Y
CAR
AT FIR5T
FLCCR AT 4d -PIM
4AAAM
dw
/-2—To T
TP
ILI—
A,201-0- MOE
ACCEM AND
I UTUTY EABEPINT
logo
Lsg"n :
(j Test Pit Location
GEOTECH
CONSULTANTS, INC.
DWYeWAY tl
AT LCUOR
GARAGE r
a
0
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67ACKEP
IBLQ=
RVANNO
10A. 1, rrp.
'hl
SITE EXPLORMION PLAN
532 - 7th Avenue South
Edmonds, Washington
Job No: Vale: to:
15193 L May 2015
L No Scale 21
a MUNI E
LOT 2
LOT
TP -4
Nem 2 S TOR Y
Rew NOE
w T
TP -3
CNIST&Y
CAR
AT FIR5T
FLCCR AT 4d -PIM
4AAAM
dw
/-2—To T
TP
ILI—
A,201-0- MOE
ACCEM AND
I UTUTY EABEPINT
logo
Lsg"n :
(j Test Pit Location
GEOTECH
CONSULTANTS, INC.
DWYeWAY tl
AT LCUOR
GARAGE r
a
0
U)
67ACKEP
IBLQ=
RVANNO
10A. 1, rrp.
'hl
SITE EXPLORMION PLAN
532 - 7th Avenue South
Edmonds, Washington
Job No: Vale: to:
15193 L May 2015
L No Scale 21
5
10
15
5
10
15
o 'ep
TEST PIT 1
Description
l opsoil over;
FILL Gray"brown SAND with gravel, fine to coarse-grained, moist, loose (FILL)
SW [.1 uray-brown SAND with gravel, fine to coarse-grained, moist, medium -dense
* Test Pit terminated at 11 feet on May 1, 2015.
* No groundwater observed during excavation.
* Caving observed below 0 feet during excavation.
50 0
10- 0J
s
TEST PIT 2
Description
i opsin over;
Cray -brown SAND with gravel, fine to coarse-grained, moist, loose to medium -dense
-becomes medium -dense
* Test Pit terminated at 6 feet on May 1, 2015.
* No groundwater observed during excavation.
* No caving observed during excavation.
GEOTLCH
CONSULTANTS, INC.
TEST PIT LOG
532 - 7th Avenue South
Edmonds, Washington
Job Date: Logged by: Plate:
15193 May 2015 1 TRC 3
5
10
15
M
10
15
oe '
Oxo
S
TEST PIT 3
Description
opsoi over;
Brown SAND with gravel, fine to coarse-grained, moist, loose to medium -dense
-becomes medium -dense and gray -brown
* Test Pit terminated at 4.5 feet on May 1, 2015.
* No groundwater observed during excavation.
* No caving observed during excavation.
TEST PIT 4
Description
04",1
opsoi over;
S, Brown SAND with gravel, fine to coarse-grained, moist, loose (Fill)
-becomes loose to medium -dense and gray -brown (Possible Fill)
r«
* Test Pit terminated at 6 feet on May 1, 2015.
* No groundwater observed during excavation.
* Caving observed below 0 feet during excavation.
GEOTECH
CONSULTANT'S, INC.
TEST PIT LOG
532 - 7th Avenue South
Edmonds, Washington
Job Date: Logged by: P/ete:
15193 May 2015 TRC ,4
5
10
15
b1
10
i6"
TEST PIT 5
Description
...............................
Topsoil over;
Brown SAND with gravel, fine to coarse-grained, moist, loose to medium -dense (FI
rown SAND with gravel, fine to coarse-grained, moist, loose to medium -dense
* Test Pit terminated at 8 feet on May 1, 2015.
* No groundwater observed during excavation.
* No caving observed during excavation.
�911-111
�.
TEST PIT 6
Description
Topsoil over;
Brown SAND with gravel, fine to coarse-grained, moist, loose to medium -dense
* Test Pit terminated at 6.5 feet on May 1, 2015.
* No groundwater observed during excavation.
* No caving observed during excavation.
G EOT CH
CONSULTANTS, INC.
TEST PIT LOG
532 - 7th Avenue South
Edmonds, Washington
Job Date: Logged bY: Plate:
15193 May 2015 TRC 5
Slope backfill away from
foundation. Provide surface
drains where necessary.
Backfill
(See text for
requirements)
Nonwoven Geotextile
Washed Rock Filter Fabric
(7/8" min. size)
Tightline Roof Drain
(Do not connect to footing drain)
Possible Slab
O,� .�%��,¢id�cr Bop
t?
o a p w o 'w"?, o « C.Y rr ro �
e��. *�,
w� ��C? 6 a
4" min. 'o o"1 Vapor Retarder/Barrier and
Capillary Break/Drainage Layer
(Refer to Report text)
4" Perforated Hard PVC Pipe
(Invert at least 6 inches below
slab or crawl space. Slope to
drain to appropriate outfall.
Place holes downward.)
NOTES:
(1) In crawl spaces, provide an outlet drain to prevent buildup of water that
bypasses the perimeter footing drains.
(2) Refer to report text for additional drainage, waterproofing, and slab considerations.
G OTECH
CONSULTANTS, INC.
FOOTING DRAIN DETAIL
532 - 7th Avenue South
Edmonds, Washington
Job Nd I Dale: Plate:
15193 Mav 2015 L 1 6