HomeMy WebLinkAboutSNOW RIDGE APARTMENTS - FDP240003 - SUBMITTAL DOCUMENTS - ROUND 1 - Geotechnical (Soils) Report (3)
Soilogic, Inc.
3522 Draft Horse Court • Loveland, CO 80538 • (970) 535-6144
September 14, 2023
MMD Built
1425 Pikes Peak Avenue
Fort Collins, Colorado 80524
Attn: Matt Deault
Re: Geotechnical Subsurface Exploration Report
Proposed Remodel & Additions to Existing Residence
Tract 2 & Part of Tract 3, Maxfield
1509 S. Shields Street
Fort Collins, Colorado
Soilogic Project # 23-1207
Mr. Deault:
Soilogic, Inc. (Soilogic) personnel have completed the geotechnical subsurface exploration
you requested for the proposed remodel and additions to the existing residential structure
located at 1509 S. Shields Street, in Fort Collins, Colorado. The results of our subsurface
exploration and pertinent geotechnical engineering recommendations are included with
this report.
We understand the existing residence to receive the remodel and additions consists of a
split-level (1½-story) wood-frame structure constructed over a basement and contains two
residential units. We understand the proposed remodel improvements will include the
reconfiguration of interior partition walls within the existing residence and demolition of
the existing attached garage. We understand the additions to the residence will consist of
two-story wood frame structures constructed over crawl spaces in order to create six (6)
additional residential units. Foundation loads for new improvements are expected to be
relatively light, with continuous wall loads less than 3.5 kips per lineal foot and individual
column loads (if any) less than 75 kips. Small grade changes (if any) are anticipated to
develop finish site grades in the areas of the proposed improvements.
The purpose of our exploration was to describe the subsurface conditions encountered in
the completed site borings and develop the test data necessary to provide recommendations
concerning design and construction of new foundations as well as an assessment of the
result of increased foundation loads on the existing structure foundations and support of
Geotechnical Subsurface Exploration Report
Proposed Remodel & Additions to Existing Residence
1509 S. Shields Street, Fort Collins, Colorado
Soilogic Project # 23-1207
2
floor slabs (if any) and site pavements. Pavement section design options for private site
drive and parking areas are also included. The conclusions and recommendations outlined
in this report are based on results of the completed field and laboratory testing and our
experience with subsurface conditions in this area.
SITE DESCRIPTION
The proposed remodel and addition improvements will be constructed to the existing
residence situated on Tract 2 & Part of Tract 3 in the Maxfield residential neighborhood,
located at 1509 S. Shields Street in Fort Collins, Colorado. We anticipate the existing
residence is supported by some type of spread footing foundation system. At the time of
our site exploration, the area surrounding the residence contained several mature, medium
to large-diameter deciduous and coniferous trees, and various landscape and flatwork
improvements. The ground surface was observed to be relatively level, with the maximum
difference in ground surface elevation across the existing residence and proposed addition
footprints estimated to be on the order of about two (2) to three (3) feet or less.
EXPLORATION AND TESTING PROCEDURES
To develop subsurface information in the areas of the proposed additions and site
pavements, five (5) soil borings were extended to depths between approximately 5 and 30
feet below present site grade within/near the proposed addition and new pavement areas.
The boring locations were established in the field by Soilogic personnel based on staking
done by the client to indicate the locations of select building corners and proposed
pavement improvement areas. A diagram indicating the approximate boring locations is
included with this report. The boring locations indicated on this diagram should be
considered accurate only to the degree implied by the methods used by the client to make
the field measurements. Graphic logs of the auger borings are also included.
The test holes were advanced using 4-inch diameter, continuous-flight auger powered by a
truck-mounted CME-45 drill rig. Samples of the subsurface materials were obtained at
regular intervals using California barrel sampling procedures in general accordance with
ASTM specification D-1586. Penetration resistance measurements were obtained by
driving the standard sampling barrel into the substrata using a 140-pound hammer falling
Geotechnical Subsurface Exploration Report
Proposed Remodel & Additions to Existing Residence
1509 S. Shields Street, Fort Collins, Colorado
Soilogic Project # 23-1207
3
a distance of 30 inches. The number of blows required to advance the sampler a distance
of 12 inches is recorded and helpful in estimating the consistency, relative density or
hardness of the soils/bedrock encountered. In the California barrel sampling procedure,
lesser disturbed samples are obtained in removable brass liners. Samples of the subsurface
materials obtained in the field were sealed and returned to the laboratory for further
evaluation, classification and testing.
The samples collected were tested in the laboratory to measure natural moisture content
and were visually classified in accordance with the Unified Soil Classification System
(USCS). The USCS group symbols are indicated on the attached boring logs. An outline
of the USCS classification system is included with this report.
As part of the laboratory testing, a calibrated hand penetrometer (CHP) was used to
estimate the unconfined compressive strength of essentially cohesive specimens. The CHP
also provides a more reliable estimate of soil/bedrock consistency than tactual observation
alone. Dry density, Atterberg limits, -200 wash and swell/consolidation tests were
completed on selected samples to help establish specific soil/bedrock characteristics.
Atterberg limits tests are used to determine soil/bedrock plasticity. The percent passing the
#200 size sieve (-200 wash) test is used to determine the percentage of fine-grained
materials (clay and silt) in a sample. Swell/consolidation tests are performed to evaluate
soil/bedrock volume change potential with variation in moisture content. The results of the
completed laboratory tests are outlined on the attached boring logs and swell/consolidation
test summaries. Water-soluble sulfate (WSS) content tests are currently being completed
on two (2) selected samples to help evaluate corrosive soil characteristics with respect to
buried concrete and results will be provided as they become available.
SUBSURFACE CONDITIONS
The materials encountered in the completed site borings can be summarized as follows.
Approximately 2 to 6 inches of turf/sod vegetation and topsoil, concrete flatwork or asphalt
pavement were encountered at the surface at the boring locations, underlain by dark brown/
red-brown/beige silty, sandy lean clay which varied to silty, clayey sand. The lean clay/
silty, clayey sand varied from medium stiff to hard in terms of consistency, or from loose
to medium dense in terms of relative density, exhibited low swell potential at current
Geotechnical Subsurface Exploration Report
Proposed Remodel & Additions to Existing Residence
1509 S. Shields Street, Fort Collins, Colorado
Soilogic Project # 23-1207
4
moisture and density conditions, and extended to the bottom of each boring at depths
between approximately 5 and 30 feet below present site grade.
The stratigraphy indicated on the included boring logs represents the approximate location
of changes in soil and/or bedrock types. Actual changes may be more gradual than those
indicated.
Groundwater was measured in boring B-3 at a depth of about 17 feet below ground surface,
but was not encountered in any of the other borings to the depths explored when checked
immediately after the completion of drilling. When checked about seven (7) days after
drilling, groundwater level remained unchanged in boring B-3, and all other borings
remained dry to the depth explored at that time. Groundwater level information is indicated
in the upper right-hand corner of the attached boring logs.
Groundwater levels will vary seasonally and over time based on weather conditions, site
development, irrigation practices and other hydrologic conditions. Perched and/or trapped
groundwater conditions may also be encountered at times throughout the year. Perched
water is commonly encountered in soils overlying less permeable soil layers and/or
bedrock. Trapped water is typically encountered within more permeable zones of layered
soil and bedrock systems. The location and amount of perched/trapped water can also vary
over time.
ANALYSIS AND RECOMMENDATIONS
General
Careful observation of the exposed foundation bearing materials should be completed at
the time of construction by Soilogic personnel or another qualified geotechnical engineer
to ensure all new footing foundations will be supported on natural, undisturbed materials
with suitable strength. Care should be taken during excavation to avoid disturbing those
soils providing support to the existing residence foundations (extending down and away
from the bottom/outside edges of the foundations at a 1:1 slope).
Geotechnical Subsurface Exploration Report
Proposed Remodel & Additions to Existing Residence
1509 S. Shields Street, Fort Collins, Colorado
Soilogic Project # 23-1207
5
Undocumented fill soils are expected to exist adjacent to the residence foundation walls.
Undocumented fill soils would not be considered suitable for support of any site
improvements. If/where existing fill is identified underlying new foundations, offsetting
new foundation elements to bear outside of the foundation wall backfill zone, extending
footing foundations to bear on natural, undisturbed lean clay/silty, clayey sand with low
volume change potential at greater depth, or performing overexcavation/backfill
procedures to redevelop controlled and compacted fill beneath new footing foundations in
these areas could be considered.
Demolition and Site Development
Within the new building addition, pavement and any proposed fill areas, all existing
foundations, floor slabs, pavements/flatwork and other site improvements should be
completely removed. Care will be needed to ensure all in-place fill/backfill materials
associated with the existing site development are also completely removed at this time. In
addition, all trees, tree root systems and dry and desiccated soils associated with the tree
root systems should be completely removed from within the proposed building, pavement
and any proposed fill areas. The depth and extent of required removal can best be
established at the time of excavation through openhole observation. If/where required, the
excavated/removed materials should be replaced as controlled and compacted fill as
outlined below.
After stripping and completing all cuts and removal procedures and prior to placement of
any fill, removal area backfill or exterior flatwork concrete, we recommend the exposed
subgrade soils be scarified to a depth of 9 inches, adjusted in moisture content and
compacted to at least 95% of the materials standard Proctor maximum dry density. The
moisture content of the scarified soils should be adjusted to be within the range of -1 to
+3% of standard Proctor optimum moisture content at the time of compaction.
Fill and removal area backfill soils required to develop the site should consist of approved,
low-volume-change (LVC) soils free from organic matter, debris and other objectionable
materials. Based on results of the completed laboratory testing, it is our opinion the natural
site lean clay and silty/clayey sand could be used as fill and backfill provided the proper
moisture content is developed in those materials at the time of placement and compaction.
Geotechnical Subsurface Exploration Report
Proposed Remodel & Additions to Existing Residence
1509 S. Shields Street, Fort Collins, Colorado
Soilogic Project # 23-1207
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If required, imported soils should consist of approved LVC and relatively impervious soils
free from organic matter and debris. Site fill and backfill should contain a minimum of
25% fines in order to reduce the ability of those materials to pond and transmit water.
Suitable fill and backfill soils should be placed in loose lifts not to exceed 9 inches thick,
adjusted in moisture content and compacted as recommended for the scarified soils above.
Care should be taken to avoid disturbing all subgrade soils prior to placement of any
overlying improvements. Soils which are allowed to dry out or become wet and softened
or disturbed by the construction activities should be removed and replaced or reworked in
place prior to concrete placement.
Foundations
Based on the materials encountered in the completed site borings and results of laboratory
testing, it is our opinion the proposed lightly-loaded remodel improvements, additions to
the existing residence and trash enclosure could be supported by continuous spread footing
and/or isolated pad foundations bearing on natural, undisturbed lean clay/silty, clayey sand
with low volume change potential and/or properly placed and compacted fill or
overexcavation/backfill (if/where required). For design of new footing foundations bearing
on natural, undisturbed medium stiff to hard/loose to medium dense to dense lean clay/silty,
clayey sand and/or properly placed and compacted fill or overexcavation/backfill, we
recommend using a maximum net allowable soil bearing pressure of 1,500 psf. As a
precaution, new footing foundations should be sized to maintain a minimum dead-load
pressure of 500 psf, or as high as practical on the foundation bearing materials. In
evaluation of existing footing foundations subjected to additionally-imposed loads as a
result of the proposed remodel improvements or addition (if any), a maximum net
allowable soil bearing pressure of 2,000 psf could be used.
Exterior footings should bear a minimum of 30 inches below finished adjacent exterior
grade to provide frost protection. We recommend formed strip footings have a minimum
width of 12 inches and isolated pad foundations have a minimum width of 24 inches in
order to facilitate construction and reduce the potential for development of eccentrically
loaded footings. Actual footing widths should be designed by a structural engineer.
Geotechnical Subsurface Exploration Report
Proposed Remodel & Additions to Existing Residence
1509 S. Shields Street, Fort Collins, Colorado
Soilogic Project # 23-1207
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For design of new footing foundations and foundation walls to resist lateral movement, a
passive equivalent fluid pressure value of 250 pcf could be used. The top 30 inches of
subgrade could be considered a surcharge load but should not be used in the passive
resistance calculations. A coefficient of friction of 0.35 could be used between foundation
and floor slab concrete and the bearing soils to resist sliding. The recommended passive
equivalent fluid pressure value and coefficient of friction do not include a factor of safety.
Care should be taken to ensure new foundations will not be supported on any disturbed or
previously placed backfill soils associated with construction of the existing residence.
If/where encountered, extending footing foundations through existing fill to bear on natural
soils at greater depth or overexcavation/backfill procedures would be required in these
areas to develop suitable foundation bearing. Structurally spanning the existing residence
foundation wall backfill zone could also be considered.
Soilogic estimates settlement of new spread footing foundations designed and constructed
as outlined above and resulting from the assumed structural loads would be less than 1
inch. If/where additional loads are imposed on existing footing foundations, some
additional settlement of those footings will occur subsequent to construction of the
addition. Assuming typical residential construction footing widths, we estimate additional
settlement of the existing footing foundations of ½ inch or less will occur subsequent to
construction as a result of the additionally-imposed loads. Some differential settlement
should be anticipated between the existing and any newly-constructed footings. An
allowance for some differential movement should be included in the design. Similarly,
some differential settlement should be expected between existing footing foundations not
subjected to additionally-imposed loads and those that are subjected to additionally-
imposed loads. Based on the subsurface conditions encountered and uniform loading
anticipated, we expect differential settlement across the existing structure would be limited
to ½ inch or less. Even limited differential settlement can result in some cosmetic distress
to existing residence finishes and some repair efforts may be required subsequent to
improvement construction and loading.
The existing basement foundation walls may be subjected to additional lateral earth
pressure loads imposed by the addition footing foundations. Soilogic recommends the
existing foundation system and basement walls be evaluated by a qualified structural
Geotechnical Subsurface Exploration Report
Proposed Remodel & Additions to Existing Residence
1509 S. Shields Street, Fort Collins, Colorado
Soilogic Project # 23-1207
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engineer prior to design and construction of the additions to ensure the walls will be able
to withstand additional surcharge loads. If it is determined the residence is not supported
by conventional spread footing foundations after additional investigation, alternative
foundation systems may be required.
Crawl Space Construction
As a precaution, we recommend a perimeter drain system be constructed around all below-
grade areas to help reduce the potential for water infiltration into the crawl space areas of
the additions and/or the development of hydrostatic pressures behind the foundation walls.
The perimeter drain system(s) should consist of a 4-inch diameter perforated drain pipe
surrounded by a minimum of six (6) inches of free-draining gravel. A filter fabric should
be considered around the free-draining gravel or perforated pipe to reduce the potential for
an influx of fine-grained soils into the system(s). The invert of the drain pipe, at its high
point, should be placed at approximate foundation bearing level, run around the interior or
exterior of crawl space areas with a minimum slope of ⅛-inch per foot to facilitate efficient
water removal and should discharge to a sump pump and pit system. Care should be taken
at the time of perimeter drain installation to avoid disturbing those soils providing support
to the existing residence and new addition footing foundations (extending down at a 1:1
slope from the bottom edges of the footings).
As an additional precaution, we recommend a vapor barrier be installed in the crawl space
areas in order to help maintain in-situ soil moisture conditions and reduce the potential for
migration of soil moisture into the crawl space areas. Subgrades in the crawl space areas
should be sloped to drain to the perimeter drain system(s). The owner/client should
consider consulting with a mold prevention specialist for additional precautions that could
be implemented to reduce the potential for development of moist air conditions in the crawl
space areas of the structure.
Backfill placed adjacent to below-grade walls should consist of relatively impervious soils
free from organic matter, debris and other objectionable materials. The site lean clay and
silty/clayey sand could be used as backfill in this area provided the proper moisture content
is developed in those materials at the time of placement and compaction. We recommend
the site lean clay, silty/clayey sand or similar backfill soils be placed in loose lifts not to
Geotechnical Subsurface Exploration Report
Proposed Remodel & Additions to Existing Residence
1509 S. Shields Street, Fort Collins, Colorado
Soilogic Project # 23-1207
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exceed 9 inches thick, adjusted in moisture content and compacted as previously outlined
in the “Demolition and Site Development” section of this report.
Excessive lateral stresses can be imposed on foundation walls when using heavier
mechanical compaction equipment. We recommend compaction of unbalanced foundation
wall backfill soils be completed using light mechanical or hand compaction equipment.
Lateral Earth Pressures
For design of below-grade walls where preventative measures have been taken to reduce
the potential for development of hydrostatic loads on the walls, we recommend using an
at-rest equivalent fluid pressure value of 65 pounds per cubic foot. A modified active
equivalent fluid pressure of 55 pounds per cubic foot could be used for partially restrained
conditioned where some rotation of the below-grade walls must occur to develop the active
earth pressure state. That rotation can result in cracking of the below-grade walls typically
in between corners and other restrained points. The amount of deflection of the top of the
wall can be estimated at 0.5% times the height of the wall.
Variables that affect lateral earth pressures include but are not limited to the shrink/swell
potential of the backfill soils, backfill compaction and geometry, wetting of the backfill
soils, surcharge loads and point loads developed in the backfill materials. The
recommended equivalent fluid pressure values do not include a factor of safety or an
allowance for hydrostatic loads. Use of expansive soil backfill, excessive compaction of
the wall backfill or surcharge loads placed adjacent to the below-grade walls can add to the
lateral earth pressures causing the equivalent fluid pressure values used in design to be
exceeded.
Floor Slabs
The addition and any other at-grade floor slabs (if any) could be supported directly on
reconditioned lean clay/silty, clayey sand with low swell potential and/or properly moisture
conditioned and compacted fill or overexcavation/backfill soils (if/where required)
developed as outlined in the “Demolition and Site Development” section of this report.
Geotechnical Subsurface Exploration Report
Proposed Remodel & Additions to Existing Residence
1509 S. Shields Street, Fort Collins, Colorado
Soilogic Project # 23-1207
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Care should be taken to maintain the proper moisture content and avoid disturbing all floor
slab subgrade soils prior to concrete placement. The exposed floor slab subgrade soils
should not be left exposed for extended periods of time. In the event that the subgrade soils
are allowed to dry out or if rain, snowmelt or water from any source is allowed to infiltrate
those materials, reworking of the subgrade soils or removal/replacement procedures may
be required.
Floor slabs should be designed and constructed as floating slabs, separated from foundation
walls, columns and plumbing and mechanical penetrations by the use of block-outs or
appropriate isolation material. Additionally, we recommend all partition walls supported
above slabs-on-grade be constructed as floating walls to help reduce the potential for
differential slab-to-foundation movement causing distress in upper sections of the
residence. A minimum one and one-half (1½) inch void space is recommended beneath all
floating walls. Special attention to door and stair framing, garage floor tracks, drywall
installation and trim carpentry should be taken to isolate those elements from the floor
slabs, allowing for some differential floor slab-to-foundation movement to occur without
transmitting stresses to the overlying structure.
Depending on the type of floor covering and floor covering adhesive used in finished slab-
on-grade areas, a vapor barrier may be required immediately beneath the floor slabs in
order to maintain flooring product manufacturer warranties. A vapor barrier would help
reduce the transmission of moisture through the floor slab. However, the unilateral
moisture release caused by placing concrete on an impermeable surface can increase slab
curl. The amount of slab curl can be reduced by careful selection of an appropriate concrete
mix, however, slab curl cannot be eliminated. We recommend the owner, architect and
flooring contractor consider the performance of the slab, in conjunction with the proposed
flooring products to help determine if a vapor barrier will be required and where best to
position the vapor barrier in relation to the floor slab. Additional guidance and
recommendations concerning slab-on-grade design can be found in American Concrete
Institute (ACI) section 302.
Geotechnical Subsurface Exploration Report
Proposed Remodel & Additions to Existing Residence
1509 S. Shields Street, Fort Collins, Colorado
Soilogic Project # 23-1207
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Site Pavements
Pavement subgrades could be developed as outlined in the “Demolition and Site
Development” section of this report. Site pavements could be supported directly on the
reconditioned subgrade soils and suitable fill and removal area backfill soils placed and
compacted as outlined in that section. The pavement subgrades are expected to consist of
lean clay/silty, clayey sand. The reconditioned lean clay/silty, clayey sand would be subject
to low remolded shear strength. A resistance value (R-value) of 5 was estimated for the
subgrade soils and used in pavement section design.
Traffic loading on the site pavements is expected to consist of areas of low volumes of
automobiles and light trucks, as well as areas of higher light-vehicle traffic volumes and
occasional heavier trash and delivery trucks. Equivalent 18-kip single axle loads (ESAL’s)
were estimated for the quantity of site traffic anticipated. Two (2) general pavement design
classifications are outlined below in Table I. Standard duty pavements could be considered
in automobile drive and parking areas. Heavy duty pavements should be considered for
access drives and other areas of the site expected to receive higher traffic volumes or heavy
truck traffic.
Proofrolling of the pavement subgrades should be completed to help identify unstable
areas. Depending on the in-place moisture content of the subgrade soils immediately prior
to paving, the time of year when construction occurs and other hydrologic conditions,
stabilization of the subgrade soils may become necessary to develop a suitable paving
platform. Isolated areas of subgrade instability can be mended on a case-by-case basis. If
more widespread subgrade instability is observed at the time of proofrolling, we
recommend consideration be given to stabilization of the pavement subgrades with Class
C fly ash or Portland concrete cement (pending results of WSS testing). With the increase
in support strength developed by the chemical stabilization procedures, it is our opinion
some credit for the stabilized zone could be included in the pavement section design,
reducing the required thickness of overlying asphaltic concrete and aggregate base course.
Pavement section design options incorporating some structural credit for the stabilized
subgrade soils are outlined below in Table I. Chemical stabilization can also eliminate
some of the uncertainty associated with attempting to pave late in the season and during
periods of inclement weather.
Geotechnical Subsurface Exploration Report
Proposed Remodel & Additions to Existing Residence
1509 S. Shields Street, Fort Collins, Colorado
Soilogic Project # 23-1207
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It has been our experience that full-depth asphaltic concrete pavement sections typically
do not perform as well as structurally-equivalent composite pavement sections in areas of
lean clay subgrade soils, and we do not recommend a full-depth asphalt section be
constructed for this project. Alternative pavement sections could be considered and we
would be happy to discuss any alternatives at your request.
TABLE 1 – PAVEMENT SECTION DESIGN
Standard Duty Heavy Duty
Option A – Composite
Asphaltic Concrete (Grading S or SX)
Aggregate Base (Class 5 or 6)
4”
6”
5”
8”
Option B – Composite on Stabilized Subgrade
Asphaltic Concrete (Grading S or SX)
Aggregate Base (Class 5 or 6)
Fly Ash Stabilized Subgrade
3”
4”
12”
4”
6”
12”
Option C - Portland Cement Concrete Pavement
PCCP
5”
6”
Asphaltic concrete should consist of a bituminous plant mix composed of a mixture of
aggregate, filler, binders and additives if required meeting the design requirements of the
City of Fort Collins. Aggregate used in the asphaltic concrete should meet specific
gradation requirements such as Colorado Department of Transportation (CDOT) grading
S (¾-inch minus) or SX (½-inch minus) specifications. Hot mix asphalt designed using
“Superpave” criteria should be compacted to within 92 to 96% of the materials Maximum
Theoretical Density. Aggregate base should be consistent with CDOT requirements for
Class 5 or Class 6 aggregate base, placed in loose lifts not to exceed 9 inches thick and
compacted to at least 95% of the materials standard Proctor maximum dry density within
±2% of standard Proctor optimum moisture content.
If chemical stabilization procedures will be completed, we recommend the addition of 12%
Class ‘C’ fly ash (or 4% Portland cement pending WSS test results) based on component
dry unit weights. A 12-inch-thick stabilized zone should be constructed by thoroughly
blending the fly ash or Portland cement with the in-place subgrade soils. Some “fluffing”
of the finish subgrade level should be expected with the stabilization procedures. The
blended materials should be adjusted in moisture content to within the range of ±2% of
standard Proctor optimum moisture content and compacted to at least 95% of the material’s
Geotechnical Subsurface Exploration Report
Proposed Remodel & Additions to Existing Residence
1509 S. Shields Street, Fort Collins, Colorado
Soilogic Project # 23-1207
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standard Proctor maximum dry density within two (2) hours of fly ash and 30 minutes of
cement addition.
For areas subjected to truck turning movements and/or concentrated and repetitive loading
such as dumpster or truck parking and loading areas, we recommend consideration be given
to the use of Portland cement concrete pavement with a minimum thickness of 6 inches.
Thicker concrete pavement sections may be warranted depending on the actual type and
quantity of heavy truck traffic anticipated to utilize areas of the site. The concrete used for
site pavements should be air entrained and have a minimum 28-day compressive strength
of 4,000 or 4,500 psi (pending results of WSS testing). Woven wire mesh or fiber entrained
concrete should be considered to help in the control of shrinkage cracking.
The proposed pavement section designs do not include an allowance for excessive loading
conditions imposed by heavy construction vehicles or equipment. Heavily loaded concrete
or other building material trucks and construction equipment can cause some localized
distress to site pavements. The recommended pavement sections are minimums and
periodic maintenance efforts should be expected. A preventative maintenance program can
help increase the service life of site pavements.
Drainage
Positive drainage is imperative for satisfactory long-term performance of the proposed
additions and associated site improvements. We recommend positive drainage be
developed away from the residence and additions during construction and maintained
throughout the life of the site improvements, with twelve (12) inches of fall in the first 10
feet away from the residence and additions. Shallower slopes could be considered in
hardscape areas. In the event that poor or negative drainage develops adjacent to the
residence and/or additions over time, the original grade and associated positive drainage
outlined above should be immediately restored.
Care should be taken in the planning of landscaping to avoid features which could result in
the fluctuation of the moisture content of the foundation bearing and/or flatwork subgrade
soils. We recommend watering systems be placed a minimum of 5 feet away from the
perimeter of the site structure and be designed to discharge away from all site
Geotechnical Subsurface Exploration Report
Proposed Remodel & Additions to Existing Residence
1509 S. Shields Street, Fort Collins, Colorado
Soilogic Project # 23-1207
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improvements. Gutter systems should be considered to help reduce the potential for water
ponding adjacent to the building with the gutter downspouts, roof drains or scuppers
extended to discharge a minimum of 5 feet away from structural, flatwork and pavement
elements. Water which is allowed to pond adjacent to site improvements can result in
unsatisfactory performance of those improvements over time.
GENERAL COMMENTS
This report was prepared based upon the data obtained from the completed site exploration,
laboratory testing, engineering analysis and any other information discussed. The
completed borings provide an indication of subsurface conditions at the boring locations
only. Variations in subsurface conditions can occur in relatively short distances away from
the borings. This report does not reflect any variations which may occur across the site or
away from the borings. If variations in the subsurface conditions anticipated become
evident, the geotechnical engineer should be notified immediately so that further evaluation
can be completed and when warranted, alternative recommendations provided.
The scope of services for this project does not include either specifically or by implication
any biological or environmental assessment of the site or identification or prevention of
pollutants or hazardous materials or conditions. Other studies should be completed if
concerns over the potential of such contamination or pollution exist.
The geotechnical engineer should be retained to review the plans and specifications so that
comments can be made regarding the interpretation and implementation of our
geotechnical recommendations in the design and specifications. The geotechnical engineer
should also be retained to provide testing and observation services during construction to
help determine that the design requirements are fulfilled.
This report has been prepared for the exclusive use of our client for specific application to
the project discussed and has been prepared in accordance with the generally accepted
standard of care for the profession. No warranties express or implied, are made. The
conclusions and recommendations contained in this report should not be considered valid
in the event that any changes in the nature, design or location of the project as outlined in
Geotechnical Subsurface Exploration Report
Proposed Remodel & Additions to Existing Residence
1509 S. Shields Street, Fort Collins, Colorado
Soilogic Project # 23-1207
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this report are planned, unless those changes are reviewed and the conclusions of this report
modified and verified in writing by the geotechnical engineer.
We appreciate the opportunity to be of service to you on this project. If you have any
questions concerning the enclosed information or if we can be of further service to you in
any way, please do not hesitate to contact us.
Very Truly Yours,
Soilogic, Inc. Reviewed by:
Darrel DiCarlo, P.E. Alec Kaljian, P.E.
Senior Project Engineer Project Engineer
09/14/2023
09/14/2023
LOG OF BORING B-1
1/1 CME 45
4" CFA
Automatic
JJ / NB
Estimated Swell % Passing
SOIL DESCRIPTION Depth "N"MC DD qu % Swell @ Pressure # 200 Sieve
(ft)(%)(pcf)(psf)500 psf (psf)LL PI (%)
4 - 6" TOPSOIL & VEGETATION -
1
-
2
-
3 CS 15 12.4 112.7 9000+0.9%2400 ---
-
4
-
5 CS 45 5.1 -9000+-----
-
6
CL-ML SILTY, SANDY LEAN CLAY -
to varies to SILTY, CLAYEY SAND 7
SC-SM red-brown, beige -
stiff to hard / medium dense 8
trace to minor GRAVEL -
9
-
10 CS 15 21.7 101.5 8500 1.2%1600 ---
-
11
-
12
-
13
-
14
-
15 CS 15 13.8 120.3 3500 -----
BOTTOM OF BORING @ 15.0'-
16
-
17
-
18
-
19
-
20
-
21
-
22
-
23
-
24
-
25
US
C
S
Sa
m
p
l
e
r
Atterberg Limits
Surface Elev.-Field Personnel:7 Days After Drilling None
Finish Date 8/29/2023 Hammer Type:After Drilling None
Sheet Drilling Rig:Water Depth Information
Start Date 8/29/2023 Auger Type:During Drilling None
REMODEL & ADDITIONS TO EXISTING RESIDENCE - TRACT 2 & PART OF TRACT 3, MAXFIELD
1509 S. SHIELDS STREET, FORT COLLINS, COLORADO
Project # 23-1207
September 2023
LOG OF BORING B-2
1/1 CME 45
4" CFA
Automatic
JJ / NB
Estimated Swell % Passing
SOIL DESCRIPTION Depth "N"MC DD qu % Swell @ Pressure # 200 Sieve
(ft)(%)(pcf)(psf)500 psf (psf)LL PI (%)
3 - 4" CONCRETE DRIVEWAY -
1
-
2
-
3 CS 13 12.5 119.3 9000+--23 8 55.8%
-
4
-
5 CS 16 7.3 118.4 9000+0.4%900 ---
-
6
CL-ML SILTY, SANDY LEAN CLAY -
to varies to SILTY, CLAYEY SAND 7
SC-SM red-brown -
stiff to very stiff /8
loose to medium dense -
trace to minor GRAVEL 9
-
10 CS 22 10.8 112.0 9000+1.7%2900 ---
-
11
-
12
-
13
-
14
-
15 CS 18 11.6 121.1 6000 -----
BOTTOM OF BORING @ 15.0'-
16
-
17
-
18
-
19
-
20
-
21
-
22
-
23
-
24
-
25
7 Days After Drilling None
US
C
S
Sa
m
p
l
e
r
Atterberg Limits
Start Date 8/29/2023 Auger Type:During Drilling None
Finish Date 8/29/2023 Hammer Type:After Drilling None
Surface Elev.-Field Personnel:
Sheet Drilling Rig:Water Depth Information
REMODEL & ADDITIONS TO EXISTING RESIDENCE - TRACT 2 & PART OF TRACT 3, MAXFIELD
1509 S. SHIELDS STREET, FORT COLLINS, COLORADO
Project # 23-1207
September 2023
LOG OF BORING B-3
1/1 CME 45
4" CFA
Automatic
JJ / NB
Estimated Swell % Passing
SOIL DESCRIPTION Depth "N"MC DD qu % Swell @ Pressure # 200 Sieve
(ft)(%)(pcf)(psf)500 psf (psf)LL PI (%)
2 - 4" TOPSOIL & VEGETATION -
1
-
2
-
3
-
4
-
5 CS 42 7.0 113.1 9000+2.4%4600 ---
-
6
-
7
-
8
-
9
-
10 CS 19 11.9 118.8 9000+0.9%2300 ---
-
11
-
CL-ML SILTY, SANDY LEAN CLAY 12
to varies to SILTY, CLAYEY SAND -
SC-SM red-brown, beige 13
medium stiff to hard /-
loose to medium dense 14
-
15 CS 20 18.1 111.7 9000+-----
-
16
-
17
-
18
-
19
-
20 CS 9 24.2 101.5 2500 -----
-
21
-
22
-
23
-
24
-
25
-
26
-
27
-
28
-
29
-
BOTTOM OF BORING @ 30.0'30 CS 15 16.4 114.5 5500 -----
7 Days After Drilling 17.0'
US
C
S
Sa
m
p
l
e
r
Atterberg Limits
Start Date 8/29/2023 Auger Type:During Drilling 17.0'
Finish Date 8/29/2023 Hammer Type:After Drilling 17.0'
Surface Elev.-Field Personnel:
Sheet Drilling Rig:Water Depth Information
REMODEL & ADDITIONS TO EXISTING RESIDENCE - TRACT 2 & PART OF TRACT 3, MAXFIELD
1509 S. SHIELDS STREET, FORT COLLINS, COLORADO
Project # 23-1207
September 2023
LOG OF BORING B-4
1/1 CME 45
4" CFA
Automatic
JJ / NB
Estimated Swell % Passing
SOIL DESCRIPTION Depth "N"MC DD qu % Swell @ Pressure # 200 Sieve
(ft)(%)(pcf)(psf)500 psf (psf)LL PI (%)
4 - 6" TOPSOIL & VEGETATION -
1
-
CL LEAN CLAY with varying 2
amounts of SILT and SAND -
dark brown, red-brown 3 CS 23 14.1 112.1 9000+2.4%6200 ---
very stiff to hard -
trace GRAVEL 4
-
5 CS 50/10 5.3 -9000+-----
BOTTOM OF BORING @ 5.0'-
6
-
7
-
8
-
9
-
10
-
11
-
12
-
13
-
14
-
15
-
16
-
17
-
18
-
19
-
20
-
21
-
22
-
23
-
24
-
25
7 Days After Drilling None
US
C
S
Sa
m
p
l
e
r
Atterberg Limits
Start Date 8/29/2023 Auger Type:During Drilling None
Finish Date 8/29/2023 Hammer Type:After Drilling None
Surface Elev.-Field Personnel:
Sheet Drilling Rig:Water Depth Information
REMODEL & ADDITIONS TO EXISTING RESIDENCE - TRACT 2 & PART OF TRACT 3, MAXFIELD
1509 S. SHIELDS STREET, FORT COLLINS, COLORADO
Project # 23-1207
September 2023
LOG OF BORING B-5
1/1 CME 45
4" CFA
Automatic
JJ / NB
Estimated Swell % Passing
SOIL DESCRIPTION Depth "N"MC DD qu % Swell @ Pressure # 200 Sieve
(ft)(%)(pcf)(psf)500 psf (psf)LL PI (%)
±3" ASPHALT PAVEMENT -
1
-
2
-
3 CS 22 14.1 117.6 9000+-----
-
4
CL-ML SILTY, SANDY LEAN CLAY -
to varies to SILTY, CLAYEY SAND 5 CS 28 7.4 113.0 9000+1.1%2300 ---
SC-SM brown, red-brown -
very stiff / medium dense 6
-
7
-
8
-
9
-
10 CS 23 12.0 120.3 9000+-----
BOTTOM OF BORING @ 10.0'-
11
-
12
-
13
-
14
-
15
-
16
-
17
-
18
-
19
-
20
-
21
-
22
-
23
-
24
-
25
7 Days After Drilling Backfilled
US
C
S
Sa
m
p
l
e
r
Atterberg Limits
Start Date 8/29/2023 Auger Type:During Drilling None
Finish Date 8/29/2023 Hammer Type:After Drilling None
Surface Elev.-Field Personnel:
Sheet Drilling Rig:Water Depth Information
REMODEL & ADDITIONS TO EXISTING RESIDENCE - TRACT 2 & PART OF TRACT 3, MAXFIELD
1509 S. SHIELDS STREET, FORT COLLINS, COLORADO
Project # 23-1207
September 2023
Liquid Limit -
Plasticity Index -
% Passing #200 -
Dry Density (pcf)112.7
500
Final Moisture 15.8%
% Swell @ 500 psf 0.9%
Swell Pressure (psf)2,400
Sample ID: B-1 @ 2
Initial Moisture 12.4%
Sample Description: Brown/Red-Brown Silty Lean Clay with Sand (CL-ML)
SWELL/CONSOLIDATION TEST SUMMARY
REMODEL & ADDITIONS TO EXISTING RESIDENCE - TRACT 2 & PART OF TRACT 3, MAXFIELD
1509 S. SHIELDS STREET, FORT COLLINS, COLORADO
Project # 23-1207
September 2023
-12
-10
-8
-6
-4
-2
0
2
4
6
8
10
12
10 100 1000 10000 100000
---------
Applied Load (psf)
Liquid Limit -
Plasticity Index -
% Passing #200 -
Dry Density (pcf)101.5
500
Final Moisture 25.4%
% Swell @ 500 psf 1.2%
Swell Pressure (psf)1,600
Initial Moisture 21.7%
Sample ID: B-1 @ 9
Sample Description: Red-Brown Silty Lean Clay with Sand (CL-ML)
SWELL/CONSOLIDATION TEST SUMMARY
REMODEL & ADDITIONS TO EXISTING RESIDENCE - TRACT 2 & PART OF TRACT 3, MAXFIELD
1509 S. SHIELDS STREET, FORT COLLINS, COLORADO
Project # 23-1207
September 2023
-12
-10
-8
-6
-4
-2
0
2
4
6
8
10
12
10 100 1000 10000 100000
---------
Applied Load (psf)
Liquid Limit -
Plasticity Index -
% Passing #200 -
Dry Density (pcf)118.4
500
Final Moisture 15.8%
% Swell @ 500 psf 0.4%
Swell Pressure (psf)900
Initial Moisture 7.3%
Sample ID: B-2 @ 4
Sample Description: Red-Brown Clayey, Silty Sand (SC-SM)
SWELL/CONSOLIDATION TEST SUMMARY
REMODEL & ADDITIONS TO EXISTING RESIDENCE - TRACT 2 & PART OF TRACT 3, MAXFIELD
1509 S. SHIELDS STREET, FORT COLLINS, COLORADO
Project # 23-1207
September 2023
-12
-10
-8
-6
-4
-2
0
2
4
6
8
10
12
10 100 1000 10000 100000
---------
Applied Load (psf)
Liquid Limit -
Plasticity Index -
% Passing #200 -
Dry Density (pcf)112.0
500
Final Moisture 16.6%
% Swell @ 500 psf 1.7%
Swell Pressure (psf)2,900
Initial Moisture 10.8%
Sample ID: B-2 @ 9
Sample Description: Brown/Red-Brown Silty Lean Clay with Sand (CL-ML)
SWELL/CONSOLIDATION TEST SUMMARY
REMODEL & ADDITIONS TO EXISTING RESIDENCE - TRACT 2 & PART OF TRACT 3, MAXFIELD
1509 S. SHIELDS STREET, FORT COLLINS, COLORADO
Project # 23-1207
September 2023
-12
-10
-8
-6
-4
-2
0
2
4
6
8
10
12
10 100 1000 10000 100000
---------
Applied Load (psf)
Liquid Limit -
Plasticity Index -
% Passing #200 -
Dry Density (pcf)113.1
500
Final Moisture 17.4%
% Swell @ 500 psf 2.4%
Swell Pressure (psf)4,600
Initial Moisture 7.0%
Sample ID: B-3 @ 4
Sample Description: Red-Brown Silty, Sandy Lean Clay (CL-ML)
SWELL/CONSOLIDATION TEST SUMMARY
REMODEL & ADDITIONS TO EXISTING RESIDENCE - TRACT 2 & PART OF TRACT 3, MAXFIELD
1509 S. SHIELDS STREET, FORT COLLINS, COLORADO
Project # 23-1207
September 2023
-12
-10
-8
-6
-4
-2
0
2
4
6
8
10
12
10 100 1000 10000 100000
---------
Applied Load (psf)
Liquid Limit -
Plasticity Index -
% Passing #200 -
Dry Density (pcf)118.8
500
Final Moisture 15.0%
% Swell @ 500 psf 0.9%
Swell Pressure (psf)2,300
Initial Moisture 11.9%
Sample ID: B-3 @ 9
Sample Description: Red-Brown Silty, Sandy Lean Clay (CL-ML), trace Gravel
SWELL/CONSOLIDATION TEST SUMMARY
REMODEL & ADDITIONS TO EXISTING RESIDENCE - TRACT 2 & PART OF TRACT 3, MAXFIELD
1509 S. SHIELDS STREET, FORT COLLINS, COLORADO
Project # 23-1207
September 2023
-12
-10
-8
-6
-4
-2
0
2
4
6
8
10
12
10 100 1000 10000 100000
---------
Applied Load (psf)
Liquid Limit -
Plasticity Index -
% Passing #200 -
Dry Density (pcf)112.1
500
Final Moisture 16.8%
% Swell @ 500 psf 2.4%
Swell Pressure (psf)6,200
Initial Moisture 14.1%
Sample ID: B-4 @ 2
Sample Description: Dark Brown Lean Clay with Sand (CL), trace Gravel
SWELL/CONSOLIDATION TEST SUMMARY
REMODEL & ADDITIONS TO EXISTING RESIDENCE - TRACT 2 & PART OF TRACT 3, MAXFIELD
1509 S. SHIELDS STREET, FORT COLLINS, COLORADO
Project # 23-1207
September 2023
-12
-10
-8
-6
-4
-2
0
2
4
6
8
10
12
10 100 1000 10000 100000
---------
Applied Load (psf)
Liquid Limit -
Plasticity Index -
% Passing #200 -
Dry Density (pcf)113.0
500
Final Moisture 14.8%
% Swell @ 500 psf 1.1%
Swell Pressure (psf)2,300
Initial Moisture 7.4%
Sample ID: B-5 @ 4
Sample Description: Red-Brown Silty, Sandy Lean Clay (CL-ML)
SWELL/CONSOLIDATION TEST SUMMARY
REMODEL & ADDITIONS TO EXISTING RESIDENCE - TRACT 2 & PART OF TRACT 3, MAXFIELD
1509 S. SHIELDS STREET, FORT COLLINS, COLORADO
Project # 23-1207
September 2023
-12
-10
-8
-6
-4
-2
0
2
4
6
8
10
12
10 100 1000 10000 100000
---------
Applied Load (psf)
UNIFIED SOIL CLASSIFICATION SYSTEM
Criteria for Assigning Group Symbols and Group Names Using Laboratory TestsA Soil Classification
Group
Symbol Group NameB
Cu ! 4 and 1 " Cc " 3E GW Well graded gravelF Clean Gravels
Less than 5% finesC Cu < 4 and/or 1 > Cc > 3E GP Poorly graded gravelF
Fines classify as ML or MH GM Silty gravelF,G, H
Coarse Grained Soils
More than 50% retained
on No. 200 sieve
Gravels
More than 50% of coarse
fraction retained on
No. 4 sieve Gravels with Fines More
than 12% finesC Fines classify as CL or CH GC Clayey gravelF,G,H
Cu ! 6 and 1 " Cc " 3E SW Well graded sandI Clean Sands
Less than 5% finesD Cu < 6 and/or 1 > Cc > 3E SP Poorly graded sandI
Fines classify as ML or MH SM Silty sandG,H,I
Sands
50% or more of coarse
fraction passes
No. 4 sieve Sands with Fines
More than 12% finesD Fines classify as CL or CH SC Clayey sandG,H,I
PI > 7 and plots on or above “A” lineJ CL Lean clayK,L,M Silts and Clays
Liquid limit less than 50
Inorganic
PI < 4 or plots below “A” lineJ ML SiltK,L,M
Liquid limit - oven
dried Organic clayK,L,M,N
Fine-Grained Soils
50% or more passes the
No. 200 sieve
Organic
Liquid limit - not
dried
<0.75 OL
Organic siltK,L,M,O
Inorganic PI plots on or above “A” line CH Fat clayK,L,M Silts and Clays
Liquid limit 50 or more PI plots below “A” line MH Elastic siltK,L,M
Liquid limit - oven dried Organic clayK,L,M,P Organic
Liquid limit - not dried <0.75 OH
Organic siltK,L,M,Q
Highly organic soils Primarily organic matter, dark in color, and organic odor PT Peat
A Based on the material passing the 3-in. (75-mm) sieve
B If field sample contained cobbles or boulders, or both, add “with cobbles
or boulders, or both” to group name.
C Gravels with 5 to 12% fines require dual symbols: GW-GM well graded
gravel with silt, GW-GC well graded gravel with clay, GP-GM poorly
graded gravel with silt, GP-GC poorly graded gravel with clay.
D Sands with 5 to 12% fines require dual symbols: SW-SM well graded
sand with silt, SW-SC well graded sand with clay, SP-SM poorly graded
sand with silt, SP-SC poorly graded sand with clay
E Cu = D60/D10 Cc =
F If soil contains ! 15% sand, add “with sand” to group name.
G If fines classify as CL-ML, use dual symbol GC-GM, or SC-SM.
HIf fines are organic, add “with organic fines” to group name.
I If soil contains ! 15% gravel, add “with gravel” to group name.
J If Atterberg limits plot in shaded area, soil is a CL-ML, silty clay.
K If soil contains 15 to 29% plus No. 200, add “with sand” or “with
gravel,” whichever is predominant.
L If soil contains ! 30% plus No. 200 predominantly sand, add
“sandy” to group name.
M If soil contains ! 30% plus No. 200, predominantly gravel, add
“gravelly” to group name.
N PI ! 4 and plots on or above “A” line.
O PI < 4 or plots below “A” line.
P PI plots on or above “A” line.
Q PI plots below “A” line.
GENERAL NOTES
DRILLING & SAMPLING SYMBOLS:
SS: Split Spoon - 1⅜" I.D., 2" O.D., unless otherwise noted HS:
ST: Thin-Walled Tube – 2.5" O.D., unless otherwise noted PA:
RS: Ring Sampler - 2.42" I.D., 3" O.D., unless otherwise noted HA:
CS: California Barrel - 1.92" I.D., 2.5" O.D., unless otherwise noted RB:
BS: Bulk Sample or Auger Sample WB:
Hand Sample
Power Auger
Hand Auger
Rock Bit
Wash Boring or Mud Rotary
The number of blows required to advance a standard 2-inch O.D. split-spoon sampler (SS) the last 12 inches of the total 18-inch
penetration with a 140-pound hammer falling 30 inches is considered the “Standard Penetration” or “N-value”. For 2.5” O.D.
California Barrel samplers (CB) the penetration value is reported as the number of blows required to advance the sampler 12
inches using a 140-pound hammer falling 30 inches, reported as “blows per inch,” and is not considered equivalent to the
“Standard Penetration” or “N-value”.
WATER LEVEL MEASUREMENT SYMBOLS:
WL: Water Level WS: While Sampling
WCI: Wet Cave in WD: While Drilling
DCI: Dry Cave in BCR: Before Casing Removal
AB: After Boring ACR: After Casing Removal
Water levels indicated on the boring logs are the levels measured in the borings at the times indicated. Groundwater levels at other
times and other locations across the site could vary. In pervious soils, the indicated levels may reflect the location of groundwater.
In low permeability soils, the accurate determination of groundwater levels may not be possible with only short-term observations.
DESCRIPTIVE SOIL CLASSIFICATION: Soil classification is based on the Unified Classification System. Coarse Grained Soils
have more than 50% of their dry weight retained on a #200 sieve; their principal descriptors are: boulders, cobbles, gravel or sand.
Fine Grained Soils have less than 50% of their dry weight retained on a #200 sieve; they are principally described as clays if they
are plastic, and silts if they are slightly plastic or non-plastic. Major constituents may be added as modifiers and minor constituents
may be added according to the relative proportions based on grain size. In addition to gradation, coarse-grained soils are defined
on the basis of their in-place relative density and fine-grained soils on the basis of their consistency.
FINE-GRAINED SOILS COARSE-GRAINED SOILS BEDROCK
(CB)
Blows/Ft.
(SS)
Blows/Ft. Consistency
(CB)
Blows/Ft.
(SS)
Blows/Ft.
Relative
Density
(CB)
Blows/Ft.
(SS)
Blows/Ft.Consistency
< 3 0-2 Very Soft 0-5 < 3 Very Loose < 24 < 20 Weathered
3-5 3-4 Soft 6-14 4-9 Loose 24-35 20-29 Firm
6-10 5-8 Medium Stiff 15-46 10-29 Medium Dense 36-60 30-49 Medium Hard
11-18 9-15 Stiff 47-79 30-50 Dense 61-96 50-79 Hard
19-36 16-30 Very Stiff > 79 >50 Very Dense > 96 > 79 Very Hard
> 36 >30 Hard
RELATIVE PROPORTIONS OF SAND AND
GRAVEL
GRAIN SIZE TERMINOLOGY
Descriptive Terms of
Other Constituents
Percent of
Dry Weight
Major Component
of Sample Particle Size
Trace < 15 Boulders Over 12 in. (300mm)
With 15 – 29 Cobbles 12 in. to 3 in. (300mm to 75 mm)
Modifier > 30 Gravel 3 in. to #4 sieve (75mm to 4.75 mm)
Sand
Silt or Clay
#4 to #200 sieve (4.75mm to 0.075mm)
Passing #200 Sieve (0.075mm)
RELATIVE PROPORTIONS OF FINES PLASTICITY DESCRIPTION
Descriptive Terms of
Other Constituents
Percent of
Dry Weight Term Plasticity Index
Trace
With
Modifiers
< 5
5 – 12
> 12
Non-plastic
Low
Medium
High
0
1-10
11-30
30+