HomeMy WebLinkAboutCT 02-19; BRESSI RANCH PA 11; GEOTECHNICAL UPDATE LETTER AND ADDENDUM RECOMMENDATIONS; 2013-03-084 ,,,.,.' c-r
Leighton and Associates, Inc.
A LEIGHTON GROUP COMPANY
March 8, 2013
Project No. 042458-001
To: Manolia Partners, LLC
1094 Cudahy, Suite 212
San Diego, California 92110
Attention: Mr. Paul Colucci
Subject: Geotechnical Update Letter and Addendum Recommendations, Lots 6
and 11, Magnolia Estates, Bressi Ranch, PA-1 1, California
References:. California Building Standards Commission (CBSC), 2010, California
Building Code (CBC)
Leighton, and Associates, 2007, Geotechnical Preliminary Investigation for
Mass Grading, Bressi Ranch Carlsbad, California, Project No. 971009-
005, dated March 14, 2001
Leighton and Associates, 2004, As-Graded Report of Rough and Fine
Grading, Lots 1 through 25, Planning Area PA-1 1, Bressi Ranch, Carlsbad
Tract No. 00-06, Carlsbad, California,, Project No. 971009-014, dated
October 8, 2004
In accordance with your request, we have prepared an update letter for the geotechnical
conditions for Lots 6 and ii, Magnolia Estates located in Bressi Ranch, Carlsbad,
California. The purpose of our geotechnical update evaluation was to observe the
existing geotechnical conditions of the subject site, review the project geotechnical
reports, and update geotechnical recommendations for the seismic design parameters
per 2010 California Building Code, and provide appropriate conclusions and additional
recommendations, if necessary, for the proposed site improvements.
Based on our recent site visits and review of the referenced project geotechnical
reports, the geotechnical conditions of the subject site have not significantly changed
since the completion of grading in 2004 (Leighton, 2004), excluding a few end dumped
3934 Murphy Canyon Road, Suite B205 • San Diego, CA 92123-4425
858.292.8030 • Fax 858.292.0771
042458-001
piles of soil on Lot 6, some minor fencing and d ri'eway improvements.' Therefore, it is
our professional opinion that the geotechnical recommendation presented in the As-
Graded Report of Rough and Fine Grading re still applicable for :its intended use,
provided the following recorrimendations are in corporated into the design of structures
and construction of the buildings/structures.
Updated Seismic Recommendations
We have provided updated seismic design parameters per California Building Code
(CBC 2010) for proposed design of buildings. TheTfoilôwing seismic design parameters
have been determined in accordance with the 2010 CBC and the USGS Ground Motion
Parameter Calculator (Version 5.10).
CBC (2010) Seismic Code - Parameters for the Site
Description Values CBC Reference
Site Class D Table 1613.5.2
Short Period Spectral Acceleration ' S 1.123 Figure 16135(3)
1-Second Period Spectral Acceleration S1.0.426 Figure 1613 5(4)
Short Period Site Coefficient ' F 1.051 Table 1613.5.3(1)
1-Second Period Site Coefficient F 1.575 Table 1613.5.3(2)
Adjusted Short Period Spectral Acceleration SMS 1.181 Equation 16-36
Adjusted 1-Second Period Acceleration SM1 0 669 Equation 16-37
Design Short Period Spectral Response
Parameter SDS 0.787 Equation 16-38
Design 1-Second Period Spectral Response
Parameter SD1 0.446 Equation 16-39
Alternative Foundation Design Recommendations
As an alternative to a post-tensioned slab and foundation systems for the mitigation of
expansive soils and/or significant fill thickness, 'we recommend conventionally
reinforced continuous and spread Jootings with interior grade beams for support of the
floor slabs (e.g., a reinforced ribbed mat slab, RRMS).
Continuous and spread" footings should extend a ,minimum of 30 and 24 inches,
respectively, beneath the lowest adjacent finish grade. At these depths, footings may be
designed for a maximum allowable bearing pressure 2,000 pounds per square foot
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(psf) The allowable pressures may be increased by one-third when considering loads of
short duration such as wind, but not for seismic forces Theminimm recommended
width is 15 inches for cortinuous footings and 24 inches for square round footings
Minimum recommended width and depth of the ribs (i.e., grade beams used tc5 support
floor slabs) is 12 and 18 inches, respectively: In addition, 'werecorrmthd .a ribs spacing
(i.e., an unsupported floor slab span length) ofj 6-feet or less.
Footing reinforcement should be' desi9. hed in accordance with. the' stctural engineer's
requirements, but not less than four No 5 reinforcing bars two top ànd two bottom) for
continuous footings Additional design and construction information for the RRMS
foundation ôan be obtained in US Army Corps of Engineer, Technical Instructions (TI)
809-28' (USACOE, 1999).
LateralEärth Pressures for Basement Wall
The. recommended lateral .'pressures.for the 'onsjtvery low to low expansive soil
(expansion index less than 50) or mediu'm expansi\ie soil (expansion index between 51
anJ 70) áid level or sloping backfilbre presented on the table below Higher medium to
very high 'expansive soils (having an expansion potential greater than 70) should not be
used asbckfilI soils!
...'. .
Lateral Earth Pressures
Conditions
Equivalent Fluid Weight (pcf)
Very Low to Low Expansive'
Soils
Medium Expansive Soils
Expansion index less thn 50 Expansion index'between 51 and 70
Level., 2:1' Slope ' Level
T
2:1 Slope
Active 35 ' 55 60 70
At-Rest 55 ' 65 70 80
Passive 350 150 350 ' 150
Embedded structural walls shOuld. be designed for; lateral earth pressures exerted on
them The magnitude of these pressures depends on the amount of deformation that the
wall can yield under load If the wall can yield enough to mobilize the full shear strength of
the soil, it can be designed for "active" pressure If the wall cannot yield under the applied
load, the shear strength of the.soil cannot be mobilized and the earthpressure will be
higher. Such walls should be designed for "at rest" conditions (i.e., a basement wall). If a
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structure moves toward the soils, the resulting resistance developed by the soil is the
"passive" resistance To account for potential redistribution of forces during a seismic
seismic pressure distribution equal to 8. H psf where H equals the overall retained
height in feet (ASCE. 2006).
For design purposes, the recommended equivalent fluid pressure for each case for walls
founded above the static ground water and backfilléd with soils of very low to low
expansion potential or medium expansion potential is provided on the table above. The
equivalent fluid pressure values assume free-draining conditions. If conditions other than
those assumed above are anticipated, the equivalent fluid pressures values should be
provided on an individual-case basis by the geoteöhnical engineer. The geotechnical and
structural engineer shOuld evaluate surcharge-loading effects from the adjacent
structures. All retaining Wall structures should be provided with appropriate drainage and
appropriately waterproofed. The outlet pipe should be sloped to drain to a suitable outlet.
Typical wall drainage design is illustrated in Appendix D.
For sliding resistance, the friction coefficient of 0.35 may be used at the concrete and soil
interface In combining the total lateral resistance, the passive pressure or the frictional
resistance should be reduced by 50 percent. Wall footings should be designed. in
accordance with structural considerations. The passive resistance value may. be
increased by one-third when considering-loads of short duration including wind or seismic
loads. The horizontal distance between fOundation elements providing passive resistance
should be minimum of three times the depth of the elements to allow full development of
these passive pressures. The total depth of retained earth for the design of cantilever
walls should be the vertical distance below, the ground surface measured at the wall face
for stem design or measured at the heel of the footing for overturning and sliding. All wall
backcuts should be made in accordance with the current OSHA requirements.
The. granular and native backfill soils should be compacted to at least 90 percent relative
compaction (based on ASTM Test Method D1557). The granular fill should extend
horizontally to a minimum distance equal to one-half the wall height behind the walls. The
walls should be constructed and backfi lied ässoon as possible after backcut excavations.
Prolonged exposure.of backcut slopes may result in some localized slope instability
The recommendations provided in this, letter are based on as-graded subsurface
conditions observed during the previous site grading. The interpolated subsurface
conditions should be checked in the field during construction. Construction observation
of all onsite excavations and field density testing of all compacted fill should be
performed by a representative of this office. All footing excavations should be reviewed
by this office prior to placing steel or concrete.
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