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Geotechnical Investigation Report

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Title: Geotechnical Investigation Report


1
Geotechnical InvestigationReport
  • July 2008
  • Hadi J. Yap, PhD, PE, GE

2
Table of Contents
  • 1.0 Introduction
  • 2.0 Scope of Services
  • 3.0 Field Investigation
  • 4.0 Laboratory Testing
  • 5.0 Geology and Seismicity
  • 5.1 regional geology
  • 5.2 regional seismicity and faulting
  • 5.3 geologic hazards
  • 6.0 Site Conditions
  • 6.1 site conditions
  • 6.2 subsurface conditions
  • 7.0 Discussions and Conclusions
  • 7.1 foundation support
  • 7.2 groundwater
  • 7.3 excavation
  • 7.4 dewatering
  • 7.5 shoring and underpinning
  • 8.0 Recommendations
  • 8.1 mat foundation
  • 8.2 pile foundation
  • 8.3 below-grade walls
  • 8.4 basement floors
  • 8.5 seismic design
  • 8.6 site preparation
  • 8.7 excavation
  • 8.8 dewatering
  • 8.9 shoring
  • 8.10 earthwork
  • 8.11 utilities
  • 8.12 construction monitoring
  • 8.13 site drainage
  • 9.0 Additional Geotechnical
  • Services
  • 10.0 Limitations

3
Introduction
  • Present our understanding of the project
  • Site location, size, conditions
  • building type, number of stories and basements,
    column loads
  • Site grading/fill to be placed
  • additional elements of the project (retaining
    walls, parking areas, etc.)

4
Scope of Services
  • Field exploration
  • Laboratory testing
  • Engineering analysis
  • Develop conclusions and recommendations
    regarding
  • soil and groundwater conditions at the site
  • the most appropriate foundation type(s) for the
    structure
  • estimates of foundation settlement
  • lateral earth pressures for the design of
    permanent and temporary below-grade walls
  • site seismicity and seismic hazards, including
    ground rupture, liquefaction, lateral spreading
    and differential compaction
  • San Francisco Building Code seismic design
    parameters
  • subgrade preparation
  • criteria for fill, quality, placement and
    compaction
  • pavement design
  • construction considerations

5
Field Investigation
  • Evaluate existing data
  • TR database
  • city records
  • geologic maps
  • historic maps
  • Perform site reconnaissance
  • Develop field investigation program
  • test pits
  • dynamic cone penetrometer tests
  • test borings
  • Cone Penetration Tests (CPTs)

6
United States Coast Survey Map - February 1852
7
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8
Laboratory Testing
  • Geotechnical parameters
  • index testing for classification
  • shear strength
  • compressibility
  • R-value (for pavement design)
  • Corrosivity

9
Site Conditions
  • Describe site history, if known
  • reclamation history
  • past development
  • previous grading
  • Describe existing conditions
  • surface conditions
  • existing site use
  • known obstructions

10
Subsurface Conditions
  • Describe soil encountered
  • thickness
  • density/strength
  • compressibility
  • Groundwater conditions

11
Typical Stratigraphic Layers
  • Fill
  • Dune Sand
  • Bay Mud
  • Colma Formation
  • Old Bay Clay
  • Franciscan Complex Bedrock

12
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13
Typical Stratigraphic Layers
  • Fill
  • Heterogeneous soil consisting of sands, clays,
    silts, gravels, construction debris
  • Engineered fill or not?
  • If not-engineered fill, can not be relied upon
    for foundation support

14
Typical Stratigraphic Layers
  • Dune Sand
  • clean fine-grained sand, wind-blown deposit
  • covers the majority of San Francisco
  • Typically loose in upper 10
  • Typically medium dense, 10 to 30
  • Typically dense below 30

15
Typical Stratigraphic Layers
  • Bay Mud
  • consists of clay and silt with occasional sand
    lenses and organic material
  • relatively low strength material
  • relatively compressible material
  • If underlain by new fill, it could settle,
    causing downdrag on piles

16
Typical Stratigraphic Layers
  • Colma Formation
  • consists predominantly of sands with occasional
    clay lenses
  • typically contains between 0 to 20 silt/clay
  • relatively strong material
  • relatively incompressible material
  • excellent foundation support

17
Typical Stratigraphic Layers
  • Old Bay Clay
  • consists of stiff to hard overconsolidated clay
  • may contain sand and gravel lenses
  • relatively strong
  • moderately compressible

18
Typical Stratigraphic Layers
  • Franciscan Complex bedrock
  • deformed bedding planes and shear zones due to
    seismic activity
  • highly variable hardness strength
  • moderately to highly weathered
  • Relatively strong and incompressible
  • excellent foundation support

19
Geology and Seismicity
  • Regional Geology
  • Seismicity Faulting
  • distance to faults
  • Geologic Hazards
  • ground shaking
  • liquefaction
  • lateral spreading
  • landsliding
  • tsunami

20
Discussion, Conclusions Recommendations
  • Discussion Conclusions
  • discuss issues, alternatives, implications
  • conclude foundations type and settlement,
    shoring, soil improvement
  • Recommendations
  • provide recommendations regarding the
    geotechnical aspects of the project

21
Settlement
  • Consolidation
  • A slow process of squeezing water out in soft
    clay, resulting in denser packing of soil
    particles, when overlain by new fill
  • Liquefaction
  • Temporary loss of shear strength in loose sand
    due to a rise in excess pore water pressure
    generated by strong seismic shaking
  • Seismic Densification
  • Densification of loose sand above the water table
    due to ground shaking
  • Foundation Settlement

22
Groundwater
  • Depth groundwater encountered
  • Likely fluctuations
  • Design

23
Ground Improvement
  • Stone columns
  • Compaction grouting
  • Chemical grouting
  • Jet grouting
  • Dynamic compaction

24
Foundations
  • The most appropriate foundation type depends on
  • Subsurface conditions
  • Building type and size
  • loading conditions
  • basement levels
  • Site constraints
  • noise
  • vibrations
  • proximity to existing improvements
  • proximity to bay, channel
  • Economics

25
Shallow Foundations
  • Footings
  • isolated
  • continuous
  • grid (waffle)
  • Mat

26
Shallow Foundations
  • suitable where competent material is encountered
    at subgrade elevation
  • can be used in fill where it is improved and
    building is small and light
  • mat can be used to span localized areas of
    non-support
  • mat can be used on softer soil in excavation
    where weight of structure is equal to or less
    than weight of soil removed

27
Deep Foundations
  • Piers
  • Piles

28
Piers
  • Efficient can use one large diameter pier in
    lieu of several piles
  • Lengths can be adjusted in the field reduce
    waste
  • Derive capacity mainly from friction
  • Use casing and/or drilling fluid if groundwater
    and/or loose soil is present

29
Driven Pile
  • Concrete piles are economical in Bay Area
  • Use where soft soil or un-documented fill is
    present
  • Can be used at sites with high groundwater table
    or thick Bay Mud
  • Fabricated at yard (concrete) good quality
    control
  • Moderately high capacity

30
Retaining Walls
  • Restrained vs. Unrestrained Walls
  • Design wall pressure is higher for restrained
    walls
  • Drained vs. Undrained Walls
  • undrained walls are designed to resist
    hydrostatic pressure
  • Drainage
  • drainage panels
  • gravel drain
  • weep holes/pipes
  • Waterproofing
  • where moisture transmission is unacceptable

31
Floor Slabs
  • Slab-on-grade
  • supported on ground
  • less expensive
  • will lose support and settle/crack if settlement
    occurs beneath slab
  • Structural slab
  • supported on foundations
  • more expensive
  • can span areas of non-support due to liquefaction
    and/or settlement

32
Floor Slabs
  • Vapor Barrier
  • typically included beneath floor slabs above the
    water table
  • consists of
  • 4 crushed rock
  • 10 mil visqueen
  • 2 sand
  • alternatives include Griffolyn T65-G
  • easier to install
  • takes less space
  • more expensive
  • perform moisture emission testing prior to
    placement of floor covering

33
Seismic Design
  • Provide site class (A through F)
  • Provide spectral acceleration values for Maximum
    Considered Earthquake (MCE) and Design Earthquake
    (DE)

34
Seismic Design
  • Site Class
  • A hard rock
  • B rock
  • C very dense soil and soft rock
  • D stiff soil profile
  • E soft soil profile
  • F
  • liquefiable
  • more than 10 feet of peat
  • more than 25 feet of very high plasticity clays
    (PIgt75)
  • more than 120 feet of soft/medium stiff clay (Bay
    Mud)

35
Excavation
  • Allowable slopes
  • Shoring
  • Dewatering

36
Site Preparation Earthwork
  • Site preparation
  • remove pavements, organics
  • abandon utilities
  • abandon/remove old foundations
  • overexcavation
  • Earthwork
  • compaction requirements
  • acceptable fill materials

37
Utilities
  • Settlement
  • hangers
  • flexible connections
  • sleeved connections

38
Pavements
  • Flexible
  • Rigid
  • Pavers
  • pedestrian
  • vehicular

39
Site Drainage
  • Keep water away from building
  • Collect all downspouts and surface water
  • All water should be directed to storm drain

40
Additional Geotechnical Services
  • Review geotechnical aspects of plans and
    specifications
  • Observation geotechnical aspects of construction
  • confirm subsurface conditions are as expected
  • contractor performs work in accordance with plans
    and specifications

41
Limitations
  • Conclusions and recommendations are based on
    limited subsurface exploration
  • We should provide observation services to check
    work is completed per plans, specs, and our
    recommendations
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