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Requirements for Foundations on Liquefiable Sites
Robert Bachman, S.E. R. E. Bachman Consulting Structural Engineers Laguna Niguel, CA
February 14, 2016
SC 10 Short Course Geo & SEI Congress, Phoenix, AZ
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Issue Team and ASCE 7 Contributing Members Evolved and Improved at Each Stage of Development
• Bob Bachman, Chair • CB Crouse, URS • Geoff Martin, USC • Lori Simpson, Langan Treadwell Rollo & Deep Foundation Institute • Gyimah Kasali, Rutherford & Chekene • Dom Campi, Rutherford & Chekene • Jon Siu, City of Seattle • Omar Jaradat, Moffatt & Nichol • Steve Harris, Simpson Gumpertz & Heger And TC-3 of the ASCE 7 Seismic Subcommittee • Martin Johnson, ABS Consulting • Ron La Plante, DSA
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Reasons for New Provisions
• ASCE 7-10
– Section 12.13 (Foundation Design) does not include provisions pertaining to Liquefaction – Chapter 18 of IBC now refers to ASCE 7 for liquefaction - POLA
– Section 11.8 (Geologic Hazards and Geotechnical Investigation) requires explicit assessment of the following for MCEG rather than DE for SDC D, E and F:
• Potential for Liquefaction and Soil Strength Loss • Assessment of potential consequences, including
– Total settlement – Differential settlement – Lateral soil movement due to lateral spreading – Reduction in soil bearing and lateral capacity – Downdrag on piles
• Gapping Hole – No foundation requirements if liquefaction potential exists at site – Huge range on what is being done in practice
• New provisions (provided in new Section 12.13.9 of ASCE 7-16) will fill
gapping hole by providing - Specific requirements for design and level of ground improvement needed if shallow foundations are to be used - Specific requirements for deep foundations at liquefiable sites
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Some Recent Experience with Liquefaction
• Moss Landing 1989 – Monterey Bay Aquarium
Research Institute • Foundations with ties • Performed well
– Moss Landing Marine Lab • No foundation ties • Collapse due to lateral
spreading • Kocaeli 1999
– Large differential settlements resulted in building collapses
• Christchurch 2012 – Large differential settlements
resulted in irreparable tilts – Pile foundations and
foundation ties improved performance
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Geo & SEI Congress, Phoenix, AZ 4
MBARI
MLML
New Requirement Concepts
• Consider reduced capacities - Soil strength and stiffness at MCEG
– Must also design for non-liquefied condition for DE loadings
• Level of shaking considered: pga @ MCEG – In most of CA, MCEG is comparable
to MCER.
• Small levels of liquefaction may be
neglected (1/4 of Table 12.3-3) • Ground improvement may be
considered
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Zip City MCER SMS MCER pga MCEG pga
90012 Los Angeles 2.52 1.01 0.9692101 San Diego 1.23 0.49 0.5594104 San Francisco 1.50 0.60 0.6095816 Sacramento 0.84 0.34 0.30
Performance Criteria for Liquefaction
• NEHRP Recommended Provisions (FEMA P-1050) • One implicit set of goals, two explicit approaches
– Structures designed for Design Earthquake (Life Safety) – Liquefaction assessed for MCEG (Collapse Prevention)
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Performance Criteria for Liquefaction
• Structural Performance Levels
• What does this mean for foundation design? – Life Safety: Maintain gravity and lateral support with some margin – Collapse Prevention: Maintain gravity support
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Operational Life Safety
Collapse Prevention
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Immediate Occupancy
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Operational
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Life Safety
Collapse Prevention
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Immediate Occupancy
New Requirement Concepts
• Shallow Foundations – Allowed only in certain cases (considering ground improvement):
• Estimated lateral spreading less than upper limit • Estimated differential settlement less than threshold limit
– or show adequacy by analysis
– Foundation ties/post tensioning required to hold building together – Mat foundations must meet minimum reinforcing or be designed
for differential settlement
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New Requirement Concepts • Deep Foundations
– Allowed in all cases – Design for normal vertical loading, plus downdrag – Piles not expected to remain elastic under lateral spreading
• Residual strength requirement – show adequacy by analysis
• Ductility through detailing – Foundation ties hold footings together (must consider racking)
February 14, 2016 SC 10 Short Course Geo & SEI Congress, Phoenix, AZ
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Compliance with New Requirements
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Liquefaction or Soil Strength
Loss?
Yes
No
No lateral spreading? No bearing loss?
< 1/4 of diff. settlement limit?
Yes
Shallow Foundations OK
with proper detailing
Within lateral spreading
limits of Table 12.13-2?
No
OK
Within diff. settlement Limits of Table
12.13-3?
Yes
No
Start
OK
Analysis shows acceptable
performance?
No
Yes No
Use Deep Foundations with proper detailing
Yes
Lateral Spreading Limits
• Table 12.13-2 – Upper Limit on Lateral Spreading Horizontal Ground
Displacement for specially tied together Shallow Foundations or Mats Beyond which Deep Foundations are Required
• Risk Category I or II: 18 in. • Risk Category III: 12 in. • Risk Category IV: 4 in.
– Basis for values is experience of collapse resistance at 0.5m displacement, scaled down for higher Risk Categories.
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Differential Settlement Threshold
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Table 12.13-2 Differential Settlement Threshold, Δva
Structure Type Risk Category
I or II III IV Single-story structures with concrete or masonry wall systems. 0.0075L 0.005L 0.002L Other single-story structures. 0.015L 0.010L 0.002L Multi-story structures with concrete or masonry wall systems. 0.005L 0.003L 0.002L Other multi-story structures. 0.010L 0.006L 0.002L
Differential Settlement Threshold
• Building Response to Excavation-Induced Settlement – Boscardin and Cording (J. Geotech. Engrg, 1989)
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g y
Multi-story structures with concrete or masonry wall systems. 0.005L 0.003L 0.002L
Differential Settlement Threshold
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• Risk Category III thresholds are generally ~2/3 of Risk Category II thresholds • Single-story thresholds are generally 50% higher than multi-story thresholds • Structures without stiff walls are permitted twice the differential settlement. (Values are
consistent with drifts for high-ductility frames in ASCE-41.)
Table 12.13-2 Differential Settlement Threshold, Δva
Structure Type Risk Category
I or II III IV Single-story structures with concrete or masonry wall systems. 0.0075L 0.005L 0.002L Other single-story structures. 0.015L 0.010L 0.002L Multi-story structures with concrete or masonry wall systems. 0.005L 0.003L 0.002L Other multi-story structures. 0.010L 0.006L 0.002L
Differential Settlement Threshold
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• Risk Category IV – Threshold is based on functionality, rather than safety. – ATC-58 project assessed fragility of damage onset for jammed
doors: Median drift = 0.0023. – Median is divided by 1.5 to account for statistical dispersion
(90% non-exceedance) – Result is multiplied by 1.5 to account for settlement assessment
at MCEG, as opposed to DE. – Therefore use 0.002.
Settlement Threshold by Analysis
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• Nonlinear analysis (static OK) required for Risk Category II and III – Residual strength of members and connections shall not be less
than 67% of nominal strength – some degradation OK
• Linear analysis is sufficient for Risk Category IV – Demands on members and connections shall not exceed
nominal strengths
Usually 20% to 40%
Shallow Foundation Detailing
• Foundation Ties – Section 12.13.8.2 already requires ties between foundations with
a force equal to the larger column load multiplied by 0.10SDS. • This is also in CBC Chapter 18, with some slightly different words.
– Where expected lateral spreading exceeds 3 inches, additional requirements apply in the new provisions:
• 𝐹𝐹𝑡𝑡𝑡𝑡𝑡𝑡 = 0.5𝜇𝜇𝑃𝑃𝑢𝑢 • 𝜇𝜇 = Coefficient of friction • 𝑃𝑃𝑢𝑢 = Sum of factored loads along a line
– Intended to hold the building together when one part moves relative to another
• Design for worst condition – soil under half the building is moving and other half isn’t
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Shallow Foundation Detailing
• Foundation Ties – Example: 𝑃𝑃𝑢𝑢𝑡𝑡 = 100𝑘𝑘 each – Coefficient of friction: 𝜇𝜇 = 0.50 (default)
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𝐹𝐹𝑡𝑡𝑡𝑡𝑡𝑡 = 0.5 𝜇𝜇 =0.5 4 100𝑘𝑘 = 100k
𝑃𝑃𝑢𝑢4 𝑃𝑃𝑢𝑢3 𝑃𝑃𝑢𝑢2 𝑃𝑃𝑢𝑢1 𝐹𝐹𝑡𝑡𝑡𝑡𝑡𝑡
𝜇𝜇𝑃𝑃𝑢𝑢3 𝜇𝜇𝑃𝑃𝑢𝑢4 𝜇𝜇𝑃𝑃𝑢𝑢1 𝜇𝜇𝑃𝑃𝑢𝑢2
Shallow Foundation Detailing • Foundation Ties for Shear
– Shear resistance between adjacent lines
• Slab-on-grade – integral or connected – Mild steel ρ = 0.0025 or 100 psi min pre-compression PTI
DC10.5 D & A Post-Tensioned Concrete Slab on Expansive Soils
• Alternate: diagonal system of grade beams
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Shallow Foundation Detailing
• Mat foundation detailing (or Post Tensioned) – Reinforcing each way, top and bottom – Detail according to ACI 318-14, Section 18.6.3.1
• Minimum longitudinal reinforcing only – OR design to accommodate expected differential settlements
• Elastic design • Consistent with small permitted differential settlements
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Performance Criteria for Deep Foundations
• Design for Collapse Prevention at MCEG – Nonlinear structural behavior allowed – More difficult engineering – Plastic hinges form in piles
• NEHRP 2015/ASCE7-16 Requirements – Pile must maintain gravity support – Pile flexural strength must not degrade significantly – Special detailing is necessary for ductility – Pile must remain elastic in shear
• Double plastic hinge
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Deep Foundation Design
• Design for vertical loads + lateral deformations from DE inertial loads – Explicit design for MCEG caused lateral
spreading deformations – Reduce capacity due to MCEG caused liquefied
condition • Vertical – downdrag • Lateral – softer p-y springs,
• Lateral Resistance reduced by liquefaction – Passive pressure and friction on caps, beams,
walls – Resistance of soil on piles
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Deep Foundation Detailing
• Design for Lateral Spreading – Analysis
• Nonlinear analysis required, except for very small deformations • Ability to carry gravity load shall not be compromised • Residual pile lateral strength must remain at least 67% of nominal • Pile shear demand must remain less than nominal capacity
– Detailing • Steel piles must meet requirements for highly ductile members • Concrete piles must comply with ACI 318-14 Sections 18.7.5.2 -.4
– Confinement as for special moment frame columns – At least 7 diameters below depth of liquefaction – Similar to current OSHPD and DSA requirements
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𝐹𝐹𝑡𝑡𝑡𝑡𝑡𝑡=𝐹𝐹𝑝𝑝𝑝𝑝
𝐹𝐹𝑝𝑝𝑝𝑝 𝐹𝐹𝑝𝑝𝑝𝑝 𝐹𝐹𝑝𝑝𝑝𝑝 𝐹𝐹𝑝𝑝𝑝𝑝
Deep Foundation Detailing
• Foundation Ties – Basic requirement (0.10SDS) still applies – For lateral spreading, design for engagement of passive
pressure on caps and beams
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Design for Lateral Resistance
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• Consider pile resistance and cap, beam resistance – Use compatible deformations – Behavior of soil is nonlinear
Downdrag loading on piles
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• Downdrag assessed at ultimate level – Safety factor applied to net ultimate capacity
• Downward (negative) skin friction within and above soils subject to liquefaction
• Downdrag load is considered a seismic load (1.0 load factor)
Liquefied soil
Summary
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• New requirements provide – Consistency with current Code performance goals – Rational means of foundation type selection given soil behavior – Design and detailing requirements
• Shallow foundations • Deep foundations
• In the 2015 NEHRP Recommended Seismic Provisions for New Buildings (FEMA P-1050)
• Coming Soon to ASCE 7-16 and Building Codes (IBC 2018 and CBC 2019) near you!
Questions?
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