ADSCCALTRANS CIDH Pile Workshop - PowerPoint PPT Presentation

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ADSCCALTRANS CIDH Pile Workshop

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Displacement Ductility Demand Limits (1.5-3/5 for bents supported by the shafts, per SDC 2.2.3) Minimum Local Displacement Ductility Capacity Limits (SDC 3.1.4.1) ... – PowerPoint PPT presentation

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Title: ADSCCALTRANS CIDH Pile Workshop


1
Overview of Structural Design and Detailing of
Large Diameter Drilled Shafts (Caltrans Practice)
  • Amir M. Malek, PE, PhD
  • Senior Bridge Engineer (Technical Specialist)
  • Office of Bridge Design Services
  • California Department of Transportation

2
Outline
  • Types of Large Diameter Shafts and Comparison
  • Design Highlights and Review of LRFD Requirements
  • Communications of Structural and Geotechnical
    Designers for LRFD of Shafts
  • Highlights of Seismic Design and Detailing
    Requirements per Caltrans Seismic Design Criteria
    (SDC)
  • Case Study

3
Applications and Types
  • Used for high seismic loads also where small
    footprint is desirable
  • Most effective where hard layer (rock) is
    reachable
  • Used with/without casing
  • Types I II per SDC classification
  • Type-I More ductile performance,
    advantageous for short columns
  • Type-II Easier post-event repair, shaft
    enlargement of at least 18 (24 under study) to
    contain inelastic action to the column
    (SDC 7.7.3.5)

4
Test of 6 diameter Type-I Shaft at UCLA
5
Test of 6 diameter Type-I Shaft at UCLA
6
Types of Large Diameter Drilled Shafts (Caltrans
SDC)
7
LRFD Seismic Design Highlights
  • Structural Designer provides Factored Loads for
    applicable Limit States
  • Geotechnical Designer will provide tip elevations
    based on Compression, Tension, and Settlement
    also Factored Nominal Resistance for Service,
    Strength and Extreme Event Limit States (LRFD)
  • Structural Designer performs Stability Analysis
    and provides tip elevation for Lateral Loads
  • Structural Designer analyzes, designs and details
    the shaft for Seismic Demands according to
    Caltrans SDC
  • Scour, Liquefaction and Lateral Spreading are
    considered in design (if applicable)

8
Review of LRFD Requirements
  • Consider Service, Strength and Extreme Event
    Limit States for Geotechnical and Structural
    Design of the Shaft
  • Follow MTD3-1 for Communications and Transfer of
    Information between SD and GS as summarized in
    the following Tables

9
Preliminary Design Data Sheet(to be provided by
SD)
10
General Foundation Information(to be provided by
SD)
11
Foundation Design Loads(to be provided by SD)
12
Lateral Stability (BDA Chapter 12) Available
Software LPILE, W-FRAME, or SAP
13
General Seismic Design Highlights (Requirements
that may be affected by size/type of the shaft)
  • Geometrical/Structural Irregularities
  • Demand and Capacity
  • P-? Effect
  • Displacement Ductility Limitation
  • Minimum Local Displacement Ductility Capacity

14
  • Geometrical/Structural Irregularities
  • Balanced Stiffness of Bents (SDC 7.1.1)
  • Balanced Frame Geometry (SDC 7.1.2)
  • Demand vs. Capacity (SDC 4.1.1)
  • P-? Effect (SDC 4.2)
  • Displacement Ductility Demand Limits (1.5-3/5 for
    bents supported by the shafts, per SDC 2.2.3)
  • Minimum Local Displacement Ductility Capacity
    Limits (SDC 3.1.4.1)

15
Structural Analysis for Demand Assessment
  • Use Expected Material Properties
  • Determine Column/Shaft Plastic Moments from
    Section Analysis
  • Use Mo1.2Mp
  • Use Push-over Analysis and Find Shear and Moment
    Demands at Collapse

16
Demand Calculation (Single Column Bent)
Mo
17
Seismic Demand Calculation (Multi-Column Bent)
Mo
Type-I
18
Seismic Demand Calculation (Multi-Column Bent)
Mo
Type-II
19
Structural Design of the Shafts
  • MneType II gt 1.25 MDemand (SDC 7.7.3.2)
  • VnType II gt VDemand (SDC 3.6.7)
  • Shear capacity is calculated as a ductile member
    using SDC 3.6 requirements (for Type-II assume
    µd1)

20
Detailing Requirements
  • No Splice Zones (SDC 8.1.1)
  • Plastic hinge region and areas of MDgtMy
  • Ultimate Splices (SDC 8.1.2)
  • Ductile members outside No Splice Zone
  • Service Splice (MTD20-9)
  • Capacity Protected Members like Bent Cap
  • For Hoops and Spirals in Ductile Members Use
    Ultimate Splices, Except
  • No splices in spirals used in No Splice
    Zones (end anchorage has been used to improve
    constructability)

21
Case Study (Type-II)
Top of the Pile Boundary Conditions V M (V150
kips, M3,750 k-ft)
22
Liquefied Layer
23
Typical
24
Typical
25
Typical
26
Typical
27
Scour Included
28
Summary (Method-I)
29
(No Transcript)
30
Thank You
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