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Seismic Design of Bridges

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Title: Seismic Design of Bridges


1
Seismic Designof Bridges
  • Lucero E. Mesa, P.E.

2
SCDOT Seismic Design Of Bridges Overview
  • AASHTO - Division IA
  • Draft Specifications, 1996
  • SCDOT 2001 Seismic Design Specifications
  • Comparison Between LRFD SCDOT Specs.
  • SCDOT Seismic Hazard Maps
  • Training and Implementation
  • Conclusions

3
AASHTO Div IA
  • USGS 1988 Seismic Hazard Maps
  • Force based design
  • Soil Classification I-IV
  • No explicit Performance Criteria
  • Classification based only on acceleration
    coefficient

4
CHARLESTON, SOUTH CAROLINAAugust 31, 1886
(Intensity IX-X)
5
Earthquake of August 31, 1886 Charleston, South
CarolinaMagnitude7.3M, Intensity X
6
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7
Draft Specifications
  • 1996 USGS Seismic Hazard Maps
  • Difference in spectral acceleration between South
    Carolina and California
  • Normal Bridges 2/3 of the 2 in 50 yr. Event
  • Essential Bridges Two-Level Analysis

8
Draft Specifications
  • Force based specifications
  • N (seat width)
  • Soil classification I IV
  • Draft Specifications Version of 1999

9
Site Specific Studies
  • Maybank Bridge over the Stono River
  • Carolina Bays Parkway
  • Broad and Chechessee River Bridges
  • New Cooper River Bridge
  • Bobby Jones Expressway

10
SEISMIC DESIGN TRIAL EXAMPLES
  • SC-38 over I-95 - Dillon County
  • Maybank Highway Bridge over the Stono River -
    Charleston County

11
SC-38 over I-95
Description of Project
  • Conventional bridge structure
  • Two 106.5 ft. spans with a composite reinforced
    concrete deck, supported by 13 steel plate
    girders and integral abutments
  • The abutments and the interior bents rest on
    deep foundations

12
SC-38 over I-95
  • Original Seismic Design
  • SCDOT version of Div-IA AASHTO (Draft)
  • 2/3 of 2 in 50 yr
  • 1996 USGS maps used
  • PGA of 0.15g, low potential for liquefaction
  • Response Spectrum Analysis
  • Trial Design Example
  • Proposed LRFD Seismic Guidelines
  • MCE 3 PE in 75 yr.
  • Expected Earthquake 50 PE in 75 yr.
  • 2000 USGS maps
  • PGA of 0.33g, at MCE, further evaluation for
    liquefaction is needed.
  • Response Spectrum Analysis

13
Maybank Highway Bridgeover the Stono River
14
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15
Maybank Highway over Stono RiverDescription of
project
  • 118 spans
  • 1-62 flat slab deck supported by PCP
  • 63-104 /33 -meter girder spans and 2 columns per
    bent supported by shafts.
  • The main span over the river channel consists of
    a 3 span steel girder frame w/ 70 meter center
    span.
  • 105-118 flat slab deck supported by PCP

16
Maybank Highway over Stono River
  • Original Seismic Design
  • SCDOT version of AASHTO Div. I-A (Draft)
  • Site Specific Seismic Hazard
  • Bridge classified as essential
  • Project specific seismic performance criteria
  • Two level Analysis
  • FEE 10 in 50 yr. event
  • SEE - 2 in 50 yr. event
  • Trial Design Example
  • Proposed LRFD Guidelines -2002
  • Two Level Analysis
  • Expected Earthquake - 50 in 75 yr.
  • MCE 3 in 75 yr.

17
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18
Maybank Highway over Stono River
  • Original Seismic Design
  • Soil Classification Type II
  • Trial Design Example
  • Stiff Marl classified as Site Class D

19
  • The SCDOT 's new specifications adopted the NCHRP
    soil site classification and the Design Spectra
    described on LRFD 3.4.1
  • If this structure were designed using the new
    SCDOT Seismic Design Specifications, October
    2001, the demand forces would be closer if not
    the same to those found using the Proposed LRFD
    Guideline -2002 .

20
Cooper River BridgeCharleston Co.
  • Seismic Design Criteria- Seismic Panel
  • Synthetic TH
  • PGA - 0.65g
  • Sa 1.85 at T0.2 sec
  • Sa 0.65 at T1 sec
  • Liquefaction

21
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22
Cooper River Bridge 2500 Yr - SEE for Main Piers
23
Need for
  • New Specifications
  • South Carolina Seismic Hazard Maps

24
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25
SCDOT Seismic Design Specifications October 2001
  • The new SCDOT specifications establish design and
    construction provisions for bridges in South
    Carolina to minimize their susceptibility to
    damage from large earthquakes.

26
PURPOSE PHILOSOPHY (1.1)
  • SCDOT Seismic Design Specifications replace
    AASHTO Division I-A SCDOT Draft
  • Principles used for the development
  • Small to moderate earthquakes, FEE, resisted
    within the essentially elastic range.
  • State-of-Practice ground motion intensities are
    used.
  • Large earthquakes, SEE, should not cause
    collapse.
  • Four Seismic Performance Categories (SPC) are
    defined to cover the variation in seismic hazard
    of very small to high within the State of South
    Carolina.

27
New Concepts and Enhancements
  • New Design Level Earthquakes
  • New Performance Objectives
  • New Soil Factors
  • Displacement Based Design
  • Expanded Design Criteria for Bridges

28
SCDOT Seismic Design Specifications October 2001
  • Small to Moderate Earthquakes
  • Essentially Elastic
  • No Significant Damage
  • Functional Evaluation Earthquake
  • (FEE) or 10 in 50 yr. event

29
SCDOT Seismic Design Specifications October 2001
  • Large Earthquakes
  • Life Safety
  • No Collapse
  • Serviceability
  • Detectable and Accessible Damage
  • Safety Evaluation Earthquake
  • (SEE) or 2 in 50 yr. event

30
SCDOT Seismic Design Specifications Background
(1.2)
  • New USGS Probabilistic Seismic Hazard Maps
  • New Design Level Earthquakes
  • New Performance Objectives
  • A706 Reinf. Steel
  • New Soil Factors
  • Displacement Based Design
  • Caltrans (SDC) new provisions included

31
Upgraded Seismic Design Requirement (1.3)
  • New Provisions meet current code objectives for
    large earthquakes.
  • Life Safety
  • Serviceability
  • Design Levels
  • Single Level 2 / 50 years
  • Normal Bridges
  • Essential Bridges
  • Two Level 2 / 50 years and 10 / 50 years
  • Critical Bridges

32
SCDOT Seismic Design Specifications Seismic
Performance Criteria
III
II
I
33
SCDOT Seismic Design Specifications October 2001
34
VALUES OF Fa AS A FUNCTION OF SITE CLASS AND
MAPPED SHORT-PERIOD SPECTRAL RESPONSE
ACCELERATION SS (TABLE 3.3.3A)
35
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36
SCDOT Seismic Design Specifications October 2001
37
DESIGN SPECTRA FOR SITE CLASS A, B, C, D AND E,
5 DAMPING (3.4.5E)
SDI-SEE
38
APPLICABILITY (3.1)
  • New Bridges
  • Bridge Types
  • Slab
  • Beam Girder
  • Box Girder
  • Spans less than 500 feet
  • Minimum Requirements
  • Additional Provisions are needed to achieve
    higher performance for essential or critical
    bridges

39
DESIGN PHILOSOPHY AND STRATEGIES
  • Specifications can be used in conjunction with
    rehabilitation, widening, or retrofit
  • SPC B demands are compared implicitly against
    capacities
  • Criteria is focused on member/component
    deformability as well as global ductility
  • Inherent member capacities are used to resist
    higher earthquake intensities
  • Using this approach required performance levels
    can be achieved in the Eastern US

40
Design Approaches (4.7.1)
41
Other New Concepts and Improvements
  • Plastic Hinge Region Lpr (4.7.7)
  • Plastic Hinge Length (4.7.7)
  • Seat Width SPC A and B, C, D(4.8.2)
  • Detailing Restrainers (4.9.3)
  • Butt Welded Hoops
  • Superstructrure Shear Keys(4.10)

42
Seismic Designof Bridges
Thanks
  • Lucero E. Mesa, P.E.
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