Seismic fragility analyses of sea-crossing cable-stayed bridges subjected to multi-support ground motions on offshore sites

•Seismic fragilities of sea-crossing cable-stayed bridges are numerically analyzed.•Multi-support ground motions at different depths of offshore sites are simulated.•Effects of SSI and hydrodynamic added mass are systematically investigated. As key components in the transportation networks at coasta...

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Bibliographic Details
Published in:Engineering structures 2018-06, Vol.165, p.441-456
Main Authors: Li, Chao, Li, Hong-Nan, Hao, Hong, Bi, Kaiming, Chen, Baokui
Format: Article
Language:English
Subjects:
Bridges
Cable-stayed bridge
Cable-stayed bridges
Chemical analysis
Coastal zone
Computer simulation
Earthquakes
Finite element analysis
Finite element method
Fragility
Ground motion
Mathematical analysis
Mathematical models
MGMDDs
Ocean floor
Offshore
Offshore drilling rigs
Offshore engineering
Offshore site
Offshore structures
Regional development
Seawater
Seismic activity
Seismic design
Seismic engineering
Seismic fragility analysis
Seismic response
Seismology
Soil-structure interaction
SSI
Synthesis
Three dimensional models
Transfer functions
Transportation
Transportation networks
Water analysis
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Summary:•Seismic fragilities of sea-crossing cable-stayed bridges are numerically analyzed.•Multi-support ground motions at different depths of offshore sites are simulated.•Effects of SSI and hydrodynamic added mass are systematically investigated. As key components in the transportation networks at coastal areas, sea-crossing cable-stayed bridges play a very important role in the development of regional economy. These bridges may be subjected to severe earthquakes during their life-cycles. Owing to the lack of actual seafloor earthquake recordings and approaches in synthesizing offshore seismic motions, the onshore seismic motions are commonly utilized as inputs in the seismic design of sea-crossing cable-stayed bridges. However, this approach may lead to erroneous structural response predictions since the characteristics of onshore and offshore seismic motions are different. In this paper, the seismic performance of a sea-crossing cable-stayed bridge is comprehensively evaluated based on the fragility function methodology. A novel approach is presented to theoretically calculate the ground motion transfer function at any location within an offshore site and stochastically synthesize the offshore multi-support ground motions at different depths (MGMDDs). The OpenSees analysis platform is employed to develop the three-dimensional finite element model of the example bridge, in which the p-y, t-z and q-z elements are installed at the pile nodes to simulate the interaction between the bridge piles and surrounding soils. Moreover, the effect of seawater on the bridge seismic responses is modeled using the hydrodynamic added mass method. The seismic fragility curves of the example bridge are generated by using the synthesized MGMDDs as inputs. The influences of spatial and depth varying offshore seismic motions, soil-structure interaction (SSI) and seawater added mass on the bridge component and system fragilities are investigated and discussed. Numerical results show that the seismic fragility of the example sea-crossing cable-stayed bridge is affected by the above mentioned influencing factors with different extents. The proposed approach can rationally and effectively assess the seismic fragilities of sea-crossing cable-stayed bridges.
ISSN:0141-0296
1873-7323
DOI:10.1016/j.engstruct.2018.03.066