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Assessment of redundancy protocols for short-span steel truss bridges

Assessment of redundancy protocols for short-span steel truss bridges Owner agencies and state transportation departments have expressed concern over costly inspection requirements for short-span steel truss bridges due to the potential designation of members as fracture-critical. This designation has a direct impact on future implementation of these structures as well as perceived inherent safety in existing bridges of this type. Throughout the years, researchers have developed methodologies to determine the degree of load-path redundancy that such structures exhibit, which, once employed, may eliminate the potential for fracture-critical designation, alleviating inspection costs and promoting these types of structures in highway bridge applications. This paper presents the results of a highly accurate, nonlinear finite element investigation of the load-path redundancy of a representative short-span steel truss bridge, which is benchmarked against physical load testing of the bridge. Once validated, the model will undergo a series of severed member analysis to determine the inherent levels of load-path redundancy. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Bridge Structures IOS Press

Assessment of redundancy protocols for short-span steel truss bridges

Bridge Structures , Volume 10 (2) – Jan 1, 2014

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Publisher
IOS Press
Copyright
Copyright © 2014 by IOS Press, Inc
ISSN
1573-2487
eISSN
1744-8999
DOI
10.3233/BRS-140078
Publisher site
See Article on Publisher Site

Abstract

Owner agencies and state transportation departments have expressed concern over costly inspection requirements for short-span steel truss bridges due to the potential designation of members as fracture-critical. This designation has a direct impact on future implementation of these structures as well as perceived inherent safety in existing bridges of this type. Throughout the years, researchers have developed methodologies to determine the degree of load-path redundancy that such structures exhibit, which, once employed, may eliminate the potential for fracture-critical designation, alleviating inspection costs and promoting these types of structures in highway bridge applications. This paper presents the results of a highly accurate, nonlinear finite element investigation of the load-path redundancy of a representative short-span steel truss bridge, which is benchmarked against physical load testing of the bridge. Once validated, the model will undergo a series of severed member analysis to determine the inherent levels of load-path redundancy.

Journal

Bridge StructuresIOS Press

Published: Jan 1, 2014

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