Safety of Cable-Supported Bridges during Fire Hazards
Publication: Journal of Bridge Engineering
Volume 21, Issue 4
Abstract
Understanding of the performance of critical bridges, such as cable-supported bridges, during accidental fire is necessary for developing mitigation strategies against potential fire damage. In this research, the structure–fire interaction of long-span cable-supported bridges, in particular, anchored suspension bridges, self-anchored suspension bridges, and cable-stayed bridges, was investigated through nonlinear finite-element analysis. To investigate the stability of these bridges during fire, a typical steel orthotropic box girder was exposed to different fire scenarios representing fires during ship and truck accidents. The stability of the three bridges during two fire scenarios was investigated in terms of fire intensity and duration and axial compressive force in the deck. Simulation results indicate that the existing axial force in the deck negatively affected the structural performance by causing buckling failure under fire loads. Generally, anchored suspension bridges had the largest safety factor among the three bridges because of nearly zero axial force in the deck. On the other hand, self-anchored suspension bridges had a significantly higher amount of existing axial compressive force in the deck and were the most vulnerable during both the truck and the ship fire scenarios. The axial forces in cable-stayed bridge decks varied longitudinally. Hence, their vulnerability during fires depends on the location of fire, the magnitude of existing axial force, and the design capacity of the deck.
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© 2015 American Society of Civil Engineers.
History
Received: Oct 2, 2014
Accepted: Oct 5, 2015
Published online: Jan 20, 2016
Published in print: Apr 1, 2016
Discussion open until: Jun 20, 2016
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