Experimental Investigation of the High-Temperature Performance of High-Strength Steel Suspension Bridge Wire

Abstract Quantification of the mechanical properties of suspension bridge main cables during fire hazards is a vital part of holistic safety assessment of infrastructure. While some researchers have examined the response of main cables to thermomechanical loading, all of these studies have mentioned...

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Veröffentlicht in:	Journal of bridge engineering 2021-07, Vol.26 (7)
Hauptverfasser:	Robinson, Jumari, Brügger, Adrian, Betti, Raimondo
Format:	Artikel
Sprache:	eng
Schlagworte:	Bridge construction Cables Civil engineering Cold working Elastic limit Fire hazards Hardening Hazard assessment High strength steels Industry standards Manufacturing industry Mechanical properties Modulus of elasticity Proportional limit Steel Steel frames Strain Strength Structural steels Suspension bridges Technical Papers Temperature data Temperature dependence Tension tests Thermal stability Ultimate tensile strength Wire
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container_title	Journal of bridge engineering
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creator	Robinson, Jumari Brügger, Adrian Betti, Raimondo
description	Abstract Quantification of the mechanical properties of suspension bridge main cables during fire hazards is a vital part of holistic safety assessment of infrastructure. While some researchers have examined the response of main cables to thermomechanical loading, all of these studies have mentioned the limitations of their predications due to the dearth in high-temperature data for ASTM A586 high-strength wire. The wire manufacturing process produces steel with very unique microstructural properties. Due to the high degree of cold-working involved, industry standards for the high-temperature performance of structural steel framing cannot be applied to bridge wire. This article presents the results of an exhaustive experimental investigation performed to empirically characterize many aspects of the high-temperature performance of the bridge wire. In addition to the typical engineering parameters of elastic modulus, yield strength, and ultimate strength, temperature dependence of proportional limit, work-hardening coefficient, work-hardening exponent, and ultimate strain is also determined. Two temperature-dependent models of the wire stress–strain behavior are presented herein. The models represent the mean behavior of multiple tension tests at each temperature, and models far more accurate high-temperature A586 wire behavior than was previously possible.
doi_str_mv	10.1061/(ASCE)BE.1943-5592.0001721
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While some researchers have examined the response of main cables to thermomechanical loading, all of these studies have mentioned the limitations of their predications due to the dearth in high-temperature data for ASTM A586 high-strength wire. The wire manufacturing process produces steel with very unique microstructural properties. Due to the high degree of cold-working involved, industry standards for the high-temperature performance of structural steel framing cannot be applied to bridge wire. This article presents the results of an exhaustive experimental investigation performed to empirically characterize many aspects of the high-temperature performance of the bridge wire. In addition to the typical engineering parameters of elastic modulus, yield strength, and ultimate strength, temperature dependence of proportional limit, work-hardening coefficient, work-hardening exponent, and ultimate strain is also determined. Two temperature-dependent models of the wire stress–strain behavior are presented herein. 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source	American Society of Civil Engineers:NESLI2:Journals:2014
subjects	Bridge construction Cables Civil engineering Cold working Elastic limit Fire hazards Hardening Hazard assessment High strength steels Industry standards Manufacturing industry Mechanical properties Modulus of elasticity Proportional limit Steel Steel frames Strain Strength Structural steels Suspension bridges Technical Papers Temperature data Temperature dependence Tension tests Thermal stability Ultimate tensile strength Wire
title	Experimental Investigation of the High-Temperature Performance of High-Strength Steel Suspension Bridge Wire
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