Numerical study on buckling capacity of steel H-beams under non-uniform temperature distribution

IF 0.9 Q4 CONSTRUCTION & BUILDING TECHNOLOGY

Journal of Structural Fire Engineering Pub Date : 2022-07-18 DOI:10.1108/jsfe-01-2022-0002

Thac-Quang Nguyen, X. Nguyen, Tri Nguyen, T. Bui-Tien, J. S. Park

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引用次数: 1

Abstract

PurposeThe strength and stiffness of steel deteriorate rapidly at elevated temperatures. Thus, the characteristics of steel structures exposed to fire have been concerned in recent years. Most studies on the fire response of steel structures were conducted at uniformly distributed temperatures. This study aims to evaluate the buckling capacity of steel H-beams subjected to different loading conditions under non-uniform heating.Design/methodology/approachA numerical investigation was conducted employing finite element analysis software, ABAQUS. A comparison between the numerical analysis results and the experimental data from previous studies was conducted to verify the beam model. Simply supported beams were loaded with several loading conditions including one end moment, end equal moments, uniformly distributed load and concentrated load at midspan. The effects of initial imperfections were considered. The buckling capacities of steel beams under fire using the existing fire design code and the previous study were also generated and compared.FindingsThe results showed that the length-to-height ratio and loading conditions have a great effect on the buckling resistance of steel beams under fire. The capacity of steel beams under non-uniform temperature distribution using the existing fire design code and the previous study can give unconservative values or too conservative values depending on loading conditions. The maximum differences of unconservative and conservative values are −44.5 and 129.2% for beams subjected to end equal moments and one end moment, respectively.Originality/valueThis study provides the buckling characteristics of steel beams under non-uniform temperature considering the influences of initial imperfections, length-to-height ratios, and loading conditions. This study will be beneficial for structural engineers in properly evaluating structures under non-uniform heating conditions.

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非均匀温度分布下H型钢梁屈曲承载力的数值研究

目的钢的强度和刚度在高温下迅速退化。因此，钢结构在火灾中的特性近年来一直受到关注。大多数关于钢结构火灾响应的研究都是在均匀分布的温度下进行的。本研究旨在评估H型钢梁在不同荷载条件下在非均匀加热下的屈曲能力。设计/方法/方法采用有限元分析软件ABAQUS进行数值研究。将数值分析结果与以往研究的实验数据进行了比较，以验证梁模型。简支梁采用单端弯矩、端部等弯矩、均布荷载和跨中集中荷载等几种荷载工况进行荷载计算。考虑了初始缺陷的影响。还生成并比较了使用现有消防设计规范和先前研究的钢梁在火灾下的屈曲能力。结果表明，长高比和荷载条件对钢梁在火灾下的抗屈曲性能有很大影响。根据现有的防火设计规范和先前的研究，钢梁在不均匀温度分布下的承载力可能会根据荷载条件给出不守恒值或过于保守的值。受端部等弯矩和一端弯矩作用的梁的非保守值和保守值的最大差值分别为−44.5%和129.2%。原创性/价值本研究提供了考虑初始缺陷、长高比和荷载条件影响的非均匀温度下钢梁的屈曲特性。这项研究将有利于结构工程师在非均匀加热条件下正确评估结构。

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来源期刊

Journal of Structural Fire Engineering CONSTRUCTION & BUILDING TECHNOLOGY-

CiteScore

2.20

自引率

10.00%

发文量