Calculation method for temperature rise of aluminum alloy structural members in large-space fires

被引：0

作者：

Guo X. ^{[1
]}

Chen C. ^{[1
]}

Zhu S. ^{[1
]}

Zhang C. ^{[1
]}

机构：

[1] College of Civil Engineering, Tongji University, Shanghai

来源：

Zhu, Shaojun (zhushaojun@tongji.edu.cn) | 1600年 / Science Press卷 / 42期

关键词：

Aluminum alloy; Fire radiation; Large-space fire; Temperature rise of member;

D O I：

10.14006/j.jzjgxb.2019.0876

中图分类号：

学科分类号：

摘要：

In the process of performance-based fire design, the calculation method for the temperature rise of structural members in fire has a significant influence on the design results. In order to study the calculation method for the temperature rise of aluminum alloy structural members in large-space fires, as well as the influence of the flame radiation on the temperature rise, two aluminum alloy specimens with commonly used sections were tested in fire. The experimental results show that the temperature of the specimens is close to that of the surrounding air due to the fire radiation. Based on the heat transfer differential equation of aluminum alloy structural members, the calculation methods for the temperature rise of aluminum alloy members under compartment fires and large-space fires were proposed and compared with the experimental results. The analysis results show that the ignorance of the effect of fire radiation on the calculation of temperature rise of aluminum alloy members in large-space fires will lead to unconservative results. The proposed method based on point fire assumption for calculating the radiative heat flux of the fire is more accurate and simpler than the method recommended by Eurocode. In addition, the emissivity of smoke under the fire radiation has great influence on the calculation of the temperature rise of members. A practical formula was fitted based on the experimental results.The results of the formula agree well with the experimental results. © 2021, Editorial Office of Journal of Building Structures. All right reserved.

引用

页码：118 / 126

页数：8

共 40 条

[21] HUANG Jueqian, LI Guoqiang, DU Yong, Et al., Influence of flame radiation on temperature rising of steel members in large space fire, Journal of Natural Disasters, 17, 5, pp. 87-94, (2008)
[22] ZHANG Guowei, ZHU Guoqing, WANG Xiaolan, Et al., The calculation of steel temperature rise in the large-space building based on the regional model, Fire Science and Technology, 29, 12, pp. 1043-1046, (2010)
[23] ZHANG Guowei, ZHU Guoqing, HUANG Lili, Experiment and theoretical model for the temperature development in steel members exposed to fire in the large space building, Journal of China University of Mining & Technology, 42, 3, pp. 370-374, (2013)
[24] ZHANG Guowei, ZHU Guoqing, YUAN Guanglin, Et al., Temperature model of steel members exposed to thermal radiation and fire in large space building, Journal of Harbin Institute of Technology, 45, 6, pp. 96-101, (2013)
[25] Eurocode 9: design of aluminum alloy structures: part 1-2: structural fire design: EN 1999-1-2, (2007)
[26] ZHENG Yongqian, CHEN Zhibo, ZHANG Zheng, Temperature rises of square aluminium alloy tubular columns in fire, Fire Science and Technology, 33, 9, pp. 991-994, (2014)
[27] SUZUKI J, OHMIYA Y, WAKAMATSU T, Et al., Evaluation of fire resistance of aluminum alloy members, Fire Science and Technology, 24, 4, pp. 237-255, (2005)
[28] GUO Xiaonong, CHEN Chen, ZHU Shaojun, Et al., Nondestructive experimental study on fire response of aluminum alloy shells with gusset joints, Journal of Building Structures, 42, 6, pp. 72-84, (2021)
[29] Technical specification for aluminum alloy reticulated structures: DG/TJ-08-95-2020
[30] YI Liang, HUO Ran, ZHANG Jingyan, Et al., Characteristics of heat release rate of diesel oil pool fire, Journal of Combustion Science and Technology, 12, 2, pp. 164-168, (2006)

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