Effect of cavity radiation on aluminium hollow tubes and facade system subjected to fire

IF 0.9 Q4 CONSTRUCTION & BUILDING TECHNOLOGY Journal of Structural Fire Engineering Pub Date : 2023-11-22 DOI:10.1108/jsfe-04-2023-0025
Dravesh Yadav, R. S. Ayyagari, G. Srivastava
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Abstract

PurposeThis paper numerically investigates the effect of cavity radiation on the thermal response of hollow aluminium tubes and facade systems subjected to fire.Design/methodology/approachFinite element simulations were performed using ABAQUS 6.14. The accuracy of the numerical model was established through experimental and numerical results available in the literature. The proposed numerical model was utilised to study the effect of cavity radiation on the thermal response of aluminium hollow tubes and facade system. Different scenarios were considered to assess the applicability of the commonly used lumped capacitance heat transfer model.FindingsThe effects of cavity radiation were found to be significant for non-uniform fire exposure conditions. The maximum temperature of a hollow aluminium tube with 1-sided fire exposure was found to be 86% greater when cavity radiation was considered. Further, the time to attain critical temperature under non-uniform fire exposure, as calculated from the conventional lumped heat capacity heat transfer model, was non-conservative when compared to that predicted by the proposed simulation approach considering cavity radiation. A metal temperature of 550 °C was attained about 18 min earlier than what was calculated by the lumped heat capacitance model.Research limitations/implicationsThe present study will serve as a basis for the study of the effects of cavity radiation on the thermo-mechanical response of aluminium hollow tubes and facade systems. Such thermo-mechanical analyses will enable the study of the effects of cavity radiation on the failure mechanisms of facade systems.Practical implicationsCavity radiation was found to significantly affect the thermal response of hollow aluminium tubes and façade systems. In design processes, it is essential to consider the potential consequences of non-uniform heating situations, as they can have a significant impact on the temperature of structures. It was also shown that the use of lumped heat capacity heat transfer model in cases of non-uniform fire exposure is unsuitable for the thermal analysis of such systems.Originality/valueThis is the first detailed investigation of the effects of cavity radiation on the thermal response of aluminium tubes and façade systems for different fire exposure conditions.
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空腔辐射对受火灾影响的铝空心管和外墙系统的影响
目的 本文通过数值方法研究了空腔辐射对空心铝管和外墙系统在火灾中的热反应的影响。通过文献中的实验和数值结果确定了数值模型的准确性。利用提出的数值模型研究了空腔辐射对铝空心管和外墙系统热响应的影响。研究考虑了不同的情况,以评估常用的叠加电容传热模型的适用性。在考虑空腔辐射的情况下,单面着火的空心铝管的最高温度要高出 86%。此外,在非均匀受火条件下达到临界温度的时间,是根据传统的叠加热容量传热模型计算得出的,与考虑空腔辐射的拟议模拟方法预测的时间相比,并不保守。达到 550 °C 金属温度的时间比块状热容模型计算的时间早约 18 分钟。这种热机械分析将有助于研究空腔辐射对外墙系统失效机制的影响。在设计过程中,必须考虑非均匀加热情况的潜在后果,因为它们会对结构的温度产生重大影响。研究还表明,在非均匀受火情况下,使用块状热容量传热模型不适合对此类系统进行热分析。
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来源期刊
Journal of Structural Fire Engineering
Journal of Structural Fire Engineering CONSTRUCTION & BUILDING TECHNOLOGY-
CiteScore
2.20
自引率
10.00%
发文量
28
期刊最新文献
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