Full-field temperature prediction in tunnel fires using limited monitored ceiling flow temperature data with transformer-based deep learning models

IF 3.4 3区 工程技术 Q2 ENGINEERING, CIVIL
Xin Guo , Dong Yang , Li Jiang , Tao Du , Shan Lyu
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Abstract

In practical tunnel scenarios, full-field coverage of sensors is impractical and costly. During a tunnel fire, the available information is constrained and localized, making the prediction of full-field smoke temperature distribution becoming a noteworthy challenge. This study proposes a transformer-based deep learning model to predict full-field smoke temperature distributions during fire incidents in real-time using limited temporal data from the sensors installed in localized regions below the ceiling, considering heat release rate of the fire source is unknown. The results indicate that proposed approach can predict the longitudinal temperature distribution throughout the tunnel with a length of 750 m by leveraging temperature data from limited sensors within a monitoring length of 210 m. It can further predict the vertical temperature profiles, and eventually estimate the full-field temperature distribution within the tunnel. The transformer model achieved R2 of 0.95 and 0.87 for longitudinal and vertical temperature distribution predictions, respectively. Under the influence of the self-attention mechanism, the transformer model has an advantage over the long short-term memory model in capturing global information, enhancing the accuracy of longitudinal temperature distribution predictions by 18.8 %. This study significantly contributes to effective emergency response and rescue strategies during tunnel fire incidents.

使用基于变压器的深度学习模型,利用有限的监测顶流温度数据预测隧道火灾中的全场温度
在实际的隧道场景中,传感器的全场覆盖是不切实际的,而且成本高昂。在隧道火灾中,可用信息是有限的、局部的,因此预测全场烟温分布成为一个值得注意的挑战。本研究提出了一种基于变压器的深度学习模型,利用安装在天花板以下局部区域的传感器提供的有限时间数据,实时预测火灾事故中的全场烟温分布,同时考虑到火源的热释放率是未知的。结果表明,所提出的方法可以利用 210 米监测长度内有限传感器的温度数据,预测整个 750 米长隧道的纵向温度分布,并进一步预测垂直温度剖面,最终估算出隧道内的全场温度分布。变压器模型在纵向和垂直温度分布预测方面的 R2 分别达到了 0.95 和 0.87。在自注意机制的影响下,变压器模型在捕捉全局信息方面比长短时记忆模型更具优势,使纵向温度分布预测的准确性提高了 18.8%。这项研究大大有助于在隧道火灾事故中采取有效的应急响应和救援策略。
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来源期刊
Fire Safety Journal
Fire Safety Journal 工程技术-材料科学:综合
CiteScore
5.70
自引率
9.70%
发文量
153
审稿时长
60 days
期刊介绍: Fire Safety Journal is the leading publication dealing with all aspects of fire safety engineering. Its scope is purposefully wide, as it is deemed important to encourage papers from all sources within this multidisciplinary subject, thus providing a forum for its further development as a distinct engineering discipline. This is an essential step towards gaining a status equal to that enjoyed by the other engineering disciplines.
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