代用模型驱动的火灾悬索桥塔绝热表面温度估算

IF 2.3 3区工程技术 Q2 ENGINEERING, MULTIDISCIPLINARY

Fire Technology Pub Date : 2024-08-16 DOI:10.1007/s10694-024-01628-3

Sara Mostofi, Ahmet Can Altunişik

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引用次数: 0

摘要

评估绝热表面温度（AST）作为火灾暴露桥梁构件的热响应是一项复杂而耗时的任务。因此，本研究将火灾动态模拟器 (FDS) 和机器学习 (ML) 简化为一个代理模型，用于预测悬索桥塔的绝热表面温度。为此，针对悬索桥塔暴露在不同车辆火灾条件下的情况，结合车辆类型、暴露持续时间和风力条件等因素，进行了各种 FDS 模拟，以生成用于训练 ML 算法的多样化桥梁火灾数据集。使用性能指标对八个 ML 模型进行了评估，其中随机森林模型在五倍交叉验证中表现出了卓越的一致性和可靠性，在所有测试中都保持了 0.99 的高 R2 值，并显示出稳定的 MAE 和 MSE 指标，证实了其在预测准确性方面的卓越性能和稳健性。所提出的代用模型提供了一种快速适应各种火灾条件的省时高效的解决方案，为增强桥梁火灾评估的复原力提供了一种稳健高效的工具。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Surrogate Model-Driven Estimation of Adiabatic Surface Temperature of Fire Exposed Suspension Bridge Towers

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Surrogate Model-Driven Estimation of Adiabatic Surface Temperature of Fire Exposed Suspension Bridge Towers

Evaluating adiabatic surface temperature (AST) as the thermal response of fire-exposed bridge elements is a complex and time-consuming task. Correspondingly, this study streamlined fire dynamic simulator (FDS) and machine learning (ML) in a surrogate model to predict the AST of suspension bridge tower. For this, various FDS simulations were conducted for suspension bridge tower exposed to different vehicular fire conditions incorporating factors such as vehicle type, exposure duration, and wind conditions to generate a diverse bridge fire dataset for training of ML algorithms. Eight ML models were evaluated using performance metrics, whereby the random forest model demonstrated exceptional consistency and reliability in a fivefold cross-validation, maintaining a high R² value of 0.99 across all tests and showing stable MAE and MSE metrics, confirming its superior performance and robustness in predictive accuracy. The proposed surrogate model offers a robust and efficient tool for enhancing the resilience of bridge fire evaluations by providing a time-efficient solution that adapts quickly to a range of fire conditions.

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来源期刊

Fire Technology 工程技术-材料科学：综合

CiteScore

6.60

自引率

14.70%

发文量

137

审稿时长

7.5 months

期刊介绍： Fire Technology publishes original contributions, both theoretical and empirical, that contribute to the solution of problems in fire safety science and engineering. It is the leading journal in the field, publishing applied research dealing with the full range of actual and potential fire hazards facing humans and the environment. It covers the entire domain of fire safety science and engineering problems relevant in industrial, operational, cultural, and environmental applications, including modeling, testing, detection, suppression, human behavior, wildfires, structures, and risk analysis. The aim of Fire Technology is to push forward the frontiers of knowledge and technology by encouraging interdisciplinary communication of significant technical developments in fire protection and subjects of scientific interest to the fire protection community at large. It is published in conjunction with the National Fire Protection Association (NFPA) and the Society of Fire Protection Engineers (SFPE). The mission of NFPA is to help save lives and reduce loss with information, knowledge, and passion. The mission of SFPE is advancing the science and practice of fire protection engineering internationally.