Numerical Investigation of Critical Velocity in Reduced Scale Tunnel Fire with Constant Heat Release Rate

IF 1.5 Q3 ENGINEERING, CHEMICAL Journal of Combustion Pub Date : 2017-01-18 DOI:10.1155/2017/7125237

R. Mouangue, Philippe M. Onguene, J. Zaida, Henri P. F. Ekobena

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引用次数: 6

Abstract

When a fire occurs in a tunnel in the absence of sufficient air supply, large quantities of smoke are generated, filling the vehicles and any space available around them. Hot gases and smoke produced by fire form layers flowing towards extremities of the tunnel which may interfere with person’s evacuation and firefighter’s intervention. This paper carries out a numerical simulation of an unexpected fire occurring in a one-way tunnel in order to investigate for the critical velocity of the ventilation airflow; this one is defined as the minimum velocity able to maintain the combustion products in the downstream side of tunnel. The computation is performed successively with two types of fuels representing a large and a small heat release rate, owing to an open source CFD code called ISIS, which is specific to fires in confined and nonconfined environments. It is indicated that, after several computations of full-scale fires of 43.103 and 19.103 kJ/kg as heat release rate, the velocities satisfying the criterion of healthy environment in the upstream side of the tunnel are 1.34 m/s and 1.12 m/s, respectively.

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等放热速率下缩尺度隧道火灾临界速度的数值研究

当隧道发生火灾时，如果没有足够的空气供应，就会产生大量的烟雾，充满车辆和周围的任何可用空间。火灾产生的高温气体和烟雾层层叠叠地流向隧道的末端，可能会干扰人员的疏散和消防员的干预。本文对单向隧道内发生的意外火灾进行了数值模拟，研究了隧道内通风气流的临界速度;这个速度被定义为能够维持燃烧产物在隧道下游的最小速度。由于有一个名为ISIS的开源CFD代码，该代码专门针对密闭和非密闭环境中的火灾，因此计算是在两种类型的燃料下依次进行的，这两种燃料代表了大和小的热释放率。结果表明，以43.103 kJ/kg和19.103 kJ/kg的全尺寸火灾放热速率进行多次计算后，隧道上游满足健康环境标准的速度分别为1.34 m/s和1.12 m/s。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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