电动汽车火灾对停车楼影响的热模拟

IF 0.7 Q4 TRANSPORTATION SCIENCE & TECHNOLOGY

SAE International Journal of Transportation Safety Pub Date : 2023-09-21 DOI:10.4271/09-11-03-0013

Andrii Gavryliuk, Roman Yakovchuk, Yaroslav Ballo, Yuriy Rudyk

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引用次数: 0

摘要

国际社会正在不断而迅速地寻求替代能源和生态清洁能源，包括运输能源，而俄罗斯对乌克兰的战争只是加剧和加速了这一进程。这种交通运输趋势反映在零有害气体排放的电池驱动电动汽车(bev)的普及上。电动汽车的数量正在迅速增加，同时也出现了一些鲜为人知的风险。在这些危险中，电动汽车发生火灾，主要是由部件故障引起的，特别是广泛使用的锂离子电池。与内燃机车辆(ICEV)的火灾相比，这种汽车的火灾具有不同的特征。本研究利用美国国家标准与技术研究院开发的火灾动力学模拟器，以特斯拉s型汽车为例，模拟了一场纯电动汽车火灾。为此，对物体及其物理特性进行了描述，设置了纯电动汽车的输入参数和环境参数，形成了火灾发展动力学的数学模型。根据建模结果发现，在自由火灾发展时间为600秒的情况下，电动汽车与各种功能用途建筑物墙体的最小防火距离应至少为3 m。

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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Thermal Modeling of the Electric Vehicle Fire Hazard Effects on Parking Building

The world community is constantly and rapidly moving toward the search for alternative and ecologically clean energy sources, including for transport, and Russia’s war against Ukraine only intensified and accelerated such processes. This trend in transport is reflected in the spread of battery-powered electric vehicles (BEVs) with zero emission of harmful gases.

Electric cars are experiencing a rapid increase in numbers, accompanied by the emergence of lesser-known risks. Among these hazards are the occurrence of fires in electric vehicles, primarily caused by component failures, notably the widely prevalent lithium-ion batteries.

Fires of such cars have a different character compared to fires of vehicles powered by an internal combustion engine vehicle (ICEV). In this study, using the fire dynamics simulator developed by the National Institute of Standards and Technology, a BEV fire was simulated on the example of the Tesla Model S. For this, a description of the objects and their physical characteristics were carried out, the input parameters of the BEV and environmental parameters were set, and a mathematical model of the development dynamics of fire was formed. According to the modeling results, it was found that the minimum fire protection distance from a BEV to the wall of buildings of various functional purposes should be at least 3 m, provided that the free fire development time is 600 s.

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来源期刊

SAE International Journal of Transportation Safety TRANSPORTATION SCIENCE & TECHNOLOGY-

CiteScore

1.10

自引率

0.00%

发文量