基于结构动力学和计算流体动力学的交通事故火灾预测

Fire Safety Science Pub Date : 2014-01-01 DOI:10.3801/IAFSS.FSS.11-584

Alexander L. Brown, K. Metzinger, G. Wagner

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引用次数: 1

摘要

一个持续的担忧是涉及液体燃料车辆的交通事故火灾。这些能量可以是高能量的，最重要的能量来源通常是运动能量(动能)和燃料中的化学能(燃烧能量)。最近的工作重点是将瞬态结构动力学代码与火灾计算流体动力学代码耦合起来，以便能够预测此类事件的结果。新的方法已被开发出来，以使这些代码之间的质量和动量守恒。其他的耦合方法也被开发出来并进行了描述。此功能已用于模拟三种场景。来自各种测试用例的结果表明这类问题的离散化准确性。验证工作表明了方法的准确性，并提供了对预测能力的信心。这些案例也有助于为这些方法的未来应用提供指导。

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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Predictions of Transport Accident Fires Using Coupled Structural Dynamics and Computational Fluid Dynamics

A continuing concern involves transportation accident fires involving liquid fuel vehicles. These can be highly energetic, with the most significant sources of energy typically being the energy of motion (kinetic energy) and the chemical energy in the fuel (fire combustion energy). Recent work has focused on coupling a transient structural dynamics code to a fire computational fluid dynamics code to be able to predict the outcome of such an event. New methods have been developed to permit conservation of mass and momentum between the codes. Other coupling approaches have been developed and are described. This capability has been used to simulate three scenarios. Results from the various test cases suggest discretization accuracy for problems of this class. Validation efforts suggest the accuracy of the methodology, and provide confidence in the predictive capability. These cases also help provide guidance for future application of these methods.

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Fire Safety Science

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