飞机火灾的数值模拟:坠毁后火灾

IF 1.5 3区工程技术 Q2 ENGINEERING, AEROSPACE

Journal of Aircraft Pub Date : 2023-10-06 DOI:10.2514/1.c037397

Houssam Eddine Nadir Hiber, Hadj Miloua

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引用次数: 0

摘要

在本研究中使用了火力动力学模拟器(FDS)模型来复制由联邦航空管理局在C-133测试设施内进行的全尺寸飞机坠毁后实验。FDS是一种计算火场模型，它包含了烟尘形成、热解和热辐射传输的子模型。它求解三维随时间变化的Navier-Stokes方程，并以大涡模拟方法和涡耗散概念为基础，作为湍流和燃烧模型。得到的结果，包括热释放率和温度，与实验数据进行了验证，并与采用不同湍流和燃烧模型的早期预测研究进行了比较。这个模拟的结果与实验的发现非常吻合。考察了防火层和随身行李对内饰材料的影响。此外，对机身结构施加了两个边界条件:1)绝热壁和2)绝热壁内热损失。阻火层和绝热边界条件对闪络的发生都起着重要作用。大涡模拟和涡耗散概念方法在很大程度上证明了预测闪络和一般火灾特性的可靠能力。

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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Numerical Modeling of Aircraft Fire: Postcrash Fire

The Fire Dynamics Simulator (FDS) model was utilized in this study to replicate a full-scale aircraft postcrash experiment conducted within the C-133 test facility by the Federal Aviation Administration. FDS is a computational fire field model that incorporates submodels for soot formation, pyrolysis, and thermal radiation transport. It solves three-dimensional time-dependent Navier–Stokes equations and is grounded in the large-eddy simulation approach and the eddy dissipation concept, serving as turbulence and combustion models. The obtained results, including the heat release rate and temperature, were validated against experimental data and compared with earlier prediction studies employing different turbulence and combustion models. The results from this simulation closely align with the experiment’s findings. The impact of fire-blocking layers and carry-on baggage on interior material was examined. Moreover, two boundary conditions were imposed on the fuselage structure: 1) the adiabatic wall, and 2) heat loss within the wall. Both the fire-blocking layers and the adiabatic boundary condition played a significant role in the flashover occurrence. The large-eddy simulation and eddy dissipation concept approaches have demonstrated a reliable ability to predict flashover and general fire properties to a considerable extent.

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来源期刊

Journal of Aircraft 工程技术-工程：宇航

CiteScore

4.50

自引率

31.80%

发文量

141

审稿时长

6 months

期刊介绍： This Journal is devoted to the advancement of the applied science and technology of airborne flight through the dissemination of original archival papers describing significant advances in aircraft, the operation of aircraft, and applications of aircraft technology to other fields. The Journal publishes qualified papers on aircraft systems, air transportation, air traffic management, and multidisciplinary design optimization of aircraft, flight mechanics, flight and ground testing, applied computational fluid dynamics, flight safety, weather and noise hazards, human factors, airport design, airline operations, application of computers to aircraft including artificial intelligence/expert systems, production methods, engineering economic analyses, affordability, reliability, maintainability, and logistics support, integration of propulsion and control systems into aircraft design and operations, aircraft aerodynamics (including unsteady aerodynamics), structural design/dynamics , aeroelasticity, and aeroacoustics. It publishes papers on general aviation, military and civilian aircraft, UAV, STOL and V/STOL, subsonic, supersonic, transonic, and hypersonic aircraft. Papers are sought which comprehensively survey results of recent technical work with emphasis on aircraft technology application.