石膏板墙组件的防火性能:全尺寸住宅建筑的CFD模拟

Dionysios I. Kolaitis, Eleni K. Asimakopoulou, Maria A. Founti
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引用次数: 16

摘要

石膏“脱水”现象,当石膏石膏板墙组件暴露在高温环境中,导致水蒸气的产生和随后的分散在防火隔间;这些现象在相关的计算流体力学(CFD)模拟中往往被忽略。为了研究石膏脱水对轻质干墙建筑全尺寸CFD模拟的影响,使用FDS规范模拟了一栋两层住宅楼,暴露在典型的家庭火灾场景中。该建筑采用钢结构框架结合石膏板墙组件。温度相关的热物理特性适用于所有建筑材料。采用有效比热模型和固相反应动力学模型两种模拟方法对石膏脱水效果进行了评价;将获得的预测与基准测试用例进行比较,在基准测试用例中没有对此类现象进行建模。结果表明,当模拟高吸热石膏脱水现象时,可以预测较低的总放热速率、气体和壁面温度。此外,开发的固体反应动力学模型首次允许对石膏脱水引起的水蒸气产生和分散现象进行定量预测。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Fire behaviour of gypsum plasterboard wall assemblies: CFD simulation of a full-scale residential building

Gypsum “dehydration” phenomena, occurring when gypsum plasterboard wall assemblies are exposed to a high temperature environment, result in water vapour production and subsequent dispersion in the fire compartment; these phenomena are often neglected in relevant Computational Fluid Dynamics (CFD) simulations. Aiming to investigate the impact of gypsum dehydration in full-scale CFD simulations of lightweight drywall buildings, the FDS code is used to simulate a two-storey residential building, exposed to a typical domestic fire scenario. The building employs a structural steel frame combined with gypsum plasterboard wall assemblies. Temperature-dependent thermo-physical properties are used for all construction materials. The effects of gypsum dehydration are assessed by using two alternative modelling approaches, an effective specific heat model and a solid reaction kinetics model; the obtained predictions are compared to a benchmark test case, where no such phenomena are modelled. The obtained results demonstrate that when the highly endothermic gypsum dehydration phenomena are simulated, lower overall heat release rates, gas and wall surface temperatures are predicted. In addition, the developed solid reaction kinetics model allows, for the first time, quantitative predictions of gypsum dehydration induced water vapour production and dispersion phenomena.

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