A Model for Combustion of Firebrands of Various Shapes

H. Baum, A. Atreya
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引用次数: 11

Abstract

The lifetime of a firebrand before burning out controls the maximum distance a firebrand can travel to cause spotting. Thus, combustion of firebrands of various shapes and sizes and their burnout time during transport is studied. The analysis assumes “quasi-steady” burning. In the present context, “quasi-steady” means that the rate processes controlling the gas phase fuel consumption and energy release are much faster than the particle fuel depletion time or the gas phase transport times. The Reynolds number based on the overall particle dimension and velocity relative to the ambient flow is assumed to be small. The gas phase combustion processes are represented by the evolution of a mixture fraction variable. It is shown that the velocity field near the particle can be described by a potential flow whose functional form is determined by the mass conservation equation and that this flow satisfies the particle surface boundary conditions. Gas phase solutions are obtained for two-parameter family of firebrand shapes composed of oblate and prolate ellipsoids of revolution. Prolate ellipsoids range from a thin needle to a sphere and oblate ellipsoids range from a sphere to a thin disc. Thus, they cover all possible firebrand shapes. The ambient velocity field does not need to be aligned with the firebrand axis of symmetry, so that the composite velocity and mixture fraction fields are three-dimensional. While a variety of steady-state condensed phase models are compatible with this picture, results are first presented for an ablating solid describable by the Spalding B number. B-numbers representative of flaming combustion of wood firebrands and glowing combustion of remaining char are used. All quantities are calculated as a function of ellipsoidal aspect ratio, B number, and the Reynolds number. Surprisingly, it is found that the firebrand burnout time is shape independent. All possible shapes were considered by using oblate and prolate ellipsoids of different sizes and aspect ratios. The burnout time depends only on the firebrand mass under the assumptions used.
不同形状燃烧弹的燃烧模型
在燃尽前的火焰寿命控制着火焰能传播的最大距离。因此,研究了不同形状和大小的燃烧物在运输过程中的燃烧及其燃尽时间。该分析假定燃烧是“准稳定的”。在目前的情况下,“准稳定”意味着控制气相燃料消耗和能量释放的速率过程比颗粒燃料耗尽时间或气相输运时间快得多。假设基于整体颗粒尺寸和相对于周围流动的速度的雷诺数很小。气相燃烧过程由混合气分数变量的演化来表示。结果表明,质点附近的速度场可以用势流来描述,势流的函数形式由质量守恒方程决定,且势流满足质点表面边界条件。得到了由扁椭球和长椭球组成的两参数火焰形状族的气相解。长形椭球的范围从细针状到球形,扁形椭球的范围从球形到薄圆盘。因此,它们涵盖了所有可能的火种形状。环境速度场不需要与火焰对称轴对齐,因此复合速度场和混合分数场是三维的。虽然各种稳态凝聚相模型都与这幅图相容,但结果首先是由斯伯丁B数描述的烧蚀固体。b号代表燃烧燃烧的木柴和燃烧残余炭的发光燃烧。所有的量都是作为椭球长径比、B数和雷诺数的函数来计算的。令人惊讶的是,我们发现燃烧器的燃烬时间与形状无关。通过使用不同尺寸和纵横比的扁椭球和长椭球来考虑所有可能的形状。在假设条件下,燃尽时间仅与引燃物质量有关。
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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