Dynamics of fuel-lean and stoichiometric methane-air explosion venting: Experiments and simulations

IF 3.6 3区工程技术 Q2 ENGINEERING, CHEMICAL Journal of Loss Prevention in The Process Industries Pub Date : 2024-08-06 DOI:10.1016/j.jlp.2024.105404

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Abstract

The computational explosion venting analyzer (EVA), a zero-dimensional (0D) model based on the conservation of mass and energy, is being developed to model centrally- and rear-ignited explosions. For this purpose, a series of explosion venting experiments in a cylinder with vent areas of $132.7$ , $86.6$ , $67.9$ cm² (corresponding to the vent area ratios of $K = 0.47, 0.31, 0.24$ , respectively) is performed. Two equivalence ratios of $ϕ = 0.8$ and $1$ are considered to represent the fuel-lean and stoichiometric methane-air mixtures, respectively. The dynamics of explosions is studied through the observation of flame propagation and pressure measurements. In rear ignition experiments, laminar, so-called “finger flame” propagation is observed, while in the case of center ignition, a flame initially expands spherically and then is pulled by the vent, acquiring a half-elliptical and half-spherical shape. The peak pressures obtained from rear ignition exceed their counterparts in the center ignition experiments. The EVA is compared with the experimental matrix. No turbulence is implemented in stoichiometric simulations, and slight turbulence has been accounted for in the lean mixture simulations. It is found that the large vent, generally, imposes more disturbances on the flame shape and the fuel-lean mixtures are more prone to the diffusional-thermal instabilities. It is shown that such a simple numerical tool, as the EVA is, can estimate a complicated problem such as pressure evolution resulted from a vented gas explosion.

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燃料贫乏和稳定计量甲烷-空气爆炸排气的动力学：实验和模拟

计算爆炸排气分析器（EVA）是一种基于质量和能量守恒的零维（0D）模型，目前正在开发中，用于模拟集中点火和后点火爆炸。为此，在排气面积分别为 132.7、86.6 和 67.9 平方厘米（对应的排气面积比分别为 K=0.47、0.31 和 0.24）的圆柱体中进行了一系列爆炸排气实验。考虑了两个等效比 ϕ=0.8 和 1，分别代表燃料稀释和甲烷-空气混合物的化学计量。通过观察火焰传播和压力测量来研究爆炸动力学。在后点火实验中，观察到的是层流，即所谓的 "指状火焰 "传播，而在中心点火的情况下，火焰最初呈球形膨胀，然后被通风口拉动，形成半椭圆形和半球形。后点火获得的峰值压力超过了中心点火实验中的峰值压力。EVA 与实验矩阵进行了比较。在计量模拟中没有湍流，而在贫油混合模拟中考虑了轻微的湍流。结果发现，大排气孔通常会对火焰形状造成更多干扰，而燃料贫乏混合物则更容易产生扩散-热不稳定性。结果表明，像 EVA 这样简单的数值工具可以估算出复杂的问题，如排出气体爆炸产生的压力演变。

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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来源期刊

Journal of Loss Prevention in The Process Industries 工程技术-工程：化工

CiteScore

7.20

自引率

14.30%

发文量

226

审稿时长

52 days

期刊介绍： The broad scope of the journal is process safety. Process safety is defined as the prevention and mitigation of process-related injuries and damage arising from process incidents involving fire, explosion and toxic release. Such undesired events occur in the process industries during the use, storage, manufacture, handling, and transportation of highly hazardous chemicals.