Detonation propagation from a cylindrical tube into a diverging cone

IF 1.2 4区工程技术 Q3 THERMODYNAMICS

Journal of Thermal Science and Technology Pub Date : 2020-01-01 DOI:10.1299/jtst.2020jtst0030

T. Endo, Ryuji Kobayashi, S. Kuwajima, Y. Seki, Wookyung Kim, T. Johzaki

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Abstract

The characteristics of the propagation of a detonation from a cylindrical tube of constant cross section into a diverging cone were experimentally investigated using the smoked-foil technique for three explosive gas mixtures: C2H2+2.5O2, 2H2+O2+4.5Ar, and C2H4+3O2+0.44N2. The initial pressure and the cone enlargement angle were varied as governing parameters. The results were summarized in terms of the ratio between the inner diameter of the cylindrical tube through which a detonation initially propagated and the detonation cell width d and of the cone enlargement half angle . Four patterns of detonation propagation were observed in the diverging cone: continuous propagation, re-initiation on the cone wall, re-initiation apart from the cone wall, and failure. The obtained results were qualitatively consistent with past experimental results reported by other researchers. However, quantitatively, the obtained results were dependent on the explosive gas mixtures, particularly on the so-called critical tube diameter. Actually, when the critical values of d against detonation failure were normalized by that corresponding to 90 , ° a single curve unifying all data to some degree was obtained. In addition, some characteristics of the detonation behavior in the diverging cone were explained by simple models.

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爆轰从圆柱形管传播到发散锥

采用烟箔技术对C2H2+2.5O2、2H2+O2+4.5Ar和C2H4+3O2+0.44N2三种爆炸性气体混合物的爆轰传播特性进行了实验研究。调节参数为初始压力和锥扩角。用爆轰最初传播的圆柱管内径与爆轰池宽度d和锥扩半角之比对结果进行了总结。在发散锥内观察到四种爆轰传播模式:连续传播、锥壁上再起爆、锥壁外再起爆和失效。所得结果与以往其他研究者报道的实验结果在质量上是一致的。然而，在定量上，所得到的结果依赖于爆炸性气体混合物，特别是所谓的临界管径。实际上，将抗爆轰破坏临界值归一化为90°对应的临界值时，得到的是一条统一所有数据的单一曲线。此外，用简单的模型解释了散锥内爆轰行为的一些特征。

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 Thermal Science and Technology 物理-热力学

CiteScore

2.30

自引率

8.30%

发文量

审稿时长

5 months

期刊介绍： JTST covers a variety of fields in thermal engineering including heat and mass transfer, thermodynamics, combustion, bio-heat transfer, micro- and macro-scale transport phenomena and practical thermal problems in industrial applications.