混合气体爆炸极限和爆炸压力影响因素研究进展

doi:10.16265/j.cnki.issn1003-3033.2025.06.0257

摘要/Abstract

摘要：

随着掺氢天然气的发展,混合气体爆炸事故逐渐引起重视,为减少混合气体爆炸事故带来的损失和影响,通过文献综述的方法,整合国内外研究成果,综合梳理试验数据与数值模拟分析结果,探讨初始温度、初始压力、气体成分、试验容器及点火条件等因素对混合气体爆炸极限和爆炸压力影响的国内外研究进展。结果表明:初始温度和初始压力对混合气体爆炸极限有较明显的影响,且二者耦合作用下的影响更大;混合气体爆炸上限和爆炸下限对影响因素的敏感性不同,相对来说,爆炸上限受到的影响更大;混合气体爆炸压力的最大值一般出现在略高于理论当量浓度时,且受到的影响因素复杂多样,其中,受混合气体成分的影响较大,氢气、乙烯等可燃气体的加入会提高甲烷等主要气体的爆炸压力;数值模拟技术可为混合气体爆炸极限和爆炸压力的研究提供很好的重要补充和验证。

关键词: 混合气体, 爆炸极限, 爆炸下限, 爆炸上限, 爆炸压力, 数值模拟

Abstract:

With the development of hydrogen-methane-mixture, mixed gas explosion accidents have gradually attracted attention. To reduce the loss and influence caused by mixed gas explosion accidents, this study integrated research results at home and abroad through literature review. The experimental data and numerical simulation analysis results were comprehensively sorted out. The research progress at home and overseas on the influence of initial temperature, initial pressure, gas composition, test vessel and ignition conditions on the explosion limit and explosion pressure of mixed gas was discussed. The results show that the initial temperature and initial pressure have a significant effect on the explosion limit of the mixed gas, and the coupling effect of the two is greater. The upper and lower explosion limits of the mixed gas exhibit different sensitivities to the influencing factors, with the upper limit being more significantly affected. The maximum explosion pressure of the mixed gas generally appears when it is slightly higher than the theoretical stoichiometric concentration, and the influencing factors are complex and diverse. Among these factors, the maximum explosion pressure is greatly affected by the composition of the mixed gas. The addition of combustible gases such as hydrogen and ethylene will increase the explosion pressure of major gases such as methane. Numerical simulation technology can provide an important supplement and verification for the study of explosion limit and explosion pressure of mixed gas.

Key words: mixed gas, explosion limit, lower explosive limit, upper explosive limit, explosion pressure, numerical simulation

中图分类号:

X932爆炸安全与防火、防爆

栾婷婷, 黄俊, 杨国梁, 任常兴, 吕鹏飞. 混合气体爆炸极限和爆炸压力影响因素研究进展[J]. 中国安全科学学报, 2025, 35(6): 79-87.

LUAN Tingting, HUANG Jun, YANG Guoliang, REN Changxing, LYU Pengfei. Research progress on influencing factors of explosion limit and explosion pressure of mixed gases[J]. China Safety Science Journal, 2025, 35(6): 79-87.

图/表 1

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参考文献	测试气体	容器形状	容器体积/L	最大爆炸压力/MPa
[19]	2%氢气-甲烷	球形	20	0.63
[22]	甲烷-空气	圆柱体	0.645	0.81
[32]	甲烷-空气	球形	20	0.80
[32]	乙烷-空气	球形	20	0.85
[33]	甲烷-空气	球形	0.52	0.69
[33]	甲烷-空气	圆柱体	0.17	0.63
[34]	甲烷-空气	圆柱体	10 000	0.60
[35]	30%氢气-甲烷	球形	20	0.65
[36]	甲烷-空气	圆柱体	40	0.80
[37]	甲烷-空气	球形	120	0.75
[37]	氢气-空气	球形	120	0.78