Scaling-effect of explosion in H2/CH4/air mixtures

Yangyang Cui; Cheng Wang; Dongping Chen; Chengeng Qian; Boyang Qiao

doi:10.1016/j.ijhydene.2022.08.040

Scaling-effect of explosion in H₂/CH₄/air mixtures

Yangyang Cui, Cheng Wang^*, Dongping Chen, Chengeng Qian, Boyang Qiao

^*此作品的通讯作者

机电学院

Beijing Institute of Technology

科研成果: 期刊稿件 › 文章 › 同行评审

14 引用（Scopus）

摘要

The scaling-effect of mixture explosion is an unresolved issue in explosion science. In this work, we carry out experimental measurements of explosion characteristics using hydrogen/methane/air (H₂/CH₄/air) mixtures in two tubes with lengths of 1.5 m and 60 m. The explosion overpressure of the mixtures increases exponentially with hydrogen mole fractions in the small tube, as expected. In contrast, explosion overpressure increases rapidly, causing detonation when hydrogen is added to the mixtures. Comparing measurements in both tubes, the explosion overpressure exhibits a clear scaling-effect dependence on the tube size. The scaling-effect cannot be explained by the aspect ratio (AR) of the tube. The analysis of the hotspot size, which is correlated with the ignition delay time of mixtures, is the critical factor governing the scaling-effect of explosion seen in a large tube.

源语言	英语
页（从-至）	34704-34714
页数	11
期刊	International Journal of Hydrogen Energy
卷	47
期	81
DOI	https://doi.org/10.1016/j.ijhydene.2022.08.040
出版状态	已出版 - 22 9月 2022

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abstract = "The scaling-effect of mixture explosion is an unresolved issue in explosion science. In this work, we carry out experimental measurements of explosion characteristics using hydrogen/methane/air (H2/CH4/air) mixtures in two tubes with lengths of 1.5 m and 60 m. The explosion overpressure of the mixtures increases exponentially with hydrogen mole fractions in the small tube, as expected. In contrast, explosion overpressure increases rapidly, causing detonation when hydrogen is added to the mixtures. Comparing measurements in both tubes, the explosion overpressure exhibits a clear scaling-effect dependence on the tube size. The scaling-effect cannot be explained by the aspect ratio (AR) of the tube. The analysis of the hotspot size, which is correlated with the ignition delay time of mixtures, is the critical factor governing the scaling-effect of explosion seen in a large tube.",

keywords = "Deflagration to detonation (DDT), Explosion, Large-scale experiments, Scaling-effect",

author = "Yangyang Cui and Cheng Wang and Dongping Chen and Chengeng Qian and Boyang Qiao",

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AU - Cui, Yangyang

AU - Wang, Cheng

AU - Chen, Dongping

AU - Qian, Chengeng

AU - Qiao, Boyang

PY - 2022/9/22

Y1 - 2022/9/22

N2 - The scaling-effect of mixture explosion is an unresolved issue in explosion science. In this work, we carry out experimental measurements of explosion characteristics using hydrogen/methane/air (H2/CH4/air) mixtures in two tubes with lengths of 1.5 m and 60 m. The explosion overpressure of the mixtures increases exponentially with hydrogen mole fractions in the small tube, as expected. In contrast, explosion overpressure increases rapidly, causing detonation when hydrogen is added to the mixtures. Comparing measurements in both tubes, the explosion overpressure exhibits a clear scaling-effect dependence on the tube size. The scaling-effect cannot be explained by the aspect ratio (AR) of the tube. The analysis of the hotspot size, which is correlated with the ignition delay time of mixtures, is the critical factor governing the scaling-effect of explosion seen in a large tube.

AB - The scaling-effect of mixture explosion is an unresolved issue in explosion science. In this work, we carry out experimental measurements of explosion characteristics using hydrogen/methane/air (H2/CH4/air) mixtures in two tubes with lengths of 1.5 m and 60 m. The explosion overpressure of the mixtures increases exponentially with hydrogen mole fractions in the small tube, as expected. In contrast, explosion overpressure increases rapidly, causing detonation when hydrogen is added to the mixtures. Comparing measurements in both tubes, the explosion overpressure exhibits a clear scaling-effect dependence on the tube size. The scaling-effect cannot be explained by the aspect ratio (AR) of the tube. The analysis of the hotspot size, which is correlated with the ignition delay time of mixtures, is the critical factor governing the scaling-effect of explosion seen in a large tube.

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KW - Large-scale experiments

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Scaling-effect of explosion in H2/CH4/air mixtures

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Scaling-effect of explosion in H₂/CH₄/air mixtures