Effect of the Ignition Position and Obstacle on Vented Methane–Air Deflagration

IF 0.9 4区 工程技术 Q4 ENERGY & FUELS
J.-L. Li, J. Guo, X.-X. Sun, F.-Q. Yang
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引用次数: 0

Abstract

In this study, explosion venting of front, centrally, and rear ignited 9% methane–air mixtures has been conducted in a 1-m3 rectangular vessel with and without cylinders placed parallel to the venting direction. Three pressure peaks \(P_{1}\)\(P_{2}\), and \(P_{\rm ext}\) caused by vent failure, flame-acoustic interaction, and external explosion, respectively, can be distinguished. The pressure peak \(P_{1}\) appears in all the tests and is insensitive to the ignition position, but the existence of obstacles increases its value. The pressure peak \(P_{2}\) only appears in the centrally and front ignited explosions without obstacles. The pressure peak \(P_{\rm ext}\) can be observed in the rear ignition tests and is strengthened by the cylinders. The duration of the Helmholtz oscillations is longer in front ignition tests, whereas addition of cylinders had a minor effect on their frequency. This study also validates the ability of FLACS in predicting a vented methane–air explosion by comparing the simulated pressure–time histories and flame propagations with experimental results. FLACS can basically predict the shape of overpressure curves. If cylinders exist, the simulation results ensure better agreement with the experimental data because FLACS cannot simulate the flame-acoustic-interaction-induced pressure peak \(P_{2}\). The performance of FLACS is satisfactory in rear ignition tests because it calculates \(P_{\rm ext}\) and obstacles’ effect on \(P_{\rm ext}\) exactly. The flame behavior simulated by FLACS is similar to that in experiments, but the effect of the Taylor instability on the flame is not sufficiently considered.

Abstract Image

点火位置和障碍物对排气甲烷-空气爆燃的影响
摘要本研究采用前、中、后三种引燃方式进行爆炸通风% methane–air mixtures has been conducted in a 1-m3 rectangular vessel with and without cylinders placed parallel to the venting direction. Three pressure peaks \(P_{1}\), \(P_{2}\), and \(P_{\rm ext}\) caused by vent failure, flame-acoustic interaction, and external explosion, respectively, can be distinguished. The pressure peak \(P_{1}\) appears in all the tests and is insensitive to the ignition position, but the existence of obstacles increases its value. The pressure peak \(P_{2}\) only appears in the centrally and front ignited explosions without obstacles. The pressure peak \(P_{\rm ext}\) can be observed in the rear ignition tests and is strengthened by the cylinders. The duration of the Helmholtz oscillations is longer in front ignition tests, whereas addition of cylinders had a minor effect on their frequency. This study also validates the ability of FLACS in predicting a vented methane–air explosion by comparing the simulated pressure–time histories and flame propagations with experimental results. FLACS can basically predict the shape of overpressure curves. If cylinders exist, the simulation results ensure better agreement with the experimental data because FLACS cannot simulate the flame-acoustic-interaction-induced pressure peak \(P_{2}\). The performance of FLACS is satisfactory in rear ignition tests because it calculates \(P_{\rm ext}\) and obstacles’ effect on \(P_{\rm ext}\) exactly. The flame behavior simulated by FLACS is similar to that in experiments, but the effect of the Taylor instability on the flame is not sufficiently considered.
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来源期刊
Combustion, Explosion, and Shock Waves
Combustion, Explosion, and Shock Waves 工程技术-材料科学:综合
CiteScore
1.60
自引率
16.70%
发文量
56
审稿时长
5.7 months
期刊介绍: Combustion, Explosion, and Shock Waves a peer reviewed journal published in collaboration with the Siberian Branch of the Russian Academy of Sciences. The journal presents top-level studies in the physics and chemistry of combustion and detonation processes, structural and chemical transformation of matter in shock and detonation waves, and related phenomena. Each issue contains valuable information on initiation of detonation in condensed and gaseous phases, environmental consequences of combustion and explosion, engine and power unit combustion, production of new materials by shock and detonation waves, explosion welding, explosive compaction of powders, dynamic responses of materials and constructions, and hypervelocity impact.
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