分岔处点火T型管道内瓦斯爆燃火焰传播规律研究

doi:10.11799/ce202010020

煤炭工程 ›› 2020, Vol. 52 ›› Issue (10): 98-103.doi: 10.11799/ce202010020

分岔处点火T型管道内瓦斯爆燃火焰传播规律研究

解北京¹,董春阳²,王广宇²,王亮¹

1. 中国矿业大学（北京）
2. 中国矿业大学（北京）应急管理与安全工程学院

收稿日期:2019-08-21 修回日期:2019-10-24 出版日期:2020-10-16 发布日期:2020-12-11
通讯作者: 解北京 E-mail:bjxie1984@163.com

Study on Propagation Law of Gas Explosion Flame in T-Tube Ignition at Branching Pipeline

Received:2019-08-21 Revised:2019-10-24 Online:2020-10-16 Published:2020-12-11

摘要/Abstract

摘要： 采用自制T型透明分岔管，由分岔处点火并测试瓦斯爆燃火焰阵面在两端完全封闭一端弱封闭的分岔管道内传播过程中的光电信号、离子电流、温度信号、超压信号的变化。结果表明：分岔处点火T型管道内瓦斯爆燃火焰向三个端口传播过程中，表现出层状火焰、振荡火焰、爆燃火焰三种典型状态|火焰向完全封闭的支管和直管右端口分别传播的过程中，速度、离子电流强度均较小(最大1.32m/s、0.024μA)，而向直管左侧弱封闭端口方向传播相对较大(最大33.17m/s、0.31μA)，均相差一个数量级|各截面测点峰值温度，分岔处1042K＞支管处928K＞直管左侧793K＞直管右侧669K，而峰值超压，支管处0.162MPa＞直管右侧0.135MPa＞直管左侧0.036MPa|爆燃火焰向两个完全封闭端口传播过程中，由于压缩波的负反馈作用产生逆流现象|特别是向支管端口传播过程中，由于分岔壁面的存在，在压缩波负反馈和高温气体产物正反馈的共同作用下，火焰又呈现出振荡前行的状态。

关键词: 爆燃火焰, 振荡燃烧, 分岔管道, 离子电流

Abstract: A self-made transparent T-type bifurcation pipe was used. Ignition by the branch and test the change of photoelectric signal, ion current, temperature signal and overpressure signal during the propagation process of gas explosion flame front in the branching pipe that is completely closed at two ends and weakly closed at one end. The results show: The gas explosion flame in the T-tube is distributed to three ports, showing three typical states of layered flame, oscillating flame and deflagration flame. During the propagation of the flame to the completely closed branch pipe and the right end of the straight pipe, the velocity and ion current intensity are small(maximum 1.32m/s, 0.024μA), and the propagation to the weak closed end of the straight pipe is relatively large(maximum 33.17 m/s, 0.31 μA), all differ by an order of magnitude. The peak temperature of each section is the branch 1042K> branch pipe 928K> straight pipe left side 793K> straight pipe right side 669K. The peak over-pressured value of each section is the branch pipe is 0.162 MPa>the right side of the straight pipe is 0.135 MPa>the left side of the straight pipe is 0.036 MPa. During the propagation of the detonation flame to the closed end, the reverse flow phenomenon occurs due to the negative feedback of the compression wave. Especially during the propagation to the branch port, due to the existence of the wall of the bifurcation, under the combined action of the negative feedback of the compression wave and the positive feedback of the high temperature gas product, the flame presents a state of oscillation.

中图分类号:

TD712

解北京, 董春阳, 王广宇, 王亮. 分岔处点火T型管道内瓦斯爆燃火焰传播规律研究[J]. 煤炭工程, 2020, 52(10): 98-103.

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分岔处点火T型管道内瓦斯爆燃火焰传播规律研究

Study on Propagation Law of Gas Explosion Flame in T-Tube Ignition at Branching Pipeline

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