Deflagration to Detonation Transition and Detonation Wave Structure of Aluminum-Air Mixture
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摘要: 在长为32.4 m、内径为0.199 m的大型长直水平管道中,对铝粉-空气两相流的燃烧转爆轰(DDT)过程及爆轰波结构进行了实验研究。对铝粉-空气混合物弱点火条件下DDT过程不同阶段的特征进行了分析,实验结果显示混合物经历了缓慢反应压缩阶段、压缩波加速冲击波形成阶段、冲击反应过渡阶段、冲击反应向过压爆轰过渡阶段和爆轰阶段,得到了混合物各阶段的DDT参数,由此进一步分析了DDT浓度的上、下限。在1.4 m爆轰测试段的4个截面的环向上各均匀安装8个传感器,对爆轰波结果进行测试,并对铝粉-空气混合物爆轰波的单头结构进行了分析。Abstract: Motivated by the current interest in the mechanism of the deflagration to detonation transition (DDT), the DDT process and detonation wave structure of aluminum-air mixture are investigated experimentally by a large scale tube with length of 32.4 m and inner diameter of 0.199 m. The overall DDT process can be divided into slow reaction compression stage, pressure wave speed-up and shock wave formation stage, transfer from shock reaction to critical shock reaction, transfer from critical shock to overdriven detonation, and detonation stage. The optimal concentrations of mixtures in this experimental tube are obtained, and the critical concentration of DDT is also studied. Eight pressure gauges are well-distributed at each periphery of four certain sections in the 1.4 m long detonation testing tube for detonation wave testing. According to the test results, the detonation wave structure of aluminum-air mixture is analyzed, which shows single head mode.
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Key words:
- deflagration to detonation transition /
- weak ignition /
- aluminum /
- self-sustained /
- detonation wave
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