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氢氧爆轰波在激波管中的成长机制研究 被引量:1

Study on the Development Mechanism of Detonation Wave for the Hydrogen-Oxygen Mixture in a Shock Tube
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摘要 针对气相爆轰波成长机制研究,采用压力传感器和高速摄影技术,测试了氢氧混合气体在点火后的火焰波、前驱冲击波以及爆轰波的成长变化过程,计算了冲击波过程参数和气体状态参数,分析了火焰加速机制。实验结果表明,APX-RS型高速摄影系统可用于拍摄气相爆轰波的成长历程;氢氧爆轰波的产生是由于湍流火焰和冲击波的相互正反馈作用,导致反应区内多处发生局部爆炸,爆炸波与冲击波相互耦合,最终成长为定常爆轰波。 This paper mainly focuses on the experimental investigation of the gaseous detonation wave build-up mechanism for hydrogen-oxygen mixture in shock tube. Five pressure sensors were used to record the pressures and a high-speed camera was used to capture velocities of flame, shock, or detonation wave. The high-speed camera records the transformation of flame, shock in the ignition phase and the attenuation of detonation wave. The experimental results show that the diagnostic system can effectively measure the DDT. The images of flame propagation show that the flame front is curving and dispersive. It is found that the interaction of shock and turbulent flame is a dominant factor for the onset of explosion. In the smooth tube, experiments indicate that the intensity of shock wave continually increases due to the acceleration of flame. The local explosion occurs in the reaction zone when the intensity of shock wave arrives at a critical pressure pc when some hot spots form in the local explosion centers. At that time, an unsteady detonation wave is formed immediately, and after a period of the propagation or attenuation process,it eventually evolves into a steady detonation wave.
作者 王建 段吉员 赵继波 文尚刚 谭多望
机构地区 中国工程物理研究院流体物理研究所
出处 《高压物理学报》 EI CAS CSCD 北大核心 2011年第6期514-518,共5页 Chinese Journal of High Pressure Physics
关键词 爆炸力学 气相爆轰波 燃烧转爆轰 氢氧混合气体 高速摄影 mechanics of explosion gaseous detonation wave deflagration to detonation transition hydrogen-oxygen mixture high-speed camera
分类号 O382.1 [理学—流体力学]
  • 相关文献

参考文献11

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二级参考文献27

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高压物理学报
2011年 第6期

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