Determination of the Velocity of the Detonation Wave and the Conditions for the Appearance of Spherical Detonation during the Interaction of Hydrogen with Oxygen

Direct Numerical Simulations - An Introduction and Applications Pub Date : 2018-11-05 DOI:10.5772/INTECHOPEN.81792

M. Polatayko

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Abstract

The well-known formula for the flat detonation wave velocity derived from the Hugoniot system of equations faces difficulties, if being applied to a spherical reactor. A similar formula has been obtained in the framework of the theory of explosion in reacting gas media with the use of a special model describing the transition of an explosive wave in the detonation. The derived formula is very simple, being also more suitable for studying the limiting processes of volume detonation. The conditions for the transition of a shock wave to a detonation wave are studied. Initial detonation conditions required for fast chemical reactions to take place at the front of a spherical explosive wave have been determined. A simple relation describing the critical detonation temperature for various pressures in the hydrogen-oxygen mixture was obtained. Using the known formulas for a shock transition, the critical temperature was coupled with the initial conditions in a static environment, such as the pressure, temperature, and hydrogen content in the mixture.

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氢氧相互作用中爆震波速度的测定及球形爆轰的形成条件

由Hugoniot方程组导出的著名的平爆波速度公式，如果应用于球形反应堆，将面临困难。在反应气体介质爆炸理论的框架下，利用描述爆炸波在爆轰过程中的过渡的特殊模型，得到了一个类似的公式。导出的公式非常简单，也更适合研究体积爆轰的极限过程。研究了激波向爆震波过渡的条件。在球形爆炸波前发生快速化学反应所需的初始爆轰条件已经确定。得到了不同压力下氢氧混合物临界爆轰温度的简单关系式。使用已知的激波转变公式，将临界温度与静态环境中的初始条件(如压力、温度和混合物中的氢含量)耦合在一起。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Direct Numerical Simulations - An Introduction and Applications

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