Peculiarities of self-ignition of a hydrogen–air mixture in shock tubes of different roughnesses

IF 1.7 4区工程技术 Q3 MECHANICS

Shock Waves Pub Date : 2024-12-14 DOI:10.1007/s00193-024-01203-3

A. V. Skilandz, O. G. Penyazkov, A. I. Leonchik

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Abstract

The induction time in shock tubes with different surface roughnesses and different mixture densities was measured, local features of self-ignition were described, and the results obtained were compared with the results for tubes with other diameters in order to determine the effect of gasdynamic parameters on the formation of ignition kernels and ignition in general. It was discovered that ignition at temperature range of 904–1200 K for \(\rho _{\textrm{5}} = 2.80\,{\hbox {kg/m}}^{\textrm{3}}\) and 1020–1120 K for \(\rho _{\textrm{5}} = 1.53\,{\hbox {kg/m}}^{\textrm{3}}\) is determined by the ignition kernel that forms near the tube axis and is a consequence of the gasdynamic effect at the tube axis (axial effect), but is not explained by the adiabatic compression of the mixture due to the expansion of gas from the reflected shock wave bifurcation stagnation region. An increase in the size of the bifurcation structure due to an increase in tube surface roughness does not affect ignition at these temperatures, but expands the ignition range at lower temperatures, in which multi-kernels or volumetric ignition is observed.

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不同粗糙度激波管内氢气-空气混合气自燃特性研究

测量了不同表面粗糙度和不同混合密度激波管内的感应时间，描述了自燃的局部特征，并将所得结果与其他直径激波管内的结果进行了比较，以确定气体动力学参数对点火核形成和点火的总体影响。研究发现，在温度范围（\(\rho _{\textrm{5}} = 2.80\,{\hbox {kg/m}}^{\textrm{3}}\)为904 - 1200k， \(\rho _{\textrm{5}} = 1.53\,{\hbox {kg/m}}^{\textrm{3}}\)为1020 - 1120k）时，着火是由在管轴附近形成的点火核决定的，是管轴处气体动力效应（轴向效应）的结果，而不是由反射激波分岔滞胀区气体膨胀引起的混合物绝热压缩来解释的。在这些温度下，由于管表面粗糙度的增加而导致的分叉结构尺寸的增加并不影响点火，但在较低温度下，可以观察到多核或体积点火，从而扩大了点火范围。

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来源期刊

Shock Waves 物理-力学

CiteScore

4.10

自引率

9.10%

发文量

审稿时长

17.4 months

期刊介绍： Shock Waves provides a forum for presenting and discussing new results in all fields where shock and detonation phenomena play a role. The journal addresses physicists, engineers and applied mathematicians working on theoretical, experimental or numerical issues, including diagnostics and flow visualization. The research fields considered include, but are not limited to, aero- and gas dynamics, acoustics, physical chemistry, condensed matter and plasmas, with applications encompassing materials sciences, space sciences, geosciences, life sciences and medicine. Of particular interest are contributions which provide insights into fundamental aspects of the techniques that are relevant to more than one specific research community. The journal publishes scholarly research papers, invited review articles and short notes, as well as comments on papers already published in this journal. Occasionally concise meeting reports of interest to the Shock Waves community are published.