High-Speed Flow Visualization by a Nanosecond Volume Discharge during Shock Wave Diffraction on an Obstacle

Q4 Computer Science

Scientific Visualization Pub Date : 2023-09-01 DOI:10.26583/sv.15.3.05

I. Mursenkova, A. Ivanova, I. Ivanov, N. Sysoev, A. Karimov

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Abstract

We study the spatial structure of nonstationary inhomogeneous supersonic airflows as shock wave diffraction on an obstacle occurs in a shock tube of a rectangular cross section. The Mach numbers of shock waves were 2.7–4.4 at initial air pressures of 10–30 Torr. The supersonic flow in the discharge chamber was visualized by high-speed shadowgraphy and by the registration of radiation of combined volume discharge by photo camera and by ICCD camera. In experiments, a combined volume discharge with a current duration of ~ 500 ns was initiated 40–150 μs after the initial shock wave have passed an obstacle. It has been established that the radiation of the volume phase of discharge lasts 400–700 ns, and the displacement of the flow during this time does not exceed 0.6 mm. A correlation is established between the spatial distribution of discharge radiation and the low-density local areas determined as a result of two-dimensional Navier-Stokes based numerical simulation of the flow. As visualized by the glow of the discharge, the shape of the shock wave front is in good agreement with the results of shadowgraphy at different stages of diffraction and with the numerical simulation results.

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激波在障碍物上衍射时纳秒体积放电的高速流动显示

研究了矩形截面激波管内激波在障碍物上衍射时的非定常非均匀超音速气流的空间结构。在初始气压为10 ~ 30 Torr时，激波马赫数为2.7 ~ 4.4。采用高速阴影成像技术，结合相机和ICCD相机对组合容积放电辐射进行配准，对放电腔内的超声速流动进行了可视化。在实验中，在初始激波通过障碍物后40 ~ 150 μs启动一个电流持续时间为~ 500 ns的组合体积放电。计算结果表明，放电体积相的辐射持续400-700 ns，这段时间内的流量位移不超过0.6 mm。通过二维Navier-Stokes流数值模拟，建立了放电辐射的空间分布与低密度局部区域之间的相关性。放电辉光显示的激波锋面形状与衍射不同阶段的阴影成像结果和数值模拟结果吻合较好。

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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来源期刊

Scientific Visualization Computer Science-Computer Vision and Pattern Recognition

CiteScore

1.30

自引率

0.00%

发文量