激波冲击V形界面的RM不稳定性实验研究

翟志刚; 董平; 罗喜胜

doi:10.11858/gywlxb.2017.06.006

激波冲击V形界面的RM不稳定性实验研究

doi: 10.11858/gywlxb.2017.06.006

中国科学技术大学近代力学系，安徽合肥 230027

基金项目:

国家自然科学基金 U1530103

国家自然科学基金 11621202

挑战计划 TZ2016001

详细信息

作者简介:
翟志刚(1985-), 男, 博士, 副教授, 主要从事实验流体力学研究.E-mail:sanjing@ustc.edu.cn

通讯作者:
罗喜胜(1971-), 男, 博士, 教授, 主要从事实验流体力学研究.E-mail:xluo@ustc.edu.cn

中图分类号: O354.5
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出版历程
- 收稿日期: 2017-05-27
- 修回日期: 2017-06-19

Experimental Investigation on Richtmyer-Meshkov Instability of a "V" Shaped Interface Subjected to Shock Wave

Department of Modern Mechanics, University of Science and Technology of China, Hefei 230027, China

摘要

摘要: 在激波管中实验研究了二维V形空气/SF₆界面在入射激波和反射激波作用下的Richtmyer-Meshkov不稳定性发展规律。实验中采用细针约束肥皂膜的方法形成了精确可控的V形初始界面，利用高速纹影技术获得了受冲击的V形界面演化图像。通过改变初始V形界面顶角表征初始扰动振幅，获得了不同初始振幅条件下的波系和界面演化。结果表明，不同顶角下，入射激波冲击过后，界面形态表现出明显的差异，进一步导致反射激波冲击后界面形态的多样性。当顶角较小时，反射激波在界面内外引起复杂的波系结构，从而对界面形态及反相现象产生较大的影响。反射激波的二次作用使流场快速进入湍流混合状态，并且顶角较小时流场趋于各向同性发展。对反射激波作用后的界面混合宽度进行了测量，并与理论模型预测结果进行对比，发现理论模型不能很好地预测混合宽度的增长，主要是因为反射激波作用之后流场并没有完全达到湍流混合状态，不符合理论模型的适用条件。
- Richtmyer-Meshkov不稳定性 /
- V形初始界面 /
- 初始扰动振幅 /
- 反射激波
Abstract: The Richtmyer-Meshkov instability of a "V" shaped air/SF₆ interface accelerated by a planar incident shock and its reshock was experimentally investigated in a shock tube.The soap film technique was adopted to form a well-controllable initial interface, and the flow field was captured by a high-speed schlieren system.Through changing the vertex angle of the interface, the initial perturbation amplitude was varied, and the effect of the initial perturbation amplitude on the wave pattern and the flow morphology was highlighted.The results show that, after the impact of the incident shock, the interface morphology is different for different vertex angles, further causing the diversity of the interface morphology after the reshock impact.For the interfaces with small vertex angles, the complicated wave patterns will emerge inside and outside the interface after the reshock, which exert an influence on the interface morphology and phase inversion phenomenon.The flow enters the turbulent mixing quickly after the reshock, and the development of interface for small vertex angles tends towards isotropy.Moreover, the mixing width after the reshock was measured from experiments and compared with the theoretical predictions.The model was found to be invalid mainly because the initial conditions of the experiments violate the requirement of the model.
- Richtmyer-Meshkov instability /
- "V" shaped initial interface /
- initial perturbation amplitude /
- reshock

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图 1 界面生成方法

Figure 1. Interface formation method

下载: 全尺寸图片幻灯片

图 2 实验中采用的高速纹影系统

Figure 2. High-speed schlieren system used in the experiment

下载: 全尺寸图片幻灯片

图 3 平面激波与不同顶角的V形界面相互作用的纹影图像(入射激波从左向右传播，反射激波接触演化界面时刻定义为零时刻)

Figure 3. Schlieren images of the interaction of a planar shock with a V shaped interface with different vertex angles

(The incident shock propagates from left to right, and the initial time is defined as the moment of the reflected shock encountering the evolving interface.)

下载: 全尺寸图片幻灯片

图 4 反射激波与V形空气/SF₆界面相互作用后特征点S的运动规律(a)及其局部放大图(b)

(图中的椭圆形虚线代表特征点S出现反向增长的阶段)

Figure 4. Time variation of the characteristic point of S after the interaction of the reflected shock with the V shaped air/SF₆ interface (a), and the partial enlargement (b) (The oval dashed lines represent the backward motion of S.)

下载: 全尺寸图片幻灯片

图 5 反射激波与V形空气/SF₆界面相互作用后界面混合宽度的增长规律

Figure 5. Time variation of the turbulent mixing width of V shaped air/SF₆ interface subjected to the reshock

下载: 全尺寸图片幻灯片

表 1 实验初始条件

Table 1. Initial conditions of experiments

θ/(°)	Ma	x/(mm)
60	1.20	181
90	1.20	210
120	1.21	293
140	1.20	235
160	1.19	243

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