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The instability of metal interface is an important problem in the process of implosion physical compression, which is significantly different from the traditional fluid interface instability. Due to the limitation of related theory and experimental diagnosis technology, this problem is studied still insufficiently. In order to understand in depth the perturbation growth behavior of metal interface instability, the technique for high explosive driven Rayleigh-Taylor instability experiment on the oxygen-free high conductivity (OFHC) copper is developed. The perturbation growth on OFHC copper interface with varying initial perturbation amplitude at a specific time is recorded by radiography. According to the data processing on the X-ray images, the perturbation growth behaviors of the interface at different times are obtained. The experimental results show that the larger the initial perturbation amplitude, the faster the perturbation grows, but the perturbation wavelength of the interface remains almost unchanged at the explosive loading. The perturbation on the front interface will have an effect on the back free interface, and cause some corresponding disturbance to occur on the surface, namely, on the back free interface, the position corresponding to the perturbation trough of the front interface first moves and gradually evolves into a spike, while the position corresponding to perturbation crest evolves into a bubble. The strain rate of instability perturbation growth reaches ~105/s, and the perturbation amplitude of the interface increases to about 700% of the initial value at 5.26 μs. The corresponding numerical simulation results show that the normal SCG model underestimates the strength of copper and cannot well describe the stabilizing effect of material strength at this high strain rate, thereby leading to the fact that the simulation results are higher than the experimental results.
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Keywords:
- Rayleigh-Taylor instability /
- explosive loading /
- perturbation growth /
- radiography
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图 1 爆轰加载下金属界面RT不稳定性实验布局
Figure 1. Scheme of the experimental assembly of high explosive driven metal RT instability.
图 2 预制初始扰动的高纯铜样品实物图与剖面图(单位: mm)
Figure 2. Pictures of a pre-machined sinusoidal perturbation oxygen-free high conductivity copper target.
图 3 不同时刻界面扰动增长的X光图像
Figure 3. Radiographs of the perturbation growth at the different times.
图 4 数据处理后样品的边界图像
Figure 4. Specimen edge images of after data processing.
图 5 扰动幅值的增长速度随时间的变化
Figure 5. Change of the perturbation growth velocity with time.
图 6 界面扰动幅值随时间增长的实验和数值模拟结果对比
Figure 6. Comparison of the perturbation growth between experiment and simulation.
表 1 不同时刻高纯铜样品界面扰动特征参数
Table 1. Interface perturbation characters of the high purity copper at different times.
实验
编号初始波
长/mm初始幅
值/mm当前幅
值/mm照相
时刻/μs1 5.0 0.3 0.86 ± 0.05 1.98 0.5 1.17 ± 0.05 2 5.0 0.3 1.65 ± 0.05 3.50 0.5 2.67 ± 0.05 3 5.0 0.3 1.98 ± 0.05 5.26 0.5 3.42 ± 0.05 
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[1] 王继海 1994 二维非定常流体和激波 (北京: 科学出版社) 第348页
Wang J H 1994 2D-Unsteady Fluid Flow and Shock Wave (Beijing: Science Press) p348 (in Chinese)
[2] 刘军, 冯其京, 周海兵 2014 物理学报 63 155201
Google Scholar
Liu J, Feng Q J, Zhou H B 2014 Acta Phys. Sin. 63 155201
Google Scholar
[3] 张维岩, 叶文华, 吴俊峰, 等 2014 中国科学G辑: 物理学 力学 天文学 44 1
Zhang W Y, Ye W H, Wu J F, et al. 2014 Sci. China, Ser. G: Phys. Mech. Astron. 44 1
[4] Mikhailov A L 2007 Phys. Mesomech. 10 265
Google Scholar
[5] Miles J W 1966 General Dynamics Technical Report No. GAMD-7335 AD 643161
[6] Drucker D C 1980 Mechanics Today 5 37
[7] Swegle J W, Robinson A C 1989 J. Appl. Phys. 66 072838
[8] Piriz A R 2010 Phys. Rev. Lett. 105 179601
[9] Park H S, Lorenz K T, Cavallo R M, et al. 2010 Phys. Rev. Lett. 105 179602
[10] Barnes J F, Blewett P J, McQueen R G, et al. 1974 J. Appl. Phys. 45 727
Google Scholar
[11] Park H S, Remington B A, Becker R C, et al. 2010 Phys. Plasmas 17 6314
[12] 黄文斌, 邹立勇, 刘金宏, 等 2010 实验流体力学 24 39
Google Scholar
Huang W B, Zhou L Y, Liu J H, et al. 2010 J. Exper. Fluid Mech. 24 39
Google Scholar
[13] 刘金宏, 谭多望, 张旭, 等 2012 高压物理学报 26 687
Google Scholar
Liu J H, Tan D W, Zhang X, et al. 2012 Chin. J. High Press Phys. 26 687
Google Scholar
[14] 柏劲松, 李平, 谭多望, 等 2007 力学学报 39 741
Google Scholar
Bai J S, Li P, Tan D W, et al. 2007 Chin J. Theor. Appl. Mech. 39 741
Google Scholar
[15] 李源, 罗喜胜 2014 物理学报 63 085203
Google Scholar
Li Y, Luo X S 2014 Acta Phys. Sin. 63 085203
Google Scholar
[16] 赵凯歌, 薛创, 王立锋, 等 2018 物理学报 67 094701
Google Scholar
Zhao K G, Xue C, Wang L F, et al. 2018 Acta Phys. Sin. 67 094701
Google Scholar
[17] 赵信文, 李欣竹, 王学军, 等 2015 物理学报 64 124701
Google Scholar
Zhao X W, Li X Z, Wang X J, et al. 2015 Acta Phys. Sin. 64 124701
Google Scholar
[18] 殷建伟, 潘昊, 吴子辉, 郝鹏程, 段卓平, 胡晓棉 2017 物理学报 66 204701
Google Scholar
Yin J W, Pan H, Wu Z H, Hao P C, Duan Z P, Hu X M 2017 Acta Phys. Sin. 66 204701
Google Scholar
[19] 何长江, 周海兵, 杭义洪 2009 中国科学G辑: 物理学 力学 天文学 39 1170
He C J, Zhou H B, Hang Y H 2009 Sci. China, Ser. G: Phys. Mech. Astron. 39 1170
[20] 潘昊, 吴子辉, 胡晓棉, 等 2013 高压物理学报 27 778
Google Scholar
Pan H, Wu Z H, Hu X M 2013 Chin. J. High Press Phys. 27 778
Google Scholar
[21] 王涛, 柏劲松, 曹仁义, 等 2018 高压物理学报 32 16
Wang T, Bai J S, Cao R Y, et al. 2018 Chin. J. High Press Phys. 32 16
[22] Bai X B, Wang T, Zhu Y X, et al. 2018 World J. Mech. 8 94
Google Scholar
[23] Steinberg D J, Cochran S G, Guinan M W 1980 J. Appl. Phys. 51 1498
Google Scholar
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