材料强度对电磁驱动固体套筒内爆过程的影响

章征伟; 魏懿; 孙奇志; 刘伟; 赵小明; 张朝辉; 王贵林; 郭帅; 谢卫平

doi:doi:10.11884/hplpb201628.045017

强激光与粒子束, 2016, 28 (4): 045017, 网络出版: 2016-04-01

材料强度对电磁驱动固体套筒内爆过程的影响

Effect of material strength on electromagnetic driven solid liner implosion

论文大纲

章征伟 ^*魏懿孙奇志刘伟赵小明张朝辉王贵林郭帅谢卫平

作者单位

中国工程物理研究院流体物理研究所, 四川绵阳, 621900

固体套筒零维模型材料强度流动应力负载设计 solid liner zero dimension model material strength flow stress load design

摘要

电磁驱动柱形固体套筒内爆加载技术是高能量密度物理实验研究的重要加载方式。由于固体金属具有一定的结合强度,需外加载荷达到特定阈值才会发生塑性流动,且在内爆过程中塑性做功会耗散部分电磁力做功而变成金属材料的内能,进而对固体套筒的内爆过程产生影响。通过弹塑性力学平面轴对称问题的解,给出了套筒发生塑性流动时外加电流(即屈服电流)与套筒参数的关系。利用考虑材料强度的零维不可压缩模型对铝套筒的内爆过程进行模拟,并分别与简单零维模型和实验数据进行对比,结果发现当电流峰值远大于(20倍于)屈服电流时,金属材料强度的影响甚微; 而当峰值电流只数倍于屈服电流时,金属材料强度的影响便不能忽略。

Abstract

The electromagnetic driven solid liner implosion is one of the high energy density physics (HEDP) experimental techniques. Because of the metal strength, there exists a threshold for driven pressure where plastic flow just begins. And the plastic work that will turn to the internal energy of the metal liner should decrease the kinetic energy of liner, which of course will affect the implosion of the solid liner. The critical current has been found via the elastic-plastic analysis of cylindrical symmetry issue. The zero-dimension (0D) simulation considering the effect of material strength has been developed, whose result is also compared with the simple model and experimental data separately. The result shows that the effect of material strength is negligible when the peak value of current is far larger than the critical current, while the effect is remarkable when the peak value is similar to the critical current.

参考文献

[1] Bowers R L, Brownell J H, Lee H, et al. Precision solid liner experiments on Pegasus Ⅱ［R］. LA-UR-95-2869,1995.

[2] Cochrane J C, Hockaday R G, Bartsch R R, et al. Direct drive foil implosion experiments on Pegasus Ⅱ［R］. LA-UR-93-1448,1993.

[3] 杨礼兵,孙承纬,廖海东,等. 高能量密度物理实验装置FP-1及其应用［J］. 强激光与粒子束,2002,14(5): 767-770.(Yang Libing, Sun Chengwei, Liao Haidong, et al. High energy density physics facility FP-1 and its applications. High Power Laser and Particle Beams, 2002, 14(5): 767 -770)

[4] 杨礼兵,孙承纬,廖海东,等. 电磁驱动固体套筒的内爆［J］. 爆炸与冲击,2000,20(2): 156-159. (Yang Libing, Sun Chengwei, Liao Haidong, et al. Implosion of solid liner driven by electro-magnetic force. Explosion and Shock Waves, 2000, 20(2): 156-159)

[5] 杨礼兵,孙承纬,丰树平,等. FP-1直接驱动套筒内爆技术研究［J］. 爆炸与冲击,1998,18(4): 338-343. ( Yang Libing, Sun Chengwei, Feng Shuping, et al. The study of technique to FP-1 directly driven liner implosion. Explosion and Shock Waves, 1998, 18(4): 338-343)

[6] 邓建军,王勐,谢卫平,等. 面向Z箍缩驱动聚变能源需求的超高功率重复频率驱动器技术［J］. 强激光与粒子束,2014,26: 100201. (Deng Jianjun, Wang Meng, Xie Weiping, et al. Super-power repetitive Z-pinch driver for fusion-fission reactor. High Power Laser and Particle Beams, 2014, 26: 100201)

[7] 段书超,阚明先,王刚华,等. 用于电磁驱动真空-等离子体系统数值模拟的驰豫磁流体力学模型［J］. 强激光与粒子束,2015,27: 065002. (Duan Shuchao, Kan Mingxian, Wang Ganghua, et al. Relaxation magnetohydrodynamics model for the computation of an electromagnetically driven vacuum-plasma system. High Power Laser and Particle Beams, 2015, 27: 065002)

[8] 徐秉业,刘信声. 应用弹塑性力学［M］. 北京: 清华大学出版社,1995: 183-191.(Xu Bingye, Liu Xinsheng. Application of elastic and plastic mechanics. Beijing: Tsinghua University Press, 1995: 183-191)

[9] 孙承纬. 应用爆轰物理［M］. 北京: 国防工业出版社,2000: 600-610.(Sun Chengwei. Application of detonation physics. Beijing: National Defence Industry Press, 2000: 600-610)

[10] 孙奇志,孙承纬. 轴线起爆式螺线管型爆炸磁通量压缩发生器理论模型［J］. 强激光与粒子束,2003,15(4): 385-390.(Sun Qizhi, Sun Chengwei. Model of helical magnetic compression generators with explosive initiated axially. High Power Laser and Particle Beams, 2003, 15(4): 385-390)

[11] Steinberg D J, Cochran S G, Guinan M W. A constitutive model for metals applicable at high-strain rate［J］. J Appl Phys, 1980, 51(3): 1498-1504.

[12] Steinberg D J, Lund C M. A constitutive model for strain rates from 10-4 to 106 s-1［J］. J Appl Phys, 1989,65(4): 1528-1533.

[13] Reinovsky R E, Atchison W L, Dimonter G, et al. Pulsed power hydrodynamics: An application of pulsed power and high magnetic fields to the exploration of material properties and problems in experimental hydrodynamics［J］. IEEE Trans Plasma Sci, 2008: 112-124.

章征伟, 魏懿, 孙奇志, 刘伟, 赵小明, 张朝辉, 王贵林, 郭帅, 谢卫平. 材料强度对电磁驱动固体套筒内爆过程的影响[J]. 强激光与粒子束, 2016, 28(4): 045017. Zhang Zhengwei, Wei Yi, Sun Qizhi, Liu Wei, Zhao Xiaoming, Zhang Zhaohui, Wang Guilin, Guo Shuai, Xie Weiping. Effect of material strength on electromagnetic driven solid liner implosion[J]. High Power Laser and Particle Beams, 2016, 28(4): 045017.

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