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微腔内气体抽离的多尺度模拟与分析
引用本文:李海洋, 张占文, 易勇, 等. 微腔内气体抽离的多尺度模拟与分析[J]. 强激光与粒子束, 2021, 33: 042001. doi: 10.11884/HPLPB202133.200243
作者姓名:李海洋  张占文  易勇  毕鹏  栾旭  史瑞廷
作者单位:1.西南科技大学 材料科学与工程学院,四川 绵阳 621000;;2.中国工程物理研究院 激光聚变研究中心,四川 绵阳 621900
基金项目:环境友好能源材料国家重点实验室自主课题资助项目(20fksy04);四川省重点研发计划项目(2019YFG0432)
摘    要:基于适用于整个克努森数范围的流动理论,建立了去除惯性约束聚变实验中靶丸内空气的理论模型,并设计实验验证了此模型的可靠性。物理实验要求靶丸内空气浓度低于10×10−6,数值模拟了去除靶丸内空气的过程,重点分析了靶丸内空气浓度、压力与除气时间的关系。计算并比较了单管路一次抽气法、单管路循环抽气法与双管路流洗法三种去除靶丸内空气方法的时间成本。数值计算结果表明:单管路一次抽气法中,靶丸上的微通道的存在对去除靶丸内空气所需时间的影响不可忽略,在考虑靶丸上微通道与充气管的情况下,需要1961.77 h才能使靶丸内的空气浓度达到标准。单管路循环抽气法中,抽气次数与单次抽气程度会影响去除靶丸内空气所需总时间,在单次抽气程度值取最优的情况下,采用充三次,抽四次的方案可使达标总时间减少至1 h左右,此方案下单次充气和抽气时间分别为6 min和10 min。而采用双管路流洗法则仅需11 min便可使靶丸内空气浓度达标。

关 键 词:抽气   充气   微管   自由分子流   数值模拟
收稿时间:2020-08-19
修稿时间:2021-04-07

Multi-scale simulation and analysis of gas evacuation processes in a microcavity
Li Haiyang, Zhang Zhanwen, Yi Yong, et al. Multi-scale simulation and analysis of gas evacuation processes in a microcavity[J]. High Power Laser and Particle Beams, 2021, 33: 042001. doi: 10.11884/HPLPB202133.200243
Authors:Li Haiyang  Zhang Zhanwen  Yi Yong  Bi Peng  Luan Xu  Shi Ruiting
Affiliation:1. School of Materials Science and Engineering, Southwest University of Science and Technology, Mianyang 621000, China;;2. Laser Fusion Research Center, CAEP, P. O. Box 919-988, Mianyang 621900, China
Abstract:Based on the flow theory applicable to the whole Knudsen number range, a theoretical model for removing air from the target shot in inertial confinement fusion was established, and the reliability of the model was verified by designed experiments. The physical experiment requires the air concentration in the target shot to be lower than 10×10−6, the process of removing air in the target shot was simulated numerically, and the relationship between the air concentration in the target shot, the pressure in the target shot and time was emphatically analyzed. The time cost of three methods for removing the air in the target shot, namely the single-pipe one-time gas evacuation method, the single-pipe circulation gas evacuation method and the double-pipe flow washing method, were calculated and compared. Numerical calculation results show that: in the single-pipe one-time gas evacuation method, the existence of the micro-channel on the target shot has a non-negligible effect on the time required to remove the air in the target shot, and it takes 1961.77 h to make the air concentration in the target shot reach the standard when the micro-channel on the target shot and the gas-filling pipe is considered. In the single-pipe cycle gas evacuation method, the number of evacuation times and the degree of single gas evacuation will affect the total time required to remove the air in the target shot. When the single gas evacuation degree is at the optimal value, the plan that filling three times and evacuation four times can reduce the total time to reach the standard to about 1 h, while the single gas filling and gas evacuation times under this plan are 6 min and 10 min, respectively. However, it only takes 11 minutes to make the air concentration in the target shot reach the standard by using the double-pipe flow washing method.
Keywords:filling  evacuation  microcapillary tube  free molecular flow  numerical simulation
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