气隙中流光动力学的仿真

Lin Zhang, Jianfeng Hui, Xiaobo Meng, Xingming Bian, Li-ming Wang, Z. Guan
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引用次数: 1

摘要

高空气隙击穿事故越来越受到研究人员的关注。随着海拔高度的增加,气压和湿度的变化,气隙放电变得更加复杂。在气隙击穿过程中,流光传播是一个重要的物理过程。对流光特性的研究有助于理解气隙击穿的机理。本文采用流体模型建立了拖缆动力学仿真模型。在不同的气压和湿度条件下,将流线动力学的数值计算结果与前人的实验结果进行了比较。在稳定传播场下,试验结果与数值计算结果吻合较好,验证了流体动力学仿真模型的有效性。然后,采用仿真模型研究了背景电场、电压脉冲持续时间和幅值对流波传播的影响。随着电压脉冲持续时间和幅值的增加,流光传播的本征稳定场和相应的传播速度减小。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The simulation of streamer dynamics in the air gap
The air gap breakdown at high altitude is attracting more and more attention from investigators. As the altitude increases, air pressure and humidity varies, discharge in air gap becomes more complex. The streamer propagation is a significant physical process during air gap breakdown. Research on streamer characteristic is helpful for understanding the mechanism of air gap breakdown. In the paper, a simulation model of streamer dynamics was carried out using fluid model. The numerical results of streamer dynamics were compared with the experiment results which had been published in former paper under different air pressure and humidity. Good agreement between test and numerical computation at stability propagation field is obtained, which demonstrates the validity of the simulation model of streamer dynamics. Then, the simulation model was adopted to study the influence of background electric field, duration and amplitude of voltage pulse on streamer propagation. With the rising of duration and amplitude of voltage pulse, the intrinsic stability field for streamer propagation and corresponding propagation velocity decrease.
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