Study on plasma expansion model of primary discharge on spacecraft solar array

Pub Date : 2024-11-01 DOI:10.1088/2058-6272/ad718b
Dejie WEI, 德杰 尉, Jianwen WU (武建文), Liying ZHU and 立颖 朱
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Abstract

In the space plasma environment, primary discharge may occur on the solar array and evolve into a destructive sustained arc, which threatens the safe operation of the spacecraft. Based on the plasma expansion fluid theory, a new multicomponent plasma expansion model is proposed in this study, which takes into account the effects of ion species, ion number, initial discharge current, and Low Earth Orbit (LEO) plasma environment. The expansion simulation of single-component and multicomponent ions is carried out respectively, and the variations of plasma number density, expansion distance, and speed during the expansion process are obtained. Compared with the experimental results, the evolution of propagation distance and speed is closed and the error is within a reasonable range, which verifies the validity and rationality of the model. The propagation characteristics of the primary discharge on the solar array surface and the influence of the initial value on the maximum propagation distance and the propagation current peaks are investigated. This study can provide important theoretical support for the propagation and evolution of the primary discharge and the key behavior of the transition to secondary discharge on spacecraft solar array.
航天器太阳电池阵列一次放电等离子体膨胀模型研究
在空间等离子体环境中,太阳电池阵列可能会发生原生放电,并演变成破坏性的持续电弧,从而威胁航天器的安全运行。本研究基于等离子体膨胀流体理论,提出了一种新的多组分等离子体膨胀模型,该模型考虑了离子种类、离子数量、初始放电电流和低地球轨道(LEO)等离子体环境的影响。分别对单组分和多组分离子进行了膨胀模拟,得到了膨胀过程中等离子体数密度、膨胀距离和速度的变化。与实验结果相比,传播距离和速度的演变是封闭的,误差在合理范围内,验证了模型的有效性和合理性。研究了太阳能电池阵表面原生放电的传播特性以及初始值对最大传播距离和传播电流峰值的影响。该研究可为航天器太阳电池阵列上一次放电的传播和演化以及向二次放电过渡的关键行为提供重要的理论支持。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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