Development of accelerated methods for calculating the pattern of current spreading over the surface of spacecraft

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
A. Vostrikov, E. Prokofeva
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引用次数: 0

Abstract

High-energy charged plasma particles pose a danger to space technology. The accumulation of charged particles on the body of the spacecraft generates discharges. Electrostatic discharge is a source of powerful electromagnetic interference that adversely affects the functioning of individual parts and entire systems. According to statistics, in about 30% of cases, the loss of satellites are the consequences of discharges. Before the operation of spacecraft, it is necessary to calculate the spreading of currents, which requires large machine and time costs. The article proposes original approaches for quickly constructing a picture of the spreading of currents over the surface of a spacecraft due to electrification. The key point of the first approach is the construction of a limited area for calculating the flow spreading. The calculation of transient currents will only take place in the electromagnetic compatibility area specified by the user, without affecting the rest of it. The paper also developed new simplified computational schemes for a system of differential equations based on the Euler methods. With the help of new computational schemes, the time for calculating unknown quantities in a local area specified by the user has been reduced by several orders of magnitude compared to the calculation of unknown full models. The article presents conclusions on new computational schemes, indicating the complexity of their construction. The adequacy and accuracy of the new computational scheme is confirmed by a practical example.
计算航天器表面电流分布模式的加速方法的发展
高能带电等离子体粒子对空间技术构成威胁。带电粒子在航天器上的积累会产生放电。静电放电是一种强大的电磁干扰源,对单个部件和整个系统的功能产生不利影响。据统计,在大约30%的情况下,卫星的损失是放电的后果。在航天器运行前,需要计算电流的扩散,这需要大量的机器和时间成本。这篇文章提出了一种新颖的方法,用于快速构建由于电气化而在航天器表面传播的电流的图像。第一种方法的关键是建立一个计算流动扩散的有限区域。暂态电流的计算只在用户指定的电磁兼容区域内进行,不影响其余部分。本文还基于欧拉方法开发了新的微分方程组的简化计算格式。在新的计算格式的帮助下,计算用户指定的局部区域的未知量的时间比未知全模型的计算时间减少了几个数量级。本文提出了新的计算格式的结论,指出了其结构的复杂性。通过实例验证了新计算方案的充分性和准确性。
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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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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