The Power Reduction of the Air-Breathing Hall-Effect Thruster

2020 IEEE International Conference on Plasma Science (ICOPS) Pub Date : 2020-12-06 DOI:10.1109/ICOPS37625.2020.9717959

Sungrae Kim, M. Keidar

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Abstract

The Hall-effect thruster (HET), a kind of the electric propulsion system, is known as one of next generation propulsion system because of a lot of benefits. Furthermore, the air-breathing Hall-effect thruster (ABHET) has additional benefits in comparison to the HET. By using the ambient air as a propellant while the HET uses the noble gas as a propellant, it doesn't require a space to store a propellant, which results the decrease in its size. It may allow the spacecraft to bring more payloads and to be able to be operated for longer time. Previously, the research1 on the ABHET has been performed, but the power was so high that the thruster can't bear with it. This is because the research was done with the consideration that all atoms are fully ionized, which resulted very high power. Thus, this research is done in order to look at the proper ionization rate for which the device can bear with. The power needs to be reduced to approximately 1kW or less. The operational altitude is from 90km to 100km, which is known as the LEO (Low Earth Orbit). The power needed is calculated by controlling the ionization rate. Also, the length of the channel is considered to control the power. Based on the results, the proper ionization rate and the proper length of the channel are presented and discussed.

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吸气式霍尔效应推进器的功率降低

霍尔效应推进器(HET)是电力推进系统的一种，因其诸多优点被誉为下一代推进系统之一。此外，吸气式霍尔效应推进器(ABHET)与HET相比具有额外的优点。通过使用环境空气作为推进剂，而HET使用惰性气体作为推进剂，它不需要空间来存储推进剂，这导致其尺寸减小。它可能允许航天器携带更多的有效载荷，并能够运行更长的时间。此前，对ABHET的研究已经进行过，但功率太高，推进器无法承受。这是因为该研究考虑到所有原子都被充分电离，从而产生了非常高的功率。因此，这项研究是为了看看适当的电离率，该设备可以承受。功率需要降低到1kW以下。操作高度从90公里到100公里，被称为LEO(近地轨道)。通过控制电离速率来计算所需的功率。此外，通道的长度被认为是控制功率的因素。在此基础上，提出并讨论了合适的电离速率和通道长度。

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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2020 IEEE International Conference on Plasma Science (ICOPS)

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