A review on solid propellant micro-thruster array based on MEMS technology

FirePhysChem Pub Date : 2023-03-23 DOI:10.1016/j.fpc.2023.03.002

Jianbing Xu , Jiangtao Zhang , Fuwei Li , Shiyi Liu , Yinghua Ye , Ruiqi Shen

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Abstract

With the development of micro-spacecraft technology, micro-nano satellites have the advantages of small size, low power consumption, short development cycle, formation networking, etc., and can complete many complex space tasks at a lower cost. Micro-nano satellites require a micropropulsion system with the capability of performing precise total impulse and thrust to execute maneuvers, such as attitude control, orbital transfer, and gravitation compensation. In contrast to other micropropulsion systems, solid propellant microthrusters (SPM) arrays based on micro-electromechanical system (MEMS) technology possess a simple structure and quick response, which is a potential micropropulsion system. In recent years, many research groups have done a lot of research on SPM arrays. In this paper, the latest progress of SPM arrays is summarized from the aspects of structure design, propellant selection, bonding technology, ignition unit type and micro-thrust test, and some suggestions for the future development direction are given.

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基于 MEMS 技术的固体推进剂微型推进器阵列综述

随着微型航天器技术的发展，微纳卫星具有体积小、功耗低、研制周期短、编队组网等优点，能以较低的成本完成许多复杂的空间任务。微纳卫星要求微推进系统能够提供精确的总冲力和推力，以执行姿态控制、轨道转移和重力补偿等机动任务。与其他微推进系统相比，基于微机电系统（MEMS）技术的固体推进剂微推进器（SPM）阵列结构简单、响应迅速，是一种潜在的微推进系统。近年来，许多研究小组对 SPM 阵列做了大量研究。本文从结构设计、推进剂选择、结合技术、点火装置类型和微推力试验等方面总结了 SPM 阵列的最新进展，并对未来的发展方向提出了一些建议。

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

FirePhysChem

CiteScore

1.40

自引率

0.00%

发文量