无人机上可重复使用运载火箭废段的回收

2022 International Conference on Computing, Communication, and Intelligent Systems (ICCCIS) Pub Date : 2022-11-04 DOI:10.1109/ICCCIS56430.2022.10037641

S. S. Sithara, P. S. Shenil

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引用次数: 0

摘要

可重复使用运载火箭(RLV)比传统运载火箭更受当前空间探索机构的青睐。rlv可以用于多次发射，这降低了发射成本并增加了空间研究计划的参与。再入飞行被认为是RLV运行中最重要的阶段。在本研究中，采用GEKKO数值优化方法寻找可重复使用的运载火箭使用最少燃料的再入着陆轨迹。在这里，动力下降是首选方案，通过控制推力水平来优化再入轨道。推力控制采用砰砰控制技术。理想轨道的三个阶段是助推器燃烧阶段，滑行或自由落体阶段，以及着陆阶段。在这三个阶段的推力方向和油门水平已经预先确定，以保持最小燃料的最佳轨迹。再入大气层着陆有三种不同的终端情况，即未指定的下射程着陆、指定的下射程着陆和返回发射场着陆。

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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Recovery of Spent Stage of Reusable Launch Vehicle on a Droneship

Reusable Launch Vehicle (RLV) is more appealing to current space exploration institutes than conventional launch vehicles. RLVs can be utilised for numerous launches, which lowers launch costs and increases participation in space research initiatives. The reentry flight is regarded as the most important stage of RLV operation. In this study, GEKKO numerical optimization is used to find a reentry landing trajectory for a reusable launch vehicle that uses the least amount of fuel. Here, powered descent is the preferred option, where the reentry trajectory is optimised by controlling the thrust level. The bangbang control technique is used in thrust control. The three phases of the ideal trajectory are the boostback burn phase, the coasting or freefall phase, and the landing phase. The thrust direction and throttle level during these three phases are already predetermined to maintain the minimum fuel optimal trajectory. The reentry landing is executed for three different terminal cases that is unspecified downrange landing, specified downrange landing and return to launch site landing.

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2022 International Conference on Computing, Communication, and Intelligent Systems (ICCCIS)

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