In Situ Propellant Alternatives for a Lunar Ascent/Descent Vehicle

IF 1.3 4区工程技术 Q2 ENGINEERING, AEROSPACE

Journal of Spacecraft and Rockets Pub Date : 2023-05-08 DOI:10.2514/1.a35507

Daria Nikitaeva, L. Dale Thomas

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Abstract

Recently, NASA has pushed for returning humans to the moon sustainably with in situ resource utilization as the central focus. The moon has an abundance of water that is proposed to be electrolyzed into hydrogen and oxygen to be used as propellant. Other volatiles such as ammonia, carbon dioxide, and methane are also present. A mission architecture for a lunar ascent/descent vehicle (LADV) from the Polytechnic University of Turin and nuclear thermal propulsion (NTP) engine models from the University of Alabama in Huntsville were used to compare in-situ-derived propellants for a LADV. This study considered a LADV originating from the lunar surface, delivering a payload in the lunar distant retrograde orbit, and returning to the lunar surface for retanking. This research analyzed the impacts on this mission of using hydrogen NTP, water/ammonia NTP, liquid-oxygen augmented nuclear thermal rocket, and Aeon 1 methane–oxygen engines using the selected architecture and tools. The results were compared to the reference hydrogen–oxygen RL10 engine. The propulsion system comparison analysis showed that combustion engines will offer better overall performance than NTP-based engines due to a 50% decrease in propellant volume, a 20% decrease in dry mass, and a lower propellant mass than the water and ammonia NTP systems. Both the hydrogen–oxygen and methane–oxygen propulsion systems will have similar propellant masses when compared to other systems. This is due to the order of magnitude higher mass of the NTP engines, with the highest mass contribution coming from the reactor. However, both water and ammonia alternative propellant NTP engines can still be viable candidates for the usage of these minimally processed propellants to satisfy this mission.

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月球上升/下降飞行器的原位推进剂替代方案

最近，美国国家航空航天局以原位资源利用为中心，推动人类可持续重返月球。月球上有大量的水，这些水被提议电解成氢气和氧气，用作推进剂。其他挥发物如氨、二氧化碳和甲烷也存在。都灵理工大学的月球上升/下降飞行器（LADV）的任务架构和阿拉巴马大学亨茨维尔分校的核热推进（NTP）发动机模型用于比较LADV的原位衍生推进剂。这项研究考虑了一种源自月球表面的LADV，它在月球遥远的逆行轨道上运载有效载荷，并返回月球表面进行重新定位。本研究分析了使用选定的架构和工具使用氢NTP、水/氨NTP、液氧增强核热火箭和Aeon 1甲烷-氧气发动机对此次任务的影响。将结果与参考氢-氧RL10发动机进行了比较。推进系统比较分析表明，由于推进剂体积减少了50%，干质量减少了20%，推进剂质量低于水和氨NTP系统，因此内燃机将比基于NTP的发动机提供更好的整体性能。与其他系统相比，氢氧和甲烷-氧气推进系统的推进剂质量相似。这是由于NTP发动机的质量更高，其中最高的质量贡献来自反应堆。然而，水和氨替代推进剂NTP发动机仍然是使用这些最低加工推进剂来满足这一任务的可行候选者。

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

Journal of Spacecraft and Rockets 工程技术-工程：宇航

CiteScore

3.60

自引率

18.80%

发文量

185

审稿时长

4.5 months

期刊介绍： This Journal, that started it all back in 1963, is devoted to the advancement of the science and technology of astronautics and aeronautics through the dissemination of original archival research papers disclosing new theoretical developments and/or experimental result. The topics include aeroacoustics, aerodynamics, combustion, fundamentals of propulsion, fluid mechanics and reacting flows, fundamental aspects of the aerospace environment, hydrodynamics, lasers and associated phenomena, plasmas, research instrumentation and facilities, structural mechanics and materials, optimization, and thermomechanics and thermochemistry. Papers also are sought which review in an intensive manner the results of recent research developments on any of the topics listed above.