Mars Direct: Combining Near-Term Technologies to Achieve a Two-Launch Manned Mars Mission

Q4 Engineering

Jbis-Journal of the British Interplanetary Society Pub Date : 1990-01-01 DOI:10.2514/6.1990-1896

D. Baker, R. Zubrin

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引用次数: 25

Abstract

This paper introduces a mission architecture called 'Mars Direct' which brings together several technologies and existing hardware into a novel mission strategy to achieve a highly capable and affordable approach to the Mars and Lunar exploratory objective of the Space Exploration Initiative (SEI). Three innovations working in concept cut the initial mass by a factor of three, greatly expand out ability to explore Mars, and eliminate the need to assemble vehicles in Earth orbit. The first innovation, a hybrid Earth/Mars propellant production process works as follows. An Earth Return Vehicle (ERV), tanks loaded with liquid hydrogen, is sent to Mars. After landing, a 100 kWe nuclear reactor is deployed which powers a propellant processor that combines onboard hydrogen with Mars' atmospheric CO2 to produce methane and water. The water is then electrolized to create oxygen and, in the process, liberates the hydrogen for further processing. Additional oxygen is gained directly by decomposition of Mars' CO2 atmosphere. This second innovation, a hybrid crew transport/habitation method, uses the same habitat for transfer to Mars as well as for the 18 month stay on the surface. The crew return via the previously launched ERV in a modest, lightweight return capsule. This reduces mission mass for two reasons. One, it eliminates the unnecessary mass of two large habitats, one in orbit and one on the surface. And two, it eliminates the need for a trans-Earth injection stage. The third innovation is a launch vehicle optimized for Earth escape. The launch vehicle is a Shuttle Derived Vehicle (SDV) consisting of two solid rocket boosters, a modified external tank, four space shuttle main engines and a large cryogenic upper stage mounted atop the external tank. This vehicle can throw 40 tonnes (40,000 kg) onto a trans-Mars trajectory, which is about the same capability as Saturn-5. Using two such launches, a four person mission can be carried out every twenty-six months with minimal impact on shared Shuttle launch facilities at Kennedy Space Center (KSC). The same launch vehicle, habitat, and upper stage of the ERV can also be used to perform Lunar missions. It is concluded that the Mars Direct architecture offers a cost effective approach to accomplishing the Lunar and Mars goals of the Space Exploration Initiative.

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火星直接:结合近期技术实现两次发射载人火星任务

本文介绍了一种名为“Mars Direct”的任务架构，该架构将几种技术和现有硬件结合到一个新的任务策略中，以实现太空探索计划(SEI)的火星和月球探测目标的高能力和可负担的方法。三个概念上的创新将初始质量减少了三倍，极大地扩展了探索火星的能力，并消除了在地球轨道上组装飞行器的需要。第一个创新，混合地球/火星推进剂生产过程如下。装有液态氢的地球返回飞行器(ERV)被送往火星。着陆后，一个100千瓦时的核反应堆被部署，为推进剂处理器提供动力，该处理器将火星上的氢气与大气中的二氧化碳结合，产生甲烷和水。然后，水被电解产生氧气，在这个过程中，氢被释放出来，用于进一步的处理。额外的氧气是通过分解火星的二氧化碳大气直接获得的。第二项创新是混合载人运输/居住方法，使用相同的栖息地转移到火星，并在火星表面停留18个月。乘员返回通过先前发射的ERV在一个适度的，轻量级的返回舱。这减少了任务质量，原因有二。首先，它消除了两个大型栖息地的不必要质量，一个在轨道上，一个在地面上。第二，它消除了跨地球注入阶段的需要。第三项创新是为逃离地球而优化的运载火箭。运载火箭是一种航天飞机衍生运载火箭(SDV)，包括两个固体火箭助推器，一个改进的外部燃料箱，四个航天飞机主发动机和一个安装在外部燃料箱顶部的大型低温上一级。这种运载工具可以将40吨(40000公斤)的重量抛到跨火星轨道上，这与土星5号的能力大致相同。使用两次这样的发射，一个四人的任务可以每26个月执行一次，对肯尼迪航天中心(KSC)共享的航天飞机发射设施的影响最小。同样的运载火箭、栖息地和ERV的上一级也可以用于执行月球任务。结论是，Mars Direct架构为完成太空探索计划的月球和火星目标提供了一种经济有效的方法。

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

Jbis-Journal of the British Interplanetary Society Earth and Planetary Sciences-Space and Planetary Science

CiteScore

0.70

自引率

0.00%

发文量

期刊介绍： The Journal of the British Interplanetary Society (JBIS) is a technical scientific journal, first published in 1934. JBIS is concerned with space science and space technology. The journal is edited and published monthly in the United Kingdom by the British Interplanetary Society. Although the journal maintains high standards of rigorous peer review, the same with other journals in astronautics, it stands out as a journal willing to allow measured speculation on topics deemed to be at the frontiers of our knowledge in science. The boldness of journal in this respect, marks it out as containing often speculative but visionary papers on the subject of astronautics.