Origami-Inspired Deployable Space Habitats

Q4 Engineering

Jbis-Journal of the British Interplanetary Society Pub Date : 2023-04-07 DOI:10.59332/jbis-076-01-0002

Joe Defillion, M. Schenk

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引用次数: 0

Abstract

Origami is increasingly used as a source of inspiration in a wide variety of disciplines. In this project, we explore cylindrical origami structures, referred to as “origami bellows”, as novel geometries for orbital space habitats. The dimensions of space habitats are limited by the tight mass and volume constraints imposed by launcher payload fairings. Future deployable habitats based on foldable origami bellows have the potential to achieve large volumes when deployed, while being capable of compacting to smaller stowed configurations for launch. To assess the feasibility of such habitat designs, the deployment performance of a selection of bellows was investigated. Bellows formed from Kresling and Miura-ori patterns were considered; both expand axially, but Miura-ori patterns experience an additional radial expansion. Our scope was also limited to patterns which are stable in both the stowed and deployed configurations. Habitats were judged on their internal and effective volume expansions; the latter being adjusted to account for the practicalities of operating within a complex habitat geometry. We find that significant internal and effective volume expansions are achievable, particularly for Miura-ori geometries. Nonetheless, we make the argument for Kresling patterns as a more practical option due to their simpler geometries, despite smaller volume expansions. We find our Kresling geometries to have effective volumes between 2.5 - 3.6 times greater than a conventional habitat launched in a fairing of equal volume. Our work shows that origami-based designs do indeed have potential to greatly outperform current space habitat designs. Keywords: Origami Bellows, Space Habitats, Deployable Structures

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折纸启发的可展开空间栖息地

折纸越来越多地被用作各种学科的灵感来源。在这个项目中，我们探索圆柱形折纸结构，被称为“折纸风箱”，作为轨道空间栖息地的新几何形状。空间栖息地的尺寸受到发射器有效载荷整流罩施加的严格质量和体积约束的限制。基于折纸波纹管的未来可部署栖息地在部署时具有实现大容量的潜力，同时能够压缩成更小的装载配置用于发射。为了评估这种栖息地设计的可行性，研究了一系列波纹管的展开性能。考虑了由Kresling和Miura-ori图案形成的波纹;两者都是轴向扩张，但三浦-奥里模式经历了额外的径向扩张。我们的范围也仅限于在装载和部署配置中都稳定的模式。根据其内部和有效体积扩张来判断生境;后者正在调整，以考虑到在复杂的生境几何结构内作业的实际情况。我们发现显著的内部和有效的体积扩张是可以实现的，特别是对于三浦里几何形状。尽管如此，我们认为Kresling模式是一个更实用的选择，因为它们的几何形状更简单，尽管体积扩展较小。我们发现我们的Kresling几何形状的有效体积比在同等体积的整流罩中发射的传统栖息地大2.5 - 3.6倍。我们的工作表明，折纸设计确实有潜力大大优于目前的太空栖息地设计。关键词:折纸波纹管，空间栖息地，可展开结构

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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.