Challenges in the Technology Development for Additive Manufacturing in Space

Andrea Zocca , Janka Wilbig , Anja Waske , Jens Günster , Martinus Putra Widjaja , Christian Neumann , Mélanie Clozel , Andreas Meyer , Jifeng Ding , Zuoxin Zhou , Xiaoyong Tian
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引用次数: 22

Abstract

Instead of foreseeing and preparing for all possible scenarios of machine failures, accidents, and other challenges arising in space missions, it appears logical to take advantage of the flexibility of additive manufacturing for “in-space manufacturing” (ISM). Manned missions into space rely on complicated equipment, and their safe operation is a great challenge. Bearing in mind the absolute distance for manned missions to the Moon and Mars, the supply of spare parts for the repair and replacement of lost equipment via shipment from Earth would require too much time. With the high flexibility in design and the ability to manufacture ready-to-use components directly from a computer-aided model, additive manufacturing technologies appear to be extremely attractive in this context. Moreover, appropriate technologies are required for the manufacture of building habitats for extended stays of astronauts on the Moon and Mars, as well as material/feedstock. The capacities for sending equipment and material into space are not only very limited and costly, but also raise concerns regarding environmental issues on Earth. Accordingly, not all materials can be sent from Earth, and strategies for the use of in-situ resources, i.e., in-situ resource utilization (ISRU), are being envisioned. For the manufacturing of both complex parts and equipment, as well as for large infrastructure, appropriate technologies for material processing in space need to be developed.

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空间增材制造技术发展的挑战
与其预见和准备所有可能出现的机器故障、事故和太空任务中出现的其他挑战,不如利用增材制造的灵活性进行“太空制造”(ISM)。载人航天任务依赖于复杂的设备,其安全运行是一个巨大的挑战。考虑到前往月球和火星的载人飞行任务的绝对距离,从地球运输维修和更换丢失的设备所需的备件将需要太多的时间。由于设计的高度灵活性和直接从计算机辅助模型中制造即用型部件的能力,增材制造技术在这方面似乎极具吸引力。此外,还需要适当的技术来制造供宇航员在月球和火星上长期停留的建筑生境以及材料/原料。将设备和材料送入太空的能力不仅非常有限和昂贵,而且还引起人们对地球环境问题的关切。因此,并非所有材料都能从地球送出,目前正在设想利用就地资源的战略,即就地资源利用战略。为了制造复杂的零件和设备以及大型基础设施,需要发展适当的空间材料加工技术。
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