首颗太阳能帆船驱动星际立方体卫星的任务构想与研制

Q4 Engineering

Jbis-Journal of the British Interplanetary Society Pub Date : 2023-05-15 DOI:10.59332/jbis-076-03-0078

Piotr Fil, Debdut Sengupta, Ivan Riesco, B. Tortosa, Bartosz Krawczyk, G. Ribeiro, Krzysztof Kwiatkowski, M.Ye. Boguslavskiy, Chang Liu, Junglin Sung

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引用次数: 2

摘要

Svarog项目是一个由学生主导的项目，旨在利用太阳帆到达日球层顶。轨道模型已经证明了这一任务的可行性，因为搭载火星任务的卫星的帆的质量面积比约为每平方米9克。太阳航行增加了外太阳系任务的灵活性，因为不再需要独特的行星排列，这对重力辅助至关重要。长期任务需要更好地了解薄膜的行为，因为帆材料在太阳辐射压力下的屈曲可能导致航天器不可预测地翻滚。因此，将膜偏转的降阶模型与轨道模拟相结合，从而确定了任务逃离太阳系的运行状态。此外，设计了真空室实验来研究太阳辐射压力和加热对风帆瞬态和稳态行为的影响。该系统被设计为一个6U立方体卫星，是第一个利用小型平台进行深空任务的任务之一。如果第一次任务成功，斯瓦罗格系统也可以作为新技术和深空研究机会的低成本测试平台。关键词:卫星，深空，立方体卫星，太阳帆，轨道力学，结构设计

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Mission Concept and Development of the First Interstellar CubeSat Powered by Solar Sailing Technology

Project Svarog is a student-led initiative aiming to reach the heliopause using a solar sail. Orbital models have proven the feasibility of the mission given the mass-to-area ratio of about 9 grams per square meter of the sail for a satellite launched on a piggyback mission to Mars. Solar sailing increases the flexibility of missions to the outer Solar System, as unique planet alignment, which was crucial for gravity assists is no longer required. Long-term missions require a better understanding of thin membrane behaviour since buckling of sail material under solar radiation pressure might cause the spacecraft to tumble unpredictably. Reduced order model of membrane deflection is thus coupled with orbital simulation, resulting in the determination of the operation regime, for which the mission escapes the Solar System. Additionally, vacuum chamber experiments designed to investigate the effects of solar radiation pressure and heating on the transient and steady-state behaviour of the sail have been devised. The system is designed to be built as a 6U CubeSat, being one of the first missions to utilise small-scale platforms for deep space missions. Granted that the first mission is successful, the Svarog system could also serve as a low-cost testbed for new technologies and research opportunities in deep space. Keywords: Satellite, Deep Space, CubeSat, Solar Sail, Orbital Mechanics, Structural Design

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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.