A Novel Design and Optimization Method for an Electrodynamic Tether Deployment Mechanism

Yi Yang; Keying Yang; Jingrui Zhang; Han Cai; Chunyang Zhou; Lincheng Li

doi:10.34133/space.0147

A Novel Design and Optimization Method for an Electrodynamic Tether Deployment Mechanism

Yi Yang^*, Keying Yang, Jingrui Zhang, Han Cai, Chunyang Zhou, Lincheng Li

^*此作品的通讯作者

宇航学院

科研成果: 期刊稿件 › 文章 › 同行评审

摘要

In the field of active deorbiting technologies, the electrodynamic tether has garnered attention due to its cost-effectiveness, light weight, and low fuel consumption. In this study, to address the low success rate of the deployment mechanisms used in previous in-orbit experiments, a novel deployment mechanism with a size of 2 U and a weight 2.3 kg based on pusher motors is proposed. In order to achieve a smooth tether deployment without rupture and rebound, an optimization method was proposed for springs, and tether within the deployment mechanism. Finally, simulation and ground ejection experiment were conducted with the objective of deploying a 50-m tether. In the experiment, the top plate was ejected with a kinetic energy of 2.3 J, and the tether was successfully unfolded. The experimental results indicate that the device is capable of deploying a tether of at least 50 m, demonstrating the effectiveness of the optimization method.

源语言	英语
文章编号	0147
期刊	Space: Science and Technology (United States)
卷	4
DOI	https://doi.org/10.34133/space.0147
出版状态	已出版 - 1月 2024

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Yang, Y., Yang, K., Zhang, J., Cai, H., Zhou, C., & Li, L. (2024). A Novel Design and Optimization Method for an Electrodynamic Tether Deployment Mechanism. Space: Science and Technology (United States), 4, 文章 0147. https://doi.org/10.34133/space.0147

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title = "A Novel Design and Optimization Method for an Electrodynamic Tether Deployment Mechanism",

abstract = "In the field of active deorbiting technologies, the electrodynamic tether has garnered attention due to its cost-effectiveness, light weight, and low fuel consumption. In this study, to address the low success rate of the deployment mechanisms used in previous in-orbit experiments, a novel deployment mechanism with a size of 2 U and a weight 2.3 kg based on pusher motors is proposed. In order to achieve a smooth tether deployment without rupture and rebound, an optimization method was proposed for springs, and tether within the deployment mechanism. Finally, simulation and ground ejection experiment were conducted with the objective of deploying a 50-m tether. In the experiment, the top plate was ejected with a kinetic energy of 2.3 J, and the tether was successfully unfolded. The experimental results indicate that the device is capable of deploying a tether of at least 50 m, demonstrating the effectiveness of the optimization method.",

author = "Yi Yang and Keying Yang and Jingrui Zhang and Han Cai and Chunyang Zhou and Lincheng Li",

note = "Publisher Copyright: {\textcopyright} 2024 Yi Yang et al.",

year = "2024",

month = jan,

doi = "10.34133/space.0147",

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journal = "Space: Science and Technology (United States)",

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AU - Yang, Yi

AU - Yang, Keying

AU - Zhang, Jingrui

AU - Cai, Han

AU - Zhou, Chunyang

AU - Li, Lincheng

PY - 2024/1

Y1 - 2024/1

N2 - In the field of active deorbiting technologies, the electrodynamic tether has garnered attention due to its cost-effectiveness, light weight, and low fuel consumption. In this study, to address the low success rate of the deployment mechanisms used in previous in-orbit experiments, a novel deployment mechanism with a size of 2 U and a weight 2.3 kg based on pusher motors is proposed. In order to achieve a smooth tether deployment without rupture and rebound, an optimization method was proposed for springs, and tether within the deployment mechanism. Finally, simulation and ground ejection experiment were conducted with the objective of deploying a 50-m tether. In the experiment, the top plate was ejected with a kinetic energy of 2.3 J, and the tether was successfully unfolded. The experimental results indicate that the device is capable of deploying a tether of at least 50 m, demonstrating the effectiveness of the optimization method.

AB - In the field of active deorbiting technologies, the electrodynamic tether has garnered attention due to its cost-effectiveness, light weight, and low fuel consumption. In this study, to address the low success rate of the deployment mechanisms used in previous in-orbit experiments, a novel deployment mechanism with a size of 2 U and a weight 2.3 kg based on pusher motors is proposed. In order to achieve a smooth tether deployment without rupture and rebound, an optimization method was proposed for springs, and tether within the deployment mechanism. Finally, simulation and ground ejection experiment were conducted with the objective of deploying a 50-m tether. In the experiment, the top plate was ejected with a kinetic energy of 2.3 J, and the tether was successfully unfolded. The experimental results indicate that the device is capable of deploying a tether of at least 50 m, demonstrating the effectiveness of the optimization method.

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A Novel Design and Optimization Method for an Electrodynamic Tether Deployment Mechanism

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