| Citation: | LI M S,YUE S,DU Z H,et al. Deployment dynamics and multi-parameter performances analysis of spatial rectangular tether-net[J]. Journal of Beijing University of Aeronautics and Astronautics,2024,50(3):994-1004 (in Chinese) doi: 10.13700/j.bh.1001-5965.2022.0342
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A spatial tether-net system is a flexible capture system for space debris. A rectangular tether-net is proposed to capture a spatial target with solar wings. The dynamic model of rectangular tether-net during the deployment process is established to analyze the deployment characteristic. The accuracy of the simulation model is verified by comparing it with the on-ground experimental results. The dimensions of the towing tether distribution circle, the launching angle of the towing block, and the deployment properties of the tether-net under various towing modes were compared by each evaluation index, which was established for the rectangular tether-net. The results show that the results of the simulation are consistent with the experimental, so the simulation model is reliable. At eight-point towing mode, ten-point towing mode and twelve-point towing mode, the ten-point towing mode can achieve the best deployment effect. When the diameter of the towing tether distribution circle is larger, the maximum deployment area and shape preserving distance of the tether-net decreases, but the deployment distance of the tether-net increases. The maximum deployment area of the rectangular tether-net and the shape-preserving distance gradually grow with an increase in the towing block's launch angle, while the deployment distance gradually decreases.
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