A bio-inspired system for simultaneous vibration isolation and energy harvesting in post-capture spacecraft
A bio-inspired system for simultaneous vibration isolation and energy harvesting in post-capture spacecraft
Vibrations and drifting motions of a post-capture spacecraft may lead to its instability and safety risk, which therefore need to be absorbed or isolated. However, it is expected that the vibrational energy is not wasted but harvested to power the wireless sensors. Motivated by this concept and inspired by the movement of a bird, a quadrilateral shape isolation system with an energy harvester is proposed for the simultaneous broadband vibration isolation and energy harvesting of the post-capture spacecraft. The governing equations of the proposed system are derived based on Hamilton's principle. The corresponding dimensionless approximate analytical model is deduced based on the harmonic balance method and validated through the comparison with the numerical Runge–Kutta method. Simulation results demonstrate that compared with its counterpart without the energy harvester, the proposed system can further improve the broadband vibration isolation performance, and achieve the energy harvesting function simultaneously. The operation principle is the energy localization effect, which is demonstrated through the investigation on system dynamics. The guideline for improving the dual performances is proposed according to the parametric studies on the mass ratios, the equivalent stiffness and damping induced by the quadrilateral shape structures, and the mechanical and electrical parameters of the energy harvester.
Broad bandwidth at low frequencies, Energy harvesting, Nonlinear monostability, Quasi-zero stiffness, Vibration isolation
Fang, Shitong
4f9ff7ec-7375-46a8-8782-317c6d575382
Chen, Keyu
7c4bda34-5329-42ed-ba2e-eedbc952a282
Lai, Zhihui
c7420c67-2b8f-4cb1-800a-7e02501111c1
Zhou, Shengxi
993a651d-d77f-45a5-88dd-93f73a100b22
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
Liao, Wei-Hsin
a63327e0-1b02-4647-8c1d-63e7d4b40b10
1 June 2023
Fang, Shitong
4f9ff7ec-7375-46a8-8782-317c6d575382
Chen, Keyu
7c4bda34-5329-42ed-ba2e-eedbc952a282
Lai, Zhihui
c7420c67-2b8f-4cb1-800a-7e02501111c1
Zhou, Shengxi
993a651d-d77f-45a5-88dd-93f73a100b22
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
Liao, Wei-Hsin
a63327e0-1b02-4647-8c1d-63e7d4b40b10
Fang, Shitong, Chen, Keyu, Lai, Zhihui, Zhou, Shengxi, Yurchenko, Daniil and Liao, Wei-Hsin
(2023)
A bio-inspired system for simultaneous vibration isolation and energy harvesting in post-capture spacecraft.
Mechanical Systems and Signal Processing, 199, [110466].
(doi:10.1016/j.ymssp.2023.110466).
Abstract
Vibrations and drifting motions of a post-capture spacecraft may lead to its instability and safety risk, which therefore need to be absorbed or isolated. However, it is expected that the vibrational energy is not wasted but harvested to power the wireless sensors. Motivated by this concept and inspired by the movement of a bird, a quadrilateral shape isolation system with an energy harvester is proposed for the simultaneous broadband vibration isolation and energy harvesting of the post-capture spacecraft. The governing equations of the proposed system are derived based on Hamilton's principle. The corresponding dimensionless approximate analytical model is deduced based on the harmonic balance method and validated through the comparison with the numerical Runge–Kutta method. Simulation results demonstrate that compared with its counterpart without the energy harvester, the proposed system can further improve the broadband vibration isolation performance, and achieve the energy harvesting function simultaneously. The operation principle is the energy localization effect, which is demonstrated through the investigation on system dynamics. The guideline for improving the dual performances is proposed according to the parametric studies on the mass ratios, the equivalent stiffness and damping induced by the quadrilateral shape structures, and the mechanical and electrical parameters of the energy harvester.
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More information
Accepted/In Press date: 20 May 2023
e-pub ahead of print date: 1 June 2023
Published date: 1 June 2023
Additional Information:
Funding Information:
This work was funded by National Natural Science Foundation of China (Grant Nos. 52205114 , 51905349 , U2013603 ), Guangdong Basic and Applied Basic Research Foundation (Grant Nos. 2023A1515012921 , 2022A1515010126 , 2020A1515011509 , 2020A1515111011 ), Excellent Science and Technology Creative Talent Training Program of Shenzhen (Grant No. RCBS20221008093252089 ), Shenzhen Natural Science Fund (the Stable Support Plan Program 20220809181431001 ) and Natural Science Foundation of Shenzhen University ( 000002112410 ).
Keywords:
Broad bandwidth at low frequencies, Energy harvesting, Nonlinear monostability, Quasi-zero stiffness, Vibration isolation
Identifiers
Local EPrints ID: 484898
URI: http://eprints.soton.ac.uk/id/eprint/484898
ISSN: 0888-3270
PURE UUID: 6019d603-d765-4218-8fa5-bb2140b9250c
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Date deposited: 24 Nov 2023 17:31
Last modified: 18 Mar 2024 04:04
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Contributors
Author:
Shitong Fang
Author:
Keyu Chen
Author:
Zhihui Lai
Author:
Shengxi Zhou
Author:
Daniil Yurchenko
Author:
Wei-Hsin Liao
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