Nonlinear electromagnetic vibration energy harvester comprising dual helical-plane springs and multiple Halbach arrays for low-frequency and small-amplitude vibrations
Nonlinear electromagnetic vibration energy harvester comprising dual helical-plane springs and multiple Halbach arrays for low-frequency and small-amplitude vibrations
Electromagnetic vibration energy harvesters are widely investigated for self-powered wireless sensors and nonlinearity has been introduced for low-frequency and broadband vibration energy harvesting. But how to realize the nonlinearity with small amplitudes, high reliability and few complexities is still a challenge in real-world applications. In this paper, a novel electromagnetic vibration energy harvester comprising dual helical-plane springs and multiple Halbach arrays is proposed. The structural characteristics are analyzed, which indicate that the helical-plane springs can have nonlinear stiffness under small-amplitude vibrations and multiple Halbach arrays can greatly enhance the magnetic field. Then a magnet-electro-mechanical model is built by combining mechanical dynamics &electrodynamics, which is numerically solved by using the Runge-Kutta algorithm. Finally, the feasibility of the nonlinear electromagnetic vibration energy harvester is validated both numerically and experimentally. The results show that it has a nonlinear stiffness, a resonance bandwidth of 3 Hz and a peak power of 14 mW when the excitation amplitude is only 0.5g. In particular, the resonance frequency range depends on the excitation amplitude. Furthermore, the prototype of a self-powered wireless temperature sensor is constructed and testified. The results of this study indicate that the proposed structure can be utilized and extended to build compact, reliable and nonlinear electromagnetic vibration energy harvesters for low-frequency, small-amplitude and broadband vibrations in real-world applications.
Self-powered wireless sensors, Electromagnetic vibration energy harvester, Nonlinearity, Helical-plane springs, Multiple Halbach arrays, Self-powered wireless sensors, Multiple Halbach arrays, Helical-plane springs, Nonlinearity, Electromagnetic vibration energy harvester
1363-1375
Chen, Zhongsheng
2ccfe055-fae6-4976-93bf-c099a85bcf47
Chen, Zhiwen
fbd83328-2645-427d-a039-bc2ade21cc0b
Wei, Yongxiang
469e67c6-d1d1-4960-9934-f56f9d0340cd
Xiong, Yeping
51be8714-186e-4d2f-8e03-f44c428a4a49
June 2024
Chen, Zhongsheng
2ccfe055-fae6-4976-93bf-c099a85bcf47
Chen, Zhiwen
fbd83328-2645-427d-a039-bc2ade21cc0b
Wei, Yongxiang
469e67c6-d1d1-4960-9934-f56f9d0340cd
Xiong, Yeping
51be8714-186e-4d2f-8e03-f44c428a4a49
Chen, Zhongsheng, Chen, Zhiwen, Wei, Yongxiang and Xiong, Yeping
(2024)
Nonlinear electromagnetic vibration energy harvester comprising dual helical-plane springs and multiple Halbach arrays for low-frequency and small-amplitude vibrations.
Energy Reports, 11, .
(doi:10.1016/j.egyr.2024.01.007).
Abstract
Electromagnetic vibration energy harvesters are widely investigated for self-powered wireless sensors and nonlinearity has been introduced for low-frequency and broadband vibration energy harvesting. But how to realize the nonlinearity with small amplitudes, high reliability and few complexities is still a challenge in real-world applications. In this paper, a novel electromagnetic vibration energy harvester comprising dual helical-plane springs and multiple Halbach arrays is proposed. The structural characteristics are analyzed, which indicate that the helical-plane springs can have nonlinear stiffness under small-amplitude vibrations and multiple Halbach arrays can greatly enhance the magnetic field. Then a magnet-electro-mechanical model is built by combining mechanical dynamics &electrodynamics, which is numerically solved by using the Runge-Kutta algorithm. Finally, the feasibility of the nonlinear electromagnetic vibration energy harvester is validated both numerically and experimentally. The results show that it has a nonlinear stiffness, a resonance bandwidth of 3 Hz and a peak power of 14 mW when the excitation amplitude is only 0.5g. In particular, the resonance frequency range depends on the excitation amplitude. Furthermore, the prototype of a self-powered wireless temperature sensor is constructed and testified. The results of this study indicate that the proposed structure can be utilized and extended to build compact, reliable and nonlinear electromagnetic vibration energy harvesters for low-frequency, small-amplitude and broadband vibrations in real-world applications.
Text
2024 Energy Reports_accepted version_Chen & Xiong.
- Accepted Manuscript
Text
2024 Energy Reports_Chen & Xiong.
- Version of Record
More information
Accepted/In Press date: 3 January 2024
e-pub ahead of print date: 13 January 2024
Published date: June 2024
Additional Information:
Publisher Copyright:
© 2024 The Authors
Keywords:
Self-powered wireless sensors, Electromagnetic vibration energy harvester, Nonlinearity, Helical-plane springs, Multiple Halbach arrays, Self-powered wireless sensors, Multiple Halbach arrays, Helical-plane springs, Nonlinearity, Electromagnetic vibration energy harvester
Identifiers
Local EPrints ID: 488278
URI: http://eprints.soton.ac.uk/id/eprint/488278
ISSN: 2352-4847
PURE UUID: 6ee807cd-1562-4817-add8-19b6bdd5a34c
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Date deposited: 19 Mar 2024 17:54
Last modified: 02 May 2024 01:36
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Author:
Zhongsheng Chen
Author:
Zhiwen Chen
Author:
Yongxiang Wei
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