Experimental and theoretical analysis of a hybrid vibration energy harvester with integrated piezoelectric and electromagnetic interaction

Harvesting vibration energy has attracted the attention of researchers in recent decades as a promising approach for powering wireless sensor networks. The hybridization of piezoelectricity and electromagnetism has proven helpful in the improvement of vibration energy harvesting. In this study, we e...

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Veröffentlicht in:	Journal of Zhejiang University. A. Science 2023-11, Vol.24 (11), p.991-1002
Hauptverfasser:	Huang, Shifan, Luo, Weihao, Zhu, Zongming, Xu, Zhenlong, Wang, Ban, Zhou, Maoying, Qin, Huawei
Format:	Artikel
Sprache:	eng
Schlagworte:	Civil Engineering Classical and Continuum Physics Electromagnetic interactions Electromagnetism Energy Energy harvesting Engineering Hybridization Industrial Chemistry/Chemical Engineering Mechanical Engineering Numerical prediction Piezoelectricity Research Article Theoretical analysis Topology Vibration Vibration analysis Wireless sensor networks
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container_end_page	1002
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container_title	Journal of Zhejiang University. A. Science
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creator	Huang, Shifan Luo, Weihao Zhu, Zongming Xu, Zhenlong Wang, Ban Zhou, Maoying Qin, Huawei
description	Harvesting vibration energy has attracted the attention of researchers in recent decades as a promising approach for powering wireless sensor networks. The hybridization of piezoelectricity and electromagnetism has proven helpful in the improvement of vibration energy harvesting. In this study, we explore the integration of piezoelectric and electromagnetic parts in one vibration energy harvesting device. Lumped-parameter models of the system are derived considering the different connection topologies of the piezoelectric and electromagnetic parts. Numerical predictions from these models are compared with experimental results to throw light on the nonlinearities in the system. Modifications of the system are also explored to provide insights into opportunities to improve its performance and that of future vibration energy harvesters.
doi_str_mv	10.1631/jzus.A2200551
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subjects	Civil Engineering Classical and Continuum Physics Electromagnetic interactions Electromagnetism Energy Energy harvesting Engineering Hybridization Industrial Chemistry/Chemical Engineering Mechanical Engineering Numerical prediction Piezoelectricity Research Article Theoretical analysis Topology Vibration Vibration analysis Wireless sensor networks
title	Experimental and theoretical analysis of a hybrid vibration energy harvester with integrated piezoelectric and electromagnetic interaction
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