Multistable vibration energy harvesters: Principle, progress, and perspectives

•The progress of multistable vibration energy harvesters (MEH) is reviewed.•Governing models and approximate analytic methods are introduced.•Design, experiment, influence mechanism and optimization are illustrated.•MEHs in rotational motion, wind energy harvesting, etc, are stated.•Critical challen...

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Vydané v:Journal of sound and vibration Ročník 528; s. 116886
Hlavní autori: Zhou, Shengxi, Lallart, Mickaël, Erturk, Alper
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: Amsterdam Elsevier Ltd 23.06.2022
Elsevier Science Ltd
Elsevier
Predmet:
Alternative energy
Bandwidths
Circuit design
Dynamic characteristics
Electric power
Electromagnetics
Electronic devices
Energy conversion
Energy harvesting
Engineering Sciences
Frequency variation
Morphing
Multistable
Nonlinear dynamics
Piezoelectricity
Principle
Robustness (mathematics)
State-of-the-art reviews
Vibration
Vibration energy harvesting
Vibration isolators
Nonlinear dynamics
Multistable
Principle
Vibration energy harvesting
ISSN:0022-460X, 1095-8568
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Shrnutí:•The progress of multistable vibration energy harvesters (MEH) is reviewed.•Governing models and approximate analytic methods are introduced.•Design, experiment, influence mechanism and optimization are illustrated.•MEHs in rotational motion, wind energy harvesting, etc, are stated.•Critical challenges, perspectives for future research directions about MEHs are presented. Vibration energy harvesting is a process by which ambient mechanical energy from environment or host structures is converted into usable energy (usually, but not always, electrical energy). This technology is considered to be a relatively new method for supplying sustainable energy to low-powered sensor networks and electronic devices. Various vibration energy harvesters utilizing piezoelectric, electromagnetic, electrostatic, and triboelectric energy conversion mechanisms were designed and tested to achieve this goal. Meanwhile, one key challenge of such approaches results from their response to the input excitation characteristics, especially in terms of frequency variation. To address that challenge, multistable characteristics commonly exist in mathematical models and physical devices, which can be used for designing vibration isolators, compliant mechanisms, morphing structures, circuits, filters, etc. Currently, multistable vibration energy harvesters have received increasing attention because of their rich nonlinear dynamic characteristics which show benefit for improving efficient vibration energy harvesting bandwidth, i.e. frequency-wise robustness. This paper aims to provide a comprehensive review of the state-of-the-art progress of multistable vibration energy harvesters.
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ISSN:0022-460X
1095-8568
DOI:10.1016/j.jsv.2022.116886