期刊
APPLIED MATHEMATICS AND MECHANICS-ENGLISH EDITION
卷 43, 期 7, 页码 959-978出版社
SHANGHAI UNIV
DOI: 10.1007/s10483-022-2867-7
关键词
vibration-driven energy harvesting; flow-induced vibration (FIV); piezoelectric approach; nonlinear design; O326
资金
- National Natural Science Foundation of China [11972051, 11672008]
- Opening Project Foundation of the State Key Laboratory of Mechanical Behavior and System Safety of Traffic Engineering Structures of China [KF-2020-11]
- Seed Foundation of Beijing University of Technology for International Research Cooperation of China [2021A08]
- Innovation and Technology Commission of the Hong Kong Special Administrative Region [K-BBY1]
This article provides a comprehensive review of the flow-induced vibration (FIV) effect for energy harvesting, including different classifications of FIV and the development of related energy harvesting techniques. It also discusses the application of hybrid techniques and nonlinear designs to improve the harvesting performance, as well as briefly mentioning the advanced FIV-based energy harvesting studies for fluid engineering applications. Finally, conclusions and future outlook are summarized.
Energy harvesting induced from flowing fluids (e.g., air and water flows) is a well-known process, which can be regarded as a sustainable and renewable energy source. In addition to traditional high-efficiency devices (e.g., turbines and watermills), the micro-power extracting technologies based on the flow-induced vibration (FIV) effect have sparked great concerns by virtue of their prospective applications as a self-power source for the microelectronic devices in recent years. This article aims to conduct a comprehensive review for the FIV working principle and their potential applications for energy harvesting. First, various classifications of the FIV effect for energy harvesting are briefly introduced, such as vortex-induced vibration (VIV), galloping, flutter, and wake-induced vibration (WIV). Next, the development of FIV energy harvesting techniques is reviewed to discuss the research works in the past three years. The application of hybrid FIV energy harvesting techniques that can enhance the harvesting performance is also presented. Furthermore, the nonlinear designs of FIV-based energy harvesters are reported in this study, e.g., multi-stability and limit-cycle oscillation (LCO) phenomena. Moreover, advanced FIV-based energy harvesting studies for fluid engineering applications are briefly mentioned. Finally, conclusions and future outlook are summarized.
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