Modeling and characteristic analysis of arch-thready nonlinear magnetic coupled piezoelectric energy harvester

被引：0

作者：

Chen X. ^{[1
,3
]}

Zhang X. ^{[1
,2
]}

Zuo M. ^{[1
]}

Fan H. ^{[1
,2
]}

Wang L. ^{[1
]}

机构：

[1] College of Mechanical Engineering, Xi'an University of Science and Technology, Xi'an

[2] Shaanxi Provincial Key Lab of Mine Electromechanical Equipment Intelligent Monitoring, Xi'an

[3] Engineering College, Zunyi Normal College, Zunyi

来源：

Zhendong yu Chongji/Journal of Vibration and Shock | 2021年 / 40卷 / 09期

关键词：

Arc-thready beam; Characteristic; Modeling; Nonlinear; Piezoelectric;

D O I：

10.13465/j.cnki.jvs.2021.09.015

中图分类号：

学科分类号：

摘要：

In order to analyze vibration characteristics of an arc-thready nonlinear magnetic coupled piezoelectric energy harvester, the magnetic force model was established by using the magnetizing current method, the energy harvester's nonlinear recovering force model was obtained using the test data fitting method, and the system's dynamic equations were established using the generalized Hamilton variation principle. The harmonic balance method was used to solve the system's dynamic equations, and reveal effects of excitation conditions and magnetic distance on the harvester's vibration characteristics. The correctness of the theoretical analysis was verified with tests. The results showed that the large-amplitude response bandwidth and response amplitude of the energy harvester increase with increase in excitation intensity; decrease in magnetic distance can increase large-amplitude response bandwidth, and decrease response amplitude; compared with the energy harvester with a straight beam structure, the harvester with arch-thready structure can increase its output voltage and improve its energy-capturing performance; the study provides a theoretical guidance for designing arch-thready piezoelectric energy harvester, and a new idea for improving its performance. © 2021, Editorial Office of Journal of Vibration and Shock. All right reserved.

引用

页码：110 / 119

页数：9

共 16 条

[1] ERTURK A, INMAN D., Piezolectric energy harvesting, (2015)
[2] XU Zhenlong, SHAN Xiaobiao, XIE Tao, A review of broadband piezoelectric vibration energy harvester, Journal of Vibration and Shock, 37, 8, pp. 190-199, (2018)
[3] ERTURK A, RENNO J M, INMAN D J., Modeling of piezoelectric energy harvesting from an L-shaped beam-mass structure with an application to UAV's[in special issue on Energy Harvesting], Journal of Intelligent Material Systems & Structures, 20, 5, pp. 529-544, (2009)
[4] YANG Z, WANG Y Q, ZUO L, Et al., Introducing arc-shaped piezoelectric elements into energy harvesters, Energy Conversion and Management, 148, pp. 260-266, (2017)
[5] CAO D X, YAN H G, HU W., Modeling and power performance improvement of a piezoelectric energy harvester for low-frequency vibration environments, Acta Mechanica Sinica, 35, 4, pp. 894-911, (2019)
[6] WANG B, LUO X, LIU Y, Et al., Thickness-variable composite beams for vibration energy harvesting, Composite Structures, 224, (2020)
[7] ERTURK A, INMAN D., Broadband piezoelectric power generation on high-energy orbits of the bistable Duffing oscillator with electromechanical coupling, Journal of Sound & Vibration, 330, 10, pp. 2339-2353, (2011)
[8] ZHOU S, CAO J, ERTURK A, Et al., Enhanced broadband piezoelectric energy harvesting using rotatable magnets, Applied Physics Letters, 102, 17, (2013)
[9] ZHANG Xuhui, LAI Zhengpeng, WU Zhonghua, Et al., Theoretical modeling and experimental study of a new bistable piezoelectric vibration engergy harvesting system, Journal of Vibration Engineering, 32, 1, pp. 91-100, (2019)
[10] ZHAO S, ERTURK A., On the stochastic excitation of monostable and bistable electroelastic power generators: relative advantages and tradeoffs in a physical system, Applied Physics Letters, 102, (2013)

← 1 2 →