Journal of Jilin University(Engineering and Technology Edition) ›› 2023, Vol. 53 ›› Issue (10): 2807-2816.doi: 10.13229/j.cnki.jdxbgxb.20211323

Previous Articles     Next Articles

Low and ultra-wideband performance optimization of spring-connected mass piezoelectric cantilever

Jian-dong JIANG(),Zhen YE,Xin QIAO()   

  1. Key Laboratory of Special Purpose Equipment and Advanced Manufacturing Technology,Ministry of Education,Zhejiang University of Technology,Hangzhou 310014,China
  • Received:2021-12-03 Online:2023-10-01 Published:2023-12-13
  • Contact: Xin QIAO E-mail:jiangjd@zjut.edu.cn;diana27qiao@zjut.edu.cn

RICH HTML

 2   

PDF (PC)

156

Abstract:

Aiming at the problems of low vibration energy collection efficiency and poor practical application effect caused by high natural frequency and narrow frequency band of piezoelectric cantilever beam, the characteristics of energy collection and vibration characteristics of cantilever beam were analyzed by the characteristic frequency equation of Euler-Bernoulli beam, and three parameters affecting the natural frequency of piezoelectric cantilever beam were obtained : effective stiffness, effective mass and free end inertia moment. A spring-connected mass block structure was proposed to optimize the cantilever beam by changing the overall effective stiffness, and the multi-degree-of-freedom spring cantilever beam was obtained by changing the inertia moment of the structure, which reduced the natural frequency of the beam and was verified in the simulation experiment. In the simulation experiment, it was found that the frequency band superposition phenomenon occured? due to the decrease of the two-order resonant frequency spacing, and the possibility of its generation was explained by the two-order frequency band decomposition. The experimental results showed that the output voltage of the spring-connected mass block cantilever beam structure was increased by 30% and the frequency band was widened by 2.5 times compared with the traditional structure. Although the improvement effect was not obvious compared with the mass cantilever beam, the output voltage can be increased by 60% and the frequency band width can be increased by 3.3 times after the introduction of multi-degree of freedom.

Key words: piezoelectric cantilever beam, natural frequency, spring-connected mass, multiple degrees of freedom, frequency band superposition

CLC Number: 

  • TN712

Fig.1

Type of spring-connected mass cantilever beam structure"

Fig.2

Lumped parameter modeling"

Fig.3

Spring cantilever beam structure with multiple degrees of freedom"

Fig.4

Piezoelectric vibrator finite element model"

Table 1

Material parameter setting of piezoelectric vibrator"

材料ρ/(kg·m-3)μE/GPa尺寸A×B×C/ (mm×mm×mm)
PZT-5H75000.317160×30×0.2
铍青铜83000.3513070×30×0.2
ABS12000.39210×80×5
弹簧(1360)80000.5015010×40×1
质量块125000.3513015×15×10
质量块225000.3513015×15×8.5
质量块378000.3513060×30×0.4

Fig.5

Frequency distribution curve of the first 6 modes of piezoelectric vibrator"

Fig.6

Piezoelectric vibrator output voltage-frequency distribution curve"

Fig.7

Energy conversion rate-frequency distribution curve"

Table 2

Design and result of influencing factors test"

序号m/gkNfO1V1O2V2
151.36336.816.275.71.60
253.02337.016.175.01.60
356.75337.815.975.41.58
4101.36327.215.551.70.24
5103.02327.215.451.90.24
6106.75327.49.453.20.22
7151.36322.610.541.70.26
8153.02322.610.741.80.26
9156.75322.610.441.80.26
10201.36319.77.436.00.31
11203.02319.87.436.20.28
12206.75319.87.436.60.28

Fig.8

Frequency distribution curve and output voltage-frequency distribution curve of the first 4 modes of the 1-12th group of piezoelectric vibrators"

Fig.9

Frequency distribution curve of first 6 modes of multi-degree-of-freedom piezoelectric vibrator"

Fig.10

Output voltage-frequency distribution curve of multi-degree-of-freedom piezoelectric vibrator"

Fig.11

2 output voltage-frequency distribution curve ofbackward piezoelectric vibrator"

Fig.12

Comparison of voltage output decomposition inthe first two order resonant frequency bands oflateral cantilever beam"

Fig.13

1 output voltage-frequency distribution curve ofpiezoelectric vibrator"

Fig.14

Energy conversion rate-frequency distribution curve"

Fig.15

Piezoelectric cantilever beam experimentalplatform system"

Fig.16

Physical drawing of a multi-degree-of-freedom spring cantilever extending in various directions"

Fig.17

Comparison curves of experimental results ofvarious cantilever beam structures"

Fig.18

Comparison curve of the experimental results of No.1-3 cantilever beam structure"

Fig.19

Comparative curve diagram of experimental results of No.4-6 cantilever beam structure"

1 钱志鸿,王义君. 面向物联网的无线传感器网络综述[J]. 电子与信息学报,2013,35(1): 215-227.
Qian Zhi-hong, Wang Yi-jun. Internet of things-oriented wireless sensor networks review[J]. Journal of Electronics & Information Technology, 2013, 35(1): 215-227.
2 Mazumdar N, Nag A. Cache-aware mobile data collection schedule for IOT enabled multi-rate data generator wireless sensor network[J]. Sustainable Computing: Informatics and Systems, 2021(31):No. 100583.
3 Worlu C, Jamal A A, Mahiddin N A. Wireless sensor networks, internet of things, and their challenges[J]. International Journal of Innovative Technology and Exploring Engineering, 2019, 8(12): 556-566.
4 Safaei M, Sodano H A, Anton S R. A review of energy harvesting using piezoelectric materials: state-of-the-art a decade later (2008–2018)[J]. Smart Materials and Structures, 2019, 28(11): No.113001.
5 徐振龙,单小彪,谢涛,等. 宽频压电振动俘能器的研究现状综述[J]. 振动与冲击,2018,7(8): 190-199, 205.
Xu Zhen-long, Shan Xiao-biao, Xie Tao, et al. A review of broadband piezoelectric vibration energy harvester[J]. Journal of Viration and Shock, 2018, 37(8): 190-199, 205.
6 Shen D, Park J H, Ajitsaria J, et al. The design, fabrication and evaluation of a MEMS PZT cantilever with an integrated Si proof mass for vibration energy harvesting[J]. Journal of Micromechanics and Microengineering, 2008, 18(5): No.055017.
7 Li W G, He S, Yu S. Improving power density of a cantilever piezoelectric power harvester through a curved L-shaped proof mass[J]. IEEE Transactions on Industrial Electronics, 2009, 57(3): 868-876.
8 Challa V R, Prasad M G, Shi Y, et al. A vibration energy harvesting device with bidirectional resonance frequency tunability[J]. Smart Materials and Structures, 2008, 17(1): No.015035.
9 Liu J Q, Fang H B, Xu Z Y, et al. A MEMS-based piezoelectric power generator array for vibration energy harvesting[J]. Microelectronics Journal, 2008, 39(5): 802-806.
10 Cao D X, Leadenham S, Erturk A. Internal resonance for nonlinear vibration energy harvesting[J]. The European Physical Journal Special Topics, 2015, 224(14): 2867-2880.
11 Chen L Q, Jiang W A, Panyam M, et al. A broadband internally resonant vibratory energy harvester[J]. Journal of Vibration and Acoustics, 2016, 138(6):No.061007.
12 Roundy S, Leland E S, Baker J, et al. Improving power output for vibration-based energy scavengers[J]. IEEE Pervasive Computing, 2005, 4(1): 28-36.
13 Erturk A, Inman D J.压电能量采集(Piezoelectric energy harvesting) [M]. 北京: 国防工业出版社, 2015.
14 蒋建东,张玖利,牛瑞征,等. 耦合弯曲-剪切载荷L型压电振子的低宽频特性[J]. 浙江大学学报:工学版,2021 55(1): 162-168.
Jian-dong Jang, Zhang Jiu-li, Niu Rui-zheng, et al. Low broadband characteristics of L-shaped piezoelectric cantilever beam with bending shear load[J]. Journal of Zhejiang University (Engineering Science), 2021, 55(1): 162-168.
15 杨斌强,徐文潭,陆国丽,等. 宽频压电振动能量采集器的分布参数模型与实验[J]. 中国机械工程,2017,28(2): 127-134.
Yang Bin-qiang, Xu Wen-tan, Lu Guo-li, et al. Distributed parameter model and experiments of a broadband piezoelectric vibration energy harvester[J]. Chinese Journal of Mechanical Engineering, 2017, 28(2): 127-134.
16 展永政,王光庆. 压电振动能量采集器的性能分析与功率优化[J]. 浙江大学学报:工学版,2014,48(7): 1248-1253.
Zhan Yong-zheng, Wang Guang-qing. Performance analysis and power optimization of piezoelectric vibration engineering harvester[J]. Journal of Zhejiang University (Engineering Science), 2014, 48(7): 1248-1253.
17 杨斌强,徐文潭,王学保,等. 带弹性放大器的双稳态压电振动能量采集器[J]. 传感技术学报,2017(30): 684-691.
Yang Bin-qiang, Xu Wen-tan, Wang Xue-bao, et al. A bistable piezoelectric vibration energy harvester with an elastic magnifier[J]. Chinese Journal of Sensors and Actuators, 2017(30): 684-691.
18 Aldraihem O J, Wetherhold R C, Singh T. Distributed control of laminated beams: Timoshenko theory vs Euler-Bernoulli theory[J]. Journal of Intelligent Material Systems and Structures, 1997, 8(2): 149-157.
19 Liu H, Xu T, Huang Z, et al. Parametric design for a piezoelectric cantilever carrying oscillators to harvest multi-frequency vibration energy[J]. International Journal of Applied Electromagnetics and Mechanics, 2013, 41(4): 389-405.
20 Tang L H, Yang Y W. A nonlinear piezoelectric energy harvester with magnetic oscillator[J]. Applied Physics Letters,2012, 101(9): 094102.
21 夏呈. 修正铁摩辛柯梁受迫振动响应分析及其应用[D]. 南京: 东南大学机械工程学院,2017.
Xia Cheng. The analysis of forced vibration response of modified Timoshenko beam theory and its application [D]. Nanjing: College of Mechanical Engineering, Southeast University,2017.
[1] Ming-wei HU,Hong-guang WANG,Xin-an PAN. Global structural optimization design of collaborative robots using orthogonal design [J]. Journal of Jilin University(Engineering and Technology Edition), 2021, 51(1): 370-378.
[2] Chun-ling ZHONG,Dong LIANG,Yun-long ZHANG,Jing WANG. Calculation of natural vibration frequency of simply supported beam strengthened by external prestressing [J]. Journal of Jilin University(Engineering and Technology Edition), 2019, 49(6): 1884-1890.
[3] WANG Xiu-gang, SU Jian, CAO Xiao-ning, LIN Hui-ying, ZHANG Yi-rui, YANG Xiao-min. Experiment on natural vibration characteristics of suspension based on simulation of semi-vehicle [J]. 吉林大学学报(工学版), 2014, 44(6): 1583-1590.
[4] ZHANG Tian-xiao, LIU Xin-hui, ZHANG Nong. Vibration analysis of hydraulic relief valve [J]. 吉林大学学报(工学版), 2014, 44(01): 91-94.
[5] LIU Han-bing, WANG Long-lin, TAN Guo-jin, CHENG Yong-chun, WU Chang-xia. Effect of prestress force on natural frequency of external prestressed simply supported steel beam [J]. 吉林大学学报(工学版), 2013, 43(01): 81-85.
[6] HAN Zhi-Wu, LV You, DONG Li-Chun, ZHANG Jun-Qiu, NIU Shi-Chao, MA Rong-Feng, REN Lou-Quan. Modal analysis of gear with bionic surface morphology [J]. 吉林大学学报(工学版), 2010, 40(06): 1604-1608.
[7] JIN Wen-ming, LI Hua-jun, KOU Shu-qing, YANG Sheng-hua. Modal analysis of frame of cantilever NC assembling machine for assembled camshaft [J]. 吉林大学学报(工学版), 2009, 39(增刊2): 319-0323.
[8] SU Tie-jian, GUAN Ai-hua, MAI Li. Dynamic Analysis of Elastic Plate with Dispersing Pressure [J]. 吉林大学学报(工学版), 2000, (3): 72-74.
[9] LIU Han-bing, GONG Guo-qing, WEI Yuan. Improved r-and h-adaptive Finite Element Method Based on Perturbation and Element Energy Ratio [J]. 吉林大学学报(工学版), 2000, (3): 56-60.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
Copyright © Journal of Jilin University(Engineering and Technology Edition), All Rights Reserved.
Tel: +86-431-85095297 Fax: +86-431-85094074 E-mail: xbgxb@jlu.edu.cn
Powered by Beijing Magtech Co. Ltd