A viscoelastic nonlinear energy sink with an electromagnetic energy harvester: Narrow-band random response

doi:10.1088/1674-1056/ad4632

中国物理B ›› 2024, Vol. 33 ›› Issue (7): 70205-070205.doi: 10.1088/1674-1056/ad4632

A viscoelastic nonlinear energy sink with an electromagnetic energy harvester: Narrow-band random response

Zhi-Jing Liao(廖志晶)¹, Ya-Hui Sun(孙亚辉)^1,2,†, and Yang Liu(刘洋)²

1 School of Mathematics and Statistics, Guangdong University of Technology, Guangzhou 510520, China;
2 Exeter Small-Scale Robotics Laboratory, Engineering Department, University of Exeter, North Park Road, Exeter EX4 4QF, UK

收稿日期:2024-03-30 修回日期:2024-04-24 接受日期:2024-05-02 出版日期:2024-06-18 发布日期:2024-06-18
通讯作者: Ya-Hui Sun E-mail:yahsun@163.com
基金资助:
Project supported by the National Natural Science Foundation of China (Grant No. 12002089), the Science and Technology Projects in Guangzhou (Grant No. 2023A04J1323), and UKRI Horizon Europe Guarantee (Grant No. EP/Y016130/1).

A viscoelastic nonlinear energy sink with an electromagnetic energy harvester: Narrow-band random response

Zhi-Jing Liao(廖志晶)¹, Ya-Hui Sun(孙亚辉)^1,2,†, and Yang Liu(刘洋)²

1 School of Mathematics and Statistics, Guangdong University of Technology, Guangzhou 510520, China;
2 Exeter Small-Scale Robotics Laboratory, Engineering Department, University of Exeter, North Park Road, Exeter EX4 4QF, UK

Received:2024-03-30 Revised:2024-04-24 Accepted:2024-05-02 Online:2024-06-18 Published:2024-06-18
Contact: Ya-Hui Sun E-mail:yahsun@163.com
Supported by:
Project supported by the National Natural Science Foundation of China (Grant No. 12002089), the Science and Technology Projects in Guangzhou (Grant No. 2023A04J1323), and UKRI Horizon Europe Guarantee (Grant No. EP/Y016130/1).

摘要/Abstract

摘要： Nonlinear energy sink is a passive energy absorption device that surpasses linear dampers, and has gained significant attention in various fields of vibration suppression. This is owing to its capacity to offer high vibration attenuation and robustness across a wide frequency spectrum. Energy harvester is a device employed to convert kinetic energy into usable electric energy. In this paper, we propose an electromagnetic energy harvester enhanced viscoelastic nonlinear energy sink (VNES) to achieve passive vibration suppression and energy harvesting simultaneously. A critical departure from prior studies is the investigation of the stochastic P-bifurcation of the electromechanically coupled VNES system under narrow-band random excitation. Initially, approximate analytical solutions are derived using a combination of a multiple-scale method and a perturbation approach. The substantial agreement between theoretical analysis solutions and numerical solutions obtained from Monte Carlo simulation underscores the method's high degree of validity. Furthermore, the effects of system parameters on system responses are carefully examined. Additionally, we demonstrate that stochastic P-bifurcation can be induced by system parameters, which is further verified by the steady-state density functions of displacement. Lastly, we analyze the impacts of various parameters on the mean square current and the mean output power, which are crucial for selecting suitable parameters to enhance the energy harvesting performance.

关键词: nonlinear energy sink, fractional-order damping, multiple-scale method, energy harvester

Abstract: Nonlinear energy sink is a passive energy absorption device that surpasses linear dampers, and has gained significant attention in various fields of vibration suppression. This is owing to its capacity to offer high vibration attenuation and robustness across a wide frequency spectrum. Energy harvester is a device employed to convert kinetic energy into usable electric energy. In this paper, we propose an electromagnetic energy harvester enhanced viscoelastic nonlinear energy sink (VNES) to achieve passive vibration suppression and energy harvesting simultaneously. A critical departure from prior studies is the investigation of the stochastic P-bifurcation of the electromechanically coupled VNES system under narrow-band random excitation. Initially, approximate analytical solutions are derived using a combination of a multiple-scale method and a perturbation approach. The substantial agreement between theoretical analysis solutions and numerical solutions obtained from Monte Carlo simulation underscores the method's high degree of validity. Furthermore, the effects of system parameters on system responses are carefully examined. Additionally, we demonstrate that stochastic P-bifurcation can be induced by system parameters, which is further verified by the steady-state density functions of displacement. Lastly, we analyze the impacts of various parameters on the mean square current and the mean output power, which are crucial for selecting suitable parameters to enhance the energy harvesting performance.

Key words: nonlinear energy sink, fractional-order damping, multiple-scale method, energy harvester

中图分类号: (Probability theory, stochastic processes, and statistics)

02.50.-r

05.40.-a (Fluctuation phenomena, random processes, noise, and Brownian motion) 05.40.Ca (Noise)

Zhi-Jing Liao(廖志晶), Ya-Hui Sun(孙亚辉), and Yang Liu(刘洋). A viscoelastic nonlinear energy sink with an electromagnetic energy harvester: Narrow-band random response[J]. 中国物理B, 2024, 33(7): 70205-070205.

Zhi-Jing Liao(廖志晶), Ya-Hui Sun(孙亚辉), and Yang Liu(刘洋). A viscoelastic nonlinear energy sink with an electromagnetic energy harvester: Narrow-band random response[J]. Chin. Phys. B, 2024, 33(7): 70205-070205.

参考文献

[1] Wang L, Zhou Y, Nagarajaiah S and Shi W 2023 Engineering Structures 294 116744
[2] Araz O, Elias S and Kablan F 2023 Soil Dynamics and Earthquake Engineering 166 107765
[3] Gatti G and Svelto C 2023 Journal of Vibration and Control 29 5713
[4] Ali A, Ahmed A, Ali M, Azam A, Wu X, Zhang Z and Yuan Y 2023 Environmental Science and Pollution Research 30 5371
[5] Shen R, Qian X, Zhou J and Lee C 2023 Journal of Vibration and Control 29 5078
[6] Vakakis A F 2001 J. Vib. Acoust. 123 324
[7] Vakakis A F and Gendelman O 2001 J. Appl. Mech. 68 42
[8] Saeed A S, Abdul Nasar R and ALshudeifat M A 2023 Nonlinear Dynam. 111 1
[9] Ding H and Chen L Q 2020 Nonlinear Dynam. 100 3061
[10] Wang Y, Kang H, Cong Y, Guo T and Zhu W 2023 Communications in Nonlinear Science and Numerical Simulation 117 106988
[11] Wang F, Yang Y, Zeng J, Yang Y and Li Y 2023 Archive of Applied Mechanics 93 4241
[12] Zeng Y, Ding H, Ji J, Jing X and Chen L 2023 Mechanical Systems and Signal Processing 202 110694
[13] Sui P, Shen Y and Wang X 2023 Nonlinear Dynam. 111 7157
[14] Li S and Ding H 2023 International Journal of Dynamics and Control 12 1671
[15] Zhang Y, Kong X, Yue C and Guo J 2023 Nonlinear Dynam. 111 15817
[16] Ding H and Shao Y 2022 Applied Mathematics and Mechanics 43 1793
[17] Zhang W, Zhang W and Guo X 2023 Applied Mathematics and Mechanics 44 1721
[18] Zhang Y, Kong X and Yue C 2023 Communications in Nonlinear Science and Numerical Simulation 116 106837
[19] Li S and Ding H 2023 Nonlinear Dynam. 111 18605
[20] Gaidai O, Gu Y, Xing Y, Wang J and Yurchenko D 2023 Theoretical and Applied Mechanics Letters 13 100422
[21] Bergeot B 2023 International Journal of Non-Linear Mechanics 150 104351
[22] Carvalho E M and Kumar S 2023 Acta Biomaterialia 163 146
[23] Yang Y, Huang M, Guo S and Sun Y 2023 Mechanical Systems and Signal Processing 186 109837
[24] Sharma P and Diebels S 2023 Journal of Materials Science 58 6254
[25] Huang D, Li R and Yang G 2019 Communications in Nonlinear Science and Numerical Simulation 79 104916
[26] Hu H, Chen L and Qian J 2023 Journal of Vibration and Control 1
[27] Moslemi A and Homaeinezhad M 2023 Applied Mathematics and Mechanics 44 141
[28] Liu L, He L, Han Y, Zheng X, Sun B and Cheng G 2023 Sensors and Actuators A: Physical 349 114054
[29] Li J, Wang G, Yang P, Wen Y, Zhang L, Song R and Hou C 2024 Energy 286 129578
[30] Chen L, Ma Y, Hou C, Su X and Li H 2023 Applied Mathematical Modelling 116 350
[31] Sun Y H, Zeng Y H and Yang Y G 2024 Acta Mechanica Sinica 40 523154
[32] Han J, Huang D, Li W, Yang G and Gubeljak N 2023 International Journal of Non-Linear Mechanics 157 104518
[33] Huang D, Han J, Li W, Deng H and Zhou S 2023 Communications in Nonlinear Science and Numerical Simulation 119 107086
[34] Franzini G R, Maciel V S F, Vernizzi G J and Zulli D 2023 Nonlinear Dynam. 111 22215
[35] Zhang H, Li Z, Yang Z and Zhou S 2023 Communications in Nonlinear Science and Numerical Simulation 125 107350
[36] Li M, Yu D, Li Y, Liu X and Dai F 2023 International Journal of NonLinear Mechanics 156 104464
[37] Starosvetsky Y and Gendelman O 2010 Nonlinear Dynam. 59 711
[38] Zang J and Zhang Y 2019 Nonlinear Dynam. 98 889
[39] Mirhashemi S, Saeidiha M and Ahmadi H 2023 Communications in Nonlinear Science and Numerical Simulation 118 107035
[40] Sun Y H, Liao Z J and Yang Y G 2024 Nonlinear Dynam. 1
[41] Xiong L, Tang L, Liu K and Mace B R 2018 J. Phys. D: Appl. Phys. 51 185502
[42] Kremer D and Liu K 2017 Journal of Sound and Vibration 410 287
[43] Zulli D and Luongo A 2015 Meccanica 50 781
[44] Yang Y, Xu W, Yang G and Jia W 2016 Chaos 26 084302

A viscoelastic nonlinear energy sink with an electromagnetic energy harvester: Narrow-band random response

A viscoelastic nonlinear energy sink with an electromagnetic energy harvester: Narrow-band random response

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