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Acta Mechanica

Erschienen in:

12.06.2023 | Original Paper

Dynamical analysis of an asymmetric tri-stable hybrid energy harvesting system driven by colored noise

verfasst von: Yanxia Zhang, Yanfei Jin, Tingting Zhang

Erschienen in: Acta Mechanica | Ausgabe 9/2023

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Abstract

The piezoelectric–electromagnetic hybrid vibration energy harvester (HVEH) has proven to be a favorable option to overcome the low-power generation issue of individual energy conversion mechanism. Considering the inevitable asymmetry and the ubiquitous ambient noise in engineering, the stochastic dynamics of an asymmetric tri-stable HVEH driven by colored noise is investigated in this paper. Facing such difficult challenges as multiple couplings, strong nonlinearity, multiple attractors, asymmetry and noise in the system, a novel stochastic averaging technique is developed to explore the dynamics. The energy-dependent frequency is first established according to the operation mechanism of the asymmetric triple-well potential function. Then, the stochastic averaging is extended to obtain the analytical expressions of the stationary probability density, the mean-square voltage, the mean-square current and the mean output power. Finally, the influences of the asymmetric parameter and colored noise on the steady-state response, the mean output power and the stochastic resonance are mainly analyzed. Results show that the energy harvesting performance can be effectively enhanced by reducing asymmetry and correlation time, adopting hybrid design and choosing appropriate electromechanical coupling coefficient and time constants ratio. The developed stochastic averaging technique is well validated by Monte Carlo numerical simulation.

Vorheriger Artikel Finite element implementation of a certain class of elasto-viscoplastic constitutive models

Nächster Artikel Modeling analysis and tuning of shunt piezoelectric damping controller for structural vibration

Lumentut, M.F., Howard, I.M.: Electromechanical analysis of an adaptive piezoelectric energy harvester controlled by two segmented electrodes with shunt circuit networks. Acta Mech. 228, 1321–1341 (2017)CrossRefMATH

Le Scornec, J., Guiffard, B., Seveno, R., Le Cam, V., Ginestar, S.: Self-powered communicating wireless sensor with flexible aero-piezoelectric energy harvester. Renew. Energy 184, 551–563 (2022)CrossRef

Nabholz, U., Lamprecht, L., Mehner, J.E., Zimmermann, A., Degenfeld-Schonburg, P.: Parametric amplification of broadband vibrational energy harvesters for energy-autonomous sensors enabled by field-induced striction. Mech. Syst. Signal Process. 139, 106642 (2020)CrossRef

Erturk, A., Inman, D.J.: Broadband piezoelectric power generation on high-energy orbits of the bistable Duffing oscillator with electromechanical coupling. J. Sound Vib. 330, 2339–2353 (2011)CrossRef

Karami, P., Ariaei, A., Hasanpour, K.: Optimum network configuration design of a multi-beam vortex-induced vibration piezoelectric energy harvester. Mech. Syst. Signal Process. 177, 109186 (2022)CrossRef

Jin, Y., Zhang, Y.: Dynamics of a delayed Duffing-type energy harvester under narrow-band random excitation. Acta Mech. 232, 1045–1060 (2021)MathSciNetCrossRefMATH

Fezeu, G.J., Fokou, I.S.M., Buckjohn, C.N.D., Siewe Siewe, M., Tchawoua, C.: Resistance induced P-bifurcation and ghost-stochastic resonance of a hybrid energy harvester under colored noise. Physica A Stat. Mech. Appl. 557, 124857 (2020)MathSciNetCrossRefMATH

Shi, G., Xu, J., Xia, Y., Zeng, W., Jia, S., Li, Q., Wang, X., Xia, H., Ye, Y.: An annular tubular wearable piezoelectric–electromagnetic hybrid vibration energy harvester driven by multi magnetic beads. Energy Convers. Manag. 269, 116119 (2022)CrossRef

Sun, Y.H., Yang, Y.G., Zhang, Y., Xu, W.: Probabilistic response of a fractional-order hybrid vibration energy harvester driven by random excitation. Chaos 31, 013111 (2021)MathSciNetCrossRefMATH

10.

Xing, J., Fang, S., Fu, X., Liao, W.H.: A rotational hybrid energy harvester utilizing bistability for low-frequency applications: modelling and experimental validation. Int. J. Mech. Sci. 222, 107235 (2022)CrossRef

11.

Hou, C., Li, C., Shan, X., Yang, C., Song, R., Xie, T.: A broadband piezo-electromagnetic hybrid energy harvester under combined vortex-induced and base excitations. Mech. Syst. Signal Process. 171, 108963 (2022)CrossRef

12.

Zhang, Y., Jin, Y., Zhang, Z.: Dynamics of a tri-stable hybrid energy harvester under narrow-band random excitation. Int. J. Non-Linear Mech. 148, 104294 (2023)CrossRef

13.

Sebald, G., Kuwano, H., Guyomar, D., Ducharne, B.: Simulation of a Duffing oscillator for broadband piezoelectric energy harvesting. Smart Mater. Struct. 20, 075022 (2011)CrossRef

14.

Huang, D., Chen, J., Zhou, S., Fang, X., Li, W.: Response regimes of nonlinear energy harvesters with a resistor–inductor resonant circuit by complexification-averaging method. Sci. China Technol. Sci. 64, 1212–1227 (2021)CrossRef

15.

Zhou, S., Lallart, M., Erturk, A.: Multistable vibration energy harvesters: principle, progress, and perspectives. J. Sound Vib. 528, 116886 (2022)CrossRef

16.

Panyam, M., Daqaq, M.F.: Characterizing the effective bandwidth of tri-stable energy harvesters. J. Sound Vib. 386, 336–358 (2017)CrossRef

17.

Li, H.T., Ding, H., Jing, X.J., Qin, W.Y., Chen, L.Q.: Improving the performance of a tri-stable energy harvester with a staircase-shaped potential well. Mech. Syst. Signal Process. 159, 107805 (2021)CrossRef

18.

Wang, G., Zhao, Z., Liao, W.H., Tan, J., Ju, Y., Li, Y.: Characteristics of a tri-stable piezoelectric vibration energy harvester by considering geometric nonlinearity and gravitation effects. Mech. Syst. Signal Process. 138, 106571 (2020)CrossRef

19.

Mei, X., Zhou, S., Yang, Z., Kaizuka, T., Nakano, K.: A tri-stable energy harvester in rotational motion: modeling, theoretical analyses and experiments. J. Sound Vib. 469, 115142 (2020)CrossRef

20.

Zhang, Y., Jin, Y.: Stochastic dynamics of a piezoelectric energy harvester with correlated colored noises from rotational environment. Nonlinear Dyn. 98, 501–515 (2019)CrossRef

21.

Zhang, Y.X., Jin, Y.F., Xu, P.: Stochastic resonance and bifurcations in a harmonically driven tri-stable potential with colored noise. Chaos 29, 023127 (2019)MathSciNetCrossRefMATH

22.

Zhang, Y., Jin, Y., Xu, P.: Dynamics of a coupled nonlinear energy harvester under colored noise and periodic excitations. Int. J. Mech. Sci. 172, 105418 (2020)CrossRef

23.

Zhu, W., Lin, Y.K.: Stochastic averaging of energy envelope. J. Eng. Mech. 117, 1890–1905 (1905)CrossRef

24.

Spanos, P.D., Sofi, A., Di Paola, M.: Nonstationary response envelope probability densities of nonlinear oscillators. J. Appl. Mech. 74, 315–324 (2006)CrossRefMATH

25.

Jia, W.T., Zhu, W.Q., Xu, Y.: Stochastic averaging of quasi partially integrable and resonant Hamiltonian systems under combined Gaussian and Poisson white noise excitations. Int. J. Nonlinear Mech. 93, 82–95 (2017)CrossRef

26.

Omar, E.K., Abdollah, S.: Enhanced stochastic averaging of non-integrable nonlinear systems subjected to stochastic excitations. Soil Dyn. Earthq. Eng. 113, 256–264 (2018)CrossRef

27.

Ge, G., Liu, J.: Stochastic averaging on a nonlinear oscillator with coordinate-dependent mass excited by Gaussian white noises. Chaos Solitons Fractals 143, 110609 (2021)MathSciNetCrossRef

28.

Xu, Y., Gu, R., Zhang, H., Xu, W., Duan, J.: Stochastic bifurcations in a bistable Duffing–Van der Pol oscillator with colored noise. Phys. Rev. E Stat. Nonlinear Soft Matter Phys. 83, 056215 (2011)CrossRef

29.

Zhu, W.Q., Cai, G.Q., Hu, R.C.: Stochastic analysis of dynamical system with double-well potential. Int. J. Dyn. Control 1, 12–19 (2013)CrossRef

30.

Liu, D., Xu, Y., Li, J.: Probabilistic response analysis of nonlinear vibration energy harvesting system driven by Gaussian colored noise. Chaos Solitons Fractals 104, 806–812 (2017)CrossRefMATH

31.

Xu, M., Li, X.: Stochastic averaging for bistable vibration energy harvesting system. Int. J. Mech. Sci. 141, 206–212 (2018)CrossRef

32.

Li, P., Gao, S., Cai, H.: Modeling and analysis of hybrid piezoelectric and electromagnetic energy harvesting from random vibrations. Microsyst. Technol. 21, 401–414 (2013)CrossRef

33.

Foupouapouognigni, O., Nono Dueyou Buckjohn, C., Siewe Siewe, M., Tchawoua, C.: Hybrid electromagnetic and piezoelectric vibration energy harvester with Gaussian white noise excitation. Physica A Stat. Mech. Appl. 509, 346–360 (2018)MathSciNetCrossRefMATH

34.

Xia, H., Chen, R., Ren, L.: Parameter tuning of piezoelectric–electromagnetic hybrid vibration energy harvester by magnetic force: modeling and experiment. Sens. Actuators A Phys. 257, 73–83 (2017)CrossRef

35.

Wu, D., Zhu, S.: Stochastic resonance in a bistable system with time-delayed feedback and non-Gaussian noise. Phys. Lett. A 363, 202–212 (2007)CrossRef

36.

Yang, T., Cao, Q.: Dynamics and energy generation of a hybrid energy harvester under colored noise excitations. Mech. Syst. Signal Process. 121, 745–766 (2019)CrossRef

37.

Zhang, Y., Jin, Y.: Colored lévy noise-induced stochastic dynamics in a tri-stable hybrid energy harvester. J. Comput. Nonlinear Dyn. 16, 041005 (2021)CrossRef

Titel: Dynamical analysis of an asymmetric tri-stable hybrid energy harvesting system driven by colored noise
verfasst von: Yanxia Zhang
Yanfei Jin
Tingting Zhang
Publikationsdatum: 12.06.2023
Verlag: Springer Vienna
Erschienen in: Acta Mechanica / Ausgabe 9/2023
Print ISSN: 0001-5970
Elektronische ISSN: 1619-6937
DOI: https://doi.org/10.1007/s00707-023-03615-1

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