Dynamics of a Tri-Stable Energy Harvesting System With Time-Delay Feedback Under Narrow-Band Random Excitation

XIAO Yuzhu; WANG Ruohan; SUN Zhongkui; ZHAO Nannan

doi:10.21656/1000-0887.450237

Volume 46 Issue 6

Jun. 2025

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XIAO Yuzhu, WANG Ruohan, SUN Zhongkui, ZHAO Nannan. Dynamics of a Tri-Stable Energy Harvesting System With Time-Delay Feedback Under Narrow-Band Random Excitation[J]. Applied Mathematics and Mechanics, 2025, 46(6): 742-754. doi: 10.21656/1000-0887.450237

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Dynamics of a Tri-Stable Energy Harvesting System With Time-Delay Feedback Under Narrow-Band Random Excitation

doi: 10.21656/1000-0887.450237

1.
School of Sciences, Chang'an University, Xi'an 710064, P.R.China
2.
School of Mathematics and Statistics, Northwestern Polytechnical University, Xi'an 710129, P.R.China

Received Date: 2024-08-29
Rev Recd Date: 2024-10-16
Publish Date: 2025-06-01

Abstract

Abstract

A tri-stable energy harvester with time-delay feedback control under narrow-band random excitation was proposed. The steady-state responses of the energy harvesting system near the main resonance were obtained with the multi-scale method. Moreover, the 1st-order and 2nd-order nontrivial steady-state moments of the system were derived with the moment method, and their accuracy was also verified through the Monte Carlo simulations. Based on the above steady-state response moments, the effects of system parameters on the performances of the energy harvester were discussed in detail. The results show that, increasing the nonlinear stiffness coefficient can enlarge the working bandwidth of the energy harvester system, while increasing the narrowband random excitation intensity can enhance the output voltage of the energy harvester. The 2nd-order steady-state moments visibly decrease with the piezoelectric coupling term, which indicates that a larger piezoelectric coupling term is beneficial to the miniaturization of energy harvesters. Furthermore, a negative control feedback gain is beneficial to realize the miniaturization design of the energy harvester and increase the power output of the system effectively. The findings provide a theoretical basis for further exploration and optimization of energy harvesting systems.
- nonlinear dynamics,
- tri-stable piezoelectric energy harvester,
- time delay feedback,
- random excitation

(Contributed by SUN Zhongkui, M.AMM Youth Editorial Board)

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References(30)

References

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