Resonance response interaction without internal resonance in vibratory energy harvesting

•Resonance response interaction occurs without internal resonance.•Resonance response interaction enhances harvesting efficiency.•Bubble shaped response curve is uncovered in the power-frequency response.•Parametric effects on the bandwidth in the presence of resonance response interaction. Resonanc...

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Bibliographic Details
Published inMechanical systems and signal processing Vol. 121; pp. 767 - 776
Main Authors Lu, Ze-Qi, Ding, Hu, Chen, Li-Qun
Format Journal Article
LanguageEnglish
Published Berlin Elsevier Ltd 15.04.2019
Elsevier BV
Subjects
Analytical solutions
Bubbles
Energy harvesting
Frequency response
Nonlinear response
Nonlinear vibration
Nonlinearity
Performance enhancement
Response resonance interaction
Springs (elastic)
Stiffness
White noise
Response resonance interaction
Energy harvesting
Nonlinear vibration
Analytical solutions
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Summary:•Resonance response interaction occurs without internal resonance.•Resonance response interaction enhances harvesting efficiency.•Bubble shaped response curve is uncovered in the power-frequency response.•Parametric effects on the bandwidth in the presence of resonance response interaction. Resonance response interaction in nonlinear multiple degrees of freedom vibration systems has always involved internal resonance. In this article, bubble shaped response curve is uncovered without pre-designated resonances relationship that is a necessary condition for internal resonance. The objective of this article is twofold: first to explore the connection between the resonance response interaction and bubble shaped response curve that may appear in the forced response of a nonlinear magnetoelectric coupled system; and, second, to exploit resonance response interaction to enhance the vibratory energy harvesting bandwidth. A nonlinear magnetoelectric oscillator coupled linearly to an additional oscillator is used to demonstrate the phenomena and the enhanced performance. The lateral springs could produce the geometrical nonlinear stiffness and its stiffness to adjust the two resonance responses such that the bubble shaped response curve appears in the power-frequency response plot. The method of harmonic balance is well established method for the analysis of such the power-frequency response. The results are also validated by some numerical work. The power-frequency response curves are generated for distinct harvesting mass, manifesting the resonance response interaction could increase the bandwidth and output power. At last, the resonance response interaction designed energy harvesting from Gaussian white noise excitation is numerically addressed to illustrate positive effects of geometrical nonlinearity.
ISSN:0888-3270
1096-1216
DOI:10.1016/j.ymssp.2018.11.035