Investigating the performance of tri-stable magneto-piezoelastic absorber in simultaneous energy harvesting and vibration isolation

•Energy harvesting and vibration mitigation by a tri-stable absorber is investigated.•Nonlinear coupled magneto-electromechanical equations are derived.•Large voltage over a wide band is harvested through chaotic inter-well oscillations.•Periodic vibrations are effectively suppressed via strongly mo...

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Bibliographic Details
Published in:Applied Mathematical Modelling 2022-02, Vol.102, p.661-693
Main Authors: Rezaei, Masoud, Talebitooti, Roohollah
Format: Article
Language:English
Subjects:
Absorbers
Beam theory (structures)
Broadband
Cantilever beams
Efficient energy harvesting
Energy dissipation
Energy harvesting
Euler-Bernoulli beams
Excitation
Hamilton's principle
Harmonic balance method
Magnetic fields
Magnets
Oscillations
Oscillators
Pseudo-arclength continuation
Strongly modulated response
Time domain analysis
Tri-stable absorber
Vibration
Vibration analysis
Vibration control
Wideband vibration mitigation
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Summary:•Energy harvesting and vibration mitigation by a tri-stable absorber is investigated.•Nonlinear coupled magneto-electromechanical equations are derived.•Large voltage over a wide band is harvested through chaotic inter-well oscillations.•Periodic vibrations are effectively suppressed via strongly modulated response.•Considerable level of voltage in periodic high-amplitude oscillations is scavenged. Tri-stable magneto-piezoelastic oscillators exhibit superior performance in terms of broadband resonance frequency and lower excitation threshold, compared to linear and bi-stable systems. Furthermore, inclusion of magnets renders them applicable, tunable, and simple designs. However, the potential of this oscillators for the purpose of simultaneous vibration suppression and energy harvesting has not been investigated. This study aims to investigate simultaneous energy harvesting and vibration isolation through a tri-stable magneto-piezoelastic absorber (TMPA). The absorber comprises a bimorph cantilever beam carrying a magnetic tip mass and two external magnets. The interplay between magnets generates a nonlinear restoring force in the TMPA structure. This absorber is attached to a host vibrating beam, which is under a transient or periodic forcing, in order to reduce its vibrations and harvest electrical energy. The nonlinear magneto-electromechanical equations governing the coupled system are obtained by employing the Hamilton's principle, Euler-Bernoulli beam theory, and a recently proposed magnetic force relationship. First, the mechanisms of tri-stability formation are investigated via bifurcation diagrams. Next the potency of the TMPA in the transient excitation scenario is examined. Furthermore, the performance of the TMPA in the presence of the periodic excitation with different forcing levels is investigated. Specifically, frequency and time domain analyses are carried out to characterize the response of the system and efficiency of the absorber when TMPA performs periodic in-well, aperiodic inter-well and periodic inter-well oscillations. In addition, to provide a better insight regarding the TMPA performance, the kinetic energies, harvested power, and dissipated power for the region of strongly modulated response are also studied. Moreover, the efficacy of the TMPA in periodic snap-through oscillations is examined by the means of the harmonic balance method in conjunction with pseudo-arclength continuation scheme. Finally, the results disclosed that
ISSN:0307-904X
1088-8691
0307-904X
DOI:10.1016/j.apm.2021.09.044