High-voltage synthetic inductor for vibration damping in resonant piezoelectric shunt

Resonant piezoelectric shunts are a well-established way to reduce vibrations of mechanical systems suffering from resonant condition. The vibration energy is transferred to the electrical domain through the bonded piezoelectric material where it is dissipated in the shunt. Typically, electrical and...

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Veröffentlicht in:	Journal of vibration and control 2021-09, Vol.27 (17-18), p.2047-2057
Hauptverfasser:	Dekemele, Kevin, Van Torre, Patrick, Loccufier, Mia
Format:	Artikel
Sprache:	eng
Schlagworte:	Cantilever beams Circuits Configurations Frequency ranges High voltages Inductance Mechanical systems Operational amplifiers Passive components Piezoelectricity Vibration Vibration damping
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container_end_page	2057
container_issue	17-18
container_start_page	2047
container_title	Journal of vibration and control
container_volume	27
creator	Dekemele, Kevin Van Torre, Patrick Loccufier, Mia
description	Resonant piezoelectric shunts are a well-established way to reduce vibrations of mechanical systems suffering from resonant condition. The vibration energy is transferred to the electrical domain through the bonded piezoelectric material where it is dissipated in the shunt. Typically, electrical and mechanical resonance frequencies are several orders apart. As such, finding a suitable high inductance component for the resonant shunt is not feasible. Therefore, these high inductance values are mimicked through synthetic impedances, consisting of operational amplifiers and passive components. A downside of these synthetic impedances is that standard operational amplifiers can only handle up to 30 V peak to peak and the state-of-the-art amplifiers up to 100 Vpp. However, as mechanical structures tend to become lighter and more flexible, the order induced voltages over the piezoelectric material electrode voltages increase above these limitations. In this research, a high-voltage synthetic inductor is proposed and built by combining the bridge amplifier configuration and the output voltage boost configuration around a single operational amplifier gyrator circuit, effectively quadrupling the range of the synthetic inductor to 400 Vpp. The impedance of the circuit over a frequency range is numerically and experimentally investigated. The synthetic inductor is then connected to a piezoelectric material bonded to a cantilever beam. Numerical and experimental investigation confirms the high-voltage operation of the implemented circuit and its suitability as a vibration damping circuit.
doi_str_mv	10.1177/1077546320952612
format	Article
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subjects	Cantilever beams Circuits Configurations Frequency ranges High voltages Inductance Mechanical systems Operational amplifiers Passive components Piezoelectricity Vibration Vibration damping
title	High-voltage synthetic inductor for vibration damping in resonant piezoelectric shunt
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