Multimode piezoelectric shunt damping of thin plates with arrays of separately shunted patches, method, and experimental validation

TL;DR

This paper develops a new modeling and experimental validation approach for separately shunted piezoelectric patches on thin plates, demonstrating improved vibration damping performance over interconnected shunting across a broad frequency range.

Contribution

It introduces a novel formulation and methodology for modeling separately shunted piezoelectric patches, enhancing vibration attenuation in thin plates.

Findings

Separately shunted patches outperform interconnected ones in damping efficiency.

The developed model accurately predicts system dynamics and frequency response.

Experimental results confirm the effectiveness of the proposed shunt configuration.

Abstract

Two-dimensional thin plates are widely used in many applications. Shunt damping is a promising way for the attenuation of vibration of these electromechanical systems. It enables a compact vibration damping method without adding significant mass and volumetric occupancy. Analyzing the dynamics of such electromechanical systems requires precise modeling tools that properly consider the coupling between the piezoelectric elements and the host structure. Although the concept of shunt damping has been studied extensively in the literature, most of the studies do not provide a formulation for modeling the multiple piezoelectric patches that are scattered on the host structure and shunted separately. This paper presents a methodology and a formulation for separately shunted piezoelectric patches for achieving higher performance on vibration attenuation. The Rayleigh-Ritz method is used for performing modal analysis and obtaining the frequency response functions of the electro-mechanical system. The developed model includes mass and stiffness contribution of the piezoelectric patches as well as the electromechanical coupling effect. In this study, the piezoelectric patches are shunted via separate electrical circuits and compared with the ones those are shunted via interconnected electrical circuits. For verification, system-level finite element simulations are performed in ANSYS software and compared with the analytical model results. An experimental setup is also built to validate the performance of the separately shunted piezoelectric patches. The effectiveness of the method is investigated for a broader range of frequencies and it was shown that separately shunted piezoelectric patches are more effective compared to connected for a wide range of frequencies.