Dynamic and wave propagation analysis of periodic smart beams coupled with resonant shunt circuits: passive property modulation

The present study deals with analyzing the dynamic behavior of a smart beam coupled with piezoelectric materials in the unimorph and bimorph configurations connected to resonant shunt circuits. The resonant shunt circuit connection is applied to promote and passively modulate the vibration and flexural wave propagation attenuation. A Spectral Element Method (SEM)-based approach for the periodic smart structure is developed that is capable of efficiently analyzing various configurations of periodicity and piezoelectric attachments in a generic framework. The wave attenuation is obtained based on the Transfer Matrix Method (TMM). Numerical analyses reveal that the effective wavenumber presents local attenuation behavior at the same frequencies of the vibration as per the shunt design, indicating the shunt circuit's impedance associated with tuned frequency. The internal resonance characteristics of the resonant shunt circuits and their effects on the beam response are investigated in detail. The proposed periodic smart beam system along with the spectral element approach for analyzing the dynamics and wave propagation behavior of such systems, lays out further potential avenues for designing more complex configurations of smart structures and multifunctional metamaterials.

Automated summary

The present study investigates the dynamic behavior of a smart beam coupled with piezoelectric materials in unimorph and bimorph configurations connected to resonant shunt circuits. A Spectral Element Method-based approach for analyzing periodic smart structures is developed, with numerical analyses showing that the resonant shunt circuits' impedance is associated with tuned frequency and can promote vibration and flexural wave attenuation. The study also examines the internal resonance characteristics of the resonant shunt circuits and their effects on the beam response.