Abstract
In this paper, an active control strategy is employed to actively tune the vibration and wave propagation properties in a piezoelectric metamaterial beam. The piezoelectric actuator and sensor are periodically arranged along the piezoelectric metamaterial beam. By using the extended Hamilton principle, the governing equations for the fully coupled piezoelectric metamaterial beam are obtained. The negative proportional feedback control strategy is introduced to achieve the periodical active stiffness for the piezoelectric metamaterial beam. The band structures and natural frequencies of the proposed periodic structure are derived by the transfer matrix method, and the spectral element method is applied as numerical validation. The influences of the feedback control gain ratio, length ratio, and the number of the unit cells on natural frequencies and bandgaps are discussed. Results indicate that the natural frequencies of the system are reduced with the increase in the feedback control gain ratio and length ratio. In addition, multiple bandgaps can be generated by using the negative proportional feedback control strategy. It is found that bandwidths can be obviously broadened by selecting the proper feedback control gain ratio and length ratio. The theoretical and numerical results show that the vibration and wave propagation properties of the proposed piezoelectric metamaterial beam can be controlled by using the negative proportional feedback control strategy.
Highlights
Metamaterials are artificial structures with unconventional effective characteristics
The negative proportional feedback control method is introduced to design the controller, which can provide an active stiffness to the elastic metamaterial beam
The results show that the natural frequency of the system decreases with the increase in η1 and η2
Summary
Metamaterials are artificial structures with unconventional effective characteristics. It is very difficult to tune both the frequency regions and bandwidths in acoustic/elastic metamaterials. Many scholars are still committed to studying bandgap properties in acoustic/elastic metamaterials. Xiao[4,5] studied the wave propagation and vibration transmission in metamaterial elastic rods with periodically attached multi-degree-of-freedom spring mass resonators. Chen et al.[6] designed a sandwich metamaterial beam with periodic multiple dissipative resonators to study the broadband wave mitigation and/or absorption. Zhou[8,9] developed a new resonator with high-static-low-dynamic stiffness, which greatly reduced the bandgaps of flexural wave propagation in beam structures. The dissipative damping[10–12] and nonlinear properties of materials[13,14] can play roles in tuning the bandgap characteristics
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