Abstract
Piezoelectric metamaterial plate (PMP) is being investigated for structural vibration energy harvesting (SVEH), in which an interface circuit is often used. Thus, it is a challenge to perform bandgap optimization of such an elastic–electro–mechanical coupling system. This paper presents a binary-like topology optimization scheme by dividing the unit cell into identical pieces, where a {0, 1} matrix is optimized to indicate material distribution. Firstly, a unified motion equation is derived for the elastic plate and the piezoelectric patch, and an electromechanical coupling model is built for a self-powered synchronized charge extraction circuit. Then, an extended plane wave expansion method is presented to model the bandgap character of the PMP with interface circuits (PMPICs), and the numerical solution of the dispersion curves is derived based on the Bloch theorem. Next, an extended genetic algorithm is applied for the topology optimization of the PMPIC. In the end, numerical and finite element simulations are performed to validate the proposed method. The results demonstrate that both the structure and the circuit can be optimized simultaneously to obtain the maximum first-order bandgap at a given central frequency. Therefore, the proposed method should provide an effective solution for the topology optimization of a PMPIC for broadband SVEH.
Highlights
The bandgap character of the PMP with interface circuits (PMPICs) is the elastic plate and the piezoelectric patch, and an electromechanical coupling model modeled based on an extended plane wave expansion method and the Bloch theorem is is built
The level set method is not feasible for optimizing the PMPIC due to the following two reasons: (i) the optimization function is difficult to be defined by including the interface circuit and the piezoelectric effect and (ii) the optimal result of the level set method may cause the piezoelectric patch to many independent pieces
A self-powered synchronized charge extraction circuit (SCEC) is used as the interface circuit connected to the Piezoelectric metamaterial plate (PMP) for harvesting structural vibration energy
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Chen et al first investigated one kind of piezoelectric metamaterial plate (PMP) for vibration energy harvesting and analyzed the effects of geometric and material parameters on vibration bandgaps by finite element simulations [19]. Xie et al proposed an improved fast plane wave expansion method for topology optimization of phononic crystals [26]. The aim of PMPIC design is to obtain proper bandgaps to meet the needs of low freA PMPIC is composed of a piezoelectric metamaterial plate and an propagation interface circuit. The aim of PMPIC design is to obtain proper bandgaps to meet the needs of low frequency the interface circuit; elastic–electro–mechanical coupling effects should be and broadband. The bandgap character of the PMPIC is the elastic plate and the piezoelectric patch, and an electromechanical coupling model modeled based on an extended plane wave expansion method and the Bloch theorem is is built.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
