Dynamics modeling and vibration analysis of a piezoelectric diaphragm applied in valveless micropump

• Published in: Journal of sound and vibration Vol. 405; pp. 133 - 143
• Main Authors: He, Xiuhua, Xu, Wei, Lin, Nan, Uzoejinwa, B.B., Deng, Zhidan
• Format: Journal Article
• Language: English
• Published: Amsterdam Elsevier Ltd 29.09.2017; Elsevier Science Ltd
• Subjects: Computer simulation; Coupling; Cycle time; Deflection; Deformation; Diaphragms (mechanics); Dynamic models; Dynamics modeling; Electric potential; Electricity; Finite element analysis; Finite element method; Finite element simulation; Fluid pressure; Mathematical models; Micropumps; Modelling; Piezoelectric diaphragm; Piezoelectricity; Plates (structural members); Simulation; Substrates; Superposition (mathematics); Valveless micropump; Vibration analysis; Valveless micropump; Piezoelectric diaphragm; Dynamics modeling; Finite element simulation
• ISSN: 0022-460X; 1095-8568
• DOI: 10.1016/j.jsv.2017.05.025

This paper presents the dynamical model involved with load of fluid pressure, electric-solid coupling simulation and experimental performance of the piezoelectric diaphragm fabricated and applied in valveless micropump. The model is based on the theory of plate-shell with small deflection, considering the two-layer structure of piezoelectric ceramic and elastic substrate. The high-order non-homogeneous vibration equation of the piezoelectric diaphragm, derived in the course of the study, was solved by being divided into a homogeneous Bessel equation and a non-homogeneous static equation according to the superposition principle. The amplitude of the piezoelectric diaphragm driven by sinusoidal voltage against the load of fluid pressure was obtained from the solution of the vibration equation. Also, finite element simulation of electric-solid coupling between displacement of piezoelectric diaphragm due to an applied voltage and resulting deformation of membrane was considered. The simulation result showed that the maximum deflection of diaphragm is 9.51 μm at a quarter cycle time when applied a peak-to-peak voltage of 150VP-P with a frequency of 90Hz, and the displacement distribution according to the direction of the radius was demonstrated. Experiments were performed to verify the prediction of the dynamic modeling and the coupling simulation, the experimental data showed a good agreement with the dynamical model and simulation. •A new dynamic model of a piezoelectric diaphragm applied in micropump is proposed.•The two-layer structure and the fluid pressure are considered in the equations.•The high-order non-homogeneous equation is solved using superposition principle.•The dynamical model can predict the amplitude of the piezoelectric diaphragm well.