DESIGN AND FABRICATION OF INTEGRATED PIEZOELECTRIC MICROPUMP WITH VORTEX ENHANCEMENT OPTIMIZATION

In this study, a 3D acoustic-solid interaction model is combined with a time-dependent vorticity enhancement method for design optimization of nozzle/diffuser micropumps. Compared with the conventional method where static pressure loss ratio is used as the performance indicator of individual nozzle/diffuser element, the vortex method provides a direct and good prediction of output characteristics of the micropumps. An integrated piezoelectric micropump prototype is fabricated with flat-panel display compatible processing techniques. The frequency characterization shows good agreement of the micropump working frequency with that predicted by finite element simulation where additional damping effects are considered. A high-speed particle image velocimetry shows successfully the movement of fluid elements driven by the piezoelectric actuator.