A walking type piezoelectric actuator with two umbrella-shaped flexure mechanisms

Abstract

A walking type piezoelectric actuator with two umbrella-shaped flexure mechanisms is proposed to reduce the backward motion. By utilizing two umbrella-shaped flexure mechanisms which could be treated as two ‘legs’, the ‘walking’ motion is accomplished. The structure and motion principle are described; Finite Element Method (FEM) is exploited to explore the static and modal performances of the umbrella-shaped flexure mechanism. Moreover, experiments have been carried out to investigate the working performance of the proposed walking type piezoelectric actuator. Results show that the walking type piezoelectric actuator with umbrella-shaped flexure mechanisms could achieve the ‘walking’ motion and reduce the backward motion. Additionally, the phase difference between two input signals U1 and U2 greatly influences the working performance. In the case of the phase difference Φ= 95°, the backward rate of the slider is able to achieve the minimum 0%; the minimum stepping displacement is 0.3 μm when the frequency f= 1 Hz; the maximum motion speed of the slider is up to 1132 μm s−1 when the input frequency f = 400 Hz and the input voltage U = 120 V; the maximum output force is 700 g while the input voltage U = 120 V and frequency f = 1 Hz.