Abstract

Piezoelectric stick–slip actuators have become viable candidates for precise positioning and precise metering due to simple structure and long stroke. To improve the performances of the piezoelectric stick–slip actuators, our team deeply studies the actuators from both structural designs and driving methods. In terms of structural designs, the trapezoid-type, asymmetrical flexure hinges and mode conversion piezoelectric stick–slip actuators are proposed to improve the velocity and load based on the asymmetric structure; besides, a piezoelectric stick–slip actuator with a coupled asymmetrical flexure hinge mechanism is also developed to achieve the bidirectional motion. In terms of driving methods, a non-resonant mode smooth driving method (SDM) based on ultrasonic friction reduction is first proposed to restrain the backward motion during the rapid contraction stage. Then, a resonant mode SDM is further developed to improve the output performance of the piezoelectric stick–slip actuator. On this basis, the low voltage and symmetry of the SDM are also discussed. Finally, the direction-guidance hybrid method (DGHM) excitation method is presented to achieve superior performance, especially for high speed.

Highlights

  • Piezoelectric stick–slip actuators have obtained considerable significance and have become the focus area of research for camera focusing mechanisms, cell phones, scanning probe micro-scopes, zoom lens systems and blue-ray devices, because of compact structure, low cost, theoretically unlimited displacement and convenient control [1–3]

  • The friction force of the parallel type stick–slip actuators cannot be adjusted during the operation, which results in an obvious backward motion

  • In terms of structural designs, the axial stiffness of the stator is unevenly distributed, and the parasitic motion is generated by introducing the flexure hinge mechanism into the design of the stator, including trapezoid-type piezoelectric stick–slip actuator [10], piezoelectric stick–slip actuators with asymmetrical flexure hinges [11, 12] and mode conversion piezoelectric stick–slip actuator [13]; these structural designs can comprehensively adjust the friction force during the movement of the stick–slip actuator, thereby significantly improving the velocity and load; besides, a coupled asymmetrical flexure hinge mechanism is developed to achieve the bidirectional motion of the non-parallel type stick–slip actuators [14]

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Summary

Introduction

Piezoelectric stick–slip actuators have obtained considerable significance and have become the focus area of research for camera focusing mechanisms, cell phones, scanning probe micro-scopes, zoom lens systems and blue-ray devices, because of compact structure, low cost, theoretically unlimited displacement and convenient control [1–3]. Li et al proposed a linear stick–slip actuator with a non-parallel structure based on the lateral motion, which could be generated by a parallelogram-type flexure hinge mechanism and a piezoelectric element [7]. In terms of structural designs, the axial stiffness of the stator is unevenly distributed, and the parasitic motion is generated by introducing the flexure hinge mechanism into the design of the stator, including trapezoid-type piezoelectric stick–slip actuator [10], piezoelectric stick–slip actuators with asymmetrical flexure hinges [11, 12] and mode conversion piezoelectric stick–slip actuator [13]; these structural designs can comprehensively adjust the friction force during the movement of the stick–slip actuator, thereby significantly improving the velocity and load; besides, a coupled asymmetrical flexure hinge mechanism is developed to achieve the bidirectional motion of the non-parallel type stick–slip actuators [14]. In terms of driving methods, a nonresonant mode smooth driving method (SDM) based on ultrasonic friction reduction is first proposed for the parallel type stick–slip actuator, and the backward motion is restrained during the rapid contraction stage [15].

Trapezoid-type piezoelectric stick-slip actuator
Mode conversion piezoelectric stick-slip actuator
Bidirectional piezoelectric stick-slip actuator
Research on non-resonant mode smooth driving method
Research on resonant mode smooth driving method
Research on low voltage characteristics of smooth driving method
Research on symmetry of smooth driving method
Operation principle of direction-guidance hybrid method
Findings
Conclusions
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