Stepping piezoelectric actuators with large working stroke for nano-positioning systems: A review

• Published in: Sensors and actuators. A. Physical. Vol. 292; pp. 39 - 51
• Main Authors: Li, Jianping, Huang, Hu, Morita, Takeshi
• Format: Journal Article
• Language: English
• Published: Lausanne Elsevier B.V 15.06.2019; Elsevier BV
• Subjects: Compliant mechanism; Finite element analysis; Global positioning systems; GPS; Large working stroke; Piezoelectric actuator; Piezoelectric actuators; Piezoelectricity; Stepping motion principle; Stroke; Transducers; Vibration; Stepping motion principle; Compliant mechanism; Piezoelectric actuator; Large working stroke
• ISSN: 0924-4247; 1873-3069
• DOI: 10.1016/j.sna.2019.04.006

[Display omitted] •Recent developments and achievements in stepping piezoelectric actuators with large working stroke were reviewed.•Three types of stepping piezoelectric actuators, inchworm type, friction-inertia type, and parasitic type, were summarized.•The future research directions of stepping piezoelectric actuators were discussed. Precision positioning systems with large working stroke (millimeter or more) and micro/nano-scale positioning resolution are widely required in both scientific research and industries. For this kind of applications, piezoelectric materials based actuators show unique advantages and have been widely employed. To overcome the demerit of the limited working stroke for single piezoelectric element, various stepping motion principles have been proposed in the past years, and accordingly, stepping piezoelectric actuators with various structures have been designed and evaluated. This review is aimed to summarize the recent developments and achievements in stepping piezoelectric actuators with large working stroke. Especially, the emphasis is on three main types of stepping piezoelectric actuators, i.e., inchworm type, friction-inertia type, and parasitic type. The motion principles of these three types of piezoelectric actuators and the corresponding developments of various actuators are discussed respectively, followed by pointing out the existing problems in these three types of piezoelectric actuators and proposing some potential research directions in this topic. It is expected that this review is helpful for relevant researchers to understand stepping motion principles as well as piezoelectric actuators, and to successfully select and design stepping piezoelectric actuators for specific applications.