A review on piezoelectric ultrasonic motors for the past decade: Classification, operating principle, performance, and future work perspectives

[Display omitted] Hundreds of piezoelectric ultrasonic motors (PUSMs) have been proposed for scientific researches and developed for commercial applications in the past decade. They are surveyed and mainly classified into three types: standing wave motor (SWM), traveling wave motor (TWM) and hybrid...

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Published in:Sensors and actuators. A. Physical. 2020-05, Vol.306, p.111971, Article 111971
Main Authors: Tian, Xinqi, Liu, Yingxiang, Deng, Jie, Wang, Liang, Chen, Weishan
Format: Article
Language:English
Subjects:
Degrees of freedom
Friction coupling
Hybrid mode
Hybrid modes
Mechanical properties
Motors
Piezoelectricity
Principles
Standing wave
Standing waves
Traveling waves
Travelling wave
Ultrasonic motor
Ultrasonic technology
Vibration
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cited_by cdi_FETCH-LOGICAL-c391t-32e42e2f06df22696b178dc21dee8829ccc8ae134c1bbe3feb26143d5c6114b63
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container_title Sensors and actuators. A. Physical.
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creator Tian, Xinqi
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description [Display omitted] Hundreds of piezoelectric ultrasonic motors (PUSMs) have been proposed for scientific researches and developed for commercial applications in the past decade. They are surveyed and mainly classified into three types: standing wave motor (SWM), traveling wave motor (TWM) and hybrid modes motor (HMM), according to their operating principles. These different types of PUSMs are discussed in detail, in terms of their operating principles, structures, features and performances. The methods to realize the multi-degree-of-freedom (multi-DOF) motions of the PUSMs are also investigated based on the basic operating principles of the SWM, TWM and HMM. Some practical applications and representative designs of the PUSMs are introduced briefly. Finally, further efforts and research perspectives of the PUSM are summarized. This review contributes to a comprehensive understanding of the state of arts of the PUSM.
doi_str_mv 10.1016/j.sna.2020.111971
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subjects Degrees of freedom
Friction coupling
Hybrid mode
Hybrid modes
Mechanical properties
Motors
Piezoelectricity
Principles
Standing wave
Standing waves
Traveling waves
Travelling wave
Ultrasonic motor
Ultrasonic technology
Vibration
title A review on piezoelectric ultrasonic motors for the past decade: Classification, operating principle, performance, and future work perspectives
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