单模态纵-弯复合直线电动机的机理与特性

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摘要提出了一种融合一阶纵振和四阶弯曲振动模式的单模态直线超声波电动机,介绍了电动机的结构和运行机理,利用有限元方法建立了电动机定子的机电耦合模型,仿真分析了电动机定子的振动特性,确定了电动机定子工作模态和工作频率;利用弹性杆的纵振动和悬臂梁的弯曲振动理论建立了电动机驱动足椭圆运动轨迹方程,分析了激励电压相位差对电动机椭圆轨迹的影响;利用粘弹性接触机理给出了电动机的机械特性输出曲线,分析了预压力、激励电压幅值和激励频率等对电动机输出特性的影响。通过数值和仿真分析得出:单模态直线超声波电动机的工作频率为39 860 Hz,在外加激励电压U_p-p=100 V时,电动机最大输出推力和空载速度分别达到19.1 N和310 mm·s^-1。

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	岳玉秋
	王光庆
	展永政

关键词 ：直线超声波电动机, 单模态, 有限元模型, 机械特性, 数值分析

Abstract：A novel single mode linear type ultrasonic motor which is combining the 1^st longitudinal vibration excited by the piezoelectric stack and the 4^th bending vibration excited by the piezoelectric plates is proposed in this paper. The structure and the operating mechanism of this new type ultrasonic motor were firstly introduced. Then the electromechanical model of the motor stator is modeled with the finite element method, the vibrating modal and the operating frequency of the stator were determined based on the numerical simulate analyses of the stator vibration performances. The elliptical orbits equation of the stator driving feet were derived according to the longitudinal vibration theory of the elastic bar and the bending vibration theory of the beam; the effects of the phase difference between the two exciting voltages on the elliptical orbits were numerically analyzed. Finally, the effects of the preload, the exciting voltage amplitude and frequency on the mechanical performances of the motor were studied based on the stick-elastic contact mechanism. Simulation and numerical results show that the operating frequency of the single model linear ultrasonic motor is 39 860 Hz; the prototype motor achieves the maximum thrust of 19.1 N and no-load speed of 310 mm·s^-1 when the exciting voltage U_p-p is 100 V.

Key words： Linear ultrasonic motor single mode finite element model mechanical performance numerical analysis

收稿日期: 2015-09-20 出版日期: 2017-03-22

PACS:

TM356

基金资助:国家自然科学基金(51277165)和浙江自然科学基金(LY15F10001)资助项目。

通讯作者: 王光庆男,1975年生,博士,教授,研究方向为超声波电动机及压电振动能量采集技术。E-mail:kele76@163.com

作者简介: 岳玉秋女,1990年生,硕士研究生,研究方向为超声波电动机。E-mail:sdhzyuqiu@163.com

引用本文:

岳玉秋,王光庆,展永政. 单模态纵-弯复合直线电动机的机理与特性[J]. 电工技术学报, 2017, 32(5): 33-40. Yue Yuqiu,Wang Guangqing,Zhan Yongzheng. Mechanism and Performances of a Single Mode Longitudinal-Bending Hybrid Type Linear Ultrasonic Motor. Transactions of China Electrotechnical Society, 2017, 32(5): 33-40.

链接本文:

https://dgjsxb.ces-transaction.com/CN/Y2017/V32/I5/33

[1] 王剑,郭吉丰.一种中空短柱径向-扭转振动复合型超声波电动机[J].电工技术学报,2009,24(10):6-11.
Wang Jian,Guo Jifeng.A radial-torsional vibration hybrid type ultrasonic motor with hollow and short cylindrical structure[J].Transactions of China Electrotechnical Society,2009,24(10):6-11.
[2] Zhao Chunsheng.Ultrasonic motors:technologies and applications[M].Beijing:Science Press,2011.
[3] Morita T.Miniature piezoelectric motors[J].Sensors and Actuators A:Physical,2003,103(3):291-300.
[4] Hou X Y,Lee H P,Ong C J,et al.Development and numerical characterization of a new standing wave ultrasonic motor operating in the 30-40 kHz frequency range[J].Ultrasonics,2013,53(5):928-934.
[5] 赵淳生,朱华.超声电机技术的发展和应用[J].机械制造与自动化,2008,37(3):3-9.
Zhao Chunsheng,Zhu Hua.Development and application of ultrasonic motors technologies[J].Machine Building & Automation,2008,37(3):3-9.
[6] Yang Xiaohui,Liu Yingxiang,Chen Weishan,et al.Miniaturization of a longitudinal-bending hybrid linear ultrasonic motor[J].Ceramics International,2015,41:S607-S611.
[7] Wan Zhijian,Hu Hong.Modeling and experimental analysis of the linear ultrasonic motor with in-plane bending and longitudinal mode[J].Ultrasonics,2014,54(3):921-928.
[8] Bein T.A linear ultrasonic motor using the first longitudinal and the fourth bending mode[J].Smart Materials and Structures,1997,6(5):619-627.
[9] He Siyuan,Chen Weishan,Xie Tao,et al.Standing wave bi-directional linearly moving ultrasonic motor[J].IEEE Transactions on Ultrasonics,Ferroelectrics,and Frequency Control,1998,45(5):1133-1139.
[10]Yang M,Richardson R C,Levesle M C,et al.Performance improvement of rectangular-plate linear ultrasonic motors using dual-frequency drive[J].IEEE Transactions on Ultrasonics,Ferroelectrics,and Frequency Control,2004,49(12):1600-1606.
[11]赵学涛,陈维山,郝铭.纵弯复合多自由度超声电机的研究[J].西安交通大学学报,2009,43(8):107-111.
Zhao Xuetao,Chen Weishan,Hao Ming.Ultrasonic motor with longitudinal-bending hybrid vibration modal[J].Journal of Xi′an Jiaotong University,2009,43(8):107-111.
[12]Yun C H,Watson B,Friend J.A piezoelectric ultrasonic linear micromotor using a slotted stator[J].IEEE Transactions on Ultrasonics,Ferroelectrics,and Frequency Control,2010,50(8):1868-1874.
[13]Guo Mingsen,Pan Song,Hu Junhui,et al.A small linear ultrasonic motor utilizing longitudinal and bending modes of a piezoelectric tube[J].IEEE Transactions on Ultrasonics,Ferroelectrics,and Frequency Control,2014,61(4):705-709.
[14]白洋,王剑,郭吉丰.基于复损耗的杆式超声波电动机定子建模及其仿真[J].电工技术学报,2012,27(12):185-190.
Bai Yang,Wang Jian,Guo Jifeng.Modeling and simulation of a bar-type ultrasonic motor based on loss coefficients[J].Transactions of China Electrotechnical Society,2012,27(12):185-190.
[15]王光庆,岳玉秋,展永政.纵-弯复合旋转式超声波电机的优化设计与性能分析[J].电工技术学报,2015,30(22):33-41.
Wang Guangqing,Yue Yuqiu,Zhan Yongzheng.Optimum design and performance analysis of the longitudinal-bending hybrid rotating type ultrasonic motor[J].Transactions of China Electrotecnical Society,2015,30(22):33-41.
[16]Liu Yingxiang,Liu Junkao,Chen Weishan,et al.A U-shaped linear ultrasonic motor using longitudinal vibration transducers with double feet[J].IEEE Transactions on Ultrasonics,Ferroelectrics,and Frequency Control,2012,59(5):981-989.
[17]蒋春容,胡民强,金龙,等.行波型超声波电动机定转子接触粘滑分布特性[J].电工技术学报,2010,25(12):48-53.
Jiang Chunrong,Hu Minqiang,Jin Long,et al.Stick-slip distribution of contact area between stator and rotor in traveling wave ultrasonic motor[J].Transactions of China Electrotechnical Society,2010,25(12):48-53.
[18]王瑞霞,金龙,潘鹏,等.一种方底座短柱超声波电机的设计[J].电工技术学报,2015,30(2):134-139.
Wang Ruixia,Jin Long,Pan Peng,et al.A short cylindrical ultrasonic motor with square base[J].Transactions of China Electrotechnical Society,2015,30(2):134-139.