Gradient design model of contact interface for ultrasonic motor

被引：0

作者：

Qu J. ^{[1
]}

Wang Y. ^{[1
]}

Zhou N. ^{[1
]}

机构：

[1] School of Mechatronics Engineering, Harbin Institute of Technology

来源：

Jixie Gongcheng Xuebao/Journal of Mechanical Engineering | 2010年 / 46卷 / 17期

关键词：

Contact interface; Friction material; Ultrasonic motor; Wear Gradient;

D O I：

10.3901/JME.2010.17.073

中图分类号：

学科分类号：

摘要：

Ultrasonic motor is a new type of motor driven by friction force between the contact interface of rotor and stator. Friction material is an important part of contact interface. Its design and wear control are key problems for ultrasonic motor. A simplified model of ultrasonic motor is established. Effect of wear of friction material on contact parameters and driving friction force is studied. The properties that worn friction material should have are obtained by keeping stable contact width between rotor and stator. Design principle and theoretical structure model of gradient friction material for ultrasonic motor are proposed. The simulation analysis shows that normal elastic modulus of friction material pasted on rotor should gradually decline from the extenior to the interior. This type of friction material can maintain the output properties and increase performance lifetime of ultrasonic motor. And a new field is opened up for choosing and researching friction material for ultrasonic motor. © 2010 Journal of Mechanical Engineering.

引用

页码：73 / 78

页数：5

共 14 条

[1] Qu J., Qi Y., Zhang Z., Et al., Advances on tribology of ultrasonic motor and its friction materials, Tribology, 18, 1, pp. 80-87, (1998)
[2] Zhao C., Ultrasonic Motors Technologies and Applications, (2007)
[3] Cui T., Wang L., Lu Q., Et al., Transmission mechanism of ultrasonic micromotors, Chinese Journal of Mechanical Engineering, 31, 2, pp. 71-76, (1995)
[4] Zhou T., Jiang K., A survey of studies on ultrasonic motor, Nature Magazine, 21, 6, pp. 340-343, (1999)
[5] Akira E., Nobutoshi S., Investigation of friction material for ultrasonic motor, Japanese Journal of Applied Phy. Sics., 26, 1, pp. 197-199, (1987)
[6] Rehbein P., Wallaschek J., Friction and wear behavior of polymer/steel and alumina/alumina under high-frequency fretting conditions, Wear, 216, 2, pp. 97-105, (1998)
[7] Ding Q., Yao Z., Zheng W., Et al., Experimental study of friction material adhere to the stator of the traveling wave type rotary ultrasonic motor, Tribology, 27, 6, pp. 578-582, (2007)
[8] Qu J., Sun F., Zhao C., Performance evaluation of traveling wave ultrasonic motor based on a model with visco-elastic friction layer on stator, Ultrasonics, 45, 1-4, pp. 22-31, (2006)
[9] Wang G., Lu G., Guo J., Analytical model of traveling-wave type ultrasonic motor based on the energy equivalent method, Chinese Journal of Mechanical Engineering, 44, 2, pp. 74-81, (2008)
[10] Chen C., Zeng J., Zhao C., Dynamic model of traveling-wave-type rotary ultrasonic motor, Chinese Journal of Mechanical Engineering, 42, 12, pp. 76-82, (2006)

← 1 2 →