Torque Motor of the Turntable Key Components of the Ultra-Precision Optical Aspheric Machine Tool

Yu Kun Xu; Zhuang De Jiang; Shuming Yang; Lin Yang; Xing Yuan Long

doi:10.4028/www.scientific.net/AMR.753-755.1547

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 753-755Torque Motor of the Turntable Key Components of...

Torque Motor of the Turntable Key Components of the Ultra-Precision Optical Aspheric Machine Tool

Abstract:

Due to the geometry complexity and high precision requirement, there are many challenges in the design, manufacture and measurement of ultra-precision micro-structured freeform surfaces with form accuracy at sub-micrometer and surface finish in nanometer range. Successful manufacturing of ultra-precision micro-structured freeform surface relies on the high precision of machine tools. The precision, stability and repeatability of the turntable are the key factors of the high precision machine tools. Thanks to the large number of poles, mechanical transmission elements associated backlash and frictional losses are dispensed with, torque motors are more frequently applied to rotary tables and axes. This paper demonstrates the selection process of the torque motor for precision turntable under certain conditions. Two torque motors are selected according to the pre-given boundary conditions and both have appropriate torque to drive the given rotational object.

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Periodical:

Advanced Materials Research (Volumes 753-755)

Pages:

1547-1552

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.753-755.1547

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Online since:

August 2013

Authors:

Yu Kun Xu, Zhuang De Jiang, Shuming Yang, Lin Yang, Xing Yuan Long

Keywords:

Direct Drive, Modern CNC Machine Tools, Precision Turntable, Torque Motor

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References

[1] Wang Chengyuan, Wang Guizi, Xia Jiakuan. Optimization design of the motor torque applied to the direct drive turntable. Journal of Shenyang University of Industrial. 2008, 30(2): 6-10).

Google Scholar

[2] Tian Xueguang, Tian Zhixing, Liu Xuan. Development of precision micro drive unit of angle used by large high-precision turntable. Optics and Precision Engineering. 2010（5）: 1112-1118）.

Google Scholar

[3] Luo Songbao, Zhang Jianming. Ultra-precision machining equipment and technology of aspheric optical parts . Optics and Precision Engneering. 2006, 36(4): 553-563.

Google Scholar

[4] J K Martin. Measured stiffness and displacement coefficients of a stationaryrotor hydrostatic bearing . Tribology International, 2008, 29(03): 1-5.

Google Scholar

[5] Xie Wenhui, Tang Yougang, Chen Yushu. Analysis of motion stability of the flexible rotor-bearing systemwith two unbalanced disks . Journal of Sound and Vibration, 2007, 31(6): 689-695.

DOI: 10.1016/j.jsv.2007.08.001

Google Scholar

[6] Wang Weimin, Gao Jinji, Jiang Zhinong. Rotating machinery malfunction diagnosis based on finite element model . Vibration and Impact, 2006, 25(4): 30-33. （in Chinese）.

Google Scholar

[7] Huang Qiang, Zhang Genbao, Luo Ji. Applied research of the built-in torque motor in the CNC hobbing machine design. Mechanical Transmission. 2011（5）: 112-118）.

Google Scholar

[8] Information on http: /www. siemens. com.

Google Scholar