Machine bed support with sliding surface for improving the motion accuracy

被引：0

作者：

Shirahama Y. ^{[1
]}

Sato R. ^{[1
]}

Takasuka Y. ^{[1
]}

Nakatsuji H. ^{[1
,2
]}

Shirase K. ^{[1
]}

机构：

[1] Department of Mechanical Engineering, Kobe University, 1-1 Rokko-dai, Nada, 657-8501, Kobe

[2] Center of Manufacturing Technology, Graduate School of Engineering, Kobe University, 1-1 Rokko-dai, Nada, 657-8501, Kobe

来源：

Shirahama, Yusaku (158t329t@stu.kobe-u.ac.jp) | 1600年 / Fuji Technology Press卷 / 10期

关键词：

Machine bed; Mathematical model; Motion accuracy; NC machine tools; Tracking motion; Vibration;

D O I：

10.20965/ijat.2016.p0447

中图分类号：

学科分类号：

摘要：

The purpose of this study is to develop a new machine bed support mechanism for reducing the vibration generated during the high-speed tracking motion of numerical control machine tools. In order to achieve this, the frequency response and motion trajectory of a machine tool with the proposed machine bed, which has a sliding surface, aremeasured and compared with that of the conventional support. Based on the modal analysis of the machine tool structure, a mathematical model representing the influence of the machine bed characteristics on the vibration is also developed. The model consists of a bed, saddle, table, column, and spindle head. Every component has three degrees of freedom for each of the translational and rotational axes. In order to evaluate the characteristics of the machine bed, the mathematical model determines the stiffness and damping along the X-, Y-, and Z-axis between the bed and the ground. The frequency response curves simulated by using the mathematicalmodel are compared with that of the measured ones. From the results of the experiments and simulations, it is confirmed that the vibration generated during high-speed tracking motions can be reduced by using the proposed machine bed with a sliding surface. © 2016, Fuji Technology Press. All rights reserved.

引用

页码：447 / 454

页数：7

共 23 条

[1] Rivin E.I., Vibration isolation of precision equipment, Precis Engineering, pp. 41-56, (1995)
[2] Yoshida K., Shimura H., Yahagi H., Yoshioka J., Effects of mounting conditions of surface gridding machines upon their rocking mode vibrations, I.C.P. E, (1995)
[3] Huo D., Cheng K., Wardle F., A holistic integrated dynamic design and modeling approach applied to the development of ultraprecision micro milling machine, Int. J. of Machine Tools & Manufacture, 50, pp. 335-343, (2010)
[4] Yu Z., Nakamoto K., Ishida T., Takeuchi Y., Interactive design assistance system of machine tool structure in conceptual and fundamental design stage, Int. J. of Automation Technology, 4, pp. 303-311, (2010)
[5] Li B., Hong J., Liu Z., Stiffness design of machine tool structures by a biologically inspired topology optimization method, Int. J. of Machine Tools & Manufacture, 84, pp. 33-44, (2014)
[6] Kono D., Inagaki Y., Matsubara A., Influence of contact stiffness on support stiffness of machine tool, Proc. of 2011 Autumn Meeting of the Japan Society for Precision Engineering, pp. 413-414, (2011)
[7] Kono D., Inagaki Y., Matsubara A., Yamaji I., A study on estimation of the support stiffness of machine tools, Proc. of 2012 Spring Meeting of the J. of The Japan Society for Precision Engineering, pp. 351-452, (2012)
[8] Kono D., Nishino S., Yamaji I., Matsubara A., A method for stiffness tuning of machine tool support considering contact stiffness, Int. J. of Machine Tools & Manufacture, 90, pp. 50-59, (2015)
[9] Mori K., Kono D., Yamaji I., Matsubara A., Support placement for machine tools using stiffness model, Int. J. of Automation Technology, 9, pp. 680-688, (2015)
[10] Yoshida K., Shimura H., Yahagi H., Yoshioka J., Effects of mounting elements of surface grinding machines upon their relative receptances between grinding wheel and work table, J. Mech. Working Technol, 17, pp. 377-386, (1988)

← 1 2 3 →