페룰 가공용 초정밀 무심 연삭기의 유정압 안내면 및 이송계에 대한 구조 특성 해석

Structural Characteristic Analysis on the Hydrostatic Guide Way and Feeding System of a High-Precision Centerless Grinder for Machining Ferrules

  • 김석일 (한국항공대학교 항공우주 및 기계공학부) ;
  • 박천홍 (한국기계연구원 지능형정밀기계연구부 공작기계그룹) ;
  • 조순주 ((주)세스코 기술연구)
  • 발행 : 2004.07.01


This paper proposes the structural characteristic analysis and evaluation on the hydrostatic guide way and feeding system of a high-precision centerless grinder for machining ferrules. In order to realize the required accuracy of ferrules with sub-micron order, the axial stiffness and motion accuracy of feeding system have to become higher level than those of existing centerless grinders. Under these points of view, the physical prototype of feeding system composed of steel bed, hydrostatic guide way and ballscrew feeding mechanism is designed and manufactured for trial. Experimental results show that the axial and vertical stiffnesses of the physical prototype are very low as compared with those design values. In this paper, to reveal the cause of these stiffness difference, the structural deformations on the virtual prototype of feeding system are analyzed based on the finite element method under experimental conditions. The simulated results illustrate that the deformation of front ballscrew support-bearing bracket is the main cause of reduction in the axial stiffness of feeding system, and the deflection of bed structure and the bending deformation of hydrostatic guide rails are the main causes of reduction in the vertical stiffness of feeding system.


  1. Rowe, W. B., Spraggett, S., Gill, R. and Davies, B.J., 1987, 'Improvements in Centre less Grinding Machine Design,' Annals of the CIRP, Vol. 36, No. 1, pp. 207-210
  2. Rowe, W. B., Miyashita, M. and Koenig, W., 1989, 'Centerless Grinding Research and Its Application in Advanced Manufacturing Technology,' Annals of the CIRP, Vol. 38, No.2, pp. 617-626
  3. Takeuchi, Y., Mitachi, S. and Nagase, R., 1997, 'High-Strength Class-Ceramic Ferrule for SC-Type Single-Mode Optical Fiber Connector,' IEEE Photonics Technology Letters, Vol. 9, No. 11, pp. 1502-1504
  4. Cho, S. J., Kim, H. G., Ebihara and Tuskisima, 2003, 'The Study on the Development of Ultra Precision Centerless Grinder,' Journal of KSPE, Vol. 20, No.6, pp. 11-14
  5. Lee, E. S., Cho, C. R. and Park, B. J., 2003, 'Development of Rotary Diamond Dressing System of Centerless Grinder for Ferrule Grinding,' Journal of KSPE, Vol. 20, No.6, pp. 15-19
  6. Park, C. H., Hwang, J. H. and Cho, S. J., 2002, 'A Study on the Feeding System of Centerless Grinder for Machining the Ferrule,' Proc. of KSPE, pp. 65-69
  7. Ro, P. I. and Hubbel, P. I., 1992, 'Nonlinear Micro-Dynamic Behavior of a Ball-Screw Driven Precision Slide System,' Precision Engineering, Vol. 14, No.4, pp. 229-233
  8. Heo, S. J., 1997, 'Development of Diamond Wheel for Ultra Precision and High Performance Grinding of Difficult-to-Materials,' Trans. of KSME (A), Vol. 21, No. 12, pp. 2172-2178
  9. NSK, 1993, 'Precision Machinery Product,' NSK Catalog No.3101
  10. THK, 1991, 'Linear Motion System', THK Catalog No.100-1K
  11. Aoyama, T., 1990, Hydrostatic Bearing, Kogyo Chosakai Publishing, pp. 29-45
  12. Swanson Analysis Systems, Inc, 1999, ANSYS Verification Manual
  13. Slocum, A. H., 1992, Precision Machine Design, Prentice Hall, pp. 551-580