한국정밀공학회지 (Journal of the Korean Society for Precision Engineering)

한국정밀공학회 (Korean Society for Precision Engineering)
권호 표지

Counter Flow 방식의 랙 다이를 이용한 고정 밀도 Worm 전조기술 개발

Development of Form Rolling Technology for High Precision Worm Using the Rack Dies of Counter Flow Type

  • 발행 : 2004.10.01
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초록

The objective of this study is to suggest the form rolling technology to produce high precision worm on the base of three dimensional finite element simulation and experiment. It is important to determine the initial workpiece diameter in form rolling because it affects the quality of tooth profile. The calculation method of the initial workpiece diameter in form rolling is suggested and it is verified by finite element simulation. The form rolling processes of worm shaft used as automotive part using both the rack dies of counter flow type and the roll dies are considered and simulated with the same numerical model as actual process by the commercial finite element code, BEFORM-3D. Deformation modes of workpiece between the form rolling by the rack dies of counter flow type and the roll dies are investigated from the result of simulation. The experiments using rack dies and roll dies are performed under the same conditions as those of simulation. The surface roughness, the straightness and the profile of worm are measured precisely using the worm shafts obtained from experiment. The results of simulation and experiment in this study show that the form rolling process of worn shaft using the rack dies is decidedly superior to that using roll dies from the aspect of the precision of worm such as the surface roughness, the straightness and the profile of worm.

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참고문헌

  1. 葉山益次郞, '回轉塑性加工學,' 東京: 近代編集社, 1981
  2. 東京: コロナ社, '回轉加工とスピニング,' 日本塑性加工學會 編, 1990
  3. Hayama, M., 'Estimation of Thread Rolling Pressure,' J. of the JSTP, Vol. 9, pp. 190-197, 1968
  4. Kasei, S., Shiho, M., Yamamoto, A., 'A Study on the Tapping Torque in the Cold Forming of Nut-Thread,' J. of the JSTP, Vol. 16, pp. 264-273, 1975
  5. Ivanov, V., 'Profiling of Rollers for Thread Rolling,' J. of Mater. Process. Technol., Vol. 59, 1995 https://doi.org/10.1016/0924-0136(95)02159-0
  6. Martin, J. A., 'Mesh Density Study for Application to Large Deformation Rolling Process Evaluations,' Fatigue, Fracture, and Residual Stresses, ASME, Pressure Vessels and Piping Division, Vol. 373, pp. 177-184, 1998
  7. Martin, J. A., 'Fundamental Finite Element Evaluation of a Three Dimensional Rolled Thread Form: Modeling and Experimental Results,' Fatigue, Fracture, and Residual Stresses, ASME, Pressure Vessels and Piping Division, Vol. 373, pp. 457-467, 1998
  8. Dotson, J. L., Henrey, C. R., Domblesky, J. P., 'Experimental Investigation of External Thread Rolling,' Wire Journal International, pp. 64-68, 2002
  9. Domblesky, J. P., Feng, F., 'A Parametric Study of Process Parameters in External Thread Rolling,' J. of Mater. Process. Technol., Vol. 121, pp. 341-349, 2002 https://doi.org/10.1016/S0924-0136(01)01223-7
  10. Gagg, C. R., 'Premature Failure of Thread Rolling Dies: Material Selection, Hardness Criteria and Case Studies,' Engineering Failure Analysis, Vol. 8, pp. 87-105, 2001 https://doi.org/10.1016/S1350-6307(99)00038-2
  11. Kim, K. H., Kim, D. H., Kim, B. M., 'Determination of Optimal Blank Diameter for High Precision of Spindle Screw,' J. of KSTP, Vo. 11, No.8, pp. 710-715, 2002 https://doi.org/10.5228/KSPP.2002.11.8.710