在塑性變形中圓環鍛粗為最常用來探討摩擦因子之方法，由Kunogi[1]文獻中發現其6:3:2(外徑:內徑:高度)為最常用之圓環比例，上述比例圓環稱之為標準圓環。故本文利用車削製作出標準圓環比例，不同尺寸大小的圓環試片來進行圓環鍛粗加工實驗，探討其圓環試片之實驗結果，針對試片尺寸的不同，其變形結果是否會因尺寸效應的存在而造成摩擦因子的變化為研究重點。

In plastic deformation, ring upsetting is the most common approach to study friction factors. In the research of Kunogi[1], 6:3:2(outer diameter: inner diameter: height) is considered the most commonly used scale of ring. Rings with the scale mentioned above are called standard rings. In this paper, we use turning to produce ring specimens with the standard scale and in different sizes to conduct ring upsetting experiments. From the experimental result of ring specimens, this paper aims at studying whether the deformation that results from the difference of sizes of specimens result due to the size effects caused by changes in the friction factor for research focus.

[1] Kunogi, M., "A new method of cold extrusion.", J. of the Scientific Research Institute, Vol.50, pp215-246, 1956.
[2] Male, A. T. and Cockcroft, M. G., " A method for the determination of the coefficient of friction of metals under conditions of bulk plastic deformation ", J. of the Inst. of Metals, Vol. 93, pp. 38-46, 1965.
[3] Baraya, G. L. and Parker, J., "Determination of the yield surfaces by notched strip specimens ", Int. J. Mech. Sci. 5, pp.353-363, 1963.
[4] Male, A.T. and Depierre, V., " The Validity of Mathematical Solutions for Determining Friction from the Ring Compression Test ", Journal of Lubrication Technology, pp.389-397, 1970.
[5] Lee, C.H. and Altan, T., "Influence of Flow Stress and Friction Upon Metal Flow in Upset Forging of Rings and Cylinders", Journal of Engineering for Industry, pp.775-782, 1972.
[6] Nellemann, Y., Bay, N., Wanheim, T., "Real area of contact and friction stress-the role of trapped lubricant. ", Wear 43, p.45, 1977.
[7] Schey, J.A. and Venner, T.R., "Shape Changes in the Upsetting of Slender Cylinders", Journal of Engineering for Industry, pp.79-83, 1982.
[8] Hsiang, S. H. and Huang, T. F., "Analysis of Deformation Behaviours in Upsetting Processes ", Proceedings of the 8th National Conference on Mechanical Engineering The Chinese Society of Mechanical Engineers, pp. 887-894, 1991.
[9] M. Geiger, U. Engel, S. Niederkom, M. Pfestorf, "Experimental investigation of contact phenomena in cold forging", ICFG plenary meeting, 1995.
[10] Hsu, T.C. and Lee, C.H., "Realistic Friction Modeling for Simple Upsetting", Journal of Society of Tribologists and Lubrication, pp.367 -373,1997.
[11] S. Y. Lin, "Analysis of the Dissimilar Interface Frictional Constraints During", The International Journal of Advanced Manufacturing Technology, Vol.13, No.9, pp.601-610, 1997.
[12] Sofuoglu H. and Rasty J.,"On the measurement of friction coefficient utilizing the ring compression test", Tribology International,Vol. 32, pp.327-335,1999.
[13] Dutton, R.E., Seetharaman, V., Goetz, R.I., and Semiatin, S.L., "Effect of flow softening on ring test calibration curves", Materials Science and Engineering, Vol. 270, pp.249-253,1999.
[14] Hu, Z.M. and Dean, T.A., " A study of surface topography, friction and lubricants in metalforming", International Journal of Machine Tools and Manufacture,Vol. 40, pp.1637-1649, 2000.
[15] Engel, U. and Eckstein, R., " Microforming-from basic research to its realization", Journal of Materials Processing Technology 125-126, pp.35-44, 2002.
[16]S.Malayappan and R.Narayanasamy, "Barrelling of aluminium. solid cylinders during cold upset forging with constraint at one end", International Journal of Material Science and Technology, Vol 19, pp 507-511,2003.
[17] Y.G. An, H. Vegter "Analytical and experimental study of frictional behavior in through-thickness compression test",Journal of Materials Processing Technology 160 ,pp. 148–155,2005.
[18] S. Malayappan and G. Esakkimuthu , "Barrelling of aluminium solid cylinders during cold upsetting with differential frictional conditions at the faces", The International Journal of Advanced Manufacturing Technology, Vol. 29, No.1-2, pp. 41-48, 2006.
[19] Yang, T.S., Hsu, Y.C., "Study on the bulging deformation of the porous metal in upsetting", Journal of Materials Processing Technology, pp.154-158, 2006.
[20] Sahin, M., Cetinarslan, C.S., Akata, H.E., "Effect of surface roughness on friction coefficients duringupsetting processes for different materials", Materials and Design, Vol. 28, pp.633-640, 2007.
[21] K. Manisekar ., R. Narayanasamy., "Effect of friction on barrelling in square and rectangular billets of aluminium during cold upset forging" , Materials and Design 28 ,pp.592–598,2007.
[22] Cetinarslan, C.S., "Effect of aspect ratio on barreling contour and variation of total surface area during upsetting of cylindrical specimen", Materials and Design , Vol. 28, pp.1907-1913, 2007.
[23] K. Baskaran, R. Narayanasamy., "Effect of various stress ratio parameters on cold upset forging of irregular shaped billets using graphite as lubricant under plane and triaxial stress state conditions",Materials and Design, Vol. 29 ,pp. 2089–2103,2008.
[24] Rao, J. B., Kamaluddin, S., Rao, J. A., Sarcar, M.M.M., Bhargava, N.R.M.R. "Deformation behavior of Al-4Cu-2Mg alloy during cold upset forging", Journal of Alloys and Compounds, Vol.471, pp.128-136, 2009.
[25] Xinghui Han, Lin Hua. "Effect of size of the cylindrical workpiece on the cold rotary-forging process",Materials and Design , Vol.30 ,pp. 2802–2812,2009.
[26] Linfa Peng , Xinmin Lai , Hye-Jin Lee , Jung-Han Song , Jun Ni. "Friction behavior modeling and analysis in micro/meso scale metal forming proce",Materials and Design,Vol. 31,pp. 1953–1961,2010.
[27] H.M.T. Khaleed , Z. Samad, A.R. Othman, M.A. Mujeebu, A.B. Abdullah, M.M. Zihad. "Work-piece optimization and thermal analysis for flash-less cold forging of AUV propeller hubs — FEM simulation and experiment "Journal of Manufacturing Processes ,Vol. 13 .pp. 41–49 ,2011.
[28] 葉哲宇，「以實驗方法建立圓環鍛粗加工的異向性摩擦模型及其驗證」，碩士論文，國立中央大學，中壢，2010年。