Please use this identifier to cite or link to this item: http://hdl.handle.net/11455/2173
標題: 微銑削刀具磨耗對切削振動之影響研究
Study of Tool Wear Effect on the Cutting Tool Vibration in the Micro Milling Processes
作者: 陳庭弘
Chen, Ting-Hung
關鍵字: Micro end mill;微細加工;Tool wear;Vibration;刀具磨耗;振動
出版社: 機械工程學系所
引用: 【1】 Masuzawa T., “State of the Art of Micromachining,” Annals of the CIRP Vol. 49, No.2, pp. 473~488, 2000. 【2】Tuckerman D.B., and Pease, R.F., High Performance Heat Sinking for VLSI, IEEE Electron Device Letters, vol. EDL-2, pp126-129, 1981. 【3】 Robinson, G.M. and Jackson, M.J. ‘A review of micro and nanomachining from a materials. Perspective’, Journal of Materials Processing Technology,2005. 【4】Rahman M, Kumar AS, Prakash JRS Micro milling of. pure copper. J Mater Process Technol 116:39-43,2001. 【5】Dhanorker A. and Özel T., “An Experimental and Modeling Study on Meso/MicroEnd Milling Process,” CD Proceedings of ASME International Conference on Manufacturing Science and Engineering, Paper No. 21127, October 8-11, 2006. 【6】Fang F. Z., Wu H., Liu X. D., Liu Y. C., S. T. Ng, Tool geometry study in micro machining,. J. Micromech. and Microeng.,. Vol: 13, pp. 726-731, 2003. 【7】 Martellotti, M. E., “An Analysis of the Milling Process,” Transaction of ASME, Vol.63, pp.677-700, 1941. 【8】Martellotti, M. E., “An Analysis of the Milling Process, Part 2: Down Milling,” Transaction of ASME, Vol.67, pp.233-251, 1945. 【9】Koenigsberger, F. and Sabberwal, A. J. P., “An Investigation into the Cutting Force Pulsations During Milling Operations,” International Journal of Machine Tool Design and Research, Vol.1, pp.15-33,1961. 【10】. Sabberwal, A. J. P., “Chip Section and Cuting Force During the Milling Operation,” Annals of the CIRP, Vol.10, pp.197-203 , 1961. 【11】 Tlusty, J. and MacNeil, P., “Dynamics of Cutting Forces in End Milling,” CIRP annals, Vol.24, pp.21-25, 1975. 【12】 Kline, W. A., DeVor, R.E. and Snareef, I. A., “The Prediction of Cutting Forces in End Milling with Application to Cornering Cuts,” International Journal of Machine Tool Design and Research, Vol.22, No.1, pp.7-22,1982. 【13】Yellowley, I., “Observations on the Mean Values of Forces, Torque and Specific Power in the Peripheral Milling Process,” International Journal of Machine Tool Design and Research, Vol.25, No.4, pp.337-346, 1985. 【14】Kline, W. A., DeVor, R. E. and Lindberg, J. R., “The Prediction of Cutting Forces in End Milling with Application to Cornering Cut, “International Journal of Machine Tool Design and Research, Vol. 22, pp. 7-22, 1982. 【15】Abrari F. and Elbestawi M. A., “Closed form formation of cutting forces for ball and flat end mills”, International Journal of Machine Tool&Manufacture, Vol. 37,, pp. 17-27, 1997. 【16】Wang, J. J., Liang, S. Y. and Book, W. J. “Convolution Analysis of Milling Force Pulsation,” ASME Journal of Engineering for Industry, Vol. 116, pp. 17-25, 1994. 【17】Wang, J.-J. Junz and Zheng, C.M., “An Analytical Force Model with Shearing and Ploughing Mechanisms for End Milling,” Int. J. of Machine Tool & Manufacture, Vol. 42, pp. 761-771, 2002. 【18】Kitsunai H., “The transitions between microscopic wear modes during repeated sliding friction observed by a scanning electron microscope tribosystem”, Vol.135, Wear, pp.237-249, 1990. 【19】Choudhury S.K., Subhashashree Rath “ In-process tool wear estimation in milling using cutting force model,” Journal of Materials Processing Technilogy. 【20】Thomsen E.G., MacDonald A.G., and S. Kobayashi, ‘Flank Friction Studies With Carbide Tools Reveal Sublayer Plastic Flow”, Trans. ASME, J. of Engineering for Industry, 1962. 【21】 Usui, E., T. Shirakashi and T. Kitagawa, “Analytical Prediction of Cutting Tool Wear,” Wear, 1984. 【22】 Teitenberg, T.M., A.E. Bayoumi, and G. Yucesan, “Tool Wear Modeling Throughand Analytic Mechanistic Model of Milling Processes,” Wear, 1992. 【23】E.G. Thomsen, A.G. MacDonald, S. Kobayashi, “Flank friction studies with carbide tools reveal sublayer plastic flow”, Trans. ASME, Journal of Engineering for Industry 84 53-62,1962. 【24】S. Kobayashi, E.G. Thomsen, “The role of friction in metal cutting”, ASME Journal of Engineering for Industry 82 324-332,1960. 【25】Waldorf D.J., “Shearing, ploughing and wear in orthogonal machining”. Ph.D. Thesis, University of Illinois at Urbana-Champaign, 1996. 【26】Smithey, D. W., Kapoor, S. G., and DeVor, R. E., “A Worn Tool Force Model for Three-Dimensional Cutting Operations,” Int. J. Mach. Tools Manuf., 40, pp. 1929-1950, 2000. 【27】Smithey, D. W., Kapoor, S. G., and DeVor, R. E., “A New Mechanistic Model for Predicting Worn Tool Cutting Forces,” Mach. Sci. Technol., 5, pp.23,2001. 【28】Ibrahim, R. A., “Friction-Induced Vibration, Chatter, Squeal, and Chaos:Part 1-Mechanics of Friction,” s, ASME DE-Vol. 49, pp. 107-121 , 1992. 【29】Ming-Chyuan Lu and E. Kannatey-Asibu Jr., “Analysis of Sound Signal Generation due to Flank Wear in Turning,” ASME Journal of Manufacturing Science and Engineering, Vol. 124 pp. 779-808, 2002. 【30】Hill, R., The Mathematical Theory of Plasticity, Clarendon Press, Oxford, 1950. 【31】Rabinowicz, E., “The Least Wear,” Wear, 100, pp. 533-541., 1984. 【32】Rabinowicz, E., “AdhesiveWear,” Friction and Wear of Materials, John Wiley & Sons, Inc., New York, pp. 143-190 , 1995.
摘要: 
隨著微切削技術在微製造的應用領域的不斷擴大與刀具材料之選擇限制,微刀具磨耗在加工中更形快速。由於刀具直徑減小,剛性相對降低,刀具磨耗量對切削品質的影響也較傳統切削顯著。為了探討刀具磨耗對切削動態系統之影響,本文使用有限元素軟體建構微型銑刀切削系統模型,整合銑削力、犁切力與刀腹運動作用力,模擬刀具磨耗量增加對切削振動系統之影響,觀察分析其時頻域切削力與加速度訊號的變化,並與實驗量測出來的數據做比較驗證。由實驗與模擬結果顯示,兩者頻域響應低頻主要峰值頻率均位於1.6kHz,另外,隨著刀具磨耗量增加時,時域振動訊號之振幅均有變大趨勢,在頻域上,模擬刀具振動能量會往高頻轉移的趨勢,工件振動實驗訊號則在各個頻率均有能量升高的情形。
URI: http://hdl.handle.net/11455/2173
其他識別: U0005-2708200811450700
Appears in Collections:機械工程學系所

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