Research on the technical progress of milling for hardened steel mould of automotive covering parts

被引：0

作者：

Liu X. ^{[1
]}

Jiang Y. ^{[1
]}

Wu S. ^{[1
]}

Li M. ^{[1
]}

Yue C. ^{[1
]}

Chen T. ^{[1
]}

机构：

[1] School of Mechanical Engineering, Harbin University of Science and Technology, Harbin

来源：

Jiang, Yancui (jiangyancui@herbust.edu.cn) | 2016年 / Chinese Mechanical Engineering Society卷 / 52期

关键词：

Automobile covering mould; Cutting tools; Dynamics; Hardened steel mould; NC milling;

D O I：

10.3901/JME.2016.17.035

中图分类号：

学科分类号：

摘要：

With the largest automobile production and best automobile sales around the globe, automobile mould processing capacity is far from being adapted to the needs of the car replacement in China. The milling quality of high-grade car key covering parts mould still can not meet the design requirements. The analysis of hardened steel mould of car large cover milling characteristics and difficult points shows that the modelling and simulation of milling process analysis, processing system dynamic characteristics, the milling stability analysis, the development of cutting tools for automotive covering parts hardened steel mould milling, free surface NC programming technology and process planning are the keys of automobile mould processing. Summarized the status of research in these areas as well as explore the car cover milling hardened steel mould remains to be the further problem. Put forward some suggestions for future research directions. © 2016 Journal of Mechanical Engineering.

引用

页码：35 / 49and57

页数：4922

共 93 条

[1] Altan T., Lilly B., Yen Y.C., Et al., Manufacturing of dies and molds, Annals of the CIRP, 50, 2, pp. 404-422, (2001)
[2] Krajnik P., Kopac J., Modern machining of die and mold tools, Journal of Materials Processing Technology, 157-158, pp. 543-552, (2004)
[3] Yu Y., Ma M., Ding Z., Advanced manufacturing technology and development of automobile die, Manufacturing Technology and Machine Tool, 5, pp. 45-47, (2010)
[4] Xiang H., Analysis of the reasons for the usage of inlays block splicing in drawing die profile, Journal of Xihua University, 25, 3, pp. 44-45, (2006)
[5] Lee P., Altintas Y., Prediction of ball-end milling forces from orthogonal cutting data, International Journal of Machine Tools and Manufacture, 36, 9, pp. 1059-1072, (1996)
[6] Subrahmanyam K.V.R., San W.Y., Soon H.G., Et al., Cutting force prediction for ball nose milling of inclined surface, The International Journal of Advanced Manufacturing Technology, 48, 1-4, pp. 23-32, (2010)
[7] Kim G.M., Cho P.J., Chu C.N., Cutting force prediction of sculptured surface ball-end milling using Z-map, International Journal of Machine Tools and Manufacture, 40, 2, pp. 277-291, (2000)
[8] Wei Z., Wang M., Cai Y., Et al., Milling force prediction for ball-end milling of 3D curved surfaces, Journal of Mechanical Engineering, 49, 1, pp. 178-184, (2013)
[9] Cao Q., Xue D., Zhao J., Et al., A cutting force model considering influence of radius of curvature for sculptured surface machining, International Journal of Advanced Manufacturing Technology, 54, 5-8, pp. 821-835, (2010)
[10] Hao H., Wang B., Tang W., Prediction of instantaneous milling force taking runout into account in peripheral milling of curved surface, International Journal of Advanced Manufacturing Technology, 79, 1-4, pp. 49-56, (2015)

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