An improved analytical model of cutting temperature in orthogonal cutting of Ti6Al4V

被引：0

作者：

Chenwei SHAN ^{[1
]}

Xu ZHANG ^{[1
,2
]}

Bin SHEN ^{[1
]}

Dinghua ZHANG ^{[1
]}

机构：

[1] Key Laboratory of Modern Design and Integrated Manufacturing Technology of Ministry of Education, Northwestern Polytechnical University

[2] 206 Institution, North Electronics Research Institute Co., Ltd

来源：

Chinese Journal of Aeronautics | 2019年 / 32卷 / 03期

基金：

中国国家自然科学基金;

关键词：

Cutting temperature; Moving heat source method; Orthogonal cutting; Relief angle; Titanium alloy;

D O I：

暂无

中图分类号：

V261 [制造工艺过程及设备];

学科分类号：

082503 ;

摘要：

Cutting heat has significant effects on the machined surface integrity of titanium alloys in the aerospace field. Many unwanted problems such as surface burning, work hardening, and tool wear can be induced by high cutting temperatures. Therefore, it is necessary to accurately predict the cutting temperature of titanium alloys. In this paper, an improved analytical model of the cutting temperature in orthogonal cutting of titanium alloys is proposed based on the Komanduri-Hou model and the Huang-Liang model. The temperatures at points in a cutting tool, chip, and workpiece are calculated by using the moving heat source method. The tool relief angle is introduced into the proposed model, and imaginary mirrored heat sources of the shear plane heat source and the frictional heat source are applied to calculate the temperature rise in a semi-infinite medium. The heat partition ratio along the tool-chip interface is determined by the discretization method. For validation purpose, orthogonal cutting of titanium alloy Ti6Al4V is performed on a lathe by using a sharp tool. Experimental results show to be consistent well with those of the proposed model,yielding a relative difference of predicted temperature from 0.49% to 9.00%. The model demonstrates its ability of predicting cutting temperature in orthogonal cutting of Ti6Al4V.

引用

页码：759 / 769

页数：11

共 19 条

[1] Cutting tool temperature prediction method using analytical model for end milling[J]. Wu Baohai,Cui Di,He Xiaodong,Zhang Dinghua,Tang Kai.Chinese Journal of Aeronautics. 2016(06)
[2] Measurement and prediction of cutting temperatures during dry milling: review and discussions[J] . N. L. Bhirud,R. R. Gawande.Journal of the Brazilian Society of Mechanical Sc . 2017 (12)
[3] Analysis of the Frictional Heat Partition in Sticking-sliding Contact for Dry Machining: An Analytical-Numerical Modelling[J] . Y. Avevor,A. Moufki,M. Nouari.Procedia CIRP . 2017
[4] Analytical model of temperature field in workpiece machined surface layer in orthogonal cutting[J] . Kun Huang,Wenyu Yang.Journal of Materials Processing Tech. . 2016
[5] Modeling and analysis of coated tool temperature variation in dry milling of Inconel 718 turbine blade considering flank wear effect
Yan, Sijie
Zhu, Dahu
Zhuang, Kejia
Zhang, Xiaoming
Ding, Han
[J]. JOURNAL OF MATERIALS PROCESSING TECHNOLOGY, 2014, 214 (12) : 2985 - 3001
[6] Prediction of sticking and sliding lengths on the rake faces of tools using cutting forces[J] . Tony Atkins.International Journal of Mechanical Sciences . 2014
[7] Modeling temperature of non-equidistant primary shear zone in metal cutting[J] . Fangjuan Zhou,Xuelin Wang,Yujin Hu,Ling Ling.International Journal of Thermal Sciences . 2013
[8] A thermo-mechanical model of dry orthogonal cutting and its experimental validation through embedded micro-scale thin film thermocouple arrays in PCBN tooling[J] . Linwen Li,Bin Li,Kornel F. Ehmann,Xiaochun Li.International Journal of Machine Tools and Manufacture . 2013
[9] The effect of tool geometry and cutting speed on main cutting force and tool tip temperature[J] . Haci Saglam,Suleyman Yaldiz,Faruk Unsacar.Materials and Design . 2005 (1)
[10] Heat generation and temperature prediction in metal cutting: A review and implications for high speed machining[J] . N.A. Abukhshim,P.T. Mativenga,M.A. Sheikh.International Journal of Machine Tools and Manufacture . 2005 (7)

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