Residual stress prediction based on MTS model during machining of Ti-6Al-4V

被引:11
作者
Pan, Zhipeng [1 ]
Liang, Steven Y. [1 ]
Garmestani, Hamid [2 ]
Shih, Donald [3 ]
Hoar, Eric [2 ]
机构
[1] Georgia Inst Technol, Woodruff Sch Mech Engn, 801 Ferst Dr, Atlanta, GA 30332 USA
[2] Georgia Inst Technol, Sch Mat Sci & Engn, Atlanta, GA 30332 USA
[3] Kumamoto Univ, Magnesium Res Ctr, Kumamoto, Japan
来源
PROCEEDINGS OF THE INSTITUTION OF MECHANICAL ENGINEERS PART C-JOURNAL OF MECHANICAL ENGINEERING SCIENCE | 2019年 / 233卷 / 11期
关键词
MTS; residual stress; machining; titanium; microstructure; modeling; CHIP FORMATION; PHASE-TRANSFORMATION; ALLOY; DEFORMATION; TEMPERATURE; SIMULATION;
D O I
10.1177/0954406218805122
中图分类号
TH [机械、仪表工业];
学科分类号
0802 ;
摘要
The material microstructure attributes are largely ignored in the machining community for the machining mechanics modeling. A physical-based mechanical threshold stress (MTS) model is proposed for the orthogonal turning application of Ti-6Al-4V material. The MTS model takes the material internal state variables, such as dislocation to dislocation interaction and dislocation/interstitial resistance, into the flow stress consideration. The MTS model is embedded into an analytical residual stress prediction model for machining induced residual stress prediction. The experimental data are provided for the model validation. The prediction generally captures the trend of the residual stress profile compared with experiments. The proposed model provides a microstructure insight of the workpiece material in the machining process modeling.
引用
收藏
页码:3743 / 3750
页数:8
相关论文
共 25 条
[1]  
Albrecht P., 1960, TRANSACTION ASME, P348
[2]   A new material model for 2D numerical simulation of serrated chip formation when machining titanium alloy Ti-6Al-4V [J].
Calamaz, Madalina ;
Coupard, Dorninique ;
Girot, Franck .
INTERNATIONAL JOURNAL OF MACHINE TOOLS & MANUFACTURE, 2008, 48 (3-4) :275-288
[3]   Modeling and simulation of the interaction of manufacturing process and machine tool structure in flycutting machining [J].
Chen, Wanqun ;
Sun, Yazhou ;
An, Chenhui ;
Su, Hao ;
Yang, Kai ;
Zhang, Qiang .
PROCEEDINGS OF THE INSTITUTION OF MECHANICAL ENGINEERS PART C-JOURNAL OF MECHANICAL ENGINEERING SCIENCE, 2015, 229 (15) :2730-2736
[4]   A universal slip-line model with non-unique solutions for machining with curled chip formation and a restricted contact tool [J].
Fang, N ;
Jawahir, IS ;
Oxley, PLB .
INTERNATIONAL JOURNAL OF MECHANICAL SCIENCES, 2001, 43 (02) :557-580
[5]   A CONSTITUTIVE DESCRIPTION OF THE DEFORMATION OF COPPER BASED ON THE USE OF THE MECHANICAL THRESHOLD STRESS AS AN INTERNAL STATE VARIABLE [J].
FOLLANSBEE, PS ;
KOCKS, UF .
ACTA METALLURGICA, 1988, 36 (01) :81-93
[6]   AN ANALYSIS OF THE LOW-TEMPERATURE, LOW AND HIGH STRAIN-RATE DEFORMATION OF TI-6AL-4V [J].
FOLLANSBEE, PS ;
GRAY, GT .
METALLURGICAL TRANSACTIONS A-PHYSICAL METALLURGY AND MATERIALS SCIENCE, 1989, 20 (05) :863-874
[7]   A comparative study on Johnson-Cook, modified Johnson-Cook and Arrhenius-type constitutive models to predict the high temperature flow stress in 20CrMo alloy steel [J].
He, An ;
Xie, Ganlin ;
Zhang, Hailong ;
Wang, Xitao .
MATERIALS & DESIGN, 2013, 52 :677-685
[8]   Manufacturing method of double-helical gears using CNC machining center [J].
Kawasaki, Kazumasa ;
Tsuji, Isamu ;
Gunbara, Hiroshi .
PROCEEDINGS OF THE INSTITUTION OF MECHANICAL ENGINEERS PART C-JOURNAL OF MECHANICAL ENGINEERING SCIENCE, 2016, 230 (7-8) :1149-1156
[9]   NEW OBSERVATIONS ON THE MECHANISM OF CHIP FORMATION WHEN MACHINING TITANIUM-ALLOYS [J].
KOMANDURI, R ;
VONTURKOVICH, BF .
WEAR, 1981, 69 (02) :179-188
[10]  
Kumar S., 1997, TRANSACTIONS-NORTH AMERICAN MANUFACTURING RESEARCH INSTITUTION OF SME, P33
123