Finite element analysis of chip formation and residual stresses induced by sequential cutting in side milling with microns to submicron uncut chip thickness and finite cutting edge radius

doi:10.1007/s40436-015-0128-z

Advances in Manufacturing ›› 2015, Vol. 3 ›› Issue (4): 309-322.doi: 10.1007/s40436-015-0128-z

Finite element analysis of chip formation and residual stresses induced by sequential cutting in side milling with microns to submicron uncut chip thickness and finite cutting edge radius

Nejah Tounsi¹, Tahany El-Wardany²

1 Open Manufacturing Solutions Inc., Pierrefonds, QC, Canada;
2 United Technologies Research Center, East-Hartford, CT, US

收稿日期:2015-05-10 修回日期:2015-10-30 出版日期:2015-12-25 发布日期:2015-12-07
通讯作者: Nejah Tounsi E-mail:nejah.tounsi@omasolutions.com

Finite element analysis of chip formation and residual stresses induced by sequential cutting in side milling with microns to submicron uncut chip thickness and finite cutting edge radius

Nejah Tounsi¹, Tahany El-Wardany²

1 Open Manufacturing Solutions Inc., Pierrefonds, QC, Canada;
2 United Technologies Research Center, East-Hartford, CT, US

Received:2015-05-10 Revised:2015-10-30 Online:2015-12-25 Published:2015-12-07
Contact: Nejah Tounsi E-mail:nejah.tounsi@omasolutions.com

摘要/Abstract

摘要： In this paper, the effect of four sequential cuts in side milling of Ti6Al4V on chip formation and residual stresses (RS) are investigated using finite element method (FEM). While the open literature is limited mainly to the studies of orthogonal sequential cutting with the constant uncut chip thickness greater than 0.01 mm, it is suggested herein to investigate not only the variable uncut chip thickness which characterises the down milling process, but also the uncut chip thickness in the sub-micron range using a finite cutting edge radius. For the resulting ductile machining regime, the characteristics of the chip morphology, the force profiles, the plastic deformation and temperature distributions have been analyzed. Furthermore, this study revealed that the RS should be extracted toward the area where the insert exits the workpiece in the FE simulation of the down-milling process. The simulation of a number of sequential cuts due to the consecutive engagements of the insert is required in order to capture the gradual accumulation of the RS before reaching an asymptotic convergence of the RS profile. The predicted RS are in reasonable agreement with the experimental results.

关键词: Finite element method (FEM), Down milling, Sequential cuts, Ductile machining regime, Chip formation, Residual stresses (RS)

Abstract: In this paper, the effect of four sequential cuts in side milling of Ti6Al4V on chip formation and residual stresses (RS) are investigated using finite element method (FEM). While the open literature is limited mainly to the studies of orthogonal sequential cutting with the constant uncut chip thickness greater than 0.01 mm, it is suggested herein to investigate not only the variable uncut chip thickness which characterises the down milling process, but also the uncut chip thickness in the sub-micron range using a finite cutting edge radius. For the resulting ductile machining regime, the characteristics of the chip morphology, the force profiles, the plastic deformation and temperature distributions have been analyzed. Furthermore, this study revealed that the RS should be extracted toward the area where the insert exits the workpiece in the FE simulation of the down-milling process. The simulation of a number of sequential cuts due to the consecutive engagements of the insert is required in order to capture the gradual accumulation of the RS before reaching an asymptotic convergence of the RS profile. The predicted RS are in reasonable agreement with the experimental results.

Key words: Finite element method (FEM), Down milling, Sequential cuts, Ductile machining regime, Chip formation, Residual stresses (RS)

Nejah Tounsi, Tahany El-Wardany. Finite element analysis of chip formation and residual stresses induced by sequential cutting in side milling with microns to submicron uncut chip thickness and finite cutting edge radius[J]. Advances in Manufacturing, 2015, 3(4): 309-322.

参考文献

1. Dehmani H, Salvatore F, Hamdi H (2013) Numerical study of residual stress induced by multi-steps orthogonal cutting. The 14th CIRP conference on modeling of machining operations, Turin

2. Zhao HW, Liu C, Cui T et al (2013) Influences of sequential cuts on micro-cutting process studied by smooth particle hydrodynamic (SPH). Appl Surf Sci 284:366-371

3. Schulze V, Osterried J, Strauß T et al (2012) Analysis of surface layer characteristics for sequential cutting operations. J Heat Treat Mater 67(6):347-356

4. Schulze V, Osterried J, Strauß T (2011) FE analysis on the influence of sequential cuts on component conditions for different machining strategies. Proc Eng 19:318-323

5. Li JL, Jing LL, Chen M (2009) An FEM study on residual stresses induced by high-speed end-milling of hardened steel SKD11. J Mater Process Technol 209(9):4515-4520

6. Outeiro JC, Umbrello D, M'Saoubi R (2006) Experimental and FEM analysis of cutting sequence on residual stresses in machined layers of AISI 316L steel. Mater Sci Forum 524-525:179-184

7. Ee KC, Dillon OW Jr, Jawahir IS (2005) Finite element modeling of residual stresses in machining induced by cutting using a tool with finite edge radius. Int J Mech Sci 47:1611-1628

8. Guo YB, Liu CR (2002) FEM analysis of mechanical state on sequentially machined surfaces. Int J Mach Sci Technol 6(1):21-41

9. Liu CR, Guo YB (2000) Finite element analysis of the effect of sequential cuts and tool-chip friction on residual stresses in a machined layer. Int J Mach Sci Technol 42:1069-1086

10. Sasahara H, Obikawa T, Shirakashi T (1996) FEM analysis of cutting sequence effect on mechanical characteristics in machined layer. J Mater Proc Technol 62:448-453

11. DEFORM 2D®. FEM software package, revision 10. Scientific Forming Technologies Corporation

12. Calamaz M, Coupard D, Girot F (2008) A new material model for 2D numerical simulation of serrated chip formation when machining titanium alloy Ti-6Al-4V. Int J Mach Tools Manuf 48:275-288

13. Calamaz M, Coupard D, Nouari M et al (2011) Numerical analysis of chip formation and shear localisation processes in machining the Ti-6Al-4V titanium alloy. Int J Adv Manuf Technol 52:887-895

14. Ozel T, Thepsonthi T, Ulutan D et al (2011) Experiments and finite element simulations on micro-milling of Ti-6Al-4V alloy with uncoated and CBN coated micro-tools. CIRP Ann Manuf Technol 60:85-88

15. Queheillalt DT, Choi BW, Schwartz DS et al (2000) Creep expansion of porous Ti-6Al-4V sandwich structures. Metall Mater Trans A 31:261-273

16. Chen L, El-Wardany TI, Harris WC (2004) Modelling the effects of flank wear land and chip formation on residual stresses. CIRP Ann 53(1):95-98

17. Alvarez R, Domingo R, Sebastian MA (2011) The formation of saw toothed chip in a titanium alloy: influence of constitutive models. J Mech Eng 57:739-749

18. Özel T, Sima M, Srivastava AK (2010) Finite element simulation of high speed machining Ti-6Al-4V alloy using modified material models. Trans NAMRI/SME 38:49-56

19. Matsumoto Y, Barash MM, Liu CR (1986) Effects of hardness on the surface integrity of AISI 4340 steel, ASME. J Eng Ind 108:169-175

20. Wu DW, Matsumoto Y (1990) The effect of hardness on residual stresses in orthogonal machining of AISI 4340 steel. J Eng Ind 112(3):245-252

[1]	Jin-Shi Wang, Xiao-Dong Zhang, Feng-Zhou Fang. Numerical study via total Lagrangian smoothed particle hydrodynamics on chip formation in micro cutting[J]. Advances in Manufacturing, 2020, 8(2): 144-159.
[2]	Gergely Gyebrószki, Daniel Bachrathy, Gábor Csernák, Gabor Stepan. Stability of turning processes for periodic chip formation[J]. Advances in Manufacturing, 2018, 6(3): 345-353.
[3]	A. Ducato, G. Buffa, L. Fratini, R. Shivpuri. Dual phase titanium alloy hot forging process design: experiments and numerical modeling[J]. Advances in Manufacturing, 2015, 3(4): 269-281.
[4]	D. Biermann, H. Abrahams, M. Metzger. Experimental investigation of tool wear and chip formation in cryogenic machining of titanium alloys[J]. Advances in Manufacturing, 2015, 3(4): 292-299.

Finite element analysis of chip formation and residual stresses induced by sequential cutting in side milling with microns to submicron uncut chip thickness and finite cutting edge radius

Finite element analysis of chip formation and residual stresses induced by sequential cutting in side milling with microns to submicron uncut chip thickness and finite cutting edge radius

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 4

编辑推荐

Metrics

本文评价