Analytical Modeling to Predict Adiabatic Shear Critical Condition for Orthogonal Cutting

Qi Biao Yang; Zhan Qiang Liu; Zhen Yu Shi

doi:10.4028/www.scientific.net/MSF.723.41

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HomeMaterials Science ForumMaterials Science Forum Vol. 723Analytical Modeling to Predict Adiabatic Shear...

Analytical Modeling to Predict Adiabatic Shear Critical Condition for Orthogonal Cutting

Abstract:

As the deformation of chip increases with cutting speed, the morphology of chip changes from continuous to serrated type. It is supposed that serrated chips generate due to adiabatic shear instability in the primary deformation zone. A new analytical model for predicting adiabatic shear critical condition in orthogonal cutting is proposed by considering cutting conditions and properties of workpiece material. It is found that the influence of shear strain on the onset of adiabatic shear could be neglected. The shear strain rate and temperature, however, play a leading role on the onset of adiabatic shear. At lower cutting speed the shear strain rate plays a dominant role while at higher cutting speed the situation is just the reverse. With the increase of cutting speed, the yield stress, material characteristic constant and uncut chip thickness will facilitate adiabatic shear instability, while the coefficient of strain rate hardening, coefficient of strain hardening, coefficient of thermal softening, thermal diffusivity and tool rake angle have negative effect on adiabatic shear instability.

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Periodical:

Materials Science Forum (Volume 723)

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41-49

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https://doi.org/10.4028/www.scientific.net/MSF.723.41

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Online since:

June 2012

Authors:

Qi Biao Yang, Zhan Qiang Liu, Zhen Yu Shi

Keywords:

Adiabatic Shear, Critical Condition, Orthogonal Cutting, Ti6Al4V

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References

[1] G. Li, M. Wang and C. Duan: J. Mater. Process. Technol. Vol. 209 (2009), p.1362.

Google Scholar

[2] H. Schulz, E. Abele and A. Sahm: CIRP Ann. Manuf. Technol. Vol. 50 (2001), p.45.

Google Scholar

[3] B. John and B. Gerald: J. Manuf. Sci. Eng. Vol. 124 (2002), p.528.

Google Scholar

[4] A. Molinari, C. Musquar and G. Sutter: Int. J. Plast. Vol. 18 (2002), p.443.

Google Scholar

[5] R. Komaduri and Z. Hou: Metall. Mater. Trans. A Vol. 33A (2002), p.2995.

Google Scholar

[6] M.D. Morehead, Y. Huang and J. Luo: Mach. Sci. Technol. Vol. 11 (2007), p.335.

Google Scholar

[7] R.F. Recht: J. Appl. Mech. Vol. 31 (1964), p.189.

Google Scholar

[8] D. Lee: J. Eng. Mater. Technol. Vol. 106 (1984), p.9.

Google Scholar

[9] J.Q. Xie, A.E. Bayoumi and H.M. Zbib: J. Mater. Eng. Perform. Vol. 4 (1995), p.32.

Google Scholar

[10] J. Huang, K. Kalaitzidou, J.W. Sutherland et al: J. Mech. Behav. Mater. Vol. 18 (2007), p.243.

Google Scholar

[11] N. Tounsi, J. Vincenti, A. Otho et al: Int. J. Mach. Tools Manuf. Vol. 42 (2002), p.1373.

Google Scholar

[12] P.L.B. Oxley: The mechanics of machining: an analytical approach to assessing machinability (Halsted Press, USA 1989).

Google Scholar

[13] A. O. Tay, M.G. Stevenson, G.D.V. Davis et al: Int. J. Mach. Tool Des. Res. Vol. 16 (1976), p.335.

Google Scholar

[14] E.G. Loewen and M.C. Shaw: Trans. ASME Vol. 76 (1954), p.217.

Google Scholar

[15] Z. Liu, J. Wu, Z. Shi et al: Tool Eng. Vol. 42 (2008), p.3.

Google Scholar

[16] X. Ai: Technology of high speed cutting (National Defense Industrial Press, Beijing 2003).

Google Scholar

[17] R. Komaduri and V.B.F. Turkovich: Wear Vol. 69 (1981), p.179.

Google Scholar