Numerical Prediction of Springback and Side-Wall Curl in U-Bending of Anisotropic Sheet Metals

Mehran Kadkhodayan

doi:10.4028/www.scientific.net/KEM.274-276.583

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Investigation of the Flange Earring of Deep-Drawing Aluminum Sheets by Rate-Independent Polycrystalline Plasticity Finite Element Analysis
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Wear Simulation Based on Node-to-Segment Element
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Numerical Prediction of Springback and Side-Wall Curl in U-Bending of Anisotropic Sheet Metals
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Numerical Prediction of Springback and Side-Wall Curl in U-Bending of Anisotropic Sheet Metals

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Key Engineering Materials (Volumes 274-276)

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583-588

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https://doi.org/10.4028/www.scientific.net/KEM.274-276.583

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October 2004

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Mehran Kadkhodayan

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Anisotropic Sheet Metal, Side-Wall Curl, Springback, U-Bending

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References

[1] L. Taylor, J. Cao, A.P. Karafillis, A.P. and M.C. Boyce: J. Mater. Process. Tech. Vol. 50 (1995), p.168.

Google Scholar

[2] K. Mattiasson, A. Strange, P. Thilderkvist and A. Samuelsson: NUMIFORM 95 (1995), p.115.

Google Scholar

[3] F. Pourboghrat and E. Chu: Int. J. Mech. Sci. Vol. 36(3) (1995), p.327.

Google Scholar

[4] D. Joannic and J.C. Gelin: NUMIFORM 95 (1995), p.729.

Google Scholar

[5] F. Pourboghrat and E. Chu: J. Mats. Proc. Tech. Vol. 50 (1995), p.361.

Google Scholar

[6] P. Apostolos, M. Karafillis and C. Boyce: Int. J. Mach. Tools Manufact. Vol. 36(4 ) (1996), p.503.

Google Scholar

[7] D. Zhou, S. Sriram, A. Jinka, and R.H. Wagoner: Engineering Systems Design and Analysis, New York, ASME Vol. 3 (1996), p.135.

Google Scholar

[8] D.K. Leu: J. Mats. Proc. Tech. Vol. 66 (1997), p.9.

Google Scholar

[9] F. Pourboghrat, K. Chung and O. Richmand: J. Appl. Mech. Vol. 65 (1998), p.671.

Google Scholar

[10] F. Pourboghrat, M. Karabin, R. Becker and K. Chung: Int. J. Plasticity Vol. 16 (2000), p . 677.

Google Scholar

[11] S. Siriram and R.H. Wagoner: Int. J. Mech. Sci. Vol. 42 (2000), p.1753.

Google Scholar

[12] S.W. Lee and D.Y. Yang: J. Mater. Proc. Tech. Vol. 80-81 (1998), p.60.

Google Scholar

[13] G.Y. Li, M.J. Tan and K.M. Liews: Int. J. Solid Struc. Vol. 36 (1999), p.4653.

Google Scholar

[14] M. Samuel: J. Mats. Proc. Tech. Vol. 105 (2000), p.382.

Google Scholar

[15] G. Liu, Z. Lin, W. Xu. and Y. Bao: J. Mats. Proc. Tech. Vol. 120 (2002), p.259.

Google Scholar

[16] ELFEN Level 3. 0. 3 Manual and Worked Examples, Rockfield Software Ltd., University of Wales Swansea, Swansea (1998).

Google Scholar

[17] R. Hill, The Mathematical Theory of Plasticity, The Oxford University Press, Oxford, London (1998).

Google Scholar

[18] D.R. Owen and E. Hinton, Finite Element in Plasticity: Theory and Practice. Pineridge Press Limited, U.K. (1980).

Google Scholar