Engineering Transactions

Engineering Transactions, 55, 3, pp. 197–216, 2007
10.24423/engtrans.217.2007

Two severe plastic deformation (SPD) processing techniques, namely equal-channel angular pressing (ECAP) and cyclic extrusion-compression (CEC), are investigated by using the finite element method. The major aspect examined is the non-uniformity of the accumulated, equivalent plastic strain after processing with the use of different shapes of the die. The quantitative effect of several parameters on the plastic flow is determined. It is found that the diameter ratio of the chambers and narrower channel in the CEC method, and also the inclination angle of connecting conical parts, can affect strongly the degree of strain non-uniformity. Comparison is made of distributions of equivalent strain after two passes of ECAP for two different routes and with two die profiles.

Copyright © Polish Academy of Sciences & Institute of Fundamental Technological Research (IPPT PAN).

V.M. Segal, Materials processing by simple shear, Mater. Sci. Eng. A, 197, 157–164, 1995.

R.Z. Valiev, T.G. Langdon, Principles of equal-channel angular pressing as a processing tool for grain refinement, Progress in Materials Science, 51, 881–981, 2006.

J. Richert, M. Richert, A new method for unlimited deformation of metals and alloys, Aluminium, 8, 604–607, 1986.

M. Richert, A. Korbel, The Effect of strain localization on mechanical properties of Al99,992 in the range of large deformations, J. Mater. Proc. Technol., 53, 331–340, 1995.

M. Richert, J. Richert, J. Zasadzinski, H. Dybiec, The boundary strain hardening of aluminium with unlimited cumulation of large deformation, Z. Metallkd., 79, 741, 1988.

M. Richert, Q. Liu, N. Hansen, Microstructural evolution over a large strain range in aluminium deformed by cyclic extrusion–compression, Materials Science and Engineering A, 260, 275–283, 1999.

M. Richert, H.P. Stuwe, M.J. Zehetbauer, J. Richert, R. Pippan, Ch. Motz, E. Schafler, Work hardening and microstructure of AlMg5 after severe plastic deformation by cyclic extrusion and compression, Materials Science and Engineering A, 355, 180–185, 2003.

L. Dupuy, E.F. Rauch, Deformation paths related to equal channel angular extrusion, Materials Science and Engineering A, 337, 241–247, 2002.

I.J. Beyerlein, C.N. Tome, Analytical modeling of material flow in equal channel angular extrusion (ECAE), Materials Science and Engineering A, 380, 171–190, 2004.

C. Liu, D.J. Alexander, A kinematic analysis of the angular extrusion (AE) operations Materials Science and Engineering A, 391, 198–209, 2005.

V.M. Segal, Equal channel angular extrusion: from macromechanics to structure formation, Materials Science and Engineering A, 271, 322–333, 1999.

V.M. Segal, Slip line solutions, deformation mode and loading history during equal channel angular extrusion, Materials Science and Engineering A 345, 36–46, 2003.

J. Alkorta, J.G. Sevillano, A comparison of FEM and upper-bound type analysis of equal-channel angular pressing (ECAP), Journal of Materials Processing Technology, 141, 313–318, 2003.

B.S. Altan, G. Purcek, I. Miskioglu, An upper-bound analysis for equal-channel angular extrusion, Journal of Materials Processing Technology, 168, 137–146, 2005.

P.B. Prangnell, C. Harris, S.M. Roberts, Finite element modelling of equal-channel angular extrusion, Scripta Mater., 37, 983–989, 1997.

H.S. Kim, M.H. Seo, S.I. Hong, On the die corner gap formation in equal channel angular pressing, Materials Science and Engineering A, 291, 86–90, 2000.

A. Rosochowski, R. Rodiet, P. Lipinski, Finite element simulation of cyclic extrusion-compression, Metal Forming 2000, Pietrzyk et al. [Eds.], 253–259, 2000.

A. Rosochowski, L. Olejnik, Numerical and physical modelling of plastic deformation in 2-turn equal channel angular extrusion, Journal of Materials Processing Technology, 125–126, 309–31, 2002.

C.J. Luis Pérez, P. González, Y. Garcés, Equal channel angular extrusion in a commercial Al–Mn alloy, Journal of Materials Processing Technology, 143–144, 506–511, 2003.

S. Li, M.A.M. Bourke, I.J. Beyerlein, D.J. Alexander, B. Clausen, Finite element analysis of the plastic deformation zone and working load in equal channel angular extrusion, Materials Science and Engineering A, 382, 217–236, 2004.

F. Yang, A. Saran, K. Okazaki, Finite element simulation of equal channel angular extrusion, Journal of Materials Processing Technology, 166, 71–78, 2005.

R.K. Oruganti, P.R. Subramanian, J.S. Marte, M.F. Gigliotti, S. Amancherla, Effect of friction, backpressure and strain rate sensitivity on material flow during equal channel angular extrusion, Materials Science and Engineering A, 406, 102–109, 2005.

A.V. Nagasekhar, Yip Tick-Hon, S. Li, H.P. Seow, Stress and strain histories in equal channel angular extrusion/pressing, Materials Science and Engineering A, 423, 143–147, 2006.

ADINA R&D Inc. ADINA, Theory and Modeling Guides, Reports ARD 05–7, 2005.

N.Q. Chinh, J. Illy, Z. Horita, T. G. Langdon, Using the stress–strain relationships to propose regions of low and high temperature plastic deformation in aluminum, Materials Science and Engineering A, 410–411, 234–238, 2005.

Y. Iwahashi, Z. Horita, M. Nemoto, T.G. Langdon, Factors influencing the equilibrium grain size in equal-channel angular pressing: Role of Mg additions to aluminum, Metall. Mater. Trans., 29A, 2503–2510, 1998.

S. Komura, Z. Horita, M. Nemoto, T.G. Langdon, Influence of stacking fault energy on the development of microstructure in equal-channel angular pressing, Journal of Materials Research, 14, 4044–4050, 1999.

A.V. Nagasekhar, T.H. Yip, Optimal tool angles for equal channel angular extrusion of strain hardening materials by finite element analysis, Computat Mater. Sci., 489–495, 2004.

J.R. Bowen, A. Gholinia, S.M. Roberts, P.B. Prangnell, Analysis of the billet deformation behaviour in equal channel angular extrusion, Materials Science and Engineering A, 287, 87–97, 2000.