On the influence of kinematic hardening on plastic anisotropy in the context of finite strain plasticity
Tóm tắt
The paper discusses the application of a newly developed material model for finite anisotropic plasticity to the simulation of earing formation in cylindrical cup drawing. The model incorporates Hill-type plastic anisotropy, nonlinear kinematic and nonlinear isotropic hardening. The constitutive framework is derived in the context of continuum thermodynamics and represents a multiplicative formulation of anisotropic elastoplasticity in the finite strain regime. Plastic anisotropy is described by means of second-order structure tensors which are used as additional tensor-valued arguments in the representation of the yield criterion and the plastic flow rule. The evolution equations are integrated by a form of the exponential map that fullfils plastic incompressibility and preserves the symmetry of the internal variables. The numerical examples investigate the influence of the hardening behaviour on an initially anisotropic yield criterion. In particular, the influence of using the kinematic hardening component of the model in addition to isotropic hardening in the earing simulations is examined. Comparisons with test data for aluminium and steel sheets display a good agreement between the finite element results and the experimental data.
Tài liệu tham khảo
Hill R (1948) A theory of the yielding and plastic flow of anisotropic metals. Proc R Soc Lond A193:281–297
Hill R (1993) A user-friendly theory of orthotropic plasticity in sheet metals. Int J Mech Sci 35:19–25
Barlat F, Yoon JW, Cazacu O (2007) On linear transformations of stress tensors for the description of plastic anisotropy. Int J Plast 23:876–896
Cazacu O, Plunkett B, Barlat F (2006) Orthotropic yield criterion for hexagonal closed packed metals. Int J Plast 22:1171–1194
Li S, Hoferlin E, Van Bael A, Van Houtte P, Teodosiu C (2003) Finite element modelling of plastic anisotropy induced by texture and strain-path change. Int J Plast 19:647–674
Van Houtte P, Kanjarla AK, van Bael A, Seefeldt M, Delannay L (2006) Multiscale modelling of the plastic anisotropy and deformation texture of polycrystalline materials. Eur J Mech A Solids 25:634–648
Böhlke T, Risy G, Bertram A (2008) A micro-mechanically based quadratic yield condition for textured polycrystals. Z Angew Math Mech 88:379–387
Miehe C, Apel N, Lambrecht M (2002) Anisotropic additive plasticity in the logarithmic strain space: modular kinematic formulation and implementation based on incremental minimization principles for standard materials. Comput Methods Appl Mech Eng 191:5383–5425
Miehe C, Apel N (2004) Anisotropic elastic-plastic analysis of shells at large strains. A comparison of multiplicative and additive approaches to enhanced finite element design and constitutive modelling. Int J Numer Methods Eng 61:2067–2113
Papadopoulos P, Lu J (2001) On the formulation and numerical solution of problems in anisotropic finite plasticity. Comput Methods Appl Mech Eng 190:4889–4910
Schröder J, Gruttmann F, Löblein J (2002) A simple orthotropic finite elasto-plasticity model based on generalized stress-strain measures. Comput Mech 30:48–64
Eidel B, Gruttmann F (2003) Elastoplastic orthotropy at finite strains: multiplicative formulation and numerical implementation. Comput Mater Sci 28:732–742
Menzel A, Steinmann P (2003) On the spatial formulation of anisotropic multiplicative elastoplasticity. Comput Methods Appl Mech Eng 192:3431–3470
Sansour C, Karsaj I, Soric J (2006) A formulation of anisotropic continuum elastoplasticity at finite strains. Part I: modelling. Int J Plast 22:2346–2365
Sansour C, Karsaj I, Soric J (2007) On anisotropic flow rules in multiplicative elastoplasticity at finite strains. Comput Methods Appl Mech Eng 196:1294–1309
Sansour C, Karsaj I, Soric J (2008) On a numerical implementation of a formulation of anisotropic continuum elastoplasticity at finite strains. J Comput Phys 227:7643–7663
Harryson M, Ristinmaa M (2007) Description of evolving anisotropy at large strains. Mech Mater 39:267–282
Bacroix B, Gilormini P (1995) Finite-element simulations of earing in polycrystalline materials using a texture-adjusted strain-rate potential. Model Simul Mater Sci Eng 3:1–21
Nakamachi E, Xie CL, Harimoto M (2001) Drawability assessment of BCC steel sheet by using elastic/crystalline viscoplastic finite element analyses. Int J Mech Sci 43:631–652
Duchêne L, Habraken AM (2005) Analysis of the sensitivity of FEM predictions to numerical parameters in deep drawing simulations. Eur J Mech A Solids 24:614–629
Raabe D, Roters F (2004) Using texture components in crystal plasticity finite element simulations. Int J Plast 20:339–361
Zhao Z, Mao W, Roters F, Raabe D (2004) A texture optimization study for minimum earing in aluminium by use of a texture component crystal plasticity finite element method. Acta Mater 52:1003–1012
Raabe D, Wang Y, Roters F (2005) Crystal plasticity simulation study on the influence of texture on earing in steel. Comput Mater Sci 34:221–234
Barlat F, Lian J (1989) Plastic behavior and stretchability of sheet metals. Part I: a yield function for orthotropic sheets under plane stress conditions. Int J Plast 5:51–66
Barlat F, Maeda Y, Chung K, Yanagawa M, Brem JC, Hayashida Y, Lege DJ, Matsui K, Murtha SJ, Hattori S, Becker RC, Makosey S (1997) Yield function development for aluminum alloy sheets. J Mech Phys Solids 45:1727–1763
Barlat F, Brem JC, Yoon JW, Chung K, Dick RE, Lege DJ, Pourboghrat F, Choi SH, Chu E (2003) Plane stress yield function for aluminum alloy sheetspart 1: theory. Int J Plast 19:1297–1319
Barlat F, Aretz H, Yoon JW, Karabin ME, Brem JC, Dick RE (2005) Linear transfomation-based anisotropic yield functions. Int J Plast 21:1009–1039
Yoon JW, Barlat F, Chung K, Pourboghrat F, Yang DY (1998) Influence of initial back stress on the earing prediction of drawn cups for planar anisotropic aluminum sheets. J Mater Process Technol 80–81:433–437
Yoon JW, Barlat F, Chung K, Pourboghrat F, Yang DY (2000) Earing predictions based on asymmetric nonquadratic yield function. Int J Plast 16:1075–1104
Yoon JW, Barlat F, Dick RE, Chung K, Kang TJ (2004) Plane stress yield function for aluminum alloy sheetspart II: FE formulation and its implementation. Int J Plast 20:495–522
Yoon JW, Barlat F, Dick RE, Karabin ME (2006) Prediction of six or eight ears in a drawn cup based on a new anisotropic yield function. International Journal of Plasticity 22:174–193
Soare S, Yoon JW, Cazacu O (2008) On the use of homogeneous polynomials to develop anisotropic yield functions with applications to sheet forming. Int J Plast 24:915–944
Ahn DC, Yoon JW, Kim KY (2009) Modeling of anisotropic plastic behavior of ferritic stainless steel sheet. Int J Mech Sci 51:718–725
Moreira LP, Ferron G, Ferran G (2000) Experimental and numerical analysis of the cup drawing test for orthotropic metal sheets. J Mater Process Technol 108:78–86
Kishor N, Ravi Kumar D (2002) Optimization of initial blank shape to minimize earing in deep drawing using finite element method. J Mater Process Technol 130–131:20–30
Miehe C, Schotte J (2004) Anisotropic finite elastoplastic analysis of shells: simulation of earing in deep-drawing of single- and polycrystalline sheets by Taylor-type micro-to-macro transitions. Comput Methods Appl Mech Eng 193:25–57
Engler O, Kalz S (2004) Simulation of earing profiles from texture data by means of a visco-plastic self-consistent polycrystal plasticity approach. Mater Sci Eng A 373:350–362
Engler O, Hirsch J (2007) Polycrystal-plasticity simulation of six and eight ears in deep-drawn aluminum cups. Mater Sci Eng A 452–453:640–651
Tikhovskiy I, Raabe D, Roters F (2007) Simulation of earing during deep drawing of an Al3% Mg alloy (AA 5754) using a texture component crystal plasticity FEM. J Mater Process Technol 183:169–175
Tikhovskiy I, Raabe D, Roters F (2008) Simulation of earing of a 17% Cr stainless steel considering texture gradients. Mater Sci Eng A 488:482–490
Rabahallah M, Bouvier S, Balan T, Bacroix B (2009) Numerical simulation of sheet metal forming using anisotropic strain-rate potentials. Mater Sci Eng A 517:261–275
Banabic D, Aretz H, Comsa DS, Paraianu L (2005) An improved analytical description of orthotropy in metallic sheets. Int J Plast 21:493–512
Chun BK, Kim HY, Lee JK (2002) Modeling the Bauschinger effect for sheet metals, part II: applications. Int J Plast 18:597–616
Choi Y, Han C-S, Lee JK, Wagoner RH (2006) Modeling multi-axial deformation of planar anisotropic elasto-plastic materials, part II: applications. Int J Plast 22:1765–1783
Thuillier S, Manach PY, Menezes LF (2010) Occurrence of strain path changes in a two-stage deep drawing process. J Mater Process Technol 210:226–232
Vladimirov IN, Pietryga MP, Reese S (2008) On the modelling of non-linear kinematic hardening at finite strains with application to springback - Comparison of time integration algorithms. Int J Numer Methods Eng 75:1–28
Vladimirov IN, Pietryga MP, Reese S (2010) Anisotropic finite elastoplasticity with nonlinear kinematic and isotropic hardening and application to sheet metal forming. Int J Plast 26:659–687
Frederick CO, Armstrong PJ (2007) A mathematical representation of the multiaxial Bauschinger effect. Mater High Temp 24:1–26
Lion A (2000) Constitutive modelling in finite thermoviscoplasticity: a physical approach based on nonlinear rheological models. Int J Plast 16:469–494
Chaboche JL (2008) A review of some plasticity and viscoplasticity constitutive theories. Int J Plast 24:1642–1693
Schwarze M, Reese S (2009) A reduced integration solid-shell finite element based on the EAS and the ANS concept—geometrically linear problems. Int J Numer Methods Eng 80:1322–1355
Vladimirov IN, Pietryga MP, Reese S (2009) Prediction of springback in sheet forming by a new finite strain model with nonlinear kinematic and isotropic hardening. J Mater Process Technol 209:4062–4075