Finite deformation plasticity often involves the multiplicative split of the deformation gradient into an elastic and plastic part. Motivated by observations in physics, the plastic part is assumed to be volume preserving, i.e., the plastic part of the deformation gradient is unimodular. In order to not accumulate errors, in the best case, one fulfills this constraint exactly to obtain accurate results (see, e.g., [3]). While other approaches where pursued as well, many authors therefore adopted the use of the exponential map, which is a geometric integrator preserving the plastic incompressibility. However, it's computation is not straightforward and performing the eigenvalue decomposition and it's linearization for the exponential function is numerically elaborate. Therefore, in this work, a new approach which also exactly preserves the incompressibility constraint is developed. It makes use of a projection of all symmetric tensors onto the manifold of unimodular tensors. The proposed method is compared to models utilizing the exponential map in numerical experiments

Dittmann, Jan

Sielenkämper, Marian

Wulfinghoff, Stephan

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14th World Congress on Computational Mechanics (WCCM)ECCOMAS Congress 2020)Virtual Congress: 11-–15 January 2021F. Chinesta, R. Abgrall, O. Allix and M. Kaliske (Eds)ON A PROJECTION METHOD FOR THE NUMERICALINTEGRATION OF CONSTITUTIVE EQUATIONS INVOLVINGLARGE INELASTIC AND INCOMPRESSIBLE DEFORMATIONSMarian Sielenkämper1, Jan Dittmann1 and Stephan Wulfinghoff11 CAU KielKaiserstr. 2, 24143 Kiel, Germany{mfs,jd,swu}@tf.uni-kiel.deKey words: Inelasticity, Finite Deformation Plasticity, Kinematic Hardening, Projection Method, In-compressibility ConstraintAbstract. Finite deformation plasticity often involves the multiplicative split of the deformation gradientinto an elastic and plastic part. Motivated by observations in physics, the plastic part is assumed tobe volume preserving, i.e., the plastic part of the deformation gradient is unimodular. In order to notaccumulate errors, in the best case, one fulfills this constraint exactly to obtain accurate results (see,e.g., [3]). While other approaches where pursued as well, many authors therefore adopted the use of theexponential map, which is a geometric integrator preserving the plastic incompressibility. However, it’scomputation is not straightforward and performing the eigenvalue decomposition and it’s linearizationfor the exponential function is numerically elaborate. Therefore, in this work, a new approach whichalso exactly preserves the incompressibility constraint is developed. It makes use of a projection of allsymmetric tensors onto the manifold of unimodular tensors. The proposed method is compared to modelsutilizing the exponential map in numerical experiments.1 INTRODUCTIONNowadays in finite plasticity modeling, many models make use of the multiplicative split of the defor-mation gradient into an elastic and plastic part, which was introduced by [1, 2]. This split is depicted inFigure 1, where the initial configuration is deformed by the plastic deformation gradient Fp, yielding theintermediate configuration. Next, the intermediate configuration is deformed by the elastic deformationgradient Fe, yielding the current configuration. To incorporate kinematic hardening into the model, weemploy a further split of Fp, which was pursued by [4] (see also [5]). Due to observations from physics,one assumes Fp to be unimodular, i.e., det(Fp) = 1. In many works, this is dealt with by using theexponential map as a geometric integrator, which exactly preserves the incompressibility of the plasticdeformations (see, e.g., [6, 7, 5] among many others). In this work however, we employ a projectionmethod which also intrinsically ensures the plastic incompressibility.1Marian Sielenkämper, Jan Dittmann and Stephan WulfinghoffFeFFpB0BdvdVFigure 1: Multiplicative split of the deformation gradient. Reference configuration on the left, interme-diate configuration at the bottom center and the current configuration on the right.2 Theory of the model2.1 KinematicsAs specified in the introduction, this model pursues the multiplicative split of the deformation gradient,i.e.,F = FeFp. (1)This allows to introduce the left elastic and right inelastic Cauchy-Green tensorsbe = FeFeT, Cp = FpTFp. (2)Further, in analogy to [4], we split the plastic deformation gradient as followsFp = FpeFpd. (3)Here, Fpe is the energetic part and Fpd is the dissipative part of Fp. This definition allows to define adissipative stretch Cpd asCpd = FpdTFpd. (4)Additionally, the Kirchhoff stress tensorτ = Jσ = FeSeFeT (5)can be given in terms of the Cauchy stress σ and the Jacobi determinant J or the second Piola-Kirchoffstress tensor Se. Finally, we can define bpe as the plastic energetic left Cauchy-Green tensor defined viabpe = FpeFpeT. (6)2.2 Contributions to the Helmholtz free energyFor the elastic contribution, a Neo-Hookean elastic energy is assumed in the form ofψe(be) =λ4(Je2−1−2ln(Je))+µ2(Ibe−3−2ln(Je)) (7)2Marian Sielenkämper, Jan Dittmann and Stephan Wulfinghoffwhere Ibe denotes the first invariant of be, J = det(F) and λ and µ are Lamé parameters. Further, for theisotropic hardening, we assume a Voce-type hardening in the form ofψh = H(α+exp(−βα)β), (8)where H and β are material parameters and α is the equivalent plastic strain. The kinematic hardeningenergy ψk is taken to beψk = µpCp : Cpd−1, (9)where µp is is a material constant. The dissipation potential is taken to beφ ={√23 σy0‖Dp‖; if tr(Dp) = 0∞ ; else,(10)where Dp is the symmetric part of the plastic velocity gradient and σy0 is the initial yield stress. Next,the flow rule and yield criterion readDp = γ∂ f∂Σe, (11)andf = ‖(Σe−Σb)′‖−√23(σy0 +q)≤ 0. (12)Here, Σe is the Mandel stress w.r.t. the intermediate configuration and Σb is the Mandel back stressdefined viaΣe =CeSe, Σb = 2FpeT∂ψk∂bpeFpe. (13)With all the energetic contributions defined, the full rate potential readsπ = ψ̇e(be)+ ψ̇h(α)+φ+µpCpd−1 : Ċp. (14)2.3 Treatment of the incompressibility constraintIn finite strain plasticity, it is important to fulfill the plastic incompressibility with high accuracy to notaccumulate errors (see, e.g., [3]). Therefore, we introduce an unconstrained counterpart Ĉp to Cp suchthatCp =(det(Ĉp))− 13 Ĉp. (15)Here, Ĉp is a positive definite symmetric but otherwise arbitrary tensor. This intrinsically ensures theunimodularity of Cp by only taking the unimodular part of Ĉp, which is depicted in Fig.2. In analogy, areparametrization for Cpd is introduced asCpd =(det(Ĉpd))− 13 Ĉpd. (16)Further, a Frederick-Armstron type hardening law is assumed. Therefore, Cpd is dependent on the plasticmultiplier γ viaĈpd =Cpdn +2∆γbcΣbn′. (17)3Marian Sielenkämper, Jan Dittmann and Stephan WulfinghoffĈpdVdet(Ĉp)−13 ICp = det(Ĉp)−13 ĈpFigure 2: Reference volume on the left gets stretched by Ĉp. Thereafter, it is volumetrically stretchedback to its original volume by det(Ĉp)−13 I, rendering Cp unimodular.2.4 Algorithmic counterpart to φTo minimize the potential from Eq. 14, we need to find an algorithmic counterpart φ∆, which is time-discrete and φ∆/∆t converges towards φ with ∆t→ 0. A possible choice isφ∆ ={12√23 σy0‖cp− I‖ ; if det(cp) = 1∞ ; else. (18)Here, cp can be interpreted as the plastic push-forward of Cp and is defined ascp = Fpn−TCpFpn−1. (19)2.5 Differentiability at ∆Cp = 0When trying to minimize the potential using a Newton scheme, one needs to differentiate it with re-spect to the internal variables. However, in it’s current form, it is not differentiable at ∆Cp = 0, whichcomplicates the numeric solution. Therefore, a further reparametrization is introduced asĈp = I +2∆γNp. (20)Here, Np is a symmetric tensor with the constraints ‖Np‖= 1 and ∆γ≥ 0. Now, it can be easily verifiedthat the potential is differentiable at ∆Cp = 0.2.5.1 Removing the constraint ‖Np‖= 1The goal when introducing the projection was to drop the incompressibility constraint. However, throughremoving it, we added the further constraint ‖Np‖ = 1. To finally remove all constraint from the mini-mization problem, we introduce one last reparametrizationNp =Ñp‖Ñp‖. (21)Here, Ñp is a symmetric, but otherwise arbitrary tensor. Obviously, the constraint is now gone.4Marian Sielenkämper, Jan Dittmann and Stephan Wulfinghoff2.5.2 Preventing singularitiesAs the observant reader might have already noticed, through reparametrizing the potential became in-variant w.r.t. change in det(Ĉp) and ‖Ñp‖. For det(Ĉp), this is depicted in Figure 3. Here, it is clearĈpdet(Ĉp)−13 ICp = det(Ĉp)−13 ĈpFigure 3: Changing the volumetric part of Ĉp does not change the resulting Cp.that changing the volumetric part of Ĉp does not induce any changes in the resulting Cp. Likewise, thisis the case for ‖Np‖, which renders the system matrix ∂2π/∂z2 singular. Here, z is the vector of internalvariables. To overcome this singularity, an artificial regularization energy πR is introduced asπR =12A(( ÎIIp−1)2 +(‖Ñp‖−1)2). (22)This term may be interpreted as a spring with spring constant A pulling IIIp and ‖Ñp‖ towards 1. Here,it has to be noted that choosing A is arbitrary, since it won’t have an influence on the final solution.This is due to the fact, that since the potential is, apart from the regularization energy, free of IIIp and‖Ñp‖. Therefore, the regularization energy is always 0 at the minimum. Further, this means that whileπR allows us to find the solution by removing the singularity, it has no influence on the final solution.Now, in the results section, we minimize the potentialΠ =∫B(ψe +ψh + ψ̃k +φ∆ +πR)dV. (23)3 ResultsTo verify the results of the presented algorithm, they are compared to a necking of a circular bar examplefrom [6]. The distribution of the equivalent plastic strains for the deformed bar are shown in Fig. 4.Additionally, the material parameters used in the finite element model are given in Tab. 1. Further, theconvergence of the proposed method was analyzed with respect to the amount of time steps. Therefore,the necking displacement is plotted against the elongation in Fig. 5. Here, one can see the solution isconverging against roughly 3.75mm. For already 30 time steps, it is fairly close to the converged solution.Additionally, the resulting necking displacements are very close to the ones from [6].5Marian Sielenkämper, Jan Dittmann and Stephan WulfinghoffFigure 4: Distribution of the equivalent plasticstrain α over the deformed bar after loading.-4-3.5-3-2.5-2-1.5-1-0.5 0 0  1  2  3  4  5  6  7Necking disp. [mm]Elongation [mm]305010025050010002000Figure 5: Convergence of the necking displacementvs. Elongation for varying amount of time steps.κ [MPa] µ [MPa] σy0 [MPa] σy∞ [MPa] β H [MPa]164210 80193.8 450 715 16.93 129.24Table 1: Material constants for necking of a circular bar.4 Summary and OutlookIn this paper, a new model to overcome incompressibility constraints in finite deformation mechanicswas proposed. The model uses a projection which projects an unconstrained counterpart to Cp ontothe manifold of unimodular tensors to exactly satisfy the constraint. Finally, the model was verifiedusing an example from the literature. Here, the results showed to be very promising. Therefore, in thefuture, further materials with incompressibility constrained, e.g., shape memory alloys or rubbers, maybe modeled using this projection method.AcknowledgmentsFinancial support of subproject A3 Cooperative Actuator Systems for Nanomechanics and Nanopho-tonics: Coupled Simulation of the Priority Programme SPP 2206 by the German Research Foundation(DFG) is gratefully acknowledged by M.S. and S.W.. Funding by the German Research Foundation(DFG) for the project P12 within the framework of the research training group GRK 2154 “Materials forBrain” is gratefully acknowledged by S. W. and J. D..REFERENCES[1] Kröner, E. Allgemeine Kontinuumstheorie der Versetzungen und Eigenspannungen. Archive forRational Mechanics and Analysis, Vol. 4, (1959).[2] Lee, E. Elastic-plastic deformation at finite strains. (1969).[3] Shutov, A.V. and Kreißig, R. Geometric integrators for multiplicative viscoplasticity: analysis of6Marian Sielenkämper, Jan Dittmann and Stephan Wulfinghofferror accumulation. Computer Methods in Applied Mechanics and Engineering (2010) 199:700–711.[4] Lion, A. Constitutive modelling in finite thermoviscoplasticity: a physical approach based on non-linear rheological models. International Journal of Plasticity (2000):16:469–494.[5] Dettmer, W. and Reese, S. On the theoretical and numerical modelling of Armstrong–Frederickkinematic hardening in the finite strain regime. Computer Methods in Applied Mechanics and En-gineering (2004) 193:87–116.[6] Simo, J.C. Algorithms for static and dynamic multiplicative plasticity that preserve the classicalreturn mapping schemes of the infinitesimal theory. Computer Methods in Applied Mechanics andEngineering (1992) 99:61–112.[7] Miehe, C. Exponential map algorithm for stress updates in anisotropic multiplicative elastoplastic-ity for single crystals. International Journal for Numerical Methods in Engineering (1996) 39:3367–3390.[8] Ortiz, M. and Stainier, L. The variational formulation of viscoplastic constitutive updates. Com-puter Methods in Applied Mechanics and Engineering (1999) 171:419–444.7

On a Projection Method for the Numerical Integration of Constitutive Equations Involving Large Inelastic and Incompressible Deformations

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On a Projection Method for the Numerical Integration of Constitutive Equations Involving Large Inelastic and Incompressible Deformations

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