Computationally efficient predictions of crystal plasticity based forming limit diagrams using a spectral database

Gupta, Akash; Bettaieb, Mohamed Ben; Abed‐Meraim, Farid; Kalidindi, Surya R.

doi:10.1016/j.ijplas.2018.01.007

Cited by 27 publications

(7 citation statements)

References 68 publications

(98 reference statements)

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“…Most of these models are at the macroscale and they are unable to provide insight into micromechanical aspects of the forming process. There has been a limited effort in the past to get insight into the micromechanics of ductile failure (for details see references [58], [59] and references therein). Viatkina et al [58] used strain localisation as the criterion for failure in the polycrystalline aggregate and the response of each of the single crystals in the aggregate was solved using the CPFEM method.…”

Section: Application Of the Constitutive Modelmentioning

confidence: 99%

“…Viatkina et al [58] used strain localisation as the criterion for failure in the polycrystalline aggregate and the response of each of the single crystals in the aggregate was solved using the CPFEM method. Gupta et al [59] used the Marciniak-Kuczynski (M-K) model at the macroscopic scale of the polycrystalline aggregate to simulate sheet-necking along with the CPFEM formulation for the nonporous single crystals. The constitutive model presented here tries to overcome this shortcoming by extending the current crystal plasticity finite element method to incorporate the effects of crystal anisotropy and the phase boundary orientation in the context of porous crystal plasticity.…”

Section: Application Of the Constitutive Modelmentioning

confidence: 99%

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A multiscale constitutive model for metal forming of dual phase titanium alloys by incorporating inherent deformation and failure mechanisms

Asim¹,

Siddiq²,

McMeeking³

et al. 2022

Modelling Simul. Mater. Sci. Eng.

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Ductile metals undergo a considerable amount of plastic deformation before failure. Void nucleation, growth and coalescence is the mechanism of failure in such metals. α–β titanium alloys are ductile in nature and are widely used for their unique set of properties such as specific strength, fracture toughness, corrosion resistance and resistance to fatigue failures. Voids in these alloys have been reported to nucleate on the phase boundaries between α and β phase. Based on the findings of crystal plasticity finite element method investigations of the void growth at the interface of α and β phases, a void nucleation, growth, and coalescence model has been formulated. An existing single-phase crystal plasticity theory is extended to incorporate underlying physical mechanisms of deformation and failure in dual phase titanium alloys. Effects of various factors [stress triaxiality, Lode parameter, deformation state (equivalent stress), and phase boundary inclination] on void nucleation, growth and coalescence are used to formulate a phenomenological constitutive model while their interaction with a conventional crystal plasticity theory is established. An extensive parametric assessment of the model is carried out to quantify and understand the effects of the material parameters on the overall material response. Performance of the proposed model is then assessed and verified by comparing the results of the proposed model with the RVE study results. Application of the constitutive model for utilisation in the design and optimisation of the forming process of α–β titanium alloy components is also demonstrated using experimental data.

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Section: Application Of the Constitutive Modelmentioning

confidence: 99%

Section: Application Of the Constitutive Modelmentioning

confidence: 99%

A multiscale constitutive model for metal forming of dual phase titanium alloys by incorporating inherent deformation and failure mechanisms

Asim¹,

Siddiq²,

McMeeking³

et al. 2022

Modelling Simul. Mater. Sci. Eng.

View full text Add to dashboard Cite

show abstract

“…In the group of mean field models, the classical Taylor model [40,41,42,43,44,45,46,47,48,39] and the viscoplastic self-consistent model [49,33,50,51,52,53,54,55,56,57,58,59,60] are often applied. Essentially, a crystal plasticity formulation together with a numerical homogenization scheme provides the stress-strain relation of a polycrystalline material, i.e.…”

Section: Mean Field Modelsmentioning

confidence: 99%

“…As mentioned above, both the MK-model and BT are very flexible in terms of the constitutive law. Hence, these mean field polycrystal models are usually coupled with the MKmodel [40,41,42,43,44,45,46,47,48,39,49,33,50,52,51,53,54,57,55,56,58,59,60] or BT [39,57,59].…”

Section: Mean Field Modelsmentioning

confidence: 99%

Assessment of full field crystal plasticity finite element method for forming limit diagram prediction

Ma¹

2018

Preprint

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This study is inspired by the recent development of "virtual material testing laboratory" in which the main equipment is a full field crystal plasticity modeling tool. Ample examples have demonstrated its applications to sheet forming operations. In those applications, the mechanical anisotropy originated from the crystallographic texture can be adequately described, such as r-values and earing. Formability is another important property in sheet metal forming, which has yet not been equipped in these virtual laboratories. Though theoretical models for formability can be dated back to 1885 due to Considère, all popular models at the moment suffer from their respective limitations. In this study, we explore the feasibility of applying full field crystal plasticity model for calculating forming limit diagram, avoiding using additional assumptions or models for determining the forming limits.

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“…The use of CP models within homogenization frameworks allows to simulate the response of a full polycrystal including texture evolution by explicitly considering grain orientation and shape changes in the micro-scale (see [8] for a review). Such type of models, due to their verified predictive capacity, have been used in the prediction of the mechanical response under monotonic loading [9,10,11,12,13,14,15] , cyclic loading [16,17,18] and fatigue response [19,20,21,22,23] or to simulate forming processes such as rolling [24,25,26,27].…”

Section: Introductionmentioning

confidence: 99%

Development of a thermo-mechanically coupled crystal plasticity modeling framework: Application to polycrystalline homogenization

Romero

Segurado

2019

International Journal of Plasticity

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Accurate predictions of thermo-mechanically coupled process in metals can lead to a reduction of cost and an increase of productivity in manufacturing processes such as forming. For modeling these coupled processes with the finite element method, accurate descriptions of both the mechanical and the thermal responses of the material, as well as their interaction, are needed. Conventional material modeling employs empirical macroscopic constitutive relations but does not account for the actual thermo-mechanical mechanisms occurring at the microscopic level. However, the consideration of the latter might be crucial to obtain accurate predictions and a complete understanding of the underlying physics.In this work we describe a fully coupled implicit thermo-mechanical framework for crystal plasticity simulations. This framework includes thermal strains, temperature dependency of the crystal behavior and heat generation by dissipation due to plastic slip and allows the use of large deformation steps thanks to the implicit integration of the governing equations. Its use within computational homogenization simulations allows to bridge the plastic deformation and temperature gradients at the macroscopic scale with the microscopic slip at the grain scale. A series of numerical examples are presented to validate the approach.

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Computationally efficient predictions of crystal plasticity based forming limit diagrams using a spectral database

Cited by 27 publications

References 68 publications

A multiscale constitutive model for metal forming of dual phase titanium alloys by incorporating inherent deformation and failure mechanisms

A multiscale constitutive model for metal forming of dual phase titanium alloys by incorporating inherent deformation and failure mechanisms

Assessment of full field crystal plasticity finite element method for forming limit diagram prediction

Development of a thermo-mechanically coupled crystal plasticity modeling framework: Application to polycrystalline homogenization

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