Constitutive modelling of mechanically induced martensitic transformations

Bortoli, D. de; Adziman, Fauzan; Neto, E. A. de Souza; Pires, F.M. Andrade

doi:10.1108/ec-03-2017-0087

Cited by 5 publications

(4 citation statements)

References 67 publications

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“…The lattice parameters are those of an ASTM A-564 alloy (also known as Sandvik Nanoflex) -a A = 3.59690 Å and a M = 2.87351 Å ‡ ‡ . 53 This metastable austenitic stainless steel is extensively documented in References 38,76,77. In addition, the critical mechanical energy is set to ΔG mech = 30 MPa.…”

Section: 27mentioning

confidence: 91%

“…Moreover, martensitic transformation is allowed — FCC‐to‐BCC, where the elasticity properties of the martensitic phase are considered equal to those of the austenitic phase †† . The lattice parameters are those of an ASTM A‐564 alloy (also known as Sandvik Nanoflex) —

a^{A} = 3.59690 Å

and

a^{M} = 2.87351 Å

‡‡ 53 . This metastable austenitic stainless steel is extensively documented in References 38,76,77.…”

Section: Computational Treatmentmentioning

confidence: 99%

“…plastic multipliers) and the associated transformation functions provide the active transformation systems selection, under isothermal conditions and within the temperature range defined by the martensite start temperature (

M_{s}

) and by the temperature at which austenite and martensite chemical free energies are identical (

T_{0}

). An initial version of the model proposed here can be found in de Bortoli et al 53 The unified constitutive model is implemented in LINKS, an in‐house finite element program entirely written in FORTRAN

^{®}

that stands for Large Strain Implicit Nonlinear Analysis of Solids Linking Scales . It allows the resolution of single scale (macro and micro analysis) and coupled problems (

{FE}^{2}

).…”

Section: Introductionmentioning

confidence: 99%

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Consistent modeling of the coupling between crystallographic slip and martensitic phase transformation for mechanically induced loadings

Carvalho

Bortoli

Pires

2022

Numerical Meth Engineering

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A computational framework is proposed to model anisotropic metallic polycrystals subjected to mechanically induced loadings. It enables the simulation of crystal‐plasticity‐like phenomena at finite strains. The unified framework of thermodynamically consistent constitutive equations is formulated such that it couples the crystallographic slip and martensitic transformation theories. The constitutive description for the slip plasticity evolution incorporates an anisotropic hyperelastic law with self and latent‐hardening. The mechanically induced martensite formation kinematics is based on the crystallographic theory of martensitic transformations. The complete set of highly coupled equations is expressed in a single system of equations and solved by a monolithic solution procedure. It is based on the Newton–Raphson methodology and incorporates the complete linearisation leading to asymptotic quadratic rates of convergence. The quasi‐static discretized evolution equations are integrated with a fully implicit scheme, except for the critical resolved slip stresses, which employ the generalized midpoint rule. The plastic flow is integrated with an implicit exponential integrator to exactly preserve the plastic incompressibility. Viscous regularizations for both deformation mechanisms are pursued to overcome numerical difficulties and model the behavior over a wide range of strain‐rate sensitivities. Numerical examples are presented to demonstrate the efficiency and predictive capability of the methodology.

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Section: 27mentioning

confidence: 91%

a^{A} = 3.59690 Å

and

a^{M} = 2.87351 Å

‡‡ 53 . This metastable austenitic stainless steel is extensively documented in References 38,76,77.…”

Section: Computational Treatmentmentioning

confidence: 99%

M_{s}

) and by the temperature at which austenite and martensite chemical free energies are identical (

T_{0}

^{®}

that stands for Large Strain Implicit Nonlinear Analysis of Solids Linking Scales . It allows the resolution of single scale (macro and micro analysis) and coupled problems (

{FE}^{2}

).…”

Section: Introductionmentioning

confidence: 99%

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Consistent modeling of the coupling between crystallographic slip and martensitic phase transformation for mechanically induced loadings

Carvalho

Bortoli

Pires

2022

Numerical Meth Engineering

Self Cite

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“…In recent years, with the development of computer technology, the finite element methods have been gradually used to deal with complex issues (Karimzadeh et al, 2014;Wang et al, 2018;Xu et al, 2019;Zhou et al, 2019), especially the multi-scale problems (Karimzadeh et al, 2014;Wang et al, 2018) and intricacy structure materials (Xu et al, 2019;Zhou et al, 2019). Crystal Plasticity Finite Element Method (CPFEM) has been proposed and used to simulate the responses of material's microstructures (de Bortoli et al, 2018;Prueger et al, 2018) and various mechanical behaviors because of the evolution of the deformation texture (Sheikh et al, 2016;Zhang et al, 2014). The microscopic factors of the plastic deformation, e.g.…”

Section: Introductionmentioning

confidence: 99%

Evolution of face-centered-cubic polycrystalline plastic anisotropy under biaxial loading by crystal plasticity finite element method

Zhao

Cun

Jin

et al. 2019

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Purpose The purpose of this study to analyze the plastic anisotropy of 6061 aluminum alloy with finite deformation using crystal plasticity finite element method. Design/methodology/approach A representative volume element (RVE) model was constructed by Voronoi tessellation. In this model, grain shapes, grain orientations and distribution of grains were involved. The mechanical response of the component under composite loading was tested using specify cruciform specimen. Moreover, different stress and strain states in the specific central region were analyzed to reveal the effects of complex loading. Findings We calculated the influence of misorientation of adjacent grains as well as the evolution of the micro structure’s plastic deformation on the macroscopic deformation of the structure. Geometry design for the cruciform specimen helps obtain a homogenous distribution of the stress and strain at the specimen center. In this process, the initial grain orientation is also an important factor, and the larger misorientations between special grains may cause greater stress concentration. Originality/value The influence of micro-scale factors on macro-scale plastic anisotropy of AA6061 is analyzed using RVE model and cruciform specimen, and they offer a reference for related research.

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On the representativeness of polycrystalline models with transformation induced plasticity

Silva

Carvalho

Coelho

et al. 2023

Finite Elements in Analysis and Design

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Constitutive modelling of mechanically induced martensitic transformations

Cited by 5 publications

References 67 publications

Consistent modeling of the coupling between crystallographic slip and martensitic phase transformation for mechanically induced loadings

Consistent modeling of the coupling between crystallographic slip and martensitic phase transformation for mechanically induced loadings

Evolution of face-centered-cubic polycrystalline plastic anisotropy under biaxial loading by crystal plasticity finite element method

On the representativeness of polycrystalline models with transformation induced plasticity

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