Simulation of the Forging Process Incorporating Strain-Induced Phase Transformation Using the Finite Volume Method

Ding, Peiran; Ju, Dongying; Inoue, Tatsuo; Imatani, Shōji; Vries, Edwin de

doi:10.2472/jsms.50.3appendix_19

Cited by 5 publications

(6 citation statements)

References 5 publications

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“…Driven by the rate of macroscopic plastic deformation, eq. (18) represents a constant rate of nucleation law, corresponding to the proportional nucleation model in [41,42], also employed in [43,44]. It should be noted, however, that the rate of nucleation in the present model is constant at a given temperature but will change with changing temperature.…”

Section: Modeling Of Grain Nucleationmentioning

confidence: 95%

A modified level set approach to 2D modeling of dynamic recrystallization

Hallberg

2013

Modelling Simul. Mater. Sci. Eng.

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The macroscopic properties of metallic materials depend on the state of the grain microstructure. Recrystallization acts as one of the most important mechanisms in the evolution of the microstructure and hence also of the macroscopic properties. This paper presents a mesoscale model of microstructure evolution due to recrystallization, based on a level set formulation employed in a finite element setting. The use of level sets to represent grains and grain boundaries in polycrystal microstructures is a relatively recent development in computational materials science and the present contribution suggests new methodologies such as interface reconstruction, allowing for example boundary conditions to be prescribed along grain boundary interfaces and distinct localization and representation of grain boundary junctions. Polycrystal plasticity is modeled by considering the evolution of dislocation density in the individual crystals. The influence of grain boundaries on dislocation accumulation is captured in the model, causing the formation of dislocation density gradients within the grains. The model is used in simulations of dynamic recrystallization, taking pure copper as example material. It is shown that the proposed model captures the salient features of dynamic recrystallization during thermomechanical materials processing.

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Section: Modeling Of Grain Nucleationmentioning

confidence: 95%

A modified level set approach to 2D modeling of dynamic recrystallization

Hallberg

2013

Modelling Simul. Mater. Sci. Eng.

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“…Renewed interest in a better understanding of this mechanism and its effect on texture evolution results from the need of reliable input parameters for the development of computer codes simulating various metallurgical forming processes (Ding et al, 2001). Since the -transformation is martensitic the crystallographic orientation relation between the starting and transformed phases is necessarily a key element in any model of the transformation mechanism.…”

Section: Introductionmentioning

confidence: 99%

Tensile Deformation Induced Texture Transformation in Austenitic Stainless Steel

Grigull

2003

Texture, Stress, and Microstructure

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Texture patterns of the starting and transformed structural phases were obtained from AISI 304 stainless steel sheets subjected to varying levels of tensile deformation using high energy X-ray diffraction in combination with the texture enhanced Rietveld method. The use of this method allows the simultaneous determination of the orientation distribution functions (ODF) of both phases, even for small -martensite fractions of the order of 5%. The texture patterns are analyzed in terms of the crystallographic orientation relation between the starting and transformed phases and the preferential formation of certain variants of this relation.

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“…The volume of strain-induced transformation is a function of equivalent plastic strainε p and temperature T . The strain and strain-rate hardening of stainless steel in austenite state is given with a power law [5]. We assume that the strain resistance of the stainless steel σ d during austenite-martensite transformation depends on the strain resistance of the steel in austenite state σ A d and on the martensite volume fraction ξ M :…”

Section: Simulation Of Hot Rolling and Subsequent Cold Torsion Processesmentioning

confidence: 99%

“…According to [5] the two volume fractions, austenite ξ A and martensite ξ M , develop under the restriction ξ A + ξ M = 1. The volume of strain-induced transformation is a function of equivalent plastic strainε p and temperature T .…”

Section: Simulation Of Hot Rolling and Subsequent Cold Torsion Processesmentioning

confidence: 99%

Simulation of strain induced austenite‐martensite transformation

Bontcheva

Petrov

Petzov

et al. 2006

Proc Appl Math and Mech

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Grain refinement due to phase transformation is an effective method for improving the mechanical properties of steel. An approach is proposed in the present work based on the FEM, for numerical simulation of the microstructure evolution as a result of hot rolling and subsequent cold torsion. Grain refinement in 304 stainless steel at four different technological schedules is considered. Results of numerical simulation are compared with experimental data. Coupling of the thermoplastic deformation with microstructure evolution is realized.

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Simulation of the Forging Process Incorporating Strain-Induced Phase Transformation Using the Finite Volume Method

Cited by 5 publications

References 5 publications

A modified level set approach to 2D modeling of dynamic recrystallization

A modified level set approach to 2D modeling of dynamic recrystallization

Tensile Deformation Induced Texture Transformation in Austenitic Stainless Steel

Simulation of strain induced austenite‐martensite transformation

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