Perceptive Review of Ferrous Micro/Macro Material Models for Thermo-Mechanical Processing Applications

Pietrzyk, M.; Madej, Łukasz

doi:10.1002/srin.201700193

Cited by 7 publications

(5 citation statements)

References 53 publications

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“…A thorough comparative discussion of the mean field and full field approaches to modelling dynamic recrystallization is presented in the Maire's PhD thesis (2018). A similar discussion regarding modelling of grain growth can be found in Furstoss et al (2020) while publication by Pietrzyk and Madej (2017) presents a general comparison of the mean field and full field material models in describing microstructure evolution during hot forming and controlled cooling of metallic materials.…”

Section: Full Field Modelsmentioning

confidence: 87%

“…JMAK equation was developed long before the multiscale modelling was proposed. A review of the development of metal forming modelling accounting for the microstructure evolution can be found in Pietrzyk and Madej (2017). The JMAK equation was originally developed for isothermal conditions, therefore, Scheil additivity rule (Scheil, 1935) had to be applied to account for changes of the temperature.…”

Section: Mean Field Modelsmentioning

confidence: 99%

“…It means that multiscale approach has to be applied. The majority of developed multi-scale models can be classified into two groups: upscaling and concurrent multi-scale computing techniques (Allix, 2006); see also authors' publications (Pietrzyk & Madej, 2017;Madej et al, 2008). The major difference in the two approaches lies in the concept of physical area description at various length scales.…”

Section: Full Field Modelsmentioning

confidence: 99%

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Mean field and full field modelling of microstructure evolution and phase transformations during hot forming and cooling of low carbon steels

Szeliga¹,

Bzowski²,

Rauch³

et al. 2020

human

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The paper describes a critical comparison of mean field and full field approaches to modelling hot deformation/controlled cooling sequences for steels. Classification of the models, based on the balance between predictive capabilities and computing costs, is presented. Mean field models, which describe microstructure evolution and phase transformations were connected with thermomechanical finite element program and applied to simulation of the hot strip rolling process and cooling of tubes after hot rolling. Full field model described in the paper is a connection of the finite element (FE) and level set (LSM) methods. These methods were used to simulate heating/cooling sequence in the continuous annealing line. A suggestion to use a stochastic model as a bridge between mean field and full field approaches is made.

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Section: Full Field Modelsmentioning

confidence: 87%

Section: Mean Field Modelsmentioning

confidence: 99%

Section: Full Field Modelsmentioning

confidence: 99%

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Mean field and full field modelling of microstructure evolution and phase transformations during hot forming and cooling of low carbon steels

Szeliga¹,

Bzowski²,

Rauch³

et al. 2020

human

Self Cite

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“…In order to analyze the evolution of microstructure during consecutive forging operations, JMAK model based on classic theory of nucleation and grain growth was employed in the study, as the model which has been successfully used in modeling dynamic behavior of hot deformed microalloyed steels (Majta et al, 2002;Pietrzyk & Madej, 2014). As far as the present demonstrative microalloyed steel is concerned, reliability of the model with regard to prediction of the microstructure changes during hammer forging of microalloyed steel is referred in related studies (Skubisz et al, 2017a;Skubisz et al, 2017b), where consistency to experimental measurements of the size of as-forged direct cooled ferrite-pearlite grains was assessed.…”

Section: Theoretical Backgroundmentioning

confidence: 99%

Effect of forging sequence on evolution of parameters controlling microstructure in multistage drop forging process

Skubisz¹,

Lisiecki²,

Majta³

et al. 2019

cmms

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The study presents the comparative analysis of competitive techniques of forging and analysis of the effect of the forging sequences on microstructure development. Starting with industrial practice of hammer-forged elongate geometry, two competitive processes were numerically analysed in term of forging economy and quality. Numerical modeling of temperature, strain and strain rate fields let theoretical prediction of the microstructure development in multi-stage drop forging process consisting of progressive sequence of multiple blows in preforming and die-impression forging operations. The aim of the modeling was prediction of the parameters of austenite in as-forged condition, which in thermomechanical controlled processing form the restored austenite condition prior to direct cooling. Dynamic recrystallization kinetics was analyzed with use of Johnson-Mehl-Avrami-Kolmogorov (JMAK) model, taking advantage of numerically calculated of temperature, strain and strain-rate in selected location in the volume of the part. The obtained results show the possibility of look-ahead microstructure prediction and form the basis for comprehensive selection of the forging process parameters aimed at producing required microstructure and its uniformity in the bulk in multi-stage hammer-forging process.

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“…[20][21][22] Since computing times for these models are very short, they can be solved at each integration (Gauss) point of the FE mesh without causing a noticeable increase in the simulation costs, even for multiscale computations. [23] Due to the relative simplicity of the mathematical formulations and execution speed, they are still common in industrial applications. However, one of the major drawbacks is that they do not consider the influence of often heterogeneous microstructures on the final product properties in a DOI: 10.1002/srin.202200657…”

Section: Introductionmentioning

confidence: 99%

Computationally Efficient Cellular Automata‐Based Full‐Field Models of Static Recrystallization: A Perspective Review

Madej

Sitko

2022

steel research int.

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The evolution of metallic material microstructures under thermomechanical treatment is a critical element that influences the in‐use properties of the final product. In the last four decades, many researchers around the world focused on reliable numerical recreation of phenomena that occur during metal processing. Particular attention is put on the phase transformation, texture evolution, and recrystallization predictions to simulate material behavior at the subsequent processing stages. In recent years, approaches taking into account explicit representation of morphological elements during simulation are becoming more frequently used even at the industrial scale. One of those methods addressed within the current article in application to static recrystallization (SRX) modeling is the cellular automata (CA) approach. A review of the CA‐based full‐field SRX models highlights the progress in capabilities of developed approaches in consideration of various mechanisms controlling microstructure evolution like heterogeneous energy distribution, probabilistic or physics‐based nucleation, grain growth driven by different driving forces, or grain boundary migration is presented within the article. The issue of the computational time associated with 3D CA modeling is particularly addressed. Possible approaches to reducing simulation times based on efficient use of modern computer architecture are finally evaluated as guidelines for further model development.

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Perceptive Review of Ferrous Micro/Macro Material Models for Thermo-Mechanical Processing Applications

Cited by 7 publications

References 53 publications

Mean field and full field modelling of microstructure evolution and phase transformations during hot forming and cooling of low carbon steels

Mean field and full field modelling of microstructure evolution and phase transformations during hot forming and cooling of low carbon steels

Effect of forging sequence on evolution of parameters controlling microstructure in multistage drop forging process

Computationally Efficient Cellular Automata‐Based Full‐Field Models of Static Recrystallization: A Perspective Review

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