Accounting for the Inhomogeneity of Deformation in Identification of Microstructure Evolution Model / Niejednorodność Odkształcenia W I Dentyfikacji Modelu Rozwoju Mikrostruktury

Szeliga, Danuta; Kuziak, R.; Kopp, Reiner; Smyk, G.; Pietrzyk, M.

doi:10.1515/amm-2015-0494

Cited by 5 publications

(3 citation statements)

References 14 publications

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“…A lot of similar research dedicated to the simulation of material morphology evolution during SRX by the CA method can be found in the recent scientific literature. [ 138–142 ] Moreover, different papers were dedicated to a wide range of materials [ 143 ] including, e.g., aluminum, [ 125 ] copper, [ 124 ] low‐carbon steel, [ 109 ] Ni‐based superalloy, [ 144 ] TRIP steel, [ 145 ] or ferritic–pearlitic steel. [ 146 ] In addition, interactions between different phenomena, e.g., phase transformations and recrystallization, can also be recreated (see the case study for DP steels annealing cycle).…”

Section: Ca Models Of Static Recrystallizationmentioning

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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Section: Ca Models Of Static Recrystallizationmentioning

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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“…For that reason, authors developed an inverse algorithm, which allows identification of the coefficients on the basis of experiments using optimization methods. Description of this algorithm for the two step compression is given in ref . and for dilatometric tests in ref .…”

Section: Microstructure Evolution and Phase Transformation Modelsmentioning

confidence: 99%

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

Pietrzyk

Madej

2017

steel research int.

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Perceptive review of progress in development of ferrous materials models for computational engineering applications is the subject of the present work. Development of both micro/macro mean field and full field material models during last forty years is presented and discussed. Evolution of conventional mean field models based on closed form or differential equations is described first to present the progression in thinking of materials. Then, recent progress and selected advancements in development of full field models are addressed to present the state-of-the-art, as well as directions for future developments. Finally, capabilities, as well as limitations and drawbacks of both groups of models are discussed on the basis of selected case studies.

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“…This disparity can, in part, be accounted for by considering the local strain distribution in both axisymmetric specimens and flat-rolled products for a given applied bulk strain. Szeliga 23) has shown that the local strain at the work piece centre is larger than the applied strain and the difference between the two strains increases with applied strain, but slightly less in flat rolling. 24) This was seen after ABAQUS ver.…”

Section: Elimination Of Local Heterogeneous Microstruc-mentioning

confidence: 99%

Roughing of Thick, Coarse-grained High-temperature-processing Steels Processed via Compact Strip Production

2017

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The roughing conditions required to avoid local heterogeneous regions in the final microstructure of high temperature processing (HTP) Nb linepipe steels have been investigated for quasi-compact strip production (CSP) conditions. The influence of strain sequence, rolling temperatures and Mn content on recrystallisation and carbonitride precipitation before and after roughing were studied using laboratory simulation, mathematical modelling and transmission electron microscopy. The roughing conditions necessary to avoid the formation of local heterogeneous regions have been established for HTP steels with an initial grain size of 850 μm. Low Mn Nb-Ti steels experience more sluggish recrystallisation kinetics and are more vulnerable to forming local heterogeneous regions during roughing. To prevent local heterogeneous regions if finishing commences at 900°C, sufficient effective strain is necessary to produce a bulk softened fraction of at least 0.55 in each of the first two roughing passes. If finishing commences at 1 000°C, slow air cooling from roughing provides additional time for recrystallisation to go to completion and so prevent the occurrence of local heterogeneous regions. Maintaining the strand temperature as high as possible prior to the commencement of roughing encourages recrystallisation. A roughing start temperature of 1 100°C, as opposed to 1 075°C, significantly reduces the risk of forming local heterogeneous regions. For the conditions tested, no correlation between softening fraction and carbonitride precipitate characteristics was found. Thus, the influence of Nb on austenite recrystallisation is expected to be due to either solute drag or solute clustering.

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Accounting for the Inhomogeneity of Deformation in Identification of Microstructure Evolution Model / Niejednorodność Odkształcenia W I Dentyfikacji Modelu Rozwoju Mikrostruktury

Cited by 5 publications

References 14 publications

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

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

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

Roughing of Thick, Coarse-grained High-temperature-processing Steels Processed via Compact Strip Production

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