Two‐Scale Modeling of Grain Size and Phase Transformation Effects

Böhlke, Thomas; Neumann, Rudolf; Rieger, Florian

doi:10.1002/srin.201300200

Cited by 10 publications

(2 citation statements)

References 47 publications

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“…All these approaches are classified as full field models, that can take into account microstructure morphology in an explicit manner. However, as was shown with the earlier case studies various multi scale models based on mean field approaches are also quite common see, for example . Enormous progress in multiscale modeling concepts and development of sophisticated metallic material models during last decade has been documented in series of books, see, for example .…”

Section: Full Field Models In Multiscale Analysismentioning

confidence: 83%

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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Section: Full Field Models In Multiscale Analysismentioning

confidence: 83%

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

Pietrzyk

Madej

2017

steel research int.

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“…A plenty of researches have been made to investigate the grain growth behavior in steels . It is noted that alloying elements segregating toward austenite grain boundaries could decrease the rate of grain growth due to the drag effect .…”

Section: Introductionmentioning

confidence: 99%

Austenitic Grain Growth Behavior during Austenization in an Aluminum-Alloyed 5% Cr-Mo-V Steel

Liu

Song

et al. 2016

steel research int.

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The influence of Al on the grain size, morphology, and grain size distribution of austenite is investigated in a wide range of austenitizing temperatures and holding times. In general, the addition of 1.1 wt% Al significantly increases the austenitic grain size at all the corresponding austenitizing conditions. The austenitic grain growth mode of the none Al-added steel is abnormal grain growth at the austenitizing temperature in the range of 1100-1200 8C, while that of the high Al-added steel has already become normal grain growth in the same temperature range. The results indicate that the Al addition can significantly accelerate the growth of austenite grains, mainly because the high content of Al affected the Zener drag and solute drag on the grain growth by reducing the activity and diffusivity of Mo and V atoms in austenite. In addition, the kinetic equations of austenite grain growth in both steels are proposed. The calculated grain growth exponents are n ¼ 0.33 and n ¼ 0.35, and the activation energies of grain growth are Q ¼ 1.51 Â 10 5 J mol À1 and Q ¼ 1.85 Â 10 5 J mol À1 for 0Al and 1.1Al, respectively.

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Microstructure based prediction and homogenization of the strain hardening behavior of dual-phase steel

Rieger

Böhlke

2015

Arch Appl Mech

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Two‐Scale Modeling of Grain Size and Phase Transformation Effects

Cited by 10 publications

References 47 publications

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

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

Austenitic Grain Growth Behavior during Austenization in an Aluminum-Alloyed 5% Cr-Mo-V Steel

Microstructure based prediction and homogenization of the strain hardening behavior of dual-phase steel

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