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Modeling recrystallization kinetics, grain sizes, and textures during multipass hot rolling

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Abstract

A physically based model for the evolution of recrystallization microstructures and textures during hot rolling of aluminum is presented. The approach taken differs from similar models developed for steels. The present model is based on recent experimental investigations directed toward identifying the nature of the nucleation sites for recrystallized grains of different crystallographic orientations. Particle stimulated nucleation (PSN) and nucleation from cube bands and grain boundary regions have been incorporated in the model. The multipass aspect complicates the modeling due to partial recrystallization between the rolling passes. Two different approaches have been suggested to handle this. The model has been applied to predictions of recrystallization kinetics, recrystallized grain sizes, and recrystallization textures during multipass hot rolling of aluminum. The predictions are reasonable compared to experimental results.

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Authors and Affiliations

  1. Hydro Aluminum, R&D Centre Sunndalsøra, N-6600, Sunndalsøra, Norway

    Hans Erik Vatne PhD & Roar Ørsund PhD (Research Metallurgists)

  2. SINTEF Materials Technology, N-7034, Trondheim, Norway

    Knut Marthinsen PhD

  3. the Department of Metallurgy, The Norwegian University of Science and Technology, N-7034, Trondheim, Norway

    Erik Nes (Professor)

Authors
  1. Hans Erik Vatne PhD
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  2. Roar Ørsund PhD
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  3. Knut Marthinsen PhD
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  4. Erik Nes
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Vatne, H.E., Ørsund, R., Marthinsen, K. et al. Modeling recrystallization kinetics, grain sizes, and textures during multipass hot rolling. Metall Mater Trans A 27, 4133–4144 (1996). https://doi.org/10.1007/BF02595661

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