Steel structure prediction for continuous steel casting by means of a parallel GPU-based heat transfer and solidification model

Steel structure prediction for continuous steel casting by means of a parallel GPU-based heat transfer and solidification model

Paper in proceedings (conference paper)

The paper presents our developed GPU-based heat transfer and solidification model for continuous casting, which is coupled with a submodel used for the prediction of the steel micro-structure. The model is implemented in CUDA/C++, which allows for rapid computing on NVIDIA GPUs. The time-dependent temperature distribution calculated by the thermal model is iteratively passed to the submodel for the steel micro-structure prediction. The structural submodel determines the spatially-dependent rates of temperature change in the strand, for which the interdendritic solidification model IDS predicts the micro-structure of steel.

The paper presents our developed GPU-based heat transfer and solidification model for continuous casting, which is coupled with a submodel used for the prediction of the steel micro-structure. The model is implemented in CUDA/C++, which allows for rapid computing on NVIDIA GPUs. The time-dependent temperature distribution calculated by the thermal model is iteratively passed to the submodel for the steel micro-structure prediction. The structural submodel determines the spatially-dependent rates of temperature change in the strand, for which the interdendritic solidification model IDS predicts the micro-structure of steel.

continuous steel casting, steel structure, GPU, dynamic solidification model

continuous steel casting, steel structure, GPU, dynamic solidification model

KLIMEŠ, L.; ŠTĚTINA, J.; MAUDER, T.

2016

13.11.2015

ASME

Houston, TX, USA

978-0-7918-5750-2

ASME 2015 International Mechanical Engineering Congress and Exposition; Volume 8B: Heat Transfer and Thermal Engineering

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