Abstract
Applying the computed software ANSYS, a 3D mathematical model of magnetic field inside the mold with FC-Mold was bewrited, in order to achieve the magnetic induction results inside the mold with the FC-Mold. The distribution features of magnetic induction results of liquid steel inside the mold with the FC-Mold was resolved and discussed. The explanation of simulation results was that the FC-Mold equipment can form a stabilizing magnetic field, the magnetic field inside the liquid steel had adequate intensity, this valid magnetic field engendered by the FC-Mold was imploded in the overlay region of magnetic pole mainly. The valid magnetic field enshrouded the region of total mold width. In the external part of the overlay region of magnetic pole, the magnetic induction intensity was slightly smaller. The magnetic intensity distribution was basically even toward the width and thickness directions of mold. Toward the direction of mold height, the magnetic intensity was appeared parabolic shape in the overlay region of magnetic pole, the two peaks of magnetic intensity appeared in the center of the overlay region of magnetic pole, and then it gradually declined from the mold top toward the mold bottom outside the overlay region of magnetic pole.
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Acknowledgments
This research was supported by Doctoral Research Funding Project of Jilin Engineering Normal University (Grant No. BSKJ201810) and Program for Innovative Research Team of Jilin Engineering Normal University.
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Li, F., Chen, Y., Liu, W. (2021). Computational Simulation of Magnetic Field of FC-Mold. In: MacIntyre, J., Zhao, J., Ma, X. (eds) The 2020 International Conference on Machine Learning and Big Data Analytics for IoT Security and Privacy. SPIOT 2020. Advances in Intelligent Systems and Computing, vol 1282. Springer, Cham. https://doi.org/10.1007/978-3-030-62743-0_75
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DOI: https://doi.org/10.1007/978-3-030-62743-0_75
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