Numerical and Experimental Study on the Molten Pool Behavior and Magnetic Properties of Nano-Crystalline Alloy Ribbon Prepared by PlanarFlow Casting.

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Title: Numerical and Experimental Study on the Molten Pool Behavior and Magnetic Properties of Nano-Crystalline Alloy Ribbon Prepared by PlanarFlow Casting.
Authors: Li, Lijun1 (AUTHOR), Ji, Hongxin2 (AUTHOR), Sun, Jianliang2,3 (AUTHOR) sunjianliang@ysu.edu.cn, Li, Deren1,3 (AUTHOR), Li, Baisong1,2 (AUTHOR), Yao, Jintao1,3 (AUTHOR)
Source: Materials (1996-1944). Apr2026, Vol. 19 Issue 8, p1510. 10p.
Subjects: Magnetic properties, Multiphase flow, Rapid solidification processing of metals, Magnetic cores
Abstract: A 2D multiphase-flow coupling simulation model for preparing nanocrystalline ribbons using planar-flow casting (PFC) with a cooling roller was established. The influence of roller speed on molten pool characteristics, cooling-roller heat transfer, and ribbon thickness was analyzed. The effect of ribbon thickness on the total loss and permeability of the magnetic cores was investigated. The results indicate that the molten pool size decreased as the roller speed increased. At t = 5 ms, the maximum heat-transfer coefficient of the roller surface increased from 2.09 × 106 W·m−2·K−1 at 15 m/s to 2.6 × 106 W·m−2·K−1 at 24 m/s. The ribbon thickness decreased from 39.96 μm to 20.02 μm (a 49.9% reduction) as the roller speed increased from 18 m/s to 30 m/s. The total loss of the nanocrystalline magnetic cores increased with ribbon thickness, whereas their permeability increased as ribbon thickness decreased. At 100 kHz, the nanocrystalline magnetic core made of 10–12 μm ribbons exhibited a high permeability of 59,507. [ABSTRACT FROM AUTHOR]
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Abstract:A 2D multiphase-flow coupling simulation model for preparing nanocrystalline ribbons using planar-flow casting (PFC) with a cooling roller was established. The influence of roller speed on molten pool characteristics, cooling-roller heat transfer, and ribbon thickness was analyzed. The effect of ribbon thickness on the total loss and permeability of the magnetic cores was investigated. The results indicate that the molten pool size decreased as the roller speed increased. At t = 5 ms, the maximum heat-transfer coefficient of the roller surface increased from 2.09 × 106 W·m−2·K−1 at 15 m/s to 2.6 × 106 W·m−2·K−1 at 24 m/s. The ribbon thickness decreased from 39.96 μm to 20.02 μm (a 49.9% reduction) as the roller speed increased from 18 m/s to 30 m/s. The total loss of the nanocrystalline magnetic cores increased with ribbon thickness, whereas their permeability increased as ribbon thickness decreased. At 100 kHz, the nanocrystalline magnetic core made of 10–12 μm ribbons exhibited a high permeability of 59,507. [ABSTRACT FROM AUTHOR]
ISSN:19961944
DOI:10.3390/ma19081510