Elucidating the promoting mechanism of nitrogen in the columnar-to-equiaxed transition of steel ingot

•Elucidate the promoting mechanism of nitrogen in the CET of steel ingot based on mechanical blocking and solutal blocking mechanism.•The influence of nitrogen solute on the constitutional supercooling ahead of the advancing columnar front was quantified.•Further improved the Qc calculation model by...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2024-03, Vol.220, p.125014, Article 125014
Main Authors: Ni, Zhuo-Wen, Zhu, Hong-Chun, Li, Hua-Bing, He, Zhi-Yu, Li, Bin, Feng, Hao, Zhang, Shu-Cai, Jiang, Zhou-Hua
Format: Article
Language:English
Subjects:
Blocking mechanism
Columnar-to-equiaxed transition
Growth
Nucleation
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Summary:•Elucidate the promoting mechanism of nitrogen in the CET of steel ingot based on mechanical blocking and solutal blocking mechanism.•The influence of nitrogen solute on the constitutional supercooling ahead of the advancing columnar front was quantified.•Further improved the Qc calculation model by introducing solute diffusion processes. Based on the behavior of heat and mass transfer ahead of the advancing columnar front, combined with the nucleation and growth of dendrites, as well as the blocking mechanism of columnar-to-equiaxed transition (CET), the promoting mechanism of nitrogen in the CET of steel ingot was elucidated. It was found that the CET moves from the center to the edge of the ingot as the nitrogen content increases, resulting in a decrease in the columnar dendrite zone and an increase in the equiaxed dendrite zone. The occurrence of this phenomenon can be attributed to two factors. On the one hand, an increase in nitrogen content leads to an increase in critical nucleation supercooling and incubation time of dendrites, causing a decrease in the number of dendrites nucleation. Additionally, the higher nitrogen content reduces the restriction effect of solute on the growth of columnar dendrites, leading to an increase in dendrite size. On the other hand, within the constitutional supercooling (CS) zone ahead of the advancing columnar front, both the CS and temperature gradient decrease with increasing nitrogen content, while the CS increases and the temperature gradient decreases with the distance from the advancing columnar front. Consequently, the nitrogen solute primarily influences the nucleation and growth of columnar and equiaxed dendrites, as well as the length, temperature gradient, and growth restriction factor Qc of the CS zone, resulting in changes in the heat and mass transfer behavior ahead of the advancing columnar front, thereby promoting CET.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2023.125014