Your search keyword '"Yang, Yong-kun"' showing total 2 results

1. In Situ Observation of P91 High‐Alloy Steel Solidification Characteristics at Different Cooling Rates.

Author

Wang, Wei-an, Yang, Yong-kun, Wang, Jian-li, Zhu, Jia-yu, Wang, Yang, and Li, Xiao-ming

Subjects

*SOLIDIFICATION, *CONTINUOUS casting, *STEEL, *LINEAR velocity, *MICROSCOPY, *CONFOCAL microscopy

Abstract

To clarify the effect of different radial cooling intensities on the formation of central cracks in large round bloom continuous casting, it is necessary to study the solidification characteristics and dynamics of P91 high‐alloy steel at different cooling rates (CRs) to improve the central defects. In this article, the solidification characteristics of P91 high‐alloy steel at different CRs are studied by using the Thermo‐Calc software, high‐temperature laser confocal microscopy, scanning electron microscopy, and optical microscopy. Meanwhile, the growth kinetics of δ‐Fe and γ‐Fe phases under different CRs are determined. The results show that the solidification path of P91 high‐alloy steel is L(L + δ‐Fe) → (L + γ‐Fe + δ‐Fe) → (δ‐Fe + γ‐Fe). The δ‐Fe and γ‐Fe phase precipitation process is divided into two stages. Stage I is the nucleation and rapid growth phase, in which a high undercooling is required. Stage II is the slow growth stage, where the undercooling decreases and remains constant. The initial growth linear velocities of the δ‐Fe phase are 0.51, 2.72, and 2.09 μm s−1 at CRs of 10, 50, and 100 °C min−1, respectively, while those of the γ‐Fe phase are 0.10, 1.42, and 1.41 μm s−1. [ABSTRACT FROM AUTHOR]

Published

2024

2. Effect of Nozzle Position on Fluid Flow and Solidification in a Billet Curved Mould using Mould Electromagnetic Stirring.

Author

Wang, Jian-Li, Qiu, Guo-Xing, Zhu, Jia-Yu, Wang, Wei-An, Yang, Yong-Kun, Li, Xiao-Ming, and Liu, Cheng-Jun

Subjects

FLUID flow, SOLIDIFICATION, HEAT transfer, MATHEMATICAL models, NOZZLES

Abstract

Owing to the smaller cross‐sectional size of the billet, the effect of the position of the submerged entry nozzle (SEN) on the fluid flow in a curved mold is more prominent. The transient fluid flow, heat transfer, and solidification behavior at different nozzle positions and mold electromagnetic stirring (M‐EMS) are investigated using a 3D transient mathematical model. The symmetry index, S, is introduced to quantitatively evaluate the symmetry of the flow field. When the SEN is offset to the outer curve, S is the highest, the flow field mixing is the best, and the liquid level fluctuation is minimal. When the SEN is offset to the inner curve, S is the lowest, and the washing of the solidified shell on the inner curve side is more significant, causing the solidified shell thickness on the inner curve to be thinner, which can easily cause steel breakout accidents. The M‐EMS can improve the uneven flow field caused by the nozzle position. In actual production, the SEN can be appropriately offset to the outer curve, and the application of M‐EMS can improve the flow field distribution of molten steel. [ABSTRACT FROM AUTHOR]

Published

2023