硅铁脱氧对 55SiCr 弹簧钢中氧化物夹杂物的演变和清除的影响

Shuai Ma, Yang Li, Zhouhua Jiang, Meng Sun, Yunqie Mao, Dengyunfei Nie, Boyang Li, Changyong Chen
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引用次数: 0

摘要

使用 OTSInca、SEM-EDS 和 FactSage 8.0 方法研究了纯硅脱氧(Si 组)和硅铁脱氧(FeSi 组)对 55SiCr 弹簧钢中氧化物夹杂物演变的影响。与 Si 组相比,FeSi 组更有利于控制钢中的总氧含量,钢锭中的总氧含量仅为 0.0012 pct。硅组夹杂物的平均当量直径随着熔化过程不断减小,而铁硅组则恰恰相反,钢锭中夹杂物的平均当量直径达到 3.64 μm。硅组夹杂物的演化过程主要由 SiO2 → SiO2-MnO-Al2O3 → SiO2-MnO-Al2O3-MgO 实现,而 FeSi 组夹杂物的演化过程主要由 Al2O3-CaO → Al2O3-CaO-SiO2 → Al2O3-CaO-SiO2-MgO 实现。然而,由于夹杂物在铸锭中分布不均,夹杂物中会析出 MgO-Al2O3 和 MgO-SiO2。继续利用化学反应的吉布斯自由能来解释夹杂物的演变。FactSage 计算结果表明,在平衡凝固条件下,Si 组的主要夹杂物为 2Al2O3-2MgO-5SiO2、5Al2O3-4MgO-2SiO2 和 Al2O3-SiO2。此外,在 FeSi 组中得到的包裹体有 CaO-2MgO-8Al2O3、MgO-Al2O3 和 2CaO-MgO-2SiO2。FeSi 组夹杂物的变形能力不如 Si 组。夹杂物完全熔化温度和杨氏模量的计算结果表明,降低 Al2O3 和 MgO 在夹杂物中的比例可改善夹杂物的变形性。这项研究旨在为控制和去除弹簧钢中的夹杂物提供可靠的参考。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Effect of Ferrosilicon Deoxidation on the Evolution and Removal of Oxide Inclusions in 55SiCr Spring Steel

Effect of Ferrosilicon Deoxidation on the Evolution and Removal of Oxide Inclusions in 55SiCr Spring Steel

The effects of pure silicon deoxidation (Si group) and ferrosilicon deoxidation (FeSi group) on the evolution of oxide inclusions in 55SiCr spring steel are methodically examined using OTSInca, SEM-EDS, and FactSage 8.0. Compared with the Si group, the FeSi group is more favorable for controlling the total oxygen content in steel, and the total oxygen content in ingots is only 0.0012 pct. The average equivalent diameter of inclusions in the Si group continuously lessens with the melting process, while it is exactly the opposite in the FeSi group, and the average equivalent diameter of the inclusions in the ingots reaches 3.64 μm. The evolution of inclusions in the Si group is essentially provided by SiO2 → SiO2–MnO–Al2O3 → SiO2–MnO–Al2O3–MgO, whereas the evolution process of inclusions in the FeSi group is mainly characterized by Al2O3–CaO → Al2O3–CaO–SiO2 → Al2O3–CaO–SiO2–MgO. However, MgO–Al2O3 and MgO–SiO2 inclusions are precipitated in the inclusions because of the uneven distribution of inclusions in the ingot. In continuing, the Gibbs free energy of chemical reaction is utilized to explain the evolution of inclusions. FactSage calculation results reveal that the main inclusions in the Si group under equilibrium solidification conditions are 2Al2O3·2MgO·5SiO2, 5Al2O3·4MgO·2SiO2, and Al2O3·SiO2. Additionally, the inclusions in the FeSi group are obtained as CaO·2MgO·8Al2O3, MgO·Al2O3, and 2CaO·MgO·2SiO2. The deformability of inclusions in the FeSi group is not as good as in the Si group. The calculated results of the complete melting temperature and Young’s modulus of inclusions indicate that reducing the proportion of Al2O3 and MgO in inclusions leads to the improvement of the deformability of inclusions. This study is aimed to provide a fairly solid reference for controlling and removing inclusions in spring steel.

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