Effect of slag composition on kinetic behavior of deep deoxidation of 5 wt.% Si high-silicon austenitic stainless steel

IF 2.5 2区材料科学

Journal of Iron and Steel Research International Pub Date : 2024-07-09 DOI:10.1007/s42243-024-01250-1

Guan-xiong Dou, Han-jie Guo, Jing Guo, Xue-cheng Peng, Qing-yun Chen

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Abstract

Based on a thermodynamic study of 5 wt.% Si high-silicon austenitic stainless steel (SS-5Si) smelting using CaF₂–CaO–Al₂O₃–MgO–SiO₂ slag to obtain a low oxygen content of less than 10 × 10⁻⁴ wt.%, a kinetic mass transfer model for deep deoxidation was established through laboratory studies, and the effects of slag components and temperature on deoxidation during the slag–steel reaction process of SS-5Si were systematically studied. The experimental data verified the accuracy of the model predictions. The results showed that the final oxygen content in the steel at 1873 K was mainly controlled by the oxygen content derived from the activity of SiO₂ regulated by the [Si]–[O] equilibrium reaction in the slag system; in particular, when the slag basicity R (R = w(CaO)/w(SiO₂), where w(CaO) and w(SiO₂) are the contents of CaO and SiO₂ in the slag, respectively) is 3, the Al₂O₃ content in the slag needs to be less than 2.7%. The mass transfer rate equation for the kinetics of the deoxidation reaction revealed that the mass transfer of oxygen in the liquid metal is the rate-controlling step under different slag conditions at 1873 K, and the oxygen transfer coefficient k_O,m increases with increasing the slag basicity from 4.0 × 10⁻⁶ m s⁻¹ (R = 1) to 4.3 × 10⁻⁵ m s⁻¹ (R = 3). k_O,m values at R = 2 and R = 3 are almost the same, indicating that high slag basicity has little effect. The integral of the mass transfer rate equation for the deoxidation reaction of SS-5Si under different slag conditions is obtained. The total oxygen content of the molten steel decreases with increasing basicity from an initial content of 22 × 10⁻⁴ to 3.2 × 10⁻⁴ wt.% (R = 3), consistent with the change in k_O,m with slag basicity. At R = 2, the slag–steel reaction takes 15 min to reach equilibrium (w[O] = 5.5 × 10⁻⁴ wt.%), whereas at R = 3, the slag–steel reaction takes 30 min to reach equilibrium (w[O] = 3.2 × 10⁻⁴ wt.%). Considering the depth of deoxidation and reaction time of SS-5Si smelting, it is recommended the slag basicity be controlled at approximately 2. Similarly, the effect of temperature on the deep deoxidation of SS-5Si was studied.

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炉渣成分对 5 wt.% Si 高硅奥氏体不锈钢深度脱氧动力学行为的影响

基于对使用 CaF2-CaO-Al2O3-MgO-SiO2 熔渣冶炼 5 wt.% Si 高硅奥氏体不锈钢（SS-5Si）以获得低于 10 × 10-4 wt.% 氧含量的热力学研究，通过实验室研究建立了深度脱氧的动力学传质模型，并系统研究了 SS-5Si 熔渣-钢反应过程中熔渣成分和温度对脱氧的影响。实验数据验证了模型预测的准确性。结果表明，1873 K 时钢中的最终氧含量主要受炉渣体系中[Si]-[O]平衡反应调节 SiO2 活性所产生的氧含量控制；特别是当炉渣碱度 R（R = w(CaO)/w(SiO2)，其中 w(CaO) 和 w(SiO2) 分别为炉渣中 CaO 和 SiO2 的含量）为 3 时，炉渣中的 Al2O3 含量需小于 2.7%。脱氧反应动力学的传质速率方程表明，在 1873 K 的不同炉渣条件下，液态金属中氧的传质是速率控制步骤，氧传质系数 kO,m 随炉渣碱度的增加而增加，从 4.0 × 10-6 m s-1 (R = 1) 增加到 4.3 × 10-5 m s-1 (R = 3)。得出了不同熔渣条件下 SS-5Si 脱氧反应的传质速率方程积分。钢水中的总氧含量随着碱性的增加而降低，从初始含量 22 × 10-4 降至 3.2 × 10-4 wt.%（R = 3），这与 kO,m 随炉渣碱性的变化是一致的。在 R = 2 时，炉渣-钢反应需要 15 分钟达到平衡（w[O] = 5.5 × 10-4 wt.%），而在 R = 3 时，炉渣-钢反应需要 30 分钟达到平衡（w[O] = 3.2 × 10-4 wt.%）。考虑到 SS-5Si 冶炼的脱氧深度和反应时间，建议将炉渣碱度控制在 2 左右。

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来源期刊

Journal of Iron and Steel Research International 工程技术-冶金工程

自引率

16.00%

发文量

161

审稿时长

2.8 months

期刊介绍： Publishes critically reviewed original research of archival significance Covers hydrometallurgy, pyrometallurgy, electrometallurgy, transport phenomena, process control, physical chemistry, solidification, mechanical working, solid state reactions, materials processing, and more Includes welding & joining, surface treatment, mathematical modeling, corrosion, wear and abrasion Journal of Iron and Steel Research International publishes original papers and occasional invited reviews on aspects of research and technology in the process metallurgy and metallic materials. Coverage emphasizes the relationships among the processing, structure and properties of metals, including advanced steel materials, superalloy, intermetallics, metallic functional materials, powder metallurgy, structural titanium alloy, composite steel materials, high entropy alloy, amorphous alloys, metallic nanomaterials, etc..