不同气氛下颗粒中 Fe3O4-MgO 体系的界面扩散和反应机理

Yuanbo Zhang, Kun Lin, Zijian Su, Xijun Chen, Ke Ma, Tao Jiang
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摘要

球团在高炉炉料结构中的比例逐渐增加,其中含镁助熔球团因其优异的冶金性能而得到广泛应用。为了进一步确定含镁熔剂球团在不同反应层中的固结机理,本研究对不同焙烧气氛下 Fe3O4-MgO 的相变和扩散行为进行了研究。结果表明,在惰性气氛中,Fe2+优先扩散到MgO层并与Mg2+结合形成MgyFe1-yO,然后,Fe3+和Fe2+与Mg2+结合形成[(MgO)x(FeO)1-x]-Fe2O3(0 ≤ x ≤ 1)。焙烧温度的升高有利于 Mg2+ 进入尖晶石相。在空气气氛中,Fe3O4 首先被氧化成 Fe2O3。Fe3+ 和 Mg2+ 反向扩散,然后结合成 MgxFe3-xO4(x = 1)。在惰性气氛中,Fe3O4 比在空气中更容易与氧化镁发生反应。增加氧分压有利于生成 MgxFe3-xO4 (x = 1)。在惰性气氛中,1200 °C时Fe3O4-MgO体系界面上Mg2+的扩散速率为1.88 µm/min,比空气气氛中的1.49 µm/min快。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Interface Diffusion and Reaction Mechanisms of Fe3O4–MgO System in Pellets Under Different Atmospheres

Interface Diffusion and Reaction Mechanisms of Fe3O4–MgO System in Pellets Under Different Atmospheres

The proportion of pellets in the blast furnace charge structure is gradually increasing, among which magnesium-bearing fluxed pellets have been widely applied due to their excellent metallurgical properties. To further determine the consolidation mechanism in different reaction layers of magnesium-bearing fluxed pellets, the phase transformation and diffusion behaviors of Fe3O4–MgO in different roasting atmospheres were investigated in this study. The results showed that Fe2+ preferentially diffused to the MgO layer and combined with Mg2+ to form MgyFe1−yO in inert atmosphere, and then, Fe3+ and Fe2+ binded to Mg2+ to form [(MgO)x(FeO)1−x]·Fe2O3 (0 ≤ x ≤ 1). The increase of roasting temperature was favorable for the entry of Mg2+ into the spinel phase. In air atmosphere, Fe3O4 was first oxidized to Fe2O3. Fe3+ and Mg2+ counter-diffused and then combined to MgxFe3−xO4 (x = 1). Fe3O4 reacted more readily with MgO in inert atmosphere than in air atmosphere. It was favorable to increase the oxygen partial pressure for MgxFe3−xO4 (x = 1) generation. The diffusion rate of Mg2+ at the interface of Fe3O4–MgO system in inert atmosphere was 1.88 µm/min at 1200 °C, which was faster than that of 1.49 µm/min in air atmosphere.

Graphical Abstract

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