Reduction and Carburization Mechanisms for CO + H2 Reduction in Shaft Furnace Conditions

Hedda Pousette, Niklas Kojola, Oscar Hessling
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Abstract

Direct reduction, with reducing gases containing CO and H2, is becoming an increasingly important process for reduction of iron ore to iron. There is a need for understanding reduction and carburization mechanisms for CO + H2 gases in shaft-like conditions. The experimental setup includes a column of pellets, where ingoing gas of 40 pct CO and 60 pct H2 and known temperature enters at the bottom and exits at the top. Experiments are carried out at 600 °C, 700 °C, 800 °C, and 900 °C for 1, 2.5, or 5 hours with gas flow rate of 4 or 6 nL/min. After reduction, pellets are removed, taking note of vertical position, and analyzed for reduction degree, total carbon, and cementite content. Results show that there is a gradient in reduction and carburization over the column height, which decreases with increasing time. Comparison of thermodynamic calculations with experimental results shows that kinetic factors have a strong influence on reduction and carburization. Consumption of gas by reduction or carburization reactions limits gas suitability at the local reaction sites. It could therefore be of interest to design the shaft process so that reduction and carburization take place in two steps.

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竖炉条件下 CO + H2 还原和渗碳机理
利用含有 CO 和 H2 的还原气体进行直接还原,正日益成为铁矿石还原成铁的重要工艺。需要了解 CO + H2 气体在类似竖井条件下的还原和渗碳机理。实验装置包括一个球团柱,在已知温度下,40 pct CO 和 60 pct H2 气体从底部进入,从顶部排出。实验在 600 ℃、700 ℃、800 ℃ 和 900 ℃ 温度下进行 1、2.5 或 5 小时,气体流速为 4 或 6 nL/min。还原后,取出颗粒,注意垂直位置,分析还原度、总碳和雪明碳柱含量。结果表明,还原和渗碳在炉柱高度上存在梯度,随着时间的增加梯度减小。热力学计算结果与实验结果的比较表明,动力学因素对还原和渗碳有很大影响。还原或渗碳反应对气体的消耗限制了局部反应点的气体适用性。因此,有必要设计竖炉工艺,使还原和渗碳分两步进行。
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