Influence of MgO on the reduction thermodynamics and kinetics of vanadium-bearing titanomagnetite carbon-containing pellet

doi:10.16085/j.issn.1000-6613.2017-0707

Abstract

Abstract: The influence of MgO on the reduction thermodynamics and kinetics of vanadium-bearing titanomagnetite carbon-containing pellet were studied and analyzed. The thermodynamic studies indicated that the MgO additive can promote the reduction reaction due to the replacement reaction between MgO and FeTiO₃, but the reduction reaction was restrained with the MgO-containing Fe-Ti-O compound production increased. The experimental results show that the reaction fraction of pellet is increased gradually by increasing the amount of MgO which the reduction temperature is lower than 1050℃;when the reduction temperature is more than 1050℃, there was a highest increase amplitude of the reaction fraction with the amount of MgO was 6%, the increase amplitude of the reaction fraction with the amount of MgO was 10% was the lowest, and the variety of the increase amplitude of the other samples was even. The kinetic study shows that the calculated value of three-dimensional diffusion model and interfacial reaction model fit well with the experimental values, it was concluded that the reduction process was controlled by diffusion and interface reaction. The reaction rate constant decrease gradually with increasing the amount of MgO.

Key words: magnesium oxide, vanadium-bearing titanomagnetite, thermodynamics, kinetics

摘要： 研究和分析了氧化镁对钒钛铁精矿含碳球团还原热力学和动力学影响。热力学研究表明：一方面在还原过程中添加氧化镁可以置换出钛铁矿中的氧化铁，促使还原反应进行；但另一方面，含氧化镁的铁钛化合物生成量增加，抑制了反应程度的进一步提高。实验结果表明：在还原温度低于1050℃时，随着氧化镁添加量的提高，球团的反应分数提高；在还原温度高于1050℃时，氧化镁添加量为6%时球团反应分数增加幅度最大，氧化镁添加量为10%时球团反应分数增幅最小，其余实验组的反应分数增幅变化较为一致。动力学研究表明：三维扩散模型和界面反应模型计算值更接近于实验值，说明添加氧化镁的钒钛铁精矿含碳球团的还原反应受扩散和界面反应混合控制；且随着氧化镁添加量的增加，反应的速率常数逐渐减小。

关键词: 氧化镁, 钒钛铁精矿, 热力学, 动力学

CLC Number:

TF559

WU Enhui, HOU Jing, LI Jun, HUANG Ping, YANG Shaoli, YU Tugang. Influence of MgO on the reduction thermodynamics and kinetics of vanadium-bearing titanomagnetite carbon-containing pellet[J]. Chemical Industry and Engineering Progress, 2017, 36(S1): 506-511.

吴恩辉, 侯静, 李军, 黄平, 杨绍利, 余图刚. 氧化镁对钒钛铁精矿含碳球团还原热力学及动力学的影响[J]. 化工进展, 2017, 36(S1): 506-511.

References

[1] 杜鹤桂.高炉冶炼钒钛磁铁矿原理[M].北京:科学出版社,1996.DU H G. Blast furnace smelting principle of vanadium-bearing titanomagnetite[M]. Beijing:Science Press, 1996.
[2] 唐国光.加强攀西战略资源创新开发试验区矿产资源开发[J].四川地质学报,2015(2):318-320.T G G. Strengthen exploitation of mineral resources in the Panxi strategic resourcesinnovation development experimental zone[J]. Acta Geologica Sichuan, 2015(2):318-320.
[3] 付卫国,谢洪恩.攀钢高炉钒钛磁铁矿冶炼的技术进步[J].钢铁,2008,43(10):21-24.FU W G, XIE H E. Progress in technology of vanadium-bearing titanomagnetite smelting at Pangang[J]. Iron and Steel, 2008, 43(10):21-24.
[4] FU W G, WEN Y C, XIE H E. Development of intensified technologies of vanadium-bearing titanomagnetite smelting[J]. Journal of Iron and Steel Research International, 2011, 18(4):7-10.
[5] 李兴华,蒲江涛.攀枝花高钛型高炉渣综合利用研究最新进展[J].钢铁钒钛,2011,32(2):10-14.LI X H, PU H T. The latest developments of integrated utilization on Panzhihua high titanium-bearing BF slag[J]. Iron Steel Vanadium Titanium, 2011, 32(2):10-14.
[6] 邹建新.攀枝花钒钛磁铁矿非高炉冶炼技术评价[J].轻金属,2010(5):51-54.ZOU Jianxin. Evaluation of non-blast furnace iron making technical on Panzhihua vanadium and titanium magnetite[J]. Light Metals, 2010(5):51-54.
[7] 陈德胜,宋波,王丽娜,等.钒钛磁铁精矿直接还原反应行为及其强化还原研究[J].北京科技大学学报,2011,33(11):1331-1336.CHEN D S, SONG B, WANG L N, et al. Direct reduction and enhanced reduction of vanadium-bearing titanomagnetite concentrates[J]. Journal of University of Science and Technology Beijing, 2011, 33(11):1131-1336.
[8] CHEN D S, SONG B, WANG L N, et al. Solid state reduction of Panzhihua titanomagnetite concentrates with pulverized coal[J]. Minerals Engineering, 2011, 24(8):864-869.
[9] ZHOU L H, ZENG F H. Statistical analysis of the effect of Na₂CO₃ as additive on the reduction of vanadic-titanomagnetite-coal mixed pellets[J]. Advanced Materials Research, 2010, 97-101:465-470.
[10] ZHANG J L, XING X D, CAO M M, et al. Reduction kinetics of vanadium titano-magnetite carbon composite pellets adding catalysts under high temperature[J]. Journal of Iron and Steel Research International, 2013, 20(2):1-7.
[11] 朱德庆,郭玉峰,邱冠周,等.钒钛磁铁精矿冷固球团催化还原机理[J].中南工业大学学报,2000,31(3):208-211.ZHU D Q, GUO Y F, QIU G Z, et al. Catalyzing the direct reduction of cold-bound pellets from titanomagnetite concentrate[J]. Journal of Central South University(Science and Technology), 2000, 31(3):208-211.
[12] HU T, LV X W, BAI C G, et al. Carbothermic reduction of titanomagnetite concentrates with ferrosilicon addition[J]. ISIJ International, 2013, 53(4):557-563.
[13] HAN G H, JIANG T, ZHANG Y B, et al. High-temperature oxidation behavior of vanadium, titanium-bearing magnetite pellet[J]. Journal of Iron and Steel Research International, 2011, 18(8):14-19.
[14] 陈德胜,王丽娜,齐涛,等.钒钛磁铁精矿的预氧化研究[J].湖南科技大学学报(自然科学版),2011,26(3):95-99.CHEN D S, WANG L N, QI T, et al. Study on preoxidation of vanadium-bearing titanomagnetite concentrates[J]. Journal of Hunan University of Science & Technology(Natural Science Edition), 2011,26(3):95-99.
[15] PARK E, OSTROVSKI O. Effects of preoxidation of titania-ferrous ore on the ore structure and reduction behavior[J]. ISIJ International, 2004, 44(1):74-81.
[16] 陈双印,储满生,唐钰,等.预氧化对钒钛磁铁矿球团矿相及内部结构的影响[J].东北大学学报(自然科学版),2013,34(4):536-541.CHEN S Y, CHU M S, TANG Y, et al. Effects of pre-oxidation on phase composition and microstructure of vanadium titano-magnetite[J]. Journal of Northeastern University(Natural Science), 2013, 34(4):536-541.
[17] 钒钛磁铁矿综合利用提取研究小组.钒钛磁铁矿球团还原过程的物理化学特点与0.2米竖炉试验[J].东北工学院学报,1977(4):1-21.The research group of comprehensive utilization for vanadium titanium magnetite. Physical and chemical characteristics for reduction process of vanadium titanium magnetite pellet and experimental study of 0.2m shaft furnace[J]. Journal of Northeastern University(Natural Science), 1977(4):1-21.
[18] 满毅,冯俊小,葛琦.含煤球团直接还原热失重及动力学分析[J].化工进展,2015,34(3):701-704.MAN Y, FENG J X, GE Q. Thermogravimetric and kinetics analysis of direct reduction of carbon-containing pellets[J]. Chemical Industry and Engineering Progress, 2015, 34(3):701-704.