Browse > Article
http://dx.doi.org/10.4191/kcers.2015.52.5.389

Phase Transition and Metalization of DRI According to the Quality of Iron Oxide  

Yun, Young Min (Energy & Environmental Div., Korea Institute of Ceramic Eng. & Tech)
Jung, Jae Hyun (Energy & Environmental Div., Korea Institute of Ceramic Eng. & Tech)
Seo, Sung Kwan (Energy & Environmental Div., Korea Institute of Ceramic Eng. & Tech)
Chu, Yong Sik (Energy & Environmental Div., Korea Institute of Ceramic Eng. & Tech)
Publication Information
Journal of the Korean Ceramic Society / v.52, no.5, 2015 , pp. 389-394 More about this Journal
Abstract
Direct reduced iron was made using an electric furnace. The reduction ratio of direct reduced iron varied depending on the grade of iron ore. Coal played an important role as a reducing agent in making the direct reduced iron. The coal must contain a suitable amount of volatile components having high calorie values and low impurity content. In this study, oxidized pellets were directly reduced using anthracite as a reductant in an electric furnace. Direct reduction behaviors of hematite and magnetite pellets were confirmed in a coal-based experiment. Reduction behaviors were demonstrated by analyzing the chemical compositions, measuring the reducibility, and observing the phase changes and microstructure. The superior reducibility of hematite pellets can be ascribed to their high effective diffusivity, which is due to their high porosity. The quickly after reducing for 40min and achieves a high value at the end of the reduction.
Keywords
Direct reduced iron; Coal based reduction; Oxidized pellets;
Citations & Related Records
연도 인용수 순위
  • Reference
1 D. Guo, M. Hu, C. Pu, B. Xiao, Z. Hu, S. Liu, X. Wang, and X. Zhu, "Kinetics and Mechanisms of Direct Reduction of Iron Ore-biomass Composite Pellets with Hydrogen Gas," Int. J. Hydrogen Energy, 40 [14] 4733-40 (2015).   DOI
2 R. Sen, S. Dehiya, U. Pandel, and M. K. Banerjee, "Utilization of Low Quality Coal for Direct Reduction of Mill Scale to Obtain Sponge Iron: Effect of Reduction Time and Particle Size," Procedia Earth and Planet. Sci., 11 8-14 (2015).   DOI
3 OSIL Process, Indian Patent No.:16457.
4 M. Kirschen, K. Badr, and H. Pfeifer, "Influence of Direct Reduced Iron on the Energy Balance of the Electric Arc Furnace in Steel Industry," Energy, 36 [10] 6146-55 (2011).   DOI
5 2011 World direct reduction statistics, www.midrex.com, Audited by WORLD STEEL.
6 Y. MAN, J. Feng, Y. Chen, and J. Zhou, "Mass Loss and Direct Reduction Characteristics of Iron Ore-coal Composite Pellets," J. Iron Steel Res. Int., 21 [12] 1090-94 (2014).   DOI
7 T. Zhang, C. Lei, and Q. Zhu, "Reduction of Fine Iron Ore via a Two-step Fluidized Bed Direct Reduction Process," Powder Technol., 254 1-11 (2014).   DOI
8 N. R. Dey, A. K. Prasad, and S. K. Singh, "Energy Survey of the Coal Based Sponge Iron Industry," Case Studies in Thermal Engineering, 6 1-15 (2015).   DOI
9 D. Mohanty, A. Chandra, and N. Chakraborti, "Genetic Algorithms Based Multi-objective Optimization of an Iron Making Rotary Kiln," Comput. Mater. Sci., 45 [1] 181-88 (2009).   DOI
10 Y. Guo, J. Gao, H. Xu, K. Zhao, and X. Shi, "Nuggets Production by Direct Reduction of High Iron Red Mud," J. Iron Steel Res. Int., 20 [5] 24-7 (2013).
11 D. Zhu, V. Mendes, T. Chun, J. Pan, Q. Li, J. Li, and G. Qiu, "Direct Reduction Behaviors of Composite Binder Magnetite Pellets in Coal-based Grate-rotary Kiln Process," ISIJ Int., 51 [2] 214-19 (2011).   DOI