Influence of Na_2CO_3 as Additive on Direct Reduction of Boron-bearing Magnetite Concentrate 被引量：1

Influence of Na_2CO_3 as Additive on Direct Reduction of Boron-bearing Magnetite Concentrate

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摘要 Boron-bearing magnetite concentrate is typically characterized by low grade of iron and boron （wTFe = 51%- 54%, WB2O3 =6%-8%）, as well as the close intergrowth of ascharite phase and magnetite phase. A promising technology was proposed to separate iron and boron by coupling the direct reduction of iron oxides and Na activation of boron minerals together. The influence of Na2CO3 as additive on the direct reduction of boron-bearing magnetite was studied by chemical analysis, kinetic analysis, XRD analysis and SEM analysis. The results showed that the ad- dition of Na2CO3 not only activated boron minerals, but also reduced the activation energy of the reaction and pro- moted the reduction of iron oxides. Besides, the addition of Na2CO3 changed the composition and melting point of non-ferrous phase, and then promoted the growth and aggregation of iron grains, which was conducive to the subse- quent magnetic separation. Thus, the coupling of the two processes is advantageous, Boron-bearing magnetite concentrate is typically characterized by low grade of iron and boron （wTFe = 51%- 54%, WB2O3 =6%-8%）, as well as the close intergrowth of ascharite phase and magnetite phase. A promising technology was proposed to separate iron and boron by coupling the direct reduction of iron oxides and Na activation of boron minerals together. The influence of Na2CO3 as additive on the direct reduction of boron-bearing magnetite was studied by chemical analysis, kinetic analysis, XRD analysis and SEM analysis. The results showed that the ad- dition of Na2CO3 not only activated boron minerals, but also reduced the activation energy of the reaction and pro- moted the reduction of iron oxides. Besides, the addition of Na2CO3 changed the composition and melting point of non-ferrous phase, and then promoted the growth and aggregation of iron grains, which was conducive to the subse- quent magnetic separation. Thus, the coupling of the two processes is advantageous,

作者 Yong-li LI Jing-kui QU Guang-ye WEI Tao QI

机构地区 National Engineering Laboratory for Hydrometallurgical Cleaner Production Technology Key Laboratory of Green Process and Engineering

出处《Journal of Iron and Steel Research International》 SCIE EI CAS CSCD 2016年第2期103-108,共6页

基金 Item Sponsored by National Natural Science Foundation of China(51304181) National Science Foundation for Distinguished Young Scholars of China(51125018)

关键词 LUDWIGITE kinetic analysis direct reduction magnetic separation sodium carbonate ludwigite kinetic analysis direct reduction magnetic separation sodium carbonate

分类号 TF55 [冶金工程—钢铁冶金]

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Influence of Na_2CO_3 as Additive on Direct Reduction of Boron-bearing Magnetite Concentrate 被引量：1

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