Transferring behavior and reaction kinetics of saprolitic laterite during metalized reduction in the presence of calcium fluoride

[Display omitted] •Thermodynamics of the NSMR in the presence of CaF2 was firstly analyzed.•Concentrating Ni with CaF2 addition under different factors was further studied.•Transformation mechanism of minerals during the NSMR process was investigated.•Reaction kinetics was firstly examined, and Ea =...

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Bibliographic Details
Published in:Minerals engineering 2022-01, Vol.176, p.107353, Article 107353
Main Authors: Yang, Weijiao, Ma, Baozhong, Li, Xiang, Hu, Die, Wang, Chengyan, Wang, Hua
Format: Article
Language:English
Subjects:
Iron
Low-nickel saprolitic laterite
Nickel
Nonmolten-state metalized reduction
Reaction kinetics
Transferring behavior
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Summary:[Display omitted] •Thermodynamics of the NSMR in the presence of CaF2 was firstly analyzed.•Concentrating Ni with CaF2 addition under different factors was further studied.•Transformation mechanism of minerals during the NSMR process was investigated.•Reaction kinetics was firstly examined, and Ea = 309.16 kJ mol−1 was determined. Laterite ore is the most important primary base source of nickel, however low-nickel saprolitic laterite is difficult to economically utilize. This study aims to investigate the proposed nonmolten-state metalized reduction (NSMR) technology for saprolitic laterite. First, the thermodynamics of NSMR in the presence of calcium fluoride was analyzed using laterite from Southwest China as raw material. Then, the process for concentrating nickel and iron under different factors was systematically studied. Subsequently, the behavior of nickel and iron during the NSMR process was analyzed. Lastly, the kinetics of the metalized reduction process was examined, and the reaction apparent activation energy was determined. Results showed that nickel and iron recoveries can reach as high as 92.9% and 84.6%, respectively, and these two metals are produced in the form of nickel–iron concentrate, which can be used as raw material for steel making. Calcium fluoride can inhibit nickel from entering the nickel-bearing magnesium silicate phase, avoiding the inertness of nickel and considerably increasing its metallization. The reaction process of NSMR conforms to the Avrami–Eroféev reaction model (n = 0.5) and the apparent activation energy (Ea) is 309.16 kJ mol−1. This research demonstrates the theoretical perfection of the proposed NSMR technology, which may realize the commercial utilization of worldwide low-nickel ore in a long-term stagnant state.
ISSN:0892-6875
1872-9444
DOI:10.1016/j.mineng.2021.107353