Study of Mineralogy and Metallurgical Properties of Lump Ores

Study of Mineralogy and Metallurgical Properties of Lump Ores

The ironmaking process in blast furnaces using iron lumps is an energy-efficient and low-carbon initiative that helps lower the cost of the ironmaking process. The physical and chemical properties of raw materials, process mineralogy, and metallurgical properties of three Malaysian iron ore lumps we...

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Bibliographic Details
Published in:Metals (Basel ) Vol. 12; no. 11; p. 1805
Main Authors: Zhu, Deqing, Jiang, Yin, Pan, Jian, Yang, Congcong
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-10-2022
Subjects:
Blast furnace chemistry
Chemical properties
Cost control
Disintegration
Emission standards
goethite
Hematite
High temperature
Iron ores
Ironmaking
Low temperature
Metallurgical analysis
metallurgical properties
Metallurgy
Mineralogy
Minerals
open porosity
ore iron lump
Particle size
Permeability
Porosity
Production costs
Quartz
Raw materials
Malaysia
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Summary:The ironmaking process in blast furnaces using iron lumps is an energy-efficient and low-carbon initiative that helps lower the cost of the ironmaking process. The physical and chemical properties of raw materials, process mineralogy, and metallurgical properties of three Malaysian iron ore lumps were researched in this paper, with the goal of showing the relationship between metallurgical qualities and mineralogy. The results show that lump ore A has a better decrepitation index, with a DI−6.3mm of only 0.2%; lump ore J has better reducibility and low-temperature reduction disintegration index, with RI and RDI+6.3mm values of 88.39% and 87.55%, respectively; and the three lump ores have excellent softening and melting properties and a high permeability index. The metallurgical properties of lump ore and mineralogical characterizations are generally correlated, the decrepitation performance of lump ore is mostly determined by the presence of goethite, and the original porosity is unrelated. The higher the content, the worse the decrepitation performance; lump ore’s reducibility is mostly determined by the open porosity and the content of newly generating hematite at high temperatures, which has no relationship to its original porosity. The higher the open porosity, the higher the goethite content, the higher the newly generated porous hematite content, and the better the lump ore’s reducibility; the higher the original hematite content in the lump ores, the lower the open porosity at high temperatures and the worse the reduction degradation characteristics.
ISSN:2075-4701
2075-4701
DOI:10.3390/met12111805