ArticleName |
Theoretical aspects of pyrometallurgical processing of sideroplesite ore |
Abstract |
An overview of the existing methods of processing and using of the Bakal sideroplesite ore is presented. Due to the high content of refractory magnesium oxide in the ore, this ore is used in a limited amount as an additive to traditional ore raw materials. To increase the use of ore, new scientific fundamentals of its pyrometallurgical processing are needed. The process of dissociation of ore carbonates is investigated, as well as the mechanism of solid-phase reduction of iron in the dissociation product. Calculated and experimental methods for studying the reduction process are presented. Based on the results of the thermodynamic calculation, it is established that the most fusible phase during metallization is metal because of carburization of iron and the formation of cast iron. Therefore, in order to realize solid-phase reduction without the formation of liquid phases, the temperature is selected to be no more than 1250 °C. It was revealed that the solid-phase reduction process is successfully realized inside the oxide phase in pieces measuring 20-30 mm. At the same time, metal contamination with harmful impurities of the reducing agent does not occur, as a result of which cheap energy coal can be used as the reducing agent. The composite metal-oxide material obtained as a result of solid-phase reduction of iron in sideroplesite contains direct reduce iron (up to 60-85 %) and magnesia (15-25 %), as well as in a small amount of silicon oxide and oxides of iron, manganese and aluminum. When analyzing the results of iron precipitate during metallization, we proceeded from the concept of an electronic mechanism for the reduction and separation in the space of the process of interaction of a reducing agent with anions of complex oxide and the precipitate of a metal phase in the volume of the oxide. Based on the obtained results, a pyrometallurgical processing scheme for lumpy sideroplesite ore in rotating furnaces is proposed to produce a composite metal oxide material that can be used as an additive to steelmaking units to increase the lining stability and reduce the concentration of non-ferrous metal impurities in the steel. |
References |
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