Investigation of the Possibility of Obtaining Nickel-Containing Ferroalloys from Lateritic Nickel Ores by a Metallothermic Method
Abdirashit A. Yessengaliyev D. Kelamanov B. Sariyev O. Abikenova G. Nurgali N. Almagambetov M. Zhuniskaliyev T. Kuatbay Y. Abylay Z.
April 2025Multidisciplinary Digital Publishing Institute (MDPI)
Metals
2025#15Issue 4
This study presents the results of laboratory experiments on the processing of lateritic nickel ores mixed with coal and CaO, followed by the use of the obtained product for the smelting of nickel-containing ferroalloy by the metallothermic method. The study analyzed the thermodynamic effects of complex reductant concentration (silicon- and aluminum-containing alloy) on the reduction degree of nickel and iron. An experimental process resulted in a product containing Nitotal (2.60%) and Fetotal (60.52%), obtained through reduction roasting of lateritic nickel ore mixed with coal and an addition of 20 g of CaO at a temperature of 1150 °C. Under laboratory conditions, a nickel-containing ferroalloy was successfully obtained using the product after reduction roasting and a complex alloy as the reducing agent. The following optimal process parameters were determined: reductant consumption of 20 g per 100 g of the reduction roasting product, smelting temperature of 1600 °C, and slag basicity (CaO/SiO2) of 0.5. In this case, a nickel-containing ferroalloy with 72% iron, 15% nickel, and up to 5% chromium was successfully obtained through silicon and aluminum reduction using a complex alloy. A microstructural analysis of the nickel-containing alloy was conducted using an electron probe microanalyzer (JXA-8230) in combination with scanning electron microscopy (SEM) and energy-dispersive X-ray spectroscopy (EDS). The results showed that silicon and iron were the dominant elements in all particles. Nickel was detected at concentrations of up to 15.02 wt. %, while chromium reached 3.47 wt. %. Depending on the silicon concentration, the nickel-containing ferroalloy is recommended for corrosion-resistant steel production (Si < 5%) and as a reducing agent for ferronickel production (Si > 5%).
laterite nickel ore , metallothermic method , nickel-containing ferroalloys , silicon- and aluminum-containing reductant , thermodynamic modeling
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Department of Metallurgy and Mining, K. Zhubanov Aktobe Regional University, Aktobe, 030000, Kazakhstan
ERG Research and Engineering Center, 010000, Astana, Kazakhstan
Department of Science, Eurasian Technological University, Almaty, 050000, Kazakhstan
Department of Metallurgy and Materials Science, Karaganda Industrial University, Temiratau, 101400, Kazakhstan
Department of Metallurgy and Mining
ERG Research and Engineering Center
Department of Science
Department of Metallurgy and Materials Science
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