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Reduction of saprolite nickel ore using methane-argon gas mixture with laboratory-scale simulated rotary kiln-electric furnace (RKEF) technology

Amalia Jihan Nabilah, Bima Satritama, Taufiq Hidayat, Pekka Taskinen, Imam Santoso, Hamzah Kurniadani, Zulfiadi Zulhan

2025Minerals Engineering6 citationsDOIOpen Access PDF

Abstract

Saprolite nickel ore is typically processed using a pyrometallurgical route called Rotary Kiln-Electric Furnace (RKEF), which contributes to about 75 % of nickel production from laterite nickel ores. In RKEF technology, coal plays multiple roles as a reductant, fuel, and electricity source. Methane is a viable option as reductant and fuel for reducing CO 2 emissions in the nickel industry, particularly as a stopgap measure until hydrogen production can be scaled up. However, there has been limited research on using methane as a reductant in nickel production. This study aims to produce ferronickel from saprolite nickel ore through a laboratory-scale RKEF using methane gas. Initially, FactSage 8.2 was used to investigate the thermodynamics of the process. A series of laboratory experiments were carried out in two stages to simulate the RKEF process. It involved varying the reduction temperature (500–900 °C), reduction time (15–120 min), and gas composition (25 and 75 vol% CH 4 /Ar) before each calcine was melted at 1550 °C for 2 h. The average composition of metals obtained was 71.3 % Fe and 14.3 % Ni. The results showed that methane can be used to produce ferronickel with a similar composition as commercial ferronickel.

Topics & Concepts

FerroalloyNickelMethaneMetallurgySaproliteMethanationMaterials sciencePyrometallurgyHydrogenLateriteCarbon fibersSlag (welding)Refining (metallurgy)Gas compositionFossil fuelMetal Extraction and BioleachingIron and Steelmaking ProcessesMetallurgical Processes and Thermodynamics
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