Abstract
More than 100 million tons of red mud were produced annually in the world over the short time range from 2011 to 2018. Red mud represents one of the metallurgical by-products more difficult to dispose of due to the high alkalinity (pH 10–13) and storage techniques issues. Up to now, economically viable commercial processes for the recovery and the reuse of these waste were not available. Due to the high content of iron oxide (30–60% wt.) red mud ranks as a potential raw material for the production of iron through a direct route. In this work, a novel process at the laboratory scale to produce iron sponge (≤ 1300 °C) or cast iron (> 1300 °C) using blast furnace sludge as a reducing agent is presented. Red mud-reducing agent mixes were reduced in a muffle furnace at 1200, 1300, and 1500 °C for 15 min. Pure graphite and blast furnace sludges were used as reducing agents with different equivalent carbon concentrations. The results confirmed the blast furnace sludge as a suitable reducing agent to recover the iron fraction contained in the red mud. For all the conditions tested, the metallization degree was higher than 70%, and the best condition to reduce red mud through blast furnace sludge was identified at 1:1 red mud/blast furnace (B.F.) sludges equal to 0.85 C/Fe2O3.
Highlights
Red muds, or red sludges, are the most concerning and produced industrial waste from primary aluminum production, i.e., the Bayer process
The best mixing conditions with graphite as reducing agent were defined as 0.85 and 1.19 C/Fe2 O3 ratios. Only these two conditions were replicated with blast furnace sludge
This work presented a new method for the reduction of the bauxite process tailings, through blast furnace sludges
Summary
Red sludges, are the most concerning and produced industrial waste from primary aluminum production, i.e., the Bayer process. From 2000 to 2018 alumina production increased from approximately 55 Mt to 130 Mt, mainly due to a fast growth in Chinese production capacity [4]. This means about 130–325 Mt of red mud produced in only 2018. This amount of hazardous waste still continues to be one of the most important disposal problems in the mining industry [5]. The other components include silica, unleached residual aluminum, titanium oxide [5,6], and rare earth traces [7,8]
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