AI Article Synopsis
- A low-temperature roasting and water-washing process can effectively treat electrolytic manganese residue (EMR) and recover manganese without hazardous impacts.
- The study assesses how different temperatures and times during roasting affect the transformation of EMR phases, finding that roasting for 60 min at 600 °C maximizes manganese recovery at 67.12%.
- After washing, the manganese concentration in the solution stabilizes after 25 minutes; with three wash cycles, the resulting concentration is suitable for electrolytic manganese production, and toxicity tests confirm compliance with safety standards.
Article Abstract
A combined low-temperature-roasting and water-washing process is investigated as a hazard-free method to treat electrolytic manganese residue (EMR) and recover manganese. In this study, the phase transformation characteristics and a thermodynamics analysis of the low temperature roasting process of EMR are evaluated. In addition, the effects of temperature and time on the phase transformation of EMR in the roasting process and the washing characteristics of roasted EMR samples are also investigated. Results reveal that some unstable phases within EMR are transformed into more stable phases depending on the treatment time/temperature conditions used and EMR roasted for 60 min at 600 °C (R) exhibit the highest rate of manganese recovery, 67.12 %. After 25 min of deionized water washing, the concentration of manganese in solution from R material become stable, whereas after 6 washing cycles the concentration of manganese in the solution is < 0.005 g/L. The R material with three wash cycles results in a manganese-water solution concentration that is suitable for use in electrolytic manganese metal production. Finally, toxicity leaching tests show that the concentrations of ions present in the leaching solution are all lower than the regulatory limits mandated by the Chinese Integrated Wastewater Discharge Standard GB 8978-1996.
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| http://dx.doi.org/10.1016/j.jhazmat.2020.123561 | DOI Listing |
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