Mechanical-Electrical dewatering (EDW) of mine Tailings: Influence of voltage level on water recovery and moisture reduction

Mechanical-Electrical dewatering (EDW) of mine Tailings: Influence of voltage level on water recovery and moisture reduction

[Display omitted] •The combination of mechanical and electrical dewatering (EDW) shows great potential to recover additional water from filtered tailings.•Water Removal, Additional Water Removal, Specific Energy and Normalized Specific Energy indices help evaluate the efficiency of the experiments.•...

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Bibliographic Details
Published in:Minerals engineering Vol. 175; p. 107303
Main Authors: Shafaei, Foojan, Doulati Ardejani, Faramarz, Bahroudi, Abbas, Hoseini, Mahdi, Khakpour, Mohammadjavad
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-01-2022
Subjects:
Electrical resistivity
Electro-dewatering
Electro-osmosis
Process water
Tailings Slurry
Process water
Tailings Slurry
Electro-osmosis
Electrical resistivity
Electro-dewatering
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Summary:[Display omitted] •The combination of mechanical and electrical dewatering (EDW) shows great potential to recover additional water from filtered tailings.•Water Removal, Additional Water Removal, Specific Energy and Normalized Specific Energy indices help evaluate the efficiency of the experiments.•The application of higher voltage results in the higher water recovery and the lower moisture content of the filtered tailings.•Because of moisture reduction, the electrical resistivity of the filtered tailings shows an ascending trend during EDW. This study aims to investigate the potential of mechanical–electrical dewatering (EDW) on the recovery of process water from tailings slurry of Miduk copper mine. The EDW experiments were carried out using three voltage levels, including 50, 70 and 90 V, and the mechanical pressures of 3 and 6 bar for 120 min. The moisture content and the pH values of the filtered tailings were determined at the end of the process. Moreover, the electrical resistivity and the electric energy consumption were calculated. To investigate the energy efficiency of the recovered/removed water, four indices were calculated including, water removal (WR), additional water removal (AWR), specific energy (SE) and normalised specific energy (NSE). Mechanical filtration extracted 63% and 71% of the process water at 3 and 6 bar, respectively. Also, EDW experiments recovered 8–31% more additional water. A higher rate was achieved for the process water by applying more voltage while increasing energy consumption. The EC and pH values of the recovered water were in a suitable range of the process water for Miduk copper mine. The average moisture content of filtered tailings reduced to 3.7–12.7% and indicated an ascending trend from anode to cathode sides. Although the pH values of the filtered tailings in the anode side decreased to the point of zero charge, the reverse electro-osmosis process did not significantly affect the potential of EDW. Due to the joined impact of moisture variation, temperature and hydrolysis process, the interpretation of electrical resistivity was complex. Overall, the least amount of energy consumption for removing the additional process water was achieved by applying a voltage level of 70 V. However, a combination of a mechanical pressure of 3 bar and a voltage of 90 V recovered up to 92% of water by the optimal values of SE and NSE indices.
ISSN:0892-6875
1872-9444
DOI:10.1016/j.mineng.2021.107303