Cementation of Copper on Zinc in Agitated Vessels Equipped with Perforated Baffles as Turbulence Promoters

In this work, the possibility of intensifying the cementation process in stirred vessels was studied by using the perforated baffles as turbulence promoters; the cementation reaction of Cu +2 on Zn was selected as a model. Zn was used in the form of a sheet lining the inner wall of an agitated vesse...

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Bibliographic Details
Published in:Minerals & metallurgical processing 2021-04, Vol.38 (2), p.1203-1213
Main Authors: Ibrahim, B. S., Abdel-Aziz, M. H., El-Ashtoukhy, E-S. Z., Zewail, T. M., Zatout, A. A., Sedahmed, G. H.
Format: Article
Language:English
Subjects:
Agitation
Cementation
Copper
Engineering
Geometry
Impellers
Mass transfer
Materials Engineering
Metallic Materials
Mineral Resources
Parameters
Performance prediction
Rotation
Turbines
Turbulence
Vessels
Wastewater treatment
Zinc
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Summary:In this work, the possibility of intensifying the cementation process in stirred vessels was studied by using the perforated baffles as turbulence promoters; the cementation reaction of Cu +2 on Zn was selected as a model. Zn was used in the form of a sheet lining the inner wall of an agitated vessel. Parameters considered are initial concentration of Cu +2 , solution temperature, impeller rotation speed, and impeller geometry. Within the present range of parameters studied, the rate of cementation was found to increase with increasing initial concentration of Cu +2 , solution temperature, and impeller rotation speed. At the same rotational speed, a flat turbine gave a higher rate of cementation than a 45° pitched turbine. The present suggested that baffles’ geometry gave superior performance in terms of mass transfer of copper cementation compared to the conventional baffle geometry. All parameters that affect the rate of cementation were correlated in the form of dimensionless equations suitable for the design and performance prediction of the agitated vessel. Potential applications of the obtained results in the field of hydrometallurgical processes and wastewater treatment were discussed.
ISSN:2524-3462
2524-3470
DOI:10.1007/s42461-020-00375-7