Lead recovery from a typical Brazilian sludge of exhausted lead-acid batteries using an electrohydrometallurgical process

Lead recovery from the nonmetallic portion of exhausted lead-acid batteries, also called sludge, was investigated using an electrohydrometallurgical process. Among 13 aqueous solutions studied in solubility tests, only the following three were chosen for the whole process (leaching and electrowinnin...

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Published in:Hydrometallurgy 2002-09, Vol.65 (2), p.137-144
Main Authors: Ferracin, Luiz C, Chácon-Sanhueza, Abel E, Davoglio, Rogério A, Rocha, Luis O, Caffeu, Daniele J, Fontanetti, Adilson R, Rocha-Filho, Romeu C, Biaggio, Sonia R, Bocchi, Nerilso
Format: Article
Language:English
Subjects:
Acidic and alkaline leaching electrolytes
Applied sciences
Electrohydrometallurgical process
Exact sciences and technology
Hydrometallurgy
Lead recovery
Lead-acid batteries
Metals. Metallurgy
Production of metals
Production of non ferrous metals. Process materials
Recycling
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Summary:Lead recovery from the nonmetallic portion of exhausted lead-acid batteries, also called sludge, was investigated using an electrohydrometallurgical process. Among 13 aqueous solutions studied in solubility tests, only the following three were chosen for the whole process (leaching and electrowinning steps): tetrafluoroboric acid (200 g/L), glycerol (92 g/L)+sodium hydroxide (120 g/L) and sodium potassium tartrate (150 g/L)+sodium hydroxide (150 g/L). The tetrafluoroboric acid showed an attractive performance as leaching electrolyte due to its low cost and reasonable leaching strength. In the electrowinning process using the solution obtained from the leaching of a desulfated sludge with this acidic electrolyte, compact, adherent and highly pure lead deposits were produced at 250 A/m 2. Scanning electron micrographs (SEM) of lead deposits obtained at different current densities in the range of 250–500 A/m 2 revealed a marked influence of the current density on the deposit morphology.
ISSN:0304-386X
1879-1158
DOI:10.1016/S0304-386X(02)00087-7