JOURNAL PAPER

 

Activated alumina-based adsorption and recovery of excess fluoride ions subsequent to calcium and magnesium removal in base metal leach circuits

 

 

L. Lorenzen^{I, II}; J.J. Eksteen^{I, III}; M. Pelser^{I, IV}; C. Aldrich^I; G. Georgalli^I

^IDepartment of Process Engineering, University of Stellenbosch, Matieland, South Africa
^IIBHP Billiton, Perth, Australia
^IIILonmin Platinum, Sandton, South Africa
^IVAnglo Research, Johannesburg, South Africa

 

 

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SYNOPSIS

An effective electrowinning process in hydrometallurgical industry requires fluoride levels in the base metal solution to be less than 10 mg/ℓ. Selective removal of the fluoride ions from base solution is thus desired, if fluoride was added to control calcium and magnesium in the circuit. Consequently, adsorption of fluoride onto activated alumina was studied in a batch and a column set-up. The effects of base metal solution pH, temperature, initial concentration and flow rate on activated alumina performance were investigated in either a batch or column configuration. A two-level factorial experimental design was implemented in studying column dynamics. Results demonstrate that activated alumina is an effective adsorbent for selective removal of fluoride from base solution. In the batch operation, fluoride was removed to values below the maximum allowable concentration (10 mg/ℓ) when pH was ≤ 8. In the column adsorption step at 55°C and 600mg/ℓ initial concentration, up to 16 bed volumes were processed before breakthrough level was reached. Desorption step using 1% sodium hydroxide solution achieved an elution of 8 bed volumes. The activated alumina (AA) had a capacity of 8.65 gF/ℓ AA at the 10 mgF/ℓ fluoride breakthrough level during the column adsorption test.

Keywords: Fluoride; activated alumina; adsorption; recovery; regeneration

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