Development of a novel process for recovering fluoride from spent pot-lining as AlF2(OH) using industrial waste solutions. Every year approximately 40,000 tonnes of a hazardous waste known as spent pot-lining is generated by Australia’s aluminium industry. It contains significant levels of leachable cyanide and fluoride and is currently being stored awaiting a suitable treatment technology. This project will develop a novel low-energy and low-cost process for extracting the fluoride as a usefu ....Development of a novel process for recovering fluoride from spent pot-lining as AlF2(OH) using industrial waste solutions. Every year approximately 40,000 tonnes of a hazardous waste known as spent pot-lining is generated by Australia’s aluminium industry. It contains significant levels of leachable cyanide and fluoride and is currently being stored awaiting a suitable treatment technology. This project will develop a novel low-energy and low-cost process for extracting the fluoride as a useful aluminium fluoride product that can be recycled back into the aluminium industry; destroy the cyanide; and recover other components for use in the metallurgical industry. If commercialised the benefit will be an end to the stockpiling of spent pot-lining in Australia, a more sustainable aluminium industry, and protection of the world’s natural fluoride resources.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100112
Funder
Australian Research Council
Funding Amount
$275,000.00
Summary
A Raman facility for advanced research supporting Australia’s natural gas, oil, coal and minerals industries. This modern Raman Spectroscopy facility will support the science and engineering that underpins the production and processing of Australia’s natural resources. Using high-pressure fibre optics, novel lasers and advanced imaging, the facility will enable the monitoring and improvement of processes and materials under extreme conditions.
Inorganic membrane percrystallisation in hydrometallurgy. This project aims is to develop the scientific and engineering basis for a new Australian inorganic membrane technology for the crystallisation of metal compounds. Inorganic membrane percrystallisation is a recent breakthrough promising improved productivity, energy savings and the ability to tailor particle properties. This project will develop a mechanistic model encompassing solution transport phenomena, crystal nucleation-growth-agglo ....Inorganic membrane percrystallisation in hydrometallurgy. This project aims is to develop the scientific and engineering basis for a new Australian inorganic membrane technology for the crystallisation of metal compounds. Inorganic membrane percrystallisation is a recent breakthrough promising improved productivity, energy savings and the ability to tailor particle properties. This project will develop a mechanistic model encompassing solution transport phenomena, crystal nucleation-growth-agglomeration and engineering process parameters affecting single and binary salt systems. This model will provide a basis for technology development benefiting Australia, such as the improvement of the production of nickel sulphate for the growing battery materials market.Read moreRead less