Industrial Transformation Research Hubs - Grant ID: IH130200004
Funder
Australian Research Council
Funding Amount
$3,966,350.00
Summary
ARC Research Hub for transforming the mining value chain. ARC Research Hub for transforming the mining value chain. This Research Hub aims to transform the mining value chain to make significant improvements to industry practices through enhancing ore deposit discovery, mineral processing, and environmental management of ores and waste materials. The Hub will bring together a team of world-class researchers, industry partners and research facilities to develop end-user driven solutions to improv ....ARC Research Hub for transforming the mining value chain. ARC Research Hub for transforming the mining value chain. This Research Hub aims to transform the mining value chain to make significant improvements to industry practices through enhancing ore deposit discovery, mineral processing, and environmental management of ores and waste materials. The Hub will bring together a team of world-class researchers, industry partners and research facilities to develop end-user driven solutions to improve profitability and productivity in Australia’s mining industry.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.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100087
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Enabling future technology by building light element analysis capability: a light element optimised ultra-high resolution electron microprobe. The capability to characterise the chemistry of materials at very small scales is critical for geologists, metallurgists and materials scientists. The new instrument is world-leading technology that will enable analysis of light element-rich materials at extremely high resolution (< 50 nanometers) with very low detection limits.
Industrial Transformation Research Hubs - Grant ID: IH140100035
Funder
Australian Research Council
Funding Amount
$5,000,000.00
Summary
ARC Research Hub for Computational Particle Technology. ARC Research Hub for Computational Particle Technology. This research hub aims to develop and apply advanced theories and mathematical models to design and optimise particulate and multiphase processes that are widely used in the minerals and metallurgical industries. This should be achieved through detailed analysis of the fundamentals governing fluid flow, heat and mass transfer at different time and length scales, facilitated by various ....ARC Research Hub for Computational Particle Technology. ARC Research Hub for Computational Particle Technology. This research hub aims to develop and apply advanced theories and mathematical models to design and optimise particulate and multiphase processes that are widely used in the minerals and metallurgical industries. This should be achieved through detailed analysis of the fundamentals governing fluid flow, heat and mass transfer at different time and length scales, facilitated by various novel research techniques. Research outcomes including theories, computer models and simulation techniques, as well as well-trained young researchers, should have a significant impact across a range of industries of vital importance to Australia’s economic and technological future, including the minerals, metallurgical, materials, chemical, energy, pharmaceutical and environment sectors.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100150
Funder
Australian Research Council
Funding Amount
$700,000.00
Summary
A Digital Mineralogy & Materials Characterisation Hub for Petrology, Mineralogy, Exploration, Metallurgy and Reservoir Characterisation Research. A digital mineralogy and materials characterisation hub for petrology, mineralogy, exploration, metallurgy and reservoir characterisation research: This project will establish a digital mineralogy and materials characterisation hub for applications in petrology, geometallurgy, reservoir characterisation, environmental science, soil science, mineral pro ....A Digital Mineralogy & Materials Characterisation Hub for Petrology, Mineralogy, Exploration, Metallurgy and Reservoir Characterisation Research. A digital mineralogy and materials characterisation hub for petrology, mineralogy, exploration, metallurgy and reservoir characterisation research: This project will establish a digital mineralogy and materials characterisation hub for applications in petrology, geometallurgy, reservoir characterisation, environmental science, soil science, mineral processing and extractive metallurgy research. An automated mineral analysis instrument would complement the mineral separation (selFrag HV pulse fragmentation) and microanalytical facilities (SHRIMP/Cameca ion microprobes and ELA-ICP-MS) available to the participants via the John de Laeter Centre for Isotope Research. The instrument and software package making up the FEI QEMSCAN 650F model is the most advanced configuration on the market, and ideally suited for the high level research projects undertaken by the partner institutions. Read moreRead less
Improved control of dioxin emissions during iron ore sintering. This project aims to develop an innovative assessment of dioxin formation through analysis and speciation of its precursors (Cl and Cu). Iron ore sintering is the industrial process with the highest emissions of dioxins and furans to the environment in Australia, which are amongst the most toxic substances produced by man. The aim of this project is to conduct critical investigations required for control of dioxin emissions during i ....Improved control of dioxin emissions during iron ore sintering. This project aims to develop an innovative assessment of dioxin formation through analysis and speciation of its precursors (Cl and Cu). Iron ore sintering is the industrial process with the highest emissions of dioxins and furans to the environment in Australia, which are amongst the most toxic substances produced by man. The aim of this project is to conduct critical investigations required for control of dioxin emissions during iron ore sintering. The expected outcome of this project is the development of control mechanisms for the process conditions responsible for dioxin formation. This should provide significant benefits, such as assisting the Australian iron ore industry to address the environmental requirements of their international trade partners and sustain their iron ore exports.Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH130200031
Funder
Australian Research Council
Funding Amount
$3,273,780.00
Summary
ARC Research Hub for Advanced Technologies for Australian Iron Ore. ARC Research Hub for Advanced Technologies for Australian Iron Ore. This Research Hub aims to bring together three world-class groups covering fine particle beneficiation, raw materials handling, and iron ore characterisation to address the complex issues that arise from the different ore types that have emerged in recent years. This Research Hub will focus on the development and adoption of advanced beneficiation and handling t ....ARC Research Hub for Advanced Technologies for Australian Iron Ore. ARC Research Hub for Advanced Technologies for Australian Iron Ore. This Research Hub aims to bring together three world-class groups covering fine particle beneficiation, raw materials handling, and iron ore characterisation to address the complex issues that arise from the different ore types that have emerged in recent years. This Research Hub will focus on the development and adoption of advanced beneficiation and handling technologies into iron ore mining operations, and new knowledge for informing producers and end-users, while providing the training for a new generation of research leaders.Read moreRead less
Hot stage separation of non-ferrous fraction during iron ore reduction. The project aims to provide in-situ investigation of the behaviour and properties of the non-ferrous fraction in iron ore during reduction. The results aim to allow industry to: improve the quality of the final metallic iron product; economically separate and recover high-value non-ferrous impurities in the iron ore; reduce waste generated by ironmaking; and enable utilisation of, and add value to, iron ores that currently a ....Hot stage separation of non-ferrous fraction during iron ore reduction. The project aims to provide in-situ investigation of the behaviour and properties of the non-ferrous fraction in iron ore during reduction. The results aim to allow industry to: improve the quality of the final metallic iron product; economically separate and recover high-value non-ferrous impurities in the iron ore; reduce waste generated by ironmaking; and enable utilisation of, and add value to, iron ores that currently are not commercially viable due to their high impurity levels and low iron contents. The project aims to help expand the mining potential of the currently unviable iron ore deposits and enable industry to maintain the economic benefits from iron ore production in the years to come.Read moreRead less
Atmospheric emissions of toxic trace metals and volatiles during thermal processing of iron ores. The project will investigate the contribution of iron ore to the composition, chemistry and mechanism of transformation of atmospheric volatile emissions and vapour trace elements during thermal processing with the aim to strengthen the environmental performance and efficiency of the ironmaking process.
Enhanced Fractionation of Mineral Particles According to Density. Aims: -to achieve a significant advance in the hydrodynamic fractionation of particles on the basis of density, and develop an algorithm to deconvolve the fractionation data to produce the underlying density distribution of the particles. Significance: This density distribution, which is used in resource assessment, plant design, and process evaluation in mineral processing, is currently produced using toxic, and environmentally d ....Enhanced Fractionation of Mineral Particles According to Density. Aims: -to achieve a significant advance in the hydrodynamic fractionation of particles on the basis of density, and develop an algorithm to deconvolve the fractionation data to produce the underlying density distribution of the particles. Significance: This density distribution, which is used in resource assessment, plant design, and process evaluation in mineral processing, is currently produced using toxic, and environmentally damaging heavy liquids, despite the emergence of alternative mineral analysers. Expected Outcomes: -a safe, cost effective basis for generating the density distribution. Benefits: -increasing mineral resource recovery through improved access to critical data, while eliminating the need for the toxic heavy liquids.
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