Discrete particle modelling and analysis of complex particle-fluid flows. Multiphase processes are widely used in both conventional and modern industries in Australia and worldwide, however rarely reach more than 60% of design capacity because of a poor understanding of their fundamental characteristics. This project aims to overcome this problem using an extensive combined fundamental and applied approach. The resulting theories, computer models and simulation techniques will be applied to imp ....Discrete particle modelling and analysis of complex particle-fluid flows. Multiphase processes are widely used in both conventional and modern industries in Australia and worldwide, however rarely reach more than 60% of design capacity because of a poor understanding of their fundamental characteristics. This project aims to overcome this problem using an extensive combined fundamental and applied approach. The resulting theories, computer models and simulation techniques will be applied to improve process design, control and optimisation. Consequentially, productivity and Australian competitiveness will be significantly enhanced in its most important industries such as minerals, metallurgical, chemical, energy, and materials.Read moreRead less
Multiscale modelling of the transport phenomena of liquid iron and slag in ironmaking blast furnace. Blast furnace ironmaking is a key operation in the steel industry which, with an annual turnover around $11 billion, is a significant manufacturing sector in Australia. This project, focused on the behaviour of liquid iron and slag, can generate computer models that can reliably describe the complicated multiphase flow and thermochemical processes in the furnace. The implementation of the resulta ....Multiscale modelling of the transport phenomena of liquid iron and slag in ironmaking blast furnace. Blast furnace ironmaking is a key operation in the steel industry which, with an annual turnover around $11 billion, is a significant manufacturing sector in Australia. This project, focused on the behaviour of liquid iron and slag, can generate computer models that can reliably describe the complicated multiphase flow and thermochemical processes in the furnace. The implementation of the resultant models and the new understanding should lead to long life campaigns, better operational control, decreased fuel consumption, improved productivity and reduced environmental impact. This, together with the proposed research training, is important to the development of Australia's competitive steel industry.Read moreRead less
Fundamental Investigation of Kinetics of Ferro-Silicon Reactions in Cupola Scrap Melting Processes. The aims of this project include development of fundamental understanding of Ferro-silicon reactions in cupola scrap melting processes. This project will advance the scrap melting processes by enhancing their economic viability and environmental compatibility by optimising the reactions of Ferro-silicon which is one of the major sources of operating problems. Specifically the project will achieve ....Fundamental Investigation of Kinetics of Ferro-Silicon Reactions in Cupola Scrap Melting Processes. The aims of this project include development of fundamental understanding of Ferro-silicon reactions in cupola scrap melting processes. This project will advance the scrap melting processes by enhancing their economic viability and environmental compatibility by optimising the reactions of Ferro-silicon which is one of the major sources of operating problems. Specifically the project will achieve optimisation of Ferro-silicon utilisation, reduction in refractory consumption, minimisation of industrial slag waste generation, improved product composition control. The scientific outcomes include data and mechanisms of Ferro-silicon reactions with gas and graphite phases, kinetic models to describe the influence of Ferro-silicon and process variables.Read moreRead less