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Particle classification using a ferrofluid in a non uniform magnetic field. The separation of micron size components of suspensions according to the size and density of the particles is presently an intractable problem. However, by using a magnetized ferrofluid it should be possible to generate unique particle trajectories for each combination of particle size and density. This study investigates the potential of this strategy for separating such particles, laying the foundation for new small-sc ....Particle classification using a ferrofluid in a non uniform magnetic field. The separation of micron size components of suspensions according to the size and density of the particles is presently an intractable problem. However, by using a magnetized ferrofluid it should be possible to generate unique particle trajectories for each combination of particle size and density. This study investigates the potential of this strategy for separating such particles, laying the foundation for new small-scale diagnostic "lab-on a chip" technology that could be used in biotechnology to study whole blood, or in mineral processing to control energy intensive ball mills for mineral particle liberation.Read moreRead less
Influence of Parallel Inclined Plates within Liquid Fluidized Beds. The aim of this study is to develop a fundamental understanding of the influence of a set of parallel inclined plates within a liquid fluidized bed. A broad range of systems that process particulate suspensions are very likely to benefit from this innovative arrangement. Considerably higher throughputs and improved separation performance are expected. A theoretical model will be developed and validated experimentally. The study ....Influence of Parallel Inclined Plates within Liquid Fluidized Beds. The aim of this study is to develop a fundamental understanding of the influence of a set of parallel inclined plates within a liquid fluidized bed. A broad range of systems that process particulate suspensions are very likely to benefit from this innovative arrangement. Considerably higher throughputs and improved separation performance are expected. A theoretical model will be developed and validated experimentally. The study will also examine whether a critical shear rate can be used to selectively separate particles on the basis of differences in density. This work will strengthen the potential exploitation of this new technology, and help train and educate a student at the PhD level in the area.Read moreRead less
Particle Transport and Separation in High Aspect Ratio Inclined Channels. This project will be of benefit to the Australian coal and mineral processing industries, worth tens of billions of dollars to the Australian economy each year. The objective is to establish new options for the processing of particles as large as 50mm, and smaller than 50 microns in size, and hence significantly extend the operating size range of the Reflux Classifier. The development of new resources, especially those of ....Particle Transport and Separation in High Aspect Ratio Inclined Channels. This project will be of benefit to the Australian coal and mineral processing industries, worth tens of billions of dollars to the Australian economy each year. The objective is to establish new options for the processing of particles as large as 50mm, and smaller than 50 microns in size, and hence significantly extend the operating size range of the Reflux Classifier. The development of new resources, especially those of poorer grade, requires more effective separation technology. Success in this project will significantly benefit the end users of the technology and also contribute to Australia's Mining Services industry.Read moreRead less
Data-driven modelling of complex reactive flows. Complex reactive flow is dominant in many chemicals, physical and biological processes and should be optimised online for operational efficiency and stability, yet it is hindered by the lack of reliable model techniques. The project tackles this challenge by developing a next-generation data-driven modelling approach via integrating continuum/discrete-scale fluid-particle dynamics with system/control theories, supported by lab/plant experiments. D ....Data-driven modelling of complex reactive flows. Complex reactive flow is dominant in many chemicals, physical and biological processes and should be optimised online for operational efficiency and stability, yet it is hindered by the lack of reliable model techniques. The project tackles this challenge by developing a next-generation data-driven modelling approach via integrating continuum/discrete-scale fluid-particle dynamics with system/control theories, supported by lab/plant experiments. Driven by online data, the generic approach can open up a powerful way to reliably describe the inner state of reactors and online predict operation anomalies. The outcomes can help transform a range of industries to smart manufacturing and design, which is vital to Australia's technological future.Read moreRead less
Fundamental research for advanced gasification technologies for low-rank coal and biomass in the carbon-constrained world. This project aims to acquire fundamental knowledge in order to develop advanced gasification technologies with high efficiencies and the capability to couple with carbon storage facilities in the carbon-constrained future. These technologies will contribute to the reduction of Australia's CO2 emissions using its cheap low-rank coal and biomass.
Phase stability of biomass fast pyrolysis bio-oil: behaviour and control. This project aims to carry out a systematic investigation into the phase behaviour and control of biomass fast pyrolysis into bio-oil and its derived fuels. The project addresses the major problem of fuel phase separation during processing and handling that cause significant operational challenges, for example pumping difficulties and line clogging, during storage, transport and applications of these fuels. The outcomes in ....Phase stability of biomass fast pyrolysis bio-oil: behaviour and control. This project aims to carry out a systematic investigation into the phase behaviour and control of biomass fast pyrolysis into bio-oil and its derived fuels. The project addresses the major problem of fuel phase separation during processing and handling that cause significant operational challenges, for example pumping difficulties and line clogging, during storage, transport and applications of these fuels. The outcomes include the discovery of fundamental knowledge on the phase structure, stability and behaviour of the products of biomass fast pyrolysis bio-oil and its derived fuels and the development of essential engineering tools for predicting and controlling phase behaviour and stability of these fuels.Read moreRead less
Oxy-cofiring of bio-slurry and coal for carbon-negative power generation. This project aims to study co-firing characteristics of bio-slurry fuels and coal under oxy-pulverised-fuel (oxy-PF) conditions. Oxy-PF stationary systems can capture the renewable carbon embedded in bio-slurry fuel from biomass pyrolysis for sequestration, leading to carbon-negative power generation. The expected outcomes are critical knowledge and data regarding the underlying thermochemical reactions responsible for the ....Oxy-cofiring of bio-slurry and coal for carbon-negative power generation. This project aims to study co-firing characteristics of bio-slurry fuels and coal under oxy-pulverised-fuel (oxy-PF) conditions. Oxy-PF stationary systems can capture the renewable carbon embedded in bio-slurry fuel from biomass pyrolysis for sequestration, leading to carbon-negative power generation. The expected outcomes are critical knowledge and data regarding the underlying thermochemical reactions responsible for the co-pyrolysis, volatiles/char co-firing and ash formation from bio-slurry/coal co-firing under oxy-PF conditions. This is expected to enhance Australia's competitive advantage in clean power generation through high-impact scientific and technological innovations, and strengthen the related knowledge and skill base in the country.Read moreRead less
Fires of halogenated industrial chemicals and their impact on the Australian environment. Recent large fires of industrial chemicals in Australia led to significant environmental pollution. In this project, we will develop sophisticated techniques to assess pollutants formed in fires of commonly used industrial chemicals. The results will find immediate applications in training fire brigades in their response to chemical fires.
Atomically thin membranes to transform chemical separations. Energy-efficient chemical separation is at the heart of modern resource and manufacturing industries, central to a prosperous and sustainable Australia. This project aims to develop next generation membrane technologies to transform chemical separations by employing recent breakthrough in materials discovery and nanofluidics. Expected outcomes include new fundamental understandings on sub-continuum transport physics and new atomically ....Atomically thin membranes to transform chemical separations. Energy-efficient chemical separation is at the heart of modern resource and manufacturing industries, central to a prosperous and sustainable Australia. This project aims to develop next generation membrane technologies to transform chemical separations by employing recent breakthrough in materials discovery and nanofluidics. Expected outcomes include new fundamental understandings on sub-continuum transport physics and new atomically thin membranes that enable energy-efficient separations for processing challenging streams beyond water purification. This project aims to position Australia at the forefront of sustainable separation technology and make the local resource and manufacturing industries more sustainable and globally competitive.Read moreRead less
Coproduction of Bioslurry and Liquid Transport Fuels from Biomass Pyrolysis. This project aims to develop a novel technology from biomass pyrolysis for coproducing a diesel/biodiesel/bio-oil blend as a liquid transport fuel for local use and a high-quality bioslurry fuel suitable for transport to centralised stationary applications. The technology aims to address key issues associated with current biofuel production from biomass pyrolysis due to the undesired high acidity, poor stability and hig ....Coproduction of Bioslurry and Liquid Transport Fuels from Biomass Pyrolysis. This project aims to develop a novel technology from biomass pyrolysis for coproducing a diesel/biodiesel/bio-oil blend as a liquid transport fuel for local use and a high-quality bioslurry fuel suitable for transport to centralised stationary applications. The technology aims to address key issues associated with current biofuel production from biomass pyrolysis due to the undesired high acidity, poor stability and high oxygen content of bio-oil. The liquid transport fuel is expected to be produced without the expensive bio-oil hydrotreating for deep de-oxygenation, which is otherwise required for using bio-oil as feedstock in conventional petroleum refining process. Both biofuel products can be adoptable for wide applications in the existing vast infrastructure.Read moreRead less