Development of constitutive models for concentrated suspensions via particle-level simulations. The outcome of this work will be a comprehensive theoretical framework by which accurate microstructural information is distilled into a macro-scale constitutive model of particulate suspensions, readily useable for modelling of practical industrial applications. This work will have a direct impact on the design capability and performance of a wide range of mechanisms and industrial processes involvin ....Development of constitutive models for concentrated suspensions via particle-level simulations. The outcome of this work will be a comprehensive theoretical framework by which accurate microstructural information is distilled into a macro-scale constitutive model of particulate suspensions, readily useable for modelling of practical industrial applications. This work will have a direct impact on the design capability and performance of a wide range of mechanisms and industrial processes involving suspensions. The development of better models for industrially useful suspensions offers a competitive advantage for a diverse range of Australia industry, from the food preparation sector, to mineral slurry transport, and water filtration and recycling.Read moreRead less
Microstructural mechanisms of magnetorheological suspensions. A magnetorheological suspension (MRS) is a "smart material" which shows an enormous but reversible increase in flow resistance upon application of a magnetic field. These tunable fluids have many engineering applications, such as in adjustable vibration damping systems. This project comprises a series of innovative experiments and computer simulations, which will lead to a predictive constitutive model. We will investigate the underly ....Microstructural mechanisms of magnetorheological suspensions. A magnetorheological suspension (MRS) is a "smart material" which shows an enormous but reversible increase in flow resistance upon application of a magnetic field. These tunable fluids have many engineering applications, such as in adjustable vibration damping systems. This project comprises a series of innovative experiments and computer simulations, which will lead to a predictive constitutive model. We will investigate the underlying physical mechanisms governing the mechanical response of MRS, including the behaviour under small strains and under squeeze flow, the effects of rheometer wall conditions, and the role of matrix viscoelasticity or viscoplasticity.Read moreRead less
Drag Force on Bubbles and Particles in Turbulent Flows. Australian exports are dominated by the minerals, metallurgical and chemicals industries, with minerals exports worth at least $40 billion annually. Many of the production processes are underpinned by the complex interaction between particles, bubbles and liquids. It is important that we understand the complex interactions taking place. This will enable us to improve existing operations and also to design completely new technologies, especi ....Drag Force on Bubbles and Particles in Turbulent Flows. Australian exports are dominated by the minerals, metallurgical and chemicals industries, with minerals exports worth at least $40 billion annually. Many of the production processes are underpinned by the complex interaction between particles, bubbles and liquids. It is important that we understand the complex interactions taking place. This will enable us to improve existing operations and also to design completely new technologies, especially in the emerging fields of nano and biotechnology. This project is important because it adds to our knowledge in the national priority area of Transforming Australian Industries, and its success will ensure that our industries remain at the forefront of innovation and are globally competitive. Read moreRead less
Multiscale modeling of flexible fibrous suspensions under flow. The outcome of this work will be a comprehensive theoretical framework by which microstructural information is distilled into an accurate multiscale model of fibre suspensions, readily applicable to industrial situations. This work will have a direct impact on the design capability and performance of a wide range of mechanisms and industrial processes involving fibres. The development of better models for industrially useful suspen ....Multiscale modeling of flexible fibrous suspensions under flow. The outcome of this work will be a comprehensive theoretical framework by which microstructural information is distilled into an accurate multiscale model of fibre suspensions, readily applicable to industrial situations. This work will have a direct impact on the design capability and performance of a wide range of mechanisms and industrial processes involving fibres. The development of better models for industrially useful suspensions offers a competitive advantage for a diverse range of Australian industries, from the paper manufacture sector, to the production of fibre-filled composite materials.Read moreRead less
The role of floc structure in the formation of sediments and filter cakes. The project aims to understand at a fundamental level if and in what way the fractal structure of aggregates of fine particles is preserved when forming sediments and filter cakes. The effect of this structure on processes for separating solids and liquids is significant: each year, millions of dollars stand to be saved though more efficient filtration, and more efficient thickening of mineral slurries. Improved understan ....The role of floc structure in the formation of sediments and filter cakes. The project aims to understand at a fundamental level if and in what way the fractal structure of aggregates of fine particles is preserved when forming sediments and filter cakes. The effect of this structure on processes for separating solids and liquids is significant: each year, millions of dollars stand to be saved though more efficient filtration, and more efficient thickening of mineral slurries. Improved understanding allows intelligent design of flocculation systems to optimise the performance of downstream solid - liquid separation processes, maximising economic and environmental returns.Read moreRead less
Investigations of Surface-Gas Reactions and Mixing in Micro-combustion. This proposal is closely aligned with the third national research priority of 'Frontier Technologies and Transforming Australian Industries'. Micro-power generation is one such technology that will provide power for a broad array of current and future devices ranging from micro-electronics to micro-propulsion systems. Studies conducted here will lead to enhanced mixing and flame stability in micro-combustors. This will place ....Investigations of Surface-Gas Reactions and Mixing in Micro-combustion. This proposal is closely aligned with the third national research priority of 'Frontier Technologies and Transforming Australian Industries'. Micro-power generation is one such technology that will provide power for a broad array of current and future devices ranging from micro-electronics to micro-propulsion systems. Studies conducted here will lead to enhanced mixing and flame stability in micro-combustors. This will place Australia at the leading edge of international research in this field and enables technological advancement in the emerging micro-power generation industry. Another benefit of this research is the training of graduates who will most likely lead future developments in micro-combustion engineering.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453823
Funder
Australian Research Council
Funding Amount
$445,124.00
Summary
Atomic Force Microscopy Facility for Soft Interfaces. This proposal seeks to establish a specialized atomic force microscopy facility capable of performing measurements on nanometre scales at soft interfaces. This will service the needs of and collaboration between leading researchers at the Universities of Newcastle, Melbourne, New South Wales and James Cook University. The facility will allow direct measurements of properties of the interactions between atoms, molecules and surfaces associated ....Atomic Force Microscopy Facility for Soft Interfaces. This proposal seeks to establish a specialized atomic force microscopy facility capable of performing measurements on nanometre scales at soft interfaces. This will service the needs of and collaboration between leading researchers at the Universities of Newcastle, Melbourne, New South Wales and James Cook University. The facility will allow direct measurements of properties of the interactions between atoms, molecules and surfaces associated with soft interfaces which are required for ongoing research in fluid-fluid interfaces, surfactant and polymer adsorbed layers, and biomolecules as well as to develop new processes in emerging fields of nanotechnology, biotechnology, and medical and pharmaceutical production.Read moreRead less
Innovative Research in Gaseous and Spray Combustion. This research will maintain Australia's lead as an international provider of new knowledge in combustion science. Novel combustion technologies which may result either direclty or indirectly from these investigations will have huge benefits to Australia. World communities will continue to call for reduced emissions of greenhouse gases and combustion-generated pollutants. This demand must be pursued and satisfied by new technologies and the res ....Innovative Research in Gaseous and Spray Combustion. This research will maintain Australia's lead as an international provider of new knowledge in combustion science. Novel combustion technologies which may result either direclty or indirectly from these investigations will have huge benefits to Australia. World communities will continue to call for reduced emissions of greenhouse gases and combustion-generated pollutants. This demand must be pursued and satisfied by new technologies and the research program proposed here makes a step forward in this direction. The training of graduates as future combustion scientists of high standards is extremely important given that such experitise is in high demand both nationally and internationally.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883111
Funder
Australian Research Council
Funding Amount
$570,000.00
Summary
A Laser Facility for Imaging the Time Evolution of Scalars in Turbulent Flows. Establishing this facility will maintain Australia's position at the international leading edge of research in energy, the environment, combustion, and fluid mechanics. The new diagnostics capabilities will advance science through projects that serve the first National Research Priority and assist industry in the design and development of clean combustion devices and energy efficient technologies. The new facility wil ....A Laser Facility for Imaging the Time Evolution of Scalars in Turbulent Flows. Establishing this facility will maintain Australia's position at the international leading edge of research in energy, the environment, combustion, and fluid mechanics. The new diagnostics capabilities will advance science through projects that serve the first National Research Priority and assist industry in the design and development of clean combustion devices and energy efficient technologies. The new facility will also be made available to researchers from non-participating institutions at operating costs and will provide the training platform for graduates from all Australian Universities. This will ensure the continuity of future research and developments in these and related fields in Australia.Read moreRead less
Strongly Transient Processes in Turbulent Combustion. This project will investigate strongly transient effects in turbulent flames and will ultimately enhance the capabilities of engineers in the design and optimisation of clean and efficient combustion technologies. The new knowledge generated will contribute to Australia's commitment to reduce the carbon footprint and facilitate the transition to a low carbon economy. It will also keep Australia at the leading edge of research in energy effici ....Strongly Transient Processes in Turbulent Combustion. This project will investigate strongly transient effects in turbulent flames and will ultimately enhance the capabilities of engineers in the design and optimisation of clean and efficient combustion technologies. The new knowledge generated will contribute to Australia's commitment to reduce the carbon footprint and facilitate the transition to a low carbon economy. It will also keep Australia at the leading edge of research in energy efficiency and environmental sustainability, a national research priority.Read moreRead less