Dynamic input adjustment to improve the stability of transient swirling flows in spray dryers. This project will use leading-edge numerical techniques to advance the science of flow stabilisation using dynamic flow modulation techniques. Improved sustainable processing will be enabled using this flow modulation in spray dryers to reduce processing problems due to the depositon of particles on dryer walls.
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
Finite Rate Chemistry Effects in Turbulent Combustion. This proposal is closely aligned with the first national research priority of an environmentally sustainable Australia. The projects outlined here will improve the modelling of finite rate chemistry effects in turbulent flames hence providing the necessary framework for advancing the science of combustion that will ultimately lead to clean combustion technologies. Improved computational design tools that result from this research will assist ....Finite Rate Chemistry Effects in Turbulent Combustion. This proposal is closely aligned with the first national research priority of an environmentally sustainable Australia. The projects outlined here will improve the modelling of finite rate chemistry effects in turbulent flames hence providing the necessary framework for advancing the science of combustion that will ultimately lead to clean combustion technologies. Improved computational design tools that result from this research will assist Australia in meeting its obligations to the AP6 program towards the development of new energy technologies. Another important benefit of this research is the training of graduates as future combustion scientists that are highly sought after both locally and overseas.Read moreRead less
Advanced Studies of Turbulent Combustion: Premixed to Nonpremixed. Despite limited resources, the world will continue to rely heavily on fossil fuels to satisfy the growing energy requirements. There is a pressing need, therefore, for cleaner, more efficient combustion not only to conserve energy but also to reduce environmental emissions of pollutants. This project tackles several major areas of turbulent combustion covering premixed and nonpremixed flames of gaseous and liquid fuels. Each pro ....Advanced Studies of Turbulent Combustion: Premixed to Nonpremixed. Despite limited resources, the world will continue to rely heavily on fossil fuels to satisfy the growing energy requirements. There is a pressing need, therefore, for cleaner, more efficient combustion not only to conserve energy but also to reduce environmental emissions of pollutants. This project tackles several major areas of turbulent combustion covering premixed and nonpremixed flames of gaseous and liquid fuels. Each project involves complex calculations and validation with measurements obtained using advanced laser diagnostic methods. This is a major research program leading to advanced numerical methods which will eventually be implemented in numerical tools to optimise combustor designs.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0238345
Funder
Australian Research Council
Funding Amount
$373,000.00
Summary
Advanced Laser Diagnostics in Dilute Heterogeneous Combustion. This proposal seeks to establish a state-of-the-art laser diagnostics facility with unique capabilities for non-intrusive measurements in dilute multi-phase flows. Such heterogeneous flows which involve stationary surfaces, disperse suspended droplets or suspended particles are found in many applications including engines, furnaces, industrial and chemical processing and micro-combustion devices. This facility will give Australian re ....Advanced Laser Diagnostics in Dilute Heterogeneous Combustion. This proposal seeks to establish a state-of-the-art laser diagnostics facility with unique capabilities for non-intrusive measurements in dilute multi-phase flows. Such heterogeneous flows which involve stationary surfaces, disperse suspended droplets or suspended particles are found in many applications including engines, furnaces, industrial and chemical processing and micro-combustion devices. This facility will give Australian researchers the unprecedented opportunity to perform measurements of flow, mixing, temperature and composition fields in the gas and liquid or solid phases simultaneously. The resulting data will advance current knowledge in these complex flows and lead to new and improved reactor designs.
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Unravelling the mechanics of particle deposition at the micro-scale. This project aims to discover the mechanisms responsible for the interactions between aerosol particles and surfaces in a range of air flow conditions. The project expects to transform our understanding of particle deposition through a combination of novel laser-based diagnostic techniques, optical coherence tomography, and state of the art particle formulation methodologies. Expected outcomes of the project include delivery of ....Unravelling the mechanics of particle deposition at the micro-scale. This project aims to discover the mechanisms responsible for the interactions between aerosol particles and surfaces in a range of air flow conditions. The project expects to transform our understanding of particle deposition through a combination of novel laser-based diagnostic techniques, optical coherence tomography, and state of the art particle formulation methodologies. Expected outcomes of the project include delivery of new methods to optimise particle deposition, development of tunable powder formulations, as well as definition of particle-surface interaction mechanisms in flows. The project should provide significant benefits to particle systems for applications ranging from additive manufacturing to aerosol delivery.Read moreRead less
Dynamics of droplets and nanoparticles in turbulent flames. This project aims to study the dynamics of liquid fragments and the morphology of synthesised nanoparticles in atomising spray flames. Outcomes will include experimental databases and predictive models for atomising spray flames and nanoparticle inception, as well as a novel atomiser for flame spray pyrolysis. These will provide significant benefits to researchers and industry working on the optimisation of nanostructured material synth ....Dynamics of droplets and nanoparticles in turbulent flames. This project aims to study the dynamics of liquid fragments and the morphology of synthesised nanoparticles in atomising spray flames. Outcomes will include experimental databases and predictive models for atomising spray flames and nanoparticle inception, as well as a novel atomiser for flame spray pyrolysis. These will provide significant benefits to researchers and industry working on the optimisation of nanostructured material synthesis for smart sensors and catalysts, and the next generation efficient and low emission combustion engines.Read moreRead less
The Formation and Emission of Soot Nanoparticles from Turbulent Flames. This project aims to develop experimental and numerical approaches that will enable designers to control the formation and emission of soot nanoparticles from combustors. Ultrafine particles polluting our atmosphere originate from combustion sources and are now confirmed to pose serious health risks. As a result, new regulations will impose strict limits on the number of particles that can be emitted from engines. Satisfying ....The Formation and Emission of Soot Nanoparticles from Turbulent Flames. This project aims to develop experimental and numerical approaches that will enable designers to control the formation and emission of soot nanoparticles from combustors. Ultrafine particles polluting our atmosphere originate from combustion sources and are now confirmed to pose serious health risks. As a result, new regulations will impose strict limits on the number of particles that can be emitted from engines. Satisfying such regulations requires a yet unavailable understanding of the mechanisms that control the evolution of soot in turbulent flames. This project plans to use laser diagnostic methods to construct the experimental framework that will facilitate model development. The resulting predictive capabilities would contribute to a platform that enables engineers to optimise combustor designs.Read moreRead less