Hybrid cooling for coal fired power stations. Water shortage is a nation wide problem facing Australian industries. The project will directly benefit the Victorian power industry through water saving. If the new proposed hybrid cooling system concept is proved to be practically feasible, it will put the Australian power industry in a strong competitive position in terms of its efficiencies and waste heat recovery technology. Lowering the temperature of water into the cooling tower by 2 degree, b ....Hybrid cooling for coal fired power stations. Water shortage is a nation wide problem facing Australian industries. The project will directly benefit the Victorian power industry through water saving. If the new proposed hybrid cooling system concept is proved to be practically feasible, it will put the Australian power industry in a strong competitive position in terms of its efficiencies and waste heat recovery technology. Lowering the temperature of water into the cooling tower by 2 degree, by using the hybrid cooling system, it would save over 17,500,000 tons of makeup water per year for the Victorian power industry alone. At the same time, the waste heat recovered by the heat pump can be fed back to the power generation cycle. Read moreRead less
Novel Nanostructured Polymeric Membranes for Energy Storage Applications. The project will bring the following significant benefit to the Australian community and economy:1. Energy and Environmental benefit: will provide the nation with renewable energy storage solution, with zero emission and urban pollution2. Global Standing: will position Australia as global leader in sustainable energy storage technology through ZBB's novel battery system development.3. Intellectual property: will deliver th ....Novel Nanostructured Polymeric Membranes for Energy Storage Applications. The project will bring the following significant benefit to the Australian community and economy:1. Energy and Environmental benefit: will provide the nation with renewable energy storage solution, with zero emission and urban pollution2. Global Standing: will position Australia as global leader in sustainable energy storage technology through ZBB's novel battery system development.3. Intellectual property: will deliver the nation a strong intellectual property (IP) position in the frontier technology4. Training: will train junior researcher and a high quality graduate in an emerging and multidisciplinary area of research with commercial turnover of more than $1000 million in AustraliaRead moreRead less
New High Temperature Proton Conducting Polymer Electrolyte For Sustainable Energy Conversion Applications. This project will bring the following significant benefit to the Australian community and economy:i)Energy and Environmental benefit: will provide the nation with an ultimate solution to zero emission vehicles and urban pollution; ii)Global Standing: will position Australia to become a global leader in sustainable energy conversion technology through the efficient fuel cell systems developm ....New High Temperature Proton Conducting Polymer Electrolyte For Sustainable Energy Conversion Applications. This project will bring the following significant benefit to the Australian community and economy:i)Energy and Environmental benefit: will provide the nation with an ultimate solution to zero emission vehicles and urban pollution; ii)Global Standing: will position Australia to become a global leader in sustainable energy conversion technology through the efficient fuel cell systems development;iii)Intellectual Property (IP): will deliver the nation a strong intellectual property (IP) position in the frontier technology, and; iv)Training: will train 2 high quality graduates in an emerging and multidisciplinary area of research with commercial turnover of more than $1000 million in Australia.Read moreRead less
Development and Modellling of Advanced Coagulation and Oxidation Processes. The success of this program will help place Australia at the forefront of water quality control and management research. It will address concerns with managing and treating waters of changing characteristics due to climate change. In addition to the socio benefits, project success will also impart economic benefits to the nation through (i) fabricating new hybrid coagulants, that are versatile with enhanced performance ....Development and Modellling of Advanced Coagulation and Oxidation Processes. The success of this program will help place Australia at the forefront of water quality control and management research. It will address concerns with managing and treating waters of changing characteristics due to climate change. In addition to the socio benefits, project success will also impart economic benefits to the nation through (i) fabricating new hybrid coagulants, that are versatile with enhanced performance for removing NOM, and possess antimicrobial properties (ii) developing a new energy efficient photocatalysis technology.The proposed research will expand the knowledge base in this area and increase Australia’s international profile as a global leader in developing cutting-edge cost effective water resource technologies.Read moreRead less
Investigating the coupled dependencies of soot in turbulent flames by advanced laser diagnostics and modelling. The community will benefit from the project by reduced air pollution and improved health and safety. Soot is a major air pollutant, adversely effecting public health, while also contributing directly to global warming. It also dominates heat transfer and influences the emissions of NOx and CO2. The project will significantly advance detailed understanding and modelling capability of fl ....Investigating the coupled dependencies of soot in turbulent flames by advanced laser diagnostics and modelling. The community will benefit from the project by reduced air pollution and improved health and safety. Soot is a major air pollutant, adversely effecting public health, while also contributing directly to global warming. It also dominates heat transfer and influences the emissions of NOx and CO2. The project will significantly advance detailed understanding and modelling capability of flames containing soot. Hence it will provide significantly improved capability to optimise these flames in applications spanning gas turbines, power generation, minerals processing and fires.Read moreRead less
Detailed understanding of the behaviour of soot in, and emission from, turbulent flames and fires. While combustion processes involving soot have been widely employed for many years, their great complexity puts them beyond present capacity to understand or model reliably. Within a flame, soot plays an important role in radiant heat transfer, and hence in energy efficiency. Beyond a flame, soot can either be emitted as an unwanted air pollutant or as a desirable source of nano-particles, dependin ....Detailed understanding of the behaviour of soot in, and emission from, turbulent flames and fires. While combustion processes involving soot have been widely employed for many years, their great complexity puts them beyond present capacity to understand or model reliably. Within a flame, soot plays an important role in radiant heat transfer, and hence in energy efficiency. Beyond a flame, soot can either be emitted as an unwanted air pollutant or as a desirable source of nano-particles, depending on the application. The benefits to society from improved understanding and predictive capability include reduced air pollution, improved health and safety, increased efficiency in the utilisation of both fossil and alternative fuels, the support of the rapidly growing sector employing carbon nano-particles and increased fire safety. Read moreRead less
Energy Dissipation and Nanoscale Processes at Moving Contact Lines. The dynamic process of liquids wetting and dewetting, as moving contact lines pass over solid surfaces is central to many industrial operations and natural phenomena. Contact line motion plays a key role in micro and nanofluidics, the foundation of an emergent technology called process intensification, where large industrial processes can be reduced to Lilliputian in size. Substantial energy reduction and other benefits are exp ....Energy Dissipation and Nanoscale Processes at Moving Contact Lines. The dynamic process of liquids wetting and dewetting, as moving contact lines pass over solid surfaces is central to many industrial operations and natural phenomena. Contact line motion plays a key role in micro and nanofluidics, the foundation of an emergent technology called process intensification, where large industrial processes can be reduced to Lilliputian in size. Substantial energy reduction and other benefits are expected from this project, including the transformation of coarse particle flotation. Young PhD scientists and engineers will be educated in a rich research environment, with strong international research collaboration in areas of national priority.Read moreRead less
Investigation of Strategies to Improve the Efficiency of Industrial Radiators and Cooling Coils. Innovative strategies for improving in-service effectiveness of tube & plate-fin heat exchange 'coils' will be explored. Such coils are used throughout chemical process industries, diesel powered plant, vehicles and air-conditioning systems. Coil manufacture is a 'mature' industry, but design concepts have changed little since 1950. Fouling of diesel engine 'radiators' in dusty conditions and in mari ....Investigation of Strategies to Improve the Efficiency of Industrial Radiators and Cooling Coils. Innovative strategies for improving in-service effectiveness of tube & plate-fin heat exchange 'coils' will be explored. Such coils are used throughout chemical process industries, diesel powered plant, vehicles and air-conditioning systems. Coil manufacture is a 'mature' industry, but design concepts have changed little since 1950. Fouling of diesel engine 'radiators' in dusty conditions and in marine environments is endemic. New design concepts evolved via Computational Fluid Dynamic analysis will be manufactured and tested in the unique heat and mass transfer wind tunnel on the University's Industry Liaison Campus. The major outcome will be a rugged design methodology with broad applicability.Read moreRead less
Study of hydrocarbon flames under heat and gas recirculation conditions. This project aims to study gaseous flames under heat and gas recirculation conditions. This technology has been proven to reduce fuel consumption, improve thermal efficiency and substantially reduce nitric oxides emission. The effect of mixing, turbulence and temperature on the structure and stability of these flames will be investigated. The project combines experimental and computational research applied to a laboratory s ....Study of hydrocarbon flames under heat and gas recirculation conditions. This project aims to study gaseous flames under heat and gas recirculation conditions. This technology has been proven to reduce fuel consumption, improve thermal efficiency and substantially reduce nitric oxides emission. The effect of mixing, turbulence and temperature on the structure and stability of these flames will be investigated. The project combines experimental and computational research applied to a laboratory scale burner and a small scale furnace. The main objectives are to better understand the chemical pathways in low temperature hydrocarbon flames under heat and gas recirculation conditions and to understand the effect of mixing and turbulence on the flame structure and pollutants emission.Read moreRead less
Quantification of heat release, NOx emissions and soot from high temperature gaseous flames. The ongoing importance of Australia's minerals processing sector depends on advanced combustion technology to minimise the emission of NOx and other greenhouse gases. The heat release and NOx emissions from the high temperature flames used in such processes is known to depend strongly on the presence of soot. However their optimisation and design is limited by a lack of fundamental data under relevant c ....Quantification of heat release, NOx emissions and soot from high temperature gaseous flames. The ongoing importance of Australia's minerals processing sector depends on advanced combustion technology to minimise the emission of NOx and other greenhouse gases. The heat release and NOx emissions from the high temperature flames used in such processes is known to depend strongly on the presence of soot. However their optimisation and design is limited by a lack of fundamental data under relevant conditions. To address this need, new measurements and analysis will be performed to quantify the complex relationship between turbulent mixing, soot formation, heat release and NOx emissions under high temperature conditions of both fundamental and practical significance.
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