High Energy Density - High Delivery Rate Thermal Energy Storage. This project aims to address the intermittency of renewable energy sources using novel thermal storage media. Advanced heat transfer modelling and in situ neutron diffraction and imaging are intended to be used to optimise the microstructure of newly developed miscibility gap thermal storage systems. The new media store energy as the latent heat of fusion of one phase in a stable, high thermal conductivity inverted microstructure. ....High Energy Density - High Delivery Rate Thermal Energy Storage. This project aims to address the intermittency of renewable energy sources using novel thermal storage media. Advanced heat transfer modelling and in situ neutron diffraction and imaging are intended to be used to optimise the microstructure of newly developed miscibility gap thermal storage systems. The new media store energy as the latent heat of fusion of one phase in a stable, high thermal conductivity inverted microstructure. The high energy density of the latent heat (0.5-4.5 Mega Joules/Litre) requires storage volumes as little as five per cent of those relying upon heat capacity and the metal matrix has a hundred-fold greater thermal conductivity than current systems. It is proposed that a range of such materials will be engineered for concentrated solar thermal and space heating applications.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150100397
Funder
Australian Research Council
Funding Amount
$340,000.00
Summary
Advanced waste heat recovery systems. Vehicle emissions have recently driven the research, development, and commercialisation of Exhaust Gas Recirculation (EGR) systems. The development of novel EGR gas coolers for such systems will probably lead to the breakthrough necessary for advancing EGR technologies, benefiting Australian clean energy supplies in general and transport vehicles in particular. The project aims to produce lighter and cleaner EGR systems at lower costs. This project also aims ....Advanced waste heat recovery systems. Vehicle emissions have recently driven the research, development, and commercialisation of Exhaust Gas Recirculation (EGR) systems. The development of novel EGR gas coolers for such systems will probably lead to the breakthrough necessary for advancing EGR technologies, benefiting Australian clean energy supplies in general and transport vehicles in particular. The project aims to produce lighter and cleaner EGR systems at lower costs. This project also aims to enhance the international reputation and impact of Australian research in the internationally focused fields of microporous materials and clean transport technology.Read moreRead less
Design and Optimisation of Novel Enthalpy Heat Exchangers. This project deals with the thermal design and optimisation of a novel type of latent energy heat exchanger. This new heat exchanger overcomes the practical implementation problems of previous latent energy heat exchangers such as heat-wheels. The main application of this innovative heat exchanger will be to improve the capacity and efficiency of air conditioning systems. As the new heat exchanger is very compact it will be ideally sui ....Design and Optimisation of Novel Enthalpy Heat Exchangers. This project deals with the thermal design and optimisation of a novel type of latent energy heat exchanger. This new heat exchanger overcomes the practical implementation problems of previous latent energy heat exchangers such as heat-wheels. The main application of this innovative heat exchanger will be to improve the capacity and efficiency of air conditioning systems. As the new heat exchanger is very compact it will be ideally suited for integration with air conditioning coils. Existing latent heat wheels are very bulky and are difficult to integrate into standard air conditioner installations.Read moreRead less
Assessment of the new technologies to maximise the internal energy efficiency by modelling the energy flows in Victorian power stations. Increased internal energy efficiency will reduce the CO2 emissions and increase the profit margin for the power stations. The aim of the proposed research is to investigate the internal energy efficiency in the brown coal fired power stations by modelling the internal energy flows to reveal the potentials in the 'waste' heat streams in the power stations, and t ....Assessment of the new technologies to maximise the internal energy efficiency by modelling the energy flows in Victorian power stations. Increased internal energy efficiency will reduce the CO2 emissions and increase the profit margin for the power stations. The aim of the proposed research is to investigate the internal energy efficiency in the brown coal fired power stations by modelling the internal energy flows to reveal the potentials in the 'waste' heat streams in the power stations, and to assess new waste heat recovery measures for the power industry. The proposed research, supported by the entire Victorian power generation industry, will help the industry to achieve their green house gas emission reduction target set by the Federal Government.
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Computational design for engineering micro/nanotopography. Micro/nanotopography and associated characteristics has major influences in several emerging areas of environmental, biomedical and energy engineering. This project will develop a new computational framework for topographical design and fabrication. It will create new research opportunities and technological innovation for the future development.
Dehumidification and cooling driven by solar/waste heat using liquid desiccants. The provision of comfort cooling is responsible for a considerable and increasing portion of the world energy demand and electricity peak demand. To substitute electrically driven vapour compression machines with their high electrical energy consumption and especially high peak loads, the use of solar energy or waste heat for a cooling and dehumidification system driven by liquid desiccants is a promising opportunit ....Dehumidification and cooling driven by solar/waste heat using liquid desiccants. The provision of comfort cooling is responsible for a considerable and increasing portion of the world energy demand and electricity peak demand. To substitute electrically driven vapour compression machines with their high electrical energy consumption and especially high peak loads, the use of solar energy or waste heat for a cooling and dehumidification system driven by liquid desiccants is a promising opportunity. The project utilises the complementary strengths in the research groups to develop practical and economically feasible cooling/dehumidification systems for different types of buildings with different moisture removal and cooling requirements at different locations (Australia, Southern Europe).Read moreRead less
The use of numerical and experimental techniques to develop energy efficient open refrigerated display cabinets. This project will provide knowledge for Australian industry to develop new energy efficient refrigerated display cabinets, putting Australia in the forefront of commercial refrigeration display cabinet technologies. This will have a significant impact on sustainability of our environment and will assist Australia to meet present and future international climate obligations by contrib ....The use of numerical and experimental techniques to develop energy efficient open refrigerated display cabinets. This project will provide knowledge for Australian industry to develop new energy efficient refrigerated display cabinets, putting Australia in the forefront of commercial refrigeration display cabinet technologies. This will have a significant impact on sustainability of our environment and will assist Australia to meet present and future international climate obligations by contributing to the reduction of greenhouse emissions. The Government has already introduced new MEPS levels, and are planning to increase these to more stringent levels in 2007. The development of the techniques proposed in this application will be essential for manufacturers if they are to economically meet these MEPS level requirements. Read moreRead less
Heat Transfer Enhancement Techniques for Air Conditioning and Refrigeration Equipment. The proposed Project will make significant contribution towards the both fundamental understanding of heat transfer enhancement using dimpled surfaces and the design of heat exchangers and, in particular to the application of dimpled surfaces in air conditioning and refrigeration industries. Unlike the previous CFD studies which have been made on the assumptions that the flow is steady and decoupled from the ....Heat Transfer Enhancement Techniques for Air Conditioning and Refrigeration Equipment. The proposed Project will make significant contribution towards the both fundamental understanding of heat transfer enhancement using dimpled surfaces and the design of heat exchangers and, in particular to the application of dimpled surfaces in air conditioning and refrigeration industries. Unlike the previous CFD studies which have been made on the assumptions that the flow is steady and decoupled from the heat transfer calculations in this Project the fully coupled problem will be solved, in which unsteady flows are allowed to occur over a dimpled surfaces. As a result we will be able to more accurately determine the resultant effects on the pressure drop and heat transfer. Read moreRead less
Heat transfer processes in evacuated tubular solar absorbers. The aim of this project is to improve the understanding of the complex heat transfer processes in evacuated tubular solar water heaters. This project will develop thermal and hydrodynamic models for advanced solar water heaters incorporating evacuated tubular absorbers and will assess the accuracy of the models through a series of outdoor experiments on prototype evacuated tubular solar water heaters. The outcomes will lead to the d ....Heat transfer processes in evacuated tubular solar absorbers. The aim of this project is to improve the understanding of the complex heat transfer processes in evacuated tubular solar water heaters. This project will develop thermal and hydrodynamic models for advanced solar water heaters incorporating evacuated tubular absorbers and will assess the accuracy of the models through a series of outdoor experiments on prototype evacuated tubular solar water heaters. The outcomes will lead to the design and manufacturing of more efficient solar collectors, which can greatly benefit both Australian domestic and export markets.Read moreRead less
Enhancing natural convection heat transfer using a single horizontal non-metallic fin. This project will develop the basis for a simple design to improve the energy efficiency of natural convection heat exchangers. Heat exchangers are widely adopted in many electronic devices and industrial processes as they require no external power input, additional space, and are quiet, reliable and economical. The research will exploit the interaction between two flows to trigger turbulence, and will result ....Enhancing natural convection heat transfer using a single horizontal non-metallic fin. This project will develop the basis for a simple design to improve the energy efficiency of natural convection heat exchangers. Heat exchangers are widely adopted in many electronic devices and industrial processes as they require no external power input, additional space, and are quiet, reliable and economical. The research will exploit the interaction between two flows to trigger turbulence, and will result in an increase of the overall capacity and performance of engineering systems. This will contribute significantly to reductions in power consumption and improvements in productivity and work environment, leading ultimately to reductions in greenhouse gas emissions and to economic benefits.Read moreRead less