Efficient photovoltaic concentrator receivers utilising commercial non-concentrator solar cells. The development of low-cost photovoltaic concentrator systems will allow the large scale depoyment of these systems, both in Australia and overseas. The current size of this market is several hundred MW of electricity per year, and growing rapidly. This will have both environmental benefits (though reduced greenhouse gas emissions)as well as economic and social benefits - through the creation of empo ....Efficient photovoltaic concentrator receivers utilising commercial non-concentrator solar cells. The development of low-cost photovoltaic concentrator systems will allow the large scale depoyment of these systems, both in Australia and overseas. The current size of this market is several hundred MW of electricity per year, and growing rapidly. This will have both environmental benefits (though reduced greenhouse gas emissions)as well as economic and social benefits - through the creation of empoyment opportunities in PV manufacturing and the generation of export earnings. It could be of particular benefit to remote communities requiring reliable, low cost off-grid power generation.Read moreRead less
Multi Tower Solar Array (MTSA) for combined heat and power applications in urban areas. The MTSA is a highly compact, middle-scale (0.5 - 10 MW) solar power concept designed for urban areas. It comprises an array of small towers with high mounted receivers which collect sunlight from a very densely packed reflector field below. Reflectors can be aimed at different towers during the day to minimise blocking and shading losses. A prototype MTSA system to be constructed will test new reflector modu ....Multi Tower Solar Array (MTSA) for combined heat and power applications in urban areas. The MTSA is a highly compact, middle-scale (0.5 - 10 MW) solar power concept designed for urban areas. It comprises an array of small towers with high mounted receivers which collect sunlight from a very densely packed reflector field below. Reflectors can be aimed at different towers during the day to minimise blocking and shading losses. A prototype MTSA system to be constructed will test new reflector modules developed in conjunction with Solahart Industries (Perth). Innovative receivers incorporating spectral control, and both photovoltaic and thermal electricity generation paths will also be developed.Read moreRead less
Efficient PV-Thermal Micro-concentrator. Australia must reduce its dependence on carbon sources for electricity, heating, and cooling. The PV-thermal hybrid micro-concentrator development will deliver a light-weight, low-profile, cost-effective system that can be installed in almost any situation, with versatile output that can deliver electricity at grid parity as well as providing water heating, space heating, industrial process heat, and solar cooling capabilities. The nation will benefit thr ....Efficient PV-Thermal Micro-concentrator. Australia must reduce its dependence on carbon sources for electricity, heating, and cooling. The PV-thermal hybrid micro-concentrator development will deliver a light-weight, low-profile, cost-effective system that can be installed in almost any situation, with versatile output that can deliver electricity at grid parity as well as providing water heating, space heating, industrial process heat, and solar cooling capabilities. The nation will benefit through enhanced energy independence, international research recognition, and reduced greenhouse gas emissions. Further, successful commercialisation of this technology will enhance Australia's research standing and provide a good royalty income that will fund future research and development.Read moreRead less
A 60% efficient solar microconcentrator for electricity and hot water. The aim of this project is to develop a microconcentrator for deployment on house roofs that will produce both solar hot water and solar electricity with a combined efficiency above 60%. The system will have a low profile and will be nearly invisible from the street. The system will track the sun. Concentration will be accomplished by a mixture of refraction and reflection. About 20% of the sunlight will be converted to elect ....A 60% efficient solar microconcentrator for electricity and hot water. The aim of this project is to develop a microconcentrator for deployment on house roofs that will produce both solar hot water and solar electricity with a combined efficiency above 60%. The system will have a low profile and will be nearly invisible from the street. The system will track the sun. Concentration will be accomplished by a mixture of refraction and reflection. About 20% of the sunlight will be converted to electricity using lines of tiny solar cells, with the balance being converted to heat which is removed by cooling fluid and stored in hot water tanks.Read moreRead less
Development of novel roofing panels integrating solar heat collection and phase change storage. The provision of comfort heating for domestic and commercial buildings contributes significantly to Australia's energy use and greenhouse gas emissions. The project aims to develop a new roofing product which will collect and store solar energy for heating. The product integrates conventional roofing products into a solar collector and a heat store. Materials that melt/freeze at suitable temperatures ....Development of novel roofing panels integrating solar heat collection and phase change storage. The provision of comfort heating for domestic and commercial buildings contributes significantly to Australia's energy use and greenhouse gas emissions. The project aims to develop a new roofing product which will collect and store solar energy for heating. The product integrates conventional roofing products into a solar collector and a heat store. Materials that melt/freeze at suitable temperatures will be used for heat storage. The project involves developing a mathematical model and a prototype design. In addition to fulfilling the conventional function of roofing products including thermal and sound insulation, the prototype is intended to be aesthetically acceptable and easily compatible with current building practices.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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