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
Functional topological materials for superior thermoelectric applications. The efficient generation of electricity from waste heat remains a significant technological challenge, hampered by the absence of efficient materials for conversion. This project aims to develop functionalized topological materials with ultra-high thermoelectric and photothermal performance for harvesting heat into electricity. A recent breakthrough in device efficiency will be a game-changer and position Australian acade ....Functional topological materials for superior thermoelectric applications. The efficient generation of electricity from waste heat remains a significant technological challenge, hampered by the absence of efficient materials for conversion. This project aims to develop functionalized topological materials with ultra-high thermoelectric and photothermal performance for harvesting heat into electricity. A recent breakthrough in device efficiency will be a game-changer and position Australian academics and industries at the forefront of next generation of renewable power generation and refrigeration products. The outcomes will provide an advantage to end-users and industry, and will open a new market for advanced thermoelectric devices in multidisciplinary fields, communities and emerging industries.Read moreRead less
Investigation of the coupled dependence of concentrated solar radiation and combustion in a novel solar hybrid technology. The project will develop the models necessary for the optimisation of a novel solar-combustion hybrid technology and a novel heat exchanger component. It will deliver a solar thermal technology that lowers the cost of solar energy with immediate potential in off-grid sites, such as in remote mines, in Australia and throughout the world.
Membrane distillation development for concentrated solar thermal systems. Membrane distillation development for concentrated solar thermal systems. This project aims to develop a new membrane distillation module that works with a high efficiency solar thermal tower system. Fresh water and energy are inextricably linked and form the basis for all human activity. Remote locations in Australia and the Middle East and North Africa are blessed with abundant solar resources and increasing levels of de ....Membrane distillation development for concentrated solar thermal systems. Membrane distillation development for concentrated solar thermal systems. This project aims to develop a new membrane distillation module that works with a high efficiency solar thermal tower system. Fresh water and energy are inextricably linked and form the basis for all human activity. Remote locations in Australia and the Middle East and North Africa are blessed with abundant solar resources and increasing levels of development, but burdened by access to reliable water treatment and electricity generation facilities. This project will use recently developed materials and design tools to overcome technical challenges that limited membrane distillation technology. This is expected to open up an innovative method for co-production of water and electricity which can handle transient solar and water quality inputs.Read moreRead less
Multiscale engineering of durable absorber coatings for solar thermal power. This project aims to advance the long-term stability and efficiency of high-temperature absorber coatings for Concentrated Solar Power (CSP) plants. Solar energy is a vast and largely untapped resource in Australia. The project will design superior light absorbers and scalable and low-cost approaches for their fabrication. Optimal absorber properties will be achieved by multi-scale engineering of the coating composition ....Multiscale engineering of durable absorber coatings for solar thermal power. This project aims to advance the long-term stability and efficiency of high-temperature absorber coatings for Concentrated Solar Power (CSP) plants. Solar energy is a vast and largely untapped resource in Australia. The project will design superior light absorbers and scalable and low-cost approaches for their fabrication. Optimal absorber properties will be achieved by multi-scale engineering of the coating composition and micro-texturing via modelling of the light absorption and heat transport within these complex nanocomposite structures. The intended outcome of the project is a set of commercially competitive absorber coatings, with superior performance and durability, that support the development of CSP as a competitive technology for energy generation.Read moreRead less
Concentrating solar thermal energy storage using metal hydrides. This project will investigate energy storage for concentrating solar thermal energy systems. These systems can be used to efficiently generate electricity in remote locations, day and night, using solar energy. The solar energy is converted to heat energy and then chemical energy stored in a metal-hydrogen compound.
Thermal transport in multi-phase flows for concentrating solar applications. This project seeks to advance the field of heat transfer in high-temperature systems involving liquid metals, with emphasis on energy storage and solar power technologies. The concept couples a tubular sodium boiler with a sodium chloride phase-change storage system for continuous energy supply. Sodium chloride is low cost and has a melting temperature suitable for a wide range of industrial processes. The project plans ....Thermal transport in multi-phase flows for concentrating solar applications. This project seeks to advance the field of heat transfer in high-temperature systems involving liquid metals, with emphasis on energy storage and solar power technologies. The concept couples a tubular sodium boiler with a sodium chloride phase-change storage system for continuous energy supply. Sodium chloride is low cost and has a melting temperature suitable for a wide range of industrial processes. The project plans to address the challenge of sodium stability in highly irradiated tubes by investigating mass, momentum, energy and radiative transport in liquid metals. It is intended that this will inform the design and testing of novel sodium boilers to provide stable and isothermal process heat for continuous or on-demand production of power, chemical fuels and commodities.Read moreRead less
Thermal Optimisation of Gigascale Solar Photovoltaics. Large-scale solar photovoltaics are critical to decarbonising the global economy. Sun Cable is developing the world’s largest solar farm in the Northern Territory, and is considering deploying the 5B MAV solar array. At this scale, temperature-induced panel efficiency losses represent a major challenge that must be overcome through thermal performance optimisation. We will build sophisticated multiscale models to simulate and understand the ....Thermal Optimisation of Gigascale Solar Photovoltaics. Large-scale solar photovoltaics are critical to decarbonising the global economy. Sun Cable is developing the world’s largest solar farm in the Northern Territory, and is considering deploying the 5B MAV solar array. At this scale, temperature-induced panel efficiency losses represent a major challenge that must be overcome through thermal performance optimisation. We will build sophisticated multiscale models to simulate and understand the multiple interacting phenomena that cause panel heating, for the first time. This project will create the tools and know-how to optimise array design and solar farm development, delivering major efficiency gains and enhancing the viability of future gigascale solar projects.Read moreRead less
Fabrication of silicon solar cells in a Lunar-like vacuum environment. In-situ power generation on the Moon is essential for the advancement of space exploration and habitation. At present this involves transportation of solar cells to the Moon. This proposal aims to pave the way for manufacture of solar cells on the Moon from Lunar materials. Utilising the future extraction and purification of silicon, abundant in lunar regolith, the project will focus on fabrication of silicon solar cells. Thi ....Fabrication of silicon solar cells in a Lunar-like vacuum environment. In-situ power generation on the Moon is essential for the advancement of space exploration and habitation. At present this involves transportation of solar cells to the Moon. This proposal aims to pave the way for manufacture of solar cells on the Moon from Lunar materials. Utilising the future extraction and purification of silicon, abundant in lunar regolith, the project will focus on fabrication of silicon solar cells. This will provide power for: water mining, oxygen extraction, vehicles and habitats on the Moon and delivery of materials to Low Earth Orbit. The proposed research aims to develop solar cells that can be manufactured on the Moon, using materials abundant there, and techniques exploiting the natural vacuum of space.Read moreRead less
Innovative high-efficiency hybrid technology for commercial solar cells. The purpose of this project is to develop improved photovoltaic devices of significantly higher efficiency and lower cost than conventional screen-printed solar cells. This in turn will contribute to greatly reduced electricity costs from non fossil-fuel based sources.