Discovery Early Career Researcher Award - Grant ID: DE160100131
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Multifunctional micro/nano-engineered solar thermal receivers. This project is designed to develop a new class of thermal receivers that overcome key challenges in today's concentrating solar thermal systems. The development of accurate micro/nanofabrication and characterisation techniques in recent years has made it possible to achieve thermofluid devices that are engineered from the bottom up to achieve high performance at relatively low cost. This project aims to develop a new class of solar ....Multifunctional micro/nano-engineered solar thermal receivers. This project is designed to develop a new class of thermal receivers that overcome key challenges in today's concentrating solar thermal systems. The development of accurate micro/nanofabrication and characterisation techniques in recent years has made it possible to achieve thermofluid devices that are engineered from the bottom up to achieve high performance at relatively low cost. This project aims to develop a new class of solar thermal receivers which use micro/nanotechnology to directly absorb concentrated solar energy with very little pumping power and minimal radiative heat loss. By tailoring the geometry and materials inside the receiver, the project expects to achieve a unique level of integrated optical, heat transfer and fluid flow control.Read moreRead less
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
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
New understanding and models for two-phase solar thermal particle receivers. The project aims to provide the new understanding of, and computational design tools for, next generation solar thermal particle receivers and their hybrids. Particle receivers, which heat fine particles in suspension, offer much greater efficiency than current tubular receivers, but are presently unreliable due to the poor understanding of the complex and coupled mechanisms that govern their performance. The results ar ....New understanding and models for two-phase solar thermal particle receivers. The project aims to provide the new understanding of, and computational design tools for, next generation solar thermal particle receivers and their hybrids. Particle receivers, which heat fine particles in suspension, offer much greater efficiency than current tubular receivers, but are presently unreliable due to the poor understanding of the complex and coupled mechanisms that govern their performance. The results are expected to speed up the development and roll-out of these devices, to deliver cost-effective, low-emissions energy technologies for future power generation and thermo-chemical processes. The aims will be met by the parallel application of advanced laser diagnostic measurements and computational fluid dynamics modelling techniques.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100968
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Lifting the Veil on Turbulent Convective Heat Transfer over Rough Surfaces. By understanding the influence of surface roughness on convective heat transfer, this project intends to reduce the unwanted heating and energy losses associated with surface roughness in gas and steam turbines used in power generation and transportation. The surface roughness that results from extended operation of gas and steam turbines can significantly increase the heating of their surfaces, increasing fuel consumpti ....Lifting the Veil on Turbulent Convective Heat Transfer over Rough Surfaces. By understanding the influence of surface roughness on convective heat transfer, this project intends to reduce the unwanted heating and energy losses associated with surface roughness in gas and steam turbines used in power generation and transportation. The surface roughness that results from extended operation of gas and steam turbines can significantly increase the heating of their surfaces, increasing fuel consumption and greenhouse gas emissions, and reducing operational life. Improvements would allow turbines to operate at higher inlet temperatures which will increase their efficiency and reduce fuel use, environmental emissions and maintenance costs.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
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.
No load diesel application in remote power systems. No load diesel application in remote power systems. This project aims to investigate and optimise no-load diesel application within remote area renewable hybrid power systems. While hundreds of remote Australian communities rely on expensive diesel for power generation, this project intends to increase penetration of alternative renewable sources into remote and isolated power systems. Using dual thermodynamic and electrical modelling, this pro ....No load diesel application in remote power systems. No load diesel application in remote power systems. This project aims to investigate and optimise no-load diesel application within remote area renewable hybrid power systems. While hundreds of remote Australian communities rely on expensive diesel for power generation, this project intends to increase penetration of alternative renewable sources into remote and isolated power systems. Using dual thermodynamic and electrical modelling, this project will investigate low to no-load diesel threshold capability, reducing diesel consumption at minimal costs. The project is expected to return immediate benefits to remote mining, defence and tourism based communities, providing a pathway to reduced diesel usage and increased renewable penetration.Read moreRead less