Early Career Industry Fellowships - Grant ID: IE230100410
Funder
Australian Research Council
Funding Amount
$452,085.00
Summary
Bridging the gap between rockfall theory and engineering practice. Fragmentation is often observed post rockfall events and it is recognised as a critical aspect of adequate rockfall risk management. Yet, rockfall fragmentation is a complex phenomenon still poorly understood and not properly considered in engineering practice. This project aims at developing a theoretical and stochastic fragmentation framework, based on high-quality and comprehensive experimental data, in collaboration with lead ....Bridging the gap between rockfall theory and engineering practice. Fragmentation is often observed post rockfall events and it is recognised as a critical aspect of adequate rockfall risk management. Yet, rockfall fragmentation is a complex phenomenon still poorly understood and not properly considered in engineering practice. This project aims at developing a theoretical and stochastic fragmentation framework, based on high-quality and comprehensive experimental data, in collaboration with leading international industry partners that provide advanced geotechnical design tools to practitioners around the world. The outcomes of the project will bridge the gap between rockfall theory and engineering practice. It will allow for more cost-effective and safer design of rockfall protection structures.Read moreRead less
Scalable daytime radiative cooling for buildings and the built environment . This project aims at the development of a scalable daytime radiative cooling technology suitable for large deployments in the built environment that will help mitigating the urban heat island effect, and reduce future cooling energy needs in buildings. The main outcomes of the project will consist of the development of radiative coolers that will be able to operate in the built environment under Australian climatic cond ....Scalable daytime radiative cooling for buildings and the built environment . This project aims at the development of a scalable daytime radiative cooling technology suitable for large deployments in the built environment that will help mitigating the urban heat island effect, and reduce future cooling energy needs in buildings. The main outcomes of the project will consist of the development of radiative coolers that will be able to operate in the built environment under Australian climatic conditions, and of clear guidelines for their large deployment. The technology is based on a passive cooling strategy requiring no energy for its operations. The outcomes of the project will also have a beneficial impact on the Australian building and construction industry.Read moreRead less
Elastocaloric cooling systems for buildings and the built environment. This project aims to develop elastocaloric cooling systems that will find application in buildings and the built environment. The main aims of the projects are to establish a new technology capable of enhancing the efficiency of traditional cooling systems used for building applications and of reducing the contribution of structural and architectural components to the urban heat island effect. This work will be supported by a ....Elastocaloric cooling systems for buildings and the built environment. This project aims to develop elastocaloric cooling systems that will find application in buildings and the built environment. The main aims of the projects are to establish a new technology capable of enhancing the efficiency of traditional cooling systems used for building applications and of reducing the contribution of structural and architectural components to the urban heat island effect. This work will be supported by a new theoretical platform that will incorporate the elastocaloric cooling behaviour into the structural, thermal and energy performance of the building components, as well as by prototype testing. The outcomes of the project will lead to new building cooling technologies, increasing efficiency of traditional cooling building systems.Read moreRead less
Fluorescent daytime radiative cooling for urban heat mitigation . This project aims to develop a fluorescent daytime radiative cooling technology suitable for the mitigation of urban overheating in the built environment and for the reduction of future cooling energy demands in buildings. The project expects to generate new knowledge in this area to enable the exploitation of fluorescent materials for urban heat mitigation and cooling of buildings. Expected project outcomes consist of the establi ....Fluorescent daytime radiative cooling for urban heat mitigation . This project aims to develop a fluorescent daytime radiative cooling technology suitable for the mitigation of urban overheating in the built environment and for the reduction of future cooling energy demands in buildings. The project expects to generate new knowledge in this area to enable the exploitation of fluorescent materials for urban heat mitigation and cooling of buildings. Expected project outcomes consist of the establishment of the new cooling technology for application on coloured surfaces, typically used in the urban built environment, and on white surfaces for boosting the cooling power of current daytime radiative coolers. This should lead to significant benefits for the Australian building and construction industry.
Read moreRead less