Discovery Early Career Researcher Award - Grant ID: DE210100056
Funder
Australian Research Council
Funding Amount
$433,746.00
Summary
Microstructured Nanohybrid Films for Passive Daytime Cooling. This project aims to develop a daytime radiative cooling surface without external energy requirement via novel microstructured nanohybrid film coatings to perpetually dump heat into cold outer space through the atmospheric window. The project expects to generate new fundamental knowledge in the area of building cooling materials, via multidisciplinary utilisation of cutting-edge construction materials and design. The expected outcome ....Microstructured Nanohybrid Films for Passive Daytime Cooling. This project aims to develop a daytime radiative cooling surface without external energy requirement via novel microstructured nanohybrid film coatings to perpetually dump heat into cold outer space through the atmospheric window. The project expects to generate new fundamental knowledge in the area of building cooling materials, via multidisciplinary utilisation of cutting-edge construction materials and design. The expected outcome of the project will place Australia in a competitive position in advanced green building infrastructure and highly demanded energy-saving technologies. This should provide benefits, such as significantly decreasing building energy consumption, and, thus reducing greenhouse gas emission.Read moreRead less
Computational analysis and design of injection stretch blow-moulded polyethylene terephthalate (PET) bottles. There are approximately 2.5 billion containers made each year representing 80,000 tonnes of polyethylene terephthalate (PET) in Australia. A weight reduction of each PET container will have a significant economic benefit and an environmental impact. This project aims to develop an integrated and innovative computer-aided design technology for assisting manufacturing of injection stretch ....Computational analysis and design of injection stretch blow-moulded polyethylene terephthalate (PET) bottles. There are approximately 2.5 billion containers made each year representing 80,000 tonnes of polyethylene terephthalate (PET) in Australia. A weight reduction of each PET container will have a significant economic benefit and an environmental impact. This project aims to develop an integrated and innovative computer-aided design technology for assisting manufacturing of injection stretch moulded PET bottles by making full use of the up-to-date computational technologies. It is expected that the research will improve the competitiveness of Australian packaging industries by developing leading-edge technology and will enhance living environment in terms of optimally designing lightweight and structurally strong PET bottles.Read moreRead less
De-consolidation and Re-consolidation of Advanced Thermoplastic Matrix Composites. The project provides a comprehensive physical understanding on thermal de-consolidation and re-consolidation processes in advanced thermoplastic composites during re-heating/cooling processes, such as thermoforming and joining. Mechanistic models based on theoretical analysis, experimental studies and computational modelling will be established to provide a unified approach to predict de-consolidation and re-conso ....De-consolidation and Re-consolidation of Advanced Thermoplastic Matrix Composites. The project provides a comprehensive physical understanding on thermal de-consolidation and re-consolidation processes in advanced thermoplastic composites during re-heating/cooling processes, such as thermoforming and joining. Mechanistic models based on theoretical analysis, experimental studies and computational modelling will be established to provide a unified approach to predict de-consolidation and re-consolidation processes. Optimum processing-windows will be established, with which the undesired deterioration in material meso-structures and mechanical performance due to de-consolidation is effectively minimised. The outcomes of the project will fill the gap in the knowledge for thermoplastic composite processing and will improve the integrity of thermoplastic composite structures in practical applications.Read moreRead less
A Unified Approach to Determine Permeabilities of Fibre Preforms for Manufacturing Advanced Composite Structures. A unified framework is developed first time to determine 3-D permeabilities of fibre preforms for advanced fibre composites using homogenisation theories based on micro-, meso- and macro-structures of fibre preforms. Mechanistic models based on experimental studies, theoretical analyses and computational modelling are established to quantify permeabilities in different scales. It off ....A Unified Approach to Determine Permeabilities of Fibre Preforms for Manufacturing Advanced Composite Structures. A unified framework is developed first time to determine 3-D permeabilities of fibre preforms for advanced fibre composites using homogenisation theories based on micro-, meso- and macro-structures of fibre preforms. Mechanistic models based on experimental studies, theoretical analyses and computational modelling are established to quantify permeabilities in different scales. It offers a unique technique to determine 3-D permeabilities for manufacturing advanced composite structures using various novel technologies based on resin impregnation or infusion, such as VARTM and RI. The outcomes of the project will fill the gap in the essential knowledge for cost-effective manufacturing of advanced composite structures in practical applications.Read moreRead less