A Fundamental Study Of The Behaviour Of Clay Brick Fines In Autoclaved Calcium Silicate Based Building Products. Clay brick fines constitute a significant proportion of Construction and Demolition waste, the disposal of which is a recognised global problem. This project aims to provide a fundamental understanding of the behaviour of clay brick fines in autoclaved calcium silicate based building products. Current practice of manufacture of these widely produced building materials does not use cla ....A Fundamental Study Of The Behaviour Of Clay Brick Fines In Autoclaved Calcium Silicate Based Building Products. Clay brick fines constitute a significant proportion of Construction and Demolition waste, the disposal of which is a recognised global problem. This project aims to provide a fundamental understanding of the behaviour of clay brick fines in autoclaved calcium silicate based building products. Current practice of manufacture of these widely produced building materials does not use clay brick fines due to a lack of technical information on this renewable resource material. Findings of this study will provide a benchmark for the development of new generation building products worldwide utlilising clay brick fines.Read moreRead less
Development of new-generation autoclaved cellulose fibre-cement composites using alumina-silica rich industrial waste. Autoclaved cellulose fibre-cement (FC) composites are used for construction purposes globally. Alumina-silica rich industrial waste, such as fired clay bricks and tiles, are proven to be highly reactive under autoclaving conditions and are generated in abundance either during the production process or demolition of buildings worldwide. The project aims to utilise this renewable ....Development of new-generation autoclaved cellulose fibre-cement composites using alumina-silica rich industrial waste. Autoclaved cellulose fibre-cement (FC) composites are used for construction purposes globally. Alumina-silica rich industrial waste, such as fired clay bricks and tiles, are proven to be highly reactive under autoclaving conditions and are generated in abundance either during the production process or demolition of buildings worldwide. The project aims to utilise this renewable waste for the manufacture of improved FC products. The successful outcomes of the project could allow a new range of cost-effective building products which need less energy for their manufacture, to be realised for both developed and developing countries.Read moreRead less
Novel biodegradable starch/clay nanocomposites with enhanced strength and moisture resistance. The outcomes of the project will make an important contribution to a new technology of biodegradable polymer nanocomposites based on natural starch and clay. The project has direct environmental benefit due to the complete biodegradation of the resulting starch/clay nanocomposites which will be able to replace some non-biodegradable polymers in packaging and disposable bags, cups and boxes, etc. The re ....Novel biodegradable starch/clay nanocomposites with enhanced strength and moisture resistance. The outcomes of the project will make an important contribution to a new technology of biodegradable polymer nanocomposites based on natural starch and clay. The project has direct environmental benefit due to the complete biodegradation of the resulting starch/clay nanocomposites which will be able to replace some non-biodegradable polymers in packaging and disposable bags, cups and boxes, etc. The reduction in use of non-biodegradable polymers will be helpful to solve the "white pollution" and improve our living environments. This study will result in huge economic benefits for the national agriculture and plastic industries since Australia has a large starch production, and will enable Australia to be at the leading edge in this area.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0237936
Funder
Australian Research Council
Funding Amount
$100,000.00
Summary
Research facility for plastics and composites : Dynamic Mechanical Analyser and Rheometer System. The Dynamic Mechanical Analyser (DMA) and Control Stress Rheometer System is a unique set of equipment where both instruments can be run simultaneously using the same controller module. The DMA can provide quantitative and qualitative information on high spectrum of mechanical and rheological properties of materials in solid state. The Rheometer complements the DMA by providing information about pro ....Research facility for plastics and composites : Dynamic Mechanical Analyser and Rheometer System. The Dynamic Mechanical Analyser (DMA) and Control Stress Rheometer System is a unique set of equipment where both instruments can be run simultaneously using the same controller module. The DMA can provide quantitative and qualitative information on high spectrum of mechanical and rheological properties of materials in solid state. The Rheometer complements the DMA by providing information about properties of materials in liquid state. The equipment will be used both for academic research of plastic, ceramic and composite materials and for industrial projects in the areas of material processing, recycling of plastics and for building a database of material's properties. Read moreRead less
High performance multifunctional hierarchical structured membrane for water processing. The water processing industry is one of the most important economic sectors in Australia, though water scarcity is an economic limiting growth factor. The project targets at developing the next generation water processing technology affordable to residential consumption and applications in the industry and agriculture.
Australian Laureate Fellowships - Grant ID: FL110100013
Funder
Australian Research Council
Funding Amount
$2,260,000.00
Summary
New materials for a sustainable energy future. This project will research and develop new selective transport materials to create new sustainable technologies for energy storage (e.g. batteries and capacitors) which will allow greater use of renewable energy sources, desalination and CO2 capture.