An Integrated Thermal and Structural Investigation for the Development of Innovative Lightweight Cold-formed Steel Wall and Floor Systems under Fire Conditions. This research will benefit the Australian building industry by providing a set of design rules that will not only enhance the fire safety standards but also the structural robustness of steel construction, thereby resulting in a reduction in loss of lives and property due to natural or man-made disasters. This will give Australian manufa ....An Integrated Thermal and Structural Investigation for the Development of Innovative Lightweight Cold-formed Steel Wall and Floor Systems under Fire Conditions. This research will benefit the Australian building industry by providing a set of design rules that will not only enhance the fire safety standards but also the structural robustness of steel construction, thereby resulting in a reduction in loss of lives and property due to natural or man-made disasters. This will give Australian manufacturers a leading edge both nationally and internationally in developing innovative prefabricated fire resistant LSF wall and floor systems using high strength steels. Australians have an opportunity to become world leaders in fire research and LSF construction. It will provide valuable research training to young Australians and will contribute to the protection of Australia's critical infrastructure.Read moreRead less
Enhancing the fire and energy ratings of cold-formed steel wall systems. This project intends to develop novel cold-formed light-gauge steel frame (LSF) wall systems with superior fire resistance and energy ratings for use in buildings. LSF systems are increasingly used in homes and offices. The project plans to investigate fundamental thermal, structural and energy performances of LSF walls and their components using experimental and numerical studies. It plans to develop enhanced plasterboards ....Enhancing the fire and energy ratings of cold-formed steel wall systems. This project intends to develop novel cold-formed light-gauge steel frame (LSF) wall systems with superior fire resistance and energy ratings for use in buildings. LSF systems are increasingly used in homes and offices. The project plans to investigate fundamental thermal, structural and energy performances of LSF walls and their components using experimental and numerical studies. It plans to develop enhanced plasterboards, insulations and innovative composite panels using suitable nanomaterials, chemical additives, fillers and phase-change materials and use these with innovative wall configurations to significantly improve the fire and energy performance of LSF walls. The new wall systems may increase occupant comfort and safety, reduce business losses in fires, and lead to low-energy buildings.Read moreRead less
An Investigation into the Behaviour of Light Gauge Steel Structures under Fire Conditions. This research will clearly result in a major national benefit with potential reduction in loss of life, loss of property and reduced insurance rates with improved fire resistant construction. Australian maufacturers will have a leading edge internationally with the use of high strength steels. There is an opportunity for Australia to become a world leader in an area of fire research. The project will assis ....An Investigation into the Behaviour of Light Gauge Steel Structures under Fire Conditions. This research will clearly result in a major national benefit with potential reduction in loss of life, loss of property and reduced insurance rates with improved fire resistant construction. Australian maufacturers will have a leading edge internationally with the use of high strength steels. There is an opportunity for Australia to become a world leader in an area of fire research. The project will assist in developing fire resistant prefabricated building systems. In also provides valuable research training to young Australians. Most importantly it will contribute to Australia's major initiatives in protecting its critical infrastructure.Read moreRead less
Net shape manufacturing of titanium alloys by powder metallurgy. This project is aiming at developing a novel net shape manufacturing for advanced materials (titanium alloys) and addresses Priority Goal of Advanced Materials of Research Priority 3: Frontier Technologies for Advanced Materials. It represents new science and innovative engineering and has the potential to produce valuable new intellectual property.
The fabrication of amorphous metallic components by powder injection moulding. This project has both national and international significance and addresses the National Research Priority: Frontier Technologies - Advanced Materials (light alloys). It represents new science and innovative engineering and has the potential to produce valuable new intellectual property. The project will contribute to emerging Australian expertise in both bulk metallic glasses and powder injection moulding. It will tr ....The fabrication of amorphous metallic components by powder injection moulding. This project has both national and international significance and addresses the National Research Priority: Frontier Technologies - Advanced Materials (light alloys). It represents new science and innovative engineering and has the potential to produce valuable new intellectual property. The project will contribute to emerging Australian expertise in both bulk metallic glasses and powder injection moulding. It will train postgraduate students in powder processing, sintering science, metallic glasses and electron microscopy. Read moreRead less
Anisotropy of strengthening by solid solution and precipitation in concentrated Mg-Al and Mg-Zn alloys. The addition of solute increases the strength of Mg in some crystallographic directions but weakens the material in others. The weakening is called solid solution softening, and it can have profound effects on the mechanical behaviour of the material. Solid solution softening has been observed in the prismatic planes of single crystals of dilute Mg-Al and Mg-Zn alloys. Easier prismatic slip lo ....Anisotropy of strengthening by solid solution and precipitation in concentrated Mg-Al and Mg-Zn alloys. The addition of solute increases the strength of Mg in some crystallographic directions but weakens the material in others. The weakening is called solid solution softening, and it can have profound effects on the mechanical behaviour of the material. Solid solution softening has been observed in the prismatic planes of single crystals of dilute Mg-Al and Mg-Zn alloys. Easier prismatic slip lowers the strain hardening rate and increases the ductility of polycrystalline alloys in comparison with pure Mg. Despite their obvious significance, these effects have not been studied in single crystals of concentrated alloys. This is the main object of this project.Read moreRead less
Rapid Manufacturing of Aluminium. The project has both national and international significance and addresses the National Research Priority: Frontier Technologies - Advanced Materials (light alloys). Rapid manufacturing produces functional parts directly from a computer solid model using a layer wise rapid prototyping device. Rapid manufacturing is particularly important in the Australian context where small production runs means that tooling and inventory costs are a much larger proportion of t ....Rapid Manufacturing of Aluminium. The project has both national and international significance and addresses the National Research Priority: Frontier Technologies - Advanced Materials (light alloys). Rapid manufacturing produces functional parts directly from a computer solid model using a layer wise rapid prototyping device. Rapid manufacturing is particularly important in the Australian context where small production runs means that tooling and inventory costs are a much larger proportion of the total cost than in North American, European or Asian countries. With a large installed machine base, a substantial automotive and automotive component industry and a major aluminium industry, this project can assist in the further development of these industries.Read moreRead less
Biodegradable magnesium alloy scaffolds for bone tissue engineering. This project aims to develop a class of porous, biocompatible, biofunctional and biodegradable magnesium alloy scaffolds with designed pore architecture and mechanical properties mimicking those of natural bone for tissue engineering applications. These magnesium alloy scaffolds will be biocompatible, able to bear loads, and will be gradually replaced by natural bone. The outcomes are expected to benefit the ageing population a ....Biodegradable magnesium alloy scaffolds for bone tissue engineering. This project aims to develop a class of porous, biocompatible, biofunctional and biodegradable magnesium alloy scaffolds with designed pore architecture and mechanical properties mimicking those of natural bone for tissue engineering applications. These magnesium alloy scaffolds will be biocompatible, able to bear loads, and will be gradually replaced by natural bone. The outcomes are expected to benefit the ageing population and people with bone abnormalities.Read moreRead less
Development of new aluminium alloys through big data analytics. This project aims to address a long-term problem to effectively discover new alloys and processes using big data analytics. It expects to develop new and high-performance aluminium alloys and to generate new knowledge in the area of materials science from investigation of the strengthening and toughening mechanisms. The intended outcomes also include a validated big data analytic model for new alloy development, which further enhan ....Development of new aluminium alloys through big data analytics. This project aims to address a long-term problem to effectively discover new alloys and processes using big data analytics. It expects to develop new and high-performance aluminium alloys and to generate new knowledge in the area of materials science from investigation of the strengthening and toughening mechanisms. The intended outcomes also include a validated big data analytic model for new alloy development, which further enhances the interdisciplinary collaboration. The high performance aluminium alloys should provide significant benefits to automotive and aerospace industries as these sectors target at improving fuel efficiency through weight reduction at lower cost.Read moreRead less
Understanding grain boundary segregation - a route to developing new advanced engineering materials. This project will investigate atomic-scale grain boundary segregation - one of the most important factors influencing the properties of engineering alloys. This will be applied in the development of new Ti, Zr and nanocrystalline alloys with a large potential market and for which Australia is extremely well positioned to become a major producer.