Precision Bending of 6xxx Aluminium Extrusions. The use of aluminium in transportation applications is predicted to double over the next 10 years. The use of extruded aluminium in structural components such as space frames is a growing area, and bending is an integral and critical process in the production of such components. The aim of this project is to develop key knowledge and technology necessary for precision bending of extruded aluminium profiles. The main outcomes will be: (i) Understand ....Precision Bending of 6xxx Aluminium Extrusions. The use of aluminium in transportation applications is predicted to double over the next 10 years. The use of extruded aluminium in structural components such as space frames is a growing area, and bending is an integral and critical process in the production of such components. The aim of this project is to develop key knowledge and technology necessary for precision bending of extruded aluminium profiles. The main outcomes will be: (i) Understanding of the relationship between extrusion conditions, microstructure and bendability of structural profiles. This will enable the optimisation of the extrusion process to ensure consistent bending behaviour. (ii) Development of the rubber-pad technology for precision bending.Read moreRead less
The Development of High Strength Aluminium and Magnesium Alloys Using "Edge-to-edge" Matching Model. The theoretical, crystallographic "edge-to-edge" matching model for diffusion-controlled phase transformations will be applied to the practical development of improved industrial aluminium and magnesium alloys with assistance of computer simulations. The model will be used to enhance the precipitation hardening response and to identify more effective grain refiners in these light alloys. The aim ....The Development of High Strength Aluminium and Magnesium Alloys Using "Edge-to-edge" Matching Model. The theoretical, crystallographic "edge-to-edge" matching model for diffusion-controlled phase transformations will be applied to the practical development of improved industrial aluminium and magnesium alloys with assistance of computer simulations. The model will be used to enhance the precipitation hardening response and to identify more effective grain refiners in these light alloys. The aims will be the development of one high strength aluminium alloy with good ductility and one high strength magnesium alloy with good creep resistance at elevated temperatures. A computer program that will help to identify the most effective grain refiners for specific light alloys will also be produced.Read moreRead less
Thixotropic Structure Generation and Semisolid Casting of Aluminium and Magnesium Alloys. A range of aluminium and magnesium alloys will be prepared by controlled-pouring to produce structures suitable for semisolid forming. The conditions around grain nucleation and growth will be studied to ascertain the controlling factors in producing suitable microstructures. A computer model to simulate the thixotropic structure formation and define the processing parameters will be developed. Semisolid c ....Thixotropic Structure Generation and Semisolid Casting of Aluminium and Magnesium Alloys. A range of aluminium and magnesium alloys will be prepared by controlled-pouring to produce structures suitable for semisolid forming. The conditions around grain nucleation and growth will be studied to ascertain the controlling factors in producing suitable microstructures. A computer model to simulate the thixotropic structure formation and define the processing parameters will be developed. Semisolid casting using the produced feedstock will lead to extensive knowledge about the effect of different microstructures and alloys on semisolid castability. Outcomes from the project will significantly advance the scientific understanding of the thixotropic structure generation and accelerate the development of semisolid processing technology.Read moreRead less
A Novel Surface Alloying Technique to Improve the Corrosion and Wear Resistance of Magnesium Alloys. Surface mechanical attrition treatment will be used to generate nanometer-sized grains in the surface layer of engineering magnesium alloys, and therefore activate the surface of this material. Together with the use of efficient activators, the project will develop a novel low temperature surface alloying technique to significantly improve the wear and corrosion resistance of magnesium alloys wi ....A Novel Surface Alloying Technique to Improve the Corrosion and Wear Resistance of Magnesium Alloys. Surface mechanical attrition treatment will be used to generate nanometer-sized grains in the surface layer of engineering magnesium alloys, and therefore activate the surface of this material. Together with the use of efficient activators, the project will develop a novel low temperature surface alloying technique to significantly improve the wear and corrosion resistance of magnesium alloys without changing the substrate properties. Microstructural features and the wear and corrosion resistance of the ultrafine-grained surface layer will be examined. In addition, it may be possible to combine the surface alloying process with the conventional ageing process together in order to save energy.Read moreRead less
Surface Nanocrystallization and Surface Alloying of Nonferrous Alloys. The research will offer materials scientists a totally new way to undertake surface modification for nonferrous alloys. The low temperature surface alloying technique to be developed will considerably improve the surface durability, therefore increase the service life of components. Combination of the surface alloying treatment with the ageing process can save energy and lower the cost of product. This will enhance Austral ....Surface Nanocrystallization and Surface Alloying of Nonferrous Alloys. The research will offer materials scientists a totally new way to undertake surface modification for nonferrous alloys. The low temperature surface alloying technique to be developed will considerably improve the surface durability, therefore increase the service life of components. Combination of the surface alloying treatment with the ageing process can save energy and lower the cost of product. This will enhance Australia's competitive ability in international markets. The study of atomic diffusion in nanomaterials will significantly contribute to material science and increase Australian research reputation in the world. In addition, the project initiates the research on surface nanocrystallization in Australia. Read moreRead less
Bulk Metallic Glasses and Their Applications. Bulk Metallic Glasses (BMG) represent a significant breakthrough in amorphous metallic materials research and opens up an enormous potential for BMG as engineering materials. However, currently there is no effective way to select optimum composition. The project will bring Australia together with two leading international research groups to develop a computer model for BMG alloy design and to further optimise BMG production processes. BMG engineering ....Bulk Metallic Glasses and Their Applications. Bulk Metallic Glasses (BMG) represent a significant breakthrough in amorphous metallic materials research and opens up an enormous potential for BMG as engineering materials. However, currently there is no effective way to select optimum composition. The project will bring Australia together with two leading international research groups to develop a computer model for BMG alloy design and to further optimise BMG production processes. BMG engineering components will be produced. The project provides Australian researchers access to leading expertise and specialized facilities which will rapidly bring us to the highest level. It represents Australia's first involvement in this significant material innovation. Read moreRead less