Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560705
Funder
Australian Research Council
Funding Amount
$825,000.00
Summary
Advanced Deformation Simulation Laboratory. For Australia to maintain its position as a world leader in the science of metals processing it must have the capability for state-of-the-art physical simulation. The present proposal is for the purchase and installation of two leading edge simulation tools: a high rate/short inter-pass hot deformation simulator and a hot equal channel angular extrusion press. Advanced hot deformation simulation is required for the development and optimisation of "fast ....Advanced Deformation Simulation Laboratory. For Australia to maintain its position as a world leader in the science of metals processing it must have the capability for state-of-the-art physical simulation. The present proposal is for the purchase and installation of two leading edge simulation tools: a high rate/short inter-pass hot deformation simulator and a hot equal channel angular extrusion press. Advanced hot deformation simulation is required for the development and optimisation of "fast" industrial processes and for understanding the complex microstructural reactions associated with them. High temperature extrusion is required for the development of ultra-fine and nano-grained light metals.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775721
Funder
Australian Research Council
Funding Amount
$520,000.00
Summary
Near Net Shaped Casting and Alloy Development Facility. Nearly all metal production is based around an initial casting phase, often followed by other deformation and thermal processes. This facility will allow us to study current and future advanced alloys and processing routes, including metals of strategic importance to Australia such as aluminium, titanium and magnesium. One of the major innovations for these metals is to directly cast to strip, followed by minimal processing to provide str ....Near Net Shaped Casting and Alloy Development Facility. Nearly all metal production is based around an initial casting phase, often followed by other deformation and thermal processes. This facility will allow us to study current and future advanced alloys and processing routes, including metals of strategic importance to Australia such as aluminium, titanium and magnesium. One of the major innovations for these metals is to directly cast to strip, followed by minimal processing to provide strip products with novel properties, low capital costs and short lead times. The outcomes from this research will support the development of existing and new metal industries in Australia.Read moreRead less
Intelligent Materials Processing: Microstructure And Texture Control In Bcc Metals. In Australia, steel companies are continuing to search for cost effective steel compositions and processing routes. Concurrently, applications for Ti alloys in chemical, medical and aerospace industries are continuing to widen. As an outcome of this project, the basis for the optimisation of processing routes in order to achieve enhanced product properties at lower cost will be established. In the course of this ....Intelligent Materials Processing: Microstructure And Texture Control In Bcc Metals. In Australia, steel companies are continuing to search for cost effective steel compositions and processing routes. Concurrently, applications for Ti alloys in chemical, medical and aerospace industries are continuing to widen. As an outcome of this project, the basis for the optimisation of processing routes in order to achieve enhanced product properties at lower cost will be established. In the course of this work, a new model for the prediction of microstructure and texture evolution during recrystallisation will be developed and new process routes will be designed. Read moreRead less
Dynamically responding metals: a new generation of engineering alloys. The manufacture of engineering metals is a major Australian industry and the worldwide metal manufacturing sector is estimated to be worth $1 trillion USD per annum. Advanced materials and, particularly the light metals, are both designated national research priority areas. The availability of new classes of metals with greatly improved combinations of properties will profoundly affect not only metal use by existing industry, ....Dynamically responding metals: a new generation of engineering alloys. The manufacture of engineering metals is a major Australian industry and the worldwide metal manufacturing sector is estimated to be worth $1 trillion USD per annum. Advanced materials and, particularly the light metals, are both designated national research priority areas. The availability of new classes of metals with greatly improved combinations of properties will profoundly affect not only metal use by existing industry, through the introduction of new, stronger and safer metal grades, but also allows for new engineering designs which will lead, for example, to lighter and more efficient automobiles and more sustainable construction.Read moreRead less
Nano-scale Modification of Paint Surfaces for Contamination Resistance. The main aim of this work is to develop a process to produce a dirt resistant paint surface. Dirt resistance is an important characteristic of prepainted steel sheets often used in architectural situations where dirt build-up is unsightly. To develop the process it will be necessary to understand the mechanism of dirt adhesion to paints and the modes of operation of current dirt resistant processes. In addition work will be ....Nano-scale Modification of Paint Surfaces for Contamination Resistance. The main aim of this work is to develop a process to produce a dirt resistant paint surface. Dirt resistance is an important characteristic of prepainted steel sheets often used in architectural situations where dirt build-up is unsightly. To develop the process it will be necessary to understand the mechanism of dirt adhesion to paints and the modes of operation of current dirt resistant processes. In addition work will be required on the rate of surface segregation of additives to the paint solution. We propose to combine experimental and theoretical modelling approaches to obtain a fundamentally sound practical solution.Read moreRead less
Development of new steel products by thin strip casting and direct thermomechanical processing. The development of strip casting is now being driven by the opportunity to produce steel products with much lower utilization of energy, land and water and lower greenhouse gas emissions. However, this process represents a radical departure from conventional steel processes and therefore the factors that determine the final properties of the strip need to be understood and controlled under high rates ....Development of new steel products by thin strip casting and direct thermomechanical processing. The development of strip casting is now being driven by the opportunity to produce steel products with much lower utilization of energy, land and water and lower greenhouse gas emissions. However, this process represents a radical departure from conventional steel processes and therefore the factors that determine the final properties of the strip need to be understood and controlled under high rates of change. We believe that these challenges actually represent an opportunity to develop new high performance steel products that exploit the unique processing conditions of strip casting and that can use much more recycled material as a feed.Read moreRead less
ARC Centre of Excellence - Design in Light Metals. Under the national Light Metals Action Agenda, Australia recognizes a strategic interest in the production, processing and applications of the light metals, and a growth in global markets for light metals technology. Light metals research is a designated national priority, and this Centre will provide the national focus in strategic fundamental research, the critical level of investment and the level of innovation necessary to achieve competiti ....ARC Centre of Excellence - Design in Light Metals. Under the national Light Metals Action Agenda, Australia recognizes a strategic interest in the production, processing and applications of the light metals, and a growth in global markets for light metals technology. Light metals research is a designated national priority, and this Centre will provide the national focus in strategic fundamental research, the critical level of investment and the level of innovation necessary to achieve competitive advantage from an outstanding research base. As a major contributor to a strategic network of national research capabilities, it will underpin substantial developments in the light metals industry nationally and globally, and extend linkages with major research centres internationally.Read moreRead less
Giant magnetic hardening in flash-annealed nanocomposite magnets. One of the most important properties required for permanent magnets is the coercivity. Recent results from an international collaboration between the Chief Investigator and researchers from the Japanese materials industry have shown that rapid heating can enhance the coercivity of chromium-added iron-neodymium-boron-based nanocomposite magnets by 30 times. The aim of this project is to clarify the mechanism of this giant magnetic ....Giant magnetic hardening in flash-annealed nanocomposite magnets. One of the most important properties required for permanent magnets is the coercivity. Recent results from an international collaboration between the Chief Investigator and researchers from the Japanese materials industry have shown that rapid heating can enhance the coercivity of chromium-added iron-neodymium-boron-based nanocomposite magnets by 30 times. The aim of this project is to clarify the mechanism of this giant magnetic hardening effect and thereby establish a basis for further development of economically viable nanocomposite magnets with low neodymium content. Our novel flash-annealing process will allow exploration of new nanocomposite alloys, which may lead to Australian-owned patents.Read moreRead less
Design Strategy for Cold Roll Formed Products. Roll forming is a widely used metal forming technology in Australia. The demands for shorter lead times, more complex shapes, new high strength materials and more demanding markets such as the automotive industry, requires increased virtual engineering at the design stage. This project will develop the models and tools required to enable the industry to efficiently design robust roll configurations to meet current and future demands. The outcomes ....Design Strategy for Cold Roll Formed Products. Roll forming is a widely used metal forming technology in Australia. The demands for shorter lead times, more complex shapes, new high strength materials and more demanding markets such as the automotive industry, requires increased virtual engineering at the design stage. This project will develop the models and tools required to enable the industry to efficiently design robust roll configurations to meet current and future demands. The outcomes from this project will not only benefit the industry partners involved but the general Australian roll forming industry, opening up new markets and opportunities.Read moreRead less
Interface Engineering of Multilayer Nanostructures. Nanostructured multilayers can outperform coatings of their constituent layers in both hardness and strength. It is believed that the nature of interfaces in these materials is critical since they mediate dislocation motion and crack propagation. This project will use advanced synthesis, microanalysis and theoretical methods to investigate multilayer coatings with sharp, diffuse and rough interfaces in order to reveal their failure mechanisms u ....Interface Engineering of Multilayer Nanostructures. Nanostructured multilayers can outperform coatings of their constituent layers in both hardness and strength. It is believed that the nature of interfaces in these materials is critical since they mediate dislocation motion and crack propagation. This project will use advanced synthesis, microanalysis and theoretical methods to investigate multilayer coatings with sharp, diffuse and rough interfaces in order to reveal their failure mechanisms under stress. This will enable us to understand the principles required to design the strongest structures and facilitate the selection of materials and deposition parameters in order to produce coatings optimised for a range of demanding applications.Read moreRead less