AM of MAX Phase parts for applications in extreme environments. This project aims to develop techniques to synthesize MAX Phase compound materials in-situ using laser additive manufacturing. The project expects to increase jet engine fuel efficiency and thrust, and to fabricate longer-lasting parts for supersonic speed applications. The expected outcomes include well-developed additive manufacturing processes to make high performance engineering components with shape complexity for extreme envir ....AM of MAX Phase parts for applications in extreme environments. This project aims to develop techniques to synthesize MAX Phase compound materials in-situ using laser additive manufacturing. The project expects to increase jet engine fuel efficiency and thrust, and to fabricate longer-lasting parts for supersonic speed applications. The expected outcomes include well-developed additive manufacturing processes to make high performance engineering components with shape complexity for extreme environment applications, and new methods to increase the 3D printability of brittle materials. This should provide significant benefits to aerospace and defense industries through solving their long standing bottleneck material and processing problems. The outcomes also enhance Australia’s manufacturing capacity.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101687
Funder
Australian Research Council
Funding Amount
$340,000.00
Summary
Nanostructure Tailoring of Inorganic Membranes by Rapid Thermal Processing. This project aims to produce inorganic membranes with desired nanostructures using a Rapid Thermal Processing (RTP) technique for gas separation applications. The key concept of the research is that the RTP will be able to achieve thin-film membrane layer with a finer microstructure and pore size control without heat stress-induced cracking. RTP aims to deliver superior membrane performance with less than 10 per cent of ....Nanostructure Tailoring of Inorganic Membranes by Rapid Thermal Processing. This project aims to produce inorganic membranes with desired nanostructures using a Rapid Thermal Processing (RTP) technique for gas separation applications. The key concept of the research is that the RTP will be able to achieve thin-film membrane layer with a finer microstructure and pore size control without heat stress-induced cracking. RTP aims to deliver superior membrane performance with less than 10 per cent of the fabrication time compared to normal slow calcination. The outcomes of this new technology aims to make inorganic membranes a commercial reality and maximize the membrane manufacturing capability and productivity of petrochemcial, chemical and clean coal/energy industries.Read moreRead less
Condition-based maintenance optimisation for Australian sugar industry. The aim of this project is to develop innovative methodologies for the implementation of condition-based maintenance in the sugar milling industry. This is designed to optimise the allocation of limited maintenance resources and to significantly reduce the $350 million spent on maintenance in the industry each year. New methodologies will account for the seasonality of production and the complexity of allocating limited main ....Condition-based maintenance optimisation for Australian sugar industry. The aim of this project is to develop innovative methodologies for the implementation of condition-based maintenance in the sugar milling industry. This is designed to optimise the allocation of limited maintenance resources and to significantly reduce the $350 million spent on maintenance in the industry each year. New methodologies will account for the seasonality of production and the complexity of allocating limited maintenance resources across numerous equipment items and different production sites. The intended outcome of the project will improve the efficiency of maintenance and hence the global competitiveness of the Australian sugar industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100003
Funder
Australian Research Council
Funding Amount
$280,000.00
Summary
Flexible forming facility for low cost light weight applications. Flexible forming facility for low-cost light-weight applications: This project will establish Australia’s first flexible roll forming facility. The facility will be unique in the world, being specifically designed to roll form the most advanced high strength alloys into complex three-dimensional shapes and investigate their material behaviour under a wide range of loading conditions. This technology represents a step change in com ....Flexible forming facility for low cost light weight applications. Flexible forming facility for low-cost light-weight applications: This project will establish Australia’s first flexible roll forming facility. The facility will be unique in the world, being specifically designed to roll form the most advanced high strength alloys into complex three-dimensional shapes and investigate their material behaviour under a wide range of loading conditions. This technology represents a step change in commercial processing and has the capacity to form materials with high strength and limited ductility. This will lead to the development of new techniques for the manufacture of new advanced materials including advanced high strength steels, composites, nano structured metals and light metal alloys for automotive and aerospace applications.Read moreRead less
A fast, eco-friendly approach to the fabrication of low cost high performance titanium components. The purpose of this project is to develop an innovative manufacturing approach by which the cost of titanium components can be substantially reduced. This will significantly increase the commercial applications of titanium and its alloys.
Ductile grinding mechanism and technology of brittle single crystals. This project aims to develop a fundamental understanding of the removal mechanics of emerging brittle single crystals under grinding-induced loading. A successful outcome will not only develop a new theoretical model for predicting the ductile removal regime of this class of difficult-to-machine materials, but their cost-effective ductile grinding processes will also be generated. It will address a longstanding bottleneck prod ....Ductile grinding mechanism and technology of brittle single crystals. This project aims to develop a fundamental understanding of the removal mechanics of emerging brittle single crystals under grinding-induced loading. A successful outcome will not only develop a new theoretical model for predicting the ductile removal regime of this class of difficult-to-machine materials, but their cost-effective ductile grinding processes will also be generated. It will address a longstanding bottleneck productivity issue in advanced manufacturing. The breakthrough technology developed in the project is expected to significantly benefit a number of industrial sectors for the fabrication of more affordable high-performance devices including mobile phones, light-emitting diodes, solar cells, sensors, and laser systems.Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH120100032
Funder
Australian Research Council
Funding Amount
$5,000,000.00
Summary
Commercial development of rock lobster culture systems: the cutting edge of aquaculture. Commercial development of rock lobster culture systems: the cutting edge of aquaculture. This Research Hub will develop unique aquaculture systems, using novel engineering manufacture to mass produce lobster seed stock. A reliable, large-scale supply of seed will enable seacage culture, evaluation of wild stock enhancement and lead to sustainable food production.
Industrial Transformation Research Hubs - Grant ID: IH130100008
Funder
Australian Research Council
Funding Amount
$4,000,000.00
Summary
ARC Research Hub for Transforming Australia’s Manufacturing Industry through High Value Additive Manufacturing. ARC Research Hub for Transforming Australia’s Manufacturing Industry through High Value Additive Manufacturing. A world class, globally-linked and industry-focussed Research Hub will be established to underpin the uptake of metal alloy based additive manufacturing (including three-dimensional printing) in Australia. Research will cover the issues that need to be resolved for success, ....ARC Research Hub for Transforming Australia’s Manufacturing Industry through High Value Additive Manufacturing. ARC Research Hub for Transforming Australia’s Manufacturing Industry through High Value Additive Manufacturing. A world class, globally-linked and industry-focussed Research Hub will be established to underpin the uptake of metal alloy based additive manufacturing (including three-dimensional printing) in Australia. Research will cover the issues that need to be resolved for success, including the effects of non-equilibrium solidification, process optimisation to achieve quality, consistency and repeatability, and new user-friendly design tools to realise the benefit of free-form manufacturing. Real components will be studied to give immediate impact. The Research Hub will also train highly skilled people needed for this growing industry.Read moreRead less
A new lapping process for difficult-to-machine brittle materials. This project aims to address a timely bottleneck issue in the conventional lapping of difficult-to-machine optoelectronic brittle materials. An innovative chemically enhanced lapping technology for fabricating such materials is expected to reduce machined subsurface damage. This is significant because it would shorten the subsequent finishing process and minimise the manufacturing cost. Intended outcomes from this project also inc ....A new lapping process for difficult-to-machine brittle materials. This project aims to address a timely bottleneck issue in the conventional lapping of difficult-to-machine optoelectronic brittle materials. An innovative chemically enhanced lapping technology for fabricating such materials is expected to reduce machined subsurface damage. This is significant because it would shorten the subsequent finishing process and minimise the manufacturing cost. Intended outcomes from this project also include an advanced machining theory and innovations in material removal characterisation. This breakthrough technology should benefit the design and fabrication of high performance electronic devices for energy, medicine and communication sectors with considerable impact on the Australian economy.Read moreRead less
Developing machining technologies for single crystal gallium oxide. Gallium oxide is a new semiconductor material that can be used to make diodes and transistors with lower loss than silicon (Si), and power electronic devices with lower cost and better performance than silicon carbide (SiC) and gallium nitride (GaN). This project aims to understand the nature of deformation and removal of this unique class of materials during machining. A successful outcome will not only develop an enabling mach ....Developing machining technologies for single crystal gallium oxide. Gallium oxide is a new semiconductor material that can be used to make diodes and transistors with lower loss than silicon (Si), and power electronic devices with lower cost and better performance than silicon carbide (SiC) and gallium nitride (GaN). This project aims to understand the nature of deformation and removal of this unique class of materials during machining. A successful outcome will not only develop an enabling machining technology for this next generation power semiconductor, but new understanding of machining and materials science will be generated.Read moreRead less