Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100139
Funder
Australian Research Council
Funding Amount
$350,000.00
Summary
A Hot Isostatic Press (HIP) for aerospace and biomedical component processing. This facility will provide a hot isostatic press of sufficiently large capacity to maximise production efficiencies in aerospace and biomedical applications through net shape manufacturing. The facility will be able to process small components or prototypes which will behave in a manner similar to larger scale components.
Low-cost, Lightweight and Liquid Helium-free Superconducting MRI Magnet. This project aims to develop a liquid-helium-free superconducting technology to address the need for more affordable MRI magnets that currently rely on expensive, limited supplies of liquid helium. This project expects to generate a world-first, much needed MRI systems to be operated in persistent mode without a power supply, to obtain high-resolution images and low-cost operation. The expected outcomes include a novel, lig ....Low-cost, Lightweight and Liquid Helium-free Superconducting MRI Magnet. This project aims to develop a liquid-helium-free superconducting technology to address the need for more affordable MRI magnets that currently rely on expensive, limited supplies of liquid helium. This project expects to generate a world-first, much needed MRI systems to be operated in persistent mode without a power supply, to obtain high-resolution images and low-cost operation. The expected outcomes include a novel, lightweight, easy-to-operate magnesium diboride superconducting MRI magnet prototype under persistent mode operation. This should provide significant benefits, including reducing the cost associated with conventional liquid helium-dependent technologies and ensuring Australia at the forefront of MRI development worldwide.Read moreRead less
Antibacterial impact assessment of nanopillar surfaces on titanium implants. This project aims to further understand the bactericidal properties of nano-pillared/textured surfaces, onto orthopaedic implants. It will do so by mimicking the nano-pillar structures derived from cicada wings by using Helium ion microscopy (HIM) and also Hydro Thermal techniques. The project also aims to study the physical mechanisms of the fracture of bacteria using numerical modelling. This project will result in ne ....Antibacterial impact assessment of nanopillar surfaces on titanium implants. This project aims to further understand the bactericidal properties of nano-pillared/textured surfaces, onto orthopaedic implants. It will do so by mimicking the nano-pillar structures derived from cicada wings by using Helium ion microscopy (HIM) and also Hydro Thermal techniques. The project also aims to study the physical mechanisms of the fracture of bacteria using numerical modelling. This project will result in new generation implants with minimal bacterial infection that could result in cost savings to the Australian healthcare, improved quality of life in aged population, and may lead to the establishment of new implant industry sector in Australia.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
Enabling Next-generation Rechargeable Aluminium-ion Batteries. This project aims to develop a new generation of high performance and low-cost cathode materials for rechargeable aluminium ion batteries. To address the low capacity issue of current cathodes, this project anticipates to generate new knowledge in the material design of novel graphene materials. By developing an innovative surface perforation technique coupled in a continuous production process, this project expects to produce scalab ....Enabling Next-generation Rechargeable Aluminium-ion Batteries. This project aims to develop a new generation of high performance and low-cost cathode materials for rechargeable aluminium ion batteries. To address the low capacity issue of current cathodes, this project anticipates to generate new knowledge in the material design of novel graphene materials. By developing an innovative surface perforation technique coupled in a continuous production process, this project expects to produce scalable and cost-effective graphene cathodes with a record-high capacity. Expected outcomes of this project include industrial adaptable manufacturing processing and advanced materials for aluminium ion batteries, thus increasing the competitiveness of the partner organisation in the rapid growing graphene market.
Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100156
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
Advanced Laser Additive Manufacturing System for Extended Applications to Surface Engineering, Direct Manufacturing and New Alloy Development. Advanced laser additive manufacturing system for extended applications to surface engineering, direct manufacturing and new alloy development: This project will provide an advanced laser additive manufacturing system for extended applications. Although the facility was originally designed for forefront additive manufacturing, it enables innovative resear ....Advanced Laser Additive Manufacturing System for Extended Applications to Surface Engineering, Direct Manufacturing and New Alloy Development. Advanced laser additive manufacturing system for extended applications to surface engineering, direct manufacturing and new alloy development: This project will provide an advanced laser additive manufacturing system for extended applications. Although the facility was originally designed for forefront additive manufacturing, it enables innovative research on surface engineering to solve the long standing corrosion and wear problems associated with metal components and to produce biomedical coatings on titanium implants. The facility can also be used to develop high quality alloys, including titanium and magnesium alloys, through an accelerated metallurgy approach, leading to breakthrough progress in metal research. Such alloys are highly desired by automotive and aerospace industries to improve fuel efficiency through weight reduction. Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH150100024
Funder
Australian Research Council
Funding Amount
$2,799,251.00
Summary
ARC Research Hub for Advanced Manufacturing of Medical Devices. ARC Research Hub for Advanced Manufacturing of Personalised Medical Devices. The project aims to transform Australia’s $10.8 billion medical technology sector by developing cost competitive technologies for the rapid production of personalised devices for Endovascular Aneurysm Repair (EVAR). To ensure the Australian industry remains globally competitive, this hub seeks to concurrently develop materials, technologies and flexible man ....ARC Research Hub for Advanced Manufacturing of Medical Devices. ARC Research Hub for Advanced Manufacturing of Personalised Medical Devices. The project aims to transform Australia’s $10.8 billion medical technology sector by developing cost competitive technologies for the rapid production of personalised devices for Endovascular Aneurysm Repair (EVAR). To ensure the Australian industry remains globally competitive, this hub seeks to concurrently develop materials, technologies and flexible manufacturing processes. The intended research outcomes include more efficient design and manufacturing processes and a new range of EVAR products generating increased market share and higher workforce capability. The resulting impacts should be better health outcomes, job creation and providing SMEs with new technologies and skills that can be transferred to the manufacture of products for other sectors.Read moreRead less
Large-volume gradient materials: Manufacturing and deformation mechanism. This project aims to develop a low-cost and high productivity process to produce large-volume metals with high strength and good ductility, suitable for engineering application. Ultrafine grained (UFG) materials and nano-grained (NG) materials are usually strong, but not very ductile. This project will use an accumulative skin-pass rolling (ASPR) technique to fabricate the metallic strips with gradient structure. The numer ....Large-volume gradient materials: Manufacturing and deformation mechanism. This project aims to develop a low-cost and high productivity process to produce large-volume metals with high strength and good ductility, suitable for engineering application. Ultrafine grained (UFG) materials and nano-grained (NG) materials are usually strong, but not very ductile. This project will use an accumulative skin-pass rolling (ASPR) technique to fabricate the metallic strips with gradient structure. The numerical simulations developed in the project are expected to contribute to understanding the deformation mechanism of gradient materials.Read moreRead less
An Integrated surface conversion for life extension of oil pipelines. This project will propose a novel, cost-effective surface engineering technique that synthesizes an effective surface coating during the pipeline manufacturing process. Seamless Steel pipelines conveying oil and contaminants can have a short life due to erosion-corrosion. The need to develop mitigation techniques against the internal corrosion-erosion has increased significantly as steel pipelines are used in more aggressive e ....An Integrated surface conversion for life extension of oil pipelines. This project will propose a novel, cost-effective surface engineering technique that synthesizes an effective surface coating during the pipeline manufacturing process. Seamless Steel pipelines conveying oil and contaminants can have a short life due to erosion-corrosion. The need to develop mitigation techniques against the internal corrosion-erosion has increased significantly as steel pipelines are used in more aggressive environments. The project expects to develop an integrated surface coating during the manufacturing process, which will provide long-term integrity and extend the life of the pipeline. The forensic evaluation and prediction of the life performance of the pipeline will quantify how the coating will combat effectively erosion-corrosion related problems in oil pipelines. Read moreRead less