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
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
Predictive modelling of the incremental sheet forming process. This project will benefit Australia with the gain of fundamental understanding of an advanced manufacturing process leading to a step change from an 'art of expertise' to a scientific understanding and improvement. The innovative design software kernel developed will facilitate a step change in manufacture of complex sheet formed product, such as aircraft and vehicle panelling. This seed collaborative research with QMI Solutions and ....Predictive modelling of the incremental sheet forming process. This project will benefit Australia with the gain of fundamental understanding of an advanced manufacturing process leading to a step change from an 'art of expertise' to a scientific understanding and improvement. The innovative design software kernel developed will facilitate a step change in manufacture of complex sheet formed product, such as aircraft and vehicle panelling. This seed collaborative research with QMI Solutions and global partner, Boeing, will enhance national modelling capability in advanced metal forming, a niche market for Australian manufacturing. The new technology and research support capabilities for its adoption, will lead to new national business and export opportunities.Read moreRead less