Industrial Transformation Training Centres - Grant ID: IC200100001
Funder
Australian Research Council
Funding Amount
$4,879,415.00
Summary
ARC Training Centre for Collaborative Robotics in Advanced Manufacturing. The Centre aims to build the human and technical capability Australia needs to underpin our global competitiveness in advanced manufacturing. The Centre will unite manufacturing businesses, including SMEs, and universities to develop collaborative robotics applications which combine the strengths of humans and robots in shared work environments. The Centre will train researchers, engineers, technologists and manufacturing ....ARC Training Centre for Collaborative Robotics in Advanced Manufacturing. The Centre aims to build the human and technical capability Australia needs to underpin our global competitiveness in advanced manufacturing. The Centre will unite manufacturing businesses, including SMEs, and universities to develop collaborative robotics applications which combine the strengths of humans and robots in shared work environments. The Centre will train researchers, engineers, technologists and manufacturing leaders with the expertise industry needs to boost safety, quality assurance, production efficiency, and workforce readiness. The intended outcome is to support Australian manufacturers to shift toward higher-potential markets, compete globally and attract and retain a digitally-capable workforce for the future.Read moreRead less
Characterization, modelling and control for robotic thermal ablation. This project aims to study the fundamental issues in robotic-assisted minimally invasive thermal ablation, an important therapy for patients with cancer. It aims to establish advanced characterisation and modelling methodologies for thermomechanical behaviours of soft tissues, together with automatic planning and precise manipulation control techniques for robotic thermal ablation therapies. The project will establish new know ....Characterization, modelling and control for robotic thermal ablation. This project aims to study the fundamental issues in robotic-assisted minimally invasive thermal ablation, an important therapy for patients with cancer. It aims to establish advanced characterisation and modelling methodologies for thermomechanical behaviours of soft tissues, together with automatic planning and precise manipulation control techniques for robotic thermal ablation therapies. The project will establish new knowledge and instrumentation for robotic-assisted thermal ablation and minimally invasive surgery. The outcomes of this project will produce important benefits to medicine, healthcare and medical technology industry, and further consolidate Australia’s position in innovative technologies and research and development of advanced healthcare systems and instruments.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC160100040
Funder
Australian Research Council
Funding Amount
$3,815,143.00
Summary
ARC Training Centre for Automated Manufacture of Advanced Composites. ARC Training Centre for Automated Manufacture of Advanced Composites. This centre aims to develop innovative researchers who can transform Australia’s high-performance carbon composites manufacturing industry. This aim will be achieved through the adoption and creative use of advanced automation technology, which brings benefits of speed, flexibility and accuracy. Industry-based research experience will be enhanced through exp ....ARC Training Centre for Automated Manufacture of Advanced Composites. ARC Training Centre for Automated Manufacture of Advanced Composites. This centre aims to develop innovative researchers who can transform Australia’s high-performance carbon composites manufacturing industry. This aim will be achieved through the adoption and creative use of advanced automation technology, which brings benefits of speed, flexibility and accuracy. Industry-based research experience will be enhanced through exposure to international partners at the cutting edge of advanced composites manufacturing research and development in developed economies. The intended outcome is a generation of innovators who can use the benefits of automation to position Australian manufacturers as world-class agile producers of high-value advanced composite structures using high-rate, error-free processes.Read moreRead less
New Ceramic: Fully Stabilised Monoclinic ZrO2 by Al2O3 + SiO2 Additions. Aim: To use conventional manufacturing and advanced manufacturing to produce an unprecedented form of zirconia: Fully stabilised monoclinic zirconia. Significance: The product utilises waste and inexpensive raw materials and it avoids the universal nanoscale transformation from the tetragonal and cubic forms of zirconia, which are commercialised. Outcomes: The product can have widespread uses in the chemical, refractory and ....New Ceramic: Fully Stabilised Monoclinic ZrO2 by Al2O3 + SiO2 Additions. Aim: To use conventional manufacturing and advanced manufacturing to produce an unprecedented form of zirconia: Fully stabilised monoclinic zirconia. Significance: The product utilises waste and inexpensive raw materials and it avoids the universal nanoscale transformation from the tetragonal and cubic forms of zirconia, which are commercialised. Outcomes: The product can have widespread uses in the chemical, refractory and mining industries and the technology aims to expand the industrial partner's commodity base from structural ceramics to high-tech ceramics. Benefits: Greater utilisation of waste and Australian raw materials, new commercialisation opportunities, new training and employment opportunities and breakthrough research.Read moreRead less
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
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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100168
Funder
Australian Research Council
Funding Amount
$550,000.00
Summary
Integrated Functional Printing Facility for Advanced Material Technologies. The project aims to develop Australia’s first fully integrated small-scale and agile prototyping facility for printing. This facility will provide critical infrastructure to deposit a wide range of advanced materials with unprecedented precision & process flexibility allowing realistic form, configuration and device-ready formats with minimal usage of functional ink. Using this unique facility, researchers will be able t ....Integrated Functional Printing Facility for Advanced Material Technologies. The project aims to develop Australia’s first fully integrated small-scale and agile prototyping facility for printing. This facility will provide critical infrastructure to deposit a wide range of advanced materials with unprecedented precision & process flexibility allowing realistic form, configuration and device-ready formats with minimal usage of functional ink. Using this unique facility, researchers will be able to assess integration of novel functional materials in a wide range of devices and applications, including critical components of affordable healthcare diagnostic devices, advanced security features in banknotes, integrated RFID tracking systems, high performance solar cells and separation membranes. Read moreRead less
High speed multi-channel discharge machining of difficult-to-cut materials. This project aims to develop a novel approach to high speed machining of difficult-to-cut materials by resolving the contradictory surface quality and machining efficiency problem with a new theory. It is expected to advance the fundamental knowledge of electrical machining. The outcomes are new machining theories, novel methods and models of using multiple low energy sparks which occur nearly simultaneously for high spe ....High speed multi-channel discharge machining of difficult-to-cut materials. This project aims to develop a novel approach to high speed machining of difficult-to-cut materials by resolving the contradictory surface quality and machining efficiency problem with a new theory. It is expected to advance the fundamental knowledge of electrical machining. The outcomes are new machining theories, novel methods and models of using multiple low energy sparks which occur nearly simultaneously for high speed machining of a wide range of advanced materials. It should significantly increase machining speed and thus dramatically reduce the costs of producing products such as titanium medical implants, alloyed engine components and new cutting tools which are vital for the biomaterials, aerospace and manufacturing industries.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101733
Funder
Australian Research Council
Funding Amount
$400,661.00
Summary
3D printing of multi-level porosity glass. This project aims to explore the fundamentals of 3D printing glass and multi-level porosity structures. 3D printing of plastics and metals fails to realise low-cost, robust, transparent, and biocompatible devices. The advent of glass and ceramic 3D printing can overcome these limitations. Moreover, multi-level porosity structures are becoming vital to the advancement of various fields, such as energy, health, and environmental. Expected outcomes of the ....3D printing of multi-level porosity glass. This project aims to explore the fundamentals of 3D printing glass and multi-level porosity structures. 3D printing of plastics and metals fails to realise low-cost, robust, transparent, and biocompatible devices. The advent of glass and ceramic 3D printing can overcome these limitations. Moreover, multi-level porosity structures are becoming vital to the advancement of various fields, such as energy, health, and environmental. Expected outcomes of the project would include the development of more sustainable glass and ceramic manufacturing procedure and new high-performance multi-level porosity devices. The project should provide significant benefits by addressing four science and research priorities of Australia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100057
Funder
Australian Research Council
Funding Amount
$650,000.00
Summary
Australian Stress Engineering Facility. This project aims to radically enhance the Australian capability for residual stress measurements and damage analysis. This project is expected to revolutionise stress engineering research in Australia by providing access to a state-of-the-art measurement capability that will enable on-site measurements at manufacturing plants and in laboratories. Expected outcomes of this project include the development and optimisation of advanced manufacturing and maint ....Australian Stress Engineering Facility. This project aims to radically enhance the Australian capability for residual stress measurements and damage analysis. This project is expected to revolutionise stress engineering research in Australia by providing access to a state-of-the-art measurement capability that will enable on-site measurements at manufacturing plants and in laboratories. Expected outcomes of this project include the development and optimisation of advanced manufacturing and maintenance technologies for civil engineering structures. This should provide significant benefits in safety, reliability and economic impact to Australian researchers in academia and industry across manufacturing, civil, transport, defence and medical sectors.Read moreRead less