Flame-Retarding and Mechanically Resilient Elastomer Composites. This project will develop a new generation of flame-retarding and mechanically resilient elastomer composites by taking advantage of nanoscale effect and synergy. The outcomes will be two types of flame-retarding additive pellets and their elastomer composites; these pellets also suit other polymers such as thermoplastics. The elastomer composites are expected to have excellent flame retardancy, mechanical properties, and fatigue p ....Flame-Retarding and Mechanically Resilient Elastomer Composites. This project will develop a new generation of flame-retarding and mechanically resilient elastomer composites by taking advantage of nanoscale effect and synergy. The outcomes will be two types of flame-retarding additive pellets and their elastomer composites; these pellets also suit other polymers such as thermoplastics. The elastomer composites are expected to have excellent flame retardancy, mechanical properties, and fatigue performance, to meet the demands from industrial partners. The project will provide a platform for elastomer manufacturing industry to develop flame-retarding, high-performance products for domestic applications and for export. Read moreRead less
Net-shape micro manufacturing of composite micro channels. This project aims to develop a high precision net-shape micro manufacturing technology for the production of composite micro channels in a one-step process with excellent overall performance in quality and productivity. The new technology will enhance the production of commercial micro channels which have extensive applications in micro-electromechanical systems, health, medical and communications industries. This project will improve th ....Net-shape micro manufacturing of composite micro channels. This project aims to develop a high precision net-shape micro manufacturing technology for the production of composite micro channels in a one-step process with excellent overall performance in quality and productivity. The new technology will enhance the production of commercial micro channels which have extensive applications in micro-electromechanical systems, health, medical and communications industries. This project will improve the competitive advantage for Australia in the field of advanced manufacturing and has the potential to stimulate economic benefit and growth of the manufacturing industry.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
Early Career Industry Fellowships - Grant ID: IE230100678
Funder
Australian Research Council
Funding Amount
$438,572.00
Summary
A Digital Twin-Driven Model for Mapping Part Quality in Multi-Jet Fusion. This project aims to develop a digital simulation model to address the irregular mechanical properties of Multi-Jet Fusion in 3D printing of automotive components. This model expects to solve a significant challenge when using Multi-Jet Fusion which is the dependence of quality on the build position. The expected outcome of this project is the development of a novel tool for quality assessment in mass customisation and pro ....A Digital Twin-Driven Model for Mapping Part Quality in Multi-Jet Fusion. This project aims to develop a digital simulation model to address the irregular mechanical properties of Multi-Jet Fusion in 3D printing of automotive components. This model expects to solve a significant challenge when using Multi-Jet Fusion which is the dependence of quality on the build position. The expected outcome of this project is the development of a novel tool for quality assessment in mass customisation and production. This project will provide significant benefits by creating an independent digital simulation model for quality mapping in Multi-Jet Fusion that reduces production costs and enhances automotive part quality.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC160100027
Funder
Australian Research Council
Funding Amount
$4,340,802.00
Summary
ARC Training Centre for Biopharmaceutical Innovation. ARC Training Centre for Biopharmaceutical Innovation. This centre aims to transform Australia’s growing biopharmaceutical industry, an advanced manufacturing capability, by training specialist biotechnologists and bioengineers. It expects the research and development outputs will create new biopharmaceuticals and antibody-based reagents, enhanced production methods, improved manufacturing capabilities and a cohort of specialist scientists. Ne ....ARC Training Centre for Biopharmaceutical Innovation. ARC Training Centre for Biopharmaceutical Innovation. This centre aims to transform Australia’s growing biopharmaceutical industry, an advanced manufacturing capability, by training specialist biotechnologists and bioengineers. It expects the research and development outputs will create new biopharmaceuticals and antibody-based reagents, enhanced production methods, improved manufacturing capabilities and a cohort of specialist scientists. New biopharmaceuticals are expected to benefit the Australian economy and provide new therapeutic options for better health outcomes. Industry-driven research projects will also provide industry-ready graduates who can drive future growth in the sector.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
Elastomer/Graphene Composites for Reinforcement at Low Strain. This project aims to develop new elastomer/graphene composites by designing and fabricating graphene precursors which can transform into graphene sheets during melt compounding with elastomers. These sheets have tunable surface affinity with elastomers, to attain expected dispersion in elastomers for effective reinforcement at low strain. The dominant filler in industry – carbon black – is ineffective at low strain. The outcomes are ....Elastomer/Graphene Composites for Reinforcement at Low Strain. This project aims to develop new elastomer/graphene composites by designing and fabricating graphene precursors which can transform into graphene sheets during melt compounding with elastomers. These sheets have tunable surface affinity with elastomers, to attain expected dispersion in elastomers for effective reinforcement at low strain. The dominant filler in industry – carbon black – is ineffective at low strain. The outcomes are anticipated to transform the current manufacturing practice of rubber products for applications in agricultural, automobile, construction, medical and mining industries.Read moreRead less
Ultralow emission panel systems for rapid modular construction. This proposed project aims to develop an innovative ultra-low emission precast panel comprising a novel ultra-low carbon concrete mixture that is cast in vertical battery moulds. The new precast panels will have several significant enhancements compared to traditional precast panels, including faster manufacturing, reduced cost, and a much lower carbon footprint and life-cycle costs. A holistic theoretical and design framework will ....Ultralow emission panel systems for rapid modular construction. This proposed project aims to develop an innovative ultra-low emission precast panel comprising a novel ultra-low carbon concrete mixture that is cast in vertical battery moulds. The new precast panels will have several significant enhancements compared to traditional precast panels, including faster manufacturing, reduced cost, and a much lower carbon footprint and life-cycle costs. A holistic theoretical and design framework will be developed for predicting the behaviour of the innovative precast panel under structural, fire and impact loading. The panel will offer desirable benefits such as industry leading durability, ease of construction and assembly, economy and recyclability.Read moreRead less