Industrial Transformation Training Centres - Grant ID: IC180100008
Funder
Australian Research Council
Funding Amount
$3,981,223.00
Summary
ARC Training Centre for Multiscale 3D Imaging, Modelling and Manufacturing. The ARC Training Centre for Multiscale 3D Imaging, Modelling and Manufacturing aims to connect the detailed microscopic characteristics of materials with their macroscopic properties and design characteristics of natural and manufactured structures. It will train a new generation of researchers and practitioners in the emerging discipline of Digital Materials. The approach allows optimisation at all scales, enabling cost ....ARC Training Centre for Multiscale 3D Imaging, Modelling and Manufacturing. The ARC Training Centre for Multiscale 3D Imaging, Modelling and Manufacturing aims to connect the detailed microscopic characteristics of materials with their macroscopic properties and design characteristics of natural and manufactured structures. It will train a new generation of researchers and practitioners in the emerging discipline of Digital Materials. The approach allows optimisation at all scales, enabling cost reductions and performance enhancements in key industries, including Oil, Gas and Energy Resources, Medical Technologies, and Advanced Manufacturing. The Centre expects to reduce the time needed in the prototyping cycle and product development, increasing industry’s capacity for accelerated innovation. The developments will build world-class Australian capabilities for developing high-value scaleable production of bespoke products and optimised process design.Read moreRead less
New Lead-Free Brass Solutions for Drinking Water Applications. The aim of this Linkage Project is to provide viable material solutions to address the health problem of Lead-contamination in drinking water arising from Leaded-brass plumbing products and the impact Lead-removal from brass will have on the brass industry. In order to achieve this, this project engages leading multidisciplinary researchers along with Australian and international industry partners from across the brass industry suppl ....New Lead-Free Brass Solutions for Drinking Water Applications. The aim of this Linkage Project is to provide viable material solutions to address the health problem of Lead-contamination in drinking water arising from Leaded-brass plumbing products and the impact Lead-removal from brass will have on the brass industry. In order to achieve this, this project engages leading multidisciplinary researchers along with Australian and international industry partners from across the brass industry supply and sales network. This project seeks to identify and harness the key material-product attributes required to develop and implement new, lead-free alloy alternatives that meet health-compliance, production and commercial viability, that offer benefits across the industry network and health benefits to society.Read moreRead less
Mechanics of the shape of thin strip with varying thickness. This project aims to develop an innovative technology for the production of thin strip with controlled varying longitudinal thickness and shape. The project will propose a new thin strip rolling theory and strip shape control strategy providing an improved understanding of the mechanics of manufacturing thin strips with varying longitudinal thickness. The technology to manufacture rolled products with varying thickness for lightweight ....Mechanics of the shape of thin strip with varying thickness. This project aims to develop an innovative technology for the production of thin strip with controlled varying longitudinal thickness and shape. The project will propose a new thin strip rolling theory and strip shape control strategy providing an improved understanding of the mechanics of manufacturing thin strips with varying longitudinal thickness. The technology to manufacture rolled products with varying thickness for lightweight structures is in significant demand for the automotive, aerospace and electronics industries to reduce weight through optimum strip thickness and minimum joints. The benefits will include reduced weight, fuel consumption and construction time of automobiles and aircraft when the developed novel thin strip products are used, and therefore reducing manufacturing costs and negative environmental impacts.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
Metal folding fundamentals to shape new corrugated building products . FormFlow has developed a ground-breaking forming process enabling the use of corrugated iron as a structural element. This is a step change for Australia`s steel and building industry and will provide a direct benefit to fireproofing homes. Up scaling of this new technology poses significant challenges due to the lack of understanding in the new forming process and the effect of pre-processing on the incoming material. Fundam ....Metal folding fundamentals to shape new corrugated building products . FormFlow has developed a ground-breaking forming process enabling the use of corrugated iron as a structural element. This is a step change for Australia`s steel and building industry and will provide a direct benefit to fireproofing homes. Up scaling of this new technology poses significant challenges due to the lack of understanding in the new forming process and the effect of pre-processing on the incoming material. Fundamental knowledge of material behaviour will be developed with advanced models that account for the unique process deformation conditions. The intended outcome includes computer software for process design and new concepts for part shape control to improve product quality, repeatability and enable high volume manufacture.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100124
Funder
Australian Research Council
Funding Amount
$374,446.00
Summary
Fabrication of large-scale two-dimensional metallic nanosheets by accumulative rolling. This project aims to develop new techniques and insight into the thinning of metals from bulk to nano thicknesses which enables bulk manufacturing of large-scale two-dimensional (2D) metallic nanosheets. A novel rolling strategy will be adopted to achieve 2D metallic sheets with thicknesses less than 5nm and lateral sizes larger than 1mm, as well as demonstrating significantly improved electro-catalytic perfo ....Fabrication of large-scale two-dimensional metallic nanosheets by accumulative rolling. This project aims to develop new techniques and insight into the thinning of metals from bulk to nano thicknesses which enables bulk manufacturing of large-scale two-dimensional (2D) metallic nanosheets. A novel rolling strategy will be adopted to achieve 2D metallic sheets with thicknesses less than 5nm and lateral sizes larger than 1mm, as well as demonstrating significantly improved electro-catalytic performance. The proposed technique is expected to be a high-yield, low-cost alternative to traditional bottom-up techniques and is expected to be ready for implementation in industry for bulk manufacturing of 2D metallic nanosheets.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
Automated Integrity Assessment of Self-Piercing Rivet Joints: i4.0 Approach. Lightweighting in the car industry by the use of aluminium reduces emissions substantially. It entails joining the car body sections by self-piercing rivets rather than the traditional spot welds. We aim to fill the technology gap for effective quality control of these joints. The project expects to solve the problem by merging industry 4.0 principles, three-dimensional X-ray technology, machine learning computer vision ....Automated Integrity Assessment of Self-Piercing Rivet Joints: i4.0 Approach. Lightweighting in the car industry by the use of aluminium reduces emissions substantially. It entails joining the car body sections by self-piercing rivets rather than the traditional spot welds. We aim to fill the technology gap for effective quality control of these joints. The project expects to solve the problem by merging industry 4.0 principles, three-dimensional X-ray technology, machine learning computer vision and structural mechanics. The expected outcomes are technologies for automation-friendly assessment of these joints. This should benefit industries from medical to electronics to automatically spot a random and delicate abnormality within a solid of complex geometry, such as that in live tissue or an electronic circuit.Read moreRead less
Designed to last: novel gradient coatings for extreme environments. Hard coatings are frequently applied to equipment operating in harsh environments. Often such coatings are highly brittle and so fragile under stress, especially at high temperatures or in corrosive environments. Premature failure can affect safety and lead to negative economic and environmental consequences. The objective of this project is to combine bioinspired microstructural design with an emerging alloying concept to produ ....Designed to last: novel gradient coatings for extreme environments. Hard coatings are frequently applied to equipment operating in harsh environments. Often such coatings are highly brittle and so fragile under stress, especially at high temperatures or in corrosive environments. Premature failure can affect safety and lead to negative economic and environmental consequences. The objective of this project is to combine bioinspired microstructural design with an emerging alloying concept to produce a breakthrough in the development of engineering coatings; for example, overcoming the long standing trade-off between hardness and toughness. Such an innovative coating is expected to be highly durable in extreme conditions, and in so doing will help transform manufacturing, mining and desalination industries.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101773
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Ultra-tough coatings via materials engineering . This project aims to develop new generation coatings that combine highly controlled compositions and bio-inspired microstructural characteristics for safety-critical applications. This is made possible through smart materials design, multi-scale modelling and novel fabrication technique. The new coatings are expected to offer exceptionally high toughness underlain by a unique combination of various strengthening modes at multiple length scales. Th ....Ultra-tough coatings via materials engineering . This project aims to develop new generation coatings that combine highly controlled compositions and bio-inspired microstructural characteristics for safety-critical applications. This is made possible through smart materials design, multi-scale modelling and novel fabrication technique. The new coatings are expected to offer exceptionally high toughness underlain by a unique combination of various strengthening modes at multiple length scales. The application of the coatings will enhance the performance and safety of mechanical components in engineering applications, reduce associated costs. In doing so, this project will bring substantial benefits to advanced manufacturing, mining and aerospace sectors. Read moreRead less