Innovation for anchorage wedge manufacturing. The consumption of tendon anchorage wedges worldwide is in the billions every year, but their manufacturing process is inadequate. The revolutionary technology to be developed by this proposed research will enable the manufacturers to achieve a cost-effective eco-fabrication with minimal material and energy wastages.
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
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
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
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
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
Mechanics of innovative high precision rolling technology in micromanufacturing. This project will focus on the establishment of high precision rolling technology for manufacturing microparts in Australia by using a unique profile and flexible rolling method. A successful outcome will provide an important breakthrough in the microrolling area and new knowledge for advanced micromanufacturing technology and its applications.
Lubrication mechanics in hot strip rolling. The economic benefits in steel production of lubrication, reduced rolling force and roll wear, energy saving on power consumption, and better strip quality are highly significant. This project will provide new knowledge on the lubrication mechanics to help the Australian metal manufacturing industry to achieve maximum benefits.
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