Efficient Strategies for Coordinating Autonomous Vehicles for Maximising Australia's Waterfront Productivity. This project will lift the productivity of container terminals by enabling the effective deployment of autonomous vehicles in large numbers. The project outcomes of practically deployable and scalable algorithms, realised as live software, will significantly enhance Patrick Stevedores Holdings' world leading technology and the potential of such automation systems to revolutionise materia ....Efficient Strategies for Coordinating Autonomous Vehicles for Maximising Australia's Waterfront Productivity. This project will lift the productivity of container terminals by enabling the effective deployment of autonomous vehicles in large numbers. The project outcomes of practically deployable and scalable algorithms, realised as live software, will significantly enhance Patrick Stevedores Holdings' world leading technology and the potential of such automation systems to revolutionise material handling around the globe. Beyond the benefits of technology commercialisation, the project will also benefit Australia economically through extending its leading role in developing autonomous systems for material handling, enhancing the frontier technologies for building Australian industries, and alleviating looming capacity constraints.Read moreRead less
Modelling the Transient Effects in Dense Phase Gas-Solids Flow in Pipelines. Almost every physical item we use in our daily lives at some point requires the transport and handling of powdered or granular materials during the manufacturing process. Be it food (sugar, flour), chemicals (soap powders, detergents), cosmetics (talc, face powder) or electricity generation (coal and ash); each of these industries uses the flexibility of pipeline systems to transport powders and granular solids using ai ....Modelling the Transient Effects in Dense Phase Gas-Solids Flow in Pipelines. Almost every physical item we use in our daily lives at some point requires the transport and handling of powdered or granular materials during the manufacturing process. Be it food (sugar, flour), chemicals (soap powders, detergents), cosmetics (talc, face powder) or electricity generation (coal and ash); each of these industries uses the flexibility of pipeline systems to transport powders and granular solids using air as the motive force. However, the cost of poor design and the inaccurate prediction of system performance adversely affect the efficiency of many industries. Improvements to the accuracy of gas-solid flow modeling particularly for low velocity dense phase systems will have a direct impact on manufacturing efficiency.Read moreRead less
A new abrasive waterjet milling technology and process models for fabricating energy-efficient electrical machines from amorphous magnetic metal laminations. As the most energy-efficient core material for electrical machines, amorphous magnetic metal (AMM) can save more than 36% of the energy wasted by ordinary electrical motors. Since electrical motors consume about 70% of all the electricity generated, if all electrical motors in Australia use AMM as the core material, an annual energy saving ....A new abrasive waterjet milling technology and process models for fabricating energy-efficient electrical machines from amorphous magnetic metal laminations. As the most energy-efficient core material for electrical machines, amorphous magnetic metal (AMM) can save more than 36% of the energy wasted by ordinary electrical motors. Since electrical motors consume about 70% of all the electricity generated, if all electrical motors in Australia use AMM as the core material, an annual energy saving worth approximately $4 billion and an annual reduction of 16 million tonnes of greenhouse gas emission in Australia are expected based on the predicted electricity consumption in 2010. This project will develop a new technology for fabricating larger electrical machines from AMM laminations. It targets the national research priorities in Frontier Technologies and An Environmentally Sustainable Australia.Read moreRead less
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
Life-time Modelling of Industrial Products for Reuse. Product disposal responsibility has shifted from consumers to manufacturers. Re-use of components is the most efficient strategy for product recovery, which requires reliable methods for assessing the quality and remaining life of used components. The aim of this project is to develop a lifetime model to estimate the remaining life and quality of a used component. This will enable manufacturers to estimate the potential reusability of a compo ....Life-time Modelling of Industrial Products for Reuse. Product disposal responsibility has shifted from consumers to manufacturers. Re-use of components is the most efficient strategy for product recovery, which requires reliable methods for assessing the quality and remaining life of used components. The aim of this project is to develop a lifetime model to estimate the remaining life and quality of a used component. This will enable manufacturers to estimate the potential reusability of a component without going through costly and time consuming disassembly processes. In addition, the data from the lifetime monitoring process will provide information for improving the design and manufacture of environmentally friendly products.Read moreRead less
Haptic exploration and manipulation of micro/nano scale environment. The proposed research is novel and innovative in character and it has potential benefits in many frontier areas utilising micro/nano manipulation systems. These include micromanufacturing and instrumentation, microbiology, microsurgery and nanotechnology. The outcomes of this project will add to the growth of world-class Australian engineering science, and consolidate Australia's position in innovative technologies and internat ....Haptic exploration and manipulation of micro/nano scale environment. The proposed research is novel and innovative in character and it has potential benefits in many frontier areas utilising micro/nano manipulation systems. These include micromanufacturing and instrumentation, microbiology, microsurgery and nanotechnology. The outcomes of this project will add to the growth of world-class Australian engineering science, and consolidate Australia's position in innovative technologies and international R&D. This highly challenging project will provide training for postdoctorate researchers, postgraduate and honours students. These researchers will gain expertise in many areas including micro/nano manipulation, sensing and control, system design and analysis, virtual reality and experimental techniques.Read moreRead less
Cleaning of tough paints on advanced composites using laser technologies. This project researches fundamental knowledge and algorithms to underpin the deployment of a novel ablation technology using pulsed lasers to remove paints, in particular tough paints, from surfaces of advanced composite structures, e.g. airframes and turbine blades. It establishes thermal mechanical models to describe ablation mechanisms of pulsed laser removal of the paint using both IR and UV bands. Optimal processing p ....Cleaning of tough paints on advanced composites using laser technologies. This project researches fundamental knowledge and algorithms to underpin the deployment of a novel ablation technology using pulsed lasers to remove paints, in particular tough paints, from surfaces of advanced composite structures, e.g. airframes and turbine blades. It establishes thermal mechanical models to describe ablation mechanisms of pulsed laser removal of the paint using both IR and UV bands. Optimal processing protocols to clean paints with different properties, without damaging the underlying composites, will be determined and demonstrated. It meets a cleaning technology need for this paint-on-composites material system to support retrofitting and re-manufacturing in industry. These are crucial industry requirements. Read moreRead less
Mechanics of mixed film lubrication in strip rolling. Rolling speeds of tandem cold rolling mills for thin steel strip are often limited by hot scratches and self excited chatter vibration, which forces the mill to slow down. Consequently the output is reduced and significant out-of-specification materials produced. Operating practices are guided by experience and trial-and-error method. In this project, a comprehensive model will be produced to quantify the effects of relevant parameters that c ....Mechanics of mixed film lubrication in strip rolling. Rolling speeds of tandem cold rolling mills for thin steel strip are often limited by hot scratches and self excited chatter vibration, which forces the mill to slow down. Consequently the output is reduced and significant out-of-specification materials produced. Operating practices are guided by experience and trial-and-error method. In this project, a comprehensive model will be produced to quantify the effects of relevant parameters that can provide a much better understanding of the rolling process at speeds higher than previously possible, and help to improve its productivity as well as product quality.Read moreRead less
Roll bite lubrication in hot strip rolling. Roll bite lubrication has been applied in hot strip rolling with significant cost savings in reduced rolling force, reduced roll wear and increasede productivity. However the mechanics of roll bite lubrication in the interface is not well understood due to the high temperature of the strip, scale oxide on the surfaces and contact asperities. It is known how the surface roughness is generated after rolling. This proposed project will develop a model to ....Roll bite lubrication in hot strip rolling. Roll bite lubrication has been applied in hot strip rolling with significant cost savings in reduced rolling force, reduced roll wear and increasede productivity. However the mechanics of roll bite lubrication in the interface is not well understood due to the high temperature of the strip, scale oxide on the surfaces and contact asperities. It is known how the surface roughness is generated after rolling. This proposed project will develop a model to simulate the roll bite lubrication process, to determine the roughness transfer from the roll surface to the strip surface, and optimise roll bite lubriation process.Read moreRead less
Contact mechanics in hot strip rolling. The mechanics of roll bite contact in hot strip rolling in the interface is not well understood due to the high temperature of the strip, scale oxide on the surfaces, contact asperities and lubrication mechanism of emulsion entrained in the roll bite. It is not known how the strip surface roughness is generated after rolling. This proposed project will develop a model to simulate the contact of the roll bite and to determine the quality of the surface roug ....Contact mechanics in hot strip rolling. The mechanics of roll bite contact in hot strip rolling in the interface is not well understood due to the high temperature of the strip, scale oxide on the surfaces, contact asperities and lubrication mechanism of emulsion entrained in the roll bite. It is not known how the strip surface roughness is generated after rolling. This proposed project will develop a model to simulate the contact of the roll bite and to determine the quality of the surface roughness transfer from the roll surface to the strip surface. The outcome would be significant cost savings in reduced rolling force, increased roll life, minimal surface defects and increased productivity.Read moreRead less