Development of a Cost-Effective Organic-Inorganic Nanocomposite for High Quality Gravure Printing. Gravure printing is the printing process of choice for long runs and high quality. The conventional process involves the manufacture of copper-plated, chrome-coated cylinders into which the desired image is engraved. The cylinders have high manufacturing and operating costs. The chemicals used in the process are highly toxic and therefore pose major threats to humans and environment. This proposa ....Development of a Cost-Effective Organic-Inorganic Nanocomposite for High Quality Gravure Printing. Gravure printing is the printing process of choice for long runs and high quality. The conventional process involves the manufacture of copper-plated, chrome-coated cylinders into which the desired image is engraved. The cylinders have high manufacturing and operating costs. The chemicals used in the process are highly toxic and therefore pose major threats to humans and environment. This proposal outlines the first attempts to develop a new and innovative hybrid organic-inorganic nanocomposite material to replace the copper plating and chrome coating. The success of the project will offer high quality, affordable and environmentally friendly printing service to both local and international clientele.
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Modelling for Optimisation and Scale-up of the Multilayer Blown Film Process. Multilayered blown film plastic films play an important role in the food and packaging industry in Australia and SE Asia. This project aims to predict the polymer film properties for a large scale line based on experimental data from the pilot scale studies using limited quantities of polymer. This project will investigate the fundamental rheology of polymer resins and blends used for multilayered films and correlate ....Modelling for Optimisation and Scale-up of the Multilayer Blown Film Process. Multilayered blown film plastic films play an important role in the food and packaging industry in Australia and SE Asia. This project aims to predict the polymer film properties for a large scale line based on experimental data from the pilot scale studies using limited quantities of polymer. This project will investigate the fundamental rheology of polymer resins and blends used for multilayered films and correlate these to the operating parameters in pilot and industrial scales using blown-film models. The interrelationship between the models in two scales will result in reducing trial and error and will optimise production costs.Read moreRead less
An Intelligent Computer Aided Engineering Environment for Design and Production of Blow Moulded PET Bottles. The aim of this research proposal is to develop an intelligent computer aided engineering environment for design and manufacturing of blow moulded PET bottles. Current techniques involve a mixture of trial and error leading to high costs in time and money. The proposed research will adopt a concurrent engineering approach and integrating intelligent knowledge based systems for optimum p ....An Intelligent Computer Aided Engineering Environment for Design and Production of Blow Moulded PET Bottles. The aim of this research proposal is to develop an intelligent computer aided engineering environment for design and manufacturing of blow moulded PET bottles. Current techniques involve a mixture of trial and error leading to high costs in time and money. The proposed research will adopt a concurrent engineering approach and integrating intelligent knowledge based systems for optimum part design of PET bottles, PET preform and moulds based on user specific requirements. The work is expected to provide a highly efficient environment able to design and produce a new PET bottle economically and quickly with maximum functional performance.Read moreRead less
Laser-based dynamic measurements, model identification and error compensation for multi-arm robotic pre-fabrication of structural components. The aim is to establish methodologies for laser-based dynamic measurements, accurate model identification and error correction in multi-arm cooperative robotic manipulation systems. The expected outcomes include development of enabling technologies and the world's first automated fabrication system for structural timber components. The novel methodologi ....Laser-based dynamic measurements, model identification and error compensation for multi-arm robotic pre-fabrication of structural components. The aim is to establish methodologies for laser-based dynamic measurements, accurate model identification and error correction in multi-arm cooperative robotic manipulation systems. The expected outcomes include development of enabling technologies and the world's first automated fabrication system for structural timber components. The novel methodologies established will increase safety, and improve and automate the fabrication of wall frames, roof trusses, and floor and ceiling panels for housing, industrial and commercial projects within Australia and overseas. Other application areas include multi-arm manufacturing and handling of large components, materials handling in hazardous environments, and robotic servicing tasks in remote places.Read moreRead less
A Stress Transfer Principle for Carbon Nanotube Reinforced Materials under Complex Loading. Many breakthrough technologies in the future will build upon carbon nanotube reinforced materials but the scientific basis in the area is still unavailable. This project aims to establish a reliable stress transfer principle so that the design, production and application of the materials can be accurately controlled and the great strength of carbon nanotubes can be wisely utilized. The research will resol ....A Stress Transfer Principle for Carbon Nanotube Reinforced Materials under Complex Loading. Many breakthrough technologies in the future will build upon carbon nanotube reinforced materials but the scientific basis in the area is still unavailable. This project aims to establish a reliable stress transfer principle so that the design, production and application of the materials can be accurately controlled and the great strength of carbon nanotubes can be wisely utilized. The research will resolve a key paradox and develop a series of innovative theories and technologies. The success of the project will make a significant impact on the nanoscience and nanotechnology associated with the applications of carbon nanotube reinforced materials.Read moreRead less
Solar Paint: Models and Mechanisms. Organic photovoltaics (OPVs) offer the tantalising prospect of renewable solar energy from low cost flexible printed coatings. However, several key scientific obstacles must be overcome before such devices become a commercial reality. In particular, nanoscale organisation of the active materials and their deposition from benign solvents must be achieved. This project will tackle the fundamental science required to print large area devices using water-based sol ....Solar Paint: Models and Mechanisms. Organic photovoltaics (OPVs) offer the tantalising prospect of renewable solar energy from low cost flexible printed coatings. However, several key scientific obstacles must be overcome before such devices become a commercial reality. In particular, nanoscale organisation of the active materials and their deposition from benign solvents must be achieved. This project will tackle the fundamental science required to print large area devices using water-based solar paint. These exciting new materials offer the possibility of both controlling nanoscale architecture and allowing large scale OPV production via simple, well established printing techniques, thus providing the first step towards the creation of an Australian OPV industry.Read moreRead less
Machining-induced damage mechanisms in KDP crystals. This project aims to produce damage-free potassium dihydrogen phosphate (KDP) crystals. How machining-induced damage reduces these crystals’ property thresholds is unclear, which hinders the development of high performance devices relying on KDP. This project will use multi-scale modelling and in-situ experiments to research machining-induced damage in KDP. This project is expected to establish a knowledge base of machining-induced damage of K ....Machining-induced damage mechanisms in KDP crystals. This project aims to produce damage-free potassium dihydrogen phosphate (KDP) crystals. How machining-induced damage reduces these crystals’ property thresholds is unclear, which hinders the development of high performance devices relying on KDP. This project will use multi-scale modelling and in-situ experiments to research machining-induced damage in KDP. This project is expected to establish a knowledge base of machining-induced damage of KDP crystals, important for high performance systems and materials sensitive to environmental conditions, including moisture and temperature.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
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.
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