Discovery Early Career Researcher Award - Grant ID: DE180100688
Funder
Australian Research Council
Funding Amount
$336,446.00
Summary
Nanosensors in artificial cochlea for natural hearing. This project aims to develop a miniaturised and implantable cochlear that closely mimics the human auditory system by utilising advanced microfabrication techniques. This project expects to generate new knowledge in engineering hearing and vestibular hair cells and also on tonotopic organisation of cochlear. Expected outcomes include study of auditory hair cells and development of implantable ear-on-a-chip devices. This project is expected t ....Nanosensors in artificial cochlea for natural hearing. This project aims to develop a miniaturised and implantable cochlear that closely mimics the human auditory system by utilising advanced microfabrication techniques. This project expects to generate new knowledge in engineering hearing and vestibular hair cells and also on tonotopic organisation of cochlear. Expected outcomes include study of auditory hair cells and development of implantable ear-on-a-chip devices. This project is expected to enable low-cost production of highly engineered implant cochlear with great potential for commercialisation.Read moreRead less
High precision material processing using ultrashort laser pulses at MHz repetition rates. The continual miniaturisation of mechanical and electronic components for biomedical, aerospace and industrial products is driving the demand for advanced fabrication techniques. Femtosecond laser micromachining in particular is emerging as a critical manufacturing process for these components and other new and unprecedented applications.
The project will build up strong links between the Photonics Institu ....High precision material processing using ultrashort laser pulses at MHz repetition rates. The continual miniaturisation of mechanical and electronic components for biomedical, aerospace and industrial products is driving the demand for advanced fabrication techniques. Femtosecond laser micromachining in particular is emerging as a critical manufacturing process for these components and other new and unprecedented applications.
The project will build up strong links between the Photonics Institute in Vienna, Austria, which is noted for their achievements in the development of femtosecond light sources, and the CLA, which has an excellent reputation for its expert knowledge in laser material processing. It is therefore believed to be beneficial for research in both countries.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0346666
Funder
Australian Research Council
Funding Amount
$260,000.00
Summary
Mobile high power diode laser for thermal processing applications. This proposal seeks to establish a mobile, high-power diode laser facility for thermal processing of in-situ components in the power generation, defence, shipbuilding and mining industries. Diode lasers offer significant advantages for laser thermal processing over conventional CO2 and Nd:YAG lasers in terms of their output wavelength, size and efficiency. The mobile high power diode laser facility will help build a strong infr ....Mobile high power diode laser for thermal processing applications. This proposal seeks to establish a mobile, high-power diode laser facility for thermal processing of in-situ components in the power generation, defence, shipbuilding and mining industries. Diode lasers offer significant advantages for laser thermal processing over conventional CO2 and Nd:YAG lasers in terms of their output wavelength, size and efficiency. The mobile high power diode laser facility will help build a strong infrastructure for in-situ repair of worn components and is expected to reduce overall component repair costs and time.Read moreRead less
Process models and control strategies for abrasive waterjet precision cutting of amorphous magnetic metal parts for energy efficient electrical machines. Amorphous magnetic metal (AMM) is the most energy-efficient material for electrical machines and can save more than 36% of the energy wasted by an electrical motor using an ordinary core material. Since electrical motors consume about 70% of all the electricity generated, energy saving of approximately $900 million annually in electricity bills ....Process models and control strategies for abrasive waterjet precision cutting of amorphous magnetic metal parts for energy efficient electrical machines. Amorphous magnetic metal (AMM) is the most energy-efficient material for electrical machines and can save more than 36% of the energy wasted by an electrical motor using an ordinary core material. Since electrical motors consume about 70% of all the electricity generated, energy saving of approximately $900 million annually in electricity bills, and an annual reduction of 2.5 million tonnes of greenhouse gas emissions in Australia are expected. This project will develop a unique technology able to cut AMM to the required quality and productivity. It targets the national research priorities in Frontier Technologies and An Environmentally Sustainable Australia. Read moreRead less
Modelling the cutting process and cutting performance in contour and multipass abrasive waterjet machining. This project will develop important new cutting techniques to increase the cutting capability and application domain of the abrasive waterjet (AWJ) cutting technology. It will gain a fundamental understanding of the cutting phenomenon and develop new mathematical models for predicting the cutting performance in AWJ contouring and multipass cutting. This project will further develop into a ....Modelling the cutting process and cutting performance in contour and multipass abrasive waterjet machining. This project will develop important new cutting techniques to increase the cutting capability and application domain of the abrasive waterjet (AWJ) cutting technology. It will gain a fundamental understanding of the cutting phenomenon and develop new mathematical models for predicting the cutting performance in AWJ contouring and multipass cutting. This project will further develop into a new branch of manufacturing science by uncovering the cutting mechanisms in AWJ machining with and without nozzle oscillation, and have significant impact to the manufacturing industry by providing machining information and cutting performance models to increase the technological and economic performance of AWJ machining.Read moreRead less
Development of micro abrasive water jetting technology for micro machining and polishing on small complex curved surfaces. The fabrication of micro-parts such as those used in integrated sensors and micro-actuators is a new challenge for the rapid development of this industry. Many existing technologies either find limitations or result in defects on the machined surfaces. This project will develop an innovative abrasive water-jetting technology for micro machining and polishing. It will deve ....Development of micro abrasive water jetting technology for micro machining and polishing on small complex curved surfaces. The fabrication of micro-parts such as those used in integrated sensors and micro-actuators is a new challenge for the rapid development of this industry. Many existing technologies either find limitations or result in defects on the machined surfaces. This project will develop an innovative abrasive water-jetting technology for micro machining and polishing. It will develop the fundamentals and prototype for further development by industry. New nozzle designs will be analyzed and optimized by computational fluid dynamics studies and experimental investigations using a Particle Image Velocimeter. Mathematical models for the processing performance will also be developed for use in process control.Read moreRead less
Modelling the jet characteristics and process performance for abrasive waterjet micro-machining. This project will develop a new manufacturing science and technology for micro-machining using a micro-abrasive waterjet. The new technology will provide an effective means for micro-cutting, etching and super-finish polishing on various micro-parts, particularly for advanced materials such as ceramics and glasses that are being increasingly used by industry while other technologies either experience ....Modelling the jet characteristics and process performance for abrasive waterjet micro-machining. This project will develop a new manufacturing science and technology for micro-machining using a micro-abrasive waterjet. The new technology will provide an effective means for micro-cutting, etching and super-finish polishing on various micro-parts, particularly for advanced materials such as ceramics and glasses that are being increasingly used by industry while other technologies either experience difficulties or result in defects in processing them. This technology will increase the capacity of the Australian manufacturing industry to exploit new leading technologies and products.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC200100001
Funder
Australian Research Council
Funding Amount
$4,879,415.00
Summary
ARC Training Centre for Collaborative Robotics in Advanced Manufacturing. The Centre aims to build the human and technical capability Australia needs to underpin our global competitiveness in advanced manufacturing. The Centre will unite manufacturing businesses, including SMEs, and universities to develop collaborative robotics applications which combine the strengths of humans and robots in shared work environments. The Centre will train researchers, engineers, technologists and manufacturing ....ARC Training Centre for Collaborative Robotics in Advanced Manufacturing. The Centre aims to build the human and technical capability Australia needs to underpin our global competitiveness in advanced manufacturing. The Centre will unite manufacturing businesses, including SMEs, and universities to develop collaborative robotics applications which combine the strengths of humans and robots in shared work environments. The Centre will train researchers, engineers, technologists and manufacturing leaders with the expertise industry needs to boost safety, quality assurance, production efficiency, and workforce readiness. The intended outcome is to support Australian manufacturers to shift toward higher-potential markets, compete globally and attract and retain a digitally-capable workforce for the future.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