Properties and Characterisation of Magneto-Rheological Materials under Rotating Magnetic Field Excitation. Through the proposed theoretical and experimental studies, new electro-magneto-mechanical phenomena of the MR materials under various vectorial magnetisations will be observed. Based on the in-depth understanding of the complex vectorial magneto-rheological mechanisms, an accurate coupled model will be developed for design and analysis of novel dampers. These outcomes will greatly enhance t ....Properties and Characterisation of Magneto-Rheological Materials under Rotating Magnetic Field Excitation. Through the proposed theoretical and experimental studies, new electro-magneto-mechanical phenomena of the MR materials under various vectorial magnetisations will be observed. Based on the in-depth understanding of the complex vectorial magneto-rheological mechanisms, an accurate coupled model will be developed for design and analysis of novel dampers. These outcomes will greatly enhance the design capacity of Australian industry in smart structures, i.e. using novel dampers to reduce harmful vibrations and protect people in vehicles, buildings, and bridges. This will help Australians to live in a safer and healthier environment, and could save billions of dollars per year nationwide for treatment, recovery, and insurance claims.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100109
Funder
Australian Research Council
Funding Amount
$240,000.00
Summary
Raman Spectroscopic System for In-Operando Electrochemical Studies. This proposal aims to establish a Raman microscopic system with real-time tracking capability, which will allow investigation of the activities of battery components during charging. An instrument that allows this level of interrogation is currently not available in Australia. Expected outcomes include advanced knowledge for improved battery technology, which will meet the increasing demand of electronic applications and provide ....Raman Spectroscopic System for In-Operando Electrochemical Studies. This proposal aims to establish a Raman microscopic system with real-time tracking capability, which will allow investigation of the activities of battery components during charging. An instrument that allows this level of interrogation is currently not available in Australia. Expected outcomes include advanced knowledge for improved battery technology, which will meet the increasing demand of electronic applications and provide commercial opportunities in Australia. This system will be highly versatile and extendable to other fields of energy and materials-related research, providing high-quality training of researchers, as well as a platform from which to enhance materials research capabilities in Australia.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL160100089
Funder
Australian Research Council
Funding Amount
$2,600,796.00
Summary
In situ electron microscopy toward new materials and applications. In situ electron microscopy toward new materials and applications. This project aims to develop materials for structural and green energy applications, using spatially-resolved, dynamic in situ transmission electron microscopy to research fundamental mechanical, electrical, thermal, optical, optoelectronic and photovoltaic properties of diverse nanostructures. These techniques measure nanomaterial (one-dimensional nanotubes and n ....In situ electron microscopy toward new materials and applications. In situ electron microscopy toward new materials and applications. This project aims to develop materials for structural and green energy applications, using spatially-resolved, dynamic in situ transmission electron microscopy to research fundamental mechanical, electrical, thermal, optical, optoelectronic and photovoltaic properties of diverse nanostructures. These techniques measure nanomaterial (one-dimensional nanotubes and nanowires and two-dimensional graphene-like nanosheets) response to external stimuli, including mechanical, electrical, optical and thermal stimuli. Anticipated outcomes are new ultralight and superstrong structural composites and ‘green-energy’ nanomaterials, such as solar cells, touch panels, batteries, supercapacitors, field-effect transistors, light sensors and displays.Read moreRead less
Hermetic encapsulated perovskite solar cells for energy harvesting glazings. This project aims is to develop fully hermetic, vacuum encapsulation for perovskite solar cells as energy harvesting glazing systems in buildings with high thermal insulation. This glazing system should simultaneously mitigate heat gain in summer and heat loss in winter, control the entry of light, and generate electric power. This project seeks to develop a new advanced glass encapsulation method with electrical feedth ....Hermetic encapsulated perovskite solar cells for energy harvesting glazings. This project aims is to develop fully hermetic, vacuum encapsulation for perovskite solar cells as energy harvesting glazing systems in buildings with high thermal insulation. This glazing system should simultaneously mitigate heat gain in summer and heat loss in winter, control the entry of light, and generate electric power. This project seeks to develop a new advanced glass encapsulation method with electrical feedthroughs that is fully compatible with perovskite solar cells. It should revolutionise the architectural glazing market with a new generation product with unprecedented electrical power generation capacity and a simultaneous increase in thermal insulation to provide the ultimate energy solution for future cities. An expected outcome from this project is a range of new products to expand the solar market beyond roof-top applications and solar farms.Read moreRead less
Biological pattern generator for control and optimization of locomotion systems. This proposal exploits the interdisciplinary nature of systems and control area and incorporates biology science. It is expected to generate a synergy between biology science and control engineering and to advance scientific understanding in both fields. The proposed research will have impact on new innovations in a variety of fields. This will bring economic benefits for Australia. It will help to develop engineers ....Biological pattern generator for control and optimization of locomotion systems. This proposal exploits the interdisciplinary nature of systems and control area and incorporates biology science. It is expected to generate a synergy between biology science and control engineering and to advance scientific understanding in both fields. The proposed research will have impact on new innovations in a variety of fields. This will bring economic benefits for Australia. It will help to develop engineers for industry who have team-oriented problem-solving skills in a multidisciplinary working environment. It will also stimulate students' intellectual curiosity into engineering and science through a series of innovative interdisciplinary research/educational activities.Read moreRead less
Reducing Blackout Risk through Live Modelling and Monitoring. This project aims to reduce the risk of blackouts through the development of on-line systems for modelling and monitoring of loads and power system controllers. This project is a collaboration with Transgrid, Powerlink, Vencorp and ElectraNetSA, four Transmission companies renowned for innovation in the area of system stability. The project proposes to develop innovative algorithms and to implement these algorithms using advanced hard ....Reducing Blackout Risk through Live Modelling and Monitoring. This project aims to reduce the risk of blackouts through the development of on-line systems for modelling and monitoring of loads and power system controllers. This project is a collaboration with Transgrid, Powerlink, Vencorp and ElectraNetSA, four Transmission companies renowned for innovation in the area of system stability. The project proposes to develop innovative algorithms and to implement these algorithms using advanced hardware, software and communication systems to dynamically generate decision tools for safe and efficient power system operating conditions. These systems will also generate alarms if any risky operational situations arise.Read moreRead less
Hot-swappable and High-efficient Grid-connected Power Electronics System For Photovoltaic Modules with Direct Power Transfer Technique. The project aims to increase the amount of available energy intake from photovoltaic panels, lengthen lifetime of power DC/AC inverter, reduce the amount of energy waste due to inefficient inverter by introducing new switching power converters with direct power transfer technique - bypassing part of the input power without repeatedly processing it, and using lon ....Hot-swappable and High-efficient Grid-connected Power Electronics System For Photovoltaic Modules with Direct Power Transfer Technique. The project aims to increase the amount of available energy intake from photovoltaic panels, lengthen lifetime of power DC/AC inverter, reduce the amount of energy waste due to inefficient inverter by introducing new switching power converters with direct power transfer technique - bypassing part of the input power without repeatedly processing it, and using long-life ceramic type capacitors. Development of this technology will mean reduced total cost, improved product lifetime and reduced global warming. It will lead to a reliable product that will help to put the Australian switching power converter industry into a leading position internationally in the design and manufacture of DC/AC inverters.Read moreRead less
Theoretical study and experimental verification of low cost, integrated and efficient AC/DC power supplies using time-multiplexing control. The project aims to reduce the amount of energy waste and cost due to inefficient AC/DC power supplies by introducing a novel power supply technique - combining conventional two-stage power circuits and using time-multiplexing control. Improvements in power supply efficiency and size will mean reduced total cost, improved product lifetime and reduced heating ....Theoretical study and experimental verification of low cost, integrated and efficient AC/DC power supplies using time-multiplexing control. The project aims to reduce the amount of energy waste and cost due to inefficient AC/DC power supplies by introducing a novel power supply technique - combining conventional two-stage power circuits and using time-multiplexing control. Improvements in power supply efficiency and size will mean reduced total cost, improved product lifetime and reduced heating up of the environment, leading to a reliable product that is particularly relevant to the Australian switching power supply industry. The development of this technology will help to put Australia into a leading position internationally in the design and manufacturing of AC/DC power supply.Read moreRead less
Advanced Future Automotive Electrical Machines based on Amorphous Iron. Electric machines consume about 70% of all electrical energy generated. Electric machines constructed from a promising magnetic material called amorphous iron can be much more efficient than conventional designs, hence saving energy. Amorphous iron is normally difficult to cut accurately into the shapes required in electric machines. We propose to design and construct high-efficiency permanent magnet machines based on amorp ....Advanced Future Automotive Electrical Machines based on Amorphous Iron. Electric machines consume about 70% of all electrical energy generated. Electric machines constructed from a promising magnetic material called amorphous iron can be much more efficient than conventional designs, hence saving energy. Amorphous iron is normally difficult to cut accurately into the shapes required in electric machines. We propose to design and construct high-efficiency permanent magnet machines based on amorphous iron for automotive applications, which will be cut using an innovative Australian waterjet cutting technique. The key challenges are to optimise the machine design for commercial production given the capabilities and limitations of the material and the new cutting process.Read moreRead less
Nanostructured Silicon-Based Tandem Solar Cells. The expected outcome from the project is a new generation of low-cost silicon solar cell that will significantly reduce the costs of generating electricity from sunlight. Solar cells are presently the world's most rapidly growing energy source, with Australians and Australian companies already major players in the associated rapidly expanding industry. Solar cells represent the most benign technology yet suggested for supplying the world's future ....Nanostructured Silicon-Based Tandem Solar Cells. The expected outcome from the project is a new generation of low-cost silicon solar cell that will significantly reduce the costs of generating electricity from sunlight. Solar cells are presently the world's most rapidly growing energy source, with Australians and Australian companies already major players in the associated rapidly expanding industry. Solar cells represent the most benign technology yet suggested for supplying the world's future energy needs. A cleaner environment in the future than would otherwise be likely is another expected outcome as is the creation of major new opportunities for Australian industry.Read moreRead less