Microstructure effect on energy harvesting ability of electrospun fibres. This project aims to provide new knowledge about how to manipulate the energy harvesting ability of electrospun fibrous mats by changing the fibre structure, components and mat configuration. Expected outcomes of the project are new fibrous materials capable of efficiently converting small mechanical forces and sounds into electricity. These high performance energy harvesting fibres will be useful for developing new power ....Microstructure effect on energy harvesting ability of electrospun fibres. This project aims to provide new knowledge about how to manipulate the energy harvesting ability of electrospun fibrous mats by changing the fibre structure, components and mat configuration. Expected outcomes of the project are new fibrous materials capable of efficiently converting small mechanical forces and sounds into electricity. These high performance energy harvesting fibres will be useful for developing new power supplies, self-powered electronics, self-sustainable sensor networks and electronic textiles.Read moreRead less
Fibre-sized energy generators and storage in multi-functional fabrics. This project proposes to do away with conventional batteries for powering portable or wearable devices by developing wearable fabrics capable of energy generation. The outcome will be a robust fabric with the capability of powering wearable or portable devices in the communications, health-care, sports and defence industries.
High Temperature, Piezoelectric Polymer Membranes. This project aims to acquire new knowledge about the preparation of flexible polymer membranes that can convert mechanical energy into electricity (“piezoelectric” conversion) stably at high temperature (e.g. 200-500 °C). This will solve the current problem where only inorganic ceramic materials can be used for high-temperature piezoelectric conversion. The expected outcomes include a new approach to prepare polymer membranes capable of high-tem ....High Temperature, Piezoelectric Polymer Membranes. This project aims to acquire new knowledge about the preparation of flexible polymer membranes that can convert mechanical energy into electricity (“piezoelectric” conversion) stably at high temperature (e.g. 200-500 °C). This will solve the current problem where only inorganic ceramic materials can be used for high-temperature piezoelectric conversion. The expected outcomes include a new approach to prepare polymer membranes capable of high-temperature piezoelectric conversion using an electrostatic spinning technology. The new breakthrough materials will not only enhance performance and reliability at high temperature, but also offer novel applications in diverse fields such as “smart” protective clothing for firefighters. Read moreRead less
Self-powered active noise control via a nanofibre acoustoelectric converter. This project aims to investigate a new, active noise control system that can eliminate low frequency noise without the use of external electricity. This project will generate new knowledge about how to realise self-powering on active noise controllers using piezoelectric nanofibres as sound detector and power generator. Expected outcomes include an effective method to produce this novel noise controller and a systemic u ....Self-powered active noise control via a nanofibre acoustoelectric converter. This project aims to investigate a new, active noise control system that can eliminate low frequency noise without the use of external electricity. This project will generate new knowledge about how to realise self-powering on active noise controllers using piezoelectric nanofibres as sound detector and power generator. Expected outcomes include an effective method to produce this novel noise controller and a systemic understanding about materials, devices and performance. This will significantly benefit development of advanced noise controlling technology and products, benefiting industry and the environment.Read moreRead less
Reinforcement of rubber products using nanostructured carbon materials. Reinforcement of rubber products using nanostructured carbon materials. This project aims to use the surface-functionalized nanostructured carbons as fillers to reinforce natural rubber. These fillers should significantly enhance the cross-linking between carbon and rubber matrix, leading to high-performance composite products with long lifetime, high thermal conductivity, high oil resistance and outstanding dynamic behaviou ....Reinforcement of rubber products using nanostructured carbon materials. Reinforcement of rubber products using nanostructured carbon materials. This project aims to use the surface-functionalized nanostructured carbons as fillers to reinforce natural rubber. These fillers should significantly enhance the cross-linking between carbon and rubber matrix, leading to high-performance composite products with long lifetime, high thermal conductivity, high oil resistance and outstanding dynamic behaviours. This project is expected to make Australia capable of fabricating superior rubber-based materials and devices that are comfortable, quiet and energy efficient, for use in aircrafts, automobiles and vessels. It should also reduce the use of non-degradable rubber materials, promoting Australia’s economic development and environment protection.Read moreRead less
Electrically conductive elastomeric composites by nanomaterials. Electrically conductive elastomeric composites by nanomaterials. This project aims to develop electrically conductive, mechanically robust, cost-effective elastomeric composites, by exploring new processing methods and studying the synergy between graphene sheets and multi-walled carbon nanotubes. Composites will be design, research and manufactured to suit the fabrication of rolling-resistance sensors that detect early-stage malfu ....Electrically conductive elastomeric composites by nanomaterials. Electrically conductive elastomeric composites by nanomaterials. This project aims to develop electrically conductive, mechanically robust, cost-effective elastomeric composites, by exploring new processing methods and studying the synergy between graphene sheets and multi-walled carbon nanotubes. Composites will be design, research and manufactured to suit the fabrication of rolling-resistance sensors that detect early-stage malfunctioning idler rolls. This technology could prevent the breakage of conveyor belts which are essential to the mining, processing and transportation of loose bulk materials; and improve the design and manufacturing of flexible sensors.Read moreRead less
Elastomer/Graphene Composites for Reinforcement at Low Strain. This project aims to develop new elastomer/graphene composites by designing and fabricating graphene precursors which can transform into graphene sheets during melt compounding with elastomers. These sheets have tunable surface affinity with elastomers, to attain expected dispersion in elastomers for effective reinforcement at low strain. The dominant filler in industry – carbon black – is ineffective at low strain. The outcomes are ....Elastomer/Graphene Composites for Reinforcement at Low Strain. This project aims to develop new elastomer/graphene composites by designing and fabricating graphene precursors which can transform into graphene sheets during melt compounding with elastomers. These sheets have tunable surface affinity with elastomers, to attain expected dispersion in elastomers for effective reinforcement at low strain. The dominant filler in industry – carbon black – is ineffective at low strain. The outcomes are anticipated to transform the current manufacturing practice of rubber products for applications in agricultural, automobile, construction, medical and mining industries.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0211003
Funder
Australian Research Council
Funding Amount
$125,000.00
Summary
A Facility for Probing Nanostructure in Polymers. The properties of a polymer are only partly determined by its molecular structure. It is now clear that the organization of molecular structure and phase morphology on a nano-scale has an equally important role in determining material behaviour. Increasingly this can be manipulated by judicious choice of formulation and processing variables. The polymer Nano-Structure Facility will bring together Australia's principal polymer experts in this a ....A Facility for Probing Nanostructure in Polymers. The properties of a polymer are only partly determined by its molecular structure. It is now clear that the organization of molecular structure and phase morphology on a nano-scale has an equally important role in determining material behaviour. Increasingly this can be manipulated by judicious choice of formulation and processing variables. The polymer Nano-Structure Facility will bring together Australia's principal polymer experts in this area of structure-property relations and provide them with shared access to the appropriate, modern analytical tools required to probe the nano-structure of such new materials with enhanced properties.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100195
Funder
Australian Research Council
Funding Amount
$1,000,000.00
Summary
Field-emission gun transmission electron microscope for the research in nanomaterials, metal alloys and biological sciences. The proposed facility is required by a large range of world-leading research programs in light metals, nanomaterials, fibres and biomaterials. These research programs are strongly supported by automobile, textile, mineral and advanced materials industries that have important roles in the current national economy and local communities. The facility will improve significan ....Field-emission gun transmission electron microscope for the research in nanomaterials, metal alloys and biological sciences. The proposed facility is required by a large range of world-leading research programs in light metals, nanomaterials, fibres and biomaterials. These research programs are strongly supported by automobile, textile, mineral and advanced materials industries that have important roles in the current national economy and local communities. The facility will improve significantly our current research ability and help the creation of new research areas in nanotechnology and energy materials beneficial to clean energy, environmental protections and health care. It is also important equipment for new research student training.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668517
Funder
Australian Research Council
Funding Amount
$220,000.00
Summary
Hyphenated techniques in polymer science and engineering. The collaborator's research capabilities will be greatly enhanced because the equipment will allow simultaneous measurements of various properties which can provide much more information than sequential experiments. Students will be able to undertake research with state-of-the-art equipment which will enhance their research careers and employment prospects. The resulting information will be invaluable to the development of polymer blends ....Hyphenated techniques in polymer science and engineering. The collaborator's research capabilities will be greatly enhanced because the equipment will allow simultaneous measurements of various properties which can provide much more information than sequential experiments. Students will be able to undertake research with state-of-the-art equipment which will enhance their research careers and employment prospects. The resulting information will be invaluable to the development of polymer blends with optimized morphology and mechanical properties; improved polymer processing techniques linked to how the structure and orientation develops; the development of new materials, including novel human tissue implants, from studies of the rheology and phase structure of a polymer during photopolymerization.Read moreRead less