Integration of Solar, Wind and Storage Systems into Distribution Grids for Network Support. This project will contribute to the development and utilisation of renewable energy technologies for a sustainable future and facilitate their integration into electricity grids for network support. Innovative methodologies and technologies will be developed to reduce network problems associated with the integration of a large number of small-scale renewable energy resources into distribution grids. This ....Integration of Solar, Wind and Storage Systems into Distribution Grids for Network Support. This project will contribute to the development and utilisation of renewable energy technologies for a sustainable future and facilitate their integration into electricity grids for network support. Innovative methodologies and technologies will be developed to reduce network problems associated with the integration of a large number of small-scale renewable energy resources into distribution grids. This project will also develop assessment tools to examine the impact of renewable energy penetration on power quality aspects, network stability and protection performance. This research will provide remedies for potential problems introduced by their integration and improve voltage support in the electricity networks. Read moreRead less
Integration of large capacity Superconducting Magnetic Energy Storage with Active Power Filter switching technology to achieve a complete power quality device. The aim of this project is to integrate large capacity SMES with Active Power Filter (APF) switching technology to achieve a complete power quality control device.
The expected outcomes of the research are 1) An SMES design suitable for APF integration, 2) Development and implementation of lossless energy switching technologies, 3) D ....Integration of large capacity Superconducting Magnetic Energy Storage with Active Power Filter switching technology to achieve a complete power quality device. The aim of this project is to integrate large capacity SMES with Active Power Filter (APF) switching technology to achieve a complete power quality control device.
The expected outcomes of the research are 1) An SMES design suitable for APF integration, 2) Development and implementation of lossless energy switching technologies, 3) Development of suitable APF switching algorithms, 4) An integrated design with competitive commercial analysis, and 5) A fully characterised prototype.
This project is innovative as the marriage of large capacity SMES with APF switching technology is essentially absent from the literature, and so there are high expectations for innovative applications and methodologies of fabrication.
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Beamforming with acoustic vector sensors for audio user interfaces. We aim to create new Audio User Interfaces (AUIs) for the automatic separation and annotation of audio from complex sound scenes using acoustic vector sensor beamforming technology. Specifically, we will develop: speech AUIs for noisy, multi-talker, reverberant environments; and sound transcription AUIs for the deaf. Ultimately, users will be able to walk into a room, hold conversations and leave with a searchable, automatically ....Beamforming with acoustic vector sensors for audio user interfaces. We aim to create new Audio User Interfaces (AUIs) for the automatic separation and annotation of audio from complex sound scenes using acoustic vector sensor beamforming technology. Specifically, we will develop: speech AUIs for noisy, multi-talker, reverberant environments; and sound transcription AUIs for the deaf. Ultimately, users will be able to walk into a room, hold conversations and leave with a searchable, automatically-generated transcript of the audio events, tagged with metadata. The application of these technologies will create new possibilities for recording audio in the music, radio, TV industries, and future home based audio communication systems.Read moreRead less
Encoding and Communicating Navigable Soundfields. While sound recording is commonplace, it is not currently practical to completely record a sound space such that the experience can be reproduced at a chosen 'listening point'. This is a significant restriction for audio applications in the entertainment, surveillance and virtual/mixed reality areas. The project will research novel and practical solutions to this problem and offers a significant conceptual advance in the transmission of complex a ....Encoding and Communicating Navigable Soundfields. While sound recording is commonplace, it is not currently practical to completely record a sound space such that the experience can be reproduced at a chosen 'listening point'. This is a significant restriction for audio applications in the entertainment, surveillance and virtual/mixed reality areas. The project will research novel and practical solutions to this problem and offers a significant conceptual advance in the transmission of complex audio scenes. This project will build fundamental new technology and IP for Australia in the digital media and audio space, one of the fastest growing sectors of our economy.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
Advanced inverter control for distributed energy systems. This project aims to discover innovative fundamental approaches for the control of electrical grids with a diverse and changing mix of generation sources. It will generate new knowledge in the area of electrical power system control by researching innovative and advanced inverter control techniques coupled to advanced power system models. The expected outcomes are advanced power system control techniques that remove the emerging barriers ....Advanced inverter control for distributed energy systems. This project aims to discover innovative fundamental approaches for the control of electrical grids with a diverse and changing mix of generation sources. It will generate new knowledge in the area of electrical power system control by researching innovative and advanced inverter control techniques coupled to advanced power system models. The expected outcomes are advanced power system control techniques that remove the emerging barriers to increased penetrations of distributed generation and energy storage. The benefit of the research includes an Australian-developed solution to many of the difficulties faced by grid operators around the world in incorporating increased renewable generation and energy storage in their power systems.Read moreRead less
Sustainable operation of transformers with better understanding of technical and economic constraints. Transformer failure can be devastating to consumers and network service providers, costing from thousands to millions of dollars in transformer replacement and lost productivity. To avoid such catastrophic failures, the goal of this project will be to develop new methods that can maximise transformer usage and minimise cost before failure occurs.
Medium voltage DC: Enabling active, flexible and efficient power networks. Medium voltage DC (MVDC) systems promise to offer the required flexibility in next generation active electricity networks to enable higher renewable energy integration, take advantage of more readily available energy storage, and manifest simpler control and operation. The intended outcome of the Project is to address the challenge of developing MVDC networks via an integrated and cohesive approach, from the initial desig ....Medium voltage DC: Enabling active, flexible and efficient power networks. Medium voltage DC (MVDC) systems promise to offer the required flexibility in next generation active electricity networks to enable higher renewable energy integration, take advantage of more readily available energy storage, and manifest simpler control and operation. The intended outcome of the Project is to address the challenge of developing MVDC networks via an integrated and cohesive approach, from the initial design of the individual power electronics converters, right up to network design and "system of systems" implementation. The outcomes of the Project will provide clear pathways and solutions for new topologies, facilitating Australia’s and the world’s transition to next generation electricity infrastructure.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC210100021
Funder
Australian Research Council
Funding Amount
$5,000,000.00
Summary
ARC Training Centre in Energy Technologies for Future Grids. The proposed Future Grids Training Centre will advance Australia’s transition to a clean energy future. It will address the complex and challenging issues currently limiting the growth of renewable energy through innovations that facilitate widespread integration of these resources into electricity grids while maintaining grid stability. The Centre will deliver the next generation of industry leaders and specialists in future grid tech ....ARC Training Centre in Energy Technologies for Future Grids. The proposed Future Grids Training Centre will advance Australia’s transition to a clean energy future. It will address the complex and challenging issues currently limiting the growth of renewable energy through innovations that facilitate widespread integration of these resources into electricity grids while maintaining grid stability. The Centre will deliver the next generation of industry leaders and specialists in future grid technologies for renewable energy generation, transmission and distribution, supported by renewable hydrogen energy storage and market driven customer responsiveness enabled by new information and communications technologies, to provide a more sustainable, reliable, secure and affordable electricity system.Read moreRead less
Charge transfer kinetics at nanostructured semiconductor surfaces. This project aims to enhance understanding of the interface science associated with charge-transfer reactions at nanostructured semiconductor surfaces. Experimental and modelling approaches will be used to unravel the contributions of surface wetting and nanostructure geometry to the kinetics of charge transfer reactions at the surfaces. Expected outcomes include an enhanced capacity to engineer nanostructured semiconductor surf ....Charge transfer kinetics at nanostructured semiconductor surfaces. This project aims to enhance understanding of the interface science associated with charge-transfer reactions at nanostructured semiconductor surfaces. Experimental and modelling approaches will be used to unravel the contributions of surface wetting and nanostructure geometry to the kinetics of charge transfer reactions at the surfaces. Expected outcomes include an enhanced capacity to engineer nanostructured semiconductor surfaces for designed functionality and an extended collaborative network which can collectively address significant problems in energy science. It is anticipated that these outcomes will be realised in reliable, low-cost metallisation for silicon photovoltaics and increased power densities for electrochemical storage systems.Read moreRead less