Solid state regulation of a distribution transformer to rapidly control voltages of low voltage distribution feeders. High penetration of domestic photovoltaic generation creates substantial voltage fluctuations along the electrical supply system. This project will explore how to use solid state electronics to create distribution transformers with advanced capability that can regulate these voltage fluctuations better than present technologies.
Customer Responsive Risk-Managed Network Planning. The aim of this project is to reduce the cost of network delivery of electricity though a reduced network build. The cost of the network is balanced against the cost of reliability of supply. The key developments are optimisation of investment considering batteries etcetera, combined with customer load response and explicit inclusion of the uncertainties of load growth and in the response level of the customer loads. The project combines skills ....Customer Responsive Risk-Managed Network Planning. The aim of this project is to reduce the cost of network delivery of electricity though a reduced network build. The cost of the network is balanced against the cost of reliability of supply. The key developments are optimisation of investment considering batteries etcetera, combined with customer load response and explicit inclusion of the uncertainties of load growth and in the response level of the customer loads. The project combines skills of power engineering optimisation, software systems and social science. Most of the demand response programs globally have focused on a pure economic incentive for variation of customer load. This project aims to make use of recent findings on the benefits of combining community engagement with the incentives.Read moreRead less
Optimising experimental design for robust product development: a case study for high-efficiency energy generation. This project tackles key mathematical challenges to provide a powerful new methodology and tool for optimal product design, making smarter use of limited information, minimising costly trials, shortening the product cycle, and boosting the competitiveness of both the Australian manufacturing and alternative energy production industries.
The impact of the mass-adoption of electric cars on the Australian electricity grid. This project represents the first technical study in Australia into the impact on the electric utility system of the mass adoption of electric vehicles. At present, road transport accounts for 12 per cent of greenhouse gas (GHG) emissions in Australia. The mass adoption of electric vehicles could reduce GHG in transport by up to 24 per cent when charged from the current grid or by 100 per cent if using renewable ....The impact of the mass-adoption of electric cars on the Australian electricity grid. This project represents the first technical study in Australia into the impact on the electric utility system of the mass adoption of electric vehicles. At present, road transport accounts for 12 per cent of greenhouse gas (GHG) emissions in Australia. The mass adoption of electric vehicles could reduce GHG in transport by up to 24 per cent when charged from the current grid or by 100 per cent if using renewable power. As well as receiving environmental advantages, Australia will benefit from this project through: (1) advancements in the management of the electricity distribution system by the development of a smart grid; (2) the development of principles for the placement of charging stations suitable for unique local conditions, such as Australia's long distances.Read moreRead less
Electricity demand side management: models, optimisation and customer engagement. This project will develop methods for management of electricity demand, meeting both customer expectations and electricity network needs. Implementation of these demand-side management methodologies will significantly reduce the need for expenditure on electricity network upgrades and improve the value proposition for distributed renewable energy.
Regulation of the Cell Bus Voltages of Large Scale Modular Multilevel Converters: Advanced Energy Converters for Future Electricity Grids. Large scale power electronic converters are essential to the emerging “Smart Grid” electrical distribution networks, using large numbers of cascaded cells to operate at the very high voltages that are required for direct grid connection. At present, the fundamental factors that drive the fluctuations of the cell DC link voltages, including in particular the c ....Regulation of the Cell Bus Voltages of Large Scale Modular Multilevel Converters: Advanced Energy Converters for Future Electricity Grids. Large scale power electronic converters are essential to the emerging “Smart Grid” electrical distribution networks, using large numbers of cascaded cells to operate at the very high voltages that are required for direct grid connection. At present, the fundamental factors that drive the fluctuations of the cell DC link voltages, including in particular the complex non-linear interactions caused by the physical cell switching processes, are very poorly understood. This project will use a new harmonic analysis strategy to investigate the basic engineering science that underpins this voltage fluctuation phenomena, to achieve a quantum step in the understanding of the fundamental operating processes of large scale cascaded converters.Read moreRead less
Advanced analytics utilising conjoint mining of data and content with applications in business, bio-medicine and electrical power systems. This project will provide techniques that enable effective analysis of unstructured content and related information from relational databases in a conjoint manner. These techniques will be applied in the business, bio-medicine and electrical power systems domains.
Piezoelectric nanofibre membranes with built-in p-n junction: new self-rectifying piezoelectric power generators. This project will aim to develop new knowledge about how to efficiently convert small mechanical energy into directly usable electric power using piezoelectric nanofibre membranes and will fill this knowledge gap by systematically understanding the influence of doping agents on the charge transport during energy conversion.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100141
Funder
Australian Research Council
Funding Amount
$326,367.00
Summary
Thermo-gravimetric infra-red imaging system for functional materials study. This proposal seeks to establish a multi-functional system for investigating surface, interface, and thermal properties of functional materials. The instrumentation features thermo-gravimetric, infra-red imaging hyphenated with gas-chromatography-mass spectrometry. The expected benefits are an enhanced research capability in solid-electrolyte-interphase and electrolyte decomposition on electrodes being used in alkaline-i ....Thermo-gravimetric infra-red imaging system for functional materials study. This proposal seeks to establish a multi-functional system for investigating surface, interface, and thermal properties of functional materials. The instrumentation features thermo-gravimetric, infra-red imaging hyphenated with gas-chromatography-mass spectrometry. The expected benefits are an enhanced research capability in solid-electrolyte-interphase and electrolyte decomposition on electrodes being used in alkaline-ion batteries, which could potentially pose risks during manufacturing and application. The system will not only facilitate high-quality research and impact the training of young researchers, but also provide a platform from which to enhance Australian materials research capabilities.Read moreRead less
Novel fuel-cell structures based on electroactive polymers. This project will tackle some of the challenges currently hindering progression of our society into a post-petroleum era via materials developments that will lead to in-expensive, more efficient fuel cell technologies. Specifically, a new class of organic catalysts and novel ion conducting membranes will be integrated into functional fuel-cells.