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Future Distribution Grids based on Reconfigurable Smart Microgrid Clusters. This aims of the project are to develop innovative paradigm shifting concepts in which power distributions grids will be self sufficient to look after themselves in the absence of power transmission infrastructure. It is expected that in future several renewable energy based distributed generators (DGs) will be dotted in power distribution systems. It is estimated that within another couple of decades sufficient number o ....Future Distribution Grids based on Reconfigurable Smart Microgrid Clusters. This aims of the project are to develop innovative paradigm shifting concepts in which power distributions grids will be self sufficient to look after themselves in the absence of power transmission infrastructure. It is expected that in future several renewable energy based distributed generators (DGs) will be dotted in power distribution systems. It is estimated that within another couple of decades sufficient number of DGs will be placed in networks so much so that they will be able to meet the load demand of domestic and commercial customers. Therefore the focus of this project is to find innovative approaches in which several microgrids, equipped with single-phase and three-phase DGs can work cohesively while supporting each other.Read moreRead less
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
Parallel operating stand-alone renewable energy microgrids for remote area power systems. This project aims to develop a remote area power supply that minimises the use of diesel in meeting the energy needs of remote communities and mining camps. Based on the concept of parallel operating AC-DC hybrid microgrids supplied by renewable energy sources, backed up by advanced battery energy storage and high-efficiency variable speed diesel engine, the project proposes to design and develop power syst ....Parallel operating stand-alone renewable energy microgrids for remote area power systems. This project aims to develop a remote area power supply that minimises the use of diesel in meeting the energy needs of remote communities and mining camps. Based on the concept of parallel operating AC-DC hybrid microgrids supplied by renewable energy sources, backed up by advanced battery energy storage and high-efficiency variable speed diesel engine, the project proposes to design and develop power system components and their control, protection and communication methods.Read moreRead less
Synthetic storage for improving flexibility and security of micro-grids. This project aims to remove the need for energy storage in micro-grids via adoption of synthetic storage. Micro-grids encounter high renewable energy penetrations early, given their small size. Typically, micro-grid variability is managed with technologies such as energy storage. Synthetic storage involves replacing fixed speed diesel assets with variable speed diesel technology. This project offers a cost-effective way to ....Synthetic storage for improving flexibility and security of micro-grids. This project aims to remove the need for energy storage in micro-grids via adoption of synthetic storage. Micro-grids encounter high renewable energy penetrations early, given their small size. Typically, micro-grid variability is managed with technologies such as energy storage. Synthetic storage involves replacing fixed speed diesel assets with variable speed diesel technology. This project offers a cost-effective way to improve renewable penetration and reduce diesel fuel consumption in micro-grids by removing the need for expensive energy storage. The expected project outcomes include reductions in cost and complexity for high renewable energy penetration micro-grids, reduced emissions and improved micro-grid reliability.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.
No load diesel application in remote power systems. No load diesel application in remote power systems. This project aims to investigate and optimise no-load diesel application within remote area renewable hybrid power systems. While hundreds of remote Australian communities rely on expensive diesel for power generation, this project intends to increase penetration of alternative renewable sources into remote and isolated power systems. Using dual thermodynamic and electrical modelling, this pro ....No load diesel application in remote power systems. No load diesel application in remote power systems. This project aims to investigate and optimise no-load diesel application within remote area renewable hybrid power systems. While hundreds of remote Australian communities rely on expensive diesel for power generation, this project intends to increase penetration of alternative renewable sources into remote and isolated power systems. Using dual thermodynamic and electrical modelling, this project will investigate low to no-load diesel threshold capability, reducing diesel consumption at minimal costs. The project is expected to return immediate benefits to remote mining, defence and tourism based communities, providing a pathway to reduced diesel usage and increased renewable penetration.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
Control and communications for high value distributed electrical storage. The project aims to develop a new framework to support the successful deployment of resilient ‘prosumer-based’ energy systems. The increasing deployment of new energy technologies, such as solar photovoltaics, wind turbines, and battery and other energy storages, challenges the current operating regimes of energy systems. The successful and active participation of prosumers, who are both producers and consumers of energy, ....Control and communications for high value distributed electrical storage. The project aims to develop a new framework to support the successful deployment of resilient ‘prosumer-based’ energy systems. The increasing deployment of new energy technologies, such as solar photovoltaics, wind turbines, and battery and other energy storages, challenges the current operating regimes of energy systems. The successful and active participation of prosumers, who are both producers and consumers of energy, becomes a critical issue in the operation and management of such systems. The proposed framework explores ways to integrate new technology into existing systems, focusing on new methods of energy management with interactions with millions of devices and storage units, and real-time communications to devices.Read moreRead less
Advanced Microgrids for Residential, Commercial and Industry Buildings. The project aims to develop and commercialise an Advanced Microgrid Energy-Management System (AM-EMS) to enhance the energy efficiency of residential, commercial and industry buildings. It will allow the industry partner to integrate their existing products in AM-EMS with maximum returns. The intended outcome of the project is an AM-EMS with optimised energy scheduling and distribution, incorporating renewable energy sources ....Advanced Microgrids for Residential, Commercial and Industry Buildings. The project aims to develop and commercialise an Advanced Microgrid Energy-Management System (AM-EMS) to enhance the energy efficiency of residential, commercial and industry buildings. It will allow the industry partner to integrate their existing products in AM-EMS with maximum returns. The intended outcome of the project is an AM-EMS with optimised energy scheduling and distribution, incorporating renewable energy sources and battery storage systems. End-users will benefit from reduced energy costs, improved energy efficiency and reliability, with the added benefit of new and innovative clean energy technology. The research community will benefit from new knowledge that will underpin international improvements in energy efficiency.Read moreRead less