Congestion control of networks: a unified stochastic framework. Systems such as the internet, wireless networks and the power grid require efficient allocation of shared resources. This research will develop ways to reduce delays in the internet and allow for growth in the power grid, without requiring additional infrastructure.
Competitive supplier bidding in supply chains. This project will use mathematical modelling to contribute to better management practice in dealing with procurement. With the increasing use of auctions and sophisticated bidding procedures it is essential to improve our understanding of this important area.
Multipoint voltage sensor for high power distribution lines. This project will develop a new electric field sensor array for electricity transmission systems. The project proposes novel sensor designs based on hybrid technology; fibre optics and liquid crystals. Investment in student and researcher training will provide the industry, still in its early growth phase, with future human resources and strengthen research and development programs. The outcomes of this project will benefit our Austr ....Multipoint voltage sensor for high power distribution lines. This project will develop a new electric field sensor array for electricity transmission systems. The project proposes novel sensor designs based on hybrid technology; fibre optics and liquid crystals. Investment in student and researcher training will provide the industry, still in its early growth phase, with future human resources and strengthen research and development programs. The outcomes of this project will benefit our Australian-based Partner Organisation, Smart Digital Optics PTY LTD and will also increase Australian research expertise in the field of photonics materials.Read moreRead less
Advanced electrochemical capacitors. This project aims to design electrochemical capacitors that can provide self-sustaining power for equipment using renewable energy sources, such as sunlight. Electrical power systems are needed to supply both the peak power and the energy demand that users, particularly those without grid electricity, and their equipment need. This project will match the capacitator electrochemistry to the power attributes of the load and charging source, making them more eff ....Advanced electrochemical capacitors. This project aims to design electrochemical capacitors that can provide self-sustaining power for equipment using renewable energy sources, such as sunlight. Electrical power systems are needed to supply both the peak power and the energy demand that users, particularly those without grid electricity, and their equipment need. This project will match the capacitator electrochemistry to the power attributes of the load and charging source, making them more efficiently charged and able to supply both peak power and energy demand for improved off-grid power supplies and integration of renewable energy into electricity grids.Read moreRead less
Exploring Emerging Collective Behaviours in Large-Scale Data-Driven Networked Systems. Understanding emerging collective behaviours in large-scale data-driven networked systems and developing methodology and approach for pattern identification and intervention are very important for high impact applications such as smart energy supply using smart meters. This project will propose a new theory for the developments, which will enhance Australia's leading position in this research and provide a cut ....Exploring Emerging Collective Behaviours in Large-Scale Data-Driven Networked Systems. Understanding emerging collective behaviours in large-scale data-driven networked systems and developing methodology and approach for pattern identification and intervention are very important for high impact applications such as smart energy supply using smart meters. This project will propose a new theory for the developments, which will enhance Australia's leading position in this research and provide a cutting-edge technology for industrial applications and training of the next generation of leading researchers.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180101118
Funder
Australian Research Council
Funding Amount
$314,446.00
Summary
Enabling high photovoltaic penetration in power distribution networks. This project aims to develop a novel hybrid control method for power distribution grid network voltage regulation with high photovoltaic penetration. The outcome of this project will enable power utilities to cost-effectively regulate network voltage and ultimately remove barriers for future photovoltaic deployment. This will deliver significant economic benefits for both the wider community and utility providers, along with ....Enabling high photovoltaic penetration in power distribution networks. This project aims to develop a novel hybrid control method for power distribution grid network voltage regulation with high photovoltaic penetration. The outcome of this project will enable power utilities to cost-effectively regulate network voltage and ultimately remove barriers for future photovoltaic deployment. This will deliver significant economic benefits for both the wider community and utility providers, along with substantial environmental outcomes through increased use of sustainable energy sources.Read moreRead less
Microgrid architectures for efficient use of renewable energy sources. This project aims to research modifications to the electrical grid in the form of microgrid architecture for better use of renewable energy.Electrical supply grid and energy management systems designed for traditional centralised power generation, transmission and distribution increasingly use renewable energy sources. A redesigned grid, based on microgrid architectures using the proposed optimisation techniques, is expected ....Microgrid architectures for efficient use of renewable energy sources. This project aims to research modifications to the electrical grid in the form of microgrid architecture for better use of renewable energy.Electrical supply grid and energy management systems designed for traditional centralised power generation, transmission and distribution increasingly use renewable energy sources. A redesigned grid, based on microgrid architectures using the proposed optimisation techniques, is expected to save money and renew the grid’s infrastructure. This should also allow better use of renewable energy sources to meet Australia’s electrical power requirements.Read moreRead less
Wide-area interconnected clean energy highway. This project aims to facilitate the deployment of the clean energy highway, an integrated electricity and gas network. Renewable energy sources, advanced transmission facilities and power-to-gas technologies are changing energy systems. All these changes, while potentially making energy systems more responsive, efficient and resilient, also make implementation difficult. This project aims to make implementation easier to ensure more sustainable solu ....Wide-area interconnected clean energy highway. This project aims to facilitate the deployment of the clean energy highway, an integrated electricity and gas network. Renewable energy sources, advanced transmission facilities and power-to-gas technologies are changing energy systems. All these changes, while potentially making energy systems more responsive, efficient and resilient, also make implementation difficult. This project aims to make implementation easier to ensure more sustainable solutions for energy generation, delivery and use in this new energy era. The expected outcome is a sound and robust suite of models and associated methodologies to study, analyse and design the clean energy highway.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100370
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
High-voltage DC grids for flexible and efficient electricity transmission. This project aims to design a high-voltage DC transmission network. Integrating large amounts of low-emission, renewable energy into the electricity network requires a transmission network capable of handling intermittency and high variability. This project will develop and functionally demonstrate a high-voltage DC transmission network based on modular multilevel power electronics converters as the future backbone of the ....High-voltage DC grids for flexible and efficient electricity transmission. This project aims to design a high-voltage DC transmission network. Integrating large amounts of low-emission, renewable energy into the electricity network requires a transmission network capable of handling intermittency and high variability. This project will develop and functionally demonstrate a high-voltage DC transmission network based on modular multilevel power electronics converters as the future backbone of the transmission network, as an extension and in support of the existing AC network. This project is expected to contribute to a low-carbon, sustainable development of the electricity transmission sector, while maintaining high levels of stability, resilience and security of supply.Read moreRead less
Power quality monitoring of grids with high penetration of power converters. The project aims to monitor and analyse power quality of grids within the frequency ranges of 0-2 kHz (existing regulations) and 2-150 kHz (new regulations). Power quality of grids deteriorate due to the high penetrations of inverter-based renewable energy systems. To estimate power quality of grids, the project expects to develop a multi-domain simulation model based on power grid configurations and operating condition ....Power quality monitoring of grids with high penetration of power converters. The project aims to monitor and analyse power quality of grids within the frequency ranges of 0-2 kHz (existing regulations) and 2-150 kHz (new regulations). Power quality of grids deteriorate due to the high penetrations of inverter-based renewable energy systems. To estimate power quality of grids, the project expects to develop a multi-domain simulation model based on power grid configurations and operating condition. Developed methodologies will assist network service providers to better analyse harmonics and resonances within low and high voltage power systems. Expected outcomes of this project are to assist partners to monitor and solve the existing communication issues of audio frequency load control and to address power quality issues arising from the increasing connection of renewable energy systems.Read moreRead less