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Transforming Microgrid to Virtual Power Plant –ICT Frameworks,Tools,Control. The project aims to enhance large scale renewable penetrations to national power grid by advancing control, optimization, and ancillary services of Virtual Power Plants (VPPs), considering different disruptive events including recent South Australian blackout. This project expects to create new control, frame communication architecture, develop plug and play type IoT enabled grid interfacing inverter, and optimize resou ....Transforming Microgrid to Virtual Power Plant –ICT Frameworks,Tools,Control. The project aims to enhance large scale renewable penetrations to national power grid by advancing control, optimization, and ancillary services of Virtual Power Plants (VPPs), considering different disruptive events including recent South Australian blackout. This project expects to create new control, frame communication architecture, develop plug and play type IoT enabled grid interfacing inverter, and optimize resource management for distributed VPPs. The anticipated benefits from this institutional level collaborations are that VPPs help in enhancing national power grid operations during normal and disruptive conditions when more renewables are connected and also secure benefits of consumers, prosumers, and grid operators.Read moreRead less
High quality and robust energy conversion systems for distribution networks. This project aims to protect distribution networks by reducing harmonics and electromagnetic Interference generated by modern power electronics equipment. Due to global demand for energy savings and reductions in greenhouse gas emissions, the utilisation of renewable energy sources and efficient loads using power electronics technology in distribution networks is increasing. Aspects of this technology are highly complex ....High quality and robust energy conversion systems for distribution networks. This project aims to protect distribution networks by reducing harmonics and electromagnetic Interference generated by modern power electronics equipment. Due to global demand for energy savings and reductions in greenhouse gas emissions, the utilisation of renewable energy sources and efficient loads using power electronics technology in distribution networks is increasing. Aspects of this technology are highly complex and not well understood and the robustness of existing and future power grids will be affected. The project will minimise risk factors associated with high frequency noise and resonances in low voltage grids both of which are very important for power electronics manufacturers and utility companies in Australia.Read moreRead less
Functional topological materials for superior thermoelectric applications. The efficient generation of electricity from waste heat remains a significant technological challenge, hampered by the absence of efficient materials for conversion. This project aims to develop functionalized topological materials with ultra-high thermoelectric and photothermal performance for harvesting heat into electricity. A recent breakthrough in device efficiency will be a game-changer and position Australian acade ....Functional topological materials for superior thermoelectric applications. The efficient generation of electricity from waste heat remains a significant technological challenge, hampered by the absence of efficient materials for conversion. This project aims to develop functionalized topological materials with ultra-high thermoelectric and photothermal performance for harvesting heat into electricity. A recent breakthrough in device efficiency will be a game-changer and position Australian academics and industries at the forefront of next generation of renewable power generation and refrigeration products. The outcomes will provide an advantage to end-users and industry, and will open a new market for advanced thermoelectric devices in multidisciplinary fields, communities and emerging industries.Read moreRead less
Advanced all-Iron flow batteries for stationary energy storage. Iron flow batteries are one of the most promising choices for clean, reliable and cost effective long-duration energy storage. The main obstacle for large scale commercial deployment is the low round-trip energy efficiency caused by the competitive side reaction that occurs at the negative electrode during battery charging. The project aims to address this issue by engineering the negative electrode-electrolyte interface with functi ....Advanced all-Iron flow batteries for stationary energy storage. Iron flow batteries are one of the most promising choices for clean, reliable and cost effective long-duration energy storage. The main obstacle for large scale commercial deployment is the low round-trip energy efficiency caused by the competitive side reaction that occurs at the negative electrode during battery charging. The project aims to address this issue by engineering the negative electrode-electrolyte interface with functional materials to improve battery performance and thus further reduce the cost of energy storage. Expected outcomes include new materials and methods for advanced battery technology and manufacturing. The success of the project will significantly support the national priority of net-zero carbon emissions by 2050.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
Nanoengineered, Encapsulated Catalysts from Fly Ash Waste. This project aims to deliver advanced catalysts and novel catalyst synthesis methods from the use of iron-rich fly ash, an otherwise abundant valueless waste with projected steady growth across Australia and globally. The as-synthesised catalysts are expected to be applicable to and exhibit excellent activity in the production of green hydrogen and renewable bio-fuels from lignocellulosic waste. These efforts are significant and benefici ....Nanoengineered, Encapsulated Catalysts from Fly Ash Waste. This project aims to deliver advanced catalysts and novel catalyst synthesis methods from the use of iron-rich fly ash, an otherwise abundant valueless waste with projected steady growth across Australia and globally. The as-synthesised catalysts are expected to be applicable to and exhibit excellent activity in the production of green hydrogen and renewable bio-fuels from lignocellulosic waste. These efforts are significant and beneficial in restoring the manufacturing capability of Australian industry, driving Australian industry towards the development of a circular economy for the appropriate management of solid waste, as well as for a seamless introduction of renewable and clean energy sources to address the pressing climate change.Read moreRead less
Phase Change Materials for Wind and Solar Energy Storage. This project aims to develop and demonstrate new phase change materials to advance the technology of thermal energy storage. The project will focus on new materials that store thermal energy in the temperature range between 100 - 220°C that is optimal for distributed storage of solar and wind energy. The utility and economics of renewable energy sources are strongly limited by their intermittent nature and inexpensive means of storage are ....Phase Change Materials for Wind and Solar Energy Storage. This project aims to develop and demonstrate new phase change materials to advance the technology of thermal energy storage. The project will focus on new materials that store thermal energy in the temperature range between 100 - 220°C that is optimal for distributed storage of solar and wind energy. The utility and economics of renewable energy sources are strongly limited by their intermittent nature and inexpensive means of storage are urgently required. Expected outcomes of this project include a practical technology, which can be implemented at household and industry level, providing cheap energy from zero-carbon sources. The project aims to provide significant benefits to energy users and support further development of renewables.Read moreRead less
A Memory Powered Engine. Classical heat engines, such as petrol motors, convert thermal energy from hot gases into useful work, but with limited efficiency as much of the thermal energy is lost as waste heat. The project aims to combine experimental techniques in quantum information processing with recent theoretical developments in quantum thermodynamics to demonstrate a proof-of-concept heat engine that converts thermal energy into work with 100% efficiency. A heat engine of this kind would pr ....A Memory Powered Engine. Classical heat engines, such as petrol motors, convert thermal energy from hot gases into useful work, but with limited efficiency as much of the thermal energy is lost as waste heat. The project aims to combine experimental techniques in quantum information processing with recent theoretical developments in quantum thermodynamics to demonstrate a proof-of-concept heat engine that converts thermal energy into work with 100% efficiency. A heat engine of this kind would provide significant benefits to Australia with its potential to revolutionise how we store and use energy. The project will enable Griffith University to continue its pioneering role in developing this technology and to maintain long-term international collaborations.Read moreRead less
Enabling Next-generation Rechargeable Aluminium-ion Batteries. This project aims to develop a new generation of high performance and low-cost cathode materials for rechargeable aluminium ion batteries. To address the low capacity issue of current cathodes, this project anticipates to generate new knowledge in the material design of novel graphene materials. By developing an innovative surface perforation technique coupled in a continuous production process, this project expects to produce scalab ....Enabling Next-generation Rechargeable Aluminium-ion Batteries. This project aims to develop a new generation of high performance and low-cost cathode materials for rechargeable aluminium ion batteries. To address the low capacity issue of current cathodes, this project anticipates to generate new knowledge in the material design of novel graphene materials. By developing an innovative surface perforation technique coupled in a continuous production process, this project expects to produce scalable and cost-effective graphene cathodes with a record-high capacity. Expected outcomes of this project include industrial adaptable manufacturing processing and advanced materials for aluminium ion batteries, thus increasing the competitiveness of the partner organisation in the rapid growing graphene market.
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Sustainable Hydrogen Production from Used Water. The project aims to address the pressing challenge of water scarcity in hydrogen production by developing an innovative approach of using used water as the feed for water electrolysis. The project will result in an in-depth understanding of the impacts of water impurities in used water on the performance and durability of water electrolysers, and develop guidelines for the design of highly durable water electrolysers and the operation and upgrade ....Sustainable Hydrogen Production from Used Water. The project aims to address the pressing challenge of water scarcity in hydrogen production by developing an innovative approach of using used water as the feed for water electrolysis. The project will result in an in-depth understanding of the impacts of water impurities in used water on the performance and durability of water electrolysers, and develop guidelines for the design of highly durable water electrolysers and the operation and upgrade of existing wastewater treatment plants. The project will advance the practical applications of water electrolysis for scalable and sustainable hydrogen production and help Australia secure a leading position in the global emerging hydrogen economy.Read moreRead less