Multifunctional trilayer separator for durable multivalent energy storage. This project aims to develop an important new family of economical, high energy, multivalent batteries based on an abundant element, sulphur. The project plans to design a new battery separator to enable long-term stability in sulphur-based rechargeable batteries. This type of separator is of critical importance in many membrane-involved energy storage technologies. The project plans to use leading-edge durable energy tec ....Multifunctional trilayer separator for durable multivalent energy storage. This project aims to develop an important new family of economical, high energy, multivalent batteries based on an abundant element, sulphur. The project plans to design a new battery separator to enable long-term stability in sulphur-based rechargeable batteries. This type of separator is of critical importance in many membrane-involved energy storage technologies. The project plans to use leading-edge durable energy technologies to strengthen the development of residential energy systems and the involvement of renewable energy sources in modern grid.Read moreRead less
Control of Distributed Energy Storage System using Vanadium Batteries. This project aims to develop a new control approach to distributed energy storage at stack, system and microgrid levels, utilising one of the most promising flow battery technologies - vanadium redox batteries. This is the first attempt of a storage centric approach that includes: an integrated approach to design and control of vanadium flow batteries with novel advanced power electronics technologies to achieve optimal charg ....Control of Distributed Energy Storage System using Vanadium Batteries. This project aims to develop a new control approach to distributed energy storage at stack, system and microgrid levels, utilising one of the most promising flow battery technologies - vanadium redox batteries. This is the first attempt of a storage centric approach that includes: an integrated approach to design and control of vanadium flow batteries with novel advanced power electronics technologies to achieve optimal charging/discharging conditions; and, a scalable distributed energy storage and power management approach incorporating energy pricing for storage dispatch that allows distributed autonomous controllers to achieve optimal local techno-economic performance and microgrid-wide efficiency and reliability.Read moreRead less
Multiscale Integrated Modelling and Control of an Ethanol-Fuelled Tubular Solid Oxide Fuel Cell. The results from this project will allow use of alternative sources for energy through a better understanding of the functioning, design, operability and control of SOFCs. Fuel Cells (FCs) with biomass ethanol feed will not only act as reliable power source but also reduce greenhouse gas emissions. A successful R&D effort to develop FCs will improve the national energy security by reducing the growin ....Multiscale Integrated Modelling and Control of an Ethanol-Fuelled Tubular Solid Oxide Fuel Cell. The results from this project will allow use of alternative sources for energy through a better understanding of the functioning, design, operability and control of SOFCs. Fuel Cells (FCs) with biomass ethanol feed will not only act as reliable power source but also reduce greenhouse gas emissions. A successful R&D effort to develop FCs will improve the national energy security by reducing the growing dependency on foreign energy sources, improve the environment by reducing carbon and other harmful emissions, and improve the economic growth by expanding the portfolio of highly efficient energy and useful spill over technologies. Read moreRead less
Transport Processes in Flexible Porous Materials for Gas Separation and Storage. This project seeks to understand the mechanisms of transport processes in flexible porous materials, which have great potential in gas separation and storage. Coal and natural gas are important to the Australian economy, and the potential applications of flexible porous materials, such as air separation and hydrogen storage, are crucial for Australia to use coal and natural gas cleanly. The analysis method to be dev ....Transport Processes in Flexible Porous Materials for Gas Separation and Storage. This project seeks to understand the mechanisms of transport processes in flexible porous materials, which have great potential in gas separation and storage. Coal and natural gas are important to the Australian economy, and the potential applications of flexible porous materials, such as air separation and hydrogen storage, are crucial for Australia to use coal and natural gas cleanly. The analysis method to be developed is useful not only to gas separation and storage, but also to hydrogeology and soil science in Australia.Read moreRead less
Cloud scheduling and management of energy systems with real-time support. This project aims to research cloud scheduling and management of modern energy systems with real-time communication support. The approach consists of optimisation with balanced benefits for customers, aggregators and network service providers for modern energy systems; real-time communication support for unified energy scheduling and management over many microgrids; and cloud energy scheduling and management with deadline ....Cloud scheduling and management of energy systems with real-time support. This project aims to research cloud scheduling and management of modern energy systems with real-time communication support. The approach consists of optimisation with balanced benefits for customers, aggregators and network service providers for modern energy systems; real-time communication support for unified energy scheduling and management over many microgrids; and cloud energy scheduling and management with deadline guarantee. This project is expected to facilitate increasing deployment of disruptive energy technologies on a massive scale, create opportunities for energy industries, and maintain Australia’s leading position in renewable energy.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775550
Funder
Australian Research Council
Funding Amount
$345,000.00
Summary
Characterisation Equipment for Advanced Gas Separation Applications. The proposed research will lead to the synthesis of new advanced materials capable of performing new and existing separations more efficiently than previous methods. We therefore expect the new materials to directly benefit the community through improved removal and recovery of a wide range of pollutants which would otherwise enter the environment. This research is directly aligned to the National Research Priority of Frontie ....Characterisation Equipment for Advanced Gas Separation Applications. The proposed research will lead to the synthesis of new advanced materials capable of performing new and existing separations more efficiently than previous methods. We therefore expect the new materials to directly benefit the community through improved removal and recovery of a wide range of pollutants which would otherwise enter the environment. This research is directly aligned to the National Research Priority of Frontier Technologies for Building and Transforming Australian Industries: Advanced Materials.Read moreRead less
A green technology for liquefied natural gas (LNG) regasification. Upon arrival to its destination, the liquefied natural gas (LNG) exported from Australia must be converted back into gas to make it suitable for distribution to end users, for which the current technologies burn up to two per cent our LNG exports. This project will design a technology that will use the energy of ambient air, which will not only increase the profit but also reduce carbon dioxide emissions.
Enhanced mixing of turbulent jet flames via side lateral injection. This innovative project will contribute significantly to the reduction of pollutant emissions from combustion of fossil and bio-fuels through new and innovative mixing approach of fuel and oxidant. It will facilitate a range of new devices with broader application leading to export earnings, local employment and reduction of our carbon footprint.
Novel Characterization of Porous Structure and Surface Chemistry of Carbon. The aim of this project is to develop novel characterisation methods that probe the structure and surface chemistry of carbons, ranging from highly graphitised thermal carbon black through ordered mesoporous carbon to disordered porous activated carbon. The project plans to develop a new generic molecular model based on wedge-shaped pores. Conventional parallel sided pore models fail to account for real structures and th ....Novel Characterization of Porous Structure and Surface Chemistry of Carbon. The aim of this project is to develop novel characterisation methods that probe the structure and surface chemistry of carbons, ranging from highly graphitised thermal carbon black through ordered mesoporous carbon to disordered porous activated carbon. The project plans to develop a new generic molecular model based on wedge-shaped pores. Conventional parallel sided pore models fail to account for real structures and therefore for the physics of adsorption in real materials. The project then plans to back the theoretical model with high-resolution experimental measurements. It is expected that the model will unify the structural analysis for all carbons and account for all experimental isotherms within a rational and physically plausible framework.Read moreRead less
Fundamentals and practical applications of hierarchically-structured bulk materials. Structured bulk materials are very promosing for process intensification. By using structured bulk materials instead of fine particles, this project will have the opportunity to realise hydrogen or methane storage at very low pressure, and significantly speed up the production of alternative transport fuels from syn gas.