Characterisation of Pyrolytic Thermal Regions in Coal Macerals using Computer Aided Thermal Analysis. The research will assist in the fundamental understanding of coal pyrolysis mechanisms. All coal contains proportions of different fossilised plant material, which behaves differently when heated. This proposal studies thermal behaviour of the density separated fractions in Australian coals using a highly sensitive technique. The characterisation adds value and use to current coal reserves and ....Characterisation of Pyrolytic Thermal Regions in Coal Macerals using Computer Aided Thermal Analysis. The research will assist in the fundamental understanding of coal pyrolysis mechanisms. All coal contains proportions of different fossilised plant material, which behaves differently when heated. This proposal studies thermal behaviour of the density separated fractions in Australian coals using a highly sensitive technique. The characterisation adds value and use to current coal reserves and is aimed towards producing an advanced modelling capability to promote efficient coal usage in existing and future technologies. Such innovative approaches support the sustainability of Australian coal reserves, particularly in the transition towards decarbonised energy.Read moreRead less
Selective generation of hydrogen from biomass and waste fuels. Biomass fuels account for 14% of global energy supply. This is likely to increase in future as the population increases, energy demand rises, cheap oil and coal reserves are depleted, and the effects of global warming become more readily visible. In Australia the development of a sustainable hydrogen economy is a national priority. The hydrogen economy could bring about improved energy security, substantially reduced greenhouse gas e ....Selective generation of hydrogen from biomass and waste fuels. Biomass fuels account for 14% of global energy supply. This is likely to increase in future as the population increases, energy demand rises, cheap oil and coal reserves are depleted, and the effects of global warming become more readily visible. In Australia the development of a sustainable hydrogen economy is a national priority. The hydrogen economy could bring about improved energy security, substantially reduced greenhouse gas emissions, improved energy efficiency and improved air quality. This proposal directly addresses this challenge by investigating the science underpinning a large-scale sustainable hydrogen synthesis process using biomass and waste fuels. Read moreRead less
Engineered functional metal silica membranes for hydrogen processing. This project focuses on hydrogen processing technologies for the petrochemical, agricultural and coal/energy industries. These sectors employ 110,000 people with annual combined revenues of $80 billion. Advanced technologies are vital for the competitiveness of the Australian economy, and to sustain Australia's social stability and economic growth.
Methane Coupling Using Mixed Conducting Catalytic Ceramic Hollow Fibre Membrane Reactor. The Gas product industry is one of the most important economic sectors in Australia, employing 10000 people with market value of $ 100 billion per year from power generation and LNG export. However, there are increasing concerns over issues of the green house gases emission and petroleum dwindling. This project addresses the technology needs in converting natural gas to more useful chemicals via a more effic ....Methane Coupling Using Mixed Conducting Catalytic Ceramic Hollow Fibre Membrane Reactor. The Gas product industry is one of the most important economic sectors in Australia, employing 10000 people with market value of $ 100 billion per year from power generation and LNG export. However, there are increasing concerns over issues of the green house gases emission and petroleum dwindling. This project addresses the technology needs in converting natural gas to more useful chemicals via a more efficient and cleaner means of methane utilization. The project target is to make the natural gas resources in Australia to delivery high value products with considerable economic benefits and increased employment opportunities. Read moreRead less
Perovskite Asymmetric Hollow Fibres for Oxygen Separation in Clean Coal Energy Delivery. The coal industry is one of the most important economic sectors in Australia, employing 30000 people, whilst black coal is Australia's largest export worth around $24.5 billion. Energy security of supply is critical to Australia's social stability and economic growth, though Australia's reliance on coal for energy delivery is under strong scrutiny due to carbon mitigation. This project addresses the technolo ....Perovskite Asymmetric Hollow Fibres for Oxygen Separation in Clean Coal Energy Delivery. The coal industry is one of the most important economic sectors in Australia, employing 30000 people, whilst black coal is Australia's largest export worth around $24.5 billion. Energy security of supply is critical to Australia's social stability and economic growth, though Australia's reliance on coal for energy delivery is under strong scrutiny due to carbon mitigation. This project addresses the technology needs in tonnage oxygen separation towards a more efficient and cleaner means of generating energy. The project's benefits target at providing Australian consumers with affordable electricity in a decarbonised economy, enabling clean coal energy delivery to underpin the international competitiveness of the entire Australian economy.Read moreRead less
Anisotropic behaviour of coal for coalbed methane recovery and CO2 geosequestration. Amongst the cheapest and safest options for clean energy are to use natural gas from coal seams for electricity and fuel production and then permanently store carbon dioxide within the depleted seams. This requires information about the underground behaviour of coal at a level of detail which is not available. In particular, the directional and dynamic response of coal to changes in pressure, stress and gas in ....Anisotropic behaviour of coal for coalbed methane recovery and CO2 geosequestration. Amongst the cheapest and safest options for clean energy are to use natural gas from coal seams for electricity and fuel production and then permanently store carbon dioxide within the depleted seams. This requires information about the underground behaviour of coal at a level of detail which is not available. In particular, the directional and dynamic response of coal to changes in pressure, stress and gas interactions is required, which is the subject of this project. Coal bed methane is rapidly growing into a multi-billion dollar industry for Australia. The geosequestration of carbon dioxide in deep coal is widely recognised presenting a secure and economical opportunity for greenhouse gas control. Read moreRead less
A Comprehensive Kinetic Model for Sulfur Reactions in Combustion, Gasification, and Chemical Processing. Sulfur chemistry in high temperature processes is poorly understood, leading to uncertainties in the design of these processes and in the control of their emissions. In particular, new approaches to lowering greenhouse emissions which depend on the combustion and gasification of coal, biomass, or refuse-derived fuel, such as integrated gasification combined cycle processes, are especially aff ....A Comprehensive Kinetic Model for Sulfur Reactions in Combustion, Gasification, and Chemical Processing. Sulfur chemistry in high temperature processes is poorly understood, leading to uncertainties in the design of these processes and in the control of their emissions. In particular, new approaches to lowering greenhouse emissions which depend on the combustion and gasification of coal, biomass, or refuse-derived fuel, such as integrated gasification combined cycle processes, are especially affected by these uncertainties. This project seeks to combine experimental measurements and quantum chemical modelling to produce a detailed mechanistic model for the reactions of sulfur in high-temperature systems. Such a model will provide designers with a tool to optimise these complex interacting systems.Read moreRead less
Fundamental research for advanced gasification technologies for low-rank coal and biomass in the carbon-constrained world. This project aims to acquire fundamental knowledge in order to develop advanced gasification technologies with high efficiencies and the capability to couple with carbon storage facilities in the carbon-constrained future. These technologies will contribute to the reduction of Australia's CO2 emissions using its cheap low-rank coal and biomass.
Oxy-cofiring of bio-slurry and coal for carbon-negative power generation. This project aims to study co-firing characteristics of bio-slurry fuels and coal under oxy-pulverised-fuel (oxy-PF) conditions. Oxy-PF stationary systems can capture the renewable carbon embedded in bio-slurry fuel from biomass pyrolysis for sequestration, leading to carbon-negative power generation. The expected outcomes are critical knowledge and data regarding the underlying thermochemical reactions responsible for the ....Oxy-cofiring of bio-slurry and coal for carbon-negative power generation. This project aims to study co-firing characteristics of bio-slurry fuels and coal under oxy-pulverised-fuel (oxy-PF) conditions. Oxy-PF stationary systems can capture the renewable carbon embedded in bio-slurry fuel from biomass pyrolysis for sequestration, leading to carbon-negative power generation. The expected outcomes are critical knowledge and data regarding the underlying thermochemical reactions responsible for the co-pyrolysis, volatiles/char co-firing and ash formation from bio-slurry/coal co-firing under oxy-PF conditions. This is expected to enhance Australia's competitive advantage in clean power generation through high-impact scientific and technological innovations, and strengthen the related knowledge and skill base in the country.Read moreRead less
Multicomponent gas counter-diffusion in coal. Coalbed methane resources in Australia surpass $20billion at present gas prices. Using CO2 as an enhancement fluid, recovery of methane can potentially be improved by 50% adding a further $10b value, simultaneously permanently and safely sequestering the CO2, with possible carbon credits of up to $15b. The nature of the simultaneous exchange of CO2, methane and other gases within the coal dictates many of the engineering requirements for optimal exp ....Multicomponent gas counter-diffusion in coal. Coalbed methane resources in Australia surpass $20billion at present gas prices. Using CO2 as an enhancement fluid, recovery of methane can potentially be improved by 50% adding a further $10b value, simultaneously permanently and safely sequestering the CO2, with possible carbon credits of up to $15b. The nature of the simultaneous exchange of CO2, methane and other gases within the coal dictates many of the engineering requirements for optimal exploitation. It underlies the development of coal gas reservoir simulators, which currently do not incorporate this critical feature. This project is directed at understanding that counterflow and exchange.Read moreRead less