Advanced modelling and optimisation of Underground Coal Gasification. The last decade is characterised by increasing interest of many countries in obtaining and developing Underground Coal Gasification (UCG) technologies. Recent long-term successful trial in Chinchilla has proven that the technology is ready for commercial use but the fundamental research into UCG is needed for further improvement of the technology performance in commercial applications. The major goal of this project is in comb ....Advanced modelling and optimisation of Underground Coal Gasification. The last decade is characterised by increasing interest of many countries in obtaining and developing Underground Coal Gasification (UCG) technologies. Recent long-term successful trial in Chinchilla has proven that the technology is ready for commercial use but the fundamental research into UCG is needed for further improvement of the technology performance in commercial applications. The major goal of this project is in combining most recent advances in combustion modelling with practical UCG operations and developing new advanced models specifically for UCG diagnostics and optimisation. The project outcomes involve: better understanding and optimisation of UCG processes and further development of advanced modelling techniques.
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In situ microbial conversion of coal to methane: Biotechnology development for clean use of Australian coal. We will develop a biotechnology that uses native microorganisms to accelerate the underground conversion of coal to methane. Approximately 90% of Australia’s coal resources cannot be accessed economically using traditional mining technologies. A technology that converts coal to methane could generate an energy supply worth an estimated $60 billion, foster the development of an energy indu ....In situ microbial conversion of coal to methane: Biotechnology development for clean use of Australian coal. We will develop a biotechnology that uses native microorganisms to accelerate the underground conversion of coal to methane. Approximately 90% of Australia’s coal resources cannot be accessed economically using traditional mining technologies. A technology that converts coal to methane could generate an energy supply worth an estimated $60 billion, foster the development of an energy industry now in its infancy, and generate numerous new employment opportunities. Environmentally, methane is a cleaner burning fuel than coal, uses much less water for processing and generates the same quantity of electricity with lower CO2 emissions. This project highlights the fact that Australia’s microbial diversity is a resource we cannot afford to ignore.Read moreRead less
Methanol to diesel. Australia has large remote gas reserves which are not accessible to markets via pipeline and cannot be effectively utilised using liquefied natural gas technology. Fischer-Tropsch conversion of gas to liquid (GTL), being capital intense, is uneconomical for these stranded gas resources. This project will develop a new GTL technology to produce sulphur-free, clean combustion diesel. The outcomes of this research will be a frontier technology that allows more effective utilisat ....Methanol to diesel. Australia has large remote gas reserves which are not accessible to markets via pipeline and cannot be effectively utilised using liquefied natural gas technology. Fischer-Tropsch conversion of gas to liquid (GTL), being capital intense, is uneconomical for these stranded gas resources. This project will develop a new GTL technology to produce sulphur-free, clean combustion diesel. The outcomes of this research will be a frontier technology that allows more effective utilisation of Australian remote gas resources to meet rising global demand for transport fuels, adding enormous value to Australian natural resources and contributing to Building and Transforming Australian industries.Read moreRead less
Development of a Novel One Step Process for Gas Conversion to Liquid. Australia has a rich natural gas reserve, most of which is in remote locations. This project will lead to a new technology to use the remote gas that would be flared into the atmosphere, thus benefiting both Australian economy and green house gas reduction. It will also reduce the risk of relying on importing oil from Overseas thus contributing to Australia's energy security. In addition, while crude-based oil emits SOx, NOx a ....Development of a Novel One Step Process for Gas Conversion to Liquid. Australia has a rich natural gas reserve, most of which is in remote locations. This project will lead to a new technology to use the remote gas that would be flared into the atmosphere, thus benefiting both Australian economy and green house gas reduction. It will also reduce the risk of relying on importing oil from Overseas thus contributing to Australia's energy security. In addition, while crude-based oil emits SOx, NOx and particulates etc into air, the liquid fuels from gas are pure and burns cleanly thus also contributing to air pollution control. Read moreRead less
Fundamental Data and Thermodynamic Modelling for Cryogenic LNG Fluids to Improve Process Design, Simulation and Operation. This research will contribute to a more environmentally sustainable Australia because it will promote the use of natural gas as a fuel supply which produces significantly fewer greenhouse gases than oil or coal. This project will improve the ability of engineers to reliably simulate LNG production plants as well as test new processes and technologies with the potential to in ....Fundamental Data and Thermodynamic Modelling for Cryogenic LNG Fluids to Improve Process Design, Simulation and Operation. This research will contribute to a more environmentally sustainable Australia because it will promote the use of natural gas as a fuel supply which produces significantly fewer greenhouse gases than oil or coal. This project will improve the ability of engineers to reliably simulate LNG production plants as well as test new processes and technologies with the potential to increase efficiency or revenue. Consequently, the level of over-engineering and, thus, the capital and operational costs of such plants will decrease. This in turn will promote the development of Australian gas reserves, particularly for those fields currently on the margins of economic viability.Read moreRead less
Nano- and micro-scale engineering of MoS2-based catalyst for conversion of syngas to ethanol. Domestic production of ethanol to provide a 10% blend in petrol (E10) can be achieved from waste methane gas that Australia currently vents or flares to atmosphere. This project aims to develop a conversion process for making ethanol from syngas (the product of coal or methane gasification). Small scale, modularised plants would make ethanol locally to the methane emission source. The benefits of local ....Nano- and micro-scale engineering of MoS2-based catalyst for conversion of syngas to ethanol. Domestic production of ethanol to provide a 10% blend in petrol (E10) can be achieved from waste methane gas that Australia currently vents or flares to atmosphere. This project aims to develop a conversion process for making ethanol from syngas (the product of coal or methane gasification). Small scale, modularised plants would make ethanol locally to the methane emission source. The benefits of local E10 production would be a reduction in the oil trade deficit of $1 billion per year, $500 million per year in lower carbon imposts to industry and government, 25 million tonnes per year of reduced CO2e release to atmosphere and significantly improved urban air through reduced emissions from car transport, with attendant human health benefits.Read moreRead less
Reforming of Liquid Hydrocarbon Fuels for Application in Solid Oxide Fuel Cells Technology. The project will aim at developing a fuel processing system for solid oxide fuel cells which will have the advantages of being fuel flexible through the conversion of liquid fuels (gasoline, LPG, diesel) for application in small to medium stationary power generation systems. This investigation will also generate fundamental information and understanding concerning the catalytic reforming of liquid hydroca ....Reforming of Liquid Hydrocarbon Fuels for Application in Solid Oxide Fuel Cells Technology. The project will aim at developing a fuel processing system for solid oxide fuel cells which will have the advantages of being fuel flexible through the conversion of liquid fuels (gasoline, LPG, diesel) for application in small to medium stationary power generation systems. This investigation will also generate fundamental information and understanding concerning the catalytic reforming of liquid hydrocarbon fuels to produce adequate feeds for SOFCs. These distributed energy devices are of high efficiency and with a novel technology the industrial partner will aim to offer products with high value propositions in the critical areas of price, reliability and service.Read moreRead less
Multi-service assessment of intertidal treatment wetlands. This project aims to investigate the use of constructed intertidal wetlands to reduce nitrogen pollution while providing co-benefits including carbon sequestration and biodiversity. This research will generate a holistic assessment of the services, disservices, and cost-effectiveness of intertidal treatment wetlands compared to traditional wastewater treatment approaches. Expected outcomes include a full-scale multi-disciplinary environm ....Multi-service assessment of intertidal treatment wetlands. This project aims to investigate the use of constructed intertidal wetlands to reduce nitrogen pollution while providing co-benefits including carbon sequestration and biodiversity. This research will generate a holistic assessment of the services, disservices, and cost-effectiveness of intertidal treatment wetlands compared to traditional wastewater treatment approaches. Expected outcomes include a full-scale multi-disciplinary environmental and economic assessment of a constructed treatment wetland in a new urban development, providing industry and government partners the knowledge required to broaden uptake of intertidal wetlands as a cost-effective solution to growing levels of coastal anthropogenic pollution.Read moreRead less
Increased liquified natural gas (LNG) production efficiency through nitrogen and carbon dioxide capture using high-pressure cryogenic adsorption onto tailored nanopore substrates. This research will contribute to a more environmentally sustainable Australia because it will promote the use of natural gas as a fuel supply which produces significantly less greenhouse gases than oil or coal. It will contribute to the harnessing of some of Australia's largest gas reserves, like the Gorgon field, whic ....Increased liquified natural gas (LNG) production efficiency through nitrogen and carbon dioxide capture using high-pressure cryogenic adsorption onto tailored nanopore substrates. This research will contribute to a more environmentally sustainable Australia because it will promote the use of natural gas as a fuel supply which produces significantly less greenhouse gases than oil or coal. It will contribute to the harnessing of some of Australia's largest gas reserves, like the Gorgon field, which are contaminated with large amounts of CO2 and are not yet economically viable. The removal of N2 from natural gas will reduce the cost of producing LNG which is the only method Australia can use to access global gas markets. The new adsorbent materials developed for this work may enhance other research programmes attempting to capture and sequester CO2 from industrial flue gases.Read moreRead less
A study of high temperature transformation of oil shale - In-situ mineral reactions and structure analysis. In the current energy market, non-traditional fuels like oil shale are becoming more economically important. Australia has >33 billion tonnes of oil shales resources with potential for >1800 million tonnes of recoverable oil. This potential multi-billion dollar industry depends upon development of an efficient technology leading to economical oil production and much cleaner organic liquid ....A study of high temperature transformation of oil shale - In-situ mineral reactions and structure analysis. In the current energy market, non-traditional fuels like oil shale are becoming more economically important. Australia has >33 billion tonnes of oil shales resources with potential for >1800 million tonnes of recoverable oil. This potential multi-billion dollar industry depends upon development of an efficient technology leading to economical oil production and much cleaner organic liquid fuels. Retorting and combustion, which are core parts of oil shale conversion technology, would benefit from improved process conditions. This research proposal intends to investigate the in-situ complex oil shale thermal conversion reactions that occur during the retorting and combustion processes. Improved understanding of these complex reactions could lead to substantial economic and environmental improvements in oil shale processing.Read moreRead less