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
Development of a Trickle Filter for Treating Sour Water from Oil Shale Processing Plants. Oil is extracted from oil shale by pyrolysing pre-dried crushed shale. Despite drying , the shale retains a residual moisture level of approximately 5% which ultimately ends up as an aqueous phase in the condensate stream from the pyrolysis process. This aqueous phase, know as sour water, contains a range of organic compounds, including carboxylic acids, nitorgen heterocyclics and ketones. This aim of thi ....Development of a Trickle Filter for Treating Sour Water from Oil Shale Processing Plants. Oil is extracted from oil shale by pyrolysing pre-dried crushed shale. Despite drying , the shale retains a residual moisture level of approximately 5% which ultimately ends up as an aqueous phase in the condensate stream from the pyrolysis process. This aqueous phase, know as sour water, contains a range of organic compounds, including carboxylic acids, nitorgen heterocyclics and ketones. This aim of this proposal is to develop trickle filters to treat the sour water. The biofilms that develop in trickle filters are ideal for supporting slow growing microbial species. Research is needed to transfer native microorganisms in the oil shale desposit to the durable gravels that will be used in the filter.Read moreRead less
Low Temperature Catlytic Wet Oxidation of Organics from Strippped Sour Water. The commercialisation of a ~$3billion Australian oil shale industry heavily depends upon environmental sustainability of its technology. One key environmental issue of this technology is a need to remove organics from an aqueous industrial stream (stripped sour water). This proposal aims to develop a method based on catalytic wet oxidation for removing organics from stripped sour water. Research will be focused to deve ....Low Temperature Catlytic Wet Oxidation of Organics from Strippped Sour Water. The commercialisation of a ~$3billion Australian oil shale industry heavily depends upon environmental sustainability of its technology. One key environmental issue of this technology is a need to remove organics from an aqueous industrial stream (stripped sour water). This proposal aims to develop a method based on catalytic wet oxidation for removing organics from stripped sour water. Research will be focused to develop and study potential catalytic systems to lower the activation energy of the rate-determining step and to increase the rate of organics oxidation. The development of such a method would be a substantial technology achievement with many applications in pollution control for wastewater treatment in many other industries.Read moreRead less
Novel technology for enhanced coal seam gas production utilising mechanisms of stimulated cleat permeability through graded particle injection. This cross-disciplinary project will develop a new integrated technology for well productivity enhancement in coal seam gas, shale, tight gas and geothermal reservoirs - the world’s fastest growing unconventional clean energy resources. It will improve our understanding of the multi scale physics of natural gas and energy production.
From organo-mineral nanocomposite to Australian basins; an integrated approach to unconventional gas exploration and development. Gas production from unconventional shale reservoirs is a potential major energy boom in Australia that will lower carbon emissions over comparable coal and oil use. The geological controls of shale are currently too poorly understood to direct effective exploration. This project will be the largest international effort to develop this knowledge.