Modelling the capillary entrapment phenomena and integrity of geological reservoirs for clean energy, water and waste management technologies. This project will improve our understanding of non-linear flow and fracture phenomena in porous media which is prerequisite for the development of new emerging technologies targeting the reduction of the greenhouse gas emission and development of effective waste and water management solutions including coal gasification, in-situ storage of natural and non ....Modelling the capillary entrapment phenomena and integrity of geological reservoirs for clean energy, water and waste management technologies. This project will improve our understanding of non-linear flow and fracture phenomena in porous media which is prerequisite for the development of new emerging technologies targeting the reduction of the greenhouse gas emission and development of effective waste and water management solutions including coal gasification, in-situ storage of natural and non-hydrocarbon gases, underground disposal of hazardous wastes and vadose zone remediation. The project will result in a dramatic improvement of the predictive tools for traditional ground water management, irrigation and petroleum recovery applications. It has the strength to place Australia in the forefront of these technologies. Read moreRead less
Production, Fate and Transport of Cyanobacterial Toxins in Waterways. Australian waterways are under severe pressure from both large variation in precipitation patterns and various sources of contamination. In particular, the management of algal blooms costs Australians hundreds of millions of dollars a year. Through the use of a unique approach this project will provide the necessary information for a science based decision making strategies to eradicate, as much as possible, algal blooms and ....Production, Fate and Transport of Cyanobacterial Toxins in Waterways. Australian waterways are under severe pressure from both large variation in precipitation patterns and various sources of contamination. In particular, the management of algal blooms costs Australians hundreds of millions of dollars a year. Through the use of a unique approach this project will provide the necessary information for a science based decision making strategies to eradicate, as much as possible, algal blooms and to reduce the risk of severe injuries to the public, livestock and the environment, resulting from contamination waterways by algal toxins. Read moreRead less
A HYBRID INTEGRATED SYSTEM FOR MUNICIPAL SOLID WASTE TREATMENT AND POWER GENERATION. The management of solid wastes is a major global environmental issue and the current practice of landfilling is not a sustainable solution. Biogasification of the organic fraction provides not only a means of waste treatment but also generates a source of energy in the form methane but current technologies are expensive due to the long degradation times. In this project we investigate an innovative waste tr ....A HYBRID INTEGRATED SYSTEM FOR MUNICIPAL SOLID WASTE TREATMENT AND POWER GENERATION. The management of solid wastes is a major global environmental issue and the current practice of landfilling is not a sustainable solution. Biogasification of the organic fraction provides not only a means of waste treatment but also generates a source of energy in the form methane but current technologies are expensive due to the long degradation times. In this project we investigate an innovative waste treatment system that will cut down the time required for processing wastes by a factor of 10 with considerable economic benefit. We will optimise the integration of this treatment system with a hybrid power generation system that utilises other renewable energy sources like solar and wind energy to deliver quality power at minimal cost.Read moreRead less
Development of a novel technology for DSP separation and soda recovery in alumina refineries. The successful completion of this project will provide economic and environmental benefits to the Australian alumina industry. For example, this project will provide an effective and economical method for separation of DSP (desilication product) from red mud (thus reducing the pollution by the long-term alkalinity) as well as a new solution to soda recovery. The technology developed will be able to be u ....Development of a novel technology for DSP separation and soda recovery in alumina refineries. The successful completion of this project will provide economic and environmental benefits to the Australian alumina industry. For example, this project will provide an effective and economical method for separation of DSP (desilication product) from red mud (thus reducing the pollution by the long-term alkalinity) as well as a new solution to soda recovery. The technology developed will be able to be used as an example to the waste management and recovery of other Australian mineral, energy and chemical industries. The modelling and mechanism studies will also contribute to materials separation and processing.Read moreRead less
Development of a Novel Flue Gas Desulphurization Technology for Alumina Refineries. This project aims to develop a novel technology of flue gas desulphurization for alumina industry. The successful completion of this project will provide a practical solution to the SOx emission problem in alumina refineries. Specifically, we aim to make use of the waste causticiser sludge discharged during the causticisation of the liquor streams and the used filter aid after the polishing filtration of the ref ....Development of a Novel Flue Gas Desulphurization Technology for Alumina Refineries. This project aims to develop a novel technology of flue gas desulphurization for alumina industry. The successful completion of this project will provide a practical solution to the SOx emission problem in alumina refineries. Specifically, we aim to make use of the waste causticiser sludge discharged during the causticisation of the liquor streams and the used filter aid after the polishing filtration of the refinery pregnant liquors as reagent to remove SOx emitted by the power house and the alumina calciners. We also aim to recover some alumina during the process of flue gas desulphurization thus further reducing the cost of air pollution control.Read moreRead less
A Novel Approach for Color and Degradation Control in Post Consumer Polyethylene Terephthalate During Recycling. Discoloration is a critical problem in the manufacturing of post-consumer polyethylene terephthalate (PET) polymeric products in which optical clarity requirement is high. The inherent weakness of the PET demands highly efficient stabilisation of this polymer. The project aims to understand and eliminate the occurrence of such discoloration and improve the quality of the Visy product ....A Novel Approach for Color and Degradation Control in Post Consumer Polyethylene Terephthalate During Recycling. Discoloration is a critical problem in the manufacturing of post-consumer polyethylene terephthalate (PET) polymeric products in which optical clarity requirement is high. The inherent weakness of the PET demands highly efficient stabilisation of this polymer. The project aims to understand and eliminate the occurrence of such discoloration and improve the quality of the Visy products. New multifunctional additives will be developed, which when added to PET during processing, will not only quench the discoloration reaction but also yield high quality products with excellent optical properties. This project is of substantial strategic importance to the Australian/global polymer processing and recycling industries.
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PREDICTING THE CLOGGING OF STORM WATER INFILTRATION SYSTEMS. Infiltration systems are widely used in sustainable management of stormwater in both urban and rural areas. They are also an integral part of large stormwater-harvesting facilities. However, they tend to fail due to clogging (infiltration medium gets filled by silt from runoff), and this phenomenon is far from being understood. The aim of this project is to develop a new prediction method of clogging of stormwater infiltration systems. ....PREDICTING THE CLOGGING OF STORM WATER INFILTRATION SYSTEMS. Infiltration systems are widely used in sustainable management of stormwater in both urban and rural areas. They are also an integral part of large stormwater-harvesting facilities. However, they tend to fail due to clogging (infiltration medium gets filled by silt from runoff), and this phenomenon is far from being understood. The aim of this project is to develop a new prediction method of clogging of stormwater infiltration systems. Extensive 1D and 2D laboratory experimental programmes will be carried out. Models of unit processes that occur in infiltration systems will be defined/developed and built into a physically based model of an infiltration system. This model could be used for reliable design of stormwater drainage and harvesting systems, bringing major benefits to the people of drier and more populated areas of Australia.Read moreRead less
Derivation of Emissions Models from Vehicle Certification Tests. This research project will aim to prove the concept that emissions models capable of modelling changes in driver behaviour can be obtained from data that has been used as part of the vehicles emission certification process. Second by second emissions data from certification tests will be disaggregated into their component phases of acceleration, cruise, deceleration and idle. The emissions characteristics of these phases will be es ....Derivation of Emissions Models from Vehicle Certification Tests. This research project will aim to prove the concept that emissions models capable of modelling changes in driver behaviour can be obtained from data that has been used as part of the vehicles emission certification process. Second by second emissions data from certification tests will be disaggregated into their component phases of acceleration, cruise, deceleration and idle. The emissions characteristics of these phases will be established and analysed to produce empirical models of emissions per unit time versus mode of operation. These models will then be able to describe the changes in emission characteristics under different vehicle operating modes modes for a range of vehicle types.Read moreRead less
A 60% efficient solar microconcentrator for electricity and hot water. The aim of this project is to develop a microconcentrator for deployment on house roofs that will produce both solar hot water and solar electricity with a combined efficiency above 60%. The system will have a low profile and will be nearly invisible from the street. The system will track the sun. Concentration will be accomplished by a mixture of refraction and reflection. About 20% of the sunlight will be converted to elect ....A 60% efficient solar microconcentrator for electricity and hot water. The aim of this project is to develop a microconcentrator for deployment on house roofs that will produce both solar hot water and solar electricity with a combined efficiency above 60%. The system will have a low profile and will be nearly invisible from the street. The system will track the sun. Concentration will be accomplished by a mixture of refraction and reflection. About 20% of the sunlight will be converted to electricity using lines of tiny solar cells, with the balance being converted to heat which is removed by cooling fluid and stored in hot water tanks.Read moreRead less
Special Research Initiatives - Grant ID: SR0354551
Funder
Australian Research Council
Funding Amount
$20,000.00
Summary
ARC Research Network for Renewable Energy. The proposed Research Network will integrate and coordinate the entire research field of renewable energy in Australia. This Network covers a diverse range of technologies, and includes all prominent researchers in the area of renewable energy in Australia. The Network is strengthened by the inclusion of key people from government agencies, industry, industry associations and international research organisations.
Australia is a leading player in the ....ARC Research Network for Renewable Energy. The proposed Research Network will integrate and coordinate the entire research field of renewable energy in Australia. This Network covers a diverse range of technologies, and includes all prominent researchers in the area of renewable energy in Australia. The Network is strengthened by the inclusion of key people from government agencies, industry, industry associations and international research organisations.
Australia is a leading player in the world's renewable energy industry. An effective structure for networking and for the exchange of people, information and research results will maintain and improve Australia's position in this rapidly growing industry.Read moreRead less