A novel process for removing phosphorus microbiologically from wastewater. Australia is a water limited continent, and its rivers and lakes are priceless assets, but because of climatic conditions, these are especially sensitive to blooms of 'blue green algae'. Some are highly toxic, and water containing them is unsuitable for most purposes. Current technology for P removal requires constructing complex plant configurations, and most of these operate unpredictably and unreliably. This project ....A novel process for removing phosphorus microbiologically from wastewater. Australia is a water limited continent, and its rivers and lakes are priceless assets, but because of climatic conditions, these are especially sensitive to blooms of 'blue green algae'. Some are highly toxic, and water containing them is unsuitable for most purposes. Current technology for P removal requires constructing complex plant configurations, and most of these operate unpredictably and unreliably. This project will develop and fully evaluate a revolutionarily different alternative with a fully aerobic system, capable of being added onto the end of a conventional treatment plant, making protection of rivers and streams simpler and more feasible. Read moreRead less
Enhancing the productivity of wastewater desalination. Climate change is causing reduced rainfall over much of populated Australia. New technology to enable membrane desalination of wastewater treatment effluent will be developed to provide secure reliable water supplies for Australian (and international) urban and regional communities. Application of the technology to Western Treatment Plant at Werribee will provide up to 10 gigalitres/year of recycled water to the local agricultural, business ....Enhancing the productivity of wastewater desalination. Climate change is causing reduced rainfall over much of populated Australia. New technology to enable membrane desalination of wastewater treatment effluent will be developed to provide secure reliable water supplies for Australian (and international) urban and regional communities. Application of the technology to Western Treatment Plant at Werribee will provide up to 10 gigalitres/year of recycled water to the local agricultural, business and tourism precincts. The economy, community and environment will benefit due to reduced use of potable, river and ground water. Wide application of this technology to wastewater and brackish water will lead to similar benefits and an environmentally sustainable Australia.
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Microbiology of Autothermal Thermophilic Aerobic Digester (ATAD) Systems for Biosolids Disposal in Wastewater Treatment Systems. The disposal of biosolids from wastewater treatment plants is expensive and troublesome. ATAD systems utilise microbes and are claimed to overcome many of the problems of more conventional disposal methods. Two have been installed in plants in central Victoria. However, virtually nothing is known about their microbiology. The study will determine which microbial popula ....Microbiology of Autothermal Thermophilic Aerobic Digester (ATAD) Systems for Biosolids Disposal in Wastewater Treatment Systems. The disposal of biosolids from wastewater treatment plants is expensive and troublesome. ATAD systems utilise microbes and are claimed to overcome many of the problems of more conventional disposal methods. Two have been installed in plants in central Victoria. However, virtually nothing is known about their microbiology. The study will determine which microbial populations are present and responsible for biosolids digestion, how these populations might change with changing operational conditions, and whether these changes in populations relate to production of odors. This information will enable these digesters to be better managed and operated.Read moreRead less
Development of design guidelines for recycled plastic material and structural components. It is estimated that by 2010 over 1.2 million tonnes of plastic will be used annually by Australians of which only 3% is currently recycled. Preliminary testing of recycled plastic products has demonstrated their potential usefulness in structural engineering applications. However, the lack of guidelines suitable for advanced applications of recycled plastic is limiting the growth of this technology. This p ....Development of design guidelines for recycled plastic material and structural components. It is estimated that by 2010 over 1.2 million tonnes of plastic will be used annually by Australians of which only 3% is currently recycled. Preliminary testing of recycled plastic products has demonstrated their potential usefulness in structural engineering applications. However, the lack of guidelines suitable for advanced applications of recycled plastic is limiting the growth of this technology. This project aims to develop a set of rational guidelines for the testing, analysis and design of recycled plastic material and structural components that will enable the continued expansion of this technology, significantly reducing waste plastic.Read moreRead less
Development of redox-mediated microbial assays for the rapid characterisation and assessment of wastewater, wastewater treatment processes and recycled water. With SE Qld on Level 5 water restrictions the need to reduce our demand on drinking water by increasing our reliance on recycled water is now urgent. To achieve this we need to ensure that the quality of our recycled wastewater is of a suitable and reliable standard. This project will assist the water industry in this endeavour by the de ....Development of redox-mediated microbial assays for the rapid characterisation and assessment of wastewater, wastewater treatment processes and recycled water. With SE Qld on Level 5 water restrictions the need to reduce our demand on drinking water by increasing our reliance on recycled water is now urgent. To achieve this we need to ensure that the quality of our recycled wastewater is of a suitable and reliable standard. This project will assist the water industry in this endeavour by the developing monitoring techniques that can rapidly characterise and assess the effectiveness of wastewater treatment processes and the quality of the water derived from them. These methods will provide early warnings of potential 'upsets' in treatment plants that would otherwise result in poor quality effluents that would need to be discharged as waste rather than be recycled.Read moreRead less
Solar Nano-photocatalytic Disinfection and Mineralization of Treated Wastewater from Sewage Treatment Plants. Reuse of the treated wastewater from sewage treatment plants (STPs) has become significantly important in Australia due to dwindling water resources. The poor quality of the wastewater has limited its use for agriculture and aquaculture. This project aims to develop a solar nano-photocatalytic tertiary wastewater treatment process for disinfection and mineralization of the treated waste ....Solar Nano-photocatalytic Disinfection and Mineralization of Treated Wastewater from Sewage Treatment Plants. Reuse of the treated wastewater from sewage treatment plants (STPs) has become significantly important in Australia due to dwindling water resources. The poor quality of the wastewater has limited its use for agriculture and aquaculture. This project aims to develop a solar nano-photocatalytic tertiary wastewater treatment process for disinfection and mineralization of the treated wastewater from STPs, making the wastewater suitable as a water resource. The newly developed nano-fibre catalysts and photocatalytic technology in the teatm will be used and further developed in this novel process. The research will focus on the water quality objectives in terms of technical reliability, and economic and environmental sustainability.Read moreRead less
Optimising biodegradation and removal of organic and inorganic pollutants in wastewater using constructed wetlands. The urgency of water recycling is dictated by drying climate and rapid expansion of population in Australia. Constructed wetlands are environmentally-benign way to purify wastewater by removing inorganics and facilitating biodegradation of organic pollutants, thus producing recycled water that can be used in a variety of fit-for-purpose applications. This project will produce a dec ....Optimising biodegradation and removal of organic and inorganic pollutants in wastewater using constructed wetlands. The urgency of water recycling is dictated by drying climate and rapid expansion of population in Australia. Constructed wetlands are environmentally-benign way to purify wastewater by removing inorganics and facilitating biodegradation of organic pollutants, thus producing recycled water that can be used in a variety of fit-for-purpose applications. This project will produce a decision-support system for optimising wetland performance in removing inorganics and biodegrading organic pollutants from wastewater, thus enhancing water recycling and reuse in this drying continent of ours.Read moreRead less
Multiscale Modelling and Thermal Design Optimisation of Large-Scale Biomass Stockpiles for Use in Renewable Energy Products. By minimising the risk of spontaneous combustion this project will significantly contribute to the ability of the Australian sugar industry to store wet bagasse (sugar cane fibre residue) in large stockpiles. This will facilitate the year-round availability of biomass as a feedstock in renewable energy production. The mathematical models developed in this project deliver a ....Multiscale Modelling and Thermal Design Optimisation of Large-Scale Biomass Stockpiles for Use in Renewable Energy Products. By minimising the risk of spontaneous combustion this project will significantly contribute to the ability of the Australian sugar industry to store wet bagasse (sugar cane fibre residue) in large stockpiles. This will facilitate the year-round availability of biomass as a feedstock in renewable energy production. The mathematical models developed in this project deliver an enabling mechanism for facilitating the diversification of the sugar industry with the potential to produce significant financial returns for the industry. This research has the potential to initiate considerable and extremely positive, down-stream environmental impacts for Australia by enhancing feedstock production for ecologically sustainable power generation systems.Read moreRead less
Functional Analyses of Bacteria Involved in Enhanced Biological Phosphorus Removal from Wastewater. The abundant growth of blue-green algae in global waterways is substantially caused by phosphorus (P) release from wastewater treatment plants. This environmental drama can be mitigated against by P-accumulating bacteria partitioning the P inside their cells. The P-removal process often fails, but since the metabolism of P-accumulating bacteria is unknown, remedial actions are based on conjecture ....Functional Analyses of Bacteria Involved in Enhanced Biological Phosphorus Removal from Wastewater. The abundant growth of blue-green algae in global waterways is substantially caused by phosphorus (P) release from wastewater treatment plants. This environmental drama can be mitigated against by P-accumulating bacteria partitioning the P inside their cells. The P-removal process often fails, but since the metabolism of P-accumulating bacteria is unknown, remedial actions are based on conjecture. This fundamental, knowledge-generating project will address this shortfall and will develop methods to evaluate the activity of P-accumulating bacteria, contributing substantial understanding of their metabolism. The final goal is to promote stable, reproducible P-removal from wastewater.Read moreRead less
The only constant is change: ecology and evolution of phage-host interactions in a model ecosystem. Microorganisms underpin life on Earth, but our understanding of their diversity and activity is limited by our inability to grow most of them in the laboratory. Recently, new techniques have emerged that allow access to the genetic information of all microorganisms by directly sequencing DNA and RNA from the environment. In this research we will further develop these frontier technologies, promoti ....The only constant is change: ecology and evolution of phage-host interactions in a model ecosystem. Microorganisms underpin life on Earth, but our understanding of their diversity and activity is limited by our inability to grow most of them in the laboratory. Recently, new techniques have emerged that allow access to the genetic information of all microorganisms by directly sequencing DNA and RNA from the environment. In this research we will further develop these frontier technologies, promoting this new area of science in Australia. We will apply these techniques to microbial communities involved in wastewater treatment in order to understand the interactions between microorganisms and the viruses that infect them. Understanding this interaction will have important implications for optimising these treatment processes.Read moreRead less