Combined Ozonation-Flotation for the Treatment of Potable Water. Water Authorities are tightly regulated to guarantee removal of pollutants such as algal cells and toxins, cryptosporidium oocysts, and geosmin from drinking water. Processing options such as membrane filtration are effective but become very expensive when continuously operated to protect against occasional contamination events. This project aims to develop a fully-integrated process combining flotation and ozonation which can be ....Combined Ozonation-Flotation for the Treatment of Potable Water. Water Authorities are tightly regulated to guarantee removal of pollutants such as algal cells and toxins, cryptosporidium oocysts, and geosmin from drinking water. Processing options such as membrane filtration are effective but become very expensive when continuously operated to protect against occasional contamination events. This project aims to develop a fully-integrated process combining flotation and ozonation which can be operated continuously when required in a number of different modes to provide a barrier against a range of contamination events. The process utilises much of the existing water treatment infrastructure reducing capital and operating costs.Read moreRead less
Ozone-Enhanced Particle Removal in Water Treatment. Combined ozonation/biologically active carbon filtration provides effective contaminant removal while minimizing disinfection by-product formation. However, the cost of installation in conventional water treatment plants is very high. This project will investigate the beneficial influence of ozonation on the micro-flocculation of small particles, with the aim to optimising particle removal by sedimentation prior to filtration. To do this, requi ....Ozone-Enhanced Particle Removal in Water Treatment. Combined ozonation/biologically active carbon filtration provides effective contaminant removal while minimizing disinfection by-product formation. However, the cost of installation in conventional water treatment plants is very high. This project will investigate the beneficial influence of ozonation on the micro-flocculation of small particles, with the aim to optimising particle removal by sedimentation prior to filtration. To do this, requires a clear understanding of how dissolved ozone interacts with particle surfaces for different water chemistries. The ideal outcome would be to develop a robust water treatment system that required BAC filtration only and eliminated the need for a conventional sand filtration stage as well.Read moreRead less
Supported biomass membrane bioreactor: optimisation of aeration for better fouling control. This project will lead to a sustainable, affordable, energy-efficient treatment system for water reuse. The technology developed will particularly benefit small sewage treatment plants in coastal and isolated communities in Australia, by maximising the utilisation of water resources where water is limited, and by reducing the environmental impact of waste discharges. This project will also strengthen rese ....Supported biomass membrane bioreactor: optimisation of aeration for better fouling control. This project will lead to a sustainable, affordable, energy-efficient treatment system for water reuse. The technology developed will particularly benefit small sewage treatment plants in coastal and isolated communities in Australia, by maximising the utilisation of water resources where water is limited, and by reducing the environmental impact of waste discharges. This project will also strengthen research links between Australian and European institutions through the development of this innovative technology. Local water industries will directly benefit from this frontier research.Read moreRead less
Membranes coupled with physico-chemcial treatment in water reuse: New hybrid systems development and fouling assessment. This project will be useful to sewage treatment systems prevalent in the coastal areas of NSW and Queensland and the interior parts of Northern Territory with isolated communities. Membrane processes are a sustainable technology in wastewater treatment for reuse. The novel pre-treatment and fouling assessment protocol proposed in this study are the keys for the cost-effective ....Membranes coupled with physico-chemcial treatment in water reuse: New hybrid systems development and fouling assessment. This project will be useful to sewage treatment systems prevalent in the coastal areas of NSW and Queensland and the interior parts of Northern Territory with isolated communities. Membrane processes are a sustainable technology in wastewater treatment for reuse. The novel pre-treatment and fouling assessment protocol proposed in this study are the keys for the cost-effective and energy-efficient operation and testing of membrane processes. This project will strengthen research links between Australian and European universities, through the development of an innovative pre-treatment technology. The technology is of direct benefit to reuse applications in Australia and has significant export potential.Read moreRead less
Recycling water and nutrients using a high-rate membrane bioreactor coupled with an ion-exchange system. Australia urgently needs to recycle both water and nutrients to protect its rivers and sustain its agriculture. This project will yield a sustainable, energy-efficient treatment system for water reuse and nutrient recovery. The technology's greater economy and efficiency will benefit decentralised systems in urban centres and small sewage treatment plants in isolated communities alike by en ....Recycling water and nutrients using a high-rate membrane bioreactor coupled with an ion-exchange system. Australia urgently needs to recycle both water and nutrients to protect its rivers and sustain its agriculture. This project will yield a sustainable, energy-efficient treatment system for water reuse and nutrient recovery. The technology's greater economy and efficiency will benefit decentralised systems in urban centres and small sewage treatment plants in isolated communities alike by enabling greater water reuse and by reducing the environmental impact of waste discharges. It will be of immediate benefit to the Australian water industry and to exports. This project will strengthen links in water science between Australian and European institutions.Read moreRead less
Cost effective in-line filtration system to improve water quality in rainwater tanks. This research will provide the basis for developing an affordable and innovative water treatment solution for domestic rainwater collection systems. The main elements of this research are:
. Provision of a cost -effective submerged membrane operated under gravity to provide water of potable standard.
. Establishing an adaptive membrane cleaning system using the concept of volume control.
. Characterisati ....Cost effective in-line filtration system to improve water quality in rainwater tanks. This research will provide the basis for developing an affordable and innovative water treatment solution for domestic rainwater collection systems. The main elements of this research are:
. Provision of a cost -effective submerged membrane operated under gravity to provide water of potable standard.
. Establishing an adaptive membrane cleaning system using the concept of volume control.
. Characterisation protocol of membrane fouling and stored rain water.
. Sizing of a permeate tank for storing treated water through demand management.
This project will increase the use of rainwater tanks, helping available water resources to go further.Read moreRead less
Cost effective treatment system for stormwater harvesting for medium scale developments. Stormwater harvesting is central to the integrated water cycle management approach now being formally endorsed by all tiers of governments as the best way to manage our water resources. Despite its immense potential, stormwater harvesting in urban centres throughout Australia is largely limited to household rainwater tanks. By developing economical and efficient treatment systems suitable for medium density ....Cost effective treatment system for stormwater harvesting for medium scale developments. Stormwater harvesting is central to the integrated water cycle management approach now being formally endorsed by all tiers of governments as the best way to manage our water resources. Despite its immense potential, stormwater harvesting in urban centres throughout Australia is largely limited to household rainwater tanks. By developing economical and efficient treatment systems suitable for medium density developments, this project will maximise the resource value of stormwater, and reduce demand on water supply systems. The project will lead to the development of medium sized communities within larger urban centres that maximises its use of stormwater for water needs.Read moreRead less
Determination of the fate of dissolved organic nitrogen in biological nutrient removal (BNR) processes and development of appropriate treatment technologies. The aim of this project is to better characterise the dissolved organic nitrogen (DON) in sewage treatment plant influent, determine its fate in biological nutrient removal (BNR) plants, and to evaluate and develop an appropriate treatment technology.
As a result of tightening effluent N licence requirements for sewage treatment plants, ....Determination of the fate of dissolved organic nitrogen in biological nutrient removal (BNR) processes and development of appropriate treatment technologies. The aim of this project is to better characterise the dissolved organic nitrogen (DON) in sewage treatment plant influent, determine its fate in biological nutrient removal (BNR) plants, and to evaluate and develop an appropriate treatment technology.
As a result of tightening effluent N licence requirements for sewage treatment plants, the dissolved organic nitrogen (DON) fraction has become extremely important. In many cases, the DON forms the major fraction of the effluent N, and is constraining further reductions in licence specifications, and in some cases it is the cause of failure to meet licence.
DON is refractory (un-biodegradable), very poorly characterised, its fate in conventional biological treatment processes not known, and its eventual impact on the environment unknown. Considering its importance, it is critical that these issues are addressed. This proposal intends to address some of them.
This project is an APA(I) PhD student project.Read moreRead less
Production of Biodegradable Polyhydroxyalkanoate Polymers using Advanced Biological Wastewater Treatment Process Technology. The aim of this project is to develop a sustainable process for producing biodegradable polyhydroxyalkanoate (PHAs)polymers from an innovative aerobic-anaerobic biological wastewater treatment process, ?treating? high strength food industry effluent. These biopolymers offer enormous potential for use as renewable and biodegradable thermoplastics.
It is proposed to inve ....Production of Biodegradable Polyhydroxyalkanoate Polymers using Advanced Biological Wastewater Treatment Process Technology. The aim of this project is to develop a sustainable process for producing biodegradable polyhydroxyalkanoate (PHAs)polymers from an innovative aerobic-anaerobic biological wastewater treatment process, ?treating? high strength food industry effluent. These biopolymers offer enormous potential for use as renewable and biodegradable thermoplastics.
It is proposed to investigate two process configurations, namely the sequencing batch reactor and a continuous two step anaerobic-aerobic reaction system. These will be studied at bench-scale. The outcomes include:
1. Determination of the optimum microbial conditions and key growth
parameters for the production of PHA.
2. Optimisation of the process configuration, operating strategies
and operating conditions to maximise the
production of PHA.
3. Assessment of the influence of the feed composition (e.g. VFA)
on the PHA composition (PHB/PHV).
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Development of a Nitrogen Removal Technology to Integrate with the Novel ‘EnRec’ Energy Recovery Sewage Treatment Process. The aim of this project is to develop a nitrogen removal technology to integrate with the novel energy recovery sewage treatment process, EnRec. EnRec is presently being developed as part of a collaborative R&D activity between the partners, and is partly supported by a Queensland Government (QSEIF) grant which was awarded in November 2002.
One important issue yet to b ....Development of a Nitrogen Removal Technology to Integrate with the Novel ‘EnRec’ Energy Recovery Sewage Treatment Process. The aim of this project is to develop a nitrogen removal technology to integrate with the novel energy recovery sewage treatment process, EnRec. EnRec is presently being developed as part of a collaborative R&D activity between the partners, and is partly supported by a Queensland Government (QSEIF) grant which was awarded in November 2002.
One important issue yet to be addressed is how to achieve nitrogen removal in the EnRec process. One of the major differences between the EnRec process and conventional sewage treatment technology is that the main process reactor is anaerobic, thus eliminating aeration costs and enabling methane production. However, anaerobic treatment processes do not provide significant nitrogen removal, and thus it will be necessary to integrate a nitrogen removal technology with the main energy recovery process. This is the aim of this project.
The project is an APA(I) PhD student project.Read moreRead less