Membrane distillation development for concentrated solar thermal systems. Membrane distillation development for concentrated solar thermal systems. This project aims to develop a new membrane distillation module that works with a high efficiency solar thermal tower system. Fresh water and energy are inextricably linked and form the basis for all human activity. Remote locations in Australia and the Middle East and North Africa are blessed with abundant solar resources and increasing levels of de ....Membrane distillation development for concentrated solar thermal systems. Membrane distillation development for concentrated solar thermal systems. This project aims to develop a new membrane distillation module that works with a high efficiency solar thermal tower system. Fresh water and energy are inextricably linked and form the basis for all human activity. Remote locations in Australia and the Middle East and North Africa are blessed with abundant solar resources and increasing levels of development, but burdened by access to reliable water treatment and electricity generation facilities. This project will use recently developed materials and design tools to overcome technical challenges that limited membrane distillation technology. This is expected to open up an innovative method for co-production of water and electricity which can handle transient solar and water quality inputs.Read moreRead less
Novel inkjet-printed organic solvent nanofiltration membranes. The pharmaceutical industry is one of fastest growing industries in Australia. Manufacturing pharmaceutical products requires the use of hazardous and expensive organic solvents, which are toxic for the environment and expensive to recover due to the energy intensive thermal process required. This project aims to discover and manufacture a novel, low-cost, chemically robust nanomaterial-based membrane using an industry scalable inkje ....Novel inkjet-printed organic solvent nanofiltration membranes. The pharmaceutical industry is one of fastest growing industries in Australia. Manufacturing pharmaceutical products requires the use of hazardous and expensive organic solvents, which are toxic for the environment and expensive to recover due to the energy intensive thermal process required. This project aims to discover and manufacture a novel, low-cost, chemically robust nanomaterial-based membrane using an industry scalable inkjet printing process. The membrane will be resistant to organic solvents while efficiently recovering valuable and hazardous organic solvents with minimum environmental footprint. It will effectively provide for the future growth of the Australian pharmaceutical industry while also having global applications.Read moreRead less
Optimising nanofiltration and reverse osmosis filtration processes for water recycling: effects of fouling and chemical cleaning on trace contaminant removal. In Australia, water recycling is considered a principal measure to manage the current ongoing water shortage and to better protect the environment. Membrane filtration processes play important roles in the treatment of reclaimed municipal wastewater. However, there is very limited knowledge regarding the reliability of such processes in re ....Optimising nanofiltration and reverse osmosis filtration processes for water recycling: effects of fouling and chemical cleaning on trace contaminant removal. In Australia, water recycling is considered a principal measure to manage the current ongoing water shortage and to better protect the environment. Membrane filtration processes play important roles in the treatment of reclaimed municipal wastewater. However, there is very limited knowledge regarding the reliability of such processes in removing trace contaminants from recycled water, which may result in unintended health consequences. This research will lead to a comprehensive understanding of the removal process of such contaminants by membrane filtration. Consequently, the likely avenue of risk can be eliminated and the treatment process can be optimised to achieve economic savings and environmental protection.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101687
Funder
Australian Research Council
Funding Amount
$340,000.00
Summary
Nanostructure Tailoring of Inorganic Membranes by Rapid Thermal Processing. This project aims to produce inorganic membranes with desired nanostructures using a Rapid Thermal Processing (RTP) technique for gas separation applications. The key concept of the research is that the RTP will be able to achieve thin-film membrane layer with a finer microstructure and pore size control without heat stress-induced cracking. RTP aims to deliver superior membrane performance with less than 10 per cent of ....Nanostructure Tailoring of Inorganic Membranes by Rapid Thermal Processing. This project aims to produce inorganic membranes with desired nanostructures using a Rapid Thermal Processing (RTP) technique for gas separation applications. The key concept of the research is that the RTP will be able to achieve thin-film membrane layer with a finer microstructure and pore size control without heat stress-induced cracking. RTP aims to deliver superior membrane performance with less than 10 per cent of the fabrication time compared to normal slow calcination. The outcomes of this new technology aims to make inorganic membranes a commercial reality and maximize the membrane manufacturing capability and productivity of petrochemcial, chemical and clean coal/energy industries.Read moreRead less
Innovative High Temperature Carbon–Air Batteries for High Power Generation. The project intends to develop carbon-air batteries which are expected to have energy density 10 times that of lithium-ion batteries. The battery is designed to use naturally-rich carbon as fuel, highly energy-efficient solid oxide fuel cells as electrochemical reactors, and an integrated mixed conducting ceramic membrane for in situ carbon dioxide separation. The success of this project would provide us with a low-carbo ....Innovative High Temperature Carbon–Air Batteries for High Power Generation. The project intends to develop carbon-air batteries which are expected to have energy density 10 times that of lithium-ion batteries. The battery is designed to use naturally-rich carbon as fuel, highly energy-efficient solid oxide fuel cells as electrochemical reactors, and an integrated mixed conducting ceramic membrane for in situ carbon dioxide separation. The success of this project would provide us with a low-carbon energy system based on Australia’s rich coal resources. New knowledge about carbon dioxide separation may also facilitate carbon dioxide sequestration in other fields.Read moreRead less
Development of smart material for the adsorption of oil spills on roads. The cost of road fuel spills in both Australia and worldwide is enormous. The research objective is to develop an admixture suitable for the absorption/adsorption of fuel and oil from road spills. The material will be designed to be contained within a fabric. The innovation is the application of the admixture in the form of a carpet, which is designed as easily used, non-toxic, recyclable and environmentally friendly. T ....Development of smart material for the adsorption of oil spills on roads. The cost of road fuel spills in both Australia and worldwide is enormous. The research objective is to develop an admixture suitable for the absorption/adsorption of fuel and oil from road spills. The material will be designed to be contained within a fabric. The innovation is the application of the admixture in the form of a carpet, which is designed as easily used, non-toxic, recyclable and environmentally friendly. The application is rapid. The successful development of the material has enormous economic benefits to Australia, providing a new industry with many employees. This new industry has the potential to bring great wealth to Australia.Read moreRead less
Rare Earth Metal Separation by Polymer Inclusion Membranes. The project aims to develop a novel hydrometallurgical method for the separation of the rare earth metals dysprosium and terbium from mixed rare earth metal solutions using polymer inclusion membranes with a crosslinked or non-crosslinked polymer backbone. These metals are crucial for the manufacturing of advanced technology products. The membrane-based method is expected to offer significant advantages over the currently used solvent e ....Rare Earth Metal Separation by Polymer Inclusion Membranes. The project aims to develop a novel hydrometallurgical method for the separation of the rare earth metals dysprosium and terbium from mixed rare earth metal solutions using polymer inclusion membranes with a crosslinked or non-crosslinked polymer backbone. These metals are crucial for the manufacturing of advanced technology products. The membrane-based method is expected to offer significant advantages over the currently used solvent extraction methods by eliminating the use of solvents and conducting the separation as a continuous process where the extraction and back-extraction steps take place simultaneously. These advantages are expected to make the separation process more cost-effective and drastically reduce its environmental impact.Read moreRead less
Overcoming performance limiting chemistries in membrane distillation. This project aims to study performance limiting chemistries associated with fouling of solution-borne components on membrane surfaces that cause critical vapour pressure loss. Membrane distillation could be used for sustainable resource recovery, but no research has overcome the total loss of membrane water flux when removing water from saturated solutions where the critical resource recovery function occurs. This project will ....Overcoming performance limiting chemistries in membrane distillation. This project aims to study performance limiting chemistries associated with fouling of solution-borne components on membrane surfaces that cause critical vapour pressure loss. Membrane distillation could be used for sustainable resource recovery, but no research has overcome the total loss of membrane water flux when removing water from saturated solutions where the critical resource recovery function occurs. This project will characterise the physical and chemical properties of the flux limiting solid on the membrane surface, and the role of membrane chemistry and functional conditions in overcoming this limit. The outcomes of the work will provide innovative sustainable solutions to recover valuable products from current wastes.Read moreRead less
The Effective Treatment of Hot Dip Galvanizing Effluent Streams. Hot Dip galvanizing effluent represents a significant environmental hazard. This wastewater is currently trucked offsite and treated by contractors to precipitate a heavy metal sludge that is disposed of through landfill. Industrial Galvanisers, as the largest hot dip galvanizing company within Australia, are keen to eliminate this hazard. We will consider the use of an innovative membrane based process for this purpose; to recover ....The Effective Treatment of Hot Dip Galvanizing Effluent Streams. Hot Dip galvanizing effluent represents a significant environmental hazard. This wastewater is currently trucked offsite and treated by contractors to precipitate a heavy metal sludge that is disposed of through landfill. Industrial Galvanisers, as the largest hot dip galvanizing company within Australia, are keen to eliminate this hazard. We will consider the use of an innovative membrane based process for this purpose; to recover valuable zinc and iron compounds from the effluent and allow the water to be re-utilised. If successful, this project will lead to a pilot plant wastewater treatment plant being constructed at an Industrial Galvanizers site.Read moreRead less
The Treatment Of Galvanizing Wastewater: Delivering An Environmentally And Economically Sustainable Approach. This project will investigate a process to treat wastewater from industrial galvanizing sites around Australia. When implemented, the process will substantially reduce the consumption of acid and fresh water at these sites. Further, the process will recover the zinc content of the wastewater in a saleable form and can also generate ferric chloride for sale as a water treatment chemical. ....The Treatment Of Galvanizing Wastewater: Delivering An Environmentally And Economically Sustainable Approach. This project will investigate a process to treat wastewater from industrial galvanizing sites around Australia. When implemented, the process will substantially reduce the consumption of acid and fresh water at these sites. Further, the process will recover the zinc content of the wastewater in a saleable form and can also generate ferric chloride for sale as a water treatment chemical. The quantity of heavy metals disposed to landfill will also be dramatically reduced. Scientific knowledge of multicomponent liquid-liquid equilibria will be of value to a wider range of solvent extraction processes including zinc and copper metal refining.Read moreRead less