Swirling turbulent pipe flow technology for drying brown coal. This project aims to understand the complex fluid mechanicalprocesses in a brown coal drying machine. Brown coal from the Latrobe Valley contains about 70 percent moisture, which must be reduced for it to be used efficiently in power stations. Utilising cutting-edge techniques in laboratory and field measurements together with advanced computational methods in fluid mechanics, the project intends to further knowledge in swirling turb ....Swirling turbulent pipe flow technology for drying brown coal. This project aims to understand the complex fluid mechanicalprocesses in a brown coal drying machine. Brown coal from the Latrobe Valley contains about 70 percent moisture, which must be reduced for it to be used efficiently in power stations. Utilising cutting-edge techniques in laboratory and field measurements together with advanced computational methods in fluid mechanics, the project intends to further knowledge in swirling turbulent flows, particle transport and vortex breakdown. The result of this research is expected to produce a drier brown coal, leading to a cleaner environment and an increase in Australian coal value. Read moreRead less
Aerodynamic enhancement of the capture of fine particle emissions and gaseous pollutants by sorbents. Fine particulate emissions alone, and just within Australia's four largest cities, are estimated to be responsible for some 1600 deaths annually, and are a leading cause of asthma and other lung disease. Hence the economic and social benefits of greatly reducing fine particulate emissions is enormous. Similar benefits can be expected to arise from the enhanced capture of SOx, NOx and heavy metal ....Aerodynamic enhancement of the capture of fine particle emissions and gaseous pollutants by sorbents. Fine particulate emissions alone, and just within Australia's four largest cities, are estimated to be responsible for some 1600 deaths annually, and are a leading cause of asthma and other lung disease. Hence the economic and social benefits of greatly reducing fine particulate emissions is enormous. Similar benefits can be expected to arise from the enhanced capture of SOx, NOx and heavy metals. Many of these pollutants also contribute to the greenhouse effect, so the international exploitation of the technology will also help to mitigate climate change. Should suitable sorbents be developed for CO2 capture, the technology will also enhance carbon capture and storage.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347603
Funder
Australian Research Council
Funding Amount
$260,876.00
Summary
Integrated Facility for Interfacial Rheology Analysis. This proposal seeks to establish a state-of-the-art facility for interfacial rheology analysis. The proposed facility will be unique in Australia and bring together leading researchers from the Universities of Newcastle, Melbourne and South Australia. The facility will allow direct measurements of physical properties at fluid-liquid interfaces which are needed for ongoing research in froth flotation, food processing and surfactant applicatio ....Integrated Facility for Interfacial Rheology Analysis. This proposal seeks to establish a state-of-the-art facility for interfacial rheology analysis. The proposed facility will be unique in Australia and bring together leading researchers from the Universities of Newcastle, Melbourne and South Australia. The facility will allow direct measurements of physical properties at fluid-liquid interfaces which are needed for ongoing research in froth flotation, food processing and surfactant applications as well as to develop new processes in emerging fields of nanotechnology, biotechnology, and medical and pharmaceutical production.Read moreRead less
New understanding and models for two-phase solar thermal particle receivers. The project aims to provide the new understanding of, and computational design tools for, next generation solar thermal particle receivers and their hybrids. Particle receivers, which heat fine particles in suspension, offer much greater efficiency than current tubular receivers, but are presently unreliable due to the poor understanding of the complex and coupled mechanisms that govern their performance. The results ar ....New understanding and models for two-phase solar thermal particle receivers. The project aims to provide the new understanding of, and computational design tools for, next generation solar thermal particle receivers and their hybrids. Particle receivers, which heat fine particles in suspension, offer much greater efficiency than current tubular receivers, but are presently unreliable due to the poor understanding of the complex and coupled mechanisms that govern their performance. The results are expected to speed up the development and roll-out of these devices, to deliver cost-effective, low-emissions energy technologies for future power generation and thermo-chemical processes. The aims will be met by the parallel application of advanced laser diagnostic measurements and computational fluid dynamics modelling techniques.Read moreRead less
Heat transfer in novel solar thermal reactors to process minerals and solar fuels. The project will develop new design tools for optimising novel solar reactors for the production of solar fuels and for low emission minerals processing. It will enable substantial cost reductions in these technologies and establish a unique and leading program in solar power tower technology within Australia.