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
A Novel Hybrid Chemical Looping Process for Production of Liquid Hydrocarbon Fuels with a Reduced Greenhouse Gas Emissions Profile. This project determines the fundamental science underpinning the operation of a novel hybrid chemical looping carbon reforming (CLCR) process for production of alternative transportation fuels with a reduced greenhouse gas emissions profile. Compare with conventional processes, the CLCR process features a 50 per cent reduction in the energy and carbon dioxide footpr ....A Novel Hybrid Chemical Looping Process for Production of Liquid Hydrocarbon Fuels with a Reduced Greenhouse Gas Emissions Profile. This project determines the fundamental science underpinning the operation of a novel hybrid chemical looping carbon reforming (CLCR) process for production of alternative transportation fuels with a reduced greenhouse gas emissions profile. Compare with conventional processes, the CLCR process features a 50 per cent reduction in the energy and carbon dioxide footprints and represents a large sink for carbon dioxide sequestration if deployed widely. To achieve the broad objectives of the project comprehensive experimental and modelling studies will be carried out at macro, micro and molecular levels. Expected outcomes include fundamental knowledge essential to the development and commercial-scale deployment of the CLCR process.Read moreRead less