Development of a low emission, pulverised fuel rotary kiln burner utilising a low pressure-drop, oscillating jet nozzle. A low pressure-drop oscillating jet nozzle, developed recently by the investigators, will be applied to pulverised fuel combustion to provide an advanced, low emission burner for the cement industry. This design is expected to overcome the high pressure drop of the present design which limits its range of application. The program will apply advanced measurement techniques to ....Development of a low emission, pulverised fuel rotary kiln burner utilising a low pressure-drop, oscillating jet nozzle. A low pressure-drop oscillating jet nozzle, developed recently by the investigators, will be applied to pulverised fuel combustion to provide an advanced, low emission burner for the cement industry. This design is expected to overcome the high pressure drop of the present design which limits its range of application. The program will apply advanced measurement techniques to study the aerodynamic behaviour of particles, which control many aspects of the combustion. These will be used to advance understanding and for the development and validation of computational fluid dynamics (CFD) models. A preferred design will be assessed in FCT's model lab and then in full-scale trials.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882833
Funder
Australian Research Council
Funding Amount
$120,000.00
Summary
Advanced infrared imaging facility for micro to macro systems. This state-of-the-art infrared imaging equipment will provide significant benefits towards research and development in a wide variety of important areas such as: green house gas reduction through efficient and clean energy production and usage, using solar thermal and solar photovoltaic energy; understanding fire propagation in buildings, and efficiently growing stem cells. This equipment will help maintain Australia's position as a ....Advanced infrared imaging facility for micro to macro systems. This state-of-the-art infrared imaging equipment will provide significant benefits towards research and development in a wide variety of important areas such as: green house gas reduction through efficient and clean energy production and usage, using solar thermal and solar photovoltaic energy; understanding fire propagation in buildings, and efficiently growing stem cells. This equipment will help maintain Australia's position as a leader in these fields, and thus attract international customers to research and development services in rapidly growing markets such as alternative/renewable energy and biotechnology.Read moreRead less
Radiative Cooling Tuned to the Spectral and Directional Infra-red Properties of the Atmosphere. Growth in the demand for cooling in Australia is a main driver for new power stations while global warming adds to cooling and refrigeration needs. This project extends Australia's leading expertise in solar control using nanoparticles into the area of active and passive cooling, enabling cooling at night to temperatures well below ambient, with little or no power and low cost. 'Cool' will be stored ....Radiative Cooling Tuned to the Spectral and Directional Infra-red Properties of the Atmosphere. Growth in the demand for cooling in Australia is a main driver for new power stations while global warming adds to cooling and refrigeration needs. This project extends Australia's leading expertise in solar control using nanoparticles into the area of active and passive cooling, enabling cooling at night to temperatures well below ambient, with little or no power and low cost. 'Cool' will be stored simply for use the next day. Our systems also allow efficient and low cost water condensation from the atmosphere. They will be of major benefit to developing countries in warm climate zones. High value products will follow, from paints to low cost cooling technology with energy savings around 50% or more.Read moreRead less
Development of Solid-state cooling chips. The performance of modern electronic, microelectronic, optoelectronic and photonic devices improves as they are cooled. We aim to develop semiconductor cooling elements that can be directly integrated into existing circuits and devices. The new solid-state cooling elements will be reliable, robust, scalable and operate in any orientation. The proposed international collaboration combines the expertise of the Chinese Academy of Science in device fabricat ....Development of Solid-state cooling chips. The performance of modern electronic, microelectronic, optoelectronic and photonic devices improves as they are cooled. We aim to develop semiconductor cooling elements that can be directly integrated into existing circuits and devices. The new solid-state cooling elements will be reliable, robust, scalable and operate in any orientation. The proposed international collaboration combines the expertise of the Chinese Academy of Science in device fabrication with the expertise of the University of Wollongong in device characterisation and modelling. The outcome of this research has the potential to revolutionize cooling of diverse electronic systems, from computer motherboards to mobile phones.Read moreRead less