Resilient design of energy pile foundations toward zero carbon buildings. This project aims to investigate the complex thermo-hydro mechanical interactions affecting the effectiveness of energy pile foundations for improved energy efficiency of new buildings. Using cutting-edge micro to field-scale methods, this project expects to underpin the development of experimentally validated predictions of the geotechnical performance of energy piles. Expected outcomes of this project are the establishme ....Resilient design of energy pile foundations toward zero carbon buildings. This project aims to investigate the complex thermo-hydro mechanical interactions affecting the effectiveness of energy pile foundations for improved energy efficiency of new buildings. Using cutting-edge micro to field-scale methods, this project expects to underpin the development of experimentally validated predictions of the geotechnical performance of energy piles. Expected outcomes of this project are the establishment of new approaches to improve the resilient design of energy pile foundations, provision of new recommendations for their design and increased integration for zero carbon buildings. These outcomes will contribute significantly toward strategies to decarbonise energy systems in buildings to meet carbon neutrality goals.Read moreRead less
High quality and robust energy conversion systems for distribution networks. This project aims to protect distribution networks by reducing harmonics and electromagnetic Interference generated by modern power electronics equipment. Due to global demand for energy savings and reductions in greenhouse gas emissions, the utilisation of renewable energy sources and efficient loads using power electronics technology in distribution networks is increasing. Aspects of this technology are highly complex ....High quality and robust energy conversion systems for distribution networks. This project aims to protect distribution networks by reducing harmonics and electromagnetic Interference generated by modern power electronics equipment. Due to global demand for energy savings and reductions in greenhouse gas emissions, the utilisation of renewable energy sources and efficient loads using power electronics technology in distribution networks is increasing. Aspects of this technology are highly complex and not well understood and the robustness of existing and future power grids will be affected. The project will minimise risk factors associated with high frequency noise and resonances in low voltage grids both of which are very important for power electronics manufacturers and utility companies in Australia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100968
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Lifting the Veil on Turbulent Convective Heat Transfer over Rough Surfaces. By understanding the influence of surface roughness on convective heat transfer, this project intends to reduce the unwanted heating and energy losses associated with surface roughness in gas and steam turbines used in power generation and transportation. The surface roughness that results from extended operation of gas and steam turbines can significantly increase the heating of their surfaces, increasing fuel consumpti ....Lifting the Veil on Turbulent Convective Heat Transfer over Rough Surfaces. By understanding the influence of surface roughness on convective heat transfer, this project intends to reduce the unwanted heating and energy losses associated with surface roughness in gas and steam turbines used in power generation and transportation. The surface roughness that results from extended operation of gas and steam turbines can significantly increase the heating of their surfaces, increasing fuel consumption and greenhouse gas emissions, and reducing operational life. Improvements would allow turbines to operate at higher inlet temperatures which will increase their efficiency and reduce fuel use, environmental emissions and maintenance costs.Read moreRead less
Turbulent wall-bounded flow in adverse pressure gradient environments. This research will create additional research capacity in turbulence control and drag reduction. It will have direct benefits to the Australian economy via the transport industry by reducing the adverse impact of the carbon tax and rising fuel prices on long-haul air, water and road transport, on which Australia is disproportionately reliant.
Reducing the energy consumed by lighting with gaze-dependent illumination. Lighting consumes approximately 18% of electricity, but only a fraction of the light emitted into buildings actually supports occupants’ vision – the rest is wasted. This research aims to reduce the energy consumed by lighting by developing strategies for illuminating only the portions of architectural environments that are visible to occupants, thereby reducing unnecessary light. The impacts of gaze-dependent lighting on ....Reducing the energy consumed by lighting with gaze-dependent illumination. Lighting consumes approximately 18% of electricity, but only a fraction of the light emitted into buildings actually supports occupants’ vision – the rest is wasted. This research aims to reduce the energy consumed by lighting by developing strategies for illuminating only the portions of architectural environments that are visible to occupants, thereby reducing unnecessary light. The impacts of gaze-dependent lighting on energy consumption and the visual environment will be characterized and design guidelines will be generated to facilitate the development of innovative lighting systems that consume less energy by producing less light, without negatively impacting the visual experiences of building occupants.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100088
Funder
Australian Research Council
Funding Amount
$275,000.00
Summary
High-resolution molecular tagging velocimetry and thermometry facility. The facility will simultaneously measure the motion of a fluid and its temperature over an area within a flow. This capability will advance engineering and scientific aims to predict, and potentially control the behaviours of thermally influenced flows that are pervasive in biological, environmental, and energy-related applications.
Entrainment and Mixing in Turbulent Negatively Buoyant Jets and Fountains. The project intends to develop tools to accurate predict fountain flows. Volcanic eruptions, building ventilation and brine discharge from desalination plants are all examples of turbulent fountains and negatively buoyant jets. The project aims to conduct an investigation into the turbulent structure of fountains and negatively buoyant jets using numerical simulation and laboratory experiments, and to assess the accuracy ....Entrainment and Mixing in Turbulent Negatively Buoyant Jets and Fountains. The project intends to develop tools to accurate predict fountain flows. Volcanic eruptions, building ventilation and brine discharge from desalination plants are all examples of turbulent fountains and negatively buoyant jets. The project aims to conduct an investigation into the turbulent structure of fountains and negatively buoyant jets using numerical simulation and laboratory experiments, and to assess the accuracy of the commonly used integral models and test the effect of the use of more accurate entrainment relations. This may have a range of applications – enabling better prediction of environmental impacts, reduction of the adverse effects of the discharge of pollutants, and reduction in energy consumption in building ventilation and other industrial applications.Read moreRead less
Structurally designed catalysts for high-performance natural gas reforming. This project aims to develop a new class of highly stable catalysts with specially designed physical and chemical structures that can be used in high temperature chemical processes. These catalysts can potentially be used for the reforming of natural gas to produce the synthesis gas, which can then be used to produce liquid fuels and chemicals.
Towards energy-efficient lighting based on light-emitting diodes: the role of silicon carbide grown on Si Wafers. This project will investigate a potential solution to the problems of cost and quality of light-emitting diodes for solid-state lighting. The expected outcome is knowledge to underpin future development of solid-state lighting that is suitable for a wide replacement of the much less efficient and effective incandescent bulbs and fluorescent tubes.
Discovery Early Career Researcher Award - Grant ID: DE120102836
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
A novel fully inorganic quantum dots based solar cell. A fully-inorganic quantum dots solar cell will be constructed by using cheap chemical solution techniques. The development of the new 3rd generation solar cell is aimed to realise the high-efficiency, low-cost, and well-stability of solar cells. It would dramatically increase commercial viability of quantum solar cells.