Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100079
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
A thermally stratified Sea-Ice-Wave Interaction Facility. A thermally stratified sea ice wave interaction facility: Predictions of climate change now impact all levels of society as future political, social and environmental plans are made on the basis of these models. Predictions require models of many complex dynamical processes with a wide range of parameters. An important process is the Marginal Ice Zone (MIZ) dynamics. The MIZ is the region between the open ocean and the fully ice-covered o ....A thermally stratified Sea-Ice-Wave Interaction Facility. A thermally stratified sea ice wave interaction facility: Predictions of climate change now impact all levels of society as future political, social and environmental plans are made on the basis of these models. Predictions require models of many complex dynamical processes with a wide range of parameters. An important process is the Marginal Ice Zone (MIZ) dynamics. The MIZ is the region between the open ocean and the fully ice-covered ocean where waves and ice interact, causing ice-breaking and wave attenuation. This unique facility will enable experiments in sea-ice-wave interactions in a controlled environment. Water and air temperature, thermal stratification, water waveform and ice properties will be adjusted in order to preserve key characteristics of the complex ocean environment.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.
Understanding particle-laden flows for clean high temperature processes. This project aims to understand and provide computational design tools for the complex heat and mass transfer processes within the new technologies that needed for the high temperature processing of minerals with low net carbon dioxide (CO2) emissions, both with and without the use of concentrated solar thermal energy. These models are needed to achieve low-cost scale-up and development of the new technologies under develop ....Understanding particle-laden flows for clean high temperature processes. This project aims to understand and provide computational design tools for the complex heat and mass transfer processes within the new technologies that needed for the high temperature processing of minerals with low net carbon dioxide (CO2) emissions, both with and without the use of concentrated solar thermal energy. These models are needed to achieve low-cost scale-up and development of the new technologies under development, because they operate in regimes of particle-laden flow for which present numerical design tools are unreliable. The project will underpin the development of new technologies that are needed for Australia to meet its greenhouse emissions targets and to capitalise on the anticipated global demand for low-carbon-intensive metals and other value-added products.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100220
Funder
Australian Research Council
Funding Amount
$760,000.00
Summary
Adaptive Electrical Capacitance Volume Tomography for Multiphase Flows. This project aims to establish a cutting edge adaptive electrical capacitance volume tomography facility for real-time metering / imaging of multi-phase flows. Optimisation of these flows which are encountered in many industries, is paramount in today's carbon-constrained global economy. This project expects to generate the new knowledge necessary for such optimisations. Expected outcomes include enhanced national capability ....Adaptive Electrical Capacitance Volume Tomography for Multiphase Flows. This project aims to establish a cutting edge adaptive electrical capacitance volume tomography facility for real-time metering / imaging of multi-phase flows. Optimisation of these flows which are encountered in many industries, is paramount in today's carbon-constrained global economy. This project expects to generate the new knowledge necessary for such optimisations. Expected outcomes include enhanced national capability for characterisation of multi-phase flows in real-time under both ambient and high temperatures. This should benefit and greatly facilitate the commercial rollout of novel technologies in industrial sectors as diverse as mineral processing, clean energy, fuels/chemicals, oil/gas, food and environmental remediation. Read moreRead less