Confined comminution and particle flow: a general model for large-scale canonical solutions. The project integrates recent advances in continuum mechanics to develop a novel theory of comminution for large-scale problems of grain-size reduction, beyond the reach of particle-based simulations. We will deliver new knowledge and predictive tools by solving fundamental and significant comminution problems. Underpinning this development will be a direct link between energy and particle kinematics. Th ....Confined comminution and particle flow: a general model for large-scale canonical solutions. The project integrates recent advances in continuum mechanics to develop a novel theory of comminution for large-scale problems of grain-size reduction, beyond the reach of particle-based simulations. We will deliver new knowledge and predictive tools by solving fundamental and significant comminution problems. Underpinning this development will be a direct link between energy and particle kinematics. This unique methodology will enable the prediction of energy flow in fault zones, and energy losses from machine to particle and between particles.Read moreRead less
Novel technology for enhanced coal seam gas production utilising mechanisms of stimulated cleat permeability through graded particle injection. This cross-disciplinary project will develop a new integrated technology for well productivity enhancement in coal seam gas, shale, tight gas and geothermal reservoirs - the world’s fastest growing unconventional clean energy resources. It will improve our understanding of the multi scale physics of natural gas and energy production.
Multiphysics instabilities during diagenesis of shale gas reservoirs. This project aims to understand the formation, geometry and fluid connectivity of unconventional high-temperature and high pressure shale gas reservoirs using volumetric instabilities of ductile materials. Unconventional shale gas/oil are the most abundant fossil fuel resources on Earth, but are inaccessible to conventional techniques. This project will investigate the mechanisms, critical parameters and applicability of the t ....Multiphysics instabilities during diagenesis of shale gas reservoirs. This project aims to understand the formation, geometry and fluid connectivity of unconventional high-temperature and high pressure shale gas reservoirs using volumetric instabilities of ductile materials. Unconventional shale gas/oil are the most abundant fossil fuel resources on Earth, but are inaccessible to conventional techniques. This project will investigate the mechanisms, critical parameters and applicability of the theory to unconventional reservoirs. It will do so by testing the theory under controlled laboratory experiments, fully coupled thermo-hydro-mechanical-chemical (THMC) modelling and analytical modelling. The outcomes should allow a rigorous assessment of the potential of unconventional reservoirs under Australia’s extreme conditions.Read moreRead less
Quantification of Multiphysics phenomena of Gas flow in organic rich shales. We address the scientific question of the nature of gas extraction from nominally impermeable rocks such as shales. Our main aim is to develop a fully coupled microstructurally enriched thermodynamic continuum model to predict the Multiphysics behaviour of shale reservoirs during gas production and verify the model with representative experiments conducted on formations from three Australian Basins including Cooper, Per ....Quantification of Multiphysics phenomena of Gas flow in organic rich shales. We address the scientific question of the nature of gas extraction from nominally impermeable rocks such as shales. Our main aim is to develop a fully coupled microstructurally enriched thermodynamic continuum model to predict the Multiphysics behaviour of shale reservoirs during gas production and verify the model with representative experiments conducted on formations from three Australian Basins including Cooper, Perth and Beetaloo, where the samples are available to the investigators. We approach this problem in a hybrid theoretical-numerical-experimental study. This is the first international attempt to develop such experimentally verified thermodynamic based model, particularly for Australian shales.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100095
Funder
Australian Research Council
Funding Amount
$620,000.00
Summary
High-resolution X-ray micro computed tomography supporting West Australian geo-, physical and biological science. An X-ray micro computed tomography facility will provide West Australian researchers with much needed access to cutting-edge instrumentation for high-resolution three-dimensional imaging. This facility will support major research programs in key disciplines, including minerals and mining, energy, medical and biological sciences.