Heat transfer and fluid flow in geomaterials: Physics-inspired AI framework. Processes involving fluid flow or heat transfer are of critical importance in engineering applications (e.g., in dams, geothermal systems, oil & gas production). Though largely overlooked, microstructural features control these processes in geomaterials. This project aims to exploit advances in high-resolution 4D imaging to extract essential microstructural information to: 1) identify new parameters that better capture ....Heat transfer and fluid flow in geomaterials: Physics-inspired AI framework. Processes involving fluid flow or heat transfer are of critical importance in engineering applications (e.g., in dams, geothermal systems, oil & gas production). Though largely overlooked, microstructural features control these processes in geomaterials. This project aims to exploit advances in high-resolution 4D imaging to extract essential microstructural information to: 1) identify new parameters that better capture pore and particle properties, connectivities and pathways, and 2) develop advanced predictive analytics tools. This will improve fundamental understanding of the link between microstructure and fluid and heat flows at the engineering scale, and provide predictive tools to reduce risk and costs to industry.Read moreRead less
Smart site investigation for offshore energy installations in sand . This project aims to develop a next generation tool for seabed site investigations. It will use free-fall penetrometers, advanced physical modelling and novel probabilistic methods to investigate fundamental science of sand responses at low stress level and generate new interpretation methods. Outcomes of this project include a scientific framework to predict soil design parameters at unsampled seabed locations. A game changer ....Smart site investigation for offshore energy installations in sand . This project aims to develop a next generation tool for seabed site investigations. It will use free-fall penetrometers, advanced physical modelling and novel probabilistic methods to investigate fundamental science of sand responses at low stress level and generate new interpretation methods. Outcomes of this project include a scientific framework to predict soil design parameters at unsampled seabed locations. A game changer in offshore site investigations, the project will provide cheaper and faster geotechnical site investigation in sand at a time of global increase in offshore energy installations (worth 4 trillion over the next decade).Read moreRead less
Constricted hydraulic fracture opening. This project aims to develop experimentally verified models for designing and monitoring of hydraulic fractures with constricted openings, to ensure adequate and robust hydraulic fracture control for example in petroleum production. Hydraulic fractures are often constricted by bridges that hold two sides of the fracture together. Failure to account for bridges and constriction of fractures can lead to premature screen-out (exceeding available pump pressure ....Constricted hydraulic fracture opening. This project aims to develop experimentally verified models for designing and monitoring of hydraulic fractures with constricted openings, to ensure adequate and robust hydraulic fracture control for example in petroleum production. Hydraulic fractures are often constricted by bridges that hold two sides of the fracture together. Failure to account for bridges and constriction of fractures can lead to premature screen-out (exceeding available pump pressure) of proppant and inadequate fracking control. The project results are expected to substantially increase the accuracy of design and monitoring of fracture opening, geometry and fluid flow to improve efficiency, safety and environmental security of the resource and energy extraction.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150100195
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Using Sandwich Pipe for Pipeline Vibration Control. Pipelines are important structures but are vulnerable to different types of damage. This damage is often associated with pipeline vibration. It is important to control adverse vibrations to reduce the risk of catastrophic damage. This project proposes using sandwich pipe to suppress different sources of vibrations that may be experienced during the lifetime of the pipeline. Analytical, numerical and experimental investigations will be carried o ....Using Sandwich Pipe for Pipeline Vibration Control. Pipelines are important structures but are vulnerable to different types of damage. This damage is often associated with pipeline vibration. It is important to control adverse vibrations to reduce the risk of catastrophic damage. This project proposes using sandwich pipe to suppress different sources of vibrations that may be experienced during the lifetime of the pipeline. Analytical, numerical and experimental investigations will be carried out to demonstrate the feasibility of the proposed method. The project aims to develop direct applications for designing pipelines to suppress different sources of vibration and to guarantee the safety of pipelines.Read moreRead less
Coal seam gas: Experimental and theoretical developments. This project aims to reduce the uncertainty and risk associated with the coal seam gas industry – control water production and optimisation of methane production. Understanding multi-physics in coal beds is necessary to address this challenge. This project will explore two-phase flow in fractures, sorption and diffusion mechanisms, stress dependency, and the complex coupling of these processes in coal beds. This is expected to enhance kno ....Coal seam gas: Experimental and theoretical developments. This project aims to reduce the uncertainty and risk associated with the coal seam gas industry – control water production and optimisation of methane production. Understanding multi-physics in coal beds is necessary to address this challenge. This project will explore two-phase flow in fractures, sorption and diffusion mechanisms, stress dependency, and the complex coupling of these processes in coal beds. This is expected to enhance knowledge of fluid transport in coal beds and improve the capacity to safely and efficiently exploit this resource.Read moreRead less
Modelling fluid-solid interaction in micro- and nano-porous media. This project aims to develop a state-of-the-art computational tool for modelling the coupled fluid transport-solid deformation behaviour in micro- and nano-porous media. A significant portion of the world’s water and energy resources are stored in fractured rocks, many of which contain characteristic pores with size ranging from nanometres to micrometres. The pore-scale particle-based modelling method will provide for better unde ....Modelling fluid-solid interaction in micro- and nano-porous media. This project aims to develop a state-of-the-art computational tool for modelling the coupled fluid transport-solid deformation behaviour in micro- and nano-porous media. A significant portion of the world’s water and energy resources are stored in fractured rocks, many of which contain characteristic pores with size ranging from nanometres to micrometres. The pore-scale particle-based modelling method will provide for better understanding and opportunities for manipulating fluid flow through fractured micro- and nano-porous media. Successful application of the model will improve the performance of diverse energy and environmental systems including carbon geo-sequestration, unconventional oil and gas recovery, enhanced geothermal energy generation and groundwater contamination.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100189
Funder
Australian Research Council
Funding Amount
$190,000.00
Summary
Integrated magnetic resonance gas and oil analyser. Magnetic resonance has enormous potential in a range of industrial applications. This facility will develop these capabilities and contribute unique insights into liquid and gas transport in systems ranging from rock cores to reverse osmosis membranes used in desalination.
Development of novel inerter-based damper for platform vibration control. This project aims to develop a novel inerter-based damper to mitigate the excessive vibrations of offshore floating platforms (OFP), which are widely used in the offshore industry for oil exploration. Harsh environmental loads such as wind and waves can induce excessive vibrations to OFPs and endanger their safety and stability. This project aims to develop a novel inerter-based damper that can produce a considerable appar ....Development of novel inerter-based damper for platform vibration control. This project aims to develop a novel inerter-based damper to mitigate the excessive vibrations of offshore floating platforms (OFP), which are widely used in the offshore industry for oil exploration. Harsh environmental loads such as wind and waves can induce excessive vibrations to OFPs and endanger their safety and stability. This project aims to develop a novel inerter-based damper that can produce a considerable apparent mass that is much larger than its physical mass through an amplifying mechanism by translating the linear motion into high-speed rotational motion, which can significantly reduce the mass and cost of the damper. Benefits of the project include more economical and safer OFP designs, which are expected to improve the competitiveness of Australian pillar oil and gas industries.Read moreRead less
Removal and degradation of microplastics using halloysite nanocomposite. The project aims to utilize halloysite clay combined with novel highly magnetized nanoparticles for the removal and degradation of microplastics in the contaminated water system. The project expects to fabricate cheap and environmentally-friendly materials using innovative chemical synthesis and surface modification for adsorption and decomposition of microplastics utilizing both high surface area of halloysite nanotubes a ....Removal and degradation of microplastics using halloysite nanocomposite. The project aims to utilize halloysite clay combined with novel highly magnetized nanoparticles for the removal and degradation of microplastics in the contaminated water system. The project expects to fabricate cheap and environmentally-friendly materials using innovative chemical synthesis and surface modification for adsorption and decomposition of microplastics utilizing both high surface area of halloysite nanotubes and catalytic activity of transition metals. This project will facilitate collaboration between multidisciplinary researchers and a vibrant group of industrial participants to advance next-generation composite materials for water treatment and ensure the supply of clean water for healthy living.Read moreRead less
Building Australia's Offshore Oil and Gas Industry on Solid Foundations: characterising multilayered soils for offshore foundation design. This project aims to characterise soils with multilayers for offshore foundation designs. The commonly used site investigation tools, cone, T-bar and ball penetrometers, will be studied using advanced large deformation finite element analysis and novel centrifuge technics. The outcome of this study will provide guidelines to interpret soil layer information a ....Building Australia's Offshore Oil and Gas Industry on Solid Foundations: characterising multilayered soils for offshore foundation design. This project aims to characterise soils with multilayers for offshore foundation designs. The commonly used site investigation tools, cone, T-bar and ball penetrometers, will be studied using advanced large deformation finite element analysis and novel centrifuge technics. The outcome of this study will provide guidelines to interpret soil layer information and soil design parameters from site investigation data, that is, penetrometers’ penetration resistance profiles. The guidelines will fill the knowledge gap in this area and will provide offshore design engineers with more reliable soil parameters for safer and more economical foundation designs.Read moreRead less