Australian Laureate Fellowships - Grant ID: FL130100059
Funder
Australian Research Council
Funding Amount
$3,204,762.00
Summary
New Frontiers in offshore geotechnics: securing Australia's energy future. Offshore gas lies at the heart of Australia's prosperity, with $120 billion of infrastructure under construction, however its future requires new technology to safely build offshore foundations in our weak and problematic soils. This project will provide engineers with science-based tools to unlock the natural gas 'stranded' in our deep oceans.
Advancement of cohesive crack approach to model shrinkage and load induced cracking in multi-phase soils. Soil cracking affects many engineering applications and infrastructure. It is also recognised that the impending climate change can affect the severity of soil cracking. Despite this, there is lack of progress in this area and significant knowledge gaps exist. This project will provide new knowledge and better design and management tools.
Aggressive corrosion of steel infrastructure in marine environments. Marine corrosion is known to be aggressive, but how aggressive it can be under long term exposures is the critical question for the safety and economics of much industrial infrastructure, including harbour, coastal and offshore oil industry facilities. Bacterial and microbiological activity is known to contribute. However, recent findings have observed very aggressive corrosion also under sterile and apparently benign condition ....Aggressive corrosion of steel infrastructure in marine environments. Marine corrosion is known to be aggressive, but how aggressive it can be under long term exposures is the critical question for the safety and economics of much industrial infrastructure, including harbour, coastal and offshore oil industry facilities. Bacterial and microbiological activity is known to contribute. However, recent findings have observed very aggressive corrosion also under sterile and apparently benign conditions. No theory to explain these observations currently exists. A new hypothesis is proposed that in certain circumstances second-phase constituents of steels will facilitate autocatalytic corrosion under anoxic conditions. This project investigates the problem and explores mechanisms and conditions. Read moreRead less
ARC Centre of Excellence for Geotechnical Science and Engineering. To pioneer new scientific approaches for geotechnical design of Australia's energy and transport infrastructure. Australia will spend over $250 billion during the next five years on the provision of physical infrastructure for energy and transport, which is the critical importance to the nation's future prosperity. The Centre for Geotechnical Science and Engineering will develop new computational and experimental approaches to un ....ARC Centre of Excellence for Geotechnical Science and Engineering. To pioneer new scientific approaches for geotechnical design of Australia's energy and transport infrastructure. Australia will spend over $250 billion during the next five years on the provision of physical infrastructure for energy and transport, which is the critical importance to the nation's future prosperity. The Centre for Geotechnical Science and Engineering will develop new computational and experimental approaches to underpin the geotechnical design of this infrastructure and provide a national focus for geotechnical research. New scientific approaches and software for designing cheaper and safer infrastructure in the energy and transport sectors.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100011
Funder
Australian Research Council
Funding Amount
$700,000.00
Summary
The national geotechnical centrifuge facility. A new geotechnical centrifuge will enable the modelling of complex offshore and onshore structures. The new facility will support many geotechnical fields, associated with the economical and geographical development of Australia, and ensure that Australia will maintain its leadership within the international physical modelling community.
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.
Discovery Early Career Researcher Award - Grant ID: DE190101296
Funder
Australian Research Council
Funding Amount
$386,552.00
Summary
Unlocking lab-to-field scaling in design for floating offshore structures. This project aims to develop rigorous, physics-based models to accurately predict hydrodynamics of floating offshore structures at different scales. The project will address the issue between laboratory-to-field scaling, a fundamental problem in fluid dynamics. This outcome will be achieved through the integration of numerical technology, with physical modelling and field data acquisition. The outputs from this project wi ....Unlocking lab-to-field scaling in design for floating offshore structures. This project aims to develop rigorous, physics-based models to accurately predict hydrodynamics of floating offshore structures at different scales. The project will address the issue between laboratory-to-field scaling, a fundamental problem in fluid dynamics. This outcome will be achieved through the integration of numerical technology, with physical modelling and field data acquisition. The outputs from this project will reduce risks and improve operability of existing offshore structures, and lead to more efficient design for potential floating offshore projects. This will benefit the whole community of floating offshore structures and cement Australia’s place as a pioneer in offshore industry and emerging renewable energy sector.Read moreRead less
Crusty Seabeds: From (Bio-)Genesis To Reliable Offshore Design. The project aims to make deep water oil and gas developments safer and cheaper by understanding better the unique seabed ‘crust’ conditions that occur in Australian waters. By studying the biogenic, structural and mechanical properties of deepwater crusts in more detail than can be done in ‘live’ oil and gas projects, this project expects to make a step change in the understanding of these seabed crusts. Expected outcomes of this pr ....Crusty Seabeds: From (Bio-)Genesis To Reliable Offshore Design. The project aims to make deep water oil and gas developments safer and cheaper by understanding better the unique seabed ‘crust’ conditions that occur in Australian waters. By studying the biogenic, structural and mechanical properties of deepwater crusts in more detail than can be done in ‘live’ oil and gas projects, this project expects to make a step change in the understanding of these seabed crusts. Expected outcomes of this project include developing new seabed investigation and design approaches for these soils. This should provide significant benefits, by facilitating the design and installation of low-risk, yet low cost seabed infrastructure (e.g. pipelines, risers, shallow foundations etc.) in these problematical seabed typesRead moreRead less
Predicting scour and scour-induced settlement of subsea infrastructure. This project aims to develop improved predictions and understanding of the potential and extent of scour and scour-induced settlement of subsea infrastructure on mobile seabeds. This is expected to enable scour and settlement to be accounted for directly in engineering stability and serviceability design, overturning current practice which ignores both effects on the basis of using scour protection and costly maintenance and ....Predicting scour and scour-induced settlement of subsea infrastructure. This project aims to develop improved predictions and understanding of the potential and extent of scour and scour-induced settlement of subsea infrastructure on mobile seabeds. This is expected to enable scour and settlement to be accounted for directly in engineering stability and serviceability design, overturning current practice which ignores both effects on the basis of using scour protection and costly maintenance and remediation. Development of accurate predictions is expected to be achieved through physical model testing, numerical modelling and analysis of field data. Predictions should improve subsea reliability and lead to omission of scour protection in some situations, increasing international competitiveness of our offshore oil and gas industry.Read moreRead less
Microbiological and abiotic marine corrosion of steel in particulate media. This project aims to study the complex interfacial physicochemical interaction between structural steel and inert particles in marine environments, including microbial growth influences. It will use field-testing and electrochemical laboratory experiments to understand the short- and long-term corrosion processes. It will develop mathematical models to predict likely corrosion loss and pitting, based on physicochemical c ....Microbiological and abiotic marine corrosion of steel in particulate media. This project aims to study the complex interfacial physicochemical interaction between structural steel and inert particles in marine environments, including microbial growth influences. It will use field-testing and electrochemical laboratory experiments to understand the short- and long-term corrosion processes. It will develop mathematical models to predict likely corrosion loss and pitting, based on physicochemical corrosion principles. Industry increasingly needs such models to manage major infrastructure not protected against corrosion, including offshore energy systems, coastal structures and buried pipelines. These outcomes are expected to benefit Australian engineering consultants in the offshore energy industry, with potential for large foreign exchange earnings.Read moreRead less