Shallow foundation solutions for offshore oil and gas facilities. This research will develop reliable predictions of limit loads for offshore skirted shallow foundations to replace current industry design guidelines that are excessively conservative. This project has direct application to the design of the range of established skirted shallow foundation systems for offshore structures as well as new concept hybrid production platforms and liquefied natural gas terminals designed to be buoyant af ....Shallow foundation solutions for offshore oil and gas facilities. This research will develop reliable predictions of limit loads for offshore skirted shallow foundations to replace current industry design guidelines that are excessively conservative. This project has direct application to the design of the range of established skirted shallow foundation systems for offshore structures as well as new concept hybrid production platforms and liquefied natural gas terminals designed to be buoyant after offloading, thus imparting a sustained uplift on the foundation. The direct economic benefit of this research would be in the region of $3-5M per project. Continued development of Australia's offshore resources will provide jobs for many Australians and sustain an essential market of the Australian economy.Read moreRead less
Development of Novel Metaconcrete to Resist Impulsive Loads. This project aims to develop innovative metaconcrete for structural protection by utilising the concept of phononic crystals and metamaterials which has been recently developed by physicists. Traditional construction materials are used in new structural forms to mitigate dynamic loading effects by exploiting the unique characteristics of the proposed metaconcrete. Theoretical, numerical and experimental methods will be used to derive t ....Development of Novel Metaconcrete to Resist Impulsive Loads. This project aims to develop innovative metaconcrete for structural protection by utilising the concept of phononic crystals and metamaterials which has been recently developed by physicists. Traditional construction materials are used in new structural forms to mitigate dynamic loading effects by exploiting the unique characteristics of the proposed metaconcrete. Theoretical, numerical and experimental methods will be used to derive the best performing metaconcrete and verify its static and dynamic load resistant capacities. The expected outcomes of the project will lead to innovative extreme-loading resistant designs and provide significant benefit to the Australian construction industry, general public and economy.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100130
Funder
Australian Research Council
Funding Amount
$320,000.00
Summary
An earthquake shaking table to investigate soil-structure interactions. An earthquake shaking table to investigate soil-structure interactions: This project aims to develop Australia's most advanced earthquake shaking table. Earthquakes are a problem of great significance to Australia. Infrastructure in civil, transport, mining and energy sectors may be at an unacceptable risk of damage under earthquake loading as current design practices do not account for the interaction between infrastructure ....An earthquake shaking table to investigate soil-structure interactions. An earthquake shaking table to investigate soil-structure interactions: This project aims to develop Australia's most advanced earthquake shaking table. Earthquakes are a problem of great significance to Australia. Infrastructure in civil, transport, mining and energy sectors may be at an unacceptable risk of damage under earthquake loading as current design practices do not account for the interaction between infrastructure and the ground under such loading. The shaking table will simulate earthquakes and enable controlled testing of three-tonne models of foundation and soil-structure interaction systems typical of Australia's infrastructure. The discoveries made are expected to be integral to the modernisation of Australia's seismic design standards so that earthquake-induced damage and risk exposure can be minimised.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101741
Funder
Australian Research Council
Funding Amount
$389,220.00
Summary
Development of a Self-powered Wireless Sensor Network from Renewable Energy for Integrated Structural Health Monitoring and Diagnosis. This project aims to develop a green and sustainable self-powered wireless sensor network from renewable energy sources, such as wind, sea wave and operational vibrations, for integrated structural health monitoring and diagnosis to support infrastructure management. Vibration based energy harvesting techniques will be investigated to power the wireless sensor ne ....Development of a Self-powered Wireless Sensor Network from Renewable Energy for Integrated Structural Health Monitoring and Diagnosis. This project aims to develop a green and sustainable self-powered wireless sensor network from renewable energy sources, such as wind, sea wave and operational vibrations, for integrated structural health monitoring and diagnosis to support infrastructure management. Vibration based energy harvesting techniques will be investigated to power the wireless sensor networks and support the long term condition monitoring. Vibration data from the sensor network will be used for damage detection, performance assessment and safety evaluation of structures. The impact of the project output includes fundamental advances in vibration energy harvesting, wireless sensor network and intelligent structural health monitoring strategy for Australian infrastructure.Read moreRead less
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.
A 21st century laboratory testing device for geotechnical engineering. This project aims to use advanced image analysis and cloud computing technologies to replace manual, time-consuming and subjective geotechnical engineering practices with a rapid, automated, and more rational approach. A new geo-materials testing system based on the existing triaxial apparatus will be developed that employs three-dimensional image capture hardware and advanced image analysis techniques. The data measured over ....A 21st century laboratory testing device for geotechnical engineering. This project aims to use advanced image analysis and cloud computing technologies to replace manual, time-consuming and subjective geotechnical engineering practices with a rapid, automated, and more rational approach. A new geo-materials testing system based on the existing triaxial apparatus will be developed that employs three-dimensional image capture hardware and advanced image analysis techniques. The data measured over the entire sample surface will feed into an automated, intelligent parameter selection procedure combining finite element analysis with numerical optimisation techniques. Application of the proposal’s findings will allow more accurate and efficient engineering design of transport and energy infrastructure that supports modern economies.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
Development of fuel storage tanks with frangible roofs to resist accidental explosion load. This project aims to study the effects of accidental explosions on industry storage tanks and develop safer and economic designs of tank structures to protect against explosion loads. The outcomes of the project will lead to better tank structures and minimise the damage and loss should an accidental explosion occur.
Advancing laterally loaded pile analysis. This project will replace out-of-date solution techniques for the design of pile foundations subjected to wind, waves and other horizontally applied forces and, in so doing, lead to more efficient designs of the foundations for structures such as elevated highways, tall buildings, bridges, jetties, towers, wind turbines and offshore platforms.
Optimal maintenance planning for critical mining and energy infrastructure. This project aims to develop cutting-edge mathematical algorithms for optimising maintenance activities in the mining and energy sectors. Such maintenance activities are prone to budget and time overruns due to poor planning - the result of outdated, inefficient manual processes. The project is expected to result in new maintenance planning methods, underpinned by rigorous mathematical theory, for reducing manual interve ....Optimal maintenance planning for critical mining and energy infrastructure. This project aims to develop cutting-edge mathematical algorithms for optimising maintenance activities in the mining and energy sectors. Such maintenance activities are prone to budget and time overruns due to poor planning - the result of outdated, inefficient manual processes. The project is expected to result in new maintenance planning methods, underpinned by rigorous mathematical theory, for reducing manual intervention and optimising both short- and long-term maintenance based on real-time sensor data. These new methods will be powerful tools for tackling the complexity of large-scale, time-critical maintenance projects, driving productivity in the resources industry and fostering collaboration between mathematicians and engineers.Read moreRead less