Industrial Transformation Research Hubs - Grant ID: IH140100012
Funder
Australian Research Council
Funding Amount
$4,997,672.00
Summary
ARC Research Hub for Offshore Floating Facilities. ARC Research Hub for Offshore Floating Facilities. This research hub aims to address the critical engineering challenges associated with Australia’s next generation of offshore oil and gas projects. These projects, in remote deep-water locations, will require innovative floating facilities. Using world-leading expertise in metocean, hydrodynamic, geotechnical and reliability engineering, the hub aims to develop the new technologies and analysis ....ARC Research Hub for Offshore Floating Facilities. ARC Research Hub for Offshore Floating Facilities. This research hub aims to address the critical engineering challenges associated with Australia’s next generation of offshore oil and gas projects. These projects, in remote deep-water locations, will require innovative floating facilities. Using world-leading expertise in metocean, hydrodynamic, geotechnical and reliability engineering, the hub aims to develop the new technologies and analysis methods that are required to make projects safe, efficient and cost-effective. This research will include wave and current forecasting, vessel motion and offloading analysis, riser and mooring longevity and novel anchoring and subsea foundations. This is expected to lead to safer, more economical projects and should develop Western Australia’s role as an oil and gas centre of excellence.Read moreRead less
Numerical Modelling of Three-dimensional Scour below Offshore Pipelines. Australia's increasing offshore oil and gas exploration has demanded more accurate and reliable methods for evaluating the safety and serviceability of pipelines. Local scour around pipelines is one of the major causes of pipeline failures, and is a major concern in Australian waters. This project not only addresses these concerns in its direct application to the design and management of offshore pipelines, but also will co ....Numerical Modelling of Three-dimensional Scour below Offshore Pipelines. Australia's increasing offshore oil and gas exploration has demanded more accurate and reliable methods for evaluating the safety and serviceability of pipelines. Local scour around pipelines is one of the major causes of pipeline failures, and is a major concern in Australian waters. This project not only addresses these concerns in its direct application to the design and management of offshore pipelines, but also will contribute to the nation's development and competitiveness in offshore exploration, and produce high quality research students. The improved design and management of pipelines in Australian waters will reduce the risk of potential environmental damages caused by leaking gas and oil.Read moreRead less
Engineering solutions for the next generation of offshore oil and gas infrastructure. Offshore extraction of oil and gas reserves is a key industry for Australia, annually contributing A$21 billion to the economy, and underpinning much of our prosperity. With reserves close to shore being exhausted and A$1 trillion of gas reserves (four times that already developed) known to be 'stranded' in deep and remote locations, the outcomes of the proposed research programme will help scientifically under ....Engineering solutions for the next generation of offshore oil and gas infrastructure. Offshore extraction of oil and gas reserves is a key industry for Australia, annually contributing A$21 billion to the economy, and underpinning much of our prosperity. With reserves close to shore being exhausted and A$1 trillion of gas reserves (four times that already developed) known to be 'stranded' in deep and remote locations, the outcomes of the proposed research programme will help scientifically underpin the reliable design of the next generation of Australia's exploration and development infrastructure. It continues Australia's leadership in the field of offshore geotechnics and engineering, fostering tomorrow's engineering leaders and ensuring the future competitiveness of Australia's offshore oil and gas industry.Read moreRead less
Numerical Modelling of Extreme Waves Generated by Tropical Cyclones. Waves generated by tropical cyclones are a key design parameter for shipping, coastal and offshore structures and coastal erosion. The accurate prediction of tropical cyclone generated extreme waves is consequently of critical importance. Outcomes of the project will lead to more accurate wave forecasts, both for tropical cyclones and other extreme events. The main result will be a new non-linear approach to be used in predicti ....Numerical Modelling of Extreme Waves Generated by Tropical Cyclones. Waves generated by tropical cyclones are a key design parameter for shipping, coastal and offshore structures and coastal erosion. The accurate prediction of tropical cyclone generated extreme waves is consequently of critical importance. Outcomes of the project will lead to more accurate wave forecasts, both for tropical cyclones and other extreme events. The main result will be a new non-linear approach to be used in prediction models. This approach is expected to be broadly implemented by the meteorological, oceanographic and scientific communities around the world and potentially replace existing algorithms in spectral wave models. The economic and social implications of an enhanced ability to predict such extremes are significant.Read moreRead less
A Global Satellite Altimeter Database for Ocean Engineering Applications. Australia is a maritime nation with major shipping activities, offshore facilities and a very significant percentage of its population living near the coast. As such, it is critical that engineers can accurately predict ocean wave conditions. This project will bring together more than 20 years of satellite observations of the ocean into a single database. This database will represent a major resource for the nation, signif ....A Global Satellite Altimeter Database for Ocean Engineering Applications. Australia is a maritime nation with major shipping activities, offshore facilities and a very significant percentage of its population living near the coast. As such, it is critical that engineers can accurately predict ocean wave conditions. This project will bring together more than 20 years of satellite observations of the ocean into a single database. This database will represent a major resource for the nation, significantly enhancing our understanding of ocean wave conditions. The research projects associated with the database will provide an understanding of the ocean wave climate, oceanic extremes, tropical cyclone conditions and nearshore ocean design parameters.Read moreRead less
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
Development of Models for the Three-Dimensional Analysis of Jack-Up Structures. Mobile jack-up structures perform most of the world's offshore drilling in water depths up to 120m, but have a higher accident rate then fixed installations. To improve their safety, this research will develop the framework for the integrated assessment of jack-up behaviour in three dimensions. To achieve this, an advanced plasticity model that describes cyclic behaviour of the circular shallow foundations of jack-up ....Development of Models for the Three-Dimensional Analysis of Jack-Up Structures. Mobile jack-up structures perform most of the world's offshore drilling in water depths up to 120m, but have a higher accident rate then fixed installations. To improve their safety, this research will develop the framework for the integrated assessment of jack-up behaviour in three dimensions. To achieve this, an advanced plasticity model that describes cyclic behaviour of the circular shallow foundations of jack-ups in both clay and sand will be developed and incorporated with random wave loading of seas in a dynamic structural analysis program. The anticipated advantages of the modelling techniques will be assessed against existing two dimensional industry guidelines and monitored field data. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101478
Funder
Australian Research Council
Funding Amount
$422,998.00
Summary
Design Waves: a new basis for safer and more efficient offshore systems. This project will overcome a fundamental issue at the heart of ocean engineering design, impacting our oil, gas and renewables industries. Ocean waves are random, yet the best design tools for wave-structure interaction (model testing and computational fluid dynamics) require short, precisely-defined wave sequences. This project will establish a paradigm shift, bridging this gap via a new unified Design Wave methodology dev ....Design Waves: a new basis for safer and more efficient offshore systems. This project will overcome a fundamental issue at the heart of ocean engineering design, impacting our oil, gas and renewables industries. Ocean waves are random, yet the best design tools for wave-structure interaction (model testing and computational fluid dynamics) require short, precisely-defined wave sequences. This project will establish a paradigm shift, bridging this gap via a new unified Design Wave methodology developed for a diverse set of offshore systems, each with different criticalities. The new methodology will fuse advanced techniques in fluid mechanics, statistics and applied maths. The outcomes will create reductions in uncertainty and improvements in design and safety for facilities such as wind farms and gas platforms.Read moreRead less
Hydroelasticity of compliant offshore structures. Australia's rich offshore oil and gas reserves are awaiting extensive deepwater extraction. However, there is still a lack of in-depth knowledge in the dynamic behavior of deepwater structures to ensure safe and cost-effective production. We hereby propose hydroelasticity theories and modelling techniques to investigate dynamic fluid-structure interaction problems for compliant offshore structures. We also propose innovative experiments to verify ....Hydroelasticity of compliant offshore structures. Australia's rich offshore oil and gas reserves are awaiting extensive deepwater extraction. However, there is still a lack of in-depth knowledge in the dynamic behavior of deepwater structures to ensure safe and cost-effective production. We hereby propose hydroelasticity theories and modelling techniques to investigate dynamic fluid-structure interaction problems for compliant offshore structures. We also propose innovative experiments to verify the theoretical work. One application is to configure a freestanding compliant tower to suit prospective deepwater oil and gas fields off North-West Australia. Expected outcomes include theoretical and experimental advances in deepwater offshore mechanics and practical computation tools for industry applications.Read moreRead less
Global trends in oceanic wind speed and wave height. This project will determine whether winds and waves over the world's oceans have changed over the past 30 years. Such information is critically important in understanding global climate change, evaporation, air-sea interaction and to safely design and operate coastal and offshore facilities.