Geotechnical engineering solutions for deep-water oil and gas developments. Offshore extraction of oil and gas lies at the heart of Australia's prosperity, but faces escalating challenges in water depths already in excess of 1 km and approaching 3 km. Safe and economic design of seabed systems and pipelines requires novel techniques for assessing the engineering properties of seabed sediments, and for foundation and anchoring systems that must withstand extreme loading conditions. This project c ....Geotechnical engineering solutions for deep-water oil and gas developments. Offshore extraction of oil and gas lies at the heart of Australia's prosperity, but faces escalating challenges in water depths already in excess of 1 km and approaching 3 km. Safe and economic design of seabed systems and pipelines requires novel techniques for assessing the engineering properties of seabed sediments, and for foundation and anchoring systems that must withstand extreme loading conditions. This project contributes to future exploitation of offshore hydrocarbon reserves, by developing new technology and improved reliability in offshore geotechnical design, with consequential benefits to our economy and in minimising impact on the marine environment. 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
Economical Offshore Foundation for Deep Water - Suction Embedded Plate Anchor. The oil/gas industry's venture in finding large resources in deep water has lead to a number of important economic and technical challenges including, among others, new types of foundations. Suction Embedded Plate Anchor (SEPA) has shown its potential of cost-saving against other types of foundations in deep waters. The aim of this project is to use the experties of investigators, on numerical and centrifuge modelling ....Economical Offshore Foundation for Deep Water - Suction Embedded Plate Anchor. The oil/gas industry's venture in finding large resources in deep water has lead to a number of important economic and technical challenges including, among others, new types of foundations. Suction Embedded Plate Anchor (SEPA) has shown its potential of cost-saving against other types of foundations in deep waters. The aim of this project is to use the experties of investigators, on numerical and centrifuge modelling, to study the behaviour of SEPA in sub-marine deposit. Successful completing of the project will contribute to the very little existing data on this new type of foundation - SEPA.Read moreRead less
Deep Penetrating Anchors - a cost effective anchoring solution for mooring oil and gas facilities in deep water. The offshore oil and gas industry is currently directing considerable research efforts towards the development of cost-effective anchoring solutions suitable for mooring floating installations in deep water. This project aims to enhance the limited understanding of the Deep Penetrating Anchor (DPA), which has been identified as having the most potential to meet industry demands as it ....Deep Penetrating Anchors - a cost effective anchoring solution for mooring oil and gas facilities in deep water. The offshore oil and gas industry is currently directing considerable research efforts towards the development of cost-effective anchoring solutions suitable for mooring floating installations in deep water. This project aims to enhance the limited understanding of the Deep Penetrating Anchor (DPA), which has been identified as having the most potential to meet industry demands as it extends the current water depth limit of 2000 metres. Successful completion of this project will result in a DPA experimental database that will not only form the basis for predicting anchor performance, but will also serve as a means of validating robust and versatile design tools that can be used in offshore engineering practice.Read moreRead less
Investigation of potential spudcan punch through failure. The safe and economic use of mobile jack-up structures is critical to the prosperous development of Australia's significant offshore oil and gas industry. However, their use is hindered by potential 'punch-through' failure during installation, when their large conical footings can unexpectedly and uncontrollably push a locally strong zone of soil into underlying softer material. To improve their safety, this research will investigate a po ....Investigation of potential spudcan punch through failure. The safe and economic use of mobile jack-up structures is critical to the prosperous development of Australia's significant offshore oil and gas industry. However, their use is hindered by potential 'punch-through' failure during installation, when their large conical footings can unexpectedly and uncontrollably push a locally strong zone of soil into underlying softer material. To improve their safety, this research will investigate a potential new site-investigation procedure and develop an appropriate calculation method for predicting failures for sites where sand overlies clay. Results will be based on a series of innovative physical and numerical experiments, and assessed against field data and existing industry standards.Read moreRead less
Numerical prediction of train and vehicle induced ground vibrations and their effects on structures. This project will develop an innovative new method based on coupled finite element and scaled boundary finite-element analysis for predicting the ground vibrations induced by road traffic and underground or surface trains. The method will have immediate application in transportation engineering to predict traffic-induced ground vibrations, in geotechnical engineering to design isolation trenches ....Numerical prediction of train and vehicle induced ground vibrations and their effects on structures. This project will develop an innovative new method based on coupled finite element and scaled boundary finite-element analysis for predicting the ground vibrations induced by road traffic and underground or surface trains. The method will have immediate application in transportation engineering to predict traffic-induced ground vibrations, in geotechnical engineering to design isolation trenches and wave barriers to dissipate wave propagation, and in structural engineering to estimate in-structure vibration level and design isolators for sensitive equipment housed within. The technique will involve fundamental advances in the scaled boundary finite-element method, as calculations will be performed in a moving reference frame.Read moreRead less
Barriers for cost - effective rock fall hazard mitigation. Rock fall barriers are used throughout Australia to protect its extensive road and rail networks. These networks are vital links in the nation's infrastructure and underpin its economic prosperity and development. There are thousands of cuttings on Australia' transport networks, many of which have the potential to be affected by rock falls. These events can take lives and severely disrupt the performance of our transport infrastructure. ....Barriers for cost - effective rock fall hazard mitigation. Rock fall barriers are used throughout Australia to protect its extensive road and rail networks. These networks are vital links in the nation's infrastructure and underpin its economic prosperity and development. There are thousands of cuttings on Australia' transport networks, many of which have the potential to be affected by rock falls. These events can take lives and severely disrupt the performance of our transport infrastructure. This project will develop new cost-effective methods for designing against rock fall events using a combination of advanced testing and computer modelling.Read moreRead less
Multi-scale modeling of transport through deformable porous materials. Understanding solute transport through porous materials is essential because it provides a technical basis for answering many important questions in society today-how can humans avoid 'brittle bones', how to design durable infrastructure, how to safely store wastes (e.g. hazardous and municipal). Solution of each of these problems requires innovation in model development, new method of analysis, and insightful interpretation ....Multi-scale modeling of transport through deformable porous materials. Understanding solute transport through porous materials is essential because it provides a technical basis for answering many important questions in society today-how can humans avoid 'brittle bones', how to design durable infrastructure, how to safely store wastes (e.g. hazardous and municipal). Solution of each of these problems requires innovation in model development, new method of analysis, and insightful interpretation of results. While theoretical developments of this project are general, in the sense that they are not restricted to particular engineering disciplines, the four chosen applications closely align with two major research priorities namely An Environmental Sustainable Australia and Promoting and Maintaining Good Health.Read moreRead less
Prediction and controlling of pipe failures in buried water and gas pipe systems. Australian Research Council has recognised water as a critical resource that must be protected from wastage. Along with water, the supply of gas to communities through extensive buried pipe networks is an essential service. As the pipe systems age, the pipe failures have increased. These failures lead to loss of valuable commodity and inconvenience and health hazard to public and workers. Effective asset manage ....Prediction and controlling of pipe failures in buried water and gas pipe systems. Australian Research Council has recognised water as a critical resource that must be protected from wastage. Along with water, the supply of gas to communities through extensive buried pipe networks is an essential service. As the pipe systems age, the pipe failures have increased. These failures lead to loss of valuable commodity and inconvenience and health hazard to public and workers. Effective asset management tools are urgently required in predicting and controlling pipe failures. A consortium of water and gas suppliers and a team of researchers from Monash University and CSIRO have joined forces to address this problem so that significant social and economic benefits to Australia can be realised. Read moreRead less
Development of cyclic loading models for application in offshore geotechnics. The response of foundations for offshore structures to repetitive (cyclic) loads is a critical but still inadequately understood area of offshore geotechnics, with designs still usually based on simple modifications to monotonic loading conditions. In this project, a definitive framework for modelling cyclic behaviour will be established. Using this new approach, numerical models will be developed to address problems a ....Development of cyclic loading models for application in offshore geotechnics. The response of foundations for offshore structures to repetitive (cyclic) loads is a critical but still inadequately understood area of offshore geotechnics, with designs still usually based on simple modifications to monotonic loading conditions. In this project, a definitive framework for modelling cyclic behaviour will be established. Using this new approach, numerical models will be developed to address problems at all scales from fundamental constitutive behaviour of soils to macroscopic models for large foundation systems. Their application to offshore design problems (for renewable energy as well as traditional oil and gas applications) will be assessed. Recommendations to current international guidelines will also be made.Read moreRead less