Transforming decision making for rockfall hazard assessment. The aim is to transform conventional approaches to rockfall hazard prediction and mitigation. The management of risks posed by rockfall in Australia currently comes at significant cost and is suboptimal; predicted environmental changes are likely to worsen these hazards. Rockfall mechanics, remote sensing, and data-driven modelling will be combined with advanced visual technologies to deliver a novel, rapid, and reliable augmented real ....Transforming decision making for rockfall hazard assessment. The aim is to transform conventional approaches to rockfall hazard prediction and mitigation. The management of risks posed by rockfall in Australia currently comes at significant cost and is suboptimal; predicted environmental changes are likely to worsen these hazards. Rockfall mechanics, remote sensing, and data-driven modelling will be combined with advanced visual technologies to deliver a novel, rapid, and reliable augmented reality based rockfall hazard assessment tool. The outcomes are expected to streamline prediction, assessment, and mitigation – supporting practitioners and governments to proactively assess triggering conditions, evaluate risk, and apply robust solutions to improve safety, with substantial economic savings.Read moreRead less
Clogging of Permeable Reactive Barrier when treating Acidic Groundwater. Proper understanding of soil-water interaction is vital for sustainable development of floodplains, and to halt acid mine drainage caused by the oxidation of pyritic soil. Permeable reactive barriers (PRB) offer a cost-effective solution to neutralize acidified groundwater. The project aims to quantify the clogging potential of PRB’s granular medium by coupling geotechnical fundamentals with integrated hydro-bio-geochemical ....Clogging of Permeable Reactive Barrier when treating Acidic Groundwater. Proper understanding of soil-water interaction is vital for sustainable development of floodplains, and to halt acid mine drainage caused by the oxidation of pyritic soil. Permeable reactive barriers (PRB) offer a cost-effective solution to neutralize acidified groundwater. The project aims to quantify the clogging potential of PRB’s granular medium by coupling geotechnical fundamentals with integrated hydro-bio-geochemical processes. Time-dependent clogging will be evaluated through geotechnical laboratory & field testing. Expected outcomes are enhanced PRB design methods and sound geotechnical field monitoring to provide significant industry benefits, such as mine-site rehabilitation, increased productivity and infrastructure longevity.Read moreRead less
Efficient geotechnical risk management of rock cliffs . Extreme events will significantly impact the severity of Australian rock cliff hazards in the coming years affecting infrastructure and public safety along major corridors and popular paths. Accurate prediction of their effect is crucial to analyse the associated rockfall risks and design mitigation measures. The project aims to provide a novel approach for the quantification of the rockfall risk by combining proximity remote sensing soluti ....Efficient geotechnical risk management of rock cliffs . Extreme events will significantly impact the severity of Australian rock cliff hazards in the coming years affecting infrastructure and public safety along major corridors and popular paths. Accurate prediction of their effect is crucial to analyse the associated rockfall risks and design mitigation measures. The project aims to provide a novel approach for the quantification of the rockfall risk by combining proximity remote sensing solutions, probabilistic models and quantitative risk analysis. The primary benefits lie in the ability to optimize protection reliability and costs and to deliver a rigorous method to support practitioners, government and emergency agencies to manage the risk, improve safety and properly allocate resources.Read moreRead less
A novel method to stabilise expansive soils by alkali-activation . This project aims to address durability and sustainability issues with traditional lime-based methods used to stabilize expansive soils by alternatively advancing an alkali-activation approach. It expects to generate new knowledge in using alkali-activation to suppress the swelling potential of expansive soils which have been deleterious to roads, pavements and overlying structures. Expected outcomes of this project include deve ....A novel method to stabilise expansive soils by alkali-activation . This project aims to address durability and sustainability issues with traditional lime-based methods used to stabilize expansive soils by alternatively advancing an alkali-activation approach. It expects to generate new knowledge in using alkali-activation to suppress the swelling potential of expansive soils which have been deleterious to roads, pavements and overlying structures. Expected outcomes of this project include development of a long-term durable treatment with reduced carbon footprint and use of waste materials. This should provide significant benefits commercially and critical insights to overcome expansive soils which cover approximately one-fifth of Australia’s surface area and six out of eight of its largest cities.Read moreRead less
Advancing the Engineering of Minipile Systems to Frontier Applications. This project aims to develop new knowledge on the performance of battered minipile systems used in a wide range of applications from solar panels to traffic signs. Minipiles provide concrete-free foundation systems, yet their behaviour under more complex loading such as wind, is yet to be fully understood. This project will examine the loading conditions experienced during installation and throughout service life. This will ....Advancing the Engineering of Minipile Systems to Frontier Applications. This project aims to develop new knowledge on the performance of battered minipile systems used in a wide range of applications from solar panels to traffic signs. Minipiles provide concrete-free foundation systems, yet their behaviour under more complex loading such as wind, is yet to be fully understood. This project will examine the loading conditions experienced during installation and throughout service life. This will include complex full-scale laboratory tests and advanced computer modelling to verify the performance against expected cyclic loading. New design approaches will be developed for this emerging foundation system, enabling more widespread adoption of this technology in the building and construction industry.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100657
Funder
Australian Research Council
Funding Amount
$330,000.00
Summary
Improving mental health and safety in the construction industry. This project aims to quantify the interdependencies of the psychosocial risk factors the construction workforce is exposed to and contribute to developing strategies for improving the mental health and safety of the Australian construction industry. The suicide rate of Australian construction workers is 84 per cent higher than non-construction workers due to the high psychosocial risks involved. The quantification of these psychoso ....Improving mental health and safety in the construction industry. This project aims to quantify the interdependencies of the psychosocial risk factors the construction workforce is exposed to and contribute to developing strategies for improving the mental health and safety of the Australian construction industry. The suicide rate of Australian construction workers is 84 per cent higher than non-construction workers due to the high psychosocial risks involved. The quantification of these psychosocial risk factors and their interdependencies will enable effective strategies to be designed. The long-term impacts of this project include improving the mental health of the construction workforce, reducing suicide rates and mental health work compensation, enhancing employee productivity, and reducing accidents and injuries. This project will make Australia a global leader in mental health and safety of the construction industry.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC170100006
Funder
Australian Research Council
Funding Amount
$3,937,625.00
Summary
ARC Training Centre for Advanced Technologies in Rail Track Infrastructure. The ARC Training Centre for Advanced Technologies in Rail Track Infrastructure aims to transform Australia’s rail construction and maintenance technologies through specialist training of industry-focused researchers. Generation of new knowledge and close collaboration with companies within the rail supply chain will result in enhanced rail capacity and supply chain efficiency across the rail network. This will include in ....ARC Training Centre for Advanced Technologies in Rail Track Infrastructure. The ARC Training Centre for Advanced Technologies in Rail Track Infrastructure aims to transform Australia’s rail construction and maintenance technologies through specialist training of industry-focused researchers. Generation of new knowledge and close collaboration with companies within the rail supply chain will result in enhanced rail capacity and supply chain efficiency across the rail network. This will include increased axle loads and higher speeds, greater safety margins, reduced construction and maintenance costs, and a body of competent railway professionals in the nation’s work force.Read moreRead less
Soil dynamics at extreme deformations. This project aims to conduct a fundamental study of a challenging class of geotechnical problems in which soil undergoes large strains and rapid deformations. The main goal of this project is to discover the fundamental principles governing soil behaviour at large and fast deformation rates. The expected outcomes are an innovative testing device for site investigation purposes, and robust solution and computational procedures for analysing a wide range of p ....Soil dynamics at extreme deformations. This project aims to conduct a fundamental study of a challenging class of geotechnical problems in which soil undergoes large strains and rapid deformations. The main goal of this project is to discover the fundamental principles governing soil behaviour at large and fast deformation rates. The expected outcomes are an innovative testing device for site investigation purposes, and robust solution and computational procedures for analysing a wide range of problems in soil dynamics. This should benefit government and engineers by providing safer and more cost-effective strategies for the design, construction, and maintenance of Australia's infrastructure.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
Next generation transport infrastructure using high performance materials. This project aims to provide structural engineers with the tools required to develop ultra-high performance fibre reinforced concrete materials and to utilise their unique material properties in design. Recent feasibility studies have shown that the replacement of conventional concrete and steel transport infrastructure with ultra-high performance fibre reinforced concrete has the potential to revolutionise the sector. Fo ....Next generation transport infrastructure using high performance materials. This project aims to provide structural engineers with the tools required to develop ultra-high performance fibre reinforced concrete materials and to utilise their unique material properties in design. Recent feasibility studies have shown that the replacement of conventional concrete and steel transport infrastructure with ultra-high performance fibre reinforced concrete has the potential to revolutionise the sector. For these cost savings benefits to be realised, guidelines for the low cost development and testing of new materials, and for the application in structural design are required. This project is expected to deliver these guidelines and potentially maximise the impact of government spending on road and rail infrastructure.Read moreRead less