Solutions for rapid penetration into sand for offshore energy installations. This project aims to develop a fundamental understanding of the response of saturated sand in seabeds during rapid penetration by offshore site investigation tools and foundation construction. The research is using innovative physical and advanced numerical modelling techniques to quantify the significant increase in sand resistance caused by rapid penetration, enabling reliable design and reducing risk of material fail ....Solutions for rapid penetration into sand for offshore energy installations. This project aims to develop a fundamental understanding of the response of saturated sand in seabeds during rapid penetration by offshore site investigation tools and foundation construction. The research is using innovative physical and advanced numerical modelling techniques to quantify the significant increase in sand resistance caused by rapid penetration, enabling reliable design and reducing risk of material failure associated with the high impact forces. Expected outcomes of the project include a conceptual framework and scientific-based design tool to predict the geotechnical performance of offshore installations. The research will provide the necessary scientific advances to install, moor and service offshore wind and wave energy devices more economically and efficiently.Read moreRead less
Improving the security of anchoring systems under extreme cyclones. This project aims to investigate the behaviour of anchoring systems under cyclonic loading and to innovate anchor designs to improve their security during extreme cyclones. Anchoring systems are increasingly playing the vital role of securing floating structures to extract ocean energies, but the current empirical knowledge and design method hinder confidence in engineering application. This project expects to advance the fundam ....Improving the security of anchoring systems under extreme cyclones. This project aims to investigate the behaviour of anchoring systems under cyclonic loading and to innovate anchor designs to improve their security during extreme cyclones. Anchoring systems are increasingly playing the vital role of securing floating structures to extract ocean energies, but the current empirical knowledge and design method hinder confidence in engineering application. This project expects to advance the fundamental scientific understanding of the geotechnical mechanism of anchors under cyclonic loading using innovative experimental and advanced numerical modelling. Outcomes will include quality first-hand data contributing to the knowledge base, innovative anchor designs and new scientific based design guidelines.Read moreRead less
Direct geothermal energy: harnessing an emerging technology. To mitigate the impacts of climate change, the demand for renewable energy technologies with low greenhouse gas (GHG) emissions is rapidly becoming a global priority. Direct geothermal systems use shallow ground as a heat source and sink for heating and cooling buildings, using ground heat exchangers (GHEs) and heat pumps. Substituting common heating and cooling systems with geothermal ones can reduce energy consumption by up to 75 per ....Direct geothermal energy: harnessing an emerging technology. To mitigate the impacts of climate change, the demand for renewable energy technologies with low greenhouse gas (GHG) emissions is rapidly becoming a global priority. Direct geothermal systems use shallow ground as a heat source and sink for heating and cooling buildings, using ground heat exchangers (GHEs) and heat pumps. Substituting common heating and cooling systems with geothermal ones can reduce energy consumption by up to 75 per cent and thus greenhouse gas emissions, since 91 per cent of electricity comes from fossil fuels in Australia. This project aims to develop new full scale physical and numerical models which will allow studying the effects of GHE configuration and intermittent use on efficiency and which will lead towards improving the poor and scarce existing design techniques.Read moreRead less
Direct geothermal energy: Reducing the rural industries’ carbon footprint. Direct geothermal energy: Reducing the rural industries’ carbon footprint. This project aims to design poultry brooder houses using geothermal technology. Reducing greenhouse gas emissions is a global priority. The lack of natural gas in rural areas and brooder houses’ heating and cooling needs make geothermal ideal. Direct geothermal systems use shallow ground both as a heat source and as a heat sink for cooling, using h ....Direct geothermal energy: Reducing the rural industries’ carbon footprint. Direct geothermal energy: Reducing the rural industries’ carbon footprint. This project aims to design poultry brooder houses using geothermal technology. Reducing greenhouse gas emissions is a global priority. The lack of natural gas in rural areas and brooder houses’ heating and cooling needs make geothermal ideal. Direct geothermal systems use shallow ground both as a heat source and as a heat sink for cooling, using heat pumps. Their application to poultry brooder houses could reduce electricity consumption by up to 75% and thus greenhouse gas emissions, since 91% of electricity comes from fossil fuels in Australia; minimise the need for expensive bottled gas heating; reduce the levels of ammonia emissions; and increase farm productivity.Read moreRead less
Turning pile foundations into sources of renewable energy: addressing remaining geotechnical challenges. Heat exchanger pile foundations are increasingly used for space heating and cooling of buildings to reduce their greenhouse gas emissions and increase their energy efficiency. This project will remove the uncertainty of their geotechnical design and will provide a springboard for the use of other buried geostructures for energy harvesting.
Cryogenic pipelines to replace trestle for liquefied gas transfer terminals. This project aims to develop geotechnical design tools, software, and publish design guidelines, for engineers to lay and keep cryogenic pipelines stable on the seabed. Transferring liquefied natural gas between floating tankers and onshore plants conventionally relies on a pipeline on a trestle system. As an alternative, novel subsea cryogenic pipelines are being considered. By ensuring the stability of subsea cryogeni ....Cryogenic pipelines to replace trestle for liquefied gas transfer terminals. This project aims to develop geotechnical design tools, software, and publish design guidelines, for engineers to lay and keep cryogenic pipelines stable on the seabed. Transferring liquefied natural gas between floating tankers and onshore plants conventionally relies on a pipeline on a trestle system. As an alternative, novel subsea cryogenic pipelines are being considered. By ensuring the stability of subsea cryogenic pipelines laid directly on the seabed, this project will provide significant benefits to Australia’s liquefied natural gas trade by unlocking substantial cost savings, and making this key export industry more competitive.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101751
Funder
Australian Research Council
Funding Amount
$351,000.00
Summary
Nanofiller reinforced concrete for high performance thermal energy storage. Harnessing the abundance of solar energy has been one of the most attractive energy alternatives. This project aims to investigate the mechanical properties, thermal energy storage capacity, thermal conductivity, long-term durability and nano/microstructural changes in nanofiller reinforced concrete composites using modern characterisation and modelling techniques. The newly developed concrete will be accessed as a therm ....Nanofiller reinforced concrete for high performance thermal energy storage. Harnessing the abundance of solar energy has been one of the most attractive energy alternatives. This project aims to investigate the mechanical properties, thermal energy storage capacity, thermal conductivity, long-term durability and nano/microstructural changes in nanofiller reinforced concrete composites using modern characterisation and modelling techniques. The newly developed concrete will be accessed as a thermal energy storage medium for concentrated solar energy plants. The project aims to create the next generation of construction materials to reduce the cost of the storage medium for solar energy harvesting.Read moreRead less
Lifting objects off the seabed. This project aims to investigate the process of lifting objects off the seabed. Understanding this breakout process is the scientific basis for a variety of offshore applications such as oil and gas decommissioning, marine salvage and securing foundations under extreme storms. This project expects to advance the understanding of soil-fluid-structure interactions of this problem using innovative high-speed photography observations and advanced numerical coupled ana ....Lifting objects off the seabed. This project aims to investigate the process of lifting objects off the seabed. Understanding this breakout process is the scientific basis for a variety of offshore applications such as oil and gas decommissioning, marine salvage and securing foundations under extreme storms. This project expects to advance the understanding of soil-fluid-structure interactions of this problem using innovative high-speed photography observations and advanced numerical coupled analyses. Outcomes will include a numerical tool, verified against a high quality experimental database, to predict the breakout process and uplift required for pressing offshore challenges. The ability for Australia’s engineers to predict lift procedures more accurately will contribute to safer operations in Australian waters and to the more economic harnessing of ocean resources.Read moreRead less
Microstructure characteristics to structural performance: the missing link in geopolymers. Geothermal energy from the deep earth's heat is emissions-free and renewable. Cements often fail in geothermal wells due to extreme temperature cycles. Alternative new geopolymer cements will be studied for trouble-free geothermal operations. Knowledge gained will also add confidence to the use of geopolymer in general construction.
Variational multiscale modelling of granular materials. Granular materials play an important role in a wide-range of problems related to physical infrastructure. These include landslides and similar catastrophic events often leading to loss of life and property. This project will aim to develop new methods for adequate simulation of granular flows to allow formulation of efficient risk mitigation strategies.