Harnessing the power of oceans: anchors for floating energy devices. This project aims to establish a geotechnical design framework for shared anchoring systems subjected to multidirectional cyclic loading for large integrated arrays of floating wind turbines and floating wave energy converters. This is expected to facilitate new, economic foundation solutions, generating radical cost savings to help unlock Australia's renewable ocean energy resources. The project aims to utilise a blend of stat ....Harnessing the power of oceans: anchors for floating energy devices. This project aims to establish a geotechnical design framework for shared anchoring systems subjected to multidirectional cyclic loading for large integrated arrays of floating wind turbines and floating wave energy converters. This is expected to facilitate new, economic foundation solutions, generating radical cost savings to help unlock Australia's renewable ocean energy resources. The project aims to utilise a blend of state-of-the-art centrifuge modelling techniques and numerical modelling, incorporating an energy-based method and yield envelopes. This innovative methodology aims to establish a validated framework for understanding and predicting foundation performance under the complex load histories arising in renewable ocean energy applications.Read moreRead less
A holistic integrated design approach for building envelopes incorporating sustainability, security and safety. This project aims to develop a highly secure and sustainable facade system for buildings with a significant enhancement over other conventional facades in terms of both protection against extreme loads and life cycle energy performance. The outcome of this project can be used to improve the sustainability and safety of buildings in Australia.
Determination of the condition and strength capacity of in-service timber poles in energy networks. The project addresses an important issue facing power industries and engineering community worldwide, that is, reliable and optimal management of power distribution infrastructures. The outcomes lead to new technologies that not only provide great social-economic benefits but advance knowledge and practice of the research at international level.
Permeable Pavements with Concrete Surface Layers- Experimental and Theoretical Basis for Analysis and Design. Permeable pavements constitute unique and effective means to address important environmental issues and support green, sustainable growth. By capturing stormwater and allowing it to seep into the ground, porous pavements are instrumental in recharging groundwater, reducing stormwater runoff and preventing pollutants from entering the Australian river systems and sea-shores. Other advanta ....Permeable Pavements with Concrete Surface Layers- Experimental and Theoretical Basis for Analysis and Design. Permeable pavements constitute unique and effective means to address important environmental issues and support green, sustainable growth. By capturing stormwater and allowing it to seep into the ground, porous pavements are instrumental in recharging groundwater, reducing stormwater runoff and preventing pollutants from entering the Australian river systems and sea-shores. Other advantages for Australian communities that are associated with the construction of permeable pavement arise from their properties such as acoustic and thermal insulation due to the high void content of the material. Thus, permeable pavements improve on the living conditions in urban areas by reducing noise levels and preventing urban heat island effects.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
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
Large-scale geotechnical analysis of new and aged pipeline infrastructure. This project aims to develop novel computational methods for predicting failure rates in geographically distributed pipeline networks affected by ground movements, one of the main triggers of bursts and leakages in buried pipe infrastructure. The project will be based on a blend of experimental work and development of simulation tools to quantify the coupled effects of pipe deterioration, poor backfilling and ground movem ....Large-scale geotechnical analysis of new and aged pipeline infrastructure. This project aims to develop novel computational methods for predicting failure rates in geographically distributed pipeline networks affected by ground movements, one of the main triggers of bursts and leakages in buried pipe infrastructure. The project will be based on a blend of experimental work and development of simulation tools to quantify the coupled effects of pipe deterioration, poor backfilling and ground movements in aged and new pipelines. The results will feed towards the formulation of a framework for the large-scale stress analysis of segmented and continuous pipes, capable of using as input high-resolution geospatial observations and predictions of ground movements.Read moreRead less
Unsaturated soil-structure interaction with emphasis on buried pipelines. Buried pipeline networks is the most common mode of transporting and distributing water, oil and gas resources and pipeline failures may have a major socioeconomic and environmental impact. The goal is to develop a framework for describing the mechanisms underlying soil-pipe interaction, aiming to reduce the failure risk of pipes affected by geohazards. The project aims to model the response of pipelines in the laboratory, ....Unsaturated soil-structure interaction with emphasis on buried pipelines. Buried pipeline networks is the most common mode of transporting and distributing water, oil and gas resources and pipeline failures may have a major socioeconomic and environmental impact. The goal is to develop a framework for describing the mechanisms underlying soil-pipe interaction, aiming to reduce the failure risk of pipes affected by geohazards. The project aims to model the response of pipelines in the laboratory, using a new custom-built apparatus. Experimental results are expected to provide insight for developing a theoretical model to quantify the effect of soil moisture on pipe integrity, and propose design formulas. A general framework is intended to be developed for handling various unsaturated soil-structure interaction problems in geotechnical engineering.Read moreRead less
Fuzzy finite element analysis of smart structures using concepts of optimization. The major aim of this research is to develop an innovative approach using fuzzy finite element method for the analysis and design of smart control systems for civil engineering structures subjected to vibrations due to earthquakes. The significance of this project is the proposal to combine, for the first time, techniques such as finite element, fuzzy logic and optimization in a unified manner. The final result wil ....Fuzzy finite element analysis of smart structures using concepts of optimization. The major aim of this research is to develop an innovative approach using fuzzy finite element method for the analysis and design of smart control systems for civil engineering structures subjected to vibrations due to earthquakes. The significance of this project is the proposal to combine, for the first time, techniques such as finite element, fuzzy logic and optimization in a unified manner. The final result will produce an efficient design tool for a structural system integrated with smart sensors/actuators for vibration control.Read moreRead less
Sustainable Technology for Removal of Trace Contaminants in Rural Water Supplies. Provision of safe drinking water treatment using sustainable technology which can be applied in rural locations and emergency situations is the main aim of this project. A hybrid membrane process will be combined with solar energy for the removal of pathogens and trace pollutants such as uranium, fluoride, arsenic, boron and nitrates. The technology will be designed for remote community situations and hence be robu ....Sustainable Technology for Removal of Trace Contaminants in Rural Water Supplies. Provision of safe drinking water treatment using sustainable technology which can be applied in rural locations and emergency situations is the main aim of this project. A hybrid membrane process will be combined with solar energy for the removal of pathogens and trace pollutants such as uranium, fluoride, arsenic, boron and nitrates. The technology will be designed for remote community situations and hence be robust and low in maintenance. Using solar energy is a challenge for trace contaminant removal as the operating conditions vary with the power fluctuations, which presents a substantially different situation to grid power connection.Read moreRead less