Industrial Transformation Research Hubs - Grant ID: IH200100010
Funder
Australian Research Council
Funding Amount
$5,000,000.00
Summary
ARC Research Hub for Transformation of Reclaimed Waste Resources to Engineered Materials and Solutions for a Circular Economy. This project aims to create new knowledge to reduce waste going to landfills and transform reclaimed waste into new materials for use in construction and other manufacturing sectors. It integrates multisector input and multidisciplinary academic research to address ten challenging waste streams. Expected outcomes are smart materials, socio-technical change, accelerated t ....ARC Research Hub for Transformation of Reclaimed Waste Resources to Engineered Materials and Solutions for a Circular Economy. This project aims to create new knowledge to reduce waste going to landfills and transform reclaimed waste into new materials for use in construction and other manufacturing sectors. It integrates multisector input and multidisciplinary academic research to address ten challenging waste streams. Expected outcomes are smart materials, socio-technical change, accelerated testing methods, predictive modeling, circular life cycle costing and a trusted evidence base. Outcomes will lead to commercial benefits as well as jobs and a significant contribution to addressing the pressing environmental impacts of waste production, management, and re-use.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.
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
Special Research Initiatives - Grant ID: SR0354894
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Innovative risk analysis, assessment, rehabilitation and strengthening of aging critical civil infrastructure. Much essential civil engineering infrastructure such as bridges, buildings, dams, pipelines and pavements was commissioned many decades ago, and sustaining the integrity of this infrastructure in developed nations as it ages is now considered to be a major challenge to the engineering and scientific community. Australia is not spared by the ramifications of its aging civil assets, and ....Innovative risk analysis, assessment, rehabilitation and strengthening of aging critical civil infrastructure. Much essential civil engineering infrastructure such as bridges, buildings, dams, pipelines and pavements was commissioned many decades ago, and sustaining the integrity of this infrastructure in developed nations as it ages is now considered to be a major challenge to the engineering and scientific community. Australia is not spared by the ramifications of its aging civil assets, and identification and rectification procedures that are often ad-hoc now represent a sizeable proportion of the GDP. This Research Network draws together the leading Australian research groups in engineering and applied mechanics in a coordinated program to address this most important cost to the community.Read moreRead less
Characterisation of granular base and sub-base pavement materials under cyclic loading. Pavement construction is a high cost item in road construction. Until very recently, pavements were designed based on empirical rules and restrictive material prescriptions. With the introduction of rational mechanistic pavement design methodology, it has become necessary to reliably characterise the behaviour of road foundation materials under cyclic loading. This project is focused on the characterisati ....Characterisation of granular base and sub-base pavement materials under cyclic loading. Pavement construction is a high cost item in road construction. Until very recently, pavements were designed based on empirical rules and restrictive material prescriptions. With the introduction of rational mechanistic pavement design methodology, it has become necessary to reliably characterise the behaviour of road foundation materials under cyclic loading. This project is focused on the characterisation of unbound granular base and sub-base materials. Since these are geo-materials, geotechnical concepts such as the influence of stress path will be used. This project will lead to better roads at lower cost, and significant leap in know-how in pavement design and material specification.Read moreRead less
Modelling and simulation of complex granular flows. Granular flows are of crucial importance in a wide range of problems related to civil infrastructure. These include landslides and similar catastrophic events, often leading to loss of life and property. The project aims to develop new methods for accurate prediction of such events thus allowing for the formulation of efficient mitigation strategies.
Innovative composite systems with enhanced resilience to extreme loads. The rapidly increasing global population (projected to be 9.8 billion by 2050) and global urbanisation have created a demand for the construction industry, thereby increasing the pressure on our planet’s limited resources for the construction industry. This high demand can yield detrimental effects to the environment due to the high carbon footprint of conventional construction materials, and is amplified by the threat of ac ....Innovative composite systems with enhanced resilience to extreme loads. The rapidly increasing global population (projected to be 9.8 billion by 2050) and global urbanisation have created a demand for the construction industry, thereby increasing the pressure on our planet’s limited resources for the construction industry. This high demand can yield detrimental effects to the environment due to the high carbon footprint of conventional construction materials, and is amplified by the threat of accidental or deliberate extreme loadings to buildings, which can trigger fatal progressive collapse events. The proposed project aims to develop an innovative structural system with that possesses superior structural resilience to extreme loads and progressive collapse using lightweight eco-friendly materials. Read moreRead less
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.
Development of structural-functional integrated concrete. This project seeks to create a structural concrete to control indoor temperature using thermal energy storage aggregates (TESA). Such concrete would improve indoor comfort without human intervention and significantly reduce the energy consumed in heating and cooling. TESA concrete is made of porous lightweight aggregate impregnated with phase-change materials. The aim of this project is to investigate and optimise the structural and funct ....Development of structural-functional integrated concrete. This project seeks to create a structural concrete to control indoor temperature using thermal energy storage aggregates (TESA). Such concrete would improve indoor comfort without human intervention and significantly reduce the energy consumed in heating and cooling. TESA concrete is made of porous lightweight aggregate impregnated with phase-change materials. The aim of this project is to investigate and optimise the structural and functional performance of TESA concrete. In particular, it aims to reveal the microstructure, mechanical, thermal, durability properties of TESA concrete and ways to optimise its overall performance. This knowledge would provide a solid foundation for the numerical simulation of TESA concrete and its use in engineering applications.Read moreRead less
The Development of a Hybrid Energy Simulation Model for Masonry Enclosures. This project aims to develop and validate a hybrid energy simulation model for assessing the thermal performance of masonry enclosures. The model will combine the zonal and computational fluid dynamics modelling techniques into a fully integrated computational tool. Once validated, the proposed model will be employed to evaluate the thermal performance of a wide range of wall designs taking into account the Australian cl ....The Development of a Hybrid Energy Simulation Model for Masonry Enclosures. This project aims to develop and validate a hybrid energy simulation model for assessing the thermal performance of masonry enclosures. The model will combine the zonal and computational fluid dynamics modelling techniques into a fully integrated computational tool. Once validated, the proposed model will be employed to evaluate the thermal performance of a wide range of wall designs taking into account the Australian climatic conditions, construction practices and typical residential developments. The results will be then employed to modify and refine the existing wall designs and develop optimum masonry walling system(s) that are well suited for the Australian climatic conditions.Read moreRead less