Industrial Transformation Research Hubs - Grant ID: IH150100030
Funder
Australian Research Council
Funding Amount
$1,577,087.00
Summary
ARC Research Hub to Transform Future Tall Timber Buildings. ARC Research Hub for Advanced Solutions to Transform Tall Timber Buildings. This hub aims to develop skills, knowledge and resources for novel designs of tall timber buildings that incorporate architectural, engineering and sustainability drivers while meeting regulatory constraints. The project aims to develop innovative engineering solutions that address crucial barriers to the use of structural timber in the fast growing and extensiv ....ARC Research Hub to Transform Future Tall Timber Buildings. ARC Research Hub for Advanced Solutions to Transform Tall Timber Buildings. This hub aims to develop skills, knowledge and resources for novel designs of tall timber buildings that incorporate architectural, engineering and sustainability drivers while meeting regulatory constraints. The project aims to develop innovative engineering solutions that address crucial barriers to the use of structural timber in the fast growing and extensive medium-rise tall buildings market where timber is, on many counts, the ideal construction material. It is expected that eliminating these barriers will open a new market for novel technologies and methods generated through this work.Read moreRead less
Microbial infestation of pre-painted steel building materials: chemical and microbial characterization, model development and control strategies. Coated steel building materials are a multi-billion dollar Australian industry. Microorganisms form slime layers on those materials, which are unsightly and reduce their energy benefits. The project will identify the problem organisms, the factors that facilitate their growth and will develop novel biofilm resistant, functional building materials.
Bushfire-enhanced wind and its effects on buildings. This project seeks to advance our understanding of bushfire–wind interaction to improve current design standards for buildings against bushfire-enhanced winds. Bushfire-enhanced winds have caused considerable property damage and loss of lives. The project aims to identify the mechanisms governing bushfire–wind interaction and determine the wind load effects on buildings due to bushfire-enhanced wind. It aims to do so by using advanced computat ....Bushfire-enhanced wind and its effects on buildings. This project seeks to advance our understanding of bushfire–wind interaction to improve current design standards for buildings against bushfire-enhanced winds. Bushfire-enhanced winds have caused considerable property damage and loss of lives. The project aims to identify the mechanisms governing bushfire–wind interaction and determine the wind load effects on buildings due to bushfire-enhanced wind. It aims to do so by using advanced computation techniques and unique fire-wind tunnel test facility. This knowledge is designed to guide the development of improved building construction standards for bushfire-prone regions to facilitate the design and construction of a new generation of bushfire-resistant buildings that safeguard lives and properties against the increasing threat of bushfire due to climate change.Read moreRead less
Improving the Environmental Performance of Australian Construction Projects. This project aims to investigate the environmental impacts of construction in Australia through the development of a sophisticated hybrid environmental assessment model. The project aims to assist in identifying the most significant environmental impacts, critical areas for mitigation efforts and informing environmental policy and programs within the Australian construction industry. The development of one of the most s ....Improving the Environmental Performance of Australian Construction Projects. This project aims to investigate the environmental impacts of construction in Australia through the development of a sophisticated hybrid environmental assessment model. The project aims to assist in identifying the most significant environmental impacts, critical areas for mitigation efforts and informing environmental policy and programs within the Australian construction industry. The development of one of the most sophisticated and comprehensive models for assessing environmental impacts ever produced is expected to enable cost- and time-efficient evaluation of multiple environmental impacts at a high level of detail and completeness. This should lead to considerable improvements to the environmental performance of Australian construction projects.Read moreRead less
Decarbonising built environments with hempcrete and green wall technology. This project aims to develop an integrated prefabricated building panel solution combining green wall and hempcrete technology to address environmental problems associated with the usage of carbon intensive construction materials, dense urbanisation, climate change and biodiversity. Innovation in hempcrete technology consist in using low carbon options including alkali-activated binders and biomineralization technology, g ....Decarbonising built environments with hempcrete and green wall technology. This project aims to develop an integrated prefabricated building panel solution combining green wall and hempcrete technology to address environmental problems associated with the usage of carbon intensive construction materials, dense urbanisation, climate change and biodiversity. Innovation in hempcrete technology consist in using low carbon options including alkali-activated binders and biomineralization technology, glass waste replacing natural sand. Hempcrete green wall panels will be design to be carbon positive, improve the thermal performance of buildings, provide better acoustic insolation, reduce the risk of mould proliferation, control indoor humidity and air quality and improve indoor thermal comfort.
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Discovery Early Career Researcher Award - Grant ID: DE210100755
Funder
Australian Research Council
Funding Amount
$462,948.00
Summary
Developing phytosystems for the biofiltration of air pollutants . This project aims to develop, evaluate and apply a range of biotechnology driven solutions for the use of phytosystem biofilters designed for air purification. The findings of the project will demonstrate the fundamental mechanisms behind botanical air pollutant biofiltration, apply systematic technological development against a range of air pollutants, and provide strategies to deploy the technology. With a transdisciplinary appr ....Developing phytosystems for the biofiltration of air pollutants . This project aims to develop, evaluate and apply a range of biotechnology driven solutions for the use of phytosystem biofilters designed for air purification. The findings of the project will demonstrate the fundamental mechanisms behind botanical air pollutant biofiltration, apply systematic technological development against a range of air pollutants, and provide strategies to deploy the technology. With a transdisciplinary approach utilising techniques new to this discipline, the project will substantially advance the fundamental science underlying this novel and highly valuable area of air-bioremediation technology, and will create a much stronger economic driver for this Australia-led innovation.Read moreRead less
Building occupants survey system Australia. The Building Occupants Survey System Australia - BOSSA - is a post-occupancy evaluation instrument. The database will become an Australian benchmark against which particular buildings can be compared, providing both a valuable quality assurance service to building owners and managers, and a resource for researchers in Australian built environments.
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.
New generation nanostructured coatings with combined control of spectral and angular emissivity. The aim of this project is to generate a complete scientific understanding of a new generation of hybrid, tri-layered, optically-selective coatings. The new design paradigm combines the very different attributes of smooth and nanostructured layers so that superior and simultaneous control of both spectral and angular properties of light can be achieved. Existing theory will be extended so that quanti ....New generation nanostructured coatings with combined control of spectral and angular emissivity. The aim of this project is to generate a complete scientific understanding of a new generation of hybrid, tri-layered, optically-selective coatings. The new design paradigm combines the very different attributes of smooth and nanostructured layers so that superior and simultaneous control of both spectral and angular properties of light can be achieved. Existing theory will be extended so that quantitative analyses of these new systems and other hybrids become possible and new and improved fabrication techniques will be developed. The work will unlock new technological possibilities for coating performance and application and is likely to be associated with significant improvements in energy conservation and generation. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE200101747
Funder
Australian Research Council
Funding Amount
$354,216.00
Summary
Mechanism and control of water droplets from condensation to defrosting. The deposition of frost/ice is inevitable and negatively impacts many fields and industries, such as the frosting of air source heat pumps and liquid natural gas vaporizers, and icing of aircraft and power cables. On the other hand, ice slurry is widely deployed for cold storage and transportation of food and organs. To accurately predict and control the frosting/icing process, this project aims to study and understand the ....Mechanism and control of water droplets from condensation to defrosting. The deposition of frost/ice is inevitable and negatively impacts many fields and industries, such as the frosting of air source heat pumps and liquid natural gas vaporizers, and icing of aircraft and power cables. On the other hand, ice slurry is widely deployed for cold storage and transportation of food and organs. To accurately predict and control the frosting/icing process, this project aims to study and understand the interrelated heat, mass and momentum transport phenomena of water droplets from condensation to defrosting. Outcomes of this project should contribute to the development of new material, such as applicable anti-icing/anti-frosting surfaces, and relative technology and equipment, and thus benefit a number of fields.Read moreRead less