Minimisation of damage to residential structures due to ground movement. In Australia some 150,000 new houses are built every year with a total value of approximately $40 billion; making it one of the most significant industries affecting consumers and industries. With a quadrupling of the cost of building new houses in the last 20 years, an increase in the levels of expectations of owners, a high rate of reported damage in new and existing houses, and predications of worsening conditions under ....Minimisation of damage to residential structures due to ground movement. In Australia some 150,000 new houses are built every year with a total value of approximately $40 billion; making it one of the most significant industries affecting consumers and industries. With a quadrupling of the cost of building new houses in the last 20 years, an increase in the levels of expectations of owners, a high rate of reported damage in new and existing houses, and predications of worsening conditions under climate change scenarios; there is an urgent need to evaluate the causes of damage. The outcomes from this project will assist in minimising damage to houses from ground movement and in adopting new performance-based design methods for new homes to better match owner expectations. This will lead to cost effective and innovative solutions to meet adverse conditions.Read moreRead less
Mixed Mode Torsion-Shear-Bending Failure in SFRC Elements . In 2017 and 2018 the Australian Standards for the design of concrete bridges and structures were released; these are some of the first in the world, to include design procedures for steel fibre reinforced concrete (SFRC) in a comprehensive way. While rules have been introduced for shear and bending of SFRC girders, the rules exclude the use fibres to carry torsional moments. This study investigates the torsion-bending-shear interaction ....Mixed Mode Torsion-Shear-Bending Failure in SFRC Elements . In 2017 and 2018 the Australian Standards for the design of concrete bridges and structures were released; these are some of the first in the world, to include design procedures for steel fibre reinforced concrete (SFRC) in a comprehensive way. While rules have been introduced for shear and bending of SFRC girders, the rules exclude the use fibres to carry torsional moments. This study investigates the torsion-bending-shear interaction performance of SFRC members. The study will provide vital data needed for for adoption by engineers and Standards bodies.Read moreRead less
Offsite manufacture reimagined for high-performance adaptable housing. The project aims to address housing performance and affordability in Australia by deploying adaptable design for spatial reconfiguration and component reuse, to advance offsite timber manufacture towards energy efficient and healthy homes as mainstream practice. The intended outcome is the development, prototyping and monitoring of an offsite manufactured panelised lightweight timber system for high-performance homes, that is ....Offsite manufacture reimagined for high-performance adaptable housing. The project aims to address housing performance and affordability in Australia by deploying adaptable design for spatial reconfiguration and component reuse, to advance offsite timber manufacture towards energy efficient and healthy homes as mainstream practice. The intended outcome is the development, prototyping and monitoring of an offsite manufactured panelised lightweight timber system for high-performance homes, that is adaptable to all Australian climates and long-term household changes. This will contribute to the sustainable growth of the Australian housing market with significant benefits on housing affordability, adaptable design and long-lasting performance, while boosting the offsite manufactured timber construction sector.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100986
Funder
Australian Research Council
Funding Amount
$425,775.00
Summary
Blast Resistant Interlocking Brick Walls Using Engineered Waste Materials. This project aims to develop a next-generation building system integrated with robotic construction, using intelligent interlocking block units with hazard resistance, and sustainable engineered recycled plastic waste materials. It spans from discovery of using recycled waste materials to development of analysis and design methods for a new interlocking structure, as well as mitigation measures for blast resistance. The s ....Blast Resistant Interlocking Brick Walls Using Engineered Waste Materials. This project aims to develop a next-generation building system integrated with robotic construction, using intelligent interlocking block units with hazard resistance, and sustainable engineered recycled plastic waste materials. It spans from discovery of using recycled waste materials to development of analysis and design methods for a new interlocking structure, as well as mitigation measures for blast resistance. The successful implementation of this project will result in a technically, financially and environmentally sound structure form for the next-generation of robotic construction. This should lead to a revolution in construction that will substantially improve construction efficiency, quality and affordability.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100289
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Structural design and distributed fabrication of folded sandwich structures. This project intends to develop a new type of modular structural form that retains the streamlined construction of existing prefabricated systems, but can be rapidly fabricated in non-specialist and low-cost manufacturing plants. ‘Folded sandwich structures’ are part of the emerging field of origami-inspired engineering design. This project intends to conduct numerical, experimental and theoretical structural analysis a ....Structural design and distributed fabrication of folded sandwich structures. This project intends to develop a new type of modular structural form that retains the streamlined construction of existing prefabricated systems, but can be rapidly fabricated in non-specialist and low-cost manufacturing plants. ‘Folded sandwich structures’ are part of the emerging field of origami-inspired engineering design. This project intends to conduct numerical, experimental and theoretical structural analysis and optimisation on plate and shell building components. Such a system would enable the establishment of a distributed local manufacturing network, for example to provide the short-term infrastructure needs of regions affected by natural disaster.Read moreRead less