Hybrid steel-framed structural systems for mid-rise buildings. The project aims to develop solutions for lightweight structural systems. Hybrid steel structures are those constructed from a mixture of conventional hot-rolled steel sections and tubes combined with lightweight cold-formed steel structural members. There is an increasing need to provide prefabricated structural systems that are highly constructible and modular in mid-rise (5–10 storeys) residential apartment and commercial building ....Hybrid steel-framed structural systems for mid-rise buildings. The project aims to develop solutions for lightweight structural systems. Hybrid steel structures are those constructed from a mixture of conventional hot-rolled steel sections and tubes combined with lightweight cold-formed steel structural members. There is an increasing need to provide prefabricated structural systems that are highly constructible and modular in mid-rise (5–10 storeys) residential apartment and commercial buildings. The major problem in producing efficient hybrid systems is the connections between the hot-rolled framing members and the lightweight cold-formed members. The main aim of the project is to carry out experimental and theoretical research into the hybrid connections. The expected outcomes of the research are more efficient and standardised structural connections and systems.Read moreRead less
Cold-rolled Aluminium Structural Members and Systems. BlueScope Permalite has recently demonstrated that it is possible to produce aluminium structural sections by roll-forming. This presents a faster and less energy consuming method of production than conventional extrusion. Through experiments and numerical simulations, the project aims to develop guidelines for the design of single members and complete structural systems in cold-rolled aluminium. The project intends to quantify the strength e ....Cold-rolled Aluminium Structural Members and Systems. BlueScope Permalite has recently demonstrated that it is possible to produce aluminium structural sections by roll-forming. This presents a faster and less energy consuming method of production than conventional extrusion. Through experiments and numerical simulations, the project aims to develop guidelines for the design of single members and complete structural systems in cold-rolled aluminium. The project intends to quantify the strength enhancements achievable by the cold-rolling process and devise guidelines for determining the strength of cold-rolled aluminium sections and systems, considering the prevalent buckling modes for C- and Z-sections, their interactions and the effect of gradual yielding.Read moreRead less
Braced batter micropile group: New design theory and performance framework. Braced batter micropile group: New design theory and performance framework. This project aims to research the design and performance of innovative biomimetic braced battered micropile group footings. This project will test Surefoot, the new concrete free footing, in the laboratory, in the field, and through numerical and analytical modelling. Surefoot’s mechanisms of action are poorly understood but clearly more complex ....Braced batter micropile group: New design theory and performance framework. Braced batter micropile group: New design theory and performance framework. This project aims to research the design and performance of innovative biomimetic braced battered micropile group footings. This project will test Surefoot, the new concrete free footing, in the laboratory, in the field, and through numerical and analytical modelling. Surefoot’s mechanisms of action are poorly understood but clearly more complex than current micropile theory; this project will research the mechanism of load transfer from micropiles to the soil and soil response.Read moreRead less
Achieving structural morphing via functionalising nonlinear buckling. This project aims to develop a general framework to analyse and design functional components of buildings and structures, where they change shapes (morphing) by buckling. Australian buildings consume 20% of the nation’s total energy production on heating and cooling, and projected population increases are likely to increase energy demands. The shape changes are optimised, e.g. to reduce energy consumption by minimising solar r ....Achieving structural morphing via functionalising nonlinear buckling. This project aims to develop a general framework to analyse and design functional components of buildings and structures, where they change shapes (morphing) by buckling. Australian buildings consume 20% of the nation’s total energy production on heating and cooling, and projected population increases are likely to increase energy demands. The shape changes are optimised, e.g. to reduce energy consumption by minimising solar radiation loads or maximising natural air ventilation. The project expects to develop building technology solutions to reduce Australia's energy consumption, and provide domestic and global market opportunities in the high-tech manufacturing sector.Read moreRead less
Prefabricated reusable building modules: reducing building life cycle environmental impacts. The outcomes of this project will enhance Australia's ability to provide globally competitive next generation building construction solutions. It will also help to not only ensure that Australian industry is at the forefront of best-practice environmental innovation but also support industry to develop and expand export markets, providing significant economic benefits. The outcomes of this project will b ....Prefabricated reusable building modules: reducing building life cycle environmental impacts. The outcomes of this project will enhance Australia's ability to provide globally competitive next generation building construction solutions. It will also help to not only ensure that Australian industry is at the forefront of best-practice environmental innovation but also support industry to develop and expand export markets, providing significant economic benefits. The outcomes of this project will be valuable to the construction industry to make implementation of ecologically sustainable design more rigorous. Strategies for improving the environmental performance of construction, particularly through prefabrication of durable building components will be able to be better facilitated by the research undertaken in this project.Read moreRead less
Elastocaloric cooling systems for buildings and the built environment. This project aims to develop elastocaloric cooling systems that will find application in buildings and the built environment. The main aims of the projects are to establish a new technology capable of enhancing the efficiency of traditional cooling systems used for building applications and of reducing the contribution of structural and architectural components to the urban heat island effect. This work will be supported by a ....Elastocaloric cooling systems for buildings and the built environment. This project aims to develop elastocaloric cooling systems that will find application in buildings and the built environment. The main aims of the projects are to establish a new technology capable of enhancing the efficiency of traditional cooling systems used for building applications and of reducing the contribution of structural and architectural components to the urban heat island effect. This work will be supported by a new theoretical platform that will incorporate the elastocaloric cooling behaviour into the structural, thermal and energy performance of the building components, as well as by prototype testing. The outcomes of the project will lead to new building cooling technologies, increasing efficiency of traditional cooling building systems.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150101512
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Behaviour of novel FRP-timber composite thin-walled structural members. This project aims to investigate the structural behaviour of innovative hybrid Fibre Reinforced Polymer - Timber Composite (FRPTC) sections manufactured from small 'sawlog' timber. These FRPTC sections are made by taking advantage of the orthotropic material properties and, unlike sawn timber, these structures have efficient cross sectional shapes and can be made easily in different sizes to match the requirements. Even thou ....Behaviour of novel FRP-timber composite thin-walled structural members. This project aims to investigate the structural behaviour of innovative hybrid Fibre Reinforced Polymer - Timber Composite (FRPTC) sections manufactured from small 'sawlog' timber. These FRPTC sections are made by taking advantage of the orthotropic material properties and, unlike sawn timber, these structures have efficient cross sectional shapes and can be made easily in different sizes to match the requirements. Even though preliminary studies have shown promising results, behaviour of these FRPTC sections are not yet fully understood. This project aims to investigate the behaviour of these novel FRPTC sections and to develop numerical models to allow wide usage of these sections.Read moreRead less
Behaviour of novel FRP-timber ultralight thin-walled structural members. This project aims to investigate the structural behaviour of innovative hybrid fibre reinforced polymer–timber composite (FRPTC) thin-walled members which could be used as structural members in roof systems, façade systems, floor systems, etc. These FRPTC sections are made by taking advantage of the orthotropic material properties. Unlike sawn timber, these structures have efficient cross-sectional shapes and can be made ea ....Behaviour of novel FRP-timber ultralight thin-walled structural members. This project aims to investigate the structural behaviour of innovative hybrid fibre reinforced polymer–timber composite (FRPTC) thin-walled members which could be used as structural members in roof systems, façade systems, floor systems, etc. These FRPTC sections are made by taking advantage of the orthotropic material properties. Unlike sawn timber, these structures have efficient cross-sectional shapes and can be made easily in different sizes to match the requirements. Preliminary studies have shown promising results, however the behaviour of these novel FRPTC members is not yet fully understood. This project aims to investigate the behaviour of these novel FRPTC thin-walled members, specifically Cee-section members.Read moreRead less
Buckling capacity of high-strength steel flexural members. This project aims to investigate the capacity of high-strength steel (HSS) flexural members by undertaking physical tests and numerical simulations, and proposes to craft innovative overarching design guidance for them within a paradigm of Design by Advanced Analysis. HSS structures are significant as they are lighter than their mild steel counterparts and so use less material, with a much lower carbon footprint. Modern metallurgical pro ....Buckling capacity of high-strength steel flexural members. This project aims to investigate the capacity of high-strength steel (HSS) flexural members by undertaking physical tests and numerical simulations, and proposes to craft innovative overarching design guidance for them within a paradigm of Design by Advanced Analysis. HSS structures are significant as they are lighter than their mild steel counterparts and so use less material, with a much lower carbon footprint. Modern metallurgical process can produce HSS of Grade 1000 Megapascals or higher, but there is no specific structural code governing their design. Surprisingly little research has been reported on HSS flexural members which fail by lateral buckling, and this is the focus of the project, filling the gap needed to produce an advanced design standard.Read moreRead less
Durability and debonding resistance of composite based strengthening techniques for deteriorated structures. Australia has many concrete structures exposed to aggressive environments that are deteriorating prior to their intended design life due to durability issues. Externally bonded fibre reinforced polymer composite applications are emerging as a method of structural rehabilitation. This project will provide safe and reliable strengthened structures.