Time Dependent Behaviour of Fibre Reinforced Concrete Structures. . The project aims to quantify the initial and long-term cracking and deformation of fibre reinforced concrete structures such as tunnel linings and slabs under sustained in-service loads and conditions. Concrete structures with and without conventional steel reinforcement and containing either steel or polypropylene fibres mixed in the concrete will be tested experimentally and modelled analytically and numerically. Expected outc ....Time Dependent Behaviour of Fibre Reinforced Concrete Structures. . The project aims to quantify the initial and long-term cracking and deformation of fibre reinforced concrete structures such as tunnel linings and slabs under sustained in-service loads and conditions. Concrete structures with and without conventional steel reinforcement and containing either steel or polypropylene fibres mixed in the concrete will be tested experimentally and modelled analytically and numerically. Expected outcomes are benchmark experimental data on structural behaviour under sustained loads, development of reliable simulation models and robust design procedures for the control of time-dependent cracking and deformation in fibre reinforced concrete, with reduced maintenance costs and more sustainable concrete structures.Read moreRead less
Development of ultra-high performance concrete columns against blasts. This project aims to develop cost-effective formulae for ultra-high performance fibre reinforced concrete (UHPFRC) material with superior strength, ductility and durability to replace conventional concrete in critical infrastructures. In recent years, increasing threat from terrorism activities highlights the need to develop advanced building materials to protect against disastrous blasts; UHPFRC is an ideal option in structu ....Development of ultra-high performance concrete columns against blasts. This project aims to develop cost-effective formulae for ultra-high performance fibre reinforced concrete (UHPFRC) material with superior strength, ductility and durability to replace conventional concrete in critical infrastructures. In recent years, increasing threat from terrorism activities highlights the need to develop advanced building materials to protect against disastrous blasts; UHPFRC is an ideal option in structural protective design. This project plans to develop a mixed design approach for cost-effective UHPFRC material. It also plans to conduct blast tests and numerical investigations study blast resistance of UHPFRC columns and to develop analytical approaches and design methods for the application of such columns in critical infrastructure.Read moreRead less
Fire engineering of prefabricated structural systems of modular buildings. With the speed and cost benefits, modular construction is considered a game-changing solution in response to pandemics and natural disasters, and tackling the affordable housing crisis on a large scale. However, its uptake has been hindered due to recent fire incidents of modular buildings. This project aims to develop novel fire experiments and advanced modelling techniques to evaluate the fire performance of modular bui ....Fire engineering of prefabricated structural systems of modular buildings. With the speed and cost benefits, modular construction is considered a game-changing solution in response to pandemics and natural disasters, and tackling the affordable housing crisis on a large scale. However, its uptake has been hindered due to recent fire incidents of modular buildings. This project aims to develop novel fire experiments and advanced modelling techniques to evaluate the fire performance of modular buildings. Computational tools and fire safety design guidelines will also be developed to enable modular buildings to be built safer and more economically. This project will promote the widespread adoption of modular buildings to benefit end-users and the wider society, especially the housing sector and low-income households.Read moreRead less
Maximising the Use of Waste Glass in Sustainable Composite Columns. This project aims to develop novel structural concrete made with over 80% waste glass for use in manufacturing sustainable concrete-filled steel tubular columns used in buildings. Because of limited established markets for recycled glass, significant stockpiling of recycled and recyclable waste glass currently exists across Australia. This study will provide a suite of novel solutions to maximise the use of waste glass in struct ....Maximising the Use of Waste Glass in Sustainable Composite Columns. This project aims to develop novel structural concrete made with over 80% waste glass for use in manufacturing sustainable concrete-filled steel tubular columns used in buildings. Because of limited established markets for recycled glass, significant stockpiling of recycled and recyclable waste glass currently exists across Australia. This study will provide a suite of novel solutions to maximise the use of waste glass in structural concrete by fully replacing sand and gravel with crushed glass and up to 72% cement with glass powder. This will provide practical solutions to address not only Australia's glass recycling crisis but also the worldwide issue of disposal of waste glass.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101662
Funder
Australian Research Council
Funding Amount
$396,958.00
Summary
Reusable Fire-Resistant Column Rehabilitation with Fibre Reinforced Polymer. The application of fibre reinforced polymer (FRP) composites in structural rehabilitation is sometimes challenged or opposed due to the limitation of its fire resistance. This project aims to solve the fire resistance problem of FRP in column jacketing work using innovative approaches. The proposed scheme will be developed by using advanced materials and mechanical fastening technology. It can ensure structural servicea ....Reusable Fire-Resistant Column Rehabilitation with Fibre Reinforced Polymer. The application of fibre reinforced polymer (FRP) composites in structural rehabilitation is sometimes challenged or opposed due to the limitation of its fire resistance. This project aims to solve the fire resistance problem of FRP in column jacketing work using innovative approaches. The proposed scheme will be developed by using advanced materials and mechanical fastening technology. It can ensure structural serviceability of FRP jackets during a fire. And after the fire, the proposed jacketing scheme is reusable by applying a new layer of epoxy. The project is expected to advance the theory and technologies in structural rehabilitation. It will also provide significant benefits to the construction industry via sustainable construction.Read moreRead less
Structural Fuses for Safer and More Economical Bridge Construction. This project aims to develop a novel structural system leading to more economical concrete bridge construction by utilising a customised structural fuse. A significant margin of safety is required in structural design to account for accidental over-loading and to reduce the risk of structural collapse. Such a margin leads to more material usage. Incorporation of a fuse into the structure that is triggered upon over-loading will ....Structural Fuses for Safer and More Economical Bridge Construction. This project aims to develop a novel structural system leading to more economical concrete bridge construction by utilising a customised structural fuse. A significant margin of safety is required in structural design to account for accidental over-loading and to reduce the risk of structural collapse. Such a margin leads to more material usage. Incorporation of a fuse into the structure that is triggered upon over-loading will cause a safer failure mode and prohibit further increase of loading, both of which result in a reduced structure without undermining safety. The project is expected to advance structural theory, and also provide significant benefits to the construction industry via cost reduction and more eco-friendly constructions.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100406
Funder
Australian Research Council
Funding Amount
$429,000.00
Summary
Next generation Floating Structures with High-Performance Composites. Floating structures are facing severe deterioration problem due to steel corrosion. This project proposes to address the deterioration problem by developing prefabricated high-performance fibre-reinforced polymer (FRP)-ultra-high performance cementitious (UHPC) composite elements for future floating structures. FRP-UHPC composite elements have excellent strength-to-weight ratio and improved durability. Basic mechanical propert ....Next generation Floating Structures with High-Performance Composites. Floating structures are facing severe deterioration problem due to steel corrosion. This project proposes to address the deterioration problem by developing prefabricated high-performance fibre-reinforced polymer (FRP)-ultra-high performance cementitious (UHPC) composite elements for future floating structures. FRP-UHPC composite elements have excellent strength-to-weight ratio and improved durability. Basic mechanical properties and durability of FRP-UHPC composites will be investigated. Also, reliable connection device for FRP-UHPC structural units will be proposed and verified. The project is expected to provide durable floating structures with low maintenance cost, leading to a revolution of the current floating structures.Read moreRead less
Composite structures: a game changer for modular buildings. Modular construction can tackle Australia's housing affordability crisis on a large scale. This project aims to develop cutting-edge technologies for the next generation of modular buildings by embracing recent breakthroughs in construction materials, computational modelling methods and construction techniques. Expected outcomes include a novel composite modular unit, a smart joining technique, a robust computational framework and desig ....Composite structures: a game changer for modular buildings. Modular construction can tackle Australia's housing affordability crisis on a large scale. This project aims to develop cutting-edge technologies for the next generation of modular buildings by embracing recent breakthroughs in construction materials, computational modelling methods and construction techniques. Expected outcomes include a novel composite modular unit, a smart joining technique, a robust computational framework and design guidelines that enable modular buildings to be built taller, safer, faster and thus cheaper than current practices allow. This project will position Australia at the forefront of modular construction technology, and make the local construction industry more competitive globally.Read moreRead less
Development of prefabricated composite building panels and connections . This project will develop a new prefabricated composite brick-concrete panel technology, by exploiting cutting-edge manufacturing capabilities for the production of bricks and concrete components. It is expected to generate new robust design methodologies at both service and ultimate conditions by relying on advanced testing and theoretical modelling.
The project is expected to transform the current brick industry by repla ....Development of prefabricated composite building panels and connections . This project will develop a new prefabricated composite brick-concrete panel technology, by exploiting cutting-edge manufacturing capabilities for the production of bricks and concrete components. It is expected to generate new robust design methodologies at both service and ultimate conditions by relying on advanced testing and theoretical modelling.
The project is expected to transform the current brick industry by replacing traditional labour-intense brick construction with advanced and cost-effective prefabricated technologies that will enable brick construction to enter new markets, such as those of multi-storey buildings and complex load-bearing facades, previously not feasible or cost-effective with traditional brick technology.
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Innovative coupled composite steel-concrete shear wall and frame systems. This project aims to develop an innovative coupled composite steel-concrete shear wall and frame system that revolutionises and improves the economical design and construction of multi-storey buildings. The proposed system uses novel cost-effective composite structural components that can be prefabricated and easily assembled on-site using innovative blind bolting techniques to speed up construction. The project will offer ....Innovative coupled composite steel-concrete shear wall and frame systems. This project aims to develop an innovative coupled composite steel-concrete shear wall and frame system that revolutionises and improves the economical design and construction of multi-storey buildings. The proposed system uses novel cost-effective composite structural components that can be prefabricated and easily assembled on-site using innovative blind bolting techniques to speed up construction. The project will offer a promising opportunity to promote prefabricated and modular construction which is believed will have a major benefit in shaping the future construction industry. This will provide significant benefits to Australian structural engineers and the construction industry in advancing their knowledge in composite construction.Read moreRead less