Retrofit of Steel Connections subject to Fatigue Load by Utilizing carbon fibre reinforced polymeric (CFRP) and Modified Epoxy Structural Adhesives. The proposed research project will challenge conventional methods of repairing or strengthening steel structures by using an advanced material (CFRP) together with modified epoxy structural adhesives. It will not only provide reliable retrofitting of existing structures but will also build safe, more economic and smarter steel structures. It will co ....Retrofit of Steel Connections subject to Fatigue Load by Utilizing carbon fibre reinforced polymeric (CFRP) and Modified Epoxy Structural Adhesives. The proposed research project will challenge conventional methods of repairing or strengthening steel structures by using an advanced material (CFRP) together with modified epoxy structural adhesives. It will not only provide reliable retrofitting of existing structures but will also build safe, more economic and smarter steel structures. It will contribute to the socio-economic wellbeing of Australia, including road and railway infrastructure, offshore, mining and recreation industries, increasing the international competitiveness of the Australian steel industry and infrastructure maintenance capability. Australia will be better positioned in the region for potential technology transfer to Asian and surrounding countries.Read moreRead less
CFRP (Carbon Fibre Reinforced Polymer) Strengthening of Steel Structures. The research will produce a breakthrough in understanding the bond characteristics between CFRP and steel. It will develop strengthening techniques for steel structures. The project will contribute to improved cost effectiveness and safety of steel structures thereby contributing to the socio-economic well-being of Australia including the road, offshore, building and mining industries. It will increase the international co ....CFRP (Carbon Fibre Reinforced Polymer) Strengthening of Steel Structures. The research will produce a breakthrough in understanding the bond characteristics between CFRP and steel. It will develop strengthening techniques for steel structures. The project will contribute to improved cost effectiveness and safety of steel structures thereby contributing to the socio-economic well-being of Australia including the road, offshore, building and mining industries. It will increase the international competitiveness of the Australian steel industry and Australia's infrastructure maintenance capability. Furthermore, Australia will be better positioned for potential technology transfer to Asian countries in this technical area.Read moreRead less
Development of economical beam-column connections for robust composite steel-concrete structural frames. The proposed construction systems will offer a competitive and more robust alternative for developers, building owners and occupants. The successful development of the proposed construction systems will lead to an increased market for blind bolts, steel circular hollow sections, steel Universal Beams and metal decking. An added benefit of the proposed systems is an anticipated improvement in ....Development of economical beam-column connections for robust composite steel-concrete structural frames. The proposed construction systems will offer a competitive and more robust alternative for developers, building owners and occupants. The successful development of the proposed construction systems will lead to an increased market for blind bolts, steel circular hollow sections, steel Universal Beams and metal decking. An added benefit of the proposed systems is an anticipated improvement in performance, relative to existing systems, under low probability, high consequence events such as 2500-year return period level earthquakes (in the relevant region) or blast loading. These unique and innovative structural solutions should drive the competitive advantage of Australian engineers in international markets.Read moreRead less
Debonding Failure in CFRP Strengthened Steel Structures. The research will make a breakthrough in understanding the bond characteristics between CFRP and steel. It will enhance the capacity of Australian researchers to participate in a new cutting-edge research area, and help create a vibrant new industry for strengthening steel structures. The project will contribute to improved cost efficiency and safety of steel structures thereby contributing to the socio-economic well being of Australia inc ....Debonding Failure in CFRP Strengthened Steel Structures. The research will make a breakthrough in understanding the bond characteristics between CFRP and steel. It will enhance the capacity of Australian researchers to participate in a new cutting-edge research area, and help create a vibrant new industry for strengthening steel structures. The project will contribute to improved cost efficiency and safety of steel structures thereby contributing to the socio-economic well being of Australia including road, offshore, building and mining industries. It will increase the international competitiveness of Australian steel industry and infrastructure maintenance capability. Australia will be better positioned in this region for potential technology transfer to Asian countries.Read moreRead less
Innovative Retrofitting Techniques for the Protection of Anchorage Zones in Cable-Stayed Bridges Subjected to Blast Loads. The project will seek to develop an innovative technology to retrofit anchorage zones in cable-stayed bridges subjected to close-in detonations and severe impulsive loading, through a comprehensive theoretical and experimental study. The innovative material used for the strengthening purposes developed as part of the study will greatly assist engineers in protection and retr ....Innovative Retrofitting Techniques for the Protection of Anchorage Zones in Cable-Stayed Bridges Subjected to Blast Loads. The project will seek to develop an innovative technology to retrofit anchorage zones in cable-stayed bridges subjected to close-in detonations and severe impulsive loading, through a comprehensive theoretical and experimental study. The innovative material used for the strengthening purposes developed as part of the study will greatly assist engineers in protection and retrofitting schemes of bridges. The results can be communicated directly to the relevant authorities, thus improving Australia's capabilities in dealing with extreme events.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
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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100019
Funder
Australian Research Council
Funding Amount
$664,580.00
Summary
Collaborative robotics for structural assembly and construction automation. Recent robotic technologies present great opportunity for construction industry to improve quality and productivity while no state of the art research infrastructure has been developed yet for this need. The proposed facility aims to provide a unique platform on research and development for structural assembly and construction automation. It
features by a flexible and adaptive design and instrumentation of structures and ....Collaborative robotics for structural assembly and construction automation. Recent robotic technologies present great opportunity for construction industry to improve quality and productivity while no state of the art research infrastructure has been developed yet for this need. The proposed facility aims to provide a unique platform on research and development for structural assembly and construction automation. It
features by a flexible and adaptive design and instrumentation of structures and space for a team of collaborative robotics in an interactive environment to achieve automated prefabrication, assembly and building. The outcomes are expected to transform current labor-intensive construction industry to highly automated and accurate manufacturing industry with significant benefits to economy and safety.Read moreRead less
Lightweight, durable and self-sustainable modular composites buildings. This project aims to establish a modular composites building system that is lightweight, integrated with power supply system and is highly resistant to harsh environments. Buildings today are designed and constructed using conventional craft-based labour-intensive methods and materials. This results in high cost and consequences for quality, safety, resource and environmental impact. By developing the modular building system ....Lightweight, durable and self-sustainable modular composites buildings. This project aims to establish a modular composites building system that is lightweight, integrated with power supply system and is highly resistant to harsh environments. Buildings today are designed and constructed using conventional craft-based labour-intensive methods and materials. This results in high cost and consequences for quality, safety, resource and environmental impact. By developing the modular building system using lightweight and durable fibre reinforced polymer (FRP) composites and innovative connection methods for fast assembly, the project outcomes can largely lift productivity in construction industry and further provide self-sustainable civil infrastructure not only in urban and rural regions but also in remote areas.Read moreRead less
Durability of carbon fibre reinforced polymer (CFRP) strengthened steel structures against environment-assisted degradation. This research project will challenge conventional methods of repairing or strengthening steel structures by using carbon fibre reinforced polymer with advanced epoxy. The outcome of this research is to remove the biggest barrier to the full utilization of such advanced material in civil, offshore and mining industry.