Discovery Early Career Researcher Award - Grant ID: DE190100217
Funder
Australian Research Council
Funding Amount
$408,000.00
Summary
Facade fire failures in buildings: a robust nanocomposite solution. This project aims to develop an innovative fire resistant composite façade system which is also strong, lightweight, thermally efficient, environmentally friendly and cost-effective. The project expects to develop new knowledge in areas of fire safety and advanced manufacturing of a nanocomposite facade utilising advanced computational fluid dynamics simulations to model the external flame spread. The outcomes will provide impro ....Facade fire failures in buildings: a robust nanocomposite solution. This project aims to develop an innovative fire resistant composite façade system which is also strong, lightweight, thermally efficient, environmentally friendly and cost-effective. The project expects to develop new knowledge in areas of fire safety and advanced manufacturing of a nanocomposite facade utilising advanced computational fluid dynamics simulations to model the external flame spread. The outcomes will provide improved insight into the mechanism of external fire spread and development of the façade system which is safe, resilient and fire resistant. This work will be useful for building owners, construction authorities and researchers to tackle the global issues of combustible façades and provide better fire design strategies to protect occupants.Read moreRead less
Structural assembly for remote housing using fibre reinforced composites. This project aims to address construction challenges in remote housing by off-site manufacturing and on-site assembly using fibre reinforced composites and digital made-to-measure approach. Its goal is to generate interdisciplinary knowledge and practical technologies for reliable, affordable and durable housing in remote harsh environments. Intended results include innovative connections and systems with valuable understa ....Structural assembly for remote housing using fibre reinforced composites. This project aims to address construction challenges in remote housing by off-site manufacturing and on-site assembly using fibre reinforced composites and digital made-to-measure approach. Its goal is to generate interdisciplinary knowledge and practical technologies for reliable, affordable and durable housing in remote harsh environments. Intended results include innovative connections and systems with valuable understanding of their performances under various loading scenarios and accurate digital visualization for remote construction. The outcomes expect to unlock remote development, enhance our competitive strengths for manufacturing and construction industries, and further offer new solutions in post-disaster recovery applications.Read moreRead less
Development of Novel Metaconcrete to Resist Impulsive Loads. This project aims to develop innovative metaconcrete for structural protection by utilising the concept of phononic crystals and metamaterials which has been recently developed by physicists. Traditional construction materials are used in new structural forms to mitigate dynamic loading effects by exploiting the unique characteristics of the proposed metaconcrete. Theoretical, numerical and experimental methods will be used to derive t ....Development of Novel Metaconcrete to Resist Impulsive Loads. This project aims to develop innovative metaconcrete for structural protection by utilising the concept of phononic crystals and metamaterials which has been recently developed by physicists. Traditional construction materials are used in new structural forms to mitigate dynamic loading effects by exploiting the unique characteristics of the proposed metaconcrete. Theoretical, numerical and experimental methods will be used to derive the best performing metaconcrete and verify its static and dynamic load resistant capacities. The expected outcomes of the project will lead to innovative extreme-loading resistant designs and provide significant benefit to the Australian construction industry, general public and economy.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100646
Funder
Australian Research Council
Funding Amount
$408,000.00
Summary
Active rheology control of fresh concrete using responsive additives. This project aims to investigate innovative techniques for Active Rheology Control (ARC) of concretes using responsive additives interacting with externally applied electromagnetic or temperature signals. ARC is a new concept which will revolutionise concrete pumping by overcoming limitations such as frequent pipe blockages. ARC will also be useful to solve the major barrier faced by 3D concrete printing (3DCP) from becoming a ....Active rheology control of fresh concrete using responsive additives. This project aims to investigate innovative techniques for Active Rheology Control (ARC) of concretes using responsive additives interacting with externally applied electromagnetic or temperature signals. ARC is a new concept which will revolutionise concrete pumping by overcoming limitations such as frequent pipe blockages. ARC will also be useful to solve the major barrier faced by 3D concrete printing (3DCP) from becoming a practical way of construction. 3DCP is an emerging idea for construction but a major barrier is that concrete needs to flow during pumping and extrusion but become stiff soon after placement. This project will explore ARC for achieving the “flow-on-demand” desired by both concrete pumping and 3DCP applications.Read moreRead less
Next generation transport infrastructure using high performance materials. This project aims to provide structural engineers with the tools required to develop ultra-high performance fibre reinforced concrete materials and to utilise their unique material properties in design. Recent feasibility studies have shown that the replacement of conventional concrete and steel transport infrastructure with ultra-high performance fibre reinforced concrete has the potential to revolutionise the sector. Fo ....Next generation transport infrastructure using high performance materials. This project aims to provide structural engineers with the tools required to develop ultra-high performance fibre reinforced concrete materials and to utilise their unique material properties in design. Recent feasibility studies have shown that the replacement of conventional concrete and steel transport infrastructure with ultra-high performance fibre reinforced concrete has the potential to revolutionise the sector. For these cost savings benefits to be realised, guidelines for the low cost development and testing of new materials, and for the application in structural design are required. This project is expected to deliver these guidelines and potentially maximise the impact of government spending on road and rail infrastructure.Read moreRead less
New Systems for High Rise Steel Structures in Rising Factory Construction. This project will develop new and innovative ways of constructing steel structures using the rising factory concept. The rising factory is a 10 storey enclosure where the final high-rise building is safely constructed within a watertight envelope which rises as the building progresses. The project will perform the necessary research to make possible high-rise steel structural systems consisting of hot-rolled (heavy gauge ....New Systems for High Rise Steel Structures in Rising Factory Construction. This project will develop new and innovative ways of constructing steel structures using the rising factory concept. The rising factory is a 10 storey enclosure where the final high-rise building is safely constructed within a watertight envelope which rises as the building progresses. The project will perform the necessary research to make possible high-rise steel structural systems consisting of hot-rolled (heavy gauge) and cold-formed (light gauge) steel structural members and connections which can be used in the rising factory. The main benefits of the rising factory are the waterproof construction environment and the substantially increased safety as a result of no external cranes.
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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
Shrinkage, cracking, self-healing and corrosion in blended cement concrete. This project aims to investigate the effects of binder quantity and composition on early-age cracking in Australian concretes caused by restrained shrinkage, the subsequent self-healing capability of the cracks, and the possibility of detrimental early chloride induced steel reinforcement corrosion, particularly in marine locations. This project will focus on concrete mix designs and the blends of cement, fly-ash and bla ....Shrinkage, cracking, self-healing and corrosion in blended cement concrete. This project aims to investigate the effects of binder quantity and composition on early-age cracking in Australian concretes caused by restrained shrinkage, the subsequent self-healing capability of the cracks, and the possibility of detrimental early chloride induced steel reinforcement corrosion, particularly in marine locations. This project will focus on concrete mix designs and the blends of cement, fly-ash and blast furnace slag that are prescribed in the revised version of the concrete bridge standard for the most severe exposure. This project will lead to a significant improvement in the serviceability and durability of concrete structures in severe environments.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
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