Development of Topological Optimisation Techniques for the Conceptual Design of Multi-storey Buildings. The building design process often begins with a case based preliminary design which derives its main parameters and features from a number of existing buildings of similar dimensions and functionality. This project aims to develop a design tool which incorporates two topological optimisation techniques in the conceptual design of multi-storey buildings. This design tool will enable inefficient ....Development of Topological Optimisation Techniques for the Conceptual Design of Multi-storey Buildings. The building design process often begins with a case based preliminary design which derives its main parameters and features from a number of existing buildings of similar dimensions and functionality. This project aims to develop a design tool which incorporates two topological optimisation techniques in the conceptual design of multi-storey buildings. This design tool will enable inefficient materials to be automatically removed from the design, thus producing a structurally efficient building system. At the same time, the new topologies generated by these optimisation techniques can be used by the designer to create innovative forms and layouts for the building.Read moreRead less
Efficient and Robust Bi-directional Evolutionary Structural Optimisation Method for Large-scale Three-dimensional Topological Design. Structural optimisation is a process of searching for the best shape and topology of an engineering structure which will consume the least amount of material or energy. This project aims to further investigate the Bi-directional Structural Optimisation (BESO) method which has recently been proposed by the applicant's team. New algorithms will be developed to subst ....Efficient and Robust Bi-directional Evolutionary Structural Optimisation Method for Large-scale Three-dimensional Topological Design. Structural optimisation is a process of searching for the best shape and topology of an engineering structure which will consume the least amount of material or energy. This project aims to further investigate the Bi-directional Structural Optimisation (BESO) method which has recently been proposed by the applicant's team. New algorithms will be developed to substantially improve the efficiency and robustness of the BESO method. The expected outcome of the project is a simple and effective optimisation technique that can be used for the conceptual design of a wide range of engineering structures.Read moreRead less
Engineering models for inland atmospheric corrosion of steel infrastructure considering microbiological and environmental influences. Some 2-3% of Gross Domestic Product is estimated to be lost every year to corrosion and by measures to counteract it. Of this a significant proportion relates to steel infrastructure, which includes buildings, bridges, transmission towers, ships, offshore and coastal structures, tanks and pipelines. Better understanding and modelling of corrosion will improve our ....Engineering models for inland atmospheric corrosion of steel infrastructure considering microbiological and environmental influences. Some 2-3% of Gross Domestic Product is estimated to be lost every year to corrosion and by measures to counteract it. Of this a significant proportion relates to steel infrastructure, which includes buildings, bridges, transmission towers, ships, offshore and coastal structures, tanks and pipelines. Better understanding and modelling of corrosion will improve our capability for assessing the long-term safety and serviceability of infrastructure. It may also be useful in improving the composition of steel to resist rusting and in the formulation of protective coatings. This project will contribute to better understanding of the likely involvement of bacteria in the longer-term corrosion of steel exposed to various inland environments.Read moreRead less
Development of innovative fibre reinforced polymer plating techniques to retrofit existing reinforced concrete structures. The demand for retrofitting reinforced concrete structures in Australia is estimated at $500 million per annum. However, with improved understanding of emerging retrofitting techniques the cost of retrofitting may be reduced. The innovative retrofitting techniques investigated in this project will address the shortcomings of existing techniques with particular emphasis on th ....Development of innovative fibre reinforced polymer plating techniques to retrofit existing reinforced concrete structures. The demand for retrofitting reinforced concrete structures in Australia is estimated at $500 million per annum. However, with improved understanding of emerging retrofitting techniques the cost of retrofitting may be reduced. The innovative retrofitting techniques investigated in this project will address the shortcomings of existing techniques with particular emphasis on the ductility of the system which is a particularly important characteristic when retrofitting for earthquake or explosive loads. It also reinforces Australia's high international standing in developing innovative retrofitting alternatives using advanced materials in this rapidly developing area.Read moreRead less
Retrofitting unreinforced masonry walls with fibre reinforced polymer strips. An efficient technique for increasing the safety of existing masonry structures under earthquake (and other) loading will be developed. This is essential to the safe continued use of existing infrastructure (avoid replacement = economic benefit). This new technique addresses many shortcomings in existing alternatives (increased performance, reduced cost). This research is particularly important in Australia where unrei ....Retrofitting unreinforced masonry walls with fibre reinforced polymer strips. An efficient technique for increasing the safety of existing masonry structures under earthquake (and other) loading will be developed. This is essential to the safe continued use of existing infrastructure (avoid replacement = economic benefit). This new technique addresses many shortcomings in existing alternatives (increased performance, reduced cost). This research is particularly important in Australia where unreinforced masonry accounts for most domestic construction, much light commercial infrastructure, as well as many heritage and post-disaster buildings. It also reinforces Australia's high international standing in developing innovative retrofitting alternatives using advanced materials in this rapidly developing area. Read moreRead less
High-strength formwork systems. The project will lead to new formwork systems which are safer, stronger and quicker to erect. The systems will rely on scientific investigations to minimise the risk of structural collapse and associated cost to community. The systems are innovative and combine advanced technology to produce a superior product with strong export potential and capacity to raise the level of efficiency in the national market. The project will also develop advanced analysis and desig ....High-strength formwork systems. The project will lead to new formwork systems which are safer, stronger and quicker to erect. The systems will rely on scientific investigations to minimise the risk of structural collapse and associated cost to community. The systems are innovative and combine advanced technology to produce a superior product with strong export potential and capacity to raise the level of efficiency in the national market. The project will also develop advanced analysis and design methods for formwork systems which can be applied more generally to advance Australian engineers' position as world leaders in innovative structural design.Read moreRead less
Advanced analysis methods for locally unstable steel structures. The project will provide structural design and consulting engineers with advanced analysis tools which will help the profession to maintain its eminent position as a leader in the field, known for creating innovative solutions to complex structural engineering projects. The availability of advanced analysis tools will promote research and innovation by Australian producers of cold-formed and thin-walled steel construction products, ....Advanced analysis methods for locally unstable steel structures. The project will provide structural design and consulting engineers with advanced analysis tools which will help the profession to maintain its eminent position as a leader in the field, known for creating innovative solutions to complex structural engineering projects. The availability of advanced analysis tools will promote research and innovation by Australian producers of cold-formed and thin-walled steel construction products, such as BlueScope Steel, and will encourage innovation in industry which will translate to enhanced export opportunities. The end consumer will benefit from the superior structural products which will eventuate from the innovation stimulated by the analysis methods devised from this project.Read moreRead less