Thermoforming Mechanisms for Cost-effective Manufacturing of Advanced Composite Structures. The cost barrier in thermoforming, due to the lack of understanding of shear deformation and wrinkling, has inhibited the large-scale application of fibre-reinforced composite structures in aerospace and automobile industries. This project aims to develop a cost-effective diaphragm thermoforming process through an in-depth understanding of the thermoforming mechanisms. The outcomes will include novel theo ....Thermoforming Mechanisms for Cost-effective Manufacturing of Advanced Composite Structures. The cost barrier in thermoforming, due to the lack of understanding of shear deformation and wrinkling, has inhibited the large-scale application of fibre-reinforced composite structures in aerospace and automobile industries. This project aims to develop a cost-effective diaphragm thermoforming process through an in-depth understanding of the thermoforming mechanisms. The outcomes will include novel theories for thermoforming, a standard method for material property characterization and new finite element models compatible with the most popular software available for industry. The project will form the basis for establishing the effective production window and enhance greatly the competitive edge of the Australian manufacturing industry.Read moreRead less
Micro-electromechanics and finite element analysis models for adaptive structures. Adaptive structures are becoming increasingly important due to their direct improvement of structural system performance. However, electroelastic behaviour and damage mechanism, which are primary concerns for adaptive structural design, are poorly understood. This project aims at developing micro-electromechanics and finite element analysis models to investigate the electroelastic properties and detect delaminatio ....Micro-electromechanics and finite element analysis models for adaptive structures. Adaptive structures are becoming increasingly important due to their direct improvement of structural system performance. However, electroelastic behaviour and damage mechanism, which are primary concerns for adaptive structural design, are poorly understood. This project aims at developing micro-electromechanics and finite element analysis models to investigate the electroelastic properties and detect delamination for adaptive structures. It combines the fields of micro-electromechanics and composite material analysis in a computational framework to provide a useful and cost-effective tool for modelling the response of adaptive structures. It is a challenging task and will have significant impact in the adaptive structure design community.Read moreRead less
Topology Optimisation of Periodic Structures for Stent Design. Stenting therapy offers new therapeutical strategies to improve the quality of healthcare for numerous cardiovascular disease patients. This project will address the critical issues in stent design involving the delivery, dilatation and ongoing interaction with blood vessel and fluid. The novel topological configurations are expected to bring significant improvement to stent ensuring long-term success. The numerical techniques to be ....Topology Optimisation of Periodic Structures for Stent Design. Stenting therapy offers new therapeutical strategies to improve the quality of healthcare for numerous cardiovascular disease patients. This project will address the critical issues in stent design involving the delivery, dilatation and ongoing interaction with blood vessel and fluid. The novel topological configurations are expected to bring significant improvement to stent ensuring long-term success. The numerical techniques to be developed for optimising topology will provide new tools for design of periodic structures, making a broader impact on an important class of engineering structures and thus benefiting many relevant fields.Read moreRead less