Enabling ambient intelligence for manufacturing processes through distributed camera networks. This project will develop methods to optimise and schedule networks of smart and traditional cameras in a manufacturing environment, enabling knowledge capture, manage performance and identify causes of quality degradation. This research will assist Australian manufacturers to stay competitive in the dynamic global market.
Laser-based sensing, measurement and control of multi-axis flexure-based mechanisms for nano manipulations. The project aims to investigate fundamental issues in measurement, design, optimisation, and control of multi-axis flexure-based nano manipulators. It aims to establish novel sensing methodologies for position and orientation measurements and feedback, and advanced control techniques for nano manipulation in view of actuators’ nonlinearities, interferences among motion axes, and external d ....Laser-based sensing, measurement and control of multi-axis flexure-based mechanisms for nano manipulations. The project aims to investigate fundamental issues in measurement, design, optimisation, and control of multi-axis flexure-based nano manipulators. It aims to establish novel sensing methodologies for position and orientation measurements and feedback, and advanced control techniques for nano manipulation in view of actuators’ nonlinearities, interferences among motion axes, and external disturbances. The research is significant as such nano manipulators and methodologies represent the building blocks for many future scientific and engineering nano manipulation systems. The project will establish new knowledge, methodologies, and instrumentations for measurement, characterisation and control of multi-axis flexure-based nano manipulators.Read moreRead less
Visual intelligence for safe vehicle operation in industrial environment. Visual intelligence for safe vehicle operation in industrial environment. This project aims to develop safety devices for loosely constrained environments with public access, building on visual-based collision avoidance technology in controlled industrial settings. Increasing productivity in industrial workplaces creates a need for faster industrial vehicles. At fruit and vegetable markets and construction sites, forklift ....Visual intelligence for safe vehicle operation in industrial environment. Visual intelligence for safe vehicle operation in industrial environment. This project aims to develop safety devices for loosely constrained environments with public access, building on visual-based collision avoidance technology in controlled industrial settings. Increasing productivity in industrial workplaces creates a need for faster industrial vehicles. At fruit and vegetable markets and construction sites, forklift drivers, crane operators and crews are under pressure to move faster. The need for higher speed and the enormous human and financial cost of unsafe operations create opportunities for the deployment of intelligent safety devices. The expected outcomes of this project are safer public industrial environments, reductions in work related injuries, injury compensation costs and associated societal burdens.Read moreRead less
Intelligent collision avoidance system for mobile industrial platforms. This project will develop a collision prevention system for mobile industrial platforms that enhances existing artificial vision perception systems to mimic human eye capabilities. The outcomes of this project will result in significant reductions in work related injuries, injury compensation costs and associated societal burdens.
Discovery Early Career Researcher Award - Grant ID: DE180101407
Funder
Australian Research Council
Funding Amount
$359,446.00
Summary
Three-dimensional metal printing based on controlled removal of self-assembled monolayers. This project aims to develop a unique approach for three-dimensional metal micro-printing based on controlled removal of self-assembled monolayers. The application of electro-deposition for three-dimensional metal printing is currently hindered by the incapacity of site-selective control of the deposition area. The project expects to produce a new three dimensional metal microprinting technology, with bene ....Three-dimensional metal printing based on controlled removal of self-assembled monolayers. This project aims to develop a unique approach for three-dimensional metal micro-printing based on controlled removal of self-assembled monolayers. The application of electro-deposition for three-dimensional metal printing is currently hindered by the incapacity of site-selective control of the deposition area. The project expects to produce a new three dimensional metal microprinting technology, with benefits to manufacturing industries, particularly those requiring production of micro/nano metallic components.Read moreRead less
Stereolithographic Additive Manufacturing of Semicrystalline Thermoplastics. This project aims to advance the development of high-throughput stereolithographic additive manufacturing of thermoplastic polymers and composites by employing a multi-colour irradiation schemes in conjunction with photopolymerisable, ring-opening monomer resin formulations. The fundamental scientific understanding, engineering expertise, and concomitant technology advances generated by this project are anticipated to e ....Stereolithographic Additive Manufacturing of Semicrystalline Thermoplastics. This project aims to advance the development of high-throughput stereolithographic additive manufacturing of thermoplastic polymers and composites by employing a multi-colour irradiation schemes in conjunction with photopolymerisable, ring-opening monomer resin formulations. The fundamental scientific understanding, engineering expertise, and concomitant technology advances generated by this project are anticipated to enable additive manufacturing to transition from the rapid prototyping of individual, unique items to the high volume production of robust, reprocessable plastic parts. By obviating the large capital expense of conventional fabrication, this developed technology should provide a path to reinvigorate Australian manufacturing.Read moreRead less
Integrity prediction of ground precision surfaces. This project aims to establish a new approach to enable a reliable and accurate prediction of precision surface grinding. Precision grinding is often the final step in the manufacturing chains for a broad range of metal, ceramic, optical glass and semiconductor components, which must have ultra-high surface integrity and accurate dimensions. To date, the surface integrity of a ground component cannot be predicted due to the involvement of many r ....Integrity prediction of ground precision surfaces. This project aims to establish a new approach to enable a reliable and accurate prediction of precision surface grinding. Precision grinding is often the final step in the manufacturing chains for a broad range of metal, ceramic, optical glass and semiconductor components, which must have ultra-high surface integrity and accurate dimensions. To date, the surface integrity of a ground component cannot be predicted due to the involvement of many random factors and variables in a precision surface grinding process, resulting in high failure rates and processes requiring repeated surface measurements. The novel approach for surface integrity prediction developed by this project will make a vital step forward in advancing the discipline of precision surfacing, establish a new knowledge base and bring about significant technological impacts to the manufacturing industry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100016
Funder
Australian Research Council
Funding Amount
$490,000.00
Summary
Multi-scale fabrication facility for complex three-dimensional surface generation from nano to macro dimensions. This facility will support advances in the manufacturing of free-form surfaces with submicron features. Its unique characteristics, such as the universal profiling ability and nanometre accuracy across large dimensions, will enable many science and engineering innovations which are presently impossible to be realised in Australia.
An integral approach enabling the defect-free manufacture of microlens arrays. Free-form microlens arrays are of central importance to the advancement of science and frontier technologies such as electronics, optics, telecommunication, biotechnology, medical surgery, energy generation, agriculture, resource exploration, environment protection and security. Using an integral approach coupling processing-microstructure-property modelling, multi-scale mechanics and damage-free mould development. Th ....An integral approach enabling the defect-free manufacture of microlens arrays. Free-form microlens arrays are of central importance to the advancement of science and frontier technologies such as electronics, optics, telecommunication, biotechnology, medical surgery, energy generation, agriculture, resource exploration, environment protection and security. Using an integral approach coupling processing-microstructure-property modelling, multi-scale mechanics and damage-free mould development. This research project will establish novel theories and technologies for the defect-free manufacture of microlens arrays. The research outcomes will lay the foundation for defect-free fabrication of a wide class of high-integrity systems.Read moreRead less
Cleaning of tough paints on advanced composites using laser technologies. This project researches fundamental knowledge and algorithms to underpin the deployment of a novel ablation technology using pulsed lasers to remove paints, in particular tough paints, from surfaces of advanced composite structures, e.g. airframes and turbine blades. It establishes thermal mechanical models to describe ablation mechanisms of pulsed laser removal of the paint using both IR and UV bands. Optimal processing p ....Cleaning of tough paints on advanced composites using laser technologies. This project researches fundamental knowledge and algorithms to underpin the deployment of a novel ablation technology using pulsed lasers to remove paints, in particular tough paints, from surfaces of advanced composite structures, e.g. airframes and turbine blades. It establishes thermal mechanical models to describe ablation mechanisms of pulsed laser removal of the paint using both IR and UV bands. Optimal processing protocols to clean paints with different properties, without damaging the underlying composites, will be determined and demonstrated. It meets a cleaning technology need for this paint-on-composites material system to support retrofitting and re-manufacturing in industry. These are crucial industry requirements. Read moreRead less