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Impinging supersonic jets: stability and control - with application to cold spray. Understanding aero-acoustics instabilities of impinging supersonic jets is vital to improve the energy efficiency of cold spray manufacturing. This project will generate the necessary knowledge to understand and control these instabilities, in order to improve the cold spray process and to extend the range of application of impinging supersonic jets flows.
Discovery Early Career Researcher Award - Grant ID: DE120102664
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
A micro-compression study of aluminium alloys: establishing the nanoscale mechanisms of precipitate-induced strengthening to achieve stronger alloys. This project will study the strengthening mechanisms of aluminium alloys by directly observing how dislocations interact with solute nanostructures. The research will advance our knowledge of dislocation dynamics in precipitation-strengthening alloys, and provide a quantitative method for controlling those nanostructures to achieve higher strength ....A micro-compression study of aluminium alloys: establishing the nanoscale mechanisms of precipitate-induced strengthening to achieve stronger alloys. This project will study the strengthening mechanisms of aluminium alloys by directly observing how dislocations interact with solute nanostructures. The research will advance our knowledge of dislocation dynamics in precipitation-strengthening alloys, and provide a quantitative method for controlling those nanostructures to achieve higher strength alloys.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100931
Funder
Australian Research Council
Funding Amount
$325,000.00
Summary
A novel intelligent prognostics platform for complex cyberphysical systems. This project aims to develop a novel data-driven dynamic reliability assessment platform to improve predictive maintenance ability in complex cyberphysical systems (CPSs). This will be achieved by identifying which degradation mechanism(s) are likely to cause an impending failure, and then highlighting the event to trigger for maintenance service or control operation. The expected outcomes are new methods and tools neede ....A novel intelligent prognostics platform for complex cyberphysical systems. This project aims to develop a novel data-driven dynamic reliability assessment platform to improve predictive maintenance ability in complex cyberphysical systems (CPSs). This will be achieved by identifying which degradation mechanism(s) are likely to cause an impending failure, and then highlighting the event to trigger for maintenance service or control operation. The expected outcomes are new methods and tools needed to leverage failure prognostics and prognostics-informed maintenance/control for making CPSs resilient with reduced levels of redundancy. This research will produce major advancements in extending core components’ life and durability in complex CPSs, bringing economic benefit for Australia industry.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101676
Funder
Australian Research Council
Funding Amount
$435,690.00
Summary
Machine learning-based design of triply periodic minimal surface structures. This project aims to develop a new approach to design of new lightweight, crashworthy and manufacturable structures by taking advantage of the latest technologies in computational optimisation, artificial intelligence and additive manufacturing. The study intends to develop a new machine learning-based multiscale design framework to seek optimal triply periodic minimal surface structures, considering fabrication-induced ....Machine learning-based design of triply periodic minimal surface structures. This project aims to develop a new approach to design of new lightweight, crashworthy and manufacturable structures by taking advantage of the latest technologies in computational optimisation, artificial intelligence and additive manufacturing. The study intends to develop a new machine learning-based multiscale design framework to seek optimal triply periodic minimal surface structures, considering fabrication-induced defects and uncertainty. The expected outcome of this project is new methodologies for generating eco-friendly structures with robust mechanical properties in crashing applications. This should provide significant benefits to transport industries by enhancing structural safety and energy saving for next generation vehicles.Read moreRead less
Modelling the cutting process and cutting performance in high-speed abrasive waterjet turning. This project will have a significant impact for the manufacturing industry by providing a new abrasive waterjet turning technology for producing highly reliable products from advanced, but difficult-to-machine, materials. It will also develop into a new branch of science by understanding the mechanics associated with the new turning process.
Design of nastic cellular structures with osmotic actuation. Shape changing structures play an imperative role in aerospace, automobile, energy and other industries. This project aims to develop novel concepts extracted from nastic motion in plants and relevant computational algorithms for the design of nastic cellular structures with osmotic actuation. The project is of significance as it offers a potential solution to the shape morphing challenge in aircraft and automobile from biomimetics vie ....Design of nastic cellular structures with osmotic actuation. Shape changing structures play an imperative role in aerospace, automobile, energy and other industries. This project aims to develop novel concepts extracted from nastic motion in plants and relevant computational algorithms for the design of nastic cellular structures with osmotic actuation. The project is of significance as it offers a potential solution to the shape morphing challenge in aircraft and automobile from biomimetics viewpoint - nastic actuation. The expected outcomes will be: a new numerical method for designing nastic cellular structures; and, validated algorithms with a novel topological geometry representation and multi objectives and constraints for applications in morphing structures with multiple target shapes.Read moreRead less
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.
Innovative Magnetorheological Powertrains for Electric Heavy Duty Vehicles. An electric vehicle powertrain mainly consists of an electric motor-driven system, a mechanical transmission and other components. This project aims to explore innovative powertrains with a regenerative braking function to maximise driving range, reduce power consumption, and enhance the dynamic performance of electrified vehicles. The proposed powertrains are expected to achieve seamless gear changing for driving and be ....Innovative Magnetorheological Powertrains for Electric Heavy Duty Vehicles. An electric vehicle powertrain mainly consists of an electric motor-driven system, a mechanical transmission and other components. This project aims to explore innovative powertrains with a regenerative braking function to maximise driving range, reduce power consumption, and enhance the dynamic performance of electrified vehicles. The proposed powertrains are expected to achieve seamless gear changing for driving and better braking performance by applying magnetorheological technology for a high-quality control of power-shifting, and therefore significantly improve vehicle dynamic and economic performance. A new era of high-efficiency electric powertrains could potentially be launched through the development of these novel technologies.Read moreRead less
Innovative X-by-Wire Control Systems for Improved Vehicle Manoeuvrability and Stability. Future automobiles will be equipped with safety-critical ‘x-by-wire’ systems, such as ‘steer-by-wire’, ‘brake-by-wire’, and ‘drive-by-wire’, to enable active safety control and improve reliability and performance. This project aims to develop a new coordinated control strategy based on an in-depth understanding of the fundamental dynamics and stability characteristics of vehicles. Corresponding x-by-wire sys ....Innovative X-by-Wire Control Systems for Improved Vehicle Manoeuvrability and Stability. Future automobiles will be equipped with safety-critical ‘x-by-wire’ systems, such as ‘steer-by-wire’, ‘brake-by-wire’, and ‘drive-by-wire’, to enable active safety control and improve reliability and performance. This project aims to develop a new coordinated control strategy based on an in-depth understanding of the fundamental dynamics and stability characteristics of vehicles. Corresponding x-by-wire systems will then be implemented, using a novel networked bilateral-control concept and new haptic devices for enhancing the overall performance and safety of vehicles. This project will lead to the innovative design of vehicle active safety systems for automobile manufacturing in Australia and the rest of the world.Read moreRead less
A human-centric eXplainable Automated Vehicle. The aim is to create a computational model to address the inability of Automated Vehicles (AV), powered by Artificial intelligence, to self explain their behaviours. This project applies novel multidisciplinary methodologies in a real-world self-driving setting to formalise the essence of driving explanations. It explores the when, why and how a driver is seeking an explanation and what type of automated explanation is truly human-interpretable. Exp ....A human-centric eXplainable Automated Vehicle. The aim is to create a computational model to address the inability of Automated Vehicles (AV), powered by Artificial intelligence, to self explain their behaviours. This project applies novel multidisciplinary methodologies in a real-world self-driving setting to formalise the essence of driving explanations. It explores the when, why and how a driver is seeking an explanation and what type of automated explanation is truly human-interpretable. Expected outcomes include the discovery of an acceptable, transparent and ethical explanation system that helps humans to understand the AVs decision making. This field will continue to rise in prominence and produce much-needed work to improve the widespread adoption of AVs.Read moreRead less