Microwave-generated plasma combustion for in-cylinder soot reduction. Microwave-generated plasma combustion for in-cylinder soot reduction. This project aims to develop a microwave-generated plasma combustion system for the in-cylinder formation of hydroxyl radicals, achieving cost-effective reduction of engine-out emissions in diesel engines. This new system should overcome high-load particulate emissions and high-cost fuel injection systems, which limit further improvement of diesel engines. T ....Microwave-generated plasma combustion for in-cylinder soot reduction. Microwave-generated plasma combustion for in-cylinder soot reduction. This project aims to develop a microwave-generated plasma combustion system for the in-cylinder formation of hydroxyl radicals, achieving cost-effective reduction of engine-out emissions in diesel engines. This new system should overcome high-load particulate emissions and high-cost fuel injection systems, which limit further improvement of diesel engines. This project expects to accomplish this by combining laser diagnostics in optical combustion facilities and computational modelling, which should lead to the scientific knowledge accelerating the development cycle of the new system.Read moreRead less
Advancing unsteady bluff body aerodynamics: applications to elite cycling. Delivering a better understanding of unsteady wakes has real potential to further our future capabilities of reducing bluff body parasitic drag. The national benefit derived from this project is the advancement of knowledge of a complex fluid mechanics problem, with secondary benefits arising from the specific and practical application to sports aerodynamics. By better understanding the wake structure and its interaction ....Advancing unsteady bluff body aerodynamics: applications to elite cycling. Delivering a better understanding of unsteady wakes has real potential to further our future capabilities of reducing bluff body parasitic drag. The national benefit derived from this project is the advancement of knowledge of a complex fluid mechanics problem, with secondary benefits arising from the specific and practical application to sports aerodynamics. By better understanding the wake structure and its interaction with a locally oscillating bluff body this knowledge can feed into the field of active flow control in the transport sector. The potential for emissions mitigation by lowering aerodynamic losses in the ground transportation section through active aerodynamic control is significant.Read moreRead less
Development of low emissions compression-ignition engines via ethanol port-injection dual-fuelling. The project aims to develop a more efficient and more cost-effective way of utilising clean-burning ethanol fuel. Port-injection fuelling of ethanol as a separate fuel stream in compression-ignition engines will be studied fundamentally and combined with novel combustion strategies to overcome problems that occur at high ethanol substitution.
Reduced fuel consumption through aerodynamic optimisation and the development of a new fuel consumption model for inter-modal trains in Australia. This project aims to improve intermodal freight train efficiency by developing new experimental and computational analytical techniques leading to aerodynamic optimisation and improved fuel consumption models. The aerodynamics solutions will be widely applicable to other rail and ground transportation modes.
Development of engine management systems for turbocharged gasoline direct-injection engines with optional natural gas port-injection. This project aims to develop universal and programmable engine management systems for gasoline direct-injection engines with lean-burn technology and optional natural gas port-injection. The new engine management system will enable higher fuel efficiency than its predecessors and the increased use of nationally-produced natural gas. The project aims to overcome th ....Development of engine management systems for turbocharged gasoline direct-injection engines with optional natural gas port-injection. This project aims to develop universal and programmable engine management systems for gasoline direct-injection engines with lean-burn technology and optional natural gas port-injection. The new engine management system will enable higher fuel efficiency than its predecessors and the increased use of nationally-produced natural gas. The project aims to overcome three main problems that limit efficiency improvement of direct-injection engines, namely: misfiring, unstable combustion, and soot emission. How these issues are impacted by additional natural gas port-injection will also be explored. This project aims to accomplish this by combining fundamental in-cylinder optical measurements and detailed modelling.Read moreRead less