An Innovative Powertrain Architecture and Optimal Energy Management for Plug-in Hybrid Electric Vehicles. Plug-in hybrid electric vehicle technologies will significantly reduce the dependence of vehicles on fossil fuels, thereby reducing their emissions of carbon and other pollutants. The project will produce new knowledge in automotive engineering, software tools for vehicle design and a novel powertrain architecture with key components almost ready for commercial application. The research will ....An Innovative Powertrain Architecture and Optimal Energy Management for Plug-in Hybrid Electric Vehicles. Plug-in hybrid electric vehicle technologies will significantly reduce the dependence of vehicles on fossil fuels, thereby reducing their emissions of carbon and other pollutants. The project will produce new knowledge in automotive engineering, software tools for vehicle design and a novel powertrain architecture with key components almost ready for commercial application. The research will directly contribute to the use of green energy and the reduction of vehicles' harmful environmental impacts. The nation will benefit from new economic activity, such as increased exports of automotive parts and components, and from strengthening its position as a world leader in reducing carbon emissions.Read moreRead less
Variable Geometry Cooling Intakes for Passenger Vehicles. Cars reject engine heat via air forced through the grille, radiator and engine bay. The associated "cooling drag" increases total aerodynamic drag by 10-15% hence increasing fuel consumption. The highest heat load that needs to be rejected by the engine determines the quantity of cooling air, resulting in systems that are over designed for typical driving. This research provides a strategy of adjusting the cooling airflow to match the ....Variable Geometry Cooling Intakes for Passenger Vehicles. Cars reject engine heat via air forced through the grille, radiator and engine bay. The associated "cooling drag" increases total aerodynamic drag by 10-15% hence increasing fuel consumption. The highest heat load that needs to be rejected by the engine determines the quantity of cooling air, resulting in systems that are over designed for typical driving. This research provides a strategy of adjusting the cooling airflow to match the engine requirements (via variable geometry intakes that can be under the control of the engine management computer) offering substantial reductions in fuel consumption and emissions.Read moreRead less
An Integrated Starter Alternator for Automobiles using a New Wide Speed Range Interior Permanent Magnet Motor and a Matrix Z-Source Converter. The projected growth of power demand and efficiency of future automobiles calls for a suitable integrated starter-alternator (ISA) to be developed. While interim solutions have been offered, a true ISA is still considered to be more than five years away. Considering the huge worldwide market, an ISA developed in Australia is expected to benefit the large ....An Integrated Starter Alternator for Automobiles using a New Wide Speed Range Interior Permanent Magnet Motor and a Matrix Z-Source Converter. The projected growth of power demand and efficiency of future automobiles calls for a suitable integrated starter-alternator (ISA) to be developed. While interim solutions have been offered, a true ISA is still considered to be more than five years away. Considering the huge worldwide market, an ISA developed in Australia is expected to benefit the large Australian automobile industry significantly. The CIs has strong links with local developers and suppliers of power semiconductors and motors, who have participated in the recent developments already carried out. A proven ISA developed locally should be a boon for these industries.Read moreRead less
Development of a gas-diesel engine injection system using a hydraulically actuated, electronically controlled unit injector (HEUI) for flexible dual-fuel operation. Achieving targets for greenhouse gas reduction will require practical, easily implemented alternative fuels for vehicles. Converting existing truck/bus diesel engines to dual-fuel systems using natural gas is important. In particular, for long distance application, these systems need to allow flexible switching from sole diesel to du ....Development of a gas-diesel engine injection system using a hydraulically actuated, electronically controlled unit injector (HEUI) for flexible dual-fuel operation. Achieving targets for greenhouse gas reduction will require practical, easily implemented alternative fuels for vehicles. Converting existing truck/bus diesel engines to dual-fuel systems using natural gas is important. In particular, for long distance application, these systems need to allow flexible switching from sole diesel to dual-fuel operation and good gas substitution at low loads within cities. An earlier ARC funded project allowed UNSW to develop the world's most compact, flexible HEUI diesel injector. This project aims to develop, test and explore dual-fuel combustion using a compact single unit, combined NG/HEUI injector which will have considerable combustion and operational advantages.Read moreRead less
Increasing the operational lifetime and optimising the design of crankcase oil-mist filters. Australia is one of the largest (per capita) users worldwide of heavy diesel engines, within sectors such as transport, mining, construction, shipping and power generation (usage of many of the above is concentrated in regional communities e.g. mining). This work will minimise emissions from such industries, as well as reduce lubricant oil usage - thereby maximising waste oil recovery and reuse (approx 5 ....Increasing the operational lifetime and optimising the design of crankcase oil-mist filters. Australia is one of the largest (per capita) users worldwide of heavy diesel engines, within sectors such as transport, mining, construction, shipping and power generation (usage of many of the above is concentrated in regional communities e.g. mining). This work will minimise emissions from such industries, as well as reduce lubricant oil usage - thereby maximising waste oil recovery and reuse (approx 5500 tonnes p.a.). Oil mists can be regarded as volatile organic compounds (VOCs) for the purposes of CO2 equivalent emissions, so therefore, the efficient capture of oil mists will reduce carbon emissions from the above industries in Australia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE170100134
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Electrifying commercial vehicles in Australia. This project aims to develop alternative hybrid electric and pure electric vehicle technologies for the Australian commercial vehicle sector. Worldwide concern about greenhouse gases and stringent vehicle fuel consumption have changed vehicle driveline systems, and created demand for hybrid and electric automotive technologies. This project will examine different powertrain configurations for commercial vehicles, and use numerical simulations to eva ....Electrifying commercial vehicles in Australia. This project aims to develop alternative hybrid electric and pure electric vehicle technologies for the Australian commercial vehicle sector. Worldwide concern about greenhouse gases and stringent vehicle fuel consumption have changed vehicle driveline systems, and created demand for hybrid and electric automotive technologies. This project will examine different powertrain configurations for commercial vehicles, and use numerical simulations to evaluate vehicle fuel economy, life cycle emissions and life cycle costs and demonstrate the benefits of these alternatives. These vehicle technologies have the potential to reduce fuel in this sector by up to 50%, and reduce vehicle emissions and operational costs across the commercial transportation sector.Read moreRead less
CoopEcoSafe: a new cooperative, green and safe driving system. Road transport plays a vital role in our economy but generates huge costs in road trauma and greenhouse gases. Eco-driving has been trialed as a cost-effective approach to reducing fuel consumption, but little research has examined its effects on safety. This research brings together disciplines of road safety, psychology and engineering to address the fundamental question: how can mobility be greener while being safer? It develops: ....CoopEcoSafe: a new cooperative, green and safe driving system. Road transport plays a vital role in our economy but generates huge costs in road trauma and greenhouse gases. Eco-driving has been trialed as a cost-effective approach to reducing fuel consumption, but little research has examined its effects on safety. This research brings together disciplines of road safety, psychology and engineering to address the fundamental question: how can mobility be greener while being safer? It develops: a new theoretical model that optimises environmental and safety outcomes; new persuasive in-vehicle Human Machine Interface supported by cooperative Intelligent Transport System; and, comprehensive benefits evaluation. This research will bring major improvements to both road safety and energy use. Read moreRead less
In-cylinder soot sampling and morphology analysis in an optically-accessible diesel engine. Black soot emissions from diesel engines are associated with respiratory illness, cancer, and heart attacks. This project aims to reduce diesel soot emissions by clarifying the nature of the structure and size of soot particles that are sampled from both the engine cylinder and the tailpipe.
Natural gas direct injection in advanced engines and powertrains. Natural gas direct injection in advanced engines and powertrains. This project aims to quantify and understand how future, advanced passenger vehicles might perform when optimised for the direct injection (DI) of natural gas. Such production vehicles do not exist, largely because production DI systems for natural gas, spark ignition engines are not yet available. This project will examine both advanced conventional and hybrid vehi ....Natural gas direct injection in advanced engines and powertrains. Natural gas direct injection in advanced engines and powertrains. This project aims to quantify and understand how future, advanced passenger vehicles might perform when optimised for the direct injection (DI) of natural gas. Such production vehicles do not exist, largely because production DI systems for natural gas, spark ignition engines are not yet available. This project will examine both advanced conventional and hybrid vehicles using a suite of state-of-the-art experimental and numerical techniques. This project will quantify these vehicles’ environmental, technical and economic performance to determine whether DI natural gas, conventional and hybrid vehicles might reduce substantial greenhouse gas (GHG) emissions whilst avoiding any consumer penalty. This research could contribute to global GHG abatement.Read moreRead less