Dynamic Modelling and Gear Shift Simulation of Powertrains with Dual Clutch Transmissions. The project will make a significant contribution to the development and commercialisation of dual clutch transmissions, which represent a breakthrough vehicle transmission technology. The acquired knowledge and advanced simulation tools will enable engineers to design superior vehicles with improved fuel efficiency and performance. The project will hence benefit the nation and community, resulting in:
1) ....Dynamic Modelling and Gear Shift Simulation of Powertrains with Dual Clutch Transmissions. The project will make a significant contribution to the development and commercialisation of dual clutch transmissions, which represent a breakthrough vehicle transmission technology. The acquired knowledge and advanced simulation tools will enable engineers to design superior vehicles with improved fuel efficiency and performance. The project will hence benefit the nation and community, resulting in:
1) powertrains with improved fuel efficiency, drivability and gear shift quality at the lowest production cost;
2) increased employment in the automotive sector benefiting from leading the world in applying the frontier technology to vehicles;
3) increased knowledge base on complex dynamic systems, well trained researchers and engineers.
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Quantitative analysis of dynamic performance of vehicles with uncertain system parameters and road inputs. Ride comfort, road holding and stability of on-road vehicles are not only important quality indicators but major public health and safety issues. To accurately predict and prevent unsafe motions of a vehicle under all circumstances is still a major technological challenge. The research, which aims to develop a novel design theory, presents a significant step forward in tackling the challeng ....Quantitative analysis of dynamic performance of vehicles with uncertain system parameters and road inputs. Ride comfort, road holding and stability of on-road vehicles are not only important quality indicators but major public health and safety issues. To accurately predict and prevent unsafe motions of a vehicle under all circumstances is still a major technological challenge. The research, which aims to develop a novel design theory, presents a significant step forward in tackling the challenge in the quantitative performance analysis of vehicles with various uncertainties. The acquired knowledge will assist engineers in developing safer vehicles and also benefit the aeronautical, military and other transportation industries. The wider community would benefit by potentially reduced death rates and fatal injuries caused by car crashes.Read moreRead less
Demand Dependent Active Suspensions for Preventing Vehicle Rollover. Rollover crashes are a major public safety issue in Australia. Reliable and low cost anti-roll technology and the availability of required design methodology and simulation tools will greatly assist the automotive industry in improving vehicle safety and consequently enhance its competitiveness in the global marketplace. The knowledge acquired from this project would provide an essential theoretical basis for commercialising th ....Demand Dependent Active Suspensions for Preventing Vehicle Rollover. Rollover crashes are a major public safety issue in Australia. Reliable and low cost anti-roll technology and the availability of required design methodology and simulation tools will greatly assist the automotive industry in improving vehicle safety and consequently enhance its competitiveness in the global marketplace. The knowledge acquired from this project would provide an essential theoretical basis for commercialising the proposed suspensions and enhance the exports of Australian car component manufacturers. It would also benefit aeronautical, military and other industries. The wide community would benefit by potentially reduced death rates and fatal injuries caused by rollover crashes, and through increased employment in industry.Read moreRead less
Dynamic Characteristics of Kinetic Suspension Systems for Vehicle Applications. Suspension systems play a key role in vehicle dynamics and, in addition to providing ride comfort, can prevent or minimise fatal collisions by enhancing vehicle stability. This project aims to advance the theory and design of the kinetic suspension systems (KSS), which break the compromise between ride comfort and vehicle handling inherent in most existing systems. Industry Partner, Kinetic, has invented many novel K ....Dynamic Characteristics of Kinetic Suspension Systems for Vehicle Applications. Suspension systems play a key role in vehicle dynamics and, in addition to providing ride comfort, can prevent or minimise fatal collisions by enhancing vehicle stability. This project aims to advance the theory and design of the kinetic suspension systems (KSS), which break the compromise between ride comfort and vehicle handling inherent in most existing systems. Industry Partner, Kinetic, has invented many novel KSS and currently leads the world in the R&D of KSS technology. The gained ability in reliable analysis and virtual experimentation on the systems prior to prototyping and on-road tests enables the industry to rapidly commercialise the cutting-edge, safety-critical technology, thus bringing great benefits to society.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
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
Protecting Occupants in Vehicle Rollover Crashes. This project addresses a public health issue involving rollover crashes. It will help prevent 340 deaths, 6000 injuries and save $3.6 billion annually in Australia and many fold this number internationally. A dynamic rollover crashworthiness test protocol, that ensures efficient and economical vehicle rollover protection systems are designed and manufactured, will be provided to consumer and regulatory bodies to consider and implement. In additio ....Protecting Occupants in Vehicle Rollover Crashes. This project addresses a public health issue involving rollover crashes. It will help prevent 340 deaths, 6000 injuries and save $3.6 billion annually in Australia and many fold this number internationally. A dynamic rollover crashworthiness test protocol, that ensures efficient and economical vehicle rollover protection systems are designed and manufactured, will be provided to consumer and regulatory bodies to consider and implement. In addition, much needed Occupational Health & Safety information regarding vehicle rollover crashworthiness, which provide a safe work place environment for professional drivers and employees using vehicles, will be supplied to industry fleet managers, defence and emergency services.Read moreRead less
Investigation into on-road vehicle rollovers using a combined rigid and flexible multibody model. Rollover propensity is one of the major safety indicators of vehicles. In-depth understanding of the causes and mechanisms of vehicle rollovers and the availability of advanced design and simulation tools will greatly assist the automotive industry in improving vehicle safety and consequently enhance the industry's competitiveness in the international marketplace. The developed knowledge would also ....Investigation into on-road vehicle rollovers using a combined rigid and flexible multibody model. Rollover propensity is one of the major safety indicators of vehicles. In-depth understanding of the causes and mechanisms of vehicle rollovers and the availability of advanced design and simulation tools will greatly assist the automotive industry in improving vehicle safety and consequently enhance the industry's competitiveness in the international marketplace. The developed knowledge would also benefit aeronautical, ship building and military industries which are generally well-equipped to absorb new technology and seek a competitive edge. The wide community would benefit by potentially reduced death rates and fatal injuries caused by rollover crashes, and through increased employment in industry. 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
Accelerating clean automotive innovation: fundamental insights into alternative fuel combustion. To achieve the maximum efficiency from alternatively fuelled engines, better understanding and predictive models are needed for the major limiting factor in spark-ignition engine efficiency: knock. The project will address this gap, thereby accelerating development of better engines and strengthening national capacity in clean engine technology.