The development of active third-generation heavy vehicle aerodynamic drag reducing devices to reduce future transport emissions. The potential for emission reductions through aerodynamic improvements is particularly apparent in long haul heavy vehicle transport. By developing active devices to be fitted to the heavy vehicle trailer of the future this work offers drag reduction potential from current levels of up to 40 per cent. If widely implemented these devices could play a major part in the t ....The development of active third-generation heavy vehicle aerodynamic drag reducing devices to reduce future transport emissions. The potential for emission reductions through aerodynamic improvements is particularly apparent in long haul heavy vehicle transport. By developing active devices to be fitted to the heavy vehicle trailer of the future this work offers drag reduction potential from current levels of up to 40 per cent. If widely implemented these devices could play a major part in the transport sector meeting medium term emissions targets. If successful not only will the project develop unique components, it will support heavy vehicle research and development that is so important to maintaining a strong manufacturing presence in Australia, especially in regional centres, such as Ballarat where Maxitrans has major headquarters. Read moreRead less
Advanced Future Automotive Electrical Machines based on Amorphous Iron. Electric machines consume about 70% of all electrical energy generated. Electric machines constructed from a promising magnetic material called amorphous iron can be much more efficient than conventional designs, hence saving energy. Amorphous iron is normally difficult to cut accurately into the shapes required in electric machines. We propose to design and construct high-efficiency permanent magnet machines based on amorp ....Advanced Future Automotive Electrical Machines based on Amorphous Iron. Electric machines consume about 70% of all electrical energy generated. Electric machines constructed from a promising magnetic material called amorphous iron can be much more efficient than conventional designs, hence saving energy. Amorphous iron is normally difficult to cut accurately into the shapes required in electric machines. We propose to design and construct high-efficiency permanent magnet machines based on amorphous iron for automotive applications, which will be cut using an innovative Australian waterjet cutting technique. The key challenges are to optimise the machine design for commercial production given the capabilities and limitations of the material and the new cutting process.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