Innovative and human-centred design in underground coalmining: a new concept vehicle for safe personnel transport. Australian coalminers commute daily on a system of underground roads to the ‘longwall’, the site where their work can begin, in vehicles that are primitive by aboveground standards. These current vehicles contribute to short- and long-term injuries amongst mining personnel. This project will develop benchmark standards for an innovative underground personnel carrier that promotes a ....Innovative and human-centred design in underground coalmining: a new concept vehicle for safe personnel transport. Australian coalminers commute daily on a system of underground roads to the ‘longwall’, the site where their work can begin, in vehicles that are primitive by aboveground standards. These current vehicles contribute to short- and long-term injuries amongst mining personnel. This project will develop benchmark standards for an innovative underground personnel carrier that promotes a safer and healthier working environment by contributing to reduced injury rates and ensuring the comfort of workers. This project contributes to the health and welfare of coalminers in regional Australia and in the international mining sector through innovative and ’human-centred’ design.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883093
Funder
Australian Research Council
Funding Amount
$285,000.00
Summary
A Haptically enabled Universal Motion Simulator Research Facility. The proposed universal motion simulator research facility will enable to develop a better understanding of issues involved in ergonomic and safe vehicle designs and provides opportunities to improve Australia's international competitiveness and economic sustainability through innovations in the manufacturing and transport sectors. This universal motion simulator will provide opportunity to extend our understanding of operator con ....A Haptically enabled Universal Motion Simulator Research Facility. The proposed universal motion simulator research facility will enable to develop a better understanding of issues involved in ergonomic and safe vehicle designs and provides opportunities to improve Australia's international competitiveness and economic sustainability through innovations in the manufacturing and transport sectors. This universal motion simulator will provide opportunity to extend our understanding of operator controlled devices, such as cars and mining machinery, and to develop effective strategies to reduce the risk of vehicle accidents.Read moreRead less
Safety management system for heavy vehicle transport. Crashes involving heavy vehicles result in around 330 deaths, over 3000 serious injuries annually, and cost over $6 billion per year. Trucks deliver 72% of Australia's total freight. The quantity delivered by trucks has increased by 40% over a decade and will double over the next 20 years. Conservatively the transport industry contributes about 5.6% to GDP and employs nearly 5% of the workforce. Safe transport is crucial for Australia's heal ....Safety management system for heavy vehicle transport. Crashes involving heavy vehicles result in around 330 deaths, over 3000 serious injuries annually, and cost over $6 billion per year. Trucks deliver 72% of Australia's total freight. The quantity delivered by trucks has increased by 40% over a decade and will double over the next 20 years. Conservatively the transport industry contributes about 5.6% to GDP and employs nearly 5% of the workforce. Safe transport is crucial for Australia's health and economic recovery. If a 10% reduction in casualty truck crashes were to result from this study, the cost benefit ratio would be around 200 to 1.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0228900
Funder
Australian Research Council
Funding Amount
$603,000.00
Summary
Testing facility for heavily loaded bridge and barrier systems. Government and industry are increasing truck masses from current single articulated 42.5 tonne trucks to 160 tonne multi-bogie trucks. This will provide Australia with over $1 billion of potential benefits and an efficient and competitive transport industry. To capture these benefits and further progress Australia's economy, considerable collaborative research on a number of fronts must be carried out investigating how bridges and b ....Testing facility for heavily loaded bridge and barrier systems. Government and industry are increasing truck masses from current single articulated 42.5 tonne trucks to 160 tonne multi-bogie trucks. This will provide Australia with over $1 billion of potential benefits and an efficient and competitive transport industry. To capture these benefits and further progress Australia's economy, considerable collaborative research on a number of fronts must be carried out investigating how bridges and barriers can perform safely when subjected to very heavy traffic and impact loads under laboratory and typical service conditions. This application seeks funds for establishing a unique hi-tech testing facility in Australia vital for advancing such infrastructure technology.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
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
Development of an Intelligent Perception System for Electric Brakes. Electric braking is a vital component of the drive by-wire systems whose development is currently being supported worldwide by many automobile manufacturers. The aim of this project is to contribute to the development of an efficient fully functional electrically operated braking system. The main focus is on development of the intelligent perceptual sensors required for optimum performance of a by-wire braking system (to be com ....Development of an Intelligent Perception System for Electric Brakes. Electric braking is a vital component of the drive by-wire systems whose development is currently being supported worldwide by many automobile manufacturers. The aim of this project is to contribute to the development of an efficient fully functional electrically operated braking system. The main focus is on development of the intelligent perceptual sensors required for optimum performance of a by-wire braking system (to be commercialised by 2007). This project will also facilitate the development of professional courses for by-wire technology. Such courses will play a crucial role in maintaining the competitiveness of the Australian car component industry as by-wire technology emerges.Read moreRead less
Optimal Topological Design of 3D Continuum Structures for Crashworthiness. There is a widespread need throughout the Australian transport, defence and construction industries for high performance energy absorption devices. Data from the Australian Transport Safety Bureau show that in 2002 there were 1,715 people killed in 1,525 crashes in Australia. The proposed research will develop advanced techniques for improving crashworthiness of vehicles, roadside barriers and other energy absorption devi ....Optimal Topological Design of 3D Continuum Structures for Crashworthiness. There is a widespread need throughout the Australian transport, defence and construction industries for high performance energy absorption devices. Data from the Australian Transport Safety Bureau show that in 2002 there were 1,715 people killed in 1,525 crashes in Australia. The proposed research will develop advanced techniques for improving crashworthiness of vehicles, roadside barriers and other energy absorption devices. This will lead to significant reductions in injury to people and damage to structures caused by impact; and thus substantial savings for the nation from the enormous costs associated with the fatalities, injuries and structural damages. Read moreRead less
Occupant Protection in Far-side Crashes. Regulations and interventions to protect far-side occupants in side impact crashes do not currently exist, even though far-side occupants account for up to 40% of harm in real world side impact crashes. Through a comprehensive test schedule this research will develop an understanding of occupant biomechanics and injury mechanisms during far-side collisions. Current dummy bio-fidelity can then be assessed and improved, appropriate far-side test measures d ....Occupant Protection in Far-side Crashes. Regulations and interventions to protect far-side occupants in side impact crashes do not currently exist, even though far-side occupants account for up to 40% of harm in real world side impact crashes. Through a comprehensive test schedule this research will develop an understanding of occupant biomechanics and injury mechanisms during far-side collisions. Current dummy bio-fidelity can then be assessed and improved, appropriate far-side test measures developed, and recommendation for regulations made. It is anticipated that application of these test procedures will allow the development of innovative and world-leading far-side countermeasures that will ultimately improve vehicle occupant safety.Read moreRead less
Advanced control and estimation strategies for electromechanical brake-by-wire systems. The project aims to investigate the application of advanced control and estimation techniques (robust nonlinear and soft-computing approaches) to the problem of maximising the effectiveness of electromechanical brake-by-wire systems in emergency braking manoeuvres. The work will be conducted using state-of-the-art control design and hardware-in-the loop simulation facilities in the Research Centre for Advance ....Advanced control and estimation strategies for electromechanical brake-by-wire systems. The project aims to investigate the application of advanced control and estimation techniques (robust nonlinear and soft-computing approaches) to the problem of maximising the effectiveness of electromechanical brake-by-wire systems in emergency braking manoeuvres. The work will be conducted using state-of-the-art control design and hardware-in-the loop simulation facilities in the Research Centre for Advanced By-Wire Technologies (RABiT), which has been established to accelerate the development and commercialisation of by-wire technology in Australia. Expected outcomes are actuator and road friction control algorithms which have been demonstrated to be robust in the context of real-world actuator and vehicle dynamics.Read moreRead less