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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100203
Funder
Australian Research Council
Funding Amount
$326,000.00
Summary
Flow measurement for large-scale industrial aerodynamics. This project aims to research the unsteady aerodynamic wakes of cars, trucks, athletes, turbines and micro-air vehicles. Researchers will use the flow measurement system for large-scale industrial aerodynamics to resolve high speed and large scale industrial flows. The system’s primary objective will be the characterisation of complex, three-dimensional turbulent flows. It is anticipated that the research will lead to reduced aerodynamic ....Flow measurement for large-scale industrial aerodynamics. This project aims to research the unsteady aerodynamic wakes of cars, trucks, athletes, turbines and micro-air vehicles. Researchers will use the flow measurement system for large-scale industrial aerodynamics to resolve high speed and large scale industrial flows. The system’s primary objective will be the characterisation of complex, three-dimensional turbulent flows. It is anticipated that the research will lead to reduced aerodynamic drag in transport and improve wind power generation, ultimately reducing emissions and improving efficiency and national competitiveness in sport. The advanced system will strengthen Australia’s position as an advanced engineering design hub.Read moreRead less
Comfort and ergonomics: Innovative seating solutions for commercial vehicles. Comfort and ergonomics: Innovative seating solutions for commercial vehicles. This project aims to develop a 6-degree-of-freedom seating system for commercial vehicles, including heavy duty trucks and mobile machinery, to reduce unwanted multiple directional vibrations to the driver’s body. Long-term exposure to vibrations from uneven road surfaces, vibrating tools, and vibrating machinery affects driver comfort, fatig ....Comfort and ergonomics: Innovative seating solutions for commercial vehicles. Comfort and ergonomics: Innovative seating solutions for commercial vehicles. This project aims to develop a 6-degree-of-freedom seating system for commercial vehicles, including heavy duty trucks and mobile machinery, to reduce unwanted multiple directional vibrations to the driver’s body. Long-term exposure to vibrations from uneven road surfaces, vibrating tools, and vibrating machinery affects driver comfort, fatigue and safety, and can also cause neck and shoulder pain, lower back injuries, and spinal injuries. The expected outcome of the project is a comfortable and ergonomic seating system that, agriculture, transportation, mining and construction vehicles, both in Australia and internationally, can widely use.Read moreRead less
Cost effective carbon fibres from polyethylene for lightweight applications. This project aims to deliver cost-effective, high-performance carbon fibres from polyethylene through the use of novel catalysts and advanced processing techniques. Carbon fibre-reinforced composites are extremely strong and light fibre-reinforced polymers that are commonly used wherever high strength-to-weight ratio and rigidity are required, such as in aerospace, automotive and civil engineering applications. However, ....Cost effective carbon fibres from polyethylene for lightweight applications. This project aims to deliver cost-effective, high-performance carbon fibres from polyethylene through the use of novel catalysts and advanced processing techniques. Carbon fibre-reinforced composites are extremely strong and light fibre-reinforced polymers that are commonly used wherever high strength-to-weight ratio and rigidity are required, such as in aerospace, automotive and civil engineering applications. However, broader market uptake is currently limited by carbon fibre costs. The project aims to deliver high-quality fibre with real potential to capture a share of the $14-billion carbon fibre composite market.Read moreRead less
In-road microwave system for traffic monitoring and vehicle identification. In-road microwave system for traffic monitoring and vehicle identification. This project aims to develop a cost-effective, in-road microwave radar system for traffic monitoring and vehicle identification. The ever increasing number of vehicles on our roads makes conventional approaches to traffic management less effective and prohibitively expensive. The new system will integrate chip-enabled license plate technology wit ....In-road microwave system for traffic monitoring and vehicle identification. In-road microwave system for traffic monitoring and vehicle identification. This project aims to develop a cost-effective, in-road microwave radar system for traffic monitoring and vehicle identification. The ever increasing number of vehicles on our roads makes conventional approaches to traffic management less effective and prohibitively expensive. The new system will integrate chip-enabled license plate technology with novel microwave radar techniques to produce real-time data that supports immediate intervention for improved road safety, vehicle identification and driver validation. Multiple sensors will also provide uniquely rich data to improve traffic management decisions, road infrastructure planning and operation. This research could significantly reduce the effect of traffic incidents and congestions across Australia.Read moreRead less
Innovative Magnetorheological Suspension Systems for Forklift Trucks. This project aims to improve forklift design to reduce the vibration experienced by forklift drivers. Research consistently links forklift driving with a high incidence of back pain and musculoskeletal injuries through exposure to hand, arm and whole-body vibrations that are caused by the rigid passive suspension in traditional forklifts, which cannot properly absorb vibration stemming from deviations in driving surfaces, chan ....Innovative Magnetorheological Suspension Systems for Forklift Trucks. This project aims to improve forklift design to reduce the vibration experienced by forklift drivers. Research consistently links forklift driving with a high incidence of back pain and musculoskeletal injuries through exposure to hand, arm and whole-body vibrations that are caused by the rigid passive suspension in traditional forklifts, which cannot properly absorb vibration stemming from deviations in driving surfaces, changes in mass, or common loading, lifting and unloading actions. The project aims to draw on the research team’s expertise in magnetorheological technology to develop and evaluate a new tuneable integrated semi-active wheel and chassis and seat suspension system that can vary damping and stiffness to control mass uncertainty and vibration.Read moreRead less
A real-time modelling of crowd dynamics for disaster prevention. This project aims to develop methods and technologies to enable urban planners to design infrastructures to ensure public safety in emergency situations and to enable emergency management to optimise effective response plans. Rapid population growth creates major challenges for urban management, which has a responsibility to ensure the safety of citizens in the case of emergencies. This project aims to develop a methodology to stud ....A real-time modelling of crowd dynamics for disaster prevention. This project aims to develop methods and technologies to enable urban planners to design infrastructures to ensure public safety in emergency situations and to enable emergency management to optimise effective response plans. Rapid population growth creates major challenges for urban management, which has a responsibility to ensure the safety of citizens in the case of emergencies. This project aims to develop a methodology to study pedestrian crowd dynamics under panic or extreme emergency conditions, using innovative experimental approaches with new multi-scale online simulation methods and optimisation techniques. The resultant methodology would support planning and prediction of pedestrian crowd movements based on data from past events as well as adaptive planning for live events as they unfold.Read moreRead less
Design features for correct use of child car restraints. This project aims to minimise incorrect use of child restraints, which triple the risk of injury to children in car crashes. One in two children travelling in cars are incorrectly restrained. Using naturalistic and epidemiological studies, this project will characterise child restraint design features that minimise errors related to the real world interaction between restraint design, parents and children, and determine the effectiveness o ....Design features for correct use of child car restraints. This project aims to minimise incorrect use of child restraints, which triple the risk of injury to children in car crashes. One in two children travelling in cars are incorrectly restrained. Using naturalistic and epidemiological studies, this project will characterise child restraint design features that minimise errors related to the real world interaction between restraint design, parents and children, and determine the effectiveness of using optimally designed restraints. This research will help child restraint manufacturers to improve their products and design better child restraint systems, that reduce injury to children in crashes.Read moreRead less
User-centric solutions to optimise safety of children in cars. Globally, incorrect use of child restraints and inappropriate use of adult seat belts are widespread and longstanding problems. In Australia alone >2 million children are at increased risk of injury because of the lack of understanding about how to solve these problems. We have pioneered development of methods to allow novel user-centred approaches coupled with behavioural theory to effectively tackle these problems. In this project ....User-centric solutions to optimise safety of children in cars. Globally, incorrect use of child restraints and inappropriate use of adult seat belts are widespread and longstanding problems. In Australia alone >2 million children are at increased risk of injury because of the lack of understanding about how to solve these problems. We have pioneered development of methods to allow novel user-centred approaches coupled with behavioural theory to effectively tackle these problems. In this project we will build on and extend these innovative methods to to deliver new understanding about how (i) to communicate with parents to ensure behaviours and decisions about restraint optimise safety, and (ii) user-driven design can solve problems inhibiting optimal protection of in cars.Read moreRead less