Prediction and control of fluid-structure interactions. Fluid-flows create a pressure that can deform the surface of a structure or cause it to vibrate; an extreme example is the fluttering of a flag. Flow-induced vibration of the external panels of vehicles causes damage, noise and can adversely affect performance. This project will develop a wholly new approach for the analysis of these interactions. The versatility and completeness of the approach permits a step-change in the design of panels ....Prediction and control of fluid-structure interactions. Fluid-flows create a pressure that can deform the surface of a structure or cause it to vibrate; an extreme example is the fluttering of a flag. Flow-induced vibration of the external panels of vehicles causes damage, noise and can adversely affect performance. This project will develop a wholly new approach for the analysis of these interactions. The versatility and completeness of the approach permits a step-change in the design of panels, reducing material and manufacturing costs without compromise to safety and performance - an immense benefit for the myriad engineered products or structures that feature flow over a deformable surface. Read moreRead less
Taming turbulence: Hydrodynamic stability and flow-structure interaction using grid-free computation. Turbulence is characterized as seemingly disordered fluctuations that impede the progress of an object through a fluid by creating increased frictional or drag forces. Using a new type of fluid-flow simulation, this project will generate advanced understanding of turbulence in the flow over the surface of a vehicle, be it a ship, car, aircraft or within a pipe, with the technological objective o ....Taming turbulence: Hydrodynamic stability and flow-structure interaction using grid-free computation. Turbulence is characterized as seemingly disordered fluctuations that impede the progress of an object through a fluid by creating increased frictional or drag forces. Using a new type of fluid-flow simulation, this project will generate advanced understanding of turbulence in the flow over the surface of a vehicle, be it a ship, car, aircraft or within a pipe, with the technological objective of reducing drag by adhering a compliant skin to the surface. While the correct choice of compliance relies upon understanding very complex flow-structure dynamics, the resulting technology is simple, robust and has low capital and maintenance costs. Clearly, drag reduction reduces fuel costs and lower fuel consumption is environmentally beneficial. Read moreRead less
Development of Nuclear Quadrupole Resonance Methods and Technology to Enhance the Detection of Explosives and Other Contraband. This project will develop new methods and technology for the detection of explosives and other compounds using Nuclear Quadrupole Resonance. This technique is of great importance to aviation security and the military and is particularly relevant to the priority goal of 'Safeguarding Australia'. The Industry partner has licensing contracts with major x-ray manufacturer ....Development of Nuclear Quadrupole Resonance Methods and Technology to Enhance the Detection of Explosives and Other Contraband. This project will develop new methods and technology for the detection of explosives and other compounds using Nuclear Quadrupole Resonance. This technique is of great importance to aviation security and the military and is particularly relevant to the priority goal of 'Safeguarding Australia'. The Industry partner has licensing contracts with major x-ray manufacturers and system integrators to integrate this technology. These investigations should yield improvements in the signal to noise ratio, false alarm rates and the spatial discrimination of targets. This work will lead to significant increases in the value of the technology and open up new areas of commercialization.Read moreRead less