Tailoring composite propellers for reduced sound radiation. This project aims to explore the generation of noise by composite propellers and to use this understanding to tailor the composite properties to reduce underwater noise. Propellers are a harmful source of noise in the marine environment, disturbing animal behaviour, revealing the location of naval vessels and interfering with sonar operation. Adaptive composite propellers are potentially quieter than metal propellers, as well as offerin ....Tailoring composite propellers for reduced sound radiation. This project aims to explore the generation of noise by composite propellers and to use this understanding to tailor the composite properties to reduce underwater noise. Propellers are a harmful source of noise in the marine environment, disturbing animal behaviour, revealing the location of naval vessels and interfering with sonar operation. Adaptive composite propellers are potentially quieter than metal propellers, as well as offering improvements in efficiency and fuel consumption. The aims of this project are to understand the physical mechanisms associated with composite propeller noise generation. The outcomes are intended to provide advanced numerical capabilities that will support the development of quieter marine propeller designs to improve defence capability and the acoustic environment for marine mammals.Read moreRead less
Prediction of radiated noise from marine propellers. Underwater noise radiated from marine vessels is a significant problem for research, fishing and military vessels, and is a major source of pollution in the marine environment. The major source contributing to underwater noise is due to the propeller. This work will develop numerical models with experimental validation that can accurately predict the sources of noise generated by marine propellers and acoustic signatures of marine vessels due ....Prediction of radiated noise from marine propellers. Underwater noise radiated from marine vessels is a significant problem for research, fishing and military vessels, and is a major source of pollution in the marine environment. The major source contributing to underwater noise is due to the propeller. This work will develop numerical models with experimental validation that can accurately predict the sources of noise generated by marine propellers and acoustic signatures of marine vessels due to propeller motion. This work has great significance for Australia’s construction and military maritime industries. The technologies developed in this project are also applicable to rotors in other industries such as in aircraft, helicopters and wind turbines.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100032
Funder
Australian Research Council
Funding Amount
$600,000.00
Summary
A state-of-the-art field emission electron microprobe for Tasmania. A state-of-the-art field emission electron microprobe for Tasmania:
This proposal aims to replace an existing 12-year old conventional electron microprobe with a state-of-the art field emission electron microprobe instrument capable of in-situ, low-level, quantitative non-destructive chemical analysis, and mapping of element distribution and texture at sub-micron resolution. This would establish new research strengths in the fi ....A state-of-the-art field emission electron microprobe for Tasmania. A state-of-the-art field emission electron microprobe for Tasmania:
This proposal aims to replace an existing 12-year old conventional electron microprobe with a state-of-the art field emission electron microprobe instrument capable of in-situ, low-level, quantitative non-destructive chemical analysis, and mapping of element distribution and texture at sub-micron resolution. This would establish new research strengths in the field of earth and materials science. In particular, it may improve efficiencies of discovery and recovery of ore deposits and develop environmentally friendly processes for waste disposal. Read moreRead less