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Leighton, Timothy
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (11/11 displayed)
- 2019Group behavioral responses of juvenile common carp (Cyprinus carpio) to pulsed tonal stimuli in the presence of masking noisecitations
- 2017Ultrasonic activated stream cleaning of a range of materials
- 2016An activated fluid stream – new techniques for cold water cleaningcitations
- 2016A comparison of ultrasonically activated water stream and ultrasonic bath immersion cleaning of railhead leaf-film contaminantcitations
- 2015The acoustic bubble: oceanic bubble acoustics and ultrasonic cleaningcitations
- 2014Bubble acoustics
- 2013A new approach to ultrasonic cleaningcitations
- 2010Cluster collapse in a cylindrical cell: correlating multibubble sonoluminescence, acoustic pressure, and erosioncitations
- 2007Studies into the detection of buried objects (particularly optical fibres) in saturated sediment. Part 2: design and commissioning of test tank
- 2007Studies into the detection of buried objects (particularly optical fibres) in saturated sediment. Part 5: an acousto-optic detection system
- 2007Cavitation, shockwaves and electrochemistry: an experimental and theoretical approach to a complex environment
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document
Ultrasonic activated stream cleaning of a range of materials
Abstract
Despite decades of routine use (starting from the industrial setting but now also with domestic products available), ultrasonic cleaning faces technical challenges that have never been overcome, and the root of many of these lies with an understanding of the interaction between the bubble population and the sound field. Ultrasonically Activated Stream (UAS) technology is designed to produce ultrasonic cleaning, and in this paper it does so for scenarios for which an ultrasonic cleaning bath would be unsuitable, e.g., removing key contaminants (such as biofilms) from delicate substrates (tissues, etc.), without damaging that substrate.