Acoustic resonance for contactless ultrasonic cavitation in alloy melts

•Contactless ultrasound is a novel, technique for the Ultrasonic Treatment (UST) of liquid metals.•To reach the necessary pressure amplitude for cavitation acoustic resonance is necessary.•Cavitation was detected experimentally and confirmed by grain size reduction in the metal.•Two numerical models...

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Veröffentlicht in:Ultrasonics sonochemistry 2020-05, Vol.63, p.104959-104959, Article 104959
Hauptverfasser: Tonry, C.E.H., Djambazov, G., Dybalska, A., Griffiths, W.D., Beckwith, C., Bojarevics, V., Pericleous, K.A.
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Sprache:eng
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Zusammenfassung:•Contactless ultrasound is a novel, technique for the Ultrasonic Treatment (UST) of liquid metals.•To reach the necessary pressure amplitude for cavitation acoustic resonance is necessary.•Cavitation was detected experimentally and confirmed by grain size reduction in the metal.•Two numerical models were used to predict the location of the resonant modes.•A good agreement is achieved between the models and experimental data. Contactless ultrasound is a novel, easily implemented, technique for the Ultrasonic Treatment (UST) of liquid metals. Instead of using a vibrating sonotrode probe inside the melt, which leads to contamination, we consider a high AC frequency electromagnetic coil placed close to the metal free surface. The coil induces a rapidly changing Lorentz force, which in turn excites sound waves. To reach the necessary pressure amplitude for cavitation with the minimum electrical energy use, it was found necessary to achieve acoustic resonance in the liquid volume, by finely tuning the coil AC supply frequency. The appearance of cavitation was then detected experimentally with an externally placed ultrasonic microphone and confirmed by the reduction in grain size of the solidified metal. To predict the appearance of various resonant modes numerically, the exact dimensions of the melt volume, the holding crucible, surrounding structures and their sound properties are required. As cavitation progresses the speed of sound in the melt changes, which in practice means resonance becomes intermittent. Given the complexity of the situation, two competing numerical models are used to compute the soundfield. A high order time-domain method focusing on a particular forcing frequency and a Helmholtz frequency domain method scanning the full frequency range of the power supply. A good agreement is achieved between the two methods and experiments which means the optimal setup for the process can be predicted with some accuracy.
ISSN:1350-4177
1873-2828
DOI:10.1016/j.ultsonch.2020.104959