Kai-Alexander Saalbach scite author profile

Ultrasonic cavitation peening is an environmentally friendly technology to improve surface properties. In the traditional ultrasonic cavitation peening process, specimens have to be immersed in a liquid and temperature control is required, which limits the wide usage of this technology due to the geometry and complicated setup. In order to improve this process, water is slowly jetted (75 mL/min) into the gap between the sonotrode tip and specimen surface. The water jet makes the gap full of water. Thus, cavitation bubbles can be generated in the gap as the traditional ultrasonic cavitation peening process. In this case, the water container and temperature control are no longer necessary. The goal of this contribution is to evaluate the treatment effectiveness of this novel approach by the impact loads, the volume loss, the surface roughness, the microhardness and the microstructure of the specimen surface. The results indicate that a higher input power is beneficial and there would be an optimal gap width for this novel ultrasonic cavitation peening process.

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Kai-Alexander Saalbach

Theoretical and experimental investigations of ultrasonic sound fields in thin bubbly liquid layers for ultrasonic cavitation peening

Impact of time on ultrasonic cavitation peening via detection of surface plastic deformation

Self-sensing cavitation detection in ultrasound-induced acoustic cavitation

Effect of different standoff distance and driving current on transducer during ultrasonic cavitation peening

A Novel Ultrasonic Cavitation Peening Approach Assisted by Water Jet

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