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AUTOMATION OF MELTING AND METAL PROCESSING
ArticleName Ensuring surface quality in AlMn alloy items during high-frequency wave impact boring
DOI 10.17580/tsm.2023.04.12
ArticleAuthor Maksarov V. V., Minin A. O., Zakharova V. P.
ArticleAuthorData

Saint Petersburg Mining University, Saint Petersburg, Russia:

V. V. Maksarov, Dean of the Mechanical Engineering Faculty, Professor, Doctor of Technical Sciences, e-mail: maks78.54@mail.ru
A. O. Minin, Postgraduate Student at the Mechanical Engineering Department, e-mail: minin.97alex@mail.ru
V. P. Zakharova, Associate Professor at the Mechanical Engineering Department, Candidate of Technical Sciences, e-mail: veraz73@mail.ru

Abstract

This paper examines the problem of build-up formation when making bore holes in items made of aluminium alloy AlMn, which can lead to increased roughness of the machined surface. The authors analyzed factors influencing the build-up formation when machining the said alloy. It is proposed to use high-frequency wave impacts for making bore holes in items made of corrosion-resistant aluminium alloys. The authors also analyzed how attenuation of sound waves may affect the productivity of this technique. The authors built a model showing how the sound wave is propagating from the magnetostrictor to the cutting zone when making bore holes in the internal surface of an AlMn alloy item using concentrators of different shapes. A study was carried out that involved simulation of the sound wave propagation from the magnetostrictor to the cutting zone when making bore holes in the internal surface of an AlMn alloy item when employing the technique taken for prototype. The sound wave propagation model helps estimate the attenuation degree of the waves as they propagate. According to the model, the wave impact registered was at its highest when a tapered concentrator was used for making bore holes in items made of corrosion-resistant aluminium alloys.

keywords Aluminium alloy AlMn, surface roughness, build-up formation, cutting modes, high-frequency wave impact, flow chip, sound wave, attenuation
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