ФОРМИРОВАНИЕ СТРУКТУРЫ И СВОЙСТВ ЛИТЫХ КОМПОЗИЦИОННЫХ МАТЕРИАЛОВ С ПОВЫШЕННЫМ  СОДЕРЖАНИЕМ ЭКЗОГЕННОЙ ФАЗЫ: OXDFNJ

Evgeny S.  Prusov; Ivan V.  Shabaldin; Vladislav B.  Deev

doi:10.25712/ASTU.2072-8921.2023.04.033

Authors

Evgeny S. Prusov Vladimir State University named after Alexander and Nikolay Stoletovs https://orcid.org/0000-0003-4189-877X
Ivan V. Shabaldin Vladimir State University named after Alexander and Nikolay Stoletovs https://orcid.org/0000-0002-1958-6852
Vladislav B. Deev Vladimir State University named after Alexander and Nikolay Stoletovs https://orcid.org/0000-0002-8349-8072

DOI:

https://doi.org/10.25712/ASTU.2072-8921.2023.04.033

Keywords:

cast composite materials, exogenous reinforcement, silicon carbide, mechanical stirring, structure and properties

Abstract

An urgent task in the field of development and improvement of metallurgical technologies for producing aluminum matrix composite materials is the search for technical and technological solutions that make it possible to increase the degree of assimilation of reinforcing particles by the matrix aluminum melt to increase their maximum concentrations while simultaneously ensuring stable quality of the resulting materials. The article presents the main results of developing technological methods for mechanical mixing of powdered particles of silicon carbide (63-75 microns) into an aluminum melt with a nominal content of the reinforcing phase of 25 vol.%. It has been shown that the synthesized materials are characterized by a uniform distribution of reinforcing particles and are distinguished by increased compressive strength and wear resistance under dry friction conditions.

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FORMATION OF THE STRUCTURE AND PROPERTIES OF CAST COMPOSITE MATERIALS WITH INCREASED EXOGENOUS PHASE CONTENT

OXDFNJ

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