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HomeKey Engineering MaterialsKey Engineering Materials Vol. 910Features of the Microstructural Composition of...

Features of the Microstructural Composition of Low-Alloyed Aluminum Alloys of the 6XXX Series with Small Additions of Zr and Sc

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Abstract:

The study investigates the effect of Zr and Sc on the dendritic structure and phase composition during casting of a silicon rich Al0.3Mg1.0Si alloy. Optical microscopy, computations using Thermo-Calc software and electron microscopy were applied. It showed that scandium and zirconium additions facilitate dendritic structure refinement, however, the maximum effect is achieved by their combined addition. Computations demonstrated the occurance of three main phases in case of Sc (without zirconium) addition to Al0.3Mg1.0Si alloy: i) the strengthening Mg₂Si phase, ii) the harmful ScSi phase and iii) free silicon. In case of only Zr addition, the same phases are observed, except for ScSi replaced with Zr₂Si, which has not been studied in Al-Mg-Si alloys. Computations predict the occurance of all three phases in the case of the combined Sc and Zr addition, besides, strengthening Al₃(ScZr) can be expected. Electron microscopy shows, that all alloys contain Mg₂Si phases as well as Al₁₂Fe₃Si and Al₉Fe₂Si₂ type phases, formed due to the iron impurity. The main Zr and Sc fractions occur in solid solution, thus, a quenching rate of 1 oС/s is sufficient to achieve a self-hardening effect.

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Periodical:

Key Engineering Materials (Volume 910)

Pages:

994-1001

DOI:

https://doi.org/10.4028/p-r1o05m

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Online since:

February 2022

Authors:

Evgeniy V. Aryshenskii*, Sergey Konovalov, Viacheslav Bazhenov, Jurgen Hirsch

Keywords:

Aluminum, Grain Refinement, Microstructure, Phases Composition, Sc Alloying, Zr Alloying

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© 2022 Trans Tech Publications Ltd. All Rights Reserved

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