Effect of Low Cu Content and Heat Treatment on the Microstructure and Mechanical Properties of High-Vacuum Die-Cast AlSiMgMn Alloys

AlSiMgMn- x Cu ( x  = 0.1wt.%, 0.3wt.%, 0.6wt.%, 0.8wt.%) alloys were produced by a high-vacuum die-casting (HVDC) process, and the effect of varying Cu contents on the microstructure evolution and mechanical properties under as-cast and T6 heat-treatment conditions have been systemically investigat...

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Bibliographic Details
Published in:JOM (1989) 2023-04, Vol.75 (4), p.1345-1356
Main Authors: Liu, Fei, Zheng, Huiting, Jiang, Yuanhang, Zhao, Haidong
Format: Article
Language:English
Subjects:
Aging
Alloys
Aluminum base alloys
Chemistry/Food Science
Copper
Corrosion resistance
Crack initiation
Die casting
Earth Sciences
Elongation
Engineering
Environment
Foundry practice
Grain boundaries
Heat treatment
Magnesium compounds
Mechanical properties
Metal silicides
Microstructure
Morphology
Phases
Physics
Silicon
Technical Article
Tensile strength
Transmission electron microscopy
Ultimate tensile strength
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Summary:AlSiMgMn- x Cu ( x  = 0.1wt.%, 0.3wt.%, 0.6wt.%, 0.8wt.%) alloys were produced by a high-vacuum die-casting (HVDC) process, and the effect of varying Cu contents on the microstructure evolution and mechanical properties under as-cast and T6 heat-treatment conditions have been systemically investigated. The results indicated that the microstructure under the as-cast state consists of α-Al, eutectic Si, β-Mg 2 Si, Q-Al 5 Cu 2 Mg 8 Si 6 , and θ-Al 2 Cu phases. Increasing the Cu content brought about an apparent change in the main precipitate of the alloys after T6 heat treatment. When the Cu content is 0.1 wt.%, the precipitate is only β′′ phase. As the Cu content increases to 0.3 wt.% and 0.6 wt.%, the β′′ and Q′ phases were co-precipitated in the α-Al matrix. As the Cu content further increases to 0.8 wt.%, the θ′ and Q′ phases were co-precipitated in the α-Al matrix and the predominant precipitate was the θ′ phase. As the content of Cu increases from 0.1 wt.% to 0.8 wt.%, the yield strength and ultimate tensile strength after T6 heat treatment increase to 241 MPa and 366 MPa, respectively. Meanwhile, the elongation increases to 8.2%. The improved mechanical properties are mainly attributed to the co-precipitation of the β′′, Q′, and θ′ phases.
ISSN:1047-4838
1543-1851
DOI:10.1007/s11837-022-05651-z