A New Technology to Improve the Elongation of A356 Alloy

Yi Jie Zhang; Nai Heng Ma; Xian Feng Li; Hao Wei Wang

doi:10.4028/www.scientific.net/SSP.217-218.450

Paper Titles

Using Semi-Solid Extrusion for the Production of Aluminum-Nanocomposite Master Alloys
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Comparison between Prediction of Liquid Fraction versus Temperature and Experimental Results from DSC and SPSC
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A New Technology to Improve the Elongation of A356 Alloy
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HomeSolid State PhenomenaSolid State Phenomena Vols. 217-218A New Technology to Improve the Elongation of A356...

A New Technology to Improve the Elongation of A356 Alloy

Abstract:

A356 alloy was widely used in automobile industry due to its excellent castability and comprehensive mechanical properties. But, with increasing demands of strictly safety of components, fatigue life of A356 alloy became the key properties which were considered seriously. To evaluate the time-consuming properties, elongation, as a replaced property, was employed for its easy testing and the relationship which was proportional to the fatigue life of materials. Semi-solid processing was proved that it can improve the elongation of materials while the mechanical properties still kept at the same level as original alloy. Presently, many semi-solid techniques were developed to produce various products, in which the additional equipment was necessary to form the semi-solid microstructure. Therefore, this work is aimed to development an easily technique to obtain the semi-solid microstructure. In present study, A356 alloy with typical semi-solid microstructure was obtained by addition of RE elements during melt processing. In addition, the melting and pouring process was kept the same as the normal gravity casting of A356 alloy. After the treatment, the elongation was 19.5% for A356 alloy with RE addition, which was much higher than that of 13% for normal A356 alloy. Microstructure observation showed that the morphology of Si was changed significantly, and the shape of spheroid was dominantly appeared other than short rod shape. The improvement of elongation was attributed to the morphology change of α-Al and eutectic Si.

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Semi-Solid Processing of Alloys and Composites XIII

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Periodical:

Solid State Phenomena (Volumes 217-218)

Pages:

450-454

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.217-218.450

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Online since:

September 2014

Authors:

Yi Jie Zhang*, Nai Heng Ma, Xian Feng Li, Hao Wei Wang

Keywords:

A356 Aluminum Alloy, Elongation, Gravity Casting, Rare Earth, Semi-Solid Microstructure

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