Pore Structure and Deformation Correlation of an Aluminum Foam Sandwich Subject to Three-Point Bending

An Al-Si matrix foam sandwich (AFS) with 6063 Al alloy cover sheets was fabricated by hot rolling combined with melt foaming. A foamable AlSiMg1/SiCp matrix precursor was prepared by the melting route. Hot rolling at 480 °C was carried out to obtain a mechanical bonding interface between the cover s...

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Published inMaterials Vol. 17; no. 3; p. 567
Main Authors Lu, Xiaotong, Jing, Lei, Zhou, Wenhao, Yang, Hui, Yuan, Pingyun, Li, Xiaocheng
Format Journal Article
LanguageEnglish
Published Switzerland MDPI AG 25.01.2024
Subjects
Aluminum alloys
Aluminum base alloys
Cooling
Deformation
Energy
Energy absorption
Failure modes
Foaming
Friction stir welding
Heat resistance
Hot pressing
Hot rolling
Mechanical properties
Metal foams
Microstructure
Morphology
Particulate composites
Pore size
Precursors
Silicon carbide
Stress-strain curves
Germany
China
melt foaming
pore structure
aluminum foam sandwich
three-bending test
hot rolling
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Summary:An Al-Si matrix foam sandwich (AFS) with 6063 Al alloy cover sheets was fabricated by hot rolling combined with melt foaming. A foamable AlSiMg1/SiCp matrix precursor was prepared by the melting route. Hot rolling at 480 °C was carried out to obtain a mechanical bonding interface between the cover sheet and the foamable precursor. Meanwhile, the pore structure of the AFS was deeply affected by the foaming temperature and foaming time during the foaming process. Different pore growth mechanics of the crack-like pore disappearance mechanism (CDM) and pore active expansion mechanism (AEM) were concluded based on the pressure difference in pores inside and outside. Three bending tests were applied to three types of AFSs with different pore structures to evaluate the relation between pore structures and AFS mechanical properties. The bending property of the AFS with fewer layers of pores is like that of a dense material. The bending property of the AFS with a pore size in the range of 0~1 mm presents a typical sandwich shear failure mode. The AFS with a uniform pore structure, in which the shapes of the pores are predominately polygons and the pore diameter is concentrated in the range of 0.5~3 mm, processes a good energy absorption capacity, and the bending stress–strain curve fluctuates greatly after the first stress drop.
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ISSN:1996-1944
1996-1944
DOI:10.3390/ma17030567