Behaviors of Oxide Film during Semisolid Brazing of SiCp/6063Al Composite Materials

The semisolid brazing of SiCp/6063Al under an applied pressure using Zn-Al-Cu filler metal was investigated. The samples to be joined were heated from 380°C to 382°C, 386°C, 392°C, and 410°C under a constant pressure of 10 MPa, respectively. Effects of the temperature on microstructural evolution an...

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Bibliographic Details
Published inAdvances in materials science and engineering Vol. 2018; no. 2018; pp. 1 - 11
Main Authors Yan, Jiuchun, Bai, Shuxin, Li, Shun, Xiao, Jing, Xiong, Degan
Format Journal Article
LanguageEnglish
Published Cairo, Egypt Hindawi Publishing Corporation 01.01.2018
Hindawi
Hindawi Limited
Subjects
Aluminum alloys
Aluminum base alloys
Bond strength
Bonded joints
Bonding strength
Brazing
Composite materials
Compressive properties
Copper
Deformation effects
Deformation mechanisms
Disruption
Filler metals
Fluid dynamics
Grains
Heating
Liquid flow
Mechanical tests
Microstructure
Oxide coatings
Particulate composites
Plastic deformation
Semisolids
Shear strength
Shear stress
Silicon carbide
Sliding
Zinc
China
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Summary:The semisolid brazing of SiCp/6063Al under an applied pressure using Zn-Al-Cu filler metal was investigated. The samples to be joined were heated from 380°C to 382°C, 386°C, 392°C, and 410°C under a constant pressure of 10 MPa, respectively. Effects of the temperature on microstructural evolution and deformation behavior of the filler metal, interfacial structure, and shear strength of the bonded joint were discussed, and the disruption behavior of the surface oxide film was studied. The results show that, after heating, the solid grains of the filler metal transform into a globular structure surrounded by liquid. The degree of sphericity and the liquid fraction tend to improve with increasing temperature. During the heating process, the deformation of the filler metal is first accomplished by plastic deformation of solid grains and then by intergrain sliding and liquid flow. The surface oxides are broken and stripped by a cocontribution of compressive and shear stress which is caused by depressing and sliding of solid grains along the composites. It is found that the heating of 380°C to 392°C under pressure is the optimum condition to disrupt the surface oxide films and obtain sound bonds. The mechanical test results show that the maximum shear strength of the bond joints is as high as 105 MPa, reaching 78% that of the parent materials.
ISSN:1687-8434
1687-8442
DOI:10.1155/2018/3246371