Effect of the Ni coating thickness on laser welding-brazing of Mg/steel

Dissimilar AZ31B-Mg and Ni-coated Q235A-steel alloys were joined in a lap configuration using a laser welding-brazing process. The effects of the Ni coating thickness on the joint appearance, interfacial reactions and mechanical properties were investigated with the assistance of thermodynamic calcu...

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Bibliographic Details
Published in:Journal of alloys and compounds 2018-11, Vol.769, p.1042-1058
Main Authors: Zhao, Xiaoye, Tan, Caiwang, Xiao, Liyuan, Xia, Hongbo, Chen, Bo, Song, Xiaoguo, Li, Liqun, Feng, Jicai
Format: Article
Language:English
Subjects:
Alloy steels
Aluminum
Base metal
Brazing alloys
Chemical potential
Coating effects
Diffusion
Dissimilar metals
Interface reactions
Killed steels
Laser beam welding
Laser welding-brazing
Magnesium base alloys
Mechanical properties
Microstructure
Ni coating thickness
Nickel coatings
Nickel manganese alloys
Organic chemistry
Reaction products
Solid solutions
Steel alloys
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Summary:Dissimilar AZ31B-Mg and Ni-coated Q235A-steel alloys were joined in a lap configuration using a laser welding-brazing process. The effects of the Ni coating thickness on the joint appearance, interfacial reactions and mechanical properties were investigated with the assistance of thermodynamic calculations. In the direct irradiation region, Ni atoms diffused and were accumulated near the interface due to the driving force of the chemical potential. Al atoms from the filler were attracted by the concentrated Ni atoms, which resulted in the formation of the FeAl phase. In the middle region and weld toe region, a Fe(Ni) solid solution formed at the interface. Heterogeneous reaction products were produced at the seam near the interface, varying from only the AlNi phase to the AlNi+(α-Mg+Mg2Ni) eutectic with the increase of the coating thickness. Additionally, a bulky Mg2Ni phase also formed in the matrix of Mg-Ni eutectic with a coating thickness of 40 μm. Strong mutual attraction occurred between the Al and Ni atoms at the seam, resulting in a higher driving force for generating the AlNi phase than for generating the Mg-Ni phase. All joints were finally fractured at the seam. The maximum value of the tensile-shear fracture load approached 230 N/mm with a Ni coating thickness of 20 μm, reaching an 88.5% joint efficiency relative to the Mg base metal. •Join Mg and varied-thickness-Ni-coated steel using laser welding-brazing process.•Ni coating significantly influenced the interfacial reaction products.•Thermodynamics calculation explained the interfacial evolution behavior.•The optimum fracture load was obtained with appropriate thickness of Ni coating.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2018.08.080