Effect of Brazing Flux Pb on Microstructure and Mechanical Property of CMT Weld-Brazed Lap Joint of 5052 Aluminum Alloy to Galvanized Q235 Steel

Hua Qing Lai; Sheng Lu

doi:10.4028/www.scientific.net/MSF.789.290

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HomeMaterials Science ForumMaterials Science Forum Vol. 789Effect of Brazing Flux Pb on Microstructure and...

Effect of Brazing Flux Pb on Microstructure and Mechanical Property of CMT Weld-Brazed Lap Joint of 5052 Aluminum Alloy to Galvanized Q235 Steel

Abstract:

5052 aluminum alloy and galvanized Q235 steel sheets with thickness of 1mm were lap welded/brazed by cold metal transfer technology (CMT) with ER4043 as the filler wire and Pb foil as the brazing flux. Scanning electron microscope (SEM), microscope with super-depth, X-ray diffraction (XRD), electronic universal tensile testing machine and hardness tester were employed to study the microstructure and mechanical properties of the joint. The results indicate that Pb foil effectively improved the mechanical properties of the joint with tensile strength up to 160Mpa which is higher than that of the joint without the brazing flux of Pb foil. Intermetallic compound (IMC) layer in the brazing joint unequally distributed in the interface of aluminum alloy and galvanized steel. The thickness of IMC layer was about 1~3.5um. The main phases of the IMC layer were FeAl and AlFe₆Si. Fine equiaxial crystals existed in the weld metal while columnar crystals existed in the fusion zone of aluminum alloy. The hardness of fusion zone was higher than base metal while the hardness of heat affected zone was lower than base metal. In most case, the lap joint was broken in the junction of base metal and fusion zone.

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Periodical:

Materials Science Forum (Volume 789)

Pages:

290-296

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.789.290

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Online since:

April 2014

Authors:

Hua Qing Lai*, Sheng Lu

Keywords:

Aluminum-Steel Welding, Brazing Flux Pb, Cold Metal Transfer, Intermetallic Compound

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References

[1] H. P. Zhang, P. F. Huang: Study status of the new arc joining of steel and aluminum, Welding&Joining Vol. 12 (2005), pp.1-3.

Google Scholar

[2] P. F. Huang, Lu Zheng yang: Low energy welding technology in bonding steel with aluminum, Journal of Mechanical Engineering Vol. 45 No. 11 (2009), 295-298.

DOI: 10.3901/jme.2009.11.295

Google Scholar

[3] H. T. Zhang, He Peng: Research status and development of welding for dissimilar materials aluminum and steel, Welding&Joining Vol. 12 (2006), pp.7-10.

Google Scholar

[4] Lei Zhen, X. Y. Wang: Analysis fo Al-Fe intermetallic compounds layer of fusion-brazed joints between aluminum and zinc coated steel by hybrid weliding, Transactions of The China Welding Institution Vol. 28 (2007), pp.1-3.

Google Scholar

[5] H.H. Zhang, J.C. Feng, P. He: Interfacial microstructure and mechanical properties of aluminium and zinc coated steel joingts made by a modified metal inert gas welding-brazing process. Materials Characterization Vol. 58(2007), 588-590.

DOI: 10.1016/j.matchar.2006.07.008

Google Scholar

[6] Yu Gang, Cao Rui: Microstructure and mechanical properties of CMT welding brazing join for dissimilar materials between aluminum and galvanized steel, China Mechanical Engineering Vol. 23 (2012), pp.1-3.

Google Scholar

[7] P. Li, D. W. Zhou: Laser lap welding of zinc-coated steel and 6061 aliuminum alloy with Pb interlayer, Transactions of The China Welding Institution Vol. 32(2011), pp.1-4.

Google Scholar

[8] Furukawa K: New CMT arc welding process-welding of steel to aluminium dissimilar meta, Welding International Vol. 20(2006), 440-445.

DOI: 10.1533/wint.2006.3598

Google Scholar

[9] F. M. Zhou, H. Song: Research on low carbon steel activating flux CMT welding, Electric Welding Machine Vol. 43(2013), 1-4.

Google Scholar

[10] J. Lin, S. M. Nin: Shear strength of CMT brazed lap joints between aluminum and zinc-coated steel, Journal of Meterials Processing Technology Vol.213(2013), pp.1-5.

DOI: 10.1016/j.jmatprotec.2013.02.011

Google Scholar

[11] Z. Q. Cui: Metallography and Heat Treatment, edited by China Machine Press, Bei jing, 1988.

Google Scholar

[12] Y. X. Zou, D. C. Sun and H. M. Chen: Theory and Process Basis of Welding, edited by Beijing University of Aeronautics and Astronautics Press, Beijing, 1992.

Google Scholar

[13] Lei Zhen, Yu Ning: Fusion brazing joining between 5A02 aluminum alloy and Q235 steel by Nd: YAG laser pulsed MIG hybrid welding, Transactions of The China Welding Institution Vol. 29(2008), pp.22-24.

DOI: 10.3901/jme.2009.03.094

Google Scholar