Improving Joint Features and Mechanical Properties of Pinless Fiction Stir Welding of Alcald 2A12-T4 Aluminum Alloy

doi:10.1016/j.jmst.2016.07.003

Abstract

Abstract:

As a new solid state welding, pinless friction stir welding (PFSW) can be used to join thin-wall structures. In this study, four new pinless tools with different groove distributions were designed and manufactured in order to enrich technological storage of PFSW and obtain sound joint with high quality of alclad 2A12-T4 alloy. The results show that the small-obliquity tool is detrimental to the transfer of plasticized materials, resulting in the formation of kissing bond defect. For the through-groove tool or the large-curvature tool, bigger flashes form on the joint surface and alclad layer is observed in the nugget zone (NZ), deteriorating mechanical properties. Compared with the above-mentioned three tools, using the six-groove tool with rational curvature and obliquity can not only yield sound joint with small flashes and thickness reduction, but also prevent alclad from flowing into NZ, which has potential to weld thin alclad aluminum alloys. Meanwhile, the tensile strength and elongation of joint using the six-groove tool reach the maximum values of 362 MPa and 8.3%, up to 85.1% and 64% of BM.

Key words: Pinless friction stir welding, Groove distribution, 2A12-T4 aluminum alloy, Macrostructures, Mechanical property

Liu Zhenlei,Cui Hutao,Ji Shude,Xu Minqiang,Meng Xiangchen. Improving Joint Features and Mechanical Properties of Pinless Fiction Stir Welding of Alcald 2A12-T4 Aluminum Alloy[J]. J. Mater. Sci. Technol., 2016, 32(12): 1372-1377.

Figures/Tables 9

Fig. 1. Four kinds of pinless tools used in this experiment: (a) the six-groove tool, (b) the large-curvature tool, (c) the small-obliquity tool, (d) the through-groove tool.

Fig. 2. Surface formation of joints using different pinless tools: (a) the six-groove tool, (b) the large-curvature tool, (c) the small-obliquity tool, (d) the through-groove tool.

Fig. 3. Macrostructures of joints using different pinless tools: (a) the six-groove tool, (b) the large-curvature tool, (c) the small-obliquity tool and (d) the through-groove tool.

Fig. 4. Enlarged pictures of kissing bond defect marked by red square in Fig. 3(c).

Fig. 5. Microstructures in different positions of typical joint using the six-groove tool: (a) BM, (b) HAZ, (c) interface between NZ and TMAZ on the AS, (d) interface between NZ and TMAZ on the RS and (e) NZ.

Fig. 6. Schematic of material flow of alclad layer when using the through-groove tool.

Fig. 7. Hardness distribution of joints using four kinds of pinless tools.

Fig. 8. Tensile properties of joints using four kinds of pinless tools.

Fig. 9. Fracture locations of tensile specimens by four kinds of pinless tools: (a) the six-groove tool, (b) the large-curvature tool, (c) the small-obliquity tool, (d) the through-groove tool.

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