A Novel Friction Stir Spot Riveting of Al/Cu Dissimilar Materials

doi:10.1007/s40195-020-01092-2

Abstract

Abstract:

In order to eliminate the disadvantages of the keyhole in conventional friction stir spot welding joint and attain the high-strength lap joint of Al/Cu dissimilar metals, a novel welding technique, named as friction stir spot riveting (FSSR), was proposed. A pinless tool and an extra filling stud were employed. The Al/Cu spot joints without keyhole defect were achieved by the FSSR. A Cu anchor-like structure was formed, which greatly increased the mechanical interlocking between the upper Al sheet and lower Cu sheet. The thin intermetallic compounds containing CuAl₂ and CuAl at the Al/Cu interface strengthened the joining interface between the Al sheet and the Cu stud. Increasing rotating velocity increased frictional heat and plastic deformation and then eliminated the interfacial joining defects. The FSSR joint with the maximum tensile shear load of 3.50 kN was achieved at a rotating velocity of 1800 rpm and a dwell time of 20 s, whose fracture path passed through the softened region of upper Al sheet. In summary, the novel FSSR technique has the advantages of strong mechanical interlocking and metallurgical bonding between dissimilar materials, thereby attaining the high-strength spot joint.

Key words: Al/Cu dissimilar materials, Friction stir spot riveting, Intermetallic compounds, Microstructures, Tensile shear strength

Jinglin Liu, Qi Song, Lihui Song, Shude Ji, Mingshen Li, Zhen Jia, Kang Yang. A Novel Friction Stir Spot Riveting of Al/Cu Dissimilar Materials[J]. Acta Metallurgica Sinica (English Letters), 2021, 34(1): 135-144.

Figures/Tables 11

Fig. 1 Schematic of FSSR process: a plunging stage, b dwelling stage, c retracting stage

Fig. 2 Surface formations of FSSR joints at different rotating velocities: a 600 rpm, b 1200 rpm, c 1800 rpm

Fig. 3 Partial microstructures in cross sections of FSSR joints under different rotating velocities: a 600 rpm, b 1200 rpm, c 1800 rpm

Fig. 4 SEM images of regions near interfaces marked in Fig. 3: a region A, b region B, c region C, d lap interface under rotating velocity of 2000 rpm and dwelling time of 40 s

Fig. 5 Al/Cu interface of region D marked in Fig. 3: a SEM image, b schematic diagram; EDS results of c Point 1, d Point 2 marked in b

Fig. 6 SEM images and EDS results: a, b region E marked in Fig. 3e, c region F marked in Fig. 3f

Fig. 7 EDS analysis of regions G and H marked in Fig. 3: a SEM image, b line scanning results at 1200 rpm; c SEM image, d line scanning results at 1800 rpm; e SEM image; f EDS results of IMCs layers at 2000 rpm and 40 s

Fig. 8 Tensile shear strengths of FSSR joints under different rotating velocities and dwelling time

Fig. 9 Fractured joints after tensile test at different rotating velocities: a 600 rpm, b 1800 rpm

Fig. 10 Schematics of fracture paths of FSSR joints at different welding parameters: b 600 rpm and 20 s; c 1800 rpm and 20 s; d 2000 rpm and 40 s

Fig. 11 Fracture surface morphologies of 1800 rpm at different positions: a to d regions a to d in Fig. 9b

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