High-Speed Friction Stir Welding of T6-Treated B4Cp/6061Al Composite

doi:10.1007/s40195-019-00932-0

Abstract

Abstract:

T6-treated 20 wt% B₄Cp/6061Al sheets were joined under welding speeds of 400-1200 mm/min by friction stir welding (FSW) with a threaded cermet pin. The macro-defect-free FSW joints could be achieved at high welding speeds up to 1200 mm/min, but larger plunge depth was required at the welding speeds of 800 and 1200 mm/min to eliminate the tunnel defect. In the nugget zone (NZ) of the joints, the B₄C particles were broken up and uniformly redistributed. The NZ exhibited lower hardness than the base metal (BM), and the hardness value almost did not change with increasing welding speed, attributable to the dissolution of precipitates. Compared with the BM, the joints showed lower tensile strength. As the welding speed increased from 400 to 800 mm/min, the joint efficiencies were nearly the same and up to ~?73%. When the welding speed increased up to 1200 mm/min, the tensile strength significantly decreased, due to the occurrence of kissing bond defect at the bottom of the NZ. With increasing welding speed, the fracture location of the joints transferred gradually from the heat-affected zone to the NZ due to the kissing bond defects.

Key words: Metal-matrix composites, Microstructures, Mechanical properties, Friction stir welding, High-speed welding

Y. Z. Li, Y. N. Zan, Q. Z. Wang, B. L. Xiao, Z. Y. Ma. High-Speed Friction Stir Welding of T6-Treated B₄Cp/6061Al Composite[J]. Acta Metallurgica Sinica (English Letters), 2020, 33(1): 67-74.

Figures/Tables 8

Fig. 1 Welding tools a before, b after all welding operations

Fig. 2 Surface of the FSW joints at various welding speeds and various plunge depths

Fig. 3 a Cross-sectional macrostructures of FSW joints under various welding speeds and plunge depths, b, c magnified views of joints 800-I and 1200-I

Fig. 4 Microstructures in the BM and in the NZ of FSW joints: a BM, b joint 400, c joint 800-II, d joint 1200-II, e B4Cp size and aspect ratio

Fig. 5 DSC curves of the BM and the NZs of FSW joints

Fig. 6 Transverse cross-sectional hardness profiles of FSW joints

Fig. 7 a Tensile properties, b engineering stress-strain curves of the BM and FSW joints, c the fracture locations of the joints after tensile test

Fig. 8 Fractographs of FSW joints: a BM, b joint 800-II, HAZ, c joint 800-II, NZ, d joint 1200-II, NZ. e, f are the magnified images around the holes pointed out by the white arrows in c, d, respectively

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High-Speed Friction Stir Welding of T6-Treated B₄Cp/6061Al Composite

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