Non-keyhole Friction Stir Welding for 6061-T6 Aluminum Alloy

doi:10.1007/s40195-021-01289-z

Abstract

Abstract:

A novel non-keyhole friction stir welding technique was proposed to weld the butt joint of 6061-T6 aluminum alloy with the thickness of 6 mm. A sound joint was obtained by this technique, simultaneously eliminating the flash, shoulder mark and keyhole defects. The sleeve directly affected zone (SDAZ) and the sleeve indirectly affected zone (SIAZ) were divided into the joint according to the plunging position of the hollow sleeve. The lack of root penetration defect was avoided when the plunging depth of the hollow sleeve was only 4.2 mm, because the hollow part inside the sleeve improved the material flow below the sleeve. An S-shaped line was left at the SIAZ, and the height of it had the minimum value of 1.47 mm at 20 mm/min. Whether the failure location of the joint was in SIAZ/SDAZ or the heat-affected zone (HAZ) depended on the height and bonding strength of the S-shaped line. The joint fracture location changed from the SIAZ/SDAZ at 35 mm/min to the HAZ at 20 and 30 mm/min. The maximum tensile strength of 224.3 MPa was obtained at 30 mm/min which was 73.7% of that of the base material. The fracture surface morphology exhibited the typical ductile fracture.

Key words: Non-keyhole friction stir welding, Welding tool simplification, Microstructures, Material flow, Mechanical properties

Peng Gong, Ying-Ying Zuo, Shu-De Ji, De-Jun Yan, Deng-Chang Li, Zhen Shang. Non-keyhole Friction Stir Welding for 6061-T6 Aluminum Alloy[J]. Acta Metallurgica Sinica (English Letters), 2022, 35(5): 763-772.

Figures/Tables 12

Fig. 1 Schematic diagram of N-KFSW process: a plunging stage, b welding stage, c refilling stage, d after welding

Fig. 2 a N-KFSW tool system, b SHT system, c welding schematic using the SHT

Fig. 3 Schematic of tensile specimens

Fig. 4 Surface morphologies at different welding velocities: a 20 mm/min, b 30 mm/min, c 35 mm/min, d 40 mm/min

Fig. 5 Cross sections at different welding velocities: a 20 mm/min, b 30 mm/min, c 35 mm/min

Fig. 6 Microstructures of typical zones: a TMAZ, b HAZ, c BM

Fig. 7 Magnified microstructures of SDAZ and SIAZ marked in Fig. 3a: a area A, b area B

Fig. 8 Schematic of material flow under the hollow sleeve

Fig. 9 Microhardness testing results at 20 mm/min

Fig. 10 Tensile strength test results

Fig. 11 Failure modes at a 20 mm/min, b 30 mm/min, c 35 mm/min

Fig.12 Fracture surface micrographs at typical areas: a middle area and b bottom area in HAZ at 20 mm/min; c SIAZ, d SDAZ at 35 mm/min

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