Research Progress of Bobbin Tool Friction Stir Welding of Aluminum Alloys: A Review

doi:10.1007/s40195-019-00946-8

Abstract

Abstract:

Bobbin tool friction stir welding (BT-FSW) is a variant of conventional friction stir welding (FSW). It can be used to weld complex curvature structures and closed sections by adding an extra shoulder instead of a rigid backing anvil, which expands the potential application of FSW in aerospace, railway, automotive and marine industries. BT-FSW has some significant advantages over conventional FSW such as no root flaws, full weld penetration, low stiffness requirements for machines and fixtures, balanced heat input, lower distortion and thus has broad prospects for development. At present, there have been numerous research reports on BT-FSW, but its widespread use is still restricted due to various factors such as tool life, process stability, control complexity and implementation cost. In this paper, the domestic and foreign research progress of BT-FSW is reviewed from four aspects of bobbin tool design and classification, temperature field and flow field during welding, microstructure and mechanical properties of welded joints as well as industrial application, and then the possible research hotspots of BT-FSW in the future are pointed out. This paper mainly aims to help researchers have a comprehensive and in-depth understanding of BT-FSW.

Key words: Bobbin tool, Temperature field, Flow field, Microstructure, Mechanical properties, Application

Guo-Qing Wang, Yan-Hua Zhao, Ying-Ying Tang. Research Progress of Bobbin Tool Friction Stir Welding of Aluminum Alloys: A Review[J]. Acta Metallurgica Sinica (English Letters), 2020, 33(1): 13-29.

Figures/Tables 24

Fig. 1 A representative of bobbin FSW tools [13]

Fig. 2 Two kinds of fixed-gap bobbin tools [16]: a fixed bobbin; b floating bobbin

Fig. 3 Pinless floating-bobbin tool [24]

Fig. 4 a Cylindrical threaded pin and its weld cross section; b tapered pin with grooves and its weld cross section [26]

Fig. 5 Features of cylindrical pins [19]: a threaded with 3 flats pin; b threaded pin; c with grooves and 1.5 mm pitch; d with grooves and 2 mm pitch; e Left Hand and Right Hand threaded pin; f 4 flats pin

Fig. 6 Adjustable-gap bobbin tool [20]

Fig. 7 a Details of the DBT; b schematic of DBT-FSW [21]

Fig. 8 Counter-rotating bobbin tool [22]

Fig. 9 Semi-stationary shoulder bobbin tool [25]

Fig. 10 Temperature history of different feature points [32]

Fig. 11 a Temperature profile across the thickness [36]; b velocity profile in the fluid region [37]

Fig. 12 Calculated velocity field in BT-FSW: a vector map; b contour map [18]

Fig. 13 Comparison between predicted shear layer and weld microstructure [42]: a microstructure at RS; b velocity profile; c combined

Fig. 14 X-ray pictures of weld cross sections, tracer material placed horizontally in the a AS, b RS [43]

Fig. 15 a A macrograph showing a typical BT-FSW joint overlaid with the probe profile; EBSD micrographs showing the grain morphologies of b the BM; c the TMAZ on the AS; d the SZ; e the TMAZ on the RS [15]

Fig. 16 a Weld cross sections of BT-FSW joints; grain morphologies of b ellipse-shaped region c triangle-shaped region [53]

Fig. 17 a Weld cross-sectional macrograph of SSUBT-FSW; material flow and defect locations in b BT-FSW c SSUBT-FSW welds [31]

Fig. 18 a Negative optical macrographs of joints produced at different rotation speeds, after being etched by a 2% NaOH solution; b a backscattered electron micrograph showing the detail of the JLR region, without etching; c a schematic diagram showing the influence of the rotation speed on the position and morphology of the JLR. [15]

Fig. 19 Typical fracture locations of joints at different rotation speeds (rpm): a 400; b 600; c, d 800; e, f 1000 [15]

Table 1 Tensile properties of BT-FSW joints of various aluminum alloys

Base materials (BM)	Thickness (mm)	Ultimate strength (MPa)		Joint efficiency = Joint/BM (%)	Elongation (%)	References
Base materials (BM)	Thickness (mm)	BM	Joint	Joint efficiency = Joint/BM (%)	Elongation (%)	References
2A14-T6	6	460	345	75	5.1	[53]
2219-T4	6	420	295	77	10.2	[56]
2219-T87	4	459	331	77	7.1	[59]
2024-T3	4	469	375	80	3.58	[60]
6082-T6	4	290	198	68.3	16	[19]
6061-T6	4	284	187	66	10.3	[51]
6056-T78	4	322	257	80	1.1	[57]
6061-T651	8	290	243	83.7	9.2	[61]
6061-T6	4	284	196	69	11.1	[62]

Fig. 20 Hardness distributions of the BT-FSW joints at different welding speeds (mm/min) [53]: a 50; b 100; c 150

Fig. 21 Robotic Weld Tool used for welding of Constellation Ares I Propellant Tanks [66]

Fig. 22 LC-FSW machine and welded panel [68]

Fig. 23 a “Fuxing” high-speed train; b its flat roof produced using BT-FSW [70]

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