Enhanced Fatigue Properties of 2219 Al Alloy Joints via Bobbin Tool Friction Stir Welding

doi:10.1007/s40195-022-01465-9

Abstract

Abstract:

In the present study, 2219-T87 Al alloy plates, 4 mm in thickness, were subjected to bobbin tool friction stir welding (BT-FSW) under relatively high welding speeds of 200 and 400 mm/min, with the aim to analyze the effect of welding speeds on fatigue properties of the joints. The results showed that the tension-tension high-cycle fatigue performance of the BT-FSW joints at room temperature was significantly enhanced compared to that of other joints of 2xxx series Al alloys counterparts. Particularly at a high welding speed of 400 mm/min, the fatigue strength of the joint reached 78% of the base material together with a high tensile strength of 311 MPa. It was found that the joint line remnants had no effects on the fatigue properties of the BT-FSW joints due to the elimination of root flaws under the action of the lower shoulder. Most of the samples with the welding speed of 200 mm/min failed at the thermo-mechanical zone (TMAZ) during fatigue tests, attributable to the coarsened grains and precipitates, but all of the samples with high welding speed of 400 mm/min randomly failed at the nugget zone due to the improved hardness value in the TMAZ.

Key words: 2219 Al alloys, Bobbin tool friction stir welding, Microstructure, Fatigue properties

Zhenlin Wang, Beibei Wang, Zhen Zhang, Peng Xue, Yunfei Hao, Yanhua Zhao, Dingrui Ni, Guoqing Wang, Zongyi Ma. Enhanced Fatigue Properties of 2219 Al Alloy Joints via Bobbin Tool Friction Stir Welding[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(4): 586-596.

Figures/Tables 16

Fig. 1 Schematic illustration of BT-FSW and the sample locations for fatigue tests

Table 1 Chemical composition of 2219-T87 Al alloy

Material	Chemical composition (wt%)
	Cu	Mn	Fe	Zr	Si	Ti	Zn	Mg	Al
2219-T87 Al	6.36	0.30	0.15	0.12	0.05	0.05	0.02	< 0.02	Bal.

Fig. 2 Schematic illustrations of the sample locations for EBSD and TEM observations

Fig. 3 Cross-sectional morphologies of BT-FSW 2219-T87 Al alloy joints under welding speeds of a 200 mm/min, b 400 mm/min

Fig. 4 Microstructures of the BT-FSW joints of 300-200 sample: a NZ, b TMAZ, c HAZ; 300-400 sample: d NZ, e TMAZ, f HAZ

Fig. 5 Precipitate distribution of a BM and sample 300-200: b NZ, and c TMAZ

Fig. 6 a Microhardness distribution of transverse cross section along the center lines of BT-FSW joints and 2D hardness contour map under welding speeds of b 200 mm/min, c 400 mm/min

Table 2 Tensile properties of BM and BT-FSW joints

Sample	YS (MPa)	UTS (MPa)	El (%)
BM	357 ± 4	447 ± 4	10.7 ± 1.2
300-200	237 ± 1	301 ± 7	5.1 ± 0.9
300-400	240 ± 1	311 ± 2	7.0 ± 0.2

Fig. 7 Tensile fracture locations of BT-FSW joints under welding speeds of a 200 mm/min, b 400 mm/min

Fig. 8 Log-log form stress-fatigue life (S-N) curves for BM and BT-FSW joints

Table 3 Fatigue properties of BM and BT-FSW joints

Sample	Fatigue strength (MPa)	Fatigue ratio	\({\sigma }_{f}^{^{\prime}}\)(MPa)	\(b\) value
BM	140	0.313	1760	− 0.154
300-200	110	0.365	1752	− 0.176
300-400	110	0.354	1396	− 0.156

Fig. 9 Fatigue strength and tensile strength of various 2xxx series Al alloy joints [2,50,52,53]

Fig. 10 Cross section fracture morphologies of BT-FSW joints under different maximum stress: a 300-200-120 MPa, b 300-200-240 MPa, c 300-400-120 MPa, d 300-400-240 Mpa

Fig. 11 Fracture surface morphologies of BM at a maximum stress of 200 MPa: a low magnification overview, b crack initiation zone, c crack propagation zone, d final fracture zone

Fig. 12 Fracture surface morphology of sample 300-200 at a maximum stress of 120 MPa: a low magnification overview, b crack initiation zone, c crack propagation zone, d final fracture zone

Fig. 13 Fracture surface morphology of sample 300-400 at a maximum stress of 120 MPa: a low magnification overview, b crack initiation zone, c crack propagation zone, d final fracture zone

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