Microstructure Evolution and Recrystallization Behavior of Friction Stir Welded Thick Al-Mg-Zn-Cu alloys: Influence of Pin Centerline Deviation

doi:10.1007/s40195-021-01307-0

Abstract

Abstract:

Four tools with different pin centerline deviations were fabricated to friction stir weld (FSW) thick plates of Al-Mg-Zn-Cu alloys. The results show that, compared with the pin without pin centerline deviation, the applying of pin centerline deviation is favorable to improve the flowability of plastic material, enlarging the size of nugget zone, refining the grains and reprecipitated phase particles, enhancing the degrees of dynamic recrystallization and quantity of high angle grain boundaries owing to higher temperature and bigger eccentric force, resulting in the increase of strain hardening. Especially for the used pin with a centerline deviation of 0.2 mm, the highest average hardness and best metallurgical properties of thick FSW joints are produced, and which are consistent with the microstructure evolution and recrystallization behavior. Moreover, the fracture mode of the joints produced by the pins with centerline deviation from 0 mm to 0.3 mm changes gradually from a brittle fracture in the nugget zone (NZ) to a ductile failure in the HAZ.

Key words: Thick Al-Mg-Zn-Cu alloys, Friction stir welding, Pin centerline deviation, Microstructure evolution, Recrystallization behavior

Yu-Qing Mao, Ping Yang, Li-Ming Ke, Yang Xu, Yu-Hua Chen. Microstructure Evolution and Recrystallization Behavior of Friction Stir Welded Thick Al-Mg-Zn-Cu alloys: Influence of Pin Centerline Deviation[J]. Acta Metallurgica Sinica (English Letters), 2022, 35(5): 745-756.

Figures/Tables 15

Table 1 Chemical compositions (wt%) of 7075 aluminum alloy

Mg	Zn	Cu	Fe	Si	Mn	Cr	Ti	Al
2.9	6.23	1.7	0.45	0.35	0.2	0.21	0.17	Bal.

Fig. 1 a Schematic diagram of pin centerline deviation, b dimensions of the tensile specimen, c EBSD micrograph of microstructure of AA7075 base material, d original coarse secondary phase particles, e dislocation distribution

Fig. 2 Arranged position of blind hole for measuring temperature during FSW

Fig. 3 Cross sections of the joints produced by different pins with centerline deviations of a 0, b 0.1, c 0.2, d 0.3

Fig. 4 Moving paths of different pins during FSW process

Fig. 5 a Thermal cycles curves during FSW, b peak temperature of the NZs

Fig. 6 Models of action force in the NZs during FSW: a without, b with pin centerline deviation

Fig. 7 Grain sizes in the NZs produced by different pins with a 0 mm, b 0.1 mm, c 0.2 mm, d 0.3 mm centerline deviation

Fig. 8 Distribution of secondary phase particles in the NZs produced by different pins with a, e 0 mm, b, f 0.1 mm, c, g 0.2 mm, d, h 0.3 mm centerline deviation

Fig. 9 Distribution of dynamic recrystallization in the NZs obtained by different pins with a 0 mm, b 0.1 mm, c 0.2 mm, d 0.3 mm centerline deviation and e statistical results of different grains

Fig. 10 Misorientation angle distribution in the NZs produced by different pins with a 0 mm, b 0.1 mm, c 0.2 mm, d 0.3 mm centerline deviation

Fig. 11 a Microhardness, b tensile properties of the joints made by pins with different centerline deviations

Table 2 Metallurgical properties of AA7075 base material and FSW joins

Tested specimens	Average microhardness (HV)	Ultimate tensile strength (MPa)	Yield strength (MPa)	Elongation (%)
Base material (AA7075-O)	68	230	105	17.9
0 mm pin centerline deviation	99	194	60	7.8
0.1 mm pin centerline deviation	102	205	75	9.9
0.2 mm pin centerline deviation	115	245	125	14.1
0.3 mm pin centerline deviation	105	212	95	8.6

Fig. 12 DIC results for strain distribution of different joints produced by different pins with a 0 mm, b 0.1 mm, c 0.2 mm, d 0.3 mm centerline deviation

Fig. 13 SEM micrographs of tensile fracture surfaces of the joints produced by different pins with a-c 0 mm, d-f 0.2 mm centerline deviation

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