Microstructure and Mechanical Properties of Friction Stir Welded 1.5 GPa Martensitic High-Strength Steel Plates

doi:10.1007/s40195-021-01358-3

Abstract

Abstract:

In this study, 2.4 mm thick high-strength martensitic steel plates with a tensile strength of 1500 MPa were friction stir welded at various welding speeds of 40, 60, 80, 100, 120 mm/min and a constant rotation speed of 300 rpm. Sound joints could be obtained when the welding speed was 40, 60 and 80 mm/min, while a kissing bond was found in the joint welded at 100 and 120 mm/min. It was revealed that the peak temperature exceeded A_C3 (the end temperature at which all ferrite transformed to austenite when the steel was heated) for all the welding conditions and martensitic structures were finally formed in the stir zone of the joints. A significant decrease in hardness was located in the heat-affected zone, which had a transitional microstructure from tempered martensite near base metal to a mixed structure containing hard martensite, soft ferrite and bainite near stir zone. For the sound joints, the specimen was fractured in the heat-affected zone during tensile tests and the highest tensile strength could reach about 1058 MPa.

Key words: Martensitic steel, Friction stir welding, Heat-affected zone, Microstructure, Mechanical properties

Pengcheng Zhu, Lin Zhang, Zhaochang Li, K. H. Lo, Jianfeng Wang, Yufeng Sun, Shaokang Guan. Microstructure and Mechanical Properties of Friction Stir Welded 1.5 GPa Martensitic High-Strength Steel Plates[J]. Acta Metallurgica Sinica (English Letters), 2022, 35(7): 1079-1089.

Figures/Tables 17

Table 1 Chemical composition (wt%) of as-received martensitic HSS plates

C	S	Si	Mn	P	Cr
0.0732	0.0065	0.1759	1.452	0.0165	0.0519
Ni	Cu	Mo	Ti	Al	Fe
0.0577	0.0278	0.3612	0.0691	0.0278	Bal.

Fig. 1 Typical appearance of a FSW joints; and the rotating tool b before and c after FSW. d Schematic illustrations of specimens prepared for tensile test

Fig. 2 Cross-sectional macrostructure of the joints made at different welding speeds: a 40 mm/min; b 60 mm/min; c 80 mm/min; d 100 mm/min; e 120 mm/min

Fig. 3 OM images of the kissing bonds: a 40 mm/min; b 100 mm/min; c 120 mm/min

Fig. 4 a EBSD; b OM images of the BM

Fig. 5 SEM images of the SZ of the joints welded at welding speed of a 40 mm/min; b 80 mm/min; c 120 mm/min

Fig. 6 SEM images of a top; b middle; c bottom region of the joint SZ welded at 40 mm/min

Fig. 7 Microstructures of the HAZ of the joint welded at 40 mm/min. a AS on the HAZ; b enlarged image of square area shown in a

Fig. 8 SEM images of HAZ region of the joints at different welding speeds: a 40 mm/min, b 80 mm/min, and c 120 mm/min in HAZ1; d 40 mm/min, e 80 mm/min, and f 120 mm/min in HAZ2; g 40 mm/min, h 80 mm/min, i 120 mm/min in HAZ3. (B: Bainite, F: Ferrite and M: Martensite)

Fig. 9 Ferrite fraction in different regions of HAZ of the joints at 40 mm/min

Fig. 10 EBSD orientation color maps of SZ center and HAZ2 at different welding speeds: a 40 mm/min, b 80 mm/min, c 120 mm/min in SZ; d 40 mm/min, e 80 mm/min, f 120 mm/min in HAZ2

Fig. 11 Distribution of grain boundary misorientation angle in SZ obtained at different welding speeds of a 40 mm/min; b 80 mm/min; c 120 mm/min

Fig. 12 TEM images of a BM; b-d SZ; e,f HAZ of the sample prepared at 40 mm/min

Fig. 13 Micro-hardness distribution at the mid-thickness of the cross section of the welds at different welding speeds

Fig. 14 a Engineering strain-stress curves of the global tensile specimens; and cross-sectional OM images of fractured specimens welded at b 40 mm/min; c 60 mm/min; d 80 mm/min; e 100 mm/min; f 120 mm/min

Table 2 Tensile results with different welding speeds

Welding speed (mm/min)	Yield strength, YS (MPa)	Ultimate tensile strength, UTS (MPa)	Elongation to fracture (%)
BM	1445	1550	14.7
40	465	1016	10.6
60	565	1036	13.2
80	640	1058	14.2
100	554	1031	8.2
120	601	794	9.7

Fig. 15 SEM micrographs showing the fracture morphology of the tensile specimen: a, d 40 mm/min; b, e 80 mm/min; c, f 120 mm/min

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