Radial Distribution Characteristics of Microstructure and Mechanical Properties of Ti-6Al-4V Butt Joint by Rotary Friction Welding

doi:10.1007/s40195-015-0325-6

Abstract

Abstract:

Ti-6Al-4V rods were butt-welded by rotary friction welding in this study. Additionally, the radial differences in microstructure and mechanical property of joints were investigated by hierarchy slicing method. The results displayed that the width of weld zone and heat-affected zone of joints became wider along radial direction. Meanwhile, the tensile strength of joints decreased gradually along the radial direction. According to the theoretical analysis, the temperature gradient and inhomogeneous forging pressure leaded to the radial differences. Through K-type thermocouples, the actual temperatures at different locations were measured, and the results were consistent with the theoretical analysis. Theoretically, the radial differences of rotary friction welding joint are an inherent phenomenon; thus, the size of weldment should be limited strictly below the corresponding critical size. In order to prevent radial differences from enlarging, the welding surface profile of weldment can be processed into oval shape, and a larger forging pressure can be used within the scope of the joint deformation allowed according to causes for radial differences.

Key words: Titanium alloys, Friction welding, Microstructure, Mechanical property

Hai-Yan Chen, Li Fu, Wen-Yuan Zhang, Fen-Jun Liu. Radial Distribution Characteristics of Microstructure and Mechanical Properties of Ti-6Al-4V Butt Joint by Rotary Friction Welding[J]. Acta Metallurgica Sinica (English Letters), 2015, 28(10): 1291-1298.

Figures/Tables 10

Table 1 Welding process parameters for rotary friction welding

Sample	Rotational speed (r/min)	Friction time (s)	Friction pressure (MPa)	Forging pressure (MPa)	Forging time (s)
R1	2500	2	28	92	2
R2	2500	4	28	92	2
R3	2500	6	28	92	2
F1	1500	4	46	92	2
F2	2000	4	46	92	2
F3	2500	4	46	92	2

Fig. 1 Schematic diagrams of slicing positions a and dimensions of tensile specimens (unit: mm) b

Fig. 2 Locations of thermocouples A, B, C, D in fixed side (unit: mm)

Fig. 3 Optical images of joints welded under different welding parameters: a sample R1, b sample R2, c sample R3, d sample F1, e sample F2, f sample F3

Fig. 4 Optical micrographs at different positions of joint R2: a overall weld at the center of joint, b weld zone at the center of joint, c heat-affected zone at the center of joint, d overall weld at the middle of joint, e weld zone at the middle of joint, f heat-affected zone at the middle of joint, g overall weld at the edge of joint, h weld zone at the edge of joint, i heat-affected zone at the edge of joint

Fig. 5 Tensile strengths of the slices of joints welded under the different friction time a, the different rotational speeds b, and the different friction pressures c

Fig. 6 Macro-characterization of slices of joint welded with process parameters R2 after tensile tests

Fig. 7 Stress-strain curves of the slices of joints welded under different process parameters: a sample R2, b sample F3

Fig. 8 Temperature-time curves of different measured positions during the friction welding: a sample R1, b sample R2, c sample R3

Fig. 9 SEM images of the fracture of joint R2: a center, b middle, c edge

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