Heterogeneous Deformation Behaviors of an Inertia Friction Welded Ti2AlNb Joint: an In-situ Study

doi:10.1007/s40195-022-01477-5

Abstract

Abstract:

A defect-free Ti₂AlNb joint has been obtained by the inertia friction welding (IFW) technology. The weld zone (WZ) is composed of B2 grains refined by discontinuous dynamic recrystallization and enhanced by grain refinement strengthening. And the average microhardness decreases by about 30 HV from the WZ to the base metal. In-situ SEM analysis reveals that the heterogeneous structure of the joint causes strong strain partitioning during tensile deformation. The microcrack initiation occurs at the interface of the initial B2 phases and B2/O boundaries. Owing to stress concentration, the multi-slip bands and cracks tend to generate in the heat-affected zone (HAZ), causing a premature fracture.

Key words: Ti₂AlNb alloy, Inertia friction welding, Microstructure, Deformation behaviors

Dingcong Cui, Qingfeng Wu, Feng Jin, Chenbo Xu, Mingxin Wang, Zhijun Wang, Junjie Li, Feng He, Jinglong Li, Jincheng Wang. Heterogeneous Deformation Behaviors of an Inertia Friction Welded Ti₂AlNb Joint: an In-situ Study[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(4): 611-622.

Figures/Tables 12

Table 1 Nominal chemical composition of Ti2AlNb alloy (wt%)

Ti	Al	Nb	O	N	H
Bal.	10.42	39.59	0.056	0.006	0.002

Fig. 1 a Standard tensile sample, b in-situ tensile sample for 2D digital image correlation (2D-DIC) analysis

Fig. 2 a, b Microstructure of the base metal; c vertical section of the Ti-Al-Nb phase diagram at 21 at.% Al, calculated by Pandat; d XRD pattern of the base metal

Fig. 3 BSE micrographs of the joint under typical welding conditions for a WZ, b TMAZ, c HAZ

Fig. 4 a EBSD IPF map of the weld zone, b misorientation distribution and the low-/high-angle grain boundaries of the WZ, c sub-grain boundary and dislocation arrays in the WZ

Fig. 5 EBSD maps of the thermo-mechanically affected zone (TAMZ): a1 IPF map, a2 complete recrystallized and substructured grain distribution, a3 grain boundary distribution. Bright-field TEM images of b O phase, c B2 and O phases. d The corresponding SAED patterns in c

Fig. 6 Bright-field TEM morphology of the HAZ: a lamellar O phases and SAED patterns showing the orientation relationship of O-B2, b HRTEM morphologies of specific regions of a, c, d the corresponding FFT patterns of specific regions of b revealing the O phase precipitated from the B2 phase. EBSD phase maps of e BM, f HAZ

Fig. 7 Interfacial Vickers hardness distribution across the joint

Fig. 8 In-situ SEM images of the microstructure evolution in the HAZ, TMAZ and WZ a. a1-a3 HAZ, TMAZ and WZ under strain ~ 3%, b1-b3 HAZ, TMAZ and WZ under strain ~ 6%, c1-c3 HAZ, TMAZ and WZ under strain ~ 8%

Fig. 9 a Micro-strain distribution map of the base metal, b the axial micro-strain distribution of a along the tensile direction, c the micro-strain distribution of the joint, d the axial micro-strain distribution of c along the tensile direction

Fig. 10 Results of in-situ SEM analysis. a-c Deformed zones from the HAZ to the WZ with emerging slip bands: a strain ~ 3%, b strain ~ 6%, c strain ~ 8%. d Crack initiation in the grain boundary, e crack propagation and intergranular crack in the HAZ. f Multi-slip bands in the HAZ close to the TMAZ

Fig. 11 Microstructure of fracture regions at a low magnification, b high magnification. SEM micrographs of the fracture surface of the joints at c low magnification, d high magnification

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Heterogeneous Deformation Behaviors of an Inertia Friction Welded Ti₂AlNb Joint: an In-situ Study

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