Formation, Structure, and In Situ Cracking of Intermediate Phases in the Friction-Diffusion Double Welding Zone Between TiAl-Based Alloy and GH3039 Alloy

doi:10.11900/0412.1961.2023.00029

Acta Metall Sin

2024, Vol. 60

Issue (12): 1637-1646 DOI: 10.11900/0412.1961.2023.00029

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Formation, Structure, and In Situ Cracking of Intermediate Phases in the Friction-Diffusion Double Welding Zone Between TiAl-Based Alloy and GH3039 Alloy

DU Suigeng(

), WANG Songlin, HU Hongyi

Key Laboratory of High Performance Manufacturing for Aero Engine, Ministry of Industry and Information Technology, Northwestern Polytechnical University, Xi'an 710072, China

Cite this article:

DU Suigeng, WANG Songlin, HU Hongyi. Formation, Structure, and In Situ Cracking of Intermediate Phases in the Friction-Diffusion Double Welding Zone Between TiAl-Based Alloy and GH3039 Alloy. Acta Metall Sin, 2024, 60(12): 1637-1646.

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Abstract

During the friction welding process of TiAl turbine and shaft used in engines, brittle intermediate phases will be generated in the welding zone, which affects the joint performance. To reveal the formation rules of the intermediate phases in the friction-diffusion double welding zone between TiAl-based alloy and GH3039 alloy, and investigate the crystal structure and fracture properties of the intermediate phases, the joints at different stages of the double welding were obtained by interrupting welding during the welding process, respectively. The morphology and evolution law of the intermediate phases of these joints in the welding zones were analyzed using SEM; the crystal structures of the intermediate phases and the crack growth behaviors of Al-Ni-Ti ternary intermetallic compound phases were analyzed using TEM and an in situ nanomechanical testing system.Results showed that during friction welding and heat treatment, phase transformation and nucleation occurred on the welding interface and preliminarily grew up to form the following new intermediate phases: Ni₃(Al, Ti), (Ni, Cr)_SS, Al₃NiTi₂, AlNi₂Ti, and Ti₃Al. In the subsequent diffusion welding process, the pressure and high temperature promoted the formation of a stable two-phase zone between Ti₃Al and Al₃NiTi₂. The amplitude-modulated decomposition in the (Ni, Cr)_SS zone formed fcc (Ni)_SS and bcc (Cr)_SS that are staggered and distributed in a column. Dispersions of pure Ti with the α phase could hardly be found in the Al₃NiTi₂ and AlNi₂Ti phases, and the phase boundary between α-Ti and Al₃NiTi₂ was in an incoherent state. Furthermore, Al₃NiTi₂ and AlNi₂Ti exhibited hexagonal and bcc structures, respectively. During the in situ compression process, neither obvious plastic deformation nor dislocation movement was observed in the nucleation and propagation of cracks in the Al₃NiTi₂ phase. However, the lattice surface near the crack tip underwent microdeformation, and the ordered structure of atomic arrangements became disordered.

Key words: TiAl-based alloy friction welding diffusion welding intermetallic compound phase in-situ crack

Received: 18 January 2023

ZTFLH:

TG457.1

Fund: National Natural Science Foundation of China(51675434)

Corresponding Authors: DU Suigeng, professor, Tel: 13709212218, E-mail: fwcenter@nwpu.edu.cn

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	DU Suigeng
	WANG Songlin
	HU Hongyi

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https://www.ams.org.cn/EN/10.11900/0412.1961.2023.00029 OR https://www.ams.org.cn/EN/Y2024/V60/I12/1637

Table 1 Chemical compositions of test materials

Fig.1 Microstructures of the weld zone in different stages of the double welding of TiAl-based alloy and GH3039 alloy (SS—solid solution)
(a) friction time 3 s (b) friction time 5 s (c) friction time 8 s (d) friction time 10 s
(e) friction time 12 s + upset (friction welding) (f) friction welding + post weld heat treatment
(g) friction welding + post weld heat treatment + diffusion welding (full process of the double welding)

Fig.2 Phase diagrams of Ti, Al, and Ni alloy elements
(a) isothermal section of the ternary system Al-Ni-Ti at 700^oC^[14]
(b) Ti-Al binary phase diagram^[15] (1d-APS: (Ti₅Al₁₁, Ti₂Al₅) four sided superstructure; TiAl₃(h): D0₂₂ structure; TiAl₃(l): Ti₈Al₂₄ structure)

Fig.3 TEM image of microstructure of the friction- diffusion double welding zone (Region A in Fig.1g)

Fig.4 TEM image (a) and EDS mappings of Ti (b), Al (c), Ni (d), and Cr (e) elements of friction-diffusion double welding zone

Fig.5 Atomic projection STEM image (a) and selected area electron diffraction (SAED) pattern (b) of Al₃NiTi₂ phase in region R1 in Fig.3 (d—spacing)

Fig.6 Atomic projection STEM image (a) and SAED pattern (b) of AlNi₂Ti phase in region R2 in Fig.3

Fig.7 Bright field TEM image of region R3 in Fig.3

Fig.8 TEM microstructure characteristics of the triangular grain boundary AlNi₂Ti phase at position A in Fig.7
(a) HRTEM image (b) HRTEM image at triangular grain boundary (c) SAED pattern at triangular grain boundary
(d) Moire stripe on (01

1 ¯

) crystal plane at grain boundary at position B in Fig.8a

Fig.9 TEM image of micro phase in region R4 in Fig.3

Fig.10 SAED pattern (a) and HRTEM image (b) at phase boundary of pure Ti and Al₃NiTi₂ at position A in Fig.9

Fig.11 TEM image of the crack growth by the in situ compression (C2-1 and C2-2 show the branches of cracks C1 and C2, respectively; R2-1 and R2-2 show the tip areas of cracks C2-1 and C2-2, respectively)

Fig.12 HRTEM image of crack tip in R2-1 area in Fig.11 (a), and the fast Fourier transforms (FFT) of zone B (b) and zone C (c) near the crack tip

Fig.13 HRTEM image of crack tip in R2-2 area in Fig.11 (a), and FFT of zone B (b) and zone C (c) near the crack tip

1	Du Z H, Zhang K F, Lu Z, et al. Microstructure and mechanical properties of vacuum diffusion bonding joints for γ-TiAl based alloy [J]. Vacuum, 2018, 150: 96
2	Song Y L, Dou Z H, Zhang T A, et al. A novel continuous and controllable method for fabrication of as-cast TiAl alloy [J]. J. Alloys Compd., 2019, 789: 266
3	Song X G, Si X Q, Cao J, et al. Microstructure and joining properties of high Nb-containing TiAl alloy brazed joints [J]. Rare Met. Mater. Eng., 2018, 47: 52
4	Hauschildt K, Stark A, Schell N, et al. The transient liquid phase bonding process of a γ-TiAl alloy with brazing solders containing Fe or Ni [J]. Intermetallics, 2019, 106: 48 doi: 10.1016/j.intermet.2018.12.004
5	Niu G B, Wang D P, Yang Z W, et al. Microstructure and mechanical properties of Al₂O₃/TiAl joints brazed with B powders reinforced Ag-Cu-Ti based composite fillers [J]. Ceram. Int., 2017, 43: 439
6	Cai X L, Sun D Q, Li H M, et al. Microstructure characteristics and mechanical properties of laser-welded joint of γ-TiAl alloy with pure Ti filler metal [J]. Opt. Laser Technol., 2017, 97: 242
7	Xu X J, Lin J P, Guo J, et al. Friction weldability of a high Nb containing TiAl alloy [J]. Materials, 2019, 12: 3556
8	Dong H G, Yu L Z, Gao H M, et al. Microstructure and mechanical properties of friction welds between TiAl alloy and 40Cr steel rods [J]. Trans. Nonferr. Met. Soc. China, 2014, 24: 3126
9	Park J M, Kim K Y, Kim K K, et al. Effects of insert metal type on interfacial microstructure during dissimilar joining of TiAl alloy to SCM440 by friction welding [J]. Met. Mater. Int., 2018, 24: 626
10	Cai X, Li Q, Li H, et al. Microstructure evolution and formation mechanism of γ-TiAl/Ni-based superalloy laser-welded joint with Ti/V/Cu filler metals [J]. Mater. Lett., 2023, 333: art. no. 133647
11	Du S G, Wang S L, Ding K. A novel method of friction-diffusion welding between TiAl alloy and GH3039 high temperature alloy [J]. J. Manuf. Process., 2020, 56: 688
12	Du S G, Li N, Wang S L. Intermediate phases of TiAl/GH3039 friction welding joint [J]. Rare Met. Mater. Eng., 2021, 50: 3102
13	Du S G, Wang S L, Xu W T. Characterizing micromechanical properties of friction welding interface between TiAl alloy and GH3039 superalloy [J]. Materials, 2020, 13: 2072
14	Huneau B, Rogl P, Zeng K, et al. The ternary system Al-Ni-Ti Part I: Isothermal section at 900^oC; Experimental investigation and thermodynamic calculation [J]. Intermetallics, 1999, 7: 1337
15	Schuster J C, Palm M. Reassessment of the binary aluminum-titanium phase diagram [J]. J. Phase Equilib. Diff., 2006, 27: 255
16	He P, Feng J C, Qian Y Y, et al. Forming mechanism of interface intermetallic compounds for difusion bonding [J]. Trans. China Weld. Inst., 2001, 22(1): 53
	何鹏, 冯吉才, 钱乙余等. 扩散连接接头金属间化合物新相的形成机理 [J]. 焊接学报, 2001, 22(1): 53
17	Tan Y H, Xu H H, Du Y. Isothermal section at 927^oC of Cr-Ni-Ti system [J]. Trans. Nonferr. Met. Soc. China, 2007, 17: 711
18	Krendelsberger N, Weitzer F, Du Y, et al. Constitution of the ternary system Cr-Ni-Ti [J]. J. Alloys Compd., 2013, 575: 48
19	Gupta K P. The Cr-Ni-Ti (chromium-nickel-titanium) system-update [J]. J. Phase Equilib., 2003, 24: 86
20	Tetsui T. Effects of brazing filler on properties of brazed joints between TiAl and metallic materials [J]. Intermetallics, 2001, 9: 253
21	Li X D, Ma H T, Dai Z H, et al. First-principles study of coherent interfaces of Laves-phase MgZn₂ and stability of thin MgZn₂ layers in Mg-Zn alloys [J]. J. Alloys Compd., 2017, 696: 109
22	Fang X D, Li C S, Sun L, et al. Hardness and friction coefficient of fused silica under scratching considering elastic recovery [J]. Ceram. Int., 2020, 46: 8200
23	Song X G, Cao J, Chen H Y, et al. Brazing TiAl intermetallics using TiNi-V eutectic brazing alloy [J]. Mater. Sci. Eng., 2012, A551: 133
24	Song X G, Cao J, Liu Y Z, et al. Brazing high Nb containing TiAl alloy using TiNi-Nb eutectic braze alloy [J]. Intermetallics, 2012, 22: 136
25	Li P, Wang S, Xia Y Q, et al. Diffusion bonding of AlCoCrFeNi_2.1 eutectic high entropy alloy to TiAl alloy [J]. J. Mater. Sci. Technol., 2020, 45: 59

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[12]	PAN Chunxu(Wuhan Transportation University;Wuhan 430063); HU Lunji (Huazhong University of Science and Technology; Wuhan 430074); Z. L. LI; T H.NORTH (University of Toronto; Canada)(Manuscript received 1995-11-07; in revised form 1996-03-08). MICROSTRUCTURAL CHARACTERISTICS OF TRANSITION ZONE IN Al-BASED COMPOSITE/STAINLESS STEEL FRICTION JOINT[J]. 金属学报, 1996, 32(8): 810-816.
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