Acta Aeronautica et Astronautica Sinica ›› 2024, Vol. 45 ›› Issue (8): 429205-429205.doi: 10.7527/S1000-6893.2023.29205
• Material Engineering and Mechanical Manufacturing • Previous Articles
Junfei TENG1, Jiahao LI2, Huiyan ZHOU2, Dawei WU2, Haitao XU3, Tiesong LIN4, Yongde HUANG2(
)
CJA
Received:2023-06-20
Revised:2023-07-15
Accepted:2023-10-10
Online:2024-04-25
Published:2023-11-09
Contact:
Yongde HUANG
E-mail:huangydhm@nchu.edu.cn
Supported by:CLC Number:
Junfei TENG, Jiahao LI, Huiyan ZHOU, Dawei WU, Haitao XU, Tiesong LIN, Yongde HUANG. Effect of TLP diffusion welding process parameters on microstructure and mechanical properties of GH5188 superalloy joint[J]. Acta Aeronautica et Astronautica Sinica, 2024, 45(8): 429205-429205.
Table 1
Composition of GH5188 alloy
| 元素 | Co | Ni | Cr | W | B | Fe | C | La |
|---|---|---|---|---|---|---|---|---|
| 含量 | 其余 | 20.0~24.0 | 20.0~24.0 | 13.0~16.0 | ≤0.015 | ≤3.0 | 0.05~0.15 | 0.03~0.12 |
Fig.1
Welding specimen and graphite fixture
Fig.2
TLP bonding process curve of GH5188 alloy
Fig.3
Joint morphology of GH5188 alloy obtained by TLP diffusion welding at 1 180 ℃ for 60 min using KCo8 interlayer
Table 2
Chemical constituents corresponding to marker points in Fig. 3 (units: at%)
| 标志点 | Co | Cr | W | Ni | C | 可能相 |
|---|---|---|---|---|---|---|
| A | 13.49 | 8.02 | 26.49 | 3.25 | 33.49 | 富W的MC |
| B | 52.13 | 19.82 | 7.67 | 20.38 | Co基固溶体 | |
| C | 8.47 | 9.52 | 44.01 | 4.29 | 33.71 | 富W的M2C |
Fig.4
EPMA element analysis of joint diffusion zone I
Table 3
Chemical constituents corresponding to marker points in Fig. 4
| 标志点 | Co | Cr | W | Ni | B | 可能相 |
|---|---|---|---|---|---|---|
| A | 5.18 | 39.09 | 11.97 | 1.94 | 41.82 | 富Cr的M3B2 |
| B | 9.05 | 35.61 | 12.79 | 4.74 | 37.81 | 富Cr的M5B3 |
| C | 18.15 | 34.77 | 7.22 | 10.11 | 29.75 | 富Cr的硼化物 |
| D | 21.57 | 37.45 | 8.29 | 13.35 | 19.91 | 富Cr的M23B6 |
Fig.5
XRD composition scanning in diffusion affected zone
Fig.6
Macroscopic morphology of joint under different holding time in 1 180 ℃
Fig.7
ISZ morphology of joint and local magnification of DAZ region at 1 180 ℃ for different holding time
Table 4
Chemical constituents corresponding to marker points in Fig. 7
| 标志点 | Co | Cr | W | Ni | C | 可能相 |
|---|---|---|---|---|---|---|
| A | 24.13 | 11.27 | 47.07 | 3.84 | 13.60 | 富W的M6C |
| B | 13.80 | 8.87 | 22.85 | 2.64 | 51.83 | 富W的MC |
Fig.8
Average tensile strength of GH5188 alloy joints obtained by holding at 1 180 ℃ for different time
Fig.9
Fracture morphology of GH5188 joint at 1 180 ℃ for different holding time
Fig.10
Macro morphology of GH5188 joint weld connected by holding for 60 min at different welding temperatures
Fig.11
Morphology of ISZ zone and local magnification of DAZ zone of weld at different welding temperatures for 60 min
Table 5
Chemical constituents corresponding to marker points in Fig. 11
| 标志点 | Co | Cr | W | Ni | C | 可能相 |
|---|---|---|---|---|---|---|
| A | 13.49 | 8.02 | 26.49 | 2.09 | 49.90 | 富W的MC |
| B | 9.03 | 34.57 | 12.06 | 44.34 | 富Cr的MC |
Fig.12
Tensile strength of GH5188 alloy joints with different welding temperatures at holding time of 60 min
Fig.13
Fracture morphology of GH5188 joint at different welding temperatures for 60 min
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