Effects of Groove Shape on Microstructure and Mechanical Responses of Laser-Directed Energy Deposition-Repaired GH4099 Ni-Based Superalloy

doi:10.1007/s40195-025-01837-x

Abstract

Abstract:

Repairing the Ni-based superalloy component remains challenging due to the limited understanding of the role of the defect’s morphology on microstructure and related deformation responses. To address this issue, GH4099 Ni-based superalloy plate with U-shaped and V-shaped grooves was prepared and repaired by laser-directed energy deposition method using GH4099 powders. Both grooves exhibit three similar regions at the repaired interphase, which are the base metal region with equiaxed grains, repaired region with columnar or elongated equiaxed grains, and a transition region in between. High-temperature gradient in the repaired region induced a high density of substructures, and the repaired region in U-shaped grooves has an even higher temperature gradient due to fewer passes of the melted metal, which induces more metallic carbides in the subgrain boundaries and improves the tensile strength of the repaired samples. However, due to the steep side walls, local vortex might form at the bottom corner of the U-shaped groove, leaving macroscale holes and micro-cracks there. Such defects will decrease the alloy’s ductility. The relationship among groove morphology-macro- and microstructure-mechanical properties is then established, which suggesting the preferred V-shaped groove considering the flatter sidewall and more passes induced near equilibrium microstructure.

Key words: Laser-directed energy deposition, Components’ repairing, Ni-based superalloy, Groove morphology, Microstructure, Mechanical properties

Wei Pan, Bin Xu, Chong Li. Effects of Groove Shape on Microstructure and Mechanical Responses of Laser-Directed Energy Deposition-Repaired GH4099 Ni-Based Superalloy[J]. Acta Metallurgica Sinica (English Letters), 2025, 38(6): 1003-1011.

Figures/Tables 11

Table 1 Composition of the GH4099 Ni-based superalloy powders by ICP-AES (wt%)

Ni	Cr	Co	Mo	Ti	Al	W
Bal.	18.24	6.39	4.26	1.21	1.99	5.96

Fig. 1 a Schematic of the GH4099 base metal with U-shaped, V-shaped grooves, and tensile sample position after repairing; images of repaired GH4099 base metal with b U-shaped, c V-shaped grooves, and d tensile samples

Fig. 2 OM images from the cross-section overview of a U-shaped and b V-shaped grooves after repaired by LDED

Fig. 3 SEM images from the cross-section of the U-shaped groove at a repaired region/base metal interphase and b repaired region

Fig. 4 SEM-EBSD: a inverse pole figure and b image quality maps with grain boundaries from the cross-section of the U-shaped groove

Fig. 5 SEM images from the cross-section of the V-shaped groove at a repaired region/base metal interphase and b repaired region

Fig. 6 SEM-EBSD: a inverse pole figure and b image quality maps with grain boundaries from the cross-section of the V-shaped groove

Fig. 7 a Engineering stress-strain curves of the U-shaped and V-shaped groove samples subtracted from the repaired region/base metal interfaces; the curves of base metal and pure printed alloy were also added. OM images at the horizontal plane of the fractured samples with b U-shaped and c V-shaped grooves

Fig. 8 SEM images from the cross-section of the U-shaped groove at repaired region/base metal interphase showing a interface crack and b intergranular crack in the base metal/base metal, c magnified SEM image in the repaired region showing metallic carbides and interdendritic features

Fig. 9 Magnified SEM image from the cross-section of the V-shaped groove at the repaired region showing metallic carbides and interdendritic features

Fig. 10 Schematic of fluid flow field in the molten pool during LDED repairing process of both U-shaped and V-shaped grooves

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