Microstructural Evolution of Creep-Induced Cavities and Casting Porosities for a Damaged Ni-based Superalloy Under Various Hot Isostatic Pressing Conditions

doi:10.1007/s40195-015-0241-9

Abstract

Abstract:

The microstructural evolution of casting porosities and creep-induced cavities for a damaged nickel-based superalloy under different hot isostatic pressing (HIP) conditions was investigated in order to understand the effects of HIP parameters on the healing behavior of micropores. A number of small-sized creep cavities formed during long-term service and large-sized porosities formed during the casting process were observed. These microdefects were partially healed after treated at high temperature of 1100 °C combined with 150 MPa pressure for 2 h, together with the formation of the so-called concentrically oriented γ′ rafting structure. When HIP temperature was increased to 1150 and 1175 °C, both the amount and the size of the microdefects were decreased. The concentrically oriented γ′ rafting around creep cavities became more remarkable, and the primary γ′ denuded zone was also formed between the raft structure and the cavity. Energy-dispersive X-ray spectroscopy analysis revealed that the γ matrix solute atoms diffused toward the cavity under the concentration gradient, whereas the γ′-forming elements diffused in a negative direction. When increasing HIP temperature up to 1200 °C, the micropores were hardly observed, indicating that both casting porosities and creep-induced cavities had almost been healed. Meanwhile, the γ′ rafting structure disappeared since HIP temperature was beyond the γ′ solvus temperature. It is revealed by the experimental results that the atomic diffusion could mainly dominate the healing process of micropores.

Key words: Nickel-based superalloy, Hot isostatic pressing, Creep-induced cavities, Casting porosities

Xiao-Meng Wang, Yu Zhou, Zi-Hua Zhao, Zheng Zhang. Microstructural Evolution of Creep-Induced Cavities and Casting Porosities for a Damaged Ni-based Superalloy Under Various Hot Isostatic Pressing Conditions[J]. Acta Metallurgica Sinica (English Letters), 2015, 28(5): 628-633.

Figures/Tables 7

Table 1 Hot isostatic pressing schedules for the damaged samples

Sample	HIP temperature (°C)	HIP pressure (MPa)	Soaking time (h)
No. 1	1100	150	2
No. 2	1150	150	2
No. 3	1175	150	2
No. 4	1200	150	2

Fig. 1 Microstructures of the turbine blade: a OM image of the sample before service; b OM image of the sample after long-term service; c SEM image showing the degraded γ′ precipitates around the creep cavity

Fig. 2 Microstructure evolution of the pores under different HIP conditions: a 1100 °C/150 MPa/2 h; b 1150 °C/150 MPa/2 h; c 1175 °C/150 MPa/2 h; d 1200 °C/150 MPa/2 h

Fig. 3 Correlation between the volume fraction of porosity and HIP temperature

Fig. 4 Microstructure evolution near the sintering cavities under different HIP conditions: a 1100 °C/200 MPa/4 h; b 1150 °C/150 MPa/2 h; c 1175 °C/150 MPa/2 h; d 1200 °C/150 MPa/2 h

Fig. 5 Atomic concentration ratios at different regions: a (C Al + C Ti + C Ta)/(C Cr + C W + C Mo + C Co) at HIP temperature of 1150 °C; b (C Al + C Ti + C Ta)/(C Cr + C W + C Mo + C Co) at HIP temperature of 1175 °C; c C rafting/C denuded for different elements at HIP temperature of 1150 °C; d C rafting/C denuded for different elements at HIP temperature of 1175 °C

Fig. 6 Schematic illustration of microstructural evolution near micropores under different HIP conditions: a before HIP; b HIP temperature below γ′ solvus temperature; c HIP temperature above γ′ solvus temperature

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