Creep-fatigue crack growth behavior in GH4169 superalloy

doi:10.1007/s11465-018-0489-7

Front. Mech. Eng.

2019, Vol. 14

Issue (3) : 369-376 https://doi.org/10.1007/s11465-018-0489-7

RESEARCH ARTICLE

Creep-fatigue crack growth behavior in GH4169 superalloy

Dianyin HU^1,^2,³(

), Xiyuan WANG¹, Jianxing MAO¹, Rongqiao WANG^1,^2,³(

)

¹. School of Energy and Power Engineering, Beihang University, Beijing 100191, China
². Collaborative Innovation Center of Advanced Aero-Engine, Beijing 100191, China
³. Beijing Key Laboratory of Aero-Engine Structure and Strength, Beijing 100191, China

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Abstract

This study aims to examine the crack growth behavior of turbine disc GH4169 superalloy under creep-fatigue loading. Crack growth experiments were performed on compact tension specimens using trapezoidal waveform with dwell time at the maximum load at 650 °C. The crack growth rate of GH4169 superalloy significantly increased with dwell time. The grain boundaries oxidize during the dwell process, thereby inducing an intergranular creep-fatigue fracture mode. In addition, testing data under the same dwell time showed scattering at the crack growth rate. Consequently, a modified model based on the Saxena equation was proposed by introducing a distribution factor for the crack growth rate. Microstructural observation confirmed that the small grain size and high volume fraction of the d phase led to a fast creep-fatigue crack growth rate at 650 °C, thus indicating that two factors, namely, fine grain and presence of the d phase at the grain boundary, increased the amount of weakened interface at high temperature, in which intergranular cracks may form and propagate.

Keywords crack growth rate creep-fatigue GH4169 superalloy CT specimen dwell time

Corresponding Author(s): Dianyin HU,Rongqiao WANG

Just Accepted Date: 12 December 2017 Online First Date: 05 January 2018 Issue Date: 24 July 2019

Cite this article:

Dianyin HU,Xiyuan WANG,Jianxing MAO, et al. Creep-fatigue crack growth behavior in GH4169 superalloy[J]. Front. Mech. Eng., 2019, 14(3): 369-376.

URL:

https://academic.hep.com.cn/fme/EN/10.1007/s11465-018-0489-7
https://academic.hep.com.cn/fme/EN/Y2019/V14/I3/369

Tab.1 Chemical composition of GH4169 superalloy

Fig.1 Diagram of semi-manufactured turbine disc and geometry of CT specimen (unit: mm)

Fig.2 Waveforms used in creep-fatigue crack growth experiments: (a) For specimen #01 and (b) for specimens #02–#05

Fig.3 Creep-fatigue crack growth rate of GH4169 superalloy under two dwell times

Fig.4 Fracture images of specimens under different dwell times, where DK = 48.6 MPa?m^1/2 and secondary cracks are indicated by arrows: (a) #01 with 100 s dwell time and (b) #02 with 25 s dwell time

Fig.5 Scatter in crack growth rate with same dwell time

Fig.6 Schematic diagram of superposed creep-fatigue crack growth curve

Tab.2 Fitting results based on Saxena model under 25 s dwell time condition

Tab.3 Metallographic parameters and distribution factors of the specimens

Fig.7 Optical microscopy images: (a,b) Specimen #02 and (c,d) Specimen #04 (The d phases are marked by white arrows.)

Fig.8 Optical microscopy images: (a,b) Specimen #03 and (c,d) Specimen #05 (The d phases are marked by white arrows.)

Fig.9 Fracture images of specimen #03 observed by scanning electron microscope (The zigzag grain boundaries are marked by white arrows.)

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