Low cycle fatigue properties and microstructure evolution at 760°C of a single crystal superalloy

Shi, Zhen-xue; Wang, Xiaoguang; Liu, Shizhong; Li, Jiarong

doi:10.1016/j.pnsc.2015.01.009

Cited by 19 publications

(5 citation statements)

References 21 publications

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“…Hysteresis loop shows a downward shift of stress coordinate with an increasing number of cycles after testing at 1.4% strain in untreated and all treated conditions as a result of inelasticity. It represents the cyclic softening of the material as discussed by other researchers 20–22 . Cyclic softening occurred due to the dislocation recovery during the cyclic loading.…”

Section: Resultsmentioning

confidence: 91%

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Influence of residual stress distribution and microstructural characteristics on fatigue failure mechanism in Ni‐based Superalloy

Kumar

Idapalapati

Wang

2021

Fatigue Fract Eng Mat Struct

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The influence of residual compressive stress (RCS) depth and magnitude generated through surface treatments such as shot peening (SP), deep cold rolling (DCR), and vibro-peening (VP) on fatigue crack mechanisms of Ni-based superalloy is investigated. The fatigue performance with associated failure mechanisms is measured under strain-controlled fatigue testing upto 10 4 cycles with total strain in the range of 0.9%-1.4% at an R ratio of 0.1 and 400 C followed by load controlled fatigue until failure. In-depth understanding of the failure mechanism is obtained through fractography analysis, cyclic stress-strain plot, and microstructural features. A pronounced improvement in fatigue life tested at low strain range (0.9%-1.1%) is achieved after inducing RCS up to 400 μm depth. However, the fatigue life is reduced when RCS increased to 800-1000 μm depth. Failure is primarily driven by micro-cracks formed due to balancing tensile stresses and high intensity stress concentration generated as the result of dislocation pile-ups and slip bands. Results are discussed in detail through the evidence of grain refinement, addition of low angle grain boundaries (LAGBs), strain accumulation, and intragranular deformation in the sub-surface.

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Section: Resultsmentioning

confidence: 91%

“…It represents the cyclic softening of the material as discussed by other researchers. [20][21][22] Cyclic softening occurred due to the dislocation recovery during the cyclic loading. During cyclic softening, residual stress combines with applied stress to cause local plastic yielding and to reduce local plastic mis-fit.…”

Section: S-n Curve Responsementioning

confidence: 99%

Influence of residual stress distribution and microstructural characteristics on fatigue failure mechanism in Ni‐based Superalloy

Kumar

Idapalapati

Wang

2021

Fatigue Fract Eng Mat Struct

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“…Rai et al 7 investigated the dislocation and cyclic plastic deformation behavior of a nickel base superalloy through extensive scanning electron microscope (SEM) and transmission electron microscope (TEM) examinations. The low‐cycle fatigue behavior of NBSX at elevated temperature has been widely investigated experimentally 8–15 . Ravi Chandran 16,17 presented an S–N curve model employing the Gumbel distribution.…”

Section: Introductionmentioning

confidence: 99%

“…The low-cycle fatigue behavior of NBSX at elevated temperature has been widely investigated experimentally. [8][9][10][11][12][13][14][15] Ravi Chandran 16,17 presented an S-N curve model employing the Gumbel distribution. Vacchieri et al 18 used the safe life approach to estimate the fatigue life of a gas turbine first-stage blade.…”

Section: Introductionmentioning

confidence: 99%

The porosity distribution of nickel‐base single‐crystal superalloy DD5 and its fatigue life property

Susmel

Jiang³

et al. 2023

Fatigue Fract Eng Mat Struct

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The porosity of nickel-base single crystals (NBSXs) is still an unavoidable casting problem that has a significant influence on the fatigue life of NBSXs. In order to quantify the porosity effect, a porosity-distribution-related life prediction method is proposed in this paper. The porosity size in a NBSX was measured, and the size distribution was regressed. The results show that the porosity size that is characterized by Feret's diameter follows a modified logarithmic normal distribution. The relation among the applied stress, porosity size, and lifetime is expressed by using the proposed method. The disperse band of S-N curve is investigated based on the probability distribution of the porosity size. The results show that the predicted S-N curve agrees well with the experimental data.

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“…Research on the microstructure of the material under different kinds of loading is of positive significance to explaining the damage mechanism of the material and the macroscopic mechanical behavior. Ample research has been done on the evolution of the microstructure of SC superalloys under creep, isothermal low-cycle fatigue, and TMF conditions [9][10][11][12][13][14][15][16], and the main evolution mechanism of microstructure under those loading has been studied. However, the research on coupled failure mode mainly focused on the interaction of creep and isothermal low-cycle fatigue [17,18].…”

Section: Introductionmentioning

confidence: 99%

Influence of Load Interaction between Creep and TMF on the Life of Single Crystal Nickel-based Superalloy

Song

2021

MSF

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Experimental investigation on the influence of load interaction on the life of Single Crystal Nickel-based Superalloy is conducted. Three kinds of load spectrums considering single and coupled failure mode are designed. Life tests are carried out under creep, thermo-mechanical fatigue (TMF), and creep-TMF interaction loading. The test results show that test lives, under the creep-TMF interaction loading, are lower than the life predictions given by the linear damage accumulation (LDA) rule, indicating that the load coupling can accelerate the damage evolution process. The microstructure of fractured specimens shows that under the creep-TMF interaction loading, rafting cause more dislocations to accumulate in the at γ/γ′ phase boundary, which could be the evidence of life decrease.

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Low cycle fatigue properties and microstructure evolution at 760°C of a single crystal superalloy

Cited by 19 publications

References 21 publications

Influence of residual stress distribution and microstructural characteristics on fatigue failure mechanism in Ni‐based Superalloy

Influence of residual stress distribution and microstructural characteristics on fatigue failure mechanism in Ni‐based Superalloy

The porosity distribution of nickel‐base single‐crystal superalloy DD5 and its fatigue life property

Influence of Load Interaction between Creep and TMF on the Life of Single Crystal Nickel-based Superalloy

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