Advanced Experimental and Analytical Investigations on Combined Cycle Fatigue (CCF) of Conventional Cast and Single-Crystal Gas Turbine Blades

Weser, Swen; Gampe, Uwe; Raddatz, Mario; Parchem, Roland; Lukáš, P.

doi:10.1115/gt2011-45171

Cited by 11 publications

(5 citation statements)

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“…To minimize the effects of pre-cracking at room temperature on the test at 550°C, we ensure that the plastic zone sizes at the end of the precracking stage were the same as the start of the crack growth rate testing [7]. The size and shape of the developed crack with this specimen are more representative of turbine disc's operation conditions than those reproducted in a compact tension or bend specimen [6,8,[19][20]. All the test pieces were cut from a forged turbine disc of GH2036 given in Fig.…”

Section: Specimen Geometrymentioning

confidence: 99%

Experimental investigation of fatigue crack growth behavior of GH2036 under combined high and low cycle fatigue

Meng

Liu

et al. 2016

International Journal of Fatigue

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Fatigue crack growth rates have been experimentally determined for the superalloy GH2036 (in Chinese series) at an elevated temperature of 550 °C under pure low cycle fatigue (LCF) and combined high and low cycle fatigue (CCF) loading conditions by establishing a CCF test rig and using cornernotched specimens. These studies reveal decelerated crack growth rates under CCF loading compared to pure LCF loading , and crack propagation accelerates as the dwell time prolongs. Then the mechanism of fatigue crack growth at different loadings has been discussed by using scanning electron microscope (SEM) analyses of the fracture surface.

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Section: Specimen Geometrymentioning

confidence: 99%

Experimental investigation of fatigue crack growth behavior of GH2036 under combined high and low cycle fatigue

Meng

Liu

et al. 2016

International Journal of Fatigue

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“…Subsequently, the idea of blade-like specimens was put forward to represent the local feature of turbine blade. 4 This idea provided a new way to simulate the failure mode and the fatigue behaviour. However, the geometry and manufacture process of blade-like specimen still differed from the full-scale turbine blade, leading to the different fatigue behaviours.…”

Section: Introductionmentioning

confidence: 99%

“…These material properties are insufficient to fully represent the durability of turbine blade due to the differences in heat treatment, processing, surface finish and geometrical feature. Subsequently, the idea of blade‐like specimens was put forward to represent the local feature of turbine blade 4 . This idea provided a new way to simulate the failure mode and the fatigue behaviour.…”

Section: Introductionmentioning

confidence: 99%

Experimental investigation on creep‐fatigue behaviours of as‐received and service‐exposed turbine blades: Mechanism and life evaluation

Shi

Yang

et al. 2020

Fatigue Fract Eng Mat Struct

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In the present study, both the as-received and the 600-h-serviced turbine blades were tested under the creep-fatigue loading. The results showed that the service-exposed blades exhibited a longer creep-fatigue life than the asreceived ones due to the refinement of grain size and the increasing of hardness during the service process. Micro structural characterization revealed that there was no directional coarsening or rafting of γ 0 precipitate after 600 h of service. Moreover, the as-received blades exhibited initial cyclic hardening followed by saturation and softening, whereas the 600-h-serviced blades only exhibited continuous softening until fracture. A conservative service life prediction approach was proposed considering the experienced mission profile. This service life estimation method provides a new way to assess the durability of turbine blade.

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“…In most cases, tested life data of smooth specimens in the laboratory environment are used to predict components behavior [7], However, the differences between blades and smooth specimens, such as heat treatment, ' processing, microstructure, surface finish, and specimen size, may cause discrepancy between their mechanical performance and life distribution, and will definitely affect the accuracy of above tradi tional life assessment methods [8]. To decrease this discrepancy, some researchers design bladelike specimens [9][10][11], or even directly use full scale blades to conduct high temperature fatigue tests [8,[12][13][14][15][16][17] in a laboratory/bench environment. Compared with smooth or bladelike specimens, full scale blades own the same manufacture process with real operating blades, therefore there do not exist mechanical behavior discrepancy between the test specimens and flight ones.…”

mentioning

confidence: 99%

“…There also exist couple effects between LCF and HCF loads. NASA has developed a multi-axial servohydraulic testing system to simulate the loading which a gas turbine engine blade experiences during operation [16], and recently Europe also initiated a program PREMECCY (Predictive methods for the combined cycle fatigue in gas turbines) to develop test system and theoretical models to predict turbine blade CCF life [9].…”

mentioning

confidence: 99%

Investigation on Material's Fatigue Property Variation Among Different Regions of Directional Solidification Turbine Blades—Part I: Fatigue Tests on Full Scale Blades

Yan

Chen

Sun

et al. 2014

Journal of Engineering for Gas Turbines and Power

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At present, directional solidification (DS) made blades are commonly used in high per formance turbine for their better high temperature mechanical, especially in creep prop erties compared with the equiaxed grain (EG) blades made by conventional casting method. To predict DS blades' fatigue life accurately, one of the practical ways is to con duct tests on full-scale blades in a laboratory!bench environment. In this investigation, two types o f full scale turbine blades, which are made from DZ22B by DS method and K403 by conventional casting method, respectively, were selected to conduct high tem perature combined low and high cycle fatigue (CCF) tests on a special design test rig, to evaluate the increase o f fatigue life benefitted from material change. Experimental results show that different from EG blades, DS blades' fracture section is not located on the position where the maximum stress point lies. By comparing fatigue test results of the two types of blade, it can be found that the fatigue properties among different regions o f the DS blade are different, and its fatigue damage is not only related to the stress field, but also affected by different parts material's fatigue properties.

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Advanced Experimental and Analytical Investigations on Combined Cycle Fatigue (CCF) of Conventional Cast and Single-Crystal Gas Turbine Blades

Cited by 11 publications

References 0 publications

Experimental investigation of fatigue crack growth behavior of GH2036 under combined high and low cycle fatigue

Experimental investigation of fatigue crack growth behavior of GH2036 under combined high and low cycle fatigue

Experimental investigation on creep‐fatigue behaviours of as‐received and service‐exposed turbine blades: Mechanism and life evaluation

Investigation on Material's Fatigue Property Variation Among Different Regions of Directional Solidification Turbine Blades—Part I: Fatigue Tests on Full Scale Blades

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