High temperature fatigue testing of gas turbine blades

Beghini, Marco; Bertini, Leonardo; Santus, Ciro; Monelli, Bernardo Disma; Scrinzi, Erica; Pieroni, Nicola; Giovannetti, Iacopo

doi:10.1016/j.prostr.2017.11.079

Cited by 17 publications

(5 citation statements)

References 8 publications

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“…A popular solution has been to use vapour or gas turbines. In the case of these devices, a higher efficiency is often the opposite of durability, in part because one of the ways of increasing the efficiency of the device is to increase the temperature of the working fluid, which significantly increases the heat load [5][6][7]. The stresses that occur in the components of high-efficiency devices are much higher than those that occur in the components of less efficient devices.…”

Section: Introductionmentioning

confidence: 99%

Fatigue Analysis of the Microturbine Rotor Disc Made of 7075 Aluminium Alloy Using a New Hybrid Calculation Method

Zych

Żywica

2022

Materials

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Today, where the production of any kind of device may have a negative impact on the environment, it is crucial to produce machines that are as efficient as possible but that can also be strong enough to withstand harsh operating conditions for a long time. That is why this paper raises the issue of the fatigue analysis of high-speed axial-flow microturbines whose components are made of commonly used 7075 aluminium alloy. The paper presents different methods that can be used to estimate and increase the fatigue life of a turbine disc. The object of study is a 10-kilowatt vapour microturbine. The various mechanical, flow and thermal loads that can occur during the operation of the microturbine have been analysed so that the most important ones can be taken into account in the final considerations. Stress calculations were performed using analytical equations, and the finite element method (FEM) was also used. Using the stresses obtained and material characteristics, fatigue analysis was conducted. Then, new hybrid calculation methods were proposed, taking into account both analytical and numerical approaches that do not require the use of ready-made programs dedicated to fatigue analysis. To verify these methods, calculations were performed for two rotor discs with different geometries. These methods can be used by both engineers and scientists in the design process of various microturbines when fatigue calculations are performed.

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Section: Introductionmentioning

confidence: 99%

Fatigue Analysis of the Microturbine Rotor Disc Made of 7075 Aluminium Alloy Using a New Hybrid Calculation Method

Zych

Żywica

2022

Materials

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“…Such conditions can be created with using the gas-dynamic rigs [Grinkrug et al, 2020] in which blades are flowed over by the gas flow of combustion products of aviation fuel or rigs of induction heating [Grinkrug et al, 2020;Wang et al, 2016;Bonnand and Pacou, 2016;Kuvaldin and Lepeshkin, 2019], taking into account axial loading (from the action of centrifugal forces). The rigs [Beghinia et al, 2017;Kukla et al, 2021;Geng et al, 2017] are designed to study hightemperature fatigue of turbine blades and their models using radiation heating and induction heating. Tests on gas-dynamic rigs simulate well the corrosion failure of blade surface.…”

Section: Introductionmentioning

confidence: 99%

Method for Modeling the Thermal State of Turbine Blades of Aircraft Engines During Thermal Cycling Tests

Lepeshkin¹,

Guanghua²

2022

Proceedings of Global Power &Amp; Propulsion Society

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Test method for turbine cooled blades of gas turbine engines is developed. The new approaches during development of inductor structures, induction heating devices, cooling systems, hydraulic force loading system and methods for their design to provide the prescribed nonuniform heating the turbine cooled blades and to carry out more effective the thermocyclic tests are presented taking into account the developed test method. Study of effect of the clearances between inductor and blade surface and change of inductor efficiency on the thermal state of blade is presented. The test rig and improved systems of induction heating and mechanical loading are used to improve accuracy and simulate more complete the operating thermomechanical loading the full-scale cooled and uncooled blades at the thermocyclic tests. The results of rig testing the turbine cooled monocrystalline blades of gas turbine engine are received according to the developed test method.

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“…Thus, new methods and experiments were developed to assess the fatigue response of nickel-based superalloy turbine blades. Beghini et al [ 21 ] introduced a test rig, which allows us to reproduce the stress and strain cycle occurred in the fillet region between the trailing edge and platform of Gas Turbine (GT) cooled blades. Wang et al [ 22 ] developed a complex thermomechanical fatigue (TMF) test rig with loading, heating, cooling, and control subsystems, in which a mechanical load of the test section was adjusted discretely by changing the combination of spacers in the joints.…”

Section: Introductionmentioning

confidence: 99%

A Novel Method for High Temperature Fatigue Testing of Nickel Superalloy Turbine Blades with Additional NDT Diagnostics

et al. 2021

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In this paper, a novel method for high temperature fatigue strength assessment of nickel superalloy turbine blades after operation at different times (303 and 473 h) was presented. The studies included destructive testing (fatigue testing at temperature 950 °C under cyclic bending load), non-destructive testing (Fluorescent Penetrant Inspection and Eddy Current method), and finite element modelling. High temperature fatigue tests were performed within load range from 5200 to 6600 N using a special self-designed blade grip attached to the conventional testing machine. The experimental results were compared with the finite element model generated from the ANSYS software. It was found that failure of turbine blades occurred in the area with the highest stress concertation, which was accurately predicted by the finite element (FE) model.

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High temperature fatigue testing of gas turbine blades

Cited by 17 publications

References 8 publications

Fatigue Analysis of the Microturbine Rotor Disc Made of 7075 Aluminium Alloy Using a New Hybrid Calculation Method

Fatigue Analysis of the Microturbine Rotor Disc Made of 7075 Aluminium Alloy Using a New Hybrid Calculation Method

Method for Modeling the Thermal State of Turbine Blades of Aircraft Engines During Thermal Cycling Tests

A Novel Method for High Temperature Fatigue Testing of Nickel Superalloy Turbine Blades with Additional NDT Diagnostics

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