Comparative Heat-Resistance Investigation of Protective Coatings

Since modern gas turbine engines operate under changing temperature load conditions, one of the important characteristics of the protective coatings on turbine blades is their high resistance to the appearance and development of cracks under mechanical and thermal loads. The effective internal heat...

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Published in:Russian metallurgy Metally 2023-12, Vol.2023 (12), p.1942-1946
Main Authors: Zorichev, A. V., Pashchenko, G. T., Parfenovskaya, O. A., Samoilenko, V. M., Golovneva, T. I.
Format: Article
Language:English
Subjects:
Chemical composition
Chemistry and Materials Science
Cracks
Fatigue cracks
Fatigue failure
Fracture mechanics
Gas turbine engines
Hardening and Coating Technologies
Heat resistance
High resistance
High temperature
Materials Science
Metallic Materials
Phase composition
Protective coatings
Surface layers
System effectiveness
Temperature
Temperature dependence
Thermal analysis
Thermal cycling
Thermal fatigue
Thermal resistance
Thermal stress
Turbine blades
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container_end_page 1946
container_issue 12
container_start_page 1942
container_title Russian metallurgy Metally
container_volume 2023
creator Zorichev, A. V.
Pashchenko, G. T.
Parfenovskaya, O. A.
Samoilenko, V. M.
Golovneva, T. I.
description Since modern gas turbine engines operate under changing temperature load conditions, one of the important characteristics of the protective coatings on turbine blades is their high resistance to the appearance and development of cracks under mechanical and thermal loads. The effective internal heat removal systems used to cool turbine blades lead to an increase in their thermal stress. Currently, the cracks induced by thermal fatigue are one of the common defects in the protective coatings on turbine blades. The heat resistance of the coatings at high temperatures is determined by the following three factors: the shape of the part onto which a coating is applied, the coating thickness, and the phase composition of the surface layers or the maximum aluminum content in the coating. Therefore, when a protective coating is chosen under specific operating conditions, it is important to know the influence of these factors on the heat resistance of the coating. In this work, we compare various coatings in terms of their resistance to cracking during cyclic temperature changes. The dependence of the heat resistance of the coatings on the method of their application and the phase-structural state is established. The revealed mechanism of thermal-fatigue crack formation and propagation as a function of the phase composition of the initial coating is especially valuable. The life of the protective coatings under cyclic temperature changes is shown to depend on the chemical composition of the coating and the method of its formation. The dependence of formation of thermal-fatigue cracks on samples with the coatings under study on the number of temperature change cycles is found.
doi_str_mv 10.1134/S0036029523120376
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The heat resistance of the coatings at high temperatures is determined by the following three factors: the shape of the part onto which a coating is applied, the coating thickness, and the phase composition of the surface layers or the maximum aluminum content in the coating. Therefore, when a protective coating is chosen under specific operating conditions, it is important to know the influence of these factors on the heat resistance of the coating. In this work, we compare various coatings in terms of their resistance to cracking during cyclic temperature changes. The dependence of the heat resistance of the coatings on the method of their application and the phase-structural state is established. The revealed mechanism of thermal-fatigue crack formation and propagation as a function of the phase composition of the initial coating is especially valuable. 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1555-6255
1531-8648
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source Springer Nature
subjects Chemical composition
Chemistry and Materials Science
Cracks
Fatigue cracks
Fatigue failure
Fracture mechanics
Gas turbine engines
Hardening and Coating Technologies
Heat resistance
High resistance
High temperature
Materials Science
Metallic Materials
Phase composition
Protective coatings
Surface layers
System effectiveness
Temperature
Temperature dependence
Thermal analysis
Thermal cycling
Thermal fatigue
Thermal resistance
Thermal stress
Turbine blades
title Comparative Heat-Resistance Investigation of Protective Coatings
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