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3D investigation of heat exchange and hydrodynamics of high pressure turbine nozzle block platforms with different cooling schemes
- Authors: Gorelov Y.G.1, Ananyev V.V.1, Zolotuhina D.A.1
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Affiliations:
- JSC Joint Propulsion Engineering Corporation
- Issue: Vol 21, No 2 (2022)
- Pages: 16-27
- Section: AIRCRAFT AND SPACE ROCKET ENGINEERING
- URL: https://journals.ssau.ru/vestnik/article/view/10490
- DOI: https://doi.org/10.18287/2541-7533-2022-21-2-16-27
- ID: 10490
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Abstract
Turbine nozzle blocks were tested and, as a result, problems of nozzle block lower platform alligatoring were detected. In the course of the research possible variants of cooling high pressure turbine nozzle block vane platforms were investigated. According to the results of 3D ANSYS CFX calculation the cooling efficiency of high pressure turbine vane platforms with film cooling and convective-film cooling were compared. Research was carried out to eliminate the alligatoring defect of the lower vane platform with convective cooling. Necessary changes in the design were made due to which the cooling air from the secondary combustion chamber area was redistributed over the surface of the turbine nozzle block lower platform. To force the gas turbine engine to the inlet gas temperature to 1800 К and more, and to increase the cooling air mass flow from the secondary combustion chamber area over the platforms using convective cooling methods not requiring developed ribbing and impingement cooling, areas of the platforms, as well as zones demanding insignificant intensity of cooling are shown.
About the authors
Yu. G. Gorelov
JSC Joint Propulsion Engineering Corporation
Author for correspondence.
Email: Yury.Dina@gmail.com
кандидат технических наук, заместитель начальника отдела
Russian FederationV. V. Ananyev
JSC Joint Propulsion Engineering Corporation
Email: vit-ananev@yandex.ru
Chief Specialist
Russian FederationD. A. Zolotuhina
JSC Joint Propulsion Engineering Corporation
Email: galenrant@gmail.com
Head of Design Bureau
Russian FederationReferences
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