Reynolds number and wind tunnel wall effects on the flow field around a generic UHBR engine high-lift configuration-Reference-Cited by-同舟云学术

Reynolds number and wind tunnel wall effects on the flow field around a generic UHBR engine high-lift configuration

Published:2020-08-31 Issue:4 Volume:11 Page:1009-1023
ISSN:1869-5582
Container-title:CEAS Aeronautical Journal
language:en
Short-container-title:CEAS Aeronaut J

Author:

Ullah Junaid,Prachař Aleš,Šmíd Miroslav,Seifert Avraham,Soudakov Vitaly,Lutz Thorsten,Krämer Ewald

Abstract

AbstractRANS simulations of a generic ultra-high bypass ratio engine high-lift configuration were conducted in three different environments. The purpose of this study is to assess small scale tests in an atmospheric closed test section wind tunnel regarding transferability to large scale tests in an open-jet wind tunnel. Special emphasis was placed on the flow field in the separation prone region downstream from the extended slat cut-out. Validation with wind tunnel test data shows an adequate agreement with CFD results. The cross-comparison of the three sets of simulations allowed to identify the effects of the Reynolds number and the wind tunnel walls on the flow field separately. The simulations reveal significant blockage effects and corner flow separation induced by the test section walls. By comparison, the Reynolds number effects are negligible. A decrease of the incidence angle for the small scale model allows to successfully reproduce the flow field of the large scale model despite severe wind tunnel wall effects.

Funder

Cleansky2

Universit├ñt Stuttgart

Publisher

Springer Science and Business Media LLC

Subject

Aerospace Engineering,Transportation

Link

https://link.springer.com/content/pdf/10.1007/s13272-020-00463-w.pdf

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