Combined Experimental and Numerical Investigations on the Roughness Effects on the Aerodynamic Performances of LPT Blades

TitleCombined Experimental and Numerical Investigations on the Roughness Effects on the Aerodynamic Performances of LPT Blades
Publication TypeJournal Article
Year of Publication2016
AuthorsBerrino M, Bigoni F, Simoni D, Giovannini M, Marconcini M, Pacciani R, Bertini F
JournalJournal of Thermal Science
Volume25
Issue1
Pagination32-42
Date Published01/2016
ISSN Number1003-2169
Accession NumberWOS:000367893500005
Other NumbersScopus 2-s2.0-84953376219
Abstract
The aerodynamic performance of a high-load low-pressure turbine blade cascade has been analyzed for three different distributed surface roughness levels (Ra) for steady and unsteady inflows. Results from CFD simulations and experiments are presented for two different Reynolds numbers (300000 and 70000 representative of take-off and cruise conditions, respectively) in order to evaluate the roughness effects for two typical operating conditions. 
Computational fluid dynamics has been used to support and interpret experimental results, analyzing in detail the flow field on the blade surface and evaluating the non-dimensional local roughness parameters (which were not available from the experimental tests), further contributing to understand how and where roughness have some influence on the aerodynamic performance of the blade. The total pressure distributions in the wake region have been measured by means of a five-hole miniaturized pressure probe for the different flow conditions, allowing the evaluation of profile losses and of their dependence on the surface finish, as well as a direct comparison with the simulations.
Results reported in the paper clearly highlight that only at the highest Reynolds number tested (Re=300000) surface roughness have some influence on the blade performance, both for steady and unsteady incoming flows. In this flow condition profile losses grow as the surface roughness increases, while no appreciable variations have been found at the lowest Reynolds number. The boundary layer evolution and the wake structure have shown that this trend is due to a thickening of the suction side boundary layer associated to an anticipation of transition process. On the other side, no effects have been observed on the pressure side boundary layer.
URLhttp://link.springer.com/article/10.1007/s11630-016-0831-5
DOI10.1007/s11630-016-0831-5
Refereed DesignationRefereed