In response to the continuous increase in aircraft noise pollution, computational aeroacoustic analyses are mandatory during the aero-engine design loop. In order to investigate the acoustic generation and propagation phenomena within a multi-stage turbomachinery, an experimental campaign on direct and indirect noise coming from a high pressure axial turbine stage has been carried out by Politecnico di Milano in the context of the European research project RECORD. The purpose of this work is to numerically predict both the direct noise produced by stator/rotor interactions and the indirect noise generated by the non-acoustic fluctuations coming from an annular combustor that impinge on the HPT stage by using URANS analyses. The computational results are in good agreement with experimental measures, confirming the possibility to include the numerical method during the engine design loop to assess noise emissions and suggest low noise design solutions.
Validation of an URANS approach for direct and indirect noise assessment in a high pressure turbine stage / Burberi, Corrado; Ghignoni, Erika; Pinelli, Lorenzo; Marconcini, Michele. - In: ENERGY PROCEDIA. - ISSN 1876-6102. - ELETTRONICO. - 148:(2018), pp. 130-137. (Intervento presentato al convegno ATI 2018 - 73rd Conference of the Italian Thermal Machines Engineering Association tenutosi a Pisa, Italy nel 12-14 September) [10.1016/j.egypro.2018.08.040].
Validation of an URANS approach for direct and indirect noise assessment in a high pressure turbine stage
BURBERI, CORRADO;GHIGNONI, ERIKA;Pinelli, Lorenzo;Marconcini, Michele
2018
Abstract
In response to the continuous increase in aircraft noise pollution, computational aeroacoustic analyses are mandatory during the aero-engine design loop. In order to investigate the acoustic generation and propagation phenomena within a multi-stage turbomachinery, an experimental campaign on direct and indirect noise coming from a high pressure axial turbine stage has been carried out by Politecnico di Milano in the context of the European research project RECORD. The purpose of this work is to numerically predict both the direct noise produced by stator/rotor interactions and the indirect noise generated by the non-acoustic fluctuations coming from an annular combustor that impinge on the HPT stage by using URANS analyses. The computational results are in good agreement with experimental measures, confirming the possibility to include the numerical method during the engine design loop to assess noise emissions and suggest low noise design solutions.I documenti in FLORE sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.