elib
DLR-Header
DLR-Logo -> http://www.dlr.de
DLR Portal Home | Impressum | Datenschutz | Kontakt | English
Schriftgröße: [-] Text [+]

Development of a fully-coupled harmonic balance method and a refined energy method for the computation of flutter-induced Limit Cycle Oscillations of bladed disks with nonlinear friction contacts

Berthold, Christian und Gross, Johann und Frey, Christian und Krack, Malte (2021) Development of a fully-coupled harmonic balance method and a refined energy method for the computation of flutter-induced Limit Cycle Oscillations of bladed disks with nonlinear friction contacts. Journal of Fluids and Structures, 102 (103233). Elsevier. doi: 10.1016/j.jfluidstructs.2021.103233. ISSN 0889-9746.

Dieses Archiv kann nicht den Volltext zur Verfügung stellen.

Kurzfassung

Flutter stability is a dominant design constraint of modern gas and steam turbines. To further increase the feasible design space, flutter-tolerant designs are currently explored, which may undergo Limit Cycle Oscillations (LCOs) of acceptable, yet not vanishing, level. Bounded self-excited oscillations are a priori a nonlinear phenomenon, and can thus only be explained by nonlinear interactions such as dry stick–slip friction in mechanical joints. The currently available simulation methods for blade flutter account for nonlinear interactions, at most, in only one domain, the structure or the fluid, and assume the behavior in the other domain as linear. In this work, we develop a fully-coupled nonlinear frequency domain method which is capable of resolving nonlinear flow and structural effects. We demonstrate the computational performance of this method for a state-of-the-art aeroelastic model of a shrouded turbine blade row. Besides simulating limit cycles, we predict, for the first time, the phenomenon of nonlinear instability, i.e. , a situation where the equilibrium point is locally stable, but for sufficiently strong perturbation (caused e.g. by an impact), the dry frictional dissipation cannot bound the flutter vibrations. This implies that linearized theory does not necessary lead to a conservative design of turbine blades. We show that this phenomenon is due to the nonlinear contact interactions at the tip shrouds, which cause a change of the vibrational deflection shape and frequency, which in turn leads to a loss of aeroelastic stability. Finally, we extend the well-known energy method to capture these effects, and conclude that it provides a good approximation and is useful for initializing the fully-coupled solver.

elib-URL des Eintrags:https://elib.dlr.de/148402/
Dokumentart:Zeitschriftenbeitrag
Titel:Development of a fully-coupled harmonic balance method and a refined energy method for the computation of flutter-induced Limit Cycle Oscillations of bladed disks with nonlinear friction contacts
Autoren:
AutorenInstitution oder E-Mail-AdresseAutoren-ORCID-iDORCID Put Code
Berthold, ChristianChristian.Berthold (at) dlr.deNICHT SPEZIFIZIERTNICHT SPEZIFIZIERT
Gross, JohannUniversität StuttgartNICHT SPEZIFIZIERTNICHT SPEZIFIZIERT
Frey, ChristianChristian.Frey (at) dlr.dehttps://orcid.org/0000-0003-0496-9225NICHT SPEZIFIZIERT
Krack, MalteUniversität StuttgartNICHT SPEZIFIZIERTNICHT SPEZIFIZIERT
Datum:April 2021
Erschienen in:Journal of Fluids and Structures
Referierte Publikation:Ja
Open Access:Nein
Gold Open Access:Nein
In SCOPUS:Ja
In ISI Web of Science:Ja
Band:102
DOI:10.1016/j.jfluidstructs.2021.103233
Herausgeber:
HerausgeberInstitution und/oder E-Mail-Adresse der HerausgeberHerausgeber-ORCID-iDORCID Put Code
de Langre, E.Ecole PolytechniqueNICHT SPEZIFIZIERTNICHT SPEZIFIZIERT
Verlag:Elsevier
ISSN:0889-9746
Status:veröffentlicht
Stichwörter:harmonic balance, fluid structure interaction, aeroelasticity, turbomachinery, nonlinear blade vibration
HGF - Forschungsbereich:Luftfahrt, Raumfahrt und Verkehr
HGF - Programm:Luftfahrt
HGF - Programmthema:Umweltschonender Antrieb
DLR - Schwerpunkt:Luftfahrt
DLR - Forschungsgebiet:L CP - Umweltschonender Antrieb
DLR - Teilgebiet (Projekt, Vorhaben):L - Virtuelles Triebwerk
Standort: Köln-Porz
Institute & Einrichtungen:Institut für Antriebstechnik > Numerische Methoden
Hinterlegt von: Berthold, Christian
Hinterlegt am:24 Jan 2022 08:13
Letzte Änderung:29 Mär 2023 00:01

Nur für Mitarbeiter des Archivs: Kontrollseite des Eintrags

Blättern
Suchen
Hilfe & Kontakt
Informationen
electronic library verwendet EPrints 3.3.12
Gestaltung Webseite und Datenbank: Copyright © Deutsches Zentrum für Luft- und Raumfahrt (DLR). Alle Rechte vorbehalten.