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Master thesis and internship[BR]- Master's thesis : Improvement of the viscous-inviscid interaction method implemented in DARTFLO[BR]- Integration internship

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Dechamps, Paul ULiège
Promoteur(s) : Terrapon, Vincent ULiège
Date de soutenance : 28-jan-2022 • URL permanente : http://hdl.handle.net/2268.2/13886
Détails
Titre : Master thesis and internship[BR]- Master's thesis : Improvement of the viscous-inviscid interaction method implemented in DARTFLO[BR]- Integration internship
Titre traduit : [fr] Amélioration de la méthode d'interaction visqueuse-non visqueuse implémentée dans DARTFLO
Auteur : Dechamps, Paul ULiège
Date de soutenance  : 28-jan-2022
Promoteur(s) : Terrapon, Vincent ULiège
Membre(s) du jury : Crovato, Adrien ULiège
Bilocq, Amaury ULiège
Dimitriadis, Grigorios ULiège
Langue : Anglais
Mots-clés : [en] Viscous-inviscid interaction
[en] Coupled IBL
[en] Boundary layer
[en] Viscous flow
[en] Separation bubble
[en] Turbulent flow
[en] Turbulence
[en] Transition
[en] DARFLO
[en] Shear-lag equation
Discipline(s) : Ingénierie, informatique & technologie > Ingénierie aérospatiale
Centre(s) de recherche : Multiphysics and Turbulent Flow Computation
Public cible : Chercheurs
Professionnels du domaine
Etudiants
Grand public
Autre
Institution(s) : Université de Liège, Liège, Belgique
Diplôme : Master en ingénieur civil en aérospatiale, à finalité spécialisée en "aerospace engineering"
Faculté : Mémoires de la Faculté des Sciences appliquées

Résumé

[en] Preliminary aircraft design often relies on solutions of the RANS equations to characterize the flow field in the different conditions of interest. Such a procedure usually comes at the expense of costly computations that can hardly be used routinely in the early stages of the design. To overcome this problematic, inviscid flow models are considered as an alternative since the associated computational time is more interesting. The main drawback of these models is their inability to predict aerodynamic drag or flow separation which is of upmost interest to optimize the aircraft for fuel consumption. Viscous corrections can be used with these flow models and offer a fast tool suited for preliminary design.
This study presents a pseudo-time dependent, two-dimensional interacting boundary layer method for compressible flows in external aerodynamics. An inviscid flow is modeled by an unstructured finite-element, full potential solver suited for transonic flow computations. The flow in the immediate wall vicinity and in the wake is distinguished from the external inviscid flow by its viscosity property and is described by the time-dependent, compressible integral boundary layer equations. Steady-state flow solutions in the boundary layer are obtained on a dedicated mesh through a damped Newton scheme and are interfaced with the inviscid solutions through a quasi-simultaneous coupling method. The eN method is used to capture the laminar to turbulent transition. A pseudo-time marching method is presented with time advancement control and spo- radic numerical information update. Results are presented subsequently for attached and mildly separated flows around a symmetrical airfoil, for high angle of attack and low Reynolds number flows. Transonic capabilities are demonstrated on a supercritical airfoil and compared to RANS solutions which constitute the current reference in the domain. Stable convergence and good agreement with reference results is observed for flows with limited separation regions. Expected limitations are shown when the regime approaches stall. Further possible improvements, such as the use of an inverse method and mesh quality improvements are discussed especially for the transonic regime and results are consequently argued.


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Auteur

  • Dechamps, Paul ULiège Université de Liège > Master ingé. civ. aérospat., à fin.

Promoteur(s)

Membre(s) du jury

  • Crovato, Adrien ULiège Université de Liège - ULiège > Département d'aérospatiale et mécanique > Interactions Fluide-Structure - Aérodynamique expérimentale
    ORBi Voir ses publications sur ORBi
  • Bilocq, Amaury ULiège Université de Liège - ULiège > Département d'aérospatiale et mécanique > Design of Turbomachines
    ORBi Voir ses publications sur ORBi
  • Dimitriadis, Grigorios ULiège Université de Liège - ULiège > Département d'aérospatiale et mécanique > Interactions Fluide-Structure - Aérodynamique expérimentale
    ORBi Voir ses publications sur ORBi
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  • Nombre total de téléchargements 2










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