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Calcul numérique de la réponse acoustique d'un aubage soumis à un sillage turbulent / Numerical calculation of the acoustic response of a blade-row impinged by a turbulent wakeClair, Vincent 26 November 2013 (has links)
Le bruit généré par l'impact du sillage de la soufflante avec les aubes du redresseur est une source prédominante des turboréacteurs en conditions d'approche, et la composante à large bande contribue fortement au niveau sonore global. Une méthode numérique basée sur un code CAA résolvant les équations d Euler est développée dans cette thèse afin d'estimer le bruit d'interaction entre un sillage turbulent et un aubage de géométrie quelconque. Le sillage amont est modélisé à l'aide d'une méthode stochastique supposant un spectre de turbulence homogène isotrope et une représentation spatiale simplifiée du champ de vitesse. Ces fluctuations de vitesse sont injectées dans le code CAA via des conditions aux limites adéquates. La méthode ainsi mise en place est validée dans un premier temps sur des cas d'interaction avec une plaque plane en comparant les résultats numériques aux solutions du modèle d'Amiet. Un chaınage avec une méthode intégrale est aussi réalisé pour estimer le rayonnement acoustique. La méthode numérique est ensuite mise en œuvre pour simuler la réponse acoustique d'un profil isolé avec un bord d'attaque ondulé conçu et testé dans la soufflerie de l'ISVR dans le cadre du projet européen FLOCON. Enfin, la méthodologie est étendue à des configurations de grilles d'aubes annulaires en conduit. Après une étape de validation sur des cas monofréquentiels issus d'un benchmark CAA, des simulations large bande sont réalisées, tout d'abord sur une configuration de grille d'aubes sans incidence (écoulement axial uniforme) testée en soufflerie au LMFA, puis sur une configuration plus complexe de grille d'aubes non chargée en écoulement tournant proposée par Atassi / Noise generation due to the rotor wakes impinging the stator vanes is a dominant turbofan source at approach conditions, and the broadband noise component is significantly contributing to the overall level. A numerical method based on a CAA code solving the Euler equations is developped in this thesis in order to simulate the interaction noise between a turbulent wake and a vane row without geometry restrictions. The upstream turbulent flow is synthesized using a stochastic approach by considering an homogeneous isotropic turbulence spectrum model and a simplified spatial representation of the velocity field. These velocity gusts are injected in the CAA code by implementing a suited boundary condition. The present methodology is first va- lidated against turbulence-flat plate interaction cases, by comparing the numerical predictions to Amiet model solutions. A chaining with an integral formulation is also performed to assess the acoustic far-field. Then, the method is used to estimate the acoustic response of an isolated airfoil with a wavy leading egde, designed and tested in ISVR wind tunnel in the framework of European FLOCON project. Finally, the computations are extended to ducted annular grid configurations. After a validation step on single-frequency cases described in a CAA benchmark, broadband noise simulations are performed, firstly on a flat-plate annular grid in a uniform axial flow tested in the LMFA wind tunnel, and then on a more complex configuration related to an unloaded grid in a swirling mean flow proposed by Atassi
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Effect of clocking on unsteady rotor blade loading in a low-speed axial compressor at design and off-design operating conditionsJia, H-X, Xi, G., Müller, L., Mailach, R., Vogeler, K. 03 June 2019 (has links)
This paper presents the results of stator clocking investigations at a design point and an operating point near the stability limit in a low-speed research compressor (LSRC). The unsteady flow field of the LSRC at several clocking configurations was investigated using a three-dimensional unsteady, viscous solver. The unsteady pressure on the rotor blades at midspan (MS) was measured using time-resolving piezoresistive miniature pressure transducers. The effect of clocking on the unsteady pressure fluctuation at MS on the rotor blades is discussed for different operating points. Based on the unsteady profile pressures, the blade pressure forces were calculated. The peak-to-peak amplitudes of the unsteady blade pressure forces are presented and analysed for different clocking positions at both the design point and the operating point near the stability limit of the compressor.
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Modifications of Coherent Structures in Fan Blade Wakes for Broadband Noise ReductionBorgoltz, Aurelien 11 December 2007 (has links)
The effects of trailing edge flow control on the wakes of a linear cascade of idealized fan blades was investigated experiments with a view to the likely effects on broadband aircraft engine interaction noise. Single and three-component hotwire velocity measurements were made downstream of the cascade for a chord Reynolds number of 390,000 and a Mach number of 0.07. Measurements of the two-point velocity correlation were used extensively to evaluate the impact of various flow control strategies on the organization of the coherent structures of the wakes and their potential to generate noise.
A baseline flow was established by measuring the wake downstream of unmodified GE-Rotor-B blades. Four sets of serrated trailing edge blades (with two different serration sizes and with two trailing edge cambers) and three sets of blades with trailing edge blowing (a simple rectangular slot, rectangular slot with Kuethe-vane vortex generators, and rectangular slot with serrated lips) were tested.
The serrated trailing edges introduce corrugations into the wake, increase the wake decay and width as well as turbulence levels (possibly because of the blunt trailing edge created at the serration valley). The serrated trailing edges also increase the turbulence scales in the direction perpendicular to the plane of the wake because of the injection of streamwise vorticity. In almost all cases the serrations reduce the spanwise and streamwise turbulence scales. Serrations do not, however, affect the apparent time scale of quasi-periodic structures in the wake, and this appears to limit the potential of this trailing edge treatment to reduce broadband noise. The analysis of the characteristic eddies (obtained from proper orthogonal decomposition combined with linear estimation) revealed that the serrations do not change the qualitative form of the eddies.
Trailing edge blowing was found to significantly decrease the wake deficit and width as well as the turbulence levels at all blowing rates. Blowing through the simple rectangular slot, at mass flow rates between 1.4 and 2.0% of the total passage through flow, was shown to significantly affect the size, the organization and the strength of the coherent structures. For small blowing rates the strong spanwise eddies near the trailing edge actually appear to be enhanced. For larger blowing rates, however, the turbulent scales are reduced in all directions. The addition of Kuethe vanes on the suction side of the blowing blade results in a low momentum region just downstream of the vanes that may result from flow separation there. This further enhances the shedding and increases the blowing rate needed to overcome it. The serrated blowing blades show the greatest potential to reduce broadband noise as they reduce the turbulence levels and scales without creating potentially detrimental structures.
While no acoustic measurements were made, analysis of hypothetical perpendicular and parallel interactions of blades with these wakes has made possible to characterize for the first time the impact of the changes in the eddy structure of these wakes on their potential to generate broadband noise. The serrated trailing edges (especially the larger serrations) actually increase the potential of the wake to generate broadband noise (a direct consequence in the overall increase in turbulence scale and intensity). In contrast, every trailing edge blowing configuration was found to produce large reductions in the potential noise (a maximum of 6dB reduction was obtained at 2.0% blowing). The addition of Kuethe vanes on the suction side of the blowing blades significantly reduced the efficiency of the simple blowing configuration (a result of the increased coherency associated with the shedding of streamwise vorticity by the vanes). The serrated blowing configuration was found to yield reductions similar to the simple blowing configuration. / Ph. D.
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On the Use of Surface Porosity to Reduce Wake-Stator Interaction NoiseTinetti, Ana Fiorella 09 October 2001 (has links)
An innovative application of existing technology is proposed for attenuating the effects of transient phenomena, such as rotor-stator and rotor-strut interactions, linked to noise and fatigue failure in turbomachinery environments. A computational study was designed to assess the potential of Passive Porosity Technology as a mechanism for alleviating interaction effects and radiated noise by reducing the fluctuating forces acting on the vane surfaces. The study involved a typical high bypass fan stator airfoil immersed in a subsonic free field and exposed to the effects of a transversely moving wake. Time histories of the primitive aerodynamic variables obtained from Computational Fluid Dynamics (CFD) calculations were input into an acoustic prediction code to estimate noise levels at a radial distance of ten chords from the stator airfoil. This procedure was performed on the solid airfoil to obtain a baseline, and on approximately fifty porous configurations in order to isolate those that would yield maximum noise reductions without compromising the aerodynamic performance of the stator.
It was found that, for a single stator immersed in a subsonic flow field, communication between regions of high pressure differential - made possible by the use of passive porosity - tends to induce a time-dependent oscillatory pattern of small inflow-outflow regions near the stator leading edge (LE), which is well established before wake effects come into play. The oscillatory pattern starts at the LE, and travels downstream on both suction and pressure sides of the airfoil. The amplitude of the oscillations seemed to be proportional to the extension of the porous patch on the pressure side. Regardless of this effect, which may not have occurred if the airfoil were placed within a stator cascade, communication between regions of high pressure differential is necessary to significantly alter the noise radiation pattern of the stator airfoil. Whether those changes result in noise abatement or enhancement depends primarily on the placement and extension of the porous patches. For most viable configurations, porosity reduced loading noise but increased thickness noise. Variations in nominal porosity were of secondary importance.
In general, the best aerodynamic performers (i.e., those configurations that were able to reduce unsteady lift without severely altering the lift and/or drag characteristics of the solid airfoil) were also the best acoustic performers. As a result of using passive surface porosity, overall peak radiated noise was reduced by approximately 1.0 dB. This reduction increased to about 2.5 dB when the effects of loading noise alone were considered. / Ph. D.
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Unsteady Aerodynamic Interaction in a Closely-Coupled Turbine Consistent with Contra-RotationOoten, Michael Kenneth 26 August 2014 (has links)
No description available.
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3-D Unsteady Simulation of a Modern High Pressure Turbine Stage: Analysis of Heat Transfer and FlowShyam, Vikram January 2009 (has links)
No description available.
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Efficiency of a high-pressure turbine tested in a compression tube facilityYasa, Tolga 01 July 2008 (has links)
Highly loaded single stage gas turbines are being developed to minimize the turbine size and weight. Such highly loaded turbines often result in transonic flows, which imply a reduction in the efficiency due to the shock losses. The efficiency of a turbine is defined as the ratio between the real work extracted by the turbine rotor from the fluid and the maximum available enthalpy for a given pressure ratio. The relationship between turbine performance and design parameters is not yet fully comprehended due to the complexity of the flow field and unsteady flow field interactions. Hence, experimental and numerical studies remain necessary to understand the flow behavior at different conditions to advance the state of the art of the prediction tools.
The purpose of the current research is to develop a methodology to determine the efficiency with an accuracy better than 1 % in a cooled and uncooled high pressure (HP) turbine tested in a short duration facility with a running time of about 0.4s. Such low level of uncertainty requires the accurate evaluation of a large number of quantities simultaneously, namely the mass flow of the mainstream, the coolant, and leakage flows properties, the inlet total pressure and total temperature, the stage exit total pressure, the shaft power, the mechanical losses and the heat transfer.
The experimental work is carried out in a compression tube facility that allows testing the turbine at the temperature ratios, Re and Mach numbers encountered in real engines. The stage mass flow is controlled by a variable sonic throat located downstream of the stage exit. Due to the absence of any brake, the turbine power is converted into rotor acceleration. The accurate measurement of this acceleration as well as those of the inertia and the rotational speed provides the shaft power. The inertia of the whole rotating assembly was accurately determined by accelerating and decelerating the shaft with a known energy. The mass-flow is derived from the measured turbine inlet total pressure and the vane sonic throat. The turbine sonic throat was evaluated based on a zero-dimensional model of the turbine.
The efficiencies of two transonic turbines are measured at design and off-design conditions. The turbine design efficiency is obtained as 91.8 %. The repeatability of the measurements for 95% confidence level varies between 0.3 % and 1.1 % of the efficiency depending on the test case. The theoretical uncertainty level of 1.2 % is mainly affected by the uncertainty of exit total pressure measurements. Additionally, the effect of vane trailing edge shock formations and their interactions with the rotor blade are analyzed based on the experimental data, the numerical tools and the loss correlations. The changes of blade and vane performances are measured at mid-span for three different pressure ratios which influence the vane and rotor shock mechanisms. Moreover, the unsteady forces on the rotor blades and the rotor disk were calculated by integration of the unsteady static pressure field on the rotor surface.
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Experimental analysis of fan noise and performance at the EESC-USP Fan Rig Workbench / Análise experimental de ruído e performance de fan na bancada EESC-USP Fan Rig WorkbenchRocamora Junior, Bernardo Martínez 08 February 2019 (has links)
The study of turbofan aeroacoustics has become important in academia and industry as noise from other aircraft sources, as jet noise, have been reduced. The EESC-USP Fan Rig is a long-duct low-speed fan experimental setup recently built at the Department of Aeronautical Engineering of the University of São Paulo. The objective is to provide a facility for studying fan aeroacoustics with a flexible configuration that allows changes in operational conditions and geometry of the rig so that each of the noise sources can be treated separately. In this work, three experimental campaign were taken aiming to extend the knowledge of this workbench capabilities and to observe the effect that some parameters can have on noise generation. A performance campaign was carried out to characterise the effects of controllable parameters on the aerodynamic characteristics of the flow. Starting from unrestricted flow to 70% area constraint, and a range of fan speeds, several flow measurements that could be translated into performance quantities were taken: volume flow rate, fan total and static pressures, compression ratio, total and net power, and efficiency. The measured compression ratio ranged from 1.00 to 1.02, with maximum axial Mach of 0.13 and maximum total efficiency of 65%. The surge effect, an unstable configuration characterised by rotor blades stall was also observed. Significant differences in fan performance due to the installation of an Inlet Control Device (ICD) and the rotor-stator spacing were not found, except under surge conditions. A parametric campaign was carried out exploring the effects of fan rotational speed, fan loading and rotor-stator spacing. Acoustic measurements were taken using an array of 77 wall-mounted microphones to provide a baseline data set for future comparisons. Hereby, data was processed to obtain the modal decomposition and power spectrum for each configuration. The last proved useful to compare tonal and broadband noise for each configuration. Experimental results indicate that changes in fan rotational speed scale noise generation mechanisms proportionally, do not affect noise spectral shape, and in consequence, are not useful to distinguish noise mechanisms. Although throttling does not seem to exhibit a clear effect on fan noise, it turns out that it is a good approach for cross-comparisons of other parameters\' effect on fan noise, because of its direct modification on the flow structure within the duct. Results also showed that increasing rotor-stator spacing reduces both blade passing frequencies tone levels and the acoustic power of the interaction modes, which are in agreement with results obtained by similar test facilities. In this work a instrumented stator vane was designed using recently available technologies, as 3D printing and the use of MEMS microphones, to measure this pressure fluctuations. Phase-averaging and the signal from a hall sensor were used to separate broadband content in time series. Broadband level distribution were analysed for two span lines of the instrumented stator vane and for a reference microphone located in the inlet antenna. Broadband levels increased with the increase in fan speed and its distribution over these span lines maintained its shape for different speeds. Cross-correlation of the microphones were calculated and showed decay of zero-delay cross-correlation with increase in distance between microphones over the vane. And, finally, the integral length scale, obtained by the integration of zero-delay cross-correlation curve, showed decay with increase in fan speed. The data generated by this work showed good agreements with what was expected from the literature and will help as input data to the semi-analytical and semi-empirical models that are being developed in parallel by the research group. / O estudo da aeroacústica de fan tornou-se importante na academia e na indústria à medida que o ruído de outras fontes nas aeronaves, como o ruído de jato, foram reduzidas. O EESCUSP Fan Rig é um túnel de vento aeroacústico voltado para fans de baixa velocidade, que foi construído recentemente no Departamento de Engenharia Aeronáutica da Universidade de São Paulo. Seu objetivo é prover uma bancada experimental para o estudo dos mecanismos de geração de ruído de fan com uma configuração flexível que permita mudanças nas condições operacionais e geométricas de forma a isolar tanto quanto possível cada uma das fontes. Neste trabalho foram realizadas três campanhas experimentais visando aprofundar os conhecimentos sobre as capacidades da bancada e observar os efeitos no ruído que algumas variações paramétricas podem gerar. Uma campanha de performance de fan foi realizada para quantificar os efeitos dos parâmetros controláveis sobre o as características aerodinâmicas do escoamento. Partindo de escoamento sem restrição até restrição de área de 70%, e para diversas velocidades de rotação do fan, diversas medidas do escoamento foram feitas para que se pudesse calcular as métricas de performance: vazão volumétrica, pressão total e estática do fan, taxa de compressão, potência útil, potência elétrica de entrada e eficiência. Os resultados apontaram para uma taxa de compressão entre 1.0 e 1.02, com Mach axial máximo de 0.13 e eficiência máxima de 65%. Os efeitos de \"surge\", uma configuração instável caracterizada pelo estol das pás do rotor também foi observado. Diferenças significativas na performance do fan devido à instalação de uma Inlet Control Device (ICD) e pelo espaçamento entre rotor e estator não foram encontradas, com exceção em condições de \"surge\". Uma campanha paramétrica para estudo de ruído foi realizada explorando os efeitos da velocidade de rotação e carregamento no fan, espaçamento entre rotor-estator e condição de entrada do escoamento no duto. Os resultados mostraram que o aumento do espaçamento do rotor-estator reduz os níveis tonais nas frequências de passagem das pás (BPFs) a uma taxa de aproximadamente 4dB quanto o espaçamento é duplicado. Os resultados experimentais indicam que as mudanças nos mecanismos de geração de ruído com a velocidade rotacional do fan escalam-se proporcionalmente, não afetam a forma espectral do ruído e, por consequência, não são úteis para distinguir os mecanismos de ruído. Embora a variação no carregamento não pareça exibir um efeito claro no ruído do fan, verifica-se que é uma boa abordagem para comparações cruzadas, em conjunto com a velocidade de rotação, do efeito de outros parâmetros no ruído do fan, já que, desta forma, é possível fazer uma modificação direta na estrutura do escoamento dentro do duto. Os modos Tyler-Sofrin, esperados pela contagem de pás e aletas usadas no conjunto rotor-estator, foram identificados e a potência acústica desses modos de interação acompanham a potências dos respectivos tons no espectro, levando à conclusão que a maior contribuição para o ruído tonal é, de fato, a interação rotor-estator. Também neste trabalho, também foi projetada uma aleta de estator instrumentada, usando tecnologias recentemente disponíveis, como a impressão 3D e o uso de microfones MEMS, para realizar medições de flutuação de pressão na superfície superior da aleta. Um método de processamento de sinal foi desenvolvido, usando a técnica de \"phase averaging\" combinada com o sinal de um sensor Hall para separar o conteúdo de banda larga em séries temporais. A distribuição do nível de ruido banda larga foi analisado para duas linhas na envergadura da aleta instrumentada e em um microfone de referência localizado na antena de microfones. Os níveis de banda larga aumentaram com o aumento da velocidade do fan e a sua distribuição ao longo destas linhas de alcance manteve a sua forma para diferentes velocidades. As correlações cruzadas dos microfones foram calculadas e mostraram o decaimento da correlação cruzada de zero-atraso com o aumento da distância entre os microfones sobre a aleta. Finalmente, a integral do comprimento de escala, obtida pela integração da curva de correlação cruzada de zero-atraso, apresentou decaimento com aumento na velocidade do fan. Os dados gerados por esse trabalho se mostraram de acordo com o esperado na literatura da área e servem de dados de entrada para modelos semi-empíricos e semi-analíticos que vem sendo desenvolvidos paralelamente pelo grupo de pesquisa.
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Numerical simulation of unsteady rotor/stator interaction and application to propeller/rudder combinationHe, Lei, doctor of civil engineering 10 November 2010 (has links)
In this thesis, a numerical approach based on a potential flow method has been developed in order to simulate unsteady rotor/stator interaction, and to predict the unsteady performance of a propeller and its rudder.
The method is first developed and tested in two-dimensions by using a boundary element method in which a front hydrofoil is moving downward, while a back hydrofoil is stationary. The wakes of the two hydrofoils are modeled by continuous dipole sheets and determined in time by applying a force free-condition on each wake surface. The wake/hydrofoil interaction is de-singularized by applying a numerical fence on the surface of the back hydrofoil. The viscous wake/hydrofoil interaction is considered by employing a viscous wake vorticity model on the rotor's wake surface. The present method is validated by comparison with analytical solutions, experimental data and by using the results from a commercial Reynolds Averaged Navier-Stokes (RANS) solver for the same set-up and conditions.
The numerical approach is further extended to three-dimensions to predict the mutual interaction between a propeller and rudder.
A fully unsteady wake alignment algorithm is implemented into a Vortex Lattice Method to simulate the unsteady propeller flow. The interaction between propeller and rudder is investigated in a fully unsteady manner, where a panel method is used to solve the flow around the rudder, and a vortex lattice method is used to solve the flow around the propeller.
The interaction between a propeller and its rudder is considered in an iterative manner by solving the propeller and the rudder problems
separately and by including the unsteady effects of one component on the other. The effect of the unsteady propeller-rudder interaction on the mean and on the unsteady propeller/rudder performance, including sheet cavitation on the rudder, is studied. / text
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Stratégie de résolution hybride structurée / non structurée pour la simulation d'effets technologiques en turbomachines / Hybrid structured / unstructured solution strategy for the simulation of turbomachinery technological effectsSoismier, Matthieu 17 October 2016 (has links)
Les motoristes aéronautiques souhaitent disposer de la représentation la plus fidèle possible du fonctionnement des propulseurs, dans une perspective d'amélioration continue de leurs performances. Les modèles numériques doivent donc intégrer au maximum les détails géométriques susceptibles d'influencer la physique de l'écoulement analysé. La prise en compte de tels effets technologiques s'avère difficile dans le contexte des solveurs structurés disponibles.Une stratégie hybride de prise en compte des effets technologiques fait coexister au sein d'un même domaine de calcul des zones structurées et non structurées. La flexibilité de génération d'un maillage non structuré permet une prise en compte aisée des détails géométriquement complexes tandis que la préservation de zones structurées dans une majeure partie du domaine de calcul permet de bénéficier de l'efficacité d'un solveur structuré. La présente thèse contribue au développement de cette stratégie hybride au sein du solveur elsA de l'ONERA en proposant des gains de précision et de robustesse par rapport à la version initialement développée pour établir la faisabilité et l'intérêt de l'approche. Après un état de l'art des techniques de discrétisation spatiale disponibles dans cette version initiale, différentes améliorations (techniques de moindres carrés, approche dite quasi-Green, méthode d'estimation des gradients aux faces) ont été analysées puis implémentées et validées sur des cas académiques. Le choix d'une stratégie hybride avec raccords coïncidents entre zones structurées et non-structurées conduit à des déformations de maillage dans la zone d'interface structuré / non-structuré qui ont exigé le développement supplémentaire de techniques d'amélioration de la robustesse (limiteurs physiques ou géométriques). Le solveur hybride rassemblant ces différentes fonctionnalités a permisde simuler avec succès des géométries d'aubes isolées dotées d'effets technologiques tels que congé de raccordement, trous de refroidissement, fentes de bord de fuite, cheminées internes d'alimentation. Enfin, une stratégie permettant l'utilisation de l'approche hybride en étage complet a été proposée et appliquée à la simulation hybride de l'interaction rotor/stator pour la configuration VKI-BRITE CT3, en stationnaire et en instationnaire, respectivement via une condition de plan de mélange et une condition de chorochronicité. / The aerospace engine manufacturers wish to rely on the most accurate description of their propulsion systems in order to continuously improve their performance levels. Therefore, numerical models must include as much as possible geometrical details likely to impact the physics of the flow under study. Taking into account such technological effects turns out to be a difficult task when working with available structured solvers. A hybrid strategy takes advantage of structured and unstructured zones within the same computational domain in order to efficiently describe technological effects. Geometrically complex local details are easily accounted for thanks to the flexibility of unstructured grid generation while keeping structured zones in the remainder of the flow domain allows to benefit from the tried and tested structured solver efficiency. The present work contributes to the development of such a hybrid strategy in ONERA elsA solver and enhances accuracy and robustness with respect to the solver initially developed to establish the feasibility and interest of hybridization. Following a review of the space discretization techniques available in the initial solver, several improvements (least square techniques, quasi-Green approach, computation of face gradients) have been analysed, then implemented and validated for academic test-cases. The choice of a hybrid strategy with coincident matching between structured and unstructured zones leads to highly deformed cells in the structured / unstructured interface region, requiring the development of supplementary robustness improvement techniques (physics- or geometry-based limiters). The hybrid solver gathering these various options allows to successfully compute isolated blade geometries including technological effects such as blade fillet, cooling holes, trailing edge cutbacks, internal coolant supply channel. Finally, a structured / unstructured strategy has been proposed and applied to the hybrid simulation of a rotor/stator interaction for the steady and unsteady
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