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21	Experimental Investigation of Active Wingtip Vortex Control Using Synthetic Jet Actuators Sudak, Peter J 01 August 2014 (has links) (PDF) An experiment was performed in the Cal Poly Mechanical Engineering 2x2 ft wind tunnel to quantify the effect of spanwise synthetic jet actuation (SJA) on the drag of a NACA 0015 semispan wing. The wing, which was designed and manufactured for this experiment, has an aspect ratio of 4.20, a span of 0.427 m (16.813”), and is built around an internal array of piezoelectric actuators, which work in series to create a synthetic jet that emanates from the wingtip in the spanwise direction. Direct lift and drag measurements were taken at a Reynolds Number of 100,000 and 200,000 using a load cell/slider mechanism to quantify the effect of actuation on the lift and drag. It was found that the piezoelectric disks used in the synthetic jet actuators cause structural vibrations that have a significant effect on the aerodynamics of the NACA 0015 model. The experiment was performed in a way as to isolate the effect of vibration from the effect of the synthetic jet on the lift and drag. Lift and drag data was supported with pressure readings from 60 pressure ports distributed in rows along the span of the wing. Oil droplet flow visualization was also performed to understand the effect of SJA near the wingtip. The synthetic jet and vibration had effects on the drag. The synthetic jet with vibration decreased the drag only slightly while vibration alone could decrease drag significantly from 11.3% at α = 4° to 23.4% at α = 10° and Re = 100,000. The lift was slightly increased with a slight increase due to the jet and showed a slight increase due to vibration. Two complete rows of pressure ports at 2y/b = 37.5% and 85.1% showed changes in lift due to actuation as well. The synthetic jet increased the lift near the wingtip at 2y/b = 85.1% and had little to no effect inboard at the 37.5% location, hence, the synthetic jet changes the lift distribution on the wing. Oil flow visualization was used to support this claim. Without actuation, the footprint of the tip vortex was present on the upper surface of the wing. With actuation on, the footprint disappeared suggesting the vortex was pushed off the wingtip by the jet. It is possible that the increased lift with actuation can be caused by the vortex being pushed outboard. Active Flow Control Wingtip Vortex Synthetic Jet Piezoelectric Wind Tunnel Testing Semispan Model Aerodynamics and Fluid Mechanics
22	Experimental Investigation Into Utilizing Synthetic Jet Actuators to Suppress Bi-modal Wake Behavior Behind an Ahmed Body Baratta, Daniel Jacob 01 September 2019 (has links) (PDF) Testing done on the flat-back Ahmed Body and other bluff bodies has shown the existence of a bi-stable reflectional symmetry-breaking wake at Reynolds numbers ranging from 340 to 2.41 x 106. Several methods of flow control, both active and passive, have been used to improve the efficiency of the Ahmed body but their effect on the bi-stable nature of the wake has not been investigated. This work details the experimental investigation done to determine if piezoelectrically driven synthetic jet actuators are capable of suppressing the bi-stable wake effects observed behind the Ahmed Body. The synthetic jets were designed and manufactured to have a maximum total coefficient of momentum of 1.0E-3 with a frequency range up to 2000 Hz or F+ = 17.25. The piezoelectric actuators used were bimorph bending disks with no center shim and were driven by a square waveform. Pressure data was collected from 25 pressure ports on the rear of the model at 625 Hz for 600 seconds per run and filtered using a lowpass filter at 35 Hz to remove interference. Center of Pressure probability distributions and Principle Component Analysis were used to identify wake shapes and modes. Results with no jet actuation showed good agreement with previously published work on the Ahmed Body. It was found that the actuation frequency had an effect on the ability of the synthetic jets to affect the wake. Actuating at F+ = 1 (116 Hz) showed a bi-stable wake with an even distribution between wake modes. Higher actuation frequencies showed either a skewed distribution with a weakening of the bi-stable effects (4 < F+ < 8) or a complete removal of the bi-stable distribution (8 < F+ < 12). Frequencies higher than F+ = 12 did not show any effect on the bi-stable distribution. There was a negative correlation between actuation frequency and average wake pressure; it is theorized that the synthetic jets enhance mixing in the shear layer around the recirculation bubble in the wake to decrease average pressure. Flow Control Bi-stable Ahmed Body Wind Tunnel Synthetic Jet Aerodynamics and Fluid Mechanics
23	Active Separation Control of High-Re Turbulent Separated Flow over a Wall-Mounted Hump using RANS, DES, and LES Turbulence Modeling Approaches Gan, Subhadeep 03 August 2010 (has links) No description available. Mechanical Engineering CFD Separated flow Active flow control Steady Suction Synthetic Jet
24	Analyse expérimentale et modélisation numérique d’un actionneur plasma de type jet synthétique / Experimental analysis and numerical modeling of a plasma synthetic jet actuator Laurendeau, François 18 October 2016 (has links) De nombreuses recherches sont actuellement menées afin de réduire les émissions polluantesdes aéronefs. Le contrôle actif des écoulements aérodynamiques est une piste envisagéepour répondre à ces enjeux. Parmi les technologies de contrôle en développement, lestechnologies plasma offrent plusieurs avantages, dont la compacité, la simplicité de mise enoeuvre et la réactivité. Ce travail de thèse a été consacré à l’étude d’un actionneur plasmade type jet synthétique. Il se présente sous la forme d’une petite cavité insérée en paroiet reliée à l’extérieur par une tuyère. Un arc électrique est généré dans la cavité, ce quientraîne une augmentation de la pression de l’air dans celle-ci. Par conséquent, un jet estproduit à la sortie de la tuyère, et celui-ci peut interagir avec l’écoulement extérieur. A lasuite de cette phase d’éjection, de l’air extérieur est naturellement aspiré par la cavité, cequi permet au processus d’être répété à des fréquences pouvant atteindre plusieurs kilohertz.L’objectif de ce travail de thèse est de construire un modèle numérique capable dereproduire ces phénomènes physiques. Pour cela, un calcul aérodynamique de type LargeEddy Simulation est mis en oeuvre. L’action du plasma d’arc est prise en compte au traversde termes sources dans l’équation de l’énergie. Ces derniers sont notamment calculés grâceà l’hypothèse d’équilibre thermodynamique local dans le plasma. De plus, l’augmentationde la température dans la partie solide de l’actionneur est simulée lorsque celui-ci est opéréà haute-fréquence. Les résultats du modèle numérique sont comparés à des mesures de vitesseeffectuées lorsque l’actionneur fonctionne dans un environnement extérieur au reposet lorsque celui-ci interagit avec une couche limite. / Nowadays, many studies are conducted in order to decrease greenhouse gases and noiseemissions from aircrafts. Active aerodynamic flow control is a way considered to meet thesechallenges. Among developed technologies of control, plasma actuators offer several advantages,including compactness, easy implementation and fast response. This thesis is devotedto the study of a plasma synthetic jet actuator which comes in the form of a small cavityinserted in wall and connected to the environment through a nozzle. An electrical arc isgenerated in the cavity, resulting in an increase of the cavity air pressure. Consequently,a jet is produced at the nozzle exhaust that can interact with the external flow. After thisejection phase, an aspiration phase naturally occurs, allowing the process to be repeatedat a frequency that can reach several kilohertz. This thesis aims at building a numericalmodel able to reproduce these physical phenomena. To do so, a Large Eddy Simulationis performed. The action of the plasma arc is taken into account through source terms inthe energy equation. In particular, these source terms are calculated using the assumptionof local thermodynamic equilibrium in the plasma. In addition, the heating of the actuatormaterials is simulated when it is operated at high frequency. The results from the numericalmodel are compared with velocity measurements, carried out when the actuator works ina quiescent environment and when it interacts with a boundary layer. Plasma Jet synthétique Contrôle actif d’écoulement LES PIV Cedre Plasma Synthetic jet Active flow control LES PIV Cedre 532
25	Techniques to inject pulsating momentum Kranenbarg, Jelle January 2020 (has links) Hydro power plants are an essential part of the infrastructure in Sweden as they stand for a large amount of the produced electricity and are used to regulate supply and demand on the electricity grid. Other renewable energy sources, such as wind and solar power, have become more popular as they contribute to a fossil free society. However, wind and solar power are intermittent energy sources causing the demand for regulating power on the grid to increase. Hydro power turbines are designed to operate at a certain design point with a specific flow rate. The plants are operated away from the design point when used to regulate the supply and demand of electricity. This can cause a specific flow phenomenon to arise in the draft tube at part load conditions called a Rotating Vortex Rope (RVR) which causes dangerous pressure fluctuation able to damage blades and bearings. A solution to mitigate a RVR is to inject pulsating momentum into the draft tube by using an actuator operating at a certain frequency. A literature study was conducted and three techniques were numerically simulated using ANSYS Workbench 19.0 R3; a fluidic oscillator, a piston actuator and a synthetic jet actuator. A dynamic mesh was used to simulate the movement of the piston actuator and diaphragm of the synthetic actuator whilst the mesh of the fluidic oscillator was stationary. The relative errors of the three numerical models were all below 3 %. All devices showed promising results and could potentially be used to mitigate a RVR because they all have the ability to produce high energy jets. The fluidic oscillator had an external supply of water, whereas the other two did not, which means that it could inject the largest mass flow. The piston actuator required a driving motor to move the piston. The diaphragm of the synthetic jet actuator was moved by a Piezoelectric element. Advantages of the fluidic oscillator are that it has no moving parts, in contrary to the two other devices, it can directly be connected to the penstock or draft tube to obtain the required water supply and it is easy to install. It will most likely also be smaller compared to the other two for the same mass flow rate. It does however not generate a pulsating jet, but rather an oscillating jet. The other two devices generate pulsating jets, but have problems with low pressure areas during the intake stroke which can cause cavitation problems. These areas cause the formation of vortex rings close to the outlet. Simulations showed that a coned piston together with a coned cylinder outlet could decrease losses by almost 16 % compared to a normal piston and cylinder. It also decreased the risk for cavitation and the required force to move the piston. Otherwise, a shorter stroke length for a constant cylinder diameter or a longer stroke length for a constant volume displacement also decreased the risk for cavitation and required force. The gasket between the piston and cylinder is a potential risk for leakage. A solution to avoid critical low pressure areas is to install an auxiliary fluid inlet or valve which opens at a certain pressure for the piston actuator as well as the synthetic jet actuator. This will also allow larger mass flow rates and a higher injected momentum. Both devices are more complicated to install and require likely more maintenance compared to the fluidic oscillator. However, there exist many possible design options for the piston actuator. The design of the synthetic jet is more limited because of the diaphragm. The amplitude of the diaphragm also has a direct effect on the pressure levels. The losses increased proportional to the mass flow to the power of three which suggests that it is better to install many small actuators instead of a few large ones. Hydro power Rotating Vortex Rope Flow control Fluidic actuator Synthetic jet actuator Piston actuator CFD Fluid Mechanics and Acoustics Strömningsmekanik och akustik
26	Etude et qualification aérothermodynamique et électrique d'un actionneur plasma de type jet / Aerothermodynamic and electrical study of a Plasma Synthetic Jet actuator for flow control Hardy, Pierrick 09 May 2012 (has links) L’amélioration des performances aérodynamiques et environnementales est un enjeu majeur dans le domaine des transports terrestres et aériens. Pour pouvoir répondre à ses exigences, une des solutions est de contrôler les écoulements. Pour cela, des actionneurs performants sont nécessaires. Une technique innovante, le jet synthétique par plasma (JSP), consiste à appliquer une décharge haute tension dans une micro cavité. Un plasma est ainsi créé dans la chambre augmentant en quelques microsecondes la température et la pression du gaz générant un micro-jet par l’orifice de l’actionneur. Le but de la thèse est de développer cet actionneur, d’en comprendre son fonctionnement et de le mettre en oeuvre pour contrôler le bruit d’un jet subsonique à grand nombre de Mach.La première partie de l’étude s’applique à définir les besoins pour le contrôle d’écoulement et de réaliser un prototype d’actionneur. Il est ensuite caractérisé expérimentalement par des mesures de la décharge électrique et de l’aérodynamique du micro-jet. En s’inspirant du modèle de Braginskii, un modèle simple de la décharge électrique est réalisé et appliqué au JSP. Le rendement de l’actionneur en est déduit. Le modèle de Braginskii modifié est ensuite couplé à une modélisation URANS ce qui permet de simuler le fonctionnement en fréquence de l’actionneur. Ces résultats sont ensuite comparés avec les mesures de l’aérodynamique du micro-jet et montrent un excellent accord.L’actionneur est ensuite mis en application pour contrôler le bruit de jet. En premier lieu, des visualisations par strioscopie de l’interaction des micro-jets avec le jet principal sont effectuées. Des mesures acoustiques sont ensuite réalisées etmettent en évidence que les JSP sont de bons candidats pour contrôler le bruit de jet. / Improvement of aerodynamics and environmental performances is a major issue for terrestrial and aeronautical industry.For fulfilling increasing demand, one of the answers is flow control. To achieve flow control, high performance actuators are needed. An innovative technique called Plasma Synthetic Jet actuator consists on applying an electrical discharge in asmall cavity. Plasma is created and increases gas temperature and pressure which results on the creation of a micro-jet through cavity opening.The PhD objectives are to develop the PSJ actuator, to describe actuator mechanisms and to apply it for controlling noise of a high subsonic jet. The first part of the study consists on defining flow control needs and on developing a PSJ actuator prototype. Then,actuator performances are characterised using electrical measurements of the discharge and using aerodynamic measurements. These measurements show that an electrical model of the discharge is needed. Based on the Braginskii model, a simple model is carried out and is applied to the actuator. Efficiency of the PSJ is deduced.The modified Braginskii model is then coupled with an URANS model to achieve frequency modelling of the actuator. Results match aerodynamics measurements .PSJ actuators are applied for controlling jet noise in a second part of the study. Schlieren visualisations are used to show micro-jet interaction with the main jet. Acoustic measurements are then performed and show that the PSJ is a goodactuator to control high subsonic jet noise. Contrôle d’écoulement Contrôle de bruit de jet Jet synthétique Actionneur Plasma Décharge électrique Flow control Jet noise control Synthetic jet actuator Plasma Electrical discharge 530
27	Estudo dos efeitos de um jato sintético simulado numericamente no atraso da separação de uma camada limite sobre um aerofólio hipotético / Study of the effects of a numerically simulated synthetic jet on the delay of separation of the boundary layer on a hipothetical airfoil Mello, Hilton Carlos de Miranda 28 November 2005 (has links) A realização deste trabalho tem como objetivo fundamental estudar os efeitos dos atuadores de jato sintético no escoamento de uma camada limite desenvolvida sobre uma placa plana e um aerofólio hipotético. A interação dos jatos sintéticos com um escoamento transversal pode conduzir a uma aparente modificação da forma aerodinâmica de corpos rombudos e, dessa forma, fornecer uma maneira de controle da separação na camada limite. Estudos recentes demonstram que tipos diferentes de escoamentos podem ser produzidos pelo atuador dependendo da oscilação da membrana. Um método numérico para solução das equações de Navier-Stokes incompressíveis bidimensionais na formulação vorticidade-velocidade é utilizado neste trabalho. As equações governantes são discretizadas utilizando-se métodos de diferenças finitas compactas de sexta ordem para as derivadas espaciais. A equação de Poisson para a componente da velocidade normal é resolvida por um método iterativo de sobre-relaxação em linhas sucessivas usando um esquema com malha composta para acelerar a convergência. Os resultados de simulações com diferentes valores de freqüência, amplitude e comprimento de fenda foram verificados através de uma análise de Fourier temporal. Através desta análise é verificado qual a melhor situação para se atrasar a separação da camada limite / This work has as a fundamental objective the study of the effects of synthetic jet actuators on the boundary layer flow on a flat plate and on a hypothetical airfoil. The interaction of synthetic jets with transverse flow can lead to an apparent modification in the aerodynamic shape of blunt bodies and, in that way, supply a means of control of transition within the boundary layer. Recent studies demonstrate that different types of flow may be produced by the actuator, depending on the amplitude of oscillation of the membrane. A numerical method for the solution of two-dimensional incompressible Navier-Stokes equations written in vorticity-velocity formulation is used in this work. The spatial derivatives are discretized with a sixth order compact finite differences scheme. The Poisson equation for the normal velocity component is solved by an iterative line successive over relaxation method and uses a multigrid full approximation scheme to accelerate the convergence. The results of simulations with different values of frequency, amplitude and slot length were verified through a temporal Fourier analysis. By way of this analysis it is verified which are the better parameters for the controlled delay of boundary layer separation active flow control atraso da separação Blasius boundary layer camada limite de Blasius camada limite de Falkner-Skan controle ativo de escoamento delay of separation Falkner-Skan boundary layer jato sintético synthetic jet
28	Resfriamento de componentes eletrônicos por jatos sintéticos tangenciais Trisch, Marino 22 June 2015 (has links) Submitted by Silvana Teresinha Dornelles Studzinski (sstudzinski) on 2016-02-04T15:21:28Z No. of bitstreams: 1 Marino Trisch_.pdf: 3535397 bytes, checksum: 4cc7a6dc219d9c91a6de57725e4515d1 (MD5) / Made available in DSpace on 2016-02-04T15:21:28Z (GMT). No. of bitstreams: 1 Marino Trisch_.pdf: 3535397 bytes, checksum: 4cc7a6dc219d9c91a6de57725e4515d1 (MD5) Previous issue date: 2015-06-22 / CAPES - Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Este trabalho apresenta um estudo experimental relacionado ao resfriamento de dispositivos eletrônicos utilizando jatos sintéticos direcionados de modo que o jato flua tangencialmente à superfície aquecida, utilizando para isso uma bancada experimental especialmente desenvolvida. Para o desenvolvimento deste trabalho foram analisados outros estudos relacionados ao assunto, simulados e experimentais, utilizando neste caso um alto-falante como membrana montada em conjunto com a estrutura da bancada para formar a câmara e consequentemente o gerador de jatos sintéticos. O jato sintético gerado irá resfriar um elemento de aquecimento que simula o funcionamento de um dispositivo eletrônico, posicionado tangencialmente em diversas posições de distância em relação à saída do jato. Os procedimentos de teste de resfriamento foram realizados na bancada experimental em diversos modos de funcionamento do elemento de aquecimento, utilizando temperatura média de 80 °C semelhante à temperatura máxima de trabalho de dispositivos eletrônicos. Para a geração do jato sintético foram aplicados sinais senoidais em frequências de pulsação entre 20 e 120 Hz e com amplitude de aproximadamente 7,52 V_p, que resulta em 20 Wrms de potência no gerador de jatos sintéticos. Nos testes utilizando potência fixa do elemento de aquecimento, a temperatura no elemento de aquecimento é monitorada. Em outro modo de teste, foi mantida uma temperatura constante e monitorada a potência máxima correspondente dissipada no elemento de aquecimento. Por fim, também foi realizado comparativo entre resfriamento eletrônico utilizando jatos sintéticos e método tradicional com a utilização de ventiladores, onde são utilizados três diferentes tamanhos de coolers acoplados à bancada experimental e arrefecendo o mesmo elemento de aquecimento, verificando e comparando velocidades e rendimento entre os métodos de resfriamento. / This paper presents an experimental study related to the cooling of electronic devices using synthetic jets directed so that the jet flows tangentially to the heated surface. A custom-built experimental test bench especially developed based on other studies related to the subject. In this case, a speaker was used as a membrane and installed in a cavity in the test bench to form the synthetic jet generator. The synthetic jet cools a heating element that simulates the operation of an electronic device, positioned tangentially at various distance in relation to the exit plane of the synthetic jet. Cooling test procedures were performed in the custom-built experimental test bench in various operation modes of the heating element, using an average temperature of 80 ° C which is similar to the operating temperature of electronic devices. To generate the synthetic jet, sinusoidal input signals were applied with frequencies between 20 and 120 Hz and with amplitude of approximately 7.52 Vp which resulted in 20 Wrms power consumed by generator. In tests using a fixed power dissipated by the heating element, the temperature drop is monitored in the heating element. In the other test mode, the temperature on the heating element was set at a constant value the maximum power dissipated in the heating element was measured. Finally, comparisons were also performed between the cooling performance of synthetic jets and the conventional method with the use of three different coolers sizes. The same tests were performed on the same heating element and the corresponding velocities and cooling performance between the two methods were compared. Jato sintético Número de nusselt Número de strouhal Resfriamento Eletrônico Experimental Synthetic jet Nusselt number Strouhal number Cooling Electronic Experimental
29	Estudo dos efeitos de um jato sintético simulado numericamente no atraso da separação de uma camada limite sobre um aerofólio hipotético / Study of the effects of a numerically simulated synthetic jet on the delay of separation of the boundary layer on a hipothetical airfoil Hilton Carlos de Miranda Mello 28 November 2005 (has links) A realização deste trabalho tem como objetivo fundamental estudar os efeitos dos atuadores de jato sintético no escoamento de uma camada limite desenvolvida sobre uma placa plana e um aerofólio hipotético. A interação dos jatos sintéticos com um escoamento transversal pode conduzir a uma aparente modificação da forma aerodinâmica de corpos rombudos e, dessa forma, fornecer uma maneira de controle da separação na camada limite. Estudos recentes demonstram que tipos diferentes de escoamentos podem ser produzidos pelo atuador dependendo da oscilação da membrana. Um método numérico para solução das equações de Navier-Stokes incompressíveis bidimensionais na formulação vorticidade-velocidade é utilizado neste trabalho. As equações governantes são discretizadas utilizando-se métodos de diferenças finitas compactas de sexta ordem para as derivadas espaciais. A equação de Poisson para a componente da velocidade normal é resolvida por um método iterativo de sobre-relaxação em linhas sucessivas usando um esquema com malha composta para acelerar a convergência. Os resultados de simulações com diferentes valores de freqüência, amplitude e comprimento de fenda foram verificados através de uma análise de Fourier temporal. Através desta análise é verificado qual a melhor situação para se atrasar a separação da camada limite / This work has as a fundamental objective the study of the effects of synthetic jet actuators on the boundary layer flow on a flat plate and on a hypothetical airfoil. The interaction of synthetic jets with transverse flow can lead to an apparent modification in the aerodynamic shape of blunt bodies and, in that way, supply a means of control of transition within the boundary layer. Recent studies demonstrate that different types of flow may be produced by the actuator, depending on the amplitude of oscillation of the membrane. A numerical method for the solution of two-dimensional incompressible Navier-Stokes equations written in vorticity-velocity formulation is used in this work. The spatial derivatives are discretized with a sixth order compact finite differences scheme. The Poisson equation for the normal velocity component is solved by an iterative line successive over relaxation method and uses a multigrid full approximation scheme to accelerate the convergence. The results of simulations with different values of frequency, amplitude and slot length were verified through a temporal Fourier analysis. By way of this analysis it is verified which are the better parameters for the controlled delay of boundary layer separation atraso da separação camada limite de Blasius camada limite de Falkner-Skan controle ativo de escoamento jato sintético active flow control Blasius boundary layer delay of separation Falkner-Skan boundary layer synthetic jet
30	An H-Infinity norm minimization approach for adaptive control Muse, Jonathan Adam 12 July 2010 (has links) This dissertation seeks to merge the ideas from robust control theory such as H-Infinity control design and the Small Gain Theorem, L stability theory and Lyapunov stability from nonlinear control, and recent theoretical achievements in adaptive control. The fusion of frequency domain and linear time domain ideas allows the derivation of an H-Infinity Norm Minimization Approach (H-Infinity-NMA) for adaptive control architecture that permits a control designer to simplify the adaptive tuning process and tune the uncertainty compensation characteristics via linear control design techniques, band limit the adaptive control signal, efficiently handle redundant actuators, and handle unmatched uncertainty and matched uncertainty in a single design framework. The two stage design framework is similar to that used in robust control, but without sacrificing performance. The first stage of the design considers an ideal system with the system uncertainty completely known. For this system, a control law is designed using linear H-Infinity theory. Then in the second stage, an adaptive process is implemented that emulates the behavior of the ideal system. If the linear H-Infinity design is applied to control the emulated system, it then guarantees closed loop system stability of the actual system. All of this is accomplished while providing notions of transient performance bounds between the ideal system and the true system. Extensions to the theory include architectures for a class of output feedback systems, limiting the authority of an adaptive control system, and a method for improving the performance of an adaptive system with slow dynamics without any modification terms. Applications focus on using aerodynamic flow control for aircraft flight control and the Crew Launch Vehicle. Flow control Nonlinear systems Limited authority Fast adaptation Slow dynamics Flight control Uncertain system Synthetic jet Launch vehicle Lyapunov stability Adaptive control systems

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