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11	Active Flow Separation Control of a Laminar Airfoil at Low Reynolds Number Packard, Nathan Owen 27 June 2012 (has links) No description available. Aerospace Engineering Fluid Dynamics active flow control experimental fluid dynamics closed-loop control
12	Dynamic control of aerodynamic forces on a moving platform using active flow control Brzozowski, Daniel Paul 15 November 2011 (has links) The unsteady interaction between trailing edge aerodynamic flow control and airfoil motion in pitch and plunge is investigated in wind tunnel experiments using a two degree-of-freedom traverse which enables application of time-dependent external torque and forces by servo motors. The global aerodynamic forces and moments are regulated by controlling vorticity generation and accumulation near the trailing edge of the airfoil using hybrid synthetic jet actuators. The dynamic coupling between the actuation and the time-dependent flow field is characterized using simultaneous force and particle image velocimetry (PIV) measurements that are taken phase-locked to the commanded actuation waveform. The effect of the unsteady motion on the model-embedded flow control is assessed in both trajectory tracking and disturbance rejection maneuvers. The time-varying aerodynamic lift and pitching moment are estimated from a PIV wake survey using a reduced order model based on classical unsteady aerodynamic theory. These measurements suggest that the entire flow over the airfoil readjusts within 2-3 convective time scales, which is about two orders of magnitude shorter than the characteristic time associated with the controlled maneuver of the wind tunnel model. This illustrates that flow-control actuation can be typically effected on time scales that are commensurate with the flow's convective time scale, and that the maneuver response is primarily limited by the inertia of the platform. Unsteady aerodynamics Flow control Wind tunnel testing Experimental fluid dynamics Fluid dynamics Aerodynamic load Aerofoils Trailing edges (Aerodynamics)
13	Flow-induced sound and vibration due to the separated shear layer in backward-facing step and cavity configurations Velikorodny, Alexey S. 25 November 2009 (has links) Fully turbulent inflow past symmetrically located side branches mounted in a duct can give rise to pronounced flow oscillations due to coupling between separated shear layers and standing acoustic waves. Experimental investigation of acoustically-coupled flows was conducted using digital particle image velocimetry (DPIV) in conjunction with unsteady pressure measurements. Global instantaneous, phase- and time-averaged flow images, as well as turbulence statistics, were evaluated to provide insight into the flow physics during flow tone generation. Onset of the locked-on resonant states was characterized in terms of the acoustic pressure amplitude, frequency and the quality factor of the resonant pressure peak. Structure of the acoustic noise source is characterized in terms of patterns of generated acoustic power. In contrast to earlier work, the present study represents the first application of vortex sound theory in conjunction with global quantitative flow imaging and numerical simulation of the 2D acoustic field. In addition to the basic side branch configuration, the effects of bluff rectangular splitter plates located along the centerline of the main duct was investigated. The first mode of the shear layer oscillation was inhibited by the presence of plates, which resulted in substantial reduction of the amplitude of acoustic pulsations and the strength of the acoustic source. These results can lead to the development of improved control strategies for coaxial side branch resonators. Motivation for the second part of this study stems from the paper manufacturing industry, where air clamp devices utilize high-speed jets to position paper sheets with respect to other equipment. Thus, vibration of the paper sheet and turbulent flow that emerged from a planar curved nozzle between a flexible wall and a solid surface containing a backward-facing step (BFS) were investigated using high-speed photography and DPIV, respectively. The emphasis was on the characterization of the flow physics in the air clamp device, as well as of the shape of the paper sheet. For the control case, that involved a solid wall with a geometry that represented the time-averaged paper profile, hydrodynamic oscillation frequencies were characterized using unsteady pressure measurements. Experimentally obtained frequencies of the paper sheet vibration were compared to the hydrodynamic frequencies corresponding to the oscillations of the shear layer downstream of the BFS. Experimental Fluid mechanics, PIV Flow-induced sound and vibration Flow-acoustic coupling
14	Experimental System Effects on Interfacial Shape and Included Volume in Bubble Growth Studies Wickizer, Gabriel Benjamin 25 September 2012 (has links) No description available. Mechanical Engineering experimental fluid dynamics adiabatic single bubble nucleation and necking capillary flows interfacial profile and aspect ratio flow visualization
15	The effect of gas on multi-stage mixed-flow centrifugal pumps Dupoiron, Marine Agnes Nicole January 2018 (has links) The production from an oil reservoir is a mixture of liquids (oil and water) and gas, and is often maintained by using a pump placed in the well to ensure a continuous flow to the surface. Electrical Submersible Pumps consist of stacked centrifugal pump stages, each comprising a bladed impeller (rotating part) and diffuser (stationary part). In multiphase conditions, the gas tends to accumulate in the impeller, severely reducing the pressure produced by the pump. Radial-flow pumps operate in a plane perpendicular to their rotation axis, while mixed-flow pumps are characterised by a lower meridional angle (generally 40 to 80 degrees), and are generally better at handling gas-liquid mixtures. We first describe the impact of gas on the whole pumping system, from the reservoir to the storage facility, and give context to the subject. The available literature shows that the size of the gas bubbles present in the fluid is critical to the pump performance. A transparent, full-scale pump was built in order to explore the flow features in single and multiphase flows. Laser Doppler Velocimetry and high speed imaging in single phase flow showed a high turbulence level in the wake of the impeller blades, and recirculation cells at low flow rates. In gas-liquid conditions, we demonstrated that the bubble size varies within a pump stage, as break-up occurs at the impeller tip, and coalescence is dominant in the diffuser, especially because of recirculation. The first impeller acted as a mixer, and at moderate to high gas fractions (10 to 30%), the flow patterns at the stage level alternated between bubbly and radially separated flows. Finally, a dispersed-gas model was developed to predict the pressure rise in a mixed-flow pump impeller under gas-liquid conditions. This model based on the forces acting on a single spherical gas bubble, was implemented with a simplified, parametric representation of the flow field in a mixed-flow impeller. In the meridional direction, the Coriolis force opposes the centrifugal force and the adverse pressure gradient. Both forces tend to retain the gas bubble within the impeller. The relative magnitude of the drag force strongly depends on the maximal bubble diameter, which was determined as a function of the flow conditions and used to calculate the gas velocity through the impeller. This method resulted in a better agreement with the experimental data than a one-dimensional two-fluid model where the gas phase follows the same path as the liquid. We used the dispersed-gas model to give quantitative evidence that low blade and meridional angles reduce the gas accumulation and the associated performance degradation.
16	Internal Fluid Dynamics and Frequency Characteristics of Feedback-Free Fluidic Oscillators Tomac, Mehmet Nazim 20 May 2013 (has links) No description available. Aerospace Engineering experimental fluid dynamics flow control flow control actuators fluidic oscillator feedback-free fluidic oscillator jet interactions jet bifurcations
17	EXPERIMENTAL ASSESSMENT OF TRANS SONIC ROSSITER CAVITY IN DEVELOPING ACOUSTIC STREAMING AND ITS EFFECTS ON HEAT TRANSFER James E Twaddle (15339181) 29 April 2023 (has links) <p> </p> <p>Acoustic streaming is a phenomenon which occurs when acoustic excitations interact with a fluid (stationary or non-stationary). Exploitation of this phenomenon has the potential to open doors to new methods of flow control through the enhancement or diminishment of the present flow instabilities. A particular use of acoustic streaming shown by previous numerical studies is the enhancement of heat transfer in violation of the Reynold’s Analogy within a small range of Mach numbers and frequencies of periodic excitation. The focus of this thesis is to experimentally assess the usage of a Rossiter cavity in generating periodic acoustic excitations and its effects on the shear stress and heat transfer. </p> <p>In the present research, two large models are tested using a blow-down facility. The models are made of aluminum and Teflon and were developed to ensure optical access for infrared thermography. The geometries are tested at Mach number ranging from 0.373 to 0. 866. The target Mach number-frequency pair where significant heat transfer enhancement is a free stream Mach number at the cavity, Mc, of 0.75 and the frequency, fc, of 7.5 kHz. The cavity is tuned using the Rossiter equation with Rossiter constants k = 0.66 and y = 0.25. The heat transfer and skin friction enhancement are measured immediately upstream and downstream of the cavity and compared to the previous numerical studies.</p> <p>When testing the Teflon model with an ambient back pressure and 11 lb/s mass flow, a frequency of 7.8 kHz was generated by the cavity. For the aluminum model tested at a high vacuum and 3 lb/s mass flow, frequencies near 7, 10, and 20 kHz were generated by the cavity with 10 and 20 kHz appearing most often. High speed schlieren imaging was used to confirm the flow structures being generated in the flow. There was good agreement with the Rossiter modes at lower Mach numbers and moderate agreement at transonic Mach numbers. A correlation is presented which defines a band of Mach number-Reynolds number pairs which present with a discontinuous frequency behavior during operation of the wind tunnel. Measurable effects on both skin friction and heat transfer between tests with comparable operating conditions to a reference were observed and are presented.</p> Acoustic Streaming Heat Transfer Enhancement Experimental Fluid Dynamics Compressible Flow High Speed Imaging Measurement Techniques Model Design
18	Liquid Jet in Oscillating Crossflow: Characterization of Near-Field and Far-Field Spray Behavior Sharma, Arvindh R. 15 October 2015 (has links) No description available. Aerospace Materials Jet in crossflow Inlet air modulation Oscillating crossflow Liquid spray penetration Near-field spray Far-field spray Aerospace Propulsion Experimental Fluid Dynamics
19	A Characterization of Seal Whisker Morphology and the Effects of Angle of Incidence on Wake Structure Rinehart, Aidan Walker January 2016 (has links) No description available. Aerospace Engineering Aquatic Sciences Engineering Fluid Dynamics Mechanical Engineering seal whisker PIV biomimicry fluid dynamics particle image velocimetry bio-engineering engineering mechanical engineering aerospace engineering experimental fluid dynamics
20	On the convective velocity of large-scale structures in compressible axisymmetric jets Thurow, Brian S. 05 January 2005 (has links) No description available. compressibility compressible free shear layers experimental fluid mechanics fluid dynamics aerodynamic measurement techniques lasers high-repetition rate lasers advanced optical diagnostics compressible fluid dynamics

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