Separated Flow Transition on an LP Turbine Blade With Pulsed Flow Control

Bons, Jeffrey P.; Reimann, Daniel; Bloxham, Matthew

doi:10.1115/gt2006-90754

Cited by 12 publications

(10 citation statements)

References 19 publications

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“…Much work has gone into studying the equilibrium effects of flow control, airfoil design, and the general properties of flow around airfoils at these lower Reynolds numbers. Even so, the short term transient and detailed unsteady effects are not as widely documented, though material does exist ( [1,2,3]). For MAV applications, these time dependent effects of flow control become very important, as oscillations and spikes in the non-dimensional forces C l , C d , and C m can cause pitching and plunging.…”

Section: Introductionmentioning

confidence: 99%

Study of Transient and Unsteady Effects of Plasma Actuation in Transitional Flow over an SD7003 Airfoil

Riherd

Roy

Rizzetta

et al. 2011

49th AIAA Aerospace Sciences Meeting Including the New Horizons Forum and Aerospace Exposition

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The short term transient and long term periodic unsteady effects of pulsed plasma actuation are studied using an unsteady, compressible Navier-Stokes solver for the case of a partially separated transitional flow over an SD7003 airfoil at 4º angle of attack and at Re=40,000. Forcing magnitude and its effect on the flow field is examined. Distinctly different behavior is observed parameters are adjusted. The unsteady simulations show that the actuators have a quick transient response, reattaching the separated flow within 2 nondimensionalized units of time, but nearly independently of the forcing magnitude. Spikes in C l , C d , and C m are observed during reattachment, most likely due to vortex pairing at the trailing edge.

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Section: Introductionmentioning

confidence: 99%

Study of Transient and Unsteady Effects of Plasma Actuation in Transitional Flow over an SD7003 Airfoil

Riherd

Roy

Rizzetta

et al. 2011

49th AIAA Aerospace Sciences Meeting Including the New Horizons Forum and Aerospace Exposition

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“…A detailed description of this facility is given by Bons et al (2008b). The cascade tunnel includes a wake generator consisting of carbon-fiber tubes mounted on a motor-driven chain assembly in order to imitate the effects of a rotor.…”

Section: Low-speed Cascade Tunnel and Instrumentationmentioning

confidence: 99%

“…The L1A blade section is characterized by an aft-loaded pressure distribution with a base separation line beginning near 57% of the axial chord C x (C x = 0.143 m) and continuing to the trailing edge (Bons et al 2008b) for a Reynolds number of 21,000 based on axial chord. With a profile designed by the US Air Force Research Laboratory, the blade had a true chord measurement of 0.156 m and span of 0.38 m. Flow control is employed on the blade in the form of vortex generator jets, an active technique for delaying separation on low-pressure turbine blades.…”

Section: Introductionmentioning

confidence: 99%

Unsteady surface signature of a pulsed vortex generator jet

Disotell

Gregory

2011

J Vis

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Porous pressure-sensitive paint (PSP) is employed as a visualization technique for unsteady flow features on a low-pressure turbine blade. Recognizing that the measurement of high-frequency pressure fluctuations in unsteady flows-especially in turbomachinery-has proven to be difficult, recent advancements in the development of porous PSP have enabled the high-resolution measurement of pressure fields with frequency content of at least 20 kHz. In this work, PSP is applied to an L1A low-pressure turbine blade section (Re = 20,000 based on axial chord) to visualize the surface dynamics of a vortex generator jet (VGJ) pulsed at 10.6 Hz with nitrogen gas. Intensity-based, time-resolved PSP measurements reveal the development and the surface structure of the VGJ as well as the spanwise variation in the blowing profile.

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“…Since the profile is supposed to be applicable over a wide Reynolds number range, an active flow control method was favoured. Comparing different active methods, several authors like Bons et al [6] and Cerretelli and Kirtley [7] reported that unsteady excitation of the boundary layer flow is much more efficient than, for example, steady blowing. Cerretelli and Kirtley [7] achieved with fluidic oscillators a 60% reduction of injection momentum combined with a 30% reduction in blowing power compared to optimal steady blowing in a diffuser test rig.…”

Section: Introductionmentioning

confidence: 99%

Active Boundary Layer Control on a Highly Loaded Turbine Exit Case Profile

Kurz

Hoeger

Niehuis

2018

IJTPP

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A highly loaded turbine exit guide vane with active boundary layer control was investigated experimentally in the High Speed Cascade Wind Tunnel at the University of the German Federal Armed Forces, Munich. The experiments include profile Mach number distributions, wake traverse measurements as well as boundary layer investigations with a flattened Pitot probe. Active boundary layer control by fluidic oscillators was applied to achieve improved performance in the low Reynolds number regime. Low solidity, which can be applied to reduce the number of blades, increases the risk of flow separation resulting in increased total pressure losses. Active boundary layer control is supposed to overcome these negative effects. The experiments show that active boundary layer control by fluidic oscillators is an appropriate way to suppress massive open separation bubbles in the low Reynolds number regime.

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Separated Flow Transition on an LP Turbine Blade With Pulsed Flow Control

Cited by 12 publications

References 19 publications

Study of Transient and Unsteady Effects of Plasma Actuation in Transitional Flow over an SD7003 Airfoil

Study of Transient and Unsteady Effects of Plasma Actuation in Transitional Flow over an SD7003 Airfoil

Unsteady surface signature of a pulsed vortex generator jet

Active Boundary Layer Control on a Highly Loaded Turbine Exit Case Profile

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