Aerodynamic Flow Control

Greenblatt, David; Wygnanski, I.; Rumsey, Christopher L.

doi:10.1002/9780470686652.eae019

Cited by 13 publications

(8 citation statements)

References 70 publications

(63 reference statements)

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“…We consider arrangements where swirl is introduced in a co-rotating (COR) or counter-rotating (CTR) manner. The magnitude of the wall-normal velocity is chosen such that the coefficient of momentum is on the same order of magnitude as in previous successful separation control studies [49]. Moreover, the magnitude of azimuthal velocity is selected such that the maximum velocity is on the same order of magnitude as the freestream, which can be regarded as the approximate upper bound for rotational motion induced by vortex generators.…”

Section: B Actuation Setupmentioning

confidence: 99%

Effects of Wall-Normal and Angular Momentum Injections in Airfoil Separation Control

Munday

Taira

2018

AIAA Journal

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The objective of this computational study is to quantify the influence of wall-normal and angular momentum injections in suppressing laminar flow separation over a canonical airfoil. Open-loop control of fully separated, incompressible flow over a NACA 0012 airfoil at α = 9 • and Re = 23, 000 is examined with large-eddy simulations. This study independently introduces wall-normal momentum and angular momentum into the separated flow using swirling jets through model boundary conditions. The response of the flow field and the surface vorticity fluxes to various combinations of actuation inputs are examined in detail. It is observed that the addition of angular momentum input to wall-normal momentum injection enhances the suppression of flow separation. Lift enhancement and suppression of separation with the wall-normal and angular momentum inputs are characterized by modifying the standard definition of the coefficient of momentum. The effect of angular momentum is incorporated into the modified coefficient of momentum by introducing a characteristic swirling jet velocity based on the non-dimensional swirl number. With this single modified coefficient of momentum, we are able to categorize each controlled flow into separated, transitional, and attached flows. Nomenclature A = Planform area Aj = Actuator jet area c = Chord length CD = Coefficient of drag CL = Coefficient of lift Cµ = Coefficient of momentum C * µ = Modified coefficient of momentum Fx = Drag force Fy = Lift force Gn = Wall-normal momentum flux G θ = Tangential momentum flux lz = Spanwise extent M∞ = Freestream Mach number n = Wall-normal unit vector Nact = Number of actuators p = Pressure p = Time-average pressure p∞ = Freestream pressure Q = Q criteria r = Radial direction ra = Radius of actuator Re = Reynolds number RMS = Root mean square S = Swirl number t = Time u = (ux, uy, uz) = Velocity (streamwise, vertical, spanwise) u = (u x , u y , u z ) = Velocity fluctuation (streamwise, vertical, spanwise) u = (ux, uy, uz) = Time-average velocity (streamwise, vertical, spanwise) Uc = Convective velocity uj = Characteristic jet velocity u * j = Modified characteristic jet velocity un = Wall-normal actuator velocity u θ = Azimuthal/rotational actuator velocity uτ = Friction velocity U∞ = Freestream velocity x = (x, y, z) = Spatial coordinates (streamwise, vertical, spanwise) x + = (x + , y + , z + ) = Spatial coordinates in wall units Greek symbols α = Angle of attack, deg Γn = Wall-normal circulation of actuator jet ν = Kinematic viscosity ρ∞ = Freestream density Σ = Diffusive vorticity flux (σx, σy, σz) = Time-average wall-normal diffusive vorticity flux (streamwise, vertical, spanwise) τxy = Spanwise Reynolds stress ω = (ωx, ωy, ωz) = Vorticity (streamwise, vertical, spanwise)

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Section: B Actuation Setupmentioning

confidence: 99%

Effects of Wall-Normal and Angular Momentum Injections in Airfoil Separation Control

Munday

Taira

2018

AIAA Journal

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“…q=q o t ≤ n pulses f (3) q=0 t> n pulses f where f is the discharge frequency and n pulses is the number of pulses within a burst. In the current investigation, the discharge is modelled as a continuous and time-constant heat source ( q o ) acting over the given discharge time n pulses /f.…”

Section: Inverse Heat Transfer Data Reductionmentioning

confidence: 99%

“…Unsteady flow control techniques [1] that use periodic excitations to manipulate flow stability [2,3] have the potential to overcome any other active flow control technique in terms of efficiency [4] because of the relatively low amount of energy they use. DBD (Dielectric Barrier Discharge) plasma actuators belong to this category.…”

Section: Introductionmentioning

confidence: 99%

Experimental method to quantify the efficiency of the first two operational stages of nanosecond dielectric barrier discharge plasma actuators

Correale

Avallone

Starikovskiy

2016

J. Phys. D: Appl. Phys.

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“…The third basic approach for the implementation of variable pitot inlet cowls is the control of the flow boundary layer [130]. By avoiding flow separations, boundary layer control allows the use of slim geometries with low aerodynamic drag [131].…”

Section: Variable Annular Inlet Cowlmentioning

confidence: 99%

Review of variable leading-edge patents for aircraft wings and engine inlets and their relevance for variable pitot inlets in future supersonic transport

Kazula

Höschler

2021

CEAS Aeronaut J

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The motivation for designing variable pitot inlets for future supersonic transport (SST) is explained. A comprehensive overview of existing technological solutions for variable leading edges of aircraft wings and engine inlets is given. The advantages and limitations of over 80 solutions, as well as their relevance for application on variable pitot inlets for SST are described. The challenges of existing solution options concerning design methodologies, level of detail, and experience with a technology are identified.

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Aerodynamic Flow Control

Cited by 13 publications

References 70 publications

Effects of Wall-Normal and Angular Momentum Injections in Airfoil Separation Control

Effects of Wall-Normal and Angular Momentum Injections in Airfoil Separation Control

Experimental method to quantify the efficiency of the first two operational stages of nanosecond dielectric barrier discharge plasma actuators

Review of variable leading-edge patents for aircraft wings and engine inlets and their relevance for variable pitot inlets in future supersonic transport

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