Numerical Study of Internal Flow Structures in a Sweeping Jet Actuator

Kara, Kursat

doi:10.2514/6.2015-2424

Cited by 25 publications

(14 citation statements)

References 23 publications

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“…From their applications in flow control, it is interesting to mention their use in combustion control [3], flow deflection and mixing enhancement [4], flow separation modification in airfoils [5], boundary layer modification on hump diffusers used in turbomachinery [6], flow separation control on compressors stator vanes [7], gas turbine cooling [8], drag reduction on lorries [9], and noise reduction in cavities [10].Despite the existence of particular fluidic oscillator configurations, like the one introduced by Uzol and Camci [11], which was based on two elliptical cross-sections placed transversally and an afterbody located in front of them, or the one proposed by Huang and Chang [12], which was a V-shaped fluidic oscillator, most of the recent studies on oscillators focused on two main, very similar, canonical geometries, which Ostermann et al [13] called the angled and the curved oscillator geometries. Some very recent studies on the angled geometry are [13][14][15][16][17][18][19][20][21][22][23], while the curved geometry was studied by [4,10,13,[23][24][25][26][27][28][29][30][31][32][33]. Ostermann et al [13], compared both geometries, concluding that the curved one was energetically the most efficient.One of the first analyses of the internal flow on an angled fluidic oscillator was undertaken by Bobusch et al [17].…”

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confidence: 99%

Analysis of the Forces Driving the Oscillations in 3D Fluidic Oscillators

Baghaei

Bergadà

2019

Energies

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One of the main advantages of fluidic oscillators is that they do not have moving parts, which brings high reliability whenever being used in real applications. To use these devices in real applications, it is necessary to evaluate their performance, since each application requires a particular injected fluid momentum and frequency. In this paper, the performance of a given fluidic oscillator is evaluated at different Reynolds numbers via a 3D-computational fluid dynamics (CFD) analysis. The net momentum applied to the incoming jet is compared with the dynamic maximum stagnation pressure in the mixing chamber, to the dynamic output mass flow, to the dynamic feedback channels mass flow, to the pressure acting to both feedback channels outlets, and to the mixing chamber inlet jet oscillation angle. A perfect correlation between these parameters is obtained, therefore indicating the oscillation is triggered by the pressure momentum term applied to the jet at the feedback channels outlets. The paper proves that the stagnation pressure fluctuations appearing at the mixing chamber inclined walls are responsible for the pressure momentum term acting at the feedback channels outlets. Until now it was thought that the oscillations were driven by the mass flow flowing along the feedback channels, however in this paper it is proved that the oscillations are pressure driven. The peak to peak stagnation pressure fluctuations increase with increasing Reynolds number, and so does the pressure momentum term acting onto the mixing chamber inlet incoming jet.Original fluidic oscillators design goes back to the 60 s and 70 s. Their outlet frequency ranges from several Hz to KHz and the flow rate is usually of a few dm 3 /min. From their applications in flow control, it is interesting to mention their use in combustion control [3], flow deflection and mixing enhancement [4], flow separation modification in airfoils [5], boundary layer modification on hump diffusers used in turbomachinery [6], flow separation control on compressors stator vanes [7], gas turbine cooling [8], drag reduction on lorries [9], and noise reduction in cavities [10].Despite the existence of particular fluidic oscillator configurations, like the one introduced by Uzol and Camci [11], which was based on two elliptical cross-sections placed transversally and an afterbody located in front of them, or the one proposed by Huang and Chang [12], which was a V-shaped fluidic oscillator, most of the recent studies on oscillators focused on two main, very similar, canonical geometries, which Ostermann et al. [13] called the angled and the curved oscillator geometries. Some very recent studies on the angled geometry are [13][14][15][16][17][18][19][20][21][22][23], while the curved geometry was studied by [4,10,13,[23][24][25][26][27][28][29][30][31][32][33]. Ostermann et al. [13], compared both geometries, concluding that the curved one was energetically the most efficient.One of the first analyses of the internal flow on an angled fluidic oscillator was undertaken by B...

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confidence: 99%

Analysis of the Forces Driving the Oscillations in 3D Fluidic Oscillators

Baghaei

Bergadà

2019

Energies

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“…• Woszidlo R. [20] • Raman G. [19] • Ott C. The literature gives numerous characterization methods such as local time-resolved at high sweeping frequency ( [8], [19], [20], [21]), spatially-resolved snapshots ( [22]), spacetime resolved at low sweeping frequency ( [23], [22], [24]), numerical analysis and simulations ( [25], [26], [27], [28]). Since the flow control actuation by sweeping jet is relatively recent [29], the state of art shows a lack of characterization process in order to correctly define the high frequency dynamic response.…”

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confidence: 99%

High frequency characterization of a sweeping jet actuator

Ott¹,

Gallas²,

Delva³

et al. 2019

Sensors and Actuators A: Physical

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Sweeping jets are an emerging type of actuators that have gained interest due to their potential use in flow control applications. The working principle of these devices is based on the bi-stable attachment of a jet to adjacent walls. They are able to produce unsteady blowing within a wide range of operating frequencies. Nevertheless, the state of art shows a lack of space-time characterization of these actuators for high sweeping frequencies. This paper resents a conditional approach that reconstructs the spatial dynamic response of sweeping jets for sweeping frequencies above 500 Hz. The time-dependent velocity is measured with two single-hot-wire sensors: a reference one placed at the edge of the exit nozzle, and a flying one. The method is then tested to characterize the flow at the exit nozzle of an in-house sweeping jet actuator with 1mm space resolution, and 50 µs time resolution. These measurements are performed with a sweeping frequency of 639 Hz. Overall this paper demonstrates that the conditional approach is very useful for understanding the physics of flow control actuators.

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“…Active Flow control (AFC) as a method to enhance lift has a great potential to reduce the size and weight of control surfaces [1][2][3][4][5][6][7]. AFC has been used to control the separated flow of vertical tails to enhance aerodynamic performance and mitigate flutter [8][9][10][11][12][13][14][15][16][17]. The research of Boeing and NASA in [8][9][10][11][12][13][14][15] on vertical tails using sweeping jets and synthetic jets AFC represents the state of the art.…”

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confidence: 99%

“…A side force increase of 13% to 16% was estimated at 30° rudder deflection for critical sideslip range between β = 0° and -7.5° with the activation of AFC. Kara [16,17] analyzed the complex flow inside the sweeping jet for design optimization of actuator geometry with minimum pressure loss. However, those studies [8][9][10][11][12][13][14][15][16][17] have not report sufficient results on energy expenditure of the sweeping jets actuators, which tend to suffer large energy loss due to jet sweeping, turning, and flow separation.…”

mentioning

confidence: 99%

“…Kara [16,17] analyzed the complex flow inside the sweeping jet for design optimization of actuator geometry with minimum pressure loss. However, those studies [8][9][10][11][12][13][14][15][16][17] have not report sufficient results on energy expenditure of the sweeping jets actuators, which tend to suffer large energy loss due to jet sweeping, turning, and flow separation. This paper explores a new control surfaces active flow control using Co-Flow Jet (CFJ) airfoil, which is a zero-net mass flux (ZNMF) flow control that has demonstrated radical lift enhancement, drag reduction, and ultra-high stall AoA [2,5,18,19,20,21,22,23,24,25,26,27].…”

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Aircraft Control Surfaces Using Co-flow Jet Active Flow Control Airfoil

Zhang

Yang

et al. 2018

2018 Applied Aerodynamics Conference

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This paper investigates the effects using high lift zero-net mass-flux Co-Flow Jet (CFJ) active flow control airfoil for aircraft control surfaces with plain flaps and with no flap. The goal is to reduce the size and weight of conventional aircraft control surfaces and save energy expenditure.Two-dimensional simulation of NACA 0012 airfoil used as a control surface is conducted for parametric trade study using a Reynolds-averaged Navier-Stokes (RANS) solver with Spalart-Allmaras (SA) model. A 5th order WENO scheme for the inviscid flux and a 4th order central differencing for the viscous terms are used to resolve the Navier-Stokes equations.The 2D numerical studies indicate that the CFJ airfoil for aircraft control surfaces with a plain flap can dramatically increase the lift coefficient and aerodynamic efficiency simultaneously compared with the conventional control surface with the same size of flap and deflection angle. CFJ airfoil control surface shows great potential to substantially reduce the size and weight of conventional aircraft control surfaces with high control authority.A series of trade study is done based on NACA0012 airfoil for control surface. The CFJ airfoil is modified from the baseline NACA0012 airfoil by translating the upper surface downward by 0.1%C. A constant deflection angle of 30° is used.The final preferred configuration has the flap length of 35%C, deflection angle of 30°, injection location at 2%C from leading edge, injection slot size of 0.5%C, and suction slot right upstream of the flap with the size twice larger than the injection size.The final trade study is to investigate the effect of injection jet momentum coefficient Cµ at 0.05, 0.15, 0.25. The lower Cµ value of 0.05 is the most energy cost effective to increase the lift coefficient. Comparing with the baseline airfoil with the same flap size and deflection angle, at sideslip angle of 0°, the case of Cµ=0.05 of the final configuration achieves a lift coefficient increase by 106.4% from CL=1.09 to 2.25 at very low power coefficient of 0.0285. At the same time, it substantially reduces the drag by 67.17%. All these compound effects result in an increase of aerodynamic efficiency(including CFJ power consumption) by 232.2%. In other words, while the CFJ control surface substantially increases the lift, it simultaneously reduces the net energy cost in a dramatical manner. This even does not count the additional benefit due to the reduced control surface size and weight Finally, CFJ airfoil with no flap is also simulated at injection jet momentum coefficient Cµ=0.05, 0.10, 0.15, 0.20, 0.25 and 0.30. The result shows that the maximum lift coefficients of 3.048 (an increase of 114%) is achieved at Cµ=0.30 with a reduced drag. The aerodynamic efficiency of the flapless control surface is not studied in this work and will be reported in future.The results indicate that flapless control surface may be a feasible option.

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Numerical Study of Internal Flow Structures in a Sweeping Jet Actuator

Cited by 25 publications

References 23 publications

Analysis of the Forces Driving the Oscillations in 3D Fluidic Oscillators

Analysis of the Forces Driving the Oscillations in 3D Fluidic Oscillators

High frequency characterization of a sweeping jet actuator

Aircraft Control Surfaces Using Co-flow Jet Active Flow Control Airfoil

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