Design of a novel vortex-based feedback fluidic oscillator with numerical evaluation

Nili-Ahmadabadi, Mahdi; Cho, Dae‐Seung; Kim, Kyung Chun

doi:10.1080/19942060.2020.1826360

Cited by 12 publications

(2 citation statements)

References 26 publications

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“…Figure 7(a1) and (b1) show the complete attachment of the jet at the left end, and Figure 7(a2) and (b2) at the right end in the mixing chamber for two operating times of these oscillators, which is beneficial for the formation of the periodic oscillating jet. When the main jet adheres to one of the inner walls of the mixing chambers, it can induce less consumption of the jet momentum and a lower pressure loss inside the oscillators (Nili-Ahmadabadi et al , 2020). For both oscillators, a large recirculating bubble forms in the mixing chamber and small vortices from inside the feedback channels.…”

Section: Results and Interpretationsmentioning

confidence: 99%

Characterisation and comparison of unsteady actuators: a fluidic oscillator and a sweeping jet

Serrar¹,

Khlifi²,

Kourta

2021

HFF

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Purpose The purpose of this study is to compare two unsteady actuators: an oscillator and a sweeping jet. Both actuators can produce an oscillating jet of different amplitudes and frequencies without any moving parts, making them an attractive actuator concept. The Coanda effect phenomenon can explain the operating principles of these two unsteady actuators. Design/methodology/approach A numerical study was conducted to compare the amplitudes and frequencies of fluidic and sweeping jet (SJ) oscillators to obtain an efficient actuator to control separated flows at high Reynolds numbers. For this goal, two-dimensional unsteady Reynolds-averaged Navier-Stokes simulations were carried out using computational fluid dynamics (CFD) fluent code to evaluate the actuator performances. The discrete fast Fourier transform method determined the oscillation frequencies. Findings The oscillation frequencies gradually increase as the inlet pressure increases. The characteristics and dimensions of the vortices produced in the mixing chamber and feedback loops vary overtime when the injected fluid is swept sideways. The frequencies supplied by the SJ are stronger than those obtained by the fluidic oscillator, which may contribute to improving the aerodynamic performance at a lower power supply cost. Originality/value The existence of the splitter in the fluidic oscillator led to the production of separate pulses, which would be useful in various industrial applications, including active control of combustion and mixing processes while other applications such as flow separation control require SJs. With the latter actuator higher and interesting frequencies can be obtained, leading to efficient flow control.

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Section: Results and Interpretationsmentioning

confidence: 99%

Characterisation and comparison of unsteady actuators: a fluidic oscillator and a sweeping jet

Serrar¹,

Khlifi²,

Kourta

2021

HFF

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“…They showed that the oscillation frequency increased with increasing plasma power. Nili et al [23] designed a vortex-based feedback fluidic oscillator with a new configuration and evaluated its performance by the numerical solution of two-dimensional URANS equations.…”

Section: Flow Features Of Feedback Fluidic Oscillatorsmentioning

confidence: 99%

Flow features of a new fluidic oscillator using time-resolved PIV measurement and 3D numerical simulation

et al. 2021

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The current study measures the instantaneous velocity field inside and outside a new designed fluidic oscillator using planar time-resolved PIV technique on its symmetry plane in a water tank. The instantaneous velocity field showed that the interaction of four vortices with the jet was the main reason of jet oscillation inside the main chamber. Threedimensional transient numerical solutions were also carried out using Ansys-Fluent 2020R2 software. Four turbulence models (k-ε, k-ε RNG, k-ω, and k-ω SST) were used for these numerical solutions, which their results were then compared with the PIV results, qualitatively and quantitatively. The comparison showed that the k-ε and k-ω SST models were better for simulating the flow of the new oscillator. However, both models over-predicted the jet spreading angle and oscillation frequency compared to the PIV results. A similar PIV measurement was accomplished outside the conventional oscillator to compare the timeaveraged velocity fields of the new and conventional oscillators. The comparison showed that the amplitude and frequency of the new oscillator were, respectively, lower and higher than those of the conventional one. The time-averaged velocity and momentum flux outside the new oscillator was significantly higher than for the conventional one. Abbreviations A Throat area (m 2 ) D Throat height (m) D h Hydraulic diameter (m) Fr Oscillation frequency (1/s) f Oscillation frequency (1/s) H Domain height outside the oscillator (m) rate k Turbulence kinetic energy (m 2 /s 2

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Numerical study of the effect of geometric scaling of a fluidic oscillator on the heat transfer and frequency of impinging sweeping jet

Joulaei

Nili-Ahmadabadi

2023

Applied Thermal Engineering

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Design of a novel vortex-based feedback fluidic oscillator with numerical evaluation

Cited by 12 publications

References 26 publications

Characterisation and comparison of unsteady actuators: a fluidic oscillator and a sweeping jet

Characterisation and comparison of unsteady actuators: a fluidic oscillator and a sweeping jet

Flow features of a new fluidic oscillator using time-resolved PIV measurement and 3D numerical simulation

Numerical study of the effect of geometric scaling of a fluidic oscillator on the heat transfer and frequency of impinging sweeping jet

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