Controlling flow separation over a curved ramp using vortex generator microjets

Introducing a fluid microjet into the boundary layer to increase fluid momentum and hence delay separation is a method for actively controlling a flow separation region. The present work numerically analyzed the control of a separation bubble behind a ramp. For this purpose, we first verified the st...

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Bibliographic Details
Published in:Physics of fluids (1994) 2022-11, Vol.34 (11)
Main Authors: Pour Razzaghi, Mohammad Javad, Masoumi, Yasin, Rezaei Sani, Seyed Mojtaba
Format: Article
Language:English
Subjects:
Arrays
Boundary layers
Flow separation
Fluid dynamics
Microjets
Physics
Upwash
Vortex generators
Vorticity
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Summary:Introducing a fluid microjet into the boundary layer to increase fluid momentum and hence delay separation is a method for actively controlling a flow separation region. The present work numerically analyzed the control of a separation bubble behind a ramp. For this purpose, we first verified the steady-state numerical results for a flow (without a jet) over the ramp against reliable experimental studies from the literature. Next, the effects of introducing a microjet to the flow were also verified. A jet was then placed at three different distances above the ramp to study its impact on various parameters, including velocities, Reynolds stresses, pressure, vorticity, streamlines, and the separation bubble size. As the jet was moved further back, the jet-induced upwash region grew considerably. Finally, the effects of using three identical jets were studied and compared against those of a single jet. The results indicated that using a three-jet array shrank the separation bubble. Using an array with d/D = 15 (distance between microjets over microjet diameter) can limit laterally the separation bubble about 2.75 times smaller than a single jet in the z-direction. Also, the employment of the jet managed to decrease the length of the separation zone in the x-direction up to 78%, in the case of Lx/L1 = 0.0143 (longitudinal distance of microjet from above the ramp over ramp length) and d/D = 10.
ISSN:1070-6631
1089-7666
DOI:10.1063/5.0122831