Nonlinear centrifugal instabilities in curved free shear layers

Es-Sahli, Omar; Sescu, Adrian; Afsar, Mohammed

doi:10.2514/6.2020-2239

Cited by 2 publications

(3 citation statements)

References 33 publications

(29 reference statements)

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“…In the present work, λ * is kept constant at 0.8 cm. Es-Sahli et al [18] elaborately studied the effect of λ * on the development of centrifugal instabilities in curved free shear layers. Periodic conditions are imposed in the spanwise direction, and extrapolation conditions are imposed at the top and bottom boundaries.…”

Section: Boundary Region Equations: a Parabolized Form Of The Navier-...mentioning

confidence: 99%

Gauging Centrifugal Instabilities in Compressible Free-Shear Layers via Nonlinear Boundary Region Equations

Es-Sahli,

Sescu,

Hattori

2024

Fluids

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Curved free shear layers emerge in many engineering problems involving complex flow geometries, such as the flow over a backward-facing step, flows with wall injection in a boundary layer, the flow inside side-dump combustors, or wakes generated by vertical axis wind turbines, among others. Previous studies involving centrifugal instabilities have mainly focused on wall-flows where Taylor instabilities between two rotating concentric cylinders or Görtler vortices in boundary layers are generated. Curved free shear layer flows, however, have not received sufficient attention, especially in the nonlinear regime. The present work investigates the development of centrifugal instabilities in a curved free shear layer flow in the nonlinear compressible regime. The compressible Navier–Stokes equations are reduced to the nonlinear boundary region equations (BREs) in a high Reynolds number asymptotic framework, wherein the streamwise wavelength of the disturbances is assumed to be much larger than the spanwise and wall-normal counterparts. We study the effect of the freestream Mach number M∞, the shear layer thickness δ, the amplitude of the incoming disturbance A, and the relative velocity difference across the shear layer ΔV on the development of these centrifugal instabilities. Our parametric study shows that, among other things, the kinetic energy of the curved shear layer flow increases with increasing ΔV and A decreases with increasing delta. It was also found that increasing the disturbance amplitude of the incoming disturbance leads to significant growth in the mushroom-like structure’s amplitude and renders the secondary instability structures more prominent, indicating increased mixing for all Mach numbers under consideration.

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Section: Boundary Region Equations: a Parabolized Form Of The Navier-...mentioning

confidence: 99%

Gauging Centrifugal Instabilities in Compressible Free-Shear Layers via Nonlinear Boundary Region Equations

Es-Sahli,

Sescu,

Hattori

2024

Fluids

Self Cite

View full text Add to dashboard Cite

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“…Görtler vortices appeared inside the boundary layer of concave-wall flow due to the imbalance between radial pressure gradients and centrifugal forces. 3,4 For concave-wall with different curvature, vortex formation occurred more rapidly. The mean velocity was altered significantly, and the laminar flow breakdown into turbulence.…”

Section: Introductionmentioning

confidence: 99%

“…Rayleigh 2 proposed that the Keluin–Helmholt instability was mixed with centrifugal instability which induced the Gӧrtler vortices along streamwise direction. Görtler vortices appeared inside the boundary layer of concave‐wall flow due to the imbalance between radial pressure gradients and centrifugal forces 3,4 . For concave‐wall with different curvature, vortex formation occurred more rapidly.…”

Section: Introductionmentioning

confidence: 99%

Numerical simulation and instability analysis of particles in liquid–solid concave‐wall jet using DPM‐RSM

Zhang

et al. 2022

Asia-Pacific J Chem Eng

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The liquid–solid concave‐wall jet existed in the vertical cylinder separator with tangential inlet; the instability near concave‐wall was the key factor for centrifugal separation. The effects of jet flowrate and wall curvature radius on the instability of solid‐particles were explored by experiment and numerical simulation. The results showed that the separation efficiency of particles decreased with the increase of centrifugal separation factor. The liquid–solid concave‐wall jet flow in separator was unstable in this study. The decay rate of jet maximum velocity on the concave‐wall was larger than that on plane‐wall jet. The ratio of half‐width value to wall curvature radius was about 0.08 at the circumferential direction 90°, which coincided with the critical value of centrifugal instability in strongly concave‐wall jet. The pressure, velocity, and vorticity fluctuated periodically along streamwise direction in separator. The fluctuation period was linearly related to the wall curvature, and the radial range of fluctuation was only half of jet width. The paired longitudinal vortices formed along the flow direction, and the longitudinal vortices merged at length 0.74 m from the inlet cross‐section along circumferential direction. After the position of vortices merged, the particle trajectory oscillated obviously.

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Nonlinear centrifugal instabilities in curved free shear layers

Cited by 2 publications

References 33 publications

Gauging Centrifugal Instabilities in Compressible Free-Shear Layers via Nonlinear Boundary Region Equations

Gauging Centrifugal Instabilities in Compressible Free-Shear Layers via Nonlinear Boundary Region Equations

Numerical simulation and instability analysis of particles in liquid–solid concave‐wall jet using DPM‐RSM

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