Stability and receptivity of boundary layers in a swirl flow channel

The analysis of the disturbances on a spiraling base flow is relevant for the design, operation, and control of technological devices such as parallel-disk turbines and swirl flow channel heat sinks. Spiraling inflow inside an annular cavity closed at the top and bottom is analyzed in the framework...

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Bibliographic Details
Published in:Acta mechanica 2018-10, Vol.229 (10), p.4005-4015
Main Authors: Herrmann-Priesnitz, B., Calderón-Muñoz, W. R., Soto, R.
Format: Article
Language:English
Subjects:
Amplification
Analysis
Base flow
Boundary layers
Boundary layers (Fluid dynamics)
Chebyshev approximation
Classical and Continuum Physics
Collocation methods
Computational fluid dynamics
Control
Design engineering
Disturbances
Dynamical Systems
Engineering
Engineering Thermodynamics
Flow stability
Fluid flow
Heat and Mass Transfer
Heat sinks
Inflow
Laminar flow
Original Paper
Parallel flow
Reynolds number
Solid Mechanics
Stability
Stability analysis
Theoretical and Applied Mechanics
Turbines
Velocity distribution
Vibration
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Summary:The analysis of the disturbances on a spiraling base flow is relevant for the design, operation, and control of technological devices such as parallel-disk turbines and swirl flow channel heat sinks. Spiraling inflow inside an annular cavity closed at the top and bottom is analyzed in the framework of modal and nonmodal stability theories. Local and parallel flow approximations are applied, and the inhomogeneous direction is discretized using the Chebyshev collocation method. The optimal growth of initial disturbances and the optimal response to external harmonic forcing are characterized by the exponential and the resolvent of the dynamics matrix. As opposed to plane Poiseuille flow, transient growth is small, and consequently, it does not play a role in the transition mechanism. The transition is attributed to a crossflow instability that occurs because of the change in the shape of the velocity profile due to rotational effects. Agreement is found between the critical Reynolds number predicted in this work and the deviation of laminar behavior observed in the experiments conducted by Ruiz and Carey (J Heat Transfer 137(7):071702, 2015 ). For the harmonically driven problem, an energy amplification of O ( 100 ) is observed for spiral crossflow waves. Transition to turbulence should be avoided to ensure the safe operation of a parallel-disk turbine, whereas large forcing amplification may be sought to promote mixing in a swirl flow channel heat sink. The analysis presented predicts and provides insight into the transition mechanisms. Due to its easy implementation and low computational cost, it is particularly useful for the early stages of engineering design.
ISSN:0001-5970
1619-6937
DOI:10.1007/s00707-018-2214-3