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Flow in a channel with accelerating or decelerating wall velocity: A comparison between self-similar solutions and Navier–Stokes computations in finite domains

Phys. Fluids 21, 113601 (2009); doi:10.1063/1.3268130

Published 24 November 2009

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Leonardo Espín1 and Demetrios T. Papageorgiou1,2
1Department of Mathematical Sciences, New Jersey Institute of Technology, University Heights, Newark, New Jersey 07102, USA
2Department of Mathematics and Department of Chemical Engineering, Imperial College London, London SW7 2AZ, United Kingdom
We investigate computationally whether a class of self-similar solutions of the Navier–Stokes equations in infinite channels driven by accelerating or decelerating walls, arises anywhere in a channel restricted to finite length. The self-similar solutions satisfy a nonlinear partial differential equation involving time and the vertical coordinate and have been studied previously. Admissible self-similar solutions include stable and unstable steady branches, time-periodic branches emerging from Hopf bifurcations, as well as chaotic solutions following a period-doubling Feigenbaum cascade. The objective here is to explore whether such solutions emerge when restricted to finite, although long, channels. The problem is addressed numerically using fast algorithms to solve the Navier–Stokes equations. It is established that all branches of the self-similar solutions (including time-periodic ones) can occur in finite channels provided the Reynolds numbers are not too high (approximately 500 for accelerating and 33 for decelerating wall flows, respectively). As the Reynolds number increases it becomes more difficult to recover the self-similar branches with general inflow conditions, and this has been overcome by utilizing the self-similar solutions as inflow Dirichlet conditions. At sufficiently high Reynolds numbers, the self-similar inflow conditions are incapable of producing the exact solution in the interior, but instead new steady or time-periodic states emerge which depend on the Reynolds number and the channel length. It is established numerically by solving the linearized Navier–Stokes equations that such phenomena are due to a spatial instability of the self-similar states to perturbations which are not of self-similar form. The results indicate that caution must be exercised in drawing conclusions from a stability theory restricted to self-similar perturbations and examples are given where such analysis is erroneous. In the case of decelerating wall flows the self-similar solutions are recovered on finite domains but for a much smaller range of Reynolds numbers as compared to accelerating wall flows. The results also show that time-periodic self-similar states are possible in finite channels (the Navier– Stokes equations are solved subject to the spatiotemporal self-similar solution at inflow) for accelerating wall flows but not for decelerating ones. Of special interest are computed aperiodic states of the Navier–Stokes equations in the case of accelerating walls and relatively high Reynolds numbers. These solutions behave intermittently and bounce between long-lived states that are congruent to the self-similar solutions to non-self-similar aperiodic ones. This is a complicated phenomenon due to the dimensionality and nonlinear nature of the system but the results indicate that the self-similar states can be strong attractors in some regions of the phase space. ©2009 American Institute of Physics
History: Received 24 June 2009; accepted 30 October 2009; published 24 November 2009
Permalink: http://link.aip.org/link/?PHFLE6/21/113601/1
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KEYWORDS and PACS

Keywords
PACS
  • 47.53.+n
    Fractals in fluid dynamics
  • 47.15.Fe
    Stability of laminar flows
  • 47.15.Rq
    Laminar flows in cavities, channels, ducts, and conduits
  • 47.52.+j
    Chaos in fluid dynamics
  • 47.10.ad
    Navier-Stokes equations
  • 47.60.Dx
    Flows in ducts and channels
  • YEAR: 2010

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PUBLICATION DATA

ISSN:
1070-6631 (print)   1089-7666 (online)
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REFERENCES (20)
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  1. P. G. Drazin and N. Riley, The Navier-Stokes Equations, A Classification of Flows and Exact Solutions (Cambridge University Press, Cambridge, 2006).
  2. P. E. Hydon and T. J. Pedley, “Axial dispersion in a channel with oscillating walls,” J. Fluid Mech. 249, 535 (1993).
  3. S. L. Waters, “Solute uptake through the walls of a pulsating channel,” J. Fluid Mech. 433, 193 (2001).
  4. S. L. Waters, “A mathematical model for the laser treatment of heart disease,” J. Biomech. 37, 281 (2004).
  5. T. W. Secomb, “Flow in a channel with pulsating walls,” J. Fluid Mech. 88, 273 (1978).
  6. P. Hall and D. T. Papageorgiou, “The onset of chaos in a class of Navier-Stokes solutions,” J. Fluid Mech. 393, 59 (1999).
  7. M. G. Blyth, P. Hall, and D. T. Papageorgiou, “Chaotic flows in pulsating cylindrical tubes: A class of exact Navier-Stokes solutions,” J. Fluid Mech. 481, 187 (2003).
  8. S. M. Cox, “Two-dimensional flow of a viscous fluid in a channel with porous walls,” J. Fluid Mech. 227, 1 (1991).
  9. J. R. King and S. M. Cox, “Self-similar `stagnation point' boundary layer flows with suction or injection,” Stud. Appl. Math. 115, 73 (2005).
  10. R. D. Bundy and H. L. Weissberg, “Experimental study of fully developed laminar flow in a porous pipe with wall injection,” Phys. Fluids 13, 2613 (1970).
  11. G. D. Raithby and D. C. Knudsen, “Hydrodynamic development in a duct with suction and blowing,” ASME J. Appl. Mech. 41, 896 (1974).
  12. J. F. Brady, “Flow development in a porous channel and tube,” Phys. Fluids 27, 1061 (1984).
  13. J. F. Brady and A. Acrivos, “Steady flow in a channel or tube with an accelerating surface velocity. An exact solution to the Navier-Stokes equations with reverse flow,” J. Fluid Mech. 112, 127 (1981).
  14. J. F. Brady and A. Acrivos, “Closed-cavity laminar flows at moderate Reynolds numbers,” J. Fluid Mech. 115, 427 (1982).
  15. R. E. Hewitt and A. L. Hazel, “Midplane-symmetry breaking in the flow between two counter-rotating disks,” J. Eng. Math. 57, 273 (2007).
  16. E. B. B. Watson, W. H. H. Banks, M. B. Zaturska, and P. G. Drazin, “On transition to chaos in two-dimensional channnel flow symmetrically driven by accelerating walls,” J. Fluid Mech. 212, 451 (1990).
  17. A. S. Berman, “Laminar flow in channels with porous walls,” J. Appl. Phys. 24, 1232 (1953).
  18. M. Griebel, T. Dornseifer, and T. Neunhoeffer, Numerical Simulations in Fluid Dynamics: A Practical Introduction (Society for Industrial and Applied Mathematics, Philadelphia, 1988).
  19. L. Durlofsky and J. F. Brady, “The spatial stability of a class of similarity solutions,” Phys. Fluids 27, 1068 (1984).
  20. R. S. Lin and M. R. Malik, “On the stability of attachment-line boundary layers. 1. The incompressible swept Hiemenz flow,” J. Fluid Mech. 311, 239 (1996).

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