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Three-dimensional instability of axisymmetric buoyant convection in cylinders heated from below (1996)

Wanschura, M. ; Kuhlmann, H. C. ; Rath, H. J.

Cambridge University Press

In: Journal of Fluid Mechanics. 1996; 326: 399-415. Published 1996 Nov 10. doi: 10.1017/s0022112096008373.

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Publication Date: 1996-11-10

Description: The stability of steady axisymmetric convection in cylinders heated from below and insulated laterally is investigated numerically using a mixed finite-difference/Chebyshev collocation method to solve the base flow and the linear stability equations. Linear stability boundaries are given for radius to height ratios Γ from 0.9 to 1.56 and for Prandtl numbers Pr = 0.02 and Pr = 1. Depending on Γ and Pr, the azimuthal wavenumber of the critical mode may be m = 1,2,3, or 4. The dependence of the critical Rayleigh number on the aspect ratio and the instability mechanisms are explained by analysing the energy transfer to the critical modes for selected cases. In addition to these results the onset of buoyant convection in liquid bridges with stress-free conditions on the cylindrical surface is considered. For insulating thermal boundary conditions, the onset of convection is never axisymmetric and the critical azimuthal wavenumber increases monotonically with Γ. The critical Rayleigh number is less then 1708 for most aspect ratios.

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Flow in two-sided lid-driven cavities: non-uniqueness, instabilities, and cellular structures (1997)

KUHLMANN, H. C. ; WANSCHURA, M. ; RATH, H. J.

Cambridge University Press

In: Journal of Fluid Mechanics. 1997; 336: 267-299. Published 1997 Apr 10. doi: 10.1017/s0022112096004727.

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Publication Date: 1997-04-10

Description: The steady flow in rectangular cavities is investigated both numerically and experimentally. The flow is driven by moving two facing walls tangentially in opposite directions. It is found that the basic two-dimensional flow is not always unique. For low Reynolds numbers it consists of two separate co-rotating vortices adjacent to the moving walls. If the difference in the sidewall Reynolds numbers is large this flow becomes unstable to a stationary three-dimensional mode with a long wavelength. When the aspect ratio is larger than two and both Reynolds numbers are large, but comparable in magnitude, a second two-dimensional flow exists. It takes the form of a single vortex occupying the whole cavity. This flow is the preferred state in the present experiment. It becomes unstable to a three-dimensional mode that subdivides the basic streched vortex flow into rectangular convective cells. The instability is supercritical when both sidewall Reynolds numbers are the same. When they differ the instability is subcritical. From an energy analysis and from the salient features of the three-dimensional flow it is concluded that the mechanism of destabilization is identical to the destabilization mechanism operative in the elliptical instability of highly strained vortices.

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Stability of thermocapillary flows in non-cylindrical liquid bridges (2003)

Nienhser, Ch. ; Kuhlmann, H. C.

Cambridge University Press

In: Journal of Fluid Mechanics. 2003; 480: 333-334. Published 2003 Apr 10. doi: 10.1017/s0022112003003719.

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Publication Date: 2003-04-10

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Nonlinear three-dimensional flow in the lid-driven square cavity (2006)

ALBENSOEDER, S. ; KUHLMANN, H. C.

Cambridge University Press

In: Journal of Fluid Mechanics. 2006; 569: 465. Published 2006 Nov 15. doi: 10.1017/s0022112006002758.

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Publication Date: 2006-11-15

Description: The three-dimensional flow in a lid-driven cuboid is investigated numerically. The geometry is an extension to three dimensions of the lid-driven square cavity by translating the two-dimensional lid-driven cavity parallel to the third orthogonal direction. The incompressible Navier-Stokes equations are discretized by a pseudospectral Chebyshev-collocation method. The singularities caused by the discontinuous velocity boundary conditions are reduced by including asymptotic analytical solutions in the solution ansatz. The flow is computed for Reynolds numbers above the critical onset of Taylor-Görtler vortices. Nonlinear Taylor-Görtler cells are calculated for periodic and for realistic no-slip endwall conditions. For periodic boundary conditions the bifurcation is either sub- or supercritical, depending on the wavenumber. The limiting tricritical case arises near the critical wavenumber of the linear-stability problem. On the other hand, no-slip endwall conditions have a significant effect on the supercritical three-dimensional flow. In agreement with recent experimental results we find that Taylor-Görtler vortices are suppressed near no-slip endwalls. © 2006 Cambridge University Press.

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Linear stability of thermocapillary convection in cylindrical liquid bridges under axial magnetic fields (1999)

PRANGE, M. ; WANSCHURA, M. ; KUHLMANN, H. C. ; [et al.]

Cambridge University Press

In: Journal of Fluid Mechanics. 1999; 394: 281-302. Published 1999 Sep 10. doi: 10.1017/s0022112099005698.

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Publication Date: 1999-09-10

Description: The stability of axisymmetric steady thermocapillary convection of electrically conducting fluids in half-zones under the influence of a static axial magnetic field is investigated numerically by linear stability theory. In addition, the energy transfer between the basic state and a disturbance is considered in order to elucidate the mechanics of the most unstable mode. Axial magnetic fields cause a concentration of the thermocapillary flow near the free surface of the liquid bridge. For the low Prandtl number fluids considered, the most dangerous disturbance is a non-axisymmetric steady mode. It is found that axial magnetic fields act to stabilize the basic state. The stabilizing effect increases with the Prandtl number and decreases with the zone height the heat transfer rate at the free surface and buoyancy when the heating is from below. The magnetic field also influences the azimuthal symmetry of the most unstable mode.

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The two-sided lid-driven cavity: experiments on stationary and time-dependent flows (2002)

BLOHM, CH. ; KUHLMANN, H. C.

Cambridge University Press

In: Journal of Fluid Mechanics. 2002; 450: 67-95. Published 2002 Jan 09. doi: 10.1017/s0022112001006267.

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Publication Date: 2002-01-09

Description: The incompressible fluid flow in a rectangular container driven by two facing sidewalls which move steadily in anti-parallel directions is investigated experimentally for Reynolds numbers up to 1200. The moving sidewalls are realized by two rotating cylinders of large radii tightly closing the cavity. The distance between the moving walls relative to the height of the cavity (aspect ratio) is Γ = 1.96. Laser-Doppler and hot-film techniques are employed to measure steady and time-dependent vortex flows. Beyond a first threshold robust, steady, three-dimensional cells bifurcate supercritically out of the basic flow state. Through a further instability the cellular flow becomes unstable to oscillations in the form of standing waves with the same wavelength as the underlying cellular flow. If both sidewalls move with the same velocity (symmetrical driving), the oscillatory instability is found to be tricritical. The dependence on two sidewall Reynolds numbers of the ranges of existence of steady and oscillatory cellular flows is explored. Flow symmetries and quantitative velocity measurements are presented for representative cases.

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Hydrodynamic instabilities in cylindrical thermocapillary liquid bridges (1993)

Kuhlmann, H. C. ; Rath, H. J.

Cambridge University Press

In: Journal of Fluid Mechanics. 1993; 247: 247-274. Published 1993 Feb 01. doi: 10.1017/s0022112093000461.

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Publication Date: 1993-02-01

Description: The hydrodynamic stability of steady axisymmetric thermocapillary flow in a cylindrical liquid bridge is investigated by linear stability theory. The basic state and the three-dimensional disturbance equations are solved by various spectral methods for aspect ratios close to unity. The critical modes have azimuthal wavenumber one and the most dangerous disturbance is either a pure hydrodynamic steady mode or an oscillatory hydrothermal wave, depending on the Prandtl number. The influence of heat transfer through the free surface, additional buoyancy forces, and variations of the aspect ratio on the stability boundaries and the neutral mode are discussed. © 1993, Cambridge University Press. All rights reserved.

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Linear stability of rectangular cavity flows driven by anti-parallel motion of two facing walls (2002)

ALBENSOEDER, S. ; KUHLMANN, H. C.

Cambridge University Press

In: Journal of Fluid Mechanics. 2002; 458: 153-180. Published 2002 May 10. doi: 10.1017/s0022112002007917.

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Publication Date: 2002-05-10

Description: The flow in an infinite slab of rectangular cross-section is investigated numerically by a finite volume method. Two facing walls which move parallel to each other with the same velocity, but in opposite directions, drive a plane flow in the cross-section of the slab. A linear stability analysis shows that the two-dimensional flow becomes unstable to different modes, depending on the cross-sectional aspect ratio, when the Reynolds number is increased. The critical mode is found to be stationary for all aspect ratios. When the separation of the moving walls is larger than approximately twice the height of the cavity, the basic flow forms two vortices, each close to one of the moving walls. The instability of this flow is of centrifugal type and similar to that in the classical lid-driven cavity problem with a single moving wall. When the moving walls are sufficiently close to each other (aspect ratio less than 2) the two vortices merge and form an elliptically strained vortex. Owing to the dipolar strain this flow becomes unstable through the elliptic instability. When both moving walls are very close, the finite-length plane-Couette flow becomes unstable by a similar elliptic mechanism near both turning zones. The critical mode produces wide streaks reaching far into the cavity. For a small range of aspect ratios near unity the flow consists of a single vortex. Here, the strain field is dominated by a four-fold symmetry. As a result the instability process is analogous to the instability of a Rankine vortex in an quadripolar strain field, resulting from vortex stretching into the four corners of the cavity.

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Stability of thermocapillary flows in non-cylindrical liquid bridges (2002)

NIENHÜSER, CH. ; KUHLMANN, H. C.

Cambridge University Press

In: Journal of Fluid Mechanics. 2002; 458: 35-73. Published 2002 May 10. doi: 10.1017/s0022112001007650.

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Publication Date: 2002-05-10

Description: The thermocapillary flow in liquid bridges is investigated numerically. In the limit of large mean surface tension the free-surface shape is independent of the flow and temperature fields and depends only on the volume of liquid and the hydrostatic pressure difference. When gravity acts parallel to the axis of the liquid bridge the shape is axisymmetric. A differential heating of the bounding circular disks then causes a steady two-dimensional thermocapillary flow which is calculated by a finite-difference method on body-fitted coordinates. The linear-stability problem for the basic flow is solved using azimuthal normal modes computed with the same discretization method. The dependence of the critical Reynolds number on the volume fraction, gravity level, Prandtl number, and aspect ratio is explained by analysing the energy budgets of the neutral modes. For small Prandtl numbers (Pr = 0.02) the critical Reynolds number exhibits a smooth minimum near volume fractions which approximately correspond to the volume of a cylindrical bridge. When the Prandtl number is large (Pr = 4) the intersection of two neutral curves results in a sharp peak of the critical Reynolds number. Since the instabilities for low and high Prandtl numbers are markedly different, the influence of gravity leads to a distinctly different behaviour. While the hydrostatic shape of the bridge is the most important effect of gravity on the critical point for low-Prandtl-number flows, buoyancy is the dominating factor for the stability of the flow in a gravity field when the Prandtl number is high.

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Experimental investigation of transitional flow in a toroidal pipe (2013)

Kühnen, J. ; Holzner, M. ; Hof, B. ; [et al.]

Cambridge University Press

In: Journal of Fluid Mechanics. 2013; 738: 463-491. Published 2013 Dec 13. doi: 10.1017/jfm.2013.603.

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Publication Date: 2013-12-13

Description: The flow instability and further transition to turbulence in a toroidal pipe (torus) with curvature ratio (tube-to-coiling diameter) 0.049 is investigated experimentally. The flow inside the toroidal pipe is driven by a steel sphere fitted to the inner pipe diameter. The sphere is moved with constant azimuthal velocity from outside the torus by a moving magnet. The experiment is designed to investigate curved pipe flow by optical measurement techniques. Using stereoscopic particle image velocimetry, laser Doppler velocimetry and pressure drop measurements, the flow is measured for Reynolds numbers ranging from 1000 to 15 000. Time- and space-resolved velocity fields are obtained and analysed. The steady axisymmetric basic flow is strongly influenced by centrifugal effects. On an increase of the Reynolds number we find a sequence of bifurcations. For Re = 4075 ± 2% a supercritical bifurcation to an oscillatory flow is found in which waves travel in the streamwise direction with a phase velocity slightly faster than the mean flow. The oscillatory flow is superseded by a presumably quasi-periodic flow at a further increase of the Reynolds number before turbulence sets in. The results are found to be compatible, in general, with earlier experimental and numerical investigations on transition to turbulence in helical and curved pipes. However, important aspects of the bifurcation scenario differ considerably. © 2013 Cambridge University Press.

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