Three-dimensional flow structures in laminar falling liquid films. (25th March 2014)
- Record Type:
- Journal Article
- Title:
- Three-dimensional flow structures in laminar falling liquid films. (25th March 2014)
- Main Title:
- Three-dimensional flow structures in laminar falling liquid films
- Authors:
- Dietze, Georg F.
Rohlfs, W.
Nährich, K.
Kneer, R.
Scheid, B. - Abstract:
- <abstract> <title>Abstract</title> <p>Full numerical simulations of the Navier–Stokes equations for four cases of vertically falling liquid films with three-dimensional surface waves have been performed. Flow conditions are based on several previous experimental studies where the streamwise and spanwise wavelengths were imposed, which we exploit by simulating periodic wave segments. The considered flows are laminar but approach conditions at which intermittent wave-induced turbulence has been observed elsewhere. Working liquids range from water to silicone oil and cover a large interval of the Kapitza number (<inline-formula><alternatives><inline-graphic xlink:href="ark:/27927/pgh190kpxg1" xlink:type="simple" xmlns:xlink="http://www.w3.org/1999/xlink" /><tex-math><![CDATA[$\textit {Ka}=18\mbox{--}3923$]]></tex-math></alternatives></inline-formula>), which relates capillary to viscous forces. Simulations were performed on a supercomputer, using a finite-volume code and the volume of fluid and continuum surface force methods to account for the multiphase nature of the flow. Our results show that surface waves, consisting of large horseshoe-shaped wave humps concentrating most of the liquid and preceded by capillary ripples on a thin residual film, segregate the flow field into two regions: an inertia-dominated one in the large humps, where the local Reynolds number is up to five times larger than its mean value, and a visco-capillary region, where capillary and/or viscous<abstract> <title>Abstract</title> <p>Full numerical simulations of the Navier–Stokes equations for four cases of vertically falling liquid films with three-dimensional surface waves have been performed. Flow conditions are based on several previous experimental studies where the streamwise and spanwise wavelengths were imposed, which we exploit by simulating periodic wave segments. The considered flows are laminar but approach conditions at which intermittent wave-induced turbulence has been observed elsewhere. Working liquids range from water to silicone oil and cover a large interval of the Kapitza number (<inline-formula><alternatives><inline-graphic xlink:href="ark:/27927/pgh190kpxg1" xlink:type="simple" xmlns:xlink="http://www.w3.org/1999/xlink" /><tex-math><![CDATA[$\textit {Ka}=18\mbox{--}3923$]]></tex-math></alternatives></inline-formula>), which relates capillary to viscous forces. Simulations were performed on a supercomputer, using a finite-volume code and the volume of fluid and continuum surface force methods to account for the multiphase nature of the flow. Our results show that surface waves, consisting of large horseshoe-shaped wave humps concentrating most of the liquid and preceded by capillary ripples on a thin residual film, segregate the flow field into two regions: an inertia-dominated one in the large humps, where the local Reynolds number is up to five times larger than its mean value, and a visco-capillary region, where capillary and/or viscous forces dominate. In the inertial region, an intricate structure of different-scale vortices arises, which is more complicated than film thickness variations there suggest. Conversely, the flow in the visco-capillary region of large-<inline-formula><alternatives><inline-graphic xlink:href="ark:/27927/pgh190kpxj4" xlink:type="simple" xmlns:xlink="http://www.w3.org/1999/xlink" /><tex-math><![CDATA[$\textit {Ka} $]]></tex-math></alternatives></inline-formula> fluids is entirely governed by the local free-surface curvature through the action of capillary forces, which impose the pressure distribution in the liquid film. This results in flow separation zones underneath the capillary troughs and a spanwise cellular flow pattern in the region of capillary wave interference. In some cases, capillary waves bridge the large horseshoe humps in the spanwise direction, coupling the two aforementioned regions and leading the flow to oscillate between three- and two-dimensional wave patterns. This persists over long times, as we show by simulations with the low-dimensional model of Scheid <italic>et al.</italic> (<italic>J. Fluid Mech.</italic>, vol. 562, 2006, pp. 183–222) after satisfactory comparison with our direct simulations at short times. The governing mechanism is connected to the bridging capillary waves, which drain liquid from the horseshoe humps, decreasing their amplitude and wave speed and causing them to retract in the streamwise direction. Overall, it is observed that spanwise flow structures (not accounted for in two-dimensional investigations) are particularly complex due to the absence of gravity in this direction.</p> </abstract> … (more)
- Is Part Of:
- Journal of fluid mechanics. Volume 743(2014:Mar.)
- Journal:
- Journal of fluid mechanics
- Issue:
- Volume 743(2014:Mar.)
- Issue Display:
- Volume 743 (2014)
- Year:
- 2014
- Volume:
- 743
- Issue Sort Value:
- 2014-0743-0000-0000
- Page Start:
- 75
- Page End:
- 123
- Publication Date:
- 2014-03-25
- Subjects:
- Fluid mechanics -- Periodicals
532.005 - Journal URLs:
- http://www.journals.cambridge.org/jid%5FFLM ↗
http://firstsearch.oclc.org ↗ - DOI:
- 10.1017/jfm.2013.679 ↗
- Languages:
- English
- ISSNs:
- 0022-1120
- Deposit Type:
- Legaldeposit
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- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library HMNTS - ELD Digital store
- Ingest File:
- 3337.xml