Experimental study of flow separation in laminar falling liquid films

In a previous publication, Dietze, Leefken & Kneer (J. Fluid Mech., vol. 595, 2008, p. 435) showed that flow separation takes place in the capillary wave region of falling liquid films. That investigation focused on the mechanistic explanation of the phenomenon mainly on the basis of numerical data. The present publication for the first time provides clear experimental evidence of the phenomenon obtained by way of highly resolving velocity measurements in a specifically designed optical test set-up. Characteristically, the refractive index of the working fluid was matched to that of the glass test section to provide optimal access to the cross-section of the film for the employed optical velocimetry techniques, namely, laser doppler velocimetry (LDV) and particle image velocimetry (PIV). Using LDV, time traces of the streamwise velocity component were recorded in high spatial (0.025 mm) and temporal resolutions (0.4 ms) showing negative velocity values in the capillary wave region. In addition, simultaneous film thickness measurements were performed using a Confocal Chromatic Imaging (CCI) technique enabling the correlation of velocity data and wave dynamics. Further, using PIV the spatio-temporal evolution of the velocity field in the cross-section of the film was measured with high spatial (0.02 mm) and temporal (0.5 ms) resolutions yielding insight into the topology of the flow. Most importantly these results clearly show the existence of a separation eddy in the capillary wave region. Due to the high temporal resolution of the PIV measurements, enabled by the use of a high-speed camera with a repetition rate of up to 4500 Hz, the effect of wave dynamics on the velocity field in all regions of the wavy film was elucidated. All experiments were performed using a dimethylsulfoxide (DMSO)–water solution and focused on laminar vertically falling liquid films with externally excited monochromatic surface waves. Systematic variations of both the Reynolds number (Re = 8.6–15.0) and the excitation frequency (f = 16–24 Hz) were performed. Results show that an increase in the wavelength of large wave humps, produced either by an increase in the Reynolds number or a decrease in the excitation frequency, leads to an increase in the size of the capillary separation eddy (CSE). Thereby, the CSE is shown to grow larger than the local film thickness, assuming an open shape with streamlines ending at the free surface.

[1]  V. Balakotaiah,et al.  Flow structure underneath the large amplitude waves of a vertically falling film , 2008 .

[2]  R. Kneer,et al.  Investigation of the backflow phenomenon in falling liquid films , 2008, Journal of Fluid Mechanics.

[3]  Serafim Kalliadasis,et al.  Heated falling films , 2007, Journal of Fluid Mechanics.

[4]  D. Markovich,et al.  Application of PIV to velocity measurements in a liquid film flowing down an inclined cylinder , 2007 .

[5]  V. Balakotaiah,et al.  Solitary waves on thin falling films in the very low forcing frequency limit , 2006 .

[6]  Paul Manneville,et al.  Wave patterns in film flows: modelling and three-dimensional waves , 2006, Journal of Fluid Mechanics.

[7]  V. Bontozoglou,et al.  Solitary waves on inclined films: their characteristics and the effects on wall shear stress , 2006 .

[8]  U. Renz,et al.  Local thickness and wave velocity measurement of wavy films with a chromatic confocal imaging method and a fluorescence intensity technique , 2005 .

[9]  Tomoaki Kunugi,et al.  DNS of falling film structure and heat transfer via MARS method , 2005 .

[10]  Neil B. Morley,et al.  Numerical simulation of wavy falling film flow using VOF method , 2003 .

[11]  T. Kunugi,et al.  Surface wave structure and heat transfer of vertical liquid film flow , 2003 .

[12]  C. Tropea,et al.  Laser Doppler and Phase Doppler Measurement Techniques , 2002 .

[13]  Markus Raffel,et al.  Particle Image Velocimetry: A Practical Guide , 2002 .

[14]  Hsueh-Chia Chang,et al.  Complex Wave Dynamics on Thin Films , 2002 .

[15]  J. Mas Mass and momentum transport in smooth falling liquid films laminarized at relatively high Reynolds numbers , 2002 .

[16]  Joseph Cohen-Sabban,et al.  Quasi-confocal extended field surface sensing , 2001, SPIE Optics + Photonics.

[17]  Philipp Adomeit,et al.  Hydrodynamics of three-dimensional waves in laminar falling films , 2000 .

[18]  A. Miyara Numerical analysis on flow dynamics and heat transfer of falling liquid films with interfacial waves , 1999 .

[19]  Petros Koumoutsakos,et al.  On the generation of vorticity at a free surface , 1997, Journal of Fluid Mechanics.

[20]  Jean Hertzberg,et al.  Experimental uncertainties associated with particle image velocimetry (PIV) based vorticity algorithms , 1999 .

[21]  Kenyu Oyakawa,et al.  Characteristics of two-dimensional waves on a falling liquid film , 1996 .

[22]  Jiezhi Wu,et al.  A theory of three‐dimensional interfacial vorticity dynamics , 1995 .

[23]  C. Boyadjiev Wave flow of liquid films: S. V. ALEKSEENKO, V. E. NAKORYAKOV and B. G. POKUSAEV, All-Rusian Inc. “Nauka”, Novosibirsk, 1992, 256 pp. , 1995 .

[24]  R. Budwig Refractive index matching methods for liquid flow investigations , 1994 .

[25]  E. P. Rood,et al.  Interpreting Vortex Interactions With a Free Surface , 1994 .

[26]  J. Westerweel,et al.  Efficient detection of spurious vectors in particle image velocimetry data , 1994 .

[27]  I. Mudawar,et al.  Measurement of mass and momentum transport in wavy-laminar falling liquid films , 1993 .

[28]  Jun Liu,et al.  Measurements of the primary instabilities of film flows , 1993, Journal of Fluid Mechanics.

[29]  B. Morton,et al.  The generation and decay of vorticity , 1984 .

[30]  L. F. Mockros,et al.  Motion of discrete particles in a turbulent fluid , 1966 .

[31]  S. Portalski Eddy Formation in Film Flow Down a Vertical Plate , 1964 .

[32]  W. Nusselt Die Oberflachenkondensation des Wasserdampfes , 1916 .