Measurements of the average properties of a suspension of bubbles rising in a vertical channel

ROBERTO ZENIT; DONALD L. KOCH; ASHOK S. SANGANI

doi:10.1017/S0022112000002743

Abstract

Experiments were performed in a vertical channel to study the behaviour of a monodisperse bubble suspension for which the dual limit of large Reynolds number and small Weber number was satisfied. Measurements of the liquid-phase velocity fluctuations were obtained with a hot-wire anemometer. The gas volume fraction, bubble velocity, bubble velocity fluctuations and bubble collision rate were measured using a dual impedance probe. Digital image analysis was performed to quantify the small polydispersity of the bubbles as well as the bubble shape.

A rapid decrease in bubble velocity with bubble concentration in very dilute suspensions is attributed to the effects of bubble–wall collisions. The more gradual subsequent hindering of bubble motion is in qualitative agreement with the predictions of Spelt & Sangani (1998) for the effects of potential-flow bubble–bubble interactions on the mean velocity. The ratio of the bubble velocity variance to the square of the mean is O(0.1). For these conditions Spelt & Sangani predict that the homogeneous suspension will be unstable and clustering into horizontal rafts will take place. Evidence for bubble clustering is obtained by analysis of video images. The fluid velocity variance is larger than would be expected for a homogeneous suspension and the fluid velocity frequency spectrum indicates the presence of velocity fluctuations that are slow compared with the time for the passage of an individual bubble. These observations provide further evidence for bubble clustering.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Hoffmann, M. Tsang, Y. Sangani, A. Koch, D. Kushch, V. and Nahra, H. 2001. Behavior of rapidly sheared bubble suspensions.

Sankaranarayanan, Krishnan and Sundaresan, Sankaran 2002. Lift force in bubbly suspensions. Chemical Engineering Science, Vol. 57, Issue. 17, p. 3521.

Garnier, C Lance, M and Marié, J.L 2002. Measurement of local flow characteristics in buoyancy-driven bubbly flow at high void fraction. Experimental Thermal and Fluid Science, Vol. 26, Issue. 6-7, p. 811.

Zenit, R. Koch, D. L. and Sangani, A. S. 2003. Impedance probe to measure local gas volume fraction and bubble velocity in a bubbly liquid. Review of Scientific Instruments, Vol. 74, Issue. 5, p. 2817.

Wang, Nianqing and Smereka, Peter 2003. Effective Equations for Sound and Void Wave Propagation in Bubbly Fluids. SIAM Journal on Applied Mathematics, Vol. 63, Issue. 6, p. 1849.

Sundaresan, Sankaran Eaton, John Koch, Donald L. and Ottino, Julio M. 2003. Appendix 2: Report of study group on disperse flow. International Journal of Multiphase Flow, Vol. 29, Issue. 7, p. 1069.

Aidun, Cyrus K. and Ding, E-Jiang 2003. Dynamics of particle sedimentation in a vertical channel: Period-doubling bifurcation and chaotic state. Physics of Fluids, Vol. 15, Issue. 6, p. 1612.

Tsang, Ying H. Koh, Young-Ho and Koch, Donald L. 2004. Bubble-size dependence of the critical electrolyte concentration for inhibition of coalescence. Journal of Colloid and Interface Science, Vol. 275, Issue. 1, p. 290.

Kitagawa, Atsuhide Sugiyama, Kazuyasu and Murai, Yuichi 2004. Experimental detection of bubble–bubble interactions in a wall-sliding bubble swarm. International Journal of Multiphase Flow, Vol. 30, Issue. 10, p. 1213.

Guet, S. Ooms, G. Oliemans, R.V.A. and Mudde, R.F. 2004. Bubble size effect on low liquid input drift–flux parameters. Chemical Engineering Science, Vol. 59, Issue. 16, p. 3315.

Brenn, Günter Kolobarić, Vladimir and Durst, F. 2004. Bubbly Flows. p. 11.

Moctezuma, M. F. Lima-Ochoterena, R. and Zenit, R. 2005. Velocity fluctuations resulting from the interaction of a bubble with a vertical wall. Physics of Fluids, Vol. 17, Issue. 9,

Figueroa-Espinoza, Bernardo and Zenit, Roberto 2005. Clustering in high Re monodispersed bubbly flows. Physics of Fluids, Vol. 17, Issue. 9,

Esmaeeli, Asghar and Tryggvason, Grétar 2005. A direct numerical simulation study of the buoyant rise of bubbles at O(100) Reynolds number. Physics of Fluids, Vol. 17, Issue. 9,

Sangani, A. S. Ozarkar, S. S. Tsang, Y. H. and Koch, D. L. 2006. IUTAM Symposium on Computational Approaches to Multiphase Flow. Vol. 81, Issue. , p. 381.

Yin, Xiaolong Koch, Donald L. and Verberg, Rolf 2006. Lattice-Boltzmann method for simulating spherical bubbles with no tangential stress boundary conditions. Physical Review E, Vol. 73, Issue. 2,

Lu, Jiacai and Tryggvason, Gretar 2006. Numerical study of turbulent bubbly downflows in a vertical channel. Physics of Fluids, Vol. 18, Issue. 10,

Guet, S. and Ooms, G. 2006. FLUID MECHANICAL ASPECTS OF THE GAS-LIFT TECHNIQUE. Annual Review of Fluid Mechanics, Vol. 38, Issue. 1, p. 225.

Yang, G.Q. Du, Bing and Fan, L.S. 2007. Bubble formation and dynamics in gas–liquid–solid fluidization—A review. Chemical Engineering Science, Vol. 62, Issue. 1-2, p. 2.

Monahan, Sarah M. and Fox, Rodney O. 2007. Effect of model formulation on flow‐regime predictions for bubble columns. AIChE Journal, Vol. 53, Issue. 1, p. 9.

Download full list

Article contents

Measurements of the average properties of a suspension of bubbles rising in a vertical channel

Abstract

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Measurements of the average properties of a suspension of bubbles rising in a vertical channel

Abstract

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests