The pressure field due to a large circular capped air bubble rising in water

G. M. Lazarek; H. Littman

doi:10.1017/S0022112074000449

Abstract

The pressure field due to a large circular capped air bubble rising in water has been determined experimentally. The results verify the Davies & Taylor cap boundary condition and the frontal pressure field is well approximated by that due to irrotational flow around an oval body.

The pressure field extends axially as far as ten bubble half-widths below the bubble floor. Immediately below the floor the pressure is constant for about two-thirds of a bubble height. The wake is closed and contains symmetric pressure minima. For the bubbles studied, turbulence, as well as the diffusion of vorticity, probably controls the momentum distribution and energy dissipation in the wake.

Crossref Citations

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

PLESKO, CYRIL and LEUTHEUSSER, HANS J. 1982. DYNAMIC EFFECTS OF BUBBLE MOTION. Chemical Engineering Communications, Vol. 17, Issue. 1-6, p. 195.

Kitano, Kunihiro and Fan, Liang-shih 1988. Near-wake structure of a single gas bubble in a two-dimensional liquid-solid fluidized bed: solids holdup. Chemical Engineering Science, Vol. 43, Issue. 6, p. 1355.

Tsuchiya, Katsumi and Fan, Liang-Shih 1988. Near-wake structure of a single gas bubble in a two-dimensional liquid-solid fluidized bed: Vortex shedding and wake size variation. Chemical Engineering Science, Vol. 43, Issue. 5, p. 1167.

Fan, Liang-Shih 1989. Gas–Liquid–Solid Fluidization Engineering. p. 33.

FAN, LIANG-SHIH and TSUCHIYA, KATSUMI 1990. Bubble Wake Dynamics in Liquids and Liquid–Solid Suspensions. p. 219.

Jean, Rong-Her and Fan, Liang-Shih 1990. Rise velocity and gas—liquid mass transfer of a single large bubble in liquids and liquid—solid fluidized beds. Chemical Engineering Science, Vol. 45, Issue. 4, p. 1057.

FAN, LIANG-SHIH and TSUCHIYA, KATSUMI 1990. Bubble Wake Dynamics in Liquids and Liquid–Solid Suspensions. p. 181.

FAN, LIANG-SHIH and TSUCHIYA, KATSUMI 1990. Bubble Wake Dynamics in Liquids and Liquid–Solid Suspensions. p. 143.

Raghunathan, K. Kumar, S. and Fan, L.-S. 1992. Pressure distribution and vortical structure in the wake behind gas bubbles in liquid and liquid-solid systems. International Journal of Multiphase Flow, Vol. 18, Issue. 1, p. 41.

Tsuchiya, Katsumi and Ohsaki, Kazutomo 1997. Prediction of the bubble-hole size of a cap bubble in a bubble swarm. Chemical Engineering Science, Vol. 52, Issue. 5, p. 775.

Chen, R.C and Chou, I.S 1998. Wake structure of a single bubble rising in a two-dimensional column. Experimental Thermal and Fluid Science, Vol. 17, Issue. 3, p. 165.

Bush, J.W.M. and Eames, I. 1998. Fluid displacement by high Reynolds number bubble motion in a thin gap. International Journal of Multiphase Flow, Vol. 24, Issue. 3, p. 411.

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.

SHIKATA, Kazuya IWAKI, Hideo MORI, Yasushige and TSUCHIYA, Katsumi 2009. Progress in Multiphase Flow Research, Vol. 4, Issue. , p. 117.

CrossRef

Roig, Véronique Roudet, Matthieu Risso, Frédéric and Billet, Anne-Marie 2012. Dynamics of a high-Reynolds-number bubble rising within a thin gap. Journal of Fluid Mechanics, Vol. 707, Issue. , p. 444.

Chow, Aaron C. and Adams, E. Eric 2012. Particle laden flows through an inverted chimney with applications to ocean carbon sequestration. Environmental Fluid Mechanics, Vol. 12, Issue. 1, p. 3.

Filella, Audrey Ern, Patricia and Roig, Véronique 2015. Oscillatory motion and wake of a bubble rising in a thin-gap cell. Journal of Fluid Mechanics, Vol. 778, Issue. , p. 60.

Wang, Xue Klaasen, Bart Degrève, Jan Mahulkar, Amit Heynderickx, Geraldine Reyniers, Marie-Françoise Blanpain, Bart and Verhaeghe, Frederik 2016. Volume-of-fluid simulations of bubble dynamics in a vertical Hele-Shaw cell. Physics of Fluids, Vol. 28, Issue. 5,

Li, Yanjun Liu, Mingyan and Li, Xiangnan 2016. Single bubble behavior in gas–liquid–solid mini-fluidized beds. Chemical Engineering Journal, Vol. 286, Issue. , p. 497.

Lei, Q. Xie, Z. Pavlidis, D. Salinas, P. Veltin, J. Matar, O. K. Pain, C. C. Muggeridge, A. H. Gyllensten, A. J. and Jackson, M. D. 2018. The shape and motion of gas bubbles in a liquid flowing through a thin annulus. Journal of Fluid Mechanics, Vol. 855, Issue. , p. 1017.

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The pressure field due to a large circular capped air bubble rising in water

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