Modeling of liquid film thickness around Taylor bubbles rising in vertical stagnant and co-current slug flowing liquids

doi:10.1016/j.cjche.2022.11.004

Abstract

Abstract: The hydrodynamic study of the liquid film around Taylor bubbles in slug flow has great significance for understanding parallel flow and interaction between Taylor bubbles. The prediction models for liquid film thickness mainly focus on stagnant flow, and some of them remain inaccurate performance. However, in the industrial process, the slug flow essentially is co-current flow. Therefore, in this paper, the liquid film thickness is studied by theoretical analysis and experimental methods under two conditions of stagnant and co-current flow. Firstly, under the condition of stagnant flow, the present work is based on Batchelor's theory, and modifies Batchelor's liquid film thickness model, which effectively improves its prediction accuracy. Under the condition of co-current flow, the prediction model of average liquid film thickness in slug flow is established by force and motion analysis. Taylor bubble length is introduced into the model as an important parameter. Dynamic experiments were carried out in the pipe with an inner diameter of 20 mm. The liquid film thickness, Taylor bubble velocity and length were measured by distributed ultrasonic sensor and intrusive cross-correlation conductivity sensor. Comparing the predicted value of the model with the measured results, the relative error is controlled within 10%.

Key words: Slug flow, Taylor bubble, Liquid film thickness, Ultrasonic sensor, Physical model

摘要： The hydrodynamic study of the liquid film around Taylor bubbles in slug flow has great significance for understanding parallel flow and interaction between Taylor bubbles. The prediction models for liquid film thickness mainly focus on stagnant flow, and some of them remain inaccurate performance. However, in the industrial process, the slug flow essentially is co-current flow. Therefore, in this paper, the liquid film thickness is studied by theoretical analysis and experimental methods under two conditions of stagnant and co-current flow. Firstly, under the condition of stagnant flow, the present work is based on Batchelor's theory, and modifies Batchelor's liquid film thickness model, which effectively improves its prediction accuracy. Under the condition of co-current flow, the prediction model of average liquid film thickness in slug flow is established by force and motion analysis. Taylor bubble length is introduced into the model as an important parameter. Dynamic experiments were carried out in the pipe with an inner diameter of 20 mm. The liquid film thickness, Taylor bubble velocity and length were measured by distributed ultrasonic sensor and intrusive cross-correlation conductivity sensor. Comparing the predicted value of the model with the measured results, the relative error is controlled within 10%.

关键词: Slug flow, Taylor bubble, Liquid film thickness, Ultrasonic sensor, Physical model

Weikai Ren, Runsong Dai, Ningde Jin. Modeling of liquid film thickness around Taylor bubbles rising in vertical stagnant and co-current slug flowing liquids[J]. Chinese Journal of Chemical Engineering, 2023, 58(6): 179-194.

Weikai Ren, Runsong Dai, Ningde Jin. Modeling of liquid film thickness around Taylor bubbles rising in vertical stagnant and co-current slug flowing liquids[J]. 中国化学工程学报, 2023, 58(6): 179-194.

References

[1] M. Abdulkadir, V. Hernandez-Perez, I.S. Lowndes, B.J. Azzopardi, S. Dzomeku, Experimental study of the hydrodynamic behaviour of slug flow in a vertical riser, Chem. Eng. Sci. 106 (2014) 60-75.
[2] W.R. Ahmad, J.M. DeJesus, M. Kawaji, Falling film hydrodynamics in slug flow, Chem. Eng. Sci. 53 (1) (1998) 123-130.
[3] K. Yan, D.F. Che, Hydrodynamic and mass transfer characteristics of slug flow in a vertical pipe with and without dispersed small bubbles, Int. J. Multiph. Flow 37 (4) (2011) 299-325.
[4] D.T. Dumitrescu, Strömung an einer luftblase im senkrechten rohr, Z. Angew. Math. Mech. 23 (3) (1943) 139-149.
[5] R.M. Davies, G. Taylor, The mechanics of large bubbles rising through extended liquids and through liquids in tubes, Proc. Roy. Soc. Lond. A 200 (1062) (1950) 375-390.
[6] P. Griffith, G.B. Wallis, Two-phase slug flow, J. Heat Transf. 83 (3) (1961) 307-318.
[7] H.L. Goldsmith, S.G. Mason, The movement of single large bubbles in closed vertical tubes, J. Fluid Mech. 14 (1) (1962) 42-58.
[8] E.T. White, R.H. Beardmore, The velocity of rise of single cylindrical air bubbles through liquids contained in vertical tubes, Chem. Eng. Sci. 17 (5) (1962) 351-361.
[9] R. Brown, The mechanics of large gas bubbles in tubes: II. The prediction of voidage in vertical gas-liquid flow, Can. J. Chem. Eng. 43 (5) (1965) 224-230.
[10] G.K. Batchelor, An Introduction to Fluid Dynamics, Cambridge University Press, Cambridge, 2000.
[11] R.C. Fernandes, R. Semiat, A.E. Dukler, Hydrodynamic model for gas-liquid slug flow in vertical tubes, AIChE J. 29 (6) (1983) 981-989.
[12] K.H. Bendiksen, On the motion of long bubbles in vertical tubes, Int. J. Multiph. Flow 11 (6) (1985) 797-812.
[13] R. Collins, A simple model of the plane gas bubble in a finite liquid, J. Fluid Mech. 22 (4) (1965) 763.
[14] R. Collins, F.F. De Moraes, J.F. Davidson, D. Harrison, The motion of a large gas bubble rising through liquid flowing in a tube, J. Fluid Mech. 89 (3) (1978) 497-514.
[15] R.A. Mazza, E.S. Rosa, C.J. Yoshizawa, Analyses of liquid film models applied to horizontal and near horizontal gas-liquid slug flows, Chem. Eng. Sci. 65 (12) (2010) 3876-3892.
[16] G.B. Wallis, One-Dimensional Two-Phase Flow, McGraw-Hill, New York, 1969.
[17] W. Nusselt, Die Oberflachenkondensation des Wasserdampfes, Zeitschrift des vereines Deutscher Ingenieure 60 (1916) 569-575.
[18] A.E. Dukler, O.P. Bergelin, Characteristics of flow in falling liquid films, Chem. Eng. Process. 48 (11) (1952) 557-563.
[19] M.R. Özgu, J.C. Chen, A.H. Stenning, Local liquid film thickness around Taylor bubbles, J. Heat Transf. 95 (3) (1973) 425-427.
[20] T.D. Karapantsios, S.V. Paras, A.J. Karabelas, Statistical characteristics of free falling films at high Reynolds numbers, Int. J. Multiph. Flow 15 (1) (1989) 1-21.
[21] T.D. Karapantsios, A.J. Karabelas, Longitudinal characteristics of wavy falling films, Int. J. Multiph. Flow 21 (1) (1995) 119-127.
[22] V.V. Lel, F. Al-Sibai, A. Leefken, U. Renz, Local thickness and wave velocity measurement of wavy films with a chromatic confocal imaging method and a fluorescence intensity technique, Exp. Fluids 39 (5) (2005) 856-864.
[23] J.D.P. Araújo, J.M. Miranda, J.B.L.M. Campos, Flow of two consecutive Taylor bubbles through a vertical column of stagnant liquid—A CFD study about the influence of the leading bubble on the hydrodynamics of the trailing one, Chem. Eng. Sci. 97 (2013) 16-33.
[24] C.W. Kang, S.P. Quan, J. Lou, Numerical study of a Taylor bubble rising in stagnant liquids, Phys. Rev. E 81 (6 Pt 2) (2010) 066308.
[25] A. Majumdar, P.K. Das, Rise of Taylor bubbles through power law fluids—Analytical modelling and numerical simulation, Chem. Eng. Sci. 205 (2019) 83-93.
[26] E.W. Llewellin, E. del Bello, J. Taddeucci, P. Scarlato, S.J. Lane, The thickness of the falling film of liquid around a Taylor bubble, Proc. Roy. Soc. Lond. A 468 (2140) (2012) 1041-1064.
[27] M.B. de Azevedo, D.D. Santos, J.L.H. Faccini, J. Su, Experimental study of the falling film of liquid around a Taylor bubble, Int. J. Multiph. Flow 88 (2017) 133-141.
[28] Y. Taitel, L. Witte, The role of surface tension in microgravity slug flow, Chem. Eng. Sci. 51 (5) (1996) 695-700.
[29] S. Nogueira, M.L. Riethmuler, J.B.L.M. Campos, A.M.F.R. Pinto, Flow in the nose region and annular film around a Taylor bubble rising through vertical columns of stagnant and flowing Newtonian liquids, Chem. Eng. Sci. 61 (2) (2006) 845-857.
[30] A.O. Morgado, J.M. Miranda, J.D.P. Araújo, J.B.L.M. Campos, Review on vertical gas-liquid slug flow, Int. J. Multiph. Flow 85 (2016) 348-368.
[31] D.J. Nicklin, Two-phase flow in vertical tubes, Trans. Inst. Chem. Eng. 40 (1962) 61-68.
[32] A. Orell, R. Rembrand, A model for gas-liquid slug flow in a vertical tube, Ind. Eng. Chem. Fund. 25 (2) (1986) 196-206.
[33] Z.S. Mao, A.E. Dukler, An experimental study of gas-liquid slug flow, Exp. Fluids 8 (3-4) (1989) 169-182.
[34] L. Shemer, Hydrodynamic and statistical parameters of slug flow, Int. J. Heat Fluid Flow 24 (3) (2003) 334-344.
[35] A.M.F.R. Pinto, M.N. Coelho Pinheiro, S. Nogueira, V.D. Ferreira, J.B.L.M. Campos, Experimental study on the transition in the velocity of individual Taylor bubbles in vertical upward co-current liquid flow, Chem. Eng. Res. Des. 83 (9) (2005) 1103-1110.
[36] A. Scammell, J. Kim, Heat transfer and flow characteristics of rising Taylor bubbles, Int. J. Heat Mass Transf. 89 (2015) 379-389.
[37] E.M.A. Frederix, E.M.J. Komen, I. Tiselj, B. Mikuž, LES of turbulent co-current Taylor bubble flow, Flow Turbul. Combust. 105 (2) (2020) 471-495.
[38] J.P. Kockx, F.T.M. Nieuwstadt, R.V.A. Oliemans, R. Delfos, Gas entrainment by a liquid film falling around a stationary Taylor bubble in a vertical tube, Int. J. Multiph. Flow 31 (1) (2005) 1-24.
[39] T.S. Mayor, V. Ferreira, A.M.F.R. Pinto, J.B.L.M. Campos, Hydrodynamics of gas-liquid slug flow along vertical pipes in turbulent regime: A simulation study, Int. J. Heat Fluid Flow 29 (4) (2008) 1039-1053.
[40] R. Kaji, B.J. Azzopardi, D. Lucas, Investigation of flow development of co-current gas-liquid vertical slug flow, Int. J. Multiph. Flow 35 (4) (2009) 335-348.
[41] M.H. Zhang, L.M. Pan, H. He, X.H. Yang, M. Ishii, Experimental study of vertical co-current slug flow in terms of flow regime transition in relatively small diameter tubes, Int. J. Multiph. Flow 108 (2018) 140-155.
[42] A.M.F.R. Pinto, M.N. Coelho Pinheiro, J.B.L. Campos, On the interaction of Taylor bubbles rising in two-phase co-current slug flow in vertical columns: turbulent wakes, Exp. Fluids 31 (6) (2001) 643-652.
[43] D. Barnea, Effect of bubble shape on pressure drop calculations in vertical slug flow, Int. J. Multiph. Flow 16 (1) (1990) 79-89.
[44] A. Bonilla Riaño, I.H. Rodriguez, A.C. Bannwart, O.M.H. Rodriguez, Film thickness measurement in oil-water pipe flow using image processing technique, Exp. Therm. Fluid Sci. 68 (2015) 330-338.
[45] D.Y. Wang, N.D. Jin, L.S. Zhai, Y.Y. Ren, Measurement of liquid film thickness using distributed conductance sensor in multiphase slug flow, IEEE Trans. Ind. Electron. 67 (10) (2020) 8841-8850.
[46] S. Polonsky, L. Shemer, D. Barnea, The relation between the Taylor bubble motion and the velocity field ahead of it, Int. J. Multiph. Flow 25 (6-7) (1999) 957-975.
[47] S. Nogueira, R.G. Sousa, A.M.F.R. Pinto, M.L. Riethmuller, J.B.L.M. Campos, Simultaneous PIV and pulsed shadow technique in slug flow: A solution for optical problems, Exp. Fluids 35 (6) (2003) 598-609.
[48] Y.A. Al-Aufi, B.N. Hewakandamby, G. Dimitrakis, M. Holmes, A. Hasan, N.J. Watson, Thin film thickness measurements in two phase annular flows using ultrasonic pulse echo techniques, Flow Meas. Instrum. 66 (2019) 67-78.
[49] F.C. Liang, Z.J. Fang, J. Chen, S.T. Sun, Investigating the liquid film characteristics of gas-liquid swirling flow using ultrasound Doppler velocimetry, AIChE J. 63 (6) (2017) 2348-2357.
[50] L.C. Yan, Y.F. Wang, Z.W. Wu, Z.H. Dai, G.S. Yu, F.C. Wang, Research of vertical falling film behavior in scrubbing-cooling tube, Chem. Eng. Res. Des. 117 (2017) 627-636.
[51] W.K. Ren, N.D. Jin, L.S. Zhai, Y.Y. Ren, Measurement of liquid film thickness in vertical multiphase slug and churn flows using distributed ultrasonic method, IEEE Sens. J. 19 (22) (2019) 10537-10544.
[52] D.Y. Wang, N.D. Jin, L.S. Zhai, Y.Y. Ren, Salinity independent flow measurement of vertical upward gas-liquid flows in a small pipe using conductance method, Sensors 20 (18) (2020) 5263.