Measurement of local two-phase flow parameters of downward bubbly flow in mini pipes

Tatsuya Hazuku; Tomonori Ihara; Takashi Hibiki

doi:10.1007/s42757-019-0039-5

Experimental and Computational Multiphase Flow 2020, 2(2): 89-98 https://doi.org/10.1007/s42757-019-0039-5

Research Article | Issue | Published: 11 October 2019

Measurement of local two-phase flow parameters of downward bubbly flow in mini pipes

Show Author's Information Hide Author's Information Tatsuya Hazuku^¹(

), Tomonori Ihara^¹, Takashi Hibiki^²

1Faculty of Marine Technology, Tokyo University of Marine Science and Technology, 2-1-6 Etchujima, Koto, Tokyo 135-8533, Japan

2School of Nuclear Engineering, Purdue University, 400 Central Drive, West Lafayette, IN 47907-2017, USA

Keywords:

two-phase flow, two-fluid model, bubbly flow, phase distribution, lift force, interfacial area transport, mini channel

Cite this article:

Hazuku T, Ihara T, Hibiki T. Measurement of local two-phase flow parameters of downward bubbly flow in mini pipes. Experimental and Computational Multiphase Flow, 2020, 2(2): 89-98. https://doi.org/10.1007/s42757-019-0039-5

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Abstract

In order to extend a precise database on local two-phase flow parameters in mini pipes, experiments were conducted for adiabatic gas-liquid bubbly flows flowing down in vertical mini pipes with inner diameters of 1.03, 3.00, and 5.00 mm. A stereo image-processing was applied to observe the phase distribution characteristics in pipe cross-section. The local flow parameters including profiles of void fraction, Sauter mean bubble diameter, and interfacial area concentration in pipe cross-section were obtained at three axial locations in the test pipes with various flow conditions: superficial gas velocity of 0.00508-0.0834 m/s and superficial liquid velocity of 0.208-3.00 m/s. The axial developments of the local flow parameters were discussed in detail based on the obtained data and the visual observation. It was confirmed that the core peak distributions were formed at low liquid flow rate conditions in which the buoyancy force dominated while the wall peak distributions were formed at high liquid flow rate conditions in which the body acceleration due to the frictional pressure gradient dominated. The result indicated the existence of lift force pushing the bubbles towards the pipe wall even in vertical downward flows. The database obtained through the present experiment is expected to be useful in modeling the interfacial area transport terms, the validation of the existing lift force models as well as the benchmarking of various CFD simulation codes.

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About this article

Measurement of local two-phase flow parameters of downward bubbly flow in mini pipes

Show Author's information Hide Author's Information Tatsuya Hazuku^¹(

), Tomonori Ihara^¹, Takashi Hibiki^²

1Faculty of Marine Technology, Tokyo University of Marine Science and Technology, 2-1-6 Etchujima, Koto, Tokyo 135-8533, Japan

2School of Nuclear Engineering, Purdue University, 400 Central Drive, West Lafayette, IN 47907-2017, USA

Abstract

Keywords: two-phase flow, two-fluid model, bubbly flow, phase distribution, lift force, interfacial area transport, mini channel

References(34)

Chuang, T. J., Hibiki, T. 2015. Vertical upward two-phase flow CFD using interfacial area transport equation. Prog Nucl Energ, 85: 415-427.

DOI Google Scholar

Delhaye, J. M., Bricard, P. 1994. Interfacial area in bubbly flow: Experimental data and correlations. Nucl Eng Des, 151: 65-77.

DOI Google Scholar

Ghiaasiaan, S. M. 2003. Gas-liquid two-phase flow and boiling in mini and microchannels. Multiphase Sci Tech, 15: 323-334.

DOI Google Scholar

Gibson, A. H. 1913. LXXXIV. On the motion of long air-bubbles in a vertical tube. The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science, 26: 952-965.

DOI Google Scholar

Hazuku, T., Hibiki, T., Takamasa, T. 2016. Interfacial area transport due to shear collision of bubbly flow in small-diameter pipes. Nucl Eng Des, 310: 592-603.

DOI Google Scholar

Hazuku, T., Takamasa, T., Hibiki T. 2012. Characteristics of developing vertical bubbly flow under normal and microgravity conditions. Int J Multiphase Flow, 38: 53-66.

DOI Google Scholar

Hazuku, T., Takamasa, T., Hibiki, T. 2010. Interfacial-area transport of vertical upward bubbly flow in mini pipe. Int J Microscale and Nanoscale Thermal and Fluid Transport Phenomena, 1: 59-84.

Google Scholar

Hazuku, T., Takamasa, T., Hibiki, T. 2015. Phase distribution characteristics of bubbly flow in mini pipes under normal and microgravity conditions. Microgravity Sci Tech, 27: 75-96.

DOI Google Scholar

Hibiki, T., Hazuku, T., Takamasa, T., Ishii, M. 2007. Some characteristics of developing bubbly flow in a vertical mini pipe. Int J Heat Fluid Fl, 28: 1034-1048.

DOI Google Scholar

Hibiki, T., Hazuku, T., Takamasa, T., Ishii, M. 2009. Interfacial-area transport equation at reduced-gravity conditions. AIAA J, 47: 1123-1131.

DOI Google Scholar

Hibiki, T., Hogsett, S., Ishii, M. 1998. Local measurement of interfacial area, interfacial velocity and liquid turbulence in two-phase flow. Nucl Eng Des, 184: 287-304.

DOI Google Scholar

Hibiki, T., Ishii, M. 2001. Interfacial area concentration in steady fully-developed bubbly flow. Int J Heat Mass Tran, 44: 3443-3461.

DOI Google Scholar

Hibiki, T., Ishii, M. 2003. One-dimensional drift-flux model and constitutive equations for relative motion between phases in various two-phase flow regimes. Int J Heat Mass Tran, 46: 4935-4948.

DOI Google Scholar

Hibiki, T., Ishii, M. 2009. Interfacial area transport equations for gas- liquid flow. The Journal of Computational Multiphase Flows, 1: 1-22.

DOI Google Scholar

Hibiki, T., Ozaki, T., Shen, X. Z., Miwa, S., Kinoshita, I., Hazuku, T., Rassame, S. 2018. Constitutive equations for vertical upward two-phase flow in rod bundle. Int J Heat Mass Tran, 127: 1252-1266.

DOI Google Scholar

Hibiki, T., Takamasa, T., Ishii, M., Gabriel, K. S. 2006. One-dimensional drift-flux model at reduced gravity conditions. AIAA J, 44: 1635-1642.

DOI Google Scholar

Ishii, M., Hibiki, T. 2010. Thermo-Fluid Dynamics of Two-Phase Flow, 2nd edn. Springer Science & Business Media.

DOI

Kandlikar, S. G. 2002. Two-phase flow patterns, pressure drop, and heat transfer during boiling in minichannel flow passages of compact evaporators. Heat Transfer Eng, 23: 5-23.

DOI Google Scholar

Kandlikar, S. G. 2004. Heat transfer mechanisms during flow boiling in microchannels. J Heat Transfer, 126: 8-16.

DOI Google Scholar

Kocamustafaogullari, G., Huang, W. D., Razi, J. 1994. Measurement and modeling of average void fraction, bubble size and interfacial area. Nucl Eng Des, 148: 437-453.

DOI Google Scholar

Lin, C. H., Hibiki, T. 2014. Databases of interfacial area concentration in gas-liquid two-phase flow. Prog Nucl Energ, 74: 91-102.

DOI Google Scholar

Liu, H., Hibiki, T. 2018. Bubble breakup and coalescence models for bubbly flow simulation using interfacial area transport equation. Int J Heat Mass Tran, 126: 128-146.

DOI Google Scholar

Milliest, M., Drew, D. A., Lahey, R. T. Jr. 1996. A first order relaxation model for the prediction of the local interfacial area density in two-phase flows. Int J Multiphase Flow, 22: 1073-1104.

DOI Google Scholar

Mishima, K., Hibiki, T. 1996. Some characteristics of air-water two-phase flow in small diameter vertical tubes. Int J Multiphase Flow, 22: 703-712.

DOI Google Scholar

Qu, W. L., Mudawar, I. 2003. Measurement and prediction of pressure drop in two-phase micro-channel heat sinks. Int J Heat Mass Tran, 46: 2737-2753.

DOI Google Scholar

Serizawa, A., Feng, Z. P., Kawara, Z. 2002. Two-phase flow in microchannels. Exp Therm Fluid Sci, 26: 703-714.

DOI Google Scholar

Shen, X. Z., Hibiki, T. 2018. Bubble coalescence and breakup model evaluation and development for two-phase bubbly flows. Int J Multiphase Flow, 109: 131-149.

DOI Google Scholar

Shen, X. Z., Schlegel, J. P., Hibiki, T., Nakamura, H. 2018. Some characteristics of gas-liquid two-phase flow in vertical large-diameter channels. Nucl Eng Des, 333: 87-98.

DOI Google Scholar

Takamasa, T., Goto, T., Hibiki, T., Ishii, M. 2003. Experimental study of interfacial area transport of bubbly flow in small-diameter tube. Int J Multiphase Flow, 29: 395-409.

DOI Google Scholar

Takamasa, T., Miyoshi, N. 1993. Measurements of bubble interface configurations in vertical bubbly flow using image-processing method. Transactions of the Japan Society of Mechanical Engineers Series B, 59: 2403-2409.

DOI Google Scholar

Tomiyama, A., Kataoka, I., Zun, I., Sakaguchi, T. 1998. Drag coefficients of single bubbles under normal and micro gravity conditions. JSME International Journal Series B, 41: 472-479.

DOI Google Scholar

Wu, Q., Ishii, M. 1999. Sensitivity study on double-sensor conductivity probe for the measurement of interfacial area concentration in bubbly flow. Int J Multiphase Flow, 25: 155-173.

DOI Google Scholar

Zhang, W., Hibiki, T., Mishima, K., Mi, Y. 2006. Correlation of critical heat flux for flow boiling of water in mini-channels. Int J Heat Mass Tran, 49: 1058-1072.

DOI Google Scholar

Zuber, N., Findlay, J. A. 1965. Average volumetric concentration in two-phase flow systems. J Heat Transf, 87: 453-468.

DOI Google Scholar

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Publication history

Acknowledgements

Publication history

Received: 06 April 2019

Revised: 01 July 2019

Accepted: 01 July 2019

Published: 11 October 2019

Issue date: June 2020

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Acknowledgements

The authors are thankful to Professor T. Takamasa and Mrs. Y. Ohkubo of Tokyo University of Marine Science and Technology for their assistance in conducting the experiment.