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Lubricated pipelining: stability of core—annular flow. Part 5. Experiments and comparison with theory

Published online by Cambridge University Press:  26 April 2006

Runyuan Bai ,
Kangping Chen  and
D. D. Joseph
Runyuan Bai
Affiliation:
Department of Aerospace Engineering and Mechanics, University of Minnesota. 107 Akerman Hall, 110 Union Street SE, Minneapolis, MN 55455, USA
Kangping Chen
Affiliation:
Department of Aerospace Engineering and Mechanics, University of Minnesota. 107 Akerman Hall, 110 Union Street SE, Minneapolis, MN 55455, USA
D. D. Joseph
Affiliation:
Department of Aerospace Engineering and Mechanics, University of Minnesota. 107 Akerman Hall, 110 Union Street SE, Minneapolis, MN 55455, USA
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Abstract

Results are given for experiments on water-lubricated pipelining of 6.01 P cylinder oil in a vertical apparatus in up- and downflow in regimes of modest flow rates, less than 3 ft/s. Measured values of the flow rates, holdup ratios, pressure gradients and flow types are presented and compared with theoretical predictions based on ideal laminar flow and on the predictions of the linear theory of stability. New flow types, not achieved in horizontal flows, are observed: bamboo waves in upflow and corkscrew waves in downflow. Nearly perfect core–annular flows are observed in downflows and these are nearly optimally efficient with values close to the ideal. The holdup ratio in upflow and fast downflow is a constant independent of the value and the ratio of values of the flow rates of oil and water. A vanishing holdup ratio can be achieved by fluidizing a long lubricated column of oil in the downflow of water. The results of experiments are compared with computations from ideal theory for perfect core–annular flow and from the linear theory of stability. Satisfactory agreements are achieved for the celerity and diagnosis of flow type. The wave is shown to be nearly stationary, convected with the oil core in this oil and all oils of relatively high viscosity. These results are robust with respect to moderate changes in the values of viscosity and surface tension. The computed wavelengths are somewhat smaller than the average length of the bamboo waves which are observed. This is explained by stretching effects of buoyancy and lubrication forces induced by the wave. Other points of agreement and disagreement are reviewed.

Type
Research Article
Information
Journal of Fluid Mechanics , Volume 240 , July 1992 , pp. 97 - 132
Copyright
© 1992 Cambridge University Press

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References

Aul, R. W. & Olbricht, W. L. 1990 Stability of a thin annular film in pressure-driven low Reynolds number flow through a capillary. J. Fluid Mech. 215, 585.Google Scholar
Bentwich, M. 1976 Two-phase axial laminar flow in a pipe with naturally curved interface. Chem. Engng Sci. 31, 71.Google Scholar
Charles, M. E. 1963 The pipeline flow of capsules. Part 2: theoretical analysis of the concentric flow of cylindrical forms. Can. J. Chem. Engng 41, 46.Google Scholar
Charles, M. E., Govier, G. W. & Hodgson, G. W. 1961 The horizontal pipeline flow of equal density of oil—water mixtures. Can. J. Chem. Engng 39, 17 (referred to herein as CGH).Google Scholar
Charles, M. E. & Lilleht, L. U. 1966 Correlation of pressure gradients for the stratified laminar—turbulent pipeline flow of two immiscible liquids. Can. J. Chem. Engng 44, 47.Google Scholar
Charles, M. E. & Redberger, R. J. 1962 The reduction of pressure gradients in oil pipelines by the addition water: numerical analysis of stratified flow. Can. J. Chem. Engng 40, 70.Google Scholar
Chen, K., Bai, R. & Joseph, D. D. 1990 Lubricated pipelining. Part 3. Stability of core—annular flow in vertical pipes. J. Fluid Mech. 214, 251 (referred to herein as CBJ).Google Scholar
Chen, K. & Joseph, D. D. 1991 Lubricated pipelining: stability of core—annular flow. Part 4. Ginzburg—Landau equations. J. Fluid Mech. 227, 587.Google Scholar
Chernikin, V. I. 1956 Combined pumping of petroleum and water in pipes. Trudi. Mock. Neft. inta 17, 101111.Google Scholar
Clark, A. F. & Shapiro, A. 1949 Method of pumping viscous petroleum. US Patent No. 2533878.Google Scholar
Frenkel, A. L. 1988 Nonlinear saturation of core—annular flow instabilities. In Proc. Sixth Symp. on Energy Engineering sciences. Argonne National laboratory.
Frenkel, A. L., Babchin, A. J., Levich, B. G., Shlang, T. & Shivashinsky, G. I. 1987 Annular flows can keep unstable films from breakup: nonlinear saturation of capillary instability. J. Colloid Interface Sci. 115, 225.Google Scholar
Gemmell, A. R. & Epstein, N. 1962 Numerical analysis of stratified laminar flow of two immiscible Newtonian liquids in circular pipes. Can. J. Chem. Engng 40, 215.Google Scholar
Glass, W. 1961 Water addition aids pumping viscous oils. Chem. Engng Prog. 57, 116.Google Scholar
Hasson, D., Mann, U. & Nir, A. 1970 Annular flow of two immiscible liquids. I. Mechanisms. Can. J. Chem. Engng 48, 514.Google Scholar
Hickox, C. E. 1971 Instability due to viscosity and density stratification in axisymmetric pipe flow. Phys. Fluids 14, 251.Google Scholar
Hooper, A. P. & Boyd, W. G. C. 1983 Shear flow instability at the interface between two viscous fluids. J. Fluid Mech. 128, 507.Google Scholar
Hu, H. & Joseph, D. D. 1989a Lubricated pipelining: stability of core—annular flow. Part 2. J. Fluid Mech. 205, 359.Google Scholar
Hu, H. & Joseph, D. D. 1989b Stability of core—annular flow in a rotating pipe.. Phys. Fluids A 1, 1677.Google Scholar
Hu, H., Lundgren, T. S. & Joseph, D. D. 1990 Stability of core—annular flow with a small viscosity ratio.. Phys. Fluids A 2, 1945.Google Scholar
Isaacs, J. D. & Speed, J. B. 1904 Method of piping fluids. US Patent No. 759374.
Joseph, D. D., Nguyen, K. & Beavers, G. S. 1984a Non-uniqueness and stability of the configuration of flow of immiscible fluids with different viscosities. J. Fluid Mech. 141, 319.Google Scholar
Joseph, D. D., Renardy, Y. & Renardy, M. 1984b Instability of the flow of immiscible liquids with different viscosities in a pipe. J. Fluid Mech. 141, 309.Google Scholar
Joseph, D. D. & Saut, J. C. 1990 Short-wave instabilities and ill-posed initial-value problems. Theor. Comput. Fluid Dyn. 1, 191.Google Scholar
Joseph, D. D., Singh, P. & Chen, K. 1990 Couette flows, rollers, emulsions, tall Taylor cells, phase separation and inversion, and a chaotic bubble in Taylor—Couette flow of two immiscible liquids. In Nonlinear Evolution of Spatio-temporal Structures in Dissipative Continuous Systems (ed. F. H. Busse & L. Kramer). Plenum
Kao, T. W. & Park, C. 1972 Experimental investigations of the stability of channel flows. Part 2. Two-layered co-current flow in a rectangular channel. J. Fluid Mech. 52, 401.Google Scholar
Lin, S. P. & Ibrahim, E. A. 1990 Instability of a viscous liquid jet surrounded by a viscous gas in a vertical pipe. J. Fluid Mech. 218, 641.Google Scholar
Looman, M. D. 1916 Method of conveying oil. US Patent No. 1119438.Google Scholar
Oliemans, R. V. A., Ooms, G., Wu, H. L. & Duÿvestin, A. 1985 Core—annular oil/water flow: the turbulent-lubricating model and measurements in a 2 in. pipe loop. Presented at the Middle East Oil Technical Conf. and Exhibition, Bahrain, March 11–14, 1985. Society of Petroleum Engineers.
Ooms, G. 1971 Fluid-mechanical studies of core—annular flow. Ph.D. Thesis, Delft University of Technology.
Ooms, G., Segal, A., Cheung, S. Y. & Oliemans, R. V. A. 1985 Propagation of long waves of finite amplitude at the interface of two viscous fluids. Intl J. Multiphase Flow 9, 481.Google Scholar
Oom, G., Segal, A., Van der Wees, A. J., Meerhoff, R. & Oliemans, R. V. A. 1984 A theoretical model for core—annular flow of a very viscous oil core and a water annulars through a horizontal pipe. Intl J. Multiphase Flow 10, 41.Google Scholar
Papageorgiou, D. T., Maldarelli, C. & Rumschitzki, D. S. 1990 Nonlinear interfacial stability of core annular film flows.. Phys. Fluids A 2, 340.Google Scholar
Preziosi, L., Chen, K. & Joseph, D. D. 1989 Lubricated pipelining: stability of core—annular flow. J. Fluid Mech. 201, 323 (referred to herein as PCJ).Google Scholar
Ranger, K. B. & Davis, A. M. 1979 Steady pressure driven two-phase stratified laminar flow through a pipe. Can. J. Chem. Engng 57, 688.Google Scholar
Russell, T. W. F. & Charles, M. E. 1959 The effect of the less viscous liquid in the laminar flow of two immiscible liquids. Can. J. Chem. Engng 39, 18.Google Scholar
Russell, T. W. F., Hodgson, G. W. & Govier, G. W. 1959 Horizontal pipeline flow of mixtures of oil and water. Can. J. Chem. Engng 37, 9.Google Scholar
Shertok, J. T. 1976 Velocity profiles in core—annular flow using a laser-Doppler velocimeter. Ph.D. Thesis, Princeton University.
Smith, M. K. 1989 The axisymmetric long-wave instability of a concentric two-phase pipe flows.. Phys. Fluids A 1, 494.Google Scholar
Stein, M. H. 1978 Concentric annular oil—water flow. Ph.D. Thesis, Pursue University.
Yu, H. S. & Sparrow, E. M. 1967 Stratified laminar flow in ducts of arbitrary space. AIChE J. 13, 10.Google Scholar