The flow of oil/water mixtures in a pipe can occur under different flow patterns. Additionally, being able to predict adequately pressure drop in such systems is of relevant importance to adequately design the conveying system. In this work, an experimental and numerical study of the fully dispersed flow regime of an oil/water mixture (liquid paraffin and water) in a horizontal pipe, with concentrations of the oil of 0.01, 0.13, and 0.22 v/v were developed. Experimentally, the values of pressure drop, flow photographs, and radial volumetric concentrations of the oil in the vertical diameter of the pipe cross section were collected. In addition, normalized conductivity values were obtained, in this case, for a cross section of the pipe where an electrical impedance tomography (EIT) ring was installed. Numerical studies were carried out in the comsolmultiphysics platform, using the Euler–Euler approach, coupled with the k–ε turbulence model. In the simulations, two equations for the calculation of the drag coefficient, Schiller–Neumann and Haider–Levenspiel, and three equations for mixture viscosity, Guth and Simba (1936), Brinkman (1952), and Pal (2000), were studied. The simulated data were validated with the experimental results of the pressure drop, good results having been obtained. The best fit occurred for the simulations that used the Schiller–Neumann equation for the calculation of the drag coefficient and the Pal (2000) equation for the mixture viscosity.
References
1.
Al-Wahaibi
, T.
, and Angeli
, P.
, 2011
, “Experimental Study on Interfacial Waves in Stratified Horizontal Oil–Water Flow
,” Int. J. Multiph. Flow
, 37
(8
), pp. 930
–940
.2.
Grassi
, B.
, Strazza
, D.
, and Poesio
, P.
, 2008
, “Experimental Validation of Theoretical Models in Two-Phase High-Viscosity Ratio Liquid–Liquid Flows in Horizontal and Slightly Inclined Pipes
,” Int. J. Multiph. Flow
, 34
(10
), pp. 950
–965
.3.
Mandal
, T. K.
, Chakrabarti
, D. P.
, and Das
, G.
, 2007
, “Oil Water Flow Through Different Diameter Pipes: Similarities And Differences
,” Chem. Eng. Res. Des.
, 85
(8
), pp. 1123
–1128
.4.
Trallero
, J. L.
, Sarica
, C.
, and Brill
, J. P.
, 1997
, “A Study of Oil-Water Flow Patterns in Horizontal Pipes
,” SPE Prod. Facil.
, 12
(03
), pp. 165
–172
.5.
Wang
, M.
, 2015
, Industrial Tomography: Systems and Applications
, Elsevier
, Boston, MA
.6.
Porombka
, P.
, and Höhne
, T.
, 2015
, “Drag and Turbulence Modelling for Free Surface Flows Within the Two-Fluid Euler–Euler Framework
,” Chem. Eng. Sci.
, 134
, pp. 348
–359
.7.
Tornberg
, A.-K.
, and Engquist
, B.
, 2000
, “A Finite Element Based Level-Set Method for Multiphase Flow Applications
,” Comput. Vis. Sci.
, 3
(1–2
), pp. 93
–101
.8.
Rosa
, E. S.
, 2012
, Escoamento Multifásico Isotérmico: Modelos de Multifluidos e de Mistura
, Bookman, Porto Alegre
, RS, Brasil
.9.
Ishii
, M.
, 2006
, Thermo-Fluid Dynamics of Two Phase-Flow
, Springer Science-Business Media
, New York
.10.
Rodriguez
, O. M. H.
, 2011
, Escoamento Multifásico
, ABCM—Associação Brasileira de Engenharia e Ciências Mecânica
, Rio de Janeiro, Brasil
.11.
Wörner
, M.
, 2003
, A Compact Introduction to the Numerical Modeling of Multiphase Flows
, Forschungszentrum Karlsruhe
, Karlsruhe, Alemanha
.12.
Hurisse
, O.
, 2017
, “Numerical Simulations of Steady and Unsteady Two-Phase Flows Using a Homogeneous Model
,” Comput. Fluids
, 152
, pp. 88
–103
.13.
Olsen
, J. E.
, and Skjetne
, P.
, 2016
, “Modelling of Underwater Bubble Plumes and Gas Dissolution With an Eulerian-Lagrangian CFD Model
,” Appl. Ocean Res.
, 59
, pp. 193
–200
.14.
Ireland
, P. J.
, and Desjardins
, O.
, 2017
, “Improving Particle Drag Predictions in Euler–Lagrange Simulations With Two-Way Coupling
,” J. Comput. Phys.
, 338
, pp. 405
–430
.15.
Kommission
, E.
, Sommerfeld
, M.
, van Wachem
, B.
, Oliemans
, R.
, and SIAMUF
, eds., 2008
, Best Practice Guidelines for Computational Fluid Dynamics of Dispersed Multi-Phase Flows
, European Research Community on Flow, Turbulence and Combustion (ERCOFTAC)
, Brüssel, Belgium
.16.
Silva
, R.
, 2015
, “Solid/Liquid Suspension Flow in Pipes: Modelling and Experimental Investigation
,” Ph.D. thesis, University of Coimbra, Coimbra, Portugal.17.
Zhou
, L. X.
, 2016
, “A Review for Developing Two-Fluid Modeling and LES of Turbulent Combusting Gas-Particle Flows
,” Powder Technol.
, 297
, pp. 438
–447
.18.
Duret
, B.
, Reveillon
, J.
, Menard
, T.
, and Demoulin
, F. X.
, 2013
, “Improving Primary Atomization Modeling Through DNS of Two-Phase Flows
,” Int. J. Multiph. Flow
, 55
, pp. 130
–137
.19.
Mollik
, T.
, Roy
, B.
, and Saha
, S.
, 2017
, “Turbulence Modeling of Channel Flow and Heat Transfer: A Comparison With DNS Data
,” Procedia Eng.
, 194
, pp. 450
–456
.20.
Tsukahara
, T.
, Kawase
, T.
, and Kawaguchi
, Y.
, 2011
, “DNS of Viscoelastic Turbulent Channel Flow With Rectangular Orifice at Low Reynolds Number
,” Int. J. Heat Fluid Flow
, 32
(3
), pp. 529
–538
.21.
Hua
, L.
, Zhao
, H.
, Li
, J.
, Wang
, J.
, and Zhu
, Q.
, 2015
, “Eulerian–Eulerian Simulation of Irregular Particles in Dense Gas–Solid Fluidized Beds
,” Powder Technol.
, 284
, pp. 299
–311
.22.
Cubero
, A.
, Sánchez-Insa
, A.
, and Fueyo
, N.
, 2015
, “Crossing Trajectories and Phase Change in Eulerian–Eulerian Models of Disperse Multiphase Flows
,” Int. J. Multiph. Flow
, 72
, pp. 141
–144
.23.
Schillings
, J.
, Doche
, O.
, Tano Retamales
, M.
, Bauer
, F.
, Deseure
, J.
, and Tardu
, S.
, 2017
, “Four-Way Coupled Eulerian–Lagrangian Direct Numerical Simulations in a Vertical Laminar Channel Flow
,” Int. J. Multiph. Flow
, 89
, pp. 92
–107
.24.
Banowski
, M.
, Hampel
, U.
, Krepper
, E.
, Beyer
, M.
, and Lucas
, D.
, 2017
, “Experimental Investigation of Two-Phase Pipe Flow With Ultrafast X-Ray Tomography and Comparison With State-of-the-Art CFD Simulations
,” Nucl. Eng. Des.
, 336
, pp. 90
–104
.25.
Burlutskiy
, E.
, and Turangan
, C. K.
, 2015
, “A Computational Fluid Dynamics Study on Oil-in-Water Dispersion in Vertical Pipe Flows
,” Chem. Eng. Res. Des.
, 93
, pp. 48
–54
.26.
Arunkumar
, S.
, Adhavan
, J.
, Venkatesan
, M.
, Das
, S. K.
, and Balakrishnan
, A. R.
, 2016
, “Two Phase Flow Regime Identification Using Infrared Sensor and Volume of Fluids Method
,” Flow Meas. Instrum.
, 51
, pp. 49
–54
.27.
Bilger
, C.
, Aboukhedr
, M.
, Vogiatzaki
, K.
, and Cant
, R. S.
, 2017
, “Evaluation of Two-Phase Flow Solvers Using Level Set and Volume of Fluid Methods
,” J. Comput. Phys.
, 345
, pp. 665
–686
.28.
Pozzetti
, G.
, and Peters
, B.
, 2018
, “A Multiscale DEM-VOF Method for the Simulation of Three-Phase Flows
,” Int. J. Multiph. Flow
, 99
, pp. 186
–204
.29.
Amiri
, H. A.
, and Hamouda
, A. A.
, 2013
, “Evaluation of Level Set and Phase Field Methods in Modeling Two Phase Flow With Viscosity Contrast Through Dual-Permeability Porous Medium
,” Int. J. Multiph. Flow
, 52
, pp. 22
–34
.30.
Olsson
, E.
, Kreiss
, G.
, and Zahedi
, S.
, 2007
, “A Conservative Level Set Method for Two Phase Flow II
,” J. Comput. Phys.
, 225
(1
), pp. 785
–807
.31.
Yap
, Y. F.
, Li
, H. Y.
, Lou
, J.
, Pan
, L. S.
, and Shang
, Z.
, 2017
, “Numerical Modeling of Three-Phase Flow With Phase Change Using the Level-Set Method
,” Int. J. Heat Mass Transfer
, 115
, pp. 730
–740
.32.
Zhao
, Y.
, Zhao
, C. Y.
, and Xu
, Z. G.
, 2018
, “Numerical Study of Solid-Liquid Phase Change by Phase Field Method
,” Comput. Fluids
, 164
, pp. 94
–101
.33.
Pouraria
, H.
, Seo
, J. K.
, and Paik
, J. K.
, 2016
, “Numerical Modelling of Two-Phase Oil–Water Flow Patterns in a Subsea Pipeline
,” Ocean Eng.
, 115
, pp. 135
–148
.34.
Walvekar
, R. G.
, Choong
, T. S. Y.
, Hussain
, S. A.
, Khalid
, M.
, and Chuah
, T. G.
, 2009
, “Numerical Study of Dispersed Oil–Water Turbulent Flow in Horizontal Tube
,” J. Pet. Sci. Eng.
, 65
(3–4
), pp. 123
–128
.35.
Liu
, N.
, Wang
, W.
, Wang
, Y.
, Wang
, Z.
, Han
, J.
, Wu
, C.
, and Gong
, J.
, 2017
, “Comparison of Turbulent Flow Characteristics of Liquid-Liquid Dispersed Flow Between CFD Simulations and Direct Measurements With Particle Image Velocimetry
,” Appl. Therm. Eng.
, 125
, pp. 1209
–1217
.36.
Rodriguez
, O. M. H.
, and Baldani
, L. S.
, 2012
, “Prediction of Pressure Gradient and Holdup in Wavy Stratified Liquid–Liquid Inclined Pipe Flow
,” J. Pet. Sci. Eng.
, 96–97
, pp. 140
–151
.37.
Wang
, W.
, Gong
, J.
, and Angeli
, P.
, 2011
, “Investigation on Heavy Crude-Water Two Phase Flow and Related Flow Characteristics
,” Int. J. Multiph. Flow
, 37
(9
), pp. 1156
–1164
.38.
Silva
, R.
, Garcia
, F. A. P.
, Faia
, P. M.
, Krochak
, P.
, Söderberg
, D.
, Lundell
, F.
, and Rasteiro
, M. G.
, 2016
, “Validating Dilute Settling Suspensions Numerical Data Through MRI, UVP and EIT Measurements
,” Flow Meas. Instrum.
, 50
, pp. 35
–48
.39.
Cotas
, C. I. P.
, 2016
, “Modelling of Fiber Suspensions Flow in Pipes
,” Ph.D. thesis
, University of Coimbra, Coimbra, Portugal.https://estudogeral.uc.pt/bitstream/10316/29788/1/Modelling%20of%20Fiber%20Suspensions%20Flow%20in%20Pipes.pdf40.
Faia
, P. M.
, Silva
, R.
, Rasteiro
, M. G.
, Garcia
, F. A. P.
, Ferreira
, A. R.
, Santos
, M. J.
, Santos
, J. B.
, and Coimbra
, A. P.
, 2012
, “Imaging Particulate Two-Phase Flow in Liquid Suspensions With Electric Impedance Tomography
,” Part. Sci. Technol.
, 30
(4
), pp. 329
–342
.41.
Polydorides
, N.
, and Lionheart
, W. R. B.
, 2002
, “A Matlab Toolkit for Three-Dimensional Electrical Impedance Tomography: A Contribution to the Electrical Impedance and Diffuse Optical Reconstruction Software Project
,” Meas. Sci. Technol.
, 13
(12
), pp. 1871
–1883
.42.
Parekh
, J.
, and Rzehak
, R.
, 2018
, “Euler–Euler Multiphase CFD-Simulation With Full Reynolds Stress Model and Anisotropic Bubble-Induced Turbulence
,” Int. J. Multiph. Flow
, 99
, pp. 231
–245
.43.
COMSOL Multiphysics
, 2013
, “User Guide Version 4.4
,” COMSOL Multiphysics, Stockholm, Sweden.44.
Ishii
, M.
, and Zuber
, N.
, 1979
, “Drag Coefficient and Relative Velocity in Bubbly, Droplet or Particulate Flows
,” AIChE J.
, 25
(5
), pp. 843
–855
.45.
Liu
, Z.
, and Li
, B.
, 2018
, “Scale-Adaptive Analysis of Euler-Euler Large Eddy Simulation for Laboratory Scale Dispersed Bubbly Flows
,” Chem. Eng. J.
, 338
, pp. 465
–477
.46.
Wachem
, V. B. G.
, Schouten
, J. C.
, van den Bleek
, C. M.
, Krishna
, R.
, and Sinclair
, J. L.
, 2001
, “Comparative Analysis of CFD Models of Dense Gas–Solid Systems
,” AIChE J.
, 47
(5
), pp. 1035
–1051
.47.
Guth
, E.
, and Simba
, R.
, 1936
, “Investigations of Viscosity of Suspensions and Solutions: Part 3. The Viscosity of Spherical Suspensions
,” Kolloid-Zeitschrift
, 74
(3
), pp. 266
–275
.48.
Kundu
, P.
, Kumar
, V.
, and Mishra
, I. M.
, 2015
, “Modeling the Steady-Shear Rheological Behavior of Dilute to Highly Concentrated Oil-in-Water (o/w) Emulsions: Effect of Temperature, Oil Volume Fraction and Anionic Surfactant Concentration
,” J. Pet. Sci. Eng.
, 129
, pp. 189
–204
.49.
Xu
, X.-X.
, 2007
, “Study on Oil–Water Two-Phase Flow in Horizontal Pipelines
,” J. Pet. Sci. Eng.
, 59
(1–2
), pp. 43
–58
.50.
Sharma
, A.
, Al-Sarkhi
, A.
, Sarica
, C.
, and Zhang
, H.-Q.
, 2011
, “Modeling of Oil–Water Flow Using Energy Minimization Concept
,” Int. J. Multiph. Flow
, 37
(4
), pp. 326
–335
.51.
Brinkman
, H. C.
, 1952
, “The Viscosity of Concentrated Suspensions and Solutions
,” J. Chem. Phys.
, 20
(4
), p. 571
.52.
Pal
, R.
, 2000
, “Viscosity-Concentration Equation for Emulsions of Nearly Spherical Droplets
,” J. Colloid Interface Sci.
, 231
(1
), pp. 168
–175
.53.
Kuzmin
, D.
, Mierka
, O.
, and Turek
, S.
, 2007
, “On the Implementation of the κ-ε Turbulence Model in Incompressible Flow Solvers Based on a Finite Element Discretisation
,” Int. J. Comput. Sci. Math.
, 1
(2/3/4
), p. 193
.54.
Lopez de Bertodano
, M.
, Lahey
, R. T.
, and Jones
, O. C.
, 1994
, “Development of a K-ɛ Model for Bubbly Two-Phase Flow
,” ASME J. Fluids Eng.
, 116
(1
), p. 128
.55.
Hou
, B.
, Wang
, X.
, Zhang
, T.
, and Li
, H.
, 2017
, “A Model for Improving the Euler–Euler Two-Phase Flow Theory to Predict Chemical Reactions in Circulating Fluidized Beds
,” Powder Technol.
, 321
, pp. 13
–30
.56.
Pond
, I.
, Ebadi
, A.
, Dubief
, Y.
, and White
, C. M.
, 2017
, “An Integral Validation Technique of RANS Turbulence Models
,” Comput. Fluids
, 149
, pp. 150
–159
.57.
COMSOL Multiphysics
, 2013
, “User Guide Version 5.5
,” COMSOL Multiphysics, Stockholm, Sweden.58.
Wilcox
, D. C.
, 2006
, Turbulence Modeling for CFD
, DCW Industries
, La Cãnada, CA
.59.
da Silva
, M.
, Sad
, C. M. S.
, Pereira
, L. B.
, Corona
, R. R. B.
, Bassane
, J. F. P.
, dos Santos
, F. D.
, Neto
, D. M. C.
, Silva
, S. R. C.
, Castro
, E. V. R.
, and Filgueiras
, P. R.
, 2018
, “Study of the Stability and Homogeneity of Water in Oil Emulsions of Heavy Oil
,” Fuel
, 226
, pp. 278
–285
.60.
Dražić
, S.
, Sladoje
, N.
, and Lindblad
, J.
, 2016
, “Estimation of Feret's Diameter From Pixel Coverage Representation of a Shape
,” Pattern Recognit. Lett.
, 80
, pp. 37
–45
.61.
Allen
, T.
, 2013
, Particle Size Measurement
, Springer
, New York
.62.
Fangary
, Y. S.
, Williams
, R. A.
, Neil
, W. A.
, Bond
, J.
, and Faulks
, I.
, 1998
, “Application of Electrical Resistance Tomography to Detect Deposition in Hydraulic Conveying Systems
,” Powder Technol.
, 95
(1
), pp. 61
–66
.63.
Norman
, J. T.
, Nayak
, H. V.
, and Bonnecaze
, R. T.
, 2005
, “Migration of Buoyant Particles in Low-Reynolds-Number Pressure-Driven Flows
,” J. Fluid Mech.
, 523
, pp. 1
–35
.64.
Wang
, M.
, Jones
, T. F.
, and Williams
, R. A.
, 2003
, “Visualization of Asymmetric Solids Distribution in Horizontal Swirling Flows Using Electrical Resistance Tomography
,” Chem. Eng. Res. Des.
, 81
(8
), pp. 854
–861
.65.
Giguère
, R.
, Fradette
, L.
, Mignon
, D.
, and Tanguy
, P. A.
, 2008
, “Characterization of Slurry Flow Regime Transitions by ERT
,” Chem. Eng. Res. Des.
, 86
(9
), pp. 989
–996
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