Real-time monitoring of pressure and flow in multiphase flow applications is a critical problem given its economic and safety impacts. Using physics-based models has long been computationally expensive due to the spatial–temporal dependency of the variables and the nonlinear nature of the governing equations. This paper proposes a new reduced-order modeling approach for transient gas–liquid flow in pipes. In the proposed approach, artificial neural networks (ANNs) are considered to predict holdup and pressure drop at steady-state from which properties of the two-phase mixture are derived. The dynamic response of the mixture is then estimated using a dissipative distributed-parameter model. The proposed approach encompasses all pipe inclination angles and flow conditions, does not require a spatial discretization of the pipe, and is numerically stable. To validate our model, we compared its dynamic response to that of OLGA©, the leading multiphase flow dynamic simulator. The obtained results showed a good agreement between both models under different pipe inclinations and various levels of gas volume fractions (GVF). In addition, the proposed model reduced the computational time by four- to sixfolds compared to OLGA©. The above attribute makes it ideal for real-time monitoring and fluid flow control applications.
Issue Section:
Multiphase Flows
References
1.
Bonizzi
, M.
, Andreussi
, P.
, and Banerjee
, S.
, 2009
, “Flow Regime Independent, High Resolution Multi-Field Modelling of Near-Horizontal Gas–Liquid Flows in Pipelines
,” Int. J. Multiphase Flow
, 35
(1
), pp. 34
–46
.2.
Nicklin
, D. J.
, 1962
, “Two-Phase Bubble Flow
,” Chem. Eng. Sci.
, 17
(9
), pp. 693
–702
.3.
Zuber
, N.
, and Findlay
, J. A.
, 1965
, “Average Volumetric Concentration in Two-Phase Flow Systems
,” ASME J. Heat Transfer
, 87
(4
), p. 453
.4.
Cunliffe
, R. S.
, 1978
, “Prediction of Condensate Flow Rates in Large Diameter High Pressure Wet Gas Pipelines
,” APPEA J.
, 18
(1
), p. 171
.5.
Modisette
, L.
, and Whaley
, R. S.
, 1983
, “Transient Two-Phase Flow
,” PSIG Annual Meeting
, Detroit, MI, Oct. 27–28, pp. 27
–28
.https://www.onepetro.org/conference-paper/PSIG-83026.
Sharma
, Y.
, Scoggins
, M. W.
, Shoham
, O.
, and Brill
, J. P.
, 1986
, “Simulation of Transient Two-Phase Flow in Pipelines
,” ASME J. Energy Resour. Technol.
, 108
(3
), pp. 202
–206
.7.
Kohda
, K.
, Suzukawa
, Y.
, and Furukawa
, H.
, 1988
, “Analysis of Transient Gas-Liquid Two-Phase Flow in Pipelines
,” ASME J. Energy Resour. Technol.
, 110
(2
), pp. 93
–101
.8.
Bendiksen
, K. H.
, Maines
, D.
, Moe
, R.
, and Nuland
, S.
, 1991
, “The Dynamic Two-Fluid Model OLGA: Theory and Application
,” SPE Prod. Eng.
, 6
(2
), pp. 171
–180
.9.
Black
, P. S.
, Daniels
, L. C.
, Hoyle
, N. C.
, and Jepson
, W. P.
, 1990
, “Studying Transient Multi-Phase Flow Using the Pipeline Analysis Code (PLAC)
,” ASME J. Energy Resour. Technol.
, 112
(1
), pp. 25
–29
.10.
Goldszal
, A.
, Monsen
, J. I.
, Danielson
, T. J.
, Bansal
, K. M.
, Yang
, Z. L.
, Johansen
, S. T.
, and Depay
, G.
, 2007
, “Ledaflow 1D: Simulation Results With Multiphase Gas/Condensate and Oil/Gas Field Data
,” 13th International Conference on Multiphase Production Technology, Edinburgh, UK, June 13–15, Paper No. BHR-2007-A2
.https://www.onepetro.org/conferences/BHR/BHR0711.
Poesio
, P.
, 2017
, “A Transient, Two Fluid Model for Slug Flow Characterization
,” AIChE Annual Meeting
, Minneapolis, MN, Oct. 30–31, Paper No. ANL-77-47.https://www.tib.eu/en/search/id/ceaba%3ACEAB1995480520/A-transient-two-fluid-model-for-the-simulation/12.
Alves
, M. V. C.
, Waltrich
, P. J.
, Gessner
, T. R.
, Falcone
, G.
, and Barbosa
, J. R.
, 2017
, “Modeling Transient Churn-Annular Flows in a Long Vertical Tube
,” Int. J. Multiphase Flow
, 89
, pp. 399
–412
.13.
Zhibaedov
, V. D.
, Lebedeva
, N. A.
, Osiptsov
, A. A.
, and Sin'kov
, K. F.
, 2016
, “On the Hyperbolicity of One-Dimensional Models for Transient Two-Phase Flow in a Pipeline
,” Fluid Dyn.
, 51
(1
), pp. 56
–69
.14.
Ishii
, M.
, 1977
, “One-Dimensional Drift-Flux Model and Constitutive Equations for Relative Motion Between Phases in Various Two-Phase Flow Regimes
,” Argonne National Laboratory Argonne, IL, Report No. ANL-77-47
.15.
Malekzadeh
, R.
, Belfroid
, S. P. C.
, and Mudde
, R. F.
, 2012
, “Transient Drift Flux Modelling of Severe Slugging in Pipeline-Riser Systems
,” Int. J. Multiphase Flow
, 46
, pp. 32
–37
.16.
Spesivtsev
, P. E.
, Kharlashkin
, A. D.
, and Sinkov
, K. F.
, 2017
, “Study of the Transient Terrain-Induced and Severe Slugging Problems by Use of the Drift-Flux Model
,” SPE J.
, 22
(5
), pp. 1570
–1584
.17.
Choi
, J.
, Pereyra
, E.
, Sarica
, C.
, Lee
, H.
, Jang
, I. S.
, and Kang
, J.
, 2013
, “Development of a Fast Transient Simulator for Gas–Liquid Two-Phase Flow in Pipes
,” J. Pet. Sci. Eng.
, 102
, pp. 27
–35
.18.
Wang
, N.
, Sun
, B.
, Wang
, Z.
, Wang
, J.
, and Yang
, C.
, 2016
, “Numerical Simulation of Two phase flow in Wellbores by Means of Drift Flux Model and Pressure Based Method
,” J. Nat. Gas Sci. Eng.
, 36
, pp. 811
–823
.19.
Osiptsov
, A. A.
, Sin'kov
, K. F.
, and Spesivtsev
, P. E.
, 2014
, “Justification of the Drift-Flux Model for Two-Phase Flow in a Circular Pipe
,” Fluid Dyn.
, 49
(5
), pp. 614
–626
.20.
Pauchon
, C. L.
, and Hasmuekh
, D.
, 1994
, “TACITE: A Transient Tool for Multiphase Pipeline and Well Simulation
,” SPE Annual Technical Conference and Exhibition, New Orleans, LA, Sept. 25–28. Paper No. SPE-28545-MS
.https://www.onepetro.org/conference-paper/SPE-28545-MS21.
Holmås
, K.
, and Løvli
, A.
, 2011
, “Flowmanager™ Dynamic: A Multiphase Flow Simulator for Online Surveillance, Optimization and Prediction of Subsea Oil and Gas Production
,” 15th International Conference on Multiphase Production Technology, Cannes, France, June 15–17, Paper No. BHR-2011-F3
.https://www.onepetro.org/conference-paper/BHR-2011-F322.
Krasnopolsky
, B.
, Starostin
, A.
, and Osiptsov
, A. A.
, 2016
, “Unified Graph-Based Multi-Fluid Model for Gas–Liquid Pipeline Flows
,” Comput. Math. Appl.
, 72
(5
), pp. 1244
–1262
.23.
Ishii
, M.
, and Hibiki
, T.
, 2005
, Thermo-Fluid Dynamics of Two-Phase Flow
, Springer
, New York
.24.
Masella
, J. M.
, Tran
, Q. H.
, Ferre
, D.
, and Pauchon
, C.
, 1998
, “Transient Simulation of Two-Phase Flows in Pipes
,” Int. J. Multiphase Flow
, 24
(5
), pp. 739
–755
.25.
Spesivtsev
, P.
, Sinkov
, K.
, and Osiptsov
, A.
, 2013
, “Comparison of Drift-Flux and Multi-Fluid Approaches to Modeling of Multiphase Flow in Oil and Gas Wells
,” WIT Trans. Eng. Sci.
, 79
, pp. 89
–99
.26.
Taitel
, Y.
, Shoham
, O.
, and Brill
, J. P.
, 1990
, “Transient Two-Phase Flow in Low Velocity Hilly Terrain Pipelines
,” Int. J. Multiphase Flow
, 16
(1
), pp. 69
–77
.27.
Minami
, K.
, and Shoham
, O.
, 1994
, “Transient Two-Phase Flow Behavior in Pipelines-Experiment and Modeling
,” Int. J. Multiphase Flow
, 20
(4
), pp. 739
–752
.28.
Aarsnes
, U. J. F.
, Ambrus
, A.
, Vajargah
, A. K.
, Aamo
, O. M.
, and van Oort
, E.
, 2015
, “A Simplified Gas-Liquid Flow Model for Kick Mitigation and Control During Drilling Operations
,” ASME
Paper No. DSCC2015-9791.29.
Aarsnes
, U. J. F.
, Ambrus
, A.
, Di Meglio
, F.
, Vajargah
, A. K.
, Aamo
, O. M.
, and van Oort
, E.
, 2016
, “A Simplified Two-Phase Flow Model Using a Quasi-Equilibrium Momentum Balance
,” Int. J. Multiphase Flow
, 83
, pp. 77
–85
.30.
Kirpalani
, D.
, 2000
, “Novel Signal Processing Approaches for Characterization of Transient Two-Phase Gas-Liquid Flow
,” Ph.D. thesis, University of Ottawa, Ottawa, ON.31.
Fichera
, A.
, and Pagano
, A.
, 2017
, “A Neural Tool for the Prediction of the Experimental Dynamics of Two-Phase Flows
,” Int. J. Heat Technol.
, 35
(2
), pp. 235
–242
.32.
Zou
, L.
, Zhao
, H.
, and Zhang
, H.
, 2017
, “Numerical Uncertainties vs. Model Uncertainties in Two-Phase Flow Simulations
,” ANS Annual Meeting
, San Francisco, CA, June 11–15, pp. 1255
–1258
.33.
Belozerov
, A. A.
, Romenski
, E. I.
, and Lebedeva
, N. A.
, 2018
, “Numerical Modeling of Gas-Liquid Compressible Pipe Flow Based on the Theory of Thermodynamically Compatible Systems
,” J. Math. Sci.
, 228
(4
), pp. 357
–371
.34.
Hu
, G.
, and Kozlowski
, T.
, 2018
, “A Roe-Type Numerical Solver for the Two-Phase Two-Fluid Six-Equation Model With Realistic Equation of State
,” Nucl. Eng. Des.
, 326
, pp. 354
–370
.35.
Zou
, L.
, Zhao
, H.
, and Zhang
, H.
, 2017
, “Application of High-Order Numerical Schemes and Newton-Krylov Method to Two-Phase Drift-Flux Model
,” Prog. Nucl. Energy
, 100
, pp. 427
–438
.36.
Krasnopolsky
, B. I.
, and Lukyanov
, A. A.
, 2018
, “A Conservative Fully Implicit Algorithm for Predicting Slug Flows
,” J. Comput. Phys.
, 355
, pp. 597
–619
.37.
Hassoun
, M. H.
, 1995
, Fundamentals of Artificial Neural Networks
, MIT Press
, Cambridge, MA
, Chap. 5.38.
Hornik
, K.
, Stinchcombe
, M.
, and White
, H.
, 1990
, “Universal Approximation of an Unknown Mapping and Its Derivatives Using Multilayer Feedforward Networks
,” Neural Networks
, 3
(5
), pp. 551
–560
.39.
Chaari
, M.
, Seibi
, A. C.
, Ben Hmida
, J.
, and Fekih
, A.
, 2018
, “An Optimized Artificial Neural Network Unifying Model for Steady-State Liquid Holdup Estimation in Two-Phase Gas–Liquid Flow
,” ASME J. Fluids Eng.
, 140
(10
), p. 101301
.40.
Kazi
, S. N.
, 1999
, An Overview of Heat Transfer Phenomena
, InTech
, London
.41.
Chaari
, M.
, Ben Hmida
, J.
, Seibi
, A. C.
, and Fekih
, A.
, 2017
, “Steady-State Pressure Drop for Two-Phase Flow in Pipelines: An Integrated Genetic Algorithm-Artificial Neural Network Approach
,” ASME
Paper No. IMECE2017-71854.42.
Maren
, A. J.
, Harston
, C. T.
, and Pap
, R. M.
, 1990
, Handbook of Neural Computing Applications
, Academic Press
, San Diego, CA
, Chap. 15.43.
Chaari
, M.
, Fekih
, A.
, Seibi
, A. C.
, and Ben Hmida
, J.
, 2018
, “A Frequency Domain Approach to Improve ANNs Generalization Quality Via Proper Initialization
,” Neural Networks
, 104
, pp. 26
–39
.44.
Hagan
, M. T.
, and Menhaj
, M. B.
, 1994
, “Training Feedforward Networks With the Marquardt Algorithm
,” IEEE Trans. Neural Networks
, 5
(6
), pp. 989
–993
.45.
Back
, T.
, and Hoffmeister
, F.
, 1991
, “Extended Selection Mechanisms in Genetic Algorithms
,” Fourth International Conference on Genetic Algorithms
, San Diego, CA, July 13–16, pp. 92
–99
.46.
Blickle
, T.
, and Thiele
, L.
, 1995
, “A Comparison of Selection Schemes Used in Genetic Algorithms
,” Computer Engineering and Communication Networks Lab (TIK)
, Swiss Federal Institute of Technology (ETH), Zurich, Switzerland, Report No. 11.47.
Hong
, T. P.
, Wang
, H. S.
, Lin
, W. Y.
, and Lee
, W. Y.
, 2002
, “Evolution of Appropriate Crossover and Mutation Operators in a Genetic Process
,” Appl. Intell.
, 16
(1
), pp. 7
–17
.48.
Beggs
, H. D.
, and Brill
, J. P.
, 1973
, “A Study of Two-Phase Flow in Inclined Pipes
,” J. Pet. Technol.
, 25
(5
), pp. 607
–617
.49.
Petalas
, N.
, and Aziz
, K.
, 2000
, “A Mechanistic Model for Multiphase Flow in Pipes
,” J. Can. Pet. Technol.
, 39
(6
), pp. 43
–55
.50.
Meziou
, A.
, Chaari
, M.
, Franchek
, M.
, Borji
, R.
, Grigoriadis
, K.
, and Tafreshi
, R.
, 2016
, “Low-Dimensional Modeling of Transient Two-Phase Flow in Pipelines
,” ASME J. Dyn. Syst. Meas. Control
, 138
(10
), p. 101008
.51.
Moody
, L. F.
, 1944
, “Friction Factors for Pipe Flow
,” Trans. ASME
, 66
(8
), pp. 671
–684
.https://www.scribd.com/document/206954171/Lewis-F-Moody-Friction-Factor-for-Pipe-Flow-194452.
Goudar
, C. T.
, and Sonnad
, J. R.
, 2008
, “Comparison of the Iterative Approximations of the Colebrook-White Equation
,” Hydrocarbon Process.
, 87
(8
), pp. 79
–83
.https://www.hydrocarbonprocessing.com/magazine/2008/august-2008/misc/comparison-of-the-iterative-approximations-of-the-colebrook-white-equation53.
Colebrook
, C. F.
, 1939
, “Turbulent Flow in Pipes, With Particular Reference to the Transition Region Between Smooth and Rough Pipe Laws
,” J. Inst. Civ. Eng.
, 11
(4
), pp. 133
–156
.54.
Brown
, F. T.
, 1962
, “The Transient Response of Fluid Lines
,” ASME J. Basic Eng.
, 84
(4
), pp. 547
–553
.55.
Ravindran
, V. K.
, and Manning
, J. R.
, 1973
, “The Frequency Response of Pneumatic Lines With Branching
,” ASME J. Dyn. Syst. Meas. Control
, 95
(2
), pp. 194
–196
.56.
Omrani
, A.
, Franchek
, M. A.
, and Grigoriadis
, K.
, 2018
, “Transmission Line Modeling of Inclined Compressible Fluid Flows
,” ASME J. Dyn. Syst. Meas. Control
, 140
, p. 011001
.57.
Hsue
, C. Y. Y.
, and Hullender
, D. A.
, 1983
, “Modal Approximation for the Fluid Dynamics of Hydraulic and Pneumatic Transmission Lines
,” Winter Annual Meeting, Fluid Transmission Line Dynamics
, Boston, MA, Nov. 13–18, pp. 51
–77
.58.
Oldenberger
, R.
, and Goodson
, R. E.
, 1964
, “Simplification of Hydraulic Line Dynamics by Use of Infinite Products
,” ASME J. Basic Eng.
, 86
(1
), pp. 1
–8
.59.
OLGA
, 2019
, “OLGA Dynamic Multiphase Flow Simulator
,” accessed May 29, 2019, https://www.software.slb.com/products/olgaCopyright © 2019 by ASME
You do not currently have access to this content.
