HYBRID MACHINE LEARNING MODEL APPLIED TO PHASE INVERSION PREDICTION IN LIQUID-LIQUID PIPE FLOW
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Published:2023
Issue:1
Volume:35
Page:35-53
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ISSN:0276-1459
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Container-title:Multiphase Science and Technology
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language:en
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Short-container-title:MultScienTechn
Author:
Bazon Pedro B.,Castro-Bolivar Johann E.,Ruiz-Diaz C. M.,Hernández-Cely Marlon M.,Rodriguez Oscar M. H.
Abstract
One of the current challenges in two-phase flow is the characterization of phase inversion in the oil and gas industry. Empirical and semi-empirical models have been developed by several researchers, allowing limited predictions through correlations. Recently, models obtained with application of artificial intelligence techniques, such as artificial neural networks, have become a promising alternative to identify flow patterns and their transition boundaries. This work's aim is to develop a hybrid model that identifies the phase inversion transition from oil-in-water to water-in-oil flow in vertical pipes. It is based on recent models found in the literature and logistic regression models based on artificial neural networks, for which information was obtained from the literature. The proposed hybrid model achieved an RMSE ≈ 0.0834, thus being an efficient contribution to the identification of phase inversion in oil-water two-phase flow.
Subject
General Engineering,Condensed Matter Physics,Modeling and Simulation
Reference52 articles.
1. Arirachakaran, S., Oglesby, K., Malinowsky, M., Shoham, O., and Brill, J., An Analysis of Oil/Water Flow Phenomena in Horizontal Pipes, SPE Production Operations Symposium, SPE-18836-MS, Oklahoma City, Oklahoma, 1989. 2. Azizi, S., Awad, M.M., and Ahmadloo, E., Prediction of Water Holdup in Vertical and Inclined Oil-Water Two-Phase Flow Using Artificial Neural Network, Int. J. Multiphase Flow, vol. 80, pp. 181-187, 2016. 3. Bakr, M.H. and Negm, M.H., Modeling and Design of High-Frequency Structures Using Artificial Neural Networks and Space Mapping, Silicon-Based Millimeter-Wave Technology-Measurement, Modeling and Applications, Amsterdam: Elsevier, pp. 223-260, 2012. 4. Banasiak, R., Wajman, R., Jaworski, T., Fiderek, P., Fidos, H., Nowakowski, J., and Sankowski, D., Study on Two-Phase Flow Regime Visualization and Identification Using 3D Electrical Capacitance Tomography and Fuzzy-Logic Classification, Int. J. Multiphase Flow, vol. 58, pp. 1-14, 2014. 5. Belyadi, H. and Haghighat, A., Machine Learning Guide for Oil and Gas Using Python, Amsterdam: Elsevier Science and Technology, 2021.
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