Application of Computational Fluid Dynamics Simulation in The Case of Upward Vertical Core Annular Flow of Oil-Water System

Cindy Dianita; Rana Nur Fatimah; Abdul Wahid

doi:10.29017/scog.v49i1.1971

Authors

Cindy Dianita Universitas Indonesia
Rana Nur Fatimah Universitas Indonesia
Abdul Wahid Universitas Indonesia

DOI:

https://doi.org/10.29017/scog.v49i1.1971

Keywords:

CFD simulation, core-annular flow, oil-water, upward flow, vertical pipe

Abstract

The energy required to transport heavy oil through pipelines can be significantly lowered by applying the core-annular flow (CAF) technique, in which a layer of water surrounds the oil as it moves through the pipe. This research investigates the behavior of upward oil–water flow in vertical pipelines using three-dimensional computational fluid dynamics (CFD) simulations. The numerical analysis is conducted based on previously published experimental studies. Validation has been completed to ensure the visual and numerical consistency of the observed interfacial wave geometry. This CFD work captures the wavy bamboo CAF pattern, illustrating the effect of buoyancy and pressure gradient in upward vertical flow, as demonstrated by experimental results. The present CFD simulation results indicate a relatively stable velocity distribution, where the central region of the pipe contains the highest concentration of oil. In addition, the absolute pressure gradually decreases along the length of the pipe, while the wall shear stress remains relatively low. The influence of gravity affecting the flow is investigated, showing a higher pressure drop compared to gravity-free flow. Compared with single-phase heavy oil transport, the CAF technique demonstrates significantly higher efficiency, achieving energy savings exceeding 90%. Furthermore, the three-dimensional simulation developed in this study provides more detailed flow pattern representation and more reliable hydrodynamic predictions than those obtained from earlier two-dimensional analyses.

References

ANSYS Inc., 2021. CFD Experts Simulate the Future.

ANSYS Inc., 2023a. Ansys Fluent Theory Guide.

ANSYS Inc., 2023b. ANSYS Fluent Tutorial Guide 18. ANSYS Fluent Tutorial Guide, 15317(April), pp.724–746.

Babakhani Dehkordi, P., Azdarpour, A. & Mohammadian, E., 2018. Hydrodynamic behavior of high viscous oil–water flow through horizontal pipe undergoing sudden expansion—CFD study and experimental validation. Chemical Engineering Research and Design, 139, pp.144–161. doi:10.1016/j.cherd.2018.09.026.

Bai, R., Chen, K. & Joseph, D.D., 1992. Lubricated pipelining: Stability of core-annular flow. Part 5: Experiments and comparison with theory. Journal of Fluid Mechanics, 240, pp.97–132. doi:10.1017/S0022112092000041.

Banerjee, S., Banik, A., Rajak, V.K., Bandyopadhyay, T.K., Nayak, J., Jasinski, M., Kumar, R., Jeon, B.-H., Siddiqui, M.R., Khan, M.A., Chakrabortty, S. and Tripathy, S.K., 2024. Two-Phase Crude Oil–Water Flow Through Different Pipes: An Experimental Investigation Coupled with Computational Fluid Dynamics Approach, ACS Omega, 9(10), pp. 11181–11193. https://doi.org/10.1021/acsomega.3c05290.

Cadence, 2022. The relationship between wall shear stress and the maximum shear stress formula [WWW Document]. Cadence.

Çengel, Y. A. and Ghajar, A. J., 2025. Heat and Mass Transfer: Fundamentals and Applications. 7th edn. New York, NY: McGraw-Hill Education.

Coelho, N. M. D. A., Ribeiro, G. C. P., do Nascimento, M. M., de Souza, A., Soares, E. J., Bannwart, A. C., 2020. Energy savings on heavy oil transportation through core annular flow pattern: An experimental approach. International Journal of Multiphase Flow, 122, p.103127. doi:10.1016/j.ijmultiphaseflow.2019.103127.

Dianita, C., Piemjaiswang, R., Chalermsinsuwan, B., 2023. Computational fluid dynamics approach for energy savings evaluation in core annular flow of a horizontal T-pipe. Energy Reports 9, 8–15. https://doi.org/10.1016/j.egyr.2023.05.218

Dianita, C., Faturahman, M. & Mardianza, A., 2025. Pore-scale 3D modeling of viscous fingering for non-Newtonian heavy oil recovery. Scientific Contributions Oil and Gas, 48(1), pp.77–90. https://doi.org/10.29017/scog.v48i1.1690

Gupta, R., Turangan, C. & Manica, R., 2016. Oil-water core-annular flow in vertical pipes: A CFD study. Canadian Journal of Chemical Engineering, 94, n/a. doi:10.1002/cjce.22451.

Kim, J. and Park, H., 2024. Characteristics of turbulent core–annular flow with water-lubricated high viscosity oil in a horizontal pipe, Journal of Fluid Mechanics, 986, p. A15. doi:10.1017/jfm.2024.345

Lintermann, A., 2021. Computational Meshing for CFD Simulations. pp. 85–115. https://doi.org/10.1007/978-981-15-6716-2_6

Peysson, Y., Bensakhria, A., Antonini, G., Argillier, J. F. 2005. Pipeline lubrication of heavy oil: Experimental investigation of flow and restart problems. In: SPE International Thermal Operations and Heavy Oil Symposium.

Rodriguez, O.M.H. & Bannwart, A.C., 2006. Experimental study on interfacial waves in vertical core flow. Journal of Petroleum Science and Engineering. doi:10.1016/j.petrol.2006.07.007.

Silva, B. F., Magalhães, H. L. F., Gomez, R. S., Cabral, E. de M., Batista, F. A., Pereira, A. B. da C., Lima, W. M. P. B. de, Lima, A. G. B. de, 2020. Isothermal Transport (Core-Flow Type) of Heavy and Ultraviscous Oil in Curved Pipes: A Transient Study by CFD. Open Journal of Fluid Dynamics 10, 122–134. https://doi.org/10.4236/ojfd.2020.102008

Susantoro, T. M., Suliantara, Setiawan, H. L., Widarsono, B., Wikantika, K., 2022. Heavy Oil Potentials in Central Sumatra Basin, Indonesia Using Remote Sensing, Gravity, and Petrophysics Data: From Literature Review to Interpretations and Analyses. Indonesian Journal of Science and Technology 7, 363–384. https://doi.org/10.17509/IJOST.V7I3.51288

Widarsono, B. et al., 2021. An integrated approach for revisiting basin-scale heavy oil potential of the Central Sumatera Basin. Scientific Contributions Oil and Gas, 44(1), pp.1–20. https://doi.org/10.29017/SCOG.44.1.493.

Xie, B., Jiang, F., Xiang, J. and Ye, C., 2023. Review of Core Annular Flow, Energies, 16(3), p. 1475. https://doi.org/10.3390/en16031496