A Study of Pressure Gradient in Multiphase Flow in Vertical Pipes

David Nwobisi Wordu; Felix J. K. Ideriah; Barinyima Nkoi

doi:10.24018/ejeng.2019.4.1.1090

Research Article

David Nwobisi Wordu

Department of Mechanical Engineering, Rivers State University, Nigeria

* Corresponding author

Felix J. K. Ideriah

Department of Mechanical Engineering, Rivers State University, Nigeria

Barinyima Nkoi

Department of Mechanical Engineering, Rivers State University, Nigeria

10.24018/ejeng.2019.4.1.1090

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Submitted 2019-01-11
Published 2019-01-23

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Abstract

The study of multiphase flow in vertical pipes is aimed at effective and accurate design of tubing, surface facilities and well performance optimization for the production of oil and gas in the petroleum industry by developing a better approach for predicting pressure gradient. In this study, field data was analyzed using mathematical model, multiphase flow correlations, statistical model, and computer programming to predict accurately the flow regime, liquid holdup and pressure drop gradient which are important in the optimization of well. A Computer programme was used to prediction pressure drop gradient. Four dimensionless parameters liquid velocity number (Nlv), gas velocity number (Ngv), pipe diameter number (Nd), liquid viscosity number (Nl), were chosen because they represent an integration of the two dominant components that influence pressure drop in pipes. These dominant component are flow channel/media and the flowing fluid. The model was found to give a fit of 100% to the selected data points. Hagedorn & Brown, Griffith &Wallis correlations and model were compared with field data and the overall pressure gradient for a total depth of 10000ft was predicted. The predicted pressure gradient measured was found to be 0.320778psi/ft, Graffith& Wallis gave 0.382649Psi/ft, Hagedorn & Brown gave 0.382649Psi/ft; whereas generated model gave 0.271514Psi/ft. These results indicate that the model equation generated is better and leads to a reasonably accurate prediction of pressure drop gradient according to measured pressure gradient.

Keywords: Two-Phase Flow Pressure Drop Gradient Flow Regimes Gas-Liquid Ratio Dimensionless Groups Regression Analysis

References

Saied, B. (2013). Prediction of Pressure Drop in vertical Air/water flow in the presence/Absence of Sodium DodecylSulfate as a surfactant. Thesis University of Dayton.
Google Scholar

Ideriah, F.J.K. (2017). 2nd edition “Fundamentals of Fluid Mechanics” Vol. 1, Engineering Fluid Mechanics Series, T & D Press Port Harcourt, Nigeria (1st Edition 1986).
Google Scholar

Ogbeide P. O. and Igbinere S. A. (2015) Nodal Analysis Approach in Minimizing Pressure Losses to Improve Well Productivity Journal of Emerging Trends in Engineering and Applied Sciences (JETEAS) 6(5): 353- 359 © Scholarlink Research Institute Journals, 2015 (ISSN: 2141-7016) Petroleum Engineering Department, University of Benin, Benin City.
Google Scholar

Musaab, M. A. & Mohammed A. A. (2014). A Comprehensive Study on the Current Pressure Drop Calculation in Multiphase Vertical Wells; Current Trends and Future Prospective. Journal of Applied Sciences, 14:3162-3171.
Google Scholar

Nwachuku, K.C. (2014). Detailed analysis of pressure drop in large diameter pipe. Msc Thesis Department of Petroleum Engineering, Africa University of Science and Technology, Nigeria.
Google Scholar

Adekomaya, O, Olafuruyi, O &Blankson, E. (2011). An improved version of calcucating pressure transverse in multiphase flow in vertical pipe. Journal of petroleum & coal (1),56-64.
Google Scholar

Omon, E., Dulu, A., &Okotiem, A. (2015). Estimation of pressure Drop, Liquid Holodup and flow pattern in a Two phase vertical flow. International Journal of Engineering and Technology 5(4). Oregon State University.
Google Scholar

Masud, B. (1991). Most Accurate Two-Phase Pressure-Drop Correlation Identified. The Oil and gas journal
Google Scholar

Mukherjee, H. & Brill, J. P. (1985). Pressure drop correlations for inclined two-phase flow. J. Energy Resour. Technol., 107: 549-554.
Google Scholar

Beggs, D.H. (2008). Production Optimization Using Nodal Analysis. 2ndedition, Oklahoma.
Google Scholar

Jain, A.K (1976) Accurate Explicit Equation for Friction Factor, J. Hydl. Div. ASCE, HY5.
Google Scholar

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[1]

2019. A Study of Pressure Gradient in Multiphase Flow in Vertical Pipes. European Journal of Engineering and Technology Research. 4, 1 (Jan. 2019), 54–59. DOI:https://doi.org/10.24018/ejeng.2019.4.1.1090.

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Vol. 4 No. 1: JANUARY 2019

[1] Saied, B. (2013). Prediction of Pressure Drop in vertical Air/water flow in the presence/Absence of Sodium DodecylSulfate as a surfactant. Thesis University of Dayton.
Google Scholar

[2] Ideriah, F.J.K. (2017). 2nd edition “Fundamentals of Fluid Mechanics” Vol. 1, Engineering Fluid Mechanics Series, T & D Press Port Harcourt, Nigeria (1st Edition 1986).
Google Scholar

[3] Ogbeide P. O. and Igbinere S. A. (2015) Nodal Analysis Approach in Minimizing Pressure Losses to Improve Well Productivity Journal of Emerging Trends in Engineering and Applied Sciences (JETEAS) 6(5): 353- 359 © Scholarlink Research Institute Journals, 2015 (ISSN: 2141-7016) Petroleum Engineering Department, University of Benin, Benin City.
Google Scholar

[4] Musaab, M. A. & Mohammed A. A. (2014). A Comprehensive Study on the Current Pressure Drop Calculation in Multiphase Vertical Wells; Current Trends and Future Prospective. Journal of Applied Sciences, 14:3162-3171.
Google Scholar

[5] Nwachuku, K.C. (2014). Detailed analysis of pressure drop in large diameter pipe. Msc Thesis Department of Petroleum Engineering, Africa University of Science and Technology, Nigeria.
Google Scholar

[6] Adekomaya, O, Olafuruyi, O &Blankson, E. (2011). An improved version of calcucating pressure transverse in multiphase flow in vertical pipe. Journal of petroleum & coal (1),56-64.
Google Scholar

[7] Omon, E., Dulu, A., &Okotiem, A. (2015). Estimation of pressure Drop, Liquid Holodup and flow pattern in a Two phase vertical flow. International Journal of Engineering and Technology 5(4). Oregon State University.
Google Scholar

[8] Masud, B. (1991). Most Accurate Two-Phase Pressure-Drop Correlation Identified. The Oil and gas journal
Google Scholar

[9] Mukherjee, H. & Brill, J. P. (1985). Pressure drop correlations for inclined two-phase flow. J. Energy Resour. Technol., 107: 549-554.
Google Scholar

[10] Beggs, D.H. (2008). Production Optimization Using Nodal Analysis. 2ndedition, Oklahoma.
Google Scholar

[11] Jain, A.K (1976) Accurate Explicit Equation for Friction Factor, J. Hydl. Div. ASCE, HY5.
Google Scholar

A Study of Pressure Gradient in Multiphase Flow in Vertical Pipes

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