A Two-Fluid Model for High-Viscosity Upward Annular Flow in Vertical Pipes

A Two-Fluid Model for High-Viscosity Upward Annular Flow in Vertical Pipes

Proper selection and application of interfacial friction factor correlations has a significant impact on prediction of key flow characteristics in gas–liquid two-phase flows. In this study, experimental investigation of gas–liquid flow in a vertical pipeline with internal diameter of 0.060 m is pres...

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Main Authors: Joseph X. F. Ribeiro, Ruiquan Liao, Aliyu M. Aliyu, Salem K. B. Ahmed, Yahaya D. Baba, Almabrok A. Almabrok, Archibong Archibong-Eso, Zilong Liu
Format: Article
Language:English
Published: MDPI AG 2021-06-01
Series:Energies
Subjects:
two-phase flow
interfacial friction factor
vertical pipes
higher viscosity
pressure drop
Online Access:https://www.mdpi.com/1996-1073/14/12/3485
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spelling doaj-0bb6824139e14d6082b008f2a3b84f172021-06-30T23:59:51ZengMDPI AGEnergies1996-10732021-06-01143485348510.3390/en14123485A Two-Fluid Model for High-Viscosity Upward Annular Flow in Vertical PipesJoseph X. F. Ribeiro0Ruiquan Liao1Aliyu M. Aliyu2Salem K. B. Ahmed3Yahaya D. Baba4Almabrok A. Almabrok5Archibong Archibong-Eso6Zilong Liu7Petroleum Engineering College, Yangtze University, Wuhan 430100, ChinaPetroleum Engineering College, Yangtze University, Wuhan 430100, ChinaSchool of Computing and Engineering, University of Huddersfield, Huddersfield HD1 3DH, UKFaculty of Mining and Energy Engineering, Sebha University, Sebha 00218, LibyaDepartment of Chemical and Biological Engineering, University of Sheffield, Sheffield S1 3JD, UKDepartment of Petroleum Engineering, Faculty of Engineering, Sirte University, Sirte 00218, LibyaDepartment of Mechanical Engineering, University of Birmingham, Dubai International Academic City, Dubai P.O. Box 341799, United Arab EmiratesPetroleum Engineering College, Yangtze University, Wuhan 430100, ChinaProper selection and application of interfacial friction factor correlations has a significant impact on prediction of key flow characteristics in gas–liquid two-phase flows. In this study, experimental investigation of gas–liquid flow in a vertical pipeline with internal diameter of 0.060 m is presented. Air and oil (with viscosities ranging from 100–200 mPa s) were used as gas and liquid phases, respectively. Superficial velocities of air ranging from 22.37 to 59.06 m/s and oil ranging from 0.05 to 0.16 m/s were used as a test matrix during the experimental campaign. The influence of estimates obtained from nine interfacial friction factor models on the accuracy of predicting pressure gradient, film thickness and gas void fraction was investigated by utilising a two-fluid model. Results obtained indicate that at liquid viscosity of 100 mPa s, the interfacial friction factor correlation proposed by Belt et al. (2009) performed best for pressure gradient prediction while the Moeck (1970) correlation provided the best prediction of pressure gradient at the liquid viscosity of 200 mPa s. In general, these results indicate that the two-fluid model can accurately predict the flow characteristics for liquid viscosities used in this study when appropriate interfacial friction factor correlations are implemented.https://www.mdpi.com/1996-1073/14/12/3485two-phase flowinterfacial friction factorvertical pipeshigher viscositypressure drop
collection DOAJ
language English
format Article
sources DOAJ
author Joseph X. F. Ribeiro
Ruiquan Liao
Aliyu M. Aliyu
Salem K. B. Ahmed
Yahaya D. Baba
Almabrok A. Almabrok
Archibong Archibong-Eso
Zilong Liu
spellingShingle Joseph X. F. Ribeiro
Ruiquan Liao
Aliyu M. Aliyu
Salem K. B. Ahmed
Yahaya D. Baba
Almabrok A. Almabrok
Archibong Archibong-Eso
Zilong Liu
A Two-Fluid Model for High-Viscosity Upward Annular Flow in Vertical Pipes
Energies
two-phase flow
interfacial friction factor
vertical pipes
higher viscosity
pressure drop
author_facet Joseph X. F. Ribeiro
Ruiquan Liao
Aliyu M. Aliyu
Salem K. B. Ahmed
Yahaya D. Baba
Almabrok A. Almabrok
Archibong Archibong-Eso
Zilong Liu
author_sort Joseph X. F. Ribeiro
title A Two-Fluid Model for High-Viscosity Upward Annular Flow in Vertical Pipes
title_short A Two-Fluid Model for High-Viscosity Upward Annular Flow in Vertical Pipes
title_full A Two-Fluid Model for High-Viscosity Upward Annular Flow in Vertical Pipes
title_fullStr A Two-Fluid Model for High-Viscosity Upward Annular Flow in Vertical Pipes
title_full_unstemmed A Two-Fluid Model for High-Viscosity Upward Annular Flow in Vertical Pipes
title_sort two-fluid model for high-viscosity upward annular flow in vertical pipes
publisher MDPI AG
series Energies
issn 1996-1073
publishDate 2021-06-01
description Proper selection and application of interfacial friction factor correlations has a significant impact on prediction of key flow characteristics in gas–liquid two-phase flows. In this study, experimental investigation of gas–liquid flow in a vertical pipeline with internal diameter of 0.060 m is presented. Air and oil (with viscosities ranging from 100–200 mPa s) were used as gas and liquid phases, respectively. Superficial velocities of air ranging from 22.37 to 59.06 m/s and oil ranging from 0.05 to 0.16 m/s were used as a test matrix during the experimental campaign. The influence of estimates obtained from nine interfacial friction factor models on the accuracy of predicting pressure gradient, film thickness and gas void fraction was investigated by utilising a two-fluid model. Results obtained indicate that at liquid viscosity of 100 mPa s, the interfacial friction factor correlation proposed by Belt et al. (2009) performed best for pressure gradient prediction while the Moeck (1970) correlation provided the best prediction of pressure gradient at the liquid viscosity of 200 mPa s. In general, these results indicate that the two-fluid model can accurately predict the flow characteristics for liquid viscosities used in this study when appropriate interfacial friction factor correlations are implemented.
topic two-phase flow
interfacial friction factor
vertical pipes
higher viscosity
pressure drop
url https://www.mdpi.com/1996-1073/14/12/3485
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