The Flow Pattern Transition and Water Holdup of Gas–Liquid Flow in the Horizontal and Vertical Sections of a Continuous Transportation Pipe

A series of experiments were conducted to investigate the flow pattern transitions and water holdup during oil–water–gas three-phase flow considering both a horizontal section and a vertical section of a transportation pipe simultaneously. The flowing media were white mineral oil, distilled water, a...

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Bibliographic Details
Published inWater (Basel) Vol. 13; no. 15; p. 2077
Main Authors Ren, Guishan, Ge, Dangke, Li, Peng, Chen, Xuemei, Zhang, Xuhui, Lu, Xiaobing, Sun, Kai, Fang, Rui, Mi, Lifei, Su, Feng
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.08.2021
Subjects
Aerodynamics
Dimensional analysis
dimensionless analysis
Dimensionless numbers
Distilled water
Experimental data
Experiments
Flow distribution
Flow mapping
Flow pattern
Fluid dynamics
Fluid flow
Gas flow
Gas pipelines
Industrial applications
Liquid flow
Mineral oils
Multiphase flow
Natural gas
oil–water–gas flow
Petroleum pipelines
Physical properties
Pipelines
Pipes
Reynolds number
Scaling laws
Two phase flow
Viscosity
water holdup
White mineral oil
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Summary:A series of experiments were conducted to investigate the flow pattern transitions and water holdup during oil–water–gas three-phase flow considering both a horizontal section and a vertical section of a transportation pipe simultaneously. The flowing media were white mineral oil, distilled water, and air. Dimensionless numbers controlling the multiphase flow were deduced to understand the scaling law of the flow process. The oil–water–gas three-phase flow was simplified as the two-phase flow of a gas and liquid mixture. Based on the experimental data, flow pattern maps were constructed in terms of the Reynolds number and the ratio of the superficial velocity of the gas to that of the liquid mixture for different Froude numbers. The original contributions of this work are that the relationship between the transient water holdup and the changes of the flow patterns in a transportation pipe with horizontal and vertical sections is established, providing a basis for judging the flow patterns in pipes in engineering practice. A dimensionless power-law correlation for the water holdup in the vertical section is presented based on the experimental data. The correlation can provide theoretical support for the design of oil and gas transport pipelines in industrial applications.
ISSN:2073-4441
2073-4441
DOI:10.3390/w13152077