Prediction of Optimum Length to Diameter Ratio for Two-Phase Fluid Flow Development in Vertical Pipes

Joao Chidamoio; Lateef Akanji; Roozbeh Rafati

doi:10.3968/9886

Prediction of Optimum Length to Diameter Ratio for Two-Phase Fluid Flow Development in Vertical Pipes

Joao Chidamoio, Lateef Akanji, Roozbeh Rafati

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Abstract

We investigate, via numerical simulation technique, the effect of length-to-diameter ratio on transient air-water two-phase flow in vertically upward cylindrical pipe geometry for parameterisation of the pilot scale laboratory multiphase flow rig. Variables such as axial velocity along the leading Taylor bubble, Taylor bubble length and Taylor bubble velocity are considered. A hydrodynamic entrance length required to establish a fully developed two phase flow was critically evaluated. Aperiodic behaviour on time and space dictates the complexity of continuous and unstable gas liquid flow. The porous injection configuration produced small bubble sizes compared to a single gas injection configuration even at higher gas injection rates.

Original language	English
Pages (from-to)	1-17
Number of pages	17
Journal	Advances in Petroleum Exploration and Development
Volume	14
Issue number	1
DOIs	https://doi.org/10.3968/9886
Publication status	Published - 30 Oct 2017

Bibliographical note

Publication assigned to Advances in Petroleum Exploration and Development,Vol.14, No.1, September 30, 2017.

Keywords

computer aided design
finite elements
Hydrodynamic entrance length
Taylor bubble

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10.3968/9886Licence: CC BY

Prediction of Optimum Length to Diameter Ratio for Two-Phase Fluid Flow Development in Vertical Pipes
This work is licensed under a Creative Commons Attribution 4.0 International License. https://creativecommons.org/licenses/by/4.0/
Final published version, 888 KBLicence: CC BY

Lateef Akanji
- Engineering, Engineering - Senior Lecturer
Person: Academic

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abstract = "We investigate, via numerical simulation technique, the effect of length-to-diameter ratio on transient air-water two-phase flow in vertically upward cylindrical pipe geometry for parameterisation of the pilot scale laboratory multiphase flow rig. Variables such as axial velocity along the leading Taylor bubble, Taylor bubble length and Taylor bubble velocity are considered. A hydrodynamic entrance length required to establish a fully developed two phase flow was critically evaluated. Aperiodic behaviour on time and space dictates the complexity of continuous and unstable gas liquid flow. The porous injection configuration produced small bubble sizes compared to a single gas injection configuration even at higher gas injection rates.",

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N1 - Publication assigned to Advances in Petroleum Exploration and Development,Vol.14, No.1, September 30, 2017.

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N2 - We investigate, via numerical simulation technique, the effect of length-to-diameter ratio on transient air-water two-phase flow in vertically upward cylindrical pipe geometry for parameterisation of the pilot scale laboratory multiphase flow rig. Variables such as axial velocity along the leading Taylor bubble, Taylor bubble length and Taylor bubble velocity are considered. A hydrodynamic entrance length required to establish a fully developed two phase flow was critically evaluated. Aperiodic behaviour on time and space dictates the complexity of continuous and unstable gas liquid flow. The porous injection configuration produced small bubble sizes compared to a single gas injection configuration even at higher gas injection rates.

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KW - finite elements

KW - Hydrodynamic entrance length

KW - Taylor bubble

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JF - Advances in Petroleum Exploration and Development

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Prediction of Optimum Length to Diameter Ratio for Two-Phase Fluid Flow Development in Vertical Pipes

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Lateef Akanji

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