Thesis

The rise of Taylor bubbles in vertical and inclined pipes

Creator
Rights statement
Awarding institution
  • University of Strathclyde
Date of award
  • 2019
Thesis identifier
  • T15220
Person Identifier (Local)
  • 201191146
Qualification Level
Qualification Name
Department, School or Faculty
Abstract
  • Slug flow is one of the key flow regimes encountered in multiphase flow systems. Through reviewing the literature, the researcher identified a research gap in performing a theoretical treatment to the problem, specifically using the dimensionless treatment and the order of magnitude analysis of equations of motions. To the best of the researcher's knowledge, an analysis of the literature identifies that there is a lack in the numerical studies on the drift of Taylor bubbles in inclined pipes with stagnant liquid.;This thesis focuses on studying the flow of the Taylor bubble in the stagnant liquid, which is considered an essential characteristic part of the slug flow regime in pipes by performing theoretical treatment of the problem. To achieve this, the following two steps are carried out (i) Performing a complete dimensionless analysis to the rise of Taylor bubble through stagnant liquid in a vertical and inclined pipe, covering inclination range of 0≤ɣ≤90° with respect to the vertical position,;(ii) Using the guideline of the order of magnitude analysis and the dimensionless group analysis, performing CFD study using the volume-of-fluid (VOF) methodology implemented in the commercial software ANSYS Fluent (Release 16.0) investigating the dynamics of single Taylor bubble drifting through stagnant Newtonian liquid in vertical and inclined pipe.;The dimensionless analysis shows that different governing parameters appear according to the range of pipe inclination angle. The adopted CFD model shows good results for the dynamics of the Taylor bubble covering three main regions the bubble nose, the bubble body and the bubble wake regions.;The simulation results show good agreement with the developed dimensionless treatment of the problem for all pipe inclination. No bubble propagates in a zero axial pressure gradient horizontal pipe, hence, a simplified model is suggested to solve the challenging problem of the three-dimensional Taylor bubble in the near horizontal and horizontal pipes.
Advisor / supervisor
  • Xiao, Qing
  • Incecik, Atilla
Resource Type
DOI
Date Created
  • 2019
Former identifier
  • 9912723192802996

Relações

Itens