Book contents
- Frontmatter
- Contents
- Preface
- List of Abbreviations
- 1 Introduction
- 2 Historical notes
- 3 Boundary conditions for viscous fluids
- 4 Helmholtz decomposition coupling rotational to irrotational flow
- 5 Harmonic functions that give rise to vorticity
- 6 Radial motions of a spherical gas bubble in a viscous liquid
- 7 Rise velocity of a spherical cap bubble
- 8 Ellipsoidal model of the rise of a Taylor bubble in a round tube
- 9 Rayleigh–Taylor instability of viscous fluids
- 10 The force on a cylinder near a wall in viscous potential flows
- 11 Kelvin–Helmholtz instability
- 12 Energy equation for irrotational theories of gas–liquid flow: viscous potential flow, viscous potential flow with pressure correction, and dissipation method
- 13 Rising bubbles
- 14 Purely irrotational theories of the effect of viscosity on the decay of waves
- 15 Irrotational Faraday waves on a viscous fluid
- 16 Stability of a liquid jet into incompressible gases and liquids
- 17 Stress-induced cavitation
- 18 Viscous effects of the irrotational flow outside boundary layers on rigid solids
- 19 Irrotational flows that satisfy the compressible Navier–Stokes equations
- 20 Irrotational flows of viscoelastic fluids
- 21 Purely irrotational theories of stability of viscoelastic fluids
- 22 Numerical methods for irrotational flows of viscous fluid
- Appendix A Equations of motion and strain rates for rotational and irrotational flow in Cartesian, cylindrical, and spherical coordinates
- Appendix B List of frequently used symbols and concepts
- References
- Index
8 - Ellipsoidal model of the rise of a Taylor bubble in a round tube
Published online by Cambridge University Press: 09 October 2009
- Frontmatter
- Contents
- Preface
- List of Abbreviations
- 1 Introduction
- 2 Historical notes
- 3 Boundary conditions for viscous fluids
- 4 Helmholtz decomposition coupling rotational to irrotational flow
- 5 Harmonic functions that give rise to vorticity
- 6 Radial motions of a spherical gas bubble in a viscous liquid
- 7 Rise velocity of a spherical cap bubble
- 8 Ellipsoidal model of the rise of a Taylor bubble in a round tube
- 9 Rayleigh–Taylor instability of viscous fluids
- 10 The force on a cylinder near a wall in viscous potential flows
- 11 Kelvin–Helmholtz instability
- 12 Energy equation for irrotational theories of gas–liquid flow: viscous potential flow, viscous potential flow with pressure correction, and dissipation method
- 13 Rising bubbles
- 14 Purely irrotational theories of the effect of viscosity on the decay of waves
- 15 Irrotational Faraday waves on a viscous fluid
- 16 Stability of a liquid jet into incompressible gases and liquids
- 17 Stress-induced cavitation
- 18 Viscous effects of the irrotational flow outside boundary layers on rigid solids
- 19 Irrotational flows that satisfy the compressible Navier–Stokes equations
- 20 Irrotational flows of viscoelastic fluids
- 21 Purely irrotational theories of stability of viscoelastic fluids
- 22 Numerical methods for irrotational flows of viscous fluid
- Appendix A Equations of motion and strain rates for rotational and irrotational flow in Cartesian, cylindrical, and spherical coordinates
- Appendix B List of frequently used symbols and concepts
- References
- Index
Summary
The rise velocity of long gas bubbles (Taylor bubbles) in round tubes is modeled by an ovary ellipsoidal cap bubble rising in an irrotational flow of a viscous liquid. The analysis leads to an expression for the rise velocity that depends on the aspect ratio of the model ellipsoid and the Reynolds and Eötvös numbers. The aspect ratio of the best ellipsoid is selected to give the same rise velocity as the Taylor bubble at given values of the Eötvös and Reynolds numbers. The analysis leads to a prediction of the shape of the ovary ellipsoid that rises with same velocity as that of the Taylor bubble.
Introduction
The correlations given by Viana et al. (2003) convert all the published data on the normalized rise velocity Fr = U/(gD)1/2 into analytic expressions for the Froude velocity versus buoyancy Reynolds number, ReG = [D3g (ρl – ρg)ρl]1/2/μ for fixed ranges of the Eötvös number, Eö = gρlD2/σ, where D is the pipe diameter, ρl, ρg, and σ are densities and surface tension. Their plots give rise to power laws in Eö; the compositions of these separate power laws emerge as bipower laws for two separate flow regions for large- and small-buoyancy Reynolds numbers.
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- Potential Flows of Viscous and Viscoelastic Liquids , pp. 51 - 69Publisher: Cambridge University PressPrint publication year: 2007