Booth, R.J. (2008) Miscible flow through porous media. PhD thesis, University of Oxford.

PDF
1MB 
Abstract
This thesis is concerned with the modelling of miscible fluid flow through porous media, with the intended application being the displacement of oil from a reservoir by a solvent with which the oil is miscible. The primary difficulty that we encounter with such modelling is the existence of a fingering instability that arises from the viscosity and the density differences between the oil and solvent.
We take as our basic model the Peaceman model, which we derive from first principles as the combination of Darcy’s law with the mass transport of solvent by advection and hydrodynamic dispersion. In the oil industry, advection is usually dominant, so that the Peclet number, Pe, is large.
We begin by neglecting the effect of density differences between the two fluids and concentrate only on the viscous fingering instability. A stability analysis and numerical simulations are used to show that the wavelength of the instability is proportional to , and hence that a large number of fingers will be formed. We next apply homogenisation theory to investigate the evolution of the average concentration of solvent when the mean flow is onedimensional, and discuss the rationale behind the Koval model. We then attempt to explain why the mixing zone in which fingering is present grows at the observed rate, which is different from that predicted by a naıve version of the Koval model. We associate the shocks that appear in our homogenised model with the tips and roots of the fingers, the tipregions being modelled by SaffmanTaylor finger solutions.
We then extend our model to consider flow through porous media that are heterogeneous at the macroscopic scale, and where the mean flow is not onedimensional. We compare our model with that of Todd & Longstaff and also models for immiscible flow through porous media.
Finally, we extend our work to consider miscible displacements in which both density and viscosity differences between the two fluids are relevant.
Item Type:  Thesis (PhD) 

Subjects:  D  G > Geophysics D  G > Fluid mechanics 
Research Groups:  Oxford Centre for Industrial and Applied Mathematics 
ID Code:  889 
Deposited By:  Eprints Administrator 
Deposited On:  28 Jan 2010 07:53 
Last Modified:  29 May 2015 18:34 
Repository Staff Only: item control page