Summary
The displacement of non-Newtonian power-law fluids in communicating
stratified reservoirs with a log-normal permeability distribution is studied.
Equations are derived for fractional oil recovery, water cut, injectivity
ratio, and pseudorelative permeability functions, and the performance is
compared with that for Newtonian fluids. Constant-injection-rate and
constant-total-pressure-drop cases are studied.
The effects of the following factors on performance are investigated: the
flow-behavior indices, the apparent mobility ratio, the Dykstra-Parsons
variation coefficient, and the flow rate. It was found that fractional oil
recovery increases for nw > no and
decreases for nw < no, as compared with
Newtonian fluids. For the same ratio of nw
/no, oil recovery increases as the apparent mobility ratio
decreases. The effect of reservoir heterogeneity in decreasing oil recovery is
more apparent for the case of nw > no .
Increasing the total injection rate increases the recovery for
nw > no, and the opposite is true for
nw < no . It also was found that the
fractional oil recovery for the displacement at constant total pressure drop is
lower than that for the displacement at constant injection rate, with the
effect being more significant when nw <
no.
Introduction
Many of the fluids injected into the reservoir in enhanced-oil-recovery
(EOR)/improved-oil-recovery (IOR) processes such as polymer, surfactant, and
alkaline solutions may be non-Newtonian; in addition, some heavy oils exhibit
non-Newtonian behavior.
Flow of non-Newtonian fluids in porous media has been studied mainly for
single-phase flow. Savins (1969) presented a comprehensive review of the
rheological behavior of non-Newtonian fluids and their flow behavior through
porous media. van Poollen and Jargon (1969) presented a finite-difference
solution for transient-pressure behavior, while Odeh and Yang (1979) derived an
approximate closed-form analytical solution of the problem. Chakrabarty et al.
(1993) presented Laplace-space solutions for transient pressure in fractal
reservoirs.
For multiphase flow of non-Newtonian fluids in porous media, the problem was
considered only for single-layer cases. Salman et al. (1990) presented the
modifications for the Buckley-Leverett frontal-advance method and for the JBN
relative permeability method for non-Newtonian power-law fluid displacing a
Newtonian fluid. Wu et al. (1992) studied the displacement of a Bingham
non-Newtonian fluid (oil) by a Newtonian fluid (water). Wu and Pruess (1998)
introduced a numerical finite-difference solution for displacement of
non-Newtonian fluids in linear systems and in a five-spot pattern. Yi (2004)
developed a Buckley-Leverett model for displacement by a Newtonian fluid of a
fracturing fluid having a Herschel-Bulkley rheological behavior. An iterative
procedure was used to obtain a solution of the model.
The methods available in the literature to predict linear waterflooding
performance in stratified reservoirs are grouped into two categories depending
on the assumption of communication or no communication between the different
layers.
In the case of noncommunicating systems, no vertical crossflow is permitted
between the adjacent layers. The Dykstra-Parsons (1950) method is the basis for
performance prediction in noncommunicating stratified reservoirs.
© 2006. Society of Petroleum Engineers
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History
- Original manuscript received:
5 January 2005
- Revised manuscript received:
6 April 2006
- Manuscript approved:
12 April 2006
- Version of record:
20 August 2006
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