An analytical solution for cyclic flow of two immiscible phases

[Display omitted] •Analytical solution derived for cyclic flow of two immiscible phases.•Solution applies to single well operations with repeated injection and production.•Dependence of solution on controlling parameters is explored.•Solution is shown to reach a periodic steady state for many cases....

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Bibliographic Details
Published in:Journal of hydrology (Amsterdam) 2019-03, Vol.570, p.682-691
Main Author: Rabinovich, Avinoam
Format: Article
Language:English
Subjects:
Analytical solution
Cyclic injection
Energy storage in aquifers
Gas storage
Periodic flow
Two-phase flow
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Summary:[Display omitted] •Analytical solution derived for cyclic flow of two immiscible phases.•Solution applies to single well operations with repeated injection and production.•Dependence of solution on controlling parameters is explored.•Solution is shown to reach a periodic steady state for many cases.•Solution is extended to model viscosity reduction between injection and production. Cyclic injection and production by a single well is a technique used in applications such as natural gas storage, compressed air energy storage and periodic pumping tests. The induced flow and saturation distribution can sometimes be modeled assuming two immiscible and incompressible fluids. An analytical solution is derived for such one-dimensional cyclic flow using the method of characteristics. The solution usually exhibits a front or discontinuity, in which case the contour integral method is applied in the derivation. Saturation (S) is expressed as a function of time, distance from well, mobility ratio and production to injection time ratio tprod/tinj. Derivation is carried out for both linear S(x) and radial S(r) flow. Dependence of the solution on these parameters is explored and various cases are analyzed. A simple model for viscosity reduction of the reservoir fluid is presented, accounting for changes in mobility ratio, e.g., following cyclic injection for enhanced oil recovery. It is found that generally, for tprod/tinj⩾1 the solution converges to a periodic steady state, however, for tprod/tinj
ISSN:0022-1694
1879-2707
DOI:10.1016/j.jhydrol.2018.12.056