Pressure Distribution of a Horizontal Well in an Oil Reservoir Subject to Simultaneous Single Edged and Bottom Water Drive Mechanisms
Loading...
Date
2023-08-10
Journal Title
Journal ISSN
Volume Title
Publisher
IOSR Journal of Mathematics (IOSR-JM)
Abstract
In this study the pressure distribution in an oil reservoir with a horizontal well is investigated. A horizontal well
with single-edged and constant bottom pressure is outlined. A reservoir bounded with two constant pressure
boundaries, like an edge and bottom water, requires that the production engineer should adhere diligently to a
production schedule, developed by a reservoir engineer, for clean oil production to be possible. This means that
arbitrary production practices through selection of production rates could lead to production of these external
fluids. This can mar the economics of the project. Production schedules or plans show acceptable rates, well
design and production time that can guarantee only clean oil production. In this study, pressure behaviour of a
horizontal well drilled and completed in a reservoir subject to with simultaneous single-edged and bottom water
drives is investigated in detail. All possible flow periods or patterns that can be exhibited by the well are
determined. Fluid flow in oil reservoirs in real time is governed by a heterogenous diffusivity equation, which
describes reservoir pressure as a function of reservoir, fluid and wellbore properties. To solve this unsteady state
problem, Greenβs functions were deployed to represent the boundaries of the reservoir selected for study. The
Greenβs functions selected are for flow from start of transient to late time, when all the external boundaries are
felt. Newman product rule was used to derive a dimensionless pressure expression for the reservoir system oil
flow. The source of pressure transient was production throughout. All the resulting integrals were performed
numerically. MATLAB programming was used to plot the curves by applying spline functions interpolation.
Influence of reservoir, fluid and wellbore properties on reservoir pressure was investigated in real time. To assist
interpretation, dimensionless pressure derivatives were also computed. Near wellbore problems, like skin and
wellbore storage, which affect well performance only at very early time, were not considered in the study. From
the results, ππ· and ππ· β² vary directly with βπ· and inversely as πΏπ·. The ππ· β² gradually reduces to zero when ππ·
begins to exhibit a constant trend. ππ· β² vary inversely with βπ· and π¦ππ· at all flow times. The number of flow periods
varies with reservoir size, well length and production time. The time at which the ππ· β² starts to exhibit a downward
trend is the external fluid breakthrough time. The breakthrough time is affected by well design. Longer wells
exhibit delayed breakthrough time because of lower pressure drawdown associated with increased well length. If
production rate is sustained for any particular well design, the well will completely water-out. Finally, infinite
conductivity π₯π· = 0.732 and uniform flux condition do not really affect ππ· and ππ· β² at early time.
Description
Keywords
Dimensionless Pressure, Bounded Oil Reservoir, Horizontal Well, Edge and Bottom Water Drive, Early Radial Flow Regime, Early Linear Flow Regime, Late Pseudo-radial Flow Regime, Late Linear Flow Regime.