Motivation
The most accurate way to simulate Aquifer Expansion (or shrinkage) is full-field 3D Dynamic Flow Model where Aquifer Expansion is treated as one of the fluid phases and accounts of geological heterogeneities, gas fluid properties, relperm properties and heat exchange with surrounding rocks. Unfortunately, in many practical cases the detailed information on the aquifer is not available which does not allow a proper modelling of aquifer expansion using a geological framework. Besides many practical applications require only knowledge of cumulative water influx from aquifer under pressure depletion. This allows building an Aquifer Drive Models using analytical methods.
Inputs & Outputs
| Inputs | Outputs | ||
|---|---|---|---|
p(t) | field-average formation pressure at time moment t | Q^{\downarrow}_{AQ}(t) | Cumulative subsurface water influx from aquifer |
p_i | initial formation pressure | q^{\downarrow}_{AQ}(t) = \frac{dQ^{\downarrow}_{AQ}}{dt} | Subsurface water flowrate from aquifer |
J_{AQ} | aquifer Productivity Index | ||
\tau | aquifer relaxation time | ||
| Detailing Inputs | |||
\displaystyle J_{AQ} = \frac{2 \pi \sigma}{\ln \frac{A_{AQ}}{A_e}+0.75} | aquifer Productivity Index | ||
\sigma | aquifer transmissibility | ||
A_e | oil pay area | ||
A_{AQ} | aquifer area | ||
\displaystyle \tau = \frac{V_{AQ} \, c_t}{J_{AQ}} | aquifer relaxation time | ||
c_t=c_r +c_w | aquifer total compressibility | ||
V_{AQ} = A_e \cdot h_e \cdot \phi | aquifer volume | ||
h_e | aquifer effective thickness | ||
\phi_e | |||
Assumptions
| Const Productivity Index Aquifer | |||||
|---|---|---|---|---|---|
J_{AQ} = \rm const |
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Equations
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See Also
Petroleum Industry / Upstream / Subsurface E&P Disciplines / Field Study & Modelling / Aquifer Drive / Aquifer Drive @model
Reference
1. Fetkovich, M.J. 1971. A Simplified Approach to Water Influx Calculations—Finite Aquifer Systems. J Pet Technol 23 (7): 814–28. SPE-2603-PA. http://dx.doi.org/10.2118/2603-PA