Fetkovich (1971) proposed a model to simplify water influx calculations further.
This method uses a pseudo-steady-state aquifer productivity index (PI) and an
aquifer material balance to represent the system compressibility. Like the CarterTracy method, Fetkovich’s model eliminates the use of superposition and therefore, it is much simpler than van Everdingen-Hurst method. However, because
Fetkovich neglects the early transient time period in these calculations, the calculated water influx will always be less than the values predicted by the previous two
models.
The Fetkovich model applies to finite-acting aquifers; the model is applicable to
both radial and linear aquifers. The Fetkovich aquifer model applies to edge-water
and bottom-water drive reservoirs, while the Carter-Tracy aquifer model applies to
edge-water drive reservoirs. In edge-water drive, water influx occurs around the
flanks of the reservoir. In bottom-water drive, the reservoir is underlain by the
aquifer which encroaches vertically into the reservoir. These are represented in the
Fig. 4.4.
Fetkovich used an inflow equation similar to fluid flow from a reservoir to a well,
to model the water influx to the reservoir. Assuming constant pressure at the original
reservoir/aquifer boundary, the rate of water influx is derived as follow:
The inflow equation is given as:
q ¼
Where qw ¼ water influx rate, j ¼ aquifer productivity index, P ¼ Pressure at thereservoir fluid contact i.e. inner aquifer boundary pressure, Pa ¼ average pressure in
the aquifer & We ¼ cumulative water influx.
The total aquifer influx due to the total pressure drop is:
The results are plotted in the figure below. This shows that there is a closeness in
value between the Van Everdingen and Fetkovich model with little deviation
from the Carter-Tracy model but that does not mean that Carter-Tracy model cannot
estimate water influx well. In some reservoir, Carter-Tracy model fits the aquifer
model used in matching historical data. Thus, these aquifer models are tested on the
reservoir to see which matches the past field performance with a minimum tolerance
of error.