Flow in Porous Media. Module 1.c Fundamental Properties of Porous Media Shahab Gerami

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Flow in Porous Media Module 1.c Fundamental Properties of Porous Media Shahab Gerami

Forces acting on a fluid in a reservoir Capillary forces Viscous forces Gravitational forces

Surface Tension

Interfacial Tension

Capillary Pressure

Capillary Pressure in a Porous Medium The curvature of the fluid-fluid interfaces changes with changing saturation. This makes the capillary pressure a function of saturation. When the wetting phase saturation is small, the interfaces occur in smaller pores and are highly curved. This makes P C high at low wetting phase saturations. The capillary pressure at a given saturation is a measure of the smallest pore being entered by the nonwetting phase at that point, suggesting the curvature of the capillary pressure curve is a function of the pore size distribution. The level of the curve is determined by the mean pore size. When the wetting phase saturation is high, the interfaces are less curved and P C is lower. P C becomes zero at certain value of the wetting phase saturation. At this point, all non-wetting phase is in the form of trapped globules.

Viscous Force

Dominance of Capillary Forces over Viscous Forces

Capillary Number We can define the capillary number as a dimensionless number that relates the magnitudes of the capillary and viscous forces. The capillary number allows us to understand whether capillary forces dominate at the pore scale.

Some authors use the Darcy velocity instead of the interstitial velocity Some authors use the below relation to account for variations in the contact angle.

Bond Number

Phase Trapping When oil is displaced from a rock, the process is never perfect and a part of the oil is left behind in the form of globules or ganglia. Developing EOR techniques requires understanding how the trapping occurs and how can the trapped oil be mobilized. The actual mechanism in real rocks is quite complex and difficult to describe mathematically. A number of simplified models provide insight into the mechanisms involved.

Requirement for Phase Trapping Nonzero interfacial tension Local heterogeneity Poor connectivity

Residual Saturations There is a residual saturation at which the capillary pressure appears to head towards infinity or zero. In the case of the wetting phase we often refer to this as the immobile saturation. No matter how much pressure we apply, we cannot reduce the wetting phase saturation any further (actually this is an oversimplification, since what we mean is that we cannot reduce it in any reasonable amount of time).

RESIDUAL OIL SATURATION (S or ) For each initial saturation of nonwetting phase, there is a certain residual saturation that would remain after flooding with the wetting phase. For example, in Figure 2.31, if a rock had the initial nonwetting phase saturation represented by point A, then were it to be saturated with wetting phase it would have the residual saturation represented by A.

Point B represents the maximum trapped nonwetting phase saturation Points A and C have equal capillary pressures but on different capillary pressure curves. The difference between the x coordinates of points A and C is the disconnected nonwetting phase saturation at point C. The connected nonwetting phase configuration is identical in configurations A and C; hence the trapped nonwetting phase saturation corresponding to an initial saturation at point A is the difference between the nonwetting phase saturation at point B minus the difference between the nonwetting phase saturations at points C and A (i.e., B [C A]). This procedure yields one point on the IR curve, but the whole curve may be traced by picking several points along the two P c curves.

Residual Non-wetting Phase Saturation The residual nonwetting phase saturation occurs because small blobs of nonwetting phase become trapped in the pores, and once disconnected from each other they can no longer flow. In a sequence of injections of non-wetting followed by wetting phase fluids (figure below ) the capillary pressure is governed by the connected nonwetting phase saturation. For each initial saturation of nonwetting phase, there is a certain residual saturation that would remain after flooding with the wetting phase.

The relationship between the initial and residual nonwetting phase saturation is of great importance in determining the effectiveness of oil recovery during waterflooding. We can plot initial vs. residual saturation in an IR curve, such as below figure.

Land Trapping Model The curve can be characterized using the Land trapping coefficient, C, defined as: Where the normalized saturations S* are defined: We can also write: C varies from zero (complete trapping) to infinity (no trapping).

Typical IR Nonwetting Phase Saturations Curves where C is positive constant and a function of rock type, porosity

Non wetting phase blocking

Conceptual Models for Trapping Trapping in Pore Doublet We are fundamentally interested in trapping of the nonwetting phase. In petroleum recovery the nonwetting phase is usually the oil, which we would earnestly like not to be trapped in the ground. Trapping in Snap-Off Model The forming of the discontinuous blobs through a running-ahead wetting phase is known as snap off. The consequences of snap off is described in more depth below but it arises largely because of the difference in the sizes between the pore throat and body, the larger the disparity, the more the trapping.

Trapping Mechanisms-Pore Doublet Model

Pore Doublet Explains Nonwetting phase trapping Trapping controlled by viscous/capillary ratio Local heterogeneity required

Water wet

Oil wet

Trapping Snap-off Model

Immobile Wetting Phase Saturation

(a): At low wetting phase saturation, the pendular rings are isolated and do not form a continuous water phase except for the very thin film of adsorbed water on the solid surfaces, a few tens of molecules in thickness. We shall discuss the effect of this film at a later stage. Thus, when all the water is in the form of pendular rings, no flow is possible, as there is no continuous pathway of water. Water pressure applied at some point cannot be transmitted to other points. (c): As water saturation increases, the pendular rings expand and coalesce, until continuous water phase is formed. Above this critical saturation, the 'bulk' water forms a continuous phase, and its saturation is called funicular; flow of 'bulk' water is possible.

Capillary Desaturation Curve (CDC) for Pore Doublet The CDC relates the amount of trapped nonwetting or wetting phase as a function of capillary number.

Capillary Desaturation Curve

Critical Capillary Number In most cases the nonwetting phase has a higher residual (more trapping) than the wetting phase. Both phases tend to have a critical Capillary number at which the trapped phase begins to mobilize. The critical Capillary number for wetting phase is often higher than that for nonwetting phase, hence the target for enhanced oil recovery is to modify the Capillary number to lie between the two critical values. In practice it is difficult to raise either the viscosity or velocity, so the most accessible way to increase Capillary number is to reduce the interfacial tension s, for example by adding surfactant.

Pore Size Distribution Broadens CDC

Trapping and Capillary Number

Trapping and Gravity

Effect of Wettability on Residual Oil Saturation

Effect of Wettability on Residual Oil Saturation

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