Reservoir Rock Mechanics Relative Permeability PDF

Summary

This document is a report on reservoir rock mechanics and relative permeability, from the UTM Summer School. It includes definitions, laboratory methods, effect of wettability, correlations, and calculations of relative permeability.

Full Transcript

RESERVOIR ROCK MECHANICS
RELATIVE PERMEABILITY
20TH July-3RD August 2019 l SCHOOL OF CHEMICAL & ENERGY ENGINEERING l FACULTY OF ENGINEERING
SUMMER SCHOOL: OIL & GAS LEARNING EXPERIENCE 2019

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SUMMER SCHOOL: OIL & GAS LEARNING EXPERIENCE 2019

Relative Permeability
Relative permeability
• Definition of relative
permeability
• Laboratory method of
measuring relative
permeabilities
• Effect of wettability
• Factors affecting relative
permeability
• Correlations
• Averaging

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It is expected that students will be able to:
• define relative permeability of rock to a
particular fluid for multi-phase fluid flow system
• draw relative permeability curves
• describe relative permeability measurements
using Steady State and Un-Steady State Flow
techniques
• explain the effect of rock wettability on relative
permeabilities and draw the relevant graph
• explain factors affecting relative permeability
• estimate relative permeabilities using published
correlations, such as Stone, Corey, and NPC.
• calculate and draw curves for relative
permeability.

Definition

Relative Permeability

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Give the accurate definition of relative permeability..
•

Determination of relative permeability in lab.
Introduce the steady state and unsteady state
methods, their strength and weaknesses.

•

Factors influencing relative perm
Discuss the effect of wettability, drainage process,
imbibition process and connate water.

•

Correlations
Discuss and apply the correlations to estimate relative
perm.

SUMMER SCHOOL: OIL & GAS LEARNING EXPERIENCE 2019

Relative Permeability

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Concept
If two or more fluid flow through a porous media, each fluid will flow
according to Darcy’s Law.

kw A ∆p
qw =
µ ∆L
ko A ∆p
qo =
µ ∆L
kg A ∆p
qg =
µ ∆L
Saturated with water, oil and gas

Theory

Relative Permeability
vos = −

ko  dPo
dz
− πo g 

ds 
µ  ds

vws = −

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kw  dPw
dz
− πw g 

ds 
µ  ds

ko = porosmedia effective permeability
to oil
kw = porosmedia effective permeability

vgs = −

kg  dPg
dz 

− πg g 
µ  ds
ds 

vos = oil phase velocity
vws = water phase velocity
vgs = gas phase velocity

to water
kg = porosmedia effective permeability
to gas

dPo

= oil phasepressuregradient

ds
dPw
= water phasepressuregradient
ds
dPg
= gas phasepressuregradient
ds

Theory

Relative Permeability

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Effective permeability is the ability of a porous media to flow a fluid in the
presence of one or more other fluids.

The effective permeability to the fluid depends on
-the amount or saturation of that fluid in the porous media
-Wettability characteristics of the porous media
-Saturation history

Theory

Relative Permeability

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Relative permeability
The effective permeability is usually presented in term of relative
permeability.
Relative permeability is the ratio of the effective permeability to a base
permeability.
For example,
The ratio of effective
permeability compared to
absolute permeability

kr =

keffective
k absolute

or,
The ratio of effective
permeability to the effective
permeability of non-wetting
phase at irreducible wetting
phase saturation.

kr =

keffective
knw@ Swir

Relative Permeability Curve

Relative Permeability

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Effective permeability

ka
Sw
0.1
0.206
0.316
0.4
0.5
0.6
0.7
0.8

250

400 md
Keffnw
200
118.7
64.9
44.2
25.1
8.8
3.7
0

Keffw
0
4.4
13.3
20.6
29.5
43.5
61.2
100

200

150

100

50

0

0

0.2

0.4

Keffnw

0.6

0.8

Keffw

1

Relative Permeability Curve

Relative Permeability

ka
Sw
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8

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kr = k effective wrt k absolute

400 md
Keffnw
200
118.7
64.9
40
21
8.8
3.7
0

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Keffw
0
4.4
13.3
20.6
29.5
43.5
61.2
100

keff/ka
krnw
krw
0.5
0
0.29675
0.011
0.16225 0.03325
0.1
0.0515
0.0525 0.07375
0.022 0.10875
0.00925
0.153
0
0.25

0.6

0.5

0.4

0.3

0.2

0.1

0

0

0.2

0.4

0.6
krnw
krw

0.8

1

Relative Permeability Curve

Relative Permeability

Sw
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8

Keffnw
200
118.7
64.9
40
21
8.8
3.7
0

Keffw
0
4.4
13.3
20.6
29.5
43.5
61.2
100

keff/knw(Swir)
krnw
krw
1
0
0.5935
0.022
0.3245 0.0665
0.2
0.103
0.105 0.1475
0.044 0.2175
0.0185
0.306
0
0.5

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k relative = k effective wrt knw(Swir)
1.2
1
0.8
0.6
0.4
0.2
0

0

0.5
krnw

1

Relative Permeability Curve

Relative Permeability

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Point 1 - on the wetting phase relative permeability
curve shows that a small saturation of
nonwetting phase will drastically reduced
the relative permeability of the wetting
phase (the nonwetting phase occupies the
larger pore spaces, and it is in the large
pore spaces that flow occurs with the least
difficulty.
Point 2 - on the nonwetting phase relative
permeability curve shows that the
nonwetting phase begins to flow at
relatively low saturation of the nonwetting
phase. The saturation of the oil at this
point is called critical oil saturation Soc.

Relative Permeability Curve

Relative Permeability

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Point 3 - on the wetting phase relative permeablity
curve shows that the wetting phase will cease to flow
at a relatively large saturation (the wetting phase
preferentially occupies smaller pore space, where
capillary forces are the greatest). The saturation of
the water at this point is refered to as the irreducible
water saturation Swir (ketepuan air tak terkurang)
Point 4 - on the nonwetting phase relative permeability
curve shows that, at low saturations of the wetting
phase, change in the wetting phase saturation have
only small effect on the magnitude of the nonwetting
phase relative permeability curve ( at low saturations
the wetting phase fluid occupies the small pore
spaces which do not contribute materially to flow, and
therefore changing the saturation in the small pore
spaces has relatively small effect on the flow of the
nonwetting phase).

Relative Permeability Curve

Relative Permeability

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Write your own note on Gas-oil relative
permeability curves

Effect of Res. Parameters on kr

Relative Permeability
2 reservoir parameters considered:

1. Saturation history
drainage
imbibition
2. Rock wettability
water wet rock
oil wet rock

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Effect of Res. Parameters on kr

Relative Permeability

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Saturation history
2 types of saturation history
Drainage process
- Porous rocks is initially saturated with wetting fluid. The wetting fluid was
then displaced with non-wetting fluid. This process, displacement of
wetting phase by non-wetting phase, is called drainage process.
Example – A water-wet rock that was saturated with water. Oil is then injected
into the rock and displacing the water. The oil was non-wetting
relative to water.
Imbibition process
- Porous rocks is initially saturated with non-wetting fluid. The non-wetting
fluid was then displaced with wetting fluid. This process,
displacement of non-wetting phase by wetting phase, is called
imbibition process.
Example – An water-wet rock was saturated with oil. Water is then injected
into the rock and displacing the oil. The oil was non-wetting relative
to water.

Effect of Res. Parameters on kr

Relative Permeability
Saturation history

Hysteresis: refers to irreversibility or
path dependence.
Drainage relative permeability curve
is higher than the imbibition curve for
non-wetting phase.

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Effect of Res. Parameters on kr

Relative Permeability
Rock wettability

Several important differences between oil-wet
curves and water-wet curves are generlly noted:
a. The water saturation at which oil and water
permeabilities are equal (intersection point of
curves) will generally be greater than 50% for
water-wet system and less than 50% for oil-wet
system.
b. The connate water saturation for a water-wet
system will generally be greater than 20%,
whereas, for oil wet-systems, it will normally be
less than 15%.
c. The relative permeability to water at maximum
water saturation (residual oil saturation) will be
less than about 0.3 for a water-wet system, but
will be greater than 0.5 for oil-wet systems.

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Relative Permeability Correlation

Relative Permeability
Two-phase relative permeability correlations
There are several correlations, among them are:
a. Wyllie and Gardner Correlation (1958)
b. Torcaso and Wyllie Correlation (1958)
c. Pirson's Correlation (1958)
d. Corey's Method (1954)

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Relative Permeability Correlation

Relative Permeability

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Two-phase relative permeability correlations (cont.)
These correlations use the effective phase saturation as the correlating
parameter.

S
S =
1− S
*

S −S
S =
1− S
*

o

o

w

wc

w

wc

wc

So*, Sw*, S g* = Effective oil, water and gas saturation
So, Sw, Sg = Oil, water and gas saturation
Swc = Connate (irreducible) water saturation

S =
*

g

S

g

1− S

wc

Relative Permeability Correlation

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Two-phase relative permeability correlations (cont.)
a. Wyllie and Gardner Correlation (1958)
Types of formation

kro

krw

Unconsolidated sand, well
sorted

(1− S )

Unconsolidated sand,
poorly sorted

(1− S ) (1− S ) (S )

Cemented sandstone,
oolitic limestone

*

(S )

3

*

w

w

*

w

2

*1.5
w

2

(1− S * ) 2 (1− S* )
o

3

w

*

3.5

o

(S )
*

o

4

Relative Permeability Correlation

Relative Permeability

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Two-phase relative permeability correlations (cont.)
a. Wyllie and Gardner Correlation (1958) (cont.)
Types of formation

kro

krg

Unconsolidated sand, well
sorted

(S )

(1− S )

Unconsolidated sand,
poorly sorted

(S )

(1− S ) (1− S )

Cemented sandstone,
oolitic limestone

(S )

*

*

3

o

*

o

3.5

o

*

o

3

*

2

o

4

*1.5
o

(1− S ) (1− S )
*

o

2

*2
o

Relative Permeability Correlation

Relative Permeability

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Two-phase relative permeability correlations (cont.)
a. Wyllie and Gardner Correlation (1958) (cont.)
If one relative permeability is available
System

kr

Oil-water system

 S 
k = (S ) − k
1 − S 


*

*

rw

w

2

w

ro

*

w

 S 
k = (S ) − k
1 − S 


*

Gas-oil system

*

ro

o

o

rg

*

o

Relative Permeability Correlation

Relative Permeability

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Two-phase relative permeability correlations (cont.)
b. Torcaso and Wyllie Correlation (1958)
kro in a gas-oil system.
kro is calculated from the measurements of krg.


(S )
k =k 
(1− S ) (1− (S
*

4

o

ro

rg

*

o

2

*
o


) )
2

Relative Permeability Correlation

Relative Permeability

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Two-phase relative permeability correlations (cont.)
c. Pirson's Correlation (1958)

Process
Imbibition

Wetting phase

k = (S ) S
rw

Nonwetting phase

*

3

w

w

(k )
r

nonwetting

1  S − S
=  − 1− S − S
 





)[1−(S )

S

w

wc

wc

Drainage

k = (S ) S
rw

*

3

w

w

(k )
r

nonwetting

2

= (1− S

*
w

nw

*

w

0.25

]

.0.5

w

Relative Permeability Correlation

Relative Permeability

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Two-phase relative permeability correlations (cont.)
d. Corey's Method (1954)
A simple mathematical expression for generating the relative permeability
data for the oil-gas system. The approximation is good for drainage
processes, i.e gas-displacing oil.

k = (1− S
ro

)

* 4
g

k = (S ) (2 − S
rg

* 3

*

g

g

)

Relative Permeability

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Example
Generate the relative permeability data for an unconsolidated well-sorted
sand by using the Wyllie and Gardner method. Assume the following critical
saturation values:
Soc = 0.3, Swc = 0.25, Sgc = 0.05
Solution
Drainage oil-water
system

k = (1− S )
*

ro

w

k = (S )
*

rw

w

3

3

Drainage oil-gas
system

k = (S )
*

ro

3

k = (1− S )
*

rg

S =
*

o

3

o

o

S =
*

g

S
1− S
S
o

S −S
S =
1− S
*

w

wc

w

wc

g

1− S

wc

wc

Relative Permeability

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Oil-water relative permeability

k = (1− S )
*

ro

w

k = (S )
*

rw

3

w

S =
*

g

S

Sw
0.25
0.31
0.37
0.45
0.52
0.60
0.67
0.70

Sw*
0.0000
0.0857
0.1607
0.2607
0.3607
0.4607
0.5607
0.6000

*

1− S

Soc 0.30
Swc 0.25
Sgc 0.05

S =

g

o

wc

S
1− S

S =
*

o

w

wc

wc

kro

0.8

krw
0.0000
0.0006
0.0042
0.0177
0.0469
0.0978
0.1763
0.2160

w

wc

1.0
0.9

kro
1.000
0.764
0.591
0.404
0.261
0.157
0.085
0.064

S −S
1− S

krw

0.7
0.6
0.5
0.4
0.3
0.2
0.1
0.0
0.0

0.2

0.4

0.6

Sw 0.8

Relative Permeability

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Oil-gas relative permeability

k = (1− S )
*

rg

3

o

Sg
0.05
0.11
0.16
0.22
0.29
0.36
0.42
0.45

k = (S )
*

ro

Soc
Swc
Sgc

0.30
0.25
0.05

So
0.7000
0.6429
0.5929
0.5262
0.4595
0.3929
0.3262
0.3000

So*
0.933
0.857
0.790
0.702
0.613
0.524
0.435
0.400

3

S =
*

g

o

S
1− S

S =
*

g

o

wc

S
1− S

S =
*

o

w

wc

S −S
1− S
w

wc

1.0
kro

0.9

krg

0.8

kro
0.813
0.630
0.494
0.345
0.230
0.144
0.082
0.064

krg
0.000
0.003
0.009
0.027
0.058
0.108
0.180
0.216

0.7
0.6
0.5
0.4
0.3
0.2
0.1
0.0
0.00

0.10

0.20

0.30

wc

0.40

Sg

0.50

Relative Permeability

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Example
Generate the relative permeability data for an unconsolidated well-sorted
sand by using the Pirson's method for water-oil system. Assume the following
critical saturation values:
Soc = 0.3, Swc = 0.25, Sgc = 0.05
Solution
Process
Imbibition

Wetting phase

k = (S ) S
rw

Nonwetting phase

*

3

w

w

(k )
r

nonwetting

  S − S 
= 1− 1 − S − S 

 
w

wc

wc

Drainage

k = (S ) S
rw

*

3

w

w

(k )
r

nonwetting

= (1− S

*
w

2

nw

)[1−(S )
*

w

0.25

S ]

.0.5

w

Relative Permeability

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S −S
S =
1− S

Oil-water relative permeability (assume oil-wet system)

k = (S ) S
rw

*

3

w

w

(k )

Soc 0.30
Swc 0.25
Sgc 0.05
Sw
0.25
0.31
0.37
0.45
0.52
0.60
0.67
0.70

Sw*
0.0000
0.0857
0.1607
0.2607
0.3607
0.4607
0.5607
0.6000

r

nonwetting

[

= (1− S )1− (S )
*

w

*

w

0.25

S

*

]

wc

1.0

Pirson's
krw
kro
0.000 1.000
0.009 0.763
0.020 0.658
0.045 0.535
0.085 0.424
0.143 0.325
0.226 0.237
0.266 0.205

0.9

krw

kro

0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0.0
0.0

0.2

0.4

wc

w

.0.5

w

w

0.6

0.8 Sw 1.0

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Example
Use Corey's approximation to generate the gas-oil relative permeability for a
formation with connate water saturation 0.25.

Solution

k = (1− S
ro

)

* 4
g

k = (S ) (2 − S
rg

* 3

*

g

g

)

Relative Permeability
Gas-oil relative permeability

k = (1− S
ro

)

* 4
g

k = (S
rg

Soc 0.30
Swc 0.25
Sgc 0.05
Sg
0.05
0.14
0.22
0.33
0.44
0.55
0.66
0.70

Sg*
0.0667
0.1905
0.2988
0.4433
0.5877
0.7321
0.8766
0.9333

kro
0.759
0.429
0.242
0.096
0.029
0.005
0.000
0.000

krg
0.001
0.013
0.045
0.136
0.287
0.498
0.757
0.867

*
g

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S =

) (2 − S )
3

S

*

g

*

g

g

1− S

wc

1.0
kro

0.9

krg

0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
0.0

0

0.2

0.4

0.6

0.8

Sg 1

Relative Permeability

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NORMALIZATION AND AVERAGING
•

Results of relative permeability tests performed on several core samples of a
reservoir rock often vary.

•

It is necessary to average the relative permeability data obtained on individual rock
samples.

•

Prior to usage for oil recovery prediction, the relative permeability curves should
first be normalized to remove the effect of different initial water and critical oil
saturations.

•

The relative permeability can then be de-normalized and assigned to different
regions of the reservoir based on the existing critical fluid saturation for each
reservoir region.

Relative Permeability

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•

The most generally used method adjusts all data to reflect assigned end values,
determines an average adjusted curve and finally constructs an average curve to
reflect reservoir conditions.

•

These procedures are commonly described as normalizing and de-normalizing the
relative permeability data.

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For a water-oil system:
Step 1. Select several values of Sw starting at Swc (column 1), and list the corresponding
values of kro and krw in columns 2 and 3.
Step 2. Calculate the normalized water saturation S*w for each set of relative
permeability curves and list the calculated values in column 4 by using the following
expression:

where ;
Soc =Critical oil saturation
Swc = Connate water saturation
S*w = Normalized water saturation

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Step 3. Calculate the normalized relative permeability for the oil phase at different
water saturation by using the relation (column 5):

where kro = relative permeability of oil at different Sw, (kro)Swc = relative
permeability of oil at connate water saturation: kr*o = normalized relative permeability
of oil.
Step 4. Normalize the relative permeability of the water phase by applying the following
expression and document results of the calculation in column 6.

where (krw)Soc is the relative permeability of water at the critical oil saturation.

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Step 5. Using regular Cartesian coordinate, plot the normalized kro* and krw* versus Sw*
for all core samples on the same graph.
Step 6. Determine the average normalized relative permeability values for oil and water
as a function of the normalized water saturation by select arbitrary values of Sw* and
calculate the average of kro* and krw* by applying the following relationships:

and

where n = total number of core samples, hi = thickness of sample i, ki = absolute
permeability of sample i.

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Step 7. The last step in this methodology involves de-normalizing the average curve to
reflect actual reservoir and conditions of Swc and Soc. These parameters are the most
critical part of the methodology and, therefore, a major effort should be spent in
determining representative values.
The Swc and Soc are usually determined by averaging the core data, log analysis, or
correlations, versus graphs, such as: (kro)Swc vs. Swc, (krw)Soc vs. Soc, and Soc vs. Swc
which should be constructed to determine if a significant correlation exists.
Often, plots of Swc and Sor versus log (k/Ф)0.5 may demonstrate a reliable correlation to
determine end-point saturations as shown schematically in Figure 5-8.
When representative end values have been estimated, it is again convenient to perform
the denormalization calculations in a tabular form as illustrated below:

Relative Permeability

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where (kro)Swc and (krw)Soc are the average relative permeability of oil and water at
connate water and critical oil, respectively, and given by:

Relative Permeability

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Relative Permeability

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Relative Permeability

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Innovative · Entrepreneurial · Global

Relative Permeability

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Innovative · Entrepreneurial · Global

Relative Permeability

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Innovative · Entrepreneurial · Global

Relative Permeability

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