FORM ULATION OF G EN ERA L RELA T IV E P ER M EA B IL IT Y CORRELATION
OF FIELD A
A BD U L HAKIM BIN BASRI
Laporan ini dikemukakan sebagai memenuhi
sebahagian daripada syarat penganugerahan
[jazah Sarjana Kejuruteraan Petroleum
Sekolah Kejuruteraan Kimia dan Kejuruteraan Tenaga
Universiti Teknologi Malaysia
MEI 2019
v
“My dearest late father, mom, wife, family, Assoc. ProfZaidi andfriends”
This is for all of you
ix
ACKNOWLEDGEMENT
First and foremost, I have to thank my supervisor, Assoc. Prof Zaidi. Without
his assistance and dedicated involvement in every step throughout the process, this
thesis would have never been accomplished. I would like to thank you very much for
your support and understanding over this past one year.
Getting through my dissertation required more than academic support, and I
have many, many people to thank for listening to and, at times, having to tolerate me
over the process. Most importantly, none of this could have happened without my
family. My wife who always been very supportive. Every time I was ready to quit, you
did not let me and I am forever grateful. This dissertation stands as a testament to your
unconditional love and encouragement.
xi
ABSTRAK
Data kebolehtelapan relatif amat penting untuk hampir semua pengiraan
pengaliran bendalir dalam takungan dan digunakan secara meluas dalam banyak
bidang kejuruteraan petroleum. Pengukuran kebolehtelapan relatif dilakukan pada
sampel teras di makmal dan kedua-duanya memakan masa dan mahal untuk
dihasilkan. Hasil daripada kesukaran dan kos yang terlibat dalam mengukur nilai
kebolehtelapan relatif, kolerasi dan pengiraan empirik sering digunakan untuk
menganggarkan nilai-nilai tersebut. Dalam bidang kajian yang merupakan Lapangan
Minyak A, hanya terdapat satu data SCAL yang boleh didapati daripada satu takungan.
Oleh itu, terdapat keperluan untuk merumuskan kolerasi am untuk digunakan dalam
lapangan minyak yang dikaji atau lapangan minyak yang lain di lembangan melayu
tanpa data SCAL. Penubuhan kolerasi tersebut telah menjadi matlamat utama
penyelidikan ini. Tiga kolerasi yang diterbitkan telah dipilih untuk dianalisa dan
dibandingkan untuk menentukan kolerasi yang paling sesuai untuk lapangan minyak
yang dikaji. Penyelidikan bermula dengan pengumpulan data yang meliputi
pemeriksaan kualiti data dan penapisan data. Analisi terperinci mengenai data dana
rumusan kolerasi dijalankan. Tiga (3) kolerasi iaitu Corey, Chierici dan LET telah
dibandingkan dan dianalisa. Dari semua kolerasi, kolerasi Corey dan Chierici tidak
cukup fleksibel untuk menyelaraskan keseluruhan set pemerhatian eksperimen.
Kolerasi LET mempamerkan fleksibiIiti untuk menyelaraskan seluruh set data
eksperimen dengan memuaskan. Tingkah laku s dimodelkan dengan baik
menggunakan kolerasi LET. Kolerasi ini telah dipilih dan diuji dalam model dinamik
untuk menguji kesahihannya. Keputusan menunjukkan bahawa pemadanan kadar
minyak dan air boleh diterima. Oleh itu, kolerasi ini telah diterima dan telah digunakan
untuk menghasilkan lengkung kebolehtelapan relatif untuk takungan minyak lain di
Lapangan Minyak A.
xii
ABSTRACT
Relative permeability data are essential for almost all fluid flow calculations in
reservoirs and are utilized extensively in many areas of petroleum engineering.
Relative permeability measurements are conducted on core samples in laboratory and
are both time-consuming and expensive to produce. As a result of the difficulties and
cost involved in measuring relative permeability values, empirical correlations and
calculations are often employed in order to estimate the values. In the field of study
which is Field A, there is only one SCAL data available from a reservoir. Hence there
is a need to formulate a general correlation to be used in the field of study or other
fields in Malay basin with no or limited SCAL data. The establishment of such
correlation will be the main objective of this research. The available SCAL data were
manipulated and analyzed to create a suitable correlation to be used for other
reservoirs. Three published correlations were chosen to be analyzed and compared to
determine the most suitable correlations for the field under study. The research started
with data collection which includes data quality checking and screening. Six (6) core
samples for kro-krw and six (6) core samples for krg-kro was were used in this
research. Then detailed analysis of the data and correlation formulation was conducted.
Three (3) correlations which are Corey, Chierici and LET were compared and
analyzed. From all the correlations, Corey and Chierici correlations are not flexible
enough to reconcile the entire set of experimental observations. LET correlation
exhibits flexibility to satisfactorily reconcile the entire set of experimental data. The s-
behaviour is well modeled by LET correlation. This correlation was chosen and tested
in the dynamic model to test its validity. Results showed that acceptable matching of
oil rate and water cut were obtained. Hence the correlations were accepted and will be
used to generate pseudo-relative permeability curves for other hydrocarbon reservoirs
in Field A.
xiii
CONTENT
DECLARATION ii
DEDICATION iii
ACKNOWLEDGEMENT xi
ABSTRAK xii
ABSTRACT xiii
CONTENT xiv
LIST OF TABLES xvii
LIST OF FIGURES xix
ABBREVIATIONS xxii
LIST OF SYMBOLS xxiii
1 INTRODUCTION 1
1.1 Background 1
1.2 Problem Statement 4
1.3 Objectives 5
1.4 Scope of Study 6
1.5 Significance of Study 7
2 LITERATURE REVIEW 9
2.1 Concept of Relative Permeability 9
2.1.1 Relative Permeability 10
2.1.2 Factors affecting relative permeability 11
2.1.2.1 Wettability effect on relative
permeability 11
CHAPTER TITLE PAGE
xiv
2.1.2.2 Effect of fluid saturation and
saturation history 12
2.1.2.3 Effect of viscous and capillary
forces 12
2.2 Two-phase relative permeability 14
2.2.1 Relative Permeability parameters 15
2.2.1.1 EndPoints 15
2.2.1.2 Shape Factor 16
2.3 Estimating two-phase relative permeability 17
2.3.1 Lab Procedures 17
2.3.1.1 Centrifuge method 17
2.3.1.2 Two-phase steady state method 18
2.3.1.3 Two-phase unsteady state method
19
2.3.2 Correlations 20
2.3.2.1 Corey correlation 21
2.3.2.2 Chierici correlation 23
2.3.2.3 LET correlation 24
2.4 Correlation Comparison 25
2.5 Software used for research 28
2.5.1 EC LIPSE 100 Reservoir Simulator 28
2.5.2 Petrel 2017 28
3 METHODOLOGY 31
3.1 Introduction 31
3.2 Data Collection 33
3.2.1 Data Source 33
3.2.2 Data Quality Checking 33
3.2.2.1 Data Screening 33
3.2.2.2 Relative Permeability Adjustment
33
3.2.2.3 End Points 34
3.3 Detailed Analysis and Correlation Formulation 34
3.3.1 End Points 34
xv
3.3.2 Shape Factor 37
3.3.2.1 Corey 37
3.3.2.2 Chierici 38
3.3.2.3 LET 39
3.4 Case Studies 40
3.5 Workflow Generation 41
4 RESULTS AND DISCUSSION 43
4.1 Data Collection 43
4.1.1 Data Source 43
4.1.1.1 Porosity and Permeability 45
4.1.1.2 Water-OiI Relative Permeability 51
4.1.1.3 Gas-OiI Relative Permeability 58
4.1.1.4 Capillary Pressure, Pc 64
4.1.2 Data Quality Checking 65
4.1.2.1 Data Screening 66
4.2 Detailed Analysis and Correlation Formulation 68
4.2.1 End Points 68
4.2.2 Shape Factor 81
4.2.2.1 Corey 81
4.2.2.2 Chierici 87
4.2.2.3 LET 90
4.2.2.4 Correlations Comparison 93
4.3 Case Studies 95
4.4 Workflow Generation 101
4.4.1 Workflow Example 104
5 CONCLUSION 109
5.1 Conclusion 109
5.2 Recommendation 110
REFERENCES 111
xv i
LIST OF TABLES
TABLE NO. TITLE PAGE
Table 2-1: Oil Water Corey Exponent with Wettability (McPhee, Reed, &
Zubizarreta, 2015) 22
Table 2-2: Another Oil Water Corey Exponent versus Wettability (Stiles, 2013) 23
Table 4-1: Porosity and Permeability for Plug samples used in Special Core Analysis
46
Table 4-2: Sample No. 21A kro-krw 52
Table 4-3: Sample No. 25A kro-krw 53
Table 4-4: Sample No. 35A kro-krw 54
Table 4-5: Sample No. 43A kro-krw 55
Table 4-6: Sample No. 47A kro-krw 56
Table 4-7: Sample No. 51A kro-krw 57
Table 4-8: Sample No. 21D kro-krg 59
Table 4-9: Sample No. 25D kro-krg 60
Table 4-10: Sample No. 35D kro-krg 61
Table 4-11: Sample No. 47D kro-krg 62
Table 4-12: Sample No. 51D kro-krg 63
Table 4-15: Capillary Pressure, Pc Data 64
Table 4-13: Table of end points for the water-oil samples 66
Table 4-14: Table of end points for the gas-oil samples 67
Table 4-16: End-Points Correlations Summary 81
Table 4-17: Sample 25A Normalized Relative Permeability 82
Table 4-18: Sample 35A Normalized Relative Permeability 83
Table 4-19: Sample 43A Normalized Relative Permeability 83
Table 4-20: Sample 51A Normalized Relative Permeability 84
xvii
Table 4-21 Corey Relative Permeability Table 86
Table 4-22 Chierici Relative Permeability Table 89
Table 4-23 LET Relative Permeability Table 92
Table 4-24 RQI Range Selected 96
Table 4-25 End Point Values for each RQI Ranges 96
Table 4-26 Relative Permeability Table (1) 104
Table 4-27 Relative Permeability Table (2) 105
Table 4-28 Relative Permeability Table (3) 106
Table 4-29 Relative Permeability Table (4) 107
xviii
LIST OF FIGURES
Figure 1-1: Example of Oil-Water Relative Permeability Curve 2
Figure 1-2: Illustration of two-phase reservoir system 3
Figure 2-1: Two-phase relative permeability curves (Ahmed, 2006) 14
Figure 2-2: Schematic of steady state displacement experiment for water-oil system
19
Figure 2-3: Schematic of unsteady state displacement experiment for water-oil
system 20
Figure 2-4: History match of differential pressure (Lomeland et a I., 2005) 25
Figure 2-5: History match of production (Lomeland et al., 2005) 26
Figure 2-6: Relative permeability curve (Lomeland et al., 2005) 26
Figure 3-2: Relative Permeability curve endpoints for Oil-Water System 36
Figure 3-3: Relative Permeability curve endpoints for Oil-Gas System 36
Figure 4-1: Sampling point in the open hole logs 44
Figure 4-2: Sampling point in the core slab 44
Figure 4-3: Poro Perm Plot by Facies 50
Figure 4-4: Sample No. 21A kro-krw 52
Figure 4-5: Sample No. 25A kro-krw 53
Figure 4-6: Sample No. 35A kro-krw 54
Figure 4-7: Sample No. 43A kro-krw 55
Figure 4-8: Sample No. 47A kro-krw 56
Figure 4-9: Sample No. 51A kro-krw 57
Figure 4-10: Sample No. 21D kro-krg 59
Figure 4-11: Sample No. 25D kro-krg 60
Figure 4-12: Sample No. 35D kro-krg 61
FIGURE NO. TITLE PAGE
xix
Figure 4-13: Sample No. 47D kro-krg 62
Figure 4-14: Sample No. 51D kro-krg 63
Figure 4-17: Pc vs Sw Plot 65
Figure 4-15: kro-krw Comparison Plot 66
Figure 4-16: kro-krg Comparison Plot 67
Figure 4-18: Swi vs Porosity 68
Figure 4-19: Swi vs Permeability 69
Figure 4-20: Swi vs RQI 69
Figure 4-21: Sorw vs Porosity 70
Figure 4-22: Sorw vs Permeability 70
Figure 4-23: Sorw vs Rock Quality Index 71
Figure 4-24: Sorg vs Porosity 72
Figure 4-25: Sorg vs Permeability 72
Figure 4-26: Sorg vs Rock Quality Index 73
Figure 4-27: krorwvs Porosity 74
Figure 4-28: krorwvs Permeability 74
Figure 4-29: krorw vs Rock Quality Index 75
Figure 4-30: krorw vs Porosity 75
Figure 4-31: krorw vs Permeability 76
Figure 4-32: krorw vs Rock Quality Index 76
Figure 4-33: krwr vs Porosity 77
Figure 4-34: krwr vs Permeability 78
Figure 4-35: krwr vs Rock Quality Index 78
Figure 4-36: krgr vs Porosity 79
Figure 4-37: krgr vs Permeability 79
Figure 4-38: krgr vs Rock Quality Index 80
Figure 4-39: O-W Relative Permeability Plot for all samples 85
Figure 4-40: Corey Normalized O-W Relative Permeability Plot 85
Figure 4-41: Corey Normalized (semilog) O-W Relative Permeability Plot 86
Figure 4-42: Chierici Normalized O-W Relative Permeability Plot 88
Figure 4-43: Chierici Normalized (semilog) O-W Relative Permeability 89
Figure 4-44: LET Normalized O-W Relative Permeability Plot 91
Figure 4-45: LET Normalized (semilog) O-W Relative Permeability 92
xx
Figure 4-46: Correlation comparison - Normalized O-W Relative Permeability Plot
94
Figure 4-47: Correlation comparsion- Normalized (semilog) O-W Relative
Permeability 95
Figure 4-48: Relative Permeability Plot for each RQI Ranges 97
Figure 4-49: A01, A02 and A03 Swi Matching 97
Figure 4-50: A04 and A05 Swi Matching 98
Figure 4-51: Well A-01 History Matching 99
Figure 4-52: Well A-02 History Matching 99
Figure 4-53: Well A-03 History Matching 100
Figure 4-54: Well A-04 History Matching 100
Figure 4-55: Well A-05 History Matching 101
Figure 4-56: Relative Permeability workflow 103
Figure 4-57: kro-krw Plot 108
xx i
ABBREVIATIONS
SCAL
RCA
RQI
Special Core Analysis
Routine Core Analysis
Rock quality index
xxii
LIST OF SYMBOLS
k - Permeability
kro - Relative permeability of oil
krw - Relative permeability of water
krg - Relative permeability of gas
Swi - Irreducible water saturation
Sgc - Critical gas saturation
Sorw - Residual oil saturation
Sorg - Residual oil saturation to gas
Q - Fluid flowrate
A - Cross-sectional area
dp/dl - Pressure gradient
\i - Viscosity
cp - Centipoise
Nc - Capillary number
g - Interfacial tension
9 - Rock porosity in fraction
Swn - Normalized water saturation
kair - Permeability to air
krin - Normalized relative permeability
kro-krw - Oil-water relative permeability
krg-kro - Gas-oiI relative permeability
xxiii
CHAPTER 1
INTRODUCTION
1.1 Background
Permeability is a property of the porous medium that measures the capacity and
ability of the formation to transmit fluids (Ahmed, 2001). The rock absolute
permeability, often given the symbol k is a very important rock property because it
controls the directional movement and the flow rate of the reservoir fluids in the
formation. If it takes a lot of pressure to squeeze fluid through a rock, that rock has
low permeability. If fluid passes through the rock easily, it has high permeability.
Relative permeability, a dimensionless quantity, is the ratio of effective
permeability to absolute permeability. Relative permeability is a crucial empirical
parameter in describing the flow of multiple immiscible fluids within a porous medium
(Honarpour and Mahmood, 1988).
E f f e c t i v e Permeabil ity, k o / k w / k gRelative P e r m e a b i l i t y , k r o / k r w / k r g = ------------------------ -— ---------------------------------------------— -------------- ----------------------
Absolute Permeability, k
1
The relative permeability to one phase changes with the relative saturation of
that phase. It is equal to one at 100% saturation of the phase and gradually decreases
to reach zero at the critical or irreducible saturation of that phase. Figure 1.1 shows the
general oil water relative permeability curve.
Figure 1-1: Example of Oil-Water Relative Permeability Curve
In hydrocarbon reservoirs, no one phase can reach the saturation of 100%.
Consequently, in a multiphase system, the relative permeability of any phase cannot
reach the value of one. However, most core analysis laboratories evaluate the relative
permeability as referenced to the maximum effective permeability of the oil phase
rather than referencing to the porous medium's absolute permeability. This leads to
reporting the value of one for the maximum relative permeability to the oil phase. In
any reservoir study, this should be noticed and all relative permeability values should
be adjusted before further proceeding. In two-phase system, the fluids consists of oil
and water, oil and gas or gas and water, while in three-phase system, the fluids consists
of oil, water and gas. An example of an oil-water system is shown in Figure 1-2.
2
Connate/Irreducible Water Siw
Pore Volume — < Residual Oil Sorw
Mobile Oil
Grain Volume^=i
Figure 1-2: Illustration of two-phase reservoir system
Relative permeability data are essential for almost all fluid flow calculations in
reservoirs and is utilized extensively in many areas of petroleum engineering such as
determining the residual fluid saturations, calculating the fractional flow and frontal
advance and making engineering estimates of productivity, injectivity and ultimate
recovery. The data are more particularly used for matching, predicting and optimizing
oil and gas reservoir performances through numerical simulations.
Relative permeability measurements are conducted on core samples in
laboratory and are both time-consuming and expensive to produce. Consequently,
relative permeability measurements are mainly requested for projects where secondary
and/or tertiary recovery is being considered. As a result of the difficulties and cost
involved in measuring relative permeability values, empirical correlations and
calculations are often employed in order to estimate the values. In the past decades,
several correlations have been developed to predict relative permeability of oil
reservoirs. In 1954, Corey introduced a correlation to estimate relative permeability of
water-oil and gas-oil systems, based on relative permeability measurements on a large
number of cores from several formations. Honarpour, Koederitz and Harvey (2000)
utilized the relative permeability data obtained from oil and gas fields in various parts
of the world, to develop a new correlation for prediction of relative permeabilities.
Chierici (1984) suggested a two-parameter exponential relationship to predict relative
permeabilites of water-oil and gas-oil systems. In the current study, these three
3
correlations are used and compared. Fine tuning of the correlation might be done to fit
the field of study.
Analysis done by Cocco (2002) concluded that each depositional environment
has its distinct relative permeability correlations. There are differences in the average
values and variances, as well as in the strength of the correlations between the variable.
Hence it is necessary to sample core plugs in the reservoir under study. Relative
permeability also depends on a combined effect of pore geometry, fluid distribution,
wettability, and fluid saturation (Okasha, Funk and Balobaid, 2001). Hence relative
permeability is unique to the field or regions. This study was conducted to formulate
the most suitable correlations for the field of study.
1.2 Problem Statement
Relative permeability is one of the most essential parameters in reservoir
engineering studies. In reservoir simulation, relative permeability is the parameter
used by reservoir simulators to define the relative movements of different reservoir
fluids. The concept of relative permeability is quite simple. However, proper
evaluation is not an easy task. Relative permeability is evaluated in laboratory as part
of the SCAL (Special Core Analysis) program. Both steady and unsteady state
displacement are used to evaluate relative permeability at different saturation values.
These measurements are being carried out on small core plugs obtained from the
available whole cores. In addition to lab work uncertainties, core coverage is an
important factor that affects the reliability of the evaluated relative permeability. Due
to operation concerns, it is very difficult to have adequate core coverage for any
reservoir. Strict precautions and high costs make it even more difficult to obtain
adequate coverage of SCAL. These factors raise the importance of careful and
effective handling of the available SCAL data to obtain reasonably representative
relative permeability data for any reservoir study.
Since obtaining relative permeability data from laboratory experiments is
rather delicate, time consuming, and costly, a series of empirical models has been
4
developed in literature to estimate them when experimental data from core samples is
not available. The empirical correlations are also employed to reproduce
experimentally determined relative permeability curves as verification. These methods
were based on experimental data and mathematical derivations or heuristic concepts
to predict relative permeability.
In the field of study, there is only one SCAL data available from a reservoir.
Hence there is a need to formulate a general correlation for other reservoirs in the field.
The available SCAL data can be manipulated and analysed to create a suitable
correlations to be used for other reservoirs. Since relative permeability is such a strong
controlling factor in determining reservoir performance, accurate determination of
water-oil and gas-oil relative permeability character for a formation matrix is essential
for accurate prediction and optimization purposes. Although a variety of correlations
to predict relative permeability are available, considerable variance can be present in
the predicted results, and experimental measurements still provide the most accurate
method of determination. Three published correlations were chosen to be analysed and
compared to determine the most suitable correlations for the field of study. Fine tuning
of the correlations might be done if none of the correlations satisfy the criteria. There
is also no general workflow of formulating the relative permeability correlation
available. Hence a general workflow will be generated in the study for the use of other
users.
1.3 Objectives
The main objectives of this study are:
i) To develop a general relative permeability correlation to be used in the
field of study or other fields in Malay Basin with no or limited SCAL
data.
ii) To establish a workflow in order to guide users on proper way of
formulating relative permeability correlations.
5
iii) To perform a case study whereby the correlation formulated is applied
in a specific field.
1.4 Scope of Study
i) Data collection and quality checking
a. Six (6) core samples for kro-krw (labelled as
21 A/2 5 A/3 5 A/4 3 A/4 7 A/51 A).
b. Six (6) core samples for krg-kro (labelled as
21 D/2 5 D/3 5 D/4 3 D/51 D).
ii) Detailed analysis and correlation formulation
a. Finding a trend using few properties to find endpoints general
formula to be used in the correlation.
b. Three correlations were generated and analysed based on the
published papers.
c. Fine tuning the generated correlations to fit the field of study.
iii) Correlation workflow generation
a. Detail workflow was generated for formulating general relative
permeability correlation.
iv) Field application
a. Formulated correlation was applied and tested in a reservoir in the
field of study to prove concept.
6
1.5 Significance of Study
i) Relative permeability is essential for dynamic simulation to forecast the
reservoir performance more effectively.
ii) The formulated relative permeability correlation can be used in other
reservoirs in the field having limited or no SCAL data.
iii) The generated workflow can be used as a guide for other users in
formulating the correlations in other regions.
7
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