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University of Calgary
PRISM: University of Calgary's Digital Repository
Graduate Studies The Vault: Electronic Theses and Dissertations
2016-01-08
Performance of Steam Assisted Gravity Drainage in
Thin Oil Sand Reservoirs: Well Pair Configuration
Zohrehvand, Shiva
Zohrehvand, S. (2016). Performance of Steam Assisted Gravity Drainage in Thin Oil Sand
Reservoirs: Well Pair Configuration (Unpublished master's thesis). University of Calgary, Calgary,
AB. doi:10.11575/PRISM/27300
http://hdl.handle.net/11023/2737
master thesis
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UNIVERSITY OF CALGARY
Performance of Steam Assisted Gravity Drainage in Thin Oil Sand Reservoirs: Well Pair Configuration
by
Shiva Zohrehvand
A THESIS
SUBMITTED TO THE FACULTY OF GRADUATED STUDIES
IN PARTIAL FULFILMENT OF THE REQUIREMENTS FOR THE
DEGREE OF MASTER OF SCIENCE
GRADUATE PROGRAM IN CHEMICAL AND PETROLEUM ENGINEERING
CALGARY, ALBERTA
January, 2016
© Shiva Zohrehvand 2016
ii
Abstract
Success of Steam Assisted Gravity Drainage (SAGD) depends on reservoir properties and
operational parameters. Here, both areas are targeted and performance of SAGD in thin
oil sand reservoirs with changing the well configuration is studied. Specifically, the
influence of the injection and production wellpair configuration as well as the number of
injector wells in a homogeneous formation with thicknesses of 5, 7, and 10m were
investigated. The wellpairs were relocated to make different patterns where the
spacing between injection and production wells was changed. SAGD performance was
assessed numerically and the cumulative steam oil ratio, oil production, heat loss, and
oil recovery factor were compared. The results suggest that the horizontal and vertical
distances between injectors and the producer well, their locations from over or
underburden and their alignments affect the performance of SAGD operation. The
results also show that addition of an offset injector well can be beneficial.
iii
Acknowledgements
First and for most I am very grateful to my supervisor Dr. Ian Gates. Thank you Ian for
being a great mentor and an incredible human being.
Thank you Dr. Bahareh Khansari for your remarkable comments and great friendship.
Thank you Jacky Wang for the invaluable discussion.
I highly appreciate the financial support of “Werner Graupe” scholarship and Computer
Modeling Group Ltd. (CMG) for providing the reservoir simulator CMG STARSTM.
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To my family
Thank you for your unconditional love and support
v
Table of Contents
Abstract...............................................................................................................................ii Acknowledgments..............................................................................................................iii Dedication..........................................................................................................................iv Table of Contents................................................................................................................v List of Tables.....................................................................................................................viii List of Figures.....................................................................................................................ix List of Symbols, Abbreviations and Nomenclature............................................................xi CHAPTER 1: INTRODUCTION...............................................................................................1
1.1. Statement of the Problem........................................................................................2 1.2. Objectives of the Thesis............................................................................................3 1.3. Research Methodology.............................................................................................3 1.4. Outlines of the Thesis...............................................................................................4
CHAPTER 2: LITERATURE REVIEW.......................................................................................6 2.1. Oil Sands Recourses..................................................................................................6 2.2. Chemistry of Heavy Oil and Bitumen........................................................................9 2.3. EOR Methodologies................................................................................................11
2.3.1. Cyclic Steam Stimulation (CSS)...................................................................13 2.3.2. Steam Flooding (SF)....................................................................................15 2.3.3. In-Situ Combustion (ISC).............................................................................16
2.4. SAGD Process..........................................................................................................17 2.4.1. SAGD Analytical Model (Butler’s Theory)...................................................20 2.4.2. SAGD Variants.............................................................................................22 2.4.3. SAGD Performance.....................................................................................22
2.5. Thin Oil Sands Reservoirs........................................................................................24 2.6. Well Spacing and Configuration..............................................................................26 2.7. What is Missing in the Literature? .........................................................................31 CHAPTER 3: PERFORMANCE OF STEAM ASSISTED GRAVITY DRAINAGE IN THIN OIL
SANDRESERVOIRS: Well-pair Configuration..................................................32 Summary..........................................................................................................................32 3.1. Introduction............................................................................................................32 3.2. Reservoir Simulation Model...................................................................................34 3.3. Reservoir Models....................................................................................................37
3.3.1. Model H10..................................................................................................37 3.3.2. Model H7....................................................................................................40
3.3.3. Model H5....................................................................................................42 3.4. Results and Discussion............................................................................................45
3.4.1. Model H10..................................................................................................45 3.4.1.1. Cumulative Steam-to-Oil Ratio....................................................45 3.4.1.2. Cumulative Produced Oil.............................................................49
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3.4.1.3. Oil Recovery Factor.....................................................................52 3.4.1.4. Cumulative Heat Loss..................................................................54
3.4.2. Model H7....................................................................................................57 3.4.2.1. Cumulative Steam-to-Oil Ratio....................................................57 3.4.2.2. Cumulative Produced Oil.............................................................60 3.4.2.3. Oil Recovery Factor......................................................................62 3.4.2.4. Cumulative Heat Loss..................................................................64
3.4.3. Model H5....................................................................................................66 3.4.3.1. Cumulative Steam-to-Oil Ratio....................................................66 3.4.3.2. Cumulative Produced Oil.............................................................69 3.4.3.3. Oil Recovery Factor......................................................................71 3.4.3.4. Cumulative Heat Loss..................................................................73
3.4.4. Best Case Scenarios....................................................................................76 3.4.4.1. Cumulative Steam-to-Oil Ratio....................................................76
3.4.4.2. Cumulative Produced Oil.............................................................77 3.4.4.3. Oil Recovery Factor.....................................................................78 3.4.4.4. Cumulative Heat Loss..................................................................79 3.4.4.5. Temperature Distributions and Well Pairs Arrangement............81
3.5. Conclusions.............................................................................................................83 CHAPTER 4: PERFORMANCE OF STEAM ASSISTED GRAVITY DRAINAGE IN THIN OIL SANDRESERVOIRS: Well-pair Configuration in a Single Producer-Double
Injector Set up...............................................................................................85 Summary..........................................................................................................................85 4.1. Introduction............................................................................................................86 4.2. Reservoir Simulation Model....................................................................................87 4.3. Reservoir Models....................................................................................................91
4.3.1. Model H10-2Inj...........................................................................................91 4.3.2. Model H7-2Inj.............................................................................................94 4.3.3. Model H5-2Inj.............................................................................................96
4.4. Results and Discussion............................................................................................98 4.4.1. Model H10-2Inj...........................................................................................99
4.4.1.1. Cumulative Steam-to- Oil Ratio...................................................99 4.4.1.2. Cumulative Produced Oil...........................................................101 4.4.1.3. Oil Recovery Factor....................................................................103 4.4.1.4. Cumulative Heat Loss.................................................................105
4.4.2. Model H7-2Inj...........................................................................................107 4.4.2.1. Cumulative Steam-to-oil Ratio...................................................107 4.4.2.2. Cumulative Produced Oil...........................................................109 4.4.2.3. Oil Recovery Factor....................................................................111 4.4.2.4. Cumulative Heat Loss.................................................................113
4.4.3. Model H5-2Inj...........................................................................................114 4.4.3.1. Cumulative Steam-to-Oil Ratio...................................................114 4.4.3.2. Cumulative Produced Oil............................................................116
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4.4.3.3. Oil Recovery Factor....................................................................118 4.4.3.4. Cumulative Heat Loss.................................................................119
4.4.4. Best Cases for the Single Producer-Dual Injector Models.........................120 4.4.5. Best Cases for the Single Injector-Single Producer and
Dual Injector-Single Producer Models....................................................125 4.5. Conclusions...........................................................................................................128 CHAPTER 5: CONCLUDING REMARKS AND RECOMMENDATION....................................130 REFERENCES....................................................................................................................132
viii
List of Tables
Table 2-1 API gravity classification of petroleum oil (API, 2013)................................7 Table 2-2 Screening criteria for choosing an EOR method for an oil resource
(modified from Taber et al. 1997)............................................................12 Table 3-1 Reservoir simulation model and fluid properties......................................35 Table 3-2 Well placement in Model H10 with a layer thickness of 10 m..................38 Table 3-3 Well placement in Model H7 with a layer thickness of 7 m......................41 Table 3-4 Well placement in Model H5 with a layer thickness of 5 m......................43 Table 4-1 Reservoir simulation model and fluid properties......................................89 Table 4-2 Well placement in Model H10-2Inj with a layer thickness of 10 m...........92 Table 4-3 Well placement in Model H7-2Inj with a layer thickness of 7 m...............95 Table 4-4 Well placement in Model H5-2Inj with a layer thickness of 5 m...............97 Table 4-5 Cross-sectional reservoir view and well configuration for best case
scenarios in dual injector-single producer..............................................121 Table 4-6 Cross-sectional reservoir view and well configuration for best case
scenarios in single injector-single producer and dual injector-single producer models.....................................................................................125
ix
List of Figures
Figure 2-1 Schematic representation of oil sand.........................................................8 Figure 2-2 A cartoon representation of asphaltene molecules: (A) the continental
and (B) the archipelago.............................................................................10 Figure 2-3 Schematic representation of Cyclic Steam Stimulation in a vertical well
configuration. ...........................................................................................14 Figure 2-4 Schematic representation of steam flooding technology.........................15 Figure 2-5 Schematic representation of In-Situ Combustion method.......................16 Figure 2-6 Cross-sectional view of the Steam-Assisted Gravity Drainage recovery
process......................................................................................................18 Figure 3-1 Cumulative steam oil ratio versus operation time for Model H10, (A)
aligned (B) not aligned, (C) best case scenarios........................................48 Figure 3-2 Cumulative produced oil versus operation time for Model H10, (A)
aligned (B) not aligned, (C) best case scenarios........................................51 Figure 3-3 Oil recovery factor versus pore volume steam injected (PVSI) for
Model H10, (A) aligned (B) not aligned, (C) best case scenarios...............53 Figure 3-4 Heat loss versus time for Model H10, (A) aligned (B) not aligned,
(C) best case scenarios..............................................................................56 Figure 3-5 Cumulative steam oil ratio (cSOR) versus operation time for Model H7
(A) aligned (B) not aligned, (C) best case scenarios..................................59 Figure 3-6 Cumulative produced oil versus operation time for Model H7,
(A) aligned (B) not aligned, (C) best case scenarios..................................61 Figure 3-7 Oil recovery factor versus pore volume steam injected (PVSI) for
Model H7, (A) aligned (B) not aligned, (C) best case scenarios................63 Figure 3-8 Heat loss versus time for Model H7, (A) aligned (B) not aligned,
(C) best case scenarios..............................................................................65 Figure 3-9 Cumulative steam oil ratio (SOR) versus operation time for Model H5,
(A) aligned (B) not aligned, (C) best case scenarios..................................67 Figure 3-10 Cumulative produced oil versus operation time for Model H5,
(A) aligned (B) not aligned, (C) best case scenarios..................................70 Figure 3-11 Oil recovery factor versus pore volume steam injected (PVSI) for
Model H5, (A) aligned (B) not aligned, (C) best case scenarios................72 Figure 3-12 Heat loss versus time for Model H5, (A) aligned (B) not aligned,
(C) best case scenarios..............................................................................74 Figure 3-13 Steam oil ratio (SOR) versus time for best case scenarios........................76 Figure 3-14 Cumulative produced oil versus operation time for best case Scenarios.78 Figure 3-15 Oil recovery factor versus pore volume steam injected (PVSI) for best
case scenarios ..........................................................................................79 Figure 3-16 Heat loss versus time for best case scenarios...........................................80 Figure 3-17 Heat loss behaviour for best case scenarios.............................................81 Figure 3-18 Wellpair arrangements and temperature distribution for best case
scenarios. (A) H10-6, (B) H7-4, (C) H5-5....................................................82 Figure 4-1 Cumulative steam-to-oil ratio versus time for Model H10-2Inj cases ....101
x
Figure 4-2 Cumulative produced oil versus time for Model H10-2Inj cases ............102 Figure 4-3 Oil recovery factor versus pore volume steam injected for
Model H10-2Inj cases..............................................................................104 Figure 4-4 Heat loss versus time for Model H10-2Inj cases.....................................106 Figure 4-5 Cumulative steam-to-oil ratio versus time for Model H7-2Inj cases......109 Figure 4-6 Cumulative produced oil versus time for Model H7-2Inj cases..............111 Figure 4-7 Oil recovery factor versus pore volume steam injected (PVSI) for
Model H7-2Inj cases...............................................................................112 Figure 4-8 Heat loss versus time for Model H7-2Inj cases.......................................113 Figure 4-9 Cumulative steam-to-oil ratio versus time for Model H5-2Inj cases......116 Figure 4-10 Cumulative produced oil versus time for Model H5-2Inj cases..............117 Figure 4-11 Oil recovery factor versus pore volume steam injected (PVSI) for
Model H5-2Inj cases................................................................................119 Figure 4-12 Heat loss versus time for Model H5-2Inj cases.......................................120 Figure 4-13 cSOR versus time....................................................................................122 Figure 4-14 Cumulative produced oil versus time.....................................................122 Figure 4-15 Oil recovery versus PVSI..........................................................................122 Figure 4-16 Heat loss versus time..............................................................................122 Figure 4-17 cSOR versus time....................................................................................124 Figure 4-18 Cumulative produced oil versus time.....................................................124 Figure 4-19 Oil recovery versus PVSI.........................................................................124 Figure 4-20 Heat loss versus time..............................................................................124 Figure 4-21 cSOR versus time....................................................................................127 Figure 4-22 Cumulative produced oil versus time.....................................................127 Figure 4-23 Oil recovery versus PVSI.........................................................................127 Figure 4-24 Heat loss versus time............................................................................127
xi
List of Symbols, Abbreviations and Nomenclature Symbols Definition
SGoil Specific gravity of the oil Q Oil production rate K Permeability g gravity acceleration ρ Oil density ϴ Inclined angle of the steam interface from horizon µ Oil viscosity ξ Distance from the interface T Temperature Ts Steam temperature Tr Initial reservoir temperature U Velocity of the advancing front Α Reservoir thermal diffusivity Ø Porosity ΔSo (Initial – residual) oil saturation g Gravity acceleration h Reservoir net pay m dimensionless constant νs Oil kinematic viscosity
Abbreviations Definition
API American Petroleum Institute cSOR cumulative Steam-to-Oil Ratio CSS Cyclic Steam Stimulation DWS Downhole Water Sink EOR Enhanced Oil Recovery ES-SAGD Expanding Solvent-Steam Assisted Gravity Drainage HWF Hot Water Flooding ISC In-Situ Combustion OOIP Original Oil In Place SAGD Steam Assisted Gravity Drainage SAGP Steam And Gas Push SF Steam Flooding SOR Steam-to-Oil Ratio VAPEX Vapor Extraction HW Horizontal Well
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CHAPTER 1. INTRODUCTION
SAGD is an effective commercial process for viscous oil recovery from oil sands
reservoirs with pay zone thickness greater than approximately 15 m (Gates, 2010).
However, in thinner oil sands reservoir (< 10 m), heat losses from the steam chamber to
the overburden and understrata are significant and therefore oil recovery will be
achieved at the cost of higher energy consumption or cumulative steam-to-oil ratio
(cSOR) compared to that of thicker reservoirs. This also implies that CO2 emissions per
unit volume oil produced will likely be higher in thinner reservoir than would be the case
from thicker reservoirs. The importance of thin oil sand reservoirs lies in the fact that
about 80% of oil sands resources exist in reservoirs with a net pay zone of less than 5 m
in Western Canada (Adams, 1982). Thus, there is a need for new efficient processes to
produce these resources.
Documented research on the design of recovery processes for thin oil sands reservoirs is
scarce. Zhao et al. (2014) discussed different thermal recovery strategies to produce
from thin (< 5 m) heavy oil reservoirs. They investigated four production methods
consisting of cold production without sand, alternating injection/production well steam
and hot water, steam flooding, and SAGD. They found that first and second processes
are not suitable due to high energy to oil ratio and relatively low recovery factor. Both
steam flooding and SAGD are applicable but they still suffer from large steam use. The
steam cost or cSOR can be reduced by using solvent as was investigated by Gates (2010)
2
and Zhao et al. (2013). These studies focused on heavy oil reservoirs where the in situ
viscosity of the oil is of order of thousands to a few tens of thousands of centipoise.
The focus of the research documented in this thesis is on the application of SAGD in thin
oil sands reservoirs (≤ 10 m) where the viscosity of the oil at original reservoir conditions
is of order of 1 million cP. Since the cost of steam is the major expense of SAGD
operation and main contributor to carbon dioxide emissions from the process, our aim
is the reduction of cSOR through proposing various well configurations to achieve higher
oil production.
1.1. Statement of the Problem
In spite large steam consumption, steam flooding and SAGD are potentially applicable
processes in thin oil sands reservoirs (Zhao et al., 2014). However, reduction of high
steam use per unit oil recovered poses a challenge. It is known that reservoir
parameters as well as operational parameters influence oil recovery and SAGD
performance. For example, decreasing the oil column thickness raises heat losses and
therefore the cSOR increases. In comparison with conventional SAGD, well pair
configuration can be changed through vertical and horizontal positioning as well as
changing the ratio of injector to producer wells. There is potential that different well
configurations may lead to delayed production or faster steam breakthrough thus
ultimately changing and hopefully improving the SOR. There is a need for a detailed
3
study to address these parameters when all other operational and reservoir parameters
kept constant. The main research question being investigated, within the context of
SAGD-like processes, here is how can well configuration be altered to improve the
efficiency and recovery factor in reservoirs that are thinner than 10 m?
1.2. Objectives of the Thesis
The main objective of this thesis is to study the performance of SAGD operation in thin
oil sands reservoir with a thickness of (≤ 10 m). The key issue, as reported in the
literature (Gates 2008; Gates 2010), suggests that the major challenge faced by thermal
(steam) recovery processes for thin reservoirs are heat losses to the overburden and
understrata – that is, the energy efficiency of the process is the key challenge. However,
if the residence time of steam is relatively short in the reservoir, there is potential that
the energy efficiency of the process could be improved by altering the well
configuration including spacing between wells and their vertical locations.
1.3. Research Methodology
The research question has been answered by using detailed thermal reservoir
simulation. In a thermal reservoir simulator, the material and energy balances are
solved by using a numerical method – in this case, the domain is tessellated into grid
4
blocks and the finite volume method is used. In the research documented here, the
commercial thermal reservoir CMG STARSTM was used (CMG, 2013).
In total, 59 cases were studied each having different well configurations in three
reservoir thicknesses: 5, 7, and 10 m. Specifically, 11 single injector-producer well pairs
and 10 double injector-single producer well pairs were evaluated in the case where the
reservoir thickness was equal to 10 m (these cases are referred to as Model H10).
Similarly, in the 7 m reservoir model (referred to as Model H7), 8 numbers of single
injector-producer well pairs and 8 number of double injector-single producer well pairs
were tested. Finally, in the 5 m reservoir model (Model H5), 13 numbers of single
injector-producer well pairs and 9 number of double injector-single producer well pairs
were simulated. For each model, the performance of the recovery process was
evaluated on the basis of its cumulative steam oil ratio, cumulative oil production,
cumulative heat loss, and oil recovery factor.
1.4. Outline of the Thesis
Chapter 1 presents an overview on the thesis including a general introduction,
statement of the problem, objectives, research methodology and the outline.
Chapter 2 provides a general literature review on oil sands and in particular, recovery of
thin oil sands reservoirs. This includes oil sands resources, composition and chemistry.
5
Enhanced Oil Recovery (EOR) methodologies are discussed with a focus on thermal
recoveries. As SAGD is the method of choice for thicker oil sands reservoirs, in this
research work, it is briefly reviewed in Chapter 2 (process description, Butler’s theory,
variants of SAGD, SAGD challenges, and SAGD performance).
Chapters 3 and 4 contain the main research work. Both chapters have been submitted
as two manuscripts to peer-reviewed journals.
Chapter 3 describes the performance of Steam Assisted Gravity Drainage in thin oil sand
reservoirs using single injector-single producer well pair configuration. Specifically, the
influence of the injection and production well pair configuration in a homogeneous
formation with thicknesses of 5, 7, and 10 m was investigated. The wellpairs were
relocated to make different patterns where the spacing between the injection and
production wells were changed both horizontally and vertically. Also their locations with
respect to the overburden and understrata rock were varied.
Chapter 4 presents an analysis of the performance of Steam Assisted Gravity Drainage in
thin oil sand reservoirs using single producer-double injector well arrangement. The
results of this study are compared with the results of best case scenarios in Chapter 3.
Chapter 5 lists concluding remarks and recommendations for further research.
6
CHAPTER 2. LITERATURE REVIEW
2.1. Oil Sands Resources
The oil sands deposits hosted in Western Canada are the third largest proven deposit of
crude oil in the world (Natural Resources of Canada, 2013). Canada, along with
Venezuela holds 90% of the world’s heavy oil and bitumen (Nasr, 2005). The largest
reserves of bitumen are located in the Athabasca, Cold Lake and Peace River oil sands
deposits in Alberta with the average deposit depth of 300, 400, and 500 m, respectively
(Nasr, 2005).
The Athabasca oil sands were first explored by Pond in 1778 and a geological survey was
initiated in 1875 (Govier, 1965). The first wells were drilled between 1897 and 1898 at
Pelican Rapids on the Athabasca River (Govier, 1965). According to the Alberta
Department of Energy (ADOE, 2014), 167.2 billion barrels of proven reserves in the oil
sands deposit exist in Northern Alberta. Nearly 80% are recoverable through in-situ
recovery processes whereas the remainder is shallow enough to be recovered by
surface mining. One of the key uncertainties for oil sands reservoirs is the choice of the
recovery process that will yield the greatest recovery factor and rates at target water
consumption and greenhouse gas emissions. The two most used recovery processes for
oil sands reservoirs are the Cyclic Steam Stimulation (CSS) and Steam-Assisted Gravity
7
Drainage (SAGD) processes (Gates, 2013). Each one of these processes uses different
recovery mechanisms and as a result, the choice of the recovery process itself is a factor
that affects recovery from the reservoir. For example, steam assisted gravity drainage
leads to about 50-60% recovery in comparison with cyclic steam stimulation which reach
to around 35-40% (ADOE, 2014).
Crude oil is classified based on the API gravity, defined by 141.5/SGoil – 131.5 (SGoil is the
specific gravity of the oil), in four major types known as light, medium, heavy, and extra
heavy. The lower the API gravity, the higher the oil viscosity. Table 2-1 lists different
types of crude oil based on API.
Table 2-1 API gravity classification of petroleum oil (API, 2013).
Classification API gravity Viscosity, cP
Light > 31.1 < 10
Medium 22.3 - 31.1 10 - 100
Heavy 10 - 22.3 100 - 10,000
Extra Heavy < 10 > 10,000
Bitumen is categorized as extra heavy oil and has a typical API gravity of 5 to 9 with a
viscosity of > 10,000 cP at room temperature (Speight, 2007). Oil sands are a mixture of
sand, water, clay and bitumen (Kleindienst, 2005). For a typical McMurray Formation oil
8
sands reservoir, the oil sand contains about 83% sand, 14% bitumen and 3% water (Nasr
and Ayodele, 2005). As stated by Speight (1978), a typical composition for Athabasca
bitumen is 84% Carbon, 10% Hydrogen, 0.9% Oxygen, O.4% Nitrogen and 4.7% Sulphur.
Fig. 2-1 illustrates a typical composition of oil sands.
Figure 2-1 Schematic representation of oil sand.
Observations of oil sands grains suggest that the particles are water wet and thus they
are coated by water film which may hold clay particles (Cottrell, 1963) as shown in Fig.
2-1. Bitumen sits within the pore space between the water films. The viscosity of
bitumen depends on temperature and drops significantly as the temperature raises.
Raicar and Proctor (1984) investigated the relationship between viscosity and
temperature for light crude oil, heavy oil, and several bitumens. They showed that the
initial viscosity (at about 10 ⁰C) is highest for Athabasca (106 cP), followed by Cold Lake
9
(105 cP) and Lloydminster (103 cP) deposits and it drops to around 100, 80 and 8 cP,
respectively, at elevated temperature of about 300 ⁰C.
2.2. Chemistry of Heavy Oil and Bitumen
The hydrocarbon components of petroleum can be divided in three classes known as
paraffins (saturated hydrocarbons, no ring structures), naphthenes (saturated
hydrocarbons with one or more rings), and aromatics (hydrocarbons with one or more
aromatic rings) (Speight, 2007). Bitumen is a complicated mixture of hydrocarbons,
consisting of 105 to 106 different molecules (Wiehe, 1999). It is very difficult to
characterize all the components. However, it is possible to classify them in groups of
compounds by utilizing different techniques such as distillation, solubility/insolubility,
and adsorption/desorption (Wiehe, 1999). The most common standard method
applicable to bitumen or heavy oil is to separate them in four general solubility groups
known as saturates, aromatics, resins, and asphaltenes (ASTM, 1999).
The viscosity of petroleum is significantly influenced by the presence and concentration
of asphaltenes. Asphaltene is defined as a fraction of petroleum that is not soluble in
paraffinic solvents, e.g. heptane, but soluble in aromatic solvents. The molecular
structure of bitumen and asphaltenes consists mostly of C-C, C-H, C=C bonds (in the
aromatic rings) and to a lesser degree C-S, C-O, C-N, S-H, and O-H covalent bonds. The
10
metal impurities are mostly attached to nitrogen in porphyrin and non-porphyrin
structures (Rahimi and Thomas, 2006). As a result molecular aggregation occurs.
Generally, two structural models are suggested for asphaltene (Rahimi and Thomas,
2006; Schulze et al., 2015) known as continental and island (archipelago) models.
Representations of these two models are illustrated in Fig. 2-2. In reality the asphaltene
is a combination of these two structures with different percentages. In the continental
model, asphaltenes are composed of large aromatic cores that also contain hetero-
aromatics and metallo-porphyrins. The aromatic cores are surrounded by functional
groups, including alkyl groups and alkyl carboxylic acids (Mullins et al., 2012). In the
archipelago model, smaller aromatic islands are joined together by alkyl chains (Gray et
al., 2011).
Figure 2-2 A cartoon representation of asphaltene molecules: (A) the continental and (B) the archipelago.
11
Due to their high viscosity, heavy oil and bitumen recovery processes require the
application of enhanced oil recovery methods. Under natural conditions, the oil is too
viscous to flow under primary drive mechanisms to the surface.
2.3. EOR Methodologies
Generally, to enable oil production after primary and secondary recovery processes,
enhanced oil recovery methods are applied to a reservoir. In typical practice, EOR is
performed via injection of a fluid into the reservoir to displace the remaining oil in the
reservoir. Displacement can be immiscible or miscible depending on the material
injected into the reservoir. In miscible displacement, the interfacial tension between the
injectant and oil is equal to zero. In immiscible displacement, the injected phase
displaces the oil phase from the reservoir. The overall displacement efficiency is related
to wettability, capillary pressure, interfacial and surface tension forces, and relative
permeability as well as the reservoir heterogeneity and oil to injectant mobility ratio
(Terry, 2001). Another key factor that influences the efficiency of oil displacement from
the reservoir is the physical arrangement of injection and production wells.
Enhanced oil recovery methods can be categorized as miscible, chemical, thermal and
microbial flooding processes (Terry, 2001). This classification is based on the main
mechanism of oil displacement and formation lithology (Kokal and Al-kaabi, 2010).
These oil mobilization mechanisms are known as oil viscosity reduction, solvent oil
extraction, and alteration of wettability. Miscible EOR is applicable to light oil reservoirs
12
through gas injection (e.g. carbon dioxide). Chemical EOR is based on mobility control by
adding polymers to reduce the mobility of the injected water and/or reduction of
interfacial tension through addition of surfactants, and/or alkali. Thermal EOR is
generally suitable for heavy oil and oil sands recovery. Thermal energy increases the oil
temperature leading to oil viscosity reduction in the reservoir. The main thermal EOR
strategies include in-situ combustion and steam injection e.g. steam flooding, steam-
assisted gravity drainage, and cyclic steam stimulation.
The choice of an EOR method depends on various reservoir properties such as depth,
thickness, porosity, permeability, oil saturations, initial hydrocarbon viscosity, density,
and composition (Gates, 2013). Some of the screening criteria for choice of suitable EOR
methods are summarized in Table 2-2 (Taber, 1997). According to Table 2-2, the method
of choice for highly viscous and permeable reservoir is the application of thermal energy
utilizing steam.
Table 2-2 Screening criteria for choosing an EOR method for an oil resource (modified from Taber et al. 1997).
Method Gravity (°API)
Viscosity (cP)
Lithology Net thickness
(ft)
Average permeability
(md)
Depth (ft)
Immiscible gases
> 12 < 600 Not critical Not critical
Not critical > 1,800
Polymer > 15 < 150 Sandstone preferred
Not critical
> 10 < 9,000
Combustion > 10 < 5,000 Highly porous sandstone
> 10 > 50 < 11,500
Steam > 8 < 200,000 Highly porous sandstone
> 20 > 200 < 4500
Surface mining
> 7 Mineable oil sand
> 10 Not critical > 3:1 Overburden/sand
13
Generally, the main aim in recovery of extra heavy oil (bitumen) is the reduction of
viscosity to make it mobile. Thermal methods, as well as solvent aided methods or their
combinations, are considered as good choices. Thermal methods are usually used for oil
recovery in heavy and extra heavy oils (Farouq-Ali, 2003). The main technologies based
on thermal recovery are Cyclic Steam Stimulation (CSS), Steam Flooding (SF), In-Situ
Combustion (ISC), Steam-Assisted Gravity Drainage (SAGD), and Hot Water Flooding
(HWF). The choice of these thermal methods is dependent on the reservoir
characteristics. For example, Mukhametshina et al. (2014) evaluated the recovery
characteristics of bitumen (8.8 API, 53,000 cP at 21 ⁰C) through application of four
thermal recovery methods including SAGD, HWI, SF and ISC. At their specific reservoir
condition, ISC showed the highest recovery factor and HWI the lowest recovery. SAGD
came second but at higher energy cost. SF showed similar results as WF but again at
higher energy consumption. They suggested that a hybrid method consist of HWI and
ISC works best for their particular reservoir.
2.3.1. Cyclic Steam Stimulation (CSS)
CSS method works based on the injection of steam at high pressure and temperature
into a reservoir. In the first step, steam is injected over a period of time into the
reservoir. In some operations, this is done above the fracture pressure and thus steam
fracturing is done in the reservoir (Gates, 2013). In other cases, steam is injected under
the fracture pressure. After the steam injection period is done, the well is shut in and
14
the hot steam zone in the reservoir further distributes its heat to oil sand there – this is
referred to as the soak period. The heated bitumen now has lower viscosity than its
original value, typically in the hottest zones of the reservoir equal to less than 20 cP.
The soak period may take up to 2 weeks. After the soak period is complete, the well is
re-opened for production and reservoir fluids are produced from the reservoir. After
the production rate of oil has dropped to a threshold value, the well is shut in and the
cycle starts again with steam injection. Typical recovery factors for CSS range from 20%
to 40% of the original oil in place (OOIP) with steam-to-oil ratios between 3 and 5
(Gates, 2013; Santos et al., 2014). A schematic representation of three steps in CSS
technology including injection, soak and production is illustrated in Fig. 2-3 in a vertical
well configuration.
Figure 2-3 Schematic representation of Cyclic Steam Stimulation in a vertical well configuration.
15
2.3.2. Steam Flooding (SF)
SF is based on continuous injection of high-pressure steam through a vertical injector
into a reservoir to create a hot zone which moves continuously across the reservoir
displacing oil to production wells. The latent heat of steam is transferred into the oil
zone and decreases the viscosity and thus raises the oil mobility. Steam zone is
expanded and the mobile oil is derived towards a vertical producer. In typical practice,
the oil recovery is about 50% of OOIP (Matthews, 1983; Nasr, 2005). A schematic
representation of SF technology is illustrated in Fig. 2-4.
Figure 2-4 Schematic representation of steam flooding technology.
16
2.3.3. In-Situ Combustion (ISC)
The process was patented in 1923 in USA and it is known as the oldest thermal recovery
method (Breston, 1958). A schematic representation of ISC technology is depicted in Fig.
2-5.
In-situ combustion works based on the oxidation of a small fraction of the reservoir oil.
Then, the combustion zone heats the oil and generates gas that displace the oil towards
the production well (Breston, 1958; Kendall, 2009). Although ISC appears to be an
effective recovery method for conventional as well as bitumen and heavy oil reservoirs
(Dayal et al., 2010), there have been no strong success cases in field operations.
Figure 2-5 Schematic representation of In-Situ Combustion method.
17
In bitumen and heavy oil application, the combustion front must be kept at high
temperature to provide the heat to keep the oil mobilized (Alamatsaz et al., 2011). This
implies that the Air-to-Oil Ratio (AOR) and the injection pressure are critical parameters
for process operation.
2.4. SAGD Process
Butler et al. (1981) combined the idea of bitumen mobilized by steam injection and
gravity drainage with the horizontal wellpair concept for the first time in Alberta in
1979. According to Edmunds and Chhina (2001), the Steam-Assisted Gravity Drainage
(SAGD) concept was used at an earlier time in steam flooding process using vertical
wellpairs in California (Doscher, 1966). The gravity drainage concept is depicted in Fig.
2-6. The main idea behind this method is rising of the injected steam at the bottom of
reservoir to heat up and decrease the oil viscosity. As a result the mobile oil and steam
condensate falls due to gravity and are collected simultaneously at the lower production
well.
In SAGD, a horizontal injection well and parallel horizontal production well is drilled near
the bottom of the reservoir with a certain vertical distance (e.g. 5 m) between them.
Prior to steam injection, the well pair is heated up by steam circulation to establish a
thermal communication between them. Then steam is introduced to the reservoir
18
through upper well and the mobile heavy oil and condensate are produced from the
reservoir through the lower well. A steam chamber develops in the chamber as oil is
drained from it. In the vertical direction, the steam chamber expansion rate is rapid until
it reaches the overburden cap rock. Thereafter, the steam chamber expands sideways
and downwards in the reservoir. At the edge of the chamber, steam loses its latent heat
to the oil sand and the bitumen beyond the edge of the chamber is heated via thermal
conduction.
Figure 2-6 Cross-sectional view of the Steam-Assisted Gravity Drainage recovery process.
19
The size of steam chamber and its uniform growth depend on how well the steam is
distributed within the reservoir and how uniform heat transfer is occurring at the edge
of the steam chamber. Permeability heterogeneity (Gotawala et al., 2010) and wellbore
undulation (Shen, 2011) can lead to a non-uniform steam chamber development in
SAGD.
Heat transfer is a vital element of SAGD. Various studies have been done to pin down
the importance and dominancy of convective and conductive heat transfer at the
interface or edge of SAGD steam chamber. Butler and Stephens (1981) considered
thermal conduction as the main heat transfer mechanism in SAGD operation and
regarded thermal convection as negligible. Further studies performed by Reis (1992),
Liang (2005) and Nukhaev et al. (2006) supported that idea. Farouq-AIi (2005) drew the
attention to the large volume of flowing steam condensate and expressed thermal
convection as dominant heat transfer mechanism. Ito and Suzuki (1996) using numerical
simulation showed that convection is dominant as well. Edmunds (1999) and Ito (1999)
suggested that the ratio of thermal convection to conduction is either less than 5%
(Edmunds, 1999) or around 55% (Ito, 1999), respectively. Sharma and Gates (2011)
showed that thermal convection provides a contribution to heat transfer at the edge of
the steam chamber. However, the increase in the heat-transfer rate by convection may
not necessarily translate to higher oil rates. They explained this behavior by relative
permeability effects at the chamber edge. Irani and Ghannadi (2013) investigated the
relative role of thermal convection in heat transfer through development of a
20
mathematical model by including both convection and conduction heat transfer to solve
the energy balance and pressure-driven condensate flow normal at the edge of SAGD
steam chamber. They concluded that convection can transfer a relatively large amount
of heat at the edge of steam chamber. However, it cannot be translated to high
temperature enhancement and supported the assumption of conduction-dominated
heat transfer. Irani and Gates (2013) spread more light on the subject of heat transfer in
SAGD process and investigated the relative roles of convective heat flux both parallel
and normal to the edge of the steam chamber. They suggested that the convective heat
flux associated with flow parallel to the chamber edge is minor compared with that
normal to the edge.
2.4.1. SAGD Analytical Model (Butler’s Theory)
Butler et al (1981) derived the oil production (drainage) rate equation for the SAGD
process based on the assumption of conductive heat transfer and Darcy’s Law. The final
result was:
𝑞𝑞 = 2�2∅∆𝑆𝑆𝑜𝑜𝑘𝑘𝑘𝑘𝑘𝑘ℎ
𝑚𝑚𝑣𝑣𝑠𝑠
where
21
q = Oil production rate
Ø = Porosity
ΔSo = Difference between Initial and residual oil saturation
K = Permeability
g = Gravity acceleration
α = Reservoir thermal diffusivity
h = Reservoir net pay
m = dimensionless constant, varies between 3 to 5 and depends on the oil
viscosity-temperature relationship
νs = kinematic oil viscosity
The temperature profile beyond the edge of the chamber used to derive this result is as
follows:
𝑇𝑇 − 𝑇𝑇𝑠𝑠𝑇𝑇𝑠𝑠 − 𝑇𝑇𝑟𝑟
= 𝑒𝑒−𝑈𝑈𝑈𝑈𝛼𝛼
where
T = Temperature
Ts = Steam temperature
Tr = Initial reservoir temperature
U = Velocity of the advancing front
ξ = Distance from the interface
α = Reservoir thermal diffusivity
22
Butler’s theory reveals that the oil production rate depends on several reservoir
parameters including the porosity, permeability, net pay thickness, reservoir thermal
diffusivity, bitumen kinematic viscosity and initial oil saturation.
2.4.2. SAGD Variants
One of the drawbacks of SAGD is its high steam consumption and therefore high cost of
steam production as well as higher greenhouse gas emissions (from carbon dioxide
resulting from the combustion of fuel for steam generation). There are several
technologies that have been developed in an attempt to reduce the energy and
environmental intensities of SAGD. These include the Steam And Gas Push (SAGP,
Butler, 1998; Jiang et al., 2000; Ito et al 2001), Expanding Solvent SAGD (ES-SAGD,
Butler, 1998; Nasr, 2005; Gates and Chakrabarty, 2008), and Vapor Extraction (VAPEX,
Butler, 1998) processes. In these three methods, additives are co-injected into the
reservoir with steam. They all use the same well configuration as that of SAGD. These
processes will not be discussed here as they are not the focus of the research
documented in this thesis.
2.4.3. SAGD Performance
The success of SAGD performance depends on the reservoir properties as well as
operational parameters. Reservoir properties include porosity, thickness, gas saturation,
23
permeability, viscosity and API gravity, wettability, heterogeneity, lithology, and geo-
mechanics. Operational parameters include start-up procedure and steam quality,
length, spacing and, placement of horizontal wells, sub-cool temperature or steam trap
control, pressure, steam chamber monitoring and size estimation, and well bore design.
The influence of these parameters has been investigated by various researchers. For
example Albahlani and Babadagli (2008) conducted a review on the influence of both
operational and reservoir properties on SAGD performance.
Sasaki et al. (1999, 2001) performed an experimental investigation with laboratory scale
together with reservoir simulation to study the role of reservoir layer thickness, steam
injection pressure and vertical spacing between SAGD well pair. Das (2005) conducted a
study based on analytical and simulation results and discussed role of well bore design
and operating pressure on SAGD performance and oil recovery rate. He reported that
lower operational pressure causes more challenging lift processes. However, low
pressure works in favour of water treatment at later time due to lower H2S production
and reduction in the amount of dissolved silica.
Carlson (2003) investigated the role of geomechanics and its influence on SAGD
production. Geo-mechanics directly ties with properties such as sampling procedure
(e.g. coring), formation properties (e.g. permeability, porosity, bitumen, water and gas
saturations), shearing and dilation. Therefore, by changing the operational conditions it
is possible to use geo-mechanics in favour of SAGD performance.
24
Su et al. (2012) developed a detailed 3D point bar model to determine the impact of
heterogeneity on SAGD performance in the McMurray Formation in the Long Lake area.
Their results revealed that SAGD orientation within the heterogeneous point bar has an
influence on the performance of SAGD. However, it requires more investigation to find
out specific well pairs arrangement to achieve an optimized cSOR and oil recovery.
Wang and Leung (2015) investigated the effect of lean zones and shale distribution on
the performance of SAGD in typical Athabasca oil sands with a pay zone of 30 m. In
particular, they studied heterogeneous distribution of shale barriers and lean zones
through variation of location, continuity, size, saturation, and proportions.
2.5. Thin Oil Sands Reservoirs
In thin oil reservoirs, in the literature, this is any reservoir that has thickness less than
about 15 m. For example Adams (1982) defined the thickness as < 5 m, whereas Gurgel
et al. (2009) described it as 5 to 15 m, and Feng et al. (2014) as 4 to 10 m and so on. In
this research work we classified a thin oil sands reservoir as any oil sands reservoir with
thickness less than 10 m.
About 80% of oil sand resources exist in reservoirs with a net pay zone of less than 5 m
in Western Canada (Adams, 1982). Thus, there is a need for new efficient processes or
strategies to produce these resources. In spite of potentially large steam consumption,
25
steam flooding and SAGD are potentially applicable processes in thin oil sands reservoirs
(Zhao et al., 2014).
Doscher and El-Arabi (1983) studied a pilot steam injection process in thin oil sands
reservoir (about 5 to 7 m in thickness) in California. They concluded that a higher steam
injection rate at the beginning of the process leads to higher oil recovery due to faster
arrival of the oil bank to producer well. Feng et al. (2014) investigated the parameters
affecting the steam breakthrough in a steam flooding operation in thin layer ultra-heavy
oil reservoirs (viscosity ≥ 50,000 cP) with a thickness of 4 to 10 m. Their results implied
that the formation of a steam breakthrough channel depended on the reservoir
permeability and oil saturation. They suggested that injection of nitrogen foam at initial
stage of steam breakthrough can help the process by hindering the steam breakthrough.
Gates (2010) evaluated the operating conditions of ES-SAGD in thin heavy oil reservoirs
with a thickness of 8 m. Specifically, he used stochastic optimization to determine the
optimal injection pressure and solvent concentration in the injected steam. The results
of the study revealed that these two parameters have an impact on the system energy
efficiency. A comparison between SAGD and ES-SAGD showed that ES-SAGD leads to
lower steam and energy usage than that of SAGD. Furthermore, it was shown that the
performance of an optimized thermal-solvent added process is comparable to VAPEX. It
implies that the injected steam provides sufficient thermal energy to keep the area near
26
the wellpair hot. Thus, solvent remains longer in the vapor phase and leads to
promotion of the oil mobilization process.
Gurgel et al. (2009) studied the influence of operational parameters in steamflooding
process in thin oil reservoirs with a thickness of 5 to 15 m. They concluded that
horizontal permeability, water and oil zone thicknesses, and thermal conductivity have
an influence on cumulative oil production. A reservoir of 5 m height showed a better
response to optimization process (steam injection rate and well distances).
Chang (2013) investigated the application and economics of horizontal well (HW)-CSS
for thin oil sand and heavy oil reservoirs. It was shown that HW-CSS is not economical
for layer thicknesses of 5 to 8 m. While a thickness of 11 m with production duration of
8 years using 8 well pads will be economical.
2.6. Well Spacing and Configuration
Well configuration and spacing or the pattern of SAGD well pairs within the reservoir
can be defined in different ways to achieve different contributions from different drive
mechanisms. Usually, well spacing reflects the distance between SAGD well pairs and is
assumed as repeated within the overall pattern of the SAGD well pairs. The
configuration indicates the vertical and horizontal distances or offsets between the
SAGD wells in each repeat unit. The SAGD well pair configuration can include horizontal,
27
vertical or slanted well arrangements. Here a review is given on the studies that are
conducted on both well pair spacing and configurations and their subsequent influence
on SAGD performance.
Joshi (1986) investigated the SAGD performance through laboratory experiment by
comparing cSOR in vertical and horizontal well configuration. The results showed that
horizontal SAGD gives a better performance. Miller and Xiao (2007) proposed a well
configuration in which vertical wells are drilled in between classical SAGD well pair
spacing in a heavy oil reservoir with a pay thickness of 20 m to improve the production.
They stated through field observation and numerical simulation that vertical production
wells are able to produce the remaining oil not produced by horizontal producer wells
leading to increased oil recovery. Jimenz (2008) performed an analysis on the
performance of SAGD projects in Canada and found out that a inter well pair spacing of
100 m is the most common with the best results with respect to field performance and
that SAGD is mostly applicable to reservoirs with a net pay zone greater than 15 m.
Mojarab et al. (2011) proposed dipping-injector SAGD well configuration for application
in Athabasca and Cold Lake reservoirs with a pay zone thickness of 20 m. Their
simulation results revealed a better performance in comparison with conventional SAGD
through an improvement in thermal efficiency and growth of a more uniform steam
chamber.
28
Cheung (2013) investigated the influence of SAGD well spacing while considering central
processing facility constraints (steam supply and fluid processing capacity). She reported
that the optimal well spacing is around 85 to 125 m with the most economical distance
of 100 m. Verney (2015) investigated the role of well pair length and spacing on SAGD
production through assessment of cSOR, bitumen rate and recovery factor for 1,111
well pairs in the McMurray Formation. Well pair spacing and length were varied in the
range of 40 to 160 m and 400 to 1400 m, respectively. He concluded that well length
does not influence SAGD performance. However, tighter inter-well spacing lead to lower
cSOR and higher recovery factors. Gupta et al. (2015) investigated the impact of well
spacing on SAGD solvent aided processes (SAGD/SAP) using results from a field trial in a
net pay zone of 24 m. Their results confirmed that it is feasible to apply a wider spacing
in SAGD/SAP system in comparison with conventional SAGD. Thus, SAGD/SAP requires
less number of well pairs which in turn reduces the cost, footprint of surface facilities
and the environmental impact.
The well configuration in conventional SAGD consists of a parallel horizontal well pair
which is drilled 5 m apart. Different well configurations have been presented in the
literature to improve SAGD performance. However, there are not many studies
contributed to the bituminous thin oil reservoirs of thickness less than 10 m. Here,
several studies on the SAGD well configuration are reviewed.
29
Tamer and Gates (2012) investigated the impact of position and geometry of the
injector wells in a McMurray Formation reservoir model with properties drawn from the
Dover SAGD Phase B. The reservoir thickness is equal to 24 m. In this study, different
injector well configurations including typical SAGD, offset SAGD and vertical/horizontal
well combination were evaluated. They suggested that a number of vertical injectors
can deliver steam to the reservoir more efficiently than a single horizontal well at early
stages of the process. This is due to smaller exposure of steam chamber to the
overburden. Regarding offset SAGD, they found out that greater offset leads to the
creation of larger steam-chamber volume and therefore higher oil recovery. However,
the initiation of thermal communication between the injection and production wells at
the start of the process revealed to be both challenging and demanding of relatively
large volumes of steam.
Tavallali et al. (2011, 2012) investigated the impact of well configurations for SAGD in
Athabasca McMurray Formation with a net pay thickness of 20 m and in Lloydminster
heavy oil reserve with a net pay thickness of 10 m. The viscosity of the oil in the
Lloydminster reservoir was equal to 5000 cP at the reservoir temperature. According to
Tavallali et al., under certain circumstances, it is possible to increase well spacing
because the lower viscosity allows for establishment of easier thermal communication
between the well pairs in comparison with higher viscosity reservoirs such as those in
the McMurray Formation where the viscosity of the oil is typically above 1 million cP.
Different well configuration including conventional SAGD, vertical injector, reversed
30
horizontal injector, inclined injector, parallel inclined injectors and multi lateral
produced were proposed and studied via numerical simulation for Athabasca reservoirs.
They observed no advantage in using vertical injectors in Athabasca reservoirs – this
contradicts Tamer and Gates’ results and results obtained from field operations (Miller
and Xiao, 2007). The best result was obtained with the application of reversed
horizontal steam injectors. Different well configurations including conventional SAGD,
offset injector, multi lateral producer and ZIGZAC pattern were proposed for thinner
Lloydminster reservoir (Tavallali et al., 2012). Their results revealed that a maximum
offset distance of 12 m leads larger drainage volume but at higher cost of cSOR. The
multi lateral configuration showed the most optimum results with a cSOR of about 5
m3/m3.
Among the conducted studies on the SAGD well pair configuration, it was found that
there are few dedicated to the role of vertical well pair spacing on SAGD performance
especially in case of thin oil sands reservoirs of ≤ 10 m. Sasaki et al. (1999), based on
their laboratory experimental results, concluded that oil production rate increases with
increasing vertical spacing in a conventional SAGD well pair configuration. However, it
comes with the cost of longer lead time for gravity drainage to initiate oil production. In
another study, Sasaki et al. (2001) suggested that the decrease in vertical spacing causes
faster establishment of thermal communication and an increase in spreading rate of
steam and leads to higher amount of oil production.
31
Tavallali et al. (2011) investigated the impact of vertical well distance on SAGD
performance in Athabasca McMurray Formation with a net pay thickness of 20 m. It was
shown that the preheating period is shortened when the distance is less that 5 m
(conventional SAGD) with no significant effect on SAGD performance. The performance
was decreased with increasing the vertical distance. They reported that a distance
within range of 3 to 6 m is desirable with an optimum distance of 4 m.
2.7. What is Missing in the Literature?
The literature review reveals that a large number of studies of the SAGD process has
been conducted to improve its performance by altering the operating strategy and the
well configuration. However, there are none that investigate how well configuration
can be modified to improve the performance of SAGD in thin (less than 10 m) oil sands
reservoirs (reservoirs with oil viscosity of order of a million cP). The research
documented in this thesis fills this gap.
32
CHAPTER 3. PERFORMANCE OF STEAM ASSISTED GRAVITY DRAINAGE IN THIN OIL SAND RESERVOIRS: WELL
CONFIGURATION
Summary
The performance of Steam Assisted Gravity Drainage (SAGD) is studied in thin oil sand
reservoirs. Specifically, the influence of the injection and production well pair
configuration in a homogeneous formation with thicknesses of 5, 7, and 10 m was
investigated. The well pairs were relocated to make different patterns where the
spacing between the injection and production wells were changed both horizontally and
vertically. Also their locations with respect to the overburden and understrata rock were
varied. SAGD performance was assessed numerically via a thermal reservoir simulator
and the cumulative steam oil ratio (cSOR), cumulative oil production, cumulative heat
loss, and oil recovery factor were compared.
3.1. Introduction
SAGD is an effective commercial process for viscous oil recovery from oil sands
reservoirs with a pay zone thickness of greater than approximately 15 m (Gates, 2010).
However, in thin oil sands reservoirs with thickness lower than 10 m, heat losses from
the steam chamber to the overburden and understrata are significant and therefore oil
33
recovery will be achieved at the cost of higher energy consumption or cumulative
steam-to-oil ratio (cSOR) compared to that of thicker reservoirs. This also implies that
carbon dioxide emissions per unit oil produced will likely be higher in thinner reservoir
than would be the case from thicker reservoirs. The importance of thin oil sand
reservoirs lies in the fact that about 80% of oil sand resources exist in reservoirs with a
net pay zone of less than 5 m in Western Canada (Adams, 1982). Thus, there is a need
for new efficient processes to produce these resources.
Zhao et al. (2014) discussed different thermal recovery strategies to produce from thin
(< 5 m) heavy oil reservoirs. They investigated four production methods consisting of
cold production without sand, alternating injection/production well steam and hot
water, steam flooding, and SAGD. They found that first and second processes are not
suitable due to high energy to oil ratio and relatively low recovery factor. Both steam
flooding and SAGD are applicable but they still suffer from large steam use. The steam
cost or cSOR can be reduced by using solvent as was investigated by Gates (2010) and
Zhao et al. (2013). These studies focused on heavy oil reservoirs where the in situ
viscosity of the oil is of order of thousands to a few tens of thousands of centipoise.
The focus of the research documented here is on the application of SAGD in thin oil
sands reservoir (thickness less than 10 m) where the impact of well configuration on
process performance will be investigated. In these reservoirs, the viscosity of the oil at
original reservoir conditions is of order of 1 million cP. Since the cost of steam is the
34
major expense of SAGD operation and main contributor to carbon dioxide emissions
from the process, our aim is the reduction of cSOR with higher oil production.
3.2. Reservoir Simulation Model
The reservoir simulation models used in the research documented here consist of a set
of two-dimensional homogenous model with horizontal well pairs. The reservoirs do
not have gas cap or bottom water zones. Specifically, three reservoir models were
developed with oil sand intervals of 5, 7, and 10 m thickness, respectively labeled as
Model H5, H7, and H10. A regular Cartesian grid system was used to discretize the
models with dimensions of 58 grids with a block size of 0.8 m in the cross well direction,
1 grid block with size of 750 m in the downwell direction. In the vertical direction, there
are 10, 14, and 20 grid blocks in the H5, H7, and H10 models, respectively, all with
dimensions equal to 0.5 m. The reservoir model properties and parameters are shown
in Table 3-1.
Simulations were performed utilizing a commercial thermal reservoir simulator, CMG
STARSTM Version 2013 (CMG, 2013). In this finite volume based thermal reservoir
simulator, the conservation of energy and mass equations are solved over each grid
block together with the phase behavior and relative permeability curves for the gas,
aqueous, and oil phases. At the lateral sides of the model, symmetry boundary
35
conditions were imposed (no flow or heat transfer). In other words, the width of the
reservoir represents the horizontal well spacing and implies that the well pairs are part
of a larger pattern.
Table 3-1 Reservoir simulation model and fluid properties.
Property
Value
Net pay, m 10, 7 and 5 SAGD wellpair length, m 750 Horizontal permeability, mD 4000 Vertical permeability, mD 2000 Average porosity 0.3 Initial oil saturation 0.75 Initial water saturation 0.25 Irreducible water saturation (Swr) 0.15 Residual oil saturation with respect to water 0.20 Relative permeability to oil at irreducible water 1.0 Relative permeability to water at residual oil 0.992 Residual gas saturation (Sgr) 0.005 Residual oil saturation with respect to gas 0.005 Relative permeability to gas at residual oil 1.0 Relative permeability to oil at critical gas Krw at irreducible oil (KRWIRO)
0.992 0.1
Residual oil for gas-liquid table endpoint saturation (SORG) 0.005 Initial temperature, °C 20 Initial pressure, kPa 2000 Rock heat capacity, J/m3 °C 2.600x106 Rock thermal conductivity, J/m day °C 6.600x105 Water phase thermal conductivity, J/m day °C 5.350x104 Oil phase thermal conductivity, J/m day °C 1.150x104 Gas phase thermal conductivity, J/m day °C 5.000x103 Bitumen Molecular weight, kg/kmol Critical temperature, °C Critical pressure, kPa Dead oil viscosity, cP at 10°C 100°C 200°C
465
903.85 792
1587285 203.91
9.71
36
Table 3-1 Reservoir simulation model and fluid properties (continued).
Liquid phase component viscosity (cP) versus temperature curves (methane viscosities are liquid equivalent viscosity) T (°C) µwater µoil µmethane
5 0 4062963.508 115.042 10 0 1587284.565 98.5940 20 0 299536.7897 68.4247 30 0 71948.7369 54.1416 40 0 21109.2585 43.3994 50 0 7318.08492 35.2174 60 0 2918.2885 28.9106 70 0 1309.6336 23.9942 80 0 649.6128 20.1206 90 0 350.9125 17.0377 100 0 203.9087 14.5607 125 0 82.3894 10.9109 150 0 29.6896 7.4943 175 0 17.7130 6.0323 200 0 9.7153 4.5479 225 0 7.1037 3.8631 250 0 4.8898 3.1238
Oil-water relative permeability curves Sw Krw Krow
0.1500 0.0000 0.9920 0.2500 0.0016 0.9500 0.3500 0.0130 0.6000 0.4500 0.0440 0.3500 0.5500 0.1040 0.1650 0.6500 0.2040 0.0700 0.7500 0.3520 0.0150 0.8000 0.4470 0.0000 0.8500 0.5590 0.0000 0.9500 0.8340 0.0000 1.0000 1.0000 0.0000
Gas-liquid relative permeability curves Sl Krg Krog
0.1500 1.0000 0.0000 0.2500 0.8400 0.0016 0.3500 0.6000 0.0130 0.4500 0.3500 0.0440 0.5500 0.1650 0.1040 0.6500 0.0750 0.2040 0.7500 0.0270 0.3520 0.8000 0.0200 0.4470 0.8500 0.0100 0.5590 0.9500 0.0000 0.8340 1.0000 0.0000 0.9920
37
To establish thermal communication between the two wells, as is typical in field
operations, the steam circulation time was set equal to 3 months. In the model, this
was done by placing temporary heaters in the locations of the wells. When SAGD mode
started, the temporary heaters were turned off and steam injection and fluid production
started. The operation was simulated for up to 3 years.
3.3. Reservoir Models
3.3.1. Model H10
The reservoir cross-sectional views and details of well placement for Model H10 with a
single producer and a single injector cases are depicted in Table 3-2. Each well location
is defined by its block number in the horizontal (I, J) and vertical (K) directions as well as
vertical and horizontal distances between the wellpairs. Model H10 was run for 11
different cases to investigate the influence of well configuration on SAGD process
performance. For all cases, producer well is placed in the block 30 in the I-direction.
Cases H10-1 through 7 represents the vertically aligned wellpairs whereas cases H10-8
to 11 are the non-vertically aligned well configurations.
In Cases H10-1 to 4, the producer well is placed at the block 17 in the vertical direction
(1.75 m above the base of the reservoir). The injection well is placed at different block
locations and in alignment with the producer well – the vertical offset between the wells
38
varies from 1 to 6.5 m. In Cases H10-5 to 7, the production well is placed at the block 20
in the vertical direction (0.25 m above the bottom of the reservoir). In the same fashion
as in the previous cases, the position of the injector well is changed vertically.
Cases H10-8 through 11 are the not aligned (in the vertical plane) well pairs. The
production well is placed in block 17 in the vertical direction. The injector well is
positioned at different block locations with a vertical distance varying from 1 to 5 m and
a horizontal distance of 1.6 to 8 m laterally away from the producer well.
Table 3-2 Well placement in Model H10 with a layer thickness of 10 m.
Case Well Grid I
Grid J
Grid K
Vert. Dist. (m)
Horiz. Dist. (m)
Image
H10-1 Prod. 30 1 17 2.5 0
Inj. 30 1 12
H10-2 Prod. 30 1 17 5 0
Inj. 30 1 7
H10-3 Prod. 30 1 17 1 0
Inj. 30 1 15
39
H10-4 Prod. 30 1 17 6 0
Inj. 30 1 5
H10-5 Prod. 30 1 20 2.5 0
Inj. 30 1 15
H10-6 Prod. 30 1 20 5 0
Inj. 30 1 10
H10-7 Prod. 30 1 20 6.5 0
Inj. 30 1 7
H10-8 Prod. 30 1 17 2.5 4
Inj. 35 1 12
H10-9 Prod. 30 1 17 2.5 8
Inj. 40 1 12
40
3.3.2. Model H7
The reservoir cross-sectional views and details of well placement for Model H7 are
illustrated in Table 3-3. Model H7 was run for 8 different cases. Cases H7-1 through 4
represents the vertically aligned wellpairs whereas Cases H7-5 through 8 represents the
non-vertically aligned well configurations. For all cases, the producer well is placed in
the block 30 in I-direction. In cases of H7-1 and 2, the producer well is placed at the
block 11 in the vertical direction (1.75 m above the base of reservoir). In Cases H7-3 and
4 producers well were positioned at the block 14 and 0.25 m above the base of
reservoir. The injection well is placed at different block locations and in alignment with
the producer well – the vertical offset between the wells varies from 1 to 5 m.
In non-vertically aligned Cases H7-5 through 7, the producer well is placed at 1.75 m and
in Case H7-8 at 0.25 m above the base of reservoir. The injector well is positioned at
H10-10 Prod. 30 1 17 1 4
Inj. 35 1 15
H10-11 Prod. 30 1 17 5 1.6
41
different block locations with a vertical distance of 1 to 5m and a horizontal distance
varying from 1.6 to 8 m from the producer well.
Table 3-3 Well placement in Model H7 with a layer thickness of 7 m.
Case Well Grid I
Grid J
Grid K
Vert. Dist. (m)
Horiz. Dist. (m)
Image
H7-1 Prod. 30 1 11
Inj. 30 1 6 2.5 0
H7-2 Prod. 30 1 11
Inj. 30 1 9 1 0
H7-3 Prod. 30 1 14
Inj. 30 1 9 2.5 0
H7-4 Prod. 30 1 14
Inj. 30 1 4 5 0
H7-5 Prod. 30 1 11
Inj. 35 1 6 2.5 4
42
H7-6 Prod. 30 1 11
Inj. 40 1 6 2.5 8
H7-7 Prod. 30 1 11 1 4
Inj. 35 1 9
H7-8 Prod. 30 1 14 5 1.6
Inj. 32 1 4
3.3.3. Model H5
The reservoir cross-sectional views and details of well placement for Model H5 are
shown in Table 3-4. Model H5 was run for 13 cases. Cases H5-1 through 7 indicates the
vertically aligned wellpairs whereas Cases H5-8 through 13 represents the non-vertically
aligned wellpairs. For all cases, the producer well is placed in the block 30 in I-direction.
In Cases H5-1 and 2, the producer well is placed at the block 7 in the vertical direction
(1.75 m above the base of reservoir). In Cases H5-3 and 7, the producer wells were
positioned at the block 10 and 0.25 m above the base of reservoir, respectively. The
injection well is placed at different block locations and in alignment with the producer
well – the vertical offset between the wells varies from 1 to 4.5 m.
43
In non-vertically aligned Cases H5-8 through 10, the producer well is placed at 1.75 m
and in Cases H5-11 to H5-13 at 0.25 m above the base of reservoir. The injector well is
positioned at different block locations with a vertical distance of 0 to 4.5 m and a
horizontal distance varying from 1.6 to 8 m from the producer well.
Table 3-4 Well placements in Model H5 with a layer thickness of 5 m.
Case Well Grid I
Grid J
Grid K
Vert. Dist. (m)
Horiz. Dist. (m)
Image
H5-1 Prod. 30 1 7 2.5 0
Inj. 30 1 2
H5-2 Prod. 30 1 7 1 0
Inj. 30 1 5
H5-3 Prod. 30 1 10 2.5 0
Inj. 30 1 5
H5-4 Prod. 30 1 10 4.5 0
Inj. 30 1 1
44
H5-5 Prod. 30 1 10 4 0
Inj. 30 1 2
H5-6 Prod. 30 1 10 3.5 0
Inj. 30 1 3
H5-7 Prod. 30 1 10 3 0
Inj. 30 1 4
H5-8 Prod. 30 1 7 2.5 4
Inj. 35 1 2
H5-9 Prod. 30 1 7 2.5 8
Inj. 40 1 2
H5-10 Prod. 30 1 7 1 4
Inj. 35 1 5
H5-11 Prod. 30 1 10 4 4
Inj. 35 1 2
45
H5- 12 Prod. 30 1 10 0 4
Inj. 35 1 10
H5-13 Prod. 30 1 10 4 1.6
Inj. 32 1 2
3.4. Results and Discussion
The simulation results are presented here as four main comparisons of the cumulative
SOR versus time, cumulative oil production versus time, oil recovery factor versus pore
volume steam injected (PVSI), and cumulative heat loss as a function of time. In the
following description of the results, whenever a value is given for cumulative SOR it is
recorded at the end of operation time of 900 days unless otherwise is mentioned.
3.4.1. Model H10
3.4.1.1. Cumulative Steam-to-Oil Ratio
Cumulative steam oil ratios (cSOR) for the H10 cases with a layer thickness of 10 m are
shown in Fig. 3-1A through C. The results in Fig. 3-1A represent the vertically aligned
46
wellpairs cases and Fig. 3-1B shows not vertically aligned cases. The best case scenarios
are depicted in Fig. 3-1C.
According to Fig. 3-1A, at a shorter wellpairs distances, regardless of the producer well
location, the cSOR curves show a smaller peak in comparison with those well pairs
located at larger distance from each other (e.g. Cases H10-4 and 7). At shorter vertical
distances, the mobilized oil is found in the vicinity of the injector well. Thus, it requires
shorter time to travel to the producer well. After more time, more steam is needed to
cover the vaster area and the cSOR increases. It appears that the temperature
distribution is affected by the reduced heat transfer rates. In the H10 Cases 1 through 4
(producer well located at 1.75 m above underburden), as the vertical distance between
the wellpairs increases, the cSOR decreases. Case H10-3 has the shortest distance equal
to 1 m whereas Case H10-4 has the longest distance equal to 6 m. In Cases H10-5
through 7, the same trend was observed. Case H10-5 has the shortest distance of 2.5 m
and Case H10-7 has the longest distance of 6.5 m. The wellpairs with the producer well
positioned at an immediate distance from the underburden (0.25 m above) give a lower
cSOR value with an exception of Case H10-5. The cSOR value for Case H10-5 appears
somewhere between Cases H10-1 and 2. The wellpair distance between Case H10-1 and
5 are the same and the only difference is the producer well position.
Also, in Cases H10-4 and 6, in spite of having different well locations and wellpairs
distances, the same cSOR value was observed after about 650 days of operation. There
47
are two parameters that balance each other out: 1. well distance and 2. producer well
location. Therefore, to reduce cSOR, the separation between the well pairs should be
increased to an optimum value around 5 to 6 m or producer well should be moved to
the adjacent block to the understrata. Performing both corrections, as shown by Case
H10-7, the cSOR is reduced further.
Fig. 3-1B shows the not aligned wellpairs. In Cases H10-8 through 11, the producer well
is located at 1.75 m above the understrata. In both Cases H10-8 and 9, the injector wells
are placed at a vertical distance of 2.5 m and a horizontal distance of 4m and 8m,
respectively. The influence of horizontal positioning is compared between Cases H10-1
(with zero horizontal distance, see also Fig. 3-1A), H10-8 and H10-9.
The cSOR values at the end of 3 years of operation are equal to about 4.5, 4.2 and 8.5
m3/m3, respectively, in Cases H10-1, H10-8, and H10-9. Similar to what was observed in
the vertically aligned cases, an optimum horizontal distance is also found to achieve a
lower cSOR. If the distance becomes larger or smaller (zero) than the optimum value,
the cSOR increases. It appears that an increase in the horizontal distance between a well
pairs requires more time for establishment of thermal communication between them.
This is in agreement with Tamer and Gates (2012) and Tavallali et al.’s (2012) work who
observed that larger horizontal offsets delay well production. For our particular
arrangement, the smallest cSOR value was achieved in Case H10-8. In Case H10-10, the
horizontal distance is kept similar to Case H10-8 and the vertical distance between well
pairs is reduced from 2.5 m to 1 m.
48
Figure 3-1 Cumulative steam oil ratio versus operation time for Model H10, (A) aligned (B) not aligned, (C) best case scenarios.
3
4
5
6
7
0 100 200 300 400 500 600 700 800 900 1000
SOR
Cum
ulat
ive
, m3 /
m3
Time, Days
H10-Case 1 H10-Case 2 H10-Case 3 H10-Case 4H10-Case5 H10-Case 6 H10-Case 7
3
4
5
6
7
8
9
0 100 200 300 400 500 600 700 800 900 1000
SOR
Cum
ulat
ive
, m3 /
m3
Time, Days
H10-Case 8 H10-Case 9 H10-Case 10 H10-Case 11
0
1
2
3
4
5
6
7
0 100 200 300 400 500 600 700 800 900 1000
SOR
Cum
ulat
ive,
m3 /
m3
Time, Days
H10-Case 6 H10-Case 7 H10-Case 11
A
B
C
49
The results reveal an increase in cSOR from 4.2 to 5.1 m3/m3. Apparently, the distance
passed an optimum value. The cSOR for Case H10-11 is the same as Case H10-8 (4.1
m3/m3) due to the balancing influences of vertical and horizontal distances on cSOR.
In Fig. 3-1C, the best case scenarios are compared. The cSORs for Cases H10-4, H10-6,
H10-8, and H10-11 are similar and are higher than that of Case H10-7. It can be
concluded that the horizontal and vertical distances between a well pair as well as the
location of producer well affects cSOR and therefore the performance of the SAGD
operation.
3.4.1.2. Cumulative Produced Oil
The cumulative oil production for vertically aligned wellpairs are shown in Fig. 3-2A
followed by not aligned and best case scenarios in Fig. 3-2B and C.
According to Fig. 3-2A, Case H10-6 has the highest cumulative oil production followed
closely by Cases H10-1, H10-2, and H10-5. Case H10-4 produces slightly lower amounts
of oil and Cases H10-7 and H10-3 achieve the lowest amount of oil produced. A
comparison between cumulative oil production amongst the cases taking into account
what was observed in Fig. 3-1A for the cSOR profiles reveals that having a lower cSOR
does not guarantee a higher cumulative oil production volume at the same time.
Therefore there are other parameters at play which should be factored in e.g. delayed
oil production. It is interesting to compare Cases H10-3 and 7 (have the shortest (1 m)
50
and longest (6.5 m) well pairs distances in their group, respectively). Case H10-3
achieves the highest cSOR whereas Case H10-7 realizes the lowest cSOR. Case H10-3
results in higher oil production than that of Case H10-7 after 520 days of operation.
After establishment of the quasi-steady cSOR, the production volumes flip between
these two cases. It confirms again that shorter vertical distances lead to early
simultaneous steam injection/oil production. Our result is in accordance with Butler
(1992) which mentioned if the oil is produced too quickly from the reservoir, then the
steam chamber will be drawn down to the well and bypassing of steam will occur, in
other words, steam trap control is lost. Therefore, more steam is needed to contact the
bitumen located at farther distances from the injector.
Fig. 3-2B illustrates the behavior of the not aligned well pair cases. Sorting the cases
from highest cumulative produced oil to the lowest volume achieved (almost no
production) leads to the sequence of Cases H10-11, H10-8, H10-10, and H10-9. A
comparison between similar cases and their cSOR confirms that at lower cSOR, higher
cumulative oil production can be expected. However, Cases H10-8 and 11 have similar
cSORs in spite of having different cumulative oil production. Cases H10-6 and 11
achieve different cumulative oil production, in spite of having similar cSOR. The only
difference between these two cases is the horizontal distance of 1.6 m that appears to
cause a slight delay in oil production. Case H10-7 realizes the lowest cSOR with the
lowest oil production. This behavior will be discussed further in the following section
where the oil recovery factor is measured based on pore volume of steam injected
(PVSI).
51
Figure 3-2 Cumulative produced oil versus operation time for Model H10, (A) aligned (B) not aligned, (C) best case scenarios.
0
10000
20000
30000
40000
50000
0 100 200 300 400 500 600 700 800 900 1000
Cum
ulat
ive
Oil
Prod
uctio
n, m
3
Time, Days
H10-Case 1 H10-Case 2H10-Case 3 H10-Case 4H10-Case 5 H10-Case 6H10-Case 7
0
10000
20000
30000
40000
50000
0 100 200 300 400 500 600 700 800 900 1000Cum
ulat
ive
Oil
Prod
uctio
n, m
3
Time, Days
H10-Case 8 H10-Case9 H10-Case 10 H10-Case 11
0
10000
20000
30000
40000
50000
0 100 200 300 400 500 600 700 800 900 1000Cum
ulat
ive
Oil
Prod
uctio
n, m
3
Time, Days
H10-Case 6 H10-Case 7H10-Case 11
A
B
C
52
Fig. 3-2B illustrates the behavior of the not aligned well pair cases. Sorting the cases
from highest cumulative produced oil to the lowest volume achieved (almost no
production) leads to the sequence of Cases H10-11, H10-8, H10-10, and H10-9. A
comparison between similar cases and their cSOR confirms that at lower cSOR, higher
cumulative oil production can be expected. However, Cases H10-8 and 11 have similar
cSORs in spite of having different cumulative oil production. Cases H10-6 and 11
achieve different cumulative oil production, in spite of having similar cSOR. The only
difference between these two cases is the horizontal distance of 1.6 m that appears to
cause a slight delay in oil production. Case H10-7 realizes the lowest cSOR with the
lowest oil production. This behavior will be discussed further in the following section
where the oil recovery factor is measured based on pore volume of steam injected
(PVSI).
3.4.1.3. Oil Recovery Factor
The results are shown in Fig. 3-3A (vertically aligned wellpairs), Fig. 3-3B (not vertically
aligned), and Fig. 3-3C for the best case scenarios. The recovery factor was measured as
a function of the pore volumes of steam injected (PVSI, expressed as cold water
equivalent) to compare the different cases. In Fig. 3-3A, the order of recovery factor
after 900 days of operation from highest to lowest is Cases H10-6, H10-2, H10-5, H10-1,
H10-7, H10-3, and H10-4.
53
Figure 3-3 Oil recovery factor versus pore volume steam injected (PVSI) for Model H10, (A) aligned (B) not aligned, (C) best case scenarios.
0
10
20
30
40
50
60
0 0.5 1 1.5 2
Oil
Reco
very
Fac
tor
PVSI
H10-Case 1 H10-Case 2 H10-Case 3H10-Case 4 H10-Case 5 H10-Case 6H10-Case 7
0
10
20
30
40
50
60
0 0.5 1 1.5 2
Oil
Reco
very
Fac
tor
PVSI
H10-Case 8 H10-Case 9 H10-Case 10 H10-Case 11
0
10
20
30
40
50
60
0 0.5 1 1.5 2
Oil
Reco
very
Fac
tor
PVSI
H10-Case 6 H10-Case 7 H10-Case 11
A
B
C
54
Case H10-6 achieves the highest recovery factor whereas Case H10-4, in which the
injector well is positioned closest to overburden, has the lowest oil recovery of the
vertically aligned cases. The recovery factor in Cases H10-5 and H10-1 is almost the
same as that of H10-2 (about 58%) but at a cost of a greater PVSI as shown in Fig. 3-1A
(the cSOR profile).
3.4.1.4. Cumulative Heat Loss
The cumulative heat loss profiles are presented in Fig. 3-4A (vertically aligned well
pairs), Fig. 3-4B (not vertically aligned well pairs), and Fig. 3-4C for the best case
scenarios. The order of heat loss is from the lowest to the highest H10-3, H10-7, H10-4,
H10-5, H10-6, H10-2, and H10-1 as shown in Fig. 3-4A. Therefore, Case H10-1 has the
highest and H10-3 shows the lowest heat loss in the vertically aligned cases. A
comparison of Cases H10-1 through H10-4, where the producer well is at the same
position, reveals that Case H10-3 exhibits the lowest heat loss – this case has the
injector well farthest from the surface. Case H10-4 has the injector well closest to
surface but it does not achieve the largest heat losses of the cases. In Cases H10-2 and
H10-1 the injector wells are located even farther from the overburden but not far
enough in comparison with Case H10-3. Thus, the heat loss increases further.
Our results show that the heat loss is not the only and main issue with respect to oil
production as in this particular case the lowest cumulative oil production was observed
(see Fig. 3-2A). Further, Case H10-3 showed the lowest cSOR (Fig. 3-1A).
55
In cases H10-5 through H10-7, H10-5 has the lowest heat loss and H10-6 the highest
heat loss.
For the not aligned well pair cases, the order with respect to heat losses from the lowest
to the highest is H10-9, H10-10, H10-8, and H10-11 (Fig. 3-4B).
According to Fig. 3-4C, the order with respect to heat losses from the highest to the
lowest is H10-3, H10-10, and H10-9. The not vertically aligned cases lead to lowest heat
losses due to delayed oil production.
The same trend in choosing the particular cases (H10-6, H10-7 and H10-11) as was
observed in the best case scenarios for cSOR, cumulative oil production and recovery
factor did not appear here. It seems that a higher oil production is achieved at higher
energy loss. A comparison between the heat losses for Cases H10-6, H10-7 and H10-11
indicates that Case H10-6 shows the highest heat loss whereas the lowest is found in
Case H10-7. In both cases, the well pairs are located with the producer well located 0.25
m above the underburden. The only difference is the position of injector well and its
distance from the producer. Although, the same trend as in cSOR (see Fig. 3-1C) is
observed, the results suggest that lower cSOR means lower heat loss. However, this
conclusion cannot be extended to all cases.
It can be concluded that to increase oil production from thin oil sand reservoirs, it is
necessary to find an optimum vertical separation and horizontal distance the injection
and production well in addition to the position of the production well.
56
Figure 3-4 Heat loss versus time for Model H10, (A) aligned (B) not aligned, (C) best case scenarios.
-2E+14
-1.5E+14
-1E+14
-5E+13
0
0 100 200 300 400 500 600 700 800 900 1000
Heat
Los
s Cu
m ,
J
Time, Days
H10-Case 1 H10-Case 2 H10-Case 3H10-Case 4 H10-Case 5 H10-Case 6H10-Case 7
-2E+14
-1.5E+14
-1E+14
-5E+13
0
0 100 200 300 400 500 600 700 800 900 1000
Heat
Los
s Cu
m ,
J
Time, Days
H10-Case 8 H10-Case 9 H10-Case 10 H10-Case 11
-1.5E+14
-1E+14
-5E+13
0
0 100 200 300 400 500 600 700 800 900 1000
Heat
Los
s Cu
m ,
J
Time, Days
H10-Case 9 H10-Case 3 H10-Case 10
A
B
C
57
The results show that position and lateral spacing between the well pair can yield lower
heat losses, lower cSOR, and higher cumulative oil produced (as well as the onset of oil
production).
The priority with respect to the commercial operation of an oil recovery process can
vary by operator – for one it may be operational costs which is reflected by the cSOR
and heat losses or it may be income and cash flow which is reflected by a combination
of the cSOR (represents ratio of cost to revenue) and the cumulative produced oil
(which reflects the oil rate which is what sets revenues). Thus, the results can be
interpreted for an oil recovery operation by deciding what is the most important factors
for the operation.
3.4.2. Model H7
3.4.2.1. Cumulative Steam-to-Oil Ratio
The cumulative steam-to-oil ratios (cSORs) for Model H7 (oil column thickness of 7 m)
are shown in Fig. 3-5A through 3-5C. Similar to the results presented for Model H10, Fig.
3-5A and Fig. 3-5B show the results of the vertically aligned and not aligned cases,
respectively. The best case scenarios are depicted in Fig. 3-5C.
58
According to Fig. 3-5A, Cases H7-3 and H7-4, where the producer well is positioned at
immediate distance from the understrata (0.25 m above), gives a lower cSOR compared
to the results of Cases H7-1 and H7-2 (producer well located 1.75 m above understrata).
In Model H10, it was shown that having an optimum distance (vertically as well as
horizontally) between the injection and production wells lead to lower cSOR. Similarly,
for the H7 cases, Case H7-4 has the lowest cSOR (well separation equal to 5 m) whereas
Case H7-1 achieves the highest cSOR (with separation of 1 m).
In Fig. 3-5B, similar to H10 model, the cSOR for Case H7-6 is higher than that of Case H7-
5 due to having a horizontal well pair distance beyond the optimum value. Case H7-5
has lower cSOR compared to Case H7-7 due to shorter vertical separation between the
wells. Finally, for the not aligned cases, Case H7-8 exhibits the lowest cSOR which is in
agreement with the results of Model 10.
Apparently, for the not aligned cases, Case H7-8 realizes the optimum vertical and
horizontal distance. For this case, the producer well is located adjacent to the
understrata.
In Fig. 3-5C, the best case scenarios are compared together. Cases H7-4 and H7-8 realize
the lowest cSORs in the vertically aligned and not aligned cases, respectively, as
depicted in Fig. 3-5A and B. The cSOR profiles are very similar for these two cases. The
only difference between these two well arrangements is a horizontal distance of 1.6m
which did not lead to a significant change of the cSOR. Case H7-3 reveals slightly higher
cSOR due to a shorter vertical separation distance of 2.5 m.
59
Figure 3-5 Cumulative steam oil ratio (cSOR) versus operation time for Model H7 (A) aligned (B) not aligned, (C) best case scenarios.
3
4
5
6
0 100 200 300 400 500 600 700 800 900 1000
SOR
Cum
ulat
ive,
m3 /
m3
Time, Days
H7-Case 1 H7-Case 2 H7-Case3 H7-Case 4
3
4
5
6
7
8
0 100 200 300 400 500 600 700 800 900 1000
SOR
Cum
ulat
ive,
m3 /
m3
Time, Days
H7-Case 5 H7-Case 6 H7-Case 7 H7-Case 8
0
1
2
3
4
5
6
0 100 200 300 400 500 600 700 800 900 1000
SOR
Cum
ulat
ive,
m3 /
m3
Time, Days
H7-Case 3 H7-Case 4 H7-Case 8
A
B
C
60
3.4.2.2. Cumulative Produced Oil
The cumulative oil production profiles for the vertically aligned well, not vertically
aligned well, and best cases are shown in Fig. 3-6A, B, and C, respectively. The results in
Fig. 3-6A reveal that Cases H7-3 and H7-4 have the highest cumulative oil production
followed closely by Case H7-1. Case H7-2 shows the lowest oil production volume of this
group. A comparison between cumulative oil production cases and cSOR profiles
(shown in Fig. 3-6A) confirms that lower cSOR does not necessarily mean a higher
cumulative oil production.
Fig. 3-6B illustrates the behavior of the not aligned well cases from highest oil
production volume to the lowest as H7-8, H7-5, H7-7, and H7-6.
A comparison between Fig. 3-6B and the related cSOR profiles in Fig. 3-5B shows that at
a lower cSOR, a higher cumulative oil production is achieved.
According to Fig. 3-6C, the difference in the volume of oil produced between Cases H7-3
and H7-4 is not significant and it is slightly more than Case H7-8. However, a comparison
between their cSOR profiles (see Fig. 3-5C) shows that Cases H7-4 and H7-8 have similar
cSOR although it is slightly lower than Case H7-3.
61
Figure 3-6 Cumulative produced oil versus operation time for Model H7, (A) aligned (B) not aligned, (C) best case scenarios.
0
5000
10000
15000
20000
25000
30000
35000
0 100 200 300 400 500 600 700 800 900 1000
Cum
ulat
ive
Oil
Prod
uctio
n, m
3
Time, Days
H7-Case 1 H7-Case 2H7-Case 3 H7-Case 4
0
5000
10000
15000
20000
25000
30000
35000
0 100 200 300 400 500 600 700 800 900 1000
Cum
ulat
ive
Oil
Prod
uctio
n, m
3
Time, Days
H7-Case 5H7-Case 6H7-Case 7H7-Case 8
0
5000
10000
15000
20000
25000
30000
35000
0 100 200 300 400 500 600 700 800 900 1000
Cum
ulat
ive
Oil
Prod
uctio
n, m
3
Time, Days
H7-Case 3 H7-Case 4 H7-Case 8
A
B
C
62
3.4.2.3. Oil Recovery Factor
The oil recovery profiles are shown in Fig. 3-7A (vertically aligned wellpairs), Fig. 3-7B
(not vertically aligned), and Fig. 3-7C for the best case scenarios. In Fig. 3-7A, the
recovery factor profiles are presented – the order of recovery factor from the lowest
recovery factor to the highest recovery factor are Cases H7-2, H7-1, and H7-4, and H7-3
for the vertically aligned cases. For the not aligned well cases, the order of recovery
factor from the lowest recovery factor to the highest recovery factor are Cases H7-6, H7-
7, H7-5, and H7-8.
Based on the results shown in Fig. 3-7C, Cases H7-4 and H7-8 have the highest oil
recovery factor with results slightly higher than was achieved by Case H7-3. This result
agrees with their cSOR trends shown in Fig. 3-5C. The results show that the recovery
factors achieved are in excess of 50% after about 1.75 pore volumes of steam injected
(PVSI, expressed as cold water equivalent) into the reservoir.
63
Figure 3-7 Oil recovery factor versus pore volume steam injected (PVSI) for Model H7, (A) aligned (B) not aligned, (C) best case scenarios.
0
10
20
30
40
50
60
0 0.5 1 1.5 2 2.5
Oil
Reco
very
Fac
tor
PVSI
H7-Case 1 H7-Case 2 H7-Case 3 H7-Case 4
0
10
20
30
40
50
60
0 0.5 1 1.5 2 2.5
Oil
Reco
very
Fac
tor
PVSI
H7-Case 5 H7-Case 6 H7-Case 7 H7-Case 8
0
10
20
30
40
50
60
0 0.5 1 1.5 2 2.5
Oil
Reco
very
Fac
tor
PVSI
H7-Case 3 H7-Case 4 H7-Case 8
A
B
C
64
3.4.2.4. Cumulative Heat Loss
Cumulative heat losses are shown in Fig. 3-8A (vertically aligned) and Fig. 3-8B (not
vertically aligned). For the aligned cases, the order of heat loss from the lowest case to
the highest is H7-2, H7-1, H7-4, and H7-3. For the not aligned cases, the order is H7-6,
H7-7, H7-5, and H7-8. A comparison between these two figures shows that, except in
H7-2, the aligned scenarios generate more heat loss than that of not aligned ones. The
highest heat loss appears when the well pair has a vertical separation of 2.5 m. An
increase of the separation to 5 m reduces the heat loss and a horizontal separation of
1.6 m reduces the heat loss further. The behavior of Cases H7-3 and H7-4 are very
similar. With the exception of the PVSI, the results of cSOR, cumulative oil production,
oil recovery factor, and heat losses during the SAGD operation are similar for these two
cases. The well configuration of Case H7-4 experiences delayed oil production and
requires more steam to achieve the same oil recovery factor as that of H7-3.
Fig. 3-8C indicates the best case scenarios with apparently lowest heat losses. The
order of heat loss from the lowest case to the highest is H7-6, H7-7, H7-5, and H7-2.
So far, it was shown that Cases H7-3, H7-4, and H7-8 present best case scenarios in
Model H7 that lead to lower cSOR, higher cumulative oil production and the highest oil
recovery factors. However, the same trend was not revealed in heat loss of the best
case scenarios. On the contrary, these well configurations show the worst heat losses.
65
Figure 3-8 Heat loss versus time for Model H7, (A) aligned (B) not aligned, (C) best case scenarios.
-2E+14
-1.5E+14
-1E+14
-5E+13
0
0 100 200 300 400 500 600 700 800 900 1000
Heat
Los
s Cu
m, J
Time, Days
H7-Case 1 H7-Case 2 H7-Case 3 H7-Case 4
-2E+14
-1.5E+14
-1E+14
-5E+13
0
0 100 200 300 400 500 600 700 800 900 1000
Heat
Los
s Cu
m, J
Time, Days
H7-Case 5 H7-Case 6 H7-Case 7 H7-Case 8
-2E+14
-1.5E+14
-1E+14
-5E+13
0
0 100 200 300 400 500 600 700 800 900 1000
Heat
Los
s Cu
m, J
Time, Days
H7-Case 2 H7-Case 5 H7-Case 6 H7-Case 7
A
B
C
66
As it was mentioned in Model H10, choosing the best case scenarios are depended on
what is the most important factors for the operation.
3.4.3. Model H5
3.4.3.1. Cumulative Steam-to-Oil Ratio
The cumulative steam-to-oil ratios (cSORs) for Model H5 (oil column 5 m thick) are
shown in Fig. 3-9A through 3-9C. Similar to the previous H10 and H7 models, Fig. 3-9A
and Fig. 3-9B represent the vertically aligned and not aligned cases, respectively. The
best case scenarios are depicted in Fig. 3-9C. According to Fig. 3-9A, Cases H5-1 and H5-
2 with the producer well positioned at 1.75 m above the understrata give higher cSORs
compared to Cases H5-3 to H5-7 (producer well located at 0.25 m above understrata).
Similar results were observed for Models H10 and H7. Therefore, positioning the
producer well at an immediate distance from the understrata will lower the cSOR.
Considering Cases H5-3 to H5-7, the vertical distance is the shortest in Case H5-3 (2.5 m)
and longest in Case H5-4 (4.5 m). The cSOR values given in Fig. 3-9A confirm that Case
H5-3 has the highest cSOR (7.4 m3/m3) and H5-4 (7.2 m3/m3) has the lowest cSOR.
The influence of horizontal positioning is shown in Fig. 3-9B. The trend is somewhat
different as was observed in Models H10 and H7. The horizontal wellpairs separation
for Cases H5-8 and H5-9 are 3.2 m and 8 m, respectively.
67
Figure 3-9 Cumulative steam oil ratio (SOR) versus operation time for Model H5, (A) aligned (B) not aligned, (C) best case scenarios.
3
4
5
6
7
8
0 100 200 300 400 500 600 700 800 900 1000
SOR
Cum
ulat
ive
, m3 /
m3
Time, Days
H5-Case 1 H5-Case 2H5-Case3 H5-Case 4H5-Case 5 H5-Case 6H5-Case 7
7
7.1
7.2
7.3
7.4
850 900
3
4
5
6
7
8
0 100 200 300 400 500 600 700 800 900 1000
SOR
Cum
ulat
ive,
m3 /
m3
Time, Days
H5-Case 8 H5-Case9 H5-Case 10H5-Case 11 H5-Case 12 H5-Case 13
3
4
5
6
7
8
0 100 200 300 400 500 600 700 800 900 1000
SOR
Cum
ulat
ive,
m3 /
m3
Time, Days
H5-Case4 H5-Case 5 H5-Case 11 H5-Case 13
A
B
C
68
In comparison with Models H10 and H7, a higher cSOR is expected for greater
separations, but on the contrary, Case H5-9 shows lower cSOR (6.9 m3/m3) than that of
Case H5-8 (7.5 m3/m3). In the case where the horizontal distance is zero (Case H5-1),
the cSOR is even larger (7.8 m3/m3).
As the horizontal separation between the wells reduce (e.g. examine results of Cases
H5-1, H5-13, and H5-11), the cSOR increases regardless of the producer well elevation
above the understrata.
A cSOR of 6.7 m3/m3 is achieved for Case H5-10 in which the vertical distance is 1 m. In
models H10 and H7, this particular well pair configuration showed slightly higher cSOR
than the corresponding case with horizontal distance of 3.2 m. The lowest cSOR (6.2
m3/m3) is observed for Case H5-12.
In Fig. 3-9C, the best case scenarios are compared together. Case H7-11 shows the
lowest cSOR (6.7 m3/m3) and Cases H7-4 and 5 realize the highest cSOR (7.2 m3/m3).
Except for Case H5-11 (has a larger horizontal distance), the rest of the H5
configurations led to similar cSOR.
69
3.4.3.2. Cumulative Produced Oil
The cumulative oil production profiles for the vertically aligned wellpairs cases are
shown in Fig. 3-10A followed by the not aligned and best case scenarios in Fig. 3-10B
and 3-10C.
Cases H5-3 to H5-7, shown in Fig. 3-10A, exhibit similar cumulative oil production. This
result is expected since the producer well in both Cases H5-1 and H5-2 is positioned at
1.75 m above the understrata. The remaining cases have their producer well 0.25 m
above the understrata.
The change of the vertical separation of the wells did not have a significant influence on
the cumulative oil production. A comparison between cumulative oil production for
different cases in Fig. 3-10A and their related cSOR in Fig. 3-9A confirms that a
significant change appears only when the producer well position is altered.
Fig. 3-10B illustrates the behavior of not aligned wellpairs. A comparison between Fig. 3-
10B and related cSOR profiles presented in Fig. 3-9B reveals that lower cSOR does not
imply a higher cumulative oil production necessarily. The H5 model follows the same
trend as that exhibited in Models H10 and H7 – they present a decrease of the
cumulative oil production as a result of reduction in horizontal separation between the
wells.
70
Figure 3-10 Cumulative produced oil versus operation time for Model H5, (A) aligned (B) not aligned, (C) best case scenarios.
0
5000
10000
15000
20000
25000
0 100 200 300 400 500 600 700 800 900 1000Cum
ulat
ive
Oil
Prod
uctio
n, m
3
Time, Days
H5-Case 1 H5-Case2H5-Case 3 H5-Case 4H5-Case5 H5-Case6H5-Case 7
20000
21000
850 900
0
5000
10000
15000
20000
25000
0 100 200 300 400 500 600 700 800 900 1000
Cum
ulat
ive
Oil
Prod
uctio
n, m
3
Time, Days
H5-Case 8 H5-Case 9H5-Case 10 H5-Case 11H5-Case 12 H10-Case 13
0
5000
10000
15000
20000
25000
0 100 200 300 400 500 600 700 800 900 1000
Cum
ulat
ive
Oil
Prod
uctio
n, m
3
Time, Days
H5-Case 4 H5-Case 5H5-Case 11 H5-Case 13
A
B
C
71
In spite of having the lowest cSOR (6.7 m3/m3), the well configuration of Case H5-11
performed poorly in comparison with the rest and the oil production was delayed
significantly. A comparison between H5-case 2 (7.9 m3/m3, the highest cSOR) and H5-
case 10 (6.9 m3/m3) reveals that an increase of the horizontal distance from zero to 4 m
between the injection and production wells led to a lowering of the cSOR.
3.4.3.3. Oil Recovery Factor
The oil recovery factor profiles are shown in Fig. 3-11A (vertically aligned), Fig. 3-11B
(not vertically aligned), and Fig. 3-11C for the best case scenarios.
Roughly, the different cases divided themselves in two groups of oil recovery factors for
the vertically-aligned cases as shown in Fig. 3-11A. This is based on the elevation of the
producer well – the greater the distance between the producer well and the
understrata, the lower the recovery factor.
The not vertically aligned cases are depicted in Fig. 3-11B. The results of Cases H5-9 and
H5-12 yielded lower cSOR, but they produced negligible volumes of oil due to length of
time it took to establish thermal communication between the wells. For other cases,
the recovery factor patterns are similar to the analogous cases of the H10 and H7
models.
72
Figure 3-11 Oil recovery factor versus pore volume steam injected (PVSI) for Model H5, (A) aligned (B) not aligned, (C) best case scenarios.
0
10
20
30
40
50
60
0 0.5 1 1.5 2 2.5 3
Oil
Reco
very
Fac
tor
PVSI
H5-Case 1 H5-Case 2H5-Case 3 H5-Case 4H5-Case 5 H5-Case 6H5-Case 7
52.5
53.5
2.75 2.8
0
10
20
30
40
50
60
0 0.5 1 1.5 2 2.5 3
Oil
Reco
very
Fac
tor
PVSI
H5-Case 8 H5-Case 9 H5-Case 10H5-Case 11 H5-Case 12 H5-Case 13
0
10
20
30
40
50
60
0 0.5 1 1.5 2 2.5 3
Oil
Reco
very
Fac
tor
PVSI
H5-Case 4 H5-Case 5H5-Case 11 H5-Case 13
47
48
49
2.3 2.4
A
B
C
73
The vertically aligned cases produced at higher recovery factors but at cost of higher
PVSI. The oil recovery factors varied between 53 and 54% at a PVSI of about 2.8.
According to Fig. 3-11C, the recovery factors for different cases, with the exception of
Case H5-11 (larger horizontal separation between the injection and production well) are
very comparable.
3.4.3.4. Cumulative Heat Loss
The profiles of the cumulative heat losses are shown in Fig. 3-12A (vertically aligned),
Fig. 3-12B (not vertically aligned), and Fig. 3-12C for the best case scenarios.
For the vertically aligned well configurations, the order of the cases with respect to heat
loss from the lowest to the highest heat loss are Cases H5-2, H5-1, H5-4, H5-5, and H5-3,
H5-6, and H5-7. However, the difference in heat losses for cases H5-3 to 7 is small.
Therefore, changing the vertical well separation from 2.5 to 4.5 m did not play a
substantial role with respect to SAGD heat loss performance. In Case H5-2, the wellpairs
is located near the middle of the reservoir. This arrangement offers the shortest vertical
distance and led to the lowest oil production and recovery factor due to insufficient
vertical well pair separation and delayed temperature distribution. Case H5-4 presents
the longest vertical well pair separation (both wells are practically positioned adjacent
to the rock bounding the reservoir).
74
Figure 3-12 Heat loss versus time for Model H5, (A) aligned (B) not aligned, (C) best case scenarios.
-2E+14
-1.5E+14
-1E+14
-5E+13
0
0 100 200 300 400 500 600 700 800 900 1000
Heat
Los
s Cu
m ,
J
Time, Days
H5-Case 1 H5-Case 2H5-Case 3 H5-Case 4H5-Case 5 H5-Case 6H5-Case 7
-1.8E+14
-1.7E+14
880 890 900
-2E+14
-1.5E+14
-1E+14
-5E+13
0
0 100 200 300 400 500 600 700 800 900 1000
Heat
Los
s Cu
m ,
J
Time, Days
H5-Case 8 H5-Case 9 H5-Case 10H5-Case 11 H5-Case 12 H5-Case 13
-2E+14
-1.5E+14
-1E+14
-5E+13
0
0 100 200 300 400 500 600 700 800 900 1000
Heat
Los
s Cu
m ,
J
Time, Days
H5-Case 9 H5-Case 10 H5-Case 11 H5-Case 12
A
B
C
75
The change of heat loss is not significant compared to the other cases (Cases H5-3, 5, 6
and 7). The temperature profile showed a better distribution in comparison with H5-2
but at cost of higher heat loss.
In Fig. 3-12B, a change of the horizontal separation between the wells has profound
effects on SAGD performance since it delays oil production significantly.
According to Fig. 3-12C, the order with respect to heat losses from the highest to the
lowest is Cases H5-11, H5-10, H5-9 and H5-12. Similar with what observed in the
previous models, not vertically aligned cases lead to lowest heat loss.
Similar to previous models, the same trend in choosing the best cases scenarios (here:
H5-4, H5-5, H5-11 and H5-13) for cSOR, cumulative oil production and recovery factor
did not appear. A comparison between Cases H5-4, H5-5, H5-11 and H5-13 indicates
that, except for Case H5-11, the change in heat losses is not significant. The highest
heat loss is achieved when the wellpairs have a vertical distance of 3 to 4.5m from each
other. Introducing a horizontal separation reduces the heat loss as well as the oil
recovery factor.
76
3.4.4. Best Case Scenarios
The best case scenarios for Models H10, H7 and H5 are compared with each other’s and
a thicker reservoir layer of 25 m known as base case in the following sections.
3.4.4.1. Cumulative Steam-to-Oil Ratio
The cumulative steam-to-oil ratios (cSORs) for the best case scenarios and the thicker
base case are shown and compared with each other in Fig. 3-13. In all cases, lower cSOR
is achieved by positioning the producer well at 0.25 m above understrata with a vertical
alignment of the injection and production wells. The optimum vertical distance attained
for the 7, 10 and 25 m reservoirs was found to be equal to 5 m and 4.5 m for the 5 m
reservoir.
Figure 3-13 Steam oil ratio (SOR) versus time for best case scenarios.
0
1
2
3
4
5
6
7
8
0 100 200 300 400 500 600 700 800 900 1000
SOR
Cum
ulat
ive
, m3 /
m3
Time, Days
H25-Base Case H10-Case 6 H7-Case 4 H5-Case 5
77
A comparison between the cases reveals that the thicker the layer, the smaller the
cSOR. Also the cSOR profile, between 100 to 300 production days, shows a local
maximum of the cSOR. Beyond this peak, the cSOR drops to a local minimum and then
it grows once again for the best case scenarios. The early peak is related to higher
capacity of reservoir to accept steam (larger net pay zone) and increasing heat losses to
the rock outside the reservoir. Slower growth of the cSOR beyond the local minimum is
observed for the thicker reservoirs. The cSOR for the thicker base case leads to a gradual
decrease. Approximately, cSOR with a value of around 3.5, 4.2, 5.4 and 7.2 m3/m3 are
obtained for oil reservoirs of thickness 25, 10, 7 and 5 m, respectively.
3.4.4.2. Cumulative Produced Oil
The cumulative produced oil volume profiles for the best case scenarios together with
the thicker base case are shown in Fig. 3-14. The same trends of the rise of the
cumulative oil production for all oil reservoir thicknesses are observed. However, the
greater the thickness of the reservoir, the higher is the cumulative oil produced and the
oil rate. Obviously, a thicker layer consists of larger pay zone and consequently higher
amount of oil which allows for higher cumulative production at the same production
time.
78
Figure 3-14 Cumulative produced oil versus operation time for best case scenarios.
3.4.4.3. Oil Recovery Factor
The profiles of the oil recovery factor versus the pore volume injected steam (PVSI) for
the best case scenarios together with the thicker base case are presented in Fig. 3-15.
Even in the thinnest case, the recovery factor of 55% can be achieved but at higher cost
of injected steam (PVSI=2.8). The thicker the oil column, the higher the oil recovery
factor is given a PVSI. A range of 55 to 60% was observed for oil reservoir thickness of 5
to 10 m. For the base case of 25 m about 33% cumulative oil recovery observed at the
end of 900 operation days. Obviously due to the size of reservoir it takes longer time to
achieve higher recovery factor. For example, the cumulative recovery factor increased
0
10000
20000
30000
40000
50000
60000
70000
0 100 200 300 400 500 600 700 800 900 1000
Cum
ulat
ive
Oil
Prod
uctio
n , m
3
Time, Days
H25-Base Case H10-Case 6H7-Case 4 H5-Case 5
79
to 69% (H25-Base Case*) after 1500 operation days. To achieve the same recovery
factor, a greater PVSI is required as the oil reservoir gets thinner.
Figure 3-15 Oil recovery factor versus pore volume steam injected (PVSI) for best case scenarios.
3.4.4.4. Cumulative Heat Loss
The cumulative heat losses for the best case scenarios are depicted in Fig. 3-16. Ignoring
Case H5-12, it can be concluded that higher layer thicknesses lead to lower heat losses.
In all cases with the exception of H5-12, the producer well is located at 1.75 m above
the underburden and the injector well is positioned with a vertical and horizontal
distances of 2.5 and 8 m respectively. Turning our attention to Case H5-12, it is shown
that this particular well configuration leads to a lower heat loss than that of layer
0
10
20
30
40
50
60
70
0 0.5 1 1.5 2 2.5 3
Oil
Reco
very
Fac
tor
PVSI
H25-Base Case H25-Base Case* H10-Case 6
H7-Case 4 H5-Case 5
80
thickness of 7 and 10 m. Here both injector and producer wells are positioned at the
adjacent block to the underburden and 4 m apart. Evaluating SAGD well performance
based on the lowest heat losses does not make sense as far as we are interested in
achieving higher oil recovery and production.
Figure 3-16 Heat loss versus time for best case scenarios.
In our investigation, the best case scenarios from the heat loss point of view led to
poorest SAGD well performances.
The selected well configuration of best case scenarios (H10-6, H7-4 and H5-5) for cSOR,
cumulative oil production and oil recovery were similar and completely different from
the well configuration selected for heat loss best case scenarios (H10-9, H7-6 and H5-
12).
-1.5E+13
-1E+13
-5E+12
0
0 100 200 300 400 500 600 700 800 900 1000
Heat
Los
s Cu
m, J
Time, Days
H10- Case 9 H7-Case 6H5-Case 12 H5- Case 9
81
In order to be able to come in conclusion, we are selecting Cases H10-6, H7-4 and H5-5
and look at their heat loss behavior. This is depicted in Fig. 3-17 and reveals that layer
thickness of 10 m leads to lower heat loss (-1.67 x 1014 J). However, for the particular
well arrangement in H7-4 and H5-5 the heat losses almost are the same. Under the
same circumstances, the base case of 25 m thickness leads to a cumulative heat loss of
(-1.14 x1014 J).Roughly, thinner layers lead to 46% up to 59% more heat loss in
comparison with the thicker base case.
Figure 3-17 Heat loss behaviour for best case scenarios.
3.4.4.5. Temperature Distributions and Well Pairs Arrangement
The wellpairs arrangements as well as temperature distribution for best case scenarios
(regardless of best heat loss cases) are depicted in Fig. 3-18. As the oil reservoir
-2E+14
-1.5E+14
-1E+14
-5E+13
0
0 100 200 300 400 500 600 700 800 900 1000
Heat
Los
s Cu
m, J
Time, Days
H25-Base Case H10- Case 6 H7-Case 4 H5-Case 5
82
thickness decreases, the steam injector position gets closer to overburden. The injector
distance from the overburden for Cases H10-6, H7-4, and H5-5 are 4.75, 1.75 and 0.75
m, respectively. Therefore, a higher heat loss to overburden is expected. As the oil
reservoir thickness increases, better temperature distribution is expected due to smaller
heat loss and better heat transfer to the larger reservoir volume.
(A)
(B)
(C)
Figure 3-18 Wellpair arrangements and temperature distribution for best case scenarios. (A) H10-6, (B) H7-4, (C) H5-5.
83
3.5. Conclusions
The influence of well configuration on the production performance of SAGD operation
was studied in thin (less than 10 m thick) oil sand reservoirs. Production is possible with
oil recovery factors of 60% to 55% at cSORs equal to about 4, 5, and 7 m3/m3 for oil
reservoir thicknesses of 10, 7 and 5m, respectively. The best case scenarios were
achieved by positioning the producer well at 0.25 m above the understrata and having a
vertical wellpairs alignment with a distance of about 4 to 5 m. The steam injector
distance from overburden was varied between 0.75 and 4.75 m. The results imply that
with the decrease in oil reservoir thickness, position of the injector well gets closer to
the overburden. The cumulative heat losses were almost in the same range for oil
reservoir equal to 5 and 7 m and slightly lower for layer thickness of 10 m. In
comparison with a thicker layer reservoir of 25 m, higher heat losses were observed –
the increase in heat loss led to 46, 56 and 59% for layer thickness of 10, 7 and 5 m
respectively.
It can be concluded that vertical as well as horizontal distances between wellpairs, and
their position or distances in respect to over and underburden rock affect the SAGD
production. Finding an optimum value will have an influence in cSOR, heat loss, recovery
factor and oil production. Therefore, to maximize SAGD production in thin oil sands
reservoirs requires finding an optimized well configuration. Introducing a horizontal
separation between the injector and producer wells usually decreases SAGD
84
performance through delayed oil production. Under our experimental condition, a
horizontal offset of about 1.6 m was found to be optimal.
85
CHAPTER 4. PERFORMANCE OF STEAM ASSISTED GRAVITY DRAINAGE IN THIN OIL SAND RESERVOIRS: WELL PAIR
CONFIGURATION IN A SINGLE PRODUCER - DOUBLE INJECTOR SET UP
Summary
The performance of Steam Assisted Gravity Drainage (SAGD) is studied in thin oil sand
reservoirs where the basic unit of operation is a single producer with two steam
injectors. Specifically, the influence of the injection and production well triplet
configuration is investigated in homogeneous oil sands formations with thicknesses of 5,
7, and 10 m. Various well configurations were explored where the vertical and
horizontal spacing between the injection and production wells were varied. Thus, well
locations with respect to the overburden and understrata rock also varied. SAGD
performance was assessed numerically by using a thermal reservoir simulator and the
cumulative steam-to-oil ratio (cSOR), cumulative oil production, cumulative heat loss,
and oil recovery factor were compared. The results of study were compared with the
best case scenarios from single producer-single injector well configurations. The results
suggest that horizontal and vertical distances between injectors and the producer well,
their locations from the overburden and understrata and their vertical alignment impact
their performance. The results also show that the addition of an offset injector well
86
reduces cSOR under certain well configuration. Generally, the dual injector-single-
producer performs better than the single injector-single-producer.
4.1. Introduction
The Steam-Assisted Gravity Drainage (SAGD) oil sands recovery process is an effective
commercial process for viscous oil recovery when the reservoir thickness is greater than
about 15 m (Gates, 2010). However, in thinner oil sands reservoir (< 10 m), heat losses
from the steam chamber to the overburden and understrata are significant and the
process is considered inefficient and uneconomic. However, the importance of thin oil
sand reservoirs lies in the fact that about 80% of extra heavy oil resources exist in
reservoirs with a net pay zone of less than about 5 m in Western Canada (Adams, 1982).
Thus, there is a need for new efficient processes to produce these resources.
In Chapter 3, the importance and influence of well configuration on SAGD performance
in thin oil sand reservoirs (≤ 10 m) were investigated. The key parameters such as
vertical as well as horizontal separation between the injector and producer wells, and
their positions with respect to overburden and understrata were evaluated by using a
single injector-single producer system. It was shown that these parameters have an
influence on the cSOR, heat losses, recovery factor, and cumulative oil production.
Introducing a horizontal separation between the wells usually decreases SAGD
performance at the cost of delaying the onset of oil production. However, unless the
87
vertical distance is already less than the optimum value, then a small horizontal shift or
offset improves process performance. From the study in Chapter 3, a horizontal offset of
about 1.6 m between the wells is suggested.
The focus of the research documented here is an evaluation of a dual injector-single
producer well configuration in thin oil sands reservoir (≤ 10 m). In practice, the dual
injector could be completed in the reservoir using multilateral drilling technology and
thus, there are no technical barriers to using dual injection wells as envisioned in the
research documented here.
4.2. Reservoir Simulation Model
The reservoir simulation model consists of a two-dimensional homogenous model with
horizontal wellpairs. The reservoirs do not have gas cap or bottom water zones.
Specifically, similar to Chapter 3, three reservoir models were developed with oil sand
intervals of 5, 7, and 10 m thickness, respectively labeled as cases H5-2Inj, H7-2Inj, and
H10-2Inj. It should be noted that for the sake of comparison with Chapter 3 results, the
2Inj suffix added to model names implies that the SAGD well configuration consists of
single-producer-double injector wells. The second injector well is referred as 2Inj or
offset well here.
88
A regular Cartesian grid system was used to discretize the models with dimensions of
58 grids with a block size of 0.8 m in the cross well direction, 1 grid block with length
750 m in the downwell direction. In the vertical direction, there are 10, 14, and 20 grid
blocks in the H5-2Inj, H7-2Inj, and H10-2Inj models, respectively, all with grid block
dimensions equal to 0.5 m. The reservoir model properties and parameters are listed in
Table 4-1.
Simulations were performed using a commercial thermal reservoir simulator CMG
STARSTM version 2013 (CMG, 2013) which has been used in the oil sands industry for
over 15 years for SAGD simulation. In this finite volume thermal reservoir simulator, the
conservation of energy and mass equations are simultaneously solved over each grid
block together with the phase behavior and relative permeability curves for the gas,
aqueous, and oil phases. At the lateral sides of the model, symmetry boundary
conditions were imposed (no flow or heat transfer). In other words, the width of the
reservoir represents the horizontal well spacing and implies that the well triplets are
part of a larger pattern.
In our models, to establish thermal communication between injector and producer
wells, the steam circulation time was set equal to 3 months. In the model, this was
done by placing temporary heaters in the locations of the wells. When SAGD mode
started, the temporary heaters were turned off and steam injection and fluid production
started. The operation was simulated for up to 3 years.
89
Table 4-1 Reservoir simulation model and fluid properties.
Property
Value
Net pay, m 10, 7 and 5 SAGD wellpair length, m 750 Horizontal permeability, mD 4000 Vertical permeability, mD 2000 Average porosity 0.3 Initial oil saturation 0.75 Initial water saturation 0.25 Irreducible water saturation (Swr) 0.15 Residual oil saturation with respect to water 0.20 Relative permeability to oil at irreducible water 1.0 Relative permeability to water at residual oil 0.992 Residual gas saturation (Sgr) 0.005 Residual oil saturation with respect to gas 0.005 Relative permeability to gas at residual oil 1.0 Relative permeability to oil at critical gas Krw at irreducible oil (KRWIRO)
0.992 0.1
Residual oil for gas-liquid table endpoint saturation (SORG) 0.005 Initial temperature, °C 20 Initial pressure, kPa 2000 Rock heat capacity, J/m3 °C 2.600x106 Rock thermal conductivity, J/m day °C 6.600x105 Water phase thermal conductivity, J/m day °C 5.350x104 Oil phase thermal conductivity, J/m day °C 1.150x104 Gas phase thermal conductivity, J/m day °C 5.000x103 Bitumen Molecular weight, kg/kmol Critical temperature, °C Critical pressure, kPa Dead oil viscosity, cP at 10°C 100°C 200°C
465
903.85 792
1587285 203.91
9.71
90
Table 4-1 Reservoir simulation model and fluid properties (continued).
Liquid phase component viscosity (cP) versus temperature curves (methane viscosities are liquid equivalent viscosity) T (°C) µwater µoil µmethane
5 0 4062963.508 115.042 10 0 1587284.565 98.5940 20 0 299536.7897 68.4247 30 0 71948.7369 54.1416 40 0 21109.2585 43.3994 50 0 7318.08492 35.2174 60 0 2918.2885 28.9106 70 0 1309.6336 23.9942 80 0 649.6128 20.1206 90 0 350.9125 17.0377 100 0 203.9087 14.5607 125 0 82.3894 10.9109 150 0 29.6896 7.4943 175 0 17.7130 6.0323 200 0 9.7153 4.5479 225 0 7.1037 3.8631 250 0 4.8898 3.1238
Oil-water relative permeability curves Sw Krw Krow
0.1500 0.0000 0.9920 0.2500 0.0016 0.9500 0.3500 0.0130 0.6000 0.4500 0.0440 0.3500 0.5500 0.1040 0.1650 0.6500 0.2040 0.0700 0.7500 0.3520 0.0150 0.8000 0.4470 0.0000 0.8500 0.5590 0.0000 0.9500 0.8340 0.0000 1.0000 1.0000 0.0000
Gas-liquid relative permeability curves Sl Krg Krog
0.1500 1.0000 0.0000 0.2500 0.8400 0.0016 0.3500 0.6000 0.0130 0.4500 0.3500 0.0440 0.5500 0.1650 0.1040 0.6500 0.0750 0.2040 0.7500 0.0270 0.3520 0.8000 0.0200 0.4470 0.8500 0.0100 0.5590 0.9500 0.0000 0.8340 1.0000 0.0000 0.9920
91
4.3. Reservoir Models
4.3.1. Model H10-2Inj
The reservoir cross-sectional views and detailed well configuration in Model H10-2Inj
with a single producer and dual injector cases are depicted in Table 4-2. Each well
location is defined by its grid block number in the horizontal (I and J) and vertical (K)
directions as well as vertical and horizontal separations between the injector wells and
the producer well. Model H10-2Inj was run with 10 different cases to investigate the
influence of well configuration on performance.
For all Model H10-2inj cases, the producer well is placed in grid block 30 in the I-
direction. However the vertical positioning of the producer well was varied. In Cases
H10-2Inj-1 to H10-2Inj-3 as well as Case H10-2Inj-6, the producer well was placed 1.75
m above the base of the oil reservoir (grid block 17 in the K-direction). For the rest of
the H10-2Inj cases, the producer well is positioned 0.25 m above the bottom of the
reservoir (grid block 20 in the K-direction).
Cases H10-2Inj-1 through H10-2Inj-5 are the vertically aligned well pairs (one of the
injector wells is aligned with the producer well). In these configurations the offset
injector well (Inj-2) was positioned with a vertical and horizontal separation away from
the producer and aligned injector (Inj-1) well. Cases H10-2Inj-6 and H10-2Inj-10 are the
92
not vertically aligned configurations where the injector wells are positioned at both
sides of the producer well.
Table 4-2 Well placement in Model H10-2Inj with a layer thickness of 10 m.
Case Well Grid i
Grid j
Grid k
Vert. Dist. (m)
Horiz. Dist. (m)
Image
H10-2Inj-1
Prod. 30 1 17
Inj-1 30 1 12 2.5 0 Inj-2 32 1 12 2.5 1.6
H10-2Inj-2
Prod. 30 1 17
Inj-1 30 1 12 2.5 0 Inj-2 35 1 12 2.5 4
H10-2Inj-3
Prod. 30 1 17
Inj-1 30 1 12 2.5 0 Inj-2 40 1 12 2.5 8
H10-2Inj-4
Prod. 30 1 20
Inj-1 30 1 10 5 0 Inj-2 35 1 10 5 4
H10-2Inj-5
Prod. 30 1 20
Inj-1 30 1 10 5 0 Inj-2 32 1 15 2.5 1.6
93
In general, the vertical separations between injectors and producers were varied
between 2.5 to 5 m. The horizontal separation of the offset injector well to the producer
well was varied between 1.6 to 8 m.
H 10-2Inj-6
Prod. 30 1 17
Inj-1 28 1 12 2.5 1.6 Inj-2 33 1 12 2.5 2.4
H10-2Inj-7
Prod. 30 1 20
Inj-1 28 1 10 5 1.6 Inj-2 33 1 10 5 2.4
H10-2Inj-8
Prod. 30 1 20
Inj-1 28 1 15 2.5 1.6 Inj-2 33 1 10 5 2.4
H10-2Inj-9
Prod. 30 1 20
Inj-1 28 1 15 2.5 1.6 Inj-2 32 1 15 2.5 1.6
H10-2Inj-10
Prod. 30 1 20
Inj-1 28 1 15 2.5 1.6 Inj-2 33 1 15 2.5 2.4
94
4.3.2. Model H7-2Inj
The reservoir cross-sectional views and detailed well configuration in Model H7-2Inj are
shown in Table 4-3. Model H7-2Inj was evaluated with 8 well configuration cases. The
producer well in Model H7-2inj is placed at grid block 30 in the I-direction for all of the
cases. In Cases H7-2Inj-1 through H7-2Inj-3, the producer well was placed 1.75 m above
the bottom of the reservoir (grid block 11 in the K-direction) and 0.25 m above the base
of the reservoir (grid block 14 in the K-direction) for Cases H7-2Inj-4 through H7-2Inj-8.
Cases H7-2Inj-1 through H7-2Inj-6 are the vertically aligned well cases (one injector is
aligned with the producer). In these configurations the offset injector well (Inj-2) was
positioned with a vertical and horizontal separation away from the producer and aligned
injector (Inj-1) wells.
Cases H7-2Inj-7 and H7-2Inj-8 are the not vertically aligned cases in which the injector
wells are positioned at both sides of the producer well. In general, the vertical distance
between the injector and producer wells was varied between 1 to 5 m. The horizontal
distance of the offset injector well was varied between 1.6 to 8 m.
95
Table 4-3 Well placement in Model H7-2Inj with a layer thickness of 7 m.
Case Well Grid i
Grid j
Grid k
Vert. Dist. (m)
Horiz. Dist. (m)
Image
H7-2Inj-1
Prod. 30 1 11
Inj-1 30 1 6 2.5 0 Inj-2 35 1 6 2.5 4
H7-2Inj-2
Prod. 30 1 11
Inj-1 30 1 6 2.5 0 Inj-2 40 1 6 2.5 8
H7-2Inj-3
Prod. 30 1 11
Inj-1 30 1 9 1 0 Inj-2 35 1 9 1 4
H7-2Inj-4
Prod. 30 1 14
Inj-1 30 1 9 2.5 0 Inj-2 35 1 9 2.5 4
H7-2Inj-5
Prod. 30 1 14
Inj-1 30 1 4 5 0 Inj-2 35 1 4 5 4
H7-2Inj-6
Prod. 30 1 14
Inj-1 30 1 4 5 0 Inj-2 32 1 9 2.5 1.6
96
H7-2Inj-7
Prod. 30 1 14
Inj-1 28 1 4 5 1.6 Inj-2 33 1 4 5 2.4
H7-2Inj-8
Prod. 30 1 14
Inj-1 28 1 9 2.5 1.6 Inj-2 33 1 4 5 2.4
4.3.3. Model H5-2Inj
The reservoir cross-sectional views and detailed well configuration of the 9 Model H5-
2Inj cases are listed in Table 4-4. The producer well in Model-H5-2inj is placed in grid
block 30 in the I-direction for all cases. In Cases H5-2Inj-1 through H5-2Inj-3, the
producer well was placed 1.75 m above the base of the oil reservoir (grid block 7 in the
K-direction). For Cases H5-2Inj-4 to H5-2Inj-9, the producer well was placed 0.25 m
above the bottom of the reservoir (grid block 10 in the K-direction).
Cases H5-2Inj-1 through H5-2Inj-7 are the vertically aligned well pairs (where one
injector is aligned with the producer well). In these configurations the offset injector
well (Inj-2) was positioned with a vertical and horizontal separation away from the
producer and aligned injector (Inj-1) wells.
97
Cases H5-2Inj-8 and H5-2Inj-9 are the not vertically aligned cases in which the injector
wells are positioned at both sides of the producer well. In general, the vertical distance
between the injector and producer wells was varied between 1 to 4 m. The horizontal
separation of the offset well was varied between 1.6 to 8 m.
Table 4-4 Well placement in Model H5-2Inj with a layer thickness of 5 m.
Case Well Grid- i
Grid- j
Grid- k
Vert. Dist. (m)
Horiz. Dist. (m)
Image
H5- 2Inj-1
Prod. 30 1 7
Inj-1 30 1 2 2.5 0 Inj-2 35 1 2 2.5 4
H5- 2Inj-2
Prod. 30 1 7
Inj-1 30 1 2 2.5 0 Inj-2 40 1 2 2.5 8
H5- 2Inj-3
Prod. 30 1 7
Inj-1 30 1 5 1 0 Inj-2 35 1 5 1 4
H5- 2Inj-4
Prod. 30 1 10
Inj-1 30 1 2 4 0 Inj-2 35 1 2 4 4
98
H5- 2Inj-5
Prod. 30 1 10
Inj-1 30 1 2 4 0 Inj-2 35 1 6 2 4
H5- 2Inj-6
Prod. 30 1 10
Inj-1 30 1 2 4 0 Inj-2 35 1 10 0 4
H5- 2Inj-7
Prod. 30 1 10
Inj-1 30 1 2 4 0 Inj-2 32 1 10 0 1.6
H5- 2Inj-8
Prod. 30 1 10
Inj-1 28 1 2 4 1.6 Inj-2 33 1 2 4 2.4
H5- 2Inj-9
Prod. 30 1 10
Inj-1 28 1 2 4 1.6 Inj-2 33 1 5 2.5 2.4
4.4. Results and Discussion
The simulation results compared consist of the cumulative steam-to-oil ratio (cSOR)
versus time, cumulative oil production versus time, oil recovery factor versus pore
volume of steam injected (PVSI), and cumulative heat loss versus time.
99
4.4.1. Model H10-2Inj
4.4.1.1. Cumulative Steam-to-Oil Ratio
Cumulative steam-to-oil ratios (cSOR) profiles for Model H10-2Inj with a layer thickness
of 10 m are shown in Fig. 4-1. The cSOR profiles change in a close range from 4.1 to 4.5
m3/m3 and include both aligned and not aligned configurations.
In Cases H10-2Inj-1 through H10-2Inj-3, the position of the offset injector well (Inj-2)
was increased from 1.6 to 8 m horizontally. This change of the separation causes a slight
decrease in cSOR.
Similar to what was observed in Chapter 3, positioning the producer well at the adjacent
layer to the understrata reduces the cSOR due to collection of oil from a larger area of
the reservoir. This result is observed for both vertically aligned and non aligned cases. A
cSOR reduction of 4.5 to 4.4 m3/m3 was observed for the not vertically aligned well
Cases H10-2Inj-6 and H10-2Inj-10. For vertically aligned cases H10-2Inj-2 and H10-2Inj-4,
a decrease of cSOR from 4.4 to 4.2 m3/m3 was found. A comparison between these two
cases reveals that the position of the injector wells and their distance from the producer
well affects the cSOR.
In the vertically aligned Case H10-2Inj-5, the position of the offset injector well was
changed such that there is no alignment between both injectors. The offset well is
100
positioned at a vertical and horizontal distances of 2.5 and 1.6 m to the producer well.
The cSOR obtained was equal to 4.2 m3/m3. A comparison between the cSOR for the
single injector-single producer, Case H10-6 described in Chapter 3, reveals no significant
change in cSOR.
Not vertically aligned Case H10-2Inj-7 leads to almost similar cSOR as in the vertically
aligned Case H10-2Inj-4. Here the lowest cSOR observed is about 4.1 m3/m3 for Cases
H10-2Inj-4 and H10-2Inj-7. Further increase of the cSOR to 4.4 m3/m3 is observed when
the vertical distance between injectors and the producer is reduced from 5 to 2.5 m in
not vertically aligned cases H10-2Inj-9 and H10-2Inj-10. Under this well configuration, a
further reduction of the separation between injectors from 5 to 3.2 m yields to a slight
reduction of cSOR.
It can be concluded that the horizontal and vertical separations between injectors and
the producer well, their positions away from the overburden and understrata and their
alignments affects cSOR. Here, 10 different triple well configurations were examined. A
comparison with single injector-single producer well configuration in Model H10 reveals
a tighter cSOR variation range in Model H10-2Inj. That is a cSOR of 4.5 to 4.1 and 4 to
8.4 m3/m3 for Model H10-2Inj and Model H10 respectively.
101
Figure 4-1 Cumulative steam-to-oil ratio versus time for Model H10-2Inj cases.
4.4.1.2. Cumulative Produced Oil
As shown in Fig. 4-2, Case H10-2Inj-5 has the highest cumulative oil production followed
by Cases H10-2Inj-8, H10-2Inj-10, H10-2Inj-9, H10-2Inj-6, H10-2Inj-1, H10-2Inj-2, H10-
2Inj-3, H10-2Inj-4 and H10-2Inj-7. Cases H10-2Inj-5 and H10-2Inj-8 are examples of
vertically aligned and not aligned configurations, respectively. Recalling the results of
their related cSOR from the previous section reveals that these cases did not led to the
lowest cSOR in their group. Therefore, it can be concluded that lower cSOR cannot be
interpreted as higher cumulative oil production or a better performance. There are
other factors in play such as heat loss and oil recovery factor.
0
1
2
3
4
5
0 100 200 300 400 500 600 700 800 900 1000
SOR
Cum
ulat
ive
, m3 /
m3
Time, Days
H10-2Inj-Case 1 H10-2Inj-Case 2H10-2Inj-Case 3 H10-2Inj-Case 4H10-2Inj-Case5 H10-2Inj-Case 6H10-2Inj-Case 7 H10-2Inj-Case 8H10-2Inj-Case 9 H10-2Inj-Case 10
4
4.1
4.2
4.3
4.4
4.5
880 890 900
102
Figure 4-2 Cumulative produced oil versus time for Model H10-2Inj cases.
In Cases H10-2Inj-1 through H10-2Inj-3, the cumulative oil production slightly decreased
as the position of the offset injector well (Inj-2) increases. It can be due to delay in
thermal communication between injectors and the producer. The impact of the
positioning of the producer well above the understrata on the cumulative oil production
is shown in Cases H10-2Inj-6 and H10-2Inj-10. The results show that lower the producer
is in the oil reservoir, the greater the cumulative oil production volume.
It was observed that the not vertically aligned Case H10-2Inj-7 with the producer wells
0.25 m above the understrata exhibit the lowest cSOR in its group. However, the same
case led to the lowest cumulative oil production in its group of the not aligned cases.
0
10000
20000
30000
40000
50000
0 100 200 300 400 500 600 700 800 900 1000
Cum
ulat
ive
Oil
Prod
uctio
n , m
3
Time, Days
H10-2Inj- Case 1H10-2Inj-Case 2H10-2Inj-Case 3H10-2Inj-Case 4H10-2Inj-Case 5H10-2Inj-Case 6H10-2Inj-Case 7H10-2Inj-Case 8H10-2Inj-Case 9H10-2Inj-Case 10
42400
42800
43200
43600
44000
830 835
103
Similar behavior was observed regarding H10-2Inj-4. Apparently, the production is
delayed in these cases. Cases H10-2Inj-10 and H10-2Inj-9 both show a higher oil
production than Cases H10-2Inj-7 but a lower produced volume than that of Case H10-
2Inj-8. These cases confirm that position of injector wells with respect to the
overburden and understrata has an impact on oil production.
4.4.1.3. Oil Recovery Factor
According to Fig. 4-3, recovery factors between 59 to 63% are achieved for all cases with
PVSI in the range of 1.77 to 1.95. At PVSI of 1.76, the recovery factor is the highest for
Cases H10-2Inj-5 and H10-2Inj-8 followed by Cases H10-2Inj-4, H10-2Inj-7, H10-2Inj-9,
H10-2Inj-10, H10-2Inj-3, H10-2Inj-2, H10-2Inj-6, and H10-2Inj-1. As expected, to achieve
higher recovery factor a higher PVSI is required. In Case H10-2Inj-7, a recovery factor of
63% at PVSI of 1.94 is realized. Cases H10-2Inj-5 and H10-2Inj-8 exhibit the same
recovery factor at PVSI of 1.75, but the well configuration in Case H10-2Inj-8 enables
higher recovery factor equal to 61.8% at a PVSI of 1.86.
In Cases H10-2Inj-1 through H10-2Inj-3, the oil recovery factor (at certain PVSI) slightly
increases as the distance between injector wells increases. However, the ultimate
recovery factor was increased at higher cost of PVSI as the separation between injector
wells decreased. It appears that longer distance between injector wells allows for more
steam injection due to the delay of thermal communication between the offset injector
104
and the producer well. The impact of the positioning of the producer well just above
the understrata on the recovery factor is illustrated by Cases H10-2Inj-6 and H10-2Inj-
10. It reveals that the oil recovery factor increases as the producer well get closer to
understrata. This is because oil under the producer well is not recovered since there is
no force that would promote movement of oil from layers under the well. Cases H10-
2Inj-4 and H10-2Inj-5 represent vertically aligned and cases H10-2Inj-7 and H10-2Inj-8
not aligned cases. A comparison between these cases reveals that not aligned cases led
to higher steam injectivity and therefore a higher recovery factor.
Figure 4-3 Oil recovery factor versus pore volume steam injected for Model- 10-2Inj cases.
0
10
20
30
40
50
60
70
0 0.5 1 1.5 2
Oil
Reco
very
Fac
tor
PVSI
H10-2Inj-Case 1 H10-2Inj-Case 2H10-2Inj-Case 3 H10-2Inj-Case 4H10-2Inj-Case 5 H10-2Inj-Case 6H10-2Inj-Case 7 H10-2Inj-Case 8H10-2Inj-Case 9 H10-2Inj-Case 10
56
57
58
59
60
61
62
63
1.65 1.75 1.85 1.95
105
4.4.1.4. Cumulative Heat Loss
The profiles of the cumulative heat losses are presented in Fig. 4-4. Case H10-2Inj-5 has
the highest loss whereas Case H10-2Inj-7 and H10-2Inj-4 show the lowest heat loss. The
rest of cases show approximately similar heat losses. Cases H10-2Inj-4 and H10-2Inj-7
represent the vertically aligned and not aligned cases. In spite of different well
alignment, the well configuration with respect to producer well position, and distance of
injector wells from the overburden and distance between injector and producer, the
results are similar. However, Case H10-2Inj-7 allows for more steam injectivity and
higher recovery factor at a cost of higher PVSI. Case H10-2Inj-5 shows that the highest
heat loss is due to positioning of the offset well at closer distance (2.5 m) to understrata
and a probable steam short circuiting directly from the injector to the producer wells.
The closer distance of offset injector well to the producer makes it possible to achieve
higher cumulative oil production as it was shown in Fig. 4-2.
Cases H10-2Inj-1 through H10-2Inj-3 represents the effect of the offset injection well
from the producer well. As the offset well distance increases, the heat losses decreases.
It implies that longer distance between injector wells prevents steam short circuiting
and probably reaches a larger region of the reservoir. However, as was mentioned
above, the delay of thermal communication between the offset injector and the
producer well causes lower recovery factor at comparable times.
106
Figure 4-4 Heat loss versus time for Model- 10-2Inj cases.
The impact of injector well positioning on the heat loss is compared in Cases H10-2Inj-7
and H10-2Inj-8. Case H10-2Inj-8 shows a higher heat loss compared to Case H10-2Inj-7.
In Case H10-2Inj-8, the well arrangement of one of the injector wells is positioned at
closer distance (2.5 m) to the producer well and underburden. Cases H10-2Inj-8 and
H10-2Inj-2 show similar heat losses in spite of having different well configuration,
different cSOR, oil recovery factor and oil production. It implies that having a lower heat
loss does not guarantee better process performance. A comparison between Cases
H10-2Inj-8 and H10-2Inj-5 shows the lower heat loss and cSOR, higher recovery factor at
cost of higher PVSI and slightly lower cumulative oil production. It is difficult to pick the
best case scenario without having an economical comparison or knowing the
operational and production priorities; Case H10-2Inj-8 has been selected as the best
case for further comparison with other cases. However, this particular case is very
-2E+14
-1.5E+14
-1E+14
-5E+13
0
0 100 200 300 400 500 600 700 800 900 1000
Heat
Los
s Cu
m, J
Time, Days
H10-2Inj-Case 1 H10-2Inj-Case 2H10-2Inj-Case 3 H10-2Inj-Case 4H10-2Inj-Case 5 H10-2Inj-Case 6H10-2Inj-Case7 H10-2Inj-Case 8H10-2Inj-Case 9 H10-2Inj-Case 10
-1.6E+14
-1.55E+14
-1.5E+14
-1.45E+14
-1.4E+14
820
107
comparable with Cases H10-2Inj-7 (not-vertically aligned) and H10-2Inj-4 (vertically
aligned).
4.4.2. Model H7-2Inj
4.4.2.1. Cumulative Steam-to-Oil Ratio
Cumulative steam-to-oil ratios (cSOR) for Model H7-2Inj (oil reservoir thickness of 7 m)
are shown in Fig. 4-5. The cSOR profiles occur in a range from 5.3 to 5.9 m3/m3. Similar
to the previous model the change in the cSOR for all the examined well configuration is
in a close range - a difference order of 0.6 m3/m3 .
In general, the aligned Cases (H7-2Inj-1 to H7-2Inj-3) with having the producer well 1.75
m away from the underburden show higher cSOR with values at around 5.7 to 5.8
m3/m3.
When the position of the offset injector well (Inj-2) was increased from 4 to 8 m
horizontally, a slight decrease in cSOR was observed.
A way to decrease cSOR in these aligned cases is the placement of the producer well at
closer distance to the underburden – as it was done in Case H7-2Inj-4 and 5 in
comparison with Case H7-2Inj-1.
108
Placing the offset injector well at closer distance to the producer well, as was done in
Case H7-2Inj-6 in comparison with Case H7-2Inj-5, causes an increase in cSOR in the
aligned cases.
While arranging the injectors on both sides of the producer well, as it is the case in H7-
2Inj-8 in comparison with Case H7-2Inj-6, decreases the cSOR. No significant changes in
cSOR were observed in vertically aligned and not aligned cases of H7-2Inj-5 and H7-2Inj-
7.
A comparison between the single injector-single producers (Case H7-4, cSOR of 5.4
m3/m3) reveals that addition of an offset injector well can help to reduce the cSOR only
under certain well configurations.
Not vertically aligned cases (where no injector is aligned with the producer) with the
producer wells positioned 0.25 m above the understrata, with the exception of Case H7-
2Inj-5, exhibit the lowest cSOR ranging from 5.3 to 5.4 m3/m3. In Case H7-2Inj-7, similar
to vertically aligned Case H7-2Inj-5, the positioning of the injector wells in an aligned
arrangement leads to lower cSOR. When the injector wells are not aligned as is the case
with Case H7-2Inj-8 and Case H7-2Inj-6, the cSOR rises to 5.4 and 5.5 m3/m3
respectively.
Similar to the results of Model H10-2Inj, it can be concluded that the horizontal and
vertical distances between injectors and the producer well, their locations from the
overburden or understrata and their alignments affect cSOR. A comparison with single
109
injector-single producer well configuration in Model H7 reveals a closer cSOR variation
range in Model H7-2Inj. That is a cSOR of 5.3 to 5.9 and 5.3 to 7.8 m3/m3 for Model H7-
2Inj and Model H7 respectively.
Figure 4-5 Cumulative steam-to-oil ratio versus time for Model H7-2Inj cases.
4.4.2.2. Cumulative Produced Oil
According to Fig. 4-6, Case H7-2Inj-6 has the highest cumulative oil production followed
very closely by Case H7-2Inj-8, and then Cases H7-2Inj-4, H7-2Inj-7, H7-2Inj-5, H7-2Inj-2,
H7-2Inj-1 and H7-2Inj-3.
1
2
3
4
5
6
0 100 200 300 400 500 600 700 800 900 1000
SOR
Cum
ulat
ive
, m3 /
m3
Time, Days
H7-2Inj-Case 1 H7-2Inj-Case 2H7-2Inj-Case 3 H7-2Inj-Case 4H7-2Inj-Case 5 H7-2Inj-Case 6H7-2Inj-Case 7 H7-2Inj-Case 8
110
Cases H7-2Inj-6 and H7-2Inj-8 present examples of the vertically aligned and not aligned
cases (one injector and the producer). Recalling the results of cSOR for these two cases,
the results reveal that both cases did not led to the lowest cSOR of their groups of well
arrangement. Here, both of these cases show the highest oil production in their own
groups. In Case H7-2Inj-8, in spite of having lower cSOR in comparison with Case H7-
2Inj-6, it did not realize a higher cumulative oil production. Again it can be concluded
that lower cSOR cannot be interpreted as higher cumulative oil production.
In Cases H7-2Inj-1 and H7-2Inj-2, the cumulative oil production rises slightly as the
position of the offset injector well (Inj-2) increases. This result is different with what was
observed in similar cases Model H10. The impact of the location of producer well on the
cumulative oil production is illustrated by Cases H7-2Inj-3 and H7-2Inj-4. The results
show that the cumulative oil production rises as the producer well is moved closer to
the understrata. A comparison between Cases H7-2Inj-7 and H7-2Inj-8 shows that Case
H7-2Inj-7 achieved lower cumulative oil production. This behavior is related to the
position of injector wells. In Case H7-2Inj-8, the well configuration provides more
balanced steam distribution in the formation due to having different distances from
overburden.
111
Figure 4-6 Cumulative produced oil versus time for Model H7-2Inj cases.
4.4.2.3. Oil Recovery Factor
According to Fig. 4-7, recovery factors achieved are between 50 to 60% for all cases with
PVSI in the range of 2.1 to 2.4. At the lowest PVSI, the recovery factor is the highest for
Cases H7-2Inj-7 and H7-2Inj-5 followed by Cases H7-2Inj-8, H7-2Inj-6, H7-2Inj-4, H7-2Inj-
2, H7-2Inj-1, and H7-2Inj-3. At this particular PVSI, the recovery factor is equal to 50%.
To achieve higher recovery factor, a higher PVSI is required. For example, in Case H7-
2Inj-7, a recovery factor of 60.2% at PVSI of 2.4 is achieved. In Cases H7-2Inj-5, H7-2Inj-
7, and H7-2Inj-8 show similar recovery factor at PVSI of 2.2, but the only well
configuration that achieves higher recovery factor (60%) is that of Case H7-2Inj-8 at PVSI
of 2.4. In Cases H7-2Inj-1 and H7-2Inj-2, the oil recovery factor (at PVSI of 2.3) rises
slightly as the distance between injector wells increases.
0
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0 100 200 300 400 500 600 700 800 900 1000
Cum
ulat
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Prod
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Time, Days
H7-2Inj- Case 1 H7-2Inj-Case 2H7-2Inj-Case 3 H7-2Inj-Case 4H7-2Inj-Case 5 H7-2Inj-Case6H7-2Inj-Case7 H7-2Inj-Case8
24500
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845 850
112
The impact of the location of producer well on the recovery factor is illustrated by Cases
H7-2Inj-3 and H7-2Inj-4. The results show that the recovery factor enlarges as the
producer well is lowered in the oil reservoir. In general, as shown in Fig. 4-7, the oil
recovery factors can be roughly categorized into three groups of higher, medium and
lower recovery factors. Cases H7-2Inj-4 through H7-2Inj-8 achieves higher recovery
factors followed by Cases H7-2Inj-1 and H7-2Inj-2, and the lowest is realized in Case H7-
2Inj-3. It is found out that in the highest category, similar to Model H10, the producer
well is located just above the understrata. Case H7-2Inj-3 shows that the lowest
recovery factor results from small inter well separation where steam short circuiting
occurs.
Figure 4-7 Oil recovery factor versus pore volume steam injected (PVSI) for Model H7-2Inj cases.
0
10
20
30
40
50
60
70
0 0.5 1 1.5 2 2.5
Oil
Reco
very
Fac
tor
PVSI
H7-2Inj-Case 1 H7-2Inj-Case 2 H7-2Inj-Case 3H7-2Inj-Case 4 H7-2Inj-Case 5 H7-2Inj-Case 6H7-2Inj-Case7 H7-2Inj-Case8
52535455565758596061
2.1 2.3 2.5
113
4.4.2.4. Cumulative Heat Loss
The cumulative heat losses are depicted in Fig. 4-8. The results show that Case H7-2Inj-6
achieves the highest losses whereas Case H7-2Inj-3 results in the lowest heat losses.
Cases H7-2Inj-5 and H7-2Inj-7 represent examples of the vertically aligned and not
aligned cases.
Cases H7-2Inj-1 and H7-2Inj-2 illustrate the effect of the offset of the injection well from
the producer well. As the offset well distance rises, no significant changes were
observed in the extent of heat loss. The impact of injector well positioning on the heat
loss is compared in Cases H7-2Inj-7 and H7-2Inj-8 (smaller separation between injector
and producer). Case H7-2Inj-8 shows a higher heat loss in comparison to that of Case
H7-2Inj-7.
Figure 4-8 Heat loss versus time for Model H7-2Inj cases.
-2E+14
-1.5E+14
-1E+14
-5E+13
0
0 100 200 300 400 500 600 700 800 900 1000
Heat
Los
s Cu
m, J
Time, Days
H7-2Inj-Case 1 H7-2Inj-Case 2 H7-2Inj-Case 3H7-2Inj-Case 4 H7-2Inj-Case 5 H7-2Inj-Case 6H7-2Inj-Case 7 H7-2Inj-Case 8
114
Similar to the previous Model H10-2Inj, it is difficult to choose the best case scenario
without knowing the operational and production priorities; Case H7-2Inj-8 has been
selected as the best case for further comparison with other cases. However, this
particular well configuration is very comparable with Cases H7-2Inj-7 (not-vertically
aligned) and H7-2Inj-5 (vertically aligned).
4.4.3. Model H5-2Inj
4.4.3.1. Cumulative Steam-to-Oil Ratio
The cumulative steam-to-oil ratios (cSOR) for Model H5-2Inj (oil reservoir thickness 5 m)
are shown in Fig. 4-9. For these cases, the cSOR ranges from 7.1 to 7.7 m3/m3
depending on the well configuration. Generally, the aligned cases, Cases H5-2Inj-1 to
H5-2Inj-3 with having the producer well 1.75 m away from the underburden, exhibit
higher cSOR at around 7.6 to 7.7 m3/m3. When the position of the offset injector well
(Inj-2) was increased from 4 to 8 m horizontally, a slight decrease in cSOR was observed.
A way to decrease cSOR in these aligned cases is the placement of the producer well at a
closer distance to the underburden - as it was done in Case H5-2Inj-4 in comparison with
Case H5-2Inj-1.
Placing the offset injector well at a closer distance to the producer well, as was done in
Case H5-2Inj-5 and Case H5-2Inj-6 in comparison with Case H5-2Inj-4, did not have a
significant effect on cSOR value. When the position of the offset injector well was
115
increased from 1.6 to 4 m horizontally, a slight decrease in cSOR was observed for Case
H5-2Inj-7 and Case H5-2Inj-6 respectively.
While arranging the injectors on both sides of the producer well, as it is the case in H5-
2Inj-8 in comparison with Case H5-2Inj-4, decreases the cSOR.
Not vertically aligned Case H5-2Inj-8 with the producer well positioned at 0.25 m above
the understrata exhibits the lowest cSOR of 7.1 m3/m3. In Case H5-2Inj-7, similar to
vertically aligned Cases, the positioning of the offset injector well in a closer
arrangement to underburden leads to higher cSOR. When the injector wells are not
aligned as it is the case in H5-2Inj-9, the cSOR rises to 7.2.
Recalling the result of cSOR for single injector-single producer well configuration in Case
H5-5 from Chapter 3, shows a value of 7.2 m3/m3. The addition of an offset injector well
to this arrangement reduces the cSOR further to 7.1 m3/m3. In cases where the
producer well is positioned at 0.25 m above the understrata and the injector wells are
not aligned with the producer well yields cSORs ranging from 7.1 to 7.2 m3/m3.
Similar to the results of the previous models, it can be concluded that the horizontal and
vertical distances between injectors and the producer well, their locations from the
overburden or understrata and their alignments affects cSOR. A comparison with single
injector-single producer well configuration in Model H5 reveals a closer cSOR variation
116
range in Model H5-2Inj. That is a cSOR of 7.1 to 7.7 and 7.1 to 7.9 m3/m3 for Model H5-
2Inj and Model H5 respectively.
Figure 4-9 Cumulative steam-to-oil ratio versus time for Model H5-2Inj cases.
4.4.3.2. Cumulative Produced Oil
As shown in Fig. 4-10, Cases H5-2Inj-4 to H5-2Inj-9 achieved the highest cumulative oil
production followed by Cases H5-2Inj-2, H5-2Inj-1, and H5-2Inj-3. Cases H5-2Inj-4 to H5-
2Inj-9 represents the vertically aligned and not aligned cases (one injector and
producer). The producer well in all cases is located at 0.25 m above the understrata. The
results show that different positioning of the offset well did not have any significant
influence on the cumulative oil production in spite of lower cSOR observed in Case H5-
2Inj-8. Here, the impact of the location of the producer well on the cumulative oil
0
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5
6
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8
0 100 200 300 400 500 600 700 800 900 1000
SOR
Cum
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, m3 /
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Time, Days
H5-2Inj-Case 1 H5-2Inj-Case 2H5-2Inj-Case 3 H5-2Inj-Case 4H5-2Inj-Case 5 H5-2Inj-Case 6H5-2Inj-Case 7 H5-2Inj- Case 8H5-2Inj- Case 9
7
7.1
7.2
7.3
890 900
117
production can be observed by comparison of Cases H5-2Inj-1 to H5-2Inj-3 with Cases
H5-2Inj-4 to H5-2Inj-9 – the lower is the producer, the higher is cumulative oil
production.
In Cases H5-2Inj-1 and H5-2Inj-2, the cumulative oil production slightly increases as the
position of the offset injector well (Inj-2) increases. This result is different with what was
observed in similar cases of Model-H10 but is similar to the results obtained with
Model-H7. The results suggest that as the oil reservoir thickness decreases, having an
offset distance of about 8 m is beneficial.
Figure 4-10 Cumulative produced oil versus time for Model H5-2Inj cases.
0
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0 100 200 300 400 500 600 700 800 900 1000
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H5-2Inj- Case 1 H5-2Inj-Case 2 H5-2Inj-Case 3H5-2Inj-Case 4 H5-2Inj-Case 5 H5-2Inj-Case 6H5-2Inj-Case7 H5-2Inj- Case 8 H5-2Inj- Case 9
118
4.4.3.3. Oil Recovery Factor
As displayed in Fig. 4-11, recovery factors of the H5-2Inj cases is between 45 and 54.7%
with PVSI in the range from 2.60 to 2.85. At the lowest PVSI, the recovery factor is the
highest for Cases H5-2Inj-8 followed by Cases H5-2Inj-9, H5-2Inj-4, H5-2Inj-5, H5-2Inj-6,
H5-2Inj-7, H5-2Inj-2, H5-2Inj-1, and H5-2Inj-3. Similar to other models (H10 and H7), a
higher recovery factor is achieved at a higher PVSI. In Cases H5-2Inj-1 and H5-2Inj-2, the
oil recovery factor (at PVSI of 2.65) slightly increases as the separation between the
injector wells grows. The impact of the location of producer well on the recovery factor
is shown in Cases H5-2Inj-1 and H5-2Inj-4; the results show that the recovery factor rises
when the producer well is placed at the base of the oil reservoir. In general, as shown in
Fig. 4-11, the oil recovery factors can be roughly categorized in two groups. Cases H5-
2Inj-4 through H5-2Inj-9 present higher recovery factors and Cases H5-2Inj-1 to H5-2Inj-
3 are the lower ones. Similar to Models H10-2Inj and H7-2Inj, the producer well located
at the base of the oil reservoir achieves the highest recovery factor. Case H5-2Inj-3
shows that the lowest recovery factor occurs in the case where a lot of steam circuiting
occurs. It seems that as the layer thickness decreases, the performance become less
sensitive to well configuration with respect to the oil recovery factor.
119
Figure 4-11 Oil recovery factor versus pore volume steam injected (PVSI) for Model H5-2Inj cases.
4.4.3.4. Cumulative Heat Loss
The cumulative heat losses for the H5-2Inj cases are depicted in Fig. 4-12. Case H5-2Inj-9
has the highest heat losses whereas Case H5-2Inj-3 has the lowest heat losses. In Cases
H5-2Inj-1 and H5-2Inj-2, as the offset well distance increases, the heat losses increase
slightly. Similar heat losses can be observed for Cases H5-2Inj-4, 7 and 8. A comparison
between Cases H5-2Inj-4 and H5-2Inj-6 reveal that positioning each of the injector wells
close to the overburden and understrata can lead to somewhat lower heat loss. As it
was discussed in previous cases, the lower heat loss cases do not correspond to better
process performance.
0
10
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30
40
50
60
0 0.5 1 1.5 2 2.5 3
Oil
Reco
very
Fac
tor
PVSI
H5-2Inj-Case 1 H5-2Inj-Case 2 H5-2Inj-Case 3H5-2Inj-Case 4 H5-2Inj-Case 5 H5-2Inj-Case 6H5-2Inj-Case 7 H5-2Inj-Case 8 H5-2Inj-Case 9
53
53.5
54
54.5
55
2.65 2.75 2.85
120
Figure 4-12 Heat loss versus time for Model H5-2Inj cases.
Case H5-2Inj-9 has been selected as the best case for further comparison with other
cases. However, this particular well configuration is very comparable with Cases H5-
2Inj-8 (not-vertically aligned) and H5-2Inj-4 (vertically aligned).
4.4.4. Best Cases for the Single Producer-Dual Injector Models
Case H10-2Inj-8 represents model H10 with a layer thickness of 10 m. Similarly, Cases
H7-2Inj-8 and H5-2Inj-9 represent Models H7 (thickness 7 m) and H5 (thickness 5 m),
respectively. For sake of comparison the reservoir cross-section well configurations are
recalled here and are shown in Table 4-5.
A comparison between cSOR, cumulative produced oil, cumulative recovery factor and
heat loss for the best case scenarios are depicted in Figs. 4-13 through 4-16.
-2E+14
-1.5E+14
-1E+14
-5E+13
0
0 100 200 300 400 500 600 700 800 900 1000
Heat
Los
s Cu
m, J
Time, Days
H5-2Inj- Case 1H5-2Inj-Case 2H5-2Inj-Case 3H5-2Inj-Case 4H5-2Inj-Case 5H5-2Inj-Case 6H5-2Inj-Case 7H5-2Inj-Case 8H5-2Inj-Case 9
-1.88E+14
-1.84E+14
-1.8E+14
-1.76E+14
-1.72E+14
-1.68E+14
-1.64E+14
-1.6E+14
890 895 900
121
Table 4-5 Cross-sectional reservoir view and well configuration for best case scenarios in dual injector-single producer.
Case H10-2Inj-8 H7-2Inj-8 H5-2Inj-9
Image
The cumulative steam-to-oil ratios for best cases are shown and compared with each
other in Fig. 4-13. In all cases, the lower cSOR achieved by positioning the producer well
at 0.25 m above understrata and in a not aligned well configuration.
A comparison between cases reveals that the thicker the layer, the smaller the cSOR.
The establishment of the steam chamber occurs faster in lower thickness followed by an
abrupt increase in cSOR. It can be related to lower capacity of reservoir to accept steam
(smaller net pay zone). After formation of a minimum in the cSOR profiles, the opposite
behavior is observed – thereafter, a slower increase of the cSOR for thicker layers is
observed. Approximately, the cSORs are equal to 4.1, 5.4 and 7.2 m3/m3 are obtained
for layer thicknesses of 10, 7 and 5 m, respectively.
The cumulative produced oil versus production time for the best cases is presented in
Fig. 4-14. The same trends in increase in cumulative oil production for all Models are
observed. However, the increase is more rapid for the thicker reservoirs. Obviously, a
122
thicker reservoir consists of larger pay zone and higher initial amount of oil which allows
for higher cumulative production at the same production time.
The oil recovery factor versus pore volume of steam injected for the best cases are
shown in Fig. 4-15.
Figure 4-13 cSOR versus time. Figure 4-14 Cumulative produced oil versus time.
Figure 4-15 Oil recovery versus PVSI. Figure 4-16 Heat loss versus time.
0
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SOR
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H10-2Inj-Case 8H7-2Inj-Case 8H5-2Inj-Case 9
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H10-2Inj-Case 8H7-2Inj-Case 8H5-2Inj-Case 9
123
Even in the thinnest case, a recovery factor of 55% is achieved but at higher cost of
injected steam. The thicker the reservoir, the higher the oil recovery factor. A range of
56% to 61% was observed for reservoir thickness of 5 to 10 m. To achieve the same
recovery factor more pore volumes of injected steam is required as the reservoirs gets
thinner.
The cumulative heat losses during production time are shown for nominal cases (H5-
2Inj-8, H7-2Inj-8 and H5-2Inj-9) in Fig. 4-16. It should be mentioned that heat losses
does not represent the lowest heat losses per se. It would be expected to achieve
higher heat losses for thinner oil reservoirs. However, the particular well arrangement in
Case H5-2Inj-9 provided slightly lower heat loss in comparison with cases in the thicker
layer of 7 m.
It worth mentioning, that it is possible to select other sets of the best case scenarios.
The selected well configuration depends on considering the production priorities.
For example by choosing the Cases H10-2Inj-7, H7-2Inj-7 and H5-2Inj-8 as the best case
scenarios lower cSOR, lower heat losses are achieved. However, the oil production is
delayed leading to lower cumulative oil production and lower cumulative oil recovery
factors. The difference between the newly selected triple well configurations with the
selected best case scenarios is the position of the first injector well. That is moved away
vertically from the underburden and set parallel to the offset well.
124
A comparison between cSOR, cumulative produced oil, cumulative recovery factor and
heat loss for the second selected set and the best case scenarios are depicted in Figs. 4-
17 through 4-20.
Figure 4-17 cSOR versus time. Figure 4-18 Cumulative produced oil versus time.
Figure 4-19 Oil recovery versus PVSI. Figure 4-20 Heat loss versus time.
0
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6
8
0 500 1000
SOR
Cum
ulat
ive
, m3 /
m3
Time, Days
H10-2Inj-Case 8H7-2Inj-Case 8H5-2Inj-Case 9H10-2Inj-Case7H7-2Inj-Case 7H5-2Inj-Case 8
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0 500 1000
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ulat
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0
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0 0.5 1 1.5 2 2.5 3
Oil
Reco
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H10-2Inj-Case 8H7-2Inj-Case 8H5-2Inj-Case 9H10-2Inj-Case 7H7-2Inj-Case 7H5-2Inj-Case 8
-2E+14
-1.5E+14
-1E+14
-5E+13
0
0 500 1000
Heat
Los
s Cu
m, J
Time, Days
H10-2Inj-Case 8H7-2Inj-Case 8H5-2Inj-Case 9H10-2Inj-Case 7H7-2Inj-Case 7H5-2Inj-Case 8
125
4.4.5. Best Cases for the Single Injector-Single Producer and Dual Injector-Single
Producer Models
The best cases for two major categories of single injector-single producer and dual
injector- single producer models are discussed here. Reservoir cross-sections and well
configurations for the best cases are depicted in Table 4-6.
The dual injector-single producer cases (not aligned) configurations led to best
performance whereas in the single injector-single producer cases, the aligned ones
appeared to perform better.
Table 4-6 Cross-sectional reservoir view and well configuration for best case scenarios in single injector-single producer and dual injector-single producer models.
Case Dual inj. - Single-prod.
Case Single-inj. - Single prod.
H10-2Inj-8
H10-6
H7-2Inj-8
H7-4
H5-2Inj-9
H5-5
Fig. 4-21 shows a comparison of cSOR performance. The dual injector-single producer
cases lead to lower cSOR values for all reservoir thicknesses. Having two injector wells in
126
comparison with one helped with faster growth of steam chamber and thus oil
mobilization.
Fig. 4-22 displays the cumulative produced oil as a function of time. The dual injector-
single producer cases deliver higher cumulative oil production.
Fig. 4-23 compares the oil recovery factor versus pore volume injected steam. The dual
injector-single producer cases realize higher oil recovery factor.
Fig. 4-24 shows the cumulative heat losses during production for the nominal cases and
do not represent the lowest heat losses per se. The dual injector-single producer cases
lead to higher heat losses.
A comparison between the single injector-single-producer and dual injector-single
producer scenarios at different reservoir thicknesses were shown in Fig. 4-20 through 4-
24. Similar trends with respect to increases or decreases of the value of a specific
parameter (e.g. PVSI, cSOR, and recovery factor) based on the reservoir thickness is
recognizable in both scenarios.
127
Figure 4-21 cSOR versus time. Figure 4-22 Cumulative produced oil versus time.
Figure 4-23 Oil recovery versus PVSI. Figure 4-24 Heat loss versus time.
In general, in the dual injector-single producer scenarios higher cumulative oil
production and higher recovery factor at cost of higher heat losses and a similar cSOR
are achieved. It should be emphasised that this trend may change - for example,
0
2
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6
8
0 500 1000
SOR
Cum
ulat
ive
, m3 /
m3
Time, Days
H10-2Inj-Case 8H7-2Inj-Case 8H5-2Inj-Case 9H10-Case 6H7-Case 4H5-Case 5
0
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0 500 1000
Cum
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Oil
Prod
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H10-2Inj-Case 8H7-2Inj-Case 8H5-2Inj-Case 9H10-Case 6H7-Case 4H5-Case 5
0
10
20
30
40
50
60
70
0 0.5 1 1.5 2 2.5 3
Oil
Reco
very
Fac
tor
PVSI
H10-2Inj-Case 8H7-2Inj-Case 8H5-2Inj-Case 9H10-Case 6H7-Case 4H5-Case 5
-2E+14
-1E+14
0
0 500 1000
Heat
Los
s Cu
m, J
Time, Days
H10-2Inj-Case 8H7-2Inj-Case 8H5-2Inj-Case 9H10-Case 6H7-Case 4H5-Case 5
128
preference of a lower heat loss and cSOR in favour of delayed oil recovery as it was
shown by altering the best case scenarios selection.
4.5. Conclusions
The influence of well configuration on the production performance in steam-injection
gravity drainage operations was studied through different well positioning by relocation
and providing vertical and horizontal spacing between the injection and production
wells. The results show that the best cases of the dual injector-single producer
configuration showed an oil recovery factor of 61%, 60%, and 56% at cSOR about equal
to 4.1, 5.4, and 7.2 m3/m3 in oil sand reservoirs with thickness equal to 10, 7 and 5 m,
respectively. These results were attained by positioning the producer well at 0.25 m
above the understrata with no vertical and horizontal alignment between producer and
injectors. This configuration led to the best performance when the vertical and
horizontal distances between the first injector and the producer were set at 2.5 and 1.6
m, respectively, for all reservoir thicknesses. Similarly, these parameters in the case of
second injector were set at 5 and 2.4 m for reservoir thicknesses of 10 and 7 m and 4
and 2.4 m for reservoir thickness of 5 m.
It can be concluded that the horizontal and vertical distances between injectors and the
producer well, their locations from the overburden and understrata and their
alignments affects cSOR and therefore the performance of the recovery process. The
results also show that addition of an offset injector well reduces cSOR. Generally, dual
129
injector-single producer in comparison with single injector-single producer cases led to a
higher cumulative oil production and higher recovery factor at cost of higher heat loss
and a similar cSOR. An economical evaluation is recommended since an additional
injector well causes additional cost to the operation.
130
CHAPTER 5. CONCLUDING REMARKS AND RECOMMENDATIONS
The results suggest that horizontal and vertical distances between injectors and the
producer well, their locations from over or underburden, and their alignments impact
the performance of steam-based recovery processes in thin oil sands reservoirs. The
conclusions are as follows:
1. Positioning the producer well at layer adjacent to underburden is necessary to attain
higher oil production and recovery.
2. It was observed that as the reservoir thickness decreases, the recovery process
performance become less sensitive to different well configuration.
3. It is necessary to find optimum vertical and horizontal distances between the
injector and producer well pair. It was found that in single injector-single producer
cases, if the vertical separation reduces, then a horizontal offset between the wells
can improve the performance of the recovery process.
4. The dual injector-single producer cases not aligned well configuration led to best
performance whereas the best performance of the single-injector-single producer
cases were obtained when the wells were aligned.
5. It is observed that the well configuration can impact heat losses based on reservoir
thickness. The results indicate that in single injector-single producer aligned cases,
the difference in heat losses for layer thicknesses of 7 and 5 m was not significant. In
131
the dual injector-single producer cases, heat loss from layer thickness of 5 m was
slightly less than that of the 7 m thickness cases.
6. For the selected well configurations, the dual injector-single producer case in
comparison with single injector-single producer cases led to higher cumulative oil
production and higher recovery factor at a cost of higher heat losses and a similar
cSOR.
7. In general, the performance of offset well and its influence on the cSOR, cumulative
oil production, recovery factor and heat loss depends on the triple well
configuration.
8. The result of the research documented here suggests that addition of an offset
injector well can improve the recovery process performance.
The following recommendation is made:
It is recommended that an economic evaluation is conducted to understand how the
additional well required in the dual injector-single producer well configuration affects
the financial viability of the recovery process compared to the single injector-producer
well processes.
132
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