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Transport in Porous Media (2019) 126:743–777https://doi.org/10.1007/s11242-018-1194-z
Transient and Pseudo-Steady-State Inflow PerformanceRelationships for Multiphase Flow in FracturedUnconventional Reservoirs
Salam Al-Rbeawi1
Received: 6 June 2018 / Accepted: 31 October 2018 / Published online: 8 November 2018© Springer Nature B.V. 2018
AbstractThe objective of this paper is developing newmethodology for constructing the inflow perfor-mance relationships (IPRs) of unconventional reservoirs experiencing multiphase flow. Themotivation is eliminating the uncertainties of using single-phase flow IPRs and approachingrealistic representation and simulation to reservoir pressure–flow rate relationships through-out the entire life of production. Several analytical models for the pressure drop and declinerate as wells productivity index of two wellbore conditions, constant Sandface flow rateand constant wellbore pressure, are presented in this study. Several deterministic models arealso proposed in this study for multiphase reservoir total mobility and compressibility usingmulti-regression analysis of PVT data and relative permeability curves of different reservoirfluids. These deterministic models are coupled with the analytical models of pressure drop,decline rate, and productivity index to construct the pressure–flow rate relationships (IPRs)during transient and pseudo-steady-state production time. Transient IPRs are generated forearly-time hydraulic fracture linear flow regime and intermediate-time bilinear and trilinearflow regimes, while steady-state IPRs are generated for pseudo-steady-state flow regime incase of constant Sandface flow rate and boundary-dominated flow regime in case of constantwellbore pressure. The outcomes of this study are as follows: (1) introducing the impactof multiphase flow to the IPRs of unconventional reservoirs; (2) developing deterministicmodels for reservoir total mobility and compressibility using multi-regression analysis ofPVT data and relative permeability curves; (3) developing analytical models for differentflow regimes that could be developed during the entire production life of reservoirs; (4)predicting transient and steady-state IPRs of multiphase flow for different wellbore condi-tions. The study has pointed out: (1) Multiphase flow conditions have significant impact onreservoir IPRs. (2)Multiphase reservoir total mobility and compressibility exhibit significantchange with reservoir pressure. (3) Constant Sandface flow rate may demonstrate IPR betterthan constant wellbore pressure. (4) Late production time is not affected by multiphase flowconditions similar to transient state flow at early and intermediate production time.
B Salam [email protected]
1 METU-Northern Cyprus Campus, Turkey
123
744 S. Al-Rbeawi
Keywords Multiphase flow · Unconventional reservoirs · Hydraulic fracturing · Fracturedformations · Inflow performance relationship
List of symbols
Bg Gas formation volume factorB ′g Derivative of gas formation volume factor
Bo Oil formation volume factorB ′o Derivative of oil formation volume factor
Bt Total formation volume factorBw Water formation volume factorB ′w Derivative of water formation volume factor
cAFq Shape factor for constant Sandface flow rate approachcAFP Shape factor for constant wellbore pressure approachcF Reservoir fluid total compressibility, psi−1
cg Gas - phase compressibility, psi−1
co Oil - phase compressibility, psi−1
cw Water - phase compressibility, psi−1
(ct)mp Multiphase reservoir total compressibility, psi−1
FCD Hydraulic fracture conductivity, dimensionlessJDP Productivity index of constant wellbore pressure, dimensionlessJDq Productivity index of constant Sandface flow rate, dimensionlessh Formation thickness, ftki Induced matrix permeability, mdkm Matrix permeability, md(k/μ)mp Multiphase reservoir total mobility, md/cpP Pressure, psiPb Bubble point pressure, psi�Pwf Wellbore pressure drop, psiPD Pressure drop, dimensionlessPDi Initial reservoir pressure, dimensionlessPwD Wellbore pressure drop, dimensionlesstDx P ′
D Pressure derivative, dimensionlessqD Sandface flow rate, dimensionlessqo oil flow rate, STB/dayqt Total flow rate, bbl/dayqw water flow rate, STB/dayqsc Gas flow rate,MScf/dayRs Solution gas − oil ratioR′s Derivative of solution gas − oil ratio
Rsb Solution gas − oil ratio at bubble point pressureRsw Solution gas − water ratioR′sw Derivative of solution gas − water ratio
s Laplace operatorSg Gas saturationSo Oil saturationSw Water saturation
123
Transient and Pseudo-Steady-State Inflow Performance… 745
T Reservoir temperaturet Time, htD Time, dimensionlessμg Gas - phase viscosity, cpμo Oil - phase viscosity, cpμw Water - phase viscosity, cpwf Hydraulic fracture − half - length, ftxe Reservoir boundary, ftxf Hydraulic fracture width, ftye Reservoir boundary, ftω Storativity∅ Porosityλ Interporosity flow coefficient
1 Introduction
The literature review of the two topics of interest in this paper is covered briefly. The first is thepressure behavior, decline rate, and productivity index of hydraulically fractured reservoirs,while the second focuses on the attempts of assembling the impact of multiphase flow withreservoir performance models. To avoid the excessive length of the manuscript, the literaturereview of the first part will not be discussed in details, while the second will be the focus ofthe literature review.
In the last couple decades, hydraulic fracturing stimulation technique has boosted updeveloping economically unconventional resources in spite of the great challenges. Improvingthe ultralow permeability of these resources and creating high-conductivity flow paths in theporous media are the key points in the process. As a matter of fact, starting from the firstsucceed of this technique and later on until the moment, a lot of researches in different topicsand disciplines have been conducted and presented in the petroleum industry literature.Within the scope of this paper, topics such as pressure transient analysis (PTA), rate transitanalysis (RTA), and productivity index of hydraulically fractured reservoirs are very wellcovered. At early 1960s, the physical meaning of dimensionless fracture conductivity wasexplained by Prats and Levine (1963) as the ratio of the ability of hydraulic fractures totransmit reservoir fluid to the wellbore, while 1970s have witnessed serious attempts toformulate pressure behavior and decline rate of fractured formations conducted byGringartenand Ramey (1973), Gringarten et al. (1974), Cinco-Ley (1974), Holditch and Morse (1976),Raghavan et al. (1978), Cinco-Ley et al. (1975), Cinco et al. (1978), andAgarwal et al. (1979).These attempts have continued during the 1980s and 1990s by Cinco-Ley and Samaniego(1981), Bennett et al. (1986), Camacho et al. (1987), Ozkan (1988), Guppy et al. (1988),Ozkan and Raghavan (1991a, b), Soliman et al. (1990), Kuchuk (1990), Larsen and Hegre(1994), Raghavan et al. (1997), El-Banbi (1998), andWan andAziz (1999). The later 20 yearshave witnessed a great attention given to rate transient analysis (RTA) as well as pressuretransient analysis (PTA). Because of the ultralow permeability in unconventional reservoirs,pressure pulse may need a very long time to reach the boundary and thereby pseudo-steady-state or boundary-dominated flow regime might not be observed. Therefore, RTA has beenused confidentially as an excellent tool for unconventional reservoir characterization morethan PTA. This has come out with a lot of models that describe decline rate with productiontime such as those proposed by Hagoort (2003), Levitan (2005), Ilk et al. (2006), Ibrahim
123
746 S. Al-Rbeawi
and Wattenbarger (2006), Camacho et al. (2008), Bello (2008), Izadi and Yildiz (2009), andCipolla (2009). Very recently, the two topics (RTA and PTA) have been supported by moreresearch papers presented by Ozkan et al. (2011), Brown et al. (2011), Duong (2011), Chenand Jones (2012), Nobakht et al. (2012), Torcuk et al. (2013), Fuentes-Cruz et al. (2014),Luo et al. (2014), Shahamat et al. (2015), Fuentes-Cruz and Valko (2015), Behmanesh et al.(2015, 2018), and Kanfar and Clarkson (2018).
In the above-mentioned studies, single-phase flow is assumed as the dominant flow patternin the porous media. This assumption might have led to misleading results for reservoirsthat undergo multiphase flow conditions. In conventional reservoirs, single-phase flow isthe common flow pattern in oil reservoirs with pressure greater than bubble point pressure.Single-phase flow is also the dominant flow pattern for natural dry gas reservoir and to someextent wet gas reservoirs. While in oil reservoirs where the pressure could drawdown thebubble point pressure, volatile oil reservoirs, and retrograde-condensate or near critical gas-condensate reservoirs, multiphase flow is the norm. Unconventional reservoirs may not havean exemption from the above-mentioned classification even though most shale layers areconsidered gas-producing plays. However, North Dakota Bakken formation and Texas EagleFord formation in the USA are two examples of ultralow permeability porous media wheremultiphase flow (black oil +gas) is the overwhelming flow pattern (Uzun et al. 2016).
No doubt, dealing with single-phase flow is much easier than with multiphase flow interms of physical properties of reservoir fluids and petrophysical properties of porous media.Reservoir modeling for fluid flow and pressure distribution in drainage areas that undergosingle-phase (oil or gas) flow can be accomplished either analytically or numerically witha consideration given to the absolute permeability of the porous media and total reservoircompressibility only. This would not be the case for multiphase flow where the consider-ations should be focused on relative permeability and saturation of each phase as well asthe continuously changing reservoir fluid properties such as density, viscosity, formationvolume factor, gas solubility, and compressibility. The problem could be more complicatedconsidering that associated linear behavior of most reservoir rock and fluid properties insingle-phase flow may not be applicable for multiphase flow. Nonlinear scheme (Tabatabaieand Pooladi-Darvish 2017) demonstrates most of the pressure- and time-dependent reservoirfluid properties as well as the changes in relative permeabilities with saturation that in turncould change with time and reservoir pressure.
Not until recently, multiphase flow has been given the attention in petroleum industry. Themathematical treatment proposed by Muskat and Meres (1936) for fluid flow in hydrocarbonreservoirs was considered by Perrine (1956) for multiphase flow and 3 years later Martin(1959) introduced a simplified equation for multiphase flow in gas drive reservoirs whereinrelative permeability of reservoir fluid phases and their physical properties were considered.This simplified equationwasobtainedby the assumptionof neglecting the pressure–saturationgradient as their vector products are small compared with the magnitude of pressure vectoror saturation vector. Martin and James (1963) applied the proposed model by Martin (1959)for pressure transient analysis of two-phase radial flow considering constant pressure andno flow at the outer boundary. Because of the difficulties that governed utilizing multiphaseflow in well test analysis, very limited attempts were conducted after the one proposed byMartin and James (1963). Chu et al. (1986) reconsidered two-phase flow problem in pressuretransient applications. In that study, the primary concern was the saturation gradient and therelative permeability of each phase of reservoir fluid. The conceptual approach presentedby Martin (1959) was adopted by Raghavan (1976, 1989) for the applications of well testanalysis for a well producing from solution gas driven at constant surface production rate.At the same time, Fraim andWattenbarger (1988) used the basic model presented by Muskat
123
Transient and Pseudo-Steady-State Inflow Performance… 747
(1937) for the applications of decline curve analysis considering multiphase flow in porousmedia. They concentrated on the effect of saturation gradient on rate–time profile as reservoirpressure moves down the bubble point pressure.
Ayan and Lee (1988) stated that even though the approaches presented by Perrine (1956)and Martin (1959) are simple, they could yield misleading results under some circumstancesas a consequence of the inherently assumptions in those two approaches including the non-uniform distribution of saturation and compressibility in the porous media. For this reason,Boe et al. (1989) believed that multiphase flow effect can be adapted to the liquid model solu-tions if totalmobility and compressibility are used and pseudo-pressure function is developed.However, creating pseudo-pressure function needs very well-defined relationship betweenoil saturation and pressure that in turn needs the assumptions followed by Perrine (1956) andMartin (1963). For more easiness and less assumptions, Al-Khalifa et al. (1989) suggestedusing pressure square approach for multiphase flow instead of pseudo-pressure approach.They stated that the rate normalization using pressure square approach may yield reasonableestimates for the individual phase permeability and thereby accurate total mobility. Morethan 10 years later, Kamal and Pan (2010, 2011) demonstrated the applicability of pressuretransient analysis for reservoir characterization under multiphase flow conditions. Recently,Li et al. (2017) proposed newmethod for construction gas–water two-phase steady-state flowproductivity of fractured horizontal wells depleting tight gas reservoirs.
Unfortunately, despite the great attention given to multiphase flow in porous media, theabove-mentioned attempts have not reached to robust techniques that rigorously includedthe impact of multiphase flow on reservoir performance. This could be explained by thedifficulties that governed the proposed models for predicting the variances of physical andpetrophysical properties such as saturation, viscosity, density, formation volume factor, andrelative permeability with time. Therefore, most of the proposed models for the IPR assumedsingle-phase flow either oil or gas. However, from time to time, two-phase flow or multiphaseflow IPRs have been suggested by several authors. Gallice and Wiggins (2004) investigatedthe IPRs for predicting pressure/production behavior of reservoirs dominated by two-phaseflow. Ten years before, Wiggins (1994) introduced a study for three-phase flow generalizedIPR, while Camacho andRaghavan (1989) used numerical model for examining the influenceof reservoir pressure on the IPR for reservoirs producing under solution gas derive.
In this paper, the IPR of unconventional reservoirs consideringmultiphase flow conditionsin the porous media is introduced. Early production time transient state flow IPR and lateproduction time pseudo-state IPR are considered for constant Sandface flow rate and constantwellbore pressure. Several deterministicmodels for reservoir totalmobility and compressibil-ity are generated from PVT data and relative permeability curves. The analytical models ofthe flow regimes, developed in bounded hydraulically fractured unconventional reservoirs,are included the impact of multiphase flow condition and used to generate transient andpseudo-steady-state IPRs.
2 Multiphase Reservoir Total Compressibility (ct)mp andMobility(k�
)mp
When the pressure in oil reservoirs declines less than bubble point pressure, free gas phaseis developed as well as liquid phase. Therefore, two-phase flow (oil and gas) or even multi-phase flow (oil, gas, and water) in case of water production is expected to occur in porousmedia. Therefore, the assumption for developing multiphase reservoir total compressibility
123
748 S. Al-Rbeawi
and mobility models is (P < Pb). For multiphase flow conditions, reservoir total compress-ibility depends on reservoir fluids’ saturation that in turn depends on reservoir pressure. Themathematical models for this compressibility can be written as:
(ct)mp � cf + Soco + Sgcg + Swcw. (1)
It is well known that formation compressibility (cf) may not significantly change withpressure, while reservoir fluid compressibilities, oil compressibility (co), gas compressibility(cg), and water compressibility (cw), are pressure-variant parameters. Several models wereintroduced in the literature for the changes in the three-phase reservoir fluid compressibilities.The following model was presented by Martin (1959), Raghvan (1989), and Tabatabaie andPooladi-Darvish (2017) for reservoir fluid total compressibility:
cF � So f (Co) + Sw f (Cw) + Sg f(Cg
), (2)
where
f (Co) � BgR′s
Bo− B ′
o
Bo, (3)
f (Cw) � BgR′sw
Bw− B ′
w
Bw, (4)
f(Cg
) � − B ′g
Bg. (5)
It can be clearly understood that the functions in Eqs. (3)–(5) are pressure-dependentfunctions since all parameters included in these functions such as oil, water, and gas forma-tion volume factors as well as the gas solubility in oil and water are functions of pressure.Therefore, reservoir fluid total compressibility (cF), given by Eq. (2), is expected to bepressure-dependent parameter. To develop deterministic models for these parameters, thethree situations (oil So, gas Sg, and water Sw) in Eq. (2) should be determined first. For thispurpose, it is required to calculate oil and water saturation derivatives with pressure. In thisstudy, the following two models (Martin 1959) are used to calculate oil and water saturationderivatives with pressure:
dS0dP
� SoB ′o
Bo+kro/μ0(kμ
)
mp
cF, (6)
dSwdP
� SwB′w
Bw+krw/μw(
kμ
)
mp
cF. (7)
To solve Eqs. (6) and (7), reservoir total mobility(kμ
)
mpshould be calculated as well as
oil, gas, and water saturation for each pressure step. Therefore, relative permeabilities of thethree phases have to be estimated. From oil–water system using water saturation, relativepermeability of water (krw) can be estimated while relative permeability of gas phase
(krg
)is
predicted from gas–water system knowing gas saturation. These two relative permeabilitiesare used to calculate the relative permeability of oil phase (kro) by several models proposedin the literature such as Stone I and II models (Stone 1970, 1973) or it could be determined
123
Transient and Pseudo-Steady-State Inflow Performance… 749
Fig. 1 Oil relative permeability behavior with water and gas saturations
graphically as shown in Fig. 1 using the two saturations of oil and water calculated by Stones’models. Mathematically, multiphase reservoir total mobility is calculated by:
(k
μ
)
mp� kro
μo+krgμg
+krwμw
. (8)
For better understanding the methodology proposed in this study for calculating reservoirtotal mobility and compressibility, a set of PVT data given in Table 1, taken from Boeet al. (1989), is used. Reservoir and fluid properties are given in Table 2. Because neitherwater formation volume factor (Bw) nor solution gas–water ratio is given in Table 1, thesetwo parameters are calculated using the following two models for reservoir temperature(T � 200
◦F)(Lee and Wattenbarger 1996):
Bw � 1.039 − 4.1 ∗ 10−6P − 7.4 ∗ 10−9P2, (9)
Rsw � 0.7883 + 2.1683 ∗ 10−3P − 0.93 ∗ 10−7P2, (10)
while formation water viscosity is calculated by:
μw � μ1
[0.9993 + 4.0295 ∗ 10−5P + 3.1062 ∗ 10−9P2
], (11)
where (μ1) formation water viscosity at atmospheric pressure and reservoir temperature andcalculated by:
μ1 � AT B , (12)
where (A) and (B) are two constants and determined by several models presented in the liter-ature based on formation water solid content or reservoir temperature (Lee andWattenbarger1996).
The calculated properties of formation water are given in Table 3.
123
750 S. Al-Rbeawi
Table 1 A set of PVT data (Boe et al. 1989)
P, psi Bo bbl/STB BGo bbl/SCF RS SCF/STB μo, cp μg, cp
5705 1.806 0.000596 1499.00 0.298 0.0298
5633 1.791 0.000600 1470.38 0.3 0.0295
5204 1.702 0.000625 1305.56 0.317 0.0281
4703 1.605 0.000661 1127.45 0.348 0.0263
4202 1.516 0.000709 963.48 0.391 0.0246
3700 1.434 0.000775 812.57 0.446 0.0228
3200 1.36 0.000870 673.78 0.515 0.021
2770 1.302 0.000991 563.79 0.587 0.0195
2340 1.249 0.001172 461.53 0.671 0.0181
1911 1.202 0.001455 366.52 0.768 0.0166
1482 1.159 0.001929 278.24 0.881 0.0152
1052 1.121 0.002826 196.10 1.011 0.0138
623 1.088 0.004998 119.14 1.164 0.0125
193 1.058 0.016881 44.29 1.35 0.0113
Table 2 Reservoir physical andpetrophysical properties (Boeet al. 1989)
Porosity, ∅ 30%
Permeability, k 10 md
Intial reservoir pressure, Pi 5705 psi
Bubble point pressure, Pb 5705 psi
Initial water saturation, Swi 30%
Initial gas saturation, Sgi 0.0
Wellbore radius, rw 0.33 ft
Reservoir radius, re 656 ft
Formation thickness, h 15.6ft
Gas specific gravity, γg 0.75
Reservoir temperature, T 200 °F
Crude oil API 35
The calculated relative permeabilities of the three phases of reservoir fluids are used tocalculate multiphase reservoir total mobility, given by Eq. (8). The results are given in Table 4and plotted in Fig. 2. Multi-regression analysis is used to generate a deterministic model formultiphase reservoir total mobility with reservoir pressure. This model is:
(k
μ
)
mp� AP2 + BP + C, (13)
where the constants(A � 8 ∗ 10−7
), (B � −0.0079), and (C � 44.9) are determined by the
PVT data of the reservoir of interest.To calculate reservoir total compressibility (ct)mp, reservoir fluid total compressibility
(cF ) should be calculated first. The following procedures illustrate the methodology used forcalculating reservoir total compressibility.
123
Transient and Pseudo-Steady-State Inflow Performance… 751
Table 3 Calculated formationwater properties
P, psi Rsw SCF/STB μw, cp Bw bbl/STB
5705 10.132 1.3304 1.0162
5633 10.051 1.3249 1.0170
5204 9.554 1.2932 1.0210
4703 8.929 1.2576 1.0250
4202 8.257 1.2236 1.0282
3700 7.538 1.1910 1.0308
3200 6.775 1.1602 1.0329
2770 6.081 1.1349 1.0343
2340 5.353 1.1107 1.0355
1911 4.592 1.0877 1.0365
1482 3.797 1.0659 1.0373
1052 2.966 1.0452 1.0379
623 2.103 1.0257 1.0384
193 1.203 1.0073 1.0388
Table 4 Reservoir total mobility results
P, psi kro krg krwo kro/o krg/g krw/w (k/μ)mp
5705 0.805 0 0 2.701 0.000 0.000 2.701
5633 0.802 0.6383 0.02 2.673 21.637 0.015 24.326
5204 0.751 0.6253 0.05 2.369 22.253 0.039 24.660
4703 0.71 0.606 0.08 2.040 23.042 0.064 25.146
4202 0.615 0.5885 0.1 1.573 23.923 0.082 25.577
3700 0.554 0.5681 0.11 1.242 24.917 0.092 26.251
3200 0.505 0.547 0.13 0.981 26.048 0.112 27.140
2770 0.462 0.5453 0.14 0.787 27.964 0.123 28.875
2340 0.421 0.5437 0.15 0.627 30.039 0.135 30.801
1911 0.382 0.5242 0.16 0.497 31.578 0.147 32.223
1482 0.351 0.5094 0.17 0.398 33.513 0.159 34.071
1052 0.331 0.508 0.18 0.327 36.812 0.172 37.311
623 0.302 0.5052 0.19 0.259 40.416 0.185 40.861
193 0.252 0.4856 0.2 0.187 42.973 0.199 43.359
1. At the bubble point pressure, the three compressibility functions given by Eqs. (3)–(5)are calculated as well as reservoir total mobility.
2. Using initial saturations at bubble point pressure, reservoir fluid total compressibility iscalculated using Eq. (2) andmultiphase reservoir total compressibility is calculated usingEq. (1).
3. Calculate oil and water saturation derivatives given by Eqs. (6) and (7) for the secondpressure interval.
4. Calculate oil and water saturation for the new pressure interval. Gas saturation is calcu-lated by
(Sg � 1 − Sw − So
).
123
752 S. Al-Rbeawi
y = 8E-07P2 - 0.0079P + 44.878R² = 0.9964
0.0
5.0
10.0
15.0
20.0
25.0
30.0
35.0
40.0
45.0
50.0
0 1000 2000 3000 4000 5000 6000
Fig. 2 Multiphase reservoir total mobility behavior with pressure
5. Calculate the relative permeability of the three phases of reservoir fluid using Stone’smodels and reservoir total mobility using Eq. (8).
6. Calculate the three compressibility functions given by Eqs. (3)–(5) and repeat steps forall pressure intervals.
The results ofmultiphase reservoir fluid total compressibility (cF) andmultiphase reservoirtotal compressibility (ct)mp are given in Table 5. Figure 3 shows the behavior of multiphasereservoir total compressibility with pressure. Multi-regression analysis is used to generate adeterministic model for multiphase reservoir fluid total compressibility:
cF � APB . (14)
According to Eq. (1), multiphase reservoir total compressibility is calculated by the sum-mation of reservoir fluid total compressibility (cF) and formation compressibility. It has beenfound that multiphase reservoir total compressibility has the same power model for reservoirfluid total compressibility regardless of the value of formation compressibility. However, thetwo constants (A) and (B) may change very slightly. Therefore, the deterministic model ofmultiphase reservoir total compressibility is:
(ct)mp � APB . (15)
The constants (A) and (B) in Eqs. (14) and (15) are determined from PVT data ofthe reservoir of interest. For example, the two constants in Eq. (15) are (A � 0.3099) and(B � −0.896) calculated by the PVT data taken from Boe et al. (1989).
To support the approach presented above for generating deterministic models for multi-phase reservoir total mobility and compressibility, another set of PVT data taken from Fraimand Wattenbarger (1988) is given in Table 6. The available information of the reservoir ofinterest is given in Table 7. The behavior of multiphase reservoir total mobility with pres-sure is shown in Fig. 4, while Fig. 5 demonstrates multiphase reservoir total compressibilitybehavior with pressure. The two deterministic models of these two parameters are similar tothose given in Eqs. (13) and (15); however, there are very slight differences in the constants
123
Transient and Pseudo-Steady-State Inflow Performance… 753
Table5Multip
hase
reservoirflu
idtotalcom
pressibilityandreservoirtotalcom
pressibilityresults
P,p
sif(Co)
f(Cw)
f(Cg)
k ro
k rg
k rw
dSo/dP
dSw/dP
5705
2.84
217E
−05
0.00
0115
124
0.00
0151
997
0.80
50
00.00
0118
04−3
.428
18E−0
5
5633
2.92
528E
−05
0.00
0112
842
0.00
0154
937
0.80
20.63
830.02
6.88
79E−0
5−3
.383
65E−0
5
5204
3.47
861E
−05
0.00
0100
175
0.00
0174
279
0.75
10.62
530.05
6.55
41E−0
5−3
.137
14E−0
5
4703
4.25
923E
−05
8.70
976E
−05
0.00
0201
683
0.71
0.60
60.08
6.16
18E−0
5−2
.848
47E−0
5
4202
5.24
708E
−05
7.54
926E
−05
0.00
0235
598
0.61
50.58
850.1
5.72
3E−0
5−2
.558
59E−0
5
3700
6.55
027E
−05
6.50
462E
−05
0.00
0277
965
0.55
40.56
810.11
5.30
49E−0
5−2
.267
47E−0
5
3200
8.34
266E
−05
5.56
038E
−05
0.00
0330
732
0.50
50.54
70.13
4.89
24E−0
5−1
.971
31E−0
5
2770
0.00
0104
926
4.81
375E
−05
0.00
0387
535
0.46
20.54
530.14
4.52
84E−0
5−1
.715
86E−0
5
2340
0.00
0135
407
4.12
212E
−05
0.00
0459
398
0.42
10.54
370.15
4.16
88E−0
5−1
.456
72E−0
5
1911
0.00
0180
454
3.48
757E
−05
0.00
0554
911
0.38
20.52
420.16
3.81
75E−0
5−1
.191
11E−0
5
1482
0.00
0251
826
2.91
979E
−05
0.00
0695
811
0.35
10.50
940.17
3.47
74E−0
5−9
.159
98E−0
6
1052
0.00
0378
684
2.45
917E
−05
0.00
0942
774
0.33
10.50
80.18
3.15
12E−0
5−6
.242
59E−0
6
623
0.00
0669
479
2.28
134E
−05
0.00
1519
608
0.30
20.50
520.19
2.86
71E−0
5−2
.773
17E−0
6
193
0.00
2199
146
4.13
836E
−05
0.00
4688
456
0.25
20.48
560.2
2.92
37E−0
55.23
169E
−06
S oS g
S wk ro/μ
ok rg/μ
gk rw/μ
wc F
(ct)mp
0.7
00.3
2.70
1342
282
00
5.44
324E
−05
6.44
324E
−05
0.69
1501
330.00
6030
382
0.30
2468
288
2.67
3333
333
21.637
2881
40.01
5094
982
5.52
937E
−05
6.52
937E
−05
0.66
1952
103
0.02
1063
747
0.31
6984
152.36
9085
174
22.252
6690
40.03
8663
299
5.84
516E
−05
6.84
516E
−05
0.62
9116
026
0.03
8182
736
0.33
2701
238
2.04
0229
885
23.041
8251
0.06
3612
677
6.34
737E
−05
7.34
737E
−05
123
754 S. Al-Rbeawi
Table5continued
S oS g
S wk ro/μ
ok rg/μ
gk rw/μ
wc F
(ct)mp
0.59
8245
605
0.05
4782
346
0.34
6972
049
1.57
2890
026
23.922
7642
30.08
1728
382
7.04
909E
−05
8.04
909E
−05
0.56
9516
207
0.07
0667
602
0.35
9816
191.24
2152
466
24.916
6666
70.09
2358
169
8.03
526E
−05
9.03
526E
−05
0.54
2991
711
0.08
5854
733
0.37
1153
555
0.98
0582
524
26.047
6190
50.11
2054
332
9.43
324E
−05
0.00
0104
332
0.52
1954
508
0.09
8415
291
0.37
9630
201
0.78
7052
811
27.964
1025
60.12
3364
244
0.00
0111
180.00
0121
18
0.50
2482
397
0.11
0509
214
0.38
7008
388
0.62
7421
759
30.038
6740
30.13
5050
138
0.00
0134
760.00
0144
76
0.48
4598
046
0.12
2144
237
0.39
3257
717
0.49
7395
833
31.578
3132
50.14
7092
982
0.00
0168
942
0.00
0178
942
0.46
8221
156
0.13
3411
276
0.39
8367
568
0.39
8410
897
33.513
1578
90.15
9483
736
0.00
0222
371
0.00
0232
371
0.45
3268
406
0.14
4425
233
0.40
2306
361
0.32
7398
615
36.811
5942
0.17
2211
233
0.00
0317
699
0.00
0327
699
0.43
9749
641
0.15
5265
928
0.40
4984
431
0.25
9450
172
40.416
0.18
5237
653
0.00
0539
586
0.00
0549
586
0.42
7420
959
0.16
6402
147
0.40
6176
894
0.18
6666
667
42.973
4513
30.19
8552
032
0.00
1736
939
0.00
1746
939
123
Transient and Pseudo-Steady-State Inflow Performance… 755
y = 0.3099P-0.986
R² = 0.9991
0.0000
0.0002
0.0004
0.0006
0.0008
0.0010
0 1000 2000 3000 4000 5000 6000
Fig. 3 Multiphase reservoir total compressibility behavior with pressure
of these two models obtained by analyzing PVT data given by Boe et al. (1989) and PVTdata given by Fraim and Wattenbarger (1988). The differences of the constants in these twomodels come from the differences in the two reservoir fluid properties and the differencesin reservoir conditions. Therefore, for more accuracy to the proposed approach used in thismanuscript, more PVT data sets can be used for developing different multiphase reservoirtotal compressibility and mobility models. Accordingly, the average values of the parametersincluded in these two models can be calculated and used for generating single and unique setof the two models of compressibility and mobility.
In the next sections, reservoir total mobility and compressibility, calculated by Eqs. (13)and (15), respectively, will be used in predicting transient and pseudo-steady-state IPR forunconventional reservoirs.
3 Transient Inflow Performance Relationship
Unconventional reservoirs are characterized by dominating transient state flow for a verylong production time. The reason for that refers to a very slow transferring rate of pressurepulse in the porous media due to ultralow permeability. Accordingly, the conclusions thatmost of the production comes from transient state flow and pseudo-steady-state flowmay notbe reached are not unrealistic. Unlike pseudo-steady-state flow, transient state flow is knownby varied productivity index. Because of that and considering multiphase flow conditions,conventional IPRmodels (Vogel 1968; Standing 1971; Fetkovich 1973;Wiggins 1994; Golanand Whitson 1995) may give misleading results. Therefore, new methodology is proposedin this study for pressure–flow rate relationships of unconventional reservoirs undergoingmultiphase flow. The new methodology states that the IPRs of this type of reservoirs arenot constant. They are changed with production time and the dominant flow regime in theporous media. Accordingly, different IPRs should be constructed for different flow regimesand production time.
123
756 S. Al-Rbeawi
Table 6 PVT data (Fraim and Wattenbarger 1988)
P, psi Bo bbl/STB Rs SCF/STB μo, cp Bg bbl/STB μg, cp
0 1.09 0.0 1.673 1.35 0.011
200 1.12 40.0 0.954 0.0938 0.0115
400 1.151 101.0 0.873 0.0463 0.0124
700 1.193 176.0 0.733 0.0261 0.0135
1000 1.229 245.0 0.662 0.018 0.0146
1300 1.265 315.0 0.598 0.0137 0.0156
1600 1.302 386.0 0.565 0.011 0.0166
1900 1.341 462.0 0.519 0.0091 0.0178
2200 1.328 543.0 0.488 0.0078 0.019
2400 1.41 598.0 0.479 0.0072 0.0198
2600 1.442 658.0 0.468 0.0067 0.0208
2755 1.467 705.0 0.460 0.0064 0.0212
3500 1.57 920.0 0.425
4000 1.64 1060.0 0.400
4500 0.005 0.0276
5000 1.73 1275.0 0.360
6000 1.87 1550.0 0.325
7000 2 1850.0 0.280 0.004 0.0374
Table 7 Reservoir information(Fraim and Wattenbarger 1988) Oil density, ρo 46.24 Ib/ft3
Formation water density, ρw 62.23 Ib/ft3
Formation water compressibility,ctw
1 ∗ 10−5 psi−1
Formation water viscosity, μw 0.31 cp
Initial water saturation 35%
Effect rock compressibility, cf 7 ∗ 10−6 psi−1
Initial reservoir pressure 3600 psi
Bubble point pressure, Pb 2755 psi
Formation porosity, ∅ 12%
Formation absolutepermeability,k
15md
Formation thickness, h 170 ft
Wellbore radius, rw 0.025 ft
Reservoir radius, re 600 ft
It is very well documented in the literature that the two dominant flow regimes in uncon-ventional reservoirs during transient state flow are hydraulic fracture linear flow followed byformation linear flow regime represented by bilinear flow and trilinear flow regime. Whilepseudo-steady-state flow regime develops at late production timewhen pressure pulse reachesthe boundary of reservoirs depleted by constant Sandface flow rate. For reservoirs depletedby constant wellbore pressure, the observed flow regime at late production time is called
123
Transient and Pseudo-Steady-State Inflow Performance… 757
y = 1.1E-06P2 - 0.0102P + 46.75R² = 0.9963
0.0
5.0
10.0
15.0
20.0
25.0
30.0
35.0
40.0
45.0
50.0
0 500 1000 1500 2000 2500 3000
Fig. 4 Multiphase reservoir fluid total compressibility behavior with pressure
y = 0.3164P-0.964
R² = 0.9798
0.0000
0.0005
0.0010
0.0015
0.0020
0.0025
0.0030
0.0035
0.0040
0 500 1000 1500 2000 2500 3000
Fig. 5 Multiphase reservoir total compressibility behavior with pressure
boundary-dominated flow regime. These flow regimes can be characterized either from pres-sure records with time (PTA) as shown in Fig. 6 or from decline rate behavior with time(RTA) as shown in Fig. 7.
Figure 6 is prepared using the following mathematical model, in dimensionless form, forwellbore pressure drop assuming constant Sandface flow rate (Brown et al. 2011; Ozkan et al.2011):
PwD � π
sFCD√AF tanh
(√AF
) , (16)
123
758 S. Al-Rbeawi
1.0E-03
1.0E-02
1.0E-01
1.0E+00
1.0E+01
1.0E+02
1.0E-07 1.0E-06 1.0E-05 1.0E-04 1.0E-03 1.0E-02 1.0E-01 1.0E+00 1.0E+01 1.0E+02 1.0E+03 1.0E+04 1.0E+05
Series1
Series2
Fig. 6 Pressure behavior with time for fractured reservoirs
1.0E-02
1.0E-01
1.0E+00
1.0E+01
1.0E+02
1.0E+03
1.0E+04
1.0E-07 1.0E-06 1.0E-05 1.0E-04 1.0E-03 1.0E-02 1.0E-01 1.0E+00 1.0E+01 1.0E+02 1.0E+03 1.0E+04 1.0E+05
Series1
Series3
Fig. 7 Rate behavior with time for fractured reservoirs
while Fig. 7 is prepared using the following mathematical model for Sandface flow rateassuming constant wellbore pressure (van Everdingen and Hurst 1949):
qD � 1
s2PwD. (17)
More details for these two models, Eqs. (16) and (17), are given in “Appendix.”The IPRs of the three flow regimes during transient state flow and pseudo-steady-state
IPR are explained as follows.
123
Transient and Pseudo-Steady-State Inflow Performance… 759
3.1 Hydraulic Fracture Linear Flow Regime
This flow regime represents linear fluid flow inside hydraulic fractures toward horizontalwellbore. It is characterized by a slope of (1/2) on pressure derivative curve. The mathemat-ical model, in dimensionless form, of wellbore pressure drop assuming constant Sandfaceflow rate is given by:
PwD � 2√
πωtDFCD
+ s, (18)
while dimensionless flow rate of constant wellbore pressure is:
qD � FCDπ
√πωtD
. (19)
In field units, Eqs. (18) and (19) can be written as:(
qtBt
�Pwf
)
mp� 1
⎡
⎣ 8.126xfhFCD
√ω
ki(kμ
)
mp∅(ct)mp
t + 141.2
ki(kμ
)
mphs
⎤
⎦
, (20)
(qtBt
�Pwf
)
mp� 0.07838h
FCDxf
√ki
(kμ
)
mp√
ω(ct)mp∅ t
, (21)
where (ki) is the induced matrix permeability or the permeability of stimulated porous mediabetween hydraulic fractures. It could bemore than the original reservoir permeability because
of the induced fractures caused by fracturing process, while(kμ
)
mpis the mobility of stim-
ulated porous media.
qt � qoBo + 1000Bg{qsc − (qoRs + qwRsw)} + qwBw, (22)
Bt � Bo + Bg(Rsb − Rs). (23)
Log–log plot of production time versus(
qtBt�Pwf
)
mpgives the IPR of hydraulic fracture
linear flow for the two cases: constant Sandface flow rate and constant wellbore pressure asshown in Fig. 8.
3.2 Bilinear Flow Regime
This flow regime represents simultaneous linear fluid flow from the matrix to the hydraulicfractures and from hydraulic fractures to the horizontal wellbore. It is characterized by a slopeof (1/4) on pressure derivative curve. The mathematical models, in dimensionless form, ofwellbore pressure drop assuming constant Sandface flow rate are given by:
PwD � π
Γ (5/4)√2FCD
4
√tDω
+ s For hydraulic fractureswith fracture conductivity (FCD ≤ 100),
(24)
PwD � 2π
Γ (5/4)√FCD
4
√tDω
+ s For hydraulic fractureswith fracture conductivity (FCD > 100),
(25)
123
760 S. Al-Rbeawi
0.01
0.1
1
10
100
1000
0.01
0.1
1
10
100
1000
00010010111.0
Series1
Series2
Fig. 8 IPR of hydraulic fracture linear flow
while dimensionless flow rates of constant wellbore pressure are:
qD �√FCD/2π
1
4√
tDω
For hydraulic fractureswith fracture conductivity (FCD ≤ 100),
(26)
qD �√FCD/22π
1
4√
tDω
For hydraulic fractureswith fracture conductivity (FCD > 100).
(27)
In field units, Eqs. (24)–(27) can be written, respectively, as:(
qtBt
�Pwf
)
mp� 1
⎡
⎢⎣ 44
h√xfFCD 4
√1
ω∅k3i(kμ
)3
mp(ct)mp
t + 141.2
ki(kμ
)
mphs
⎤
⎥⎦
, (28)
(qtBt
�Pwf
)
mp� 1
⎡
⎢⎣ 62.33
h√xfFCD 4
√1
ω∅k3i(kμ
)3
mp(ct)mp
t + 141.2
k3i
(kμ
)
mphs
⎤
⎥⎦
, (29)
(qtBt
�Pwf
)
mp� 0.0125h
√FCDxf 4
√k3i
(kμ
)3
mp
4√
1ω(ct)mp∅ t
, (30)
(qtBt
�Pwf
)
mp� 0.00626h
√FCDxf 4
√k3i
(kμ
)3
mp
4√
1ω(ct)mp∅ t
. (31)
123
Transient and Pseudo-Steady-State Inflow Performance… 761
1
10
100
1000
1
10
100
1000
00001000100101
Series1
Series2
Fig. 9 IPR of bilinear flow, FCD ≤ 100.0
10
100
1000
10
100
1000
00001000100101
Series1
Series2
Fig. 10 IPR of bilinear flow, FCD > 100.0
The IPRs of bilinear flow for constant Sandface flow rate and constant wellbore pressureare shown in Figs. 9 and 10 for [FCD ≤ 100.0] and [FCD > 100.0], respectively.
3.3 Trilinear Flow Regime
Unconventional reservoirsmay consist of stimulated reservoir volume (SRV)where hydraulicfractures propagate in the porous media and unstimulated reservoir volume (USRV) whereno hydraulic fractures. Trilinear flow regime is observed in this type of reservoirs whereinpetrophysical properties are significantly different in these two volumes. It represents threesimultaneous linear flow regimes. The first is the flow from unstimulated to stimulated reser-
123
762 S. Al-Rbeawi
1.0E-04
1.0E-03
1.0E-02
1.0E-01
1.0E+00
1.0E+01
1.0E+02
1.0E-08 1.0E-06 1.0E-04 1.0E-02 1.0E+00 1.0E+02 1.0E+04 1.0E+06 1.0E+08
Series1
Series2
Fig. 11 Trilinear flow regimes
voir volume. The second is the flow from stimulated reservoir volume to the hydraulicfractures, while the third is the linear flow inside these fractures. It is characterized by aslop of (1/8) on pressure derivative curve. It is always seen after bilinear flow regime andbefore pseudo-steady-state flow or boundary-dominated flow regime as shown in Fig. 11.The mathematical model of pressure drop caused by this flow regime assuming constantSandface flow rate is:
PwD � 2π
Γ (9/8)FCD8
√tDω
+ s, (32)
while dimensionless flow rate for constant wellbore pressure is:
qD � FCDπ
1
8√
tDω
. (33)
In field units, Eqs. (32) and (33) can be written, respectively, as:
(qtBt
�Pwf
)
mp� 1
⎡
⎣ 336
ki(kπ
)
mphFCD
8
√ki
(kπ
)
mp
ω∅x2f (ct)mpt + 141.2
ki(kμ
)
mphs
⎤
⎦
, (34)
(qtBt
�Pwf
)
mp� 0.0265h
FCDki( ku
)mp
8√
tωx2f (ct)mp∅
. (35)
The IPRs of trilinear flow of constant Sandface flow rate and constant wellbore pressureare shown in Fig. 12.
123
Transient and Pseudo-Steady-State Inflow Performance… 763
1
10
100
1000
1
10
100
1000
000001000010001001
Series3
Series4
Fig. 12 IPR of trilinear flow regime
3.4 Pseudo-steady-State (Boundary-Dominated) Flow Regime
Unlike hydraulic fracture linear flow, bilinear flow, and trilinear flow regimes, pseudo-steady-state flow regime (constant Sandface flow rate) or boundary-dominated flow regime (constantwellbore pressure) is characterized by constant productivity index as shown in Fig. 13. Thesetwo flow regimes represent the impact of reservoir boundary on pressure behavior. For con-stant Sandface flow rate, stabilized productivity indexmeans that the pressure drop is constantwith time and pseudo-steady state has been reached, while boundary-dominated flow couldexhibit asymptotically constant productivity index even though production rate and reservoirpressure change with time (Aulisa et al. 2009). The productivity index during pseudo-steady-state flow regimes is given by:
JDq � 1
0.5 ln(
4xeDyeD1.781CAFq
)+ s
, (36)
and during boundary-dominated flow regime, the index is:
JDP � 1
0.5 ln(
4xeDyeD1.781CAFP
)+ s
. (37)
(CAFq
)and (CAFP) in Eqs. (36) and (37) are the shape factors of hydraulically frac-
tured reservoirs for constant Sandface flow rate and constant wellbore pressure, respectively.Figure 14 shows these two shape factors for hydraulically fractures reservoirs.
In field units, Eqs. (36) and (37) can be written as:
(qtBt
�Pwf
)
mp�
ki(kμ
)
mp
141.2
[0.5 ln
(4xeye
1.781CAFqx2f
)] , (38)
123
764 S. Al-Rbeawi
0.1
1
10
100
1000
10000
1.0E-01
1.0E+00
1.0E+01
1.0E+02
1.0E+03
1.0E+04
1.0E-07 1.0E-05 1.0E-03 1.0E-01 1.0E+01 1.0E+03 1.0E+05
Series1
Series2
Fig. 13 Productivity index behavior
1E-18
1E-16
1E-14
1E-12
1E-10
1E-08
1E-06
0.0001
0.01
1
1.0E-18
1.0E-16
1.0E-14
1.0E-12
1.0E-10
1.0E-08
1.0E-06
1.0E-04
1.0E-02
1.0E+00
0 4 8 12 16 20 24 28 32 36
Series1
Series2
Fig. 14 Shape factor of hydraulically fractured reservoirs
(qtBt
�Pwf
)
mp�
k(kμ
)
mp
141.2
[0.5 ln
(4xeye
1.781CAFPx2f
)] . (39)
Even though the two models in Eqs. (38) and (39) include multiphase stimulated reservoir
total mobility(kμ
)
mp, productivity indices are considered constant as the rate of change in
the mobility with pressure at late production time is very minor.
123
Transient and Pseudo-Steady-State Inflow Performance… 765
0.00001
0.0001
0.001
0.01
0.1
1
0.0
10.0
20.0
30.0
40.0
50.0
0.0 1,000.0 2,000.0 3,000.0 4,000.0 5,000.0 6,000.0 7,000.0
Series1
Series2
Fig. 15 Comparison of multiphase flow reservoir total mobility and compressibility for two different reservoirs
4 Application
The proposed approach in this study is applied for two PVT data sets of two different reser-voirs. The first is given in Table 1 (Boe et al. 1989), and the second is given in Table 6(Fraim and Wattenbarger 1988). Analyzing these PVT data and following the methodologypresented in section 2, multiphase flow reservoir total mobility and compressibility given byEqs. (13) and (15) are determined, respectively, for the first reservoir:
(k
μ
)
mp� 8 ∗ 10−7P2 − 0.0079P + 44.9, (40)
(ct)mp � 0.3099P−0.896, (41)
while for the second reservoir:
(k
μ
)
mp� 1.1 ∗ 10−6P2 − 0.0102P + 46.75, (42)
(ct)mp � 0.3164P−0.964. (43)
The above-mentioned four models indicate that multiphase reservoir total mobility andcompressibility may not be significantly affected by reservoir type and reservoir fluid type.Even though two PVT data sets are used only in this study, the conclusion that the behaviorsof multiphase flow reservoir mobility and compressibility with reservoir pressure are similarregardless of reservoir type might be true. This conclusion could be supported by using dif-ferent PVT data sets for different reservoirs, generate the two models of multiphase reservoirmobility and compressibility, and compare them with the models given by Eqs. (40)–(43).Figure 15 depicts the behaviors of the two models of multiphase flow reservoir total mobilityand compressibility with pressure. It can be seen that the two models demonstrate similarbehavior for the two PVT data sets. Therefore, it is quite reasonable using the average val-
123
766 S. Al-Rbeawi
Table 8 Bakken and Eagle Ford formations (Uzun et al. 2014)
Black oil-1Well Bakken formation
Volatile oilWell Eagle Ford formation
Initial reservoir pressure, Pi 7802 psi 8428 psi
Bubble point pressure, Pb 2130 psi 4350 psi
Bottom hole temperature, T 240◦F 269
◦F
Solution gas–oil ratio, Rs 850 SCF/STB 1112 SCF/STB
Oil formation volume factor, Bo 1.61RBBL/STB 1.56RBBL/STB
Water formation volume, Bw 1.04RBBL/STB 1.04RBBL/STB
Gas formation volume factor, Bg 0.9RBBL/MScf 0.55RBBL/MScf
Oil viscosity, μo 0.39 cp 0.29 cp
Formation water viscosity, μw 1.0 cp 1.0 cp
Gas viscosity, μg 0.01 cp 0.034 cp
Spacing between stages 587 ft 297 ft
No. of stages 15 16
Wellbore length, L 8800 ft 5860 ft
Formation thickness, h 49.5 ft 120 ft
Well spacing 1320 ft 700 ft
Porosity 0.055 0.055
Estimated hydraulic fracture half-length, xf 396 ft 146 ft
Total compressibility, ct 1 ∗ 10−5 psi−1 1.38 ∗ 10−5 psi−1
Matrix permeability,km 6.27 ∗ 10−4 md 0.5 ∗ 10−6 md
Natural fracture permeability, kf 5.9 ∗ 10−3 md
Hydraulic fracture permeability, khf 600 md 600 md
Hydraulic fracture width, wf 0.25 in 0.25 in
ues of the two models obtained from the two PVT data sets for calculating multiphase totalmobility and compressibility of other reservoirs. These two models can be written as:
(k
μ
)
mp� 9.7 ∗ 10−7P2 − 0.009P + 46.0, (44)
(ct)mp � 0.313P−0.93. (45)
The proposedmodels ofmultiphase flow reservoir totalmobility and compressibility givenby Eqs. (44) and (45) can be used in predicting transient and pseudo-steady-state IPRs of dif-ferent reservoirs. To examine these two models, two hydraulically fractured unconventionalreservoirs are considered in this study. The first is the Bakken formation located in WillistonBasin in North Dakota, USA, and the second is the Eagle Ford formation in Texas, USA.The available information for these two formations is given in Table 8 (Uzun et al. 2014).Dimensionless parameters of these two reservoirs are calculated and given in Table 9.
Dimensionless pressure and pressure derivative of Bakken and Eagle Ford formations arecalculated using dimensionless parameters given in Table 9 and plotted as shown in Fig. 16,while dimensionless flow rate behavior is calculated and plotted as shown in Fig. 17. Transientand pseudo-steady-state productivity index of the two reservoirs in dimensionless form is
123
Transient and Pseudo-Steady-State Inflow Performance… 767
Table 9 Dimensionless parameters
Black oil-1 wellBakken formation
Volatile oil wellEagle Ford formation
xeD 1.667 2.4
yeD 0.741 1.017
FCD 5.35 14.51
ω 1000 1000
λ 100 100
RCD 12.7 1.16 ∗ 104
wD 5.26 ∗ 10−5 1.427 ∗ 10−4
ηFD 1.017 ∗ 10−5 1.017 ∗ 105
ηmD 0.1063 8.474 ∗ 10−5
1.0E-04
1.0E-03
1.0E-02
1.0E-01
1.0E+00
1.0E+01
1.0E+02
1.0E-08 1.0E-06 1.0E-04 1.0E-02 1.0E+00 1.0E+02 1.0E+04 1.0E+06 1.0E+08 1.0E+10
Series3
Series4
Fig. 16 Pressure and pressure derivative behavior of Bakken and Eagle Ford formations
calculated for the twowellbore conditions, constant Sandface flow rate and constant wellborepressure, and plotted in Fig. 18. Four flow regimes are observed for the two reservoirs:Hydraulic fracture linear flow, bilinear flow, trilinear flow, and pseudo-steady-state flowregime.
To validate the proposed models of multiphase flow properties, bottom hole flowing pres-sure of the two wells, black oil well-1 (Bakken formation) and volatile oil well (Eagle Fordformation), is calculated as follows:
1. For each pressure step, the following parameters are calculated:
Bo Bg Bw Rs Rsw.
123
768 S. Al-Rbeawi
1.0E-01
1.0E+00
1.0E+01
1.0E+02
1.0E+03
1.0E+04
1.0E-08 1.0E-06 1.0E-04 1.0E-02 1.0E+00 1.0E+02 1.0E+04 1.0E+06 1.0E+08
Series1
Fig. 17 Flow rate behavior
1.0E+00
1.0E+01
1.0E+02
1.0E+03
1.0E+04
1.0E+00
1.0E+01
1.0E+02
1.0E+03
1.0E+04
1.0E-08 1.0E-06 1.0E-04 1.0E-02 1.0E+00 1.0E+02 1.0E+04 1.0E+06 1.0E+08
Series3
Series1
Fig. 18 Transient and pseudo-steady-state productivity index behaviors
It is important to emphasize that oil formation volume factor (Bo) and solution gas oil–oilratio (Rs) are determined by the following two models, respectively:
Bo � aP2 + bP + c, (46)
Rs � aP2 + bP + c, (47)
where (a), (b), and (c) are determined from PVT data. For PVT data given in Table 1,these two relationships are plotted in Fig. 19, while water formation volume factor (Bw) andsolution gas–water ratio (Rsw) are calculated using the mathematical models presented in the
123
Transient and Pseudo-Steady-State Inflow Performance… 769
Bo = 1E-08P2 + 5E-05P + 1.0497R² = 1
Rs = 2E-05P2 + 0.1333P + 27.227R² = 0.9999
0
200
400
600
800
1000
1200
1400
1600
1
1.1
1.2
1.3
1.4
1.5
1.6
1.7
1.8
1.9
0 1000 2000 3000 4000 5000 6000
Series1
Series2
Fig. 19 Oil formation volume factor and solution gas–oil ratio
Bw = -7E-09P2 - 4E-06P + 1.039R² = 1
Rsw = -9E-08P2 + 0.0022P+ 0.7883R² = 1
0
2
4
6
8
10
12
0.60
0.65
0.70
0.75
0.80
0.85
0.90
0.95
1.00
1.05
1.10
0 1000 2000 3000 4000 5000 6000
Fig. 20 Water formation volume factor and solution gas–water ratio
literature, Eqs. (9) and (10), and plotted in Fig. 20. Similarly, gas formation volume factor iscalculated and plotted in Fig. 21.
2. Calculate total flow rate (qt ) using Eq. (22) and total formation volume factor (Bt) usingEq. (23).
3. Calculate multiphase reservoir total compressibility (ct)mp using Eq. (45).4. Calculate multiphase reservoir total mobility using Eq. (44).5. Calculate wellbore pressure drop (�Pwf) by:
123
770 S. Al-Rbeawi
Bg = 2.9481x-0.997
R² = 0.9937
0.000
0.005
0.010
0.015
0.020
0 1000 2000 3000 4000 5000 6000
Fig. 21 Gas formation volume factor
Fig. 22 Comparison for bottom hole flowing pressure; a Bakken formation and b Eagle Ford formation
�Pwf � 141.2(qtBt)PwD
km(kμ
)
mp
, (48)
where (PwD) is dimensionless wellbore pressure drop calculated by Eq. (16) for differentdimensionless production times.
6. Real production time is calculated from dimensionless production time by:
t � ∅(ct)mpx2f tD
0.0002637km(kμ
)
mp
. (49)
The calculated bottom hole flowing pressure is plotted and compared with the pressurerecords of the two reservoirs. Excellent matching is obtained as shown in Fig. 22.
123
Transient and Pseudo-Steady-State Inflow Performance… 771
0
1000
2000
3000
4000
5000
6000
0 200 400 600 800 1000 1200 1400 1600 1800 2000
Fig. 23 The IPR for different flow regimes—Bakken formation
0500
1000150020002500300035004000450050005500600065007000750080008500
0 500 1000 1500 2000 2500 3000
Fig. 24 The IPR for different flow regimes—Eagle Ford formation
The IPRs of Bakken and Eagle Ford reservoirs assuming constant Sandface flow rate fordifferent flow regimes are plotted in Figs. 23 and 24, respectively. The starting time of eachflow regime is determined using Eq. (49). The following points are inferred from these twoplots:
1. The productivity of Eagle Ford formation for the same pressure drop is better than ofBakken formation.
2. It takes longer time in Eagle Ford formation to reach pseudo-steady-state flow comparedwith Bakken formation because Eagle Ford formation has ultralow matrix permeability
123
772 S. Al-Rbeawi
(km � 0.5 ∗ 10−6 md
)less than the one in Bakken formation
(km � 6.27 ∗ 10−4 md
).
Similar thing is observed for all flow regimes.3. Trilinear flow regime dominates fluid flow in Eagle Ford formation longer than in Bakken
formation as the fracture half-length is shorter than the fracture half-length of Bakkenformation.
5 Conclusions
1. Multiphase flow may have significant impact on pressure heavier, decline rate pattern,and productivity index as well as inflow performance relationship of reservoirs regardlessthe inner boundary condition of the wellbore whether it is constant Sandface flow rate orconstant wellbore pressure.
2. Multiphase reservoir total mobility and compressibility significantly change with reser-voir pressure. Reservoir compressibility demonstrates more changes than the mobilityespecially at low reservoir pressure; however, it shows more steady-state changes at highreservoir pressure compared with the mobility.
3. Multiphase reservoir total mobility and compressibility show similar behavior for dif-ferent reservoirs and different reservoir fluids. Therefore, very slight differences in themathematical models of these two parameters are seen for different PVT data sets.
4. Multiphase flow may not have significant impact on the inflow performance relationshipat late production time when pseudo-steady-sate or boundary-dominated flow regime isthe dominant flow pattern.
5. There is no significant difference between the constant Sandface flow rate and constantwellbore pressure conditions; however, the inflow performance relationship of constantSandface flow rate is better than of constant wellbore pressure.
Appendix
Consider the formation shown in Fig. 25 where multiple hydraulic fractures propagate in thestimulated reservoir volume (SRV). The formation could have also unstimulated part (USRV)where the stimulation process does not have any impact on the porous media. Formationboundaries are indicated by (2xe, 2ye) and fracture half-length is (xf). Hydraulic fracturesconsidered fully penetrate the formation, i.e., hydraulic fracture height is considered equalto the formation thickness. Stimulated and unstimulated reservoir volumes and hydraulicfracture dimensions are depicted in Fig. 26.
Fig. 25 Schematic drawing for a hydraulically fractured reservoir
123
Transient and Pseudo-Steady-State Inflow Performance… 773
Fig. 26 Stimulated and unstimulated reservoir volumes and hydraulic fracture dimensions
Wellbore pressure drop, in dimensionless form, assuming constant Sandface flow rate isgiven by (Brown et al. 2011; Ozkan et al. 2011):
PwD � π
sFCD√AF tanh
(√AF
) , (50)
while the mathematical model for dimensionless Sandface flow rate assuming constant well-bore pressure is given by (van Everdingen and Hurst 1949):
qD � 1
s2PwD, (51)
where
FCD � kfwf
kixf. (52)
The assumptions used in developing the mathematical models given by (50) and (51) are:
123
774 S. Al-Rbeawi
1. Constant porosity and uniform reservoir thickness.2. Symmetrically distributed hydraulic fractureswith symmetrical hydraulic fracture dimen-
sions.3. Fractures fully penetrate the formation in the vertical direction.
Initial reservoir conditions are:
PD(xD, yD, tD � 0.0) � PDi, (53)
while reservoir inner and outer boundary conditions are:
∂PD∂xD
∣∣∣∣xD�xeD
� 0.0, (54)
∂PwD∂xD
∣∣∣∣xD�0.0
� π
sFCD. (55)
The parameter (AF) refers to the configurations of the stimulated and unstimulated reser-voir volumes in addition to the petrophysical properties of the two volumes. Mathematically,this parameter is written:
AF � 2BF
FCD+
s
ηfD, (56)
where
BF � √Ar tanh
[√Ar(yeD − wD/2)
], (57)
Ar � Br
RCDyeD+ s f (s), (58)
Br �√
s
ηmDtanh
[√s
ηmD(xeD − 1)
], (59)
RCD � ki xfkmye
, (60)
ηmD � ηm
ηi, (61)
ηfD � ηf
ηi, (62)
xeD � xexf
, (63)
yeD � yexf
, (64)
wD � wf
xf, (65)
PD �ki
(kμ
)
mph�P
141.2(qtBt), (66)
tD �0.000263ki
(kμ
)
mpt
(∅ct)fx2f. (67)
123
Transient and Pseudo-Steady-State Inflow Performance… 775
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