In this paper, a pragmatic and consistent framework has been developed and validated to accurately predict reservoir performance in tight sandstone reservoirs by coupling the dynamic capillary pressure with gas production models. Theoretically, the concept of pseudo-mobile water saturation, which is defined as the water saturation between irreducible water saturation and cutoff water saturation, is proposed to couple dynamic capillary pressure and stress-induced permeability to form an equation matrix that is solved by using the implicit pressure and explicit saturations (IMPES) method. Compared with the conventional methods, the newly developed model predicts a lower cumulative gas production but a higher reservoir pressure and a higher flowing bottomhole pressure at the end of the stable period. Physically, a higher gas production rate induces a greater dynamic capillary pressure, while both cutoff water saturation and stress-induced permeability impose a similar impact on the dynamic capillary pressure, though the corresponding degrees are varied. Due to the dynamic capillary pressure, pseudo-mobile water saturation controlled by the displacement pressure drop also affects the gas production. The higher the gas production rate is, the greater the effect of dynamic capillary pressure on the cumulative gas production, formation pressure, and flowing bottomhole pressure will be. By taking the dynamic capillary pressure into account, it can be more accurate to predict the performance of a gas reservoir and the length of stable production period, allowing for making more reasonable development schemes and thus improving the gas recovery in a tight sandstone reservoir.
References
1.
Yang
, T.
, Zhang
, G.
, Liang
, K.
, Zheng
, M.
, and Guo
, B.
, 2012
, “The Exploration of Global Tight Sandstone Gas and Forecast of the Development Tendency in China
,” Eng. Sci.
, 14
(6
), pp. 64
–68
.2.
Rushing
, J. A.
, Newsham
, K. E.
, Van Fraassen
, K. C.
, Mehta
, S. A.
, and Moore
, G. R.
, 2008
, “Laboratory Measurements of Gas-Water Interfacial Tension at HP/HT Reservoir Conditions
,” CIPC/SPE Technology Symposium Joint Conference
, Calgary, AB, June 16-19, SPE Paper No. 114516
.3.
Tsakiroglou
, C.
, Ioannidis
, M.
, Amirtharaj
, E.
, and Vizika
, O.
, 2009
, “A New Approach for the Characterization of the Pore Structure of Dual Porosity Rocks
,” Chem. Eng. Sci.
, 64
(5
), pp. 847
–859
.4.
Rashid
, F.
, Glover
, P.
, Lorinczi
, P.
, Collier
, R.
, and Lawrence
, J.
, 2015
, “Porosity and Permeability of Tight Carbonate Reservoir Rocks in the North of Iraq
,” J. Pet. Sci. Eng.
, 133
(9), pp. 147
–161
.5.
Xi
, K.
, Cao
, Y.
, Haile
, B. J.
, Zhu
, R.
, Jahern
, J.
, Bjørlykke
, K.
, Zhang
, X.
, and Hellevang
, H.
, 2016
, “How Does the Pore-Throat Size Control the Reservoir Quality and Oiliness of Tight Sandstones? the Case of the Lower Cretaceous Quantou Formation in the Southern Songliao Basin, China
,” Mar. Pet. Geol.
, 76
, pp. 1
–15
.6.
Zhang
, S.
, Xian
, X.
, Zhou
, J.
, Liu
, G.
, Guo
, Y.
, Zhao
, Y.
, and Lu
, Z.
, 2018
, “Experimental Study of the Pore Structure Characterization in Shale With Different Particle Size
,” ASME J. Energy Resour. Technol.
, 140
(5
), p. 054502
.7.
Zhao
, M.
, Zhao
, X.
, and Yang
, D.
, 2018
, “Preparation and Characterization of Chemical Agents for Augmenting Injectivity in Low Permeability Reservoirs
,” ASME J. Energy Resour. Technol.
, 140
(3
), p. 032914
.8.
Golf-Racht
, T. V.
, 1974
, “Gas Production and Interference Effects
,” SPE-European Spring Meeting of AIME
, Amsterdam, The Netherland, May 29–30, SPE Paper No. 4833
.9.
Rahman
, M. M.
, Rahman
, M. K.
, and Rahman
, S. S.
, 2002
, “An Analytical Model for Production Estimation From Hydraulically Fractured Tight-Gas Reservoirs
,” SPE Asia Pacific Oil and Gas Conference and Exhibition
, Melbourne, Australia, Oct. 8–10, SPE Paper No. 77901
.10.
Yuan
, H.
, Bhuiyan
, M.
, and Xu
, J. F.
, 2012
, “A Case Study to Evaluate Shale Gas Performance Models With Actual Well Production Data
,” SPE Canadian Unconventional Resources Conference
, Calgary, AB, Oct. 30–Nov. 1, SPE Paper No. 162598
.11.
Cheng
, C.
, and Li
, K.
, 2014
, “Comparison of Models Correlating Cumulative Oil Production and Water Cut
,” ASME J. Energy Resour. Technol.
, 136
(3
), p. 032901
.12.
Hassanizadeh
, S.
, Celia
, M.
, and Dahle
, H.
, 2002
, “Dynamic Effect in the Capillary Pressure-Saturation Relationship and Its Impact on Unsaturated Flow
,” Vadose Zone J.
, 1
(2
), pp. 38
–57
.13.
Hassanizadeh
, S.
, and Gray
, W.
, 1993
, “Thermodynamic Basis of Capillary Pressure in Porous Media
,” Water Resour. Res.
, 29
(10
), pp. 3389
–3405
.14.
Abreu
, E.
, and Viera
, J.
, 2017
, “Computing Numerical Solutions of the Pseudo-Parabolic Buckley–Leverett Equation With Dynamic Capillary Pressure
,” Math. Comput. Simul.
, 137
, pp. 29
–48
.15.
El-Amin
, M. F.
, 2017
, “Stability Analysis of the Modified IMPES Scheme for Two-Phase Flow in Porous Media Including Dynamic Pressure
,” Procedia Comput. Sci.
, 108C
, pp. 2328
–2332
.16.
Hsu
, S. Y.
, Huang
, V.
, Park
, S. W.
, and Hilpert
, M.
, 2017
, “Water Infiltration Into Prewetted Porous Media: Dynamic Capillary Pressure and Green-AMPT Modeling
,” Adv. Water Resour.
, 106
, pp. 60
–67
.17.
Zhang
, H.
, and Zegeling
, P. A.
, 2017
, “Numerical Investigations of Two-Phase Flow With Dynamic Capillary Pressure in Porous Media Via a Moving Mesh Method
,” J. Comput. Phys.
, 345
, pp. 510
–527
.18.
Abbasi
, J.
, Ghaedi
, M.
, and Riazi
, M.
, 2018
, “A New Numerical Approach for Investigation of the Effects of Dynamic Capillary Pressure in Imbibition Process
,” J. Pet. Sci. Eng.
, 162
, pp. 44
–54
.19.
Milišic
, J. P.
, 2018
, “The Unsaturated Flow in Porous Media With Dynamic Capillary Pressure
,” J. Differential Equations
, 264
(9
), pp. 5629
–5658
.20.
Zhou
, Y.
, Helland
, J.
, and Jettestuen
, E.
, 2013
, “Dynamic Capillary Pressure Curves From Pore-Scale Modeling in Mixed-Wet-Rock Images
,” SPE J.
, 15
(4
), pp. 634
–645
.21.
Liu
, G.
, Bai
, Y.
, Gu
, D.
, Lu
, Y.
, and Yang
, D.
, 2018
, “Determination of Static and Dynamic Characteristics of Microscopic Pore-Throat Structure in a Tight Oil-Bearing Sandstone Formation
,” AAPG Bull.
, 102
(9
), pp. 1867
–1892
.22.
Zhang
, H.
, He
, S.
, Jiao
, C.
, Luan
, G.
, Mo
, S.
, and Lei
, G.
, 2015
, “Investigation of Dynamic Effect of Capillary Pressure in Ultra-Low Permeability Sandstones
,” Indian Geotech. J.
, 45
(1
), pp. 79
–88
.23.
Kalaydjian
, F.
, 1992
, “Dynamic Capillary Pressure Curve for Water/Oil Displacement in Porous Media: Theory vs. Experiment
,” 67th SPE Annual Technical Conference and Exhibition
, Washington, DC, Oct. 4–7, SPE Paper No. 24813
.24.
Fan
, Z.
, Cheng
, L.
, Yang
, D.
, and Li
, X.
, 2018
, “Optimization of Well Pattern Parameters for Waterflooding in an Anisotropic Formation
,” Math. Geosci.
(epub).25.
Tian
, L.
, Yang
, D.
, Zheng
, S.
, Wang
, D.
, and Feng
, B.
, 2018
, “Parametric Optimization of Vector Well Patterns for Hydraulically Fractured Horizontal Wells in Tight Sandstone Reservoirs
,” J. Pet. Sci. Eng.
, 162
, pp. 469
–479
.26.
Topp
, G. C.
, Klute
, A.
, and Peters
, D. B.
, 1967
, “Comparison of Water Content-Pressure Head Data Obtained by Equilibrium, Steady-State, and Unsteady-State Methods
,” Soil Sci. Soc. Am. J.
, 31
(3
), pp. 312
–314
.27.
Gray
, W. G.
, and Hassanizadeh
, S. M.
, 1991
, “Unsaturated Flow Theory Including Interfacial Phenomena
,” Water Resour. Res.
, 27
(8
), pp. 1855
–1863
.28.
Stauffer
, F.
, 1978
, “Time Dependence of the Relations Between Capillary Pressure, Water Content and Conductivity During Drainage of Porous Media
,” International Association of Hydraulic Engineering and Research
, pp. 335
–352
.29.
Brooks
, R.
, and Corey
, A.
, 1964
, Hydraulic Properties of Porous Media
, Colorado State University
, Fort Collins, CO
.30.
Wildenschild
, D.
, Hopmans
, J.
, and Simunek
, J.
, 2001
, “Flow Rate Dependence of Soil Hydraulic Characteristics
,” Soil Sci. Soc. Am. J.
, 65
(1
), pp. 35
–48
.31.
Abidoye
, L. K.
, and Das
, D. B.
, 2014
, “Scale Dependent Dynamic Capillary Pressure Effect for Two-Phase Flow in Porous Media
,” Adv. Water Resour.
, 74
, pp. 212
–230
.32.
Das
, D.
, and Mirzaei
, M.
, 2013
, “Experimental Measurement of Dynamic Effect in Capillary Pressure Relationship for Two-Phase Flow in Weakly Layered Porous Media
,” AIChE J.
, 59
(5
), pp. 1723
–1734
.33.
Tian
, S.
, Lei
, G.
, He
, S.
, and Yang
, L.
, 2012
, “Dynamic Effect of Capillary Pressure in Low Permeability Reservoirs
,” Pet. Explor. Dev.
, 39
(3
), pp. 378
–384
.34.
Zhu
, W.
, Song
, H.
, and He
, D.
, 2008
, “Low-Velocity non-Darcy Gas Seepage Model and Productivity Equations of Low-Permeability Water-Bearing Gas Reservoirs
,” Nat. Gas Geosci.
, 19
(5
), pp. 685
–689
.35.
Das
, D.
, and Mirzaei
, M.
, 2012
, “Dynamic Effects in Capillary Pressure Relationships for Two-Phase Flow in Porous Media: Experiments and Numerical Analyses
,” AIChE J.
, 58
(12
), pp. 3891
–3903
.36.
Boulon
, M.
, Selvadurai
, A.
, Benjelloun
, H.
, and Feuga
, B.
, 1993
, “Influence of Rock Joint Degradation on Hydraulic Conductivity
,” Int. J. Rock Mech. Min. Sci. Geomech. Abstr.
, 30
(7
), pp. 1311
–1317
.37.
Yang
, M.
, 2004
, “The Study of Oil-Gas Reservoir Porosity Medium's Deformation Theory and Applications
,” Ph.D. dissertation, Southwest Petroleum University, Chengdu, China.38.
Dykstra
, H.
, and Parsons
, R.
, 1950
, “The Prediction of Oil Recovery by Water Flood
,” Second Recovery Oil United States
, Vol. 160
, pp. 160
–174
.39.
Yi
, J.
, 2014
, “Water Production Modeling and Water Control Strategy for Gas Wells in Tight Gas Reservoirs: Eastern Sulige Gas Reservoir
,” M.Sc. thesis, China University of Petroleum-Beijing, Beijing, China.40.
Kou
, J.
, and Sun
, S.
, 2010
, “A New Treatment of Capillarity to Improve the Stability of IMPES Two-Phase Flow Formulation
,” Comput. Fluids
, 39
(10
), pp. 1923
–1931
.41.
Redondo
, C.
, Rubio
, G.
, and Valero
, E.
, 2018
, “On the Efficiency of the IMPES Method for Two Phase Flow Problems in Porous Media
,” J. Pet. Sci. Eng.
, 164
, pp. 427
–436
.42.
Zhang
, F.
, and Yang
, D.
, 2017
, “Effects of non-Darcy Flow and Penetrating Ratio on Performance of Horizontal Wells With Multiple Fractures in a Tight Formation
,” ASME J. Energy Resour. Technol.
, 140
(3
), p. 032903
.43.
Aziz
, K.
, and Settari
, A.
, 1979
, Petroleum Reservoir Simulation
, Elsevier Applied Science Publishers
, New York
.44.
Wu
, Y.
, Moridis
, G.
, Bai
, B.
, and Zhang
, K.
, “A Multi-Continuum Model for Gas Production in Tight Fractured Reservoirs
,” SPE Hydraulic Fracturing Technology Conference
, Woodlands, TX, Jan. 19–21, SPE Paper No. 118944
.45.
Lekia
, S. D. L.
, and Evans
, R. D.
, 1990
, “A Water-Gas Relative Permeability Relationship for Tight Gas Sand Reservoirs
,” ASME J. Energy Resour. Technol.
, 112
(4
), pp. 239
–245
.46.
Zhang
, F.
, and Yang
, D.
, 2014
, “Determination of Fracture Conductivity in Tight Formations With non-Darcy Flow Behaviour
,” SPE J.
, 19
(1
), pp. 34
–44
.47.
Yang
, D.
, Zhang
, F.
, Styles
, J. A.
, and Gao
, J.
, 2015
, “Performance Evaluation of a Horizontal Well With Multiple Fractures by Use of a Slab-Source Function
,” SPE J.
, 20
(3
), pp. 652
–662
.48.
You
, L.
, Kang
, Y.
, Chen
, Y.
, Cheng
, Q.
, and You
, H.
, 2006
, “Stress Sensitivity of Fractured Tight Gas Sands in Consideration of Fractures and Water Saturation
,” J. China Univ. Pet. (Nat. Sci. Ed.)
, 30
(2
), pp. 59
–63
.49.
Yang
, D.
, Zhang
, Q.
, Fan
, L.
, and Feng
, Y.
, 1999
, “Inflow Performance of Horizontal Wells in Naturally Fractured Reservoirs
,” J. Univ. Pet. (Nat. Sci. Ed.)
, 23
(6
), pp. 44
–49
.50.
Chen
, S.
, Li
, H.
, Zhang
, Q.
, and Yang
, D.
, 2008
, “A New Technique for Production Prediction in Stress-Sensitive Reservoirs
,” J. Can. Pet. Technol.
, 47
(3
), pp. 49
–54
.51.
Zhou
, D.
, 2006
, “Study on the Relationship Between Irreducible Water Saturation and Critical Water Saturation
,” Pet. Geol. Recovery Efficiency
, 13
(6
), pp. 81
–83
.52.
Samstag
, F. J.
, and Morgan
, F. D.
, “Effective Medium Approach to Critical Saturation
,” SEG Annual Meeting
, Houston, TX, Nov. 10–14, SEG Paper No. 1991-0152
https://library.seg.org/doi/abs/10.1190/1.1888999.53.
Bassiouni
, Z.
, 1994
, “Theory, Measurement, and Interpretation of Well Logs
,” Society of Petroleum Engineers (SPE)
, Richardson, TX, pp. 1–24.54.
Alamooti
, A. M.
, Ghazanfari
, M. H.
, and Masihi
, M.
, 2018
, “Investigating the Relative Permeability Behavior in Presence of Capillary Effects in Composite Core Systems
,” J. Pet. Sci. Eng.
, 160
, pp. 341
–350
.55.
Chen
, W.
, 2014
, “Methods to Evaluate Formation Pressure in the Sulige Gas Field
,” M.Sc. thesis, Xi'an Shiyou University, Xi'an, China.56.
Zhang
, Z.
, 2015
, “Well Management and Dynamic Analysis of Eastern Sulige Gas Field
,” M.Sc. thesis, Xi'an Shiyou University, Xi'an, China.57.
Huang
, W.
, Guo
, P.
, Jiang
, Y.
, and Bi
, J.
, 2005
, “Experimental Study on Movable Water in Qiaobai Gas Reservoir
,” Nat. Gas Explor. Dev.
, 28
(2
), pp. 39
–42
.58.
Yang
, Z.
, Jiang
, H.
, Zhu
, G.
, Li
, S.
, and Shan
, W.
, 2008
, “Research on Reservoir Evaluation Index for Low-Permeability Water-Bearing Gas Reservoir
,” Acta Petrolei Sin.
, 29
(2
), pp. 252
–255
.59.
Zhang
, Y.
, Li
, H.
, and Yang
, D.
, 2012
, “Simultaneous Estimation of Relative Permeability and Capillary Pressure Using Ensemble-Based History Matching Techniques
,” Transp. Porous Media
, 94
(1
), pp. 259
–276
.60.
Zhang
, Y.
, Yang
, D.
, and Song
, C.
, 2016
, “A Damped Iterative EnKF Method to Estimate Relative Permeability and Capillary Pressure for Tight Formations From Displacement Experiments
,” Fuel
, 167
(5
), pp. 306
–315
.61.
Zhang
, Y.
, Fan
, Z.
, Yang
, D.
, Li
, H.
, and Patil
, S.
, 2017
, “Simultaneous Estimation of Relative Permeability and Capillary Pressure for PUNQ-S3 Model With a Damped Iterative-ensemble-Kalman-Filter Technique
,” SPE J.
, 22
(3
), pp. 971
–984
.62.
Zhang
, Y.
, and Yang
, D.
, 2013
, “Simultaneous Estimation of Relative Permeability and Capillary Pressure for Tight Formations Using Ensemble-Based History Matching Method
,” Comput. Fluids
, 71
(1
), pp. 446
–460
.63.
Elzeftawy
, A.
, and Mansell
, R.
, 1975
, “Hydraulic Conductivity Calculations for Unsaturated Steady-State and Transient-State Flow in Sands
,” Soil Sci. Soc. Am. J.
, 39
(4
), pp. 599
–603
.64.
Wanna-Etyem
, C.
, 1982
, “Static and Dynamic Water Content-Pressure Head Relations of Porous Media
,” Ph.D. dissertation, Colorado State University, Fort Collins, CO.65.
Kalaydjian
, F.
, 1987
, “A Macroscopic Description of Multiphase Flow in Porous Media Involving Space-Time Evolution of Fluid-Fluid Interfaces
,” Transp. Porous Media
, 2
(6
), pp. 537
–552
.66.
Hollenbeck
, K.
, and Jensen
, K.
, 1998
, “Experimental Evidence of Randomness and Non-Uniqueness in Unsaturated Outflow Experiments Designed for Hydraulic Parameter Estimation
,” Water Resour. Res.
, 34
(4
), pp. 595
–602
.67.
Wang
, X.
, and Alvarado
, V.
, 2017
, “Effects of Low-Salinity Waterflooding on Capillary Pressure Hysteresis
,” Fuel
, 207
(1
), pp. 336
–343
.68.
Archer
, R. A.
, 2008
, “Impact of Stress Sensitive Permeability on Production Data Analysis
,” SPE Unconventional Reservoirs Conference
, Keystone, CO, Feb. 10–12, SPE Paper No. 114166
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