Numerical Simulation and Production Decline Analysis of Multiply Fractured Horizontal Wells in Shale Gas Reservoirs
Abstract
Multiply fractured horizontal wells (MFHWs) have been widely applied into shale gas production recently. Thus, analyzing well performances, in particular of production decline analysis of MFHWs is important for exploiting shale gas reservoirs effectively. There are various analytical and numerical methods which have been employed to investigate pressure transient or well productivity of MFHWs in shale reservoirs. However, most of them are not good enough to accurately predict fluid flow behaviors of shale gas by applying the modified Darcy’s law and oversimplified facture models.
Based on the Dusty-Gas Model and Langmuir isotherm equation, a set of equations that can govern gas flow in shale matrix is firstly derived in this work. In these equations, desorption of adsorbed gas, diffusion and convective flow are considered. A numerical model is constructed by applying the perpendicular bisection (PEBI) grids to discretize the flowing equations. This model is proposed to investigate the effects of hydraulic fractures and shale reservoir properties on gas production. The simulation results show that (1) desorption of adsorbed gas increases the gas rate and prolongs each flow period, (2) diffusivity and matrix permeability mainly affect the appearance of compound linear flow period, (3) the larger the simulation reservoir volume is, the longer the formation linear flow lasts. In addition, this study also indicates that the optimized number of fractures and fractures with larger conductivity leads to increased well production. The proposed numerical model presents a new way to numerically simulate and analyze the production decline of multiply fractured horizontal shale gas wells.References
Amann-Hildenbrand, A., Ghanizadeh, A., Krooss, B.M.: Transport properties of unconventional gas systems. Mar. Petrol. Geol. 31(1), 90–99 (2012). doi:10.1016/j.marpetgeo.2011.11.009
Curtis, J.B.: Fractured shale-gas systems. AAPG bulletin, 86(11), 1921–1938 (2002)
Bumb, A.C., McKee, C.R.: Gas-well testing in the presence of desorption for coalbed methane and Devonian shale. SPE Formation Evaluation, 3(1), 179–185 (1988). doi:10.2118/15227-PA
Mengal, S.A., Wattenbarger, R.A.: Accounting for adsorbed gas in shale gas reservoirs. SPE Paper 141085 presented at SPE Middle East Oil and Gas Show and Conference, Manama, Bahrain, 25–28 September 2011. doi:10.2118/141085-MS
Swami, V., Settari, A.: A pore scale gas flow model for shale gas reservoir. SPE Paper 155756 presented at SPE Americas Unconventional Resources Conference, Pittsburgh, Pennsylvania, 5–7 June 2012. doi:10.2118/155756-MS
Thorstenson, D.C., Pollock, D.W.: Gas transport in unsaturated porous media: The adequacy of Fick's law. Rev. Geophys. 27(1): 61–78 (1989)
Webb, S.W.: Gas-phase diffusion in porous media-evaluation of an advective-dispersive formulation and the dusty-gas model for binary mixtures. J. Porous Media 1, 187–199 (1998)
Jaynes, D.B., Rogowski A.S.: Applicability of Fick's law to gas diffusion. Soil Sci. Soc. Am. J. 47(3), 425–430 (1983)
Webb, S.W., Pruess, K.: The use of Fick’s law for modeling trace gas diffusion in porous media. Transp. Porous Med. 51, 327–341 (2003)
Evans III, R.B., Watson G.M., Mason E.A.: Gaseous diffusion in porous media at uniform pressure. J. Chem. Phys. 35, 2076–2083 (1961)
Evans III, R.B., Watson G.M., Mason E.A.: Gaseous diffusion in porous media. II. Effect of pressure gradients. J. Chem. Phys. 36, 1894–1902 (1962)
Chapman, S., Cowling, T.G.: The mathematical theory of non-uniform gases: an account of the kinetic theory of viscosity, thermal conduction and diffusion in gases. Cambridge University Press, Cambridge, (1970)
Cunningham, R.E., Williams, R.J.J.: Diffusion in gases and porous media. New York: Plenum press, (1980)
Mason, E.A., Malinauskas, A.P.: Gas transport in porous media: The dusty-gas model. Elsevier, Amsterdam, Netherlands (1983)
Van Kruysdijk, C., Dullaert, G.M.: A boundary element solution to the transient pressure response of multiple-fractures horizontal wells. Paper presented at the 1st European Conference on the Mathematics of Oil Recovery, Cambridge, England, July 1989
Guo, B., Yu, X.: A simple and accurate mathematical model for predicting productivity of multifractured horizontal wells. Paper SPE 114452 presented at CIPC/SPE Gas Technology Symposium 2008 Joint Conference, Calgary, Alberta, Canada, 16–19 June 2008
Medeiros, F., Ozkan, E., Kazemi, H.: Productivity and drainage area of fractured horizontal wells in tight gas reservoirs. SPE Reserv. Eval. Eng. 11(05), 902–911 (2008)
Guo, J., Zhang, L., Wang, H., Feng, G.: Pressure transient analysis for multi-stage fractured horizontal wells in shale gas reservoirs. Transp. Porous Med. 93(3), 635–653 (2012). doi:10.1007/s11242-012-9973-4
Cheng, Y.: Pressure transient characteristics of hydraulically fractured horizontal shale gas wells: Paper SPE 149311 presented at SPE Eastern Regional Meeting, Columbus, Ohio, USA, 17–19 August 2011. doi: 10.2118/149311-MS
Freeman, C.M., Moridis, G., Ilk, D., Blasingame, T.A.: A numerical study of performance for tight gas and shale gas reservoir systems. J. Petrol. Sci. Eng. 108, 22–39, (2013)
An, Y., Wu, X., Gao, D.: On the use of PEBI grids in the numerical simulations of two-phase flows in fractured horizontal wells. Comp. Model. Eng. 89(2), 123–141 (2012)
Abu-El-Sha’r, W., Abriola, L.M.: Experimental assessment of gas transport mechanisms in natural porous media: Parameter evaluation. Water Resour. Res. 33(4), 505–516 (1997). doi: 10.1029/96WR03536
Fathi, E., Akkutlu, I.Y.: Matrix heterogeneity effects on gas transport and adsorption in coalbed and shale gas reservoirs. Transp. Porous Med. 80(2), 281–304 (2009). doi: 10.1007/s11242-009-9359-4
Civan, F.: Effective correlation of apparent gas permeability in tight porous media. Transp. Porous Med. 82(2), 375–384 (2010). doi:10.1007/s11242-009-9432-z
Freeman, C.M., Moridis, G.J., Blasingame T.A.: A numerical study of microscale flow behavior in tight gas and shale gas reservoir systems. Transp. Porous Med. 90, 253–268 (2011). doi: 10.1007/s11242-011-9761-6
Javadpour, F., Fisher, D., Unsworth, M.: Nanoscale gas flow in shale gas sediments. J. Can. Pet. Technol. 46 (10), 55–60 (2007). doi:10.2118/07-10-06
Karniadakis, G.E., Beskok, A.: Micro flows: Fundamentals and simulation. New York: Springer–Verlag (2002)