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Journal of Engineering Mathematics

Erschienen in:

01.06.2015

Analytical solution and mechanisms of fluid production from hydraulically fractured wells with finite fracture conductivity

verfasst von: Yan Jin, Kang Ping Chen, Mian Chen

Erschienen in: Journal of Engineering Mathematics | Ausgabe 1/2015

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Abstract

A comprehensive study of the physical mechanisms of fluid production from a well intersected by a narrow elliptically shaped vertical fracture with finite fracture conductivity is carried out using a newly obtained analytical solution. The flow pattern, flux density distribution along the fracture surface, and fluid production rate are analyzed systematically with respect to finite fracture conductivity. The simplicity of the new analytical solution reveals many physical insights not attainable from existing analytical or numerical solutions. It is shown that the nearly singular pressure gradient developed at the fracture tip induces the reservoir flow to converge to and focus at the tip region, promoting flux density along the entire fracture surface and enhancing the production rate. It is established that the flow in the reservoir is a superposition of two basic flows, a confocal elliptical flow responsible for the fluid production, and a redistributive nonproducing flow induced by a finite fracture conductivity that draws fluids out of the fracture from the part near the tip and redeposits them back to the part of the fracture close to the wellbore. An explicit analytical formula for the fluid production rate is also derived that exhibits a simple dependency on the dimensionless fracture conductivity.

Vorheriger Artikel A time spectral method for solving the nonlinear dynamic equations of a rectangular elastic plate

Nächster Artikel Non-isothermal hydrophobicity-dependent two-phase flow in the porous cathode gas diffusion layer of a polymer electrolyte fuel cell

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Clarkson CR (2013) Production data analysis of unconventional gas wells: review of theory and best practices. Int J Coal Geol 109–110:101–146CrossRef

Ratts PAC (2007) Uptake of water from soils by plant roots. Transp Porous Med 68:5–28CrossRef

Roose T, Schnepf A (2008) Mathematical models for plant–soil interaction. Phil Trans R Soc A 366:4597–4611CrossRefADSMathSciNet

Prats M (1961) Effect of vertical fractures on reservoir behavior—incompressible fluid case. SPE J 1(2):105–118CrossRef

Prats M, Hazebroek P, Strickler WR (1962) Effect of vertical fractures on reservoir behavior—compressible fluids case. SPE J 2(2):87–94CrossRef

Raghavan R, Cady GV, Ramey HJ Jr (1972) Well-test analysis for vertically fractured wells. J Pet Technol 24(8):1014–1020CrossRef

Gringarten AC, Ramsey HJ Jr (1974) Unsteady pressure distribution created by a well with a single infinite-conductivity vertical fracture. SPE J 14:347–360CrossRef

Gringarten AC, Ramey HJ Jr, Raghavan R (1975) Applied pressure analysis for fractured wells. J Pet Technol 27(7):887–892CrossRef

Earlougher R (1977) Advances in well test analysis. Society of Petroleum Engineers of AIME, Dallas

10.

Cinco-Ley H, Samaniego VF, Dominguez AN (1978) Transient pressure behavior for a well with a finite-conductivity vertical fracture. SPE J 18(4):253–264CrossRef

11.

Agarwal RG, Carter RD, Pollock CB (1979) Evaluation and performance prediction of low-permeability gas wells stimulated by massive hydraulic fracturing. J Pet Technol 31(3):362–372CrossRef

12.

Kuchuk FJ, Brigham WE (1979) Transient flow in elliptical systems. SPE J 19(6):401–410CrossRef

13.

Kuchuk FJ, Brigham WE (1981) Unsteady-state water influx in elliptic and anisotropic reservoir/aquifer systems. SPE J 21(3):309–314

14.

Cinco-Ley H, Samaniego VF (1981) Transient pressure analysis for fractured wells. J Pet Technol 33(9):1749–1766CrossRef

15.

Lee ST, Brockenbrough JR (1986) A new approximate analytic solution for finite-conductivity vertical fractures. SPE Form Eval 1(1):75–88CrossRef

16.

Obuto ST, Ertekin T (1987) A composite system solution in elliptic flow geometry. SPE Form Eval 2(3):227–238CrossRef

17.

Wilkinson DJ (1989) New results for pressure transient behavior of hydraulically-fractured wells. SPE Paper 18950

18.

Riley MF (1991) Finite conductivity fractures in elliptical coordinates. Ph.D. Dissertation, Stanford University, Stanford

19.

Valko P, Economides MJ (1995) Hydraulic fracture mechanics. Wiley, Chichester

20.

Bourdet D (2002) Well test analysis: the use of advanced interpretation models. Elsevier, Amsterdam

21.

Meyer B, Jacot R (2005) Pseudosteady-state analysis of finite conductivity vertical fractures. SPE Paper 95941

22.

Amini S, IIik D, Blasingame TA (2007) Evaluation of the elliptical flow period for hydraulically-fractured wells in tight gas sands-theoretical aspects and practical considerations. SPE Paper 106308

23.

Kamal M, Abbaszadeh M, Cinco-Ley H, Hegeman P, Horne R, Houze O, Kabir S, Kikani J, Kuchuk F, Landa J, Murray M, Ozkan E, Raghavan R, Samaniego F, Soliman M (2009) Transient well testing. Society of Petroleum Engineers of AIME, Dallas

24.

Ozkan E (2012) Releasing shale gas potential with fractured horizontal wells. SPE Distinguished Lecture

25.

Biryukov D, Kuchuk FJ (2012) Transient pressure behavior of reservoirs with discrete conductive faults and fractures. Transp Porous Med 95:239–268CrossRefMathSciNet

26.

Economides MJ, Nolte KG (eds) (2000) Reservoir stimulation, 3rd edn. Wiley, New York

27.

Chen KP, Jin Y, Chen M (2013) Pressure-gradient singularity and production enhancement for hydraulically-fractured wells. Geophys J Int 195:923–931CrossRefADS

28.

Lafe OE, Montes JS, Cheng AH-D, Liggett JA, Liu PL-F (1980) Singularities in Darcy flow through porous media. J Hydraul Div Proc ASCE 106(HY6):977

29.

Phillips OM (1991) Flow and reactions in permeable rocks. Cambridge University Press, New York

30.

Kikani J (1995) Flux determination of finite conductivity fractures using higher order interpolation functions. SPE Adv Technol Ser 3(1):76–84CrossRef

31.

Chin WC (2002) Quantitative methods in reservoir engineering. Gulf Professional Publishing, Woburn

32.

Matthäi SK, Belayneh M (2004) Fluid flow partitioning between fractures and a permeable rock matrix. Geophys Res Lett 31(7):L07602CrossRefADS

33.

Mathias SA, van Reeuwijk M (2009) Hydraulic fracture propagation with 3-D leak-off. Transp Porous Med 80(3):1573–1634CrossRef

34.

Mathias SA, Tsang C, van Reeuwijk M (2010) Investigation of hydromechanical processes during cyclic extraction recovery testing of a deformable rock fracture. Int J Rock Mech Min Sci 47(3):517–522CrossRef

35.

Exadaktylos G (2012) A study of the transient fluid flow around a semi-infinite crack. Int J Solids Struct 49(23–24):3323–3334CrossRef

36.

Pouya A (2012) Three-dimensional flow in fractured porous media: a potential solution based on singular integral equations. Adv Water Res 35:30–40CrossRef

37.

Pouya A, Ghabezloo S (2010) Flow around a crack in a porous matrix and related problems. Transp Porous Med 84:511–532CrossRefMathSciNet

38.

Pouya A, Vu MN (2012) Fluid flow and effective permeability of an infinite matrix containing disc-shaped cracks. Adv Water Res 42:37–46CrossRef

39.

Cheng Y, Lee WJ, McVay DA (2009) A new approach for reliable estimation of hydraulic fracture properties using elliptical flow data in tight gas wells. SPE Reserv Eval Eng 12(2):254–262CrossRef

40.

Craft BC, Hawkins M (1959) Applied petroleum reservoir engineering. Prentice-Hall, Englewood Cliffs

Titel: Analytical solution and mechanisms of fluid production from hydraulically fractured wells with finite fracture conductivity
verfasst von: Yan Jin
Kang Ping Chen
Mian Chen
Publikationsdatum: 01.06.2015
Verlag: Springer Netherlands
Erschienen in: Journal of Engineering Mathematics / Ausgabe 1/2015
Print ISSN: 0022-0833
Elektronische ISSN: 1573-2703
DOI: https://doi.org/10.1007/s10665-014-9754-x

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