ライブラリ登録: Guest
Begell Digital Portal Begellデジタルライブラリー 電子書籍 ジャーナル 参考文献と会報 リサーチ集
Journal of Porous Media
インパクトファクター: 1.752 5年インパクトファクター: 1.487 SJR: 0.43 SNIP: 0.762 CiteScore™: 2.3

ISSN 印刷: 1091-028X
ISSN オンライン: 1934-0508

巻:
巻 23, 2020 巻 22, 2019 巻 21, 2018 巻 20, 2017 巻 19, 2016 巻 18, 2015 巻 17, 2014 巻 16, 2013 巻 15, 2012 巻 14, 2011 巻 13, 2010 巻 12, 2009 巻 11, 2008 巻 10, 2007 巻 9, 2006 巻 8, 2005 巻 7, 2004 巻 6, 2003 巻 5, 2002 巻 4, 2001 巻 3, 2000 巻 2, 1999 巻 1, 1998

Journal of Porous Media

DOI: 10.1615/JPorMedia.2019024313
pages 1351-1370

3D PRESSURE TRANSIENT ANALYSIS MODEL OF FRACTURED-CAVED RESERVOIR BASED ON SEISMIC CHARACTERIZATION

Yizhao Wan
The Key Laboratory of Gas Hydrate, Ministry of Natural Resources of the People's Republic of China, Qingdao Institute of Marine Geology, Qingdao, 266071, China; Laboratory for Marine Mineral Resources, Qingdao Pilot National Laboratory for Marine Science and Technology, Qingdao, 266071, China
Nengyou Wu
The Key Laboratory of Gas Hydrate, Ministry of Natural Resources of the People's Republic of China, Qingdao Institute of Marine Geology, Qingdao, 266071, China; Laboratory for Marine Mineral Resources, Qingdao Pilot National Laboratory for Marine Science and Technology, Qingdao, 266071, China
Changling Liu
The Key Laboratory of Gas Hydrate, Ministry of Natural Resources of the People's Republic of China, Qingdao Institute of Marine Geology, Qingdao, 266071, China; Laboratory for Marine Mineral Resources, Qingdao Pilot National Laboratory for Marine Science and Technology, Qingdao, 266071, China
Qiang Chen
The Key Laboratory of Gas Hydrate, Ministry of Natural Resources of the People's Republic of China, Qingdao Institute of Marine Geology, Qingdao, 266071, China; Laboratory for Marine Mineral Resources, Qingdao Pilot National Laboratory for Marine Science and Technology, Qingdao, 266071, China
Yuewu Liu
Institute of Mechanics, Chinese Academy of Sciences, Beijing 100190, China; University of Chinese Academy of Sciences, Beijing 100049, China

要約

Large-scale fractures and cavities cause difficulties of geological modeling, which in turn makes the fluid flow simulation difficult. In this paper, a geological modeling process based on three-dimensional (3D) seismic characterization is proposed to model real reservoirs, and then a 3D pressure transient analysis model is developed to model the fluid flow in the fractured-caved reservoirs. In this model, the reservoir is characterized as three types of media explicitly: cavities simplified as irregular polyhedrons, fractures represented by slabs, and the matrix of the rest. A finite-element method is implemented to obtain the solutions of the governing equations. Two idealized cases of fractures and cavities are presented using the model. The results show fractures and cavities play the dominant role in the fluid flow. In the fractures case, the log-log type curves can be divided into six stages, and the bilinear flow is the main feature. A larger permeability of fractures causes a longer period of bilinear flow. The log-log type curves of the cavity case are also divided into six stages. The larger permeability of cavities, the lower the horizontal line of the pressure derivative, but the influence of cavities not connected with the wellbore is limited. Comparison with the radial-composite model shows that the radial-composite model gets a volume-equivalent radius of the cavity, but a higher permeability and a negative skin factor. The developed model is also applied for the well test analysis of a field case, which shows a significant ability to characterize the fluid flow of fractured-caved reservoirs.

参考

  1. Barenblatt, G.I., Zheltov, I.P., and Kochina, I.N., Basic Concepts in the Theory of Seepage of Homogeneous Liquids in Fissured Rocks [Strata], J. Appl. Math. Mech, vol. 24, pp. 1286-1303,1960.

  2. Bourdet, D., Well Test Analysis: The Use of Advanced Interpretation Models, First Ed., Amsterdam, Netherlands: Elsevier, 2002.

  3. Clossman, P.J., An Acquirer Model for Fissured Reservoir, SPE J., vol. 15, pp. 385-398, 1975.

  4. Dayani, S., Baghbanan, A., and Karami, M., Evaluating the Permeability Tensor of a Fractured Rock Mass Using Effective Medium Theory, Proc, Rock Engineering and Technology for Sustainable Underground Construction, the 2012ISRM Int. Symp., Stockholm, Sweden, May 28-30, 2012.

  5. de Swaan, O.A., Analytic Solutions for Determining Naturally Fractured Reservoir Properties by Well Testing, SPE J., vol. 16, pp. 117-122, 1976.

  6. Fuentes-Cruz, G. and Valko, P.P., Revisiting the Dual-Porosity/Dual-Permeability Modeling of Unconventional Reservoirs: The Induced-Interporosity Flow Field, SPE J, vol. 20, pp. 124-141, 2015.

  7. Galerkin, B.G., Rods and Plates: Series in Some Problems of Elastic Equilibrium of Rods and Plates, Vestn. Inzh. Tech., (USSR), vol. 19, pp. 897-908, 1915.

  8. Grillo, A., Lampe, M., Logashenko, D., Stichel, S., and Wittum, G., Simulation of Salinity and Thermohaline-Driven Flow in Fractured Porous Media, J. Porous Media, vol. 15, no. 5, pp. 439-458, 2012.

  9. Gringarten, A.C., Well Test Analysis in Practice, The Way Ahead, vol. 8, pp. 10-14, 2012.

  10. Huang, Z.Q., Xia, Y., and Yao, J., A Two-Phase Flow Simulation of Discrete-Fractured Media Using Mimetic Finite Difference Method, Commun. Comput. Phys, vol. 16, pp. 799-816, 2014.

  11. Huang, Z.Q., Yao, J., Li, Y.J., Wang, C.C., and Lu, X.R., Permeability Analysis of Fractured Vuggy Porous Media based on Homogenization Theory, Sci. China: Tech. Sci., vol. 53, pp. 839-847, 2010.

  12. Jambayev, A.S. and Hoffman, B.T., Predicting Water Movement Using a Discrete Fracture Network Approach Combined with Fluid Flow Modeling in a Naturally Fractured Carbonate Reservoir, SPE-172785-MS, SPE Middle East Oil & Gas Show and Conf., Manama, Bahrain, March 8-11, 2015.

  13. Kazemi, H., Pressure Transient Analysis of Naturally Fractured Reservoirs with Uniform Fracture Distribution, SPE J., vol. 9, pp. 451-462, 1969.

  14. Khvatova, I.E., Renaud, A., Golitsina, E., Malutina, G., Sansiev, G., and Kuzilov, I., Simulation of Complex Carbonate Field: Double Media vs. Single Media Kharyaga Field Case (Russian), SPE Russian Oil and Gas Exploration and Production Technical Conf. and Exhibition, Moscow, Russia, October 16-18,2012.

  15. Kim, J.G. and Deo, M.D., Comparison of the Performance of a Discrete Fracture Multiphase Model with Those Using Conventional Methods, SPE Reservoir Simulation Symposium, Houston, Texas, February 14-17, 1999.

  16. Kolditz, D.I.O., Non-Linear Flow in Fractured Media, Berlin: Springer, 2002.

  17. Li, Y., Zhang, J., Liu, Z.L., and Li, B., A Systematic Technique of Production Forecast for Fractured Vuggy Carbonate Gas Condensate Reservoirs, The SPE Kingdom of Saudi Arabia Technical Symposium and Exhibition, Dammam, Saudi Arabia, April 25-28, 2016.

  18. Long, J.C.S., Remer, J.S., and Wilson, C.R., Porous Media Equivalents for Networks of Discontinuous Factures, Water Resour. Res., vol. 18, pp. 645-658,1982.

  19. Loucks, T.L. and Guerrero, E.T., Pressure Drop in a Composite Reservoir, SPE J, vol. 1, pp. 170-176, 1961.

  20. Ran, Q., Wang, Y., Sun, Y., Yan, L., and Tong, M., Volcanic Gas Reservoir Characterization, First Ed., Boston: Gulf Professional Publishing, 2014.

  21. Shakerinezhad, S., Samadi, F., and Esmaielzadeh, F., Pressure Transient Response of Partially Fractured Reservoirs, Spcl. Top. Rev. Porous Media-Int. J., vol. 4, no. 1,pp. 1-11,2013.

  22. Snow, D.T., Anisotropic Permeability of Fractured Media, Water Resour. Res., vol. 5, pp. 1273-1289,1969.

  23. Teimoori, A., Calculation of the Effective Permeability and Simulation of Fluid Flow in Naturally Fractured Reservoirs, PhD, University of New South Wales, Sydney, Australia, 2005.

  24. Wan, Y.Z. and Liu, Y.W., Three Dimensional Discrete-Fracture-Cavity Numerical Well Test Model for Fractured-Cavity Reservoir, Chin. J. Theor. Appl. Mech., vol. 47, pp. 1000-1008,2015.

  25. Wan, Y.Z. , Liu, Y.W. , Chen, F.F. , Wu, N. Y. , and Hu, G.W. , Numerical Well Test Model for Caved Carbonate Reservoirs and Its Application in Tarim Basin, China, J. Pet. Sci. Eng., vol. 161, pp. 611-624, 2018.

  26. Wan, Y. Z . , Liu, Y. W. , Ouyang, W. P. , Han, G . F. , and Liu, W. C . , Numerical Investigation of Dual-Porosity Model with Transient Transfer Function based on Discrete-Fracture Model, Appl. Math. Mech, vol. 37, pp. 611-626,2016.

  27. Warren, J.E. and Root, P. J., The Behavior of Naturally Fractured Reservoirs, SPE J., vol. 3, pp. 245-255,1963.

  28. Xing, C.Q., Yin, H.J., Liu, K.X., and Fu, J., Well Test Analysis for Fractured and Vuggy Carbonate Reservoirs of Well Drilling in Large Scale Cave, Energies, vol. 11, pp. 80-85, 2018.

  29. Yao, J., Wang, C.C., Yang, Y.F., Huang, Z.Q., Fan, D.Y., and Sun, H., The Construction Method and Microscopic Flow Simulation of Carbonate Dual Pore Network Model, Sci. Sin-Phys: Mech. Astron., vol. 43, pp. 896-902, 2013.

  30. Yao, S.S., Wang, X.Z., and Zeng, F.H., A Composite Model for Multi-Stage Fractured Horizontal Wells in Heterogeneous Reservoirs (Russian), The SPE Russian Petroleum Technology Conference and Exhibition, Moscow, Russia, October 24-26, 2016.

  31. Yu, X., Rutledge, J., Leaney, S., and Maxwell, S., Discrete Fracture Network Generation from Microseismic Data Using Moment-Tensor Constrained Hough Transforms, SPE Hydraulic Fracturing Technology Conf, The Woodlands, Texas, February 4-6, 2014.

  32. Zendehboudi, S., Chatzis, I., Shafiei, A., and Dusseault, M.B., Empirical Modeling of Gravity Drainage in Fractured Porous Media, Energy Fuels, vol. 25, pp. 1229-1241, 2011.

  33. Zendehboudi, S., Elkamel, A., Chatzis, I., Ahmadi, M.A., Bahadori, A., and Lohi, A., Estimation of Breakthrough Time for Water Coning in Fractured Systems: Experimental Study and Connectionist Modeling, AIChE J., vol. 60, pp. 1905-1919,2014.

  34. Zendehboudi, S., Mohammadzadeh, O., and Chatzis, I., Experimental Study of Controlled Gravity Drainage in Fractured Porous Media, J. Canadian Petro. Tech, vol. 50, pp. 56-71,2009.

  35. Zhang, G.K., and Xu, W.Y., Analysis of Joint Network Simulation Method and REV Scale, Rock Soil Mech., vol. 29, pp. 1675-1680,2008.

  36. Zheng, D.M., Li, Z.H., Zhao, K.Z., Shen, F., Dang, Q.N., and Gao, L.H., Quantitative Seismic Characterization of Ordovician Fracture-Cavity Carbonate Reservoirs in Tarim Oilfield, China Petro. Explo., vol. Z1, pp. 57-62, 2011.

  37. Zhu, G.Y., Zou, C.N., Yang, H.J., Wang, K., Zheng, D., and Zhu, Y., Hydrocarbon Accumulation Mechanisms and Industrial Exploration Depth of Large-Area Fracture-Cavity Carbonates in the Tarim Basin, Western China, J. Pet. Sci. Eng., vol. 133, pp. 889-907, 2015.


Articles with similar content:

Dynamics of Pulsed Two-Phase Flow in Porous Media: Bead Pack and Core Plug Experiments
Journal of Porous Media, Vol.11, 2008, issue 1
Mariela Araujo Fresky , Denis Ivanov, Oneida Leon, Richard Marquez
INVESTIGATION OF FRACTURE BALLOONING-BREATHING USING AN EXPONENTIAL DEFORMATION LAW AND HERSCHEL−BULKLEY FLUID MODEL
Special Topics & Reviews in Porous Media: An International Journal, Vol.3, 2012, issue 4
Mojtaba Pordel Shahri, Mohammad Zeyghami, Reza Majidi
MULTISCALE AND MULTIPHASE MODELING OF FLOW BEHAVIOR IN DISCRETE FRACTURE NETWORKS FOR TIGHT OIL RESERVOIRS
Journal of Porous Media, Vol.22, 2019, issue 7
Ning Li, Qiquan Ran, Yu-Shu Wu, Lifeng Liu
REDUCING FRACTURE PREDICTION UNCERTAINTY BASED ON TIME-LAPSE SEISMIC (4D) AND DETERMINISTIC INVERSION ALGORITHM
International Journal for Uncertainty Quantification, Vol.9, 2019, issue 2
Liming Zhang, Yi Wang, Qin Luo, Chenyu Cui, Kai Zhang, Jun Yao, Zhixue Sun
ANALYSIS ON UNSTEADY FLOW FOR POWER-LAW FLUIDS IN DUAL FRACTAL MEDIA
Journal of Porous Media, Vol.20, 2017, issue 12
Xiao-Ping Li, Ming-Qing Kui, Xiao-Hua Tan, Jianchao Cai