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2016 | OriginalPaper | Buchkapitel

2. Advancement in Numerical Simulations of Gas Hydrate Dissociation in Porous Media

verfasst von : Zhen Liu, Xiong Yu

Erschienen in: New Frontiers in Oil and Gas Exploration

Verlag: Springer International Publishing

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Abstract

The amount of research on gas hydrates has been rising dramatically due to the significant role gas hydrates play as a persistent trouble for gas industry, a promising energy source, and a potential threat to environment. In the energy exploration perspective, numerical simulations play a major role in improving our understanding of the fundamentals gas hydrate dissociation as well as hydrate reservoir behaviors. This chapter presents an integrative review on the computer simulation models of gas hydrate dissociation, which have boomed since their first appearance in 1980s. Necessary background knowledge for gas hydrates and the existing investigations on this topic are firstly summarized. A unified framework is then developed for the purpose of integrating and classifying the existing models. The major mechanisms involved in the phase change process are illustrated and explained on the level of governing equations. The similarities and discrepancies among the models are demonstrated and discussed using this framework. Discussions continue on the auxiliary relationships for describing the material properties based on their categories. The various auxiliary relationships employed in the existing computational models are summarized and compared. Finally, the results obtained by previous simulations as well as other laboratory or field data are discussed. Noteworthy trends in the numerical simulations of gas hydrates behaviors are also unveiled. Recommendations are provided for future research. By providing an overview of the topic area, this chapter intends to provide scientific basis to understand the existing gas hydrate simulation models as well as serve as a guide for future research on advanced gas hydrate simulations.

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Vorheriges Kapitel Understanding Asphaltene Aggregation and Precipitation Through Theoretical and Computational Studies

Nächstes Kapitel Discrete Element Modeling of the Role of In Situ Stress on the Interactions Between Hydraulic and Natural Fractures

Selim M. S. & Sloan, E. D. (1985). Modeling of the dissociation of in-situ hydrate. SPE 1985 California Regional Meeting, Bakersfield, CA, March 27–29.

Bishnoi, P. R., & Natarajan, V. (1996). Formation and decomposition of gas hydrates. Fluid Phase Equilibria, 117, 168–177.CrossRef

Englezos, P. (1993). Clathrate hydrates. Industrial and Engineering Chemistry Research, 32, 1251–1274.CrossRef

Kneafsey, T. J., Tomutsa, L., Moridis, G. J., Seol, Y., Freifeld, B. M., Taylor, C. E., et al. (2007). Methane hydrate formation and dissociation in a partially saturated core-scale sand sample. Journal of Petroleum Science and Engineering, 56, 108–126.CrossRef

Bayles, G. A., Sawyer, W. K., & Malone, R. D. (1986). A steam cycling model for gas production from a hydrate reservoir. Chemical Engineering Communication, 47, 225–245.CrossRef

Holder, G. D., & Angert, P. F. (1982). Simulation of gas production from a reservoir containing both gas hydrates and free natural gas. SPE Annual Technical Conference and Exhibition, 26–29 September 1982, New Orleans, Louisiana.

Ahmadi, G., Ji, C., & Smith, D. H. (2007). Natural gas production from hydrate dissociation: an axisymmetric model. Journal of Petroleum Science and Engineering, 58, 245–258.CrossRef

Hong, H., Pooladi-Darvish, M., & Bishnoi, P. R. (2003). Analytical modeling of gas production from hydrates in porous media. Journal of Canadian Petroleum Technology, 42(11), 45–56.CrossRef

Katz, D. L. (1971). Depths to which frozen gas fields (gas hydrates) may be expected. Journal of Petroleum Technology, 23(4), 419–423.CrossRef

10.

Makogon, Y. F. (1965). Hydrate formation in the gas-bearing beds under permafrost conditions. Gazovaia Promyshlennost, 5, 14–15.

11.

Makogon, Y. F. (1997). Hydrates of natural gas. Tulsa, Oklahoma: Penn Well Books.

12.

Sun, X., Nanchary, N., & Mohanty, K. K. (2005). 1-D modeling of hydrate depressurization in porous media. Transport in Porous Media, 58, 315–338.CrossRef

13.

Janicki, G., Schluter, S., Hennig, T., Lyko, H., & Deergerg, G. (2011). Simulation of methane recovery from gas hydrates combined with storing carbon dioxide as hydrates. Journal of Geological Research, 2011, 1–15.CrossRef

14.

Phale, H. A., Zhu, T., White, M. D., & McGrail B. P. (2006). Simulation study on injection of CO₂-microemulsion for methane recovery from gas hydrate reservoirs. SPE Gas Technology Symposium, Calgary, Alberta, Canada, 15–17 May 2006.

15.

Burshears, M., O’Brien, T. J., & Malone, R. D. (1986). A multi-phase, multi-dimensional, variable composition simulation of gas production from a conventional gas reservoir in contact with hydrates. Unconventional Gas Technology Symposium of the Society of Petroleum Engineers, Louisville, KY, May 18–21.

16.

Rempel, A. W., & Buffett, B. A. (1997). Formation and accumulation of gas hydrate in porous media. Journal of Geophysical Research, 102(5), 151–164.

17.

Kvenvolden, K. A., Carlson, P. R., & Threlkeld, C. N. (1993). Possible connection between two Alaskan catastrophes occurring 25 years apart (1964 and 1989). Geology, 21, 813–816.CrossRef

18.

Booth, J. S., Rowe, M. M., & Fischer, K. M. (1996). Offshore gas hydrate sample database with an overview and preliminary analysis. U.S. Geological Survey, Open File Report 96-272, Denver, Colorado.

19.

MacDonald, G. J. (1990). The future of methane as an energy resource. Annual Review of Energy, 15, 53–83.CrossRef

20.

White, M. D., & McGrail, B. P. (2008). Numerical simulation of methane hydrate production from geologic formations via carbon dioxide injection. 2008 Offshore Technology Conference, Houston, Texas, 5–8 May.

21.

Nazridoust, K., & Ahmadi, G. (2007). Computational modeling of methane hydrate dissociation in a sandstone core. Chemical Engineering Science, 62, 6155–6177.CrossRef

22.

Sun, X., & Mohanty, K. K. (2006). Kinetic simulation of methane hydrate formation and dissociation in porous media. Chemical Engineering Science, 61, 3476–3495.CrossRef

23.

Hammerschmidt, E. G. (1934). Formation of gas hydrates in natural gas transmission lines. Industrial, 26(8), 851–855.

24.

Makogon, Y. F., Holditch, S. A., & Makogon, T. Y. (2007). Natural gas-hydrates—a potential energy source for the 21st Century. Journal of Petroleum Science and Engineering, 56, 14–31.CrossRef

25.

Maksimov, A. M. (1992). Mathematical model of the volume dissociation of gas-phase hydrates in a porous medium with water-phase mobility. Moscow: Institute for Gas and Oil Problems, Academy of Sciences of the USSR and GKNO of the USSR.

26.

Dickens, G. R. (2003). Rethinking the global carbon cycle with a large dynamic and microbially mediated gas hydrate capacitor. Earth and Planetary Science Letters, 213, 169–183.CrossRef

27.

Kennett, J. P., Cannariato, K. G., Hendy, I. L., & Behl, R. J. (2000). Carbon isotopic evidence for methane hydrate stability during Quaternary Interstadials. Science, 288, 128–133.CrossRef

28.

Kayen, R. E., & Lee, H. J. (1991). Pleistocene slope instability of gas hydrate-laden sediment on the Beaufort Sea margin. Marine Georesources & Geotechnology, 10, 125–141.CrossRef

29.

Paull, C. K., Buelow, W. J., Ussler, W., & Borowski, W. S. (1996). Increased continental-margin slumping frequency during sea-level lowstands above gas hydrate-bearing sediments. Geology, 24, 143–146.CrossRef

30.

Moridis, G. J., & Sloan, E. D. (2006). Gas production potential of disperse low-saturation hydrate accumulations in oceanic sediments. LBNL-52568, Berkeley, CA: Lawrence Berkeley National Laboratory.

31.

Moridis, G. J., & Collett, T. S. (2003). Strategies for gas production from hydrate accumulations under various geologic conditions. LBNL-52568, Berkeley, CA: Lawrence Berkeley National Laboratory

32.

Moridis, G. J., Kneafsey, T. J., Kowalsky, M., & Reagan, M. (2006). Numerical, laboratory and field studies of gas production from natural hydrate accumulations in geologic media. Berkeley, CA: Earth Science Division, Lawrence Berkeley National Laboratory.

33.

Esmaeilzadeh, F., Zeighami, M. E., & Fathi, J. (2008). 1-D modeling of hydrate decomposition in porous media. Proceedings of World Academy of Science, Engineering and Technology, 41, 647–653.

34.

Hyndman, R. D., & Davis, E. E. (1992). A mechanism for the formation of methane hydrate and seafloor bottom-simulating reflectors by vertical fluid expulsion. J. Geophys. Res., 97, 7025–7041.CrossRef

35.

Kowalsky, M. B., & Moridis, G. J. (2007). Comparison of kinetic and equilibrium reaction models in simulating gas hydrate behavior in porous media. Berkeley, CA: Earth Science Division, Lawrence Berkeley National Laboratory.

36.

Uddin, M., Coombe, D., Law, D., & Gunter, B. (2008). Numerical studies of gas hydrate formation and decomposition in a geological reservoir. Journal of Energy Resources Technology, 130, 032501-1–032501-14.

37.

White, M. D., Wurstner, S. K., & McGrail, B. P. (2009). Numerical studies of methane production from Class 1 gas hydrate accumulations enhanced with carbon dioxide injection. Marine and Petroleum Geology, 28(2), 546–560.CrossRef

38.

Goel, N. (2006). In situ methane hydrate dissociation with carbon dioxide sequestration: current knowledge and issues. Journal of Petroleum Science and Engineering, 51, 169–184.CrossRef

39.

Kamath, V. A., & Godbole, S. P. (1987). Evaluation of hot-brine simulation technique for gas production from natural gas hydrates. Journal of Petroleum Technology, 39, 1379–1388.

40.

Sloan, E. D., & Koh, C. A. (2007). Clathrate hydrates of natural gases (3rd ed.). Boca Raton: CRC Press.CrossRef

41.

Graue, A., Kvamme, B., Baldwin, B., Stevens, J., Howard, J., & Aspenes, E. (2006). Environmentally friendly CO₂ storage in hydrate reservoirs benefits from associated spontaneous methane production. In Proceedings of the Offshore Technology Conference (OTC-18087), Huston, Texas, United States.

42.

Stevens, J., Howard, J., Baldwin, B., Ersland, B., Huseb, J., & Graue, A. (2008). Experimental hydrate formation and production scenarios based on CO2 sequestration. Proceedings of the 6th International Conference on Gas Hydrates (ICGH 2008), Vancouver, British Columbia, Canada, July 6–10, 2008.

43.

McGruire, P. L. (1982). Methane hydrate gas production by thermal stimulation. Proceedings of the Fourth Canadian Permafrost Conference, H.M. French (ed.), Calgary.

44.

Selim, M. S., & Sloan, E. D. (1990). Hydrate dissociation in sediments. SPE Reservoir Engineering, 5(2), 245–251.CrossRef

45.

Yousif, M. H., Abass, H. H., Selim, M. S., & Sloan, E. D. (1991). Experimental and theoretical investigation of methane-gas-hydrate dissociation in porous media. SPE Reservoir Engineering, 6(1), 69–76.CrossRef

46.

Guo, T., Wu, B., Zhu, Y., Fan, S., & Chen, G. (2004). A review on the gas hydrate research in China. Journal of Petroleum Science and Engineering, 41, 11–20.CrossRef

47.

Sloan, E. D. (2003). Clathrate hydrate measurements: microscopic mesoscopic, and macroscopic. The Journal of Chemical Thermodynamics, 35, 41–53.CrossRef

48.

Pooladi-Darvish, M. (2004). Gas production from hydrate reservoirs and its modeling. Society of Petroleum Engineers, 56(6), 65–71.

49.

Davy, H. (1881). The bakerian lecture on some of the combinations of oxymuriatic gas and oxygen, and on the chemical relations of these principles to inflammable bodies. Philosophical Transactions of the Royal Society, London 1811,101, (Part I), pp. 1-35.

50.

Faraday, M. (1823). On fluid chlorine. Philosophical Transactions of the Royal Society B: Biological Sciences, London, 113, 160–165.CrossRef

51.

Davidson, D. W. (1973). Gas hydrates. In F. Frank (Ed.), Water: A comprehensive treatise (Vol. 2, pp. 115–234). New York: Plenum Press. Chapter 3.

52.

Deaton, W. M., & Frost, E. M. Jr. (1946). US Bureau of Mines Monograph 8, No. 8.

53.

Chersky, N. J., & Makogon, Y. F. (1970). Solid gas world reserves are enormous. Oil Gas International, 10(8), 82–84.

54.

Makogon, Y. F., Trebin, F. A., Trofimuk, A. A., Tsarev, V. P., & Chersky, N. V. (1972). Detection of a pool of natural gas in a solid (hydrate gas) state. Doklady Akademii Nauk SSSR, 196, 203–206. originally published in Russian, 1971.

55.

Shipley, T. H., Houston, K. J., Buffler, R. T., Shaub, F. J., McMillen, K. J., Ladd, J. W., et al. (1979). Seismic evidence for widespread possible gad hydrate horizons on continental slopes and rises. American Association of Petroleum Geologists Bulletin, 63, 2204–2213.

56.

Stoll, R. D., & Bryan, G. M. (1979). Physical properties of sediments containing gas hydrates. Journal of Geophysical Research, 84, 1629–1634.CrossRef

57.

Finlay, P., & Krason, J. (1990). Evaluation of geological relationships to gas hydrate formation and stability: Summary report., Gas Energy Rev. Vol., 18, 12–18.

58.

Beauchamp, B. (2004). Natural gas hydrates: myths facts and issues. Comptes Rendus Geoscience, 226, 751–765.CrossRef

59.

Kim, J., Yang, D., & Rutqvist, J. (2011). Numerical studies on two-way coupled fluid flow and geomechanics in hydrate deposits. SPE Reservoir Simulation Symposium, Woodlands, Texas, 21–23 February.

60.

Klar, A., & Soga, K. (2005). Coupled deformation-flow analysis for methane hydrate production by depressurized wells. Proceeding of 3rd International Biot Conference on Poromechanics, pp. 653–659.

61.

Koh, C. A., & Sloan, E. D. (2007). Natural gas hydrates: recent advances and challenges in energy and environmental applications. American Institute of Chemical Engineers, 53(7), 1636–1643.CrossRef

62.

Kwon, T., Song, K., & Cho, G. (2010). Destabilization of marine gas hydrate-bearing sediments induced by a hot wellbore: a numerical approach. Energy Fuels, 24, 5493–5507.CrossRef

63.

Li, L., Cheng, Y., Zhang, Y., Cui, Q., & Zhao, F. (2011). A fluid-solid coupling model of wellbore stability for hydrate bearing sediments. Procedia Engineering, 18, 363–368.CrossRef

64.

Rutqvist, J., Moridis, G. J., Grover, T., & Collett, T. (2009). Geomechanical response of permafrost-associated hydrate deposits to depressurization-induced gas production. Journal of Petroleum Science and Engineering, 67, 1–12.CrossRef

65.

Yamamoto, K. (2008). Methane hydrate bearing sediments: a new subject of geomechanics. The 12th International Conference of International Association for Computer Methods and Advances in Geomechanics (IACMAG), 1–6 October 2008, Goa, India.

66.

Gudmundsson, J., & Borrehaug, A. (1996) Frozen hydrate for transport of natural gas. Proc. 2nd Int. Conf.on Natural Gas Hydrates, pp. 415–422.

67.

Gudmundsson, J., Andersson, V., Levik, O. I., Mork, M., & Borrehaug, A. (2000). Hydrate technology for capturing stranded gas. Ann. NY Acad. Science, 912, 403–410.CrossRef

68.

Stern, L. A., Circone, S., Kirby, S. H., & Durham, W. B. (2001). Anomalous preservation of pure methane hydrate at 1 atm. The Journal of Physical Chemistry, 105(9), 1756–1762.CrossRef

69.

Takaoki, T., Hirai, K., Kamei, M., & Kanda, H. (2005). Study of natural gas hydrate (NGH) carriers. Proceedings of the Fifth International Conference on Natural Gas Hydrates, June 13-16, Trondheim, Norway. Paper 4021.

70.

Florusse, L. J., Peters, C. J., Schoonman, J., Hester, K. C., Koh, C. A., Dec, S. F., et al. (2004). Stable low-pressure hydrogen clusters stored in a binary clathrate hydrate. Science., 306(5695), 469–471.CrossRef

71.

Mao, W. L., Mao, H., Goncharov, A. F., Struzhkin, V. V., Guo, Q., Hu, J., et al. (2002). Hydrogen clusters in clathrate hydrate. Science, 297, 2247–2249.CrossRef

72.

Hunt, S. C. (1992). Gas hydrate thermal energy storage system. United States Patent No. 5140824.

73.

Guo, K. H., Shu, B. F. & Yang, W. J. (1996). Advances and applications of gas hydrate thermal energy storage technology. Proceedings of 1st Trabzon Int. Energy and Environment

74.

Chen, G. J., Sun, C. Y., Ma, C. F., & Guo, T. M. (2002). A new technique for separating (Hydrogen + Methane) gas mixtures using hydrate technology. Proceedings of the 4th International Conference on Gas Hydrates, May 19-23, 2002, Yokohama, Japan, pp. 1016–1020.

75.

Pawar, R. J., & Zyvoloski, G. A. (2005). Numerical simulation of gas production from methane hydrate reservoirs. Proceedings of the Fifth International Conference on Gas Hydrates, Trondheim, Norway, pp. 259–267.

76.

McGuire, P. L. (1981). Methane hydrate gas production by thermal stimulation. Proceedings of the Fourth Canadian Permafrost Conference, March 2-6, 1981, Calgary, Alberta.

77.

Goel, N., Wiggins, M., & Shah, S. (2001). Analytical modeling of gas recovery from in situ hydrates dissociation. Journal of Canadian Petroleum Technology, 29, 115–127.

78.

Ji, C., Ahmadi, G., & Smith, D. H. (2001). Natural gas production from hydrate decomposition by depressurization. Chemical Engineering Science, 56, 5801–5814.CrossRef

79.

Vasil’ev, V. N., Popov, V. V., & Tsypkin, G. G. (2006). Numerical investigation of the decomposition of gas hydrates coexisting with gas in natural reservoirs. Fluid Dynamics, 41(4), 599–605.MATHCrossRef

80.

Bai, Y., Li, Q., Li, X., & Du, Y. (2008). The simulation of nature gas production from ocean gas hydrate reservoir by depressurization. Science in China Series E: Technological Sciences, 51(8), 1272–1282.MATHCrossRef

81.

82.

Tsypkin, G. G. (2007). Analytical solution of the nonlinear problem of gas hydrate dissociation in a formation. Fluid Dynamics, 42(5), 798–806.MathSciNetMATHCrossRef

83.

Gerami, S., & Pooladi-Darvish, M. (2007). Predicting gas generation by depressurization of gas hydrates where the sharp-interface assumption is not valid. Journal of Petroleum Science and Engineering, 56, 146–164.CrossRef

84.

Hong, H., & Pooladi-Darvish, M. (2005). Simulation of depressurization for gas production from gas hydrate reservoirs. Journal of Canadian Petroleum Technology, 44(11), 39–46.CrossRef

85.

Mandelcorn, L. (1959). Clathrates. Chemical Reviews, 59, 827–839.CrossRef

86.

van der Waals, J. H., & Platteeuw, J. C. (1959). Clathrate Solutions. Advances in Chemical Physics, 2, 1–57.

87.

Byk, S. S., & Fomina, V. J. (1968). Gas Hydrates. Russian Chemical Reviews, 37(6), 469–491.CrossRef

88.

Hand, J. H., Katz, D. L., & Verma, V. K. (1974). Review of gas hydrates with implication for ocean sediments. In I. R. Kaplan (Ed.), Natural Gases in Marine Sediments (pp. 179–194). New York: Plenum.CrossRef

89.

Jeffrey, G. A., & McMullan, R. K. (1967). The clathrate hydrates. Progress in inorganic chemistry, 8, 43–108.CrossRef

90.

Jeffrey, G. A. (1984). Hydrate inclusion compounds. Journal of Inclusion Phenomena and Macrocyclic Chemistry, 1(3), 211–222.CrossRef

91.

Holder, G. D., Zetts, S. P., & Pradham, N. (1988). Phase behavior in systems containing clathrate hydrates. Reviews in Chemical Engineering, 5(l), 1–69.CrossRef

92.

Makogon, Y. F. (1981). Hydrates of natural gas. Tulsa, OK: Penn Well Publishing. (translated by W. J. Cieslewicz).

93.

Berecz, E., & Balla-Achs, M. (1983). Studies in Inorganic Chemistry 4: Gas Hydrates (pp. 184–188). Amsterdam: Elsevier.

94.

Cox, J. L. (1983). Natural gas hydrates: Properties, occurrence and recovery. Woburn, MA: Butterworth Publiehere.

95.

Sloan, E. D. (1990). Clathrate hydrates of natural gases. New York: Dekker.

96.

Sloan, E. D., Jr. (1998). Clathrate hydrates of natural gases (2nd ed.). New York, NY: Marcel Deckker Inc.

97.

Buffett, B. A. (2000). Clathrate hydrates. Annual Review of Earth and Planetary Sciences, 28, 477–507.CrossRef

98.

Koh, C. A. (2002). Towards a fundamental understanding of natural gas hydrates. Chemical Society Reviews, 31, 157–167.CrossRef

99.

Waite, W. F., Santamarina, J. C., Cortes, D. D., Dugan, B., Espinoza, D. N., Germaine, J., et al. (2009). Physical properties of hydrate-bearing soils. Reviews of Geophysics, 47, RG4003.CrossRef

100.

Sung, W., Lee, H., Lee, H., & Lee, C. (2002). Numerical study for production performances of a methane hydrate reservoir stimulated by inhibitor injection. Energy Sources, 24, 499–512.CrossRef

101.

Tonnet, N., & Herri, J. M. (2009). Methane hydrates bearing synthetic sediments-experimental and numerical approaches of the dissociation. Chemical Engineering Science, 64(19), 4089–4100.CrossRef

102.

Yu, F., Song, Y., Liu, W., Li, Y., & Lam, W. (2011). Analyses of stress strain behavior and constitutive model of artificial methane hydrate. Journal of Petroleum Science and Engineering, 77, 183–188.CrossRef

103.

Bagheri, M., & Settari, A. (2008). Modeling of geomechanics in naturally fractured reservoirs. SPE Reservoir Evaluation & Engineering, 11(1), 108–118.CrossRef

104.

Freeman, T. L, Chalatumyk, R. J., & Bogdanov, I. I. (2009). Geomechanics of heterogeneous bitumen carbonates. SPE Reservoir Simulation Symposium, 2-4 February 2009, The Woodlands, Texas.

105.

Kosloff, D., Scott, R., & Scranton, J. (1980). Finite element simulation of Wilmington oil field subsidence: I linear modelling. Tectonophysics, 65, 339–368.CrossRef

106.

Lewis, R. W., & Schreflei, B. A. (1998). The finite element method in the deformation and consolidation of porous media. Wiley, Chichester, Great Britain, 2nd edition.

107.

Merle, H. A., Kentie, C. J. P., van Opstal, G. H. C., & Schneider, G. M. G. (1976). The Bachaquero study—a composite analysis of the behavior of a compaction drive/solution gas drive reservoir. Journal of Petroleum Technology, 28(9), 1107–1115.CrossRef

108.

Morris, J. P. (2009). Simulations of injection-induced mechanical deformation: A study of the In Salah CO₂ storage project. Society of Exploration Geophysicists 2009 Summer Research Workshop, Banff, Canada, August, 2009.

109.

Rutqvist, J., & Moridis, G. J. (2009). Numerical Studies on the Geomechanical Stability of Hydrate-Bearing Sediments. SPE Journal, 14(2), 267–282.CrossRef

110.

Allen, M. B. (1954). In: M.B. Allen, G.A. Behie, and J.A. Trangenstein (Eds.), Multiphase flow in porous media: Mechanics, mathematics, and numerics. New York, Berlin: Springer-Verlag, 1988.

111.

Kimoto, S., Oka, F., Fushita, T., & Fujiwaki, M. (2007). A chemo-thermo-mechanically coupled numerical simulation of the subsurface ground deformations due to methane hydrate dissociation. Computers and Geotechnics, 34, 216–228.CrossRef

112.

Garg, S. K., Pritchett, J. W., Katoh, A., Baba, K., & Fujii, T. (2008). A mathematical model for the formation and dissociation of methane hydrates in the marine environment. Journal of Geophysical Research, 113, B01201.CrossRef

113.

Phirani, J., & Mohanty, K. L. (2010). Kinetic simulation of CO ₂ flooding of methane hydrates. SPE Annual Technical Conference and Exhibition, Florence, Italy, 19–22 September.

114.

Liu, Y., & Gamwo, I. K. (2012). Comparison between equilibrium and kinetic models for methane hydrate dissociation. Chemical Engineering Science, 69, 193–200.CrossRef

115.

Tsypkin, G. G. (1998). Decomposition of gas hydrates in low-temperature reservoirs. Fluid Dynamics, 33(1), 82–90.MATHCrossRef

116.

Ruan, X., Song, Y., Zhao, J., Liang, H., Yang, M., & Li, Y. (2012). Numerical simulation of methane production from hydrates induced by different depressurizing approaches. Energies, 5, 438–458.CrossRef

117.

Liu, X., & Flemings, P. B. (2007). Dynamics multiphase flow model of hydrate formation in marine sediments. Journal of Geophysical Research, 112, B03101.

118.

Liu, Y., Strumendo, M., & Arastoopour, H. (2008). Numerical simulation methane production from a methane hydrate formation. Industrial & Engineering Chemistry Research, 47, 2817–2828.CrossRef

119.

Masuda, Y., Kurihara, M., Ohuchi, H., & Sato, T. (2002). A field-scale simulation study on gas productivity of formations containing gas hydrates. Proceedings of 4th International Conference on Gas Hydrates, Yokohama, Japan, May 19–23.

120.

Schnurle, P., & Liu, C. (2011). Numerical modeling of gas hydrate emplacements in oceanic sediments. Marine and Petroleum Geology, 28, 1856–1869.CrossRef

121.

Scott, D. M., Das, D. K., & Subbaihaannadurai, V. (2006). A finite element computational method for gas hydrate. Part I: theory. Petroleum Science and Technology, 24, 895–909.CrossRef

122.

Campbell, G. S. (1985). Soil physics with BASIC: transport models for soil-plant systems (1st ed.). BV Amsterdam, Netherlands: Elsevier Sci.

123.

De Vries, D. A. (1963). Thermal properties of soils. In W. R. van Wijk (Ed.), Physics of plant environment (pp. 210–235). Amsterdam: North-Holland Publ. Co.

124.

Bai, Y., Li, Q., Li, F., & Du, Y. (2009). Numerical simulation on gas production from a hydrate reservoir underlain by a free gas zone. Chinese Science Bulletin, 54, 865–872.

125.

Du, Q., Li, Y., Li, S., Sun, J., & Jiang, Q. (2007). Mathematical model for natural gas hydrate production by heat injection. Petroleum Exploration and Development, 34(4), 470–487.

126.

Ng, M. Y. A., Klar, A., & Soga, K. (2008). Coupled soil deformation-flow-thermal analysis of methane production in layered methane hydrate soils. 2008 Offshore Technology Conference, Houston, Texas, 5–8 May.

127.

Tsypkin, G. G. (1993). Mathematical model of the dissociation of gas hydrates coexisting with ice in natural reservoirs. Translated from Izvestiya Rossiiskoi Akademii Nauk, Mekhanika Zhidkosti i Gaza, No. 2, pp. 84-92, March–April.

128.

Chen, Z., Bai, W., & Xu, W. (2005). Prediction of stability zones and occurrence zones of multiple composition natural gas hydrate in marine sediment. Chinese Journal of Geophysics, 48(4), 939–945.CrossRef

129.

Williams, P. J. (1964). Specific heat and apparent specific heat of frozen soils. pp. 225–229. In 1st International Conference of Permafrost, 1964, National Academy of Sciences, Washington, DC.

130.

Anderson, D. M., & Morgenstern, N.R. (1973). Physics, chemistry and mechanics of frozen ground: A review. In Proceeding of 2nd International Conference of Permafrost, Yakutsk, Siberia, 13-28 July 1973, National Academy of Sciences, Washington, DC, pp. 257–288.

131.

Quintard, M., & Whitaker, S. (1995). Local thermal equilibrium for transient heat conduction: theory and comparison with numerical experiments. International Journal of Heat and Mass Transfer, 38(15), 2779–2796.MATHCrossRef

132.

Henninges, J., Schrötter, J., Erbas, K., & Huenges, E. (2002). Temperature field of the Mallik gas hydrate occurrence. Implications on phase changes and thermal properties, GEO Technologien 2002.

133.

Perry, R. H., & Chilton, C. H. (1973). Chemical engineers handbook. New York, NY: McGraw Hill.

134.

Waite, W. F., Stern, L. A., Kirby, S. H., Winters, W. J., & Mason, D. H. (2007). Simultaneous determination of thermal conductivity thermal diffusivity and specific heat in sl methane hydrate. Geophysical Journal International, 169, 767–774.CrossRef

135.

Liu, Z., Sun, Y., & Yu, X. (2012). Theoretical basis for Modeling Porous Geomaterials under Frost Actions: A Review. Soil Science Society of America Journal, 76(2), 313–330.MathSciNetCrossRef

136.

Johansen, O. (1975). Thermal conductivity of soils. Ph.D. dissertation. Norwegian University of Science and Technology, Trondheim (CRREL draft transl. 637, 1977).

137.

Cote, J., & Konrad, J. M. (2005). A generalized thermal conductivity model for soils and construction materials. Canadian Geotechnical Journal, 42, 443–458.CrossRef

138.

Lu, S., Ren, T., Gong, Y., & Horton, R. (2007). An improved model for predicting soil thermal conductivity from water content at room temperature. Soil Science Society of America Journal, 71, 8–14.CrossRef

139.

Gaddipati, M. (2008). Code comparison of methane hydrate reservoir simulators using CMG STARS, Master Thesis. West Virginia University, Morgantown, West Virginia.

140.

Sean, W., Sato, T., Yamasaki, A., & Kiyono, F. (2007). CFD and experimental study on methane hydrate dissociation part No. dissociation under water flow. American Institute of Chemical Engineers, 53(1), 262–274.CrossRef

141.

Kimoto, S., Oka, F., & Fushita, T. (2011). A chemo-thermo-mechanically coupled analysis of ground deformation induced by methane hydrate dissociation. Bifurcations, Instabilities and Degradations in Geomaterials, Springer Series in Geomechanics and Geoengineering, 0, 145–165.

142.

Konno, Y., Oyama, H., Nagao, J., Masuda, Y., & Kurihara, M. (2010). Numerical analysis of the dissociation experimental of naturally occurring gas hydrate in sediment cores obtained at the Eastern Nankai Trough, Japan. Energy Fuels, 24(12), 6353–6358.CrossRef

143.

Civan, F. C. (2001). Scale effect on porosity and permeability: Kinetics, model and correlation. AIChE Journal, 47(2), 271–287.CrossRef

144.

Jeannin, L., Bayi, A., Renard, G., Bonnefoy, O., & Herri, J. M. (2002). Formation and dissociation of methane hydrates in sediments part II: numerical modeling. Proceeding of 4th International Conference on Gas Hydrates, Yokahama, Japan, May 19–23.

145.

Sung, W., Huh, D., Ryu, B., & Lee, H. (2000). Development and application of gas hydrate reservoir simulator based on depressurizing mechanism. Korean Journal of Chemical Engineering, 17(3), 344–350.CrossRef

146.

Van Genuchten, M. T. (1980). A close-form equation for predicting the hydraulic conductivity of unsaturated soil. Soil Science Society of America Journal, 44, 892–898.CrossRef

147.

Parker, J. C., Lenhard, R. J., & Kuppusamy, T. (1987). A parametric model for constitutive properties governing multiphase flow in porous media. Water Resources Research, 23, 618–624.CrossRef

148.

Bear, J. (1972). Dynamics of Fluids in Porous Media. Mineola, NY: Dover.MATH

149.

Brooks, R. H., & Corey, A. T. (1964). Hydraulic properties of porous media. Hydrology Papers, No. 3, Colorado State University, Fort Collins.

150.

Lake, L. W. (1989). Enhanced Oil Recovery. Upper Saddle River, NJ: Prentice-Hall.

151.

Gamwo, I. K., & Liu, Y. (2010). Mathematical modeling and numerical simulation of methane production in a hydrate reservoir. Industrial & Engineering Chemistry Research, 49, 5231–5245.CrossRef

152.

Verigin, N. N., No, L. K., & Khalikov, G. A. (1980). Linear problem of the dissociation of the hydrates of a gas in a porous medium. Fluid Dynamics, 15(1), 144–147.CrossRef

153.

Willhite, P. G. (1986). Water flooding. Society of Petroleum Engineers Textbook Series (Vol. 3). Texas: Society of Petroleum Engineers.

154.

Williams, P. J., & Smith, M. W. (1989). The frozen earth: Fundamentals of geocryology. Cambridge: Cambridge University Press.CrossRef

155.

Fayer, M. J. (2000). UNSAT-H version 3.0: Unsaturated soil water and heat flow model, theory, user manual, and examples. Rep. 13249.Pac. Northwest Natl. Lab., Richland, WA.

156.

Fredlund, D. G., & Xing, A. (1994). Equations for the soil-water characteristic curve. Canadian Geotechnical Journal, 31, 521–532.CrossRef

157.

Vogel, T., van Genuchten, M. T., & Cislerova, M. (2001). Effect of the shape of the soil hydraulic functions near saturation on variably saturated flow predictions. Advances in Water Resources, 24, 133–144.CrossRef

158.

Grant, S. A., & Salehzadeh, A. (1996). Calculation of temperature effects on wetting coefficients of porous solids and their capillary pressure functions. Water Resources Research, 32(2), 261–270.CrossRef

159.

Hassanizadeh, S. M., & Gary, W. G. (1993). Thermodynamic basics of capillary pressure in porous media. Water Resources Research, 29, 3389–3405.CrossRef

160.

Morrow, N. R. (1969). Physics and thermodynamics of capillary. In Symposium on Flow Through Porous Media. Washington, DC: The Carnegie Inst.

161.

Burdine, N. T. (1953). Relative permeability calculations from pore-size distribution data. Transactions of the American Institute of Mining, Metallurgical and Petroleum Engineers, 198, 71–78.

162.

Childs, E. C., & Collis-George, G. (1950). The permeability of porous materials. Proceedings of the Royal Society of London. Series A, 201, 392–405.CrossRef

163.

Webb, S. W. (1998). Gas-phase diffusion in porous media-evaluation of an advective-dispersive formulation and the dusty-gas model for binary mixtures. Journal of Porous Media, 1(2), 187–199.MATH

164.

Pruess, K., & Moridis, G. (1999). TOUGH2 User’s Guide, Version 2.0. LBNL-43134. Lawrence Berkley National Laboratory, University of California, Berkley, CA.

165.

Yaws, C. L. (1995). Handbook of Transport Property Data: Viscosity, Thermal Conductivity, and Diffusion Coefficients of Liquids and Gases. Houston, TX: Gulf Publishing Company.

166.

Haeckel, M., & Wallmann K., et al. (2010). Main equations for gas hydrate modeling. SUGAR Internal Communication.

167.

Ahmadi, G., Ji, C., & Smith, D. H. (2004). Numerical solution for natural gas production from methane hydrate dissociation. Journal of Petroleum Science and Engineering, 41, 269–285.CrossRef

168.

Peaceman, D.W. (1977). Fundamentals of numerical reservoir simulation. Amsterdam: Elsevier Scientific Pub. Co.

169.

Weast, R. C. (1987). CRC handbook of chemistry and physics. Boca Raton: CRC Press, Inc.

170.

Shpakov, V. P., Tse, J. S., Tulk, C. A., Kvamme, B., & Belosludov, V. R. (1998). Elastic moduli calculation and instability in structure I methane clathrate hydrate. Chemical Physics Letters, 282(2), 107–114.CrossRef

171.

Tsimpanogiannis, I. N., & Lichtner, P. C. (2007). Parametric study of methane hydrate dissociation in oceanic sediments driven by thermal stimulation. Journal of Petroleum Science and Engineering, 56, 165–175.CrossRef

172.

Sloan, E. D. (1998). Clathrate hydrates of natural gases (2nd ed.). New York, NY: Marcel Dekker.

173.

Moridis, G. J. (2002). Numerical studies of gas production from methane hydrates. SPE Journal, 8(4), 1–11.

174.

Bakker, R. (1998). Improvements in clathrate modeling II: The H₂O-CO₂-CH₄-N₂-C₂H₆ fluid system. In J. P. Henriet & J. Mienert (Eds.), Gas hydrates: Relevance to world margin stability and climate change (Vol. 137, pp. 75–105). London: Geological Society Special Publication.

175.

Adisasmito, S., Frank, R. J., & Sloan, E. D. (1991). Hydrates of carbon dioxide and methane mixtures. Journal of Chemical & Engineering Data, 36, 68–71.CrossRef

176.

Moridis, G. J. (2003). Nummerical Studies of Gas Production from Methane Hydrates. SPE Journal, 8(4), 359–370.CrossRef

177.

Tishchenko, P., Hensen, C., Wallmann, K., & Wong, C. S. (2005). Calculation of the stability and solubility of methane hydrate in seawater. Chemical Geology, 219, 37–52.CrossRef

178.

Holder, G. D., & John, V. T. (1985). Thermodynamics of multicomponent hydrate forming mixtures. Fluid Phase Equilibria, 14, 353–361.CrossRef

179.

Kim, H. C., Bishnoi, P. R., Heidemann, R. A., & Rizvi, S. S. H. (1987). Kinetics of methane hydrate decomposition. Chemical Engineering Science, 42(7), 1645–1653.CrossRef

180.

Peng, D., & Robinson, D. B. (1976). A new two-constant equation of state. Industrial & Engineering Chemistry Fundamentals, 15(1), 59–64.CrossRef

181.

Amyx, J. W., Bass, D. M., & Whiting, R. L. (1960). Petroleum reservoir engineering-physical properties. New York City: McGraw-Hill Book Co.

182.

Englezos, P., Kalogerakis, N., Dholabhai, P. D., & Bishnoi, P. R. (1987). Kinetics of formation of methane and ethane gas hydrates. Chemical Engineering Science, 42, 2647–2658.CrossRef

183.

Boswell, R., Kleinberg, R., Collett, T., & Frye M. (2007). Exploration priorities for methane gas hydrate resources. Fire in the Ice, 1194 Spring/Summer 2007. pp. 11-13. (USDOE National Energy Technology Laboratory, Hydrate Newsletter).

184.

Yamamoto, K., Yasuda, M., & Osawa, O. (2005). Geomechanical condition of deep water unconsolidated and hydrate related sediments off the Pacific coast of central Japan. Proceeding of 5th International Conference on Gas Hydrate, Trondheim, Norway, Vol.3, 922 (Paper ref.3031), 13–16 June, 2005.

185.

Brugada, J., Cheng, Y. P., Soga, K., & Santamarina, J. C. (2010). Discrete element modelling of geomechanical behaviour of methane hydrate soils with pore-filling hydrate distribution. Granular Matter, 12(5), 517–525.CrossRef

186.

Soga, K., Lee, S. L., Ng, M. Y. A., & Klar, A. (2006). Characterization and engineering properties of methane hydrate soils. Proceedings of the Second International Workshop on Characterization and Engineering Properties of Natural Soils, Singapore, 29 November-1 December, Taylor & Francis, London.

187.

Durham, W., Kirby, S., & Stern, L. (2003). The strength and rheology of methane hydrate. Journal of Geophysical Research, A, Space Physics, 108, 2182–2193.

188.

Nixon, M. F., & Grozic, J. L. H. (2007). Submarine slope failure due to hydrate dissociation: A preliminary quantification. Canadian Geotechnical Journal, 44, 314–325.CrossRef

189.

Xu, W., & Germanovich, L. N. (2006). Excess pore pressure resulting from methane hydrate dissociation in marine sediments: A theoretical approach. Journal of Geophysical Research, 111, B01104.

190.

Santamarina, J. C., & Ruppel, C. (2008). The impact of hydrate saturation on the mechanical ,electrical, and thermal properties of hydrate-bearing sand, silts, and clay. Proceedings of the 6th International Conference on Gas Hydrates (ICGH 2008).

191.

Ran, H., Silin, D. B., & Patzek, T. W. (2008). Micromechanics of hydrate dissociation in marine sediments by grain-scale simulations. 2008 SPE Western Regional and Pacific Section AAPG Joint Meeting, Bakersfield, CA, 31 March-2 April.

192.

Masui, A., Miyazaki, K., Haneda, H., Ogata, Y., & Aoki, K. (2008). Mechanical characteristics of natural and artificial gas hydrate bearing sediments. Proceedings of the 6th International Conference on Gas Hydrates, ICGH.

193.

Winters, W. J., Pecher, I. A., Waite, W. F., & Mason, D. H. (2004). Physical properties and rock physics models of sediment containing natural and laboratory-formed methane gas hydrate. American Mineralogist, 89, 1221–1227.CrossRef

194.

Hyodo, M., Nakata, Y., Yoshimoto, N., & Ebinuma, T. (2005). Basic research on the mechanical behavior of methane hydrate-sediments mixture. Soils & Foundations, 45(1), 75–85.

195.

Masui, A., Haneda, H., Ogata, Y., & Aoki, K. (2005). The effect of saturation degree of methane hydrate on the shear strength of synthetic methane hydrate sediments. Proceedings of the 5th International Conference on Gas Hydrates (ICGH 2005), pp. 2657–2663.

196.

Winters, W. J., Waite, W. F., Mason, D. H., Gilbert, L. Y., & Pecher, I. A. (2007). Methane gas hydrate effect on sediment acoustic and strength properties. Journal of Petroleum Science and Engineering, 56, 127–135.CrossRef

197.

Hyodo, M., Nakata, Y., Yoshimoto, N., & Orense, R. (2007). Shear behavior of methane hydrate-bearing sand. Proceedings of the 17th International Offshore and Polar Engineering Conference, ISOPE, pp. 1326–1333.

198.

Aziz, K., & Settari, A. (1979). Petroleum reservoir simulation. Imprint London: Applied Science Publishers.

199.

Biot, M. A. (1941). General theory of three-dimensional consolidation. Journal of Applied Physics, 12(2), 155–164.MATHCrossRef

200.

Wang, H. F. (2000). Theory of linear poroelasticity: With applications to geomechanics and hydrogeology. Princeton, NJ: Princeton University Press.

201.

Bishop, A. W. (1959). The principle of effective stress.□Teknisk. Ukeblad, 106(39), 859–863.

202.

Fredlund, D. G., & Morgenstern, N. R. (1977). Stress state variables for unsaturated soils. Journal of Geotechnical Engineering, ASCE, 103(5), 447–466.

203.

Lu, N., & Likos, W. J. (2006). Suction stress characteristic curve for unsaturated soil. Journal of Geotechnical and Geoenvironmental Engineering, 132(2), 131–142.CrossRef

204.

Coussy, O. (Ed.). (2004). Poromechanics. Chichester, England: John Wiley & Sons, ltd.MATH

205.

Schrefler, B. A., & Gawin, D. (1996). The effective stress principle: incremental or finite form. International Journal for Numerical and Analytical Methods in Geomechanics, 20(11), 785–814.CrossRef

206.

Chin, L. Y., Silpngarmlert, S., & Schoderbek, D. A. (2011). Subsidence prediction by coupled modeling of geomechanics and reservoir simulation for methane hydrate reservoirs. 45th U.S. Rock Mechanics/Geomechanics Symposium, June 26-29, 2011, San Francisco, CA.

207.

Morland, L. W., Foulser, R., & Garg, S. K. (2004). Mixture theory for a fluid-saturated isotropic elastic matrix. International Journal of Geomechanics, 4(3), 207–215.CrossRef

208.

Dominic, K., & Hilton, D. (1987). Gas production from depressurization of bench-scale methane hydrate reservoirs. US Department of Energy, DOE/METC-87/4073, pp. 1–9.

209.

Kamath, V. A., Mutalik, P. N., Sira, J. H., & Patil, S. L. (1991). Experimental study of brine injection and depressurization methods for dissociation of gas hydrates. SPE Formation. Evaluation, 6(4), 477–484.

210.

Li, S., Chen, Y., & Du, Q. (2005). Sensitivity analysis in numerical simulation of natural gas hydrate production. Geoscience, 19(1), 108–112.

211.

Yang, X., Sun, C., Su, K., Yuan, Q., Li, Q., & Chen, G. (2012). A three-dimensional study on the formation and dissociation of methane in porous sediment by depressurization. Energy Conversion and Management, 56, 1–7.CrossRef

212.

Bai, Y., & Li, Q. (2010). Simulation of gas production from hydrate reservoir by the combination of warm water flooding and depressurization. Science China, 53, 2469–2475.MATHCrossRef

213.

Hovland, M., Judd, A. (Eds.). (1988). Seabed pockmarks and seepages. Impact on Geology, Biology and the Marine Environment, Graham and Trotman, London, 1988, pp. 293.

Titel: Advancement in Numerical Simulations of Gas Hydrate Dissociation in Porous Media
verfasst von: Zhen Liu
Xiong Yu
Verlag: Springer International Publishing
Buch: New Frontiers in Oil and Gas Exploration
Print ISBN: 978-3-319-40122-5

Electronic ISBN: 978-3-319-40124-9

Copyright-Jahr: 2016
DOI: https://doi.org/10.1007/978-3-319-40124-9_2

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