Mechanical Properties of Fluid-Bearing Rocks

Nikolai Bagdassarov

doi:10.1017/9781108380713.007

6 - Mechanical Properties of Fluid-Bearing Rocks

Published online by Cambridge University Press: 19 November 2021

Nikolai Bagdassarov

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Nikolai Bagdassarov: Affiliation:
Goethe-Universität Frankfurt Am Main

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Summary

Poroelastic problems are considered for drained and undrained rock conditions. The effective pressure coefficient a for bulk modulus is introduced to describe the effective pressure. The Skempton’s coefficient characterizes the relationship between pore pressure change and change in ambient pressure. The Gassman equation relates the bulk modulus of rock matrix, fluid and undrained rock with porosity and drained bulk modulus. Pore pressure follows the diffusion type equation: fluid transport and diffusion. Stress in rocks at depth may be estimated from hydraulic fracturing conditions. To calculate effective bulk and shear moduli of porous rocks, the differential Mori-Tanaka scheme is used. The effective bulk and shear moduli of a medium containing a family of identical-shaped pores can be expressed via the pore compressibility P and shear Q compliances. Focus Box 6.1: Elliptical coordinates and elliptical-shaped pores.

Keywords

Poroelasticity effective pressure Gassmann equation fluid transport and diffusion hydraulic fracture time constants of fluid transport in porous rocks.

Type: Chapter
Information: Fundamentals of Rock Physics , pp. 211 - 244

DOI: https://doi.org/10.1017/9781108380713.007 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2021

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Literature

Berge, P. A., Wang, H. F. & Bonner, B. P. (1993). Pore pressure buildup coefficient in synthetic and natural sandstones. International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts 30(7), 1135–1141.Google Scholar

Biot, M. A. (1941). General theory of three-dimensional consolidation. Journal of Applied Physics 12, 155–164. https://doi.org/10.1063/1.1712886.Google Scholar

Brady, B. H. G. & Brown, E. T. (2004). Rock Mechanics. For Underground Mining. Kluwer Academic Press, Dordrecht, p. 628.Google Scholar

Carpenter, C. B. & Spencer, G. E. (1940). Measurements of compressibility of consolidated oil-bearing sandstones. Report of Investigations 3540, United States Department of The Interior – Bureau of Mines, Washington, DC.Google Scholar

David, E. C. & Zimmerman, R. W. (2011). Compressibility and shear compliance of spheroidal pores: Exact derivation via the Eshelby tensor, and asymptotic expressions in limiting cases. International Journal of Solids and Structures 48, 680–686.CrossRef Google Scholar

David, E. C. & Zimmerman, R. W. (2012). Pore structure model for elastic wave velocities in fluid-saturated sandstones. Journal of Geophysical Research 117, B07210. doi: 10.1029/2012JB009195.Google Scholar

Geertsma, J. (1957). The effect of fluid pressure decline on volumetric changes of porous rock. Transactions of the AIME 210, 331–339.CrossRef Google Scholar

Guéguen, Y., Dormieux, L. & Boutéca, M. (2004). Fundamentals of poromechanics. In: Guéguen, Y. & Boutéca, M. (Eds.) Mechanics of Fluid Saturated Rocks. Elsevier Academic Press, Amsterdam, Boston, International Geophysics Series 89, chapter 1: 1–54.Google Scholar

Guéguen, Y. & Palciauskas, V. (1994). Introduction to the Physics of Rocks. Princeton University Press, Princeton, NJ, p. 294.Google Scholar

Haimson, B. & Fairhurst, C. (1967). Initiation and extension of hydraulic fractures in rocks. Society of Petroleum Engineers 1710, 310–318.CrossRef Google Scholar

Hantush, M. S. (1960). Modification of the theory of leaky aquifers. Journal of Geophysical Research 65(11), 3713–3725.CrossRef Google Scholar

Hart, D. J. (2000). Laboratory measurements of poroelastic constants and flow parameters and some associated phenomena, PhD thesis, University of Wisconsin, Madison, p. 122.Google Scholar

Hofmann, R., Xu, X., Batzle, M., et al. (2005). Effective pressure or what is the effect of pressure? The Leading Edge 24(12), 1256–1260.Google Scholar

Jaeger, J. C., Cook, N. G. & Zimmerman, R. W. (2009). Fundamentals of Rock Mechanics. J. Wiley & Sons, New York, 593 S.Google Scholar

Key, P. L. (1969). A relation between crack surface displacements and the strain energy release rate. International Journal of Fracture Mechanics 5, 287–296.Google Scholar

Krumbein, W. C. & Sloss, L. L. (1953). Stratigraphy and Sedimentation. Freeman & Co., San Francisco, California, p. 218.Google Scholar

Kümpel, H.-J. (1991). Poroelasticity: parameters reviewed. Geophysical Journal International 105, 783–799.CrossRef Google Scholar

Lan, Y., Moghanloo, R. G. & Davudov, D. (2017). Pore compressibility of shale formations. Society of Petroleum Engineers 22(6), SPE-185059-PA (12pp.). doi:10.2118/185059-PA.Google Scholar

Landau, L. D. & Lifschitz, E. M. (1986). Theory of Elasticity. Pergamon, Oxford.Google Scholar

LeRavalec, M. & Guéguen, Y. (1996). High- and low-frequency elastic moduli for a saturated porous/cracked rock – Differential self-consistent and poroelastic theories. Geophysics 61, 1080–1094.CrossRef Google Scholar

Luo, X., Were, P., Liu, J. & Hou, Z. (2015). Estimation of Biot’s effective stress coefficient from well logs. Environmental Earth Sciences 73, 7019–7028. doi: 10.1007/s12665-015-4219-8.Google Scholar

Marcussen, Ø., Maast, T. F., Mondol, N. H., Jahren, J. & Bjørlykke, K. (2010). Changes in physical properties of a reservoir sandstone as a function of burial depth – The Etive Formation, northern North Sea. Marine and Petroleum Geology 27, 1725–1735.CrossRef Google Scholar

Mavko, G., Mukerji, T. & Dvorkin, J. (1998). The Rock Physics Handbook. Cambridge University Press, Cambridge, p. 330.Google Scholar

Nur, A., Mavko, G., Dvorkin, J & Gal, D. (1995). Critical porosity: The key to relating physical properties to porosity in rocks. SEG Technical Program Expanded Abstracts 14(1), 878–881.Google Scholar

Perras, M. A. & Diederichs, M. S. (2014). A review of the tensile strength of rock: Concepts and testing. Geotechnical and Geological Engineering 32, 525–546. doi: 10.1007/s10706-014-9732-0.CrossRef Google Scholar

Pimienta, L., Fortin, J. & Guéguen, Y. (2016). Effect of fluids and frequency on Poisson’s ratio of sandstone samples. Geophysics 82(2), D35–D47. doi:10.1190/GEO2015-0310.1.Google Scholar

Saberi, R. M. & Jenson, F. (2018). Determining dynamic Biot’s coefficient for unconventionals. www.hartenergy.com/exclusives/determining-dynamic-biots-coefficient-unconventionals–177102.Google Scholar

Salemi, H., Iglauer, S., Rezagholilou, A. & Sarmadivaleh, M. (2018). Laboratory measurement of Biot’s coefficient and pore pressure influence on poroelastic rock behaviour. The APPEA Journal 58(1), 182–189. www.publish.csiro.au/aj/AJ17069.Google Scholar

Schmitt, D. R. & Zoback, M. D. (1989). Poroelastic effects in the determination of the maximum horizontal principal stress in hydraulic fracturing tests: A proposed breakdown equation employing a modified effective stress relation for tensile failure. International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts 26(6), 499–506.Google Scholar

Sneddon, I. N. (1946). The distribution of stress in the neighborhood of a crack in an elastic solid. Proceedings of the Royal Society 187A, 229–260. https://doi.org/10.1098/rspa.1946.0077.Google Scholar

Timoshenko, S. P. & Goodier, J. N. (1951). Theory of Elasticity. McGraw Hill, New York, p. 506.Google Scholar

Todd, T. & Simmons, G. (1972). Effect of pore pressure on the velocity of compressional waves in low-porosity rocks. Journal of Geophysical Research 77(20), 3731–3743. doi:10.1029/JB077i020p03731.CrossRef Google Scholar

Valkó, P. & Economides, M. J. (1994). Propagation of hydraulically induced fractures a continuum damage mechanics approach. International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts 31(3), 221–229.Google Scholar

Vasquez, G. F., VargasJr., E. A., Ribeiro, C. J. B., Leão, M. & Justen, J. C. R. (2009). Experimental determination of the effective pressure coefficients for Brazilian limestones and sandstones. Revista Brasileira de Geofísica 27(1), 43–53.CrossRef Google Scholar

Wang, H. F. (2000). Theory of Linear Poroelasticity with Applications to Geomechanics and Hydrogeology. Princeton University Press, Princeton and Oxford.Google Scholar

Zimmerman, R. W. (1985). Compressibility of an isolated spheroidal cavity in an isotropic elastic medium. Journal of Applied Mechanics 52, 606–608. doi: 10.1115/1.3169108.CrossRef Google Scholar

Zimmerman, R. W. (2017). Pore volume and porosity changes under uniaxial strain conditions. Transport in Porous Media 119, 481–498. doi: 10.1007/s11242-017-0894-0.CrossRef Google Scholar