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Hydrogeology Journal

Erschienen in:

01.06.2010 | Paper

Cubic law with aperture-length correlation: implications for network scale fluid flow

verfasst von: Christian Klimczak, Richard A. Schultz, Rishi Parashar, Donald M. Reeves

Erschienen in: Hydrogeology Journal | Ausgabe 4/2010

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Abstract

Previous studies have computed and modeled fluid flow through fractured rock with the parallel plate approach where the volumetric flow per unit width normal to the direction of flow is proportional to the cubed aperture between the plates, referred to as the traditional cubic law. When combined with the square root relationship of displacement to length scaling of opening-mode fractures, total flow rates through natural opening-mode fractures are found to be proportional to apertures to the fifth power. This new relationship was explored by examining a suite of flow simulations through fracture networks using the discrete fracture network model (DFN). Flow was modeled through fracture networks with the same spatial distribution of fractures for both correlated and uncorrelated fracture length-to-aperture relationships. Results indicate that flow rates are significantly higher for correlated DFNs. Furthermore, the length-to-aperture relations lead to power-law distributions of network hydraulic conductivity which greatly influence equivalent permeability tensor values. These results confirm the importance of the correlated square root relationship of displacement to length scaling for total flow through natural opening-mode fractures and, hence, emphasize the role of these correlations for flow modeling.

Vorheriger Artikel Semi-empirical equations for the systematic decrease in permeability with depth in porous and fractured media

Nächster Artikel Hydraulic conductivity distribution in crystalline rocks, derived from inflows to tunnels and galleries in the Central Alps, Switzerland

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Baghbanan A, Jing L (2006) Hydraulic properties of fractured rock masses with correlated fracture length and aperture. Int J Rock Mech Min Sci 44:704–719

Bandis SC, Makurat A, Vik G (1985) Predicted and measured hydraulic conductivity of rock joints. Proceedings of the International Symposium on Fundamentals of Rock Joints, Bjorkliden, Sweden, 15–20 September, pp 269–280

Barton NR, Bandis SC, Bakhtar K (1985) Strength, deformation and conductivity coupling of rock joints. Int J Rock Min Sci Geomech Abstr 22(3):121–140CrossRef

Bear J, Tsang CF, de Marsily G (1993) Flow and contaminant transport in fractured rock. Academic, San Diego, CA

Best DJ, Fisher NI (1979) Efficient simulation of the von Mises distribution. Appl Stat 28(2):152–157CrossRef

Bonnet E, Bour O, Odling NE, Davy P, Main I, Cowie P, Berkowitz B (2001) Scaling of fracture systems in geologic media. Rev Geophys 39(3):347–383CrossRef

Boussinesq J (1868) Memoire sur l’influence des frottements dans les mouvements reguliers des fluids [Thesis about the influence of friction within the steady flow of fluids]. J Math Pures Appl 13:377–424

Brown SR (1987) Fluid flow through rock joints: the effect of surface roughness. J Geophys Res 92:1337–1347CrossRef

Brown SR, Scholz CH (1985) The closure of random elastic surfaces in contact. J Geophys Res 90:5531–5545CrossRef

Chen SH, Feng XM, Isam S (2008) Numerical estimation of REV and permeability tensor for fractured rock masses by composite element method. Int J Numer Anal Meth Geomech 32:1459–1477CrossRef

Clark RM, Cox SJD (1996) A modern regression approach to determining fault displacement-length scaling relationship. J Struct Geol 18:147–152CrossRef

Cook AM, Myer LR, Cook NGW, Doyle FM (1990) The effect of tortuosity on flow through a natural fracture. In: Hustrulid WA, Johnson WA (ed) Rock mechanics contributions and challenges, Proceedings of the 31st US Symposium on Rock Mechanics. Golden, CO, June 1990

Cowie PA, Scholz CH (1992a) Physical explanation for the displacement-length relationship of faults using a post-yield fracture mechanics model. J Struct Geol 14:1133–1148CrossRef

Cowie PA, Scholz CH (1992b) Displacement-length scaling relationship for faults: data synthesis and discussion. J Struct Geol 14:1149–1156CrossRef

Davy P (1993) On the frequency-length distribution of the San Andreas fault system. J Geophys Res 98:12141–12151CrossRef

Dawers NH, Anders MH (1995) Displacement-length scaling and fault linkage. J Struct Geol 17:607–614CrossRef

Dawers NH, Anders MH, Scholz CH (1993) Growth of normal faults: displacement-length scaling. Geology 21:1107–1110CrossRef

De Dreuzy J-R, Davy P, Bour O (2001) Hydraulic properties of two-dimensional random fracture networks following a power law length distribution 2: permeability networks based on lognormal distribution of apertures. Water Resour Res 37:2079–2095CrossRef

Dreuzy D, Davy P, Bour O (2002) Hydraulic properties of two-dimensional fracture networks following power law distributions of length and aperture. Water Resour Res 38, W06412. doi:10.1029/2001WR001009

Gangi AF (1978) Variation of whole and fractured porous rock permeability with confining pressure. Int J Rock Min Sci Geomech Abstr 15:249–257CrossRef

Hartley L, Cox L, Holton D, Hunter F, Joyce S, Gylling B, Lindgren M (2004) Groundwater flow and radionuclide transport modelling using CONNECTFLOW in support of the SR Can assessment. SKB Rapport R-04-61, Svensk Kärnbränslehantering AB. Swedish Nuclear Fuel and Waste Management Co, Stockholm

Irwin GR (1957) Analysis of stresses and strains near the end of a crack. J Appl Mech 24:361–369

Jaeger JC (1969) Elasticity, fracture and flow: with engineering and geological applications. Chapman and Hall, London

Jaeger JC, Cook NGW (1979) Fundamentals of rock mechanics. Chapman and Hall, London

Krantz RE, Frankel AD, Engelder T, Scholz CH (1979) The permeability of whole and jointed Barre granite. Int J Rock Min Sci Geomech Abstr 16:225–234CrossRef

Kulatilake PHSW, Panda B (2000) Effect of block size and joint geometry on jointed rock hydraulics and REV. J Engrg Mech 126(8):850–858CrossRef

Lawn B (1993) Fracture of brittle solids. Cambridge University Press, CambridgeCrossRef

Lomize GM (1961) Filtrarsiia v Treshchinovatykh Porod [Water flow in jointed rock]. Gosenergoizdat, Moscow

Long JCS, Gilmour P, Witherspoon PA (1985) A model for steady fluid flow in random three-dimensional networks of disc-shaped fractures. Water Resour Res 21:1105–1115CrossRef

Louis CA (1969) A study of groundwater flow in jointed rock and its influence of the stability of rock masses. Rock Mechanics Research Report 10. Imperial College, London

Marrett R (1996) Aggregate properties of fracture populations. J Struct Geol 18:169–178CrossRef

Masihi M, King PR (2007) A correlated fracture network: modeling and percolation properties. Water Resour Res 43, W07439. doi:10.29/2006WR005331

Min KB, Jing L, Stephansson O (2004) Determining the equivalent permeability tensor for fractured rock masses using a stochastic REV approach: method and application to the field data from Sellafield, UK. Hydrogeol J 12:497–510CrossRef

Neuman SP (2008) Multiscale relationships between fracture length, aperture, density and permeability. Geophys Res Lett 35, L22402. doi:10.1029/2008GL035622 CrossRef

National Research Council (1996) Rock fractures and fluid flow: contemporary understanding and applications. National Academy Press, Washington, DC

Odling NE (1997) Scaling and connectivity of joint systems in sandstones from western Norway. J Struct Geol 19:1257–1271CrossRef

Olson JE (2003) Sublinear scaling of fracture aperture versus length: an exception or the rule? J Geophys Res 108(B9), 2413. doi:10.1029/2001JB000419

Paris PC, Sih GC (1965) Stress analysis of cracks. In: Fracture toughness testing and its applications. Special Technical Publication, vol. 381, American Society for Testing and Materials, West Conshohocken, PA, pp 30–83

Pollard DD, Segall P (1987) Theoretical displacements and stresses near fractures in rock: with applications to faults, joint, veins, dikes and solution surfaces. In: Atkinson BK (ed) Fracture mechanics of rock. Academic Press, San Diego, CA

Priest SD (1993) Discontinuity analysis of rock engineering. Chapman and Hall, London

Raven KG, Gale JE (1985) Water flow in a natural rock fracture as a function of stress and sample size. Int J Rock Mech Min Sci Geomech Abstr 22(4):251–261CrossRef

Renshaw CE (1995) On the relationship between mechanical and hydraulic apertures in rough-walled fractures. J Geophys Res 100:24629–24636CrossRef

Renshaw CE (1996) Influence of subcritical fracture growth on the connectivity of fracture networks. Water Resour Res 32(6):1519–1530CrossRef

Renshaw CE (1999) Connectivity of joint networks with power law length distributions. Water Resour Res 35(9):2661–2670CrossRef

Rivard C, Delay F (2004) Simulations of solute transport in fractured porous media using 2D percolation networks with uncorrelated hydraulic conductivity fields. Hydrogeol J 12:613–627CrossRef

Rubin AM (1995) Propagation of magma-filled cracks. Annu Rev Earth Planet Sci 23:287–336CrossRef

Scholz CH (2002) The mechanics of earthquakes and faulting. Cambridge Univ Press, Cambridge

Schultz RA, Soliva R, Fossen H, Okubo CH, Reeves DM (2008a) Dependence of displacement-length scaling relations for fractures and deformation bands on the volumetric changes across them. J Struct Geol 30:1405–1411CrossRef

Schultz RA, Mège D, Diot H (2008b) Emplacement conditions of igneous dikes in Ethiopian Traps. J Volc Geotherm Res 178(4):683–692CrossRef

Sih GC (1962) On singular character of thermal stresses near a crack tip. J Appl Mech 29:587

Sih GC, Libowitz H (1968) Fracture. Academic, New York

Snow DT (1965) A parallel plate model of fractured permeable media. PhD Thesis Univ. of Calif., Berkeley, USA

Taylor WL, Pollard DD, Aydin A (1999) Fluid flow in discrete joint sets: field observations and numerical simulations. J Geophys Res 104:28983–29006CrossRef

Timoshenko SP, Goodier JN (1970) Theory of elasticity. McGraw-Hill, New York

Tsang YW, Witherspoon PA (1981) Hydromechanical behavior of a deformable rock fracture subject to normal stress. J Geophys Res 86:9287–9298CrossRef

Vermilye JM, Scholz CH (1995) Relation between vein length and aperture. J Struct Geol 17:423–434CrossRef

Ward KA (1993) Dike emplacement and deformation in the Donner Summit pluton, central Sierra Nevada, California. MSc Thesis, Univ. of Nev., USA

Watanabe N, Hirano N, Tsuchia N (2008) Determination of aperture structure and fluid flow in a rock fracture by high-resolution numerical modeling on the basis of a flow-through experiment under confining pressure. Water Resour Res 44, W06412. doi:10.1029/2006WR005411

Witherspoon PA, Wang JSY, Iwai K, Gale JE (1980) Validity of cubic law for fluid flow in a deformable rock fracture. Water Resour Res 16:1016–1024CrossRef

Zhang X, Sanderson DJ, Harkness RM, Last NC (1996) Evaluation of the 2-D permeability tensor for fractured rock masses. Int J Rock Mech Min Sci Geomech Abstr 33(1):17–37CrossRef

Titel: Cubic law with aperture-length correlation: implications for network scale fluid flow
verfasst von: Christian Klimczak
Richard A. Schultz
Rishi Parashar
Donald M. Reeves
Publikationsdatum: 01.06.2010
Verlag: Springer-Verlag
Erschienen in: Hydrogeology Journal / Ausgabe 4/2010
Print ISSN: 1431-2174
Elektronische ISSN: 1435-0157
DOI: https://doi.org/10.1007/s10040-009-0572-6

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