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Rock Mechanics and Rock Engineering

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09.11.2015 | Original Paper

Calculation Method and Distribution Characteristics of Fracture Hydraulic Aperture from Field Experiments in Fractured Granite Area

verfasst von: Yang-Bing Cao, Xia-Ting Feng, E-Chuan Yan, Gang Chen, Fei-fei Lü, Hui-bin Ji, Kuang-Yin Song

Erschienen in: Rock Mechanics and Rock Engineering | Ausgabe 5/2016

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Abstract

Knowledge of the fracture hydraulic aperture and its relation to the mechanical aperture and normal stress is urgently needed in engineering construction and analytical research at the engineering field scale. A new method based on the in situ borehole camera measurement and borehole water-pressure test is proposed for the calculation of the fracture hydraulic aperture. This method comprises six steps. The first step is to obtain the equivalent hydraulic conductivity of the test section from borehole water-pressure tests. The second step is a tentative calculation to obtain the qualitative relation between the reduction coefficient and the mechanical aperture obtained from borehole camera measurements. The third step is to choose the preliminary reduction coefficient for obtaining the initial hydraulic aperture. The remaining three steps are to optimize, using the genetic algorithm, the hydraulic apertures of fractures with high uncertainty. The method is then applied to a fractured granite engineering area whose purpose is the construction of an underground water-sealed storage cavern for liquefied petroleum gas. The probability distribution characteristics of the hydraulic aperture, the relationship between the hydraulic aperture and the mechanical aperture, the hydraulic aperture and the normal stress, and the differences between altered fractures and fresh fractures are all analyzed. Based on the effects of the engineering applications, the method is proved to be feasible and reliable. More importantly, the results of the hydraulic aperture obtained in this paper are different from those results elicited from laboratory tests, and the reasons are discussed in the paper.

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Nächster Artikel A Novel Mogi Type True Triaxial Testing Apparatus and Its Use to Obtain Complete Stress–Strain Curves of Hard Rocks

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Amadei B, Illangasekare T (1994) A mathematical model for flow and solute transport in non-homogeneous rock fractures. Int J Rock Mech Min Sci Geomech Abstr 31:719–731CrossRef

Baghbanan A, Jing L (2007) Hydraulic properties of fractured rock masses with correlated fracture length and aperture. Int J Rock Mech Min Sci 44:704–719CrossRef

Baghbanan A, Jing L (2008) Stress effects on permeability in a fractured rock mass with correlated fracture length and aperture. Int J Rock Mech Min Sci 45:1320–1334CrossRef

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

Carlsson A, Olsson T (1993) The analysis of fractures, stress and water flow for rock engineering projects. Compr Rock Eng 2:126–133

Chen Z, Narayan SP, Yang Z, Rahman SS (2000) An experimental investigation of hydraulic behavior of fractures and joints in granitic rock. Int J Rock Mech Min Sci 37:1061–1071CrossRef

Gale JE (1982) The effects of fracture type (induced verses natural) on the stress-fracture closure permeability relationships. The 23rd US symposium on rock mechanics, pp. 209–217

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

Hakami E (1995) Aperture distribution of rock fractures. PhD thesis, Royal Institute of Technology, Stockholm, Sweden

Hjerne C, Nordqvist R (2014) Relation between mass balance aperture and hydraulic properties from field experiments in fractured rock in Sweden. Hydrogeol J 22:1285–1292CrossRef

Hubbert KM, Willis DG (1957) Mechanics of hydraulic fracturing. Pet Trans AIME TP 4597 210:153–166

Hvorslev MJ (1951) Time lag and soil permeability in ground-water observations. Transp Res Board 36, pp 50

Ju Y, Zhang QG, Yang YM, Xie HP, Gao F, Wang HJ (2013) An experimental investigation on the mechanism of fluid flow through single rough fracture of rock. Sci China Technol Sci 56:2070–2080CrossRef

Kishida K, Sawada A, Yasuhara H, Hosoda T (2013) Estimation of fracture flow considering the inhomogeneous structure of single rock fractures. Soils Found 53:105–116CrossRef

Klimczak C, Schultz RA, Parashar R, Reeves DM (2010) Cubic law with aperture-length correlation: implications for network scale fluid flow. Hydrogeol J 18:851–862CrossRef

Koyama T, Li B, Jiang Y, Jing L (2009) Numerical modelling of fluid flow tests in a rock fracture with a special algorithm for contact areas. Comput Geotech 36:291–303CrossRef

Kranz RL, Frankel AD, Engelder T, Scholz CH (1979) Permeability of whole and jointed Barre granite. Int J Rock Mech Min Sci Geomech Abstr 16:225–234CrossRef

Li SJ, Feng XT, Wang CY, Hudson JA (2013) ISRM suggested method for rock fractures observations using a borehole digital optical televiewer. Rock Mech Rock Eng 46:635–644CrossRef

Lomize GM (1951) Flow in fractured rocks. Gosenergoizdat, Moscow

Louis C (1969) A study of groundwater flow in jointed rock and its influence on the stability of rock masses. Imperial College of Science and Technology, London

Louis C (1972) Rock hydraulics in Rock mechanics. Springer, Vienna

Matsuki K, Chida Y, Sakaguchi K, Glover PWJ (2006) Size effect on aperture and permeability of a fracture as estimated in large synthetic fractures. Int J Rock Mech Min Sci 43:726–755CrossRef

Méheust Y, Schmittbuhl J (2003) Scale effects related to flow in rough fractures. Pure Appl Geophys 160:1023–1050CrossRef

Meng Z, Zhang J, Wang R (2011) In-situ stress, pore pressure and stress-dependent permeability in the Southern Qinshui Basin. Int J Rock Mech Min Sci 48:122–131CrossRef

Min KB, Rutqvist J, Tsang CF, Jing L (2004) Stress-dependent permeability of fractured rock masses: a numerical study. Int J Rock Mech Min Sci 41:1191–1210

Mortimer L, Aydin A, Simmons CT, Love AJ (2011) Is in situ stress important to groundwater flow in shallow fractured rock aquifers? J Hydrol 399:185–200CrossRef

Pan PZ, Feng XT, Xu DP, Shen LF, Yang JB (2011) Modelling fluid flow through a single fracture with different contacts using cellular automata. Comput Geotech 38:959–969CrossRef

Pan PZ, Rutqvist J, Feng XT, Yan F (2014) TOUGH–RDCA modeling of multiple fracture interactions in caprock during CO₂ injection into a deep brine aquifer. Comput Geosci 65:24–36CrossRef

Pyrak-Nolte LJ, Morris JP (2000) Single fractures under normal stress: the relation between fracture specific stiffness and fluid flow. Int J Rock Mech Min Sci 37:245–262CrossRef

Qian J, Zhan H, Luo S, Zhao W (2007) Experimental evidence of scale-dependent hydraulic conductivity for fully developed turbulent flow in a single fracture. J Hydrol 339:206–215CrossRef

Rasouli V, Hosseinian A (2011) Correlations developed for estimation of hydraulic parameters of rough fractures through the simulation of JRC flow channels. Rock Mech Rock Eng 44:447–461CrossRef

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 22:251–261CrossRef

Rutqvist J (2015) Fractured rock stress–permeability relationships from in situ data and effects of temperature and chemical–mechanical couplings. Geofluids 15:48–66CrossRef

Scesi L, Gattinoni P (2007) Roughness control on hydraulic conductivity in fractured rocks. Hydrogeol J 15:201–211CrossRef

Snow DT (1969) Anisotropic permeability of fractured media. Water Resour Res 5:1273–1289CrossRef

Tsang YW (1984) The effect of tortuosity on fluid flow through a single fracture. Water Resour Res 20:1209–1215CrossRef

Tsang YW (1992) Usage of “equivalent apertures” for rock fractures as derived from hydraulic and tracer tests. Water Resour Res 28:1451–1455CrossRef

Tsang YW, Tsang CF (1987) Channel model of flow through fractured media. Water Resour Res 23:467–479CrossRef

Tsang YW, Witherspoon PA (1981) Hydromechanical behavior of a deformable rock fracture subject to normal stress. J Geophys Res 86(B10):9287–9298CrossRef

Tsang YW, Witherspoon PA (1983) The dependence of fracture mechanical and fluid flow properties on fracture roughness and sample size. J Geophys Res 88(B3):2359–2366CrossRef

Watanabe N, Hirano N, Tsuchiya N (2009) Diversity of channeling flow in heterogeneous aperture distribution inferred from integrated experimental–numerical analysis on flow through shear fracture in granite. J Geophys Res 114:B04208

Wen Z, Huang G, Zhan H (2006) Non-Darcian flow in a single confined vertical fracture toward a well. J Hydrol 330:698–708CrossRef

Witherspoon PA, Amick CH, Gale JE, Iwai K (1979) Observations of a potential size effect in experimental determination of the hydraulic properties of fractures. Water Resour Res 15:1142–1146CrossRef

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

Yoon JS, Zang A, Stephansson O (2014) Numerical investigation on optimized stimulation of intact and naturally fractured deep geothermal reservoirs using hydro-mechanical coupled discrete particles joints model. Geothermics 52:165–184CrossRef

Zhang Z, Nemcik J (2013) Friction factor of water flow through rough rock fractures. Rock Mech Rock Eng 46:1125–1134CrossRef

Zhang Z, Nemcik J, Ma S (2013) Micro- and macro-behaviour of fluid flow through rock fractures: an experimental study. Hydrogeol J 21:1717–1729CrossRef

Zhou CB, Sharma RS, Chen YF (2008) Flow–stress coupled permeability tensor for fractured rock masses. Int J Numer Anal Meth Geomech 32:1289–1309CrossRef

Titel: Calculation Method and Distribution Characteristics of Fracture Hydraulic Aperture from Field Experiments in Fractured Granite Area
verfasst von: Yang-Bing Cao
Xia-Ting Feng
E-Chuan Yan
Gang Chen
Fei-fei Lü
Hui-bin Ji
Kuang-Yin Song
Publikationsdatum: 09.11.2015
Verlag: Springer Vienna
Erschienen in: Rock Mechanics and Rock Engineering / Ausgabe 5/2016
Print ISSN: 0723-2632
Elektronische ISSN: 1434-453X
DOI: https://doi.org/10.1007/s00603-015-0881-0

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