2013
DOI: 10.1016/j.enggeo.2013.05.013
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The use of discrete fracture network simulations in the design of horizontal hillslope drainage networks in fractured rock

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Cited by 41 publications
(13 citation statements)
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“…The discrete fracture network (DFN) model, which can consider most of the above parameters, has been increasingly utilized to simulate fluid flow in the complex 2 Geofluids fractured rock masses [57][58][59][60], although it cannot model the aperture heterogeneity of each fracture [61][62][63]. In the numerical simulations and/or analytical analysis, the linear governing equation such as the cubic law is solved to simulate fluid flow in fractures by applying constant hydraulic gradients ( ) on the two opposing boundaries, such as = 1 [57,[64][65][66][67][68]], = 0.1 [41], = 0.001 [69,70], and = unknown constants [11,34,46,[71][72][73]. This assumption that fluid flow obeys the cubic law is suitable for characterizing hydraulic behaviors of deep underground engineering, in which the flow rate is sufficiently small.…”
Section: Introductionmentioning
confidence: 99%
“…The discrete fracture network (DFN) model, which can consider most of the above parameters, has been increasingly utilized to simulate fluid flow in the complex 2 Geofluids fractured rock masses [57][58][59][60], although it cannot model the aperture heterogeneity of each fracture [61][62][63]. In the numerical simulations and/or analytical analysis, the linear governing equation such as the cubic law is solved to simulate fluid flow in fractures by applying constant hydraulic gradients ( ) on the two opposing boundaries, such as = 1 [57,[64][65][66][67][68]], = 0.1 [41], = 0.001 [69,70], and = unknown constants [11,34,46,[71][72][73]. This assumption that fluid flow obeys the cubic law is suitable for characterizing hydraulic behaviors of deep underground engineering, in which the flow rate is sufficiently small.…”
Section: Introductionmentioning
confidence: 99%
“…The previous works of calculating the equivalent permeability of fracture networks commonly presumed that the fluid flow follows the cubic law by applying constant hydraulic gradients (J) on the opposite boundaries such as J = 1 (Long et al 1982;Zhang et al , 1999Klimczak et al 2010;Zhao et al 2010aZhao et al , 2011b, J = 0.1 , J = 0.001 (Cvetkovic et al 2004;Zhao 2013), and J = unknown constants (Min et al 2004;Jing 2007, 2008;Parashar and Reeves 2012;Reeves et al 2013;Latham et al 2013), which, however, deviates from the in-situ hydraulic test results where increasing the hydraulic gradient would decrease the permeability of rock masses when the hydraulic gradient is sufficiently large (Gale 1984;Kohl et al 1997;Chen et al 2015a, c). Liu et al (2016a) established a series of DFN models as described in section 'Permeability and number of intersections', and studied the effects of hydraulic gradient on the equivalent permeability of rock fracture networks.…”
Section: Permeability and Hydraulic Gradientmentioning
confidence: 99%
“…Actually, in natural fractured rock masses, the fracture length has very broad distributions and is observed to follow the power-law, exponential, and lognormal types of functions (Chelidze and Gueguen 1990;Chang and Yortsos 1990;Sahimi 1993;Watanabe and Takahashi 1995a, b;Andrade et al 2009;Torabi and Berg 2011;Torabi 2012, 2013). Among them, the power law distribution has been most widely utilized (Segall and Pollard 1983;Gudmundsson 1987;Childs et al 1990;Sornette et al 1993;Davy 1993;Bour and Davy 1997;Bogdanov et al 2007;Reeves et al 2013), with a typical form of…”
Section: Permeability and Fracture-length Distributionmentioning
confidence: 99%
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“…It is well-known that the interconnected fracture network forms the preferred flow paths in the formation [22,58,59]. These pathways are "paths of least resistance", where most of the flow and solute is concentrated [7,26,36,60], resulting in early arrivals. Matrix block size, which is typically characterized using fracture spacing, affects trapping time and influences late-time tailing in BTCs.…”
Section: Impact Of Fracture Density On Non-fickian Transportmentioning
confidence: 99%