Non-Darcy Flow Experiments of Water Seepage through Rough-Walled Rock Fractures

Ni, Xiaodong; Niu, Yulong; Yuan, Wancheng; Yu, Ke

doi:10.1155/2018/8541421

Cited by 23 publications

(15 citation statements)

References 27 publications

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“…This deviation in the flow can be a result of significant inertial effect or fracture dilation. The results are consistent with previous literature [23,26].…”

Section: Nonlinear Flow Characteristics Under Different Jrcsupporting

confidence: 94%

Laboratory Simulation of Flow through Rough-Walled Microfractures under High Hydraulic Gradient

Zhang

Qiao

et al. 2019

Geofluids

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Laboratory experiments on fluid flow through fracture are important in solving the fluid-in-rush problems that happen during the tunnel excavation. In order to study the mechanism of fluid flow through a rough-walled microfracture, fluid flow experiments were carried out and the fiber Bragg grating (FBG) strain sensors were applied to monitor the deformation of the microfracture surface during the seepage process. Considering the difficulty of collection of undisturbed rock samples from the deep locations, a methodology to simulate fluid flow through a fractured rock mass using analog materials containing a single fracture was developed. This method is easy to simulate the fluid flow through a fracture of certain aperture. Experimental data showed that Forchheimer equation could provide an excellent description of the nonlinear relationship between hydraulic gradient and flow velocity, and the variations of Forchheimer coefficients with joint roughness coefficient (JRC) were studied. It was found that the deformation of the microfracture surface subjected to seepage could be accurately captured by the quasi-distributed FBG strain sensors. The test results also demonstrated that the surface strain is significantly affected by hydraulic pressure.

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“…This deviation in the flow can be a result of significant inertial effect or fracture dilation. The results are consistent with previous literature [23,26].…”

Section: Nonlinear Flow Characteristics Under Different Jrcsupporting

confidence: 94%

Laboratory Simulation of Flow through Rough-Walled Microfractures under High Hydraulic Gradient

Zhang

Qiao

et al. 2019

Geofluids

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“…This difference can be attributed to the result of inertial effect or fracture dilation, with the increase of flow velocity, the effect of inertial force becomes more and more significant, and the relationship between hydraulic gradient and velocity deviates from the linear relationship more and more 12 . For samples with different aperture, with the increase of the fracture aperture, the increase rate of the average velocity decreases gradually, as has been reported in the literature 24 .…”

Section: The Variation Of Normal Deformation Of the Microfracture Undsupporting

confidence: 78%

Experimental study on seepage characteristics of microfracture with different aperture

Zhang

Qiao

et al. 2020

Sci Rep

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Exploring the flow mechanism of fluid in rock mass is important in solving the water inrush problems during tunnel excavation. However, it is difficult to obtain an undisturbed rock mass from the actual site conditions and study the flow mechanism of fluid through a fracture network composed of multiple single fractures. Therefore, a solution to simulate rock seepage using rock-like samples with single microfracture was presented in this paper. Water flow through microfracture was tested and the deformation of microfracture was recorded by quasi-distributed fiber Bragg grating (FBG) technology. Experimental data showed that Forchheimer's law and Izbash's law could well describe the nonlinear relationship between flow velocity and hydraulic gradient. The coefficient b in Forchheimer's equation decreased with the increase of microfracture aperture. A critical value of E = 0.8 was proposed to classify the nonlinear flow regime: weak turbulence (E < 0.8) and fully developed turbulence (E > 0.8).

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“…Recent 3DP studies investigated shear response (and asperity degradation) (Ishibashi et al., 2020) and non‐Darcian flow regimes (Yin et al., 2020) in polymeric rough fractures. Attempts to more accurately replicate natural fracture material properties produced 3DP fracture replicas that were later molded into concrete (Q. Jiang, Feng, Gong, et al., 2016; Ni et al., 2018) or natural minerals (Fang et al., 2018). However, replicating fractures using higher strength materials is resolution‐limited.…”

Section: Introductionmentioning

confidence: 99%

“…Attempts to more accurately replicate natural fracture material properties produced 3DP fracture replicas that were later molded into concrete (Q. Ni et al, 2018) or natural minerals (Fang et al, 2018). However, replicating fractures using higher strength materials is resolution-limited.…”

mentioning

confidence: 99%

A Systematic Investigation Into the Control of Roughness on the Flow Properties of 3D‐Printed Fractures

Phillips

Bultreys

Bisdom

et al. 2021

Water Resources Research

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Non-Darcy Flow Experiments of Water Seepage through Rough-Walled Rock Fractures

Cited by 23 publications

References 27 publications

Laboratory Simulation of Flow through Rough-Walled Microfractures under High Hydraulic Gradient

Laboratory Simulation of Flow through Rough-Walled Microfractures under High Hydraulic Gradient

Experimental study on seepage characteristics of microfracture with different aperture

A Systematic Investigation Into the Control of Roughness on the Flow Properties of 3D‐Printed Fractures

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