Estimation of Hydraulic Conductivity Tensor of Nearly-horizontal Stratified Fractured Rock Mass Based on Seepage-Stress Coupling Theory

doi:10.11988/ckyyb.20231110

Abstract

Abstract:

Quantitative evaluation of the permeability and anisotropy of fractured rock masses is crucial for engineering geological investigations in water conservancy and hydropower projects. Such evaluations provide essential technical support for designing anti-seepage curtains, foundation pit drainage systems, and predicting water inrush in hydraulic tunnels. In this paper, we introduce a method for estimating the hydraulic conductivity tensor of nearly horizontally layered fractured rock masses based on “seepage-stress” coupling theory. This method integrates conventional vertical borehole water pressure tests, horizontal directional borehole water pressure tests, and rock mass stress tests. By establishing a negative exponential function relationship between normal stress and aperture, the equivalent hydraulic aperture of the structural plane is estimated, and the hydraulic conductivity tensor of the rock mass is calculated. This method has been applied to the Guxian water resources management project on Yellow River as a case study. The anisotropy of the hydraulic conductivity in the dam site area was analyzed. Results demonstrate that, compared with conventional vertical borehole water pressure tests, the proposed method better characterizes the permeability and anisotropic properties of the rock masses. Specifically, the comprehensive permeability coefficient obtained using the proposed method is approximately 15 times that of conventional tests, providing valuable scientific guidance for the design of seepage control engineering.

Key words: fractured rock mass, hydraulic conductivity tensor, directional water pressure test, in-situ stress test, Yellow River Guxian water resources management project

CLC Number:

TV543灌浆和防渗墙工程

WANG Jun-zhi, CHEN Yan-guo, ZHANG Hai-feng, WAN Wei-feng. Estimation of Hydraulic Conductivity Tensor of Nearly-horizontal Stratified Fractured Rock Mass Based on Seepage-Stress Coupling Theory[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(2): 115-121.

Figures/Tables 6

Fig.1 Schematic diagram of structural planes,in-situ stress distribution, and layout of water pressure test boreholes for nearly-horizontal stratified fractured rock mass

Fig.2 Steps for estimating the hydraulic conductivity tensor of nearly-horizontal stratified fractured rock mass

Fig.3 Schematic diagram of calculating the normal stress of structural planes based on single structural plane rock mass mechanics theory

Table 1 Geometric characteristics and normal stresses of the structural planes of fractured rock mass

代表性结构面组	产状		间距s/ (m·条^-1)	等效水力张开度 $b$ /mm	法向应力σ_n/ MPa
代表性结构面组	倾向α/ (°)	倾角β/ (°)	间距s/ (m·条^-1)	等效水力张开度 $b$ /mm	法向应力σ_n/ MPa
J1	310	90	1.5	0.274 0	1.95
J2	30	90	1.5	0.008 9	4.61
J3	NAN	0	3.0	0.096 8	2.81

Table 1 Geometric characteristics and normal stresses of the structural planes of fractured rock mass

代表性结构面组	产状		间距s/ (m·条^-1)	等效水力张开度 $b$ /mm	法向应力σ_n/ MPa
代表性结构面组	倾向α/ (°)	倾角β/ (°)	间距s/ (m·条^-1)	等效水力张开度 $b$ /mm	法向应力σ_n/ MPa
J1	310	90	1.5	0.274 0	1.95
J2	30	90	1.5	0.008 9	4.61
J3	NAN	0	3.0	0.096 8	2.81

Fig.4 Statistical results of horizontal directional and conventional vertical borehole water pressure tests

Fig.5 Negative exponential relationship between the opening of structural plane and rock mass stress

[1]	ZHANG Jian, MA Jian-lin, WANG Qin-ke, SU Wei. Stability of Tunnel Anchorage of Long-span Suspension Bridge in Fractured Rock Interlayer [J]. Journal of Changjiang River Scientific Research Institute, 2024, 41(4): 149-156.
[2]	WAN Fa, JIANG Zhong-ming, LI Hai-feng, LIANG Xian-hao. Impact of Lining Cracking of Compressed Air Energy Storage Cavern on Two-phase Seepage and Heat Transfer Characteristics of Fractured Surrounding Rock [J]. Journal of Changjiang River Scientific Research Institute, 2023, 40(11): 102-110.
[3]	YU Jia-fu, WU Yong-jin, WANG Teng-fei, ZHANG Yi-hu. Numerical Simulation on Cave Forming and Bearing Characteristics of Tunnel Type Anchorage in Fractured Rock Mass [J]. Journal of Changjiang River Scientific Research Institute, 2022, 39(6): 101-106.
[4]	PENG Shu-quan, ZHANG Ke-jia, KANG Jing-yu, FAN Ling, WANG Fan. Experimental Study on Microbial Impermeability Mechanism of Fractured Rock Mass [J]. Journal of Changjiang River Scientific Research Institute, 2020, 37(9): 57-63.
[5]	CHEN Jun,WANG Peng-cheng,JI Yong-xin,ZHANG Bin-bin. Analysis and Discussion on Vertical Bearing Capacity of Single Pile in Broken Rock Foundation [J]. Journal of Changjiang River Scientific Research Institute, 2016, 33(10): 98-101.
[6]	DU Qiang,WANG Chao,ZHAO Guang-ming,JIA Han-wen. Development of Constitutive Model of Fractured Rock Mass Based on Strain Softening Effect and Its Application [J]. Journal of Changjiang River Scientific Research Institute, 2015, 32(11): 82-86.
[7]	CHEN Jun guo, LIU Wei qun, LIANG Hao nan. Creep seepage Coupled Analysis of UndergroundFractured Rock Mass [J]. Journal of Changjiang River Scientific Research Institute, 2015, 32(11): 45-51.
[8]	ZHOU Shi, HUANG Yi-sheng, HU Yao-pu, LIU Ling,ZUO Ya. Optimization Back Analysis and Application of Slope Rock Macro-mechanical Parameters of Ma’erdang Hydropower Station [J]. Journal of Changjiang River Scientific Research Institute, 2014, 31(7): 49-52,59.
[9]	JIANG Zhong-ming, WU Dong-wei, ZHAO Hai-bin, FENG Shu-rong. Numerical Test on Mechanical Behavior of Complicated Fractured Rock Mass [J]. Journal of Changjiang River Scientific Research Institute, 2013, 30(11): 72-76.
[10]	XU Ming-Ming, XU Jin, REN Hao-Nan, YANG Hao-Tian, HE Ya-Qin. Water Pressure-Stress Coupling Tests on the Mechanical Properties of Marble Rock [J]. Journal of Changjiang River Scientific Research Institute, 2012, 29(8): 34-38.
[11]	XU Dong-dong , WU Ai-qing , SUN Yu-jie . Simulation of Sudden Blow in Diversion Tunnel of Some Hydropower Station [J]. Journal of Changjiang River Scientific Research Institute, 2010, 27(8): 44-49.