Analyzing the Effect of Soil Hydraulic Conductivity Anisotropy on Slope Stability Using a Coupled Hydromechanical Framework
Autor: | Yi Jin Tsai, Hsin Fu Yeh |
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Rok vydání: | 2018 |
Předmět: |
lcsh:Hydraulic engineering
010504 meteorology & atmospheric sciences Geography Planning and Development 0211 other engineering and technologies Soil science 02 engineering and technology Aquatic Science Silt infiltration coupled hydromechanical framework 01 natural sciences Biochemistry lcsh:Water supply for domestic and industrial purposes Hydraulic conductivity lcsh:TC1-978 Slope stability Anisotropy hydraulic conductivity anisotropy 021101 geological & geomatics engineering 0105 earth and related environmental sciences Water Science and Technology lcsh:TD201-500 Infiltration (HVAC) slope stability Permeability (earth sciences) Loam Slope stability analysis Geology |
Zdroj: | Water, Vol 10, Iss 7, p 905 (2018) Water Volume 10 Issue 7 |
ISSN: | 2073-4441 |
Popis: | In studies on the effect of rainfall on slope stability, soil hydraulic conductivity is usually assumed to be isotropic to simplify the analysis. In the present study, a coupled hydromechanical framework based on transient seepage analysis and slope stability analysis is used to investigate the effects of hydraulic conductivity anisotropy on rainfall infiltration and slope safety at various slope locations (the top of the slope, the slope itself and the toe of the slope). The results show that when the vertical hydraulic conductivity (Ky) is constant, the horizontal hydraulic conductivity (Kx) increases (i.e., anisotropy increases). This occurs because rainfall tends to infiltrate into the interior of the slope, resulting in the soil on top of the slope and on the slope itself being easily influenced by rainfall, leading to soil instability. The change of rainfall infiltration at the slope itself is the most significant. When the anisotropic ratio Kr (=Kx/Ky) increased from 1 to 100, the depth of the wetting zones for loam, silt and clay slopes increased by 23.3%, 33.3% and 50%, respectively. However, increased Kr led to a slower infiltration rate in the vertical direction at the toe of the slope. Compared to the results for Kr = 1 and for Kr = 100, the thickness of the wetting zones at the toe of loam and silt slopes decreased by 23.3% and 30.0%, respectively. For the clay slope, Kr changes did not significantly affect the wetting zones because of poor permeability. The results of this study suggest that the effect of soil hydraulic conductivity anisotropy should be considered when estimating slope stability to better understand the effect of rainfall on slopes. |
Databáze: | OpenAIRE |
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