摘要Based on the assumption that the hydrostatic pressure is maximum at half the total groundwater level, which improved the groundwater pressure distribution in the slope body, the safety factor expression for anti-slide stability of the rock slope along the river were deduced using the limit equilibrium theory. This deduction included various influencing factors, such as slope-top surcharge, seismic load, anchor load, river pressure on the slope surface, groundwater pressure, and scouring effect. The relationship diagrams between the safety factor and the influencing factors were constructed. Results show that the new assumption, which improved the hydrostatic pressure distribution, is reasonable. Hydrostatic pressure is an important influencing factor to the slope anti-slide stability. The higher river water level and the lower groundwater level are beneficial to improve the safety factor of the slope anti-slide stability. Whether the outflow joint blocking has significant effect on the slope stability against sliding, the outflow joint blocking has adverse effect on anti-slide stability of the rock slope along the river in the general case. The anti-slide stability safety factor of the outflow joint blocked is larger than that of the outflow joint unblocked only when Hr>Hw.
Abstract:Based on the assumption that the hydrostatic pressure is maximum at half the total groundwater level, which improved the groundwater pressure distribution in the slope body, the safety factor expression for anti-slide stability of the rock slope along the river were deduced using the limit equilibrium theory. This deduction included various influencing factors, such as slope-top surcharge, seismic load, anchor load, river pressure on the slope surface, groundwater pressure, and scouring effect. The relationship diagrams between the safety factor and the influencing factors were constructed. Results show that the new assumption, which improved the hydrostatic pressure distribution, is reasonable. Hydrostatic pressure is an important influencing factor to the slope anti-slide stability. The higher river water level and the lower groundwater level are beneficial to improve the safety factor of the slope anti-slide stability. Whether the outflow joint blocking has significant effect on the slope stability against sliding, the outflow joint blocking has adverse effect on anti-slide stability of the rock slope along the river in the general case. The anti-slide stability safety factor of the outflow joint blocked is larger than that of the outflow joint unblocked only when Hr>Hw.
基金资助:Supported by the National Natural Science Foundation of China (No.51078359, No.51208522);the China Postdoctoral Science Foundation (No.20110491269, No.2012T50708);the Science and Technology Plan Projects of Guizhou Province Transportation Hall (No.2012122033);the Science and Technology Plan Projects of Hunan Province Science and Technology Department (No.2012SK3231);and the Fundamental Research Funds for the Central Universities of Central South University (No.2013zzts048)
通讯作者:
LUO Wei, luoweicsu@126.com
E-mail: luoweicsu@126.com
引用本文:
罗伟, 李亮, 赵炼恒, 程盼, 陈嘉祺. 临河岩石边坡抗滑稳定性分析[J]. Journal of Highway and Transportation Research and Development, 2014, 8(2): 23-30.
LUO Wei, LI Liang, ZHAO Lian-heng, CHENG Pan, CHEN Jia-qi. Study on Anti-slide Stability of Rock Slope along River. Journal of Highway and Transportation Research and Development, 2014, 8(2): 23-30.
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