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缪海波, 柴少峰, 王功辉. 强降雨下无黏性土坡破坏的影响因素试验研究[J]. 岩土工程学报, 2021, 43(2): 300-308. DOI: 10.11779/CJGE202102010
引用本文: 缪海波, 柴少峰, 王功辉. 强降雨下无黏性土坡破坏的影响因素试验研究[J]. 岩土工程学报, 2021, 43(2): 300-308. DOI: 10.11779/CJGE202102010
MIAO Hai-bo, CHAI Shao-feng, WANG Gong-hui. Influence factors for failure of cohesionless soil slopes triggered by heavy rainfall[J]. Chinese Journal of Geotechnical Engineering, 2021, 43(2): 300-308. DOI: 10.11779/CJGE202102010
Citation: MIAO Hai-bo, CHAI Shao-feng, WANG Gong-hui. Influence factors for failure of cohesionless soil slopes triggered by heavy rainfall[J]. Chinese Journal of Geotechnical Engineering, 2021, 43(2): 300-308. DOI: 10.11779/CJGE202102010

强降雨下无黏性土坡破坏的影响因素试验研究

Influence factors for failure of cohesionless soil slopes triggered by heavy rainfall

  • 摘要: 利用自行研制的室内水槽模型试验系统,对日本#6,#7和#8硅砂试样开展了固定降雨强度(90 mm/h)下诱发无黏性土坡破坏的模型试验;描述了强降雨条件下无黏性土坡的破坏过程,探讨了坡体厚度、前缘卸荷、土样颗粒尺寸及细颗粒含量对破坏过程的影响规律,分析了土坡破坏过程中的孔隙水压力响应特征。结果表明:①在持续强降雨作用下,无黏性土坡的破坏过程可分为3个阶段,即入渗、初始破坏与主要破坏阶段。②主要破坏阶段拉裂缝自坡脚向坡体中部、坡肩及坡顶渐次出现,且破坏模式受土颗粒尺寸和细颗粒含量的控制,控制机制为土体剪胀效应的强弱。③坡体厚度越小,其破坏过程的持续时间越短,但滑动距离和速率也将越小;前缘卸荷可加速土坡的破坏,并使其具有更长的滑动距离和更大的滑动速率。④当饱和土坡加速变形时,滑动面处会产生超静孔隙水压力,进而诱发突然滑动。与此同时,滑动面处的孔隙水压力由于坡体厚度减小和剪胀效应的发生而急剧降低。

     

    Abstract: Using the self-developed flume, the model tests are conducted to trigger heavy rainfall-induced failure of cohesionless soil slopes with Japan silica sand No. 6, No. 7 and No. 8 under the fixed rainfall intensity of 90 mm/h. The failure process is described and the effects of slope thickness and unloading at the leading edge, and the particle size and fine-particle content on the failure process are discussed. Moreover, the response of pore-water pressure in the failure process is also studied. The results show that: (1) Under the sustained heavy rainfall, the failure process of cohesionless soil slopes can be divided into three stages, i.e., rainfall infiltration, initial failure and major failure. (2) At the major failure stage, the tension cracks gradually appear from the toe to the middle, shoulder and top of the slope. The failure mode is controlled by the particle size of soils and fine-particle content with the mechanism of the extent of shear dilation effect. (3) The smaller the slope thickness is, the shorter the duration of failure process is, while the smaller the sliding distance and velocity are. In addition, unloading at the leading edge can accelerate the failure process of the slope, and make it have a longer sliding distance and a larger sliding rate. (4) When the deformation of the saturated slope is accelerated, the excess pore-water pressure is generated at the sliding surface, and then the sudden sliding is induced. At the same time, the pore-water pressure at the sliding surface decreases sharply due to the decrease of slope thickness and the occurrence of shear dilation effect.

     

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