首页/文章/ 详情

三峡库区谭家河滑坡影响因素、变形机理及破坏过程预测

10月前浏览934

论文题目


 

Influencing factors,deformation mechanism and failure process prediction for reservoir rock landslides:Tanjiahe landslide,three gorges reservoir area


Yushan Chen1,2,Yeming Zhang1,2,Li Wang1,2,3*Shimei Wang1,2Dongfang Tian1,2and Lun Zhang1,2
1 Key Laboratory of Geological Hazards on Three Gorges Reservoir Area, Ministry of Education, China Three Gorges University, Yichang, Hubei, China
2 National Field Observation and Research Station of Landslides in Three Gorges Reservoir Area of Yangtze River, China Three Gorges University, Yichang, Hubei, China

3 Badong National Observation and Research Station of Geohazards, China University of Geosciences, Wuhan, Hubei, China



 

研究内容

Abstract:Compared with terrestrial rock landslides, reservoir rock landslides are also affected by the rise and fall of the reservoir water level, and these landslides are more threatening. High-speed debris flows may form once they lose stability, and once they enter the water a surge is formed. This endangers the safe operation of reservoirs. This study explored the deformation characteristics and influencing factors of the Tanjiahe reservoir rock landslide in the Three Gorges Reservoir using field investigations, GPS surface displacement monitoring, and groundwater level monitoring. The discrete element system MatDEM was used to simulate failure motion, and predict the hazard area affected by the Tanjiahe landslide. The results show that within the reservoir water variation section (145–175 m), the Tanjiahe landslide mass was composed of surface soil (156–175 m) with low permeability and deep cataclastic rock (145–156 m) with high permeability. Due to the difference in permeability between the deep and surface layers, the response of landslide deformation to water level rise is not obvious. The high-level (175 m) operation of the reservoir and the decline in the reservoir water level (175–145 m) are key factors affecting the landslide deformation. Rainfall had a positive effect on landslide deformation. Under their combined action, the stability of the front gentle anti-sliding section of the landslide decreases, and the displacement of the middle and rear steeper sliding section increases under the driving force, which may lead to slope failure. The simulation results show that the upper part of the Tanjiahe landslide slides first and pushes the lower part to move, which is a typical of thrust load-caused failure. The speed of the sliding mass has three stages: rapid rise, rapid decline, and slow decline. The higher the slope angle, the higher the acceleration of the sliding mass in the direction parallel to the slope surface, the higher the speed peak value and the faster the sliding mass speed reaches the peak value. During the failure process, energy is transferred between sliding mass through collisions. Landslides can easily lead to debris flow. The maximum height of the first wave generated when the debris flow entered the water is 5.95 m, and the wave height that propagated to the opposite bank is 3.09 m. The landslide-induced waves propagated along the reservoir area for 30 km.

Keywords:reservoir rock landslide, reservoir high-level operation, reservoir water level drop,failure movement process prediction, MatDEM

FIGURE 2  Tanjiahe landslide.
(A) Panoramic view of the landslide. (B) Planar map of the landslide. (C) Geological profile.

FIGURE 8  Tanjiahe landslide.
(A) Numerical model. (B)Layout of landslide monitoring points.

FIGURE 10  Unit distribution characteristics of various parts before and after landslide.

FIGURE 13  Energy conversion during landslide process.

了解详情

 
 
Chen Y, Zhang Y, Wang L, Wang S, Tian D and Zhang L (2022) Influencing factors, deformation mechanism and failure process prediction for reservoir rock landslides: Tanjiahe landslide, three gorges reservoir area. Front. Earth Sci. 10:974301.
doi: 10.3389/feart.2022.974301

来源:矩阵离散元MatDEM
ACTSystemDeformUGUM离散元
著作权归作者所有,欢迎分享,未经许可,不得转载
首次发布时间:2023-12-30
最近编辑:10月前
MatDEM
中国自己的工程数值计算软件
获赞 163粉丝 1209文章 142课程 36
点赞
收藏
未登录
还没有评论
课程
培训
服务
行家
VIP会员 学习 福利任务 兑换礼品
下载APP
联系我们
帮助与反馈