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复合型滑坡固液耦合过程数值模拟分析——以无山坪滑坡为例

张晗 高杨 李滨 李军 吴伟乐

张晗, 高杨, 李滨, 等, 2022. 复合型滑坡固液耦合过程数值模拟分析——以无山坪滑坡为例. 地质力学学报, 28 (6): 1104-1114. DOI: 10.12090/j.issn.1006-6616.20222832
引用本文: 张晗, 高杨, 李滨, 等, 2022. 复合型滑坡固液耦合过程数值模拟分析——以无山坪滑坡为例. 地质力学学报, 28 (6): 1104-1114. DOI: 10.12090/j.issn.1006-6616.20222832
ZHANG Han, GAO Yang, LI Bin, et al., 2022. Numerical simulation analysis of the solid-liquid coupling process in a hybrid landslide: A case study of the Wushanping landslide. Journal of Geomechanics, 28 (6): 1104-1114. DOI: 10.12090/j.issn.1006-6616.20222832
Citation: ZHANG Han, GAO Yang, LI Bin, et al., 2022. Numerical simulation analysis of the solid-liquid coupling process in a hybrid landslide: A case study of the Wushanping landslide. Journal of Geomechanics, 28 (6): 1104-1114. DOI: 10.12090/j.issn.1006-6616.20222832

复合型滑坡固液耦合过程数值模拟分析——以无山坪滑坡为例

doi: 10.12090/j.issn.1006-6616.20222832
基金项目: 

国家自然科学基金面上基金项目 42177172

国家自然科学基金青年基金项目 41907257

详细信息
    作者简介:

    张晗(1997—), 男, 在读硕士, 主要从事地质灾害研究工作。E-mail: 164073178@qq.com

    通讯作者:

    高杨(1989—), 男, 副研究员, 主要从事地质灾害防治研究工作。E-mail: 737263992@qq.com

  • 中图分类号: P642.22

Numerical simulation analysis of the solid-liquid coupling process in a hybrid landslide: A case study of the Wushanping landslide

Funds: 

the General Project of the National Natural Science Foundation of China 42177172

the Youth Fund of the National Natural Science Foundation of China 41907257

  • 摘要:

    固液耦合作用是碎屑流向泥石流转化形成复合型滑坡灾害的关键因素, 会导致成灾范围和规模放大, 是防灾减灾领域研究中的热点和难点问题之一。文中采用自主研发的滑坡后破坏数值模拟平台(LPF3D, Landslides post failure 3D), 以2014年9月强降雨诱发的重庆奉节无山坪滑坡为例, 探讨了滑坡在水动力作用下远程成灾的动力过程, 揭示了固液耦合影响机制。研究结果显示: 水动力作用在滑坡运动过程中主要体现为液化和拖曳两种, 两种力学作用的增程效应明显, 往往使得碎屑流转化为泥石流, 导致远程成灾; 基于光滑粒子流体动力学(SPH)方法的两相耦合计算模型, 考虑流体状态方程、固体黏塑性本构方程和相间作用力的共同影响, 基本还原了强降雨条件下重庆奉节无山坪滑坡两相运动过程; 数值计算结果显示无山坪滑坡最大运动速度为34 m/s, 最大堆积厚度为21.5 m, 堆积面积为0.12 km2, 最远运动距离为1300 m, 模拟结果同实际滑坡的堆积形态基本一致。综上认为, 在高位远程滑坡风险调查与预测过程中, 需充分考虑强降雨工况下孔隙水压力和固液相间作用, 基于LPF3D方法的数值模拟为高位远程滑坡的风险定量评估提供了依据。

     

  • 图  1  研究区地质构造图

    Figure  1.  Geological structural map of the study area

    图  2  无山坪滑坡滑前滑后遥感对比图

    Figure  2.  Image comparison before and after the Wushanping landslide

    图  3  无山坪滑坡平剖面图

    Figure  3.  Profile and plan of the Wushanping landslide

    图  4  滑源区、流通区及堆积区现场调查照片

    Figure  4.  Site photos of the slide source area, propagation area and accumulation area

    图  5  四种工况下的堆积结果图

    Figure  5.  Accumulations of the Wupingshan landslide under four working conditions

    图  6  工况Ⅳ下运动过程图

    Figure  6.  Diagrams showing the fluid-solid coupled movement of the Wushanping landslide under working condition Ⅳ

    图  7  工况Ⅳ下运动速度图

    Figure  7.  Velocity diagrams of the Wupingshan landslide under working condition Ⅳ

    图  8  工况Ⅳ下滑坡堆积厚度图

    红色线为真实滑坡边界

    Figure  8.  Diagrams showing the deposition thickness with time of the Wupingshan landslide under working condition Ⅳ

    图  9  无山坪滑坡速度曲线图

    Figure  9.  Velocity change of the front-edge granules under different working conditions

    表  1  无山坪滑坡LPF模拟参数

    Table  1.   LPF simulation parameters of the wushanping landslide

    工况 颗粒相 流体相
    密度/
    (kg/m3)
    颗粒粒径/m 摩擦系数 孔隙水系数 密度/
    (kg/m3)
    黏滞系数/
    (Pa·s)
    2240 0.1 0.5 0
    2240 0.1 0.5 0.4
    2240 0.1 0.5 0 1200 0.2
    2240 0.1 0.5 0.4 1200 0.2
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