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崔芳鹏, 许强, 殷跃平, 胡瑞林, 张明. 地震纵横波时差耦合作用的斜坡崩滑响应研究[J]. 岩土工程学报, 2010, 32(8).
引用本文: 崔芳鹏, 许强, 殷跃平, 胡瑞林, 张明. 地震纵横波时差耦合作用的斜坡崩滑响应研究[J]. 岩土工程学报, 2010, 32(8).
Collapsing and sliding response of slopes triggered by single and combined action with time difference of P and S seismic waves[J]. Chinese Journal of Geotechnical Engineering, 2010, 32(8).
Citation: Collapsing and sliding response of slopes triggered by single and combined action with time difference of P and S seismic waves[J]. Chinese Journal of Geotechnical Engineering, 2010, 32(8).

地震纵横波时差耦合作用的斜坡崩滑响应研究

Collapsing and sliding response of slopes triggered by single and combined action with time difference of P and S seismic waves

  • 摘要: 运用离散元数值模拟技术,对北川新中崩滑体在具地域性和空间非均质性的地震纵横波时差耦合作用下产生崩滑破坏的动力全过程进行了研究,确定了该斜坡体在强震动力作用下产生崩滑破坏的形成机制及主控因素。研究表明:①对于新中崩滑体的先期崩滑破坏而言,由于其距离初始震中较远,故源自初始震源的地震纵横波到达该斜坡体的时差较长,为约15.21 s,而该斜坡体在地震纵波作用于斜坡体后8 s后即开始破裂,故其先期崩滑破坏是受到地震纵波产生的水平与竖向拉裂耦合作用所致,并以水平拉裂作用占优,而后期的抛射及运动过程则是受到地震纵横波的耦合作用所致;②对其发生先期崩滑的主控因素言,在地震构造组合机制、岩体结构与构造、斜坡岩体风化程度及物理力学参数等因素既定的情况下,地震纵波产生的水平与竖向拉裂耦合作用是诱发斜坡体产生初期崩滑破坏的主控因素,而斜坡所处地形(如高程差、沟谷延伸方向)则是促使破坏后的斜坡体形成后续碰撞解体及碎屑流等运动过程的控制诱发因素;③该斜坡体动力响应特征值的放大效应表明,其放大系数值从大到小依次是水平加速度>竖向加速度>水平速度>竖向速度,该结果与斜坡体发生先期崩滑破坏的形成机制及主控因素相符合,即地震纵波产生的水平加速度起到了优势破坏作用。以上研究为强震动力作用下的斜坡体先期崩滑破坏提供了新方法。

     

    Abstract: The collapsing and sliding response of Xinzhong slope in Beichuan County and its collapsing process triggered by the single and combined action with time difference and the regionality and spatial heterogeneity of P and S seismic waves are studied. The formation mechanism and key factors are determined by applying DEM numerical simulation. The results show that the initial collapsing and sliding of the slope in running time, i.e. 8 seconds of numerical model, is triggered by the combined action of horizontal and vertical tensions caused by P seismic waves because of their relatively long distance from the initial epicenter inducing larger difference, i.e. 15.21 seconds in time, which P and S seismic waves consume from the hypocenter to the slope. What’s more, the horizontal tension plays a superior role. Ejecting and flowing of the broken slope mass is triggered by the combined action of P and S seismic waves. Secondly, the combined action between horizontal and vertical tensions of P waves is the key factor inducing the collapsing and sliding of the slope under the known seismic tectonics, structure and tectonics of slope mass, weathering degree of rock mass as well as the physical and mechanical parameters of slope body. At the same time, the slope topography is the key factor leading to collision and debris flow of the slope mass fractured in latter process. Finally, the amplification effect of parameters in dynamic response of the slope shows that the amplification coefficient of horizontal acceleration is larger than that of vertical acceleration. The horizontal velocity and the vertical velocity decrease one by one, and this trend is consistent with the key factor inducing slope fracturing, i.e. horizontal seismic loads play a superior role. It provides a new method for studies on the initial collapsing and sliding of slopes triggered by seismic loads.

     

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