滇西高烈度区某陡倾反倾红层边坡动力破坏模式实验研究

    EXPERIMENTAL STUDY ON DYNAMIC FAILURE MODES OF A STEEP-DIP COUNTER-DIP RED-BED SLOPE IN THE HIGH-INTENSITY SEISMIC ZONE OF WESTERN YUNNAN

    • 摘要: 为降低滇西区域红层边坡破坏对公路网络的威胁,以滇西红层区域内某一边坡为原型,考虑红层特有岩石性质,分别设计地震以及地震-降雨耦合作用下的振动台实验,从PGA放大系数、孔隙水压力、HHT边际谱峰值以及边坡破坏现象等方面,探究两种作用下边坡的动力响应以及破坏模式。结果表明:两种作用下的PGA放大系数均存在“高程放大效应”以及“趋表放大效应”,“趋表放大效应”随着高程的增加而减弱,并且单一地震下PGA放大系数与加速度幅值呈规律性变化,地震-降雨耦合作用下则无规律;增加降雨因素,对比两种作用下的PGA放大系数,边坡上部区域更容易发生失稳破坏,破坏程度更加剧烈。边坡内的孔隙水压力与高程以及地震波加载幅值均出现正相关,并且孔隙水的存在对于地震响应具有放大效应,坡顶部位放大效应最突出。HHT边际谱峰值PMSA变化曲线显示,两种作用下边坡破坏都是先坡顶部位后坡腰部位。观察振动台实验现象,单一地震作用下边坡在地震波幅值0.7g失稳破坏,破坏阶段依次为裂隙发育→层面弯曲→层面强烈弯曲→边坡破坏,破坏模式为坡顶岩层弯曲-拉裂破坏模式。地震-降雨耦合作用下边坡在地震波幅值0.4g失稳破坏,破坏阶段依次为降雨坡顶崩解不规则破坏→坡面溜滑→层面弯曲及裂隙扩展→层面强烈弯曲→边坡失稳破坏,破坏模式为崩解破坏,弯曲、蠕滑-拉裂复合破坏模式。该研究可为滇西红层区域边坡的设计、治理提供参考,更好地保障公路网络的安全运行。

       

      Abstract: To mitigate the threat of slope failures to highway networks in the Western Yunnan red bed region of China, shaking table experiments were conducted on a representative slope prototype. The dynamic response and failure mechanisms of the slope were analyzed under seismic action and coupled seismic-rainfall conditions using peak ground acceleration (PGA) amplification factors, pore water pressure, Hilbert-Huang transform (HHT) marginal spectral peaks (PMSA), and failure mode observations. The results indicate that under both conditions, PGA exhibited"elevation amplification" and"surface amplification" effects, with surface amplification gradually decreasing as elevation increased. Under seismic action alone, PGA showed a regular correlation with acceleration intensity, whereas under coupled seismic-rainfall conditions, this relationship became irregular. Rainfall significantly increased instability risks and damage severity in the upper slope compared to seismic action alone. Pore water pressure was positively correlated with elevation and seismic amplitude, with the strongest seismic response amplification observed at the slope crest. PMSA curves confirmed that failure progressed from the crest to the midslope in both scenarios. Under pure seismic action, slope failure occurred at 0.7g acceleration through sequential stages: crack development → stratum bending → intense bending → collapse, characterized by crest bending-tensile failure. Under coupled seismic-rainfall conditions, instability initiated earlier at 0.4g acceleration, progressing as follows: rainfall-induced crest disintegration and surface sliding → crack propagation and stratum bending → intense bending → failure, resulting in composite disintegration with combined bending-tensile and creep-tensile damage. This study provides critical references for slope design and hazard mitigation in Western Yunnan red bed areas, contributing to enhanced highway safety.

       

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