地震作用下顺层岩质滑坡启动机制研究

doi:10.13722/j.cnki.jrme.2020.1098

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Abstract To seek the initiation mechanism of bedding rock landslide under seismic load，the geometry and stress conditions of landslide′s initial crack propagation are analyzed and the calculating formula of the most dangerous initial crack angle is deduced by theory of fracture mechanics. Furthermore，based on completely cut-through of landslide′s back fault zone，the starting speed of landslide under the composite effect of elastic impulse，peak-residual strength drop and wave oscillation is derived. The results prove that if initial crack angle starts to break along the secondary joint structural plane，the initial crack of landslides whose dip angle of secondary joint′s structural plane is 39.5°will crack more easily；the landslide′s initiation has experienced a process of cumulative fracture of initial crack，cut-through of landslide′s back fault zone，instantaneous fracture of the locking segment，release of elastic impulse strain energy and peak-residual strength drop strain energy into starting kinetic energy of the slip mass，further accelerated by wave oscillation，and finally being thrown from landslide shear outlet. Based on the analysis of the Qingchuan Donghekou landslide happened in the 5?12 Wenchuan Earthquake，it is concluded that the starting speed of landslide is significantly affected by the elastic impulse effect and decisively controlled by the height of elastic impulse area′s slices and length of locking segment under instantaneous fracture of locking segment，if the internal relationship between height of the slices and length of the locking segment is not considered，the upper limit of landslide′s starting speed will be 12.5 m/s when energy conversion rate reaches 100%.

Key words： slope engineering seismic action bedding rock landslide；initiation mechanism crack propagation elastic impulse starting speed

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	Articles by authors
	ZHAO Yuanping1
	XU Ming1
	2
	LIU Xianshan1
	2
	LUO Bin3

Cite this article:

ZHAO Yuanping1,XU Ming1,2, et al. Study on the initiation mechanism of bedding rock landslide under seismic load[J]. , 2021, 40(S1): 2692-2700.

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https://rockmech.whrsm.ac.cn/EN/10.13722/j.cnki.jrme.2020.1098 OR https://rockmech.whrsm.ac.cn/EN/Y2021/V40/IS1/2692

[1] 殷跃平. 汶川地震地质与滑坡灾害概论[M]. 北京：地质出版社，2009：81–103.(YIN Yueping. Introduction to Wenchuan Earthquake geology and landslide disaster[M]. Beijing：Geological Publishing House，2009：81–103.(in Chinese)) [2] 殷跃平. 汶川八级地震滑坡特征分析[J]. 工程地质学报，2009，17(1)：29–38.(YIN Yueping. Characteristics analysis of landslide in Wenchuan Earthquake with magnitude 8[J]. Journal of Engineering Geology，2009，17(1)：29–38.(in Chinese)) [3] 许强，裴向军，黄润秋. 汶川地震大型滑坡研究[M]. 北京：科学出版社，2009：221–263.(XU Qiang，PEI Xiangjun，HUANG Runqiu. Large-scale landslide research in Wenchuan earthquake[M]. Beijing：Science Press，2009：221–263.(in Chinese)) [4] 黄润秋. 汶川地震地质灾害研究[M]. 北京：科学出版社，2009：246–259.(HUANG Runqiu. Study of geological disasters in Wenchuan Earthquake[M]. Beijing：Science Press，2009：246–259.(in Chinese)) [5] 何思明，吴永，李新坡. 地震诱发岩体崩塌的力学机制[J]. 岩石力学与工程学报，2010，29(增1)：3 359–3 363.(HE Siming，WU Yong，LI Xinpo. Mechanical mechanism of rock mass collapse induced by earthquake[J]. Chinese Journal of Rock Mechanics and Engineering，2010，29(Supp.1)：3 359–3 363.(in Chinese)) [6] 罗刚，胡卸文，顾成壮. 强震作用下顺层岩质斜坡动力失稳机制及启动速度研究[J]. 岩土力学，2013，34(2)：483–490.(LUO Gang，HU Xiewen，GU Chengzhuang. Study on dynamic instability mechanism and start-up speed of bedding rock slope under strong earthquake[J]. Rock and Soil Mechanics，2013，34(2)：483–490.(in Chinese)) [7] 邹宗兴，唐辉明，熊承仁，等. 高速岩质滑坡启动弹冲加速机制及弹冲速度计算—以武隆县鸡尾山滑坡为例[J]. 岩土力学，2014，35(7)：2 004–2 012.(ZOU Zongxing，TANG Huiming，XIONG Chengren，et al. Acceleration mechanism and calculation of ballistic velocity of high speed rock landslide—A Case study of Jiwei-shan Landslide in Wulong County[J]. Rock and Soil Mechanics，2014，35(7)：2 004–2 012.(in Chinese)) [8] LING Z，XIANGJUN P，SHENGHUA C，et al. On the initiation mechanism of the Daguangbao landslide triggered by the 2008 Wenchuan(Ms 7.9) earthquake[J]. Soil Dynamics and Earthquake Engineering，2020，137：106272. [9] 胡广韬. 滑坡动力学[M]. 北京：地质出版社，1995：71–77.(HU Guangtao. Landslide dynamics[M]. Beijing：Geological Publishing House，1995：71–77.(in Chinese)) [10] 毛彦龙，胡广韬，赵法锁，等. 地震动触发滑体滑动的机制[J]. 西安工程学院学报，1998，20(4)：45–52.(MAO Yanlong，HU Guangtao，ZHAO Fasuo，et al. Mechanism of landslide triggered by ground vibration[J]. Journal of Xi′an Institute of Engineering，1998，20(4)：45–52.(in Chinese)) [11] 程谦恭，胡厚田，胡广韬，等. 高速岩质滑坡临床弹冲与峰残强降复合启程加速动力学机制[J]. 岩石力学与工程学报，2000，19(2)：173–176.(CHENG Qiangong，HU Houtian，HU Guangtao，et al. Dynamic mechanism of acceleration of high speed rock landslide by combined impact and peak residual strength reduction[J]. Chinese Journal of Rock Mechanics and Engineering，2000，19(2)：173–176.(in Chinese)) [12] 赵晓彦，胡厚田. 汶川大型地震滑坡的类型及启程剧动机制研究[J]. 工程地质学报，2015，23(1)：78–85.(ZHAO Xiaoyan，HU Houtian. Study on the types of large-scale earthquake landslides in Wenchuan and the motive reasons of starting the Earthquake[J]. Journal of Engineering Geology，2015，23(1)：78–85.(in Chinese)) [13] 赵晓彦，胡凯，梁瑶，等. 王家岩滑坡锁固段剪切震动触发启程剧动试验[J]. 岩石力学与工程学报，2018，37(1)：104–111. (ZHAO Xiaoyan，HU Kai，LIANG Yao，et al. Shear vibration triggering dynamic test in the locked section of Wangjiayan landslide[J]. Chinese Journal of Rock Mechanics and Engineering，2018，37(1)：104–111.(in Chinese)) [14] SCHEIDEGGER A E. On the prediction of the reach and velocity of catastrophic landslides[J]. Rock Mechanics，1973，5(4)：231–236. [15] XU M，TANG Y F，LIU X S，et al. A shaking table model test on a rock slope anchored with adaptive anchor cables[J]. International Journal of Rock Mechanics and Mining Sciences，2018，112：201–208. [16] ATKINSON B K. Fracture mechanics of rock[M]. London：Academic Press，1987：45–49. [17] ERDOGAN F，SIH G C. On the crack extension in plates under plane loading and transverse shear[J]. Journal of Basic Engineering，1963，85(4)：519–525. [18] WESTERGAARD H M W. Bearing pressures and cracks[J]. Journal of Applied Mechanics，1939，(6)：49–53. [19] 李世愚，和泰名，尹祥础. 岩石断裂力学[M]. 北京：科学出版社，2015：68–76.(LI Shiyu， HE Taiming，YIN Xiangchu. Rock fracture mechanics[M]. Beijing：Science Press，2015：68–76.(in Chinese)) [20] 程谦恭，胡厚田. 剧冲式高速滑坡全程动力学机制分析[J]. 水文地质工程地质，1999，(4)：21–25.(CHENG Qiangong，HU Houtian. Dynamic mechanism analysis of the whole process of dramatic impact high-speed landslide[J]. Hydrogeology and Engineering Geology，1999，(4)：21–25.(in Chinese)) [21] 邢爱国，陈龙珠，陈明中. 岩石力学特性分析与高速滑坡启动速度预测[J]. 岩石力学与工程学报，2004，23(10)：1 654–1 657.(XING Aiguo，CHEN Longzhu，CHEN Mingzhong. Analysis of rock mechanics characteristics and prediction of high speed landslide start-up speed[J]. Chinese Journal of Rock Mechanics and Engineering，2004，23(10)：1 654–1 657.(in Chinese)) [22] NEWMARK N M. Effects of earthquakes on dams and embankments[J]. Geotechnique，1965，15(2)：139–159. [23] GOODMAN L E，ROSENBLUETH E，NEWMARK N M. Aseismic design of firmly founded elastic structures[J]. Transactions ASCE，1955，120：782–802. [24] 陶振宇，唐方福，张黎明. 节理与断层岩石力学[M]. 武汉：中国地质大学出版社，1992：6–10.(TAO Zhenyu，TANG Fangfu，ZHANG Liming. Joint and fault rock mechanics[M]. Wuhan：China University of Geosciences Press，1992：6–10.(in Chinese))