Rock and Soil Mechanics ›› 2021, Vol. 42 ›› Issue (3): 863-873.doi: 10.16285/j.rsm.2020.0660

• Geotechnical Engineering • Previous Articles     Next Articles

Mobilized strength of sliding zone soils with gravels in reactivated landslides

REN San-shao1, 2, 3, ZHANG Yong-shuang1, 3, XU Neng-xiong2, WU Rui-an4, LIU Xiao-yi4   

  1. 1. Institute of Hydrogeology and Environmental Geology, Chinese Academy of Geological Sciences, Shijiazhuang, Hebei 050061, China; 2. School of Engineering and Technology, China University of Geosciences, Beijing 100083, China; 3. Key Laboratory of Quaternary Chronology and Hydrological Environmental Evolution, China Geological Survey, Shijiazhuang, Hebei 050061, China; 4. Institute of Geomechanics, Chinese Academy of Geological Sciences, Beijing 100081, China
  • Received:2020-05-20 Revised:2020-12-30 Online:2021-03-11 Published:2021-03-17
  • Supported by:
    This work was supported by the Key Project of National Natural Science Foundation of China(41731287) and the Major Special Projects of National Natural Science Foundation of China(41941017).

PDF (Chinese)

331

Abstract: Gravels are widely found in the sliding zone soils (SZS) of ancient landslides. It is the key to determine the mobilized strength of SZS with gravels for the stability evaluation and prevention of ancient landslides. Taking the reactivation of Jiangdingya ancient landslide in Zhouqu County, Gansu Province in 2018 as an example, the mobilized strength of SZS with gravels was studied based on the test and back analysis. The results suggested that: (1) after long-distance shearing, the cementation in the SZS has been gradually lost, and the residual strength is mainly controlled by the sliding frictional resistance and occlusion between the soil particles. When the gravel content is higher, the interaction force between the soil particles is stronger, so the residual strength is relatively larger. There is a positive linear correlation between the friction coefficient and roughness of the shear surface. The gravel changes the roughness of the shear surface, which increases the friction resistance and leads to the increase of its residual strength. (2) The statistical analysis showed that the φr of SZS with gravels is controlled by both clay and gravel content, which is significantly different from the mechanism that the φr of SZS without gravels is mainly controlled by clay content. It is suggested that the ratio of gravel content to clay content should be used as an index to estimate the φr of SZS with gravels. (3) The mobilized strength of ancient landslides is generally greater than the residual strength, but slightly less than the recovery strength. Before reactivation, the strength of SZS has gradually attenuated from the recovery strength to the residual strength. At this time, the ancient landslide is in the creeping state as a whole. Under the action of external forces, the strength of SZS tends to decay sharply, which induces the accelerated sliding of the ancient landslide.

Key words: landslide reactivation, sliding zone soils with gravels, residual strength, strength recovery, mobilized strength

CLC Number: 

  • TU457
[1] YAN Qi-wei, LI Xin-po, HE Si-ming, LUO Yu, TIAN Hong-ling, WU Yong, . Experimental study of self-healing of slip zone soil in typical red bed landslide [J]. Rock and Soil Mechanics, 2020, 41(9): 3041-3048.
[2] CHEN Run-fa, MIAO Lin-chang, SUN Xiao-hao, WU Lin-yu, WANG Cheng-cheng. Quantitative analysis of alumina addition on microbial remediation of concrete cracks [J]. Rock and Soil Mechanics, 2020, 41(3): 933-938.
[3] XIE Hui-hui, XU Zhen-hao, LIU Qing-bing, HU Gui-yang, . Evolution of peak strength and residual strength of weak expansive soil under drying-wetting cycle paths [J]. Rock and Soil Mechanics, 2019, 40(S1): 245-252.
[4] SHAO Sheng-jun, CHEN Fei, DENG Guo-hua, . Seismic passive earth pressure against the retaining wall of structural loess based on plane strain unified strength formula [J]. Rock and Soil Mechanics, 2019, 40(4): 1255-1262.
[5] HUANG Hong-xiang, CHEN Yu-min, WANG Jian-ping, LIU Han-long, ZHOU Xiao-zhi, HUO Zheng-ge, . Ring shear tests on shear strength of calcareous sand [J]. , 2018, 39(6): 2082-2088.
[6] LI Lei, JIANG Ming-jing, ZHANG Fu-guang, . Quantitative simulation of triaxial test considering residual strength on deep rock using DEM and parameter analysis [J]. , 2018, 39(3): 1082-1090.
[7] LIN Bo, ZHANG Feng, FENG De-cheng, MA Hong-yan, FENG Xin,. Experimental investigation on strain rate effects of saturated clay subjected to freeze-thaw cycles [J]. , 2017, 38(7): 2007-2014.
[8] LIU Qing-bing, WANG Shun, XIA Dong-sheng, XIANG Wei, . Experimental study of residual-state creep behavior of intact sliding-zone soil [J]. , 2017, 38(5): 1305-1313.
[9] LI Hai-chao, ZHANG Sheng, . A constitutive damage model of rock based on the assumption of modified Lemaitre strain equivalence hypothesis [J]. , 2017, 38(5): 1321-1326.
[10] MA Lin. Experimental study of shear characteristics of calcareous gravelly soil [J]. , 2016, 37(S1): 309-316.
[11] MIAO Hai-bo, YIN Kun-long, WANG Gong-hui,. Dynamic mechanism of intermittent reactivation of deep-seated reservoir ancient landslide [J]. , 2016, 37(9): 2645-2653.
[12] PENG Jun , RONG Guan , CAI Ming , PENG Kun,. Determination of residual strength of rocks by a brittle index [J]. , 2015, 36(2): 403-408.
[13] JIANG Xiu-zi, WEN Bao-ping. Creep behavior of slip zone of reactivated slow-moving landslide and its characteristic strength [J]. , 2015, 36(2): 495-501.
[14] ZHANG Chun-hui,ZHAO Quan-sheng. Triaxial tests of effects of varied saturations on strength and modulus for sandstone [J]. , 2014, 35(4): 951-958.
[15] LI Xin-ming , KONG Ling-wei , GUO Ai-guo , LIU Yu , LIU Xue-dong,. Experimental research on shear strength of expansive soil under wetting-drying cycles based on wrapping method [J]. , 2014, 35(3): 675-682.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
[1] WANG Gang, LI Shu-cai, WANG Ming-bin. Study of stability of anchoring jointed rockmass under seepage pressure[J]. , 2009, 30(9): 2843 -2849 .
[2] YANG Jian-min, ZHENG Gang. Classification of seepage failures and opinion to formula for check bursting instability in dewatering[J]. , 2009, 30(1): 261 -264 .
[3] ZHOU Hua,WANG Guo-jin1,,FU Shao-jun,ZOU Li-chun,CHEN Sheng-hong. Finite element analysis of foundation unloading and relaxation effects of Xiaowan Arch Dam[J]. , 2009, 30(4): 1175 -1180 .
[4] YE Fei, ZHU He-hua, HE Chuan. Back-filled grouts diffusion model and its pressure to segments of shield tunnel[J]. , 2009, 30(5): 1307 -1312 .
[5] LUO Qiang , WANG Zhong-tao , LUAN Mao-tian , YANG Yun-ming , CHEN Pei-zhen. Factors analysis of non-coaxial constitutive model’s application to numerical analysis of foundation bearing capacity[J]. , 2011, 32(S1): 732 -0737 .
[6] WANG Yun-Gang ,ZHANG Guang ,HU Qi. Study of force characteristics of battered pile foundation[J]. , 2011, 32(7): 2184 -2190 .
[7] GONG Wei-ming, HUANG Ting, DAI Guo-liang. Experimental study of key parameters of high piled foundation for offshore wind turbine[J]. , 2011, 32(S2): 115 -121 .
[8] ZHANG Chun-yang,CAO Ping,FAN Xiang,LIN Hang,WAN Lin-hui. Hopper discharge experiment for high viscosity bauxite flow and micromechanics research[J]. , 2012, 33(6): 1653 -1659 .
[9] ZHOU Ai-zhao , LU Ting-hao , JIANG Peng-ming . General description of soil-structure interface constitutive model based on generalized potential theory[J]. , 2012, 33(9): 2656 -2662 .
[10] LU Kun-lin, ZHU Da-yong, YANG Yang. Calculation charts for estimating safety factors of 3D homogeneous slopes[J]. , 2012, 33(S2): 111 -117 .
Copyright © Rock and Soil Mechanics, All Rights Reserved.
Tel: 027-87198484, 87199252, 87199253, 87198752 E-mail: ytlx@whrsm.ac.cn
Powered by Beijing Magtech Co. Ltd