SIMULATION STUDY OF ROAD-CUT EFFECTS ON SLOPE STABILITY

doi:10.3969/j.issn.0253-4967.2018.06.014

Abstract

Abstract: Landslides and rock falls along the highway are common geological hazards in Southwest China. As an influencing factor on potential landslides behavior, roads or distance to roads have been successfully used in landslide susceptibility assessments in mountainous area. However, the relationship between the road-cut and the slope stability is not clear. Therefore, we performed two-dimensional slope stability calculation using the general limit equilibrium (GLE)method incorporated in the software SLOPE/W of GeoStudio for stability analysis of slopes. Our studies show that the man-made roads influence on the slope stability mainly exists in two ways:One is to create a new steep slope, which will result in rock falls and shallow landslides along the roads; the other is to influence the stability of the original slope, which will result in comparatively huge landslides. For the latter, our simulation study reveals that the road location, namely at which part of a natural slope to construct a road is important for the slope stability. For a natural slope with a potential slip surface, if a road is constructed at or near the slope toe where the potential slip surface surpasses, it will greatly degrade the slope's factor of safety (Fs) and make the slope unstable; however, if a rode-cut is near the top of the slope, it will increase the slope's Fs and make the slope more stable. The safety location is different for different slope angle, steeper slope needs a higher location for a safety road-cut in comparison with gentle slopes. Moreover, the slope stability decreases when loading a seismic force and it varies with the slope angle. Firstly, the Fs decreases when the slope angle increasing, and when the slope angle reaches 45°, the Fs then becomes greater with the slope angle increasing.

Key words: slope stability, road-cut, limit equilibrium method, factor of safety(Fs), seismic loading

摘要： 公路边的滑坡崩塌在中国西南地区是常见的一类地质灾害。道路的开挖一方面改变了边坡原有的地表形态，形成了新的较陡的边坡，如果缺乏保护措施，新的陡坡很容易失稳，从而形成以滚石或浅层滑坡为主的边坡破坏。另一方面，道路开挖有可能会改变原有坡体的结构，降低坡体的安全系数，引起较大规模的滑坡，造成更为严重的灾害。因此，坡体开挖的位置对其稳定程度会产生一定的影响。文中以岩质边坡为例，在建立边坡模型的基础上，采用二维极限平衡数值模拟方法，分析了道路开挖位置对整体边坡稳定性的影响；同时，对加载地震作用的边坡稳定性也进行了模拟分析。研究结果表明，对于有潜在滑动面的坡体，在不同位置进行开挖对坡体稳定性的影响是不同的：在坡脚处或接近滑动面滑出位置开挖道路，将减小阻滑力而导致整体稳定性降低；在接近坡顶处开挖道路则会因卸载坡体物质而提高整体稳定性。合理的开挖位置与坡体坡度有密切关系，在不降低整体安全系数的情况下，坡度较陡的坡体，其开挖位置相应要高一些。无论坡体角度大小，地震作用能够显著降低边坡的稳定性。

关键词: 边坡稳定性, 道路开挖, 极限平衡法, 安全系数, 地震加载

CLC Number:

P315.2

CHEN Xiao-li, WANG Ming-ming, ZHANG Ling. SIMULATION STUDY OF ROAD-CUT EFFECTS ON SLOPE STABILITY[J]. SEISMOLOGY AND GEOLOGY, 2018, 40(6): 1390-1401.

陈晓利, 王明明, 张凌. 道路开挖位置对边坡稳定性影响的数值模拟[J]. 地震地质, 2018, 40(6): 1390-1401.

References

丁彦慧, 王余庆, 孙进忠, 等. 2000. 地震崩滑预测方法及其工程研究应用［J］. 工程地质学报, 8(4):475-480. DING Yan-hui, WANG Yu-qing, SUN Jin-zhong et al. 2000. Research on the method for prediction of earthquake-induced landslides and its application to engineering projects［J］. Journal of Engineering Geology, 8(4):475-480(in Chinese).
黄润秋, 李为乐. 2008. "5·12"汶川大地震触发地质灾害的发育规律研究［J］. 岩石力学与工程学报, 27(12):2585-2592. HUANG Run-qiu, LI Wei-le. 2008. A study on the development and distribution rules of geohazards triggered by "5·12" Wenchuan earthquake［J］. Chinese Journal of Rock Mechanics and Engineering, 27(12):2585-2592(in Chinese).
黄润秋, 张伟峰, 裴向军. 2014. 大光包滑坡工程地质研究［J］. 工程地质学报, 22(4):557-585. HUANG Run-qiu, ZHANG Wei-feng, PEI Xiang-jun. 2014. Engineering geological study on Daguangbao landslide［J］. Journal of Engineering Geology, 22(4), 557-585(in Chinese).
祁生文, 伍法权, 刘春玲, 等. 2004. 地震边坡稳定性的工程地质分析［J］. 岩石力学与工程学报, 23(16):2792-2797. QI Sheng-wen, WU Fa-quan, LIU Chun-ling, et al. 2004. Engineering geology analysis on stability of slope under earthquake［J］. Chinese Journal of Rock Mechanics and Engineering, 23(16):2792-2797(in Chinese).
王余庆, 辛鸿博, 高艳平, 等. 2001. 预测岩土边坡地震崩滑的综合指标法研究［J］. 岩土工程学报, 23(3):311-314. WANG Yu-qing, XIN Hong-bo, GAO Yan-ping, et al. 2001. Study on comprehensive index method for predicating earthquake-induced landslide［J］. Chinese Journal of Geotechnical Engineering, 23(3):311-314(in Chinese).
许冲, 徐锡伟, 郑文俊, 等. 2013. 2013年四川省芦山 "4·20" 7.0级强烈地震触发滑坡［J］. 地震地质, 35(3):641-660. doi:10.3969/j.issn.0253-4967.2013.03.018. XU Chong, XU Xi-wei, ZHENG Wen-jun, et al. 2013. Landslides triggered by the April 20, 2013 Lushan, Sichuan Province M_S7.0 strong earthquake of China［J］. Seismology and Geology, 35(3):641-660(in Chinese).
许强, 李为乐. 2010. 汶川地震诱发大型滑坡分布规律研究［J］. 工程地质学报, 18(6):818-826. XU Qiang, LI Wei-le. 2010. Distribution of large scale landslides induced by the Wenchuan earthquake［J］. Journal of Engineering Geology, 18(6):818-826(in Chinese).
杨有辉, 郑治. 2006. 公路滑坡预测预报研究现状及前景展望［J］. 公路交通技术, (6):18-22. YANG You-hui, ZHENG Zhi. 2006. Current situation and prospect of expressway landslide forecast［J］. Technology of Highway and Transport, (6):18-22(in Chinese).
殷跃平. 2008. 汶川八级地震地质灾害研究［J］. 工程地质学报, 16(4):433-444. YIN Yue-ping. 2008. Research on the geo-hazards triggered by Wenchuan earthquake, Sichuan［J］. Journal of Engineering Geology, 16(4):433-444(in Chinese).
Bishop A W. 1955. The use of the slip circle in the stability analysis of slopes［J］. Geotechnique, 5:7-17.
Bommer J J, Carlos E, Rodríguez C R. 2002. Earthquake-induced landslides in Central America［J］. Engineering Geology, 63(3):189-220.
Chen X L, Ran H L, Yang W T. 2012. Evaluation of factors controlling large earthquake-induced landslides by the Wenchuan earthquake［J］. Natural Hazards and Earth System Sciences, 12(12):3645-3657.
Chen X L, Yu L, Wang M M, et al. 2014. Brief communication:Landslides triggered by the M_S=7.0 Lushan earthquake, China［J］. Natural Hazards and Earth System Sciences, 14(5):1257-1267.
Devkota K C, Regmi A D, Pourghasemi H R, et al. 2013. Landslide susceptibility mapping using certainty factor, index of entropy and logistic regression models in GIS and their comparison at Mugling-Narayanghat road section in Nepal Himalaya［J］. Natural Hazards, 65(1):135-165.
Fellenius W. 1936. Calculation of the stability of earth dams［C］. Proceedings of the Second Congress of Large Dams, 4:445-463.
Fredlund D G, Krahn J. 1977. Comparison of slope stability methods of analysis［J］. Canadian Geotechnical Journal, 14(3):429-439.
Guzzetti F, Carrara A, Cardinali M, et al. 1999. Landslide hazard evaluation:A review of current techniques and their application in a multi-scale study, Central Italy［J］. Geomorphology, 31(1-4):181-216.
Keefer D K. 1984. Landslides caused by earthquakes［J］. Geological Society of America Bulletin, 95(4):406-421.
Morgenstern N R, Price V E. 1965. The analysis of the stability of general slip surfaces［J］. Geotechnique, 15(1):79-93.
Su L J, Hu K H, Zhang W F, et al. 2017. Characteristics and triggering mechanism of Xinmo landslide on 24 June 2017 in Sichuan, China［J］. Journal of Mountain Science, 14(9):1689-1700.
Wang H B, Sassa K, Xu W Y. 2007. Analysis of a spatial distribution of landslides triggered by the 2004 Chuetsu earthquakes of Niigata Prefecture, Japan［J］. Natural Hazards, 41:43-60.
Wen B P, Wang S J, Wang E Z, et al. 2004. Characteristics of rapid giant landslides in China［J］. Landslides, 1(4):247-261.

[1]	YANG Chen-yi, LI Xiao-ni, FENG Xi-jie, HUANG Yin-di, PEI Gen-di. SHALLOW STRUCTURE AND QUATERNARY ACTIVITY OF THE TAOCHUAN-HUXIAN FAULT, THE SUB-STRAND OF THE NORTHERN QINLING FAULT ZONE [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 464-483.
[2]	LI Yi-shi. RESEARCH ON COMPREHENSIVE STANDARDIZATION FOR SURVEYING AND PROSPECTING OF ACTIVE FAULT [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 455-463.
[3]	ZHANG Ling, MIAO Shu-qing, YANG Xiao-ping. THE ANALYSIS AND IMPLEMENTATION OF THE AUTOMATIC EXTRACTING METHOD FOR ACTIVE THRUST FAULTS IN THE NORTH TIANSHAN MOUNTAINS BASED ON ARCGIS SOFTWARE PLATFORM [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 422-434.
[4]	JIANG Feng-yun, JI Ling-yun, ZHU Liang-yu, LIU Chuan-jin. THE PRESENT CRUSTAL DEFORMATION CHARACTERISTICS OF THE HAIYUAN-LIUPANSHAN FAULT ZONE FROM INSAR AND GPS OBSERVATIONS [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 377-400.
[5]	WANG Liao, XIE Hong, YUAN Dao-yang, LI Zhi-min, XUE Shan-yu, SU Rui-huan, WEN Ya-meng, SU Qi. THE SURFACE RUPTURE CHARACTERISTICS BASED ON THE GF-7 IMAGES INTERPRETATION AND THE FIELD INVESTIGA-TION OF THE 2022 MENYUAN M_S6.9 EARTHQUAKE [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 401-421.
[6]	LIU Qing, LIU Shao, ZHANG Shi-min. PALEOSEISMOLOGIC STUDY ON THE YUEXI FAULT IN THE MIDSECTION OF THE DALIANGSHAN FAULT ZONE SINCE THE LATE QUATERNARY [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 321-337.
[7]	ZHAO Peng, LI Jun-hui, TAO Yue-chao, SHU Peng, FANG Zhen. NEW ACTIVITY PHENOMENA REVEALED BY TRENCH ON THE NORTH SIDE OF NÜSHAN LAKE IN THE TANLU FAULT ZONE AND DISCUSSION [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 338-354.
[8]	ZUO Yu-qi, YANG Hai-bo, YANG Xiao-ping, ZHAN Yan, LI An, SUN Xiang-yu, HU Zong-kai. EVIDENCE OF LATE QUATERNARY TECTONIC ACTIVITY OF THE BEIDA SHAN FAULT, SOUTHERN MARGIN OF THE ALASHAN BLOCK [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 355-376.
[9]	LI Xiao-ni, YANG Chen-yi, LI Gao-yang, FENG Xi-jie, HUANG Yin-di, LI Chen-xia, LI Miao, PEI Gen-di, WANG Wan-he. SHALLOW STRUCTURE AND LATE QUATERNARY ACTIVITIES OF BRANCH FAULTS ON THE NORTHERN SIDE OF THE WEINAN TABLELAND IN THE SOUTHEASTERN MARGIN OF THE WEIHE BASIN [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 484-499.
[10]	LIU Bai-yun, ZHAO Li, LIU Yun-yun, WANG Wen-cai, ZHANG Wei-dong. THE RESEARCH ON RELOCATION AND FAULT PLANE SOLUTION AND GEOMETRIC MEANING OF THE MADUO M7.4 EARTHQUAKE ON 22 MAY 2021 [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 500-516.
[11]	ZHAO De-zheng, QU Chun-yan, ZHANG Gui-fang, GONG Wen-yu, SHAN Xin-jian, ZHU Chuan-hua, ZHANG Guo-hong, SONG Xiao-gang. APPLICATIONS AND ADVANCES FOR THE COSEISMIC DEFORMA-TION OBSERVATIONS, EARTHQUAKE EMERGENCY RESPONSE AND SEISMOGENIC STRUCTURE INVESTIGATION USING INSAR [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(2): 570-592.
[12]	LI An, WAN Bo, WANG Xiao-xian, JI Hao-min, SUO Rui. NEW EVIDENCE OF THE PALEOEARTHQUAKE RUPTURE IN THE NORTH GAIZHOU-ANSHAN SEGMENT OF THE JINZHOU FAULT [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(1): 111-126.
[13]	ZHENG Hai-gang, YAO Da-quan, ZHAO Peng, YANG Yuan-yuan, HUANG Jin-shui. NEW ACTIVITY CHARACTERISTICS IN THE CHISHAN SECTION OF TAN-LU FAULT ZONE IN HOLOCENE [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(1): 127-138.
[14]	TIAN Yi-ming, YANG Zhuo-xin, WANG Zhi-shuo, SHI Jin-hu, ZHANG Yang, TAN Ya-li, ZHANG Jian-zhi, SONG Wei, JI Tong-yu. A PRELIMINARY STUDY OF THE SHALLOW EXPLORATION AND QUATERNARY ACTIVITIES OF THE FENGQIU SEGMENT OF THE XINXIANG-SHANGQIU FAULT [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(1): 139-152.
[15]	YANG Jian-wen, JIN Ming-pei, CHA Wen-jian, ZHANG Tian-ji, YE Beng. CRUSTAL S-WAVE VELOCITY STRUCTURE BENEATH THE XIAO-JIANG FAULT ZONE AND ADJACENT REGIONS REVEALED BY TWO-STEP INVERSION METHOD OF RECEIVER FUNCTIONS [J]. SEISMOLOGY AND GEOLOGY, 2023, 45(1): 190-207.