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Bulletin of Engineering Geology and the Environment

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01-01-2023 | Original Paper

Flexural toppling characteristics of anti-dip soft rock slope with base friction test

Authors: Xingtao Beng, Guangcheng Zhang, Yichen Yang, Chun Zhu, Murat Karakus, Dasheng Wang

Published in: Bulletin of Engineering Geology and the Environment | Issue 1/2023

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Abstract

As one of the primary failure modes in the anti-dip soft rock slope, the research of flexural toppling is mainly focused on the deformation and failure mechanism. To recreate the whole flexural toppling process of the anti-dip soft rock slopes with different slope angles and rock stratum dip angles, the indoor base friction physical model tests were carried out based on the similarity ratio theory in this study. Based on the macroscopic phenomenon analysis, the displacement vector cloud plots, and the displacement–time curves during the tests are obtained, here are some conclusions. The main results are as follows: According to the flexural toppling deformation characteristics of the anti-dip soft rock slope, the tensile crack formed along the rock stratum on the middle and trailing edge of the slope crest, and it was caused by the differential deformation of the rock stratum; the toppling process can be divided into three stages: the initial deformation stage, the uniform deformation stage, and the accelerated deformation stage, while the anti-dip soft rock slope can be spatially divided into four zones: the stability zone, the active toppling tensile zone, the passive toppling tensile zone, and the shearing zone.

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Alejano LR, Iván GM, Roberto MA (2010) Analysis of a complex toppling-circular slope failure. Eng Geol 114(1):93–104CrossRef

Ashby J (1971) Sliding and toppling modes of failure in models and jointed rock slopes. MSc thesis, Imperial College, University of London

Bobet A (1999) Analytical solutions for toppling failure. Int J Rock Mech Min Sci 36(7):971–980CrossRef

Bray JW, Goodman RE (1981) The theory of base friction models. Int J Rock Mech Min Sci Geomech Abs 18(6):453–468CrossRef

Cheng DX, Liu DA, Ding EB, Zhao HM, Pan W, Guo HF (2005) Analysis on infuential factors and toppling conditions of toppling rock slope. Chin J Geotech Eng 27(11):1362–1366 (in Chinese)

Chen ZY (2005) Stability analysis of soil slope: principle, method and program. China Water Power Press, Beijing (in Chinese)

Ding BD, Han ZY, Zhang GC, Beng XT, Yang YC (2021) Flexural toppling mechanism and stability analysis of an anti-dip rock slope. Rock Mech Rock Eng 54:3721–3735CrossRef

Dong M, Zhang F, Lv J, Fei Y, Li Z (2020) Study of stability influencing factors of excavated anti-dip rock slope. KSCE J Civ Eng 24:2293–2303CrossRef

Goodman RE, Bray JW (1976) Toppling of rock slopes. In: Proceedings of the specialty conference on rock engineering for foundations and slopes, vol 2. American Society of Civil Engineering, Boulder, pp 739–760

Gu DM, Huang D (2016) A complex rock topple-rock slide failure of an anaclinal rock slope in the Wu Gorge, Yangtze River, China. Eng Gol 208:165–180

Hsu SC, Nelson PP (1995) Analyses of slopes in jointed weak rock masses using distinct element method. Proceedings of mechanics of jointed and faulted rock, April 6–9, Vienna, Austria, pp 589–594

Huang RQ, Li YS, Yan M (2017) The implication and evaluation of toppling failure in engineering geology practice. J Eng Geol 25(5):1165–1181 (in Chinese)

Huang RQ, Zhao JJ, Ju NP, Li G, Lee ML, Li YR (2013) Analysis of an anti-dip landslide triggered by the 2008 Wenchuan earthquake in China. Nat Hazards 68(2):1021–1039CrossRef

Li Z, Wang JA, Li L, Wang LX, Liang RY (2015) A case study integrating numerical simulation and GB-InSAR monitoring to analyze flexural toppling of an anti-dip slope in Fushun open pit. Eng Geol 197:20–32CrossRef

Liu CH, Jaksa MB, Meyers AG (2009) A transfer coefficient method for rock slope toppling. Can Geotech J 46(1):1–9CrossRef

Liu CH, Jaksa MB, Meyers AG (2010) Toppling mechanisms of rock slopes considering stabilization from the underlying rock mass. Int J Rock Mech Min Sci 47(2):348–354CrossRef

Majdi A, Amini M (2011) Analysis of geo-structural defects in flexural toppling failure. Int J Rock Mech Min Sci 48(2):175–186CrossRef

Nichol SL, Hungr O, Evans SG (2002) Large-scale-brittle and ductile toppling of rock slopes. Can Geotech J 39(4):773–788CrossRef

Ning Y, Zhang G, Tang H, Shen W, Shen P (2019) Process analysis of toppling failure on anti-dip rock slopes under seismic load in Southwest China. Rock Mech Rock Eng 52:4439–4455CrossRef

Ning YB, Tang HM, Zhang BC, Shen PW, Zhang GC, Xia D (2020) Investigation of the rock similar material proportion based on orthogonal design and its application in base friction physical model tests. Rock Soil Mech 41(6):2009–2020 (in Chinese)

Pritchard MA, Savigny KW (1990) Numerical modelling of toppling. Can Geotech J 27:823–834CrossRef

Pritchard MA, Savigny KW (1991) The Heather Hill landslide: an example of a large scale toppling failure in a natural slope. Can Geotech J 28:410–422CrossRef

Talobre J (1957) La me´canique des roches: appliquee´ aux travaux publics. Dunod

Tu GX, Deng H, Shang Q, Zhang Y, Luo XP (2020) Deep-seated large-scale toppling failure: a case study of the Lancang slope in Southwest China. Rock Mech Rock Eng 53(8):3417–3432CrossRef

Wang YK, Sun SW, Pang B, Liu L (2020) Base friction test on unloading deformation mechanism of soft foundation waste dump under gravity. Measurement 163:108054CrossRef

Wei W, Duan SH, Jiang QH, Qi ZF, Zhang FF (2008) Research on some factors influencing the toppling stability in anti-inclined slope. Rock Soil Mech 29(S1):431–434 (in Chinese)

Whyte RJ (1973) A study of progressive hanging wall caving at Chambishi coppermine in Zambia using the base friction model concept. Imperial College, London University, London

Zanbak C (1983) Design charts for rock slopes susceptible to toppling. J Geotech Eng 109:1039–1062CrossRef

Zhang GC, Wang F, Zhang H, Tang HM, Li XH, Zhong Y (2018) New stability calculation method for rock slopes subject to flexural toppling failure. Int J Rock Mech Min Sci 106:319–328CrossRef

Zhang L, Chen Z, Bao M, Nian G, Zhou Z, Zhu T (2022) Stability analysis and movement process determination of rock masses under open-pit to underground mining conditions. Geomech and Geophy Geo 8(5):1–9

Zhang S, Shi W, Yang C, Wang Y, Yu X (2022b) Experimental evaluation of gentle anti-dip slope deformation and fracture network under the action of underground mining. Landslides 1–28

Zhao H, Li WL, Wei JJ, Pang B (2018) Model test study on toppling deformation evolution process of counter-tilt slope. J Eng Geol 26(03):749–757 (in Chinese)

Zheng Y, Chen C, Liu T, Zhang H, Xia K, Liu F (2018) Study on the mechanisms of flexural toppling failure in anti-inclined rock slopes using numerical and limit equilibrium models. Eng Geol 237:116–128CrossRef

Zhu C, He MC, Karakus M, Cui XB, Tao ZG (2020) Investigating toppling failure mechanism of anti-dip layered slope due to excavation by physical modelling. Rock Mech Rock Eng 53(11):5029–5050CrossRef

Title: Flexural toppling characteristics of anti-dip soft rock slope with base friction test
Authors: Xingtao Beng
Guangcheng Zhang
Yichen Yang
Chun Zhu
Murat Karakus
Dasheng Wang
Publication date: 01-01-2023
Publisher: Springer Berlin Heidelberg
Published in: Bulletin of Engineering Geology and the Environment / Issue 1/2023
Print ISSN: 1435-9529
Electronic ISSN: 1435-9537
DOI: https://doi.org/10.1007/s10064-022-03037-8

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