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Rock Mechanics and Rock Engineering

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01-05-2010 | Original Paper

Controls on Block Toppling Using a Three-Dimensional Distinct Element Approach

Authors: Marc-André Brideau, Doug Stead

Published in: Rock Mechanics and Rock Engineering | Issue 3/2010

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Abstract

Analysis methods for block toppling are most commonly undertaken in two dimensions. This paper investigates the influence of discontinuity orientations on three-dimensional block toppling mechanisms using a three-dimensional distinct element code. The three-dimensional models allow one to kinematically appraise if toppling conditions derived for two-dimensional geometries can be extended into three dimensions. Two conceptual model geometries were considered in order to represent a road cut or open-pit bench. The first geometry examined a slope with fixed vertical lateral boundaries, while the second geometry assumed an unrestrained lateral slope as a model boundary condition. This “along-strike slope profile” of the models was found to play an important role in the failure mechanism and displacement direction. The dip direction and dip angle of the toppling, basal and lateral release discontinuities were varied one at the time using angular ranges of up to 30° from an assumed mutual orthogonal relationship. This made it possible for the influence and importance of each discontinuity set to be independently evaluated. The results are presented in a stereographic format with preliminary zones outlining discontinuity aspect combinations that potentially result in block toppling failures.

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Adachi T, Ohnishi Y, Arai K (1991) Investigation of toppling slope failure at Route 305 in Japan. In: Wittke W (ed) Proceedings of the 7th international congress on rock mechanics. Balkema, Rotterdam, pp 843–846

Adhikary DP, Dyskin AV (2007) Modelling of progressive and instantaneous failures of foliated rock slopes. Rock Mech Rock Eng 40(4):349–362CrossRef

Adhikary DP, Dyskin AV, Jewell RJ, Stewart DP (1997) A study of the mechanism of flexural toppling failure of rock slopes. Rock Mech Rock Eng 30(2):75–93CrossRef

Alfonsi P, Durville J-L, Rachez X (1999) Modélisation numérique d’une fondation sur versant rocheux par la méthode des éléments distincts comparaison 2-D/3-D. 9ième Congrès International de Mécanique des Roches. Balkema, Rotterdam, pp 71–76

Amini M, Majdi A, Aydan O (2008) Stability analysis and the stabilization of flexural toppling failure. Rock Mech Rock Eng. doi:10.1007/s00603-008-0020-2

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

Aydan O, Kawamoto T (1992) The stability of slopes and underground openings against flexural toppling and their stabilisation. Rock Mech Rock Eng 25:143–165CrossRef

Barla G, Borri-Brunetto M, Devin P, Zaninetti A (1995) Validation of a distinct element model for toppling rock slopes. In: Proceedings of the 8th congress of the international society for rock mechanics. Balkema, Rotterdam, pp 417–421

Barnett WP (2003) Geological control on slope failure mechanisms in the open pit at the Venetia Mine. S Afr J Geol 106:149–164CrossRef

Benko B (1997) Numerical modelling of slope deformations. Ph.D. thesis. University of Saskatchewan, Saskatoon, Saskatchewan, 366 pp

Bovis MJ (1991) Limits to common toppling: discussion. Can Geotech J 28:463–464CrossRef

Bovis MJ, Stewart TW (1998) Long-term deformation of a glacially undercut rock slope, Southwest British Columbia. In: Hungr O, Moore DP (eds) 8th international IAEG congress. Vancouver, British Columbia, pp 1267–1275

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

Brideau M-A, Stead D, Couture R (2006) Structural and engineering geology of the East Gate Landslide, Purcell Mountains, British Columbia, Canada. Eng Geol 84(3–4):183–206CrossRef

Caine N (1982) Toppling failures from alpine cliffs on Ben Lomond, Tasmania. Earth Surf Process Landf 7:133–152CrossRef

Corkum AG, Martin CD (2004) Analysis of a rock slide stabilized with a toe-berm: a case study in British Columbia, Canada. Int J Rock Mech Min Sci 41(7):1109–1121CrossRef

Cruden DM (1989) Limit to common toppling. Canadian Geotech J 26:737–742CrossRef

Cruden DM, Hu X-Q (1994) Topples on underdip slopes in the Highwood Pass, Alberta, Canada. Q J Eng Geol 27:57–68CrossRef

Cruden DM, Hu X-Q, Lu Z (1993) Rock topples in the highway cut west of Clairvaux, Jasper, Alberta. Can Geotech J 30:1016–1023CrossRef

Cundall PA (1988) Formulation of a three-dimensional distinct element model–part I. A scheme to detect and represent contacts in a system composed of many polyhedral blocks. Int J Rock Mech Min Sci Geomech Abstr 25(3):107–116

de Freitas MH, Watters RJ (1973) Some field examples of toppling failure. Geotechnique 23(4):495–514CrossRef

Deangeli C, Ferrero AM (2000) Rock mechanics studies to analyse toppling failure. In: Landslides in research: theory and practices. Thomas Telford, London

Goodman RE (1989) Introduction to rock mechanics, 2nd edn. Wiley, New York, 576 pp

Goodman RE, Bray JW (1976) Toppling of rock slopes. In: Specialty conference on rock engineering for foundations and slopes. American Society of Civil Engineering, Boulder, CO, pp 201–234

Goodman RE, Shi GH (1985) Block theory and its application to rock engineering. Prentice Hall, New Jersey, 338 pp

Hart R, Cundall PA, Lemos J (1988) Formulation of a three-dimensional distinct element model–part II. Mechanical calculations for motion and interaction of a system composed of many polyhedral blocks. Int J Rock Mech Min Sci Geomech Abstr 25(3):117–125

Hencher SR, Liao Q-H, Monaghan BG (1996) Modelling slope behaviour for open-pits. Trans Inst Min Metall Sect A Min Ind 105:A37–A47

Hoek E, Bray JW (1981) Rock slope engineering, 2nd edn. Institution of Mining and Metallurgy, London, 358 pp

Holmes G, Jarvis JJ (1985) Large-scale toppling within a sackung type deformation at Ben Attow, Scotland. Q J Eng Geol 18:287–289CrossRef

Ishida T, Chigira M, Hibino S (1987) Application of the distinct element method for analysis of toppling observed on a fissured rock slope. Rock Mech Rock Eng 20:277–283CrossRef

Itasca (2008) 3DEC-3 dimensional distinct element code. Itasca Consulting Group Inc., Minneapolis, MN

Jarman D (2006) Large rock slope failures in the Highlands of Scotland: characterisation, causes and spatial distribution. Eng Geol 83:161–182CrossRef

Kalenchuk KS, Diederichs MS, McKinnon S (2006) Characterizing block geometry in jointed rockmasses. Int J Rock Mech Min Sci 43(8):1212–1225CrossRef

Kinakin D (2004) Occurrence and genesis of alpine linears due to gravitational deformation in south western British Columbia. M.Sc. thesis. Simon Fraser University, Burnaby, BC, 174 pp

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

Merrien-Soukatchoff V, Quenot X, Guglielmi Y (2001) Modélisation par éléments distincts du phénomène de fauchage gravitaire. Application au glisssement de La Clapière (Saint-Etienne-de-Tinée, Alpes-Maritimes). Revue Francaise de Géotechnique 95–96:133–142

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

Piteau DR, Stewart AF, Martin DC (1981) Design examples of open pit slopes susceptible to toppling. In: Proceeding of third international conference of stability in surface mining. Society of Mining Engineering of AIME, Vancouver, pp 679–712

Pritchard MA (1989) Numerical modelling of large scale toppling. M.A.Sc. thesis. University of British Columbia, Vancouver, BC, 179 pp

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

Richards LR, Leg GMM, Whittle RA (1978) Appraisal of stability conditions in rock slopes. In: Bell FG (ed) Foundation engineering in difficult ground. Newnes-Butterworths, London, pp 449–512

Stacey TR (2006) Considerations of failure mechanisms associated with rock slope instability and consequences for stability analysis. J S Afr Inst Min Metall 105:485–493

Stead D, Yan M, Coggan JS, Eberhardt E (2005) New developments in the analysis of surface mine slopes. Proceedings of the 2005 computer applications in the minerals industries (CAMI 2005), Banff, AB, pp 1204–1226

Tosney JR, Milne D, Chance AV, Amon F (2004) Verification of a large scale slope instability mechanism at Highland Valley Copper. Int J Surf Min Reclam Environ 18(4):273–288CrossRef

Woodward RC (1988) The investigation of toppling slope failures in welded ash flow tuff at Glennies Creek Dam, New South Wales. Q J Eng Geol 21:289–298CrossRef

Wyllie DC (1980) Toppling rock slope failures: examples of analysis and stabilization. Rock Mech 13:89–98CrossRef

Yeung MR (1999) Sliding and toppling of rigid blocks under base friction. In: Amadei, Kranz, Scott, Smeallie (eds) Proceedings of rock mechanics for industry. Balkema, Rotterdam, pp 559–566

Yeung MR, Wong KL (2007) Three-dimensional kinematic conditions for toppling. In: Eberhardt E, Stead D, Morrison T (eds) 1st Canada-US rock mechanics symposium. Balkema, Rotterdam, pp 335–340

Zhang JH, Chen ZY, Wang XG (2007) Centrifuge modeling of rock slopes susceptible to block toppling. Rock Mech Rock Eng 40(4):363–382CrossRef

Title: Controls on Block Toppling Using a Three-Dimensional Distinct Element Approach
Authors: Marc-André Brideau
Doug Stead
Publication date: 01-05-2010
Publisher: Springer Vienna
Published in: Rock Mechanics and Rock Engineering / Issue 3/2010
Print ISSN: 0723-2632
Electronic ISSN: 1434-453X
DOI: https://doi.org/10.1007/s00603-009-0052-2

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