[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/gae.2016.10.1.059

Limit analysis of 3D rock slope stability with non-linear failure criterion

Gao, Yufeng (Key Laboratory of Ministry of Education for Geomechanics and Embankment Engineering, Hohai University)
Wu, Di (Key Laboratory of Ministry of Education for Geomechanics and Embankment Engineering, Hohai University)
Zhang, Fei (Key Laboratory of Ministry of Education for Geomechanics and Embankment Engineering, Hohai University)
Lei, G.H. (Key Laboratory of Ministry of Education for Geomechanics and Embankment Engineering, Hohai University)
Qin, Hongyu (School of Computer Science, Engineering and Mathematics, Flinders University)
Qiu, Yue (Key Laboratory of Ministry of Education for Geomechanics and Embankment Engineering, Hohai University)

Publication Information

Geomechanics and Engineering / v.10, no.1, 2016 , pp. 59-76 More about this Journal

Abstract

The non-linear Hoek-Brown failure criterion has been widely accepted and applied to evaluate the stability of rock slopes under plane-strain conditions. This paper presents a kinematic approach of limit analysis to assessing the static and seismic stability of three-dimensional (3D) rock slopes using the generalized Hoek-Brown failure criterion. A tangential technique is employed to obtain the equivalent Mohr-Coulomb strength parameters of rock material from the generalized Hoek-Brown criterion. The least upper bounds to the stability number are obtained in an optimization procedure and presented in the form of graphs and tables for a wide range of parameters. The calculated results demonstrate the influences of 3D geometrical constraint, non-linear strength parameters and seismic acceleration on the stability number and equivalent strength parameters. The presented upper-bound solutions can be used for preliminary assessment on the 3D rock slope stability in design and assessing other solutions from the developing methods in the stability analysis of 3D rock slopes.

Keywords

limit analysis; rock slope; three-dimensional; stability; failure criterion;

Citations & Related Records

Times Cited By KSCI : 1 (Citation Analysis)

Reference
Cited By KSCI

1	Carranza-Torres, C. (2004), "Some comments on the application of the Hoek-Brown failure criterion for intact rock and rock masses to the solution of tunnel and slope problems", MIR 2004-X Conference on Rock and Engineering Mechanics, Torino, 285-326.
2	Carranza-Torres, C. and Fairhurst, C. (1999), "The elasto-plastic response of underground excavations in rock masses that satisfy the Hoek-Brown failure criterion", Int. J. Rock Mech. Min. Sci., 36(6), 777-809. DOI
3	Chakraborti, S., Konietzky, H. and Walter, K. (2012), "A comparative study of different approaches for factor of safety calculations by shear strength reduction technique for non-linear Hoek-Brown failure criterion", Geotech. Geol. Eng., 30(4), 925-934. DOI
4	Chen, W.F. (1975), Limit Analysis and Soil Plasticity, Elsevier, Amsterdam, The Netherlands.
5	Chen, Z.Y. (1992), "Random trials used in determining global minimum factors of safety of slopes", Can. Geotech. J., 29(2), 225-233. DOI
6	Chen, W.F. and Liu, X.L. (1990), Limit Analysis in Soil Mechanics, Elsevier, Amsterdam, The Netherlands.
7	Collins, I.F., Gunn, C.I.M., Pender, M.J. and Yan, W. (1988), "Slope stability analyses for materials with a nonlinear failure envelope", Int. J. Numer. Anal. Methods Geomech., 12(5), 533-550. DOI
8	Dawson, E., You, K. and Park, Y. (2000), "Strength-reduction stability analysis of rock slopes using the Hoek-Brown failure criterion", Geotechnical Special Publication, 65-77.
9	Fraldi, M. and Guarracino, F. (2009), "Limit analysis of collapse mechanisms in cavities and tunnels according to the Hoek-Brown failure criterion", Int. J. Rock Mech. Min. Sci., 46(4), 665-673. DOI
10	Fu, W. and Liao, Y. (2010), "Non-linear shear strength reduction technique in slope stability calculation", Comput. Geotech., 37(3), 288-298. DOI
11	Hammah, R.E., Curran, J.H., Yacoub, T.E. and Corkum, B. (2004), "Stability analysis of rock slopes using the finite element method", Proceedings of the ISRM Regional Symposium, EUROCK.
12	Hobbs, D. (1966), "A study of the behaviour of broken rock under triaxial compression and its application to mine roadways", Int. J. Rock Mech. Min. Sci., 3(1), 11-43. DOI
13	Hoek, E. (1983), "Strength of jointed rock masses", Geotechnique, 33(3), 187-223. DOI
14	Hoek, E. (2007), Rock Mass Properties, Practical rock engineering, Rocscience Inc. http://www.rocscience.com/hoek/corner/11_Rock_mass_properties.pdf
15	Hoek, E. and Brown, E.T. (1980), "Empirical strength criterion for rock masses", J. Geotech. Eng. Div. ASCE, 106(GT9), 1013-1035.
16	Hoek, E., Wood, D. and Shah, S. (1992), "A modified Hoek-Brown failure criterion for jointed rock masses", Proc. Rock Characterization, Symp. Int. Soc. Rock Mech.: Eurock, 92, 209-214.
17	Hoek, E., Carranza-Torres, C. and Corkum, B. (2002), "Hoek-Brown failure criterion-2002 edition", Proceedings of the North American Rock Mechanics Society Meeting, Toronto, Canada, January, pp. 267-273.
18	Li, A.J., Merifield, R.S. and Lyamin, A.V. (2008), "Stability charts for rock slopes based on the Hoek-Brown failure criterion", Int. J. Rock Mech. Min. Sci., 45(5), 689-700. DOI
19	Li, A.J., Lyamin, A.V. and Merifield, R.S. (2009), "Seismic rock slope stability charts based on limit analysis methods", Comput. Geotech., 36(1-2), 135-148. DOI
20	Lin, H., Zhong, W., Xiong, W. and Tang, W. (2014), "Slope stability analysis using limit equilibrium method in nonlinear criterion", Sci. World J.
21	Michalowski, R.L. and Drescher, A. (2009), "Three-dimensional stability of slopes and excavations", Geotechnique, 59(10), 839-850. DOI
22	Michalowski, R.L. and Martel, T. (2011), "Stability charts for 3D failures of steep slopes subjected to seismic excitation", J. Geotech. Geoenviron. Eng., 137(2), 183-189. DOI
23	Michalowski, R.L. and You, L.Z. (2000), "Displacements of reinforced slopes subjected to seismic loads", J. Geotech. Geoenviron. Eng., 126(8), 685-694. DOI
24	Saada, Z., Maghous, S. and Garnier, D. (2012), "Stability analysis of rock slopes subjected to seepage forces using the modified Hoek-Brown criterion", Int. J. Rock Mech. Min. Sci., 55, 45-54.
25	Sharan, S.K. (2003), "Elastic-brittle-plastic analysis of circular openings in Hoek-Brown media", Int. J. Rock Mech. Min. Sci., 40(6), 817-824. DOI
26	Shen, J. and Karakus, M. (2013), "Three-dimensional numerical analysis for rock slope stability using shear strength reduction method", Can. Geotech. J., 51(2), 164-172. DOI
27	Shen, J., Karakus, M. and Xu, C. (2013), "Chart-based slope stability assessment using the Generalized Hoek-Brown criterion", Int. J. Rock Mech. Min. Sci., 64, 210-219.
28	Sheorey, P.R., Biswas, A.K. and Choubey, V.D. (1989), "An empirical failure criterion for rocks and jointed rock masses", J. Eng. Geol., 26(2), 141-159. DOI
29	Yang, X.L. and Qin, C.B. (2014), "Limit analysis of rectangular cavity subjected to seepage forces based on Hoek-Brown failure criterion", Geomech. Eng., 6(5), 503-515. DOI
30	Yang, X.L., Li, L. and Yin, J.H. (2004), "Seismic and static stability analysis for rock slopes by a kinematical approach", Geotechnique, 54(8), 543-549. DOI
31	Yudhbir, Y., Lemanza, W. and Prinzl, F. (1983), "An empirical failure criterion for rock masses", Proceedings of the 5th ISRM Congress, International Society for Rock Mechanics, Melbourne, Australia, April.

6	Vahab Sarfarazi. (2016) Computers and Concrete The effect of non-persistent joints on sliding direction of rock slopes / 17 (6) , 723
1435-9537	(2018) Bulletin of Engineering Geology and the Environment Modification of the gravity increase method in slope stability analysis / (1435-9537)
2	(2017) Geomechanics & engineering A novel story on rock slope reliability, by an initiative model that incorporated the harmony of damage, probability and fuzziness / 12 (2) , 269
6	(2016) Geomechanics & engineering Influence of undercut and surface crack on the stability of a vertical escarpment / 12 (6) , 965
4	(2017) Geomechanics & engineering Investigation of the effect of surcharge on behavior of soil slopes / 13 (4) , 653
1	(2016) Geomechanics & engineering Numerical analysis of a complex slope instability: Pseudo-wedge failure / 15 (1) , 669
4	(2018) Geomechanics & engineering Three-dimensional simplified slope stability analysis by hybrid-type penalty method / 15 (4) , 947
2	(2016) Geomechanics & engineering LE analysis on unsaturated slope stability with introduction of nonlinearity of soil strength / 19 (2) , 179
4	(2016) Geomechanics & engineering Stability assessment of soil slopes in three dimensions: The effect of the width of failure and of tension crack / 22 (4) , 319
3	(2016) Geomechanics & engineering Passive earth pressure for retaining structure considering unsaturation and change of effective unit weight of backfill / 23 (3) , 207