DOI QR코드

DOI QR Code

Analysis of slope stability based on evaluation of force balance

  • Razdolsky, A.G. (National Building Research Institute) ;
  • Yankelevsky, D.Z. (National Building Research Institute) ;
  • Karinski, Y.S. (National Building Research Institute)
  • Received : 2004.09.09
  • Accepted : 2005.03.31
  • Published : 2005.06.20

Abstract

The paper presents a new approach for the analysis of slope stability that is based on the numerical solution of a differential equation, which describes the thrust force distribution within the potential sliding mass. It is based on the evaluation of the thrust force value at the endpoint of the slip line. A coupled approximation of the slip and thrust lines is applied. The model is based on subdivision of the sliding mass into slices that are normal to the slip line and the equilibrium differential equation is obtained as the slice width approaches zero. Opposed to common iterative limit equilibrium procedures the present method is straightforward and gives an estimate of slope stability at the value of the safety factor prescribed in advance by standard requirements. Considering the location of the thrust line within the soil mass above the trial slip line eliminates the possible development of a tensile thrust force in the stable and critical states of the slope. The location of the upper boundary point of the thrust line is determined by the equilibrium of the upper triangular slice. The method can be applied to any smooth shape of a slip line, i.e., to a slip line without break points. An approximation of the slip and thrust lines by quadratic parabolas is used in the numerical examples for a series of slopes.

Keywords

References

  1. Bishop, A.W. (1955), 'The use of the slip circle in stability analysis of slopes', Geotechnique, 5(1), 7-17 https://doi.org/10.1680/geot.1955.5.1.7
  2. Fellenius, W. (1936), 'Calculation of the stability of earth dams', Proc. 2nd Congress on Large Dams, 4, 445-462
  3. Ginzburg, L. and Razdolsky, A. (1992), 'Determination of maximum sliding soil pressure', osnovaniya, fundamenty i mekhanika gruntov, 5, 11-14 (in Russian)
  4. Janbu, N. (1954), 'Application of composite slip surface for stability analysis', Proc. of European Conference on Stability of Earth Slopes, Stockholm, 3, 43-49
  5. Janbu, N. (1973), 'Slope stability computations. Embankment-dam engineering', Casagrande Volume, R.C. Hirschfeld and S.S. Poulos, eds., John Wiley and Sons, N.Y, 47-86
  6. Leshchinsky, D. (1990), 'Slope stability analysis: generalized approach', J. Geotechnical Engrg., ASCE, 118(10), 851-867
  7. Morgenstern, N.R. and Price, V,E. (1965), 'The analysis of the stability of general slip surfaces', Geotechnique, 15(1), 70-93
  8. Sharma, S. and Moudud, A. (1992), 'Interactive slope analysis using Spencer's method', Proc. Spec. Conference on Stability and Performance of Slopes and Embankments-II, ASCE, 1, 506-520
  9. Spencer, E. (1973), 'Thrust line criterion in embankment stability analysis', Geotechnique, 23(1), 85-100 https://doi.org/10.1680/geot.1973.23.1.85
  10. Takuo, Y., Jing-Cai, J. and Katsutoshi, U. (2000), 'Limit equilibrium stability analysis of slopes with stabilizing piles', Geotechnical Special Publication. No.101, ASCE, 343-354
  11. Yang, H., Wang, J. and Liu, Y. (2001), 'A new approach for the slope stability analysis', Mech. Research Communications, 28(6), 653-669 https://doi.org/10.1016/S0093-6413(02)00217-3
  12. Zhu, D.-Y. and Qian, Q. (2000), 'Determination of passive earth pressure coefficients by the method of triangular slices', Canadian Geotechnical Journal, 37, 485-491 https://doi.org/10.1139/cgj-37-2-485

Cited by

  1. Slope stability analysis based on the direct comparison of driving forces and resisting forces vol.33, pp.8, 2009, https://doi.org/10.1002/nag.761
  2. Three-dimensional simplified slope stability analysis by hybrid-type penalty method vol.15, pp.4, 2018, https://doi.org/10.12989/gae.2018.15.4.947