Numerical Investigation for the Effect of Joint Persistence on Rock Slope Stability Using a Lattice Spring-Based Synthetic Rock Mass Model

Author:

Al-E’Bayat Mariam1,Guner Dogukan2ORCID,Sherizadeh Taghi2ORCID,Asadizadeh Mostafa2

Affiliation:

1. Department of Geosciences and Geological and Petroleum Engineering, Missouri University of Science and Technology, 1400 N. Bishop Ave., Rolla, MO 65409, USA

2. Department of Mining and Explosives Engineering, Missouri University of Science and Technology, 1400 N. Bishop Ave., Rolla, MO 65409, USA

Abstract

This study underscores the profound influence of rock joints, both persistent and non-persistent with rock bridges, on the stability and behavior of rock masses—a critical consideration for sustainable engineering and natural structures, especially in rock slope stability. Leveraging the lattice spring-based synthetic rock mass (LS-SRM) modeling approach, this research aims to understand the impact of persistent and non-persistent joint parameters on rock slope stability. The Slope Model, a Synthetic Rock Mass (SRM) approach-based code, is used to investigate the joint parameters such as dip angle, spacing, rock bridge length, and trace overlapping. The results show that the mobilizing zones in slopes with non-persistent joints were smaller and shallower compared to slopes with fully persistent joints. The joint dip angle was found to heavily influence the failure mode in rock slopes with non-coplanar rock bridges. Shallow joint dip angles led to tensile failures, whereas steeper joint dip angles resulted in shear-tensile failures. Slopes with wider joint spacings exhibited deeper failure zones and a higher factor of safety, while longer rock bridge lengths enhanced slope stability and led to lower failure zones. The overlapping of joint traces has no apparent impact on slope stability and failure mechanism. This comprehensive analysis contributes valuable insights into sustainable rock engineering practices and the design of resilient structures in natural environments.

Publisher

MDPI AG

Reference52 articles.

1. Deere, D.U., Hendron, A.J., Patton, F.D., and Cording, E.J. (1966, January 15–17). Design of surface and near-surface construction in rock. Proceedings of the 8th U.S. Symposium on Rock Mechanics (USRMS), Minneapolis, MN, USA.

2. Engineering Classification of Jointed Rock Masses;Bieniawski;Civ. Eng. S. Afr.,1973

3. Engineering classification of rock masses for the design of tunnel support;Barton;Rock Mech.,1974

4. Characterizing rock masses by the RMi for Use in Practical Rock Engineering: Part 1: The development of the Rock Mass index (RMi);Tunn. Undergr. Space Technol.,1996

5. Strength of rock and rock masses;Hoek;ISRM New J.,1994

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