A Simplified Model for Time-Dependent Deformation of Rock Joints

A Simplified Model for Time-Dependent Deformation of Rock Joints

Understanding the time-dependent deformation behavior of rock joint is important when evaluating long-term stability of structures built on or in jointed rock masses. This study focuses on the time-dependent strength and deformation of unweathered clean rock joints. First, five grain-scale joint mod...

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Bibliographic Details
Published in:Rock mechanics and rock engineering Vol. 54; no. 4; pp. 1779 - 1797
Main Authors: Wang, Mingzheng, Cai, Ming
Format: Journal Article
Language:English
Published: Vienna Springer Vienna 01-04-2021
Springer Nature B.V
Subjects:
Civil Engineering
Creep strength
Deformation
Discrete element method
Earth and Environmental Science
Earth Sciences
Geophysics/Geodesy
Joints (timber)
Original Paper
Rock masses
Rocks
Roughness
Shear strength
Simulation
Sliding
Slumping
Solifluction
Stability
Stability analysis
Structural stability
Time dependence
Velocity
Rock joints
Creep model of joint
Time-dependent behavior
Grain-based model
GBM-UDEC
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Summary:Understanding the time-dependent deformation behavior of rock joint is important when evaluating long-term stability of structures built on or in jointed rock masses. This study focuses on the time-dependent strength and deformation of unweathered clean rock joints. First, five grain-scale joint models are established based on Barton’s standard joint profiles using the GBM-TtoF creep material model. Barton’s non-linear shear strength criterion is adopted to determine the short-term shear strength of the joints. Second, a series of creep simulations are conducted to investigate major factors (normal stress, shear loading ratio, and joint roughness) that influence the long-term shear strength and the sliding velocity of the joints. The results reveal that normal stress has more influence than joint roughness on resisting creep slipping of the joints. Third, an equation for the prediction of creep sliding velocity is developed by fitting the simulation results and the equation is verified by experimental data. Finally, a creep slipping model for simplified flat joints is proposed, which can be used to model the long-term shear strength and sliding velocity of joints under creep deformation conditions. The creep slipping model, which can be used in both stationary and variable stress conditions, is useful for simulating time-dependent behaviors of jointed rock mass using the distinct element method.
ISSN:0723-2632
1434-453X
DOI:10.1007/s00603-020-02346-2