The continuum–discontinuum method (CDM) is a promising tool for the study of the rock fracture and fragmentation process under static or dynamic loading conditions, e.g., blasting. The hybrid/combined finite element method (FDEM) might be the most widely used continuum–discontinuum method. Based on the FDEM, many tools are developed for modelling the entire rock fracture process, e.g., Y-2D, Y-GUI, Y-GEO, Y-Slope, Y2D/3D IDE, and the commercial software ELFEN.
Numerical Code |
Modelled Results |
Reference |
---|---|---|
Y-Slope |
Y-Slope considers the tensile and shear failure. The failure is caused by gravity. By decreasing the strength parameters, the cracks initiate from the toe of the slope and propagate further into the slope. Finally, the cracks form a discontinuity surface. The crack initiation, propagation, colliding, fragmentation, and piling are modelled. |
[14] |
FDEM realized using ABAQUS/Explicit |
The FDEM framework is implemented in the ABAQUS/Explicit. The cohesive zone model (CZM) is employed to model the fracture occurring along the bulk elements boundary. The gravity increase method is implanted in the ABAQUS/Explicit-based FDEM program to model the slope failure process. The failure processes of the laboratory-scale slope with various joint inclination surfaces are modelled. |
[15] |
Y-Geo based on Munjiza’s Y-code |
Y-Geo is used to model the evaluation of a rock slide that occurred in Italy in 1997. The modelled results in terms of the runout profiles and evaluation of the slopes agree well with the site observation. |
[16] |
ELFEN |
A modified Mohr–Coulomb elastoplastic model is implemented in ELFEN to model the material softening, and deal with both the tension and shear states. Then, the ELFEN was employed to model the 1991 Randa rockslide. Due to strength degradation, the rock mass breaks into blocks and are modelled using ELFEN. |
[17] |
Y-2D with Y-GUI |
The failure process of the rock avalanche is modelled. The weak interface in the slope was firstly produced, then, the rock avalanche was initiated. A large volume of rock mass started to move, which further fragmented. During the process, the blocks were progressively broken into smaller fragments. |
[18] |
Numerical methods have been implemented to model the fracture process and the FDEM is considered as a promising tool. However, the computing power limited the FDEM, not only with 3D modelling but also in carrying out large-scale 2D modelling with a small mesh size in the past. The recently developed general purpose graphic processing unit (GPGUP) accelerators have dramatically improved this situation. Thus, this section gives a brief insight into the GPGUP-parallelized FDEM in modelling the rock slope failure process.
For the modelling of the rock slope failure process using GPGUP-parallelized Y-HFDEM, the strength reduction method (SRM) is implemented in the proposed method. Then, a typical rock high slope is modelled to gain insight into the GPGUP-parallelized Y-HFDEM on the rock slope stability analysis. More details including input parameters and the slope size can be found in[41] [41].
Figure 1 illustrates a typical rock slope failure process using the proposed method with the implementation of the SRM. The left part of Figure 1 indicates the stress distribution while the right part shows the fracture initiation and propagation. Figure 1a indicates the stress equilibrium state after the gravity of the rock mass is applied to the model. The stress concentration can be observed at the toe of the slope, where fractures initiate (Figure 1b). Then, the fractures propagate into the slope (Figure 1c) and form a sliding failure surface (Figure 1d). The rock mass slides along the newly formed sliding surface. Due to the sliding, rotation, and colliding, the rock mass breaks into fragments and finally piles at the lower bench of the slope (Figure 1e).
Figure 1. GPGUP-parallelized Y-HFDEM IDE modelling of rock slope failure process. (a) Stress equilibrium state; (b) 1 s; (c) 3 s; (d) 10 s; (e) 25 s.
The Figure 1 illustrates that the GPGUP-parallelized Y-HFDEM can effectively model the entire slope failure evolution process due to the implementation of the SRM in the proposed method. The GPGUP-parallelized FDEM with the implementation of SRM is a promising technique in the back analysis and prediction of the slope failure process, as it combined the advantages of the continuum methods and discontinuum methods, and it can naturally model the transition for rock from continuum to discontinuum through fracture and fragmentations.
[1] Abramson, L. W.; Lee, T. S.; Sharma, S. et al., Slope stability and stabilization methods. John Wiley & Sons: 2001.
[2] Jin, Y.-F.; Yin, Z.-Y.; Yuan, W.-H., Simulating retrogressive slope failure using two different smoothed particle finite element methods: A comparative study. Engineering Geology 2020, 279, 105870.
[3] Lv, Z. Q.; Wang, B. S.; Zhang, X. X. In The PFC2DSimulation of the Slope Stability, Advanced Materials Research, Trans Tech Publ: 2015; pp 240-243.
[4] Yang, Y.; Xu, D.; Liu, F. et al., Modeling the entire progressive failure process of rock slopes using a strength-based criterion. Computers and Geotechnics 2020, 126, 103726.
[5] Shen, J.; Karakus, M., Three-dimensional numerical analysis for rock slope stability using shear strength reduction method. Canadian geotechnical journal 2014, 51 (2), 164-172.
[6] Li, A. J.; Lyamin, A. V.; Merifield, R. S., Seismic rock slope stability charts based on limit analysis methods. Computers & Geotechnics 2009, 36 (1-2), 135-148.
[7] Li, A. J.; Merifield, R. S.; Lyamin, A. V., Stability charts for rock slopes based on the Hoek–Brown failure criterion. International Journal of Rock Mechanics & Mining Sciences 2008, 45 (5), 689-700.
[8] Yodsomjai, W.; Keawsawasvong, S.; Likitlersuang, S., Stability of Unsupported Conical Slopes in Hoek-Brown Rock Masses. Transportation Infrastructure Geotechnology 2021, 8 (2), 279-295.
[9] Yodsomjai, W.; Keawsawasvong, S.; Senjuntichai, T., Undrained Stability of Unsupported Conical Slopes in Anisotropic Clays Based on Anisotropic Undrained Shear Failure Criterion. 2021.
[10] Yodsomjai, W.; Keawsawasvong, S.; Thongchom, C. et al., Undrained stability of unsupported conical slopes in two-layered clays. Innovative Infrastructure Solutions 2020, 1, 15.
[11] Jing, L., A review of techniques, advances and outstanding issues in numerical modelling for rock mechanics and rock engineering. International Journal of Rock Mechanics and Mining Sciences 2003, 40 (3), 283-353.
[12] Jiang, M.; Murakami, A., Distinct element method analyses of idealized bonded-granulate cut slope. Granular Matter 2012, 14 (3), 393-410.
[13] Zhang, Y.; Xu, Q.; Chen, G. et al., Extension of discontinuous deformation analysis and application in cohesive-frictional slope analysis. International Journal of Rock Mechanics and Mining Sciences 2014, 70, 533-545.
[14] Sun, L.; Liu, Q.; Abdelaziz, A. et al., Simulating the entire progressive failure process of rock slopes using the combined finite-discrete element method. Computers and Geotechnics 2022, 141, 104557.
[15] Zhou, W.; Yuan, W.; Ma, G. et al., Combined finite-discrete element method modeling of rockslides. Engineering Computations 2016, 33 (5), 1530-1559.
[16] Barla, M.; Piovano, G.; Grasselli, G., Rock Slide Simulation with the Combined Finite-Discrete Element Method. International Journal of Geomechanics 2012, 12 (6), 711-721.
[17] Eberhardt, E.; Stead, D.; Coggan, J. S., Numerical analysis of initiation and progressive failure in natural rock slopes-the 1991 Randa rockslide. International Journal of Rock Mechanics and Mining Sciences 2004, 41 (1), 69-87.
[18] Mahabadi, O.; Grasselli, G.; Munjiza, A., Y-GUI: A graphical user interface and pre-processor for the combined finite-discrete element code, Y2D, incorporating material heterogeneity. Computers & Geosciences 2010, 36 (2), 241-252.
[19] An, H.; Wu, S.; Liu, H. et al., Hybrid Finite-Discrete Element Modelling of Various Rock Fracture Modes during Three Conventional Bending Tests. Sustainability 2022, 14 (2), 592.
[20] An, H.; Song, Y.; Liu, H. et al., Combined Finite-Discrete Element Modelling of Dynamic Rock Fracture and Fragmentation during Mining Production Process by Blast. Shock and Vibration 2021, 2021, 6622926.
[21] An, H.; Song, Y.; Liu, H., FDEM Modelling of Rock Fracture Process during Three-Point Bending Test under Quasistatic and Dynamic Loading Conditions. Shock and Vibration 2021, 2021, 5566992.
[22] An, H.; Liu, H.; Han, H., Hybrid finite–discrete element modelling of rock fracture process in intact and notched Brazilian disc tests. European Journal of Environmental and Civil Engineering 2021, 1-34.
[23] Huaming, A.; Hongyuan, L.; han, H., Hybrid finite-discrete element modelling of rock fracture during conventional compressive and tensile strength tests under quasi-static and dynamic loading conditions. Latin American Journal of Solids and Structures 2020, 17 (6), 1-32.
[24] An, H.; Liu, H.; Han, H., Hybrid Finite-Discrete Element Modelling of Excavation Damaged Zone Formation Process Induced by Blasts in a Deep Tunnel. Advances in Civil Engineering 2020, 2020, 7153958.
[25] An, H.; Liu, H.; Han, H. et al., Hybrid finite-discrete element modelling of dynamic fracture and resultant fragment casting and muck-piling by rock blast. Computers and Geotechnics 2017, 81, 322-345.
[26] Mohammadnejad, M.; Liu, H.; Chan, A. et al., An overview on advances in computational fracture mechanics of rock. Geosystem Engineering 2021, 24 (4), 206-229.
[27] Bradley, A. L. In Investigating the Influence of Mechanical Anisotropy on the Fracturing Behavior of Brittle Clay Shales with Application to Deep Geological Repositories, 13th ISRM International Congress of Rock Mechanics, International Society for Rock Mechanics: 2015.
[28] Zhao, Q.; Lisjak, A.; Mahabadi, O. et al., Numerical simulation of hydraulic fracturing and associated microseismicity using finite-discrete element method. Journal of Rock Mechanics and Geotechnical Engineering 2014, 6 (6), 574-581.
[29] Lukas, T.; Schiava D'Albano, G. G.; Munjiza, A., Space decomposition based parallelization solutions for the combined finite–discrete element method in 2D. Journal of Rock Mechanics and Geotechnical Engineering 2014, 6 (6), 607-615.
[30] Jing, L.; Hudson, J., Numerical methods in rock mechanics. International Journal of Rock Mechanics and Mining Sciences 2002, 39 (4), 409-427.
[31] Munjiza, A., The Combined Finite-Discrete Element Method. Wiley Online Library: 2004.
[32] Munjiza, A.; Xiang, J.; Garcia, X. et al., The virtual geoscience workbench, VGW: open source tools for discontinuous systems. Particuology 2010, 8 (2), 100-105.
[33] Vyazmensky, A.; Stead, D.; Elmo, D. et al., Numerical Analysis of Block Caving-Induced Instability in Large Open Pit Slopes: A Finite Element/Discrete Element Approach. Rock Mechanics and Rock Engineering 2010, 43 (1), 21-39.
[34] Styles, T., Numerical Modelling and Analysis of slope stability within fracture dominated rock masses. UNIVERSITY OF EXETER 2009.
[35] Tatonea, B.; Grassellia, G., A calibration procedure for two-dimensional laboratory-scale hybrid finite-discrete element simulations.
[36] Mohammadi, S., Discontinuum mechanics: Using finite and discrete elements. WIT press Southampton: 2003.
[37] Munjiza, A.; Andrews, K.; White, J., Combined single and smeared crack model in combined finite‐discrete element analysis. International Journal for Numerical Methods in Engineering 1999, 44 (1), 41-57.
[38] Liu, H.; Kou, S.; Lindqvist, P.-A. et al., Numerical studies on the failure process and associated microseismicity in rock under triaxial compression. Tectonophysics 2004, 384 (1), 149-174.
[39] Xiang, J.; Munjiza, A.; Latham, J. P., Finite strain, finite rotation quadratic tetrahedral element for the combined finite–discrete element method. International journal for numerical methods in engineering 2009, 79 (8), 946-978.
[40] Grasselli, G.; Lisjak, A.; Mahabadi, O. et al. In Slope Stability Analysis Using a Hybrid Finite-Discrete Element Method Code (EMDEM), 12th ISRM Congress, OnePetro: 2011.
[41] An, H.; Fan, Y.; Liu, H. et al., The State of the Art and New Insight into Combined Finite–Discrete Element Modelling of the Entire Rock Slope Failure Process. Sustainability 2022, 14 (9), 4896.