Rock and Soil Mechanics ›› 2022, Vol. 43 ›› Issue (10): 2911-2922.doi: 10.16285/j.rsm.2021.2094

• Numerical Analysis • Previous Articles     Next Articles

Numerical simulation of fracturing processes of rock specimens in uniaxial compression based on the continuum-discontinuum method considering the dynamic constitutive model

WANG Xue-bin1, 2, LIU Tong-xin2, BAI Xue-yuan2, LI Ji-xiang2   

  1. 1. Institute of Computational Mechanics, Liaoning Technical University, Fuxin, Liaoning 123000, China; 2. College of Mechanics and Engineering, Liaoning Technical University, Fuxin, Liaoning 123000, China
  • Received:2021-12-10 Revised:2022-07-05 Online:2022-10-19 Published:2022-10-18
  • Supported by:
    This work was supported by the National Natural Science Foundation of China (52074142).

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Abstract: It is important to study failures of rocks under dynamic loads for expounding mechanisms of geological disasters and for predicting and preventing these disasters on theoretical and practical aspects. Owing to advantages of numerical simulation, numerical methods applicable to modeling dynamic fracturing processes must be especially emphasized. Based on the combined Lagrangian-discrete element method, a continuum-discontinuum method considering the dynamic constitutive model was presented, in which the Zhu-Wang-Tang constitutive model was used to replace the generalized Hooke law. The continuum-discontinuum method considering the dynamic constitutive model was validated through modeling uniaxially compressive experiments of sandstone rock specimens for different loading velocities. Evolution of the number of crack segments with the longitudinal strain of the rock specimen was investigated, and evolution of the minimum principal stresses of nodes at the longitudinal symmetric line was also monitored. Deformation-fracturing processes of granite specimens for different loading velocities were modeled, and fracturing mechanisms of rock specimens were revealed. The following results were found. Shear bands include en echelon shear cracks. The minimum principal stress of the node exhibits a fluctuant decrease, followed by an increase in the oscillation form. The increasing stage corresponds to the strain-softening stage of the rock specimen. A large oscillatory amplitude of the minimum principal stress is found for the separating node, which is due to the fact that large stress waves are induced by node separations and contact between elements. Shear separations of nodes occur due to concentrations of the minimum principal stresses at the shear band tip. Motion of the triangle wedge of the rock specimen leads to tensile separations of nodes whose stress states are similar to those of the compact tension experiment.

Key words: rock, dynamic fracturing, Zhu-Wang-Tang constitutive model, continuum-discontinuum method, uniaxial compression, shear band, fracturing mechanism

CLC Number: 

  • TD 313
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