Abstract
A discrete element method code was used to investigate the damage characteristics of jointed rock masses under repetitive impact loading. The Flat-Joint Contact Model (FJCM) in the two-dimensional particle flow code (PFC2D) was used to calibrate the microparameters that control the macroscopic behavior of the rock. The relationship between macro- and microparameters by a series of uniaxial direct tension and compression numerical tests based on an orthogonal experimental design method was obtained to calibrate the microparameters accurately. Then, the Synthetic Rock Mass (SRM) method that incorporates joints into the calibrated particle model was used to construct large-scale jointed rock mass specimens, and the repetitive drop hammer impact numerical tests on SRM specimens with different numbers of horizontal joints and dip angle joints were carried out to study the damage evolution, stress wave propagation, and energy dissipation characteristics. The results show that the greater the number of joints, the greater the number of cracks generated, the greater the degree of damage, and the more energy dissipated for rock masses with horizontal joints. The greater the dip angle of joints, the less the number of cracks generated, the less the degree of damage, and the less energy dissipated for rock masses with different dip angles of joints. The impact-induced stress waves will be reflected when they encounter preexisting joints in the process of propagation. When the reflected stress waves meet with subsequent stress waves, the stress waves will change from compressional waves to tensile waves, producing tensile damage inside rock masses.
Highlights
Joints are commonly found in rock masses and play a key role in controlling the mechanical behavior of the rock structure, slowing down and attenuating the propagation of stress waves and accelerating the damage of jointed rock masses and dominating the failure modes, which has a significant impact on the dynamic mechanical properties of rock masses [1, 2]
In underground metal mining, the failure of surrounding rock subjected to repeated impact loading often occurs due to continuous blasting operations [4]. e damage of rock masses under repetitive impact loading is a dynamic process of cumulative damage evolution. erefore, it is important to study the damage evolution of rock masses under repetitive impact loading to understand the dynamic characteristics of rock masses and assess the structural stability of rock engineering
Based on PFC2D, the relationship between the macro- and microparameters is firstly obtained by an orthogonal experimental design method in order to accurately calibrate the microparameters
Summary
Joints are commonly found in rock masses and play a key role in controlling the mechanical behavior of the rock structure, slowing down and attenuating the propagation of stress waves and accelerating the damage of jointed rock masses and dominating the failure modes, which has a significant impact on the dynamic mechanical properties of rock masses [1, 2]. Dai et al [8] analyzed the dynamic properties, damage characteristics, energy dissipation, and damage pattern of rock specimens containing holes under cyclic impact loading. Qiu et al [11] focused on the influence of layer plane structure on dynamic tensile properties and fracturing behavior of this phyllite and found that the damage of bedding rock masses with different layer dip angles shows three different damage patterns. E discrete element method (DEM) based on discontinuous media is a direct modeling approach of impact-induced damage It has been widely and successfully applied in modeling the dynamic behavior of rocks. PFC2D was used to study the damage evolution, stress wave propagation, and energy dissipation characteristics of jointed rock mass specimens with different numbers and dip angle joints under repetitive drop hammer impact loading
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