A microscopic DEM investigation on fracture shearing characteristics of infilled grains with different geometrical shapes in rock discontinuities
Zhi-Cheng Tang, Zhifei Zhang, Lichun Zhao, Suguang Xiao
Abstract
Rock discontinuities or faults often contain a layer of granular material. However, the evolutionary behaviors (movement and breakage) of such infilled grains under shearing have not been comprehensively studied. To better understand this issue microscopically, numerical direct shear tests are performed on small rock discontinuity with single-grain infilled under different normal stresses by PFC 2D , with emphasis on the effects of grain geometry [reflected by the aspect ratio ( a / b ) and shear rate. Under the low normal stress (i.e., 0.1 MPa), circular grains ( a / b = 1.0) move in pure rolling during the shear process, with slight surface erosion, and the shear stress remains almost constant except for several fluctuations. The movement of grains with larger a / b changes from rolling to sliding or even crushing as the shear displacement increases. Under the high normal stress (i.e., 0.6 MPa), grains can eventually be crushed into a few large angular fragments and many fine comminuted particles, accompanied by severe damage to discontinuity surfaces, significant shear shrinkage, and violently fluctuating shear stress. The volume fraction of large angular fragments increases with the increase in a / b value, while that of fine comminuted particles decreases. Shear rate also has a significant impact on grain behavior. The main movement of grain with a / b = 2.0 changes from rolling to sliding and even crushing under the low normal stress with the increase in shear rate. Rock discontinuity exhibits unstable shearing, and surface damage is less significant under the high normal stress and higher shear rate. The dominant failure mode in grains and discontinuity surfaces involves tension microcracks at different shear rates, while tension microcracks in the grain under high normal stress decrease drastically as the shear rate increases. Effects of micro-parameters of infilled grain are also investigated through sensitivity analysis. The observations provide implications for the macro-shear mechanism of rock discontinuity infilled with granular materials. • Shear behaviors of infilled rock discontinuity are investigated by PFC 2D . • Shear responses of infilled grains in rock fracture are greatly influenced by normal stress, grain shape, and shear rate. • Size distribution of grain fragments affects friction behaviors of infilled fracture. • Sensitivity of main microscopic parameters of the numerical model is analyzed.