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Shear properties of non-persistent coplanar fractured hard rocks under normal stress unloading

Guoqing Chen, Liangjie Gu, Qiang Xu, Xing Yang, Yang Zhao

2024Journal of Rock Mechanics and Geotechnical Engineering12 citationsDOIOpen Access PDF

Abstract

During the excavation of large-scale rock slopes and deep hard rock engineering, the induced rapid unloading serves as the primary cause of rock mass deformation and failure. The essence of this phenomenon lies in the opening-shear failure process triggered by the normal stress unloading of fractured rock mass . In this study, we focus on local-scale rock fracture and conduct direct shear tests under different normal stress unloading rates on five types of non-persistent fractured hard rocks. The aim is to analyze the influence of normal stress unloading rates on the failure modes and shear mechanical characteristics of non-persistent fractured rocks. The results indicate that the normal unloading displacement decreases gradually with increasing normal stress unloading rate, while the influence of normal stress unloading rate on shear displacement is not significant. As the normal stress unloading rate increases, the rocks brittle failure process accelerates, and the degree of rocks damage decreases. Analysis of the stress state on rock fracture surfaces reveals that increasing the normal stress unloading rate enhances the compressive stress on rocks, leading to a transition in the failure mode from shear failure to tensile failure. A negative exponential strength formula was proposed, which effectively fits the relationship between failure normal stress and normal stress unloading rate. The findings enrich the theoretical foundation of unloading rock mechanics and provide theoretical support for disasters prevention and control in rock engineering excavations.

Topics & Concepts

GeologyShear (geology)Geotechnical engineeringShear stressNormal faultMaterials sciencePetrologyComposite materialSeismologyFault (geology)Rock Mechanics and ModelingGeotechnical and Geomechanical EngineeringTunneling and Rock Mechanics