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Numerical study on spalling failure of rock surrounding deep buried tunnel based on DEM
Abstract Spalling failure is a common phenomenon in hard and brittle rocks surrounding deep buried tunnels. The particle discrete element method and the flat-joint model are useful for describing the characteristics of such rocks. Based on discrete element method (DEM) and Particle Flow Code (PFC3D, version 5.0), this study established a three-dimensional model of brittle rock by using layered modeling to simulate the spalling failure of rock surrounding a deep buried tunnel. The DBSCAN (density-based spatial clustering of application with noise) algorithm was used to process the data and establish a connection between macro- and meso-fractures. Spalling failure occurred mainly at the spandrel and the foot of the arch of the tunnel, and dense zones of intersection of the meso-fractures occurred at the top and bottom of the tunnel. Given that the axis of the tunnel was aligned with the in-situ intermediate principal stress, the magnitudes of the maximum and minimum in-situ principal stress acted as external factors affecting the occurrence of spalling failure. The in-situ intermediate principal stress influenced the depth and range of spalling failure, where this instability depended on the Poisson's ratio of the rock. The post-peak behavior of the rock also influenced the depth of the spalling failure.
Numerical study on spalling failure of rock surrounding deep buried tunnel based on DEM
Abstract Spalling failure is a common phenomenon in hard and brittle rocks surrounding deep buried tunnels. The particle discrete element method and the flat-joint model are useful for describing the characteristics of such rocks. Based on discrete element method (DEM) and Particle Flow Code (PFC3D, version 5.0), this study established a three-dimensional model of brittle rock by using layered modeling to simulate the spalling failure of rock surrounding a deep buried tunnel. The DBSCAN (density-based spatial clustering of application with noise) algorithm was used to process the data and establish a connection between macro- and meso-fractures. Spalling failure occurred mainly at the spandrel and the foot of the arch of the tunnel, and dense zones of intersection of the meso-fractures occurred at the top and bottom of the tunnel. Given that the axis of the tunnel was aligned with the in-situ intermediate principal stress, the magnitudes of the maximum and minimum in-situ principal stress acted as external factors affecting the occurrence of spalling failure. The in-situ intermediate principal stress influenced the depth and range of spalling failure, where this instability depended on the Poisson's ratio of the rock. The post-peak behavior of the rock also influenced the depth of the spalling failure.
Numerical study on spalling failure of rock surrounding deep buried tunnel based on DEM
Chen, Long (author) / Jin, Aibing (author) / Wu, Shunchuan (author) / Chu, Chaoqun (author) / Li, Xue (author)
2022-01-24
Article (Journal)
Electronic Resource
English
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