Parameters deterioration rules of surrounding rock for deep tunnel excavation based on unloading effect

Abstract

How to ensure the construction safety is one of the key problems for the deep tunnel excavation. Since a tunnel excavation 
is an unloading process in essence, a novel method to accurately 
evaluate the damage evolution of the surrounding rock was conducted to study the deformation and failure mechanism of the 
tunnel by considering the unloading effect. A typical tunnel in 
Shimen Mine in China was regarded as the background, the threedimension computational model was built by using FLAC3D technique. Then the different unloading zones of the surrounding rock 
were determined according to the unloading principle of tunnel 
excavation. The results show that the mechanical parameters for 
the different unloading zones, such as cohesion, internal friction 
angle, elastic modulus, and Poisson’s ratio, display the nonlinear degradation characteristics. And it can be found that the increasing range of the mechanical response index, such as displacement, 
stress and force, increase about 0.73-2.10 times comparing the 
conventional analysis with the unloading calculation. The unloading effect has a great influence on the stress field, the displacement field, and the forces of the supporting during the tunnel 
excavation. So it is more practical to consider the unloading effect 
during the deep tunnel excavation. The conclusions obtained in 
the study are of important theoretical value to direct the similar 
engineering practice.