Tunnel Face Stability Considering the Influence of Excess Slurry Pressure

With excess slurry pressures exerted on the tunnel face, slurry particles tend to infiltrate into the soil in front of the tunnel. There will be excess pore pressure ahead of the tunnel in the case of infiltration, leading to an impairment in the supporting effect contributed by the excess slurry pr...

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Bibliographic Details
Published in:Sustainability 2023-05, Vol.15 (10), p.8230
Main Authors: Zhong, Junhao, Zhao, Shihe, Wang, Pengqin, Hou, Chuantan
Format: Article
Language:English
Subjects:
Analysis
Comparative analysis
Disclaimers
Equilibrium flow
Failure mechanisms
Filter cake
Kinematics
Limit analysis
Numerical analysis
Optimization
Permeability
Pore pressure
Pore water pressure
Pressure
Pressure distribution
Pressure drop
Pressure transfer
Safety factors
Seepage
Slurries
Slurry infiltration
Soil conditions
Soil properties
Soil strength
Soil structure
Stability analysis
Tunnels
Upper bounds
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Summary:With excess slurry pressures exerted on the tunnel face, slurry particles tend to infiltrate into the soil in front of the tunnel. There will be excess pore pressure ahead of the tunnel in the case of infiltration, leading to an impairment in the supporting effect contributed by the excess slurry pressure. Corresponding to three slurry infiltration scenarios distinguished by the forms of the filter cake, different pressure transfer models are employed to describe the pore pressure distribution. Using the kinematic approach of limit analysis and the numerically simulated seepage field, the study of tunnel face stability under different slurry infiltration cases is extended by employing a 3D discretization-based failure mechanism. In addition, two simple empirical formulas describing the pore pressure distributions above the tunnel and in advance of the tunnel are established and verified. Combined with the dichotomy method and strength reduction method, the safety factors yielding rigorous upper-bound solutions are obtained by optimization. The proposed method is validated by a comparative analysis. The developed framework allows considering the influence of excess pore pressure on the whole failure mechanism and the three-dimensional characteristics of seepage. A parameter analysis is performed to study the effect of the excess slurry pressure, hydraulic conditions, soil strength properties, and pressure drop coefficient. The results show that the steady-state flow model leads to much more conservative results than the full-membrane model. The safety factor increases with the increasing excess slurry pressure and the decreasing pressure drop coefficient. The present work provides an effective framework to quickly assess the face stability of tunnels under excess slurry pressure considering different filter cake scenarios.
ISSN:2071-1050
2071-1050
DOI:10.3390/su15108230