Abstract
Proper mechanical model selection is critical in tunnel support design and stability analysis, especially to reflect the creep and strain-softening behavior of soft rock. We present a coupled nonlinear Burgers strain-softening (NBSS) model and numerical calculation method to investigate the coupled effects of creep and strain-softening of soft rock tunnels. The nonlinear elastic-viscous model is used to simulate the steady creep behavior of mudstone, and the nonlinear viscoplastic strain-softening model is used to simulate the accelerated creep behavior and post-peak strength attenuation behavior. The experimental results show that the viscoplastic parameters and post-peak softening parameters of mudstone are highly sensitive to confining pressure and exhibit nonlinear characteristics. The accelerated creep curve obtained by the numerical calculation is consistent with the experiments, which verifies the model reliability. We use the NBSS and nonlinear Burgers Mohr-Coulomb (NBMC) models to calculate the plastic zone distribution characteristics and deformation law. The distribution of the plastic zone calculated by the NBSS model is larger with more localized fractures. The NBSS model is useful for studying the evolution of stress and displacement fields of complex surrounding rock mass, which provides important theoretical guidelines for the support design and stability analysis of soft rock tunnel engineering.
Highlights
Rock strength attenuation and creep characteristics control the stability of supporting structures during tunnel excavation and support engineering [1,2,3,4,5]
In order to study the deformation law of soft surrounding rock and provide a theoretical basis for soft rock tunnel support engineering, this paper firstly analyzes the creep characteristics of yellow mudstone through laboratory tests, and proposes a nonlinear creep and strain softening coupling model (NBSS)
FLAC3D finite difference software was used to numerically solve the nonlinear Burgers strain-softening (NBSS) model to verify the reliability of the model
Summary
Rock strength attenuation and creep characteristics control the stability of supporting structures during tunnel excavation and support engineering [1,2,3,4,5]. The material strength characteristics of surrounding rock strength gradually decreases with time, in soft rock settings [6,7]. The micro-cracks in soft rock expand over time and the rock strength gradually decreases with increasing viscoplastic strain. When the strength is reduced to the load stress level, the soft rock will enter the accelerated creep stage. The strength attenuation process of soft rock over time can be characterized by creep damage and strain-softening models [8,9,10,11]
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