Investigation on the strength characteristics of frozen lean clay influenced by anisotropy

Artificial ground freezing (AGF) technology is commonly utilized to stabilize adjacent soils and guarantee the safety during subway tunnel construction by inserting freezing pipes into the ground to form a frozen soil mass. Nonetheless, inclined installation of freezing pipes, aside from the conventional horizontal or vertical configurations, frequently arises due to the complex subterranean pipelines and restricted construction areas. The directional dependence of mechanical properties of lean clay under such conditions remains insufficiently investigated. To address this issue, it is essential to systematically analyze the coupled effect of freezing temperature and sampling angle on the mechanical behavior of lean clay, which is commonly encountered in shield tunnel excavation. Consequently, this study proposed an apparatus and its method for preparing anisotropic clay specimens sampled at various angles ranging from 0° to 90° relative to the natural deposition direction. The anisotropic characteristics of the specimens was verified through the 3D X-ray computed tomography (CT) scanning, focusing on porosity. Uniaxial compressive strength (UCS) tests were then conducted on lean clay specimens prepared by slurry-based consolidation method. The impact of anisotropy on mechanical properties was comprehensively investigated by testing specimens at different sampling angles θ (0°、30°、45°、60° and 90°). The UCS results showed consistent strain-hardening behavior across different sampling angles under subfreezing temperatures of −5 °C, −10 °C and − 15 °C. The combined influences of anisotropy and freezing temperature on the strength of frozen lean clay were discussed by regression analysis. UCS exhibited an exponential decrease with increasing sample angle, and a linear rise with decreasing freezing temperature. A mathematical model was established to predict strength and deformation behavior of lean clay, incorporating the coupled effects of anisotropy and freezing conditions. In addition, the correlation between macroscopic strength and mesoscopic porosity was investigated. The augmentation of porosity resulted in a diminution of frozen soil strength. The research provides a reliable foundation for predicting of mechanical properties of lean clay in the AGF-reinforced engineering of subway tunnel and holds practical engineering significance for disease control.