Experimental study on the triaxial mechanical behaviors of the Cemented Paste Backfill: Effect of curing time, drainage conditions and curing temperature

The application of CPB (Cemented Paste Backfill) can realize the clean, efficient, and safe mining of underground metal mines. Clear understanding on the triaxial mechanical properties of CPB is important to the CPB design and the stability analysis of the backfilled CPB structure. The triaxial mechanical properties of CPB can be significantly affected by the different curing conditions. In this research, triaxial compression tests of the CPB samples were carried out using the GCTS (Geotechnical Consulting & Testing System), and the considered curing conditions include different curing time (1, 3, 7 and 28 days), drainage conditions (drained and undrained) and curing temperatures (20 degrees C, 35 degrees C and 45 degrees C). The measured mechanical parameters were compared and analyzed against the framework of the Mohr-Coulomb criterion. Then, the vertical stress distribution of the backfilled CPB structure was calculated and discussed using the measured mechanical parameters. The results show that with the increase of the lateral constraint ratio (sigma(c)/S-d0), the elastoplastic stage of the measured deviator stress versus axial strain curve of CPB sample is gradually obvious. The peak deviator stress (S-p(d)) and the ultimate axial strain (epsilon(u)) show the linear and negative exponential increase with the sigma(c)/S-d0 respectively. The number of cracks on the fractured surface of the CPB samples gradually decreased with the increase of sigma(c)/S-d0. The failure types of CPB samples were changed from tensile failure (sigma(c)/S-d0 = 0%) to the mixed tensile-shear failure (sigma(c)/S-d0 approximate to 10%) and compression-shear failure (sigma(c)/S-d0 >= 20%). Moreover, with the increase of curing time and curing temperature or under the drained curing condition, the peak deviator stress and cohesion (c(b)) of CPB can be significantly increased, but the corresponding internal friction angle (phi(b)) is decreased. The shear mechanical parameters of CPB can significantly affect the vertical stress distribution inside the CPB structure. Therefore, when estimating the vertical stress distribution inside the backfilled CPB structure in engineering practices, it is necessary to focus on the changes of CPB shear parameters (c(b) and phi(b)) caused by different curing conditions.

Automated summary

The application of CPB can lead to clean, efficient, and safe mining in underground metal mines. The triaxial mechanical properties of CPB are significantly influenced by different curing conditions, with the deviator stress versus axial strain curve becoming more obvious with the increase of lateral constraint ratio. Increases in curing time and temperature, or drainage conditions, can lead to significant increases in peak deviator stress and cohesion of CPB, but a decrease in internal friction angle.