Mesoscopic damage evolution and acoustic emission characteristics of cemented paste backfill under different loading rates

The cemented paste backfill (CPB) has a significant loading rate (LR) effect. The damage evolution process of CPB is closely related to the characteristics of acoustic emission (AE). This paper analyzes the damage evolution law of the filling body under different loading rates using indoor test and numerical simulations. We introduce the moment tensor theory to simulate the AE characteristics of the whole process of filling loading and explore the LR effect of the backfill with the help of the energy conservation. The results indicate the following: (1) when LR increases from 0.1 to 2 mm/min, the UCS of the backfill first increases and then decreases, contributing to the occurance of the critical LR. (2) There are no microcracks occurred in the backfill at the initial stage of loading, and the microcracks increase slowly, which is not obviously affected by LR. After the peak value, the microcracks in backfill expand and propagat rapidly to form mesoscopic cracks. (3) The mesoscopic AE events based on the moment tensor theory are in good agreement with the laboratory tests results, which can be divided into the initial period, quiet period, slow raising period, rapid raising period, and rapid falling period. (4) The temporal and spatial distribution characteristics of AE are consistent with the evolution law of microcracks. There are fewer AE events before the peak value, and AE events increase significantly and frequently with large magnitude events after the peak value. AE events dense zone and AE events with larger magnitude increase under higher LR. (5) Besides, the boundary energy and dissipation energy also gradually increased; at the same time, the strain energy first increased and then decreased. The results can provide a reference for understanding the damage evolution characteristics of backfill by different LR and AE mesoscopic simulation.

Automated summary

This paper analyzes the damage evolution of cemented paste backfill (CPB) under different loading rates using indoor tests and numerical simulations. The moment tensor theory is introduced to simulate the acoustic emission (AE) characteristics during the loading process, and the energy conservation principle is used to explore the loading rate (LR) effect on the backfill. The results show that the uniaxial compressive strength (UCS) of the backfill first increases and then decreases as LR increases. Microcracks in the backfill slowly increase and are not significantly affected by LR until after the peak value, when they rapidly expand and propagate to form mesoscopic cracks. The temporal and spatial distribution of AE events based on the moment tensor theory are consistent with laboratory test results, and they can be divided into different periods. The characteristics of AE events are also consistent with the evolution of microcracks, with fewer events before the peak value and a significant increase in magnitude and frequency after the peak value. AE events dense zone and events with larger magnitudes increase under higher LR. Furthermore, the boundary energy and dissipation energy gradually increase, while the strain energy first increases and then decreases. These findings provide insights into the damage evolution characteristics of backfill under different LR and AE mesoscopic simulation.