Abstract
Rock deterioration under freeze–thaw cycles is a concern for in-service tunnel in cold regions. Previous studies focused on the change of rock mechanical properties under unidirectional stress, but the natural rock mass is under three dimensional stresses. This paper investigates influences of the number of freeze–thaw cycle on sandstone under low confining pressure. Twelve sandstone samples were tested subjected to triaxial compression. Additionally, the damage characteristics of sandstone internal microstructure were obtained by using acoustic emission (AE) and mercury intrusion porosimetry. Results indicated that the mechanical properties of sandstone were significantly reduced by freeze–thaw effect. Sandstone’ peak strength and elastic modulus were 7.28–37.96% and 6.38–40.87% less than for the control, respectively. The proportion of super-large pore and large pore in sandstone increased by 19.53–81.19%. We attributed the reduced sandstone’ mechanical properties to the degenerated sandstone microstructure, which, in turn, was associated with increased sandstone macropores. The macroscopic failure pattern of sandstone changed from splitting failure to shear failure with an increasing of freeze–thaw cycles. Moreover, the activity of AE signal increased at each stage, and the cumulative ringing count also showed upward trend with the increase of freeze–thaw number.
Highlights
Rock deterioration under freeze–thaw cycles is a concern for in-service tunnel in cold regions
The ice melts into water and re-immerses the pore space of rock, which makes the permeability of rock increase[4]
After several freeze–thaw cycles, irreversible freeze–thaw damage occurs and rock strength gradually decreases, which poses a great threat to the stability of geotechnical engineering in cold r egion[5]
Summary
Rock deterioration under freeze–thaw cycles is a concern for in-service tunnel in cold regions. Seyed et al and Yu et al conducted triaxial compression tests on frozen-thawed rocks and found that the cohesion and internal friction angle of rocks decreased exponentially with the increase of the number of freeze–thaw c ycles[4,12] They found that the correlation between rock compressive strength, confining pressure and cycles can be described by the Mohr–Coulomb strength criterion[13]. In order to obtain the damage mechanism of frozen-thawed rocks, scholars have carried out a lot of detection and analysis on the internal structure characteristics of rocks using modern micro-detection technology They have carried out nuclear magnetic resonance (NMR) experiments on sandstone after freeze–thaw cycles and found that porosity gradually increases with the increase of c ycles[19,20,21]. Due to the extremely complex pore structure characteristics of rock, there is little research on quantitative analysis of microstructure changes after rock freeze–thaw damage
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