Abstract
The effect of temperature fluctuation on rocks needs to be considered in many civil engineering applications. Up to date the dynamic characteristics of rock under freeze-thaw cycles are still not quite clearly understood. In this study, the dynamic mechanical properties of sandstone under pre-compression stress and freeze-thaw cycles were investigated. At the same number of freeze-thaw cycles, with increasing axial pre-compression stress, the dynamic Young’s modulus and peak stress first increase and then decrease, whereas the dynamic peak strain first decreases and then increases. At the same pre-compression stress, with increasing number of freeze-thaw cycles, the peak stress decreases while the peak strain increases, and the peak strain and peak stress show an inverse correlation before or after the pre-compression stress reaches the densification load of the static stress–strain curve. The peak stress and strain both increase under the static load near the yielding stage threshold of the static stress–strain curve. The failure mode is mainly shear failure, and with increasing axial pre-compression stress, the degree of shear failure increases, the energy absorption rate of the specimen increases first and then decreases. With increasing number of freeze-thaw cycles, the number of fragments increases and the size diminishes, and the energy absorption rates of the sandstone increase.
Highlights
When rocks are subjected to freeze-thaw weather, in the freezing process, the water undergoes an ice phase volume expansion which produces a freezing force acting on the rock matrix [1]
It is very important to study the dynamic characteristics of rock masses under the action of the freeze-thaw cycle, which is significant in the study of rock mechanics theory and practical application of rock mass engineering
The failure modes of specimens are significant indicators of the failure mechanism of rocks
Summary
When rocks are subjected to freeze-thaw weather, in the freezing process, the water undergoes an ice phase volume expansion which produces a freezing force acting on the rock matrix [1]. Rock mechanics engineering has to account for complex and freeze-thaw cycling environments and for various types of static load and dynamic disturbances in cold areas, such as in situ stress, blasting in the rock mass of the slope, and earthquakes. Considering the strain-rate effect, some empirical expressions for the dynamic mechanical degradation of sandstone were proposed after long-term freeze-thaw weathering [20,21] These studies only explain the effect of freeze-thaw processes without considering the combined effect of the freeze-thaw process coupled with static (pre-compression) and dynamic loads. The results indicate that the pre-compression stress and the number of freeze-thaw cycles together have a very significant effect on the rock mechanical properties and failure characteristics
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