Energy-driven fracture and instability of deeply buried rock under triaxial alternative fatigue loads and multistage unloading conditions: Prior fatigue damage effect

Energy-driven fracture and instability of deeply buried rock under triaxial alternative fatigue loads and multistage unloading conditions: Prior fatigue damage effect

•Alternative cyclic loading and unloading tests were performed on deeply buried rock.•Energy conversion and mesoscopic crack pattern are all impacted by the prior fatigue damage.•The relationships between strain energy and confining pressure were established.•Post-test CT scanning suggests that the...

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Bibliographic Details
Published in:International journal of fatigue Vol. 168; p. 107410
Main Authors: Wang, Yu, Tang, Pufeng, Han, Jianqiang, Li, Peng
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-03-2023
Subjects:
Crack pattern
Disturbed loads
Energy conversion
Prior fatigue damage
Unloading effect
Unloading effect
Disturbed loads
Energy conversion
Crack pattern
Prior fatigue damage
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Summary:•Alternative cyclic loading and unloading tests were performed on deeply buried rock.•Energy conversion and mesoscopic crack pattern are all impacted by the prior fatigue damage.•The relationships between strain energy and confining pressure were established.•Post-test CT scanning suggests that the consumed energy is not proportional to the crack scale. Rock failure subjected to respective cyclic loading or unloading have been well investigated, however, the energy mechanism of deeply buried rock under alternative cyclic loading and unloading are not well understood. This work aims to reveal the effect of prior fatigue damage on rock fracture and energy evolution characteristics subjected to triaxial alternative cyclic loads and unloading confining pressure. Testing results show that rock stress strain responses, deformation, energy dissipation, and mesoscopic crack pattern are all impacted by the prior fatigue damage. The incremental radial and volumetric strain at the unloading confining pressure stage (UCPS) is larger than the cyclic loading stage (CLS), and their relationships and the confining pressure are revealed. The total energy, elastic energy, and radial strain energy increases and dissipated energy decreases with the increase of disturbed cycles. The relationship between strain energy and confining stress was established at both the UCPS and CLS, it is found that dissipated energy at the UCPS is larger than at the CLS. A series of post-test CT images reveal the internal failure modes and confirm the effect of the number of disturbed cycles on energy release and dissipation. It is suggested that the consumed energy is not proportional to the crack scale, the formation of shear cracks consumes much more energy than those of tensile cracks.
ISSN:0142-1123
1879-3452
DOI:10.1016/j.ijfatigue.2022.107410