The Role of Pore Pressure on the Mechanical Behavior of Coal Under Undrained Cyclic Triaxial Loading

Geofluids widely exist in natural rocks, and the fluid overpressure affects the mechanical behavior of rocks, triggering dynamic instability events. To investigate the role of pore fluid in low-permeability coal away from excavation boundary but still influenced by the periodic excavation disturbanc...

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Bibliographic Details
Published in:Rock mechanics and rock engineering 2022-03, Vol.55 (3), p.1375-1392
Main Authors: Zhong, Chunlin, Zhang, Zhenyu, Ranjith, P. G., Zhang, Chengpeng, Xue, Kangsheng
Format: Article
Language:English
Subjects:
Axial strain
Civil Engineering
Coal
Crack closure
Cracking (corrosion)
Cracks
Cyclic loading
Cyclic loads
Deformation
Dilatancy
Dredging
Dynamic stability
Earth and Environmental Science
Earth Sciences
Evolution
Excavation
Geophysics/Geodesy
Instability
Mechanical properties
Membrane permeability
Original Paper
Overpressure
Permeability
Pore pressure
Pore water
Rock
Rocks
Shrinkage
Strain
Surface stability
Tensile stress
Triaxial loads
Unloading
Volumetric strain
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Summary:Geofluids widely exist in natural rocks, and the fluid overpressure affects the mechanical behavior of rocks, triggering dynamic instability events. To investigate the role of pore fluid in low-permeability coal away from excavation boundary but still influenced by the periodic excavation disturbance, a series of undrained cyclic triaxial compressive tests were conducted on saturated coal. The results show that pore water has little effect on the axial strain evolution of coal, but has a significant effect on the radial and volumetric strain evolution. Different from dry coal, the saturated coal samples (except the coal samples SUC 1-1 and SUC 1-2 which show a slight volume shrinkage stage) show dilation deformation directly without any volume shrinkage, due to regional overpressure caused by the undrained condition. With this constraint against crack closure, a low frictional strength of crack surfaces was produced, favoring instability. Moreover, the saturated coal cracks cannot close tightly at the loading stage due to water propping effect, resulting in that the crack could not keep stationary, instead it slips throughout the loading and unloading processes. Also, the pore overpressure provides tensile stress, producing a large number of macro-tensile cracks in the final failure. This tensile cracking process is influenced by the loading frequency, as the pore pressure decay lags behind the unloaded stress, producing pore overpressure to tensile cracking in the unloading process. This lag effect becomes more prominent with the increase of cyclic loading frequency. Consequently, the number of tensile cracks of saturated coal at the loading frequency of 0.4 Hz is larger than that at the loading frequency of 0.1 Hz. Highlights The pore overpressure promote the deformation growth to the direction of minimum principal stress. Dilatancy occurred directly from the start of loading for saturated coal due to regional overpressure. Pore overpressure provides tensile stress to the crack, producing a large number of macro tensile cracks in the final failure of the coal. The number of tensile cracks of saturated coal increased with the cyclic loading frequency due to the prominent lag effect of strain behind stress.
ISSN:0723-2632
1434-453X
DOI:10.1007/s00603-021-02705-7