The Impacts of Bedding Strength Parameters on the Micro-Cracking Morphology in Laminated Shale under Uniaxial Compression

The Impacts of Bedding Strength Parameters on the Micro-Cracking Morphology in Laminated Shale under Uniaxial Compression

The micro-cracking morphology in laminated shale formation plays a critical role in the enhancement of shale gas production, but the impacts of bedding strength parameters on micro-cracking morphology have not been well understood in laminated shale formation. This paper numerically investigated the...

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Bibliographic Details
Published in:Applied sciences Vol. 10; no. 16; p. 5496
Main Authors: Dou, Fakai, Wang, Jianguo, Leung, Chunfai
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-08-2020
Subjects:
Anisotropy
Bedding
bedding strength parameters
Complexity
Compression
Compressive strength
Computer simulation
crack fractal dimension
Crack initiation
crack morphology
Crack propagation
Cracking (fracturing)
Finite element analysis
Fracture mechanics
Gas production
Laboratories
laminated shale
Mathematical models
Matrix cracks
Mechanical properties
Medical imaging
Microcracks
Morphology
Oil and gas production
Propagation
Shale
Shale gas
Shear strength
Simulation
Stress-strain curves
Tensile strength
Two dimensional flow
Two dimensional models
uniaxial compression strength
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Summary:The micro-cracking morphology in laminated shale formation plays a critical role in the enhancement of shale gas production, but the impacts of bedding strength parameters on micro-cracking morphology have not been well understood in laminated shale formation. This paper numerically investigated the initiation and evolution of micro-cracking morphology with bedding strength parameters in laminated shale under uniaxial compression. First, a two-dimensional particle flow model (PFC2D) was established for laminated shale. Then, the micro-mechanical parameters of this model were calibrated using stress-strain curves and final fracture morphology measured in the laboratory. Finally, the impacts of bedding strength parameters on the uniaxial compressive strength (UCS), crack type and the complexity of fracture network were analyzed quantitatively. Numerical simulation results indicate that the UCS of shale varies linearly with the bedding strength, especially when the shear failure of beddings is dominant. Matrix cracks mainly depend on bedding strength, while the generation of tensile cracks is determined by the shear-to-tensile strength ratio of beddings (STR). The shale with a higher STR is likely to produce a more complex fracture network. Therefore, the bedding strength parameters should be carefully evaluated when the initiation and evolution of micro-cracking morphology in laminated shale formation are simulated.
ISSN:2076-3417
2076-3417
DOI:10.3390/app10165496