The evolution of fractures in deep, weakly cemented overlying strata and the characteristics of severe and mild fracture zones

Fracture development in the overlying strata of a quarry is a key factor leading to aquifer water loss. Clearly understanding the fracture characteristics of deeply weakly cemented overburden is of significant importance for water-preserved mining. In order to investigate further the laws governing...

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Bibliographic Details
Published in:Geomechanics and geophysics for geo-energy and geo-resources. 2024-12, Vol.10 (1), p.1-17, Article 94
Main Authors: Xu, Liangke, Yu, Fenghai, Tan, Yunliang, Zhang, Chuang, Zhou, Kai
Format: Article
Language:English
Subjects:
Aquifers
Coal mining
Compaction
Energy
Engineering
Environmental Science and Engineering
Evolution
Foundations
Fracture zones
Fractures
Geoengineering
Geomechanical challenges in the process of comprehensive utilization of closed/abandoned mines
Geophysics/Geodesy
Geotechnical Engineering & Applied Earth Sciences
Hydraulics
Microseismic monitoring
Microseisms
Mining
Monitoring
Numerical simulation
Overburden
Overlying strata fracture zone
Permeability
Permeability coefficient
Quarries
Research methods
Retention
Rock
Rocks
Seepage
Simulation analysis
Spatial distribution
Strata
Theoretical analysis
Velocity
Water
Water conservation
Water loss
Water-blocking capacity
Weakly cemented soft rock
Work face
Zoning
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Summary:Fracture development in the overlying strata of a quarry is a key factor leading to aquifer water loss. Clearly understanding the fracture characteristics of deeply weakly cemented overburden is of significant importance for water-preserved mining. In order to investigate further the laws governing fracture evolution and zoning characteristics of deep, weakly cemented overlying strata, research methods, including theoretical analysis, numerical simulation, and engineering measurement, are employed. The calculation method of seepage velocity is derived by using the formula for the vertical permeability coefficient of the mining aquiclude. Based on the relationship between the seepage velocity of the aquiclude and the recharge velocity of the overlying aquifer under critical water conservation conditions, a quantitative formula characterizing the water-blocking capacity of the aquiclude is proposed. It is found that the variation in permeability of the aquiclude is negatively correlated with the distance from the working face. Consequently, the fracture zoning characteristics of deeply weakly cemented overburden rock, centered around the water-blocking capacity of fractured rock strata, are summarized. The simulation analysis of the evolution of fractures in overlying rock reveals that the compaction range of fractures increases as the working face lengthens. However, the overall development range of fractures remains largely unchanged. Additionally, the expansion of the tensile fracture range occurs solely in the vertical direction as mining height increases, while the compaction range of fractures gradually diminishes. Microseismic monitoring indicates higher incidences of fractures in the structural equilibrium zone and severe fracture zone, with more frequent occurrences of tensile and shear failures. Conversely, the mild fracture zone exhibits fewer occurrences of fractures. Article highlights According to the critical condition of water retention of aquiclude, the quantitative characterization formula of water blocking capacity of mining aquiclude and the influencing factors of permeability change of mining aquiclude are put forward, and the water blocking capacity of aquiclude is used as the judgment method to divide the severe and mild fracture zone of overburden. Based on the critical water retention condition of aquicludes, a quantitative formula is proposed for characterizing the water-blocking capacity of mining aquicludes, along with the identif
ISSN:2363-8419
2363-8427
DOI:10.1007/s40948-024-00801-w