Mass-loss effects on the non-Darcy seepage characteristics of broken rock mass with different clay contents

A seepage testing system was designed and a series of seepage experiments on broken rock was conducted using different original porosity conditions and clay contents. The mass-loss process of the broken rock and the change in water flow velocity were investigated. After the mass-loss test, the non-D...

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Published inGeomechanics and geophysics for geo-energy and geo-resources. Vol. 9; no. 1
Main Authors Cao, Zhilin, Xie, Qiang, Xu, Xianyu, Sun, Weichen, Fumagalli, Alessio, Fu, Xiang
Format Journal Article
LanguageEnglish
Published Cham Springer International Publishing 01.12.2023
Springer Nature B.V
Subjects
Acceleration
Clay
Coefficients
Critical flow
Energy
Engineering
Environmental Science and Engineering
Evolution
Flow velocity
Fluctuations
Foundations
Geoengineering
Geophysics/Geodesy
Geotechnical Engineering & Applied Earth Sciences
Hydraulics
Liquid limits
Original Article
Particle size
Permeability
Permeability coefficient
Porosity
Prediction models
Rock
Rock masses
Rocks
Seepage
Testing
Velocity
Water
Water flow
Water inrush
Mass-loss
Fault rocks
Non-Darcy flow
Fault gouge
Water inrush
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Summary:A seepage testing system was designed and a series of seepage experiments on broken rock was conducted using different original porosity conditions and clay contents. The mass-loss process of the broken rock and the change in water flow velocity were investigated. After the mass-loss test, the non-Darcy seepage characteristics of the broken rock were tested through a step-by-step pressure-reduced seepage test. The experimental results show that the mass-loss and water velocity evolution during the water inrush could be divided into four stages: acceleration, stable with slight fluctuations, reacceleration, and stable. The lost-mass and change in water velocity were positively correlated with the clay contents and negatively correlated with the original porosity. By introducing the evolution equation of the Kozeny-Carman equation and the liquid limit index which characterises the effective particle size, the prediction model of the permeability coefficient was built. Six prediction models of the non-Darcy coefficient were verified against the testing results. The prediction model of the critical flow velocity from a Darcy flow to a non-Darcy flow using the Forchheimer number was also established. The results could provide an important reference for understanding water inrush mechanisms, adopting effective control measures for water inrush events, and calculating the water influx of tunnels. Article Highlights The mass-loss process of the broken rock and the change in water flow velocity were investigated. The mass-loss and water velocity evolution during the water inrush could be divided into four stages: acceleration, stable with slight fluctuations, reacceleration, and stable. By introducing the evolution equation of the Kozeny-Carman equation and the liquid limit index which characterises the effective particle size, the prediction model of the permeability coefficient was built.
ISSN:2363-8419
2363-8427
DOI:10.1007/s40948-023-00534-2