Theoretical Research on Grouting in Deep Loose Layers Based on the Cylindrical Diffusion Model of Radial Tube Flow

Grouting in deep, loose layers are a complex process in which many modes such as infiltration, splitting, and compaction coexist. It is of great significance to establish a realistic, simplified physical model to study the law of slurry diffusion. Herein, a cylindrical diffusion model of radial tube...

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Bibliographic Details
Published inGeofluids Vol. 2022; pp. 1 - 12
Main Authors Wang, Xuesong, Cheng, Hua, Yao, Zhishu, Rong, Chuanxin, Huang, Xianwen, Guo, Longhui
Format Journal Article
LanguageEnglish
Published Chichester Hindawi 2022
John Wiley & Sons, Inc
Hindawi Limited
Hindawi-Wiley
Subjects
Analysis
Coal
Coal mines
Coal mining
Differential equations
Diffusion
Diffusion layers
Diffusion rate
Distribution (Probability theory)
Distribution functions
Flow
Grouting
Laws, regulations and rules
Modelling
Permeability
Pressure
Pressure distribution
Radiation
Slurries
Velocity
China
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Summary:Grouting in deep, loose layers are a complex process in which many modes such as infiltration, splitting, and compaction coexist. It is of great significance to establish a realistic, simplified physical model to study the law of slurry diffusion. Herein, a cylindrical diffusion model of radial tube flow is established, and the control differential equations of both the Bingham slurry diffusion velocity in a single tube and the diffusion velocity of the radial tube flow are deduced. Additionally, the calculation formulas for the diffusion radius and slurry pressure distribution function are obtained. The rationality of the theory is verified by combining our results with those of the field grouting test of the Guotun coal mine. The results show that the cylindrical diffusion model of radial tube flow can successfully characterize the slurry diffusion law of grouting in a deep, loose layer. The slurry pressure attenuation shows distinguishable stages: within the first 30% of the diffusion radius, the slurry pressure decreased sharply by approximately 70%, and the slurry pressure decreases slowly in the later stages. Furthermore, the diffusion radius has a nonlinear, negative correlation with the height of the grouting section and the comprehensive injection rate of formation; the change rate is relatively more gradual, and there are no distinguishable stages. The research results provide a theoretical basis for reasonably determining the grouting parameters of deep, loose layers in the future.
ISSN:1468-8115
1468-8123
DOI:10.1155/2022/1302260