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Numerical study of critical behaviour of deformation and permeability of fractured rock masses

Numerical study of critical behaviour of deformation and permeability of fractured rock masses
Numerical study of critical behaviour of deformation and permeability of fractured rock masses
The connectivity of fractures in rock masses is determined using a numerical simulation method. There is a continuous fracture cluster throughout a fractured rock mass if fracture density (d) is at or above a threshold fracture density dc, Fractal dimension (Df) is used to describe the connectivity and compactness of the largest fracture clusters. Df increases with increasing fracture density. Percolation theory is used to determine the universal law, Df = Af(d?dc)f, which describes the critical behaviour of connectivity of fractures in rock masses. The results from numerical modeling show that the deformability of fractured rock masses increases greatly with increasing fracture density (i.e., fractal dimension), and the critical behaviour of deformability can be described by Bs = A(d?df)s. Also, the overall permeability of a fractured rock mass occurs at or above a critical fracture density (dc) and increases with increasing fracture density. The critical behaviour of permeability can be described by q = Ap(d?dc)p. The critical behaviour of connectivity and permeability of naturally fractured rock masses is examined using the universal forms.

fractured rock, critical behaviour, connectivity, deformability, permeability
0264-8172
535-548
Zhang, Xing
e92abcc2-6163-40b0-9b53-0a61bdf864d7
Sanderson, D.J.
5653bc11-b905-4985-8c16-c655b2170ba9
Zhang, Xing
e92abcc2-6163-40b0-9b53-0a61bdf864d7
Sanderson, D.J.
5653bc11-b905-4985-8c16-c655b2170ba9

Zhang, Xing and Sanderson, D.J. (1998) Numerical study of critical behaviour of deformation and permeability of fractured rock masses. Marine and Petroleum Geology, 15 (6), 535-548. (doi:10.1016/S0264-8172(98)00030-0).

Record type: Article

Abstract

The connectivity of fractures in rock masses is determined using a numerical simulation method. There is a continuous fracture cluster throughout a fractured rock mass if fracture density (d) is at or above a threshold fracture density dc, Fractal dimension (Df) is used to describe the connectivity and compactness of the largest fracture clusters. Df increases with increasing fracture density. Percolation theory is used to determine the universal law, Df = Af(d?dc)f, which describes the critical behaviour of connectivity of fractures in rock masses. The results from numerical modeling show that the deformability of fractured rock masses increases greatly with increasing fracture density (i.e., fractal dimension), and the critical behaviour of deformability can be described by Bs = A(d?df)s. Also, the overall permeability of a fractured rock mass occurs at or above a critical fracture density (dc) and increases with increasing fracture density. The critical behaviour of permeability can be described by q = Ap(d?dc)p. The critical behaviour of connectivity and permeability of naturally fractured rock masses is examined using the universal forms.

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More information

Published date: 15 September 1998
Keywords: fractured rock, critical behaviour, connectivity, deformability, permeability

Identifiers

Local EPrints ID: 76120
URI: http://eprints.soton.ac.uk/id/eprint/76120
DOI: doi:10.1016/S0264-8172(98)00030-0
ISSN: 0264-8172
PURE UUID: d02f8dd8-89fb-4b04-bf55-b78f18bdec36
ORCID for D.J. Sanderson: ORCID iD orcid.org/0000-0002-2144-3527

Catalogue record

Date deposited: 11 Mar 2010
Last modified: 14 Mar 2024 02:53

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Contributors

Author: Xing Zhang
Author: D.J. Sanderson ORCID iD

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