Hoek–Brown failure criterion explained
The Hoek–Brown failure criterion is an empirical stress surface that is used in rock mechanics to predict the failure of rock. The original version of the Hoek–Brown criterion was developed by Evert Hoek and E. T. Brown in 1980 for the design of underground excavations. In 1988, the criterion was extended for applicability to slope stability and surface excavation problems. An update of the criterion was presented in 2002 that included improvements in the correlation between the model parameters and the geological strength index (GSI).
The basic idea of the Hoek–Brown criterion was to start with the properties intact rock and to add factors to reduce those properties because of the existence of joints in the rock. Although a similar criterion for concrete had been developed in 1936, the significant tool that the Hoek–Brown criterion gave design engineers was a quantification of the relation between the stress state and Bieniawski's rock mass rating (RMR).The Hoek–Brown failure criterion is used widely in mining engineering design.
The original Hoek–Brown criterion
The Hoek–Brown criterion has the form
\sigma1=\sigma3+\sqrt{A\sigma3+B2}
where
is the effective maximum principal stress,
is the effective minimum principal stress, and
are materials constants. In terms of the mean normal stress (
) and maximum
shear stress (
)
\taum=\tfrac{1}{2}\sqrt{A(\sigmam-\taum)+B2}
where
\taum=\tfrac{1}{2}(\sigma1-\sigma3)~;~~\sigmam=\tfrac{1}{2}(\sigma1+\sigma3)~.
We can convert the above relation into a form similar to the Mohr–Coulomb failure criterion by solving for
to get
\taum=\tfrac{1}{8}\left[-A\pm\sqrt{A2+16(A\sigmam+B2)}\right]
The material constants
are related to the unconfined compressive (
) and
tensile strengths (
) by
Symmetry issue
If we set
in the above equation, we get the
pure shear Hoek–Brown criterion:
\taum=\tfrac{1}{8}\left[-A\pm\sqrt{A2+4B2}\right]
The two values of
are unsymmetric with respect to the
axis in the
-plane. This feature of the Hoek–Brown criterion appears unphysical and care must be exercised when using this criterion in
numerical simulations.
See also
References
[1] [2] [3] [4] [5] [6]
External links
Notes and References
- Book: Hoek E. . Brown E.T. . 1980 . Underground Excavations in Rock . London . Institution of Mining and Metallurgy.
- Book: Pariseau, W. G. . 2009 . Design Analysis in Rock Mechanics . Taylor and Francis . 499.
- Hoek E. . Brown E.T. . 1980 . Empirical strength criterion for rock masses . Journal of the Geotechnical Engineering Division . 1013–1025.
- Hoek, E. and Brown . 1988 . The Hoek-Brown failure criterion - a 1988 update . Proc. 15th Canadian Rock Mech. Symp. . 31–38 .
- Hoek E, Carranza-Torres CT, Corkum B . 2002 . Hoek-Brown failure criterion-2002 edition . Proceedings of the Fifth North American Rock Mechanics Symposium . 1 . 267–273 .
- Bieniawski, Z. T. . 1976 . Rock mass classification in rock engineering . Proc. Symposium on Exploration for Rock Engineering . Z. T. Bieniawski . 97–106 . Balkema, Cape Town.