Rock mechanics for underground mining, 3rd ed �~��)\E&c�
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by %+,�7�=Wt-
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B. H. G. Brady
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Emeritus Professor, The University of Western Australia, and Consulting �u4UQM�j|q
Engineer, Montville, Queensland, Australia 6��#rj3^�]
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E. T. Brown pN�z�Sy"Y$
Emeritus Professor, The University of Queensland, and Senior Consultant, )m�7� �Y�o
Golder Associates Pty Ltd, Brisbane, Australia V!94I2%#x�
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KLUWER ACADEMIC PUBLISHERS ��_;1H2o2f
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2005 Springer Science + Business Media, Inc $ }D9�)&f;
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Preface to the third edition m"CsJ'\ors
Sometimes it is suggested that mining engineering and its supporting engineering _PR>��<L_
sciences have reached a state of maturity. However, this proposition is inconsistent ;^K4�kK�&f
with major developments in the twenty years that have elapsed since the preparation of �@a{1�vT9b
the first edition of this book, and the ten years since it has been subject to any substantial �����#�nS
revision. Over those periods, innovations and improvements in engineering practice X( H-U
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in mining and mining rock mechanics, and advances in the engineering science of ��^Q'^9M2)
rock mechanics, have been extraordinary. For these reasons the third edition, which �/?,c4K,ap
results from comprehensive and thorough revision of the earlier editions, has involved �Xv�IrO]F-
the replacement or substantial modification of the equivalent of about half of the text _Bh ^�<D-�
and figures of those versions of the book. jml
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One of the key drivers for many significant developments in fundamental rock mechanics 2�X�t$KF,?
over the period has been the mining industry’s recognition of the economic '�[n�H]�N
returns of better understanding and more rigorous application of the governing sciences `zJ�T�Vi�4
embedded in its industrial operations and processes. The result has been some Um�RI! WQl
notable advances in mining engineering practice, involving improvements in mining )j[rm�
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methods in particular. For example, caving methods are now more widely applied V!Q1o�!��J
as understanding of their scientific basis has improved and their economic and operational rfdT0xfcU
advantages have been realised. Whereas sublevel caving was once regarded �</OZ�,3J=
in some places as a method of marginal interest, the advent of very large scale sublevel mar
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caving, made possible in part by improved drilling technology and in part by %j3��*��j�
understanding of the governing rock mechanics, it is now an attractive proposition for lQolE P.pc
many orebodies. Similarly, block caving is now conducted efficiently and reliably in .Y"H{|]Mnh
orebody settings that would have been inconceivable two decades ago. At the same x�3JX}yCX
time, methods such as overhand cut-and-fill stoping and shrink stoping have declined ]^63n/Twj�
in application, replaced in part by open stoping and bench-and-fill stoping, where large *Q�@�%<�R
scale mechanisation, improved backfill technology, reliable rock mass reinforcement )O�A�d[u<
of stope walls and the intrinsic advantages of non-entry methods of working have led p�+;[i%��`
to superior economics and enhanced operational safety. ^\��X-e�eA
The scope of developments in mining rock mechanics science and practice has been Q'o�k%9q!p
as impressive as that in mining engineering. Perhaps the most significant advance has \v�'�\
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been the resolution of some longstanding issues of rock fracture, failure and strength FD&�"k=p+X
and their relation to the modes of deformation and degradation of rock around mining Hkt�vUJ(Ii
excavations. The fact that the key research on this topic was conducted at the Underground �3',|HA /x
Research Laboratory of Atomic Energy of Canada Limited demonstrates the MU�;
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extent to which mining rock mechanics has benefited from fundamental research in )� Dz�b�J}
other fields of rock engineering. The mechanics of blocky rock has also been a field of R0n#��FL^E
impressive development, particularly in regard to formulation of a broad spectrum of �BihX�Yux*
methods of analysis of block jointed rock and their application in excavation engineering �j(`L)/�|O
and support and reinforcement design. More generally, improved understanding k8}*b&+{vz
of the mechanics of discontinuous rock has had a profound effect on simulation of y3 R+060\3
caving mechanics and therefore on the design and operation of block caving and Kug�_0+�gI
sublevel caving mines. u�H}cvshv�
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Mining-induced seismicity and the related phenomenon of rockbursts have become u49�v,,WGw
more prevalent in hard rock mining. Developments in mineworthy seismic equipment �/idQfff��
and associated data recording, processing and analysis hardware and software have [_��&\w�HX
contributed greatly to measurement, characterisation and management of the problem. S�9�$*�w!W
These developments have been complemented by measures in excavation design b-1cA1#_cP
and extraction sequencing which have done much to mitigate the serious operating H�vn{aLa.
problems which can occur in seismically active, rockburst prone mines. In large-scale zF6]2Y�?k%
open stope mining, Canadian developments based on pillarless stoping, formulation >&|�C
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of extraction sequences which promote the evolution and uniform displacement of a O;�u&>�BMk
regular mine stress abutment, and the extensive use of cement-stabilised backfill, have &gn^i!%�Z)
been successful in managing an acute mining challenge. Notably, these measures have VPB,�8zb�]
been based on sound conceptual and analytical models of the relation of damaging 8u,f<XHi"a
seismicity to induced stress, geological structure, potential rock displacements and !18M!8Xea
strain energy release during mining. +w��
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Some remarkable developments in computational methods have supported these c&1�:H1��#
improvements in rock mechanics practice. Many mining rock mechanics problems 0u]!C"VX��
are effectively four-dimensional, in that it is the evolution of the state of stress over the l@x��/{��0
time scale of the mining life of the orebody which needs to be interpreted in terms of �&uh|!��lD
the probable modes of response of the host rock mass. The computational efficiency C0�x��j�M0
of tools for three-dimensional stress analysis now permits modelling of key stages of W��?5�u O�
an extraction sequence, for example, as a matter of routine rock mechanics practice. �~�mqiXr8
Similarly, computer power and efficient algorithms provide a notable capacity to r>=�)Y32Q
simulate the displacement and flow of rock in cave mining and to support design of ~�Bll�\3-=
optimum caving layouts. �+Mb;;�h�b
Notwithstanding these developments, it is encouraging to note continued attention �F��xu'(xa
to formal mathematical analysis in solution of rock mechanics problems. The results ;T�Af[[P��
of such analysis provide the canonical solutions for the discipline of rock mechanics �f\W1u#;u)
and ensure a sound base for both the science and engineering practice. �0]C�~C�vO
In preparing this extensive revision, the authors have been fortunate to have the 8._
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support of many colleagues and several organisations. In particular, they would like GZ�.�F���q
to record the helpful advice and comment of colleagues on possible improvements �nQ*��9|v4
in earlier editions of the book and in identifying inevitable errors in the text. They zFy0Sz��F�
acknowledge the generous assistance of the Brisbane office of Golder Associates in �RJ ,a}w[9
providing facilities and many helpful services, particularly in assistance with drafting CzF#fe�T�A
of the figures for this edition. One of the authors was supported for part of the
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work of revision by The University of Western Australia, and the other by the Julius ,\�y)k}0lH
Kruttschnitt Mineral Research Centre of The University of Queensland. This support, Y�<�'T�;�@
including the associated library services, is acknowledged with gratitude. The authors �H'f��mQf
thank the many individuals and organisations who generously gave permission to use !2)$lM�1@J
published material. Finally, they record the encouragement of publisher’s representative, �NuLyu=.�?
Petra van Steenbergen, and her patient assistance and advice during this major ���
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undertaking. l�2))�StEm
B. H. G. B. 9o��|=n�'o
E. T. B. 7��V6gT�}R
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