Integration of borehole geophysical data in 2D and 3D to develop a hazard index

Bronwyn L Chalke; Timothy WJ Chalke

doi:10.1071/ASEG2007ab019

ISSN: 2202-0586
E-ISSN:

oa Integration of borehole geophysical data in 2D and 3D to develop a hazard index
Authors Bronwyn L Chalke^a and Timothy WJ Chalke^b
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^a Anglo American, 2, 205 Moggill Rd. Taringa QLD Aus, [email protected] ^b MIRA Geoscience Asia Pacific, Level1, 1 Swann Road. Taringa QLD Aus, [email protected]
Publisher: Australian Society of Exploration Geophysicists
Source: ASEG Extended Abstracts, Volume 2007, Issue ASEG2007 - 19th Geophysical Conference, Dec 2007, p. 1 - 5
DOI: https://doi.org/10.1071/ASEG2007ab019
- Published online: 01 Dec 2007

Abstract

Summary

A borehole hazard index is the integration of interpreted risk indexes with an existing geological and structural 3D mine or exploration model. Individual risk indexes are produced and combined with the purpose of providing a clear visual and quantitative method for determining varying degrees of risk associated with development through a particular geological rock volume.

Disparate data sets are used to characterize separate risk indexes established from user defined criteria. Input data sets include geological and structural logs and mine layouts, complemented by a borehole geophysical suite including borehole radar, optical & acoustic televiewers, density, neutron, flowmeter and full wave form sonic.

The user defined criteria are established for individual project requirements and can include factors such as the intersection of structures, the presence of water ingress, proximity to structures with specific orientations and the presence of lithological units prone to failure.

The requirements of the integration environment vary; certain criteria can be adequately assessed in a 2D environment while other hazard indexes require data to exist in a true topological 3D environment where spatial queries can be performed.

The applications of a borehole hazard index include shaft site evaluations, and shaft sinking development planning. Additionally a hazard index can serve as a mine production tool, evaluating hazards in front of the face which will affect both safety and production rates. Successful deployment requires regular and timely update of the local structural model which can be achieved by automating the hazard index generation once the starting model has been defined.

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References

Bonham-Carter, G.F. 1994, Geographic Information Systems for Geoscientists: Modelling with GIS: Pergamon Press, Oxford.
Du Pisani, P. and Vogt, D., 2004, Borehole radar delineation of the Ventersdorp contact reef in three dimensions : Exploration Geophysics 35, 319-323.
McGaughey, J., 2006, The Common Earth Model: A Revolution in Mineral Exploration Data Integration: GIS Applications in the Earth Sciences: Geological Association of Canada Special Publication 44, 567-576.
McGaughey, J., McLeod, R., and Pears, G., 2007, Integrated Real-Time, 3D GIS-based Geotechnical Hazard Assessment: 1st Canada-U.S. Rock Mechanics Symposium, Vancouver, 27-31.
Peacock, D.C.P., 2006, Predicting variability in joint frequencies from boreholes: Journal of Structural Geology 28, 353-361.
Pretorius, C.C., Muller, M.R., Larroque, M., and Wilkins, C., 2003. A Review of 16 years of Hardrock Seismics on the Kaapvaal Craton, in Eaton,D.W.,Milkereit,B.,Salisbury, M.H.,Eds, Hardrock seismic exploration, Geophysical Developments No.10, Society of Exploration Geophysicists.
Sassa, K., 2006, International Society for Rock Mechanics, Commision on application of Geophysics to Rock Engineering, Suggested methods for Borehole Geophysics in Rock Engineering, International Journal of Rock Mechanics and Mining Sciences 43, 337-368.
Turner, G., Mason, I., Hargreaves, J., and Wellington, A., 2001, Detailed orebody mapping using borehole radar, Exploration Geophysics 32, 56-63.

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Article Type: Research Article

Keyword(s): Borehole Geophysics; Bushveld; Hazard Index; Risk

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