Summary
In an effort to minimize cutter roof failures in longwall development entries of a West Virginia coal mine, a three-entry system was developed with the center entry arched into the strata above the coal seam. The purpose of the arched entry was to modify the horizontal stress envelope associated with the three-entry system and improve roof conditions in the adjacent outside entries.
Contrary to the predictions of elastic analyses, the presence of the arched entry improved roof conditions by eliminating cutter roof failures in the outside entries.In situ stress determinations and numerical modeling techniques were employed to quantify the impact of the arch and investigate the mechanism of stress relief associated with the arched entry. Stress determinations and underground observations indicated that the roofs of the outside entries were within the zone of stress relief generated by the arch, and that failure or movement along bedding plane discontinuities played a major role in the formation of the stress relieved zone. The numerical model incorporated horizontal joints to simulate bedding plane discontinuities. The properties of the joints were adjusted until roof stresses predicted by the model were in agreement with measured stress profiles. This process resulted in a calibrated analytical tool that could be used to evaluate alternate mining geometries.
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References
Aggson, J.R. (1978)In situ stress fields and associated mine roof stability, SME-AIME Mini-Symposium Series No. 78–1.
Aggson, J.R. (1979) Stress induced failures in mine roof. USBM RI 8338.
Bieniawski, Z.T. and Van Heerden, W.L. (1975) The significance ofin situ tests on large rock specimens,International Journal of Rock Mechanics, Mining Science and Geomechanics Abstracts,12, 101–113.
Crouch, S.L. (1976)Analysis of Stresses and Displacements around Underground Excavations: An Application of the Displacement Discontinuity Method, University of Minnesota Geomechanics Report.
Duvall, W.I. and Aggson, J.R. (1980) Least squares calculation of horizontal stress from measurements in vertical boreholes. USBM RI 8414.
Heuze, F.E. (1980) Scale effects in the determination of rock mass strength and deformability,Rock Mechanics,12, 167–192.
Hooker, V.E. and Bickel, D.L. (1974) Overcoring equipment and techniques used in rock stress determination. USBM Information Circular 8618.
Hooker, V.E., Aggson, J.R. and Bickel, D.L. (1974) Improvements in the three-component deformation gage and overcoring techniques, USBM RI 7894.
Kripakov, N.P. (1982) Alternatives for controlling cutter roof in coal mines,Proceedings of the 2nd Conference on Ground Control in Mining, West Virginia, pp. 142–151.
Nichols, B. (1978) Pillar extraction on the advance at Oakdale Colliery,Proceedings of the First International Symposium on Stability in Coal Mining, Vancouver, B.C., Canada, pp. 182–196.
Peng, S.S. (1978)Coal Mine Ground Control, John Wiley & Sons, Inc., New York, p. 27.
Su, W.H. and Peng, S.S. (1984) An investigation of the causes of roof falls in a deep underground coal mine, SME-AIME Preprint 84–433.
Su, W.H. and Peng, S.S. (1985) Cutter roof and its causes, presented at the SME-AIME Annual Meeting, New York, N.Y., February.
Wang, F.D., Ropchan, D.M. and Sun, M.C. (1974) Proposed technique for improving coal mine roof stability by pillar softening,SME-AIME Transactions,255, March, 59–63.
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Aggson, J.R., Mouyard, D.P. Geomechanical evaluation of a coal mine arched entry. International Journal of Mining and Geological Engineering 6, 185–193 (1988). https://doi.org/10.1007/BF00880973
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DOI: https://doi.org/10.1007/BF00880973