A ground reaction curve based upon block theory |
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Authors: | Jesse L Yow Jr Richard E Goodman |
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Affiliation: | (1) Lawrence Livermore National Laboratory, 94720 Berkeley, CA, U.S.A.;(2) University of California, 94720 Berkeley, CA, U.S.A. |
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Abstract: | Summary Discontinuities in a rock mass can intersect an excavation surface to form discrete blocks (keyblocks) which can be unstable. Once a potentially unstable block is identified, initial normal and shear stresses on each block face are calculated using elastic theory, and are then modified by discontinuity deformations as the keyblock displaces. The modified stresses are summed into resultant forces to evaluate block stability. Since the resultant forces change with displacement, successive increments of block movement are examined to see whether the block ultimately becomes stable or fails. Calculated keyblock stability increases with larger in situ stress magnitudes, larger lateral stress ratios, and larger shear strengths. Discontinuity stiffness controls block displacement more strongly than it does stability itself. Large keyblocks are less stable than small ones, and stability increases as blocks become more slender. |
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