The Mine Safety and Health Administration's Roof Control Division responded to a massive ground failure at an underground marble mine in northern Georgia. The ground failure occurred in a benched area that had been abandoned in the early 1990s. It involved the failure of an estimated 19 pillars, in conjunction with a massive roof fall of an undetermined extent that was at least 60 ft high. Pillars in the benched area had been mined nominally 40 x 40 feet to a height of SO feet ft, with 40-ft mining widths, although it seems likely from measurements and accounts from mining personnel that pillars were even smaller than intended. Average overburden depth was 500 ft, and the rock mass was characterized by three sets of intersecting geological discontinuities that not only defined very blocky conditions that were conducive to pillar spalling and volume loss, but they were also adversely oriented in such a way as to cut diagonally through pillars at a high angle. The recently released S-Pillar software from NIOSH was used to determine pillar safety factors in the failure area and indicated that pillars were undersized for the conditions. S-Pillar was used to assess pillar stability in active areas to evaluate the likelihood of experiencing similar collapses in the future. S-Pillar correctly identified the pillars in the bench area as having been at risk for instability, in light of their ultimate failure. A two-dimensional finite element model was used to evaluate the possible stages of failure and to assess the likelihood of continued failure in the benched area that might affect more distal mine openings. Although stone mines are generally characterized as having more forgiving conditions than those found in softer sedimentary rocks, the failure shares some characteristics with domino-style massive pillar collapses experienced in coal and trona mines. First, the minimum dimension of the benched area approached 350 ft; second, the pillars defined by benching had small width-to-height ratios (0.8), and; third, the pillar failure area was slightly greater than 4 acres. The massive pillar collapse and associated roof fall illustrate the importance of incorporating pillars that have been properly sized for depth and for the final bench height. Furthermore, the designed dimensions must be adhered to during the actual mining process. Finally, the importance of understanding the geological conditions and their effect on the rock mass is critical.
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机译:矿山安全与健康管理局的屋顶控制部门对佐治亚州北部一个地下大理石矿的大规模地面倒塌做出了回应。地面故障发生在一个在1990年代初期被遗弃的台阶地区。它涉及估计的19根支柱的故障,并伴随着至少60英尺高的不确定的大规模屋顶塌落。尽管从测量和采矿人员的估计来看,立柱甚至比预期的要小,但在台阶区域的柱子名义上已开采到40 x 40英尺,高度为SO英尺ft,采矿宽度为40 ft。平均上覆层深度为500英尺,岩体的特征是三组相交的地质不连续面,这些不连续面不仅定义了非常块状的条件,有利于柱剥落和体积损失,而且它们的定向也不利于切割对角地以大角度穿过支柱。 NIOSH最近发布的S-Pillar软件用于确定破坏区域中的支柱安全系数,并表明在这种情况下支柱尺寸过小。 S-Pillar用于评估活动区域的支柱稳定性,以评估将来发生类似坍塌的可能性。 S-Pillar鉴于其最终失败,正确地确定了工作台区域中的支柱存在不稳定的风险。使用二维有限元模型来评估可能的破坏阶段,并评估可能影响更多远端矿口的工作区域继续破坏的可能性。尽管一般说来,比软质沉积岩中所具有的条件更为宽容,但这种破坏与煤矿和天然碱中经历的多米诺骨牌式大型柱倒塌具有某些共同特征。首先,工作区的最小尺寸接近350英尺;第二,长凳划分的支柱的宽高比(0.8)小,并且第三,支柱破坏面积略大于4英亩。巨大的柱子倒塌和相关的屋顶倒塌说明了合并尺寸合适的柱子的重要性,这些柱子的尺寸适合深度和最终工作台高度。此外,在实际采矿过程中必须遵守设计尺寸。最后,了解地质条件及其对岩体的影响至关重要。
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