Between 1996 and 1999, a high-performance Robbins TBM [235-282] excavated a 5 mile long, 23 ft 2 in wide, and approx 700' deep tunnel through the subsurface of southwestern Queens. Low penetration rates (approx 6'/hr [actual] vs. approx 9'/hr [anticipated]) resulted from changed rock mass conditions mostly attributable to high-grade metamorphism of the rocks. Over a three-year period, as-built circumferential geologic mapping (scale 1 in=10 ft) and digital imagery of the tunnel, fracture and fault analysis, structural, lithologic, and petrographic studies have shown that the rocks of the Queens Tunnel consist of orthogneiss of mesocratic, leucocratic, and mafic composition. These metaigneous rocks developed coarse-grained fabrics during Grenvillian (approx 1.0 Ga) granulite facies metamorphism, and retained their nearly anhydrous, poorly foliated character during subsequent high-grade Ordovician deformation. Lacking a penetrative foliation, the coarse granoblastic rock texture and extraordinary garnet content (up to 50 percent in some zones) together proved an impediment to efficient chip production and resulted in bimodal production of blocks and excessive fines. TBM excavation of the Queens Tunnel was also hindered by geological conditions that included unexpected lithology and rock fabric orientation, a zone of crosscutting hypabyssal rhyodacite dikes, and unanticipated extent of brittle faults. The dikes and brittle faults produced blocky ground conditions and a collapsing face condition that produced cutter damage and decreased utilization. Such fundamental textural, mineralogic, and lithologic control over hard-rock TBM penetration can be predicted by careful pre-bid geological analysis. To determine the causes of lower than anticipated TBM performance, a detailed investigation was carried out that included analysis of operational data from the TBM data logger and an extensive laboratory test program on cores retrieved from tunnel walls. Integrated laboratory testing included punch, point load, tensile strength, Cerchar abrasivity, and linear cutting tests, independent petrographic analysis and machine performance analysis. These allied investigations have provided quantification that the rock mass exhibited an unusually high degree of toughness and rock directional properties and established geological causes for decreased TBM penetration rates.
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机译:1996年至1999年间,高性能罗宾斯TBM [235-282]通过西南女王的地下挖掘了5英里的宽度,23英尺23英尺2,大约700英尺的隧道。低渗透率(约6'/ hr [实际]与大约9'/ hr [预期])由改变的岩石质量条件归因于岩石的高档变质形状。在三年期间,围绕隧道的圆周地质映射(尺寸为1英寸)和隧道的数字图像,裂缝和故障分析,结构,岩性和岩体研究表明,皇后隧道的岩石组成Orthogneiss of Erthogneiss of Erthogneiss和Mafic组合物。这些型岩石在Grenvillian(约1.0AG)颗粒状面部变质期间开发了粗粒织物,并在随后的高档耳莫妇变形期间保留其几乎无水较差的特征。缺乏渗透性叶子,粗糙的碎原岩纹理和非凡的石榴石含量(在某些区域最多50%)一起证明了有效芯片生产的障碍,导致块的双峰和过度罚款。皇后隧道的TBM挖掘也受到了地质条件的阻碍,包括意想不到的岩性和岩石织物取向,一个横切的催眠术堤坝区域,以及意外的脆性故障程度。堤坝和脆性故障产生块状的地面条件和折叠面部条件,产生切割器损坏并降低利用率。通过仔细预先出价地质分析,可以预测对硬岩TBM渗透的这种基本纹理,矿物学和岩性控制。为了确定低于预期的TBM性能的原因,进行了详细的调查,其中包括来自TBM数据记录器的运营数据分析以及从隧道墙中检索的核心的广泛实验室测试程序。集成实验室检测包括打孔,点负荷,拉伸强度,CER炭磨料和线性切削测试,独立的岩体分析和机器性能分析。这些盟军的调查提供了量化的,即岩体呈现异常高的韧性和岩石定向性能,并确定了TBM渗透率下降的地质原因。
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