ArticleName |
Construction of anti-seepage curtains during jet mining |
ArticleAuthorData |
Russian State Geological Prospecting University of S. Ordzhonikidze, Moscow, Russia:
O. S. Bryukhovetskiy, Head of Center of Scientific, Technical and Environmental Evaluation of Mining and Geological Operations, Professor, Doctor of Engineering Sciences, bos.rggru@mail.ru Yu. A. Borovkov, Professor, Doctor of Engineering Sciences I. Yu. Naydenko, Associate Professor, Candidate of Engineering Sciences |
Abstract |
One of the jet technologies is hydraulic borehole mining successfully applied at the stage of lifting big process mineral samples. A common geomechanical factor for erodible minerals is their structural strength value that should be not higher than 7 MPa for the existing models of borehole jets. This article proposes the method to determine basic geomechanical parameters of thin holes made by borehole jets. Washing-out is carried out by free jets in dried excavation zone with hydraulic elevation of slurry. This creates favorable conditions for the next fill of the holes with an anti-seepage material. The geomechanical calculation is based on a rheological model. Thin holes are used in construction of seepage or anti-seepage walls, in recovery or enhancement of well production, and in soil reinforcement. The authors analyze interaction between parameters of a thin hole such as length, width and tolerance time. Aimed at the local improvement of ecological situation at Orsknefteorgsintez refiner, anti-seepage curtains 110 m long, 15–20 m high and 5–230 m deep have been created. As a consequence, fluid loss gradient has decreased more than by an order of magnitude. Based on the performed analysis, the following conclusions have been drawn: 01–0.3 wide holes have no influence on next deformation behavior and temporal stability; within the current limit of time taken by drivage, assembling-disassembling and backfilling, stability of walls in a hole, including close-spaced holes inside a depth interval studied, is guaranteed; it is possible to implement hydraulicking in two boreholes with close-spaced thin holes not wider than 0.2 m. |
References |
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