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A characteristic feature of the "solid" rock is that it has an inhomogeneous structure and is divided up Into separate structural elements of various orders in which the rocks differ tndenslty, strength, and deformability.Inhomogeneity in rocks is due to various geological-tectonic causes, including stratification, folding, large fractures with zones of influence, and regions of increased jointlng. These factors give rise to the primary lnhomogeneity; near exposures this Is supplemented by zones of lithification (compaction and cementation), weathering, load relief, and deconsolidation. The thickness of the zones of deconsolidation varies from the first few meters near mine workings to several tens of hundreds of meters in the sides of quarry slopes and bases. The rocks in these zones have increased Dinting, marked water permeability, low strength, and low modulus of elasticity.The inhomogeneity of the mechanical properties of the rock causes a complex stress distribution in It. In the solid rock there are centers of concentration and regions of low stress; their distribution is governed by the stiffness of the neighboring blocks. Ifinsucha rock, acted on, say, by a uniform compressive load, we distinguish some region, then the stress distrtbutiono, along the middle cross sectionAB will be as shown in Fig. 1. The structural blocks with higher deformation and strength characteristics are subjected to higher loads and are centers of stress concentration; conversely, the blocks with lower characteristics are partly relieved of load. An important part is played by the shape, size, orientation, and position of each block.In research on the state of stress of the solid rock, the need to take account of the inhomogenetty isgoverned by the relative sizes of the test region and the elements of the tnhomogeneity. Thus the inhomogeneity due to the crystalline structure, the granular structure, and fine stratification and fissuring will not much influence the general laws of distribution of stresses near the exposed rock. In this case the rock mass can be regarded as quasthomogeneous, and the stress distribution in it can be regarded as uniform.A marked influence on the stress distribution in the solid rock can be exerted by lnhomogenelty due to interbedding of rocks of different compositions, to the presence of horizons with different structures, zones of deconsolililliilillllil ~I I ~,.~,.#,~71 i~/ll.?J'g~!. ,I',, 11 ' I e, e,.~e, II i l~i"tPl t i f ~ y r i Fig. 1. Distribution of vertical stresses in inhomogeneous rock. The E i are the moduli of deformation of the rocks in the separate structural blocks.dation, tectonic faults and fissures, and to large inclusions of rocks with different properties.Inhomogeneity of the solid rock can be of two types [1,2,8]i it may be randomly distributed, or regularly varying. The former is due to random variations of the conditions of formation on the rock; the latter is due to regular spatial variation in these conditions. The state of stress wilt correspondingly depend on the spa...
A characteristic feature of the "solid" rock is that it has an inhomogeneous structure and is divided up Into separate structural elements of various orders in which the rocks differ tndenslty, strength, and deformability.Inhomogeneity in rocks is due to various geological-tectonic causes, including stratification, folding, large fractures with zones of influence, and regions of increased jointlng. These factors give rise to the primary lnhomogeneity; near exposures this Is supplemented by zones of lithification (compaction and cementation), weathering, load relief, and deconsolidation. The thickness of the zones of deconsolidation varies from the first few meters near mine workings to several tens of hundreds of meters in the sides of quarry slopes and bases. The rocks in these zones have increased Dinting, marked water permeability, low strength, and low modulus of elasticity.The inhomogeneity of the mechanical properties of the rock causes a complex stress distribution in It. In the solid rock there are centers of concentration and regions of low stress; their distribution is governed by the stiffness of the neighboring blocks. Ifinsucha rock, acted on, say, by a uniform compressive load, we distinguish some region, then the stress distrtbutiono, along the middle cross sectionAB will be as shown in Fig. 1. The structural blocks with higher deformation and strength characteristics are subjected to higher loads and are centers of stress concentration; conversely, the blocks with lower characteristics are partly relieved of load. An important part is played by the shape, size, orientation, and position of each block.In research on the state of stress of the solid rock, the need to take account of the inhomogenetty isgoverned by the relative sizes of the test region and the elements of the tnhomogeneity. Thus the inhomogeneity due to the crystalline structure, the granular structure, and fine stratification and fissuring will not much influence the general laws of distribution of stresses near the exposed rock. In this case the rock mass can be regarded as quasthomogeneous, and the stress distribution in it can be regarded as uniform.A marked influence on the stress distribution in the solid rock can be exerted by lnhomogenelty due to interbedding of rocks of different compositions, to the presence of horizons with different structures, zones of deconsolililliilillllil ~I I ~,.~,.#,~71 i~/ll.?J'g~!. ,I',, 11 ' I e, e,.~e, II i l~i"tPl t i f ~ y r i Fig. 1. Distribution of vertical stresses in inhomogeneous rock. The E i are the moduli of deformation of the rocks in the separate structural blocks.dation, tectonic faults and fissures, and to large inclusions of rocks with different properties.Inhomogeneity of the solid rock can be of two types [1,2,8]i it may be randomly distributed, or regularly varying. The former is due to random variations of the conditions of formation on the rock; the latter is due to regular spatial variation in these conditions. The state of stress wilt correspondingly depend on the spa...
No abstract
To increase the overhaul time of the turbine bearings at the Kremenchug hydrostation the following measures were taken:i. The rotors of the units were balanced by placing weights of 450-800 kg on the rotor rim. Balancing was carried out by the method and under the supervision of workers of the I. I. Polzynov Central Boiler and Turbine Research and Development Institute with consideration ofmechanical, electrical, and hydraulic imbalance.2. The ellipticity of the turbine bearings was determined and eliminated. Ellipticity was determined by measuring the gaps between the rubberized bushings and turbine shaft with the thrust bearing raised. The gaps were measured by a special gauge witha vernier. Three measurements at the trailing and leading edges and in the center (a, b, c) were taken opposite each segment.The measurement results are given in Table i. A further determination of ellipticity was carried out by the graphic method with the use of the data of column 6 of Table i. With the use of an arbitrary circle at a scale of 10:1 (or any other scale) the values of the deviations from the circle are plotted with the use of the data in column 6 of Table i. A circle is inscribed in the figure obtained and the final values of the deviation from a circle (ellipticity) of individual segments of the bearings in millimeters are determined.Individual shims are installed under segments having deviations from a circle of more than 0.3 mm to eliminate ellipticity. In addition to this, shims of the same thickness are installed under all segments (including under the segments with individual shims) in accordance with the data of "rocking" or play of the shaft before repair. Turbine bearings with elimination of ellipticity last the overhaul period with allowable values of play of the shaft.The accomplishment of the indicatedmeasures considerably increased the operational reliability of the bearings of the units of the Kremenchug hydrostation.The concrete dam of the Toktogul hydroelectric station, constructed in a narrow canyon of the Naryn River, is a massive structure consisting of a central and six side sections (three on each bank). The total height of the\dam is 215 m with a base width along the flow of 173 m.Thick-layered, quite strong marmorized limestones with widespread wall and bottom release joints are the foundation of the dam. A front grout curtain and drainage in the foundation and canyon walls are the cutoff measures.The characteristic design features of the dam are the absence of cuts into the canyon walls, the use of an additional surcharge by water, and the presence of deformation joints between sections in the shape of a fan, which made it possible to direct the main load to the foundation of the structure and to provide independent deformation of each section [i, 2].The dam was constructed by the layer-by-layer method with sectioning into concreting blocks measuring 60 x 32 m in plan and 0.5-1 m high [3]. Systematic filling of the reservoir began in August 1977. By mid-1980 the upper pool level reached the maxi...
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