RU2007510C1 - Local material dam - Google Patents

Abstract

FIELD: hydraulic engineering. SUBSTANCE: dam includes screen 1, bottom prism 2, draining prism 3 located between them and connected to downstream wall with layer of water-resistant, water-permeable material 4 laid into base of bottom prism. Draining prism may be connected to downstream wall with derivation drains and should be filed by zones with two-three water-permeable soils. Transition layer may be laid between zones of drain prism filled with different soils, under drain prism and under screen. On back of dam there can be arranged weight, protective layer and slope strengthening and on crest of dam and slope - screen and strengthening. EFFECT: reduced cost of construction of dam. 2 cl, 1 dwg

Description

 The invention relates to hydraulic structures and can be used in the construction of dams from soil materials with anti-filter elements in the form of a screen.

 The purpose of the invention is to increase the efficiency of using local materials, simplifying work and reducing the cost of construction.

 The drawing shows a transverse profile of the dam.

 The dam includes a screen 1, a bottom prism 2 and a drainage prism 3 located between them, connected to a lower pool, laid at the base of the bottom prism with a layer of permeable material 4. A drainage (discharge) ditch 5 can be located along the bottom of the bottom slope, and on the top slope of the screen - loading, protective layer and fastening of the slope 6.

 The dam screen is constructed from weakly and very weakly permeable soils (clay, loam, sandy loam or peat), a mixture of these soils with coarse rocks or from non-soil materials. Under the screen of non-primed materials, an underlying layer can be scoured, and under the screen of soil materials - a transition layer.

 A drainage prism and a layer of permeable soil at the base of the lower prism of the dam are designed to completely intercept the water filtered through the dam and divert it to the downstream. With their help, the material laid in the bottom prism of the dam is protected from the effects of the filtration flow, which reduces the requirements for this material and the quality of its laying.

 For the installation of a drainage prism and a permeable layer, crushed rock, as well as gravel, pebble, or sandy soils, are used at the base of the lower prism. In this case, the drainage prism can be completely filled from one soil or zoned, from two to three different soils.

 With zoned dumping of the drainage prism, the filtration coefficient of the material laid in it should increase along the filtration flow. A transition layer 7. A transition layer 7. A transition layer can also be laid at the base of the drainage prism and layers of coarse-grained material connecting it to the lower pool, can be laid between the areas of the drainage prism that are sprinkled from different soil. The height of the latter should exceed the maximum possible water level in the downstream by at least 0.5 m.

 In the absence of water in the downstream drainage prism can be connected to the downstream discharge drains (collectors). The latter are arranged in the form of ditches or trenches filled with waterproof coarse-grained material.

 The lower prism of the dam is sprinkled from coarse, sandy or clay soils in the construction area, a natural mixture of these soils and industrial wastes (mining and metallurgical industries, thermal power plants, etc.), including from soils and industrial wastes containing water-soluble inclusion, filtering unstable, soaking, softening and collapsing in water. To protect the material laid in the lower prism from atmospheric precipitation and other destructive factors on the crest and downhill slope, the dam can be equipped with a screen and a fastener. The mowing zone of the lower prism of the dam can be dumped from clay soil.

 The economic effect of the use of the proposed dam is achieved due to the wider use of local soil and industrial waste. Such a dam can be dumped in the process of dumping with powerful mining equipment (mining excavators, railway transport, etc.).

 In addition, the use of the proposed technical solution will allow local construction organizations to use rock overburden, which was used for dumping the enclosing structures of tailings, which were developed during the opening of quarries of mining plants, instead of imported crushed stone. The use of weathering overburden in the construction of tailings dams will reduce the area of land allotments for overburden dumps. (56) Design and construction of large dams P 79. Iss. 3 Pavchich M.P. et al. Design and construction of special type soil dams. M.: Energoizdat, 1981, fig. 40, p. 85.. . 89.

 Moiseev S.N., Moiseev I.S. Stone and earthen dams. M.: Energy, 1977, p. 13, fig. 1.11.

Claims (2)

 1. A DAM OF LOCAL MATERIALS, including a screen and a bottom prism, characterized in that, in order to increase the efficiency of using local materials, simplify work and reduce the cost of construction, a drainage prism is connected between the screen and the bottom prism of the dam connected to the downstream laid in the bottom prism base with a layer of waterproof permeable material or discharge drains.  2. The dam according to claim 1, characterized in that the drainage prism is dumped zoned from two to three different types of permeable soils.

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