SU1618823A1 - Dam - Google Patents

Abstract

The invention relates to hydraulic construction and can be used in the construction of dams in harsh climatic conditions. The purpose of the invention is to increase the reliability of the dam and reduce the cost of its construction. The dam includes a soil filtering element in the form of core 1, filters 2 and 3 on the upper side of the core, filters 4 and 5 on the lower side of the core, upper b and lower 7 side prisms from a rough outline. The top of the core is equipped with a non-pile soil head 8. The required temperature conditions of the upper part of the impervious element are carried out with the help of a heating device. The device for heating is made in the form of an electrically conductive layer of bulk material 9 with electrodes 1.1 placed in it, which are connected by tokovods to a source of electric current. The electrically conductive layer is located between the core and the tip. It can also be located within a part of the core and bottom filter. The conductive layer may be in the form of a mixture of coarse-grain electrically conductive material with fine earth or in the form of an electrically conductive film or fabric. The surface of the lower prism of the dam is provided with a heat insulating layer of 12. 4 Cp f-ly, 3 ill. 11 V 9c, / / / / 4 SP C T 12 00 00 th CJ Shig.1

Description

The invention relates to hydraulic construction and can be used in the construction of dams from soil materials in areas with harsh climatic conditions.

The purpose of the invention is to increase the reliability of the dam and reduce the cost of its construction.

Fig. 1 shows a dam with a cap of non-abrasive soil and an electrically conductive layer of bulk material, a transverse section; in fig. 2 and 3 are the same, with an electrically conductive layer, respectively, of a mixture and of an electrically conductive film.

The dam includes a soil filter element 1 in the form of core 1, filters 2 and 3 on the upper side of the core, filters 4 and 5 on the lower side of the core, upper 6 and lower 7 side prisms from a rough outline, tip of non-foamy ground 8, electrically conductive layer in the form of an electrically conductive bulk material 9 (FIGS. 1 and 2) or in the form of an electrically conductive film 10 (FIG. 3) and electrodes 11 arranged in an electrically conductive layer and connected by current leads to an electric current source (the current leads and source are not shown). The electrically conductive layer is located in the upper part of the dam, adjacent to the impervious element 1 or within it and together with the electrodes, tokovodami and a source of electric current forms a device for heating the impervious element.

When the electrically conductive bulk material 9 is positioned outside the impervious element 1 (Fig. 1), its grain composition is made the same as for earth-bonding soils with a non-bulkhead cap 8 or filter 4. When the electrically conductive bulk material 9 is located within the core 1 (Fig. 2), it should contain grains larger than 0.5 cm in size and less than 65% by volume, which, when evenly distributed in the layer, ensures the waterproofness of the material. In this case, the bulk material 9 is a mixture of coarse-grained electrically conductive material (electrically conductive composition) and fine-grained soil and is located at the crest of the DraCh or in the inner part of the core 1 (in FIG. 2, layer 9 is shown dotted).

As a bulk electrically conductive material, for example, metallurgical ferrous slag, substandard electrographite and coal, as well as granulated claydite with a metallized surface and other conductive materials are used.

The electrically conductive layer can also be made of. electrically conductive

film or fabric (Fig. 3).

Bottom prism of the dam is provided with a heat insulating layer 12.

The dam works as follows. During the dam operation period, almost all of the water pressure with level 13 on the upstream side is perceived by core 1. With the onset of the cold season, devices for heating the core 1 are turned on.

5 through the electrically conductive bulk layer 9 (Figs. 1 and 2) or through the electrically conductive film 10 (Fig. 3), they are heated, resulting in the heating of the upper part of the core 1 along with the filter

0 along water, which, on the lower edge of the core, protects it from freezing from the downstream and provides a natural filtration mode in the dam. The presence on the surface of the bottom

The 5 prisms of the heat insulating layer 12 contribute to the preservation of heat in the downstream prism.

The presence in the layer 9 of coarse-grained electrically conductive grains that make up the layer for a few years increases the electrical conductivity of the mixture constituting layer 9, since the current passes predominantly along these electrically conductive grains. At the same time, the deformative-strength characteristics of the material of the upper part of the core are improved.

Use as a conductive bulk material 9 metallurgical slag porous structure

0 reduces the weight of the upper part of the dam, which increases the stability of the slopes of the dam, while layer 9 exhibits high thermal insulation properties and in the absence of electric current therein. Use the same

5 for heating the core of a waterproof electrically conductive film covering the ridge core (FIG. 3) further protects the upper part of the core from being overwetted by atmospheric precipitation.

0

Temperature control of the core is carried out using remote temperature transducers. The use of the invention enhances

5 reliability of the dam by increasing the efficiency of heating the impervious element, as well as by preserving the natural filtration regime in the dam and by increasing the stability of the dam. Is also achieved

cost savings by simplifying the heating device.

Claims (5)

Claim 1. The dam, which includes a soil filtering element, side prisms, filters, non-rock bottom soil and a device for heating the upper part of the filter layer, characterized in that, in order to increase the reliability of the dam and reduce the cost of its construction, the device heating is made in the form of an electrically conductive layer in the upper part of the dam and electrodes located in an electrically conductive layer and connected by tokovods with a source of electrical current, conductive layer is directly adjacent to the anti-filter elements or hosted within it. 13 PGSHG /%: No. - hZhr / 9 M Editor S.Pekar 2 7 Fig.Z Compiled by V. Volkov Tehred M. Morgental 5 10 15 20 / 2. Dam pop 1, characterized in that the electrically conducting layer is made of a bulk electrically conducting material and is located above the impervious element within the tip and (or) from its lower face within the filter. 3. A dam according to claim 1, wherein the electrically conductive layer is made of a bulk electrically conductive material, which is a mixture of coarse-grained electrically conductive material and fine earth soil, and is located within the impervious element. 4. A dam under item 1, characterized in that the electrically conductive layer is made in the form of an electrically conductive film or fabric. 5. A dam according to claim 1, characterized in that the lateral bottom prism is covered with a heat insulating layer. ,,. 12 PGSHG / 9 MS non Proofreader M Pojo