SU1698355A1 - Method of erecting ground weirs - Google Patents

Abstract

The invention relates to hydraulic construction and can be applied in the construction of dams in areas with harsh climatic conditions. The purpose of the invention is to simplify the production of works, save money and increase the reliability of the dam. Core 1, filters 2. 3, 4 and 5 and side prisms b and 7 are raised to the level of ridge 8 of core 1 located below the maximum water level in front of the dam by known methods. Comb 8 is covered with a protective layer 9 of non-fossil granular soil with a particulate / u content of less than 50% in diameter less than 2 mm. After that, the soil is compacted by the protective layer 9 by vibrating it to the full depth before the separation of the protective layer 9 to the ground with a high content of small particles in the lower part 10 of the protective layer 9 and to the soil with a reduced content of small particles in its upper part 11, located directly at the surface of the deep dam 12. 3 Cp. f-ly, 1 ill. with

Description

The invention relates to hydraulic engineering and can be used in the construction of dams in areas with severe climatic conditions.

The purpose of the invention is to simplify work, save money and improve the reliability of the dam.

The drawing shows the upper part of the soil dam in the process of completing the construction, cross section.

The construction of a soil dam is as follows.

Known methods are used to construct core 1, filters 2 and 3 on the top side of the core, filters 4 and 5 on the bottom side of the core and top 6 and bottom 7 side prisms from the stone outline to the level of ridge 8 of core 1, located below the maximum (forced) level and close to a normally retained upstream level. At the final stage of construction, the dam is brought up to the design height by coating the core 1 with a protective layer 9 of non-porous, non-grained soil with a particle content of less than 2 mm in diameter not more than 50%. Then, the soil of the protective layer 9 is compacted by vibrating it to its full depth until the soil of the protective layer 9 is divided into soil with a high content of fine particles in the lower part 10 of the protective layer 9 and on the soil with a low content of small particles in its upper part 11 located directly near the surface dam crest 12.

Different-grained soil with a reduced content of fine particles in a dehydrated state is easily developed in the winter, and when laying it in a protective layer and vibrating it completely restores the flowability property.

The sealing of the protective layer 9 by vibration is carried out, for example, by immersion of a spatial package of four vibration rods 13 of the base machine 14 with the rearrangement of the vibration rods 13 in the pope. river direction of the dam from the central part of the crest of the dam 12 towards the side prisms of the dam. As a result of such vibration, small particles are moved (sprinkled) inside the protective layer 9 from top to bottom and partially from the periphery to the center. • The peripheral part 15 of the protective layer 9, located beyond the limits of the ridge 8 of the core 1, does not vibrate.

If necessary, the vibration is repeated in the summer after saturation of the lower part of the protective layer with water of the upper pool, and also with the addition of fine-grained soil to the lower part of the protective layer, for example, through a cavity in the vibrating rod.

Soil dam, erected by the proposed method, works as follows.

In winter, when the water level in front of the dam is below the normal retaining level and crest 8 of core 1, the entire pressure from the water of the upper pool is taken by core 1. Moreover, the upper part 11 of the protective layer 9 practically does not contain small particles, has a high porosity and therefore has improved thermal insulation properties, which allows to reduce the thickness of the protective layer 9, and therefore, in some cases, to lower the mark of the crest of the dam 12. Moreover, this part of the protective layer is never saturated with capillary water, which increases m dam slope stability.

In the summer, when the water level in front of the dam can rise to the maximum retaining level, the lower part 10 of the protective layer 9, enriched with small particles of soil, temporarily works as an anti-filter element, while in this part of the protective layer 9, heat accumulates from the filtering water.

The effectiveness of the method is significantly increased, especially in terms of thermal insulation, the crest 8 of the core 1 and increase the stability of the slopes of the dam in the case of the execution of the protective layer 9 from a slag-ash mixture having high thermal insulation properties and low bulk weight of about 1.4 t / m ³ .

Using the invention allows to save money by increasing the efficiency of the protective layer of the dam crest and to increase the stability of the dam by reducing the weight of the protective layer.

Claims (4)

Claim 1. A method of erecting a soil dam, including the implementation of side prisms from incoherent soil and an anti-filter element from a cohesive soil with a crest mark below the maximum water level of the upper discharge, subsequent coating of the anti-filter element crest with a protective layer of non-porous granular material with a thickness greater than the freezing depth, and limited water permeability in its lower part, with the fact that, in order to simplify, carry out work, save money and increase the reliability of the dam, the protective layer is erected from a different-grained material with a particle content of less than 2 mm in diameter of not more than 50%, and the sealing of the protective layer is carried out by vibrating to its full depth until the protective layer material is divided into material with a high content of small particles in the lower part of the protective layer and material with a reduced content of fine particles in its upper part. 2. The method according to claim 1, characterized in that the vibration is carried out starting from the central part of the crest of the anti-filtration element towards the side prisms. 3. The method of pop. 1, characterized in that the vibration is repeated in the summer after saturation of the lower part of the protective layer with water of the upper pool. 4, the method of pop. 1, characterized in that the protective layer is made of a slag mixture.