RU2033493C1 - Method for construction of earth-and-rockfill dam in water - Google Patents

Abstract

FIELD: hydraulic engineering. SUBSTANCE: earth is laid into dam body, first, to the deepest places in dam site up to attaining elevation under water at depth not exceeding two heights of calculated wave in water reservoir for period of dam construction. Employing the pioneer method, dam body is finally filled over length of entire dam site to height exceeding the normal maximum operating level. Then, dam is finally filled to the required height with continuous leading of ground filling successively in core, transition zone and toes of dam with lead determined by trials. EFFECT: higher efficiency. 2 dwg

Description

 The invention relates to the field of hydraulic engineering, and in particular to methods of erecting stone-and-earth shut-off dams in the conditions of existing reservoirs.

Known methods of erecting a soil structure by washing the soil into water [1, 2]
The dam of the reservoir-cooler of the Zaporizhzhya NPP at the Kakhovka reservoir was erected by pouring sand into water to a depth of 8 m.

 The Leningrad protection dam was erected by pouring sand and an embankment of moraine loam in a pioneer way into water up to 8 m deep on the principle of instant landslide (Sevenard Yu.K. Gorelik L.V. et al. Study of soil consolidation in a dam constructed by dumping loam into water // Hydrotechnical construction, 1985, N 1, S. 21-23).

The HUGH Keenlyside dam on the Columbia River was erected by pouring local soil into water to a depth of 17 m. The soil was pre-accumulated on the edge of the erected screen, then it was instantly (by the principle of instant landslide) immersed in water, which ensured the preservation of natural high density and natural boulder clay moisture [3]
The disadvantage of all the above methods of erection of stone-earthen dams is that the soil was dredged to a small depth of 8-17 m, while the increase in the turbidity of the aquatic environment was not limited. In addition, the base and body of these structures did not require the installation of impervious curtains.

 The purpose of the invention is to increase the static stability and filtration strength of the foundation and body of the dam by providing the required physical and mechanical properties.

 The goal can be achieved by the fact that during the construction of a stone-earth dam, including the preparation of soil, its delivery to the place of immersion in water, immersion in the transportation of soil in the aquatic environment to the place of installation and its laying in the body of the structure, the soil is laid in the dam body initially to the deepest places in the dam site until the mark is located below the water level at a depth not exceeding two heights of the calculated wave and the body of water for the construction period. After this, the dam body is refilled along the length of the entire alignment to a height of 0.5 m above the normal retaining level (NPU) by the pioneer method. Then the dam is completed to the required height with continuous advancement of the soil laying sequentially in the core, transition zones and thrust prisms with a lead value determined experimentally.

 Signs that distinguish the claimed technical solution are not identified in other similar technical solutions in the study of this and related areas of technology, and, therefore, ensure compliance of the claimed device with the criterion of "novelty."

 A comparative analysis of the claimed device in relation to the combination of its essential features with the prototype shows that the phased installation of soil in the body is new in the method of erecting a stone-earthen dam in the water: initially in the deepest places in the dam alignment until the mark is located below the water level at a depth not exceeding two heights of the calculated wave in the pond. After that, they fill up the length of the entire alignment to a height of 0.5 m above the NPU and then complete the erection to the required height while continuously ahead of the laying of the soil in the core, transition zones and thrust prisms.

 Thus, the claimed method of construction of a stone and earthen dam in water meets the criteria of the invention of "inventive step".

 In FIG. 1 shows a dam erected in water, a cross section; in FIG. 2 the same, longitudinal profile along the alignment.

 The proposed method of construction of a stone and earthen dam is as follows.

The construction of dam 1 begins in the deepest places in the alignment. Clay soil intended for laying in core 2 is prepared ashore in the form of clod blocks 3. Soil in clod blocks 3 is compacted to a maximum density γ _d ≅ γ _dred ≅γ _s , where γ _{d is the} maximum soil density, t / m ³ ; γ _dlimit ultimate density of soil, t / m ³ ; γ _{s the} density of soil particles at the level of solid semi-solid consistency, t / m ³ ; I _L ≅ (0-0.25), where I _{L is} the consistency indicator.

The ultimate density γ _dred and the consistency index I _L are established by pilot tests. The manufactured clod blocks 3 are loaded into inventory containers 4, and the interblock cavities are filled with sand under the influence of vibration. Sand is pre-washed from dusty and clay particles. The density in container 4 should be at the level of soil density in clod blocks 3 with deviations of ± 3-5%. The walls and bottom of the container should be dense, without cracks, so that sand does not wake up, and the soil in containers does not become loose during transportation.

 The shape and weight of clod blocks 3 is selected depending on the aggregate composition of quarry clay soil and the possibility of its tight packing in containers 4 and in the body of dam 1. The size and weight of containers 4 with laid soil are selected based on the carrying capacity of vehicles and crane equipment.

 Clay material delivered to the construction site in containers 4 is supplied to the water by a crane 5 from a previously built floating bridge 6. The surface of each core layer formed is leveled by sand filling. Simultaneously with the erection of the core 2, the transition zones 7 are being poured from the fine rock mass and persistent prisms 8 from the rock mass. Soils are laid with continuous advancement, first in the core, then transition zones and thrust prisms. Dumping of the rock mass is carried out from the floating bridge 6 through single-slope screens afloat. A small fraction of the rock mass wakes up through the openings of the screens and goes to the transition zones 7, and a large fraction along the inclined slope of the screen rolls into the persistent side prisms 8.

 The construction of core 2 should be ahead of the construction of transition zones 7, and the construction of transition zones 7 should be ahead of the construction of stubborn prisms 8. The amount of lead is determined by pilot production tests.

 The dam begins to be erected in the deepest part of the alignment. At the first stage, the dam is erected to the top mark located below the water level at a depth not exceeding two heights of the calculated wave 2h, where h is the wave height in the reservoir for the construction period, m. The core and transition zones should not be destroyed by the waves.

 In the second stage, the second layer of the dam is erected in a more efficient pioneering way, with a height of (2h + 0.5 m), i.e. 0.5 m higher than the NPU to reduce the likelihood of eroded wave effects on the core and transition zones.

 At the third, final stage, a part of the dam is erected above the wave run in height from (2h + 0.5 m) to the design elevation of the ridge.

 After the filling of the dam 1 at the base in the alignment of the clay core 2 is completed, a cementation-proof curtain 9 is arranged, as well as one double-row curtain 10 in the body of the core 2, thus forming a continuous antifiltration front.

 The depth and extent in terms of antifiltration curtains 9 is determined by geofiltration studies.

 The application of the invention will ensure the static stability of the foundation and body of the dam by providing the required physical and mechanical properties.

Claims (1)

 METHOD FOR BUILDING A STONE-EARTH DAM IN WATER mainly for fencing part of the reservoir water area, including harvesting soil, delivering it to the place of immersion in water, immersing and transporting soil in an aqueous medium to the place of laying and laying it in the body of the structure, characterized in that the soil is laid the dam’s body is initially produced in the deepest places in the dam alignment until it reaches a mark located below the water level at a depth not exceeding two heights of the calculated wave in the reservoir for the period then, in a pioneering way, the dam body is refilled along the entire length of the gauge to a height exceeding the normal retaining level by 0.5 m, and then the dam is completed to the design height, while the dam body is erected with continuous advancing of the soil laying sequentially in the core , transition zones and thrust prisms.

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