KR20220091026A - Concrete dam - Google Patents

Abstract

The present invention mixes water and cement with the existing hard fill material constituting the dam body to form protective/waterproof concrete and protective concrete, so that the dam body, protective/waterproof concrete, and protective concrete are simultaneously constructed, expanding material sources, improving workability, and construction It relates to a concrete dam that forms protective and waterproof concrete and protective concrete by mixing cement grout with hard-fill material that can shorten the period and improve surface strength.
One preferred embodiment of the present invention is a dam body consisting of a trapezoidal cross section made of a hard fill material that is a mixed material mixed with cement and water in the bed material; a dam floor formed in a predetermined thickness on the upper surface of the dam body; a protective/water-repellent concrete formed to a certain thickness on the upstream surface of the dam body; Protective concrete formed to a predetermined thickness on the top and downstream surfaces of the dam body; It consists of sub-mixed concrete constructed to a certain thickness at the joint between the dam body and the base ground, and the protective/waterproof concrete and protective concrete are formed by mixing 200 kg of cement per m3 of hard fill material at a water-cement ratio of 65%. It is made by mixing cement grout solution with filling material.

Description

Concrete dam that mixes hard-fill material with cement grout to form protective and waterproof concrete and protective concrete {Concrete dam}

The present invention relates to a concrete dam that forms protective/waterproof concrete and protective concrete by mixing cement grout liquid with hardfill material, and more specifically, protective/waterproofing concrete by mixing water and cement with an existing hardfill material constituting the dam body. Cement grout solution is mixed with hard-fill material to expand the material source, improve workability, shorten construction period, and improve surface strength by simultaneously constructing the dam body, protective/waterproof concrete, and protective concrete by forming protective concrete It is related to the concrete dam that forms the protective and water-repellent concrete and protective concrete.

As shown in FIG. 1, the structure of the existing hard fill dam consists of a sieve by hard fill, protective concrete on the dam floor and downstream surface, protective/watering concrete on the upstream surface, sub-mix hard fill on the floor, gallery and order It consists of grouting (Curtain Grouting), etc.

The concept of hard-fill dams has emerged as it is difficult to obtain dam materials, and the constructability is gradually disadvantageous. In the current dam design standards ('19, Ministry of Environment), the material for protection and water blocking of the upper and downstream surfaces of the dam is concrete. As a result, there is a need for improvement in order to apply the concept of hard fill dam and expand material sources.

As the background technology of the present invention, there is Patent Registration No. 0750386 "Dam Concrete Casting Method" (Patent Document 1). In the background art, 'a formwork is formed so that the width becomes narrower from the bottom of the river to the upper side, and after pouring concrete inside the formwork, a water-repellent material is embedded in the upper surface of the poured concrete to cure the concrete and the foundation forming concrete; Forming a formwork so that the width becomes narrower from the upper surface of the cured base concrete to the upper side, pouring concrete inside the formwork, and then embedding a water repellent material in the upper surface of the poured concrete to cure the concrete repeatedly forming a plurality of central concrete on the upper side of the base concrete; In a dam concrete pouring method comprising the steps of forming a form so that the width becomes narrower from the upper surface of the cured central concrete to the upper side, pouring concrete inside the form, and curing the concrete to form upper concrete , a step of forming a coupling groove for forming a “U”-shaped coupling groove for each concrete in which the inner side of the formwork is masonry laminated in the step before pouring the concrete of each step, and the coupling groove of the upper surface of the concrete cultivated in each step We propose a 'dam concrete pouring method, characterized in that it further comprises a coupling protrusion forming step of forming a coupling protrusion on the inside of the upper concrete formwork for fitting.

However, the background technology also did not prepare a plan to utilize locally generated aggregates such as river bed sandstone and blast rock of the dam body, and it was difficult to reduce the heat of hydration during hardening due to the large amount of cement used, and it was difficult to reduce the construction cost and shorten the period.

Patent registration No. 0750386 "Dam concrete pouring method"

The present invention is to solve the above problems, and it is possible to construct a dam body, protective/waterproof concrete, and protective concrete at the same time, while expanding the material source, improving the workability, shortening the construction period, and improving the surface strength. An object of the present invention is to provide a concrete dam that forms protective and waterproof concrete and protective concrete by mixing cement grout liquid with materials.

The present invention is a dam body consisting of a trapezoidal cross section made of a hard fill material that is a mixed material mixed with cement and water in the bed material; a dam floor formed in a predetermined thickness on the upper surface of the dam body; a protective/water-repellent concrete formed to a certain thickness on the upstream surface of the dam body; Protective concrete formed to a predetermined thickness on the top and downstream surfaces of the dam body; It consists of sub-mixed concrete that is installed at a certain thickness at the joint between the dam body and the base ground, and is formed by mixing 200 kg of cement per m3 of hard fill material with a water-cement ratio of 65% and constructing at the same time as the dam body. An object of the present invention is to provide a concrete dam that forms protective/waterproof concrete and protective concrete by mixing cement grout solution with hard fill material, characterized in that.

In addition, it is an object of the present invention to provide a concrete dam that forms protective/waterproof concrete and protective concrete by mixing cement grout solution with hard-fill material, which is characterized in that the protective concrete is poured in a vertical stepwise manner.

In addition, it is an object of the present invention to provide a concrete dam that forms protective and waterproof concrete and protective concrete by mixing cement grout solution with hard fill material, which is characterized in that the protective and waterproofing concrete is poured in a vertical stepwise manner.

In addition, an object of the present invention is to provide a concrete dam that forms protective/waterproof concrete and protective concrete by mixing cement grout solution with hard fill material, characterized in that a wire mesh is formed inside the dam floor.

In addition, it is an object of the present invention to provide a concrete dam that forms protective/water-repellent concrete and protective concrete by mixing cement grout solution with hard-fill material, characterized in that a wire mesh is formed inside the sub-mixed concrete.

The present invention mixes water and cement with the existing hard fill material constituting the dam body to construct the dam body, the protective/waterproof concrete, and the protective concrete at the same time, thereby expanding the material source, improving the workability, shortening the construction period, and improving the surface strength, The dam body made of hard-fill material and the external protective concrete are simultaneously poured and the closet compacted to increase the order and reinforcement effect, so the workability is excellent. The weir can reduce the scouring pressure at the lower part of the dam compared to the slope, thereby increasing safety. It is economical as it can be expected to reduce the construction cost by about 20%. Conventionally, protective concrete construction should be carried out through separate formwork and concrete pouring after completion of the hard fill dam. It can be completed in 33 days, reducing the construction period by 27%, reducing carbon generated during concrete production, and minimizing damage to nature by using on-site materials, which is an eco-friendly and very useful effect.

The following drawings attached to this specification illustrate preferred embodiments of the present invention, and serve to further understand the technical spirit of the present invention together with the detailed description of the present invention, so the present invention is limited to the matters described in the accompanying drawings It should not be construed as being limited.
1 is a conceptual diagram of a conventional hard fill dam.
Figure 2 is a cross-sectional view of the concrete dam of the present invention.

Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the presented embodiments are illustrative for a clear understanding of the present invention, and the present invention is not limited thereto.

Hereinafter, the technical configuration of the present invention will be described in detail according to a preferred embodiment.

Figure 2 is a cross-sectional view of the concrete dam of the present invention.

As shown in FIG. 2, the concrete dam of the present invention has a dam body 10 having a trapezoidal cross section, a dam floor 10a formed to a predetermined thickness on the upper surface of the dam body 10, and an upstream surface of the dam body 10. Constructed with a certain thickness at the junction between the protective/waterproof concrete 20 formed to a certain thickness, the protective concrete 30 formed to a certain thickness on the top and downstream surfaces of the dam body 10, and the dam body 10 and the base ground It is made of a sub-mixed concrete (40).

The dam body 10 having a trapezoidal cross-section has a large volume compared to a conventional gravity-type concrete dam having a right-angled triangular cross-section, but has high stability against conduction and activity, and has a small amount of stress generated inside the dam body 10 .

For the dam body 10, locally generated bedrock materials such as bedrock sandstone and blast rock are used. By using aggregates with a maximum size of 150mm or less through minimum classification without separate particle size selection, air through grain size selection of aggregates at the site Delay can be prevented and the utilization of the fill material source can be maximized because it is used without sorting.

The dam body 10 is formed by repeatedly mixing aggregates with cement and water and then stacking and hardening the mixed materials by compaction using a machine such as a vibrating roller.

In the present invention, the protective/water-reinforced concrete 20 and the protective concrete 30 are poured simultaneously with the dam body 10 and compacted to increase the water-reinforcement and reinforcing effects while providing excellent workability.

The protective/waterproof concrete 20 is installed on the inclined surface of the upstream side of the dam body 10 for the purpose of securing watertightness and durability against water, etc., and the protective concrete 30 is the dam body 10 for the purpose of securing durability. It is to be formed on the ceiling and the downstream slope, and the sub-mixed concrete 40 with a large amount of unit cement is formed at the junction between the dam body 10 and the base ground to ensure durability.

In the formation of the protective/waterproof concrete 20 and the protective concrete 30, the protective/waterproof concrete 20 and the protective concrete 30 are mixed with 200 kg of cement per m3 of hard fill material at a water-cement ratio of 65% to form a dam body. By constructing at the same time as (10), it is possible to secure aggregates and manufacture construction materials with relatively simple equipment, and rapid construction is possible, thereby reducing construction costs and reducing environmental load.

In particular, the protective concrete 30 makes the inclined surface to be formed into a stair-shaped slope so that the stair-shaped slope is used as a stair-type spillway. 30) so that energy can be very effectively dissipated during overflow, and the scouring pressure of the lower end of the dam body 10 can be reduced.

In order to reduce the scouring pressure, etc., the inclined surface of the outer surface of the protective/water-reducing concrete 20 may also be formed as a step-like slope.

The dam floor (10a) is formed of concrete of a certain thickness at the upper end of the dam body (10), so that overflow into the protective concrete (30) from the upstream side is possible.

Such a dam floor (10a) may be formed in various shapes covering the upper end of the dam body (10), and a pre-fabricated PC member may be used. It can also be formed by casting on site using the material.

The wire mesh 80 is configured inside the dam floor 10a to reinforce the tensile strength of concrete, which is relatively weak to the dam floor 10a where overflow occurs, to have a more economical and stable structure.

In addition, by configuring the wire mesh 80 in the interior of the sub-mixed concrete 40, it is possible to prevent cracks and increase the tensile strength.

<Experimental Example 1>

Compressive strength test according to cement mixing ratio

mixing ratio division Experimental Example 1 Experimental Example 2 Experimental Example 3
combination water-cement ratio 65% 65% 65% cement 293 kg/m ³ 200 kg/m ³ 150kg/m ³ promise manpower manpower manpower installation 50cm 50cm 50cm Uniaxial compressive strength (28 days) 11.3Mpa 7.1Mpa 5.8Mpa

As shown in Table 1, the 28-day compressive strength was tested by varying the amount of cement per m3 of hard fill material.

The water-cement ratio was fixed at 65%, and all experimental examples were installed with manpower compaction and a thickness of 50 cm.

As a result of the experiment, in the case of the mixing ratio of 293 kg of cement per m3 of hard filling material in Experimental Example 1, the compressive strength was the highest at 11.3Mpa, but economic feasibility was lowered due to the large amount of cement used. showed a low compressive strength of 5.8Mpa, and in Experimental Example 2, the mixing ratio of 200kg cement per m3 of hard fill material was 7.1Mpa, which satisfies both compressive strength and economic feasibility.

As described above, the present invention mixes water and cement with the existing hard fill material constituting the dam body to construct the dam body, the protective/water-repellent concrete, and the protective concrete at the same time, thereby expanding the material source, improving the workability, shortening the construction period, and improving the surface strength. It is possible to simultaneously pour the dam body made of hard-fill material and the external protective concrete and compact the closet to increase the order and reinforcement effect, so the workability is excellent. The downstream part is a Stepped Weir, which can reduce the scouring pressure at the lower part of the dam compared to the slope, thereby increasing safety. It is economical because it can reduce the construction cost by about 20% compared to concrete. In the past, after completing the internal hardfill dam, protective concrete construction should be carried out through separate formwork and concrete pouring, but the conventional 45 By reducing work by 12 days and completing it in 33 days, it is possible to achieve a 27% reduction in construction period, and it is possible to reduce carbon generated during concrete production and minimize damage to nature by using on-site materials, which is an eco-friendly and very useful effect. there is

So far, the present invention has been described in detail with reference to the presented embodiments, but those skilled in the art can make various modifications and modified inventions without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The present invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

10: dam body
10a : Dam floor
20: protection and waterproofing concrete
30: protective concrete
40: submixed concrete
80: wire mesh

Claims (5)

A dam body (10) made of a trapezoidal cross section made of a hard fill material that is a mixed material mixed with cement and water in the bed material;
a dam floor 10a formed on the upper surface of the dam body 10 to a predetermined thickness;
A protective/water-repellent concrete 20 formed to a predetermined thickness on the upstream surface of the dam body 10;
a protective concrete 30 formed to a predetermined thickness on the top and downstream surfaces of the dam body 10;
It consists of a sub-mixed concrete (40) constructed to a certain thickness at the junction of the dam body (10) and the base ground;
The protective/waterproof concrete 20 and the protective concrete 30 are formed by mixing 200 kg of cement per m3 of hard fill material at a water-cement ratio of 65% and simultaneously constructing the dam body 10 to form cement grout. A concrete dam that mixes liquid to form protective/waterproof concrete and protective concrete. The method according to claim 1,
Protective concrete 30 is a concrete dam that forms protective / waterproofing concrete and protective concrete by mixing cement grout solution with hard fill material, characterized in that it is poured in a vertical stepwise manner. 3. The method according to claim 2,
Concrete dam that forms protective and waterproof concrete 20 by mixing cement grout solution with hard fill material, characterized in that it is poured in a vertical stepwise fashion. The method according to claim 1,
A concrete dam that forms protective/waterproof concrete and protective concrete by mixing cement grout solution with hard-fill material, characterized in that a wire mesh 80 is formed inside the dam floor 10a. The method according to claim 1,
Concrete dam forming protection/waterproofing concrete and protection concrete by mixing cement grout solution with hardfill material, characterized in that the wire mesh 80 is configured inside the submixed concrete 40.

Images