KR101185626B1 - Environmentally-friendly construction method for mountain reservoir using solidified material - Google Patents

Abstract

PURPOSE: An environmentally-friendly construction method of a mountain reservoir using a solidified material is provided to construct a high-strength dam in a short time using soil on a construction site. CONSTITUTION: An environmentally-friendly construction method of a mountain reservoir using a solidified material is as follows. The ground of a construction position is cut, and a soil cement mixture is produced by mixing soil generated when the ground is cut, cement, and a solidified material. The produced soil cement mixture is spread, and a foundation layer for an erosion control dam(23) and a foundation layer(33) for a reservoir dam are formed. Flow passages(21,31) are formed on the foundation layers. Concrete layers(24,34) are formed by placing concrete on the outer surfaces of the foundation layers. Vegetation layers(25,35) are formed by spreading culture soil having seeds on the outer surfaces of the concrete layers. A screen(22) for filtration and a water gate(32) are installed in the flow paths, respectively.

Description

ENVIRONMENTALLY-FRIENDLY CONSTRUCTION METHOD FOR MOUNTAIN RESERVOIR USING SOLIDIFIED MATERIAL}

The present invention relates to an environment-friendly disaster prevention dam mountain reservoir construction method, and more specifically, to the four-sided dam with a screen to block the earth and stone, and a small reservoir dam downstream of the water gate is installed in the mountain valley to control the amount of water It is related to the environment-friendly disaster prevention dam mountain reservoir construction method using the solidified fire to form the foundation by using the high-strength and high durability solidified fire to improve the uniaxial compressive strength and freeze-thaw action, but to make the reservoir.

Recently, the intensity of disasters is increasing due to global warming, and as a result, the floating materials such as driftwood caused by landslides are diversified, and the damage power of the downstream is also increasing. As it accounts for a large proportion of the dead, continuous disaster prevention investment is needed to reduce landslide damage.

In addition, the incidence of damage caused by forest fires is increasing every year, and the increase factors include the 5-day workweek and the increase in the population who chose mountain climbing for leisure, and the continuation of dry weather due to climate change.

When large forest fires occur in the mountains, the helicopters are spraying water from nearby reservoirs, so the amount of water in the reservoirs is drastically reduced. In particular, the recent drought caused by irregular rainfall has led to insufficient use of reservoir water as agricultural water, so it is urgent to secure new water sources.

Therefore, a method for constructing a reservoir using four sides dam has been proposed. Debris barrier refers to a dam installed in a direction intersecting the flow direction to reduce the flow rate of the mountain valley to prevent erosion, block soil, trees, etc. coming from upstream to improve the water quality.

In addition, the four-sided dam may be divided into concrete four-sided dam and all-round four-sided dam to block the storage or soil, and slit-shaped four-sided dam and screen-shaped four-sided dam to block the driftwood, while mixing the complex to pass the reservoir It is provided as a permeate or overflow type in the form of retardation of clay, rather than the use of stored water, such as blocking the soil and driftwood.

These four dams have been strengthened by installing concrete or steel structures to prevent them from being damaged by a large amount of rainwater during infiltration or flooding.However, these dams are not harmonized with the surrounding environment. have.

In addition, when looking at the construction method of the conventional four-sided dam, first cut the ground to be constructed, strengthen the ground strength by compacting the cut ground, reinforce the reinforcement on the upper surface of the compacted ground, or install the formwork by installing only the formwork The method of curing by pouring concrete inside is applied. Wherein the conventional four-sided dam has the disadvantage of increasing the amount of concrete used to increase the structural strength, low use of the soil generated by cutting. In particular, there is a disadvantage in that it is not used when the quality of the soil generated by cutting is low.

Patent Registration No. 10-0779545 Patent Registration No. 10-0785637

The present invention is to solve the problems as described above, by installing a double dam in the mountain valley to add a reservoir function can be utilized in a variety of stored water, and to make the outside of the vegetation and dam construction The purpose of this project is to provide an ecological disaster prevention dam mountain reservoir construction method using solid fire which can build a high-strength dam in a short period of time even using the site soil obtained from the city site.

The environmentally friendly disaster prevention dam mountain reservoir construction method of the present invention for solving the above problems, the construction of a four-sided dam formed with a screen to block the soil and driftwood in the river, the downstream of the four-sided dam to build a reservoir dam formed with a sluice Forming a reservoir between the reservoir dam, the upstream four-way dam and the downstream reservoir dam, the first step of cutting the ground of the construction position and producing a soil cement mixture of the cut-off soil, cement and solidified material ; The second step of constructing the four-layer dam base layer and the reservoir dam base layer by laying and compacting the soil cement mixture prepared in the first step, and forming a flow path in the four-side dam base layer and the reservoir dam base layer and ; A third step of forming concrete layers by laying concrete on the outer surfaces of the base layer for all four dams and the base layer for the water dam after the two steps; A fourth step of forming a vegetation layer by spraying a cultured soil mixture mixed with water and cultured soil containing seeds on the outer surface of the concrete layer formed through the third step; And a fifth step of installing a screen for filtration in the flow path of the four dams, and installing a water gate for fresh water and discharge in the flow path of the reservoir dam, wherein the solidified material is 5 to 40 parts by weight based on 100 parts by weight of the cement. Gypsum, 5 to 30 parts by weight of lime based on 100 parts by weight of the cement, pozzolanic material adjusted to have two or more particle sizes of 20 to 80 parts by weight to 100 parts by weight of the cement, and a surfactant, the particle size control The pozzolanic substance may comprise a first component having a particle size of 15 to 30 μm of 50 to 60 wt% with respect to the particle size controlled pozzolanic substance, and 40 to 50 wt% of 3 to 8 wt% with respect to the particle size controlled pozzolanic substance. It is composed of a second component having a particle size of μm, the surfactant forms a charging layer on the surface of the solid material, naphthalene compound, polycarboxylic acid compound, melamine compound It is characterized in that any one selected from the group consisting of water and aminosulfonic acid compound.

According to the eco-friendly disaster prevention dam mountain reservoir construction method using solidified fire according to the present invention, a four-sided dam is formed in the stream screen to block the soil and driftwood, the downstream of the four-sided dam to build a downstream reservoir dam formed with a water gate By forming a reservoir between the reservoir and the reservoir dam, when the heavy rain is predicted, the reservoir can be emptied to store rainwater during flooding, and during a drought, stable water resources can be supplied through previously stored reservoirs. It can be used as a water supply source for extinguishing wildfires during occurrence, and can be utilized as a safe water play area in summer or a sled use facility in winter.

In addition, since the vegetation is possible on the surfaces of the dams and reservoir dams to create a nature-friendly environment, it does not harm the stream ecosystem, and also can be recognized as a beneficial facility, not a harmful document, so that it can be actively distributed.

Figure 1 is a schematic diagram showing the construction of the reservoir according to the environmentally friendly disaster dam mountain reservoir reservoir construction method using the solid fire according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail with reference to the accompanying drawings. It should be understood, however, that the appended drawings illustrate only the contents and scope of technology of the present invention, and the technical scope of the present invention is not limited thereto. In addition, it will be apparent to those skilled in the art that various modifications and changes can be made within the scope of the present invention based on these examples.

1 is a schematic diagram illustrating an mountain reservoir according to an embodiment of the present invention.

As shown, the construction method of the mountain reservoir 10 according to the present invention builds the four-side dam 20 and the reservoir dam 30 at two points of the river. That is, the four sides dam 20 is relatively upstream, the reservoir dam 30 is constructed downstream.

The four-side dam 20 is formed with a flow path 21 perpendicular to the inner or middle portion of the length of the dam, and the screen 21 is installed on the flow path 21 to store the soil and driftwood contained in the stream water flowing from the upstream. To block).

Screen 22 is a porous that does not block the inflow of soil and driftwood while preventing the inflow of river water, and can apply a well-known technique of various four-way dams such as mesh networks, multiple horizontal bars or vertical bars, stone networks, and replace due to damage. It is mounted to be replaceable for the back, for example, by installing the rails in the longitudinal direction on both sides of the flow path (21) and housed in the rails 23 so as to be replaced. Of course, the screen 22 is fixed by the locking device so as not to leave the rail 23 by buoyancy.

One or more flow paths 21 and screens 22 are applied to all four dams 20.

The size of the four-side dam 20 can be variously constructed, but typically has a structure (a triangle when viewed from the side) to have a narrow cross-sectional area to the top to have a structure that has a large bearing capacity for water pressure, for example, It is preferable to form the width of about 1M and the height of about 3M to prevent oversoil and driftwood from overflowing.

In addition, the reservoir dam 30 is installed in the stream downstream (approximately 50m to 500m) spaced from the four sides dam 20 so that the reservoir 10 is formed between the four sides dam 20 upstream.

This downstream reservoir dam 30 is constructed in the form of narrowing the cross-sectional area while going to the top for the same purpose as the upstream four-way dam 20, one or more passages 31 and the water gate 32 for the control of fresh water amount is provided Freshwater flows through the four sides dam 20 to the reservoir 10 and discharges the fresh water.

The size of the reservoir dam 30 may vary depending on the terrain, but for example, the upper end is formed with a width of about 2M, and the height is set to about 5M to set the maximum reservoir amount.

The water gate 32 of the downstream reservoir dam 30 can adjust the amount of storage by opening and closing. The low amount of water can be stored in advance during heavy rains to prevent the flooding of the river due to temporary rain by temporarily storing a considerable amount of rainwater during heavy rains. In addition, the reservoir water can be used for nearby agricultural water, and can contribute to securing water resources, such as being used as fire fighting water in case of wildfires.

The upstream four-side dam 20 and the downstream reservoir dam 30 are composed of foundation layers 23 and 33, concrete layers 24 and 34, and vegetation layers 25 and 35.

The base layer (23, 33) uses the field soil obtained during the construction of the reservoir 10, the four-side dam 20 and the reservoir dam 30, and it is possible to build in a short time and to increase the strength of the site soil and solidified material Is constructed from the mixed base layer material.

Field soils are generally soils containing sand and gravel.

Soil cement mixture of the base layer material is composed of a ratio of 75 to 90% by weight of soil, 3 to 10% by weight of cement, 3 to 15% by weight of water. Wherein the mixing ratio of the cement is less than 3% by weight, the strength is low, if more than 10% by weight, the strength is high, but the amount of use of cement, etc. is increased, so that the manufacturing cost increases and of course can pollute the river, It is desirable to ensure the required bond strength while minimizing river pollution.

Cement is usually one of Portland Cement, Medium Heat Portland Cement, Crude Portland Cement, and Sulfate Resistant Portland Cement. Generally, Portland cement is most commonly used. However, in winter, when the temperature is low, such as winter (below 5 ℃), the hydration rate of the solidified material is lowered and the initial strength is low, so it is preferable to use a crude steel portland cement or to use a coagulant or crude admixture.

As an additive to the portland cement, any one selected from the group consisting of blast furnace slag powder, coal ash powder, volcanic ash, rice hull ash, diatomaceous earth, silica fume and zeolite, which are generally pozzolanic materials, is used. It is used a lot. Mixing these materials can reduce heat of hydration and improve long-term strength, but tends to lower initial strength.

The present invention has the disadvantages that the soil has a mixture of solidified fire to complement the air, strength. The solidifying material may have 5 to 40 parts by weight of gypsum, 100 parts by weight of cement, 5 to 30 parts by weight of lime, and 20 to 80 parts by weight of two or more particle sizes of 100 parts by weight of cement. The adjusted pozzolanic material and the surfactant are mixed.

Gypsum (anhydrous gypsum) is 5 to 40 parts by weight based on 100 parts by weight of Portland cement. The function of the gypsum is to reduce the cracking due to the increase of compaction of the ground and dry shrinkage, and the crack reduction is low when the mixing ratio of the gypsum is 5 parts by weight or less, and the manufacturing cost is increased by 40 parts by weight or more.

Lime uses quicklime or slaked lime and is 5-30 parts by weight relative to 100 parts by weight of Portland cement. The function of lime here is to help the dewatering and condensation of the high water content, the mixing ratio of 5 to 30 parts by weight is the most efficient and economical.

The pozzolanic material is any one selected from the group consisting of blast furnace slag powder, coal ash powder, volcanic ash, rice hull ash, diatomaceous earth, silica fume and zeolite, 20 to 80 parts by weight based on 100 parts by weight of cement. The pozzolanic material is adjusted to have at least two particle sizes, the first component having a particle size of 15 μm to 30 μm at 50 to 60% by weight relative to the particle size adjusted pozzolan material and 40 to 50 weight relative to the particle size adjusted pozolan material And a second component having a particle size of 3 μm to 8 μm in%. Pozzolanic material refers to a material of calcium silicate or calcium aluminum component which is hydrophobic and reacts with calcium hydroxide in the presence of moisture, and the pozzolanic material contains such silica-based components.

The finer the particle size of the pozzolanic material, the better the pozzolanic activity. Thus, when the pozzolanic materials are used in the pulverization, the strength and durability of the small cement are improved. However, when a large amount of fine particles of less than 10㎛ (for example, more than 60% of the total) in the powder of pozzolanic material, the aggregation phenomenon is remarkably occurred, so the required amount to obtain the same workability increases, rather condensation It takes longer and increases free water moving voids inside. Therefore, the increase in strength of the soil cement due to the fine grinding of the pozzolanic material may be canceled and the durability may be reduced. Therefore, in order to solve these problems, the pozzolanic material is composed of two or more particle size components to improve the initial strength of the solidified soil.

The pozzolan material has 20 to 80 parts by weight of the pozzolan material with respect to 100 parts by weight of portland cement, but the first component having a particle size of 15 μm to 30 μm of the pozzolan material is 3 μm to 50 to 60% by weight of the entire pozzolan material. When the second component having a thickness of 8 to 8 µm is 40 to 50% by weight, the flowability of the soil cement is increased, thereby reducing the unit quantity for obtaining the same workability, thereby improving the strength (especially the initial strength) of the soil cement. This may be due to the reduction of the median particle size of the pozzolanic material, thereby reducing the friction between the particles and increasing the filling effect.

On the other hand, 0.1 to 5 parts by weight of surfactant is added to 100 parts by weight of cement as a admixture capable of reducing the required amount (unit amount) for obtaining the same workability due to the fine powder of pozzolanic material. The surfactant is any one selected from the group consisting of naphthalene-based, polycarboxylic acid-based, melamine-based and aminosulfonic acid-based compounds.

Generally, when the micronized solid particles come into contact with water, they tend to aggregate with each other in order to reduce surface energy rather than wetting of a three-dimensional surface, thereby decreasing fluidity. However, when the surfactant is added, the surfactant is adsorbed on the particle surface of the solidifying material to form a charging layer called a diffusion electric double layer. However, the electrical repulsive force is generated between particles having similar dislocations in the charging layer, and thus the fluidity of the solidified soil mixed with the solidified component in the granules may be greatly improved. According to this principle, the use of surfactant reduces the unit quantity of the hardened soil and prevents the condensation caused by the rapid hydration in the early stage, thereby showing the initial high fluidity. In addition, the surfactant is attached to the surface of the solid particles in the early stage of hydration will also act to delay the condensation.

Accordingly, the initial fluidity is considerably improved compared to the prior art, so that it is convenient to carry out road pavement construction using a soil cement, and there is an effect of preventing the loss of workability and the occurrence of cold joint generated during the cement paving in summer. In addition, by adjusting the hydration rate according to the particle size of the fine powder of pozzolanic material by step by step to adjust the shrinkage cracking caused by the dry shrinkage, which is the weakest point in the soil cement packaging construction step by step shrinkage shrinkage significantly.

The air entrainer is mixed with 0.01 to 1 part by weight based on 100 parts by weight of cement and is a conventional organic agent entrainer. Air entraining agent ensures high fluidity of injection material and improves workability. The mixing ratio for air entraining is less than 0.01 by weight, and more than 1 increases manufacturing cost.

The solidified material according to the present invention acts as follows.

When the solidified material is mixed with the field soil, R-COOH organic acid generated by the corrosion of organic matter in the field soil or the organic material introduced from the outside is formed on the surface of the granules. R is an alkyl group. These organic acids interfere with the reaction between the fire and the particulates. However, ethrinzite, a chain-shaped acicular crystal hydrate that is produced in a large amount during the reaction of gypsum and lime, covers the surface of the organic acid, so that even if the organic acid is present, the calcium silicate hydrate does not interfere with the subsequent generation. That is, in the early stage of hydration, ethrinzide hydrate confines the granules surrounded by organic acids to make the granule units large, and then stabilizes the granules.In the mid-hydration stage, the calcareous component (CaO) and siliceous component ( As the hydration reaction of SiO ₂ ) reacts with water, the CSH (I) gel (where CSH refers to a hydrate in a gel state formed by the reaction of CaO with SiO ₂ and H ₂ O) is formed. One month later, CSH (I) gel was formed, and the hydration gap generated by Ca (OH) ₂ or active Ca (OH) ₂ in the soil reacted with amorphous SiO ₂ in pozzolanic material. II) A gel is produced. The secondary hydrate generation step is referred to as pozzolanic reaction, and the pozzolanic reaction makes the hydrated tissue more dense, so that the high strength of the soil cement is exerted, and a membrane is formed to express high durability.

As described above, in the present invention, the granules may be divided into a first stage process initially bound by ethrinzite and a two stage process of enhancing the strength by solidifying the bound granules. It is further subdivided into lime-silicate hydration reactions found in conventional soil cements and additional pozzolanic reactions of pozzolanic materials.

In addition, in the present invention, the high strength is expressed, and the water content of the soil cement is reduced by the surfactant, thereby reducing the open voids through which free water can move, thereby increasing the strength of the mixture of the soil cement and obtaining a condensation delay effect. In addition, the air entrainer sufficiently entrains a stable closed air bubble of 200 μm or less, whereby the air entrainer exhibits an effective sponge action that sufficiently absorbs the inflation pressure generated when free water in the sodium cement freezes, thereby freezing the soil cement. The durability against melt fracture is greatly improved.

Using such a material, the base layers 23 and 33 are constructed as follows.

The base layer material is laid and compacted so that flow paths 21 and 31 are formed.

The SCM mixture can be compacted by installing the formwork and installed in the interior, or installed at a predetermined thickness on the surface of the soil, and then compacting, and repeating the compaction after re-establishment, so that it can be built at a certain height. The compaction energy is added in the range of 15 to 70 kgf · cm / cm 3.

In addition, the flow paths 21 and 31 form the base layers 23 and 33 except for the portions of the flow paths 21 and 31 when the base layers 23 and 33 are formed, or the base layers 23 and 33 are constructed. A portion of the passage may be formed to form the flow paths 21 and 31.

Meanwhile, when the foundation layers 23 and 33 are formed, a plurality of grooves or protrusions may be formed on the surfaces of the foundation layers 23 and 33 to increase the binding force with the concrete layers 24 and 34.

After the foundation layers 23 and 33 are completed, concrete is laid to form concrete layers 24 and 34.

The concrete layers 24 and 34 are installed on the outer surfaces of the foundation layers 23 and 33 so that curing is performed. The laid concrete layers 24 and 34 are both side surfaces and the upper surfaces of the foundation layers 23 and 33. In addition, it can be installed on the lower surface. That is, after the installation site is made of clay, the concrete floor layer is laid and cured first, and then the foundation layers 23 and 33 are formed thereon, and on both sides and the upper surfaces of the foundation layers 23 and 33 formed. In addition, by forming the concrete layers 24 and 34, all of the outer surfaces of the base layers 23 and 33 may be covered with the concrete layers 24 and 34 to prevent the penetration of moisture.

In this way, the base layer (23, 33) using the base layer material strengthening the binding force than the existing site soil is provided to provide the necessary strength, and the outer surface of the concrete layer (24,34) of a constant thickness, for example 10-20 cm thick It is possible to provide an environmentally friendly method that provides structural strength while minimizing the amount of cement used, such as preventing the structural strength decrease by the permeated water by forming a.

In addition, a plurality of grooves or protrusions are formed on the upper surfaces of the concrete layers 24 and 34 to increase the contact area with the vegetation layers 25 and 35 stacked on the concrete layers 24 and 34 so that the vegetation layers are self-weight or It can be prevented from flowing down easily by external factors such as rainwater, so that a stable vegetation layer can be maintained until the seed germinates and approaches.

Next, the culture soil mixture in which the seed-containing culture soil and water are mixed is sprayed on the concrete layers 24 and 34 to form the vegetation layers 25 and 35.

Cultured soil mixture to form the vegetation layer (25,35) is to mix 3 ~ 5L of water per 1m ³ cultured soil. If the mixing amount of water is larger than the mixing ratio, there is a disadvantage in that the cultured soil mixture does not settle in the spraying place and flows down. If the mixing amount of water is smaller than the mixing ratio, the spraying is not performed well, and more preferably mixed within the above range. Mix 4 liters of water per ^three . In addition, the mixed culture soil mixture is to be sprayed within 5 hours after mixing, it is preferable to spray after further stirring after 5 hours.

Vegetation layers (25,35) made by spraying the cultured soil mixture is preferably formed in a thickness of 5 ~ 20cm to seed the seeds mixed in the cultured soil germinates so that the root is fixed.

Varieties of seeds included in the culture soil forming the vegetation layers (25, 35) are high-density cover, high-growing, cold-growing grass with tall fescue, perennial ryegrass and Use a non-repair, a wild native plant, as a kind or a mixture of two or more species.

The culture soil mixture may further include an anti-erosion stabilizer (synthetic adhesive) and a coating curing agent. The anti-erosion stabilizer is an adhesive that aggregates the culture soil with the soil to form a coating can be used in an appropriate amount mixed according to rainfall, slope and soil quality, the mixing is preferably made of 110 ~ 140g / m ³ . The coating curing agent is a vegetable fiber, which aggregates the field soil to form a coating to prevent loss, and has the effect of coating, moisturizing, boiling and keeping warm of seeds. The coating curing agent is a material used as an organic fertilizer after plant growth, and can be used in an appropriate amount according to soil and slope conditions, the mixing is preferably made of 200 ~ 300 g / m ³ .

In addition, the culture soil mixture may be further mixed with fertilizer to help plant growth. The fertilizer may use a single fertilizer, or a compound fertilizer mixed with mineral fertilizers for fertilizing the initial growth during germination and inorganic fertilizers that are slowly absorbed until completion of work and complete soil aggregation. And, it is preferably mixed at 80 ~ 120g / m ³ .

In addition, the vegetation layers 25 and 35 are compacted with compaction energy (compacting force) of 12 to 15 kgf? Cm / cm3 to prevent scattering of culture soil or seeds after drying, and 15 kgf? Cm / When it exceeds 3 cm 3, the strength of the vegetation layer is increased to inhibit the root growth of the germinated plant, and when the compaction energy is less than 12 kgf · cm / cm 3, it is preferable that the compaction effect is insufficient to be within the above range.

The flow path 31 of the reservoir dam 30 is formed by the same process as the formation of the flow path 21 of the four-side dam 20.

In this process, the step of installing the screen 22 or the water gate 32 is performed in the flow paths 21 and 31 of the four-side dam 20 and the reservoir dam 30.

That is, the screen 22 is installed in the flow path 21 of the upstream four-side dam 20 to block the inflow of soil and driftwood into the reservoir, and the water gate 32 is provided in the flow path 31 of the downstream storage dam 30. Install to control low water volume. The installation of the screen 22 and the sluice 32 is made by mixing in the concrete layer forming process to be fixed by the concrete, or when the concrete layer is formed in advance to install a frame or a frame for installing the sluice and vegetation layer The step of installing the screen 22 or the sluice 32, such as to be mounted after the formation of the (25, 35), may be appropriately made by mixing the above steps.

10: reservoir,
20: four sides dam,
21,31: Euro, 22: Screen
23,33: foundation layer, 24,34: concrete layer
25,35: vegetation layer
30: downstream reservoir dam,
32: water gate,

Claims (2)

Construct a four-sided dam 20 formed with a screen 22 to block the soil and driftwood in the river, and the downstream of the four-sided dam to build a reservoir dam 30 is formed between the four-side dam and the reservoir dam Form a reservoir 10,
The upstream four-way dam and the downstream reservoir dam,
A first step of preparing a soil cement mixture by cutting the ground at the construction position and mixing 75 to 90% by weight of the cut-off soil, 3 to 10% by weight of cement, 3 to 15% by weight of water, and a solid material;
By installing and compacting the soil cement mixture prepared through the first step, the four-side dam base layer 23 and the reservoir dam base layer 33 are constructed, respectively, the four-side dam base layer 23 and the reservoir dam base layer A second step of forming the flow paths 21 and 31 in the 33;
A third step of forming concrete layers 24 and 34 by installing concrete on the outer surfaces of the base layer for the four-side dam and the base layer for the reservoir dam after the two steps;
A fourth step of forming a vegetation layer (25, 35) by spraying a cultured soil mixture mixed with water and cultured soil containing seeds on the outer surface of the concrete layer formed through the third step;
And a fifth step of installing a screen 22 for filtration in the channel 21 of the four dams, and installing a water gate 32 for fresh water and discharge in the channel 31 of the reservoir dam.
The solidified material may have 5 to 40 parts by weight of gypsum, 100 parts by weight of lime, 5 to 30 parts by weight of lime, and 20 to 80 parts by weight of two or more particle sizes of 100 parts by weight of the cement. A pozzolanic material adjusted to have, and 0.1 to 5 parts by weight of a surfactant, the particle size controlled pozzolanic material having a particle size of 15 to 30 μm of 50 to 60% by weight relative to the particle size controlled pozzolanic material One component and a second component having a particle size of 3 to 8 μm of 40 to 50 wt% based on the particle size-controlled pozzolanic material, wherein the surfactant forms a charging layer on the surface of the solidifying material, and naphthalene Environment-friendly disaster prevention using a solid fire, characterized in that any one selected from the group consisting of compounds, polycarboxylic acid compounds, melamine compounds and amino sulfonic acid compounds Mountain pond construction method.
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