KR100966038B1 - Rainwater infiltration system - Google Patents

Abstract

PURPOSE: A rainwater infiltration system is provided to protect the environment by efficiently eliminating polluted materials in rainwater and to efficiently transfer the rainwater in which the polluted materials are eliminated underground. CONSTITUTION: A rainwater filtration system(1) comprises a precipitation part(100), a filtration part(200), and a storage part(300). The filtration part has a filtration tank(210) and a phosphorus removal layer(223). Multiple rainwater filtration holes(213) are formed in the bottom surface of the filtration tank. The phosphorus removal layer is formed inside the filtration tank. The phosphorus removal layer is formed by loading filtration materials.

Description

Rainwater penetration system {RAINWATER INFILTRATION SYSTEM}

The present invention relates to a rainwater permeation system, and specifically, to protect the environment by efficiently removing not only particulate pollutants contained in rainwater, but also dissolved pollutants dissolved in rainwater. The present invention relates to a rainwater infiltration system that can prevent groundwater level drop and flood by improving the penetration efficiency of infiltrating the removed rainwater.

Korea has undergone rapid urbanization since the 1970s, and now more than 90% of the population lives in cities. In this process, as the development space of Korea increased, the natural green area decreased, and various soil covering facilities such as houses, factories, roads, public facilities, and industrial facilities occupied a large part of the urban space. As a result, the city is transformed into a space where rainwater cannot penetrate, causing problems such as a lack of soil water and a drop in the groundwater level. As such, the lack of moisture in the soil and the lowering of the groundwater level cause disturbances of plant ecosystems and are a direct cause of dryness and ground instability of urban rivers. In addition, rainwater that did not penetrate into the soil flows into urban streams at one time, and the city suffers from the contradiction of urban flooding despite the decrease of the groundwater level. In addition, the rapid increase in impermeable surface caused by concrete, asphalt, etc. caused by urban development projects caused the problem of further increasing pollution by directly spilling pollutants accumulated on the road due to rainwater that failed to pass through the impervious surface during heavy rains.

In order to solve these problems, it is necessary to install and repair stormwater and sewage pipes that can cope with extreme weather with huge budgets, or to quickly store rainwater that exceeds the exclusion capacity of sewage pipes in local effective spaces or buildings in terms of rainwater storage. Rainwater storage facilities are installed to reduce rainwater discharge, and non-point pollution reduction facilities such as vortex type, screen type, and filtration type are installed to remove pollutants contained in rainwater.

In recent years, attempts have been made to treat rainfall runoff and penetrate underground. Looking at the conventionally applied device, Korean Patent No. 2004-0101903 "water treatment functional collection and storage device" is coated with a water-permeable packaging material, the surface of the water and the like through the water-permeable packaging material It is configured to collect the water, purify the collected water and then stored in the basement to infiltrate or recycle as needed, the Korean Patent No. 2004-0101903 is the external pollution contained in the excellent permeable pavement surface There is a problem that the clogging caused by the material to clean the permeable pavement surface from time to time the efficiency of the device was inferior.

Therefore, the conventional water collecting and storage devices as described above are changed to an impermeable surface when the voids are blocked by coarse contaminants such as leaves and cigarette butts, and the rainwater does not flow into the device, and thus loses its function. Because of the contact, air gaps can be frequently blocked, requiring frequent maintenance, which can increase economic costs. In addition, due to the difficulty of maintenance, it is difficult to replace the non-point pollution reduction facilities installed in the existing riverside. In addition, due to the strength limitations of permeable packaging materials, the installation area is limited due to the difficulty of installation in places with high loads on the surface. As described above, the conventional stormwater penetration facility has a problem of poor penetration efficiency, applicability, and economic efficiency.

The problem to be solved by the present invention, as well as particulate contaminants contained in rainwater generated during rainy weather, to effectively remove dissolved pollutants dissolved in rainwater to protect the environment, and to remove rainwater It is to provide an excellent penetration system that can prevent groundwater level drop and flood by improving the penetration efficiency to penetrate underground.

The problem to be solved in accordance with the present invention, in the rainwater penetration system is installed in the basement to purify the foreign matter of rainwater and penetrates into the basement, a cylindrical penetration tank having a plurality of rainwater penetration holes formed on the bottom surface, It is achieved by including a penetrating portion having a phosphorus removing layer formed by stacking a penetrating material coated with a phosphorus removing material therein.

On the other hand, the problem to be solved, according to the present invention, in the rainwater penetration system that is installed in the basement to purify the foreign matters of rainwater to penetrate the ground, it is supplied to the rainwater of the ground to precipitate the foreign matters having a higher specific gravity than water A precipitation section; Phosphorus removal layer and the phosphorus removal layer formed by laminating a cylindrical penetration tank formed on the bottom surface of the rainwater receiving the rainwater from the precipitation portion and penetrates underground, and a penetrating material coated with a phosphorus removing material inside the penetration tank. A first penetrating layer having a first penetrating material laminated on the layer and a second penetrating layer having a second penetrating material laminated thereon, and a third penetrating material having a larger particle diameter than the first penetrating material being laminated at the lower portion of the phosphorus removing layer. It can also be achieved by including a penetration with a third penetration layer.

The sedimentation unit has a rainwater inlet through which rainwater flows from the ground and a rainwater inlet flowing into the rainwater inlet through the rainwater inlet, and has a tubular precipitation tank in which a precipitate having a higher specific gravity than water is precipitated; The rainwater conveyance is formed so that the inner space of the sedimentation tank and the rainwater conveying port form a 'U'-shaped flow path at a predetermined height to prevent a floating material having a smaller specific gravity than water from the rainwater of the sedimentation tank directly flowing into the rainwater conveying port. It is characterized by including a blocking portion covering the sphere.

A rain tank having a rain tank supplied with rainwater from the penetrating unit, at least one of rainwater penetration holes penetrating through at least one wall surface of the storage tank to penetrate rainwater underground and rainwater discharge pipes conveying rainwater from the storage tank to the outside; It is characterized by further including a reservoir.

The penetrating portion further comprises a rainwater conveying tube having a plurality of through holes in at least an upper region in a radial direction and buried between the third penetrating layers to convey rainwater of the penetrating tank introduced into the through hole to the storage tank. .

The penetrating portion is characterized in that it further comprises a rainwater penetration hole penetrating through the bottom surface of the penetration tank to penetrate rainwater underground.

The first penetrating member is gravel having a diameter of 20 to 30 mm; The second penetrating member is sand having a diameter of 0.3 to 2 mm; The third penetrating member has at least one of gravel having a diameter of 30 to 60 mm and crushed stone having a diameter of 40 to 150 mm; The penetrating material coated with the phosphorus removing material has a diameter of 0.15 to 30 mm.

The first penetration layer has a height of 0.1-0.6 m; The second penetrating layer has a height of 0.2-0.4 m; The phosphorus removing layer has a height of 0.15 to 0.45 m; The third penetration layer is characterized in that it has a height of 0.2 ~ 1m.

A permeable sheet is laminated between each layer of the penetration layer and at least one of the bottom surfaces of the penetration tank.

The settling tank, the penetrating tank and the storage tank are each characterized in that the upper wall surface is open or provided to be opened and closed by a manhole cover.

The penetrating material coated with the phosphorus removing material is Al ₂ O ₃ , Fe ₂ O ₃ , FeO and Fe in at least one penetrating material of sand, gravel, clay, expandable polyethylene, expandable polypropylene, activated carbon, anthracite, zeolite and pearlite. It is characterized by being provided by the oxidation coating of at least one phosphorus removing material of ₃ O ₄ .

According to the present invention, not only particulate pollutants contained in rainwater generated during rainy weather, but also effectively remove dissolved pollutants dissolved in rainwater to protect the environment, and the rainwater from which pollutants have been removed penetrates underground. It is possible to provide a stormwater penetration system that can improve the penetration efficiency to prevent groundwater level drop and flooding.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In order to clearly describe the present invention, parts irrelevant to the description are omitted, and like reference numerals designate like elements throughout the specification.

1 is a cutaway perspective view of a stormwater penetration system 1 according to a preferred embodiment of the present invention, FIG. 2 is a longitudinal sectional view of the stormwater penetration system 1 according to a preferred embodiment of the present invention, and FIG. 3 is a preferred embodiment of the present invention. It is a cross-sectional view of the stormwater penetration system 1 according to an example.

As shown in Figures 1 to 3, the rainwater penetration system 1 according to the present embodiment is installed in the basement, is a device for removing the foreign matter contained in the rainwater to penetrate the basement. Rainwater infiltration system 1 includes a precipitation portion 100, a penetration portion 200 and a reservoir 300.

The settling part 100 has a settling tank 110 and a blocking part 120.

The settling tank 110 is provided in a tubular shape that is buried underground so that a precipitate having a larger specific gravity than the water contained therein is precipitated. The precipitation tank 110 is formed with a rainwater inlet 111 through which the rainwater flows from the ground and a rainwater inlet 113 for transporting the rainwater flowed into the rainwater inlet 111 to an upper portion of the infiltration unit 200.

Rainwater inlet 111 is formed through one side of the settling tank (110). Rainwater inlet 111 is preferably formed in the upper region of the precipitation tank (110). On the other hand, the ground is provided with a drainage path (not shown) that can collect rainwater, etc., the drainage passage and the settling tank 110 is connected through the drainage pipe (20). That is, the rainwater inlet 111 of the precipitation tank 110 is connected to the drain pipe 20.

Rainwater transport port 113 is formed through the other side of the settling tank (110). Rainwater transport port 113 is formed to face the rainwater inlet 111. Rainwater delivery port 113 is preferably formed at a height lower than or equal to the height of the rainwater inlet 111. Thus, rainwater introduced into the precipitation tank 110 can be prevented from flowing back through the rainwater inlet 111. The shielding part 120 is installed in the vicinity of the rainwater conveyance port 113.

The blocking unit 120 includes a blocking plate 121. The blocking plate 121 is a suspended material having a specific gravity smaller than that of water, such as oil or grease, among the rainwater of the precipitation tank 110 by forming an inner space of the precipitation tank 110 and the rainwater discharge port 113 having a 'U'-shaped flow path. Cover the rainwater conveying port 113 to prevent the rain flows directly into the rainwater conveying port (113).

The blocking plate 121 has a flat cross-sectional shape of the letter 'c' and covers the peripheral region of the rainwater conveying port 113. The blocking plate 121 is open at the bottom. The blocking plate 121 divides the internal space of the settling tank 110 into the rainwater conveying port 113 side and the rainwater inlet 111 side.

In detail, in the state where the water level of the sedimentation tank 110 is maintained higher than the lower end of the blocking plate 121, the rainwater that is transferred to the rainwater conveying port 113 is not the rainwater directly introduced from the outside but the lower portion of the sedimentation tank 110. The area between and top is excellent. That is, since the U-shaped flow path is formed inside the settling tank 110 by the blocking plate 121, the rainwater transport port 113 has a specific gravity greater than that of the contaminants and the top water deposited in the lower region of the settling tank 110. Only rainwater with this low contaminant removed is continuously supplied. The blocking plate 121 may prevent the floating material having a smaller specific gravity than the water such as oil or grease into the rainwater conveying port 113.

The penetrating part 200 has a penetrating tank 210 and a plurality of penetrating layers 220.

The infiltration tank 210 is in communication with the precipitation tank 110 through the rainwater conveyance port 113 of the precipitation tank 110, and receives the rainwater from which oil, grease and deposits are removed through the rainwater conveyance port 113. Rainwater conveyance port 113 is formed in one upper region of the penetration tank 210, rainwater conveying pipe passage hole 211 through which the rainwater conveying pipe 230 to be described later is formed in the other lower region. In addition, a plurality of rainwater penetration holes 213 are formed in the bottom surface of the penetration tank 210 to penetrate rainwater underground. Rainwater penetrating hole 213 is preferably formed smaller than the particle size of the third penetrating material forming the third penetrating layer.

The penetrating layer 220 is formed by stacking the first penetrating layer 221, the second penetrating layer 222, the phosphorus removing layer 223, and the third penetrating layer 225 from the top. The first penetrating layer 221 is disposed lower than the rainwater conveying port 113. That is, the rainwater port 113 is formed at a higher position than the penetration layer 220. Thus, the rainwater supplied from the precipitation tank 110 can be passed through the penetration layer 220 to remove the foreign matter.

The first penetrating layer 221 constitutes the uppermost layer of the penetrating layer 220, and is formed by stacking the first penetrating material. The first penetration layer 221 preferably has a height of 0.1 ~ 0.6m. The first penetrating material constituting the first penetrating layer 221 is gravel having a diameter of 20 to 30 mm. The first penetrating layer 221 removes particulate matter having a relatively large size from the rainwater introduced into the penetration tank 210 through the rainwater conveying port 113.

The second penetrating layer 222 is formed under the first penetrating layer 221 and is formed by stacking the second penetrating material. It is preferable that the second penetration layer 222 has a height of 0.3 m. The second penetrating material constituting the second penetrating layer 222 is sand having a diameter of 0.3 to 2 mm. The second penetrating layer 222 removes fine particulate contaminants from rainwater that have passed through the first penetrating layer 221.

The third penetrating layer 225 constitutes the lowest layer of the penetrating layer, and is formed by stacking third penetrating materials. It is preferable that a 3rd penetration layer has a height of 0.2-1 m. It is preferable that the 3rd penetration material which comprises a 3rd penetration layer has at least 1 among gravel which has a diameter of 30-60 mm, and a crushed stone which has a diameter of 40-150 mm. The third penetration layer performs a function of supporting and protecting the rainwater conveying pipe 230 described later.

The phosphorus removing layer 223 is a penetrating layer between the second penetrating layer 221 and the third penetrating layer 225, and is formed by stacking a penetrating material coated with a phosphorus removing material. The phosphorus removing layer 223 preferably has a height of 0.15 to 0.45 m. Here, the penetrating material coated with the phosphorus removing material has a diameter of 0.15 to 30 mm.

The penetrant coated with phosphorus removing material is Al ₂ O ₃ , Fe ₂ O ₃ , FeO and Fe ₃ in at least one penetrating material of sand, gravel, clay, expandable polyethylene, expandable polypropylene, activated carbon, anthracite, zeolite and pearlite. It is prepared by oxidation coating at least one phosphorus removing material of O ₄ .

The phosphorus removing layer 223 physically removes foreign substances such as particulate phosphorus, heavy metal, etc., of which some of the rainwater passing through the first penetrating layer 221 and the second penetrating layer 222 physically dissolves the dissolved phosphorus. Adsorbed and removed. In particular, the phosphorus removing layer 223 physically removes particulate phosphorus and removes dissolved phosphorus by chemical sorption (sorption, adsorption and absorption). In addition, the phosphorus removing layer 223 absorbs and removes heavy metals and fine suspended solids by a penetrating material coated with a phosphorus removing material having a lot of sieving or fine pores. The penetrating material coated with the phosphorus removing material constituting the phosphorus removing layer 223 has an advantage of extending the life of the penetrating material because it can process a quantity of 100 to 1,000 times the same concentration than the general penetrating material.

Meanwhile, the principle of removing the dissolved phosphorus from the penetrant coated with the phosphorus removing material is as follows.

Phosphorus adsorption principle of Al

Excessive phosphorus in the water can cause eutrophication such as overgrowth of aquatic organisms and cause aesthetic discomfort. Algae is a major pollutant of water pollution. It is composed of nitrogen and phosphorus, and the source of organic matter is combined with C, H and O. In particular, phosphorus secondary oxygen consumption is relatively large and severe when compared to nitrogen.

Phosphorus exists in various forms such as organic phosphorus and complex inorganic phosphorus (poly-P) and dissolved phosphorus (PO ₄ -P), but the final product in the circulation is dissolved phosphorus.

In the case of lake water with increased pollution in water and sedimentary layers, the removal method of phosphorus by chemical bonding is effective. The Al ³⁺ flocculant is added to remove phosphorus, which is a source of algae, with suspended solids. Phosphorus removal by chemical reaction is the principle that Al (III) -based metal salts are combined with dissolved phosphorus to induce the formation of insoluble or low solubility salts.

H ₃ PO ₄ ↔ H ₂ PO ₄ ^- ↔ HPO ₄ ^2- ↔ PO ₄ ^3-

_{^{Al 3+ + H 2 PO 4 -}} → [AlH 2 PO 4] 2+ for pH <5

Al (OH) ²⁺ + HPO ₄ ^2- → [Al (OH) (HPO ₄ )] ⁰ ↓ for 6 <pH <8

Al (OH) ₃ + PO ₄ ^3- → [Al (OH) ₃ (HPO ₄ )] ^3- for pH> 9

Phosphorus adsorption principle of Fe

Iron is oxidized in the water it may be eluted with Fe ^2+, Fe ^3+, in the water of phosphate (PO ₄ ^3-) and a hydroxyl group (OH ^-) are coupled to the adsorption and precipitation. The material produced at this time is FePO ₄ , Fe ₃ (PO ₄ ) ₂ , Fe _x (OH) _y (PO ₄ ) _{3 And the like} .

It is thought that the tendency of phosphorus adsorption to occur on the surface of Fe ₃ O ₄ (or FeO · Fe ₂ O ₃ ) of iron oxide is caused by the following reaction.

^{_{≡FeOH + H 2 PO 4 - (}} aq) ↔ ≡FeH 2 PO 4 - + OH - (aq)

^{_{≡FeH 2 PO 4 - (aq)}} ↔ ≡FeHPO 4 2 - + H + (aq)

_{^{≡FeOH + HPO 4 2 - ↔ ≡FeHPO}} 4 - + OH - (aq)

Phosphorus adsorption reaction is a ligand-exchange between coordinated water on the adsorbent surface and H ₂ PO ₄ ^- or HPO ₄ ^2- ions, which forms coordinating bonds by providing electron pairs to the central metal atoms in the complex. Magnetism or atomic group).

On the other hand, the penetrating unit 200 may further include an excellent transport pipe 230. Rainwater transport pipe 230 is transferred to the storage tank 310 to be described later to the rainwater tank 210. Rainwater delivery pipe 230 is provided with a hollow pipe, is embedded between the third penetration layer (225). Rainwater feed pipe 230 is formed with a plurality of through holes 231 in the radial direction. The through hole 231 may be formed only in the upper region of the rainwater conveying pipe 230, but is preferably formed throughout the radial hole.

The through hole 231 is formed smaller than the third penetrating member so that the third penetrating member does not pass through. Rainwater that has passed through the third penetration layer 225 in the upper region of the rainwater conveying pipe 230 is introduced into the rainwater conveying pipe 230 through the through hole 231, and the rainwater of the rainwater conveying pipe 230 is stored in the storage tank. Transferred to 310. However, the rainwater that does not flow into the rainwater conveyance pipe 230 penetrates underground through the rainwater penetration hole 213 of the penetration tank 210 through the third penetration layer 225 of the lower region of the rainwater conveyance pipe 230. do. In addition, although it flows into the rainwater conveying pipe 230, it passes through the third penetration layer 225 in the lower region of the rainwater excellent conveying pipe 230 again discharged into the third penetration layer 225 through the through hole 231. Through the rain penetrating hole 213 of the penetration tank 210 is penetrated underground.

The penetration part 200 of the stormwater penetration system 1 according to the present embodiment may further include at least one water permeable sheet 240. The permeable sheet 240 may be laminated between each layer of the permeable layer and at least one of the bottom surfaces of the permeation tank 210. In the present embodiment, the permeable sheet 240 may include a phosphorus removing layer 223 between the first penetration layer 221 and the second penetration layer 222, between the second penetration layer 222 and the phosphorus removal layer 223. And between the third penetration layer 225 and between the third penetration layer 225 and the bottom surface of the penetration tank 210. Permeable sheet 240 may be provided only between any one layer. The permeability sheet 240 preferably has a permeability coefficient of 10 ⁻¹ to 10 ⁻² cm / sec or more.

As such, by removing the contaminants of rainwater from the precipitation unit 100 and the penetration unit 200, it is possible to improve the penetration efficiency to penetrate underground.

The storage part 300 includes a storage tank 310 and a rainwater discharge part 320.

The storage tank 310 is provided in a cylindrical shape in which rainwater is supplied from the penetrating portion 200. That is, the settling tank 110, the penetrating tank 210 and the storage tank 310 is provided in the adjacent tubular shape in order. Here, the settling tank 110, the penetrating tank 210 and the storage tank 310 may be integrally molded in a cylindrical shape partitioned with each other. The precipitation tank 110, the penetration tank 210, and the storage tank 310 may be provided with concrete, or may be provided with various materials such as plastic, wood, and metal.

Rainfall discharge unit 320 has at least one of rainwater infiltration hole 321 and rainwater discharge pipe (325).

Rainwater penetration hole 321 is formed through the wall surface of the storage tank (310). Rainwater penetrating hole 321 may be formed only on the bottom surface of the storage tank 310, as shown in Figure 1, as shown in Figure 5 of the wall surface of the storage tank 310 partitioned with the penetration tank 210 It may be formed on all walls except for one. As shown in FIG. 5, if the rainwater penetrating hole 321 is formed on all walls of the storage tank 310 except for the wall partitioned with the penetration tank 210, the rainwater of the storage tank 310 is discharged to the ground to penetrate underground. The penetration efficiency can be improved. The opening ratio of the rainwater penetration hole 321 is 2 to 30% of the side wall area per sidewall, and the diameter of each storm penetration hole 321 is 30 to 150 mm.

Rainfall discharge pipe 325 transfers the rainwater of the storage tank 310 to the outside. Rainwater discharge pipe 325 is provided to pass through the side of the storage tank (310). Rainwater that has passed through the storm drain pipe 325 is discharged to a separate storage tank, sewer or storm pipe. Rainwater discharge pipe 325 is preferably formed at a height lower than or equal to the height of the rainwater inlet 111 of the sedimentation tank (110).

In this embodiment, as shown in Figures 1 to 3, the settling tank 110, the penetration tank 210 and the storage tank 310 is shown as the upper wall surface is all open. This embodiment is a natural-friendly form using the landscape stone 250 in the upper portion of the penetration tank 210, as shown in Figure 7 to harmonize with the surrounding environment without installing the rainwater penetration system 1 deep underground It can be installed and operated as a facility.

On the other hand, as shown in Figure 8, by planting trees, plants, etc. in the upper portion of the infiltration tank 210 may be installed and operated as a facility of a nature-friendly form. In this case, the first penetration layer 221 is thickly stacked up to the upper region of the rainwater conveying port 113, and after the cover layer 260 covering the soil is provided, the landscape stone is placed or plants are planted.

However, as shown in FIG. 4, the manhole cover M may be mounted on the upper wall surfaces of the settling tank 110, the penetration tank 210, and the storage tank 310 so as to be opened and closed. In this case, the rainwater permeation system 1 can be installed deep underground.

Meanwhile, in the present exemplary embodiment, the first penetration layer 221, the second penetration layer 222, the phosphorus removal layer 223, and the third penetration layer 225 have four penetration layers. The lower penetrating layer may be further laminated according to the builder's choice, such as the fifth penetrating layer, the sixth penetrating layer, and the like.

Hereinafter, with reference to Figure 6 will be described in detail the process of rainwater penetrates underground in the rainwater penetration system 1 according to the present embodiment having such a configuration.

First, the rainwater of the ground is introduced into the sedimentation tank 110 through the rainwater inlet 111 through the drainage channel and the drainage pipe 20 of the ground. Rainwater introduced into the sedimentation tank 110 includes a variety of particulate contaminants and dissolved pollutants coming off the road surface in the rain.

Among the rainwater introduced into the sedimentation tank 110, contaminants having a lower specific gravity than water, such as oil or grease, float to the uppermost region of the rainwater.

When the rainwater of the settling tank 110 reaches a predetermined level or more, the internal space is partitioned by the blocking plate 121. When the water level is higher and the rainwater is transferred to the rainwater port 113, the rainwater is moved to the penetration tank 210 through the rainwater flow port 113. Here, since the blocking plate 121 forms a 'U'-shaped flow path, oil or grease may be blocked by the blocking plate 121 and thus may not move to the rainwater conveying port 113.

Through this process, relatively large particulate contaminants, oils, greases, etc. are removed from the precipitation unit 100.

Rainfall of the precipitation unit 100 is moved to the penetration tank 210 through the rainwater conveying port (113). Rainwater particulate contaminants introduced into the permeation tank 210 are first removed from the first permeation layer 221 and fine particulate in the second permeation layer 222 having smaller particles than the first permeation layer 221. Contaminants are removed and particulate / dissolved phosphorus and heavy metals are removed from the phosphorus removal layer 223. Here, the third penetration layer 225 serves to protect the rainwater conveying pipe 230, and the rainwater from which the contaminants have been removed plays a buffer role to smoothly penetrate into the soil layer through the rainwater penetration hole 213.

Rainwater dissolved contaminants introduced into the infiltration tank 210 are removed from the phosphorus removing layer 223.

Rainwater passing through the first penetration layer 221, the second penetration layer 222, and the phosphorus removal layer 223 moves to the third penetration layer 225. Some of the rainwater of the third penetration layer 225 is introduced into the rainwater transport pipe 230 through the through hole 231 of the rainwater transport pipe 230 is transferred to the storage tank (310). The rest of the rainwater of the third penetration layer 225 passes through all of the third penetration layer, and then penetrates underground through the rainwater penetration hole 213 of the penetration tank 210. Meanwhile, some of the rainwater inside the rainwater conveying pipe 230 is discharged to the third penetration layer 225 through the through hole 231 again, and after passing through all of the third penetration layers 225, It penetrates underground through rainwater penetration holes 213.

Rainwater introduced into the storage tank 310 through the rainwater transport pipe 230 is penetrated underground through the rainwater penetration hole 321 of the storage tank 310. Here, when the water level of the storage tank 310 is increased to reach the rainwater discharge pipe 325, the rainwater is discharged to the outside through the rainwater discharge pipe 325.

As described above, according to the present invention, by providing a phosphorus removing layer 223 formed by stacking a penetrating material coated with a phosphorus removing material in the interior of the penetration tank 210, particulate and dissolved contaminants contained in rainwater Can be removed efficiently.

It not only protects the environment by removing pollutants contained in rainwater, but also improves the penetration efficiency of infiltrating rainwater from which pollutants have been removed, thereby preventing groundwater levels from falling and flooding.

Although some embodiments of the invention have been shown and described, it will be apparent to those skilled in the art that modifications may be made to the embodiment without departing from the spirit or spirit of the invention. . It is intended that the scope of the invention be defined by the claims appended hereto and their equivalents.

1 is a cutaway perspective view of a stormwater penetration system according to a preferred embodiment of the present invention,

2 is a longitudinal sectional view of the stormwater penetration system according to a preferred embodiment of the present invention;

3 is a cross-sectional view of the stormwater penetration system in accordance with a preferred embodiment of the present invention;

Figure 4 is a longitudinal cross-sectional view showing a rainwater penetration system according to an embodiment further equipped with a manhole cover in FIG.

FIG. 5 is a cutaway perspective view illustrating a stormwater penetration system according to an embodiment in which stormwater penetration holes are formed in sidewalls of a storage tank in FIG. 1; FIG.

Figure 6 is a state diagram showing the flow of rain in the stormwater penetration system according to a preferred embodiment of the present invention,

7 is a view showing the installation of the landscape stone on the top of the penetration tank in the rainwater penetration system according to a preferred embodiment of the present invention,

8 is a view showing that the vegetation is installed on top of the infiltration tank in the rainwater penetration system according to a preferred embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

1: storm water penetration system 20: drainage pipe

100: sedimentation unit 110: sedimentation tank

111: rainwater inlet 113: rainwater conveyance

120: blocking portion 121: blocking plate

200: penetrating portion 210: penetrating tank

213: excellent penetration hole 220: penetration layer

221: first penetration layer 222: second penetration layer

223 phosphorus removal layer 225 third penetration layer

230: excellent conveying pipe 231: through hole

240: permeable sheet 300: reservoir

310: storage tank 320: storm drain

321: rainwater penetration hole 325: rainwater discharge pipe

M: Manhole Cover

Claims (10)

In the rainwater penetration system that is installed underground to purify the foreign matter of the rainwater and penetrates underground Rainwater inlet through which rainwater flows from the ground flows, a cylindrical sedimentation tank for depositing rainwater introduced into the rainwater inlet, and a rainwater conveying port for transporting the rainwater of the sedimentation tank are provided. A precipitation part including a blocking part covering the rainwater transport port to prevent the rainwater from being directly introduced into the rainwater transport port; It is provided with a concrete material and the rainwater is supplied from the sedimentation section and the rainwater penetration hole formed in the bottom surface is formed with a plurality of rainwater penetration holes in the bottom surface, sand, gravel, Clay, foamable polyethylene, expandable polypropylene in the interior of the penetration tank, Phosphorus formed by laminating at least one penetrating material of activated carbon, anthracite, zeolite and perlite by oxidizing and coating a phosphorus removing material of at least one of Al ₂ O ₃ , Fe ₂ O ₃ , FeO and Fe ₃ O ₄ A removal layer, a first penetration layer and a second penetration layer in which the first penetration material and the second penetration material are sequentially stacked on the upper portion of the phosphorus removal layer, and a lower portion of the phosphorus removal layer than the first penetration material. A third penetrating layer is provided in which the third penetrating member of size is laminated, The first penetrating layer has a height of 0.1 ~ 0.6m, the first penetrating material is provided of gravel having a diameter of 20 ~ 30mm, The second penetrating layer has a height of 0.2 ~ 0.4m, the second penetrating material is provided with sand having a diameter of 0.3 ~ 2㎜, The phosphorus removing layer has a height of 0.15 ~ 0.45m, the phosphorus removing material is provided with a penetration material having a diameter of 0.15 ~ 30㎜ coated with an oxide, The third penetration layer has a height of 0.2 ~ 1m, the third penetration member is provided with at least one of gravel having a diameter of 30 ~ 60mm and crushed stone having a diameter of 40 ~ 150mm, A penetrating portion, wherein a permeable sheet is laminated between each layer of the penetrating layer and at least one of the bottom surfaces of the penetrating tank; And A storage tank having rainwater supplied from the infiltration unit, a storage unit having at least one of a rainwater penetration hole penetrating through at least one wall surface of the storage tank to penetrate the rainwater underground and a rainwater discharge pipe transferring the rainwater of the storage tank to the outside; , The penetrating part further includes a rainwater conveying pipe having a plurality of through holes in at least an upper region in a radial direction and buried between the third penetrating layers and transferring rainwater of the penetrating tank introduced into the through hole to the storage tank. , The infiltration tank and the storage tank are each excellent wall infiltration system, characterized in that the upper wall surface is open or provided to be opened and closed by a manhole cover. delete delete delete delete delete delete delete delete delete

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