KR100771586B1 - Tunnel type rainwater processing system - Google Patents

Abstract

A tunnel type rainwater processing system is provided to allow heavy rain to flow into water tanks and then in the soil, and to reduce damage due to the heavy rain by forming rainwater permeable holes in the water tanks and flowing the water from the upper part to the inside of the water tanks. A tunnel type rainwater processing system comprises an inlet pipe(10), a precipitated tank(20), at least one water tank(30), a connecting pipe(40), and a drain pipe(50). The water tanks store the flowed water temporarily. The water tanks flow the rainwater to the underground soil. The water tanks have a plurality of rainwater permeable holes(30a) to flow the rainwater from the upper part to the inner part of the water tanks. The water tanks include front, rear, and center water tanks(31,33,32). Blocking devices(37) are installed between the water tanks to limit the flowed volume of the rainwater.

Description

Tunnel Type Rainwater Processing System

1 is a schematic perspective view showing a tunnel-type rainwater treatment system according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view of the tunnel type rainwater treatment system shown in FIG. 1. FIG.

3 is a partially separated perspective view of the storage tank shown in FIG.

Figure 4 is a plan view showing a tunnel-type rainwater treatment system according to another embodiment of the present invention.

<Description of Symbols for Major Parts of Drawings>

10. Rainwater inlet 20. Sedimentation tank

30 .. Storage tank 31. Front storage tank

32 .. Medium storage tank 33. Rear storage tank

34,35.Combination rib 36.Reinforcement rib

37. Barrier 38. Scaffolding rib

40..Connector 50..Drain

60. Nonwoven 70. Overflow bath

The present invention relates to a rainwater treatment system, and more particularly, to infiltrate and temporarily store rainwater in case of heavy rainfall due to prolonged rainfall, heavy rain, heavy rainfall, etc. The present invention relates to a tunnel type rainwater treatment system for preventing damages such as flooding of rivers and surface subsidence.

Unlike natural green areas, urban areas are now covered with asphalt, concrete, and blocks that are difficult to penetrate rainwater. Therefore, most of the rainwater during the rainfall does not penetrate into the soil below the ground surface, is directly flowed into the river through rainwater pipes or sewage pipe, or flows into the sewage treatment plant. In such a situation, if the amount of rainwater to be treated due to heavy rain or torrential rain exceeds the design value of storm pipes or sewage pipes, backwater, surface subsidence, etc. of rainwater may occur. Disasters such as flooding of rivers occur.

Recently, due to environmental pollution and egg development, various forms of extreme weather are continuously occurring. In particular, record rainfall due to heavy rain, heavy lagoon, and local heavy rain is frequent, so the processing capacity of storm water pipes and sewage pipes designed and constructed in the past is insufficient. In order to improve the treatment capacity of rainwater, it is necessary to install additional storm drains, sewer pipes, manholes, etc. with huge budget.

In addition, rainwater introduced directly into the stream through rainwater pipes or sewage pipes or into sewage treatment plants contains various pollutants. In other words, when the rainwater is collected immediately, the pollution level is almost as high as that of the first or second water level, but the rainwater collected through rainwater pipes or sewer pipes deteriorates the water quality to the third to fifth water levels. When the water of 3 to 5 grades directly flows into the rivers, it causes various environmental problems due to water pollution, and even when collected into sewage treatment plants, huge costs are required to treat them.

To solve this problem, the concrete covering the urban area is replaced with permeable concrete with voids through which rainwater can pass, or by installing manholes and blocks made of permeable concrete, the rainwater penetrates into the soil below the surface of the earth. There was an attempt to make it happen.

However, the air gap of the water-permeable concrete as described above has a problem that is easily clogged by contaminants or soil in the rain water. If air gaps are blocked by contaminants or soil, the amount of rainwater that penetrates into the soil below the ground surface is significantly reduced. To solve this problem, it is necessary to reinstate the closed air gaps by applying manpower after periodic or heavy rains and heavy rains. There is a problem.

The present invention was devised to improve the above problems, and improved tunnel to reduce the damage caused by heavy rain and heavy rain by allowing rainwater to temporarily penetrate into the soil below the ground surface while retarding in the reservoir. The purpose is to provide a rainwater treatment system.

Another object of the present invention is to solve the problem that the air gap of the permeable concrete is easily clogged, a lot of cost and manpower to solve this problem.

In addition, another object of the present invention is a tunnel-type rainwater with improved structure to prevent a significant portion of the water quality deteriorated into the river through rainwater pipe or sewage pipe, and to effectively treat the water quality deteriorated To provide a processing system.

Tunnel type rainwater treatment system of the present invention for achieving the above object, the inlet pipe to which the rainwater collected from the building or the ground surface; A sedimentation tank buried in the basement to filter foreign matter in the introduced rainwater and temporarily store the incoming rainwater; One or more storage tanks buried in the basement and having a semi-cylindrical shape in which front and rear sides are blocked and open downward to allow rainwater to flow into the underground soil; A connecting pipe connecting the front of the settling tank and the storage tank; And a drain pipe formed at the rear of the storage tank to drain rainwater that has not been absorbed to the bottom of the storage tank, wherein the rainwater penetrates into the storage tank from the top of the storage tank. The ball is formed.

Here, the storage tank, and the front storage tank connected to the connecting pipe; A rear storage tank connected to the drain pipe; And at least one intermediate storage tank connected between the front and rear storage tanks. It is preferable that a blocking film is provided between the respective storage tanks to limit the temporary discharge of rainwater.

In addition, the blocking film is preferably formed at one end of each of the front, rear and intermediate storage tank.

In addition, the upper portion of the storage tank is preferably provided with a nonwoven fabric for preventing the penetration hole is blocked by the soil.

In addition, it is preferable to further include a overflow tank connected to the drain pipe, buried underground to temporarily store rainwater drained through the drain pipe.

In addition, the storage tank may include a coupling rib formed in a semicircular shape at both edges and at least one reinforcing rib provided between the coupling ribs.

In addition, the coupling ribs may be formed to have a width and a thickness larger than that of the reinforcing ribs so that corresponding coupling ribs of adjacent storage tanks overlap each other.

In addition, the bottom of the storage tank is preferably formed with a scaffold type rib for preventing the storage tank from sinking into the soil.

In addition, the inlet pipe, the settling tank, the connection, the storage tank, the drain pipe is preferably formed of a synthetic resin material.

In addition, the storage tank is preferably a plurality connected in parallel between the connecting pipe and the drain pipe.

Hereinafter, a rainwater treatment system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a tunnel-type rainwater treatment system according to an embodiment of the present invention, Figure 2 is a longitudinal cross-sectional view of the tunnel-type rainwater treatment system shown in FIG.

Referring to FIG. 1, the tunnel type rainwater treatment system according to the embodiment of the present invention filters the inflow pipe 10 through which the rainwater collected from the building or the ground surface is introduced, and the foreign matter in the rainwater that is buried underground. A sedimentation tank 20 for temporarily storing rainwater, one or more storage tanks 30 of a semi-cylindrical shape which are buried in the basement and blocked in front and rear so that rainwater can flow into the underground soil, and the sedimentation tank 20 and It is provided with a connecting pipe 40 for connecting the front of the storage tank 30, and a drain pipe 50 is formed in the rear of the storage tank 30 to drain the rain water that has not been absorbed below the storage tank 30. The connecting pipe 40 forms a pipeline through which the rainwater passing through the settling tank 20 flows into the storage tank 30, and the drain pipe 50 drains the remaining rainwater that has not penetrated into the soil in the storage tank 30. Form a pipeline. The inlet pipe 10 may be adopted to about 100mm to 300mm depending on the site.

In consideration of soil pollution and the like, foreign matter in the rainwater is preferably not introduced into the storage tank (30). To this end, it is possible to install a filter 11 for filtering foreign matter in the inlet pipe 10 for introducing the collected rainwater into the settling tank 20.

Alternatively, a screen not shown may be installed in the settling tank 20 which is connected to the connecting pipe 40. The filter 11 or screen may optionally be employed.

The settling tank 20 may be implemented in a manhole structure having a lid 21. Rainwater temporarily stored in the current collector tank 20 through the inlet pipe 10 flows to the connection pipe 40 while the floating foreign matter or the precipitated foreign matter is once again removed from the sedimentation tank 20.

The storage tank 30 is buried in the underground soil, has a semi-cylindrical shape is blocked front and rear, and open downward. The storage tank 30 can be implemented in various forms other than a semi-cylindrical shape, but the semi-cylindrical shape is adopted in the present invention because it has a durability that can effectively withstand the earth pressure and the dynamic load of the ground surface due to its structural features.

The size of the settling tank 20 and the size and number of the storage tank 30 may vary depending on the amount of rain water to be treated. That is, the size of the sedimentation tank 20 and the size and number of the storage tank 30 are selected in consideration of the rainfall of the area, the area of the building and / or the ground surface. In consideration of the production and construction of the storage tank, the preferred diameter D of the unit storage tank 30 is 1 to 3 m, and the length is preferably in the range of 3 to 10 m.

The storage tank 30 may be formed by connecting a plurality of unit storage tanks in series. In the embodiment of the present invention, the storage tank 30 is the front storage tank 31 to which the connection pipe 40 is connected, the rear storage tank 33 to which the drain pipe 50 is connected, and the front and rear storage tank 31, 33) an intermediate reservoir 32 connected therebetween. The front storage tank 31 is blocked in front of the semi-cylindrical body (31a) by the front wall (31b), the front wall (31b) is connected through a connecting pipe (40).

The rear reservoir 33 has a structure in which a rear wall is formed behind the semi-cylindrical body 33a and is blocked.

One or a plurality of intermediate storage tanks 32 may be provided and interposed between the front and rear storage tanks 31 and 33 so as to be connected and separated.

Here, the storage tank 30, preferably in each of the storage tank (31, 32, 33) in addition to the connecting pipe 40, a plurality of rain water from the upper portion of the storage tank 30 to be introduced into the storage tank (30) Rainwater penetrating holes 30a are formed. The penetration holes 30a are holes having a diameter of about 20 mm to 30 mm, and are formed at intervals of 200 mm or more. In this way, by forming a plurality of penetration holes (30a) on both the upper side and the side of the storage tank 30, the ground surface is introduced into the storage tank 30 through the soil in the case of a green or water permeable to rainwater penetration. That is, during heavy rains or torrential rain, rainwater that cannot be introduced into the storage tank 30 through the inflow pipe 10 and the connection pipe 40 may be directly introduced into the storage tank 30 through the infiltration hole 30a. Can be. In addition, after the rain is finished, the rainwater in the storage tank 30 can be drained more effectively by slowly penetrating into the soil through the penetration hole 30a drilled on the side of the storage tank 30 as well as the lower portion. Therefore, the storage tank 30 of the present invention can be installed not only on the impermeable pavement surface but also on the base of the permeation surface, so that the storage tank 30 can be expanded.

Here, it is preferable that a nonwoven fabric 60 is further installed on the outer upper surface of the storage tank 30 to prevent soil or foreign matter from flowing through the penetration holes 30a or blocking the penetration holes 30a. .

In addition, each of the plurality of storage tanks 31, 32, and 33 is provided with coupling ribs 34 and 35 formed at both ends and reinforcement provided between the coupling ribs 34 and 35, respectively, as shown in FIG. 3. It has ribs 36. The coupling ribs 34 and 35 are formed to be thicker or larger in width than the reinforcing ribs 36. The coupling ribs 34 and 35 are coupled to overlap each other when the adjacent storage tanks 31 and 32 are coupled to each other. The reinforcing rib 36 increases the strength and durability of the storage tanks 31, 32, and 33 together with the coupling ribs 34 and 36, and serves to suppress deformation due to the load. The coupling ribs 34 and 35 may be firmly coupled to each other by a fastening means such as a screw nail.

In addition, between each of the storage tanks (31, 32, 33), rain water flows out at once to limit the load on the storm drain, and a blocking film 37 is installed to prevent the soil dig phenomenon. The blocking films 37 are provided between the storage tanks 31, 32, and 33 when the storage tanks 31, 32, and 33 divided into several units are assembled and installed in the field, so that the rainwater moves sequentially. do. This is to prevent the gravel layer, such as when the rainwater is introduced into the storage tank 30 at the same time, and to allow the rainwater to be evenly distributed to a wider area by moving the rainwater sequentially. The blocking films 37 may be integrally formed at the end portions of the respective storage tanks 31, 32, and 33 at a predetermined height. In addition, the blocking films 37 may prevent the semi-cylindrical storage tanks 31, 32, and 33 from being opened by the load of the soil.

In addition, the storage tank (31, 32, 33) is preferably formed on the lower end of each of the storage tank (31, 32, 33) scaffold type rib 38 so as to withstand structural stability and earth pressure. Thus, by forming the scaffold type rib 38 to be bent at a predetermined angle, preferably horizontally, at the lower ends of the storage tanks 31, 32, 33, even if the cross section of the semicircular storage tank 30 continuously presses the gravel layer, 30 may be turned off into the ground, or the gravel layer may be introduced into the storage tank 30 to reduce the storage space. The scaffold ribs 38 are preferably formed with a width between approximately 5 cm and 10 cm.

In addition, the overflow pipe 70 may be further connected to the drain pipe 50. The overflow tank 70 is for storing the rain water discharged from the drain pipe 50 for a predetermined time to move to the next storage tank, it may have the same structure as the submerged tank (20). This overflow tank 70 is also buried underground.

In the above configuration, it is preferable that the rainwater effectively penetrates into the soil by laying gravel at a predetermined thickness on the lower and side surfaces of the storage tank 30.

The inflow pipe 10, the settling tank 20, the storage tank 30, the connection pipe 40, the drain pipe 50, the overflow tank 70 may be formed of a variety of materials, such as metal, concrete, synthetic resin. However, in order to prevent shortening of life and soil contamination due to corrosion by rainwater, it is preferable to be made of synthetic resin material. In particular, considering the convenience of construction and economics, the synthetic resin material may be most suitable polyethylene. In addition, the inlet pipe 10, the connection pipe 40, the drain pipe 50 is preferably formed of a PVC material.

According to the tunnel-type rainwater treatment system according to an embodiment of the present invention having the above configuration, the rainwater collected from the building and / or the ground surface is the inlet pipe 10-> sedimentation tank 20-> connecting pipe 40-> storage tank Go to (30) order. In this process, foreign matter in the rainwater is first filtered by the filter 11 in the inlet pipe 10, and once again in the sedimentation tank 20. That is, the floating foreign matter will float on the top of the settling tank 20, the settled foreign matter will sink to the bottom of the settling tank (20). And the foreign matter in the rain water can be filtered by a separate screen that is installed in the settling tank 20, that is, a filter.

Thus, foreign matter is removed, rainwater introduced into the storage tank 30 through the connection pipe 40 is penetrated into the underground soil through the storage tank 30, and if the amount of rainwater flowing into the underground soil If the amount is greater than that, the excess rainwater is sequentially moved over the blocking membrane 37 between the storage tanks 31, 32, and 33 to the drain pipe 50 and eventually drained to the drain pipe 50.

In addition, in addition to the inflow pipe 10 and the settling tank 20, rainwater that has penetrated into the soil around the storage tank 30 is introduced into the storage tank 30 through the penetration hole 30a of the storage tank 30. In this way, the rain water is also introduced into the storage tank through the penetration hole 30a formed in the storage tank 30, so that the storage tank 30 may be installed in the underground part of the area such as concrete or asphalt.

In addition, after the rain stops rainwater introduced into the storage tank 30 can be slowly drained back to the soil through the penetration hole (30a) of the side of the storage tank 30, the drainage efficiency is also improved.

On the other hand, the rainwater overflowing from the storage tank 30 and drained to the drain pipe 50 is temporarily stored in the overflow pipe 70, and then discharged to the public pipe through the drain pipe 71 connected to the overflow pipe 70.

In addition, as shown in Figure 4, a plurality of the storage tank 30 is provided between the connecting pipe 40 connected to the settling tank 20, and the rear drain pipe 50, all in parallel rainwater treatment system It is also possible to implement In this case, each of the storage tank 30 has the same configuration as the storage tank 30 described above with reference to Figures 1 to 3, the front is all connected to the connecting pipe 40, the rear of the drain pipe 50 It is characterized by a point all connected to. Rainwater infiltration and storage systems of this configuration can be installed in large spaces, such as sports grounds, parks, stadiums, etc., to have a great effect.

According to the tunnel-type rainwater treatment system of the present invention as described above, by allowing the rainwater to be penetrated into the soil beneath the ground surface, it is possible to significantly reduce the damage caused by heavy rain, heavy rain.

In addition, the air permeability of the existing permeable concrete is easily clogged, it is possible to solve the problem that a lot of cost and manpower was put in order to overcome this.

In addition, it is possible to effectively prevent the water deteriorated inflow into the river through rainwater pipes or sewage pipes, it is possible to solve the problem that a huge cost to treat the water deteriorated water.

In the above, certain preferred embodiments of the present invention have been illustrated and described. However, the present invention is not limited to the above-described embodiments, and any person having ordinary skill in the art to which the present invention pertains without departing from the spirit and spirit of the present invention claimed in the claims may make various modifications and variations. Implementation will be possible.

Claims (10)

An inflow pipe into which rainwater collected from a building or the ground surface flows; A sedimentation tank buried in the basement to filter foreign matter in the introduced rainwater and temporarily store the incoming rainwater; One or more storage tanks buried in the basement and having a semi-cylindrical shape in which front and rear sides are blocked and open downward to allow rainwater to flow into the underground soil; A connecting pipe connecting the front of the settling tank and the storage tank; And And a drain pipe formed at the rear of the storage tank to drain rainwater that has not been absorbed under the storage tank. A plurality of rainwater infiltration holes are formed in the storage tank so that rainwater can penetrate into the storage tank from the upper portion of the storage tank. The storage tank includes a front storage tank connected to the connection pipe, a rear storage tank connected to the drain pipe, and at least one intermediate storage tank connected between the front and rear storage tanks, Tunnel-type rainwater treatment system, characterized in that the barrier between the respective reservoirs is installed to limit the inflow of rainwater. delete The tunnel type rainwater treatment system according to claim 1, wherein the blocking film is integrally formed at one end of each of the front, rear, and intermediate storage tanks. The tunnel type rainwater treatment system according to claim 1, wherein a nonwoven fabric is installed on an upper portion of the storage tank to prevent the penetration hole from being blocked by soil. The tunnel type rainwater treatment system of claim 1, further comprising a overflow pipe connected to the drain pipe and buried underground to temporarily store rainwater drained through the drain pipe. An inflow pipe into which rainwater collected from a building or the ground surface flows; A sedimentation tank buried in the basement to filter foreign matter in the introduced rainwater and temporarily store the incoming rainwater; One or more storage tanks buried in the basement and having a semi-cylindrical shape in which front and rear sides are blocked and open downward to allow rainwater to flow into the underground soil; A connecting pipe connecting the front of the settling tank and the storage tank; And And a drain pipe formed at the rear of the storage tank to drain rainwater that has not been absorbed under the storage tank. A plurality of rainwater infiltration holes are formed in the storage tank so that rainwater can penetrate into the storage tank from the upper portion of the storage tank. The storage tank is a tunnel-type rainwater treatment system, characterized in that it comprises a coupling rib formed in a semicircular shape at both edges, and at least one reinforcing rib provided between the coupling ribs. The tunnel type rainwater treatment system according to claim 6, wherein the coupling ribs are formed to have a width and a thickness greater than that of the reinforcement ribs so that corresponding coupling ribs of adjacent storage tanks overlap each other. The tunnel type rainwater treatment system according to claim 6, wherein scaffold ribs are formed at a lower end of the storage tank to prevent the storage tank from penetrating into the soil. The tunnel type rainwater treatment system according to claim 6, wherein the inflow pipe, the sedimentation tank, the connection section, the storage tank, and the drainage pipe are formed of a synthetic resin material. The tunnel-type rainwater treatment system according to claim 6, wherein the storage tank is connected in parallel with the connection pipe and the drain pipe in between.

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