KR20110011506A - Infiltration trench having natural water circulation and nonpoint source pollution reduction - Google Patents

Abstract

PURPOSE: A ditch with natural water circulating and non-point contamination reducing functions is provided to enable non-point contaminating source to be effectively removed and reduced since a perforated pipe is horizontally arranged in a filter portion to be suitable for a terrain of city. CONSTITUTION: A ditch with natural water circulating and non-point contamination reducing functions comprises an inflow portion(20), a filter portion(30) and an outflow portion(40). An inflow pipe(21) is formed on one side of the inflow portion so that contaminated water flows into. A filtration layer is formed in the filter portion. The filter portion comprises an outflow hole(34) and an outflow pipe(41). The outflow pipe externally discharges the contaminated water, which flows into through the outflow hole of the filter portion.

Description

Infiltration trench having natural water circulation and nonpoint source pollution reduction

The present invention relates to a permeation groove having a natural water circulation and non-point pollution reducing function installed inside the filtration unit, and more particularly, to arrange a plurality of ducts inside the filtration unit horizontally so as to be suitable for urban areas and to remove non-point pollution sources. The present invention relates to an infiltration ditch having a natural water circulation and non-point pollution reduction function that induces rainwater to fall underground.

Pollutants generated in urban areas are largely divided into point sources and nonpoint pollution sources. Point sources are pollutants with specific emission paths, such as household sewage and factory wastewater, which can be expressed as a single point, and are relatively easy to handle because of their clear movement paths.Non-point sources are city, road, farmland, mountain, and construction sites. This refers to the sources of unspecified emissions of water pollutants from unspecified places (see the Law on Water Quality and Ecosystem Conservation).

These nonpoint sources are scattered pollutants, unlike point sources that occur continuously at certain points, such as domestic sewage or factory wastewater, and it is difficult to identify the exact outflow path and the inflow is non-persistent. In particular, it is difficult to collect pollutants and their discharge paths are not clearly distinguished, and it is difficult to collect them. Nonpoint pollutants include earth and sand, nutrients (floating substances, nitrogen and phosphorus), bacteria and viruses, oils and greases, heavy metals, organic substances, pesticides and contaminants.

In addition, non-point source was not recognized as the source of pollutant because the outflow of nonpoint source was concentrated only during rainfall and the source was dispersed in a large area. However, the first-flush effluent from which the surface non-point source flows out during the early rainfall has a high concentration of non-point source effluents, especially in urban areas, which may contain toxic substances such as heavy metals, so appropriate control measures are required. have. In other words, the outflow of nonpoint source by rain is very irregular, contains many kinds of non-degradable nonpoint source, large amount of overload fluctuation is large, that is, the fluctuation of flow rate with time is large, Has a characteristic such as increasing rapidly.

Therefore, pollutants such as soil, nutrients and high concentrations of heavy metals, which are spilled with rain from nonpoint sources, are difficult to collect and treat, but if they enter the river without special treatment, they contaminate the water quality. The habitat is destroyed and the aquatic ecosystem is disturbed.

Also, when we look at the characteristics of urban areas, the urbanization and population concentration make our surroundings covered with roads and buildings, and it is difficult to step on or touch the soil, the source of life. Thus, when it rains, shoes and clothes no longer need to be wet with muddy water, which makes it convenient. However, the soft smell of soil and the texture of the soil have moved away from us, and many benefits that the soil brings have disappeared. In addition, as land development is accelerated due to the progress of urbanization and industrialization, and the impermeable layer area such as roads, industrial complexes, and residential lands is increased, adverse effects on the water quality of rivers and lakes caused by nonpoint source are increasing.

It does not stop here, but when it rains, the rainwater quickly travels along the paved roads and storm pipes, containing many nonpoint sources of the road along the stream. As the surface is paved, the amount of water that passes through the soil and becomes groundwater diminishes gradually, and when it rains in the river, the water blows up and overflows quickly, and when the rain stops, the water is quickly depleted. The plant-based soil of the trees remaining in the parks and gardens is washed away by rainwater and hardened so that it is difficult to support the creatures in the ground and to receive rainwater and send it to the groundwater.

At present, facilities that reduce non-point pollution sources include storage type, infiltration type, vegetation type, device type, and sewage treatment type, but this is to remove specific pollutants contained in the contaminated water. There is a need for an integrated treatment facility that removes nonpoint sources contained in stormwater and leads rainwater from which nonpoint sources are removed to groundwater.

Accordingly, an object of the present invention is to provide a permeation trench having a natural water circulation and non-point pollution reduction function capable of effectively removing or reducing nonpoint pollution sources by horizontally arranging the perforated pipes in the filter medium to be suitable for urban topography.

Another object of the present invention is to provide an infiltration ditch having a natural water circulation and non-point pollution reduction function that easily induces rainwater from which a nonpoint source is removed or reduced.

Still another object of the present invention is to provide a permeation trench having a natural water circulation and non-point pollution reduction function that effectively removes non- pollutants even when rainwater over a design quantity is introduced.

In order to achieve the above object, the present invention is the inlet 20 is formed with an inlet tube 21 on one side so that the contaminated water; Filtration layer is formed therein and contaminated water in the inlet part 20 flows into one side of the filtration layer or flows into the upper part of the filtration layer, and the filter medium outlet hole 34 on the other side so that the filtered contaminated water flows out. The filter medium 30 is formed; Combined with the natural water circulation and non-point pollution reduction function, including; and the outlet portion 40 is formed with an outlet tube 41 on one side so that the contaminated water introduced through the filter medium outlet hole 34 to the outside Provide a penetration ditch.

In addition, the wood chip pack 25 is formed horizontally in the inlet 20 to filter the contaminated water in the inlet 20, the inlet 20 is introduced into one side of the filter medium (30) ) Vertically formed inside the inlet 20 to filter the contaminated water.

In addition, a plurality of perforated pipes 39 are horizontally disposed inside the filter unit 30 so that the contaminated water introduced through one side surface of the inlet unit 20 moves into the filter unit 30. It is done.

In addition, it is characterized in that the underground induction unit 50 is formed in the lower portion of any one of the inlet 20, the filter unit 30 and the outlet 40 to guide the filtered contaminated water underground.

Infiltration ditch having a natural water circulation and non-point pollution reduction function according to the present invention is equipped with a filter part composed of a wood chip pack and a filtration layer to efficiently remove or reduce the non-contaminant contained in rainwater, and to level the hollow pipe inside the filter part. Since it is arranged to fully utilize the space of the filter medium, it is useful in areas where land use space is small, such as urban areas. As a result, it is possible to maintain and restore a healthy water ecosystem through efficient nonpoint source management, so it is used as a nonpoint source treatment facility suitable for urban areas.

In addition, the penetration groove having a natural water circulation and non-point pollution reduction function according to the present invention is effective for the collection of particles of heavy metal and fine soil by using wood chip pack and sand layer.

In addition, the infiltration ditch having a natural water circulation and non-point pollution reducing function according to the present invention has a filter part composed of a gravel layer and a sand layer, so that the replacement of the filter part is easy, the replacement cost is low, and the use period is long, so the maintenance is easy. have.

In addition, the penetration groove having a natural water circulation and non-point pollution reduction function according to the present invention is a connection groove is formed between the inlet and the filter medium and between the filter medium and the outlet, and an overflow layer is formed on the upper portion of the filter medium, the design quantity or more Even if rainwater enters, it effectively removes nonpoint source.

In addition, the infiltration ditch having a natural water circulation and non-point pollution reduction function according to the present invention has an underground induction part formed at the lower part, so that the contaminated water from which the non-point source has been removed penetrates into the underground through the underground induction part, thereby securing ground water. It helps with the surrounding vegetation and prevents soil loss during heavy rains. Therefore, it is applied as a low impact development (LID) technology for improving the water circulation system in the city under the government policy.

1 is a longitudinal sectional view of a penetration groove having a natural water circulation and non-point pollution reduction function according to an embodiment of the present invention.
2 is a plan view of a penetration groove having a natural water circulation and non-point pollution reduction function according to an embodiment of the present invention.
3 is a cross-sectional view taken along the line AA shown in FIG.
4 is a cross-sectional view taken along line BB shown in FIG. 1.
5 is a cross-sectional view taken along line CC shown in FIG. 1.
6A and 6B are views for explaining an embodiment of a perforated pipe in a penetration groove having a natural water circulation and a nonpoint pollution reduction function according to the present invention, respectively.
7 is a view for explaining the underground guide portion of the penetration ditch having a natural water circulation and non-point pollution reduction function according to an embodiment of the present invention.
8 is a view for explaining the operation when a small amount of rainfall infiltration of the infiltration ditch having a natural water circulation and non-point pollution reduction function according to an embodiment of the present invention.
9 is a view for explaining the operation during design rainfall inflow of the penetration ditch having a natural water circulation and non-point pollution reduction function according to an embodiment of the present invention.
10 is a view for explaining the operation when the design rainfall excess inflow of the penetration ditch having a natural water circulation and non-point pollution reduction function according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail the penetration groove having a natural water circulation and non-point pollution reduction function according to a preferred embodiment of the present invention. 1 is a longitudinal sectional view of a penetration groove having a natural water circulation and non-point pollution reduction function according to an embodiment of the present invention, Figure 2 is a penetration in combination with a natural water circulation and non-point pollution reduction function according to an embodiment of the present invention Top view of the ditch. As shown in Figures 1 and 2, the penetration groove having a natural water circulation and non-point pollution reduction function according to an embodiment of the present invention includes an inlet 20, the filter medium 30 and the outlet 40 do. Therefore, the contaminated water introduced into the inlet 20 is introduced into the filter unit 30, and the contaminated water in the filter unit 30 is filtered and then moved to the outlet unit 40 to be discharged to the outside. do. In addition, the lower portion of the inlet portion 20, the filter portion 30 and the outlet portion 40 is formed with an underground guide portion 50 to guide the filtered contaminated water underground.

3 is a cross-sectional view taken along the line AA shown in FIG. As shown in Figures 1 and 3, the inlet 20 is formed with an inlet tube 21 on one side. The inlet pipe 21 is connected to the rainwater conduit installed on the side of the road, and thus the rainwater collected in the rainwater conduit flows into the inlet 20 through the inlet pipe 21.

In addition, the wood chip pack 25 is formed horizontally and vertically in the inflow part 20 to remove the non-point pollution source included in the rainwater flowing in. The wood chip pack 25 is formed by embedding a wood chip made by crushing wood finely into a mesh or the like. The wood chip has a large specific surface area and thus has a high specific surface area, so that the particulate soil in adsorbing and filtering fine soil particles and heavy metals. An increase in the removal efficiency of over- dissolved pollutants can be expected. In addition, the wood chip pack can be easily replaced to increase the removal efficiency of the non-point source. Therefore, the wood chip pack 25 is disposed horizontally in the inlet 20 to remove the non-point source from the contaminated water moving downward by gravity, and also vertically arranged through the median inlet hole 31 to be described later. The non-point source is removed from the contaminated water moving to the filter unit 30.

In addition, a gravel layer 26 and a sand layer 27 are formed below the inflow portion 20, that is, the lower portion of the wood chip pack 25. That is, the contaminated water passing through the wood chip pack 25 passes through the gravel layer 26 and the sand layer 27 in order to further remove the non-point source. In addition, only the sand layer 27 may be formed in consideration of the space of the inlet 20. Sand is an excellent material for removing particulate nonpoint sources and is effectively used to treat nonpoint sources for a long time. In addition, a nonwoven fabric 28 is formed between the gravel layer 26 and the sand layer 27. The use of the nonwoven fabric 28 has the effect that the position of the gravel layer 26 and sand layer 27 is firm and the filtration action is improved. The non-woven fabric (non-woven fabric) refers to the raw material fiber made of a felt shape by arranging the fibers in parallel or in a non-directional direction, combined with a synthetic resin adhesive without going through a woven fabric process.

Therefore, the contaminated water passing through the wood chip pack 25, the gravel layer 26, or the sand layer 27 moves to the filter part 30 through the filter part inlet hole 31. In addition, the contaminated water sequentially passing through the wood chip pack 25, the gravel layer 26, and the sand layer 27 is guided underground through the underground induction part 50. This makes it possible to secure groundwater, to help the surrounding vegetation, and to prevent the loss of soil even during heavy rains. In addition, the underground induction part 50 is installed in the lower part of the filter part 30 and the outlet part 40 as well as the inlet part 20, so that the natural water circulation and non-point pollution reduction function according to the present invention infiltration The ditch will be applied as a Low Impact Development (LID) technology to improve the water circulation system in the city under government policy. In addition, the installation of the underground induction part 50 prevents contaminant water from stagnating in the inlet part 20, the filter part 30, and the outlet part 40.

In addition, the steel grating 22 is formed at the upper end of the inlet 20. Therefore, torrential rain such as heavy rain is introduced directly into the inlet 20 through the steel grating 22. The steel grating 22 may be a conventional steel grating in the form of a lattice.

4 is a cross-sectional view taken along the line BB shown in FIG. As shown in Figures 1 and 4, the filter portion 30 has a connection groove 32 is formed on one side of the upper side, a plurality of filter inlet hole 31 is formed on one side and the filter medium on the other side Outflow hole 34 is formed, the connection groove 32 'is formed at the other end. In addition, the basement induction part 50 is formed under the filter part 30. Therefore, the contaminated water in the inlet 20 flows into the upper end of one side of the filter unit 30 through the connecting groove 32 or through the filter unit inlet hole 31 to one side of the filter unit 30. It will flow in. In addition, the contaminated water filtered by the filtration layer is moved to the outlet portion 40 through the filter medium outlet hole 34 or guided underground through the basement guide portion 50. In addition, the contaminated water in the filter medium 30 may move to the outlet 50 through the connection groove 32 ′. In this case, the placement portion and the number of the outlet holes 34 vary depending on the design capacity. In addition, the underground induction part 50 and the crushed stone storage layer 55 are formed in the lower part of the filter part 30 similarly to the inflow part 20.

In the filter layer in the filter medium 40, a plurality of gravel layers 36 and sand layers 37 cross each other. As described above, the gravel layer 36 and the sand layer 37 are excellent in the ability to remove and remove the particulate nonpoint source. As shown in FIGS. 1 and 4, the gravel layer 36 and the sand layer 37 may be disposed to cross two layers, but three or more layers may be disposed without being limited thereto. In addition, a nonwoven fabric 38 is formed between the gravel layer 36 and the sand layer 37, and the nonwoven fabric 38 has the same structure and function as the nonwoven fabric 28 formed at the inlet 20. By using the nonwoven fabric 38, the position of the gravel layer 36 and the sand layer 37 is firm, and the effect of improving the filtration is exerted.

In addition, a wood chip pack 35 is formed on the gravel layer 35 disposed above. The wood chip pack 35 performs the same function and role as the wood chip pack 25 formed in the inlet 20. Therefore, the contaminated water introduced through the connection groove 32 passes through the wood chip pack 35 in the same way as the contaminated water introduced through the filter medium inlet hole 31, so that particulate contaminants and dissolved contaminants are removed. Will be removed.

In addition, the filter unit 30 is formed to be inclined downward to the right. The degree of inclination may be adjusted as needed, and the degree of inclination of the contaminated water in the filter medium 30 is adjusted by adjusting the degree of inclination. Therefore, the contaminated water in the filter unit 30 moves to the lower right side of the filter unit 30 while passing through the filter layer by gravity and inflow force, and the outlet unit through the filter unit outlet hole 34. 40 is to be introduced.

In addition, an overflow layer 33 is formed on the wood chip pack 35. Therefore, when the contaminated water introduced through the connection groove 32 or directly into the filter medium 30 flows into the design quantity or more, the connection groove 32 'moves while moving through the overflow layer 33. It moves to the outlet 40 through. A gravel layer or vegetation may be formed in the overflow layer 33. In addition, the steel grating (not shown) may be formed at the upper end of the overflow layer 33, that is, at the upper end of the filter part 30, in the same manner as the inflow part 20.

In addition, the filter unit 30 has a plurality of perforated pipes 39 are formed horizontally at regular intervals up and down. 6A and 6B are views for explaining an embodiment of the perforated pipe in the penetration groove having a natural water circulation and non-point pollution reduction function according to the present invention. As shown in FIG. 6A, the perforated pipe 39 has a surface. A hole hole 39 'is formed in the hole. Therefore, the contaminated water moved through the hole tube 39 flows out through the hole hole 39 ′ and is filtered through the filter layer, that is, the gravel layer 36 and the sand layer 37. In addition, the hole tube 39 is preferably located in the gravel layer 36 formed in the filter unit 30, which can be quickly penetrated into the filter unit 30 contaminated water flowing from the hole tube 39. Because there is.

Therefore, the hole 39 serves to directly introduce the contaminated water into the filter medium 30. That is, the infiltration ditch having a natural water circulation and non-point pollution reducing function according to the present invention passes the contaminated water introduced into the inlet 20 and the contaminated water introduced into the overflow layer 33 through the filter unit 30. While being filtered while the contaminated water moves by gravity and inflow force in the filter unit 30, the upper left portion of the filter unit 30 is used for filtration. That is, not all of the filtration layers of the filter medium 30 are used for the filtration action, but only a specific portion of the filter medium 30 is used for the filtration action, so that the use period of the filter medium 30 is shortened and the filtration efficiency is reduced. This problem of sharp drop occurs. In order to solve this problem, the size of the filter unit 30 may be manufactured and used to be large, but this is not an appropriate method when the space for use of land such as an urban area is limited. Therefore, in order to increase the use efficiency of the filter unit 30, it is necessary to variously designate the inflow point of the contaminated water flowing into the filter unit 30. That is, by placing the plurality of holes (39) in the filtration layer of the filter unit 30, the contaminated water introduced through the inlet 20, the inside of the filter unit 30 through the hole (39) Allow direct entry. Therefore, the hole tube 39 is disposed to be connected to the filter medium inlet hole 31 and more preferably arranged to match the center of the filter medium inlet hole 31.

In addition, since the plurality of the perforated pipes 39 are arranged at regular intervals up and down, the length of the perforated pipes 39 is preferably longer toward the bottom. As shown in FIG. 6A, the length L1 of the perforated tube 39 positioned at the top, the length L2 of the perforated tube 39 positioned at the middle point, and the length L3 of the perforated tube 39 positioned at the bottom are shown in FIG. It gets longer towards the bottom. For example, as shown in Figure 6a, the length (L3) of the lower perforated tube 39 is the same as the total length (L) of the filter medium 30, the length (L2) of the suspended perforated tube (39) Is 1/2 of the total length L of the filter medium 30, and the length L1 of the upper perforated pipe 39 is 1/3 of the total length L of the filter medium 30. That is, since the contaminated water flowing from the inlet 20 through the lower perforated pipe 39 directly penetrates into the lower right of the filter unit 30, the entire filtration layer of the filter unit 30 is effectively used. Eventually, because the entire filter layer of the filter medium 30 is effectively used, when the rain drops below the designed quantity, the contaminated water having the natural water circulation and the non-point pollution reduction function according to the present invention effectively removes the contaminated water such as rainwater. It will be filtered. In addition, if necessary, the length of the perforated pipe 39 may be formed to be the same as shown in Figure 6b. In addition, the hole tube 39 may be used only the lower end hole tube 39, it may be replaced by sand or gravel.

5 is a cross-sectional view taken along line CC shown in FIG. 1. As shown in Figures 1 and 5, the outlet portion 40 is formed with a steel grating 22 'on the top and the outlet pipe 41 is formed on one side. The outflow pipe 41 is connected to the rainwater conduit formed on the outside, and the contaminated water flowing into the outflow part 40 through the outflow hole 34 is discharged to the outside through the outflow pipe 41. Will be. In addition, in case of heavy rain or the like, rainwater may be directly introduced into the outlet portion 40 through the steel grating 22 ′, and the introduced rainwater may be discharged into the rainwater pipe through the outlet pipe 41. The steel grating 22 ′ has the same structure and function as the steel grating 22. In addition, the base portion 50 and the crushed stone storage layer 55 are formed in the lower portion of the outlet portion 40 in the same manner as the inlet portion 20.

The underground guide 50 is described in detail. 7 is a view for explaining the underground guide portion of the penetration ditch having a natural water circulation and non-point pollution reduction function according to an embodiment of the present invention. As shown in FIG. 7, the underground induction part 50 is an underground induction hole 51 formed in the lower part of the inlet part 20, the filter part 30, and the outlet part 40, respectively, and the underground induction part. It consists of an underground guide pipe 52 inserted into the hole 51. In addition, the underground induction pipe 52 is filled with a filter medium (not shown) for filtering the contaminated water to further filter the contaminated water. The outer diameter of the underground guide pipe 52 is the same as or smaller than the inner diameter of the underground guide hole 51, the length of the underground guide pipe 52 is longer than the length of the underground guide hole 51 is inserted. And maintenance in terms of dismantling and the like. In addition, the underground guide hole 51 and the underground guide pipe 52 may take a variety of cross-sections, such as a circle, a square, it is preferable to have a circular cross section in terms of structure. In addition, the underground guide pipe 52 is preferably made of a PVC pipe.

In addition, a crushed stone storage layer 55 is formed at the bottom of the inflow portion 20. Therefore, the contaminated water from which the non-point pollutant reached the crushed reservoir 55 is easily introduced into the underground induction part 50. The crushed stone storage layer 55 may be, for example, gravel used in the gravel layer 26.

Next, a description will be given of the operation of the penetration groove having a natural water circulation and non-point pollution reduction function according to an embodiment of the present invention.

Contaminated water, such as rainwater, is collected in rainwater conduits and flows into the inlet 20 through the inlet pipe 21 or into the inlet 20 through the steel grating 22. The contaminated water introduced into the inlet 20 is primarily filtered by the wood chip pack 25. In this case, since the fine earth sand or heavy metal is adsorbed or filtered on the wood chip pack 25, particulate and dissolved nonpoint sources of polluted water are removed. The contaminated water passing through the wood chip pack 25 moves to the filter part 30 through the filter part inlet hole 31. In addition, some contaminated water passes through the wood chip pack 25 and then passes through the gravel layer 26 and the sand layer 27 to remove the non-point source. In addition, the contaminated water passing through the sand layer 27 passes through the crushed stone storage layer 55 and then penetrates underground through the underground induction part 50. In addition, when rain or rain falls, when the contaminated water in the inlet 20 is filled, the contaminated water flows into the filter unit 30 through the connection groove 32.

The contaminated water introduced through the filter medium inlet hole 31 moves to the gravel layer 36 and the sand layer 37 through the hole pipe 39. In particular, as shown in Figure 1, the hole tube 39 is disposed in three stages so that the contaminated water passing through the hole tube 39 in each position is moved to the inside of the filter medium (30). Therefore, the polluted water discharged from the hole pipe 39 passes through the gravel layer 36 and the sand layer 37 to remove the non-point source. The contaminated water from which the non-point source is removed is discharged through the filter medium outlet hole 34. Move to the outlet 40. In addition, a part of the contaminated water from which the non-point source is removed is penetrated underground through the crushed stone reservoir 55 and the underground induction part 50. In addition, the contaminated water flowing through the connecting groove 32 or directly flowing through the overflow layer 33 is preferentially passed through the wood chip pack 35 to remove particulate and dissolved non-point sources, and secondary. As it passes through the gravel layer 36 and the sand layer 37 in order to be filtered, the filter medium flows into the outlet 40 through the outlet hole 34 or the crushed stone storage layer 55 and underground guide 50 Penetrates underground through. In addition, the contaminated water moving to the overflow layer 33 is moved to the outlet 40 through the connection groove 32 '. Since the filter unit 30 is formed to be inclined, the contaminated water increases the filtration rate by the action of gravity as well as the inflow force and prevents the contaminated water.

The contaminated water introduced into the outlet 40 is discharged to the outside through the outlet pipe 41. In addition, the contaminated water introduced into the outlet 40 through the steel grating 22 ′ formed at the upper end is also discharged to the outside through the outlet pipe 41. Similarly, the contaminated water may penetrate underground through the crushed stone reservoir 55 and the underground induction part 50 formed at the lower portion of the outlet 40.

That is, the operation of the infiltration ditch having a natural water circulation and non-point pollution reduction function according to the present invention according to the inflow rainfall is different. 8 to 10 are diagrams for explaining the operation when the small rainfall inflow, the design rainfall inflow and the design rainfall excess inflow of the infiltration ditch having a natural water circulation and non-point pollution reduction function according to an embodiment of the present invention, respectively.

In the case of a small amount of rainfall, as shown in (A) of FIG. 8, the rainwater is introduced into the inlet 20 through the inlet pipe 21 and the wood chip pack 25, the gravel layer 26 and the sand layer in the inlet. The contaminated water, such as rainwater filtered and filtered while passing through 27, penetrates underground through the underground induction part 50 and flows into the filter part 30 through the filter part inlet hole 31 and is filtered. In addition, when the amount of rainwater is increased, as shown in (B) of FIG. 8, the increased contaminated water is not only filtered in the inlet 20, but also through the filter inlet 31. ) And further filtered in the gravel layer 36 and the sand layer 37 in the filter medium 30, and after flowing into the outlet 40 through the filter medium outlet hole 34, the outlet pipe 41. It is discharged to outside through). In addition, a part of the purified polluted water penetrates underground through the underground induction part 50. That is, in the case of a small amount of rainfall, it is mainly purified in the inlet 20 and discharged underground through the underground guide 50 of the inlet 20 and the filter unit 30.

In the case of design rainfall, as shown in FIG. 9A, contaminated water, such as rainwater, flows into the inlet 20 through the inlet pipe 21, and primarily in the inlet 20. It is filtered while passing through the wood chip pack 25, the gravel layer 26 and the sand layer 27 and penetrates underground through the underground induction part 50. In addition, the filter unit is introduced into the filter unit 30 through the inlet hole 31 and in particular, the filter unit 30 is introduced into the filter unit 30 through the hole tube 39. Therefore, it is filtered while passing through the gravel layer 36 and the sand layer 37 in the filter medium 30 and penetrates underground through the underground induction part 50. In addition, the contaminated water filtered by the filter unit 30 is discharged to the outlet unit 40 through the filter unit outlet hole 34 and penetrated underground through the underground guide unit 50 within the outlet unit 40. It is discharged to the outside through the outflow pipe 41.

In addition, when the amount of inflow increases, as shown in (B) and (C) of Figure 9, the contaminated water in the inlet 20 is filtered through the filter inlet 31 and the hole (39) It is introduced into the part 30 and the filtering action is made in the gravel layer 36 and the sand layer 37 in the filter medium 30. The contaminated water flowing into the filter medium inlet hole 31 passes through a wood chip pack 25 that is formed vertically in the inlet 20 to perform a filtration action first. Therefore, the contaminated water flows into the filter medium 30 through the hole tube 39, thereby effectively using the filter medium 30. In addition, the contaminated water flows into the filter unit 30 through the connection groove 32 as well as the filter unit inlet hole 31. Therefore, the contaminated water flowing into the filter medium 30 passes through the wood chip pack 35, the gravel layer 36, and the sand layer 37 in the filter medium 30. The wood chip pack 35, the gravel layer 36, and the sand layer 37 may have different sizes, such as sizes, to suit the design quantity. In addition, the size and quantity of the filter inlet hole 31 and the connecting groove 32 is adjusted to allow the inlet 20 and the filter unit 30 to treat the contaminated water of the designed quantity.

When the design quantity is exceeded, as shown in FIG. 10, the contaminated water exceeding the design quantity is introduced into the filter part 30 through the connection groove 32 and the contaminated water introduced is the filter part 30. It moves through the inner overflow layer 33 and flows into the outlet 50 through the connection groove 32 '. Therefore, the contaminated water exceeding the design quantity is not filtered at the inlet 20 and the filter unit 30, but is introduced into the outlet 40 and discharged to the outside through the outlet pipe 41. Therefore, the size, arrangement, and arrangement of the inlet part 20, the filter part 30, and the outlet part 40 vary according to the design quantity.

As described above, the soil soil tillage device according to the present invention has been described with reference to the drawings, but the present invention is not limited by the embodiments and drawings disclosed herein, but within the scope of the technical idea of the present invention. Of course, various modifications may be made by those skilled in the art.

20: inlet 21: inlet tube
22, 22 ': Steel grating 25: Woodchip pack
26: gravel layer 27: sand layer
28: nonwoven fabric 30: filter media
31: Inlet hole 32, 32 ': connecting groove
33: overflow layer 34: filter medium outflow hole
35: wood chip pack 36: gravel layer
37: sand layer 38: nonwoven fabric
39: Yugong Hall 39 ': Yugong Hall
40: outlet 41: outlet pipe
50: underground guide portion 51: underground guide hole
52: underground guide pipe 55: crushed reservoir layer

Claims (13)

An inlet 20 having an inlet pipe 21 formed on one side thereof so that the contaminated water is introduced;
Filtration layer is formed therein and contaminated water in the inlet part 20 flows into one side of the filtration layer or flows into the upper part of the filtration layer, and the filter medium outlet hole 34 on the other side so that the filtered contaminated water flows out. The filter medium 30 is formed; And
Infiltration having a natural water circulation and non-point pollution reduction function, including; an outlet portion 40 having an outlet pipe 41 formed on one side thereof so that the contaminated water introduced through the filter medium outlet hole 34 flows out to the outside. ditch.
The method of claim 1,
A plurality of filter part inlet holes 31 are formed at one side of the filter part 30 so that the contaminated water in the inlet part 20 flows into one side of the filter part 30, and the inlet part 20 is formed. ) A penetration groove having a natural water circulation and non-point pollution reducing function, characterized in that the connection groove 32 is formed at one upper end of the filter medium 30 so that the contaminated water flows into the upper portion of the filter medium 30. .
The method of claim 1,
Wood chip pack 25 is formed horizontally in the inlet 20 to filter the contaminated water in the inlet 20, in the inlet 20 is introduced into one side of the filter medium (30) Penetration groove having a natural water circulation and non-point pollution reducing function, characterized in that formed in the vertical in the inlet 20 so that contaminated water is filtered.
The method of claim 1,
Penetration groove having a natural water circulation and non-point pollution reduction function characterized in that the gravel layer 26 or the sand layer 27 is formed in the lower portion of the inlet 20.
The method of claim 1,
The filtration layer has a natural water circulation and non-point pollution reduction function characterized in that the plurality of gravel layer 36 and the sand layer 37 is formed to cross.
The method of claim 5,
Wood chip pack 35 is formed on the gravel layer 36 located in the upper penetration penetrating combines natural water circulation and non-point pollution reduction function.
The method of claim 1,
A plurality of perforated pipes 39 are arranged horizontally in the interior of the filter part 30 so that the contaminated water introduced through one side of the inlet part 20 moves into the filter part 30. Penetration ditch with natural water circulation and non-point pollution reduction.
The method of claim 7, wherein
The perforated pipe 39 has a natural water circulation and non-point pollution reduction function characterized in that the length is longer toward the bottom.
The method of claim 1,
Penetration groove having a natural water circulation and non-point pollution reduction function characterized in that the steel grating 22, 22 'is formed on the upper end of the inlet 20 or outlet 40 so that the contaminated water flows from the outside. .
The method of claim 1,
The filter medium 30 has a natural water circulation and non-point pollution reducing function characterized in that the inclined downward downward.
The method of claim 1,
Natural water circulation, characterized in that the underground induction portion 50 is formed in the lower portion of any one of the inlet 20, the filter unit 30 and the outlet 40 to guide the filtered polluted water underground. Penetration ditch with non-point pollution reduction function.
The method of claim 11,
The underground induction part 50 is inserted into the underground induction hole 51 and the underground induction hole 51 formed below any one of the inlet part 20, the filter part 30, and the outlet part 40. Penetration groove having a natural water circulation and non-point pollution reducing function, characterized in that it consists of an underground guide pipe (52).
The method of claim 11,
An infiltration ditch having a natural water circulation and non-point pollution reduction function, characterized in that the crushed stone layer 55 is formed on the underground induction part 50.

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