KR20120095767A - Non-point contaminants purification system for treating first rain - Google Patents

Abstract

PURPOSE: A facility for treating the non-point pollutants of initial rainwater is provided to completely separate and eliminate suspended impurities and grease and to form the generation of vortex by introducing water to a tangential direction. CONSTITUTION: A facility for treating the non-point pollutants includes a screen chamber(100), a filtering chamber, a second partition, and a filtering unit. The screen chamber includes an inlet(130), a cylindrical screen(120), a comb-shaped screen(150), and a drain(140). A rainwater inlet and a treated water outlet are installed at both sides of the screen chamber. The cylindrical screen primarily filters solid materials from rainwater. The comb-shaped screen secondarily filters the primarily filtered rainwater. The second partition connects the screen chamber and the filtering chamber based on the drain. The filtering unit is arranged at the filtering chamber. The filtering unit defines a space between the drain and the outlet.

Description

NON-POINT CONTAMINANTS PURIFICATION SYSTEM FOR TREATING FIRST RAIN}

The present invention relates to an initial excellent non-point pollutant treatment equipment, and more specifically, to separate and remove oils and suspended solids through a cylindrical screen with a plate that can increase the vortex formation, comb-type screen having a comb A screen chamber having a flow of upflow by means of which the solids can be efficiently removed at the same time, and a buffer chamber which is formed at the bottom of the screen chamber and communicates with the screen chamber up and down by a drainage through hole of the wedge screen, A second water filtration chamber having a sloped drain plate formed on one side wall, and a continuous water channel communicating with the second filtration chamber and the sloped drain plate, and comprising a filtration chamber having a filter plate formed at the center of the channel. It is about.

In general, nonpoint source refers to a source that emits unspecified water pollutants at an unspecified place as a city, road, farmland, mountainous area, or construction site. On the other hand, point source refers to the source of pollutants that are easy to collect because of the cleared outflow path of pollutants. Non-point source is difficult to collect because the discharge and discharge paths of pollutants are not clearly distinguished and it is difficult to collect and the amount of generation is highly dependent on weather conditions such as precipitation. And there is a problem that is difficult to maintain.

Non-point sources such as fertilizers and pesticides remaining in agricultural lands, untreated livestock waste from livestock farms, untreated livestock waste discharged from livestock farms, air pollutants mixed with rainwater, and road surface sediments It has the characteristic of flowing down to rivers with rainwater.

Therefore, non-point sources contaminate the water quality by being introduced into the stream without any special treatment along with rainfall, thereby causing fish to collectively die or destroy habitats of benthic organisms, causing aquatic ecosystems to be disturbed.

Moreover, the recent increase in impermeable layers caused by land development increases the amount of rainwater that is not absorbed or evaporated into the soil during rainfall, increasing the risk of flooding and reducing the groundwater replenishment. It can also be a trigger.

In particular, in the case of non-point pollution in urban areas, the area of green and permeable layers is decreasing in urban areas, and the area of impermeable layers is increasing instead due to the development of residential lands, and due to the increase in traffic volume, population expansion, etc. Pollutants that have been adsorbed on the back and drifted together during the rainy season, do not pass through the impervious surface, flow like rainwater, and flow into the stream at once. While the risk of flooding is increasing, there is a problem that the river becomes dry stream due to lack of river maintenance water during the dry season. In addition, residential districts, roads, etc. generally emit not only suspended solids (SS) and nutrients but also bacteria and metallic substances and some organic toxic substances.

On the other hand, when looking at the movement of the non-point source in rainy weather, the first-flush effect has the highest concentration of pollutants emitted during the initial rainfall as the particulate pollutants deposited on the surface of the surface are swept away by rainwater ) And concentration decreases as rainfall continues. That is, rainfall runoff contains high concentrations of organic and various toxic substances, which can be the main cause of destruction of river ecosystems such as fish population death and water pollution.

Since these nonpoint sources are dispersed in large areas and concentrated only during rainfall, they have not recognized the seriousness of the problem as a source of pollution, but today, due to environmental pollution, the toxicity of nonpoint sources is highlighted along with acidification of rainwater. This has attracted attention, and in particular, the effluent from the first-flush that occurs during the early rainfall has a high concentration of pollutants and a high probability of containing toxic substances such as heavy metals. It is required.

In general, the facilities that are applied as non-point source treatment facilities are largely divided into natural type and device type. Natural type treatment facilities include artificial wetland, storage facility, infiltration facility, vegetation type facility, etc. Filtration type used, vortex type using vortex, and screen type.

The storage non-point source treatment facility is capable of large-capacity treatment of rainwater, but has a problem that is difficult to apply to the urban areas where space is insufficient because the treatment facility must be large.

In addition, in the case of the filtration type of the device type treatment facility, it is possible to remove suspended solids and contaminants attached to the solids, but it is not suitable for large drainage areas, and it is difficult to maintain and maintain maintenance costs due to regular replacement of filter media. In addition, it is not desirable for construction sites, rural areas, mountainous areas where large amounts of earth and sand are discharged.

On the other hand, the vortex type is capable of large-scale flow rate treatment and separate treatment of sediment and suspended matter, but it is difficult to remove fine particles (50 ~ 100㎛) and dissolved substances, and the removal effect is insufficient when the flow rate fluctuates. On the other hand, the screen-type method can be applied to small and large capacity, easy to maintain, and to remove the colloids, but it is difficult to remove dissolved substances, so the treatment items are limited and the water treatment effect is insufficient. There is a drawback to the need for regular solid removal.

In general, the initial rainwater and sewage overflow water (CSOs) contain a large amount of contaminants in addition to the earth and sand, there is a problem that occurs such as clogging of the filter in the subsequent process if the coarse solids are not removed smoothly when the first inflow.

The present invention has been made to solve the above problems, to provide an initial excellent non-point pollutant treatment equipment that can increase the vortex formation for the smooth removal of coarse solids during the initial inflow of the excellent rainwater and sewage overflow. There is this.

In addition, an object of the present invention is to provide an excellent non-point pollutant treatment facility having an upstream flow by a comb-shaped screen and capable of efficiently removing fine solids at the same time.

In addition, there is provided a lifting device that can easily take out the solids loaded on the bottom to the outside, the purpose is to provide an excellent initial non-point pollutant treatment equipment easy to maintain.

In addition, it is an object of the present invention to provide an excellent non-point pollutant treatment equipment that is economical by operation of the non-powered operation, easy to install and easy to install, and increased convenience in an integrated structure.

In addition, the present invention is to pay attention to the very efficient management of the initial rainfall runoff in order to block the inflow of non-point source of the river, the object of the present invention is to provide a non-point pollutant treatment equipment of the initial excellent rain blocking the inflow of the non-point source of rain. .

In order to achieve the above object, in the present invention, a contaminated rainwater inlet is mounted on one side, and a cylindrical screen for firstly separating the solids in the rainwater introduced through the inlet is separated into the chamber body. And a comb-type screen for separating and separating the rainwater firstly filtered through the cylindrical screen, and a drain hole for discharging the treated water from which pollutants are separated by the cylindrical screen and the comb-type screen. A screen chamber installed at the wall, a filtration chamber having an outlet formed on one side wall, a second partition wall connecting the screen chamber and the filtration chamber to each other by the drain port, and a space provided between the drain port and the outlet port provided at the filtration chamber. Non-point contaminants of the initial excellent rain, characterized in that it comprises a filtration device for partitioning The treatment system is provided.

The screen chamber is buried in the ground, the lower portion of the cylindrical chamber body is provided with a collecting unit for collecting solids, the solid storage box is provided to collect and store the solids stored in the collecting unit and removed from the rain, the It is installed inside the cylindrical screen, and may further include a vortex forming plate for increasing the vortex formation of rainwater flowing through the inlet.

The cylindrical partition wall is formed inside the chamber to surround the cylindrical screen, and the comb-shaped screen is installed to connect the lower portion of the partition to the outer cylinder of the chamber, and the treated water passing through the cylindrical screen moves from the bottom to the top. While passing through the comb-type screen again it can be removed by precipitation of the fine solids.

Here, the comb-shaped screen is comb teeth are formed at a tighter interval than the cylindrical screen to filter the micro-solids passing through the cylindrical screen, '<<<' shaped comb teeth may be formed at a predetermined interval.

In addition, the comb-shaped screen may be formed of a double screen, the comb in the '＼' direction is formed on the lower screen, the comb in the '/' direction may be formed on the upper screen.

In the present invention, the inlet is installed in the tangential direction of the cylindrical screen can be introduced into the rainwater.

As a lifting device for easily carrying out the solid matter collected in the solid matter collecting box, a wire connected to the ground or a position close to the ground may be further installed.

In addition, the vortex forming plate is spirally connected from the inlet to the lower portion of the cylindrical screen, formed to match the inner diameter of the cylindrical screen can flow down the vortex forming plate flowing through the inlet.

The vortex forming plate may have a through hole so that rainwater or solids may fall downward.

The filtration device is horizontally arranged to partition the upper and lower sides of the filtration chamber, the horizontal support plate having a plurality of mounting holes, a plurality of through-holes are formed, the filter medium form retaining member is mounted on the mounting hole of the horizontal support plate; It may be made to include a filter medium which is attached to the filter medium shape maintaining member to maintain its shape.

The filter medium shape holding member is formed with at least a plurality of outer through-hole outer support portion of the tubular shape extending up and down, the lower connection portion bent inwardly from the lower end of the outer support portion, a plurality of inner through hole is formed It extends from the inner edge of the lower connection portion to the upper end and comprises a tubular inner support portion provided inside the outer support portion, wherein the filter medium is the outer side of the outer support portion and the lower side of the lower connection portion and the inner side of the inner support portion It may be a structure covering the.

According to the present invention as described above, the inlet of the screen chamber is installed in the tangential direction of the cylindrical screen and the vortex forming plate is installed inside the cylindrical screen, the influent flows in the tangential direction to further increase the vortex when forming the vortex Since it is possible to form, there is an effect capable of complete separation and removal of solids such as oils and grease, suspended contaminants.

In addition, since the treated water that primarily passed through the cylindrical screen is passed through the comb-shaped screen once more from the bottom to the top flow there is an excellent effect of removing the fine solids.

In addition, there is an effect of reducing the power cost by the operation of the non-power, it is easy to manufacture and install in an integrated structure has the low installation cost effect.

In addition, the initial rainfall runoff is managed efficiently. There is an advantage that the initial excellent non-point pollutant treatment equipment that blocks the inflow of non-point source in the rain during the early rain is provided.

1 is an exploded perspective view showing a screen chamber of a non-point pollutant treatment facility of the present invention;
Figure 2 is a longitudinal sectional view showing a screen chamber of the non-point pollutant treatment facility of the present invention,
3 is a longitudinal sectional view showing a first embodiment of a non-point pollutant treatment plant of the present invention;
Figure 4 is a plan view showing a first embodiment of the non-point pollutant treatment facility of the present invention,
5 is a longitudinal sectional view showing an influent circulation in the screen chamber of the present invention;
Figure 6 is a longitudinal cross-sectional view showing that the solids in the screen chamber of the present invention in the solids box,
7 is a longitudinal sectional view showing the solids carried out from the screen chamber of the present invention;
8 is a longitudinal sectional view showing a second embodiment of a non-point pollutant treatment plant of the present invention;
9 is a plan view showing a second embodiment of a non-point pollutant treatment plant of the present invention;
10 is a perspective view of a filtration device,
11 is a perspective view of a horizontal support plate of the filtration device,
12 is a cross-sectional structural view of the filter medium attached to the mounting hole of the horizontal support plate;
13 is a perspective view and a conceptual sectional view of the filter medium form retaining member;
14 is a perspective view and a conceptual sectional view of the filter medium.

Hereinafter, the present invention will be described with reference to the drawings. In the following description of the present invention, a detailed description of related arts or configurations will be omitted when it is determined that the gist of the present invention may be unnecessarily obscured will be.

The terms to be described below are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators, and the definitions should be made based on the contents throughout the specification for describing the present invention.

1 is an exploded perspective view showing a screen chamber of a non-point pollutant treatment plant of the present invention, Figure 2 is a longitudinal sectional view showing a screen chamber of the non-point pollutant treatment plant of the present invention, Figure 3 is a non-point pollution of the present invention 4 is a longitudinal sectional view showing the first embodiment of the substance treatment plant, and FIG. 4 is a plan view showing the first embodiment of the non-point pollutant treatment plant of the present invention.

As shown in the figure, the present invention is a non-point pollutant treatment facility of the initial excellent divided into the screen chamber 100 and the filtration chamber 300.

The screen chamber 100 and the filtration chamber 300 separate and filter the contaminants of the initial downpour during rain as part of a continuous channel.

Screen chamber 100 is formed with a chamber body 110 formed in a substantially cylindrical shape, is equipped with an inlet 130 for rainwater flows into the chamber body 110, the other side is treated water separated pollutants The drain port 140 is discharged to the outside is mounted.

The chamber body 110 includes a lid (2) detachably coupled to the upper opening, the lid (2) is opened and closed to clean the solids such as impurities and suspended matter accumulated in the chamber body (110) To lose.

The chamber body 110 according to the present invention is embedded in the ground, and as shown in FIG. 1, a collecting unit 112 for collecting solids is provided integrally at the bottom.

A cylindrical screen 120 is installed inside the chamber body 110, and the cylindrical screen 120 is installed inside the chamber body 110 to have excellent suspended solids or solids introduced through the inlet 130. In order to primarily filter the separation, the solid collecting unit 112 is located at the bottom of the cylindrical screen 120.

The inlet 130 is mounted on one side of the chamber body 110 to guide the contaminated rainwater into the cylindrical screen 120, so that the end of the inlet 130 communicates with the cylindrical screen 120. It is installed, in the present invention is characterized in that the inlet 130 is installed in the tangential direction of the cylindrical screen 120.

That is, as shown in Figure 4, the inlet 130 is installed in communication with the cylindrical screen 120 to guide the rainwater into the interior of the cylindrical screen 120, by being installed in the tangential direction of the cylindrical screen 120 The contaminated rainwater induced from the inlet 130 to the cylindrical screen 120 forms an efficient vortex within the screen.

This can form a vortex that is further increased than the vortex formed by the inlet by the conventional simple central rotary cylinder, so that the separation and removal of oils, grease, and floating contaminants can be performed smoothly.

In addition, a vortex forming plate 170 is installed inside the cylindrical screen 120 to increase vortex formation of rainwater flowing through the inlet 130.

As shown in FIG. 1, the vortex forming plate 170 is a plate spirally connected from the inlet port 130 to the lower portion of the cylindrical screen 120, and is formed to fit the inner diameter of the cylindrical screen 120. The rainwater flowing through the inlet 130 flows along the vortex forming plate 170 to maximize the vortex.

In the first embodiment of the present invention, the vortex forming plate 170 is formed as a flat plate, and the through hole 172 is formed in the vortex forming plate 170 so that rainwater or solids may fall downward. The through hole 172 is preferably formed at a predetermined interval, the size or number is not limited in the present invention.

On the other hand, the comb-shaped screen 150 is provided in the chamber body 110 so as to filter the rainwater filtered primarily through the cylindrical screen 120.

As a structure for installing the comb-shaped screen 150, a cylindrical partition 114 having a shape surrounding the cylindrical screen 120 is installed inside the chamber body 110.

The partition wall 114 is formed in a cylindrical shape concentric with the cylindrical screen 120, and is installed at a predetermined distance from the cylindrical screen 120.

The comb-shaped screen 150 is installed to connect the lower portion of the partition wall 114 and the outer cylinder of the chamber body 110, the comb-shaped screen 150 is a comb teeth of the '<<<' shape at a predetermined interval The screen is formed.

In the first embodiment of the present invention, as shown in the enlarged view in FIG. 2, the comb-toothed screen 150 is formed of dual screens 151 and 152, and is disposed in a '에' direction on the lower screen 152. Comb 154 is formed, and the comb 153 of the '/' direction is formed on the upper screen 151 to filter the suspended matter.

Such comb-shaped screen 150 is preferably formed with a comb teeth at a tighter spacing than the cylindrical screen 120 to filter out the micro-solids passed through the cylindrical screen 120.

In the chamber body 110 of the present invention as shown in FIG. 5, the treated water flowing down the chamber body 110 while passing through the cylindrical screen 120 moves upward from the lower portion of the chamber body 110. By passing through the comb-shaped screen 150 again will be able to remove the fine solid precipitated.

As such, the treated water from which the contaminated solid is separated through the comb-shaped screen 150 is discharged through the drain 140, and the solid 10 is collected by the gravity and vortex at the bottom of the solid collecting part 112. ) Is captured.

The collecting unit 112 accommodates a solid collecting box 160 for collecting and storing the solid 10 removed from the rainwater.

The solid collecting box 160 of the present invention is positioned below the cylindrical screen 120 and performs a function of collecting and storing the solids removed by the cylindrical screen 120 and the comb-shaped screen 150.

More specifically, the solids smaller than the opening of the cylindrical screen 120 is precipitated downward by the vortex and stored in the solid collecting box 160, and the solids larger than the opening of the cylindrical screen 120 are lowered by the vortex and gravity. Precipitated to and stored in the solid collection box 160.

In the present invention, the lifting device for easily carrying out the solids 10 collected in the solids collecting box 160, by installing a wire 162 connected to the ground or close to the ground collecting box 160 periodically The solids 10 can be removed.

The treated water discharged from the drain 140 is introduced into the filtration chamber 300.

That is, the relatively large particles are filtered in the screen chamber 100, and the treated water passing through the screen chamber 100 moves to the filtration chamber 300.

A second partition 310 is provided to communicate the screen chamber 100 and the filtration chamber 300 with each other by the drain port 140.

The filtration chamber 300 is provided with a filtration device 320 for partitioning the space between the drain 140 and the outlet 301.

Therefore, the rainwater introduced through the drain 140 is necessarily filtered out of the filtration device 320 and then flows out through the outlet 301.

In the present embodiment, the filtration device 320 includes a filter plate formed of a fiber membrane, and the filtration device 320 is a component that performs fine purification.

The filter plate is known in the pre-registration technology (Patent Registration 10-0750461), the same or similar in this embodiment is used, and also to install the filter plate in the form of a zigzag to improve the purification ability of the filter plate is also known Same as the pre-registered technology. Therefore, the technical matters described in Patent Registration No. 10-0750461 are considered to be integrated in the present specification, and may be appropriately applied to the present invention.

Hereinafter, a second embodiment according to the present invention will be described.

8 is a longitudinal sectional view showing a second embodiment of the non-point pollutant treatment plant of the present invention, FIG. 9 is a plan view showing a second embodiment of the non-point pollutant treatment plant of the present invention, and FIG. 11 is a perspective view of a horizontal support plate of the filtration apparatus, FIG. 12 is a cross-sectional structural view of the filter medium mounted to the mounting hole of the horizontal support plate, FIG. 13 is a perspective view and a conceptual sectional view of the filter medium form retaining member, and FIG. It is a perspective view and a conceptual sectional drawing of a filter medium.

In this embodiment, only portions different from those in the first embodiment will be described.

In the present embodiment, the configuration of the filtration device 320 is different from that of the first embodiment.

The filtration device 320 according to the present embodiment includes a horizontal support plate 321, a filter medium shape holding member 322, a filter medium 323, and the like.

The horizontal support plate 321 is arranged horizontally to partition the upper and lower sides of the filtration chamber 300.

In addition, a plurality of mounting holes 321a are formed in the horizontal support plate 321.

A filter medium shape holding member 322, a filter medium 323, and the like are mounted to each mounting hole 321 a.

The filter medium shape maintaining member 322 is to maintain the shape of the filter medium 323 and may be made of plastic, metal, or the like.

The filter medium shape holding member 322 has an upper edge thereof mounted in the mounting hole 321a of the horizontal support plate 321.

In addition, a plurality of through holes are formed in the filter medium shape maintaining member 322 to provide a path through which the rainwater passing through the filter medium 323 can flow.

The filter medium shape holding member 322 may be manufactured by processing a wire mesh or using a porous tube.

As the filter medium 323, a nonwoven fabric or the like may be used, and the filter medium 323 may be mounted on the filter medium shape maintaining member 322 to maintain its shape. Such a filter medium shape holding member 322 has a structure as follows to secure the filtration area of the filter medium 323 to the maximum.

The filter medium shape holding member 322 includes a first mounting portion 322a, an outer support portion 322b, a lower connection portion 322c, an inner support portion 322d, and a second mounting portion 322e.

The outer support portion 322b has a plurality of outer through-holes are formed in the form of tubes extending vertically long.

At the upper end of the outer support part 322b, a first mounting part 322a for mounting to the mounting hole 321a is bent outwardly.

The lower connection portion 322c is formed while bending inwardly from the lower end of the outer support portion 322b. The lower connection part 322c performs a function of connecting the outer support part 322b and the inner support part 322d, and it is preferable that the lower connection part 322c has a relatively large through hole formed therein. If a large sized through hole is formed in the lower connection portion 322c, when the filter medium 323 is separated from the filter medium shape maintaining member 322 for cleaning, foreign matter accumulated on the upper portion of the lower connection portion 322c may be easily discharged to the lower portion. Can be.

The inner support portion 322d is formed in a plurality of inner through-holes and extends upwardly from the inner edge of the lower connection portion 322c, and is provided inside the outer support portion 322b.

The second mounting portion 322e is formed while the upper edge of the inner support portion 322e is bent and extended inward.

When the filter medium 323 is attached to the filter medium shape maintaining member 322 having such a structure, the filter medium 323 is at least the outer side of the outer support part 322b, the lower side of the lower connection part 322c, and the inner support part 322d. It has a structure that can cover the inside.

Therefore, the filter medium 323 exerts a filtration function in each of the surfaces in contact with the outer support portion 322b and the inner support portion 322d. Since the filter area in the form of two tubes exists in one mounting hole 321a, the filtration is performed. The efficiency is doubled.

In order to mount the filter medium shape holding member 322 and the filter medium 323 in the mounting hole 321a, two assembly bars 324 are provided on the upper surface of the filter medium shape holding member 322 in a cross shape, and a second mounting part is provided. The lower surface of the 322e is provided with a filter medium support plate 325 in the form of a disk.

A fixing bolt is integrally formed at the center of the upper surface of the filter medium support plate 325.

The first mounting portion 322a of the filter medium shape retaining member 322 and the upper edge of the filter medium 323 are bolted to both ends of the two assembly bars 324 and the mounting hole 321a, and also the filter medium shape retaining member 322. ), The second mounting portion 322e and the upper center portion of the filter medium 323 are bolted to the center of the two assembly bars 324 and the filter medium support plate 325.

Such an assembly structure is very easy to assemble and dismantle the filter medium shape holding member 322 and the filter medium 323 is very convenient for their maintenance.

According to the above structure, the apparatus forms a flow path consisting of the screen chamber 100 and the filtration chamber 300 at the initial rainwater in which the contaminants are concentrated in a small amount of inflow water, and the initial rainwater purification operation ( Remove debris).

That is, the rainwater introduced into the cylindrical screen 120 through the inlet 130 forms an efficient vortex in the screen through the vortex forming plate 170.

The rainwater filtered primarily through the cylindrical screen 120 is to pass through the comb-shaped screen 150 again while moving from the bottom to the top of the chamber body 110 to precipitate and remove the fine solids.

As such, the treated water from which the contaminated solid is separated through the comb-shaped screen 150 is discharged through the drain 140, and the solid 10 is collected by the gravity and vortex at the bottom of the solid collecting part 112. ) Is captured.

The treated water introduced into the filtration chamber 300 flows out from the filtration chamber 300 to the outlet 301 through the filtration device 320.

Embodiments shown for the purpose of the present invention described above is only one embodiment in which the present invention is embodied, it can be seen that various forms of combinations are possible to realize the gist of the present invention as shown in the drawings.

Therefore, the present invention is not limited to the above-described embodiments, and various changes can be made by any person having ordinary skill in the art without departing from the gist of the present invention as claimed in the following claims. It will be said that the technical spirit of this invention is to the extent possible.

100: screen chamber 110: chamber body
112: solids collecting portion 114: partition wall
120: cylindrical screen 130: inlet
140: drain hole 150: comb-type screen
160: collection box 170: vortex forming plate
300: filtration chamber 320: filtration apparatus
321: horizontal support plate 322: filter medium shape retaining member
323: filter medium 325: filter medium support plate

Claims (10)

An inlet through which the contaminated rainwater flows in is mounted on one side, and a cylindrical screen is provided inside the chamber body to separate the solids in the rainwater introduced through the inlet, and is primarily filtered through the cylindrical screen. A screen chamber having a comb-type screen for separating the second rainwater and a drainage port for discharging the treated water from which the pollutant is separated by the cylindrical screen and the comb-type screen;
A filtration chamber formed with an outlet at one side wall;
A second partition wall for communicating the screen chamber and the filtration chamber with each other by the drain hole;
And an filtration device provided in the filtration chamber to partition a space between the drain port and the outlet port. The method of claim 1,
The screen chamber is embedded in the ground, provided with a collecting portion for collecting the solids in the lower portion of the cylindrical chamber body,
A solids collecting box which is stored in the collecting unit and collects and stores the solids removed from the rainwater is provided,
It is installed inside the cylindrical screen, the initial excellent non-point pollutant treatment equipment further comprises a vortex forming plate for increasing the vortex formation of rainwater flowing through the inlet. The method according to claim 1 or 2,
A cylindrical partition wall is formed inside the chamber body to surround the cylindrical screen.
The comb-shaped screen is installed to connect the lower portion of the partition and the outer cylinder of the chamber,
The treated water passing through the cylindrical screen is passed through the comb-type screen again while moving from the bottom to the upper portion of the initial excellent non-point pollutant treatment equipment, characterized in that to precipitate and remove the fine solid. The method of claim 1,
The comb-type screen is the initial excellent non-point pollutant treatment equipment, characterized in that the comb teeth are formed at a tighter interval than the cylindrical screen to filter the fine solids passing through the cylindrical screen. The method of claim 1,
The comb-type screen is a non-point pollutant treatment facility of the initial excellent, characterized in that the comb teeth of the '<<<' shape is formed at a predetermined interval. The method of claim 1,
The comb-shaped screen is formed of a double screen,
An initial excellent non-point pollutant treatment facility, characterized in that the comb teeth in the '＼' direction is formed on the lower screen, the comb teeth in the '/' direction is formed on the upper screen. The method of claim 1,
The inlet is a non-point pollutant treatment facility of the initial excellent, characterized in that installed in the tangential direction of the cylindrical screen. The method of claim 1,
An initial excellent non-point pollutant treatment facility as a lifting device for easily carrying out the solid matter collected in the solid collection box, the wire is connected to the ground or close to the ground. The method of claim 1,
The vortex forming plate is spirally connected from the inlet to the lower portion of the cylindrical screen, and formed to match the inner diameter of the cylindrical screen, the rainwater flowing through the inlet flows down the initial excellent water, characterized in that flowing along the vortex forming plate Non-point pollutant treatment facility. 10. The method of claim 9,
The vortex forming plate is an excellent initial non-point pollutant treatment facility, characterized in that the through-hole is formed so that the rain or solid falls to the bottom.

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