KR100896056B1 - Excellent treatment system - Google Patents

Abstract

The present invention relates to an excellent treatment apparatus for treating non-point pollution source contaminants in rain water, comprising an inlet through which rainwater flows and a plurality of filtration holes through which the rainwater flowing into the inlet passes and is filtered, A first filtration unit to be primarily filtered; A spinning up pre-swirling section for swirling the primary filtered out stream to settle the contaminants in the primary filtered out stream; And a second filtration unit for forming a plurality of voids through which the rainwater passes and secondly filtering the rainwater that has passed through the rotation settling unit. Thus, the pollutants of the non-point pollution source included in the initial rainfall occurring during rainfall are removed and discharged, so that the water pollution can be prevented in advance and can be easily maintained.

Description

[0001] RAINWATER TREATMENT EQUIPMENT [0002]

TECHNICAL FIELD The present invention relates to a water treatment apparatus as a water pollution prevention technology, and more particularly, to a water treatment apparatus for reducing a non-point source included in an initial waterfall occurring during rain.

In recent years, there has been a growing awareness that the management of point pollution sources and the management of non-point pollution sources are indispensable for the environmental preservation of efficient public waters.

Point pollution sources are pollution sources such as domestic sewage, industrial wastewater and livestock wastewater which have clear discharge points, and nonpoint pollution sources are pollution sources such as forests, grasslands, construction sites, agricultural lands, river sediments, roads and industrial sites, The source of pollutants.

Since non-point pollutants are not only widely discharged, but also run out along with rainfall runoffs in rainfall, daily and inter-seasonal emissions vary widely, are difficult to predict and quantify, and are affected by weather conditions, geology and topography.

Especially, the nonpoint pollution sources that have remained on the surface of the earth are washed away by rainwater in a rainy season, which flows into public water bodies such as rivers, rivers, inner lakes, and lakes and pollutes the water quality and acts as a main factor for destroying the ecosystem.

According to the comprehensive measures for water management in the Four Rivers, it is estimated that the pollution load occupied by nonpoint pollution sources in the total water pollution source reaches 22 ~ 37%, and the nonpoint pollution source accounts for 44.5% of the total discharge load. Which is a significant influence.

As facilities for removing these non-point sources, there are vegetation purification waters, vegetation filtration basins, artificial wetlands, device-type facilities, reservoirs, apparatus type + reservoirs, infiltration ditches, and infiltration reservoirs. However, it is difficult to install non-point pollution source removal facilities other than the device-type facilities in a city area where the installation site is limited. Also, among the apparatus-type facilities, there is a demand for a facility capable of high-efficiency processing, requiring a small area and easy maintenance.

According to the present invention, it is possible to prevent water pollution by removing contaminants from a non-point pollution source included in an initial rainfall occurring in a rainfall and discharging the polluted water, And to provide an excellent treatment apparatus.

According to an aspect of the present invention, there is provided a stormwater treatment apparatus for treating nonpoint pollution source contaminants in stormwater, comprising: an inlet through which stormwater is introduced; and a plurality of filtration holes through which the stormwater introduced into the inlet passes and is filtered A first filtration part in which the storm surge flows and is primarily filtered; A spinning up pre-swirling section for swirling the primary filtered out stream to settle the contaminants in the primary filtered out stream; And a second filtration unit for forming a plurality of voids through which the rainwater passes and secondly filtering rainwater that has passed through the rotation settling unit.

A contaminant storage tank provided below the first filtration unit and storing contaminants filtered by the first filtration unit; And a retention tank provided between the first filtration unit and the rotation settling unit for retaining the primary filtered outflow discharged from the first filtration unit.

Wherein the retention tank is formed with a retention tank inlet through which the primary filtrated stormwater flows into the retention tank and a retention tank discharge port through which the primary filtered stormwater in the retention tank is discharged to the rotary sedimentation section, Is formed to be smaller than the cross-sectional area of the retention tank inlet, the passing speed of the primary filtrate through the retention tank outlet is increased, and the swirling flow of the primary filtrate, which is firstly filtered at the rotating needle, .

The retention tank inflow port is formed at a position higher than the retention tank discharge port, so that the flow of stormwater can be induced using the difference of the head.

The first filtration unit may include a plurality of filtration holes through which the stormwater flows, a plurality of filtration holes through which the stormwater introduced through the inlet passes, and contaminants introduced together with the stormwater are formed, ; And a discharge guide for guiding discharge of the storm that passes through the filtration hole to the outside of the screen.

The discharge guide protrudes obliquely in the direction of the swirling flow on the inner circumferential surface of the screen and protrudes obliquely on the outer circumferential surface of the screen in the direction opposite to the swirling flow of the screen, So that contaminants in the inflowing storm are not caught on the inner circumferential surface of the screen due to the swirling flow inside the screen with a high flow velocity, so that the filtration function can be continuously performed without clogging the filtration ball, Maintenance is also very convenient because there is no need to clean the screen separately.

The inlet is deflected with respect to the center of the screen so that the rain flows in the tangent to the inner periphery of the screen so that the swirling flow of the rainwater flowing into the screen smoothly improves the sedimentation efficiency of the contaminants in the rainwater .

Wherein the inflow pipe has a cross-sectional area larger than a cross-sectional area of the inflow port so that the inflow rate of the inflow into the first filtration unit So that the swirling flow of the swirling flow is smooth in the first filtration part, and the sedimentation efficiency can be improved.

The rotation settling unit includes a settling tank having a rectangular cross-sectional shape; And a rotation induction unit disposed at each corner of the sedimentation tank and guiding the stormwater flowing into the sedimentation tank to swirl.

Here, the retention tank discharge port is disposed adjacent to the inner wall surface on one side of the sedimentation tank, whereby the stormwater flowing into the sedimentation tank can smoothly circulate along the inner wall surface of the sedimentation tank.

The second filtration part is preferably a porous plate composed of 10 to 20 parts by weight of cement based on 100 parts by weight of crushed stones and having a plurality of voids formed therein.

The second filtration part contains at least one of ferric oxide, hydroxide, zeolite, limestone, and expanded clay, so that dissolved contaminants in the storm can be adsorbed.

The porosity of the second filtration part is preferably 25% on average.

The second filtration part increases the porosity toward the rotation settling part so that the contaminant is not adsorbed and filtered only on the surface of the second filtration part but penetrates into the inside of the second filtration part and is adsorbed and filtered to improve the filtration efficiency .

Wherein the pollutant storage tank, the retention tank, and the rotation settling unit are formed of one block, the pollutant storage tank, the retention tank and the rotation settling unit are partitioned by partition walls, the first filtration unit is disposed on the contaminant storage tank, By arranging the second filtration part above the spin settlement part, the size of the device can be minimized and the limitation of the installation space can be reduced.

And the bypass pipe for bypassing the rainwater of the rotary sedimentation unit to the outside of the second filtration unit. Thus, when the inflow flow rate is increased or the second filtration unit is clogged, the load of the rotary sedimentation unit can be reduced.

Therefore, according to the solution of the above-mentioned problem, the pollutants of the non-point pollution source contained in the initial pollution occurring in rainy weather are removed and discharged, so that the water pollution can be prevented in advance and can be easily managed.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 to 6 show a stormwater treatment apparatus according to the present invention.

The apparatus for treating rainwater according to the present invention comprises a first filtration section 11 for firstly filtering rainwater, a spinning-up and sinking section 41 for sinking the contaminants in the firstly filtered rainwater, A contaminant storage tank 31 for storing contaminants filtered by the first filtration unit 11, a first filtration unit 11 and a rotation settling unit 41, And a retention tank 35 provided between them.

The first filtration section 11 is provided with a screen 13 for swirling the rain and filtering the rainwater and a plurality of discharge guides for discharging the rainwater filtered by the screen 13 to the outside of the screen 13 23).

The screen 13 has a hollow cylindrical shape with both open sides as shown in Fig. 4A, and is disposed in an upright position on the top of the pollutant storage tank 31. As shown in Fig. The screen 13 includes a screen main body 15 which swirls and flows through the stormwater introduced into the screen 13 to primarily filter the contaminants introduced into the stormwater, that is, floating matters and contaminants, and discharges them to the outside of the screen 13 And a separating portion 19 provided on the upper portion of the screen main body 15 for separating the outflow from the inflow opening and the first filtered out storm.

The screen main body 15 is provided with a plurality of filtration holes 17 through which the rainwater flowing through the inlet 21 passes and a solid contaminant of a predetermined size or more is filtered. On the other hand, the rain that has flowed into the screen main body 15 swirls along the inner peripheral surface of the screen main body 15. The contaminants introduced into the screen main body 15 are swirled by the swirling flow so that the contaminants having a large specific gravity are settled downwardly of the screen main body 15 and at the same time the specific gravity is small and the fine contaminants are supplied to the respective filtration holes 17 And is discharged to the outside of the screen body 15, i.e., primary filtered.

The separating portion 19 is formed with an inlet 21 through which external rainwater flows. The inlet 21 is biased with respect to the center of the screen 13 so that the bleed flows into the inner circumferential tangential direction of the screen 13. Thus, the swirling flow of the rainwater flowing into the screen 13 is smooth, and the sedimentation efficiency of contaminants in the rainwater can be improved.

The inlet 21 is connected to an inlet pipe 25 for guiding the external storm to the screen 13 of the first filtration part 11. The cross-sectional area of the inflow pipe 25 is formed to be larger than the cross-sectional area of the inflow port 21, thereby increasing the inflow speed of the inflow into the screen 13, The sedimentation efficiency can be improved.

The discharge guide 23 is provided around each of the filtration holes 17 and guides the discharge through the filtration holes 17 to the outside of the screen 13. 4B, the discharge guide 23 is formed on the inner circumferential surface of the screen 13 in an inclined manner in the direction of the swirling flow, and is formed on the outer circumferential surface of the screen 13 so as to be inclined in the opposite direction of the swirling flow have. The contaminants present in the rainwater flowing into the screen 13 do not directly contact with the filtration holes 17 of the screen body 15 and are collected by the screen 13 while swirling along the inner circumferential surface of the screen 13, And the rainwater that has passed through each of the filtration holes 17 is discharged in a direction opposite to the swirling flow direction due to the discharge guide 23. As a result, the rainwater flowing into the screen 13 passes through the filtration hole 17 of the screen 13, and the flow direction thereof is reversed, so that the flow velocity outside the screen 13 becomes smaller than the flow velocity inside the screen 13 . Accordingly, contaminants present in the incoming storm are trapped in the swirling flow inside the screen 13 with a high flow velocity, and do not stick to the inner circumferential surface of the screen 13. This operation makes it possible to perform the filtering function continuously without clogging the filtration holes 17 of the screen 13, and it is not necessary to separately clean the screen 13, which makes maintenance very convenient.

On the other hand, the contaminants settled and filtered by the screen 13 are collected in the contaminant storage tank 31 located at the lower portion of the screen 13, and the rainwater primarily filtered by the screen 13 is discharged to the outside upper end And is introduced into the retention tank 35 through the retention tank inlet 37 located in the retention tank 35.

The primary filtered outflow that has flowed into the retention tank 35 flows into the rotation settling portion 41 through the retention tank discharge port 39. The retention tank discharge port 39 is located at a position lower than the retention tank inflow port 37 so as to have a height difference from the retention tank inflow port 37. This is to induce the flow of stormwater using the difference of the head. Here, it is preferable that the retention tank discharge port 39 is formed adjacent to the bottom of the retention tank 35.

In addition, the cross-sectional area of the retention tank discharge port 39 is formed to be smaller than the cross-sectional area of the retention tank inflow port 37, so that the passing speed of the primaryly filtered storm passing through the retention tank discharge port 39 is increased, The filtration storm smoothes the swirling flow in the rotation settling portion (41) and improves sedimentation efficiency.

The rotary settling portion 41 swirls the primary filtrated stormwater to sediment the contaminant having a large specific gravity present in the primary filtered storm, for example, suspended impurities and contaminants having a specific gravity of 2.6 or more.

The rotary settling portion 41 has a rectangular settling tank 43 and a rotation inducing portion 45 disposed at each corner of the settling tank 43 to guide swirls flowing into the settling tank 43 to swirl.

Although the settling tank 43 in this embodiment has a rectangular cross-sectional shape, the settling tank 43 may have a circular cross-sectional shape.

On the other hand, the retention tank discharge port 39 is disposed adjacent to the inner wall surface on one side of the sedimentation tank 43 so that the stormwater flowing into the sedimentation tank 43 flows smoothly along the inner wall surface of the sedimentation tank 43.

As a result, the primary filtered outflow that has flowed into the settling tank 43 through the retention tank discharge port 39 is swirled along the inner wall surface of the settling tank 43, as shown in FIG. 5, The contaminants having a large specific gravity in the storm are settled to the lower part of the settling tank 43 by the swirling flow and the contaminants having a small specific gravity not settled are passed through the second filtering section 51 located at the upper part of the settling tank 43 together with the storm do.

The second filtration unit 51 secondly filters contaminants in the stormwater through the rotary sedimentation unit 41, that is, fine contaminants that have passed through the first filtration unit 11. The second filtration part 51 is made of 10 to 20 parts by weight of cement based on 100 parts by weight of crushed stone, and has a porous plate shape in which a plurality of voids C are formed. The second filtration part 51 is spaced apart from the bottom of the settling tank 43 and supported by a plurality of supports 53 standing up from the bottom of the settling tank 43. Here, it is more effective that the average porosity of the second filter portion 51 is 25%. The size of the crushed stone is preferably 0.25 to 0.4 mm. The second filtration unit 51 preferably contains at least one of ferric oxide, hydroxide, zeolite, limestone, and expanded clay so as to adsorb dissolved pollutants in the storm.

6, the second filtration portion 51 has a shape in which the gap C increases toward the rotation settling portion 41. In this case, Therefore, the contaminants in the storm that pass through the second filtration section 51 are not adsorbed and filtered only on the surface of the second filtration section 51, but penetrate into the interior of the second filtration section 51 and are adsorbed and filtered. Can be improved.

An outlet tank 55 for discharging the secondarily filtered storm to the outside is disposed on the upper portion of the second filtration unit 51. A discharge pipe 55 for guiding the stormwater, 57) are connected.

The second filtration section 51 of the stormwater treatment apparatus according to the present invention is provided with a plurality of bins for bypassing the rainwater of the rotary sedimentation section 41 to the outside of the second filtration section 51, And the pass pipe 61 is coupled through. The bypass pipe 61 communicates the settling tank 43 and the outlet tank 55 so that the bypass pipe 61 is connected to the rotation settling unit 41 when the inflow flow rate is increased or when the second filter unit 51 is clogged. Of the load. Here, the bypass pipe (61) is connected to the discharge pipe (57) so that the discharge of the discharge port (41) can be bypassed to the discharge pipe (57).

Also, in this embodiment, the pollutant storage tank 31, the retention tank 35, and the rotary sedimentation unit 41 are formed as one block. The contaminant storage tank 31, the retention tank 35, and the rotary settling portion 41 are partitioned by partition walls 65, respectively. The first filtration part 11 is disposed on the upper part of the pollutant storage tank 31 and the second filtration part 51 is disposed on the upper part of the rotation settling part 41. Accordingly, it is possible to minimize the size of the stormwater treatment apparatus and to minimize the required site, thereby reducing the construction cost, and also enabling installation in a downtown area having few available sites.

Here, reference numerals 71a and 71b, which are not illustrated, are maintenance bores for maintaining the first filtering portion 11 and the second filtering portion 51. Although not shown in the drawings, the pollutant storage tank 31 and the settling tank 43 may be provided with manholes for removing pollutants settled in the pollutant storage tank 31 and the settling tank 43, respectively, to the outside.

With this configuration, a description will be made of a process of processing the storm mixed with contaminants of a non-point source in the stormwater treatment apparatus of the present invention.

When the rainwater mixed with pollutants of the non-point pollution source flows into the screen 13 through the inlet 21 of the screen 13 from the inlet pipe 25, the rainwater flowing into the inlet 21 flows into the inner surface of the screen 13 And the fine contaminants that have not settled down to the lower side of the screen 13 are passed through the respective filtration holes 17 through the screen 13 And is introduced into the retention tank 35 through the retention tank inlet 37. [

The primary filtered outflow that has flowed into the retention tank 35 flows into the settling tank 43 of the rotary settling portion 41 through the retention tank discharge port 39.

The primary filtrate that flows into the settling tank 43 flows orbits along the inner wall surface of the settling tank 43. Some of the fine contaminants in the storm settles to the lower portion of the settling tank 43, The contaminants flow into the second filtration section 51 located at the top together with the storm.

The rainwater which has flowed into the second filtration section 51 through the rotation settling section 41 passes through the clearances C of the second filtration section 51 and the fine contaminants in the rainwater are filtered to be second filtered.

The secondary filtered outflow is discharged to the outside through the discharge pipe 57 via the discharge tank 55 located at the upper portion of the second filtration unit 51.

Meanwhile, in the above-described embodiment, the outflow introduced into the first filtration unit is circulated and filtered. However, the outflow introduced into the first filtration unit can be filtered through the filtration hole of the screen body without swirling.

Although the pollutant storage tank, the retention tank, and the rotary sedimentation unit are described as one block in the above-described embodiment, it is needless to say that the contaminant storage tank, the retention tank, and the rotary sedimentation unit may each be a separate structure.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

Fig. 2 is a sectional view taken along the line II-II in Fig. 1,

3 is a sectional view taken along line III-III in Fig. 1,

4A is a front view of a screen of the stormwater treatment apparatus according to the present invention,

FIG. 4B is a view showing the flow state of the storm in the screen of the stormwater treatment apparatus according to the present invention,

FIG. 5 is a view showing a flow state of storm in the rotatably settling portion of the stormwater treatment apparatus according to the present invention,

FIG. 6 is a view showing the flow of rainwater in the second filtration section of the rainwater treatment apparatus according to the present invention. FIG.

Description of the Related Art [0002]

11: first filtering section 13: screen

17: filtration hole 21: inlet

23: exhaust guide 25: inlet pipe

31: Contaminant storage tank 35:

41: spinning sedimentation part 43: sedimentation tank

45: rotation induction unit 51: second filtration unit

57: discharge pipe 61: bypass pipe

65: partition wall

Claims (16)

An excellent treatment apparatus for treating non-point source pollutants in storms, A first filtration part forming a plurality of filtration holes through which the rainwater flowing into the inflow port passes and which is swirled and flowed first; A spinning up pre-swirling section for swirling the primary filtered out stream to settle the contaminants in the primary filtered out stream; A second filtration unit forming a plurality of voids through which the rainwater passes and secondly filtering rainwater that has passed through the rotation settling unit; And a bypass pipe for bypassing the rainwater of the spin settlement unit to the outside of the second filtration unit. The method according to claim 1, A contaminant reservoir provided at a lower portion of the first filtration unit and storing contaminants filtered by the first filtration unit; Further comprising a retention tank provided between the first filtration unit and the rotation settling unit for retaining the primary filtered outflow discharged from the first filtration unit. 3. The method of claim 2, Wherein the retention tank is formed with a retention tank inlet through which the primary filtrated stormwater flows into the retention tank and a retention tank discharge port through which the primary filtered stormwater in the retention tank is discharged to the rotary sedimentation section, Is smaller than the cross-sectional area of the retention tank inlet. The method of claim 3, Wherein the retention tank inlet is formed at a position higher than the retention tank discharge port. The method according to claim 1, Wherein the first filtering unit comprises: A screen having a plurality of filtration holes through which the rainwater flowing through the inlet passes, and a plurality of filtration holes through which contaminants introduced together with the rainwater are filtered, the screen having swirling flow; And a discharge guide for guiding discharge of the storm that passes through the filtration hole to the outside of the screen. 6. The method of claim 5, Wherein the discharge guide protrudes obliquely to the inner circumferential surface of the screen in the swirling flow direction of the outer circumferential surface and protrudes obliquely to the outer circumferential surface of the screen in the direction opposite to the swirling flow of the outer circumferential surface. The method according to claim 1, Wherein the inlet is deflected with respect to the center of the screen so that the storm is introduced into the inner circumferential tangential direction of the screen. The method according to claim 1, And an inflow pipe connected to the inflow port and guiding an outer storm to the first filtration unit, Wherein the cross-sectional area of the inflow pipe is larger than the cross-sectional area of the inflow port. The method of claim 3, The rotation settling unit includes: A settling tank having a rectangular cross-sectional shape; And a rotation inducing unit disposed at each corner of the sedimentation tank and guiding the stormwater flowing into the sedimentation tank to swirl. 10. The method of claim 9, Wherein the retention tank discharge port is disposed adjacent to an inner wall surface on one side of the sedimentation tank. The method according to claim 1, Wherein the second filtration unit is a porous plate composed of 10 to 20 parts by weight of cement based on 100 parts by weight of crushed stones and having a plurality of voids formed therein. 12. The method of claim 11, Wherein the second filtration section contains at least one of ferric oxide, hydroxide, zeolite, limestone, and expanded clay. 12. The method of claim 11, And the porosity of the second filtration portion is 25% on average. 12. The method of claim 11, And the second filtration unit increases the gap toward the spin settlement unit. 3. The method of claim 2, Wherein the pollutant storage tank, the retention tank, and the rotation settling unit are formed of one block, the pollutant storage tank, the retention tank and the rotation settling unit are partitioned by partition walls, the first filtration unit is disposed on the contaminant storage tank, And the second filtration unit is disposed above the spin settlement unit. delete

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