KR101327526B1 - Water treatment structure - Google Patents

Abstract

The present invention relates to the field of civil engineering and environment, and more particularly, to a water treatment structure for purifying water bodies such as sewers. In particular, the present invention is installed along the discharge direction of the water body from the outlet (2A) of the water discharge structure 2, the water body discharged from the structure 2 to precipitate the pollutants (S) A storage tank 10 discharged to the side of the heavy water structure 2B; Contaminants in the water body while being installed between the outlet port 2A of the structure 2 and the storage tank 10 along the discharge direction of the water body to guide the water body discharged from the structure 2 to the storage tank 10. (S) to filter the contaminant (S) is caught and discharged to the water supply structure (2B) side of the storage tank 10, the cross section is formed in a wedge shape and arranged parallel to each other at a predetermined interval A water treatment structure may be provided that includes a pretreatment filter 200 comprising a plurality of wedge wires 212 disposed such that an axis passing through the center of the cross section is inclined.

Description

Water Treatment Structures {WATER TREATMENT STRUCTURE}

The present invention relates to the field of civil engineering and environment, and more particularly, to a water treatment structure for purifying water bodies such as sewers.

In general, water bodies (ie, water) such as stormwater, sewage, sewage, and wastewater are subjected to various water treatment processes such as filtration and sedimentation for the purpose of prevention of river pollution and use of high-grade water.

However, in the case of a method of treating water by temporarily storing water bodies such as sedimentation among water treatment methods, it is a reality that large facilities are being constructed to treat a large amount of water bodies at once. In particular, rainwater does not occur steadily, but only during rainfall, and rainfall varies drastically depending on whether there is a heavy rainfall. The facility for stormwater treatment responds to the amount of water in heavy rain so that it can always handle the water bodies that are generated. To be made very large.

Therefore, there is an urgent need for research on ways to reduce water treatment facilities to small size.

The present invention has been made to solve the above problems, it is an object of the present invention to provide a water treatment structure that can substantially reduce the water capacity to be treated even when a large amount of water generation, such as during heavy rains.

In order to solve the above problems, the present invention is installed along the discharge direction of the water body from the discharge port (2A) of the structure (2) in which the water body is discharged, the water body discharged from the structure (2) to store the pollutants ( A storage tank 10 which is discharged after precipitating S); It is installed between the discharge port 2A of the structure 2 and the storage tank 10 along the discharge direction of the water body, and guides the water body discharged from the structure 2 to the storage tank 10 while polluting the water body. The pretreatment filter 200 which filters the substance S and discharges the water bodies in which the pollutants S are caught may be provided.

The storage tank 10 has an inner space with an upper surface open to allow the water body to flow into the storage body, and a discharge port may be formed at an upper side of the side wall to discharge the upper water in the storage tank 10.

In the outlet 12A of the storage tank 10, a strainer for filtering the contaminant S may be installed.

The bottom of the pretreatment filter 200 may form a passage for guiding the water body into the storage tank 10 together with the bottom portion 202 and the bottom portion 202 where the outlet is formed so that the water body may be discharged. It may include a filter frame including a pair of side wall portions 204 protruding upward of the portion 202, and a strainer that is installed in the outlet of the bottom portion 202 to filter the pollutants (S). .

The side wall part 204 of the filter frame is formed with a discharge port so that the water body can be discharged, and a screen for filtering the contaminant S may be installed at the outlet port of the side wall part 204.

The strainer may be composed of a wedge wire screen having a plurality of wedge wires arranged in a row in cross section.

The water treatment structure may be installed in the heavy water structure 2B.

According to the present invention, since the water body from which contaminants are filtered by the pretreatment filter is immediately discharged, and the remaining water body is introduced into the storage tank together with the contaminant, the water treatment structure can significantly reduce the water treatment capacity in the storage tank compared to the amount of water generated. Can be presented.

1 is a block diagram of a water treatment structure according to the present invention.
2 is a perspective view of a water treatment structure according to the present invention.
3 is a cross-sectional view of a water treatment structure according to the present invention.
In Figure 4 (a) is a perspective view from the front of the wedge wire screen, (b) is a perspective view from above inclined.
5 is a partially enlarged cross-sectional view of the wedge wire and the slit constituting the wedge wire screen.

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

As shown in Figure 1 below, the water treatment structure according to the present invention, is installed along the discharge direction of the water body from the discharge port 2A of the structure 2 is discharged, such as 'arrow A' shown in the figure A storage tank 10 for storing water bodies discharged from the structure 2 as shown in 'arrow B' to precipitate the pollutants S and then discharging as 'arrow C' as shown in the drawings; It is installed between the discharge port 2A of the structure 2 and the storage tank 10 along the discharge direction of the water body, and guides the water body discharged from the structure 2 to the storage tank 10 as shown by the 'arrow C' shown in the drawing. While filtering the contaminant (S) in the water body and the pre-treatment filter 200 for discharging the water body in which the contaminant (S) is caught; may include.

That is, in the pretreatment filter 200, the filtered water body in which the contaminants S are filtered by the pretreatment filter 200 is discharged directly through the pretreatment filter 200, and the storage tank 10 is formed along the discharge direction of the water body. As it is spaced apart from the outlet 2A of 2), the pollutants S caught by the pretreatment filter 200 may be swept away by the water discharged from the outlet 2A of the structure 2 and flow into the storage tank 10. have.

Therefore, since a substantial portion of the water body discharged from the outlet 2A of the structure 2 can be discharged directly from the pretreatment filter 200 without flowing into the storage tank 10, the structure 2 as in the case of heavy rains. Even if a large amount of exports are discharged from the outlet 2A, only a small amount of water can flow into the storage tank 10 together with the contaminant S. Accordingly, the treatment capacity of the storage tank 10 can be significantly reduced compared to the case of treating all the amount of water discharged from the existing structure (2).

In addition, as the amount of water flowing into the storage tank 10 is significantly reduced, it takes a considerable time until the water level in the storage tank 10 becomes high, so that the large pollutants S in the storage tank 10 as well as the floating pollutants S. , Fine contaminants (S) can also be sufficiently precipitated, the precipitation efficiency can be maximized, thereby improving the purification efficiency of the water body.

In particular, such a storage tank 10 has an inner space with an open top surface so that water can flow into the storage body, and a discharge port 12A is formed at an upper side of the side wall 12 so that the supernatant in the storage tank 10 can be discharged. It may be more advantageous to take the configuration.

That is, as the storage tank 10 is formed in a structure in which the water body flows along with the pollutant S through the upper surface of the storage tank 10, the pretreatment filter 200 is discharged by being installed above the storage tank 10. It may be installed so as not to be immersed in the back, the back flow of the water body and contaminants (S) introduced into the storage tank 10 can be prevented, and as the water body flows through the upper surface of the storage tank 10 to fall in the storage tank (10) As the stirring action of the water body becomes active, precipitation after aggregation of the contaminants (S) can be made more easily, and the chemical and biological treatment in the storage tank 10 can be made more smoothly as necessary by this stirring action. In addition, as the water body drops through the upper surface of the storage tank 10, the floating of the settled pollutant (S) may be prevented.

In addition, as the discharge port 12A of the storage tank 10 is formed at the upper side of the storage tank 10, only the clean supernatant in which the pollutant S is precipitated may be naturally discharged in an overflow manner without power. .

Here, in the discharge port 12A of the storage tank 10, a sieve 14 for filtering the pollutants S may be installed to prevent the floating pollutants S from being discharged together with the water body.

The pretreatment filter 200 is installed between the outlet 2A of the structure 2 and the storage tank 10, and the filter frame 200 in which the outlets 202A and 204A are formed so that the water body can be discharged, and contaminated from the water body discharged. In order to filter the material (S) may include a strainer 210 is installed in the outlet 202A, 204A of the filter frame 200.

In particular, the filter frame 200 has a water reservoir 10 together with a bottom portion 202 and a bottom portion 202 which serve as a bridge connecting the outlet 2A of the structure 2 and the upper surface of the storage tank 10. It may include a pair of side wall portion 204 protruding to the upper side of the bottom portion 202 to form a passage leading to).

Accordingly, the filter frame 200 guides the water body to the storage tank 10, but the water body discharged from the structure 2 by the pair of side wall portions 204 is filtered by the strainer 210 of the pretreatment filter 200. This can be prevented from being discharged immediately.

Here, the outlets 202A and 204A of the filter frame 200 may be discharged immediately after being filtered by the strainer 210 of the pretreatment filter 200 without collecting water in the filter frame 200. It is preferably formed in). In addition, the discharge port 204A is further formed at the side wall portion 204 of the filter frame 200, and the strain screen 210 of the pretreatment filter 200 may be installed at the discharge port 204A of the side wall portion 204. have.

On the other hand, any of the filtering nets (14,210) used for the storage tank 10, the pretreatment filter 200 as described above may have any filtration function. However, at least the sieve 210 of the pretreatment filter 200 may be more advantageously made as follows.

That is, the sieve 210 of the pretreatment filter 200 may be formed of a wedge wire screen having a plurality of wedge wires having a wedge shape in one direction.

The wedge wire screen is as shown in FIGS. 4 and 5.

The wedge wire screen is configured by arranging a plurality of wedge wires 212 having a wedge-shaped cross section in parallel, and minute slits 214 of about 10 μm to lmm may be formed between the wedge wires 212. have.

Each wedge wire 212 may be fixed to the plurality of support rods 216 by spot welding or the like. In addition, each wedge wire 212 and the support rod 216 may be made of a corrosion-resistant metal material such as stainless steel. Each slit 214 formed in such a wedge wire screen prevents the passage of solids on the order of 10 μm to 1 mm, allowing only liquids containing solids smaller than the slit width to pass.

The wedge wires 212 having a wedge shape in cross section are arranged in parallel with each other at predetermined intervals, and the surface of the head portion 212a may form part of the surface on the inflow chamber side. The axis S of the wedges extending in the vertical direction from the surface of the head 212a can be formed to be inclined on the downstream side in the up-and-down swirling flow direction shown by the arrow L. FIG. The angle α between the swirl flow direction L and the surface of the head 212a may be set to about 3 degrees to 8 degrees, and usually about 5 degrees. When the axis S of each wedge wire 212 is formed to be inclined in this manner, as shown in the drawing, the end portion 212b of the head portion 212a located on the upstream side of the swirl flow is located on the downstream side 212a. It may protrude in the inward direction of the inlet chamber 5 than the end (212c) of). As a result, the swirl flow impinges on the protruding end 212b of each wedge wire 212, and can be efficiently attracted to the slit 214 by a Coanda effect. Therefore, when the slit width is reduced to separate the micron-based solids, the aperture ratio of the screen 200 is very small. However, the permeability of the liquid is improved by the Coanda effect, thereby substantially increasing the aperture ratio of the screen 200. Can be exercised.

When it becomes possible to improve the permeability of liquid in this way, even if the slit space | interval is made extremely small in order to isolate | separate fine solid matter, a separation process capability can be maintained at a considerable level.

Of course, the strainer 14 of the reservoir 10 may also consist of the wedge wire screen described above.

Such a water treatment structure can be configured wherever water treatment, such as sewage, rivers are needed, and may be particularly useful as a heavy water structure 2B installed in sewage structures 2 'such as living water.

In other words, the sewage water originates from the fact that it is located between the water supply and the sewerage system, but it is not suitable for drinking water, but it refers to water of sufficient quality such as fire water, landscaping water, toilet water, and cleaning water. Water can reduce the consumption of tap water and reduce the amount of sewage produced, thereby improving the quality of water, reducing the demand for dam construction by reducing the supply of tap water, and reducing the difficulty of water shortage during the dry season.

Therefore, the water body discharged from the water treatment structure of the present invention is not lacking at all in being used as a heavy water.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

2; Structure 2B; Waterworks structures
10; Storage tank 20; Pretreatment filter
200; Filter frame 210; Filter

Claims (7)

It is installed inside the water supply structure 2B spaced apart from the water supply structure 2B along a discharge direction of the water body from the outlet 2A of the structure 2 through which the water body is discharged, and discharged from the structure 2. Storage tank 10 for storing the water body to be precipitated pollutants (S) and then discharged to the water supply structure (2B) side;
The water body is installed between the outlet 2A of the structure 2 and the storage tank 10 side by side along the discharge direction of the water body and guides the water body discharged from the structure 2 to the storage tank 10. Filtering pollutants (S) and discharged the water bodies in which the pollutants (S) are caught are discharged to the side of the water supply structure (2B) outside the storage tank 10, the cross section is formed in a wedge shape and arranged parallel to each other at a predetermined interval And a pretreatment filter (200) consisting of a plurality of wedge wires (212) disposed such that an axis passing through the center of the cross section is inclined.
The bottom of the pretreatment filter 200 may form a passage for guiding the water body into the storage tank 10 together with the bottom portion 202 and the bottom portion 202 where the outlet is formed so that the water body may be discharged. And a filter frame including a pair of side wall portions 204 protruding upward from the portion 202, and a strainer installed at the outlet of the bottom portion 202 to filter the contaminants S. Water treatment structure. The method according to claim 1,
The storage tank 10 has an inner space having an upper surface open to allow the water body to flow into the storage body, and a water outlet structure is formed at an upper side of the side wall to discharge the upper water in the storage tank 10. . The method according to claim 2,
Water treatment structure, characterized in that the discharge port (12A) of the storage tank 10 is provided with a strainer for filtering the pollutants (S). delete The method according to claim 1,
The side wall portion 204 of the filter frame is formed with a discharge port so that the water body can be discharged, the water treatment structure, characterized in that the filter screen for filtering the pollutant (S) is installed in the outlet of the side wall portion (204). delete delete

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