KR101201492B1 - Front end weir device for purifying discharge water - Google Patents

Abstract

The present invention relates to a shear wear device for improving the sewage effluent water quality, the shear ware installed in the shear region of the sedimentation basin; And a bypass pipe connected to the shear ware and bypassing a part of the flow rate received in the shear ware to a rear end ware installed at the rear end of the sedimentation basin, wherein the shear ware includes: a trough having a plurality of notches formed at a side thereof; And a scum blocking film disposed on a front surface of the trough on which the notch is formed to prevent scum from being directly introduced into the trough.

Description

Front end weir device for purifying discharge water

The present invention relates to a shear wear device for improving the quality of sedimentation effluent water, and more specifically, by installing a shear ware at the front end of the sedimentation basin by bypassing a part of the flow rate to the rear weir caused by the reduction of the cross-sectional area according to the structure of the sedimentation basin. The present invention relates to a shear wear device for improving sedimentation effluent water quality by suppressing an increase in flow rate in the sedimentation basin, which can improve the phenomenon of deterioration of effluent water quality.

In sewage treatment plants and sewage treatment plants, sedimentation basins are formed to sew sludge by gravity sedimentation. The primary sedimentation basin is a facility that performs the role of pretreatment for biological treatment, and the secondary sedimentation basin is a facility that separates sludge and treated water by performing a process of sinking microorganisms ingesting organic matter in aeration tank.

In order to remove the settled sludge from the sedimentation basin, an orbital sludge collector is generally used. The sludge collector is a scum channel formed at the inlet end of the sedimentation basin by continuously rotating and scraping the sediment deposited at the lower part of the sedimentation basin. The scum that is collected and discharged to the upper part and floated to the upper part is configured to collect and discharge the scum with a scum skimmer disposed on the sedimentation basin.

Accordingly, due to the scum channel formed in the lower part of the sedimentation basin, the inlet end of the sedimentation basin has a wide cross-sectional area, but the cross-sectional area gradually decreases from the point where the sedimentation basin passes. It is common to be.

However, due to such a sudden decrease in cross-sectional area, the raw water flowing into the sedimentation basin may increase its flow rate, but the increase of the flow rate may impact the sludge, such as the fine flocs deposited in the sedimentation basin, causing the sludge to be injured or pushed by the flow rate. It may not be able to move to the back of the sedimentation basin without being included in the water.

As a result, the sedimentation in the sedimentation basin does not proceed efficiently, so that the water quality of the effluent water flowing into the rear ware (or the overflow ware) is deteriorated, and thus an alternative is required.

Korean Patent Office Application No. 10-2010-0114488

An object of the present invention is to improve the phenomenon that the discharge water quality is deteriorated by suppressing an increase in the flow rate in the sedimentation basin caused by the reduction in the cross-sectional area according to the structure of the sedimentation basin by installing a shear weir at the front end of the sedimentation basin and bypassing some of the flow rate to the rear weir. It is to provide a shear wear device for improving the sewage effluent water quality.

The object is a shear ware installed in the front end region of the sedimentation basin; And a bypass pipe connected to the shear ware and bypassing a part of the flow rate received in the shear ware to a rear end ware installed at the rear end of the sedimentation basin, wherein the shear ware includes: a trough having a plurality of notches formed at a side thereof; And a scum shielding film disposed on the front surface of the trough on which the notch is formed to prevent scum from being directly introduced into the trough.

The apparatus may further include a plurality of spacers disposed between the scum blocking film and the trough to space the scum covering film and the trough.

The spacer may be a bolt connected to the scum screen, and raw water may flow into the inner region of the trough through the lower region of the scum screen, the region between the scum screen and the trough, and the notch. Can be.

It may further include a flow rate control valve coupled to the bypass pipe for adjusting the flow rate of the raw water flowing along the interior of the bypass pipe.

The notch may be a V-type notch or a rectangular notch and may be continuously disposed on one surface of the trough, and a bent flange bent toward the trough may be formed at both ends of the scum blocking film.

According to the present invention, by installing a shear weir at the front end of the sedimentation basin by bypassing a part of the flow rate to the rear weir to suppress the increase in flow rate in the sedimentation basal caused by the reduction of the cross-sectional area according to the structure of the sedimentation basin to improve the phenomenon that the effluent water quality deteriorated Can be.

1 is a schematic plan view of a shear wear device for improving the sewage effluent water quality according to an embodiment of the present invention,
2 is a side structural view of FIG. 1;
3 is a perspective view of the coupling state between the scum screen, the trough and the bypass pipe,
4 is a partially exploded perspective view of FIG. 3;
5 is a cross-sectional view taken along line AA of FIG. 3.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

1 is a schematic plan structure diagram of a shear wear device for improving the sewage effluent water quality according to an embodiment of the present invention, Figure 2 is a side structure diagram of Figure 1, Figure 3 between the scum screen, the trough and the bypass pipe 4 is a partially exploded perspective view of FIG. 3, and FIG. 5 is a cross-sectional view taken along line AA of FIG. 3.

Referring to these drawings, the present invention installs the shear ware 100 in the front end region of the sedimentation basin by passing a partial flow to the rear weir 300, that is, by directly transferring the flow rate even if the cross-sectional area is reduced through the inlet end of the sedimentation basin. As it is not increased, the front end ware 100 and a bypass pipe 200 for bypassing the flow rate accommodated in the front end ware 100 to the rear end ware 300.

Prior to the description of the components of the present invention with reference to Figures 1 and 2 will be briefly described the structure of the sedimentation basin.

1 and 2 may be, for example, a secondary settling basin installed in the next step of the aeration tank.

In general, a relatively wide scum channel 101 is formed below the inlet end of the sedimentation basin to form a passage for collecting and discharging the sludge settled in the lower part. Therefore, due to the scum channel 101, the raw water inlet end of the sedimentation basin has a wide cross-sectional area, but the sedimentation basin is formed in a form in which the cross-sectional area gradually decreases after passing the inlet end.

Meanwhile, a sludge collector 102 for removing or collecting sludge is disposed in the sedimentation basin, and the sludge collector 102 rotates the upper and lower portions in an orbital manner to scrape the sludge settled in the lower portion of the scum channel 101. ), And the sludge rising to the top is collected and discharged to the scum skimmer (103).

Therefore, as described above, since the sedimentation basin is formed in a form in which the cross-sectional area gradually decreases while passing through the inflow end where the scum channel is formed, the flow rate of the raw water introduced into the sedimentation basin may rapidly increase while passing through the sedimentation basin inlet. This rapid increase in flow rate can impact sludges such as fine flocs that are deposited in the sedimentation basin, causing them to float, or be pushed into the flow rate, so that the sludge is not sedimented and contained in the water and can move to the rear of the sedimentation basin. Precipitation does not proceed efficiently may be a factor that deteriorates the water quality of the discharged water discharged into the rear weir (300).

Therefore, the present invention is to improve the discharge water quality by increasing the sedimentation efficiency by preventing the flow rate is rapidly increased in the sedimentation basin, it is possible to bypass a portion of the flow rate of the sedimentation basin to the rear end of the sedimentation basin. At this time, the bypass flow rate is preferably a flow rate equal to the cross-sectional area of the scum channel formed in the sedimentation basin inlet.

 To this end, the present invention installs a shear ware 200 composed of a trough 110 and a scum screen 120 at the front of the sedimentation basin, and bypasses the flow rate accommodated in the shear ware 200 to the rear ware 300. Pass pipe 200 is installed to improve the water quality of the sedimentation effluent.

The shear ware 100 includes a trough 110 and a scum screen 120, and is provided in the sedimentation basin front end region, and the bypass pipe 200 connects the shear ware 110 and the rear end ware 120 to shear. The flow rate flowing into the weir 110, that is, the flow rate introduced into the trough 110 serves to bypass, that is, directly transfer to the rear weir 300.

Looking at the trough 110 first, the trough 110 is an upper open tube structure installed at the edge of the front end region of the sedimentation basin.

Although one trough 110 is illustrated as one installed at the edge of the front end region of the sedimentation basin in FIG. 1, a plurality of troughs 110 may be disposed or used depending on the size of the sedimentation basin.

A plurality of notches 111 are formed on one surface of the trough 110, that is, one surface of the trough 110 facing the central region of the sedimentation basin.

In the present embodiment, the plurality of notches 111 may be V-shaped notches, rectangular notches, or other notches, and are continuously disposed on one surface of the trough 110. Although not shown in detail in the drawing, a notch may be formed on one surface of the rear wear 300.

The scum blocking film 120 is disposed on the front surface of the trough 110 where the notches 111 are formed, and serves to prevent the scum from being directly introduced into the trough 110.

That is, in the present embodiment, to prevent the scum floating on the sedimentation basin to flow into the discharge water, the scum screen 120 is installed on the front of the trough 110 to discharge the scum blocked water to the rear wear 300. To make it possible. Both ends of the scum screen 120 are formed with a bending flange 121 bent toward the trough 110 to block the introduction of scum through both ends.

On the other hand, in the present embodiment, the spacer member 120 is further provided between the scum blind layer 120 and the trough 110 to separate the scum blind layer 120 and the trough 110. In the present embodiment, the spacer 122 is applied with a bolt connected to the scum blocking film 120. The spacer 122 as the bolt may be partially inserted into the bolt hole 112 of the trough 110, and then may be fastened to the nut from the rear side.

Thus, as shown in FIG. 5, raw water in which scum is prevented from flowing through the lower region A of the scum screen 120, the region B between the scum screen 120 and the trough 110, and the notch 111 may be removed. It may be introduced into the inner region (C) of the rough 110, and then a portion of the rough 110 may be bypassed to the rear end wear 300.

As described above, the bypass pipe 200 has one end connected to the trough 110 and the other end connected to a region of the rear weir 300 of the sedimentation basin so that a part of the raw water in the trough 110 is rear end weir 300. Bypass, or direct delivery.

The bypass tube 200 may have a substantially inverted U shape so as not to interfere with the operation of the scum skimmer 103.

In order for the bypass pipe 200 to be connected to the trough 110, the flanges 200a and 110a are formed in the bypass pipe 200 and the trough 110, respectively.

And the bypass pipe 200 may be further connected to the flow rate control valve 210 for adjusting the flow rate of the raw water flowing along the interior of the bypass pipe 200, the control handle 211 of the flow control valve 210 It is desirable to be exposed to the top of the settling basin to allow manual control. However, the flow control valve 210 may be implemented as a solenoid valve capable of electronic control.

With this configuration, the raw water whose scum is blocked by the scum screen 120 is the lower region A of the scum screen 120, and the region B between the scum screen 120 and the trough 110 as shown in FIG. 5. And, it may be introduced into the inner region (C) of the trough 110 through the notch 111, after which a portion of the flow rate is bypassed to the rear weir 300 by the bypass pipe (200).

As such, by bypassing a part of the raw water in the sedimentation basin front end area through the bypass pipe 200 to the rear weir 300, even if the cross-sectional area is reduced by the structure of the sedimentation basin, the flow rate of the effluent is not deteriorated due to the rapid increase in the flow rate. You can do it.

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 or scope of the invention. Therefore, such modifications or variations will have to be belong to the claims of the present invention.

101: Scum Aqueduct 102: Sludge Collector
103: scum skimmer 100: shear wear
300: end wear 110: Trough
111: notch 112: bolt hole
120: scum shielding film 121: bending flange
122: spacer 200: bypass pipe
210: flow control valve

Claims (5)

A shear ware installed in the shear region of the sedimentation basin; And
A bypass pipe connected to the shear ware and bypassing a part of the flow rate received in the shear ware to a rear end ware installed at the rear end of the sedimentation basin,
The shear wear is
Troughs in which a plurality of notches are formed on the side;
A scum shielding film disposed on a front surface of the trough on which the notch is formed to prevent scum from being directly introduced into the trough; And
And a plurality of spacers disposed between the scum screening film and the trough and spaced apart from the scum screening film and the trough.
delete The method of claim 1,
The spacer is a bolt connected to the scum shielding film,
Raw water is introduced into the inner region of the trough through the lower region of the scum screen, the region between the scum screen and the trough, and the notch, the shear wear device for water quality improvement.
The method of claim 1,
And a flow rate control valve coupled to the bypass pipe to adjust a flow rate of raw water flowing along the inside of the bypass pipe.
A shear ware installed in the shear region of the sedimentation basin; And
A bypass pipe connected to the shear ware and bypassing a part of the flow rate received in the shear ware to a rear end ware installed at the rear end of the sedimentation basin,
The shear wear is
Troughs in which a plurality of notches are formed on the side; And
And a scum shielding film disposed on the front surface of the trough on which the notch is formed to prevent scum from being directly introduced into the trough.
The notch is a V-type notch or a square notch and is continuously disposed on one surface of the trough,
Shear wear device for improving the sewage effluent water quality, characterized in that the bending flange bent toward the trough is formed at both ends of the scum screening film.

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