KR100799251B1 - Removal apparatus of non-point source pollutants for rainwater drain ditch - Google Patents

Abstract

The present invention is to remove the various pollutants introduced with the initial rainwater to the rainwater drainage to discharge the rainwater collected directly from the road drainage treatment device installed on the road side to the river, etc. At the same time the pollutants are washed out by the initial rainwater After the downfall, the rainfall can be discharged to a river, etc., so that the contaminants on the road can be removed together with the initial rainwater with a simple configuration, thereby preventing the pollution of the river and reducing the installation cost for the removal of nonpoint source. The present invention relates to a non-point source removal device for rainwater drainage, which is provided with a road drainage on the roadside, and a drainage facility for drainage treatment of rainwater on the road drainage by connecting storm drains connected to rivers. The rainwater drainage path is provided with a diaphragm, and the bottom of the diaphragm The filter network and filtration system are installed to allow the initial rainwater flowing through the road drainage channel to the bottom of the rainwater drainage to be filtered out from the filtering net and the filtration system. It is an invention that can be achieved by configuring a non-point source removal device to be discharged on the diaphragm after filling the gap.

 Excellent initial rain, nonpoint source, rainwater drainage

Description

Removal apparatus of non-point source pollutants for rainwater drain ditch}

1 is a perspective view of the storm drain according to the present invention

Figure 2 is a side cross-sectional view of the rainwater drainage path of the present invention is installed

Figure 3 is an enlarged cross-sectional view taken along line A-A of the present invention Figure 2

Figure 4 is a side cross-sectional view showing another embodiment of the storm drain according to the present invention

Figure 5 is a side cross-sectional view showing another embodiment of the storm drain according to the present invention

Figure 6a to 6c is a cross-sectional view showing another embodiment of the diaphragm by storm drain of Figure 5 of the present invention

Figures 7a and 7b is a cross-sectional view showing an embodiment of a state in which the diaphragm according to the present invention is installed to the outside with drainage

Figure 8 is a cross-sectional view of the upper portion of the present invention Figures 7a and 7b in plan view

9 is a cross-sectional view showing the lower portion of the present invention Figures 7a and 7b.

10 is a cross-sectional view showing a suction member and a filter net provided in the diaphragm of the present invention.

Explanation of symbols on the main parts of the drawings

100: storm drain 110: floor

120: sedimentation unit 130: water collecting well

Plates: 200, 200a, 200b, 200c, 200d

201: connector 202: guide plate

210: filtration network 220: filtration filter device

230: adsorption member 231: adsorption cloth

300: settling filtration box 301, 311, 321, 330, 341: hall

310, 320: partition plate 340: drain filter

342 activated carbon 400

410: road drainage

The present invention relates to a non-point source removal device for rainwater drainage to remove contaminants from rainwater drainage that directly discharges rainwater collected from a road drainage treatment apparatus installed at a roadside.

In particular, non-point pollutant removal device for storm drainage system that effectively removes various pollutants from the initial rainwater discharged with various pollutants on the road and drains smoothly after the pollutants are removed. It is about.

In general, the recognition of the necessity of management of point sources and management of nonpoint sources is essential for efficient environmental conservation of public waters, and various legislations to reduce water pollution due to the initial storm road, one of the nonpoint sources. Regulatory and control measures are urgently needed.

That is, on the road surface, environmental pollutants such as particulates contained in exhaust gases emitted by driving of automobiles, especially diesel engine cars, dust caused by tire wear, and dust caused by asphalt wear, etc. It is easy to deposit mixed with pollutants floating in the atmosphere.

In addition to organic pollutants such as polycyclic aromatic hydrocarbons and heavy metals such as cadmium, the initial storm road runoff as a nonpoint source contains not only various substances such as bacteria, oil components and eutrophic flames such as nitrogen and phosphorus, but also adversely affect the ecosystem. There are also substances that can cause endocrine disruptors, such as environmental hormones.

In this way, the pollutants deposited on the road may be transported along the roadside drainage system due to rainfall and then merged with the sewage system.However, bridges or roadsides collect rainwater from the road and discharge it immediately into the river. Most of them had a problem that the rivers were seriously polluted by various pollutants that were washed down to rainwater.

On the other hand, the road surface initial excellent runoff water is intermittently discharged unlike the sewage and wastewater discharged constantly, and the difference in the flow rate according to the season is large. The concentration of pollutants in the initial runoff is greatly affected by local characteristics and rainfall concentrations.In particular, the initial washing effect causes high concentrations of runoff in the early stages of rainfall, and as the rainfall persists, the concentration of the pollutant gradually decreases, resulting in very low or limited detection limits. It becomes as follows. In view of this, in order to treat the initial excellent effluent, a small drainage treatment that can selectively treat only the initial excellent water containing a high concentration of contaminants may be effective, rather than a large capacity treatment device.

As a plan for the effective drainage of the initial runoff, the “road road drainage treatment device” of Korean Utility Model Registration No. 298299 has been proposed, which settles the particulate matter having a high specific gravity after the initial stormwater flows into the maintenance tank. The main focus is to remove and treat contaminants through filtration and adsorption by the media in the media filter tank.

However, the above structure can increase the treatment efficiency of high concentration pollutants drained through the road during the initial rainfall stage, but if it exceeds the treatment capacity of the maintenance tank due to the sudden rainfall, various pollutants deposited on the road are maintained. It was devised to have a problem that is discharged to the drain pipe or wetland as it is without going through the management tank.

Therefore, an object of the present invention is to remove the various pollutants introduced with the initial rainwater to the rainwater drainage to discharge the rainwater collected directly from the road drainage treatment apparatus installed on the road side to the river, etc. After the pollutants have been washed down, the rainfall continues to flow to the rivers, which not only removes the pollutants on the road with the initial rainfall, but also prevents the pollution of the streams and eliminates nonpoint sources. It is to provide a non-point source removal device for rainwater drainage to reduce the cost.

An object of the present invention is to install a road drainage on the side of the road, the road drainage is provided with a drainage drainage connected to a river or the like in the drainage facility for drainage treatment of the road surface, the drainage to the drainage The bottom surface of the diaphragm is provided with a filtering net and a filtration device so that the initial rainwater flowing through the road drainage to the bottom of the rainwater drain can be filtered out of the filtering net and the filtration device while exceeding the filtration capacity. If rainwater flows through, it is achieved by configuring a nonpoint source removal device to fill the gap between the diaphragm and the bottom and then discharge it onto the diaphragm.

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

1 to 3, the road drainage 410 of the conventional roadside installed with a road drainage 410 on the side of the road 400, the drainage runway 100 connecting the road drainage 410 and the river. ) Inclinedly.

In this case, the road drainage 410 installed on the side of the road 400 may use any one of a drainage passage or an open drainage with a cover installed on the side of the road.

The rainwater drainage passage 100 connected to the road drainage passage 410 has a structure in which an upper portion is opened while having both sides and a bottom surface 110, and horizontally with the bottom surface 110 at the center of the rainwater drainage passage 100. The diaphragm 200 is installed to configure the rainwater drainage path 100 to be separated into an upper side and a lower side of the diaphragm 200.

In addition, the rainwater drainage path 100 in which the waterway is separated into the upper and lower sides by the diaphragm 200 as described above is between the bottom of the diaphragm 200 and the bottom surface 110 of the rainwater drainage path 100. By installing a filtration filter device 220 to filter the contaminants contained in the rainwater, it is preferable that the filtration network 210 and the filtration filter device 220 is installed at the bottom of the diaphragm (200).

The present invention configured as described above is installed in the drainage drainage 100 to the road drainage 410 is installed on the side of the road 400 as shown in Figures 1 to 3, the storm drainage 100 is configured to be inclined toward the river, etc. When the initial rainwater flows along the road drainage 410 along with the pollutants on the road 400 and flows into the rivers along the rainwater drainage 100, the pollutants contained in the initial rainwater can be discharged to the stream. Will be.

That is, when rain starts to fall and the initial rainwater flows into the storm drain 100 through the road drain 410 from the road 400, the initial rain flows along with various pollutants accumulated on the road 400.

At this time, the initial rainwater flowing along with the pollutant flows along the bottom surface 110 of the rainwater drainage path 100, and thus flows downward to the diaphragm 200 installed in the rainwater drainage path 100.

Therefore, the initial rainwater flowing along the bottom surface 110 of the rainwater drainage path 100 at the bottom of the diaphragm 200 passes through the filtering network 210 and the filtration filter device 220, and contaminants pass through the filtered purified water. It is possible to prevent contamination.

On the other hand, as the amount of rain falling through the initial rain after the rain starts to increase, the rainwater that exceeds the filtration capacity of the filter network 210 and the filter unit 220 flows along the bottom surface 110 of the storm drain 100. The rainwater rises between the diaphragm 200 and the bottom surface 110.

If rainwater continues to rise between the diaphragm 200 and the bottom surface 110 as described above, the rainwater overflows over the diaphragm 200, so the rainwater flowing into the rainwater drainage path 100 from the road drainage drainage 410 is the diaphragm 200. Flow along the rainwater drainage (100) above is to be discharged to the river.

At this time, the rainwater overflowing over the diaphragm 200 is an excellent rainwater after the pollutants of the road 400 are filtered in the initial rainwater, thereby preventing contamination of rivers and the like.

On the other hand, Figure 4 is a side cross-sectional view showing another embodiment of the storm drain according to the present invention, the precipitation section 120 is configured on the bottom surface 110 of the storm drain 100, the precipitation section 120 is the filter network 210 Since the rainwater flowing along the basin surface is configured to flow through the settling unit 120 to precipitate the sediment contained in the rainwater, the filtration efficiency of the initial excellent water using the filtering network 210 and the filtration filter device 220). As well as to increase, it is possible to extend the life of the filter net 210 and the filter device 220.

In addition, Figure 5 is a side cross-sectional view showing another embodiment of the storm drain according to the present invention, such another embodiment is applied when the concrete sump 130 is provided at the bottom of the storm drain 100 The state is illustrated.

That is, the rainwater drainage passage 100 provided with the concrete sump 130 is provided with a connection pipe 201 at the lower end of the diaphragm 200 to be detachably provided with the precipitation filtration box 300, and the filtration filter device 220 The sedimentation filtration box 300, which is provided therein, is installed in the sump 130, and the bottom one side of the precipitation filtration box 300 is installed with a drain filter 340 at the bottom of the rainwater drainage path 100. The initial rainwater introduced between the 110 and the diaphragm 200 flows into the sedimentation filtration box 300 through the connection pipe 201 and then precipitates and filters, and then flows into the sump 130 and drains 140. Configured to be discharged through.

Since the lower part of the diaphragm 200 for draining the initial excellent water as described above is configured in a watertight state to the precipitation filtration box 300 in which the filtration filter device 220 is installed, the water pressure of the initial excellent cold to the diaphragm 200 is lowered. Constant and stable filtration can be achieved.

In addition, when the initial rainwater introduced to the lower portion of the diaphragm 200 together with various contaminants on the road 400 flows into the precipitation filtration box 300, the initial rainwater is initially formed in the compartment formed by the partition plates 310 and 320 therein. The rainwater flows through the holes 311 and 321 formed in the partition plates 310 and 320 and passes through the filtration filter device 220 after rainwater flows. Through the sump 130 will flow out.

On the other hand, the initial rainwater discharged into the sump 130 as described above is drained through the drain 140 while the sedimentation is once again made in the sump 130, the remaining rain remaining in the precipitation filtration box 300 is precipitated It is discharged through the activated carbon 342 and the hole 341 of the hole 301 and the drain filter 340 formed in the lower portion of the filter box 300, the precipitation filtration box 300 as described above is of the diaphragm 200 Separation from the connection pipe 201 to discharge the internal precipitate or to be replaced with a new precipitation filtration box (300).

Figure 6a to 6c is a cross-sectional view showing another embodiment of the diaphragm by the storm drainage channel of Figure 5 of the present invention, the present invention is connected to the bottom of the diaphragm 200, such as the flat plate 200 shown in FIG. Not only can be used in the state provided with the pipe 201, in addition to it may be used by installing a plate (200a) bent in the 'b' shape in the storm drain 100, as shown in Figure 6b, When used together with the connection pipe 201 at the bottom to connect the precipitation filtration box 300 and at the same time the upper side of the diaphragm (200a) is provided with a guide plate 202, the initial excellent guide plate 202 Blocked by both flows into the diaphragm (200a) and after the inside of the diaphragm (200a) is filled with rainwater is to continue to fall through the rainwater drainage path 100 over the guide plate 202.

In addition, in the storm drain 100, a diaphragm 200b having a circular cross-sectional shape as shown in FIG. 6C may be installed and used in the storm drain 100, and when the diaphragm 200b having a circular cross section is used as described above, On one side, the guide plate 202 is installed and the lower end is provided with a connection pipe 201 to connect the precipitation filtration box 300.

On the other hand, Figure 7a to Figure 9 is a cross-sectional view showing an embodiment of a state in which the externally installed diaphragm according to the present invention in the drainage, and a cross-sectional view showing a cross-sectional view and a lower portion of the upper portion in plan view, the plate of the various shapes ( In the case of installing the 200 (200a) (200b) in the storm drain 100, the use of the present invention for removing the non-point source of the initial rain by using the existing storm drain 100 already installed When the new drainage drainage 100 is newly constructed, the above-described method can be used as well as the diaphragm 200c having a circular cross section as shown in FIG. 7A is installed on one side of the drainage drainage 100 outside, or in FIG. 7B. As shown in the figure, a diaphragm 200d having a rectangular cross-sectional shape may be installed and used at an outer side of the storm drain 100.

At this time, one side of the diaphragm 200c and 200d is installed with a guide plate 202 blocking the lower portion of the rainwater drainage path 100 so that the initial excellent water is blocked by the guide plate 202 and flows into the diaphragm 200c and 200d. At the bottom of the diaphragm 200c and 200d, the diaphragm is provided by the induction plate 202 by providing a connection pipe 201 to be coupled with the precipitation filtration box 300 installed in the sump 130. The initial rainwater introduced into the (200c) (200d) can not only be discharged through the precipitation filtration box 300, but also effectively remove the non-point source from the initial rain as described in Figures 5 to 6c. You can do it.

Figure 10 is a cross-sectional view showing the adsorption member and the filter net provided in the diaphragm of the present invention, the inside of the air divider 200, 200a (200b) (200c) (200d), the adsorption member 230 and It is preferable to install the filter net 210, in which the adsorption member 230 is formed in a shape such as 'y' and provided with an adsorption cloth 231 on its upper surface to adsorb oily debris contained in the initial excellent water. At the same time, it is possible to prevent backflow of the initial excellent float.

As described above, the present invention enables to remove various contaminants introduced with the initial rainwater and the initial rainwater at the same time as the rainwater drainage channel which directly discharges the collected rainwater from the road drainage treatment apparatus installed at the roadside. After the pollutants have been washed down, the rainfall continues to flow to the rivers, which not only removes the pollutants on the road with the initial rainfall, but also prevents the pollution of the streams and eliminates nonpoint sources. Cost savings are also provided.

Claims (10)

In the drainage facility to install the road drainage on the side of the road, and the drainage drainage is connected to the drainage drainage to the river, etc. The rainwater drainage is provided with a diaphragm, and a bottom of the diaphragm is provided with a filtering net and a filtration filter device so that the initial water flowing through the road drainage to the bottom of the rainwater drainage is filtered out of the filtering net and the filtration filter apparatus. And rainwater exceeding the filtration capacity at the same time is filled between the plate and the bottom surface and discharged over the plate, characterized in that non-point source removal device for rainwater drainage. The method of claim 1, Rainfall source removal device for rainwater bath furnace, characterized in that the rainwater flow into the rainwater drainage to the bottom surface of the rainwater drainage is configured to pass through the filter network and the filter unit through the precipitation. In the drainage system is provided on the side of the road, the road drainage is provided with a concrete sump well to drain the storm water The sewage filtration box provided with a connection pipe at the bottom of the diaphragm is installed in the rainwater drainage provided with the concrete sump, and the sediment filtration box equipped with a filtration filter device is installed in the sump, On the lower side, the drain filter is installed so that the initial rainwater introduced between the bottom of the rainwater drainage and the diaphragm installed in the rainwater drainage flows into the precipitation filtration box through the connecting pipe, and is sedimented and filtered. Nonpoint source removal device for rainwater drainage. The method according to claim 1 or 3, The diaphragm is formed in the shape of a flat plate non-point pollutant removal device for rainwater drainage characterized in that it is installed inside. The method according to claim 1 or 3, The diaphragm is a non-point pollutant removal device for storm drains, characterized in that the 'b' shape is installed inside the storm drain. The method according to claim 1 or 3, The diaphragm is formed in a circular cross-sectional shape non-point source removal device for storm drainage, characterized in that installed in the storm drain. The method according to claim 1 or 3, The diaphragm is formed in a circular cross-section and installed on the outside with rainwater drainage, and an upper side of the diaphragm is provided with an induction plate so that the initial water flows into the diaphragm, and a sediment filtration box is connected to the lower end of the diaphragm. Non-point source removal device for storm drainage. The method according to claim 1 or 3, The diaphragm is formed in a rectangular cross-sectional shape and installed on the outside with rainwater drainage, and an upper side of the diaphragm is provided with an induction plate so that the initial water flows into the diaphragm. Non-point source removal device for storm drainage. The method according to claim 1 or 3, The inside of the diaphragm is a non-point pollutant removal device for storm drainage, characterized in that the adsorption cloth is provided with an adsorption member and the filter net is configured to adsorb the oil residue contained in the initial excellent. The method of claim 3, wherein The sedimentation filtration box has a plurality of compartments formed in the partition plate formed therein, the rain water flows through the hole formed in the partition plate and passes through the filtration filter device to be drained through the hole to the sump. The lower portion of the precipitation filtration box is provided with a drain filter filled with activated carbon so that rainwater remaining in the precipitation filtration box can be discharged through the drain filter.

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