KR101306943B1 - Draining device for use in a bridge - Google Patents

Abstract

The present invention relates to a bridge drainage device (D) for draining and draining the water of the bridge top plate (100). In particular, the present invention is installed under the bridge top plate 100, the first drain pipe 200 for draining the water flowing out of the bridge top plate 100, respectively; A second drain pipe including a first drain guide part 302 installed in a longitudinal direction of the bridge to guide drainage and a plurality of second drain guide parts 304 installed in a standing direction to guide drainage to the lower side of the bridge; 300; Collecting water flowing out from the bridge top plate 100, the initial rainwater is discharged to the first drain pipe 200, the continuous rainwater collecting portion 400 to discharge to the second drain pipe (300); It presents a bridge drainage device (D) characterized in that.

Description

Draining device for use in a bridge}

The present invention relates to a bridge drainage device for draining and draining water from the bridge deck.

Bridges installed in rivers or rivers are provided with a drainage device for smoothly draining water when rainwater is collected on the bridge, such as during rainy weather.

1 is a view showing a part of a conventional bridge that employs such a drainage device.

As shown in FIG. 1, in a typical bridge, a plurality of piers 20 are provided at equal intervals around the alternates 10 installed on the left and right sides of the river, and are provided on the upper portions of the piers 20. It has a structure in which a plurality of top plates 30 are installed in a bridge.

A plurality of water collecting pipes 50 for collecting rainwater, etc., collected on the upper plate are provided below the upper plates 30. Typically, the upper plate 30 has a shape in which rainwater is gradientd in a direction flowing toward the collecting pipe 50 so that rainwater is collected in the collecting pipe 50.

The lower part of the collecting pipe 50 is provided with a drain pipe 60 for receiving water flowing out to the lower end of the collecting pipe 50 and draining it outward. The drain pipe 60 is suspended by the hanging member 70 in the lower part of the upper plate 30. The drain pipe 60 is installed corresponding to each top plate 30 one by one. That is, the drain pipe 60 is typically installed between each of the piers 20 corresponding to one under the top plate (30). The drain pipe 60 is disposed to be inclined with respect to the horizontal direction so that water discharged from the collection pipes 50 flows to the pier 20 side.

Each pier 20 is provided with a drain guide pipe 80 disposed in the standing direction. The upper end of the drain guide pipe 80 is open to the end of the drain pipe 60, and the lower end extends to the lower side of the piers 20. Therefore, the water flowing near the pier 20 through the drain pipe 60 is introduced into the drain guide pipe 80 to be guided to the lower portion of the pier 20, and as a result, the water introduced into the upper plate 30 is pier. Drain into the river at the bottom of 20.

By the way, in the conventional bridge structure as described above, there is a problem that water introduced on the upper plate 30 can be directly drained to the river to cause environmental pollution. That is, the top plate 30 is usually made of a material containing a large number of environmentally polluting chemicals, such as asphalt. When the water on the top plate 30 is drained to a river, the water containing the chemicals dissolved in the asphalt or the like. Long-term and continuous inflow into these streams causes severe environmental pollution.

In order to solve this problem, in recent years, without installing the drain guide pipe 80 in the pier 20, the drain guide pipe 80 is installed only in the vicinity of the shift 10, and the drain pipe 60 is a land shift 10 ), It is forced to extend to the perimeter, so that the drained water does not flow directly into the stream. The bridge employing the conventional drainage device in which the drainage pipe is extended as shown in FIG. 2.

As shown in FIG. 2, the drain pipe 60 extends from the central portion of the entire bridge to the shift 10 side under the bridge upper plate 30. Therefore, one bridge is provided with two drain pipes 60 extending from the center portion to both shifts 10. In FIG. 2 only the left half of the bridge is shown. The drainage pipe 60 is suspended below the upper plate 30 by a plurality of suspension members 70, and in this case, the drainage pipe 60 is disposed downwardly toward the shift 10 side so that the drainage pipe 60 is horizontal toward the shift 10 side as a whole. It is arranged to be inclined at a predetermined angle with respect to the direction.

Corresponding to the shape of the drain pipe 60 extending to the alternate 10 side, the drain guide tube 80 is provided only on the alternate 10 side and is not provided to each pier 20. Accordingly, the water flowing into the upper plate 30 is drained only to the alternate 10 side, not to the side of the piers 20. The lower portion of the drain guide pipe 80 installed in the shift 10 is connected to a purifier (not shown), and the drained water is purified by the purifier and then flows into the stream.

As such, the water drained near the shift 10 is treated with water through a water treatment facility such as a predetermined purification facility, thereby minimizing contamination of the river.

By the way, as shown in Figure 2, as the water treatment of all the water flowing out of the bridge deck 30, a large facility expansion and enormous treatment costs, etc. have been pointed out as a problem.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a bridge drainage system that can reduce the water treatment facilities of the water flowing out of the bridge deck and reduce the treatment cost.

In order to solve the above problems, the present invention is installed in the lower bridge deck 100, the first drain pipe 200 and the second drain pipe 300 for draining the water flowing out of the bridge top plate 100, respectively; And collecting water flowing out from the bridge top plate 100, the initial rainwater discharged into the first drain pipe 200, and the sustained rainwater discharged into the second drainpipe 300. A bridge drainage device (D) is featured.

The first drain pipe 200 is connected to a water treatment facility for water treatment, the second drain pipe 300 is installed along the bridge 110 of the bridge may drain the water to the river below the bridge.

The water collecting unit 400 discharges the collected water up to a predetermined water level to the first drain pipe 200, and discharges the water exceeding the predetermined water level to the second drain pipe 300. It may have a second outlet 412 to.

The water collecting unit 400 is installed in an up and down direction, and an upper end forms an inlet through which water flowing out from the bridge upper plate 100 is collected, and a lower end forms the first outlet 411, and the first outlet (up and down) A distribution pipe 410 having the second outlet 412 formed at a position higher than 411 may be included.

The distribution pipe 410 may be installed to be located directly above the first drain pipe 200.

The water collecting unit 400 is connected to a water collecting port formed in the bridge top plate 100 so that water from the bridge top plate 100 flows out into the water collecting unit 400, and is detachable from the distribution pipe 410. A combined collecting pipe 420 may be further included.

The bridge drainage device (D) of any one of claims 1 to 6 may be installed on the upper plate 100 side or the girder side of the ramp section.

In the present invention, since the initial rainwater having a high pollution rate and the relatively clean continuous rainwater can be separately treated, ultimately, only the initial rainwater having high pollution degree may be sufficient to treat water, thereby reducing water treatment facilities and reducing treatment costs.

1 and 2 are side views of a bridge employing a conventional bridge drainage.
3 or less shows an embodiment of the present invention,
Figure 3 is a side view of a bridge employing the bridge drainage device according to the present invention.
4 is an enlarged view of a portion 'A' of FIG. 3.
5 is a front view of a bridge employing the bridge drainage device according to the present invention
6 is a cross-sectional view of the portion 'B' of FIG. 5 (initial storm drainage state).
FIG. 7 is a cross-sectional view of the portion 'B' of FIG. 5 (continuous storm drainage state).

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

As shown below in Figure 3, the bridge drainage device (D) according to the present invention, is installed under the bridge top plate 100, the first drain pipe 200 for respectively draining the water flowing out of the bridge top plate 100 ), And a first drainage guide part 302 installed in the longitudinal direction of the bridge to guide drainage and a plurality of second drainage guide parts 304 installed in an upright direction to guide drainage to the lower side of the bridge. Collecting the second drain pipe 300 and the water flowing out from the bridge top plate 100, the first rainwater discharged to the first drain pipe 200, the continuous rainwater discharged to the second drain pipe (300) It may include the hand 400.

That is, the pollutants accumulated on the bridge top plate 100 is drained through the bridge drainage device (D) according to the present invention with rainwater (rain water), etc., most of the rainfall within a certain time from the start of the rain (that is, It is important to purify the initial rainwater, so it is important to clean it.

Therefore, the bridge drainage device (D) according to the present invention can separate the initial rain with a high degree of pollution and the relatively clean continuous rain, respectively, and can drain the following excellent effects. That is, the initial stormwater can be drained as shown by the arrows in FIG. 6. The sustained rainfall can be drained as shown by the arrows in FIG. 7.

First, because the sustained rainwater can be seen as a state that does not contain the contaminants accumulated on the bridge top plate 100, it is relatively clean enough to be discharged directly into the river. Therefore, since only the initial rainwater with high pollution degree is sufficient to be water-treated by the water treatment facility, the water treatment facility can be reduced accordingly and the treatment cost can be reduced.

Second, since rain can be quickly drained by dividing rainwater into the first drain pipe 200 and the second drain pipe 300 during heavy rains, drainage clogging due to overload, the first drain pipe 200, and the second drain pipe 300 ) Problems such as sag and departure due to overload can also be prevented. In particular, if the stormwater discharged immediately into the stream, the effect of preventing clogging and drainage overload is superior.

As described above, it may be preferable that the first drain pipe 200 is connected to a water treatment facility for the initial rainwater treatment having a high degree of pollution for the initial rainwater treatment. The second drain pipe 300 may be connected to a facility for treatment of sustainable rainwater for continuous stormwater treatment, but is installed along the bridge bridge 110 of the bridge so that the stormwater can be immediately discharged to a river as shown. It may be more desirable to be able to drain water into the stream.

In addition, since the first drain pipe 200 is a place where the first rainwater can be discharged, the water treatment facility installed on the ground, so as to drain the initial rainwater discharged over the entire bridge top plate 100 in the longitudinal direction of the bridge, In order to prevent the drainage overload of the initial rainwater, it may be preferable that the diameter of the first drain pipe 200 is made of a pipe having a relatively large diameter so as to be larger than the diameter of the second drain pipe 300. Since the first drain guides 202 and 302 of the second drain pipe 300 may discharge the rainwater immediately into the river, the rainwater discharge may be installed to drain the rainwater to the stream in various ways along the longitudinal direction of the bridge. Since there is no need to worry about overload, it may be more preferable that the first drain pipe 200 is made of a relatively small diameter pipe.

The water collecting unit 400 may collect various water discharged from the bridge top plate 100 to be separated into an initial rainwater and a sustained rainwater to drain to the first drain pipe 200 and the second drain pipe 300.

However, the catcher 400 is drained immediately and immediately without clogging during the initial rain, and the water level is increased due to the drainage load during the continuous rain. It can be done forever. That is, the water collecting unit 400 discharges the first discharge port 411 for discharging the collected water up to a predetermined water level to the first drain pipe 200, and discharges the water exceeding the predetermined water level to the second drain pipe 300. It may be made to have a second outlet 412.

In particular, the water collecting unit 400 is installed in the vertical direction, the upper end forms an inlet 413 through which the water flowing out of the bridge top plate 100 is collected, and the lower end forms the first outlet 411 described above, It may include a distribution pipe 410 in which the second outlet 412 is formed at a position higher than the first outlet 411. In this case, simply and clearly drilling the second outlet 412 in the basic pipe is performed. It may be more preferable in that it can be made to be able to separate the initial rain and continuous rain depending on the water level.

The distribution pipe 410 has a lower end thereof to form a second outlet 412 so that the water discharged from the second outlet 412 can be drained directly to the first drain pipe 200 without undergoing an intermediate step. It may be installed to be located directly above the first drain pipe (200).

Such a distribution pipe 410 may be structurally integrated with the first drain pipe 200 and the second drain pipe 300, and water discharged from the water collecting unit 400 does not leak even if the structural pipe is not integrally coupled. It may be installed closely to the first drain pipe 200 and the second drain pipe (300).

In addition, the water collecting unit 400 is connected to the water collecting port formed in the bridge top plate 100 so that water from the bridge top plate 100 flows into the water collecting unit 400, the water collecting coupled to the distribution pipe 410 and detachable. It may further include a pipe 420. Therefore, the distribution pipe 410 and the collecting pipe 420 can be separated to facilitate the work such as cleaning and replacing the inside of the pipe.

In addition, the water collecting part 400 is formed to extend from the second outlet 412 of the distribution pipe 410, for easy connection with the second drain pipe 300, the extension pipe connected to the second drain pipe 300 ( 430 may be further included.

On the other hand, the first drain pipe 200 and the second drain pipe 300 are connected to the collecting portion 400, respectively, the first drain guide portion (202, 302) and pipes installed in the longitudinal direction of the bridge to guide the drainage, and the first It may include a second drain guide portion (204, 304) connected to the drain guide portion (202,302) is installed in the standing direction along the bridge 110 or the alternating 120 to guide the drainage to the lower side of the bridge.

The first drain pipes 202 and 302 of the first drain pipe 200 and the second drain pipe 300 may be installed in parallel with each other on the same height line.

The first drain guides 202 and 302 of the first drain pipe 200 and the second drain pipe 300 may each have a spherical shape, and drain holes may be formed to be connected to the water collecting part 400 in the middle of the pipe in the middle. Or, the upper surface may be made of a hemispherical open.

The above-described bridge drainage device (D) may be installed in a straight section of the bridge, but in particular, when installed in the upper plate 100 or the girder of the ramp section (deep curve section), the above-described effect can be obtained even more.

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.

100; Bridge deck 110; pier
200; First drain pipe 300; Second drain
400; Catchment 410; Drain pipe
420; Collecting pipe 430; Extension pipe

Claims (7)

A first drain pipe 200 installed under the bridge upper plate 100 to drain water flowing out of the bridge upper plate 100;
A second drain pipe including a first drain guide part 302 installed in a longitudinal direction of the bridge to guide drainage and a plurality of second drain guide parts 304 installed in a standing direction to guide drainage to the lower side of the bridge; 300;
A water collecting part 400 collecting water flowing out from the bridge top plate 100, an initial rainwater discharged to the first drain pipe 200, and a sustained rainwater discharged to the second drainpipe 300;
Bridge for drainage, characterized in that it comprises a. The method according to claim 1,
The first drain pipe 200 is connected to the water treatment facility for water treatment,
The second drain pipe (300) is installed along the bridge (110) of the bridge drainage device for bridges, characterized in that to drain the water to the river below the bridge. The method according to claim 1,
The water collecting unit 400 discharges the collected water up to a predetermined water level to the first drain pipe 200, and discharges the water exceeding the predetermined water level to the second drain pipe 300. Bridge drainage, characterized in that it has a second discharge port (412). The method according to claim 3,
The water collecting unit 400 is installed in an up and down direction, and an upper end forms an inlet through which water flowing out from the bridge upper plate 100 is collected, and a lower end forms the first outlet 411, and the first outlet (up and down) Bridge (D) characterized in that it comprises a distribution pipe 410, the second outlet 412 is formed at a position higher than 411. The method of claim 4,
The distribution pipe (410) is a bridge drainage device, characterized in that it is installed to be located directly above the first drain pipe (200). The method of claim 4,
The water collecting unit 400 is connected to a water collecting port formed in the bridge top plate 100 so that water from the bridge top plate 100 flows out into the water collecting unit 400, and is detachable from the distribution pipe 410. Drainage for bridges (D), characterized in that it further comprises a combined collecting pipe (420). A bridge, characterized in that the bridge drainage device (D) of any one of claims 1 to 6 is installed on the upper plate (100) or girder of the ramp section.

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