KR101887087B1 - Apparatus for draining wastewater of bridge to improve clogging - Google Patents

Abstract

According to an aspect of the present invention, provided is a bridge road drainage device with alleviated clogging. Clogging is alleviated when draining sewage of a road surface of a bridge. The present invention comprises: a drainage pipe part which is arranged to penetrate from the upper surface to the lower surface of a bottom plate of a bridge, and includes an inlet disposed in the upper part of the bottom plate of the bridge and allowing the sewage to flow from one end thereof, a stepped part formed inwardly from the other end of the inlet, and an inclined pipe disposed to extend from the inlet and penetrate the bottom plate while having a cross-section reducing from the upper end toward the lower end of the bottom plate of the bridge; and a drainage grating which is inserted into the inlet, and includes a plurality of support blocks supported by the stepped part, an outer rib separated from the inside of the inlet to introduce sewage of the road surface and connecting the support blocks to be closed, and an inner rib arranged to cross the inside of the outer rib.

Description

TECHNICAL FIELD [0001] The present invention relates to a bridge drainage system,

The present invention relates to a bridge surface drainage apparatus which improves clogging. More particularly, the present invention relates to a bridge surface drainage apparatus capable of effectively preventing clogging of a drainage apparatus and effectively treating a large amount of wastewater by discharging dirt mixed with sewage on a bridge road surface.

Drainage is installed on the side of the road surface in order to drain the sewage such as rainwater falling on the road surface of the bridge to the lower part of the bridge. In order to install the drainage system, it is necessary to install the drainage pipe in the drainage system in advance when the concrete is laid to form the bottom plate of the bridge, and to grind the dirt on the upper part of the drainage pipe when the concrete is laid and cured. (grating) is installed and used.

1 and 2 show a bridge road drainage apparatus according to the prior art, wherein FIG. 1 shows a bridge road drainage apparatus according to the prior art embedded in a bottom plate of a bridge, And the bridge road drainage apparatus according to the present invention.

When the bottom plate 102 of the bridge is completed through pouring and curing of concrete or the like, the asphalt 104 is installed thereon. When the asphalt (104) is installed, a previously formed drain pipe (108) is installed so as not to be clogged.

In the drainage device according to the related art, the upper part of the drainage pipe is enlarged in cross section so that wastewater and the like can be collected easily, and a drainage pipe 108 having a smaller cross section is extended thereunder. The drain pipe 108, which shrinks sharply in the cross-sectional enlarged portion, is extended, so that the step portion 110 is formed on the drain pipe 108.

A large amount of waste water may be generated on the road surface of the bridge in a heavy rainfall situation. In the process of moving the waste water to the drainage device, the soil 112 such as leaves on the road surface moves together. In the case of the conventional drainage apparatus, as shown in FIG. 1, when the waste water mixed with the dirt 112 is introduced into the drainage apparatus, dirt accumulates in the step unit 110 except for the upper part of the drainage pipe 108, There is a problem in that a large amount of wastewater can not be processed because the cross section is substantially reduced and as a result, the debris accumulates on the grating 106.

Korean Patent Publication No. 10-2016-0146247 (published Dec. 21, 2016)

The present invention can provide a bridge surface drainage apparatus with improved clogging which can effectively treat a large amount of wastewater by preventing clogging of the drainage apparatus by effectively discharging dirt mixed with sewage on the bridge road surface.

According to an aspect of the present invention, there is provided a bridge road surface drainage apparatus improved in clogging when draining sewage on a road surface of a bridge, the bridge surface drainage apparatus comprising: an inlet disposed at an upper portion of a bottom plate of the bridge, And an inclined pipe extending from the inlet and disposed to penetrate through the bottom plate and having a section reduced in a direction from a top end to a bottom end of the bridge bottom plate, wherein an upper surface of the bottom plate of the bridge A drain pipe portion disposed to pass through the lower surface; A plurality of support blocks supported on the step portion; an outer rib spaced from the inner side of the inlet to connect the plurality of support blocks to each other to allow wastewater from the road surface to flow therethrough; And a drainage grating inserted into the inlet. The bridge surface drainage apparatus improved the clogging.

The bridge surface drainage apparatus having improved clogging may further include an annular receiving portion protruding along the outer circumference of the drain pipe portion.

The inlet may be inclined such that its cross section is reduced toward the lower end of the bottom plate of the bridge. In this case, the outer rib may be inclined to the support block so as to be parallel to the inclination of the inlet.

The inlet may have a quadrangular shape and the step may be formed at a corner of an inlet of the quadrangle. In this case, the supporting block may be formed of four supporting blocks corresponding to corners of the inlet.

The inner rib of the drainage grating may be formed to extend radially from the center of the outer rib in the form of a vortex so that the wastewater from the road surface flows in a swirl form.

The inlet may have a circular shape. In this case, the step is formed in a corner portion of a square which is in contact with the inside of the circular shape, and the supporting block is composed of four supporting blocks corresponding to the respective step portions The outer ribs may be circular to connect the four support blocks.

The bridging road surface drainage apparatus may further include an outlet extending from a lower end of the slant pipe to protrude from a lower surface of the bottom plate of the bridge, and a drain pipe may be coupled to the outlet.

The bottom plate of the bridge may be formed by placing unhardened concrete in a mold for forming a bottom plate. In this case, the drain pipe portion may be formed by a leveling process in which a lower end of the slant pipe is inserted, A tube; The tapered portion may include a tapered portion having an outer surface corresponding to the inner surface of the lower end of the tapered tube and an extension portion extending from the tapered portion. The outflow tube may be inserted into the tapered tube to penetrate the extended portion.

The bridge surface drainage apparatus having improved clogging may further include a vortex forming portion disposed inside the tortuous tube and causing a swirl in the waste water flowing into the tortuous tube.

The vortex forming part may include a wing plate having a wave shape at an upper end and a lower end and being warped about a central part.

A guide protrusion is formed on both sides of the wing plate, and the guide protrusion is slidably inserted into the inner surface of the inclined pipe so that the guide groove is formed in the depth direction.

According to the embodiment of the present invention, it is possible to effectively discharge a large amount of wastewater by preventing clogging of the drainage device by effectively discharging the dirt mixed with the wastewater on the road surface.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view showing a state in which a bridge floor is filled with a bridge surface drainage apparatus improved in clogging according to the prior art. Fig.
2 is a plan view of a bridge road drainage apparatus according to the prior art;
3 is a cross-sectional view of a bridge to which a clogged road surface drainage apparatus according to an embodiment of the present invention is applied.
4 is a plan view of a bridge surface drainage apparatus in which clogging is improved according to an embodiment of the present invention.
5 is a view showing a drainage grating of a bridge road drainage apparatus improved in clogging according to an embodiment of the present invention.
6 is a view showing a variation of a drainage grating of a bridge road drainage apparatus with improved clogging according to an embodiment of the present invention.
7 is a view showing a bridge road drainage apparatus in which clogging is improved according to another embodiment of the present invention.
8 is a view showing a bridge road drainage apparatus improved in clogging according to another embodiment of the present invention.
9 is a view showing an arrangement of a vortex forming portion of a bridge road drainage apparatus with improved clogging according to another embodiment of the present invention.
10 is a partially enlarged view of Fig.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the following description, the same or corresponding components are denoted by the same reference numerals And redundant explanations thereof will be omitted.

FIG. 3 is a cross-sectional view of a bridge to which a clogged road surface drainage apparatus according to an embodiment of the present invention is applied, and FIG. 4 is a plan view of a bridge surface drainage apparatus with improved clogging according to an embodiment of the present invention. 5 is a view showing a drainage grating of a bridge road drainage apparatus with improved clogging according to an embodiment of the present invention. 6 is a view showing a variation of the drainage grating of the bridge road drainage apparatus with improved clogging according to an embodiment of the present invention.

3 to 5 show the bottom plate 12, the asphalt 14, the inlet 16, the step 18, the inclined tube 20, the outlet 22, the drain pipe 24, The drainage pipe 26, the receiving portion 27, the drainage grating 28, the support block 30, the outer ribs 32, the inner ribs 34 and 34 ', the side end drainage holes 36, Are shown.

The bridge drainage apparatus according to the present embodiment is a bridge road drainage apparatus that improves clogging when draining sewage on the road surface of a bridge. The bridge drainage apparatus is disposed above the bottom plate 12 of the bridge, A stepped portion 18 formed inwardly from the other end of the inlet port 16 and extending from the inlet port 16 so as to penetrate through the bottom plate 12, A drain pipe portion 24 including an inclined pipe 20 whose cross section is reduced in a direction from the upper end to the lower end of the bridge and disposed on the lower surface of the bottom plate 12 of the bridge through the lower surface; A plurality of support blocks 30 supported by the step portion 18 and a plurality of support blocks 30 spaced apart from the inner side of the inlet 16 so as to introduce the wastewater from the road surface, And an inner rib 34 disposed across the interior of the outer rib 32 and includes a drainage grating 28 inserted into the inlet 16.

The drain pipe section 24 is a component that penetrates the bottom plate 12 of the bridge and discharges the waste water from the bridge road surface. The drain pipe section 24 can be installed in the mold before the concrete is laid to form the bridge bottom plate 12. When the concrete is installed and cured in a state where it is installed in the form, it is installed through the bottom plate 12 of the bridge. When the bottom plate 12 of the bridge is completed, the asphalt 14 or the like is installed thereon. When the asphalt (14) is installed, a previously formed drain pipe (24) is installed so as not to be clogged.

The drainage grating 28 is disposed above the drain pipe section 24 and serves to catch dirt such as leaves mixed with sewage on the bridge road surface.

Hereinafter, each configuration of the drain pipe section 24 and the drainage grating 28 will be described in detail with reference to FIGS. 3 to 5. FIG.

The inlet (16) is disposed on the top of the bottom plate (12) of the bridge, and sewage flows in one end. The inlet 16 according to this embodiment has a rectangular shape and is exposed on the bridge bottom plate 12 and has a rectangular frame shape. The inlet 16 may be formed in the shape of a rectangle, a square, a circle, or the like and may be formed into a rounded rectangle having a rounded corner.

The step portion 18 extends from the other end of the inlet port 16 and is formed inward. The step portion 18 is configured to support the support block 30 of the drainage grating 28 to be described later. The length of the step portion 18 inwardly is sufficient so long as the support block 30 is not detached downward. The stepped portions 18 are respectively formed at the corners of the rectangular inlet 16 and are thus constituted by four supporting blocks 30 of a drainage grating 28 to be described later.

In the case of the drainage device according to the related art, a step portion is also formed, which is not a construction for supporting the support block 30 of the drainage grating 28 like the present invention, It can be said that it is different from the step portion of the present invention as a step portion which necessarily occurs.

The inclined pipe 20 extends from the inlet 16 and is arranged to penetrate through the bottom plate 12 so that the inner surface of the inclined pipe 20 is inclined such that the cross section is reduced from the upper end of the bridge bottom plate 12 toward the lower end. The inclined pipe 20 can be disposed through the bottom plate 12. The cross section of the channel can be continuously reduced at the same inclination from the step 18 to the bottom end of the bottom plate 12. [

The inclined tube 20 may extend from the step portion 18 when the step portion 18 extends from the lower end of the inlet 16 to have a rectangular shape. However, if the step 18 is formed only at the four corners of the inlet 16, the slope tube 20 may extend from the inlet 16.

The inclined pipe 20 is formed at a single inclined angle so that it is possible to prevent clogging of the drainage device due to dirt while passing through the drainage grating 28 without passing dirt mixed with the wastewater.

The lower end of the inclined pipe 20 is embedded in the bottom plate 12 of the bridge and the outlet 32 is connected to the bottom plate of the bridge (20) so as to protrude from the undersurface of the bottom wall (12). A drain pipe 26 is connected to the outlet 32 and the wastewater that has passed through the bottom plate 12 of the bridge is drained to the lower portion of the bridge through the drain pipe 26.

The upper end of the inclined pipe 20 extending from the lower end of the inlet port 16 may have a quadrangular shape, but the lower end of the inclined pipe 20 may have a circular shape. A circular outlet 32 may be extended and coupled at the lower end of the circular ramp 20 and a circular drain pipe 26 may be connected to the circular outlet 32. [

3, the inlet port 16, the step portion 18, the inclined pipe 20 and the outlet port 32 are integrally formed to form one drain pipe portion 24, and the drain pipe portion 24 is connected to the bridge Penetrates through the bottom plate 12 and is embedded in the bridge bottom plate 12.

An annular receiving portion 27 protruding along the outer periphery of the drain pipe portion 24 may be formed on the outer periphery of the drain pipe portion 24. When the drain pipe portion 24 is installed in the bottom plate 12 of the bridge, the receiving portion 27 is embedded in the upper portion of the bottom plate 12 of the bridge.

Asphalt 104 may be installed on the upper part of the bottom plate 12 of the bridge to effectively treat the infiltration water of the bridge. In this case, the wastewater passing through the asphalt 104 flows along the outer surface of the drain pipe section 24 And can penetrate into the interior of the bridge deck 12.

If moisture penetrates into the bridge deck 12, it may cause deterioration of the concrete or reinforcing bars, thereby reducing the durability of the bridge. Therefore, in order to prevent such wastewater from penetrating into the bridge deck 12, And a receiving portion 27 is provided at the upper end of the receiving portion 24. When the bridge bottom plate 12 is formed of concrete by the protrusion of the receiving portion 27 to the outside of the drain pipe portion 24, the coupling force between the drain pipe portion 24 and the concrete is strengthened, It is possible to prevent infiltration into the interior of the first and second openings 12,

The drainage grating 28 includes a plurality of support blocks 30 supported by the step portion 18 and a plurality of support blocks 30 spaced from the inside of the inlet 16 so as to introduce the wastewater into the road surface, And an inner rib 34, 34 'disposed across the interior of the outer rib 32. The inner ribs 34, 34' The drainage grating 28 is supported by the step portion 18 while being inserted into the inlet 16 of the drainage pipe portion 24.

The support block 30 is arranged so as to be respectively supported by the corner portions of the rectangular step portion 18. The support block 30 is in the form of a block so that the load applied to the drainage grating 28 is transmitted to the bottom plate 12 of the bridge via the step 18.

In this embodiment, four supporting blocks 30 are provided corresponding to the step portions 18 formed at the corner portions of the rectangular inlet 16.

The outer ribs 32 are spaced apart from the inside of the inlet 16 to connect the plurality of support blocks 30, respectively. The four support blocks 30 are respectively disposed on the step portions 18 and the support blocks 30 located in the four corner portions are connected by the outer ribs 32. [ At this time, the outer ribs 32 are coupled to the support block 30 while being spaced a predetermined distance from the inside of the inlet port 16 in a state where they are inserted into the drain pipe portion 24. A side end drain port 36 is formed between the inner side of the inlet port 16 and the outer side rib 32 as the outer rib 32 is spaced a certain distance from the inlet port 16 so that the wastewater flowing from the end of the inlet port 16 And can be drained through the side-end drains 36.

The inner ribs 34 are coupled to the outer ribs 32 across the inside of the outer ribs 32. The inner ribs 34 according to the present embodiment are disposed between the outer ribs 32 in a direction perpendicular to the mutually facing outer ribs 32 and parallel to the remaining outer ribs 32. Although the linear inner rib 34 is disposed between the outer ribs 32 in this embodiment, it is also possible to arrange the inner ribs 34 'in the form of a lattice shape and small stones between the outer ribs 32.

If the outer ribs 30 and the inner ribs 34 serve to filter out dirt in a large lump mixed with wastewater, the dirt that has passed through the drainage grating 28 is drained by the slope tube 20 according to the present embodiment .

On the other hand, the inlet port 16 may be inclined so as to reduce the cross-section toward the lower end of the bottom plate 12 of the bridge. The inlet 16 is also provided with a slope on the inner wall so that the slope decreases toward the lower end of the bottom plate 12 in the same manner as the slant pipe 20 described above. 5, the outer ribs 32 are inclinedly engaged with the support block 30 so as to be parallel to the inclination of the inlet port 16, so that the gap between the inner side of the inlet port 16 and the outer ribs 32 Side drain port 36 is formed to have the same inclination as that of the inclined pipe 20 so that the wastewater passing through the side end drain port 36 is drained through the inclined pipe 20.

A plurality of drain grooves 38 are formed at the lower end of the outer rib 32 so that a large amount of wastewater is drained through the side end drains 36 between the inside of the inlet 16 and the outside ribs 32 . A large amount of wastewater can be easily drained while the wastewater flowing into the side-end drain port (36) moves to the inside of the sloped pipe (20) through the drainage groove (38).

FIG. 6 is a view showing a variation of the drainage grating of the bridge road drainage apparatus with improved clogging according to an embodiment of the present invention. In this modification, the shape of the inner rib is different, and the inner rib 34 'is formed in a spiral shape so as to extend radially from the central portion of the outer rib 32 so that wastewater from the road surface flows in a swirl form. When the amount of the wastewater is large, the wastewater can be formed as the wastewater flows into the drainage device, and the inner ribs 34 'are formed in the spiral shape corresponding to the spiral shape of the wastewater.

FIG. 7 is a view showing a bridge surface drainage apparatus improved in clogging according to another embodiment of the present invention. In the present embodiment, the inlet port 16 of the drain pipe section 24 is formed in a circular shape. In the present embodiment, the step portion 18 is formed in an imaginary square corner portion in contact with the inside of the circular inlet port 16 The support block 30 is also formed by four support blocks 30 corresponding to the step portions 18 and the inlet 16 is circular so that the outer ribs 32 are circular So that four supporting blocks 30 are connected.

In this embodiment as well, the inner ribs 34 'are formed in the form of small stones so as to easily discharge the wastewater, and the receiving portions 27 are also circularly shaped.

8 is a view showing a bridge road drainage apparatus in which clogging is improved according to another embodiment of the present invention. FIG. 9 is a view showing the arrangement of the vortex forming part of the bridge road drainage apparatus with improved clogging according to another embodiment of the present invention, and FIG. 10 is a partially enlarged view of FIG.

8 to 9 show an example in which the bottom plate 12, the asphalt 14, the inlet 16, the step 18, the inclined pipe 20, the drain pipe 24, the drain pipe 26, 27, a drainage grating 28, a leveling pipe 40, a tapered portion 41, an extension portion 42, an outlet pipe 43, a vortex forming portion 44, a wing plate 45, And a guide groove 48 are shown.

In this embodiment, the shape of the drain pipe portion is different from that of the above embodiment. In the drain pipe portion according to the present embodiment, in addition to the slant pipe 20, the lower end of the slant pipe 20 is inserted, A leveling pipe (40) to be determined; And an extension portion 42 extending from the tapered portion 41. The extension portion 42 is formed on the inclined tube 20 so that the extension portion 42 is connected to the tapered portion 41. [ And an outlet pipe (43) inserted so as to pass therethrough.

Since the height of the inclined pipe 20 is determined in advance, the bottom plate 12 of various thicknesses can be used as the bottom plate 12 ). Therefore, a separate leveling pipe 40 is provided to correspond to the height of the bottom plate 12. When the level of the bottom plate 12 is determined in the field, the leveling pipe 40 is cut to an appropriate height and the lower end of the inclined pipe 20 is positioned on the upper side of the leveling pipe 40, The slope tube 20 is installed so as to be inserted and supported. At this time, the height of the inclined pipe 20 and the leveling pipe 40 corresponds to the height of the bottom plate 12.

The height of the leveling pipe 40 is adjusted so that the upper end of the drain pipe portion is located on the same level as the upper portion of the asphalt pavement 14 in consideration of the height of the asphalt pavement 14 installed on the upper portion of the bottom plate 12 And suggests the installed form.

The slope pipe 20 and the leveling pipe 40 are installed through the bottom plate 12 and then the drain pipe 43 is connected to the slope pipe 20 and the leveling pipe 40 And the water pipe portion is installed. A tapered portion 41 is formed in the upper portion of the outflow pipe 43. When the outflow pipe 43 is passed through the inclined pipe 20, the inner surface of the inclined pipe 20 and the outer surface of the tapered portion 41 are in contact with each other The outflow pipe 43 is coupled to the inclined pipe 20.

After the outflow pipe 43 is installed, a drain pipe 26 may be connected to the lower end of the outflow pipe 43.

On the other hand, the vortex forming portion 44 can be disposed inside the inclined pipe 20 so that the drainage of the wastewater flowing into the drain pipe portion can be rotated in the form of a vortex so that drainage can be easily performed.

The swirl forming portion 44 is disposed inside the slant pipe 20 and causes swirling in the waste water flowing into the slant pipe 20. In the case of this embodiment, (44) includes a wing plate (45) whose upper and lower ends are corrugated and warped about a central portion. The wing plate 45 is inserted and disposed in the longitudinal direction of the inclined pipe 20. Guide projections 46 are formed on both sides of the blade plate 45 to facilitate the engagement between the blade plate 45 and the slant tube 20. The guide plate 46 is formed on the inner surface of the slant tube 20, The guide groove portion 48 into which the guide projection portion 46 is slidably inserted can be formed in the depth direction. The guide protrusion 46 of the blade plate 45 is slid along the guide groove 48 formed in the depth direction on the inner surface of the inclined pipe 20 when the blade plate 45 is inserted from the upper end of the inclined pipe 20 So that the wing plate 45 is coupled to the inside of the inclined pipe 20.

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 as defined in the appended claims. It will be understood that the invention may be varied and varied without departing from the scope of the invention.

Many embodiments other than the above-described embodiments are within the scope of the claims of the present invention.

12: bottom plate 14: asphalt
16: inlet port 18:
20: slant tube 22: outlet
24: drain pipe section 29: outlet pipe section
26: drain pipe 27: receiving portion
28: drainage grating 30: support block
32: outer ribs 34, 34 ': inner ribs
36: side end drain hole 38: drain drain groove
40: Leveling tube 41: Tapered part
42: extension part 43: outlet pipe
44: spiral forming part 45: wing plate
46: guide protrusion 48: guide groove

Claims (11)

As a bridge road drainage system that improves clogging when draining sewage on the road surface of bridges,
A bottom plate disposed at an upper portion of the bottom plate of the bridge and having an inlet through which the wastewater flows at one end, a stepped portion extending inward from the other end of the inlet, A drain pipe portion including an inclined pipe whose section is continuously reduced from the upper end to the lower end in the same inclination, the drain pipe portion passing through the lower surface of the upper surface of the bottom plate of the bridge;
A plurality of support blocks supported by the step portion; an outer rib spaced apart from the inner side of the inflow port to connect the plurality of support blocks to each other to allow wastewater from the road surface to flow therethrough; A drainage grating inserted into the inlet;
And a vortex forming part disposed inside the inclined pipe and causing a swirl in the waste water flowing into the inclined pipe,
The swirl-
And a wing plate having a top and a bottom formed in a corrugated shape and warped within one rotation about a central portion.
The method according to claim 1,
Further comprising an annular receiving portion protruding along the outer periphery of the drain pipe portion, wherein the clogging is improved.
The method according to claim 1,
Wherein the inlet is inclined so that a cross section thereof is reduced toward the lower end of the bottom plate of the bridge,
Wherein the outer rib is coupled to the support block in an inclined manner so as to be parallel to the inclination of the inlet.
The method according to claim 1,
The inlet has a quadrangular shape,
The step portion is formed at the corner portion of the inlet of the quadrangle,
The support block includes:
Wherein the bridge is constructed by four support blocks corresponding to corners of the inlet.
The method according to claim 1,
Wherein said inner rib of said drainage grating
Wherein the wastewater is radially extended from a central portion of the outer rib in a swirling manner so that wastewater on the road surface flows in a swirling manner.
The method according to claim 1,
The inlet has a circular shape,
The step-
And a plurality of protrusions formed on corner portions of a square in contact with the inside of the circular shape,
The support block includes:
And four support blocks corresponding to the step portions, respectively,
The outer rib
And the four supporting blocks are circularly connected to each other.
The method according to claim 1,
Further comprising an outlet extending from the lower end of the ramp so as to protrude from the lower surface of the bottom plate of the bridge,
Characterized in that a drain pipe is coupled to the outlet.
The method according to claim 1,
The bottom plate of the bridge is formed by placing unhardened concrete in a mold for forming a bottom plate,
The water pipe portion,
A leveling pipe into which a lower end of the inclined pipe is inserted and whose height is determined according to a height of the bottom plate;
Further comprising a tapered portion whose outer surface corresponds to the inner surface of the lower end of the tapered tube and an extension portion extending from the tapered portion and which is inserted into the tapered tube so as to penetrate the extended portion, Surface drainage.
delete delete The method according to claim 1,
Wherein a guide protrusion is formed on both sides of the wing plate and a guide groove is formed in an inner surface of the inclined pipe so that the guide protrusion is slidably inserted in a depth direction.

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