KR20130092842A - Drain pipe for bridge - Google Patents

Abstract

PURPOSE: A drainpipe for a bridge surface is provided to flow smoothly drainage instantaneously according to a rain fall pattern change by ejecting while controlling a flow rate of a flux. CONSTITUTION: A drainpipe for a bridge surface comprises a drainpipe (100) and a flow control means. The drainpipe comprises a bottom surface, a sidewall, and a waterway (104). A bottom inclined plane (110) is included in order to perform drainage of rain water quickly, and to adjust a flow of the rain water flowed in by being formed integrally in both sides of the drainpipe.

Description

Drain pipe for bridge

The present invention relates to a bridge bridge drain pipe, and more particularly, to a bridge bridge drain pipe that provides a drain pipe installed in the bridge drainage passage of the bridge, the rainwater flowing through the drain pipe can increase the stable drainage efficiency without disturbing the flow.

In general, as shown in FIG. 14, in the bridge 1, a water collecting port 2 is installed at the side of a shoulder barrier or a central separator side of the bridge top plate to prevent flooding in the bridge by rainy weather or localized torrential rain, and the horizontal drain pipe 3 ) Was discharged to the bottom of the bridge (1) through the drain pipe (10) installed on the side of the bridge (1).

However, the bridge drainage pipe 10 installed in the conventional bridge has a wide installation interval with the horizontal drainage pipe 3, so that when the instantaneous drainage flows rapidly due to the change of rainfall patterns such as localized heavy rainfall, the blockage occurs and leaks. There was a problem that the drainage efficiency rapidly decreases with increasing distance.

This may provide a cause of increasing traffic accidents due to flooding of bridge sections.

In addition, when the drain pipe 10 is steeply inclined and the flow rate rapidly descends, many soils and residues are mixed together with the flow rate to block the drain pipe.

In addition, when the flow of the drain is not smooth, there are various problems, such as dirt or plant growth occurs in the connection of the drain pipe, not only poor appearance, but also rust easily occurs, resulting in time and cost for maintenance.

An object of the present invention is to bridge the bridge cross-drain pipe to facilitate the flow of instantaneous drainage according to the change in the rainfall pattern by discharging the flow rate discharged to the catch port for draining the inundation in the bridge while adjusting the flow rate of the flow rate in the drain pipe Is to provide.

Another object of the present invention is to provide a bridge bridge drain pipe to prevent the rapid decrease in drainage efficiency due to the increase in the outflow distance of the drain pipe installed in the bridge.

The present invention is another object. It is intended to provide a bridge bridge drain pipe to provide a smooth drainage structure by providing a rapid drainage structure to the drainage pipe is drained to maximize the drainage efficiency due to the sudden increase in flow rate.

The present invention, in order to achieve the above object, the bottom; Side walls erected vertically on both sides of the floor; A drain passage through which rainwater flows inside the bottom and the sidewalls; Comprising a drain pipe, comprising a flow rate adjusting means having a bottom inclined surface which is formed integrally on both sides with respect to the center of the bottom of the drain pipe to adjust the flow of rainwater flowing in, and to enable the drainage of rainwater quickly; It provides a bridge bridge drain pipe, characterized in that comprising a.

In addition, the present invention, in order to achieve the above object, the bottom inclined surface of the flow rate adjusting means, it is raised from the center bottom of the drain pipe is formed to form a predetermined inclination angle to both sides to the front and rear inlet of the drain pipe Provide a cross drain.

In addition, the present invention, in order to achieve the above object, the bottom inclined surface of the flow rate adjusting means is perpendicular to the step shape along the bottom inclined surface. It provides a bridge bridge drain pipe, characterized in that it is formed to have a stepped inclined portion is repeated horizontally.

In another aspect, the present invention provides a bridge bridge drain pipe, characterized in that the bottom inclined surface of the flow rate adjusting means is formed to have a slope inclined portion is repeated diagonally on the bottom inclined surface.

In addition, the present invention provides a bridge bridge drain pipe, characterized in that the bottom inclined surface of the flow rate adjusting means is formed to have a plurality of concave grooves along the inclined angle of the bottom inclined surface.

In addition, the present invention, in order to achieve the above object, the flow rate adjusting means is formed to have a certain depth across the drain pipe longitudinally in the center of the bottom inclined surface, drainage inlet formed to receive the rainwater flowing into the drain pipe It provides a bridge bridge drain pipe characterized in that it further comprises a groove.

In addition, the present invention, in order to achieve the above object, the drain inlet, the bottom of the drain inlet vertically penetrates the bottom of the drain pipe, the lower end portion of the front and rear of the drain pipe in one direction It provides a bridge bridge drain pipe, characterized in that the drain hole further penetrates to the inlet of.

In addition, the present invention, in order to achieve the above object, the flow rate adjusting means is divided into both sides at the center of the bottom inclined surface formed to have a certain depth across the drain pipe longitudinally, to receive the excellent flow into the drain pipe It further comprises a double drain inlet is formed to give, the drain inlet is vertically penetrates the bottom of the drain pipe from the bottom, the lower end of the penetrating penetrates to the inlet of the front and rear of the drain pipe in both directions It is provided a bridge bridge drain pipe, characterized in that the drain hole is further formed.

The present invention, the bottom; Side walls erected vertically on both sides of the floor; A drain passage through which rainwater flows inside the bottom and the sidewalls; Comprising a drain pipe, comprising a flow rate adjusting means having a bottom inclined surface which is formed integrally on both sides with respect to the center of the bottom of the drain pipe to adjust the flow of rainwater flowing in, and to enable the drainage of rainwater quickly; It is made, including, the flow rate discharged to the catchment drain draining the inundation in the bridge while controlling the flow rate of the flow rate in the drain pipe to greatly improve the effect of smoothly instantaneous drainage flow according to the rainfall pattern change have.

In another aspect, the present invention, the flow rate adjusting means is raised from the bottom of the center of the drain pipe to have a bottom inclined surface on both sides to the front and rear inlet of the drain pipe, so as to cross a predetermined depth to the center of the bottom slope of both sides. It is configured to further include a boundary groove formed, there is a greatly improved effect to prevent the rapid decrease in drainage efficiency due to the increase in the outflow distance of the drain pipe installed in the bridge.

In addition, the present invention. In the center of the boundary groove is further provided with a drainage hole which vertically penetrates to the bottom, one end of which penetrates penetrates in one direction or in both directions along the longitudinal direction of the drainage pipe. It is provided with a greatly improved effect to maximize the drainage efficiency due to the sudden increase in flow rate to enable a smooth drainage.

1 to 6 show a first embodiment of the bridge bridge drain pipe according to the present invention,
1 is a state diagram showing a bridge provided with bridge bridge drain pipe according to the present invention,
Figure 2 is a longitudinal sectional view showing a main portion of the bridge bridge drain pipe is installed according to the present invention,
3 is a perspective view showing a bridge bridge drain pipe according to the present invention,
4 is a longitudinal sectional view of Fig. 3,
5 is a cross-sectional view of FIG. 3,
6 is a state diagram showing that the bridge bridge drain pipe according to the present invention is installed for each section,
Figure 7 is another second embodiment showing an inclined surface which is a flow rate adjusting means according to the bridge bridge drain pipe according to the present invention,
Figure 8 is another third embodiment showing an inclined surface which is a flow rate adjusting means according to the bridge bridge drain pipe according to the present invention,
Figure 9 is another fourth embodiment showing an inclined surface which is a flow rate adjusting means according to the bridge bridge drain pipe according to the present invention,
10 is another fifth embodiment of the drain pipe according to the bridge bridge drain pipe according to the present invention;
11 is a longitudinal sectional view of FIG. 10;
12 is a cross sectional view of FIG. 10;
Figure 13 is another sixth embodiment of the drain pipe according to the bridge bridge drain pipe according to the present invention,
14 is a state diagram showing a bridge bridge drain pipe according to the prior art.

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

It is to be understood that the present invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to inform.

1 to 6 show a first embodiment of the bridge bridge drain pipe according to the present invention.

The bridge bridge drain pipe according to the present invention includes: a drain pipe 100 having a drain passage 104 through which rainwater flows; A flow rate adjusting means formed on the bottom 101 of the drain pipe 100; .

1 and 2, the drain pipe 100 is discharged to the lower end of the bridge receiving the rain discharged through the horizontal drain pipe (3) connected to the catch (2) installed on the shoulder or the central separator of the bridge (1) In this case, it is preferable to be installed in combination with the horizontal drainage pipe (3) which is provided in a protruding form in both the transverse direction of the bridge in the direction of passage of the vehicle along the passage (not shown) of the water collecting port (2).

3 to 5, the drain pipe 100 is connected to the horizontal drain pipe 3 connected to the water collecting port 2 of the bridge 1 and flows rainwater. It includes a side wall (102) (103) perpendicular to both sides of the floor 101, and the drainage passage (104) opened so that rainwater flows inside the floor (101) and the side walls (102) (103). It is configured by.

In addition, the drain pipe 100 is preferably formed to have a drain pipe connecting groove 105 for connecting the horizontal drain pipe (3) to any one of the side walls (102, 103) of the left and right side walls. It is preferably installed so as to be connected to the protruding end of the horizontal drain pipe (3), the horizontal drain pipe (3) may be installed on the upper portion of the drain pipe (10).

In addition, the drain pipe 100 is configured to further include a flow rate adjusting means for adjusting the flow rate of rainwater falling from the horizontal drain pipe (3) along the bottom (101).

The flow rate adjusting means is preferably formed to have a bottom inclined surface (110, 110 ') is raised from the center of the bottom 101 of the drain pipe 100 and separated to both sides to the front and rear inlet of the drain pipe (100). Do.

Referring to FIGS. 3 and 4, the flow rate adjusting means of the drain pipe 100 has both rain bottom slopes 110 (as the rain drops falling from the horizontal drain pipe 3 spread through the bottom slope 110). 110 '), the flow rate first flowing down the one bottom inclined plane 110 is quickly flowed along the bottom inclined plane 110, the flow rate flowing to the other bottom inclined plane 110' is drain pipe (100) By joining with the flow rate drained in the previous step of overflowing again to the bottom slope 110, it is possible to adjust the excellent flow rate from the sudden inflow of the horizontal drain pipe (3).

In other words, as shown in FIG. 6, the bottom inclined surfaces 110 and 110 ′ of the drain pipe 100 are different from the drain pipe 100 and other drain pipes 100 which are continuously installed along the longitudinal direction of the bridge 1. It is preferable that a plurality of bottom inclined surfaces 110 and 110 ′ are continuously connected along the bottom 101 for each section length direction of the cross section. This is because the flow rate of the rainwater flowing along the drain pipe 100 matches with the rainwater discharged from the horizontal drain pipe 3 installed at each interval of the drain pipe 100, but it is possible to adjust that the flow rate suddenly increases.

On the other hand, the flow rate adjusting means, when instant rainfall occurs rapidly, more rainwater can be introduced rapidly through the drainage pipe 100 through the horizontal drain pipe (3). Therefore, it is possible to provide a structure that can separate the flow of flow by classifying the water spread (wave) of the flow rate flowing into the drain pipe 100 rapidly flowing through the horizontal drain pipe (3) to both sides.

Thus, another embodiment of the floor inclined surface as a flow rate adjusting means according to the bridge bridge drain pipe according to the present invention as follows.

Hereinafter, the embodiments will be described with reference to a partially enlarged view applied to the “P” portion of the bottom inclined surface 100 of FIG. 5.

< Example  2>

 Figure 7 is another second embodiment showing a floor inclined surface which is a flow rate adjusting means according to the bridge bridge drain pipe according to the present invention.

The bottom inclined surface 110, which is the flow rate adjusting means, is raised from the center bottom 101 of the drain pipe 100 and has bottom inclined surfaces 110 and 110 ′ on both sides to the front and rear inlets of the drain pipe 100. The bottom slopes 110 and 110 'may be formed on both sides of the bottom slopes 110 and 110' such that the stepped slope 111 is repeated in a step shape.

That is, rainwater falling from the horizontal drain pipe 3 to the bottom inclined surfaces 110 and 110 ′ of the drain pipe 100 is stepwise along the stepped slope 111 formed on the bottom inclined surfaces 110 and 110 ′. It is possible to give an effect to flow down, so that the inflow flow rate and the time difference joining through the horizontal drain pipe (3) in the entire section of the drain passage (104). This is to prevent sudden confluence of flow in one place by instantaneous flow inflow according to the change of rainfall pattern so that it can be quickly dealt with and drained.

< Example  3>

Figure 8 is another third embodiment showing a floor inclined surface which is a flow rate adjusting means according to the bridge bridge drain pipe according to the present invention.

The bottom inclined surface 110, which is the flow rate adjusting means, is raised from the center bottom 101 of the drain pipe 100 and has bottom inclined surfaces 110 and 110 ′ on both sides up to the front and rear inlets of the drain pipe 100. The bottom slopes 110 and 110 ′ may be formed on both sides of the bottom slopes 110 and 110 ′ in which the slope slopes 113 are inclined diagonally.

That is, the rain drops falling from the horizontal drain pipe 3 to the bottom slopes 110 and 110 ′ of the drain pipe 100 are stepwise along the slope slopes 111 formed on the bottom slopes 110 and 110 ′. It is possible to give an effect to flow down, so that the inflow flow rate and the time difference joining through the horizontal drain pipe (3) in the entire section of the drain passage (104). This is to prevent sudden confluence of flow in one place by instantaneous flow inflow according to the change of rainfall pattern so that it can be quickly dealt with and drained.

< Example  4>

Figure 9 is another fourth embodiment showing a bottom inclined surface which is a flow rate adjusting means according to the bridge bridge drain pipe according to the present invention.

The bottom inclined surface 110, which is the flow rate adjusting means, is raised from the center bottom 101 of the drain pipe 100 and has bottom inclined surfaces 110 and 110 ′ on both sides up to the front and rear inlets of the drain pipe 100. And a plurality of concave grooves 115 formed along the inclination angles of the bottom inclined surfaces 110 and 110 'to both sides of the bottom inclined surfaces 110 and 110'.

That is, the rainwater falling from the horizontal drain pipe 3 to the bottom inclined surfaces 110 and 110 ′ of the drain pipe 100 is stepwise along the concave groove 115 formed in the bottom inclined surfaces 110 and 110 ′. It can be effected to flow down, it is possible to put a time difference and the inflow flow rate that is joined through the horizontal drain pipe (3) in the entire section of the drainage passage (104). This is to prevent sudden confluence of flow in one place by instantaneous flow inflow according to the change of rainfall pattern so that it can be quickly dealt with and drained.

On the other hand, the flow rate adjusting means of the drain pipe 100, when the instant rainfall occurs rapidly, more rainwater through the horizontal drain pipe (3) can be introduced more rapidly through the drain pipe (100). Therefore, it may be provided with a structure that can slow down the flow (wave) of the flow rate flowing through the horizontal drain pipe (3) rapidly falling into the drain pipe (100).

Thus, another embodiment of the floor inclined surface which is the flow rate adjusting means according to the bridge bridge drain pipe according to the present invention as follows.

< Example  5>

10 is yet another embodiment of the drain pipe according to the bridge bridge drain pipe according to the present invention.

The drain pipe 100 is formed to cross at a predetermined depth in the center of the bottom inclined surfaces 110 and 110 ′ which are bisected along the center of the floor 101 to receive rainwater falling from the horizontal drain pipe 3. A drain inlet groove 120 may be configured.

In addition, a center of the drain inlet 120 is vertically penetrated to the bottom 101, the lower end of which is further provided with a drain hole 121 is penetrated along the longitudinal inner side of the drain pipe 100 in one direction. desirable.

 That is, while receiving the rainwater flowing in the horizontal drainage pipe 3 through the drainage inlet 120, at the same time to reduce the water spread (wave) of the falling rain can be concentrated in one place, the drainage Some of the rainwater is rapidly drained through the hole 121, and the flow rate overflowing the drain inlet groove 120 is rapidly drained through the bottom slopes 110 and 110 'or the flow rate is rapidly contained in one place. The control function can be prevented to prevent it.

In other words, part of the rainwater is discharged quickly, and another part of the rainwater may give a time difference in which the flow rate is contained while flowing along the bottom slopes 110 and 110 ', and the drainage path 104 of the drain pipe 100 It will be able to cope with the sudden increase in rainwater flowing along.

< Example  6>

Figure 13 is another sixth embodiment of the drain pipe according to the bridge bridge drain pipe according to the present invention.

The drain pipe 100 is formed to cross at a predetermined depth in the center of the bottom inclined surfaces 110 and 110 ′ which are bisected along the center of the floor 101 to receive rainwater falling from the horizontal drain pipe 3. The drainage inlet grooves 130 and 130 'may be configured to have a double structure that is classified into both sides.

In addition, the center of the drain inflow grooves 130 and 130 ′ vertically penetrates to the bottom 101, and a lower end thereof penetrates along the longitudinal direction of the drain pipe 100 in both directions. 132 is preferably further provided.

 That is, while receiving the rainwater flowing in the horizontal drainage pipe (3) through the drainage inlet 130, at the same time to reduce the water spread (wave) of the falling rain can be concentrated in one place, the both sides Drainage holes 131 and 132 of the drain is to be drained more quickly, and the flow rate overflowing the drain inlet grooves 130, 130 'is quickly drained through the bottom slopes (110, 110') or It is possible to have a control function to prevent the flow rate from rapidly confining in one place.

In other words, part of the rainwater is discharged quickly, and another part of the rainwater may give a time difference in which the flow rate is contained while flowing along the bottom slopes 110 and 110 ', and the drainage path 104 of the drain pipe 100 It will be able to cope with the sudden increase in rainwater flowing along.

On the other hand, the drain pipe 100 may be protected by covering a separate protective cover 200.

Therefore, it is preferable that the upper ends of the left and right sidewalls 102 and 103 are bent outward to form guide pieces 106 and 107 for sliding the protective cover 200.

Here, the protective cover 200 is superimposed on the open upper end of the drain pipe 100 to prevent contaminants such as dirt, garbage, etc. in addition to rainwater in the drain 104 of the drain pipe 100, the protective cover ( It is formed as a flat cover plate 201 made horizontally along the longitudinal direction of the 200, and is formed in a shape that is bent inwardly bent at both sides of the longitudinal direction of the cover plate 201 to the left and right of the drain pipe 100 Preferably, slide pieces 202 and 203 for sliding along the guide pieces 106 and 107 formed on the upper sidewalls 102 and 103 are formed.

For reference, the protective cover 200 is overlapped with the drain pipe 100 is preferably a sliding form, in some cases the rubber seal for sealing (not shown) to the guide piece 106, 107 of the drain pipe 100 It can be installed by covering the protective cover in the form of a lid.

And it is preferable that the drain pipe 100 is installed by connecting to the bridge (1) with a connecting bracket 300 for fixing the drain pipe (100), the connecting bracket 300 is along the bridge (1) It is preferable to be installed to maintain a constant interval along the drain pipe 100 installed for each section.

Hereinafter, the operational effects of the bridge bridge drain pipe according to the present invention will be described.

The bridge bridge drain pipe according to the present invention can drain a large amount of instantaneous inflow, such as localized heavy rain, by the cross-sectional horizontal drain pipe 3 connected to the catchment port along the longitudinal direction of the bridge.

In addition, by the bottom slopes 110 and 110 ′ formed on the bottom 101 of the drain pipe 100, the flow rate of rainwater flowing in a predetermined section is concentrated in one place at a time to reduce the drainage efficiency. The bottom slopes 110 and 110 ′ continuously connected to each section of the drain pipe 100 may adjust the flow rate due to time difference so that a large amount of rain may not be concentrated in one place, thereby achieving smooth drainage efficiency.

In addition, it is preferable that the bottom inclined surfaces 110 and 110 ′ of the drain pipe 100 have a height about 3 cm higher than that when the bottom of the drain pipe 100 is horizontal. This is a flow rate at one place by adjusting the flow rate of the flow rate flowing through the bottom inclined plane 110 (110 ') while giving a time difference between the flow rate flowing into the drain pipe 100 first and the flow rate which flows continuously immediately afterwards. This is to maintain a desirable slope to give a margin of time that can be gathered.

On the other hand, while receiving the rainwater flowing in the horizontal drainage pipe (3) through the drainage inlet 120, at the same time to reduce the water spread (wave) of the falling rain can be concentrated in one place A portion of the rainwater is rapidly drained through the drainage hole 121, and the flow rate overflowing the drainage inflow groove 120 is quickly drained through the bottom slopes 110 and 110 ′ or where the flow rate is rapidly. The control function can be prevented from being contained in the system.

That is, a part of the rainwater is discharged quickly, and the other part of the rainwater may give a time difference in which the flow rate is contained while flowing along the bottom slopes 110 and 110 ', and the drainage path 104 of the drain pipe 100 is discharged. It will be able to cope with the sudden increase in the amount of rain that flows along.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims and their equivalents.

100: drain pipe 101: bottom
102, 103 sidewall 104: drainage
105: drain pipe connection groove 110, 110 ': floor slope
111: stepped slope 113: slope slope
115: recessed groove 120, 130, 130 ': drainage inlet groove
121, 131: drainage hole

Claims (8)

Bottom 101;
Sidewalls (102) (103) erected perpendicular to both sides of said floor;
A drain passage 104 through which rainwater flows inside the bottom 101 and the side walls 102 and 103; It consists of a drain pipe 100,
The bottom slopes 110 and 110 ′ are formed integrally with both sides based on the center of the bottom 101 of the drain pipe 100 to adjust the flow of rainwater flowing in, and to allow drainage of rainwater quickly. Flow rate adjusting means having; Bridge bridge drain pipe, characterized in that consisting of.
According to claim 1, wherein the bottom slope 110, 110 'of the flow rate adjusting means,
A bridge bridge drain pipe, characterized in that it is raised from the center bottom 101 of the drain pipe 100 to form a predetermined inclination angle to both sides to the front and rear inlet of the drain pipe (100).
According to claim 2, wherein the bottom inclined surface 110, 110 'of the flow rate adjusting means,
Vertically in a staircase shape along the bottom slopes 110 and 110 ′. Bridge bridge drainage pipe, characterized in that it is formed to have a stepped inclined portion 111 is repeated horizontally.
According to claim 2, wherein the bottom inclined surface 110, 110 'of the flow rate adjusting means,
Bridge bottom drain pipe, characterized in that formed on the bottom slopes 110, 110 'to have a slope inclined portion 113 is repeated inclined diagonally.
According to claim 2, wherein the bottom inclined surface 110, 110 'of the flow rate adjusting means,
Bridge bridge drainage pipe, characterized in that it is formed to have a plurality of concave grooves 115 along the inclination angle of the bottom inclined surface (110) (110 ').
The method of claim 1, wherein the flow rate adjusting means,
The drain inlet groove 120 is formed to have a predetermined depth across the drain pipe 100 in the center of the bottom slopes 110 and 110 ′, and to receive rainwater flowing into the drain pipe 100. Bridge bridge drain pipe, characterized in that further comprises.
The method of claim 1 or 6, wherein the drain inlet groove 120,
The drainage that vertically penetrates the bottom 101 of the drainage pipe 100 from the bottom of the drainage inflow groove 120, and the lower end portion thereof penetrates to the inlet of the front and rear ends of the drainage pipe 100 in one direction. Bridge bridge drain pipe, characterized in that the hole 121 is further formed.
The method of claim 1, wherein the flow rate adjusting means,
It is divided into both sides in the center of the bottom inclined surface (110, 110 ') is formed to have a certain depth across the drain pipe 100 in the longitudinal, and is formed to receive the rainwater flowing into the drain pipe (100) It further comprises a drain inlet groove 130, 130 ',
The drain inlet grooves 130 and 130 ′ vertically penetrate the bottom 101 of the drain pipe 100 at the bottom thereof, and the lower end portion thereof penetrates to the inlet of the front and rear ends of the drain pipe 100 in both directions. Bridge bridge drain pipe, characterized in that the drainage holes 131, 132 are further formed.

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