KR20210131096A - Bridge drainage system for increasing drainage power and drainpipe safety - Google Patents

Abstract

The present invention relates to a bridge drainage system having improved drainage capacity and pipe installation safety, which is connected to a water catchment basin installed on a pavement surface of a bridge and allows drainage through a drain pipe supported through a hanger installed on an upper structure of the bridge.

Description

Bridge drainage system for increasing drainage power and drainpipe safety

The present invention relates to a drainage system applied to a bridge, and in particular, to a bridge drainage system having an increase in drainage power and safety in piping installation by increasing drainage power at a catchment and stably supporting a drain pipe by adding a hanger support. will be.

The bridge's drainage system helps vehicles drive safely by discharging rainwater covered by the pavement to the outside of the road in case of rain. To this end, the pavement is provided with a water collecting port for collecting rainwater that has fallen on the pavement at predetermined intervals, and a drain pipe is connected to the water collecting port to discharge rainwater to a designated location. At this time, the drain pipe is installed to have a slope for drainage and is connected to the bridge structure through a hanger.

Therefore, the water collecting port should be able to collect water smoothly even during heavy rain, so that it should be discharged through the drain pipe quickly. If drainage is not performed smoothly at the catchment, rainwater collects on the road surface, making it more difficult for the vehicle to safely drive. On the other hand, since the drain pipe is installed long in structure, it is supported through a plurality of hangers, and since the drain pipe is installed with an inclination, the length of the hanger is installed differently. Therefore, in order to increase the support capacity of the hanger, it is necessary to consider the length of the hanger.

Therefore, in the bridge drainage system, a method to increase the drainage capacity of the catchment and the support capacity of the hanger is required.

As a technology that is the background of the present invention, as Korean Patent Registration No. 10-1002440, 'a catchment port of a rainwater drainage device for a bridge' is proposed. This is because when rainwater generated on the bridge surface of the bridge top is collected and drained through the catchment, the sludge filter in the form of a blower fan of the cover body and the sloping plate forming the bottom of the collecting tank are formed in the form of an impeller in the lateral direction. It is designed to increase the drainage efficiency of rainwater generated on the bridge surface of the bridge deck even through the catchment of the same size by increasing the flow rate of the drained rainwater. However, in the background art, since the impeller-shaped swash plate is a fixed type, there is a limit in increasing the drainage power.

As another background art of the present invention, as Korean Utility Model Registration No. 20-0461566, a 'bridge drainage pipe structure' is proposed. This is to install a T-shaped rail in the drain pipe, insert the embedded hanger insert spacer to the T-shaped rail and connect the hanger rod to the embedded hanger insert spacer to support it. However, in the background art, since the drain pipe is hung on the hanger bar, not only the supporting force of the hanger bar is increased, but also the hanger bar is vulnerable to shaking, thereby reducing the installation safety of the drain pipe.

Korean Patent Registration No. 10-1002440 Korea Registered Utility Model Registration No. 20-0461566

An object of the present invention is to provide a bridge drainage system having an increase in drainage capacity and safety in piping installation by increasing drainage power at a catchment and stably supporting a drain pipe by adding a hanger support.

Bridge drainage system having increased drainage power and pipe installation safety according to a suitable embodiment of the present invention is connected to a water catchment installed on the pavement surface of the bridge and at the same time draining the bridge drainage through a drain pipe supported through a hanger installed on the bridge superstructure In the system, the water collecting port comprises: a catchment body having an upper water collecting inlet for introducing rainwater at an upper end and a lower collecting and draining port having a smaller diameter than the upper water collecting inlet at the lower end and draining rainwater; a grating installed on the upper water collecting inlet side of the water collecting body to divide the upper water collecting inlet into several smaller sizes; a wing support shaft for inducing a vortex having one end fixedly installed in the central portion of the grating and disposed inside the water catchment body; A propeller for inducing a vortex that is freely supported on the other end of the wing support shaft for forming a vortex and causes a water vortex in the rainwater flowing in from the upper catchment inlet; and the hanger is an upper connection bracket that is fixedly installed on the upper structure of the bridge, a vertical hanger comprising a full screw bolt having one end inserted into the upper connection bracket and fixed with a nut, a clamp coupler connected to the lower end of the front screw bolt, and a circular clamp connected to the clamp coupler by wrapping and tightening the drain pipe; It is characterized in that it includes a hanger support to increase safety by grabbing the all-screw bolt from the bridge superstructure to catch the shaking that may be generated due to drainage or wind load.

In addition, the bridge drainage system having increased drainage power and pipe installation safety according to another suitable embodiment of the present invention is connected to a water catchment installed on the pavement surface of the bridge and at the same time drained through a drain pipe supported through a hanger installed on the bridge upper structure. A bridge drainage system comprising: a catchment body having an upper catchment inlet for introducing rainwater at an upper end and a lower collecting outlet having a smaller diameter than the upper catchment inlet at the lower end and draining rainwater; a grating installed on the upper water collecting inlet side of the water collecting body to divide the upper water collecting inlet into several smaller sizes; an actuator mounted on the lower surface of the central part of the grating; It is coupled to the rotation shaft of the actuator and forcibly pushes rainwater flowing in from the upper catchment inlet into a vertical pipe to increase the discharge flow rate; consists of a propeller for pressurizing water flow; a vertical hanger comprising a bracket, a full screw bolt having one end inserted into the upper connection bracket and fixed with a nut, a clamp coupler connected to the lower end of the front screw bolt, and a circular clamp connected to the clamp coupler by wrapping and tightening the drain pipe; It is characterized in that it includes a hanger support to increase safety by grabbing the all-screw bolt from the upper structure of the bridge to catch the shaking that may be generated due to drainage or wind load.

In addition, the hanger support is a position adjustment jig that is inserted into the all-screw bolt to adjust the position up and down, a tilting rod having one end hinged to the position adjustment jig, a screw shaft for length adjustment having one end screwed to the other end of the tilting rod, a hinge bracket fixed to the other end of the screw shaft for length adjustment, a hinge bracket and a reinforcing hanger upper bracket that is hingedly connected to the upper connection bracket of the vertical hanger at a predetermined distance and fixed to the bridge; The all-screw bolt is characterized in that the upper and lower jig fixing nuts are screwed to fix the position of the position adjustment jig.

In addition, the positioning jig includes a jig body having a U shape, a through hole through which a full screw bolt is inserted into one end of the jig body, a tilting rod insertion groove formed in the other end of the jig body, and a tilting rod insertion groove in the jig body. It is characterized in that it includes a hinge bolt installed to hinge the tilting rod through it.

In addition, the water collecting port has a predetermined radius of curvature and an inclined surface for inducing a tornado inclined in one direction along the curvature radius, which is arranged in a circle on the inclined inner wall of the water catchment body, and generates a tornado according to centrifugal force in the drainage flow. It is characterized in that more sides are provided.

In addition, the central axis of the vertical pipe is installed with a certain amount of eccentricity (S) from the central axis of the drain pipe, so that the water flow in the vertical pipe flows in a tangential direction to the drain pipe.

In addition, it is characterized in that the connection portion of the vertical pipe is installed to have a constant inclination angle with the vertical perpendicular to the central axis of the drain pipe so that the water flow flowing into the drain pipe from the vertical pipe is converted into a vortex shape.

In addition, in the catchment, a ring flange to be installed in the lower catchment and drain hole, a cylindrical wall formed with the same radius as the lower catchment in the ring flange, a part of the cylindrical wall is cut in a circular arrangement, and inclined in one direction to generate a tornado-type discharge water flow. It is characterized in that a tornado water flow induction ring having a blade for inducing a tornado water flow is further installed.

In addition, it has a buried hanger insert spacer that is installed in the bridge superstructure to determine the covering interval of reinforced reinforcement and is coupled to a hanger bolt that supports the hanger to the bridge superstructure, and a screw hole screwed with the hanger bolt. A tab block for height adjustment combined with the hanger insert spacer is further included; The embedded hanger insert spacer is composed of a rectangular channel type penetrating from one side to the other, and is characterized in that a tab block coupling groove is formed on the lower surface and a concave reinforcing bar support jaw is formed on the upper surface.

In addition, in response to an increase in the covering interval of the reinforcing bars, it is characterized in that one or more additionally installed height-adjustable tab blocks are additionally provided at the lower portion of the embedded hanger insert spacer.

According to the bridge drainage system with increased drainage power and pipe installation safety of the present invention, the propeller for vortex induction installed in the catchment generates a tornado in the rainwater flow, so that even if a large amount of rainwater is introduced, it is quickly discharged to the lower catchment drain without clogging. The driving safety of the vehicle on the bridge will be improved even in rainy weather.

In addition, the blade for inducing a drainage tornado installed in the catchment can provide the centrifugal force to the drainage flow from the inclined inner wall of the catchment body to generate a larger tornado, thereby further increasing the drainage force.

In addition, the hanger installed to support the drain pipe is composed of a vertical hanger and a hanger support, and the supporting force is shared. rises

In addition, it is possible to adjust the length of the hanger shaft by the screw shaft for adjusting the length of the hanger support side, and at the same time, the position of the position adjustment jig coupled to the vertical hanger can be adjusted with the all-screw bolt, so it is easy to support the hanger according to the length of the vertical hanger can be installed easily.

The following drawings attached to this specification illustrate preferred embodiments of the present invention, and serve to further understand the technical spirit of the present invention together with the detailed description of the present invention, so the present invention is limited to the matters described in the accompanying drawings It should not be construed as being limited.
1 is a block diagram of a bridge drainage system according to an embodiment of the present invention.
FIG. 2 is a configuration diagram of the water collecting port shown in FIG. 1 ;
Fig. 3 is a perspective view of the water collecting port body shown in Fig. 2;
Fig. 4 is a plan view of Fig. 3;
5 is a cross-sectional view taken along line KK of FIG.
Figure 6 is a perspective view of a hanger applied to the bridge drainage system of the present invention.
Fig. 7 is a front view of the hanger shown in Fig. 6;
8 is a partially exploded view of the hanger shown in FIG. 6 ;
9A is a perspective view of a water sump according to another embodiment of the present invention;
Fig. 9B is a longitudinal sectional view of Fig. 9A;
Fig. 9c is an exploded perspective view of the water collecting port shown in Fig. 9a;
Figure 10a is a perspective view of the tornado water flow induction ring applied to Figure 9a.
Figure 10b is a plan view of the tornado water flow induction ring shown in Figure 10.
11 is a connection state diagram between a vertical pipe and a drain pipe according to another embodiment of the present invention.
12A (A) and (B) are enlarged views of the connection state between the vertical pipe and the drain pipe shown in FIG. 11, a front view and a side view.
(A) and (B) of FIG. 12B are front and side views as enlarged views of another connection state between the vertical pipe and the drain pipe shown in FIG. 11 .
13 is an installation state diagram of a hanger according to another embodiment of the present invention.
Fig. 14 is an enlarged view of a part of the hanger shown in Fig. 13;
15 is an exploded perspective view of the embedded hanger insert spacer, the height adjustment tab block and the hanger bolt shown in FIG. 14;
16 is a side view of the embedded hanger insert spacer shown in FIG. 14;
17 (A) and (B) are views of various installation states of the tab block for height adjustment according to the covering interval of the reinforcing bar.
18 is a perspective view in which the embedded hanger insert spacer is installed on the upper connection bracket shown in FIG. 6;

Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the presented embodiments are illustrative for a clear understanding of the present invention, and the present invention is not limited thereto.

The present invention is connected to the water catchment 20 installed on the pavement 101 of the bridge 10 as shown in FIG. 1 and at the same time the drain pipe 40 supported through a plurality of hangers 30 installed on the bridge upper structure 12. Provide a bridge drainage system that drains through the In particular, it provides a bridge drainage system in which drainage power increases according to the structural improvement of the catchment 20 and the installation safety of the hanger 30 is increased.

2 to 4, the water collecting port 20 has a smaller diameter than the upper water collecting inlet 201a for introducing rainwater at the upper end and the upper water collecting inlet 201a at the lower end, and the lower collecting and draining port for draining rainwater. A water catchment body 201 having a 201b, and a grating 202 installed on the upper water collecting inlet 201a side of the water collecting body 201 to divide the upper water collecting inlet 201a into several small sizes; One end is fixedly installed in the central part of the grating 202 and is rotatably supported on the other end of the vortex induction wing support shaft 203 and the vortex-forming wing support shaft 203 disposed inside the catchment body 201 to support the upper housing It is composed of a propeller 204 for inducing a vortex that causes a water whirl in the rainwater introduced from the water inlet 201a.

The water collecting port 20 configured as described above is discharged to the lower water collecting and draining port 201b through the vortex induction propeller 204 after rainwater passes through the grating 202 through the upper water collecting inlet 201a in rainy weather. Rainwater discharged to the lower catchment and drain port 201b is discharged to the outside of the bridge 10 through the drain pipe 40 .

In this process, the grating 202 filters out relatively large foreign materials such as fallen leaves or garbage. In addition, the rotation of the propeller 204 for vortex induction is induced by the rainwater flow passing through the grating 202, and a tornado is generated in the rainwater flow according to the rotation of the propeller 204 for vortex induction. This tornado flow induces rapid and smooth discharge to the lower collecting and draining port 201b without clogging even if a large amount of rainwater is introduced. Therefore, even if a lot of rain falls on the road surface of the bridge 10, fast drainage is made to increase the driving safety of the vehicle.

Here, as shown in FIGS. 3 to 5 , the water collecting port 20 is circularly arranged on the inclined inner wall 201c of the water collecting port body 201 and inclined in one direction along a predetermined radius of curvature R and the radius of curvature R. A wing piece 205 for inducing a tornado may be further provided with an inclined surface 205a for inducing a tornado and generating a tornado according to centrifugal force in the drainage flow.

In this case, the blade piece 205 for inducing a drainage tornado applies a centrifugal force to the drainage flow at the inclined inner wall 201c of the catchment body 201 to generate a greater tornado, thereby further increasing the drainage force.

On the other hand, as shown in FIGS. 6 to 8 , the hanger 30 includes a vertical hanger 32 and a hanger support 34 . The hanger support 34 grabs the vertical hanger 32 from the bridge superstructure 12 to catch the shaking that may occur due to drainage or wind load, and at the same time share the support load of the drain pipe 40 to increase installation safety. play a role

The vertical hanger 32 is an upper connection bracket 321 that is fixedly installed on the bridge upper structure 12, one end of which is inserted into the upper connection bracket 321 and fixed with a nut. ) consists of a clamp coupler 323 connected to the lower end, and a circular clamp 324 connected to the clamp coupler 323 with a bolt 329 by wrapping and tightening the drain pipe 40 . In addition, it is preferable that the front screw bolt 322 is provided with upper and lower jig fixing nuts 325 and 326 screwed together to fix the position of the position adjustment jig 341 to be described later.

The hanger support 34 is a position adjustment jig 341 that is inserted into the all-screw bolt 322 and is positioned up and down, one end of the tilting rod 342 is hinged to the position adjustment jig 341, and one end of the tilting rod The length adjustment screw shaft 343 screwed to the other end of the 342, the hinge bracket 344 fixed to the other end of the length adjustment screw shaft 343, the hinge bracket 344 and the bolt 349 are hinged. It consists of a reinforcement hanger upper bracket 345 fixed to the upper structure 12 of the bridge at a predetermined distance from the upper connection bracket 321 of the vertical hanger 32 .

Here, the position adjustment jig 341 is a jig body 3411 having a U-shape, a through hole 3412 through which a full screw bolt 322 is inserted into one end of the jig body 3411, and the jig body 3411. It includes a tilting rod insertion groove 3413 formed at the other end, and a hinge bolt 3414 installed to hinge-connect the tilting rod 342 through the tilting rod insertion groove 3413 in the jig body 3411 .

The hanger 30 configured as described above is composed of a vertical hanger 32 and a hanger support 34 , and since the hanger support 34 firmly holds the vertical hanger 32 , the drain pipe 40 is drained or a gust of wind. Even if it receives a wind load from the vertical hanger 32, the shaking of the vertical hanger 32 is suppressed, so that the installation safety is increased.

In addition, it is possible to adjust the length of the hanger shaft 34 by the screw shaft 343 for length adjustment, and at the same time, the position of the position adjustment jig 341 can be adjusted with the all-screw bolt 322, so the length of the vertical hanger 32 Correspondingly, the hanger support 34 can be easily installed. That is, by adjusting the length of the screw shaft 343 for length adjustment as the length of the front screw bolt 322 increases little by little at the installation position according to the installation slope of the drain pipe 40, the position adjustment jig 341 is connected to the front screw bolt ( 322) can be fixed to the desired position to firmly hold the vertical hanger 32 and support it so as not to be shaken. In addition, since the support load of the drain pipe 40 is shared by the vertical hanger 32 as well as the hanger support 34 , the installation safety of the drain pipe 40 can be further improved.

On the other hand, as shown in FIGS. 9A to 9C , the water collecting port 20 is coupled to the actuator 210 mounted on the lower surface of the central part of the grating 202 and the rotation shaft of the actuator 210 and introduced from the upper water collecting inlet 201a. It may be composed of a propeller 204 for pressurizing the water flow to increase the discharge flow rate by forcibly pushing the rainwater into the vertical pipe 25 . The actuator 210 is a means capable of rotating the propeller 204 for water flow pressurization, and may be, for example, a motor. Accordingly, when the water flow pressurization propeller 204 is rotated by driving the actuator 210, rainwater flowing in from the upper water collection inlet 201a is forcibly pushed into the vertical pipe 25, thereby increasing the discharge flow rate.

Here, the tornado water flow guide ring 50 may be installed in the water collecting port 20 as shown in FIGS. 9 and 10 . The tornado water flow guide ring 50 is a ring flange 501 to be installed in the lower water collecting and draining port 201b, a cylindrical wall 502 formed with the same radius as the lower water collecting and draining port 201b in the ring flange 501, and a cylindrical wall At 502, it has a blade piece 205 for inducing a tornado water flow that is partially cut and arranged in a circular shape and inclined in one direction to generate a tornado-shaped discharge water flow. When the tornado water flow inducing ring 50 is installed in this way, a tornado water flow is generated in the rainwater discharged down the vertical pipe 25 to improve drainage capacity.

On the other hand, as shown in FIGS. 11 and 12A, the central axis V of the vertical pipe 25 is installed with a certain amount of eccentricity S from the central axis H of the drain pipe 40, so that the water flow in the vertical pipe 25 is It may be made to flow in a tangential direction to the drain pipe 40 . Therefore, the water flow in the vertical pipe 25 flows in a tangential direction to the drain pipe 40 to generate a centrifugal force, which in turn generates a swirling flow, thereby increasing the flow rate.

At this time, as shown in FIG. 12b , the connection part of the vertical pipe 25 is installed with a vertical line perpendicular to the central axis H of the drain pipe 40 and a constant inclination angle β, so that the drain pipe 40 is separated from the vertical pipe 25 . In addition to the centrifugal force, the water flow flowing into the furnace receives a boost by the inclination angle (β), which transforms the drainage flow into a vortex shape and further increases the drainage capacity. Unexplained code '251' is a 'see-through window'.

On the other hand, in the present invention, as shown in FIGS. 13 to 16 , the hanger 30 is installed in the bridge superstructure 12 to support the reinforced rebar 122 and determine the covering interval of the reinforcing bar 122 . The embedded hanger insert spacer 14 coupled to the hanger bolt 17 supporting the upper structure 12, the screw hole 161 screwed with the hanger bolt 17 in the center, and the shoulder mounting jaw 162 to the lower surface. A height-adjustable tab block 16 coupled to the embedded hanger insert spacer 14 may be further configured. Here, the buried hanger insert spacer 14 is installed in a buried state in the bridge superstructure 12 without an anchor operation, so that the anchor installation operation is unnecessary, and the drilling operation for the anchor installation is also eliminated, thereby eliminating the concern of dust generation.

The embedded hanger insert spacer 14 is composed of a rectangular channel type penetrating from one side to the other, so that the tab block coupling groove 141 for coupling the tab block 16 for height adjustment on the lower surface and the reinforcing bar 122 on the upper surface are supported. A concave reinforcing bar supporting jaw 142 is formed for this purpose.

At this time, as shown in FIG. 17 (A) and (B), in order to adjust the height of the embedded hanger insert spacer 14 in response to an increase in the covering interval of the reinforcing bar 122, the lower portion of the embedded hanger insert spacer 14 has an additional height. One or more adjustment tab blocks 16 may be further installed.

As described above, since the embedded hanger insert spacer 14 is embedded in the bridge upper structure 12, and the hanger 30 side upper connection bracket 321 can be installed through the hanger bolt 17, the anchor of the hanger as in the prior art. The drilling work in the lower part for installation is omitted and the generation of dust is eliminated, thereby improving the working environment and improving the safety of workers. In addition, by installing the height-adjustable tab block 16 in the embedded hanger insert spacer 14, it has the advantage of responding to the increase in the covering interval of the reinforcing bar 122.

So far, the present invention has been described in detail with reference to the presented embodiments, but those skilled in the art can make various modifications and modified inventions without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The present invention is not limited by such variations and modifications, but only by the claims appended hereto.

20: catchment
201: catchment body
203: vortex induction wing support shaft
204: vortex induction propeller
30: hanger
32: vertical hanger
34: hanger support

Claims (10)

It is connected to the water catchment port 20 installed on the pavement 101 of the bridge 10 through a vertical pipe 25 and at the same time through a drain pipe 40 supported through a hanger 30 installed on the bridge upper structure 12. In the bridge drainage system for drainage,
The water catchment (20),
a catchment body 201 having an upper water collecting inlet 201a for introducing rainwater at the upper end and a lower collecting and draining port 201b having a smaller diameter than the upper water collecting inlet 201a at the lower end and draining rainwater;
a grating 202 installed on the upper water collecting inlet 201a side of the water collecting body 201 to divide the upper water collecting inlet 201a into several smaller sizes;
a vortex induction wing support shaft 203 having one end fixedly installed in the central portion of the grating 202 and disposed inside the water catchment body 201;
A vortex induction propeller 204 that is freely supported on the other end of the vortex-forming blade support shaft 203 to cause a water whirl in the rainwater flowing in from the upper catchment inlet 201a;
The hanger 30,
The upper connection bracket 321 fixedly installed on the bridge upper structure 12, the front screw bolt 322 having one end inserted into the upper connection bracket 321 and fixed with a nut, the clamp connected to the lower end of the front screw bolt 322 a coupler 323 and a vertical hanger 32 comprising a circular clamp 324 connected to the clamp coupler 323 by wrapping and tightening the drain pipe 40;
Drainage increase and piping installation safety, characterized in that it includes a hanger support 34 that increases safety by grabbing the all-screw bolt 322 from the bridge upper structure 12 to catch shaking that may occur due to drainage or wind load A bridge drainage system with It is connected to the water catchment port 20 installed on the pavement 101 of the bridge 10 through a vertical pipe 25 and at the same time through a drain pipe 40 supported through a hanger 30 installed on the bridge upper structure 12. In the bridge drainage system for drainage,
The water catchment (20),
a catchment body 201 having an upper water collecting inlet 201a for introducing rainwater at the upper end and a lower collecting and draining port 201b having a smaller diameter than the upper water collecting inlet 201a at the lower end and draining rainwater;
a grating 202 installed on the upper water collecting inlet 201a side of the water collecting body 201 to divide the upper water collecting inlet 201a into several smaller sizes;
an actuator 210 mounted on the lower surface of the central portion of the grating 202;
It is coupled to the rotation shaft of the actuator 210 and forcibly pushes the rainwater flowing in from the upper water collection inlet 201a into the vertical pipe 25 to increase the discharge flow rate.
The hanger 30,
The upper connection bracket 321 fixedly installed on the bridge upper structure 12, the front screw bolt 322 having one end inserted into the upper connection bracket 321 and fixed with a nut, the clamp connected to the lower end of the front screw bolt 322 a coupler 323 and a vertical hanger 32 comprising a circular clamp 324 connected to the clamp coupler 323 by wrapping and tightening the drain pipe 40;
Drainage increase and piping installation safety, characterized in that it includes a hanger support 34 that increases safety by grabbing the all-screw bolt 322 from the bridge upper structure 12 to catch shaking that may occur due to drainage or wind load A bridge drainage system with 3. The method of claim 1 or 2,
The hanger support 34 is a position adjustment jig 341 that is inserted into the all-screw bolt 322 to adjust the position up and down, one end of the tilting rod 342 is hinged to the position adjustment jig 341, and one end is tilted. The length adjustment screw shaft 343 screwed to the other end of the rod 342, the hinge bracket 344 fixed to the other end of the length adjustment screw shaft 343, the hinge bracket 344 and the hinge are connected to the vertical hanger (32) of the upper connection bracket (321) and a fixed distance is made of a reinforcing hanger upper bracket (345) fixed to the bridge;
The all-screw bolt 322 has upper and lower jig fixing nuts 324 and 325 screwed to fix the position of the position adjustment jig 341, characterized in that it is provided with increased drainage power and pipe installation safety. bridge drainage system. 4. The method of claim 3,
The positioning jig 341 includes a jig body 3411 having a U-shape, a through-hole 3412 through which a full-screw bolt 322 is inserted into one end of the jig body 3411, and the jig body 3411. The tilting rod insertion groove 3413 formed at the other end, the hinge bolt 3414 installed to hinge the tilting rod 342 through the tilting rod insertion groove 3413 in the jig body 3411. and bridge drainage system with pipe installation safety. The method of claim 1,
The water catchment 20 has a circular arrangement on the inclined inner wall 201c of the water catchment body 201 and has a predetermined radius of curvature R and an inclined surface 205a for inducing a tornado inclined in one direction along the radius of curvature R. A bridge drainage system with increased drainage power and pipe installation safety, characterized in that it further includes a blade piece 205 for inducing a drainage tornado that generates a tornado according to centrifugal force in the drainage flow. 3. The method of claim 1 or 2,
The central axis (V) of the vertical pipe (25) is installed with a certain amount of eccentricity (S) from the central axis (H) of the drain pipe (40), so that the water flow in the vertical pipe (25) is a drain pipe in order to increase the discharge flow rate. (40) Bridge drainage system with increased drainage power and pipe installation safety, characterized in that it flows in a tangential direction. 7. The method of claim 6,
The connecting portion of the vertical pipe 25 is installed with a vertical perpendicular to the central axis H of the drain pipe 40 and a constant inclination angle β, and the water flow flowing into the drain pipe 40 from the vertical pipe 25 is installed. Bridge drainage system with increased drainage power and pipe installation safety, characterized in that it is converted into a vortex form. 3. The method of claim 2,
The water collecting port 20 has a ring flange 501 to be installed in the lower water collecting and draining port 201b, a cylindrical wall 502 formed in the ring flange 501 having the same radius as the lower water collecting and draining port 201b, and a cylindrical wall 502 ), a tornado water flow guide ring 50 having a blade piece 205 for inducing a tornado water flow that is partially cut in a circular arrangement and inclined in one direction to generate a tornado-type discharge water flow is further installed. Bridge drainage system with safety. 3. The method of claim 1 or 2,
A hanger bolt 17 that is embedded in the bridge superstructure 12 and determines the support of the reinforced reinforcement 122 and the covering interval of the reinforcement 122 and supports the hanger 30 to the bridge superstructure 12 at the same time. ) and has a buried hanger insert spacer 14 that eliminates the installation work of anchors and generation of dust, and a screw hole 161 that is screwed with the hanger bolt 17 and is coupled to the buried hanger insert spacer 14 A tab block 16 for height adjustment is further included;
The buried hanger insert spacer 14 is configured in a rectangular channel type penetrating from one side to the other, so that a tab block coupling groove 141 for additionally stacking a tab block 16 for height adjustment and height adjustment is formed on its lower surface, and on its upper surface Bridge drainage system with increased drainage power and pipe installation safety, characterized in that a concave reinforcement support jaw 142 for supporting the reinforcement 122 is formed. 10. The method of claim 9,
In order to adjust the height of the embedded hanger insert spacer 14 in response to an increase in the covering interval of the reinforcing bar 122, the lower portion of the embedded hanger insert spacer 14 additionally has a height adjustment tab having a shoulder 162 on the lower surface. Bridge drainage system with increased drainage power and pipe installation safety, characterized in that one or more blocks 16 are stacked and installed.

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