KR102277420B1 - Girder system using steel pipe for bridge and its construction method - Google Patents

Abstract

The present invention relates to a bridge girder system using a steel pipe and a construction method thereof. The steel pipe girder includes: a segment for a positive moment section including a longitudinal connector, a web plate, a lower steel pipe, and a lower steel pipe connector; and a segment for a negative moment section including a longitudinal connector, an upper steel pipe, a web plate, lower filling steel pipes, and a lower steel pipe connector for connection between the lower filling steel pipes. The construction method of the bridge girder system using the steel pipe comprises the steps of: a) manufacturing the segment for the positive moment section; b) manufacturing the segment for the negative moment section; c) installing a temporary vent in each segment connection part, and installing temporary supports in an abutment and a pier part; d) after placing the segment for the negative moment section, and placing the segment for the positive moment section; e) after welding each segment connection part, and pouring concrete on a floor plate; and f) after curing is completed, removing the temporary vent and the temporary supports. According to the present invention, the amount of steel used can be greatly reduced.

Description

Bridge girder system using steel pipe and its construction method {Girder system using steel pipe for bridge and its construction method}

The present invention relates to a bridge girder system using a steel pipe and a construction method thereof, wherein in the central part of the bridge, the lower flange plate of the abdominal plate of the existing steel box girder is replaced with a steel pipe, and the upper and lower flanges of the abdominal plate of the existing steel box girder at the branch point It is an economical girder system that is very advantageous for bridge structure planning as it can maximize the efficiency of the cross section resisting external loads by replacing the plate with a steel pipe, and optimize the amount of steel to reduce the amount of steel.

In general, the girder installed on the bridge is one of the very important factors to transmit the load such as the fixed load and the vehicle load acting from the upper part to the pier of the bridge.

Looking at the shape of the conventional girder bridge, it can be largely classified into a steel girder bridge and a concrete girder bridge. Among these, steel girder bridges use a large amount of steel, which is disadvantageous in terms of economic efficiency and constructability due to a lot of welding during manufacturing, and is expensive, while, when compressive load is applied, buckling due to the compressive load As it is easy to be damaged, stiffeners such as stiffeners are required, and at the same time, the rigidity is small, so there is a high possibility of sagging and vibration. Also, since there are many elements to be painted, the steel surface must be painted at regular intervals. It was somewhat irrational.

In addition, in the case of a concrete girder bridge, the weight acting on the entire bridge increased due to the heavy concrete itself, which was uneconomical in designing the bridge, and cracks that may occur due to the nature of the concrete had to be tolerated.

Meanwhile, as a technology related to the girder mentioned above, a 'steel pipe girder for a bridge' has been proposed in Korean Patent Publication No. 10-1725686.

In the above technique, an upper inclined wall extending to the side while facing obliquely upward is formed on the upper end of the vertical partition wall, and a lower inclined wall extending laterally while facing obliquely downward is formed at the lower end of the vertical partition wall, and the upper inclined wall is formed. The side outer wall is formed so as to connect the end of the wall and the end of the lower inclined wall, so that a first side tube and a second side tube having a tubular shape are included, wherein the first side tube and the second side tube are mutually vertical partition walls. They are bolted to face each other with their backs facing each other and are installed in parallel with each other, and an upper outer wall is formed to connect the end of the upper inclined wall of the first side tube and the end of the upper inclined wall of the second side tube, and the second A lower outer wall is formed to connect the end of the lower inclined wall of the side tube and the end of the lower inclined wall of the second side tube, so that the upper inclined wall of the first side tube, the upper inclined wall of the second side tube, and the upper outer wall has an upper pipe as a circumferential wall, a lower sloping wall of the first side pipe, a lower sloping wall of the second side pipe, and a lower pipe having the lower outer wall as a circumferential wall; has been cast and made.

The steel pipe girder for a bridge configured as described above serves to support the upper plate of the bridge by bracing several structures vertically and horizontally. However, as a number of steel materials are welded and connected, there is a high possibility of damage due to buckling caused by the compressive load when a compressive load is applied. Therefore, a separate reattachment of several reinforcing materials or a separate bracing operation was required. In addition, the manufacturing process and construction process were complicated, inefficient in terms of workability, and in particular, a large amount of reinforcement was required, so a fundamental solution to the excessive material cost was still not presented.

Korean Patent Publication No. 10-1725686 (Steel pipe girder for bridge, registered on April 5, 2017) US Registered Patent Publication No. 10,718,094 (Tub girls and related manufacturing methods, registered on July 21, 2020) Japanese Patent Publication No. 06374353 (Registered on August 15, 2018)

The present invention was created to solve the problems of the prior art as described above, and an object of the present invention is to use a steel pipe that replaces the plate at both ends of the abdominal plate, so that the cross-sectional efficiency is excellent, so that it can be implemented between long legs, and the amount of steel Bridge girder system and its construction method using steel pipe that can achieve economic feasibility by significantly reducing the use of expensive steel, unlike conventional girder, as a bridge structure that introduces a structural concept with superior economic feasibility with the advantage of reducing is to provide.

Another object of the present invention is to provide a bridge girder system and a construction method thereof using a steel pipe to sufficiently respond to stress by using a steel pipe in the upper part as well as the lower part of the bridge point part.

Another object of the present invention is to introduce a steel pipe structure with good rigidity to the longitudinal beams of a wide bridge, so that it is composed of a single girder without using multiple girder, so a bridge girder system using a steel pipe superior in economic efficiency and constructability and its construction to provide a method.

Another object of the present invention is to provide a bridge girder system using a steel pipe having excellent functional and aesthetic advantages by forming a pattern that looks beautiful in appearance on the surface of the abdominal plate and a construction method thereof.

The bridge girder system using the steel pipe of the present invention for achieving the above object,

As a bridge girder system using a steel pipe to support the load acting on the base plate (P) concrete of the bridge,

The longitudinal connector 110 provided on both sides of the bottom plate along the installation direction of the bottom plate, and the longitudinal connector 110 on both sides of the lower surface of the bottom plate P along the installation direction A pair of abdominal plates 120 to be connected, a pair of lower steel pipes 130 welded and fixed to each end of the pair of abdominal plates 120, and the pair of lower steel pipes 130 are connected a segment 100 for a positive moment section, including a lower steel pipe connecting member 140 disposed at a predetermined interval and disposed in a section M1 in which a positive moment is applied by a fixed load; and

The longitudinal connector 210 provided on both sides of the bottom plate P along the installation direction of the bottom plate, and the longitudinal connector 210 on both sides of the lower surface of the bottom plate P along the installation direction A pair of upper steel pipes 270 welded to each other, a pair of abdominal plates 220 connected in a vertical direction to each surface of the pair of upper steel pipes 270, and the pair of abdominal plates 220 each A pair of lower filling steel pipes 230 welded to the ends and fixed thereto, and a lower steel pipe connecting member 240 disposed at a predetermined interval connecting the pair of lower filling steel pipes 230 are included, and fixed The segment 200 for the negative moment section is arranged in the section (M2) where the negative moment acts by the load;

According to another embodiment of the present invention, when the width of the bottom plate (P) is wider than a predetermined width, a steel pipe stringer disposed in the center of the bottom plate (P) of the positive moment section (M1) and the negative moment section (M2) It may further include a cross beam 400 that connects between the inside of the 300 and the pair of abdominal plates 120 .

According to another embodiment of the present invention, a transverse plate disposed at a predetermined interval for connecting the pair of longitudinal connectors 110 and 210 located on the pair of abdominal plates 120 and 220 in the transverse direction. Connection materials 150 and 250 may be further included.

According to another embodiment of the present invention, a stud serves at the connection point between the bottom plate P and the longitudinal connector 110 and 210 or the connection point between the bottom plate P and the transverse plate connector 150 , 250 . It can be installed with a shape that is interposed.

According to another embodiment of the present invention, on one side of the surface of the abdominal plate 120 of the segment 100 for the positive moment section, a pattern made of a circular shape or a polygonal shape may be perforated in a regular pattern or an irregular pattern, , By using the perforation formed in the abdominal plate 120, a drainage channel may be formed so that the water drained from the drainage facility (D) can be moved into the internal space, and on the surface of the abdominal plate (120, 220), At least one drain hole may be formed with a diameter corresponding to the diameter of the drain pipe so that a drain pipe connected to the drain facility D can pass therethrough.

According to another embodiment of the present invention, the segment 100 for the positive moment section and the segment 200 for the negative moment section may be formed in a shape in which the height decreases from the point part of the bridge to the central part, and a steel pipe of a different shape It can also be combined with structures such as trusses and steel box girders.

According to another embodiment of the present invention, the pair of abdominal plates 120 and 220 may be formed to have a cross-section of the dosage form by a shape in which each of the symmetrical lower ends is inclined at a certain angle inward.

According to another embodiment of the present invention, the pair of abdominal plates (120, 220) may further include horizontal reinforcement (160, 260).

On the other hand, the construction method of the bridge girder system using the steel pipe of the present invention,

a) After connecting the lower steel pipe 130 with the lower steel pipe connecting members 140 arranged at predetermined intervals, and connecting the abdominal plate 120 to the upper end of each surface of the lower steel pipe 130 in the vertical direction, the abdominal After connecting the longitudinal connector 110 to the upper end of the plate 120 and connecting both ends of the transverse plate connector 150 disposed at a predetermined interval with the inner surface of the longitudinal connector 110, the longitudinal connector 110 ) and connecting the upper surface of the transverse plate connecting material 150 to the lower surface of the bottom plate (P) to produce a segment 100 for a positive moment section having a box-shaped cross section;

b) connecting the lower filling steel pipe 230 with the lower steel pipe connecting member 240 disposed at a predetermined interval, and connecting the abdominal plate 220 to the upper end of each surface of the lower filling steel pipe 230 in the vertical direction Next, the upper steel pipe 270 and the longitudinal connector 210 are sequentially connected to each upper end of the abdominal plate 220 , and the transverse plate connector is disposed at a predetermined distance from the inner surface of the longitudinal connector 210 . After connecting both ends of 250, the upper surface of the longitudinal connecting material 210 and the transverse plate connecting material 250 is connected to the lower surface of the bottom plate (P) to have a box-shaped cross section for the negative moment section segment manufacturing (200);

c) installing a temporary vent in each segment connection part, and installing a temporary support in the abutment and pier;

d) After moving the segment 200 for the negative moment section of step b) to the temporary position and passing it at a predetermined interval, the segment 100 for the positive moment section of step a) is moved to the temporary position at a predetermined interval mounting with;

e) after step d), welding each segment connection part and pouring the bottom plate with concrete; and

f) after completing curing of the concrete poured in step e), removing the temporary vent and the temporary support;

According to another embodiment of the present invention, on one side of the surface of the abdomen plate 120 of the segment 100 for the positive moment section of step a), a pattern made of a circular shape or a polygonal shape is perforated in a regular pattern or an irregular pattern can be

According to another embodiment of the present invention, after step f), a drainage facility (D) in any one of the segment 100 for the positive moment section or the segment 200 for the negative moment section or the internal space of both The step of installing may be further included.

According to the bridge girder system using the steel pipe of the present invention and its construction method,

First, unlike the conventional girder, since steel pipe with excellent cross-sectional efficiency is applied to the main girder, the amount of steel used in other members can be greatly reduced, and the construction cost can be reasonably lowered along with the introduction of a structural concept with superior economic feasibility.

Second, by forming a pattern that looks beautiful in appearance on the surface of the abdominal plate, it can induce an aesthetic sense for the viewer,

Third, it is very effective for long-span bridges because it can sufficiently respond to vertical stress by using steel pipes for the upper part as well as the lower part of the bridge point.

Fourth, it is possible to sufficiently respond to a wide bridge by applying a steel pipe stringer to the center of the bridge deck,

Fifth, by manufacturing the girder in the form of a box-shaped cross-sectional structure consisting of upper and lower steel pipes and abdominal plates as the main member, it has excellent cross-sectional properties to resist external loads, thereby providing an advantage in cross-sectional construction of bridges.

1 is a longitudinal cross-sectional view of a bridge to which a bridge girder system structure using a steel pipe of the present invention is applied;
Figure 2 is a '-A' cross-sectional view for explaining the segment for the positive moment section of Figure 1,
3 is a cross-sectional view A'-A' for explaining the segment for the negative moment section of FIG. 1;
4 is a cross-sectional view A'-A' for explaining a segment of a cross-section of a formulation according to another embodiment of the present invention;
5 is a cross-sectional view A'-A' showing a state in which a pattern is perforated in the abdominal plate of the segment for the positive moment section of FIG. 1;
6 is a cross-sectional view A'-A' showing a state in which a drainage facility is installed in the segment for the positive moment section of FIG. 1;
7 is a cross-sectional view for explaining a segment in which a steel pipe stringer and crossbeam are installed in the center of the bridge deck;
Figure 8 is a block diagram showing the sequence of the construction method of the bridge girder system utilizing the steel pipe of the present invention.

Hereinafter, the bridge girder system using the steel pipe of the present invention will be described in detail with reference to the accompanying drawings.

A bridge girder system using a steel pipe according to the present invention,

As a bridge girder system using a steel pipe to support the load acting on the base plate (P) concrete of the bridge,

As shown in FIG. 2 , the longitudinal connector 110 provided on both sides of the bottom plate P along the installation direction of the bottom plate, and the longitudinal connector on both sides of the bottom plate P A pair of abdominal plates 120 connected along the installation direction of 110), a pair of lower steel pipes 130 welded and fixed to each end of the pair of abdominal plates 120, and the pair of lower parts a segment 100 for a positive moment section, including a lower steel pipe connecting member 140 disposed at a predetermined interval connecting the steel pipes 130, and disposed in a section M1 where a positive moment is applied by a fixed load; and

As shown in FIG. 3 , the longitudinal connector 210 provided on both sides of the bottom plate P along the installation direction of the bottom plate, and the longitudinal connector on both sides of the lower surface of the bottom plate P ( A pair of upper steel pipes 270 welded along the installation direction of 210, a pair of abdominal plates 220 vertically connected to each surface of the pair of upper steel pipes 270, and the pair A pair of lower filling steel pipes 230 that are welded and fixed to each end of the abdominal plate 220 of the lower steel pipe connecting member disposed at a predetermined interval connecting the pair of lower filling steel pipes 230 ( 240), and the segment 200 for the negative moment section disposed in the section (M2) where the negative moment acts by the fixed load.

In addition, when the width of the bottom plate (P) is wider than the predetermined width, as shown in FIG. 7, a steel pipe stringer disposed in the center of the bottom plate (P) of the positive moment section (M1) and the negative moment section (M2) It may further include a cross beam 400 that connects between the inside of the 300 and the pair of abdominal plates 120 .

The bridge girder system using the steel pipe of the present invention configured as described above uses a girder of a box-type cross-sectional structure to form an efficient bridge cross-section, and it is possible to significantly reduce the amount of relatively expensive steel material, thereby promoting economic feasibility. It has a structure that induces an aesthetic sense to the viewer and implements it concretely.

In the configuration of the present invention, the segment 100 for the positive moment section is disposed in the section M1 where the positive moment acts by a fixed load, as shown in FIGS. 1 and 2, and the longitudinal connector 110 ), an abdominal plate 120 , a lower steel pipe 130 for filling, a lower steel pipe connector 140 and a transverse plate connector 150 .

The longitudinal connecting member 110 is provided on both sides of the bottom plate (P) along the installation direction of the bottom plate, and serves to directly support the bottom plate (P) as well as to prevent deformation due to load. , and also increase the rigidity according to the length extension.

The abdominal plate 120 is connected to the lower surface of the longitudinal connector 110 along its installation direction.

A transverse plate connector 150 is welded to the inner surface of the longitudinal connector 110 at predetermined intervals, and the connection between the bottom plate P, the longitudinal connector 110, and the transverse plate connector 150 is A shear connection material such as a stud allows a solid connection to be made.

According to another embodiment of the present invention, as shown in FIG. 5 , a pattern made of a circular shape or a polygonal shape may be perforated in a regular or irregular pattern on the surface of the abdominal plate 120 . As described above, the pattern perforated on the abdominal plate 120 can realize a sophisticated and beautiful appearance by itself even without attaching a separate attachment to the abdominal plate 120 .

The abdominal plate 120 with a perforated surface can reduce the amount of material and facilitate the flow of internal and external air to prevent dew condensation caused by the internal and external temperature difference.

According to another embodiment of the present invention, as shown in Figure 4, the pair of abdominal plates 120 can be formed to have a cross-section of the dosage form by a shape in which each symmetrical lower end is inclined at a certain angle inward. have.

On the other hand, the lower steel pipe 130 is welded to the end of the abdominal plate 120 is fixedly coupled.

The lower steel pipe connecting member 140 connects between the pair of lower steel pipes 130, and is provided at least two or more at a predetermined interval along the lateral direction of the bridge, and includes the above-mentioned components for a positive moment section segment. (100) is disposed in the section (M1) in which the static moment acts by the fixed load.

Here, the positive moment action section M1 refers to a section in which a so-called bending moment that induces a convex bending displacement downward by the fixed load of the bridge acts.

In the configuration of the present invention, the segment 200 for the negative moment section is arranged in the section M2 where the negative moment acts by a fixed load, as shown in FIGS. 1 and 3 , the longitudinal connector 210 . , an abdominal plate 220 , a lower filling steel pipe 230 , a lower steel pipe connecting member 240 , a transverse plate connecting member 250 and an upper steel pipe 270 .

The longitudinal connecting member 210 is provided on both sides of the bottom plate (P) along the installation direction of the bottom plate, directly supporting the bottom plate (P) and at the same time preventing deformation due to vertical load. It also serves to increase the stiffness as the length increases.

A transverse plate connecting member 250 is welded to the inner surface of the longitudinal connecting member 210 at regular intervals.

The upper steel pipe 270 is fixedly coupled to the lower surface of the longitudinal connector 210 by welding along the installation direction of the longitudinal connector 210 . The connection between the bottom plate P, the longitudinal connector 210 and the transverse plate connector 250 is a shear connector such as a stud so that a solid connection can be made.

In this case, the upper steel pipe 270 has a circular cross-section and an empty interior, for example, high-performance TMCP (Thermo-Mechnical Control Process) steel or API (American Petroleum Institete) steel pipe may be used.

According to another embodiment of the present invention, the pair of abdominal plates 220 may be formed to have a cross-section of the dosage form by a shape in which each of the symmetrical lower ends is inclined at an inward angle.

The lower filling steel pipe 230 is fixedly coupled to the lower end of the abdominal plate 220 through welding.

According to another embodiment of the present invention, a separate hole may be formed on the outer peripheral surface of the lower filling steel pipe 230 so that the concrete to be filled during construction can easily permeate into the lower filling steel pipe 230 . have. In the hole, concrete easily seeps into and fills the lower filling steel pipe 230, and in the case of concrete flowing from the left and right sides during pouring, a kind of bulkhead phenomenon is caused by the lower filling steel pipe 230. This may occur, and the hole serves to prevent this.

The lower steel pipe connecting member 240 serves to connect between the lower filling steel pipes 230 .

The segment 200 for the negative moment section including the above components is arranged in the section M2 where the negative moment acts by the fixed load. Here, the negative moment action section (M2) refers to a section (or continuous point section) where a so-called bending moment that induces an upward convex bending displacement by the fixed load of the bridge acts.

On the other hand, according to another embodiment of the present invention, as shown in Figure 6, any one or both of the segment 100 for the positive moment section or the segment 200 for the negative moment section has a drainage facility ( D) to form a drainage channel so that the water drained from it can move, and at least one drainage hole can be formed on the surface of the abdominal plate 120 and 220 so that the drainage pipe connected to the drainage facility can pass through, thereby The usability aspect can be maximized.

At this time, the vertical pipe among the drainage holes is preferably formed in the central portion of the abdominal plate (120, 220). As a drain hole is formed in the central portion of the abdominal plates 120 and 220, an inclined drain pipe is formed on the outside of the segment and at the same time, a 'Y'-shaped drainage facility can be provided through the central portion, thereby This is because it is advantageous in terms of appearance as it is not possible to check the drain pipe.

According to another embodiment of the present invention, a pattern formed in a circular shape or a polygonal shape formed on one side of the surface of the abdomen plate 120 of the segment 100 for the positive moment section is a space perforated in a regular pattern or an irregular pattern. It can be configured so that the drain pipe connected to the drain facility (D) passes through.

According to another embodiment of the present invention, the segment 100 for the positive moment section and the segment 200 for the negative moment section may be formed in a form in which the height decreases from the point part of the bridge to the central part, and a different type of steel pipe truss And it can be combined with structures such as steel box girder.

In addition, by manufacturing the girder in the form of a box-shaped cross-sectional structure composed of upper and lower steel pipes and abdominal plates as the main member, it has excellent cross-sectional properties to resist external loads, which provides an advantage in cross-sectional construction of bridges. It provides the advantage of increasing strength and improving stress against normal loads.

In addition, it is possible to effectively bear and support the compressive stress acting on the static moment section M1 acting by the fixed load such as self-weight and the active load during common use. Accordingly, it is possible to increase the cross-sectional rigidity of the continuous branch portion, the bending moment generated in the negative moment section (M2) is reduced, it becomes possible to reduce the cross-section of the steel material or to lower the mold height of the continuous branch portion.

According to another embodiment of the present invention, as shown in FIGS. 2 and 3 , the pair of abdominal plates 120 and 220 may further include longitudinal stiffeners 160 and 260 .

Hereinafter, the construction method of the bridge girder system using the steel pipe of the present invention will be described in detail.

As shown in Figure 8, the construction method of the bridge girder system using the steel pipe according to the present invention,

a) After connecting the lower steel pipe 130 with the lower steel pipe connecting members 140 arranged at predetermined intervals, and connecting the abdominal plate 120 to the upper end of each surface of the lower steel pipe 130 in the vertical direction, the abdominal After connecting the longitudinal connector 110 to the upper end of the plate 120 and connecting both ends of the transverse plate connector 150 disposed at a predetermined interval with the inner surface of the longitudinal connector 110, the longitudinal connector 110 ) and connecting the upper surface of the transverse plate connecting material 150 to the lower surface of the bottom plate (P) to produce a segment 100 for a positive moment section having a box-shaped cross section;

b) connecting the lower filling steel pipe 230 with the lower steel pipe connecting member 240 disposed at a predetermined interval, and connecting the abdominal plate 220 to the upper end of each surface of the lower filling steel pipe 230 in the vertical direction Next, the upper steel pipe 270 and the longitudinal connector 210 are sequentially connected to each upper end of the abdominal plate 220 , and the transverse plate connector is disposed at a predetermined distance from the inner surface of the longitudinal connector 210 . After connecting both ends of 250, the upper surface of the longitudinal connecting material 210 and the transverse plate connecting material 250 is connected to the lower surface of the bottom plate (P) to have a box-shaped cross section for the negative moment section segment manufacturing (200);

c) installing a temporary vent in each segment connection part, and installing a temporary support in the abutment and pier;

d) After moving the segment 200 for the negative moment section of step b) to the temporary position and passing it at a predetermined interval, the segment 100 for the positive moment section of step a) is moved to the temporary position at a predetermined interval mounting with;

e) after step d), welding each segment connection part and pouring the bottom plate with concrete; and

f) after completing curing of the concrete poured in step e), removing the temporary vent and the temporary support;

According to another embodiment of the present invention, a pattern made of a circular shape or a polygonal shape is perforated in a regular pattern or an irregular pattern on one side of the surface of the abdomen plate 120 of the segment 100 for the positive moment section of step a). can

In addition, after step f), the step of installing a drainage facility (D) in either the internal space of any one of the segment 100 for the positive moment section or the segment 200 for the negative moment section or both of them is further included. can

At this time, a drain hole may be formed on the surface of the abdominal plate 120 and 220 so that the external drain pipe can be connected to the drain facility D installed in the inner space.

The vertical pipe among the drainage holes is preferably formed in the central portion between the abdominal plates 120 and 220 . As a drain hole is formed in the central portion between the abdominal plates 120 and 220, a sloping drain pipe is formed on the outside of the segment and a 'Y'-shaped drainage facility can be provided through the central portion at the same time, whereby from the outside This is because it is aesthetically advantageous because the drain pipe cannot be checked.

As described above, according to the bridge girder system using the steel pipe of the present invention and the construction method thereof, unlike the conventional girder, a steel pipe with excellent cross-sectional efficiency is applied to the main girder, so that it is possible to greatly reduce the amount of steel used in other members. Therefore, it is possible to rationally lower the construction cost along with the introduction of a structural concept with superior economic feasibility, and by forming a pattern that looks beautiful on the surface of the abdominal plate, it can induce an aesthetic feeling in the viewer, and the lower part of the bridge Of course, by using steel pipe in the upper part, it is very effective for long-span bridges because it can sufficiently respond to vertical stress. By applying a steel pipe stringer to the center of the bridge deck, it can sufficiently respond to a wide bridge, and upper and lower steel pipes and abdominal plates It is a very useful invention that provides an advantage to the cross-sectional structure of a bridge because it has a cross-sectional property with excellent resistance to external loads by manufacturing a girder in the form of a box-shaped cross-section structure as the main member.

P : Bottom plate D : Drainage facility
M1: Positive moment action section M2: Negative moment action section
100: segment for positive moment section 110, 210: longitudinal connector
120, 220: abdominal plate 130: lower steel pipe
140,240: lower steel pipe connector 150,250: transverse plate connector
200: segment for negative moment section 230: steel pipe for lower filling
160,260: horizontal reinforcement 270: upper steel pipe
300: steel pipe longitudinal beam 400: cross beam

Claims (10)

As a bridge girder system using a steel pipe to support the load acting on the base plate (P) concrete of the bridge,
The longitudinal connector 110 provided on both sides of the bottom plate along the installation direction of the bottom plate, and the longitudinal connector 110 on both sides of the lower surface of the bottom plate P along the installation direction A pair of abdominal plates 120 to be connected, a pair of lower steel pipes 130 welded and fixed to each end of the pair of abdominal plates 120, and the pair of lower steel pipes 130 are connected a segment 100 for a positive moment section, including a lower steel pipe connecting member 140 disposed at a predetermined interval and disposed in a section M1 in which a positive moment is applied by a fixed load; and
The longitudinal connector 210 provided on both sides of the bottom plate P along the installation direction of the bottom plate, and the longitudinal connector 210 on both sides of the lower surface of the bottom plate P along the installation direction A pair of upper steel pipes 270 welded to each other, a pair of abdominal plates 220 connected in a vertical direction to each surface of the pair of upper steel pipes 270, and the pair of abdominal plates 220 each A pair of lower filling steel pipes 230 welded to the ends and fixed thereto, and a lower steel pipe connecting member 240 disposed at a predetermined interval connecting the pair of lower filling steel pipes 230 are included, and fixed The segment 200 for the negative moment section is arranged in the section (M2) where the negative moment acts by the load;
When the width of the bottom plate (P) is wider than the predetermined width, the steel pipe stringer 300 and a pair of abdominal plates disposed in the center of the bottom plate (P) of the positive moment section (M1) and the negative moment section (M2) (120) further comprising a crossbeam 400 connecting between the interior,
At least one hole is formed on one side of the outer circumferential surface of the lower filling steel pipe 230,
On one side of the surface of the abdominal plate 120, 220 of any one or both of the segment 100 for the positive moment section or the segment 200 for the negative moment section, a pattern made of a circular shape or a polygonal shape is a regular pattern or irregular Perforated in a pattern,
A drain is formed in the inner space using the perforations formed in the abdominal plates 120 and 220 so that water drained from the drainage facility D can be moved, and on the surface of the abdominal plates 120 and 220, the At least one drain hole including a vertical pipe formed in the center of the abdominal plate (120, 220) so that the drain pipe connected to the drain facility (D) can pass through, characterized in that it is formed with a diameter corresponding to the diameter of the drain pipe Bridge girder system using steel pipe. delete delete According to claim 1,
A bridge girder system using a steel pipe, characterized in that a shape serving as a stud is interposed at the connection point of the bottom plate (P) and the longitudinal connector (110, 210) and the transverse plate connector (150, 250). According to claim 1,
The segment 100 for the positive moment section and the segment 200 for the negative moment section may be formed in a form in which the height decreases from the point part of the bridge to the central part, and structures such as other types of steel pipe trusses and steel box girder and A bridge girder system using a steel pipe, characterized in that it can also be combined. According to claim 1,
The pair of abdominal plates (120, 220) is a bridge girder system using a steel pipe, characterized in that the symmetrical lower end has a cross section of the formulation by a shape inclined at a certain angle toward the inside. According to claim 1,
In the segment 100 for the positive moment section, a transverse plate connecting member 150 arranged at a predetermined interval on the inner surface of the pair of longitudinal connecting members 110 and fixedly installed on the lower surface of the bottom plate P is provided. further including,
The segment 200 for the negative moment section includes a transverse plate connector 250 that is arranged at a predetermined interval on the inner surface of the pair of longitudinal connectors 210 and fixedly installed on the lower surface of the bottom plate P. Bridge girder system using a steel pipe, characterized in that it further comprises. As a construction method of a bridge girder system using the steel pipe of claim 1,
a) After connecting the lower steel pipe 130 with the lower steel pipe connecting members 140 arranged at predetermined intervals, and connecting the abdominal plate 120 to the upper end of each surface of the lower steel pipe 130 in the vertical direction, the abdominal After connecting the longitudinal connector 110 to the upper end of the plate 120 and connecting both ends of the transverse plate connector 150 disposed at a predetermined interval with the inner surface of the longitudinal connector 110, the longitudinal connector 110 ) and connecting the upper surface of the transverse plate connecting material 150 to the lower surface of the bottom plate (P) to produce a segment 100 for a positive moment section having a box-shaped cross section;
b) connecting the lower filling steel pipe 230 with the lower steel pipe connecting member 240 disposed at a predetermined interval, and connecting the abdominal plate 220 to the upper end of each surface of the lower filling steel pipe 230 in the vertical direction Next, the upper steel pipe 270 and the longitudinal connector 210 are sequentially connected to each upper end of the abdominal plate 220 , and the transverse plate connector is disposed at a predetermined distance from the inner surface of the longitudinal connector 210 . After connecting both ends of 250, the upper surface of the longitudinal connecting material 210 and the transverse plate connecting material 250 is connected to the lower surface of the bottom plate (P) to have a box-shaped cross section for the negative moment section segment manufacturing (200);
c) installing a temporary vent in each segment connection part, and installing a temporary support in the abutment and pier;
d) After moving the segment 200 for the negative moment section of step b) to the temporary position and passing it at a predetermined interval, the segment 100 for the positive moment section of step a) is moved to the temporary position at a predetermined interval mounting with;
e) after step d), welding each segment connection part and pouring the bottom plate with concrete; and
f) after completing curing of the concrete poured in step e), removing the temporary vent and the provisional support; a construction method of a bridge girder system using a steel pipe, comprising the steps of: 9. The method of claim 8,
On one side of the surface of the abdomen plate 120 of the segment 100 for the positive moment section of step a), a pattern made of a circular shape or a polygonal shape is perforated in a regular pattern or an irregular pattern. Construction method of bridge girder system. 9. The method of claim 8,
After step f), the step of installing a drainage facility (D) in either the internal space of any one of the segment 100 for the positive moment section or the segment 200 for the negative moment section is further included A method of constructing a bridge girder system using a steel pipe characterized by its characteristics.

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