KR101130968B1 - The fixing structre using girder for rahmen bridge - Google Patents

Abstract

PURPOSE: A girder fixing structure for a rahmen bridge is provided to improve durability and stability by distributing tension and compressive stress to a girder. CONSTITUTION: A girder fixing structure for a rahmen bridge comprises multiple fixing bolts, vertical beams(2), girders(3), first stress dispersion units(4). The fixing bolts are assembled in screw holes of a fixing plate and are buried in piers(12). The vertical beams have multiple first coupling holes in which the protruded ends of the fixing bolts are inserted. The girders are coupled to the top of the vertical beams. Each first stress dispersion unit is composed of guide brackets(41), strand fixing brackets(43), and strands(45). The strand fixing brackets have one or more second coupling holes. The strands are fixed to the second coupling holes through strand fixing nuts(44).

Description

The fixing structre using girder for Rahmen bridge}

The present invention relates to a girder fixture for a ramenized bridge, which will be described in more detail. The present invention relates to a girder fixed structure for ramenized bridges developed so that the distribution of tensile and compressive stresses is evenly distributed without being concentrated in part.

Bridges are classified into Girder Bridge, Arch Bridge, Truss Bridge, Ramen Bridge, Cable Stayed Bridge and Suspension Bridge according to the type of superstructure.

Among them, the Ramen Bridge is a bridge that increases the rigidity of the entire structure by connecting the upper and lower structures of the bridge with steel, and at the same time, instead of reducing the magnitude of the bending moment occurring in the bridge, it is burdened by the shift or the bridge.

This type of bridge can be hypothesized without expansion joints or pressure plates up to 50m, and it is advantageous compared to simple bridges in the same area in terms of maintenance, and the thickness of the mold can be designed to be relatively small. This has a wonderful characteristic.

In Korea, it can be seen a lot in highway cross-section bridges, and it is possible to design a variety of forms, and the thickness of the pier is relatively thick because it is common to make the beam thin.

FIG. 8 is a bending moment diagram of a general ramen bridge, in which a center portion of a beam mounted between an area, ie, an adjacent pier, has a parent moment that sags downward due to its own load and a load caused by a passing person or a vehicle. On the other hand, the piers generate positive moments that bend upwards.

However, as can be seen from the moment diagram, the simple repetitive distribution affects the tensile and compressive stresses acting only at one point, thus adversely affecting the durability of the bridge.

(Patent Document 1) Korea Patent Registration 10-0989586-0000 (October 18, 2010) (Patent Document 2) Republic of Korea Patent Registration 10-0936629-0000 (January 05, 2010) (Patent Document 3) Republic of Korea Patent Registration 10-0989313-0000 (October 15, 2010) (Patent Document 4) Republic of Korea Utility Registration 20-0300023-0000 (December 23, 2002)

The present invention was developed to solve the above problems, and its object is to develop a ramenized bridge girder fixed structure that can distribute the tensile and compressive stress distributed in the ramen bridge to be evenly distributed throughout the girder. have.

In order to achieve the above object, the present invention is fixed to the pier with the fixing plate in the state assembled to correspond to the screw holes of the fixing plate is formed with several screw holes, some of the fixing bolts protruding upwards and ;

A vertical beam having a shape of an H beam vertically inserted therein, and having a bottom surface blocked and having a plurality of first coupling holes formed therein so that the protruding end of the fixing bolt is inserted and fixed by the fixing nut;

A girder having an H beam shape extending horizontally and having an upper surface coupled to a bottom surface adjacent to both ends;

At least two guide brackets vertically formed at regular intervals in the center of both sides of the girder, and a strand wire fixing bracket having one or more second coupling holes penetrating both ends of the guide brackets formed therethrough; The outer circumferential surface of both ends is characterized in that it comprises a first stress distribution means consisting of one or more strands that are formed by a thread is formed through the second coupling hole and fixed by the strand fixing nut.

In addition, the upper fixed beam which protrudes from the upper end of the mutually opposite inner surface of the vertical beams located on both sides and extends to the lower side, the lower fixed beam protruding from the lower end and extending upward, and between the upper fixed beam and the lower fixed beam A second stress distributing means composed of a screw jack mounted to the second jack;

A steel wire guide beam having a top surface corresponding to the upper end of the vertical beam on the other side on which the second stress dispersing means of the vertical beam is formed, and the bottom surface being slightly spaced upward from the lower end of the vertical beam, and the bottom of the steel wire guide beam And a plurality of first through holes formed through the upper surface, a second through hole penetrating the bottom surface of the girder corresponding to the first through hole in the upper portion, and mounted on the side of the girder and perpendicular to the second through hole. Steel wire fixing bracket having a third through hole on the extension line, several steel wires through the first to third through holes formed with a screw thread formed on the outer peripheral surface of both ends, and several steel wires fixing both ends of the steel wire Characterized in that it comprises a third stress distribution means composed of a fixed nut.

In addition, the girder is mounted on a vertical beam at the center of the bottom surface is fixed to the three piers, the first stress distribution means is formed in the center between the adjacent piers, respectively, the second to third stress distribution means are perpendicular to both sides except the center And mounted to the beam.

As described above, the present invention gives an artificial stress to the girder of the ramenized bridge so as to disperse the concentrated stress to another place, thereby improving durability and stability.

1 is an exploded perspective view showing a ramen bridge according to an embodiment of the present invention
2 is a side view showing a ramen bridge according to an embodiment of the present invention
3 is a perspective view showing a ramen bridge according to another embodiment of the present invention
Figure 4 is a side view showing a ramen bridge according to another embodiment of the present invention
Figure 5 is an exploded perspective view showing a coupling portion of the girder according to another embodiment of the present invention
Figure 6 is a side view showing the coupling portion of the girder according to another embodiment of the present invention
7 is a bending moment diagram of the ramen bridge constructed in accordance with the present invention
8 is a bending moment diagram of a general ramen bridge

Accordingly, the configuration of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily understand and reproduce.

1 is an exploded perspective view showing a ramen bridge according to an embodiment of the present invention, Figure 2 is a side view showing a ramen bridge according to an embodiment of the present invention, the screw of the fixing plate 11 is formed several screw holes A plurality of fixing bolts 1 which are embedded in the piers 12 together with the fixing plate 11 in the assembled state corresponding to the holes, and part of which is fixed upward;

It has the shape of the H-beam vertically, but the bottom surface is blocked, and the first end of the fixing bolt (1) is inserted into the protruding end is inserted into a plurality of first coupling holes 21 are formed to be fixed by the fixing nut (13) Beam 2;

A girder 3 having an H beam shape extending horizontally and having an upper surface of the vertical beam 2 coupled to a bottom surface adjacent to both ends;

At least two or more guides 41 extending horizontally in the center of both sides of the girder 3 are formed at regular intervals vertically, and one or more second ends of both ends of the guide brackets 41 are closed. The strand wire fixing bracket 43 having the coupling hole 42 formed therein, and at least one strand wire fixed with the strand wire fixing nut 44 after a thread is formed on the outer circumferential surfaces of both ends thereof, penetrating the second coupling hole 42. Ramenized bridge girder fixed structure, characterized in that it consists of a first stress distribution means (4) consisting of (45).

At this time, the strand 45 is preferably located below the center of the girder (3).

When the first stress distribution means 4 is tightly tightened on both sides of the strand wire 45 by the strand wire fixing nut 44, the girder 3 is a bending moment to be bent upwards, which is a load By this will serve to distribute the stress against the bending moment sagging downwards.

3 is a perspective view showing a ramen bridge according to another embodiment of the present invention, Figure 4 is a side view showing a ramen bridge according to another embodiment of the present invention, Figure 5 is a combination of girder according to another embodiment of the present invention Figure 6 is an exploded perspective view showing a portion, Figure 6 is a side view showing a coupling portion of the girder according to another embodiment of the present invention, Figure 7 is a bending moment diagram of the ramen bridge constructed in accordance with the present invention, the first stress distribution means (4) Is to counter the bending moment acting in the direction in which the girder 3 sags between adjacent piers 12, the bending moment in which the girder 3 lifts upward in the piers 12 acts to prevent this. In order to achieve the present invention, the second to third stress distribution means 5 and 6 are further formed.

The second stress dispersing means 5 includes an upper fixed beam 51 protruding from the upper end of the mutually facing inner side surfaces of the vertical beams 2 located on both sides and extending downward, and a lower end protruding from the lower end. It consists of a fixed beam 52, and a screw jack 53 mounted between the upper fixed beam 51 and the lower fixed beam (52).

In addition, the third stress dispersing means 6 has an upper surface corresponding to the upper end of the vertical beam 2 on the other side on which the second stress distributing means 5 of the vertical beam 2 is formed, and the bottom of the vertical stress dispersing means 6. The steel wire guide beam 61 slightly spaced upward from the lower end of (2), several first through holes 62 penetrating through the bottom and the upper surface of the steel wire guide beam 61, and the first upper portion The second through hole 63 penetrating the bottom of the girder 3 corresponding to the through hole 62, and is mounted on the side of the girder 3 on the vertical extension of the second through hole 63 Steel wire fixing bracket (65) having a third through hole (64), and several steel wires (66) penetrating through the first through third through holes (62, 63, 64) with threads formed at both ends of the outer circumferential surface thereof. And a third stress distributing means 6 composed of several steel wire fixing nuts 67 for fixing both ends of the steel wire 66.

The second stress distributing means 6 acts to force the screw jack 53 to be opened between the upper fixed beam 51 and the lower fixed beam 52, and the third stress distributing means 6 is tightened. The force acts so that the force of the girder 3 is basically caused by the load so that the force in the opposite direction and the bending moment to be lifted in the opposite direction, that is, upward, act to distribute the force.

In this embodiment, in the present invention, the girder 3 has a vertical beam 2 mounted at the center of the bottom thereof, and is fixed to three piers 12, and the first stress distributing means 4 is disposed between the adjacent piers 12. It is formed in the center, respectively, the second to third stress distribution means (5, 6) has shown an embodiment mounted on both vertical beams 2, except the center.

The bending moment according to the embodiment has a state as shown in FIG. 7, which is smaller than that of the conventional bending moment diagram in the bridge having the same structure in the prior art of FIG. 8. It can be seen that the distribution of the positive moment and the sub-moment also has a direction opposite to that of the prior art, which is a result of effectively dispersing the stress.

1: fixing bolt
11: fixing plate 12: pier
13: fixing nut
2: vertical beam
21: first coupling hole
3: girder
4: first stress distribution means
41: guide bracket 42: second coupling hole
43: strand wire fixing bracket 44: strand wire fixing nut
45: stranded wire
5: second stress distribution means
51: upper fixed beam 52: lower fixed beam
53: screw jack
6: third stress distribution means
61: steel wire guide beam 62: first through hole
63: second through hole 64: third through hole
65: steel wire fixing bracket 66: steel wire
67: steel wire fixing nut

Claims (3)

Several fixing bolts 1 which are fixed to the pier 12 together with the fixing plate 11 in a state where they are assembled corresponding to the screw holes of the fixing plate 11 in which several screw holes are formed, and part of which protrudes upward. Wow;
It has the shape of the H-beam vertically, but the bottom surface is blocked, and the first end of the fixing bolt (1) is inserted into the protruding end is inserted into a plurality of first coupling holes 21 are formed to be fixed by the fixing nut (13) Beam 2;
A girder 3 having an H beam shape extending horizontally and having an upper surface of the vertical beam 2 coupled to a bottom surface adjacent to both ends;
At least two or more guides 41 extending horizontally in the center of both sides of the girder 3 are formed at regular intervals vertically, and one or more second ends of both ends of the guide brackets 41 are closed. The strand wire fixing bracket 43 having the coupling hole 42 formed therein, and at least one strand wire fixed with the strand wire fixing nut 44 after a thread is formed on the outer circumferential surfaces of both ends thereof, penetrating the second coupling hole 42. Ramenized bridge girder fixed structure, characterized in that it comprises a first stress distribution means (4) consisting of (45).
According to claim 1, wherein the upper fixed beam (51) protruding from the upper end of the mutually opposite inner surface of the vertical beams (2) located on both sides extending downward, and the lower fixed beam (52) protruding from the lower end and extending upward A second stress dispersing means (5) composed of a screw jack (53) mounted between the upper fixed beam (51) and the lower fixed beam (52);
The upper surface corresponding to the upper end of the vertical beam (2) on the other side on which the second stress distribution means 5 of the vertical beam (2) is formed, the bottom is slightly spaced apart above the lower end of the vertical beam (2) The girder corresponding to the steel wire guide beam 61, several first through holes 62 penetrating through the bottom and the upper surface of the steel wire guide beam 61, and the first through hole 62. A second through hole 63 penetrating the bottom of (3) and a third through hole 64 mounted on a side surface of the girder 3 on a vertical extension line of the second through hole 63; Steel wire fixing bracket 65, a screw thread is formed on the outer peripheral surface of both ends and several steel wire 66 through the first to third through holes 62, 63, 64, and both side ends of the steel wire 66 Ramenized bridge girder fixed structure, characterized in that consisting of a third stress distribution means (6) consisting of several steel wire fixing nuts (67) for fixing the.
2. The girder (3) according to claim 1, wherein the girders (3) are mounted on three piers (12) with vertical beams (2) mounted at the center of the bottom, and the first stress distributing means (4) at the center between adjacent piers (12). Respectively formed, and the second to third stress distribution means (5, 6) are mounted on both vertical beams (2) excluding the center.

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