KR101588280B1 - Prestressed girder bridge having tension regulator for steal wire - Google Patents

Abstract

Provided is a prestress girder bridge having a tension regulator for a support steel wire. The prestress girder bridge comprises: abutments (10) separated from each other at a predetermined interval; a girder (20) having a first girder (22) formed at a predetermined length with both ends fixated on one side of an upper part of each abutment (10), and a second girder (26) formed at a predetermined length with both ends fixated on an other side of each abutment (10) while being separated from the first girder (22) at a predetermined interval; a support beam (30) having a first support beam (32) with both ends fixated on an inner surface of the first and second girders (22, 26) positioned in one among the abutments (10), and a second support beam (36) fixated on an inner surface of the first and second girders (22, 26) positioned in the other abutment among the abutments (10); a plurality of support steel pipes (40) separated from each other at a predetermined interval between the first and second support beams (32, 36) while both ends are fixated on each inner surface of the first and second girders (22, 26); and a plurality of support steel wires (50) successively separated from each other at a predetermined interval supporting the support steel pipes (40) while one end is fixated on the first support beam (22) and the other end is fixated on the second support beam (26).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a prestressed girder bridge having a tension regulator for steal wire,

The present invention relates to a prestressed girder bridges, and more particularly, to a prestressed girder bridges capable of easily absorbing not only a self-load of a bridge but also a passing load of a pedestrian by using a supporting steel wire having a plurality of supporting steel pipes and tension adjusting means, And a structurally very stable prestress girder bridge that can be dispersed.

Bridges are structures that can be safely walked or operated by pedestrians or cars over natural valleys or rivers, or other traffic or building structures in the city. In a typical bridge, the girder is an important part of the bridge that absorbs the load of the top plate and the passing load of the vehicle and the pedestrian, and transmits it by alternating or piercing.

Taking this into consideration, when constructing a bridge, the girder itself is used as a large diameter pipe of a large diameter, or the concrete is filled in a steel pipe to achieve structural stability of the bridge. However, if the girder is constructed by installing the girder with the large diameter pipe or charging the concrete into the steel pipe, the construction cost will increase remarkably, and the construction period will be long, which is not efficient from the construction economical point of view. This is also applicable to the construction of footbridge for pedestrians, and urgent improvement is needed.

Korean Utility Model No. 0296004, Korean Registered Patent No. 1339526

It is an object of the present invention to provide a girder bridge having a very stable structure that can be installed in a short period of time regardless of the conditions of a construction site.

In order to accomplish this object, the present invention provides an alternating arrangement (10) spaced apart from one another by a predetermined distance; A first girder 22 having a predetermined length and fixed at both ends thereof to one side of the upper portion of each of the alternations 10, a first girder 22 having a predetermined length and fixed at both ends of the upper portion of each of the alternations 10, 1) a girder 20 made up of a second girder 26 disposed at a predetermined distance from the girder 22; A first support beam 32 fixedly coupled to inner surfaces of first and second girders 22 and 26 located at one side of the alternation 10 at opposite ends thereof, A support beam 30 made up of a second support beam 36 fixedly coupled to the inner surfaces of the first and second girders 22, 26 located alternately; The first and second support beams 32 and 36 are spaced apart from each other by a predetermined distance. The opposite ends of the support steel tubes 22 and 26 are fixed to the inner surfaces of the first and second girders 22 and 26, (40); The first support beams 32 and the second support beams 40 are sequentially supported by the plurality of support steel tubes 40. The first support beams 32 are fixedly coupled to the first support beams 32, (36); Both end portions of the support wire 50 are fixedly coupled to the first and second support beams 32 and 36 via elastic brackets 320 and 360, First support plates 322 and 362 fixedly coupled to inner surfaces of the first and second support beams 32 and 36 by fastening bolts 321 and 361 and a pair of fastening bolts 321 and 361 The first and second support plates 324 and 364 are spaced a predetermined distance from the first support plates 322 and 362 and have brackets 325 and 365 formed on one surface thereof. And the other end portion is composed of fasteners 328 and 368 which are rotatably mounted on the brackets 325 and 365 at a predetermined angle.

The diameter of the supporting steel pipe 40 may gradually decrease from the central portion of the girder 20 toward the alternating (10) direction.

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The elastic members 326 and 266 are mounted on the outer surfaces of the fastening bolts 321 and 361 exposed between the first and second support plates 322 and 362 and the first and second support plates 324 and 364, The spacing adjusting nuts 323 and 363 for adjusting the distance between the first and second supporting plates 322, 362, 324 and 364 may be fastened to the fastening bolts 321 and 361 exposed to the outside through the through holes 321 and 362.

The present invention proposes a structure in which a plurality of support steel pipes are disposed between the girders and each of the support steel pipes is supported as a support steel wire or an elastic bracket is further provided at the end of the support wire so that even if a large diameter girder is not used, Not only can it have a stable structure, it also makes it very easy to construct a long bridge, and it allows the ana to actively cope with the load acting on the bridge.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic plan view of a girder bridge according to the present invention;
Fig. 2 is a schematic side view of a girder bridge according to the present invention; Fig.
Figure 3 is a schematic diagram of the line AA 'in Figure 2;
4 is a schematic side elevational view of another girder bridge according to the present invention;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the technical features of the present invention, A detailed description thereof will be omitted.

1 and 2 are a schematic plan view and a side view, respectively, of a girder bridge according to the present invention, and FIG. 3 is a schematic structural view of the line A-A 'in FIG. As disclosed in the drawings, the present invention proposes a girder bridge including an alternation 10, a girder 20, a support beam 30, a support steel pipe 40, and a support steel wire 50. The specific configuration of each of these is as follows.

The alternations 10 are spaced apart from one another by a certain distance. Although the case of the alternation 10 consisting of a pair of left and right pairs is shown in the figure, at least one bridge bridge 12 is installed between the alternations 10 as shown in a schematic side construction diagram of another girder bridge according to the present invention It is possible. Whether or not these piers are installed and how many piers are installed will depend on the width between the shifts.

The girder 20 is composed of a pair of left and right first and second girders 22 and 26 having a predetermined length. The both ends of the first girder 22 are fixedly coupled to one upper side of each of the alternations 10 and the both ends of the second girder 26 are fixedly coupled to the other side of the upper portion of each of the alternations 10, (22). The first and second girders 22 and 26 may be steel tubes having a predetermined thickness.

The support beam 30 is composed of first and second support beams 32, 36 as means for securing the support wire 50. The first support beams 32 are fixedly coupled to the respective inner surfaces of the first and second girders 22 and 26 located at alternate positions in the alternation 10 while the second support beams 36 are fixed to both ends Are fixedly coupled to the respective inner surfaces of the first and second girders (22, 26) located at the other alternate of the turns (10). Each of the first and second support beams 32 and 36 may be made of a steel having a predetermined thickness.

4, the supporting beam 30 is also installed between the alternating 10 and the pier 12 and between the opposite piers 12. In this case, . In this case, each of reference numerals 31, 34 and 37 functions as a first support beam, and each of reference numerals 33, 35 and 38 functions as a second support beam.

The supporting steel pipe 40 is a means for absorbing a load acting on the bridge and transmitting it to the girder 20 to disperse it. The supporting steel pipes 40 are arranged between the first and second support beams 32 and 36 at a predetermined distance from each other so that both end portions of the supporting steel pipes 40 are fixedly coupled to the inner surfaces of the first and second girders 22 and 26 . As shown in FIG. 4, when the piers 12 are installed between the alternations 10, a plurality of supporting steel pipes 40 are installed spaced apart from each other by a predetermined distance between the alternation 10 and the piers 12, ) At a predetermined interval.

In the meantime, when a plurality of supporting steel pipes 40 are installed between the first and second supporting beams 32 and 36, as shown in the respective figures, as the distance from the central portion of the girder 20 to the alternating (10) And the diameter is gradually decreased. In this case, the central part of the bridge can be structurally more stable, considering that the bridge itself has a load, and the passing loads of the vehicle or pedestrians are concentrated in the central part of the bridge. Needless to say, even when a plurality of piers 12 are provided between the alternations 10, the structure of the supporting steel pipe 40 can be equally applied.

The supporting steel wire 50 is a means for absorbing a load acting on the bridge and transmitting it to the alternating system 10 to disperse it. The supporting strands 50 are composed of a plurality of supporting strands 50 spaced apart from each other by a predetermined distance. Each one end portion is fixedly coupled to the first supporting beam 22, and each of the other supporting portions supports the supporting steel pipe 40 sequentially And the other end portion is fixedly coupled to the second support beam 26. The supporting steel wire is preferably made of a metal and the supporting steel wires 51, 53 and 55 are configured to have a large diameter even when a plurality of bridge piers 12 are provided between the turns 10.

In this way, when the supporting steel tubes having a certain diameter or different diameters are disposed between the girders and the supporting steel tubes are supported as the supporting steel wires, part of the passing load acting on the bridge as well as the load of the bridge itself, Is absorbed and transferred to the girder to be dispersed and the remainder is absorbed by the supporting steel wire and is alternately transferred and dispersed, so that the bridge has a very stable structure for a long time.

In addition, since the support steel pipe and the support steel wire can handle most of the loads acting on the bridge, it is possible to construct the bridge without using the large diameter girder, and it is possible to easily construct the bridge without using the large diameter girder It is very efficient in construction economics.

2, the case where both ends of the supporting steel wire 50 are fixedly coupled to the first and second supporting beams 32 and 36 via the elastic brackets 320 and 360 is excluded I never do that. The elastic brackets 320 and 360 are attached to the first and second support plates 322 and 364 and the elastic members 326 and 266 and the fixtures 328 and 368 and the fixing bolts 321 and 361, , 363).

Each of the first and second support plates 322, 362, 324 and 364 is a means for maintaining a tightly constrained state of the support steel wire 50. Each of the first support plates 322 and 362 is fastened by fastening bolts 321 and 361 The second support plates 324 and 364 are fixedly coupled to the inner surfaces of the first and second support beams 32 and 36 and the first and second support plates 322 and 364 are inserted through the fastening bolts 321 and 361, As shown in FIG. Brackets 325 and 365 are provided on the respective sides of the second support plates 324 and 364.

The elastic members 326 and 366 are means for maintaining the interval between the first and second support plates 322, 362, 324 and 364 using the restoring force. The elastic members 326 and 366 include first support plates 322 and 362 spaced from each other by a predetermined distance, 2 supporting plates 324 and 364 and the outer surface of the fastening bolts 321 and 361. The other ends of the fixing members 328 and 368 are rotatably mounted on the brackets 325 and 365 at a predetermined angle, and a support wire 50 is inserted and fixed at one end thereof.

The spacing adjusting nuts 323 and 363 are means for adjusting the distance between the first and second supporting plates 322 and 362. The spacing adjusting nuts 323 and 363 are formed on the first and second supporting plates 324 and 364, Bolts 321 and 361, respectively. The gap between the first and second support plates 322, 362, 324, and 364 controlled by the spacing nuts 323 and 363 is maintained by the restoring force of the elastic members 326 and 366 described above.

When the means for adjusting the spacing and the means for maintaining the adjusted spacing are provided between the end portions of the support beams and the support steel wires, it is possible to more appropriately adjust the tension of the support steel wires supporting the support steel pipes, It can actively cope with the acting load. If it is necessary to readjust the tension of the installed support wire, the interval between the first and second support plates may be set again by using a gap adjusting nut.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. It will be apparent that the present invention can be practiced with added features.

10: shift 20: girder
30: Support beam 40: Supported steel pipe
50: support wire 320, 360: elastic bracket

Claims (4)

An alternating arrangement 10 spaced apart from one another by a predetermined distance;
A first girder 22 having a predetermined length and fixed at both ends thereof to one side of the upper portion of each of the alternations 10, a first girder 22 having a predetermined length and fixed at both ends of the upper portion of each of the alternations 10, 1) a girder 20 made up of a second girder 26 disposed at a predetermined distance from the girder 22;
A first support beam 32 fixedly coupled to inner surfaces of first and second girders 22 and 26 located at one side of the alternation 10 at opposite ends thereof, A support beam 30 made up of a second support beam 36 fixedly coupled to the inner surfaces of the first and second girders 22, 26 located alternately;
The first and second support beams 32 and 36 are spaced apart from each other by a predetermined distance. The opposite ends of the support steel tubes 22 and 26 are fixed to the inner surfaces of the first and second girders 22 and 26, (40);
The first support beams 32 and the second support beams 40 are sequentially supported by the plurality of support steel tubes 40. The first support beams 32 are fixedly coupled to the first support beams 32, (36); Including,
Both end portions of the support steel wire 50 are fixedly coupled to the first and second support beams 32 and 36 via elastic brackets 320 and 360. The elastic brackets 320 and 360 are fixed to the first and second support beams 32 and 36, (322, 362) fixedly coupled to inner surfaces of the first and second support beams (32, 36) by first and second support beams (321, 361) Second support plates 324 and 364 having brackets 325 and 365 formed on one side thereof spaced apart from the support plates 322 and 362 by a predetermined distance, Is provided with tension adjusting means for the supporting steel wire composed of fixing holes (328, 368) which are rotatably mounted on the brackets (325, 365) at a certain angle. The method according to claim 1,
Wherein the diameter of the supporting steel pipe (40) gradually decreases from the central portion of the girder (20) toward the alternating (10) direction. delete The method according to claim 1,
Elastic members 326 and 266 are mounted on outer surfaces of fastening bolts 321 and 361 exposed between the first and second support plates 322 and 362 and the first and second support plates 324 and 364 Spacing nuts 323 and 363 for adjusting the distance between the first and second support plates 322, 362, 324 and 364 are fastened to the fastening bolts 321 and 361 exposed to the outside through the first and second support plates 321 and 322. [ A prestressed girder bridge provided with means for tensioning the support strand.

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