KR102280432B1 - Variable steel girder structure for deflection prevention - Google Patents

Abstract

The present invention relates to preventing deflection of a steel bridge structure and, more particularly, to a technique capable of coping with deflection caused by long-term deformation by a steel girder installed at an adjusted inclination angle to prevent long-term deformation of a bridge deck due to loading. To solve the problem, the present invention provides a steel bridge structure comprising: column piers disposed on the ground at regular intervals; a steel girder for connecting the column piers to each other; and an upper plate placed on top of the steel girder. The steel bridge structure further comprises: a vertical wall provided on the heads of the column piers; the steel girder having flanges and a web; and a gusset plate for connecting the vertical wall and the steel girder, and including a flat plate and a connecting member formed on the flat plate in a vertical direction to connect to the web. A fastening hole is formed on an upper portion of the web provided on an end of the steel girder, and an arc-shaped hole is formed in a lower portion of the web. The connecting member has upper and lower connecting holes. The steel girder and the gusset plate are coupled to each other by a first fastener hinged through the upper connecting hole and the fastening hole and a second fastener passing through the lower connecting hole and coupled while moving along the arc-shaped hole.

Description

Variable steel girder structure for deflection prevention

The present invention is to prevent deflection of a steel bridge structure, and relates to a technology configured to cope with deflection due to long-term deformation by adjusting the inclination angle of a steel girder and installing it in order to prevent long-term deformation of the bridge top plate due to a load.

A general steel bridge structure is composed of a post pier arranged at regular intervals on the ground, a steel girder connecting the post piers, and a top plate placed on the upper part along the steel girder, and the deflection phenomenon due to the load acting in the longitudinal direction Occurs.

At this time, the load acting in the longitudinal direction includes the load of its own structure such as steel girder and the top plate, and the repeated traffic load acting on the top plate of the structure. Deflection occurs on the upper plate of the structure.

Here, the longer the distance (span) between the strut and the pier supporting the upper plate and the steel girder, the greater the deformation is due to the increase in the bending stress applied to the steel girder, and the steel girder is deformed because it mainly uses H-beam structural steel. There was a problem in that it was difficult to repair the steel girder or to restore the deformed and drooping steel bridge structure. If deflection occurs due to deformation of the steel girder, it becomes difficult to perform the role of a normal steel bridge, such as inclination of the upper plate and cracks in the pavement.

Methods to prevent deflection of such structures include designing a narrow span or increasing the strength of the upper plate and steel girder. However, as the number of poles increases, the construction cost increases and the construction period is delayed. In some cases, it is difficult to install a pier, which reduces the efficiency. In addition, if the thickness of the material is increased in order to increase the strength of the upper plate and the steel girder, the load of the upper plate and the steel girder increases and the stress acting on the strut increases, thereby reducing the deflection without increasing the strength of the upper plate and the steel girder. There is a need for technology to prevent it.

Registered Patent 10-0783593 "Device for preventing deflection of a temporary bridge" is a device for preventing deflection of a temporary bridge that is installed under both ends of a truss girder used for a temporary bridge to prevent deflection of the girder, comprising: steel rods having threads formed at both ends; Anchors for fixing and supporting the steel rods at both ends of the lower girder; a steel bar connector connecting the steel bar to the steel bar; and a slide guide for limiting the flow range of the steel rod, wherein the slide guide is provided with a solid member having a through hole through which the steel rod penetrates to the lower side, and fixed to the solid member at a predetermined interval, respectively, the solid There is provided a device for preventing deflection of a temporary bridge, characterized in that it includes a flow prevention rod that is longer than the width of the member, but the existing device for preventing sagging is equipped with a separate support device at the lower end of the bridge or tension is applied. It can be used only in limited situations by using the method of installing and supporting the applying device, and there is a limitation in that it takes a lot of cost to install a separate supporting device. In addition, most of the patents are focused on the device or structure for measuring the deflection of the bridge, so the technology for preventing the deflection is insufficient.

In order to solve such a problem, a technology for preventing deflection of steel bridge structures that prevents deflection due to long-term load, which is easy to restore and does not require much cost for installation of the device, is needed.

1. Registered Patent 10-0783593 "Deflection prevention device of temporary bridge" 2. Registered Patent 10-1917619 "Bridge Deflection Measurement System" 3. Registered Patent 10-0733004 "Structure to prevent sagging of the upper part of the bridge" 4. Registered Patent 10-0851246 "A device for diagnosing the state of deflection of facilities above the bridge" 5. Patent Publication 10-2020-0137300 "A device for preventing sagging of bridge connection slab and its construction method"

The present invention is to prevent deflection of steel bridge structures, and to prevent long-term deformation of the bridge top plate due to load, by adjusting the inclination angle of the steel girder and installing it, it is possible to cope with deflection due to long-term deformation.

In addition, an object of the present invention is to provide a structure that lowers the manufacturing cost, reduces the working time, and provides a reinforcing method for deformation due to load and vibration because a complicated structure or a device with high manufacturing cost is not required.

In order to solve the above problems, the present invention is a "steel bridge structure consisting of a strut disposed at regular intervals on the ground, a steel girder connecting the piers to each other, and a top plate placed on the upper plate along the steel girder, transverse wall of pier perimeter; steel girder with flange and web; and a gusset plate that connects the transverse wall and the steel girder, is formed in a direction perpendicular to the flat plate and the plate coupled to the transverse wall, and is connected to the web, and is configured to include, a web at the end of the steel girder A fastening hole is formed in the upper part, an arc-shaped hole is formed in the lower part, and upper and lower connecting holes are formed in the connecting member, and the steel girder and the gusset plate are formed by connecting the upper connecting hole and the fastening hole. a first fastener through which the hinge is coupled; and a second fastener that passes through the lower connection hole and moves along the arc-shaped hole and is coupled;

In addition, by the coupling of the steel girder and the gusset plate, a separation space is formed between the end of the steel girder and the flat plate of the gusset plate, and an elastic pad inserted upwardly from below the separation space; further comprising characterized in that

In addition, the support is disposed under the gusset plate; and rail portions provided on both sides of the supporter, characterized in that it further includes, wherein the supporter is configured to ascend and descend along the rail portion.

In addition, a fixture provided on the lower surface of the steel girder; It is configured to further include a traction device provided on the post pier, wherein the traction device applies a tension to pull the tension line connected to the fixture, characterized in that it fixes the steel girder.

In addition, it is characterized in that the cross section is formed at regular intervals in the lower portion of the arc-shaped hole.

According to the present invention, there are the following effects.

1. By predicting the angle of deflection due to repeated traffic loads, etc., and installing it by adjusting the inclination angle of the steel girder in advance, it is possible to prepare for deflection due to long-term repeated loads.

2. When deflection occurs, the step difference caused by deflection can be offset by adjusting the inclination angle of the steel girder at the end of the steel girder and raising the steel girder.

3. By inserting an elastic pad between the steel end and the flat plate of the gusset plate, the supporting force for the steel end is strengthened, and deformation due to vibration is suppressed.

4. The durability of the connection is increased by providing a support at the connection between the steel end and the gusset plate.

5. It prevents sagging by increasing the bearing capacity of the steel girder by the tension generated by pulling the tension line connected to the steel girder.

[FIG. 1] is a perspective view showing the connection between the transverse wall and the steel girder in the steel bridge structure according to the present invention.
[Figure 2] is a perspective view showing the configuration of the gusset plate, steel girder and support according to the present invention.
[Figure 3] shows the inclination angle control structure of the steel girder according to the present invention.
[Figure 4] shows a traction device according to the present invention.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. In adding reference numerals to the components of each drawing, the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the embodiment of the present invention, if it is determined that a detailed description of a related known configuration or function interferes with the understanding of the embodiment of the present invention, the detailed description thereof will be omitted.

The present invention is a "steel bridge consisting of a strut (1) disposed at regular intervals on the ground, a steel girder 200 connecting the piers (1) to each other, and a top plate placed on the top along the steel girder 200. In the structure, the transverse wall 100 of the pier (1) perimeter; a steel girder 200 having a flange 210 and a web 220; And the transverse wall 100 and the steel girder 200 are connected, the flat plate 310 coupled to the transverse wall 100 and the flat plate 310 are formed in a vertical direction and are connected to the web 220 A gusset plate 300 composed of a member 320; is configured to include, a fastening hole 221 is formed in the upper portion of the web 220 of the end of the steel girder 200, and an arc-shaped hole in the lower portion 222 is formed, and upper and lower connection holes 321 and 322 are formed in the connection member 320, and the steel girder 200 and the gusset plate 300 have the upper connection hole ( 321) and a first fastening hole 410 for hinge-coupled through the fastening hole 221; and a second fastening hole 420 that passes through the lower connection hole 322 and moves along the arc-shaped hole 222 and is coupled; a deformable steel girder structure for preventing sagging, characterized in that it is coupled by the ' is provided.

Hereinafter, a deformable steel girder structure for preventing sagging of the present invention will be described in detail with reference to FIGS. 1 to 4 below.

The deformable steel girder structure for preventing sagging according to the present invention is a steel girder 200 connecting the transverse wall 100 of the perimeter of the post pier 1 disposed at regular intervals on the ground as shown in FIG. 1 and the post piers 1 with each other. ) and the pole pier (1) is applied to a steel bridge structure consisting of a gusset plate 300 connecting the transverse wall 100 and the steel girder 200 of the perimeter.

The main part is the strut pier 1, the transverse wall 100 of the perimeter, the steel girder 200 having the flange 210 and the web 220, the gusset plate 300 consisting of the flat plate 310 and the connecting member 320. A fastening hole 221 is formed in the upper portion of the web 220 of the end of the steel girder 200, and an arc-shaped hole 222 is formed in the lower portion, and the connecting member ( The upper and lower connection holes 321 and 322 are formed in the 320 .

The transverse wall 100 is a wall surface for fixing the transverse member connecting the post pier 1 to the vertical surface of the perimeter of the post pier 1, and in the structure of the present invention, the gusset plate 300 connected to the steel girder 200. is the wall that holds the

The steel girder 200 is mainly made of steel for an H-beam structure having a flange and a web, and a fastening hole 221 is formed in the upper portion of the web 220 at the end of the steel girder 200, and an arc-shaped hole is formed in the lower portion. Form space) 222 may be formed. The fastening hole 221 is formed as a circular through-hole to which a fastener 400 such as a general rivet or bolt can be coupled, and the arc-shaped hole 222 is the center of the fastening hole 221 . It is formed in an arc shape with the same distance from the

[Fig. 3] shows a connection structure in which a transverse wall 100 is formed on the left side and a steel girder 200 is coupled to the right side, and the installation angle of the steel girder 200 is shown based on the arrangement of [Fig. 3] below. An example to be changed will be described.

In [FIG. 3], in order to install the steel girder 200 to be inclined upwardly to the right centering on the fastening hole 221 in advance in preparation for a sagging phenomenon that will occur in the future, the first fastening hole 410 is used as a rotation axis for the steel girder The central portion of the 200 is rotated upward to the right, and when the steel girder 200 is disposed at a predetermined angle, the second fastener 420 is fastened and fixed.

In this case, the clasp 223 may be formed at regular intervals in the lower portion of the arc-shaped hole 222 . The spanning portion 223 is formed by protruding at regular intervals; Or a girding groove formed by digging at regular intervals; It may consist of any one of. [Fig. 2] to [Fig. 4] shows a case in which the clasp 223 is formed as a clasp groove. The clasp 223 may be fixed across the second fastener 420 in order to prevent the second fastener 420 from sliding along the curved groove of the arc-shaped hole 222 . .

The gusset plate 300 includes a flat plate 310 and a connecting member 320 protruding vertically from the flat plate 310 . The flat plate 310 is in contact with the transverse wall 100 and is coupled to the transverse wall 100 with a connecting hardware such as an anchor bolt, and upper and lower connecting holes 321 and 322 are formed in the connecting member 320 . The connecting member 320 may be formed of a single plate having upper and lower connecting holes 321 and 322 formed thereon, or an upper and lower plate having upper and lower connecting holes 321 and 322 formed respectively. In addition, the connecting member 320 may be configured as a double plate so that the web 220 of the steel girder 200 is formed to be disposed between the double plates, or may be configured as a single side plate to be coupled only to one side. However, it is preferable that the connecting member 320 is configured as a double plate in order to respond to the shear force, and is configured to sandwich the web 220 of the steel girder 200 between the double plates.

The fastener 400 is made of fasteners such as bolts and rivets, and can be fastened, removed, and disassembled without damaging the fastening hole 221 , the arc-shaped hole 222 and the connecting hole. it is designed to be

In the present invention, a space 500 is formed between the end of the steel girder 200 and the flat plate 310 of the gusset plate 300 by combining the steel girder 200 and the gusset plate 300 . and an elastic pad 600 inserted upwardly from the lower side of the separation space 500; characterized in that it further comprises.

The elastic pad 600 is a member inserted into the spaced space 500 between the end of the steel girder 200 and the flat plate 310 of the gusset plate 300, which is formed when the steel girder 200 is installed at an angle. In order to correspond to the size of 500, it is preferable to form a leaf spring having elasticity and a composite thereof. In this case, the elastic pad 600 may be formed in a wedge-shaped shape converging upward so as to be inserted upwardly from below the separation space 500 . Accordingly, when the elastic pad 600 is inserted into the separation space 500 , the elastic pad 600 is fixed in close contact with the end of the steel girder 200 and the flat plate 310 of the gusset plate 300 . The load transferred from the steel girder 200 is transferred to the pole pier 1 .

In addition, the elastic pad 600 is disposed between the steel girder 200 and the post pier 1 serves to absorb the vibration transmitted from the steel girder (200). By absorbing vibrations such as vibrations generated from vehicles passing through the top plate or horizontal inertia support force due to earthquakes, it serves to disperse and reduce vibrations, thereby preventing damage to members due to vibrations.

In the present invention, in order to prevent separation of the elastic pad 600 and to reinforce the rigidity of the connection part by supporting the connection part of the steel girder 200 and the gusset plate 300, the gusset plate 300 Earth 700 can be placed.

The support unit 700 may be installed on the flat plate 310 of the gusset plate 300 or the chest wall of the strut 1, and is disposed closely at the lower end of the end of the steel girder 200 to the steel girder 200. It can support by distributing the applied load.

At this time, since the height in contact with the lower end of the steel girder 200 can be changed according to the inclination angle of the steel girder 200, rail parts 710 are provided on both sides of the support member 700 and the support member 700 ) may be configured to elevate along the rail portion 710 . Therefore, the support device 700 having the rail portion 710 elevates the support member 700 according to the inclination angle of the steel girder 200 to the lower end of the steel girder 200 end of the support member 700. It can be fixed by adhering the upper surface. In addition, it may be configured to further include a support fixing part 720 for fixing the support part 700 to the rail part 710 . The support fixing part 720 is composed of a fixing protrusion capable of fastening and detaching, and is configured as a rotatable ring as in the embodiment of [FIG. 2]. When the support device 700 is disposed at a predetermined position, the rail part It is fastened to the groove of the 710 and may be configured to fix the support unit 700 .

The support member 700 is a bulkhead (not shown) protruding upwards on both sides of the support member 700 to prevent corrosion and damage by blocking the connection portion between the steel girder 200 and the gusset plate 300 from the side. can form. The support unit 700 may be formed in a flat plate shape or a ∪ shape with the partition walls (not shown) provided on both sides.

In addition, the present invention is a fixture 800 provided on the lower surface of the steel girder 200 in order to prevent sagging of the steel girder 200; a traction device 810 provided in the post pier (1); Doedoe configured to further include, the traction device 810 may apply a tension to pull the tension line 820 connected to the fixture 800 to fix the steel girder 200 .

[Figure 4] shows a traction device 810 according to the present invention, the structure in which the fixture 800 and the traction device 810 are connected by a tension line 820 is shown.

The fixture 800 is for hanging the tension wire 820 , and may be mounted on the lower surface of the steel girder 200 .

The traction device 810 may be provided on the upper part of the post pier 1, pull the tension line 820 to generate tension, and to be fixed in a state in which the tension is generated.

The tension wire 820 is a wire such as a cable in which an iron core is bundled, and one side may be hung and fixed to the fixture 800 , and the other end may be wound around the traction device 810 .

In one embodiment of applying the structure according to the traction device 810, the fixture 800 is disposed at the point of the steel girder 200 where the occurrence of deflection is expected, and the tension line 820 is connected to the fixture 800. And after being connected to the traction device 810 is configured to pull the tension wire 820 according to the operation of the traction device (810). After that, when sufficient tension is applied to the tension wire 820 , the tension wire 820 is fixed to the traction device 810 . Therefore, since the tension line 820 is in a state that continuously pulls the steel girder 200, as a result, the sag of the upper plate or the steel girder 200 is prevented. When sagging occurs, the traction device 810 is operated to pull the tension wire 820 until the steel girder 200 has a predetermined gradient, thereby simplifying repair work for sagging.

In addition, the deformable steel girder structure for preventing sagging according to the present invention may be implemented on one side of the steel girder 200 or implemented on both sides. The end of the steel girder 200 may be installed by rotating the first fastener 410 as the center to adjust the angle of inclination to the optimum according to the span length of the steel bridge or the predicted load value. Since the occurrence of deflection increases in the central portion of the transverse upper structure of the steel bridge, it is preferable to install the steel girder 200 by adjusting both sides of the steel girder 200 at a constant inclination angle and installing it so that the central portion of the steel girder 200 has an upward gradient. do. When the present invention is carried out on both sides as described above, the central portion of the steel girder 200 is installed to have a gradient in the upward direction in advance to offset the step difference with the peripheral portion due to sagging that occurs in the long term.

The present invention is not limited to the specific preferred embodiments described above, and without departing from the gist of the present invention claimed in the claims, anyone with ordinary skill in the art to which the invention pertains can implement various modifications Of course, such modifications are intended to be within the scope of the claims.

1: Post pier
100: transverse wall
200: steel girder
210: flange
220: web
221: fastening hole 222: arc shape hole
223: hanging part
300: gusset plate
310: reputation
320: connecting member
321: upper connection hole 322: lower connection hole
400: fastener
410: first fastener 420: second fastener
500: separation space 600: elastic pad
700: support
710: rail unit 720: support fixing unit
800: fixture
810: traction device 820: tension wire

Claims (5)

In a steel bridge structure composed of a strut (1) disposed at regular intervals on the ground, a steel girder (200) connecting the piers (1) to each other, and a top plate placed on the top along the steel girder (200),
Post pier (1) transverse wall of the main column (100);
a steel girder 200 having a flange 210 and a web 220;
The horizontal wall 100 and the steel girder 200 are connected, and the flat plate 310 coupled to the horizontal wall 100 and the connecting member formed in the vertical direction to the flat plate 310 and connected to the web 220 Gusset plate 300 composed of 320;
a support member 700 disposed under the gusset plate 300; and
Rail units 710 provided on both sides of the support unit 700; Consists of including,
A fastening hole 221 is formed in the upper portion of the web 220 at the end of the steel girder 200, and an arc-shaped hole 222 is formed in the lower portion,
Upper and lower connecting holes 321 and 322 are formed in the connecting member 320,
The steel girder 200 and the gusset plate 300 are,
a first fastener 410 for hinged coupling through the upper connection hole 321 and the fastener hole 221; and
a second fastener 420 that passes through the lower connection hole 322 and moves along the arc-shaped hole 222 and is coupled; combined by
The support (700) is a deformable steel girder structure for preventing deflection, characterized in that configured to elevate along the rail portion (710).
In claim 1,
By the coupling of the steel girder 200 and the gusset plate 300, a space 500 is formed between the end of the steel girder 200 and the flat plate 310 of the gusset plate 300,
an elastic pad 600 inserted upwardly from the lower portion of the separation space 500; Deflectable steel girder structure for preventing sagging further comprising a.
delete In claim 1,
A fixture 800 provided on the lower surface of the steel girder 200;
a traction device 810 provided in the post pier (1); Consists of further comprising,
The traction device 810 is a deformable steel girder structure for preventing deflection, characterized in that by applying a tension to pull the tension line 820 connected to the fixture 800, to fix the steel girder 200.
5. In any one of claims 1 to 2 and 4,
Deflectable steel girder structure for preventing sagging, characterized in that the clasp 223 is formed at regular intervals in the lower portion of the arc hole 222.

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