KR102199927B1 - up-lift control and Anti-fall prevention steel box girder bridge - Google Patents

Abstract

The present invention is formed of a lower flange and a girder including a pair of abdomens coupled to both sides of the lower flange, in the case of a large difference between the branches in a continuous girder or a small radius of curvature in a curved girder, an alternating or pier point portion Set the negative reaction force control load generated in the, and calculate the equivalent height (H) of the support to have a restoring force against the bending or torsion of the girder by the set negative reaction force control load, and when the girder is installed, the corresponding negative reaction force support is determined. It relates to a side reaction force control and dropping prevention steel box girder bridge, characterized in that it is installed downward by H and jack-up the negative reaction force support installed downward by H after completion of the bridge, and by installing a negative reaction force control device at an abutment or pier point, When the difference between the branches in the continuous girder is large or the radius of curvature in the curved girder is small, it is possible to easily introduce a sub-reaction control load corresponding to the sub-reaction force generated at the abutment or pier point. By installing the bracket to prevent the falling bridge under the girder to be installed, even if the girder is separated from the abutment device due to an earthquake or external force, it is possible to provide an effect of preventing the girder from falling and collapsing to the lower side of the bridge or pier.

Description

{Up-lift control and Anti-fall prevention steel box girder bridge}

The present invention relates to a steel box girder bridge for controlling side reaction force and preventing falling bridge, and in detail, to a technology for introducing a negative reaction force control load to control the side reaction force generated at the alternation of the girder or at the pier point and preventing the girder from falling. About.

In general, a girder bridge is constructed by placing a girder between the pier and the bridge or between the abutment and the pier, and then pouring concrete on the top of the girder to form a top plate.

In the case of the above-described girder bridge, if the difference in ratio between any arbitrary span between the pier and the adjacent span is large, or the radius of curvature is small in the curved girder, a side reaction force occurs at the abutment or pier point, or in case of an earthquake, the girder There is a problem that can be defeated.

In such a girder bridge, a structure to control the side reaction force is applied by installing a bridge support in the abutment or by synthesizing the concrete filled in a certain section with a counter weight inside the girder to control the side reaction force. Concrete bulkheads are installed on both sides of the abutment to prevent falling bridges in the event of an earthquake.

In this case, the bridge support of the built-in structure is not good looking, and the abutment must be extended, and the negative reaction force generated from the curved bridge cannot be completely controlled only by the load loading caused by the composite of filled concrete inside the box girder. Falling prevention structure by the installation of bulkheads can prevent falling bridges in the direction of the bridge axis, but not only acts as a factor that hinders the aesthetics of the bridge, but also has a problem in that it does not prevent falling bridges in the bridge axis direction of the girders.

Accordingly, there is a need to develop a technology capable of easily introducing a sub-reaction control load at an alternating or pier point portion of a girder bridge and preventing falling bridges in both the bridge axis direction and the bridge axis direction.

Patent 1: Korean Patent Registration No. 10-0629250

In order to solve the above problem, the present invention is to install a sub-reaction force control device at an alternating or pier point, so that when the difference between the branches in the continuous girder is large or the radius of curvature in the curved girder is small, the alternate or pier point portion It is intended to provide a steel box girder bridge that can easily introduce a negative reaction force control load that responds to the negative reaction force generated in the system and prevents falling bridges.

In addition, by installing a fall prevention bracket on the lower side of the girder installed on the upper side of the bridge or pier, the side reaction force control and dropping prevention steel box girder bridge that can prevent the girder from falling down and collapse due to earthquake or external force are provided. I want to.

The secondary reaction force control and fall prevention steel box girder bridge according to an example of the present invention is formed of a girder including a lower flange and a pair of abdomens coupled to both sides of the lower flange, and the difference between the branches in the continuous girder is large or When the radius of curvature is small in the curved girder, the height of the supporting part of the equivalent height (H) to set the negative reaction force control load generated at the abutment or pier point, and to have a restoring force against the bending or torsion of the girder by the set negative reaction force control load. ) Is calculated, and when the girder is installed, the corresponding negative reaction force support is installed downward by H, and the negative reaction force support installed downward after completion of the bridge is jacked up by H.

In addition, it is provided in the abutment or pier and includes a negative reaction force control device for controlling the negative reaction force control load, wherein the negative reaction force control device is a fixing reinforcing plate buried in the abutment or pier; A fixing bracket provided on the girder; And it may be characterized in that it comprises a PS steel material connecting the fixing reinforcing plate and the fixing bracket.

In addition, the fixing reinforcing plate is a plate shape installed in a horizontal direction, and anchor bolts are installed in the vertical direction, and the PS steel material may be coupled through the fixing reinforcing plate.

In addition, the fixing reinforcing plate is a plate shape installed in the horizontal direction, and anchor bolts are installed in the vertical direction, and one side protrudes outward from the side of the pier or the abutment, and the PS steel material has a portion protruding outward from the side of the fixing reinforcing plate. It may be characterized by being coupled through.

In addition, the fixing bracket includes a U-shaped base plate installed on the lower flange of the girder; Left and right support plates that are inside the base plate and are coupled to the left and right flanges in a right angle direction; A pair of front and rear support plates coupled in a right angle direction while being inside the left and right support plates; It is characterized in that it comprises a reinforcing plate that is coupled in a horizontal direction between the pair of front and rear support plates and has a long hole having a long length in the throttling direction, and the PS steel is coupled by passing through the long hole of the reinforcing plate upwardly. I can.

In addition, the upper side of the reinforcing plate and further comprising a second reinforcing plate coupled in a horizontal direction between the pair of front and rear support plates and having a long hole having a long length in the throttling direction, wherein the PS steel material is of the second reinforcing plate. It may be characterized in that it is coupled by passing through the long hole upward.

In addition, it may include filled concrete that is filled into the inside of the girder in order to control the side reaction force acting on the girder, and the filled concrete is synthesized from the abutment device of the girder to a certain section toward the center of the branch. .

In addition, a fall prevention bracket is provided on an abutment or pier to prevent the girder from falling, and the fall prevention bracket is coupled to a lower side of the lower flange and supported by the abutment device of the girder.

In addition, the fall prevention bracket may be characterized in that it is supported by the thrusting device of the girder in a throttle direction and a direction perpendicular to the thrust shaft.

In addition, the fall prevention bracket may be characterized in that at least one.

Through the present invention, by installing a sub-reaction force control device at the abutment or pier point, when the difference between the spans in the continuous girder is large or the radius of curvature in the curved girder is small, it responds to the sub-reaction force generated at the alternate or pier point. It is possible to provide an effect that can easily introduce a negative reaction force control load.

In addition, by installing a fall prevention bracket on the lower side of the girder installed on the upper side of the bridge or pier, it is possible to provide an effect of preventing the girder from falling and collapsing under the abutment or bridge due to earthquake or external force. have.

1A to 1D are diagrams showing an embodiment of setting a negative reaction force control load by a bending or torsional restoring force according to an exemplary embodiment of the present invention.
1E to 1H are diagrams showing still another embodiment of setting a negative reaction force control load by a bending or torsional restoring force.
2A is a front view showing a state in which a sub-reaction control device is installed on a single box bridge.
2B is a cross-sectional view showing a cross-sectional view taken along AA in FIG. 2A.
2C is a cross-sectional view showing a state in which a negative reaction force control device, which is another embodiment, is installed.
2D is a front view showing a state in which the auxiliary reaction force control devices are respectively installed on the double box bridge.
2E is a three-dimensional view of FIG. 2A.
2F is a three-dimensional view of FIG. 2D.
3A is a three-dimensional view showing in detail the negative reaction force control device.
3B is a detailed view of a reinforcement plate of the negative reaction force control device.
3C is a detailed view showing a change in the amount of expansion and contraction in a long hole formed in the reinforcing plate.
4A is a front view showing a state in which a negative reaction force control device and a fall prevention bracket are installed.
4B is a cross-sectional view showing a cross-section AA of FIG. 4A.
4C is a front view showing a state in which a secondary reaction force control device and a fall prevention bracket are installed on a double box bridge.
4D is a three-dimensional view of FIG. 4A.
4E is a three-dimensional view of FIG. 4C.
Figure 4f is a three-dimensional view showing a state in which a bi-directional fall prevention bracket installed in both the bridge axis direction and the right angle direction of the bridge axis is installed on a single box bridge.
Figure 4g is a three-dimensional view showing a state in which a bi-directional fall prevention bracket installed in both the bridge axis direction and the right angle direction of the bridge axis is installed on the double box bridge.

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

In addition, in describing the constituent elements of an embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only used to distinguish the component from other components, and the nature, order, or order of the component is not limited by the term. When a component is described as being "connected", "coupled" or "connected" to another component, that component may be directly connected or connected to that other component, but another component between each component May be “connected”, “coupled” or “connected”.

With reference to FIGS. 1 to 4, a steel box girder bridge for controlling side reaction force and preventing falling bridges according to an example of the present invention will be described in detail.

1 to 4, formed of a girder 10 including a lower flange according to an example of the present invention and a pair of abdomens coupled to both sides of the lower flange, in the continuous girder 10 When the difference is large or the radius of curvature is small in the curved girder 10, a negative reaction force control load generated at the abutment or pier point is set, and a restoring force against the bending or torsion of the girder 10 by the set negative reaction force control load It is possible to calculate the height (H) of the equivalent support to have an equivalent height (H), install the corresponding negative reaction force downward by H when the girder 10 is installed, and jack up the negative reaction force support installed downward by H after completion of the bridge.

The present invention can be applied to control the negative reaction force when the difference between the branches is large in the continuous girder 10 or the radius of curvature is small in the curved girder 10 and the negative reaction force acts.

In this embodiment, the girder 10 may be a steel box girder 10 including a lower flange and a pair of abdomens coupled to both sides of the lower flange.

In this embodiment, when the difference between one span of the continuous girder 10 and the span adjacent thereto is large, or the radius of curvature in the curved girder 10 is small, alternate or alternate to control the side reaction force generated at the pier point. Alternatively, a negative reaction force control load can be set at the pier point.

1A to 1D, as a method for controlling the side reaction force in a curved girder bridge, in order to have the torsional restoring force of the girder 10 when the side reaction force control load is set, the equivalent height of the support part (H) is calculated, and the girder In the initial installation of (10), the sub-reaction support located inside the curve is installed downward by H, and after completion of the construction of the girder (10), the sub-reaction support installed downward is jacked up again by H with a hydraulic jack and restored. As the torsional restoring force of the girder 10 acts, the secondary reaction force bearing is raised by the acting torsional restoring force to be converted into a regular reaction force bearing. Accordingly, the negative reaction force control load is set to control the negative reaction force. In the above description, the inner side refers to the direction of the center of the curve in the curved girder bridge.

1E to 1H, as a method for controlling the side reaction force in a girder bridge with a different length of the span, the equivalent height of the support part (H) is set to have the bending restoring force of the girder 10 when the negative reaction force control load is set. Calculation, and during the initial installation of the girder 10, install the negative reaction force support located at the end of the long span downward by H, and jack-up the negative reaction force support installed downward by H after completion of the construction of the girder 10 again with a hydraulic jack. When it is restored and constructed, the flexural restoring force of the girder 10 acts so that the negative reaction force support is raised by the acting flexural restoring force and can be converted into a regular reaction force support. Accordingly, the negative reaction force control load is set to control the negative reaction force.

In addition, referring to Figures 1a to 1h, it is a method for controlling the side reaction force in a girder bridge that is curved and has a different length between the spans, and is equivalent in order to have the bending and torsional restoring force of the girder 10 when the negative reaction force control load is set. Calculate the height (H) of the support part of the girder (10), and at the initial mounting of the girder (10), the negative reaction force support located inside the curve and the negative reaction force support located at the end of the long span are installed downward by H, and the girder (10) ) After the construction is completed, the downwardly installed sub-reaction support is again jacked up by H with a hydraulic jack and restored, the bending and torsional resilience of the girder (10) acts, and the sub-reaction support is raised by the torsion resilience that acts as a positive reaction support. Can be converted. Accordingly, the negative reaction force control load is set to control the negative reaction force.

2 to 3, a negative reaction force control device 20 may be installed in an alternate or pier. The negative reaction force control device 20 may be installed on the rear or front surface of the bridge support.

In addition, the negative reaction force control device 20 is installed over the alternating or pier point portion and the girder 10, it is possible to control the negative reaction force control load set in the alternating or pier.

The negative reaction force control device 20 includes a fixing reinforcing plate 21 buried in an alternating or piercing, a fixing bracket 23 provided in the girder 10, and a PS connecting the fixing reinforcing plate 21 and the fixing bracket 23 It may include a steel material (25).

PS steel 25 may be composed of a steel bar or steel wire.

The fixing reinforcing plate 21 has a plate shape installed in a horizontal direction, and anchor bolts may be installed in the vertical direction. A through hole is formed in the central portion of the fixing reinforcing plate 21 so that the lower end of the PS steel 25 can be penetrated and coupled. That is, the fixing reinforcing plate 21 may be installed by being buried in an abutment or inside a pier, and anchor bolts may be installed in the vertical direction to reinforce the supporting force.

The fixing reinforcing plate 21 may be coupled to the lower end of the PS steel 25 through the central portion and connected to the fixing bracket 23 to be described later.

The PS steel 25 may be coupled with the fixing reinforcing plate 21 by fastening a nut at the end.

The fixing bracket 23 is a U-shaped base plate 231 installed on the girder 10, left and right support plates 233 which are inside the base plate 231 and are coupled in a right angle direction to the left and right flanges, and left and right support plates 233 ) A pair of front and rear support plates 235 coupled in a right angle direction and a reinforcement plate 237 coupled in the horizontal direction between the pair of front and rear support plates 235 and having a long hole in the axle direction It may include.

The U-shaped base plate 231 may be formed including a bottom plate and a pair of left and right flanges. The bottom plate may be welded or bolted to the upper side of the lower flange. A through hole through which the PS steel 25 can pass may be formed in the center of the bottom plate. The bottom plate may be a lower flange of the girder 10.

The left and right support plates 233 may be coupled to the upper side of the bottom plate and between the left and right flanges by welding or the like. The left and right support plates 233 may be coupled to the left and right flanges in a right angle direction and may be formed to incline upward toward the center.

Inside the left and right support plates 233, the front and rear support plates 235 may be coupled in a right angle direction.

A reinforcing plate 237 may be coupled in a horizontal direction between the pair of front and rear support plates 235.

The reinforcing plate 237 may be formed with a long hole having a length in the throttling direction. The PS steel 25 may be installed by penetrating the long hole of the reinforcing plate 237 upward and then fastening the nut to be coupled. Accordingly, as the reinforcing plate 237 having a long hole is coupled, the negative reaction force control device 20 can accommodate the movement displacement of the PS steel 25 due to the contraction and elongation of the girder 10. In addition, the long hole can facilitate the coupling of the PS steel (25).

The second reinforcing plate 239 may be coupled in the horizontal direction between the upper side of the reinforcing plate 237 and between the pair of front and rear support plates 235. The second reinforcing plate 239 may have a long hole having a long length in the throttling direction like the reinforcing plate 237.

The upper end of the PS steel 25 may be installed by penetrating the long hole of the second reinforcing plate 239 upward and then fastening a nut to be coupled. By the reinforcing plate 237 and the second reinforcing plate 239, the PS steel material 25 and the fixing bracket 23 may be more firmly coupled.

The U-shaped base plate 231, the left and right support plates 233, the front and rear support plates 235, the reinforcing plate 237, and the second reinforcing plate 239 may all be made of a steel plate.

By configuring the sub-reaction control device 20 through the above-described configurations, it is possible to prevent the girder 10 from being raised by the sub-reaction force generated at the alternate or pier point.

In addition, referring to 2c, the secondary reaction force control device 20 is a plate shape installed in the horizontal direction of the fixing reinforcing plate 21, and anchor bolts are installed in the vertical direction to be buried in a pier or an abutment, and one side is an alternate or pier. It protrudes outward from the side of the PS steel material 25 may be coupled by passing through a portion protruding outward from the side of the fixing reinforcing plate 21. That is, the other side of the fixing reinforcing plate 21 is installed by being buried in the abutment or the inside of the pier, and one side may be installed to protrude to the outside of the pier or the side of the bridge, and the PS steel material 25 is the fixing reinforcing plate 21 It can be coupled through the protruding portion of the fixing bracket 23.

Another embodiment of the side reaction force control according to an example of the present invention may include a filled concrete 30 filled in the inside of the girder 10. The filled concrete 30 may be synthesized from the seating device of the girder 10 to a certain section toward the central part of the span.

By filling the filled concrete 30 into the inside of the girder 10, the self-weight of the steel girder 10 at the abutment or pier point portion is increased so that it is applied as a count weight and the load is applied, thereby alternating or pier point It is possible to suppress the side reaction force generated in the minor part.

As described above, the negative reaction force control method is by adjusting the height of the bridge support of the steel box girder 10, installing the negative reaction force control device 20, or filling the filled concrete 30 inside the girder 10, It can be carried out, and by mixing the above method according to the magnitude of the negative reaction force, it is possible to easily suppress the negative reaction force in the girder 10.

4, the secondary reaction force control and fall prevention steel box girder bridge according to an example of the present invention may include a fall prevention bracket 40 that is provided on an alternating or bridge pier to prevent fall of the girder 10.

The fall prevention bracket 40 may be coupled to the lower side of the lower flange of the girder 10 and may be installed to be supported by the abutment device of the girder 10.

The fall prevention bracket 40 may be supported by the thrusting device of the girder 10 in the throttling direction or may be supported in a direction perpendicular to the throttling. In addition, the fall prevention bracket 40 may be installed to be supported simultaneously in a throttling direction and a right angle direction of the throttling axis to the thrusting device.

Falling prevention bracket 40 may be installed in one or more under the negative reaction force control device (20). That is, the fall prevention bracket 40 may be composed of a pair of left and right as a pair of one or two sets on the lower side of the girder 10.

The fall prevention bracket 40 is a configuration capable of supporting the girder 10 from the lower side of the girder 10, and prevents the girder 10 from being separated from the abutment device by an earthquake load or an external force and falling downward, Collapse of the girder 10 can be prevented.

The fall prevention bracket 40 may include an upper member 41 coupled to a lower portion of the girder 10 and a lower member 42 coupled to a bridge or abutment. The lower member 42 may have a rectangular shape or a b shape. The b-shape can be used when supported in the direction of the bridge axis and the direction at right angles to the bridge axis. The upper member 41 is a portion extending upward from the lower member 42 and coupled to the lower flange of the girder 10 by welding or the like. The upper member 41 may gradually increase in width toward the upper side. This increases the coupling force with the lower flange and at the same time increases the rigidity of the fall prevention bracket 40 itself so that it can withstand large earthquake loads.

In the above, even if all the constituent elements constituting an embodiment of the present invention are described as being combined into one or operating in combination, the present invention is not necessarily limited to these embodiments. That is, within the scope of the object of the present invention, all the constituent elements may be configured or operated by selectively combining one or more. In addition, terms such as "include", "consist of" or "have" described above mean that the corresponding component may be present unless otherwise stated, excluding other components Rather, it should be interpreted as being able to further include other components. All terms, including technical or scientific terms, have the same meaning as commonly understood by a person of ordinary skill in the art, unless otherwise defined. Terms generally used, such as terms defined in the dictionary, should be interpreted as being consistent with the meaning of the context of the related technology, and are not interpreted as ideal or excessively formal meanings unless explicitly defined in the present invention.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

10: girder
20: negative reaction force control device
21: fixing reinforcing plate
23: fixing bracket
231: base plate
233: left and right support plates
235: front and rear brace
237: reinforcement plate
239: second reinforcing plate
25: PS steel
30: filled concrete
40: Fall prevention bracket
41: upper member
43: lower member

Claims (10)

Formed by a girder including a lower flange and a pair of abdomens coupled to both sides of the lower flange, when the difference between the spans in a continuous girder is large or the radius of curvature in a curved girder is small, Set the negative reaction force control load,
It is provided on the alternating or pier and includes a negative reaction force control device for controlling the negative reaction force control load,
The auxiliary reaction force control device may include a fixing reinforcing plate buried in the abutment or pier; A fixing bracket provided on the girder; And a PS steel material connecting the fixing reinforcing plate and the fixing bracket,
The fixing bracket includes a U-shaped base plate installed on the lower flange of the girder; Left and right support plates that are inside the base plate and are coupled to the left and right flanges in a right angle direction; A pair of front and rear support plates coupled in a right angle direction while being inside the left and right support plates; It includes a reinforcing plate coupled in a horizontal direction between the pair of front and rear support plates and having a long hole having a long length in the axle direction
The PS steel is coupled by passing through the long hole of the reinforcing plate upwardly. delete The method according to claim 1,
The fixing reinforcing plate is a plate shape installed in a horizontal direction, and anchor bolts are installed in the vertical direction, and the PS steel is coupled through the fixing reinforcing plate. The method according to claim 1,
The fixing reinforcing plate has a plate shape installed in the horizontal direction, and anchor bolts are installed in the vertical direction, and one side protrudes outward from the side of the pier or the abutment, and the PS steel has a portion protruding outward from the side of the fixing reinforcing plate. A steel box girder bridge for controlling side reaction force and preventing falling bridge, characterized in that it is coupled through through. delete The method according to claim 1,
Further comprising a second reinforcing plate that is an upper side of the reinforcing plate and is coupled in a horizontal direction between the pair of front and rear support plates, and has a long hole having a long length in the axle direction,
The PS steel is coupled by passing through the long hole of the second reinforcing plate upwardly. The method according to claim 1,
Containing filled concrete that is filled into the inside of the girder to control a side reaction force acting on the girder,
The filled concrete is a steel box girder bridge for controlling side reaction force and preventing falling bridge, characterized in that it is synthesized from the abutment device of the girder to a certain section toward the center of the branch. The method according to claim 1,
Includes a fall prevention bracket provided on the abutment or pier to prevent fall of the girder,
The fall prevention bracket is coupled to a lower side of the lower flange and is supported by an abutting device of the girder. The method of claim 8,
The fall prevention bracket is a side reaction force control and fall prevention steel box girder bridge, characterized in that supported by the thrusting device of the girder in a direction perpendicular to the thrust shaft. The method of claim 8,
The secondary reaction force control and fall prevention steel box girder bridge, characterized in that at least one fall prevention bracket.

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