KR20190105489A - Bridge bearing appratus - Google Patents

Abstract

The present invention relates to a bridge bearing device. The bridge bearing device includes: an upper plate (200) connected to the lower part of an upper structure; a lower plate (100) including an anchor socket (110) to be embedded in the vertical direction and connected to the upper part of a pier (30); an elastic pad unit (300) connected between the upper plate (200) and the lower plate (100) and absorbing shock applied to an upper structure (20); and an anchor bolt unit (400) connecting the elastic pad unit (300) to be detached from the lower plate (100). The anchor bolt unit (400) includes: a shear reinforcing member (410) connected to the inside of the anchor socket (110) by a screw; and an anchor bolt (420) connected to the inside of the shear reinforcing member (410) by the screw. A screw connection direction of the anchor bolt (420) and the shear reinforcing member (410) is opposite to the screw connection direction of the anchor socket (110) and the shear reinforcing member (410). The anchor bolt (420) protrudes as much as a predetermined length to the lower part of the shear reinforcing member (410). A lower end of the anchor bolt (420) protruding to the lower part of the shear reinforcing member (410) is connected to the lower part of the anchor socket (110) by the screw in the same direction as the screw connection direction of the shear reinforcing member (410) and the anchor bolt (420).

Description

Bridge device for bridges {BRIDGE BEARING APPRATUS}

The present invention relates to a bridge bridge device, and more particularly to a bridge bridge bridge device that can be maintained in a stable coupling state between the lower plate and the bridge device is detachably coupled.

In general, the bridge is to be constructed across the elevated road or river, etc., the upper slab is installed on the top of the bridge piling civil engineering to have a constant interval through the bridge device.

The bridge is a structure in which fixed load, live load, earthquake load, wind load, and elastic stress act on the upper slab, which is the upper structure, and its shock and vibration are transmitted to the lower part through the bridge device. Therefore, it is important to maintain a stable connection between the bridge device and the bridge after installation.

On the other hand, as the bridge passes after a long time after installation, cracks or breakages occur in upper slabs, bridge devices, etc. due to natural aging or artificial factors. In this case, after the upper slab is raised, the bridge device is separated from the piers and maintained.

Accordingly, the chair apparatus can be detachably coupled from the bridge, and the restraining force in the engaged state needs to be stably maintained. However, the coupling bolt for coupling the lower plate and the bridge of the bridge device is released by the impact or vibration generated by the driving of the vehicle, the problem arises that the bridge device can not be unloaded.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above-described problem, and to provide a chair apparatus in which a loosening is prevented from external shocks and vibrations so that a stable coupling state can be maintained.

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention by those skilled in the art.

An object of the present invention is a bridge device for a bridge disposed between the bridge and the upper structure of the bridge, the bridge bridge device is provided between the lower plate coupled to the bridge, the upper plate coupled to the upper structure, and the lower plate and the upper plate It includes an elastic pad portion and the anchor bolt portion 400 to absorb the shock, the anchor bolt portion 400, the shear reinforcing material 410 is screwed into the anchor socket 110 of the lower plate 100; And anchor bolts 420 screwed into the interior of the shear stiffener 410, including anchor bolts 420 screwed into the interior of the shear stiffener 410, and the anchor bolt 420. The screw coupling direction of the shear stiffener 410 is formed opposite to the screw coupling direction of the anchor socket 110 and the shear stiffener 410, the anchor bolt 420 is fixed to the lower portion of the shear stiffener 410 The length of the anchor bolt 420 and the lower end of the anchor bolt 420 protruding downward of the shear reinforcing material 410, the anchor bolt 420 and the shear reinforcing material 410 screwing direction Screwed in the same direction as the, the shear reinforcement 410 is provided on the reinforcement shaft 413 and the reinforcement shaft 413 inserted into the anchor socket 110, the upper portion of the lower plate 100 Reinforcement head 411 is disposed in the, the anchor bolt 420 is A bolt shaft 423 inserted into the steel shaft 413 and a bolt head 421 provided on an upper portion of the bolt shaft 423 to be mounted on the reinforcement head 411. 411 is located at the top of the hexagonal plate (411a) consisting of a hexagonal shape, and formed integrally from the lower portion of the hexagonal plate (411a) is mounted on the upper surface of the lower plate 100 and a thread is formed on the outer wall surface, And a cap coupling member 411b formed in a circular shape circumscribed to the hexagonal plate 411a, and having a receiving space accommodating the reinforcement head 411 and the bolt head 421 therein, It characterized in that it further comprises a first cap 430 is formed threaded to be screwed in the same direction as the bolt shaft 423 for coupling with the cap coupling member (411b).

According to one embodiment, the first projection (416) protruding from each side of the hexagonal plate (411a) of the stiffener head 411 and positioned on the cap coupling member (411b); And a second protrusion 436 in the receiving space of the first cap, wherein the lower portion of the second protrusion 436 is shifted so that the lower side of the second protrusion 436 is in contact with the upper side of the first protrusion 416 when screwed together. It is characterized by maintaining the contact state.

According to one embodiment, the elastic pad unit 300, a plurality of elastic pads (310,320) laminated and patched up and down; It is disposed above and below the plurality of elastic pads (310, 320) is coupled to the upper plate 200 and the lower plate 100, and includes a pair of external reinforcing steel plate (330, 340) is introduced, the pair of external reinforcement Iron plate (330, 340) and the upper plate 200 and the lower plate 100 is characterized in that they are tightly coupled by the high-tensile bolts (130, 230), respectively.

In the chair according to the present invention, the shear reinforcing material and the anchor bolt are coupled to each other between the lower plate and the anchor socket opposite to each other in the screw coupling direction. Accordingly, since the screw coupling is opposite to each other, even if the external force acts in either the clockwise or counterclockwise direction, the coupling binding force can be maintained without loosening the screw coupling.

As a result, since the stabilizing device is stably maintained between the upper plate and the lower plate, the elastic pad absorbs the shock and vibration acting through the upper structure, thereby enabling a stable use for a long time.

In addition, the teaching apparatus according to the present invention can further improve the coupling restraint force by adding a cap to prevent rotation of the reinforcement head and the bolt head.

In addition, due to the shape of the tannery bolt extending to the top plate can physically limit the height of the tannery bolt can be rotated to improve the binding binding force.

1 is an exemplary view showing a cross-sectional configuration of a bridge to which a bridge device according to a preferred embodiment of the present invention is applied;
Figure 2 is a cross-sectional view showing a cross-sectional configuration of the anchor bolt portion according to a preferred embodiment of the teaching device of the present invention,
Figure 3 is an exploded perspective view showing an exploded configuration of the anchor bolt portion according to a preferred embodiment of the teaching apparatus of the present invention,
4 is an exemplary view showing a coupling process of the elastic pad of the chair device according to the present invention;
5 and 6 are a cross-sectional view and an exploded perspective view showing the configuration of the anchor bolt portion according to the second embodiment of the teaching device of the present invention,
7 is a view showing an anchor bolt portion according to a third embodiment of the chair apparatus of the present invention;
8 is a cross-sectional view showing the configuration of the anchor bolt portion according to the fourth embodiment of the chair apparatus of the present invention.
9 is a view showing an anchor bolt portion according to a fifth embodiment of the teaching apparatus of the present invention;
10 is a view showing an anchor bolt portion according to a sixth embodiment of the teaching apparatus of the present invention;
11 is a cross-sectional view showing a modification of the teaching device of the present invention.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Embodiment of the present invention may be modified in various forms, the scope of the invention should not be construed as limited to the embodiments described in detail below. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shape of the elements in the drawings and the like may be exaggerated to emphasize a more clear description. It should be noted that the same members in each drawing are sometimes shown with the same reference numerals. Detailed descriptions of well-known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention are omitted.

1 is a schematic view showing a bridge 1 to which the bridge device 10 is applied according to a preferred embodiment of the present invention, Figure 2 is a cross-sectional view showing the configuration of the anchor bolt portion 400 according to a preferred embodiment, 3 is an exploded perspective view showing an exploded configuration of the chair apparatus 10.

As shown in FIG. 1, the bridge 1 includes an upper structure 20 such as a slab, a bridge 30 disposed at regular intervals, and a bridge device disposed between the upper structure 20 and the bridge 30. 10).

The device 10 is disposed between the upper structure 20 and the pier 30 to cushion the shock and vibration acting on the upper structure (20). The device 10 is provided between the lower plate 100 coupled to the pier 30, the upper plate 200 coupled to the upper structure 20, and the lower plate 100 and the upper plate 200 to absorb shocks. It includes an elastic pad portion 300, the anchor bolt portion 400 for detachably coupling the lower plate 100 to the piers 30.

The lower plate 100 and the upper plate 200 support the elastic pads 310 and 320 accommodated therein. The lower plate 100 supports the anchor bolt portion 400 so that the elastic pads 310 and 320 can be stably coupled to the piers 30. The upper plate 200 is coupled to the elastic pad 300 to allow the vibration and shock of the upper structure 20 to be transmitted to the elastic pad 300.

Here, the anchor socket 110 is coupled between the lower plate 100 and the piers 30 to be embedded. The anchor socket 110 supports the anchor bolt portion 400 to be detachably coupled. Anchor socket 110 is a reinforcement shaft insertion hole 111 is inserted into the reinforcement shaft 413 of the shear stiffener 410, and the bolt shaft 423 of the anchor bolt 420 is inserted as shown in FIG. The bolt shaft insertion hole 115 is formed stepped.

The reinforcement shaft insertion hole 111 is formed to correspond to the diameter of the reinforcement shaft 413, the first screw thread 113 is formed on the lower inner wall surface. The bolt shaft insertion hole 115 is formed at a lower portion of the reinforcement shaft insertion hole 111 to correspond to the diameter of the bolt shaft 423. Since the diameter of the bolt shaft 423 is smaller than the reinforcement shaft 413, a step is formed in the boundary region between the bolt shaft insertion hole 115 and the reinforcement shaft insertion hole 111.

The second screw thread 117 is formed on the inner wall surface of the bolt shaft insertion hole 115. Here, the first screw thread 113 and the second screw thread 117 are formed in opposite directions to each other. For example, when the first screw thread 113 is formed clockwise, the second screw thread 117 is formed counterclockwise.

The elastic pad part 300 absorbs the shock transmitted through the upper structure 20 to attenuate the shock and vibration transmitted to the bridge 1. The elastic pad part 300 includes a plurality of elastic pads 310 and 320 and a pair of external reinforcing steel plates 330 and 340 provided with the elastic pads 310 and 320 above and below.

4 is an exemplary view illustrating a coupling process of the elastic pad unit 300, the upper plate 200, and the lower plate 100.

Here, the pair of external reinforcing plate 330, 340 is pre-stress is introduced is formed to be bent at a certain curvature toward the inside.

As shown in FIG. 4A, the upper plate 200 is coupled to the upper external reinforcing plate 330, and the lower plate 100 is coupled to the lower reinforcing plate 340. In this case, a plurality of bolt holes 120 and 220 are formed in the pair of external reinforcing steel plates 330 and 340.

As shown in (b) of FIG. 4, the upper plate 200 and the lower plate 100 are disposed in contact with the pair of external reinforcing steel plates 330 and 340, and the high tension bolts 130 and 230 are coupled to the bolt holes 120 and 220. . As shown in (c) of FIG. 4, when the pair of the outer reinforcing steel plates 330 and 340 and the upper plate 200 and the lower plate 100 are completed, the pair of horizontal reinforcing steel plates 330 and 340 which are horizontally stretched is initially displayed. Force is applied to bend to the state. As a result, the force in the inclined direction is applied to the high tension bolts 130 and 230, thereby preventing the high tension bolts 130 and 230 from being released by an external force. As a result, the coupling force of the elastic pad part 300 and the upper plate 200 and the lower plate 100 may be stably maintained.

Anchor bolt portion 400 is detachably coupled to the anchor socket 110 embedded in the lower plate 100, so that even if the external force or impact is applied for a long time, it is possible to remain stable without being released.

Anchor bolt portion 400 according to a preferred embodiment of the present invention is a shear stiffener 410 is screwed to the anchor socket 110 through the lower plate 100, and the anchor socket 110 through the shear stiffener 410 Anchor bolt 420 is screwed. Here, the shear reinforcing material 410 and the anchor bolt 420 are respectively formed in the opposite direction to be screwed to prevent loosening.

The shear reinforcement 410 is a reinforcement shaft 413 inserted into the reinforcement shaft insertion hole 111 of the anchor socket 110, and the reinforcement head 411 is coupled to the upper portion of the reinforcement shaft 413 is mounted on the lower plate 100 And a bolt insertion hole 415 formed through the reinforcing material head 411 and the reinforcing material shaft 413.

The reinforcement head 411 is formed in a circular or hexagonal cross section, is formed to have a larger area than the reinforcement shaft insertion hole 111 is mounted on the upper surface of the lower plate (100).

The lower outer periphery of the reinforcement shaft 413 is formed with a fourth screw thread 417 that is screwed with the first screw thread 113 of the reinforcement shaft insertion hole 111. In addition, a third screw thread 415a which is screwed with the bolt shaft 423 of the anchor bolt 420 is formed at a lower portion of the inner wall surface of the bolt insertion hole 415.

Here, the fourth screw thread 417 and the third screw thread 415a are formed in opposite directions.

The anchor bolt portion 400 is provided with a bolt shaft 423 inserted into the bolt insertion hole 415 of the shear reinforcing material 410 and the upper portion of the bolt shaft 423 is mounted on the upper surface of the reinforcement head 411 The bolt head 421 and the fifth screw thread 425 formed on the lower outer periphery of the bolt shaft 423.

The bolt head 421 is formed in a hexagonal shape and is formed in a larger area than the bolt insertion hole 415 and is mounted on the upper surface of the reinforcing head 411.

The bolt shaft 423 is formed longer than the reinforcing shaft 413. As shown in FIG. 2, the lower portion of the bolt shaft 423 is exposed to the lower portion of the reinforcement shaft 413 to be inserted into the bolt shaft insertion hole 115 of the anchor socket 110.

That is, the reinforcement shaft 413 is inserted through the bolt insertion hole 415, the lower end is inserted into the bolt shaft insertion hole 115 of the anchor socket 110. At this time, a fifth screw thread 425 is formed below the reinforcing shaft 413. The fifth screw thread 425 is screwed to the third screw thread 415a of the bolt insertion hole 415 and the second screw thread 117 of the bolt shaft insertion hole 115.

As described above, the third thread 415a formed in the reinforcement shaft 413 of the shear reinforcement 410 and the fifth thread 425 formed in the bolt shaft 423 of the anchor bolt 420 are formed in opposite directions. .

Thereby, when the external force is applied in either direction, the relative position is constrained by the threads formed in the opposite direction to prevent loosening.

For example, when the third thread 415a is formed in the clockwise direction and the fifth thread 425 is formed in the counterclockwise direction, the shear reinforcing material 410 is screwed and counterclockwise when a force is applied in the clockwise direction. A force must be applied to loosen the screw.

On the contrary, the fifth screw thread 425 is screwed when a force is applied in a counterclockwise direction and a screw is released when a force is applied in a clockwise direction. Furthermore, the lower portion of the anchor bolt 420 is coupled to the anchor socket 110 as well as the shear reinforcement 410.

The worker first rotates the shear reinforcement 410 clockwise to couple to the anchor socket 110. In addition, the anchor socket 110 is fixed to the anchor socket 110 in a fixed position, and the anchor bolt 420 is rotated counterclockwise into the shear reinforcement 410 to be coupled.

When the force is applied in the clockwise direction by the external impact in the state in which the coupling is completed, the anchor bolt 420 is rotated and the screw coupling is to be released. However, the shear reinforcement 410 is screwed more securely when the force is applied in the clockwise direction so that the anchor bolt 420 screwed inside the shear reinforcement 410 is not released.

As long as the operator does not exert a force in a state in which the operator is physically fixed by the screw coupling in different directions, the coupling restraint force of the anchor bolt portion 400 can be stably maintained without being released.

5 and 6 are a cross-sectional view and an exploded perspective view showing the configuration of the anchor bolt portion 400a according to the second embodiment of the present invention. The anchor bolt portion 400a according to the second embodiment may further improve the coupling restraint force by adding a configuration of the first cap 430 as compared to the anchor bolt portion 400 of the above-described preferred embodiment.

The anchor bolt portion 400a according to the second embodiment is provided with a cap coupling member 411b between the hexagonal plate 411a and the reinforcement shaft 413 of the reinforcement head 411 of the shear reinforcement 410a. As shown in the, the reinforcing material head 411 is located at the top and formed in a hexagonal shape of the hexagonal plate 411a, the lower portion of the hexagonal plate 411a and integrally mounted on the upper surface of the lower plate 100 And a cap coupling member 411b having a circular shape circumscribed to the hexagonal plate 411a.

Then, a sixth screw thread 411c is formed on the outer wall surface of the cap coupling member 411b. The sixth thread 411c is formed in the same direction as the fifth thread 425 of the anchor bolt 420.

The first cap 430 covers the upper portion of the shear reinforcing material (410a) and the anchor bolt 420. At this time, the hemispherical inner wall surface 433 is formed inside the first cap 430. The diameter of the inner wall surface 433 is formed to correspond to the diameter of the cap coupling member (411b).

A seventh screw thread 435 corresponding to the sixth screw thread 411c is formed below the inner wall surface 433. As a result, as shown in FIG. 5, the seventh screw thread 435 of the first cap 430 is screwed to the sixth screw thread 411c of the cap coupling member 411b.

Since the first cap 430 and the anchor bolt 420 are threaded in the same direction, and the shear reinforcing material 410a is threaded in the opposite direction thereof, the first bolt 430 and the anchor bolt 420 are formed in the opposite direction. The anchor bolt portion 400 according to the second embodiment has a greater resistance to the acting rotation force, the coupling stability can be further improved.

7 is a cross-sectional view and a perspective view showing the configuration of the anchor bolt portion according to the third embodiment of the present invention. The anchor bolt portion according to the third embodiment has been added to the configuration of the second cap 440. The first cap 430 described above was a structure in which the cap coupling member 411b and the first cap 430 of the shear reinforcing material 410a are screwed to prevent loosening.

On the other hand, the anchor bolt portion according to the third embodiment is provided with anti-rotation teeth 441a, 443a to prevent the slip in the second cap 440 to prevent the rotation of the shear reinforcing material 410 and the anchor bolt 420. .

The second cap 440 is provided in the upper portion of the reinforcing head receiving wall 441 and the reinforcing head receiving wall 441 provided in contact with the outer wall surface of the reinforcing head 411, the outer wall of the bolt head 421 Bolt head receiving walls 443 in contact with the surface are respectively formed.

In the reinforcing head receiving wall 441, the first anti-rotation saw teeth 441a are continuously formed in the vertical direction, and in the bolt head receiving wall 443, the second anti-rotating teeth 443a are formed continuously in the vertical direction. The first anti-rotation teeth 441a and the second anti-rotation teeth 443a respectively support the outer wall surfaces of the smoothly formed reinforcement head 411 and the bolt head 421 so as not to rotate. As a result, compared with the case without the second cap 440, the loosening prevention function of the screw coupling can be increased.

8 is a cross-sectional view showing the configuration of the anchor bolt portion 400b according to the fourth embodiment of the present invention. As shown, the anchor bolt portion 400b is a tanned bolt 450 is inserted into the shear reinforcing material 410. At this time, the tannery bolt 450 is provided longer than the anchor bolt 420 is formed to extend to the top of the shear reinforcing material 410 as shown.

The lower portion of the tannery bolt 450 is screwed to the shear reinforcing material 410 and the anchor socket 110, the upper portion is coupled to the connection nut 460.

The wrench groove 451 is coupled to the upper surface of the tannery bolt 450 so that the operator rotates the tannery bolt 450 using a wrench (not shown) to couple to the shear reinforcement 410. Then, the connection nut 460 is coupled to the lower portion, and the anti-loosening bolt 470 coupled to the adjustment nut 480 is coupled to the tannery bolt 450.

The operator inserts the upper end of the anti-loosening bolt 470 into the bolt groove 210 and arranges the anti-loosening bolt 470 to be coaxially positioned with the tannery bolt 450, and then rotates the connection nut 460. As shown in the enlarged view, the tanned bolt 450 is coupled to the lower portion of the connection nut 460.

At this time, the height (h2) between the adjustment nut 480 and the lower end of the upper plate 200 is shorter than the length (h1) protruding to the bottom of the shear reinforcing material 410 adjustment nut 480 Adjust the position of. As a result, even though the screw coupling is loosened due to external force, vibration, or impact, the nut nut 450 moves upward in contact with the lower end of the upper plate 200, and further restricts the rise of the nutless bolt 450. It is effective.

Therefore, the binding force of the coupling state of the tannery bolt 450 and the shear reinforcement 410 may be improved.

On the other hand, Figure 9 is a cross-sectional view showing the configuration of the anchor bolt portion 400c according to the fifth embodiment of the present invention. Anchor bolt portion 400c according to the fifth embodiment shown in FIG. 9 (a) is between the anchor socket 110 and the lower plate 100 as compared with the anchor bolt portion 400 of the preferred embodiment shown in FIG. A shear reinforcing washer 490 is further disposed at the boundary region of the.

Shear reinforcement washer 490 is wrapped around the outside of the anchor socket 110 to prevent the anchor socket 110 is rotated when a shear force in the horizontal direction is applied. This prevents the rotation of the shear reinforcement 410 and the anchor bolt 420 coupled to the anchor socket 110 to prevent loosening of the screw coupling. Accordingly, the binding restraining force can be maintained stably.

Shear reinforcement washer 490 is formed in a ring shape having a predetermined area, as shown in (b) of Figure 9, has a structure in which the support tube 491 is formed to extend a predetermined length.

On the other hand, Figure 10 is an exploded perspective view showing the configuration of the anchor bolt portion 400d according to the sixth embodiment of the present invention. The anchor bolt portion 400d according to the sixth embodiment illustrated in FIG. 10 is a modification of the anchor bolt portion 400a according to the second embodiment of FIG. 6 described above, protruding from the side of the reinforcing head 411. The first protrusion 416 is formed, and the second protrusion 436 is formed to protrude on the inner wall surface of the first cap 430.

Specifically, the first protrusion 416 is protruded from each side of the hexagonal plate (411a) of the reinforcing material head 411 is located on the upper portion of the cap coupling member 411b, the second protrusion 436 is the first It may be formed in the receiving space of the cap 430.

When the first cap 430 is screwed to the cap coupling member 411b of the stiffener head 411, the first protrusion 416 and the second protrusion 436 remain spaced apart from each other, but the screwing proceeds. When the seventh screw thread 435 is completely screwed to the sixth screw thread 411c, the second protrusion 436 is positioned to contact the first protrusion 416.

At this time, the first protrusion 416 and the second protrusion 436 are not positioned coaxially up and down with each other, but are positioned in a displaced position so that the lower portion of the second protrusion 436 is positioned on the upper side of the first protrusion 416. Is placed in contact.

When the screwing is completed, it is kept in contact with each other to prevent further rotation to prevent the screwing is loosened.

11 is a cross-sectional view showing a modification of the teaching device 10 of the present invention. Under the lower plate 100 of the teaching device 10 may be provided with a fixing aid 500 as shown.

The fixing aid 500 serves to support the reinforcing bar when the reinforcing bar is placed under the lower plate 100. The fixing aid 500 is formed in a "c" shape, and the rebar is arranged on the upper side. When concrete is poured in this state, the bonding force between the reinforcing bar and the concrete can be improved.

As described above, the stabilizing device according to the present invention is coupled between the lower plate and the anchor socket so that the shear reinforcing material and the anchor bolt are opposite to each other in a double overlap. Accordingly, since the screw coupling is opposite to each other, even if the external force acts in either the clockwise or counterclockwise direction, the coupling binding force can be maintained without loosening the screw coupling.

As a result, since the stabilizing device is stably maintained between the upper plate and the lower plate, the elastic pad absorbs the shock and vibration acting through the upper structure, thereby enabling a stable use for a long time.

In addition, the teaching apparatus according to the present invention can further improve the coupling restraint force by adding a cap to prevent rotation of the reinforcement head and the bolt head.

In addition, due to the shape of the tannery bolt extending to the top plate can physically limit the height of the tannery bolt can be rotated to improve the binding binding force.

The embodiment of the bridge bridge device of the present invention described above is merely exemplary, and those skilled in the art to which the present invention pertains that various modifications and equivalent other embodiments are possible. You will know. Therefore, it will be understood that the present invention is not limited to the forms mentioned in the above detailed description. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims. It is also to be understood that the present invention includes all modifications, equivalents, and substitutes within the spirit and scope of the invention as defined by the appended claims.

411c: 6th thread 420: anchor bolt
421: bolt head 423: bolt shaft
425: fifth thread 430: first cap
431 head accommodation 433 inner wall
435: 7th thread 440: 2nd cap
441: reinforcement head receiving wall 441a: the first anti-rotation tooth
443: bolt head receiving wall 443a: second anti-rotation tooth
450: tanned bolt 451: wrench groove
460: connection nut 470: loosening bolt
480: adjusting nut 490: shear reinforcing washer
500: fixing aid

Claims (2)

In the bridge bridge device disposed between the bridge pier and the superstructure,
The bridge device for bridge includes a lower plate coupled to the pier, the upper plate coupled to the upper structure, and provided between the lower plate and the upper plate elastic pad portion and the anchor bolt portion 400 to absorb shock,
The anchor bolt portion 400,
Shear reinforcement material 410 is screwed into the anchor socket 110 of the lower plate 100;
And; anchor bolts 420 screwed into the inside of the shear reinforcement 410.
Screwing direction of the anchor bolt 420 and the shear reinforcing material 410 is formed opposite to the screwing direction of the anchor socket 110 and the shear reinforcing material 410,
The anchor bolt 420 protrudes a predetermined length to the lower portion of the shear reinforcing material 410, the lower end of the anchor bolt 420 protruding to the lower portion of the shear reinforcing material 410 in the lower portion of the anchor socket 110 Screwed in the same direction as the screwing direction of the anchor bolt 420 and the shear reinforcing material 410,
The shear reinforcing material 410 is a reinforcement shaft 413 inserted into the anchor socket 110 and the reinforcement head 411 is provided on the upper portion of the reinforcement shaft 413 is disposed on the upper plate 100 Include,
The anchor bolt 420 is formed of a tanned bolt 450 extending to protrude a predetermined length to the top of the reinforcing head 411,
A connection nut 460 on which an upper portion of the tannery bolt 450 is screwed;
The lower end is screwed to the connection nut 460, the upper end of the anti-loosening bolt 470 is inserted into the upper plate 200;
An adjusting nut coupled between the anti-loosening bolt 470 and the upper plate 200 to restrict the height of the anti-loosening bolt 470 inserted into the upper plate 200 to limit the rotation of the tannery bolt 450. 480) comprising a device.
The method of claim 1,
The elastic pad unit 300,
A plurality of elastic pads 310 and 320 laminated and patched up and down;
Is disposed above and below the plurality of elastic pads (310, 320) and coupled to the upper plate 200 and the lower plate 100 and includes a pair of external reinforcing steel plate (330, 340) is introduced,
The pair of external reinforcing steel plate (330, 340) and the upper plate 200 and the lower plate 100 is a chair device, characterized in that the close coupling by the high-tensile bolts (130, 230), respectively.

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