KR100997423B1 - Bridge lifting method and lifting apparatus with temporary bearing function - Google Patents

Abstract

PURPOSE: A bridge lifting apparatus having a bridge bearing function and a bridge lifting method using the same are provided to control displacement of a bridge by more stably absorbing the expansion and contraction of the superstructure. CONSTITUTION: A bridge lifting apparatus(100) having a bridge bearing function comprises a lower support plate(110), a sliding plate(120), and an upper support plate(130). The lower support plate comprises a lower plate(111), a lower guide block(112), a stopping block(113) and a lifting device(114). The sliding plate is attached to the bottom of a bottom block(133) with an adhesive, wherein the bottom block is installed to protrude down from the front center of the upper support plate. The upper support plate comprises an upper plate(131) and an upper support block(132).

Description

Bridge Lifting Device with Bridge Support Function and Bridge Lifting Method Using The Same [BRIDGE LIFTING METHOD AND LIFTING APPARATUS WITH TEMPORARY BEARING FUNCTION}

The present invention relates to a bridge lifting device having a bridge bearing function and a bridge lifting method using the same. More specifically, to raise or replace the bridge bearings, the bridge upper structure (girder, slab) is raised, and the bridge lifting device and bridge lifting method that have the bridge bearing function for the upper structure in such a raised state. It is about.

In general, the bridge structure is due to the nature of the bridge, such as the bridge longitudinal, transverse direction (bridge direction, perpendicular to the bridge direction) occurs due to the live load, such as frequent traffic and temperature changes of the vehicle or train.

Accordingly, as shown in FIG. 1A, the bridge support 50 is installed to support the bridge upper structure (slab) while absorbing the expansion and contraction of the bridge upper structure (slab).

The bridge support 50 is fixed to the supporting concrete 51 installed on the upper surface of the bridge substructure by the anchor 52, and the lower plate 54, the brass bearing plate (the hemispherical groove 53 is formed on the center upper surface). 55), an oilless bridge bearing including the upper plate 56, and the like can be used for various purposes.

However, since the bridge support (50, bridge device) serves as a medium for transferring the load between the upper structure of the bridge and the lower structure of the bridge, the bridge support used until the endurance as time passes, the work to repair or replace eventually It is necessary.

Therefore, in the related art, the hydraulic jack is simply installed on the upper surface of the lower structure to raise the upper structure, and the bridge support is repaired or repaired by replacing the new bridge support.

Since the work of raising the bridge upper structure should be continuously raised during the repair and replacement of the bridge bearing, the hydraulic jack should be continuously installed during the construction period.

However, the problem is that even during this period, the upper structure of the bridge is repeatedly stretched in the direction of the bridge, so even during the pulling period of the bridge upper structure, the lifting device having the function of the bridge support is required.

Thus, as shown in Figure 1b is introduced such an impression device.

The pulling device includes a bridge upper structure bonded steel plate 10 fixed to the lower surface of the bridge upper structure (G1); A displacement control bracket 20 fixedly installed under the bridge upper structure bonded steel plate 10 and having a resin plate or elastic rubber pad 27 attached to an upper surface thereof; A hydraulic jack 30 fixed to the lower portion of the displacement control bracket 20 and having a plate-shaped circular steel plate 32 attached to an upper surface of the cylinder 31 to absorb a rotational displacement; It is installed in the lower portion of the hydraulic jack 30 and at the same time is composed of a fixing bracket 40 for fixing the hydraulic jack 30, the bridge upper structure joined steel plate 10 is attached to the steel stopper 11 in one direction or in both directions. .

As a result, it can be seen that it is possible to raise the upper structure of the bridge by the hydraulic jack 30, the steel stopper 11 with the expansion and contraction of the upper structure of the bridge by the steel stopper 11, such steel stopper ( It can be seen that the movement of 11) allows the movement to be prevented by the displacement control bracket 20 so as to eventually absorb the displacement of the bridge upper structure.

Therefore, there is no need for an expensive special hydraulic jack when the bridge bearing is replaced by the pulling device, and since the simple displacement absorbing device and the existing hydraulic jack are used, the bridge bearing can be replaced at a very low cost. Since the device absorbs various displacements (horizontal, rotation, etc.) generated when the bridge superstructure is raised, the advantages of safely replacing the bridge bearing can be recognized.

However, the bonded steel sheet 10 is mounted on the bottom of the bridge upper structure (G1) by an anchor, so it is not easy to apply to various types of bridge upper structure (G1), and also the bridge upper structure (G1) and the bridge lower structure ( If the space between G2) is low, there is a limit to the application.

In addition, in order to prevent the fall of the hydraulic jack 30 which is fixed when the bridge upper structure G1 moves due to temperature change, etc., when installing the circular steel pipes 41 and 42 installed above and below the hydraulic jack 30, the hydraulic jack 30 Difficult to install from outside the plate-shaped circular steel plate 32 attached to the), the circular steel plate 32 is located in a closed space inside the upper circular steel pipes (41, 42) to slide when lifting the bridge structure (G1) It was difficult to accurately grasp the degree and the height of the raise.

Accordingly, the present invention basically ensures the bridge support function that can act as a movable end or a fixed end by simple installation position operation while controlling the displacement by absorbing the expansion and contraction of the upper structure of the bridge more stably while having the function of the bridge support. The technical problem to be solved is to provide a bridge lifting device and a bridge lifting method using the bridge support function that can be applied to various bridge types.

The present invention

Preferably the lower plate is formed on the upper surface of the lifting means; A lower fixing block including a lower guide block formed on an upper surface of the lower plate with the pulling means interposed therebetween and a stop block formed across the lower guide block; An upper support block formed on the lower surface of the upper plate so as to face each other and installed downward in the lower guide block; And a bottom block which is a steel plate of a circular shape installed on the center lower surface of the upper plate. And a sliding plate attached to the bottom surface of the bottom block with an adhesive. It provides a bridge lifting device having a bridge support function including an upper support plate configured to include.

In addition, the upper support block is a bridge lifting function having a bridge support function to be slided along the lower guide block, or fixed to the inner surface of the stop block to enable the upper support plate to move or be fixed relative to the lower support plate. Provide a device.

In addition, the pulling means is provided with a bridge lifting function having a bridge receiving function including ;; the upper surface is opened on the upper surface of the lower plate and the hydraulic jack receiver of the cylindrical shape formed so that the hydraulic line can pass through.

Also preferably, the lower plate may be formed of a horizontal plate, and the lower guide block may be formed of a vertical plate on an upper surface of the horizontal plate, and the stop block may be formed as both side vertical plates formed on a horizontal plate perpendicular to the vertical plate. It provides a bridge lifting device having a bridge support function to be formed on both sides of the direct plate.

In addition, the sliding plate is a material with a small coefficient of friction including a brass plate is attached to the bottom surface of the circular block attached to the center bottom of the upper support plate with an adhesive containing epoxy to the bottom surface of the sliding plate and the hydraulic jack Provided is a bridge lifting device having a bridge support function to slide as a reference.

Also preferably, the upper support block is installed to be orthogonal to the lower guide block, the bridge lifting device having a bridge bearing function consisting of a vertical plate extending downward with the lower guide block between both sides of the lower guide block. to provide.

In addition, the upper plate is preferably the upper plate is directly fixed to the bottom of the bridge upper structure by the anchor by extending the upper support plate when the type of the upper structure of the bridge is a slab, the upper by the anchor in accordance with the behavior of the upper structure of the bridge Provide a bridge lifting device with bridge support to allow plates to behave together with bridge superstructures.

Also preferably, when the type of the bridge upper structure is a girder bridge, the upper plate is further formed so that the engaging groove is dug inward from the outer surface, the locking means caught in the engaging groove is the upper structure of the bridge upper structure It is fixed to, and provides a bridge lifting device having a bridge support function that allows the upper plate to move with the bridge upper structure by the locking means according to the behavior of the bridge upper structure.

Also preferably, the locking means is provided with a bridge lifting device having a bridge receiving function including a vertical plate is fixed to the locking groove by the lower end is fixed to the outer surface of the bridge upper structure.

Also preferably, the locking means includes a vertical plate hooked to the locking groove; And a L-shaped locking plate that is bent from the upper end of the vertical plate to the upper surface of the bridge upper structure and includes a horizontal plate having a vertical support plate formed on the upper surface, wherein the vertical support plate is connected to the bridge upper structure. Branches provide a bridge lifting device.

In addition, the lower flange of the I-type steel plate girder, the outer surface of the concrete girder, to provide a variety of methods for installing the bridge lifting device having the bridge support function described above on the bottom of the slab.

By the bridge lifting device having the bridge support function of the present invention, the bridge support function is more stable than the lifting of the bridge upper structure.

Further, the pulling apparatus according to the present invention can function as a fixed end or a movable end simply by supporting the bridge simply by changing the installation position in the direction of the bridge or the perpendicular to the bridge, thereby ensuring a highly efficient bridge support function.

The scope of the present invention is shown by the following claims rather than the above description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

1A is an assembled perspective view of an oilless bridge bearing as a conventional bridge bearing,
Figure 1b is an installation perspective view of the lifting device having the function of the conventional bridge receiving,
2a, 2b and 2c is a perspective view of the pulling device of the present invention,
3a, 3b and 3c is a perspective view of the installation of the pulling apparatus according to the first embodiment of the present invention,
4A, 4B and 4C are perspective views of installation of the pulling apparatus according to the second embodiment of the present invention;
5a and 5b is a perspective view of the installation of the pulling device according to a third embodiment of the present invention,
6a, 6b and 6c is a flow chart of the installation of the impression device of the present invention,
7 is a fixed end and movable end operation of the bridge lifting device of the present invention,
8A and 8B are cross-sectional views of a bridge in a direction perpendicular to the bridge lift apparatus of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

<Bridge lifting device 100 having a bridge support function according to the present invention>

First, the bridge lifting apparatus 100 according to the present invention having a bridge bearing function is composed of a lower support plate 110, a sliding plate 120, and an upper support plate 130, based on FIGS. 2A, 2B, and 2C. Take a look.

That is, the bridge lifting device 100 according to the present invention is guided by the lower support plate 110 and the upper support plate 130 is slid, and eventually the sliding of the upper support plate is blocked by the lower support plate to prevent the upper support plate. It is possible to control the displacement caused by the expansion and contraction of the bridge upper structure integrated with the sliding plate, the sliding plate 120 having a small coefficient of friction, such as brass bearing plate is a circular steel sheet of the bottom block 133 is an adhesive by epoxy or the like The displacement amount is predictable and makes the sliding of the upper support plate more stable.

The lower support plate 110 is a lower plate 111; Lower guide block 112; It is largely composed of a stop block 113 and the pulling means (114).

First, the lower plate 111 may be manufactured using a steel plate in the form of a horizontal plate as a rectangular plate. The lower plate 111 is installed on the upper surface of the bridge lower structure (200, shift, bridge, etc.) to be described later.

The lifting means 114 is installed at the center of the upper surface of the lower plate 111. The raising means 114 is a cylindrical body having an upper surface open on the upper surface of the lower plate 111 and forming a spaced portion 114d through which a hydraulic line can pass. Hydraulic jack receiver 114b in the form; And a hydraulic jack 114c mounted inside the hydraulic jack receiver.

That is, since the hydraulic jack is merely a pulling means, it may not be easy to fix the position due to excessive hydraulic pressure, impact transmitted from the upper structure of the bridge. In this case, the actual hydraulic jack integrates the hydraulic jack receiver 114b having the upper portion open on the upper surface of the lower plate, and allows the hydraulic jack 114c to be fixed inside the hydraulic jack receptor 114b.

In order to supply hydraulic pressure by connecting the hydraulic line to the hydraulic jack 114c, the hydraulic jack receiver 114b forms a spaced portion 114d through which the hydraulic line can pass, and when the hydraulic pressure is supplied, the hydraulic cylinder 114f is upward. Protrudes to allow the impression to occur.

The lower guide block 112 is installed so as to face each other with the pulling means 114 therebetween, it can be produced using a steel plate in the form of a vertical plate as a rectangular plate material, according to Figure 2a know that the two are spaced apart Can be. The lower guide block 112 has a function of guiding the sliding of the upper support block by the expansion and contraction of the upper support plate 130 to be described later as its name.

The stop block 113 is a side vertical plate formed on the upper surface of the lower plate 111 orthogonal to the lower guide block 112 and can also be manufactured using a steel plate in the form of a vertical plate as a rectangular plate. It can be seen that they are installed on both sides of the lower guide block 112 facing each other. The stop block 113, as its name, when the upper support block by the expansion and contraction of the upper support plate 130 is slid along the lower guide block 112, thereby acting to block the sliding and eventually by this function It can be seen that to control the expansion and contraction of the upper support plate 130.

Next, the sliding plate 120 may use a brass bearing plate normally used for bridge support as a member for inducing sliding and may be manufactured in the form of a circular plate.

The sliding plate 120 is directly attached to the bottom of the bottom block 133 of the circular shape is installed protruding downward to the center bottom of the upper support plate 130 to be described later and the adhesive by an epoxy or the like, the upper end of the hydraulic jack (114c) And sliding plate 120 to allow the slip. It can be seen that the bridge upper structure integrated with the upper support plate can be raised.

Next, the upper support plate 130 is the upper plate 131; And an upper support block 132.

The upper support plate 130 is integrated with the upper structure of the bridge to generate a sliding according to the expansion and contraction of the upper structure, the means to be integrated with the upper structure of the bridge (to be described later) and the means that the sliding can occur stably (upper support) Block) is formed.

First, the upper plate 131 may be manufactured in the same form as the lower plate 111 and may be manufactured using a steel plate in the form of a horizontal plate as a rectangular plate. The top plate 131 is installed on the bottom of the bridge upper structure 300, girder, slab, etc. to be described later.

In addition, the sliding plate 120 is attached to the lower surface of the bottom block 133 made of a steel plate of a circular shape by an adhesive such as epoxy to form integrally.

In addition, it can be seen that the locking groove 134 is formed on the outer surface so that the locking means 400 to be described later is caught.

The locking means 400 is a L-shaped locking plate by the vertical plate 410 or the vertical plate 421 and the horizontal plate 422 on which the vertical support plate 423 is formed, according to the shape of the bridge upper structure 300. It may be formed in the form of (420).

Next, the upper support block 132 is disposed on the bottom surface of the upper plate 131 so as to be fitted to the lower guide block 112 corresponding to the position of the lower guide block 112 described above with the sliding plate 120 interposed therebetween. Is installed.

Accordingly, the upper support block 132 is two opposite vertical plates in order to form a space in which the lower guide block 112 can be fitted on the bottom of the upper plate, with the lower guide block 112 therebetween from the bottom of the upper plate. It extends downward and is formed to be divided.

Accordingly, the upper support block 132 may be guided along the lower guide block 112 to be slid, and the upper support block 132 slid by the stop block 113 may stop while contacting the upper end. It is possible to more stably control the expansion and contraction of the upper support plate and the bridge upper structure according to the sliding control of the support block 132.

<Installation Example 1, 2, 3 of Bridge Lifting Device 100 Having a Bridge Support Function According to the Present Invention>

Embodiments 1, 2, and 3 according to the type of bridge upper structure 300, for example, the steel plate girder 310, concrete girder 320 and the slab 330 according to the present invention As a form, this will eventually bring a difference in the connection configuration between the bridge upper structure 300 and the pulling device 100.

<Example 1: Mounting Example for Steel Plate Girder 310 of I Type Cross Section>

First, FIGS. 3A and 3B may be referred to as the case where the bridge lifting device 100 of the present invention is installed in the steel plate girder 310 having an I-type cross section, in particular, as the bridge upper structure 300.

Thus, it can be seen that the bridge lifting device 100 composed of the lower support plate 110, the sliding plate 120, and the upper support plate 130 described above is used, and the bridge lifting device 100 is replaced with a bridge bearing ( A) It can be seen that the steel plate is installed between the bottom surface of the girder 310 and the upper surface of the bridge lower structure 200.

At this time, the upper support plate 130 of the bridge lifting device 100 by a horizontal plate 422 having a vertical plate 421 and a vertical support plate 423 on the upper surface as a locking means 400 in the locking groove 134. It can be seen that the L-shaped locking plate 420 is formed.

In addition, the vertical support plate 423 of the L-shaped locking plate 420 is inverted a-shaped connection spaced apart from each other on the outer surface of the abdomen 312 constituting the steel plate girder 310 as the bridge upper structure 300 It is inserted in the spaced space between the reinforcing plate 430 is fixed by fasteners by bolts and nuts, so that the behavior of the steel plate girder 310 by the connecting reinforcing plate 430, the L-shaped locking plate 420 The bridge lifting device 100 is controlled.

That is, according to FIG. 3B, the width d1 of the vertical plate and the horizontal plate constituting the L-shaped locking plate 420 is formed to be smaller than the extension length d2 of the locking groove 134 so that the L-shaped locking plate ( It can be seen that the 420 is able to control the size of the behavior when the behavior according to the expansion along the locking groove 134, this control eventually controls the displacement of the excessive bridge upper structure 300, such as falling off due to earthquake load It can be seen that it is possible to prevent such.

<Example 2: Mounting example for the concrete girder 320 of the I-type cross section>

The mounting example according to the second embodiment is the same as that of the first embodiment using the bridge lifting device 100 having the upper support plate 130 with the locking groove 134 formed in comparison with the first embodiment, and if there is a difference , Since the mounting target corresponds to the concrete girder, there is a difference in the locking means 400 in comparison with the first embodiment.

That is, in Example 1, although the connecting reinforcing plate 430 mounted on the steel plate girder 310 and the L-shaped locking plate 420 were used, the locking means 400 was used. 410).

That is, the vertical plate 410 is fixed to the outer surface of the concrete girder 320 using an anchor bolt as shown in FIGS. 4a and 4b, and the lower end of the vertical plate 410 is caught by the upper support plate 130. It can be seen that the mounting to the groove 134.

Also, the width d1 of the vertical plate 410 is formed to be smaller than the extension length d2 of the locking groove 134, so that the size of the behavior of the vertical plate 410 according to the expansion and contraction along the locking groove 134. It can be seen that it can be controlled, this control can be seen that eventually controls the displacement of the excessive bridge upper structure 300, it can prevent falling, such as earthquake load.

Example 3 Attachment Example to Slab 330

Depending on the type of bridge, the girder may not be installed and the slab 330 may be supported by the bridge support as the slab bridge 300, as referred to as a slab bridge.

In this case, when installing the bridge lifting device 100 of the present invention as shown in Figures 5a and 5b, the upper support plate 130 is extended so as to be fixed as it is using the anchor bolt 450. The locking groove 134 is not formed in the upper support plate 130.

<Construction Example of Bridge Lifting Device 100 Having a Bridge Support Function According to the Present Invention>

The bridge lifting device 100 will be installed on the bridge to look first how to eventually raise the bridge upper structure 300. This will first look at the construction example of the bridge lifting apparatus 100 according to the first embodiment described above.

First, the bridge lifting device 100 having the bridge receiving function described above is prepared.

The bridge lifting device 100 is composed of a lower support plate 110, a sliding plate 120 and the upper support plate 130, the engaging groove 134 is formed on the outer surface of the upper support plate 130 Will be. The bridge lifting device 100 is mounted on the upper surface of the bridge lower structure 200.

Thus, as shown in FIG. 6a, the inlet a-shaped connecting reinforcing plate 430 is mounted to be spaced apart from the abdomen 322 of the steel plate girder 320 of the upper bridge structure 300, which is the bridge lifting device 100 is installed. Function as a means of reinforcing the site.

Next, as shown in Figure 6b vertical plate 421; At the upper end of the vertical plate is bent to the upper surface of the bridge upper structure and the L-shaped locking plate 420 including a horizontal plate 422 formed on the upper surface of the vertical support plate 423 is installed, but connecting the vertical support plate 423 It is to be mounted between the reinforcing plate 430.

The L-shaped locking plate 420 is supported on the upper surface of the lower flange 321 of the steel plate girder 320, or the steel box girder, the vertical plate 421 is located on the outer side of the lower flange 321 side. It is to be mounted on the locking groove 134 of the upper support plate 130 to be described later.

Next, as shown in FIG. 6C, the bridge lifting device 100 of the present invention is installed on the upper surface of the bridge lower structure 200 so that the locking groove 134 of the upper support plate 130 is caught by the vertical plate 421. Done.

Thus, the lifting means 144 of the bridge lifting device 100 is operated to raise the upper structure of the bridge so that the bridge lifting method using the bridge lifting device having the final bridge support function can be completed.

Next, the construction example of the bridge lifting apparatus 100 according to the second embodiment described above

In addition, the bridge lifting device 100 having the bridge receiving function described above is prepared. The bridge lifting device 100 is composed of a lower support plate 110, a sliding plate 120 and the upper support plate 130, the engaging groove 134 is formed on the outer surface of the upper support plate 130 Will be. The bridge lifting device 100 is mounted on the upper surface of the bridge lower structure 200.

Accordingly, the locking means 400 which is a vertical plate 410 is fixed to the outer surface of the concrete girder 320 by using an anchor bolt.

Next, the bridge lifting device 100 of the present invention is installed on the upper surface of the bridge lower structure 200 to set the locking groove 134 of the upper support plate 130 to be caught by the vertical plate 410.

Thus, the lifting means 144 of the bridge lifting device 100 is operated to raise the upper structure of the bridge so that the bridge lifting method using the bridge lifting device having the final bridge support function can be completed.

Next, the construction example of the bridge lifting apparatus 100 according to the third embodiment described above

In addition, the bridge lifting device 100 having the bridge receiving function described above is prepared. The bridge lifting device 100 is composed of a lower support plate 110, a sliding plate 120 and the upper support plate 130, the engaging groove 134 is formed on the outer surface of the upper support plate 130 This is because the locking means are not used. The bridge lifting device 100 is mounted on the upper surface of the bridge lower structure 200.

Next, the bridge lifting device 100 of the present invention is installed on the upper surface of the bridge lower structure 200 to extend the upper support plate 130 to be fixed to the bottom surface of the bridge upper structure by using an anchor bolt.

Thus, the lifting means 144 of the bridge lifting device 100 is operated to raise the upper structure of the bridge so that the bridge lifting method using the bridge lifting device having the final bridge support function can be completed.

<Installation example of fixed end and movable end of bridge raising device of the present invention>

Next, according to FIG. 7 when the upper support block 132 of the bridge raising device 100 of the present invention is not fixed to the stop block 113 and is moved along the lower guide block 112 when spaced apart, the bridge is supported by the bridge. It can be seen that the pulling device 100 functions as a movable end, and when the upper support block 132 is not spaced apart from the stop block 113 (fixed with each other), it can function as a fixed end. At this time, it can be seen that the sliding direction of the upper support plate 130 is the axial direction.

<Installation Example of the Bridge Shaft Orthogonal Direction of the Bridge Lifting Device of the Present Invention>

In addition, as shown in FIG. 8A, the upper support block 132 is simply installed in a right angle direction in the bridge direction if the bridge raising device of the present invention is fixed to the stop block 113 so as to function as a fixed end bridge bearing in the direction perpendicular to the bridge axis. You can rotate the position to place the bridge lifter,

As shown in FIG. 8B, the upper support block 132 slides along the lower guide block 112 to be controlled by the stop block 113 so as to function as a bridge end support in the direction perpendicular to the bridge axial direction. The bridge lifting device can be arranged by simply rotating the installation position in the direction perpendicular to the bridge axis.

100: bridge raising device
110: lower support plate
120: sliding plate
130: upper support plate
200: bridge undercarriage
300: bridge upper structure
400: locking means

Claims (14)

A lower plate 111 on which the pulling means 114 is formed on the upper surface of the center; And a lower support plate (110) formed on an upper surface of the lower plate with the pulling means interposed therebetween, and a lower guide block (112) formed to face each other and a stop block (113) formed across the lower guide block. And
The upper support block 132 is formed to face each other on the lower surface of the upper plate 131 and is inserted downward into the lower guide block and the lower surface block and the lower surface of the bottom block which are circular steel plates installed on the lower surface of the upper plate. Bridge support apparatus having a bridge support function comprising a; an upper support plate (130) comprising a sliding plate (120) attached with an adhesive. According to claim 1, wherein the upper support block 132 is to be slided along the lower guide block 112, or to be fixed to the inner surface of the stop block 113, the upper support plate 130 is lower support plate ( Bridge lifting device having a bridge support function, characterized in that to be movable or fixed based on 110). According to claim 1, The lifting means 114 is an upper surface is opened on the lower plate and the hydraulic jack receiver 114b of the cylindrical form formed with a spaced portion (114d) so that the hydraulic line can penetrate; And a hydraulic jack (114c) mounted inside the hydraulic jack receiver. According to claim 1, wherein the lower plate 111 is formed of a horizontal plate, the lower guide block 112 is formed of a vertical plate on the upper surface of the horizontal plate, the stop block 113 is perpendicular to the vertical plate Bridge lifting device having a bridge receiving function, characterized in that formed on both sides of the vertical plate as a vertical plate on both sides of the horizontal plate. According to claim 1, The sliding plate 120 is made of a material with a small coefficient of friction including a brass plate is attached to the bottom surface of the circular shape of the bottom block is attached to the center of the upper support plate with an adhesive containing epoxy to the sliding plate Bridge lifting device having a bridge support function characterized in that the sliding on the basis of the lower surface and the hydraulic jack. According to claim 4, wherein the upper support block 132 is installed to be perpendicular to the lower guide block 112, consisting of a vertical plate extending downwards with the lower guide block between both sides of the lower guide block. Bridge lifting device having a bridge support function characterized in. According to claim 1, wherein the upper support plate 130 by the anchor bolt 450, the upper plate is directly fixed to the bottom of the bridge upper structure, the upper plate by the anchor in accordance with the behavior of the bridge upper structure with the bridge upper structure Bridge lifting device having a bridge bearing function, characterized in that to enable movement. According to claim 1, wherein the upper plate 131 is formed so that the engaging groove 134 is dug inwardly from the outer surface, the locking means 400 caught in the locking groove 134 is on the upper surface of the upper plate The bridge lifting device having a bridge support function, which is fixed to the upper structure of the bridge so that the upper plate can be moved together with the upper structure by the locking means according to the behavior of the upper structure of the bridge. The method according to claim 8, wherein the locking means 400 has a bridge supporting function, characterized in that it comprises a vertical plate is fixed to the locking groove 134 by the anchor bolt on the outer surface of the bridge upper structure Bridge lifting device. The method of claim 8, wherein the locking means 400 comprises a vertical plate (421) caught in the locking groove 134; The upper portion of the vertical plate is curved to the upper surface of the bridge and includes a L-shaped locking plate 420 including a horizontal plate 422 formed with a vertical support plate 423 formed on the upper surface, the vertical support plate is the bridge upper portion Bridge lifting device having a bridge receiving function, characterized in that to be connected to the structure. Preparing a bridge lifting device 100 having a bridge receiving function according to claim 1 and installing on the bridge lower structure;
Vertical plate 421 in the engaging groove 134 of the upper plate 131 constituting the upper support plate 130 of the lifting device 130 on the bridge upper structure; At the upper end of the vertical plate is bent to the upper surface of the bridge upper structure and the U-shaped locking plate 420 including a horizontal plate 422 formed with a vertical support plate 423 is formed on the upper surface, the vertical support plate 423 is To be installed between the connecting reinforcing plate 430 installed on the outer surface of the bridge upper structure,
Raising the bridge upper structure by operating the lifting means (144) of the bridge lifting device (100); Bridge lifting method using a bridge lifting device having a bridge support function, comprising a. Preparing a bridge lifting device 100 having a bridge receiving function according to claim 1 and installing on the bridge lower structure;
Fixing the upper plate 131 constituting the upper support plate 130 of the pulling device 130 to the upper structure of the bridge with an anchor bolt 450; And
Raising the bridge upper structure by operating the lifting means 114 of the bridge lifting device (100); Bridge lifting method using a bridge lifting device having a bridge support function comprising a. Preparing a bridge lifting device 100 having a bridge receiving function according to claim 1 and installing on the bridge lower structure;
The locking means (400), which is a vertical plate 410, is mounted on the hook groove 134 of the upper plate 131 constituting the upper support plate 130 of the pulling device 130 on the bridge upper structure. Securing 400 to an outer surface of the bridge upper structure;
Raising the bridge upper structure by operating the lifting means (144) of the bridge lifting device (100); Bridge lifting method using a bridge lifting device having a bridge support function, comprising a. The method according to any one of claims 11 to 13, wherein the bridge lifting device 100 is arranged in the axial direction or perpendicular to the direction of the bridge, and the lower fixing block of the bridge lifting device 100 is spaced apart or stopped from the stop block. Bridge lifting method using a bridge lifting device having a bridge receiving function, characterized in that to be fixed.

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