KR100660034B1 - Apparatus for pulling up a structure and height adjustable bridge bearing utilizing the same - Google Patents

Abstract

Disclosed is a structure lifting device and a bridge device using the same, which can be suitably used to raise an upper structure or to support an upper structure between a bridge piers and a top plate structure of a bridge. The structure lifting device and the chair device is a wedge member having a top surface and a bottom that are gradually narrower toward one direction, a wedge bottom member having a top surface of the same slope as the bottom surface of the wedge member and in contact with the bottom surface of the wedge member, the wedge A wedge top member and the wedge bottom surface having a bottom surface in contact with the top surface of the member and having the same inclination as the top surface of the wedge member, the bottom surface being inclined with the top surface of the wedge bottom member, the height of which changes in accordance with the front and back positions of the wedge member. Supported by one end of the member and the upper surface of the wedge member is configured to include a wedge member moving means for adjusting the forward and backward positions of the wedge member, easy to adjust the height of the pre-installed teaching apparatus, the process of installing the upper structure By measuring the load applied to the device and increasing or decreasing the height of the device. It provides the effect that it is possible to precisely install the designed load.

Bridge device, bridge, pier, top plate, superstructure, height adjustment

Description

Apparatus for pulling up a structure and height adjustable bridge bearing utilizing the same}

1 is a front view showing the installation state of the bridge device in a general bridge,

2 is a side view of the bridge installed in the canyon,

3 is a side view of a railway bridge,

4 is a cross-sectional view showing the installation state of the chair apparatus according to the present invention,

5 is an exploded perspective view of the chair apparatus according to the present invention;

6 is a cross-sectional view showing an example in which the present invention is applied to a pot bearing,

7 is a cross-sectional view showing an example in which the present invention is applied to the elastic support,

8 is a cross-sectional view of the structure lifting apparatus according to the present invention.

Explanation of symbols on the main parts of the drawings

100: teaching device 110: wedge member

113, 115: stainless steel plate 114: hole

130: wedge member moving means 131: bolt

132 nut 150 wedge bottom member

152, 162: PTFE member 155, 165: guide jaw

160: upper wedge surface member 180: load cell

The present invention relates to a structure lifting device and a bridge device using the same, and in particular, the structure lifting device that can be suitably used to raise the upper structure or to support the upper structure is installed between the bridge and the top of the bridge structure using the same It relates to a teaching device.

In general, the bridge device is installed between the bridge pier and the upper structure to buffer and support the load or impact of the upper structure, the upper plate for fixing to the upper structure side and the lower plate and upper plate for fixing to the lower structure side and It is comprised by the buffer member provided between lower boards. In such bridges, there are many cases where the variation of working loads occurs due to the concrete shrinkage, creep, elastic shrinkage, etc., in which case the height of the bridge device should be adjusted. In this regard, it will be briefly described with reference to the accompanying drawings.

1 is a front view showing the installation state of the bridge device in a general bridge.

As shown, the bridge 10 includes a bridge device 20 installed between the bridge 12 and the superstructure 14. The bridge device 20 is to support the load of the upper structure 14 and to buffer the impact force acting between the upper structure 14 and the pier 12. The bridge device 20 is installed on a plurality of bridges 12 in accordance with the width and load of the upper structure (14). As shown in FIG. 1 due to various causes such as dry shrinkage, creep, elastic shrinkage, etc. of concrete during or after installation of the bridge device 20 in the bridge 10, the loads supported by the bridge device 20 are unbalanced, respectively. This can happen. In this case, if the design load of each bridge device is 100 tons, for example, the bridge device 20 that receives a load of 150 tons and 130 tons in FIG. 1 may be damaged. Lowering, the load device 20 that receives less load than the design load, such as 30 tons, 80 tons, the height should be slightly increased.

However, the conventional teaching device 20 could not adjust its height. In this case, if you want to maintain the load acting on each bridge device evenly, measure the load on each bridge device 20, estimate the dimensions to increase or decrease each bridge device, and then install the jack-up device on the bridge. Thus, after the upper structure 14 is raised, a thin plate is inserted between the upper structure 14 and the pier 12 and the lower structure is lowered, which is very troublesome and requires a lot of time and manpower. . In addition, it is difficult to accurately correct the load deviations between the teaching devices. However, it is difficult to repeat the cumbersome and time-consuming work as described above many times.

2 is a side view of a bridge installed in a canyon.

As shown in FIG. 2, the length difference between the bridges 32, 32a, and 32b of the bridge 30 provided in the canyon is very large. For example, the height of the pier 32a, 32b of both sides is 10-15m, and the height of the bridge 32 between them may be 100m inside and outside. In this case, the high piers 32 have a greater amount of dry shrinkage and long-term creep than the low piers 32a, 32b on both sides. Large deviations may occur in the load acting on the device 40, 40a, 40b installed in the. For example, 500 tons of load is applied to the bridge device 40 installed in the high piers 32, while 1250 tons of bridge devices 40a and 40b installed in the low bridge piers 32a and 32b are applied. The load may work. In this case, for example, if the bridge device 40, 40a, 40b is designed based on a load of 1000 tons, the bridge device (40a, 40b) installed in both bridges (32a, 32b) will be accompanied by a bunch, the life of the bridge is short Can cause damage or bridge collapse. In this case, it is also necessary to eliminate the load deviation by adjusting the height of the teaching device (40a, 40b).

3 is a side view of a railway bridge.

When installing the jackup device 70 or the like on the pier 52 to replace the upper structure 54 of the old or damaged railway bridge 50, the height of the rail 56 must be accurately adjusted. Generally, the deflection limit of the rail 56 is about 2-3 mm. No matter how precise the upper structure 54 of the railway bridge 50, it is very difficult to accurately match the height of the rail 56. In this case, conventionally, the jackup device 70 raises the upper structure 54 and repeats the method of inserting a thin plate between the pedestal device 60 and the upper structure 54 to adjust the height again. Precision construction is difficult In particular, when the railway bridge is installed in the canyon as shown in Figure 2 is very large need to modify the height of the bridge device (40).

In addition, the jack-up device, which is mainly used as a conventional device for lifting a structure, has to process cylinders and pistons precisely and uses hydraulic oil, so that there is a high possibility of problems in the oiltight structure, and it is difficult to maintain the structure for a long time in the state of lifting the structure. There is a risk of an accident due to problems in the hydraulic line.

In addition, the settlement of bridge piers in bridges installed on soft grounds such as shores may cause load imbalance between bridge units.

It is an object of the present invention to provide a height adjustable seating device.

It is another object of the present invention to provide a bridge arrangement which makes it easy to correct the load imbalance between several bridges.

Still another object of the present invention is to provide a bridge device capable of precision construction when replacing a railway bridge superstructure.

The other object of the present invention is to provide a structure pulling apparatus that does not require a working fluid, is easy to make, excellent in stability, and can support large loads for a long time.

In the teaching apparatus according to the present invention, in the teaching apparatus having a buffer member having a buffer member, an upper plate installed on the upper buffer member, a lower plate installed on the lower buffer member,

It includes a height adjusting device installed on the upper or lower plate,

The height adjustment device,

A wedge member having an upper surface and a lower surface arranged to be narrower in one direction;

A wedge bottom member contacting the bottom surface of the wedge member and having an upper surface of the same inclination as the bottom surface of the wedge member, contacting an upper surface of the wedge member and inclined with an upper surface of the wedge bottom member and having the same inclination as the top surface of the wedge member. A wedge upper surface member having a bottom surface which is disposed and whose height is changed according to the forward and backward positions of the wedge member and a wedge for adjusting the forward and backward positions of the wedge member by being supported by one end of the wedge bottom member and the wedge upper surface member. It has a structure including a member moving means.

Preferably, a load cell is interposed between the wedge member moving means and the end of the wedge upper surface member or the end of the wedge bottom surface member, or between the wedge member moving means and the wedge member.

The upper plate and the wedge bottom face member may be integrally formed, and the lower plate and the wedge top face member may also be integrally formed.

Preferably, the stainless steel plate and the PTFE member are attached to the corresponding surfaces of the wedge member, the wedge upper surface member, and the wedge bottom surface member.

The wedge member is formed with a hole along the longitudinal direction of the wedge member, the wedge member moving means is provided with a bolt that is inserted into the hole and the end is protruded to the opposite side and the nut coupled to the protruding bolt and One of the bolt and the nut is supported at the end of the wide surface of the wedge member and the other is preferably supported at the end of the upper surface of the wedge member or the wedge bottom member.

The wedge member is formed with a fastening hole having a spiral formed on the inner circumferential surface along the longitudinal direction of the wedge member, the wedge member moving means is one end is coupled to the fastening hole and the other end is supported by the wedge bottom member or the upper surface of the wedge member It may have a configuration.

At least one of the wedge member, the wedge bottom member, and the wedge upper surface member is preferably provided with a guide jaw for guiding the wedge member, the wedge bottom member and the wedge upper surface member to move in the same direction without departing from the side. .

Structure lifting device according to the present invention is a wedge member having a top surface and a bottom that is gradually narrower toward one direction, a wedge bottom member in contact with the bottom surface of the wedge member and having a top surface of the same slope as the bottom of the wedge member, the wedge A wedge top member and the wedge bottom surface having a bottom surface in contact with the top surface of the member and having the same inclination as the top surface of the wedge member, the bottom surface being inclined with the top surface of the wedge bottom member, the height of which changes in accordance with the front and back positions of the wedge member. It is supported by one end of the member or the upper surface of the wedge member is configured to include a wedge member moving means for adjusting the forward and backward positions of the wedge member.

Preferably, the load cell is interposed between the wedge member moving means and the end of the wedge upper surface member or the wedge bottom member or between the wedge member moving means and the end of the wedge member.

It is preferable that a stainless steel plate and a PTFE member are attached to the corresponding surface of the wedge member, the wedge upper surface member and the wedge bottom surface member, respectively.

The wedge member is formed with a hole along the longitudinal direction of the wedge member, the wedge member moving means is provided with a bolt that is inserted into the hole and the end is protruded to the opposite side and the nut coupled to the protruding bolt and Preferably, one of the bolt and the nut is supported on the wide surface of the wedge member and the other is supported on the wedge upper surface member or the wedge bottom member.

The wedge member has a fastening hole having a spiral formed on the inner circumferential surface along the longitudinal direction of the wedge member, the wedge member moving means is one end is coupled to the fastening hole and the other end is supported by the wedge bottom member or the upper surface of the wedge member Can have

At least one of the wedge member, the wedge bottom member, and the wedge upper surface member may be formed with a guide jaw for guiding the wedge member, the wedge bottom member and the wedge upper surface member to move in the same direction without departing from the side.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

4 is a cross-sectional view showing an installation state of the teaching apparatus according to the present invention, Figure 5 is an exploded perspective view of the teaching apparatus according to the present invention.

As shown, the device 100 according to the present invention is provided with a wedge member (110). The wedge member 110 has an upper surface 111 and a lower surface 112 disposed to be inclined. In some cases, any one of the upper surface 111 and the lower surface 112 may be horizontally disposed, and only the other surface may be disposed to be inclined. The upper surface 111 and the lower surface 112 are arranged to become narrower toward one direction. Stainless steel plates 113 and 115 are attached to the upper and lower surfaces of the wedge member 110, and PTFE members 152 and 162 are attached to the corresponding surfaces in contact with them.

As shown, the wedge member 110 is formed with a hole 114 along its longitudinal direction. Through this hole 114, the wedge member moving means 130 is coupled. This wedge member moving means 130 will be described in more detail later.

As shown, the wedge bottom member 150 is installed below the wedge member 110. The upper surface 151 of the wedge bottom surface member 150 is in contact with the bottom surface 112 of the wedge member 150. The upper surface 151 of the wedge bottom surface member 150 has the same slope as the bottom surface 112 of the wedge member 110. The PTFE member 152 is attached to the upper surface 151 of the wedge bottom member 150. The PTFE member 152 is to reduce the friction force acting between the wedge member 110 and the wedge bottom member 150 together with the stainless steel plate 115. It is preferable that the groove 153 is formed on the surface of the PTFE member 152, and the groove 153 is filled with a lubricant 154. Here, the stainless steel plate 115 and the PTFE member 152 may be provided with the position changed mutually. In the wedge bottom member 150, guide jaw 155 for guiding the movement of the wedge member 110 is formed at both sides. In some cases, the upper surface 151 of the wedge bottom member 150 may be formed to protrude upward, and the guide jaw 155 may be formed on the wedge member 110. In addition, in some cases, the wedge upper surface member 160, which will be described later, extends downward from the side of the wedge bottom member 150 to guide the wedge member 110 and the wedge bottom member 150 in one direction without being separated. You can do this, and vice versa. The guide jaw 155 does not have to be present. In some cases, the upper surface 111 and the lower surface 112 of the wedge member 110 is thickened from both side edges toward the inner side, and the corresponding surfaces of the upper wedge upper member 160 and the lower wedge bottom member 150 are It may be formed in a groove shape that deepens from the left and right edges toward the center.

As shown, the upper surface of the wedge member 110, the upper wedge member 160 is mounted. The bottom surface 161 of the wedge upper surface member 160 is in contact with the upper surface 111 of the wedge member 110. The bottom surface 161 of the wedge upper surface member 160 has the same slope as the top surface 111 of the wedge member 110. The PTFE member 162 is attached to the bottom 161 of the wedge upper surface member 160. The PTFE member 162 is to reduce the frictional force acting between the wedge member 110 and the wedge upper surface member 160 together with the stainless steel plate 113. It is preferable that the groove 163 is formed on the surface of the PTFE member 162, and the groove 163 is filled with a lubricant 164. Here, the stainless steel plate 113 and the PTFE member 162 may be provided with the position changed mutually. In the wedge upper surface member 160, guide jaws 165 for guiding the movement of the wedge member 110 are formed at both sides, respectively. In some cases, the bottom surface 161 of the wedge upper surface member 160 may be formed to protrude downward, and the guide jaw 165 may be formed on the upper surface side of the wedge member 110. The bottom surface 161 of the wedge top surface member 160 is disposed to be inclined with the top surface 151 of the wedge bottom surface member 150. The upper surface of the wedge member 160 is changed in height depending on the position of the front, the back of the wedge member 110, so that the height of the chair device 100 can be changed.

The device 100 according to the present invention includes a wedge member moving means 130. The wedge member moving means 130 pulls the wedge member 110 while being supported at one end of the wedge bottom member 150 or the wedge top surface member 160 so that the height of the wedge top member 160 is increased or wedges. The member 110 is to be retracted so that the height of the upper surface of the wedge member 160 is lowered. The wedge member moving means 130 is provided with a bolt 131 is coupled to the hole 114 formed in the wedge member 110, one end protrudes to the other side. The nut 132 is coupled to a portion protruding to the other side of the bolt 131. It is preferable to form a hexagonal groove 116 on the side of the wedge member 110 of the portion where the nut 132 is coupled to prevent the nut 132 from rotating. The mounting direction of the bolt 131 and the nut 132 of the wedge member moving means 130 may be changed.

The wedge member moving means 130 may be configured in various ways in addition to the above-mentioned type. For example, instead of the hole 114 of the wedge member 110, a spiral groove may be formed to form the wedge member moving means 130 without the nut 132, and in some cases, the hole (w) in the wedge member 110 may be formed. Without forming 114, one end of the wedge member 110 extends to both sides, a hole or a spiral groove is formed in the extended portion, and the wedge member moving means 130 is provided with bolts on both sides of the wedge member 110, respectively. ) Can also be configured.

A pair of auxiliary plates 170 are inserted between the head 131a of the bolt 131, the wedge bottom member 150, and the upper wedge top member 160, and the load cell 180 is disposed between the two auxiliary plates 170. Is combined. The load cell 180 is for measuring the load applied to the chair device 100 by measuring the tensile force applied to the bolt 131. The center cell type (center hole type) is used as the load cell 180, and various capacities and specifications are developed and sold on the market. The load cell 180 is provided with a load measuring port 182, by connecting the measuring equipment to this port can measure the tension applied to the bolt 131. The load cell 180 or the like may be provided on the opposite side of the wedge member 110.

Since the tensile force applied to the bolt 131 is equal to the horizontal component force of the force that holds the object of the load acting on the stapling device 110 on the inclined surface of the wedge member 110 so as not to slip on the inclined surface, the bolt 131 Knowing the tension applied to the frictional force and the area of the contact surface and the inclination angle of the top or bottom surface of the wedge member 110, it is possible to easily calculate the load on the stapling device (100).

The wedge member 110, the wedge upper surface member 160, the wedge bottom surface member 150, the wedge member moving means 130, the load cell 180 described above to adjust the height of the chair device 100 according to the present invention Corresponds to the height adjustment device for.

4 and 5, the wedge bottom member 150 is installed in the pier 62 through the base nut 63 installed in the pier 62 through the fixing bolt 157, the upper surface of the wedge member 160 is a buffer support It is connected to the lower plate 191 of the 190. A buffer member 192 and an upper plate 193 are installed on the lower plate 191, and the upper plate 193 is fixed to the upper structure 60 through the sole plate 194. A groove 195 is formed in the lower plate 191, and a pin 196 is provided in the upper plate 193. The pin 196 is inserted into the groove 195 through the buffer member 192. This is identical to the structure in a chair arrangement known as a disc bearing. The structure of the upper portion of the lower plate 191 may be applied to the structure of the other bridge devices known in various forms as it is.

Here, the wedge upper surface member 160 may be configured integrally with the lower plate 191, and, as shown in Figures 4 and 5, the teaching device 100 according to the present invention can be installed upside down Is easy to see.

6 is a cross-sectional view showing an example in which the present invention is applied to a pot bearing, and FIG. 7 is a cross-sectional view showing an example in which the present invention is applied to an elastic support.

The wedge top member 160 of the height adjustment device described in the previous embodiment or the wedge bottom member 150 is installed on the bottom of the pot bearing 190c or the elastic support 190b to configure the chair apparatus 100 according to the present invention. can do. The rest is as described above.

8 is a cross-sectional view of the structure lifting apparatus according to the present invention.

The basic configuration of the structure lifting device 190a according to the present invention is substantially the same as the configuration of the height adjusting device of the above-described teaching device, and the difference is provided by installing a nut 132 at both ends of the bolt 131, thereby providing a torque wrench ( The nut 132 can be easily locked in the tensioned state of the bolt 131 by using 80). Of course, this structure can be applied as it is to the height adjustment device of the device 100 described above.

In addition, a stainless steel plate 202 and a PTFE member 203 are installed between the upper support plate 201 and the upper surface 166 of the upper wedge upper surface member 160 to form the upper wedge upper surface member 160 and the upper support plate 201. Somewhat horizontal flow in the liver is to be made smoothly. Here, the upper support plate 201 and the rubber is installed between the rubber pad 204 and the lower support plate 205, the upper structure 60 and the wedge upper surface member 160 is installed on the pier 62 or the ground The pads 206 are auxiliary components of the structure pulling apparatus 190a.

That is, in the state in which the structure lifting device 190a is installed between the upper structure 60 and the pier 62 as shown in FIG. 8, the nut 132 is used by using the torque wrench 80 in the state of being tensioned using the tensioning device. Locking the wedge 110 can be moved to increase the height of the upper wedge surface member 160, thereby increasing the height of the upper structure (60). If you want to lower the height of the upper structure 60, the work is done in the reverse process.

When measuring the load acting by the upper structure 60 in the pulling process of the upper structure 60, by connecting the measuring device to the load cell 180 of the upper structure 60 acting on the structure lifting device 190a Load measurement is possible.

In the teaching apparatus according to the present invention, it is possible to precisely measure the load acting on the teaching apparatus during the installation of the upper structure, thereby increasing or decreasing the height of the teaching apparatus so that the designed load acts on the teaching apparatus.

If the load applied to the device is less than the designed value during the new installation or replacement of the device, the height of the device is increased by operating the wedge moving member. If the load is greater than the design, the wedge moving member is operated by operating the wedge moving member. By lowering the height of the bridge, it is possible to apply a load close to the design load of the bridge arrangement.

In addition, the height of the device can be adjusted in real time while measuring the load acting on the device in the installation process of the device, thereby completing the installation or replacement of the superstructure at once.

In addition, it is easy to measure the load imbalance caused by dry shrinkage or creep, etc. in bridges with a large difference in bridge heights and bridges installed on the soft board, and also to easily correct the load imbalance between the generated bridge devices. In addition, it enables excellent construction when replacing railway bridges, and its compatibility is excellent because its height can be adjusted.

In addition, the structure lifting device according to the present invention is not based on the hydraulic pressure is excellent in stability and easy to make, it is also easy to adjust the height.

Claims (14)

In the teaching device comprising a buffer support having a buffer member, an upper plate installed on the upper portion of the buffer member, a lower plate provided on the lower portion of the buffer member, It includes a height adjusting device installed on the upper or lower plate, The height adjustment device, A wedge member having an upper surface and a lower surface arranged to be narrower in one direction; A wedge bottom member which is in contact with a bottom surface of the wedge member and has an upper surface of the same slope as the bottom surface of the wedge member; A wedge upper surface member which is in contact with an upper surface of the wedge member and has a same slope as the upper surface of the wedge member, and has a bottom surface disposed to be inclined with an upper surface of the wedge bottom member, the height of which changes in accordance with the front and back positions of the wedge member; And And a wedge member moving means which is supported on one end of the wedge bottom surface member and the wedge top surface member to adjust the forward and backward positions of the wedge member. The load cell is interposed between the wedge member moving means and the end of the wedge upper surface member or the end of the wedge bottom surface member, or between the wedge member moving means and the wedge member. Device. The method of claim 1, wherein the top plate and the wedge bottom member is characterized in that the unit is configured integrally. The method of claim 1, wherein the lower plate and the wedge upper surface member is a pedestal device, characterized in that configured integrally. The method of claim 1, wherein the wedge member, the wedge upper surface member and the contact surface of the wedge bottom member, the stainless steel plate and the PTFE member is attached to the corresponding surface, respectively. According to claim 1, wherein the wedge member is formed with a hole along the longitudinal direction of the wedge member, the wedge member moving means is inserted into the hole and the end is coupled to the bolt and the protruding bolt protruding in the opposite side And a nut supported at one end of the wide surface of the wedge member and the other supported at the end of the upper surface of the wedge member or the bottom surface of the wedge member. According to claim 1, wherein the wedge member is formed with a fastening hole formed with a spiral on the inner peripheral surface along the longitudinal direction of the wedge member, the wedge member moving means is coupled to the fastening hole one end and the other end of the wedge bottom member or wedge A chair device, characterized in that supported on the upper member. The wedge member, the wedge bottom member, and the wedge top member, at least one of the wedge member, the wedge bottom member and the wedge top member are not separated from the side in the same direction. A guide device, characterized in that the guide jaw is formed to guide to move to. A wedge member having an upper surface and a lower surface arranged to be narrower in one direction; A wedge bottom member which is in contact with a bottom surface of the wedge member and has an upper surface of the same slope as the bottom surface of the wedge member; A wedge upper surface member which is in contact with an upper surface of the wedge member and has a same slope as the upper surface of the wedge member, and has a bottom surface disposed to be inclined with an upper surface of the wedge bottom member, the height of which changes in accordance with the front and back positions of the wedge member; And And a wedge member moving unit, which is supported by one end of the wedge bottom surface member or the wedge top surface member, and configured to move forward and backward positions of the wedge member. 10. The structure pulling apparatus according to claim 9, wherein a load cell is interposed between the wedge member moving means and the end of the wedge upper surface member or the wedge bottom member or between the wedge member moving means and the end of the wedge member. . 11. The structure pulling apparatus according to claim 9 or 10, wherein a stainless steel plate and a PTFE member are attached to corresponding surfaces of the wedge member, the wedge upper face member, and the wedge bottom face member, respectively. The wedge member according to claim 9 or 10, wherein the wedge member is formed with a hole along the longitudinal direction of the wedge member, the wedge member moving means is inserted into the hole and the end of the bolt and the protruding end oppositely And a nut coupled to the bolt, wherein one of the bolt and the nut is supported on the wide surface of the wedge member and the other is supported on the wedge top member or the wedge bottom member. The wedge member according to claim 9 or 10, wherein the wedge member is formed with a fastening hole having a spiral formed on the inner circumferential surface along the longitudinal direction of the wedge member, the wedge member moving means is one end is coupled to the fastening hole and the other end is the wedge Structure lifting device, characterized in that supported on the bottom member or the wedge upper surface member. The wedge member, the wedge bottom member and the wedge top member are guided so that the wedge member, the wedge bottom member and the wedge top member are moved in the same direction without being separated laterally. Structure lifting device, characterized in that the guide jaw is formed.

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