KR102440250B1 - Friction pendulum type seismic isolation support with fine tuned wedge - Google Patents

Abstract

The present invention, the upper block for supporting the bridge deck; a support block installed on the pier to support the upper block and the bridge top plate; a flow support part interposed between the upper block and the support block so that the support block and the upper block are in close contact with each other so as to be spaced apart; Limiting the flow amount of the upper block so as to limit the flow of the bridge top plate by the flow support part within a specific range, is installed in any one of the upper block or the support block, opposite the other one of the upper block or the support block wedges positioned to be; And the upper block or the support block and the wedge are installed in close contact so that the wedge to limit the flow direction of the upper block or the support block by the wedge to closely connect the wedge to the upper block or the support block. After a fine adjustment is performed so that the wedge and the upper block or the support block maintain a constant distance, after the wedge is connected in a slidable state by temporarily coupling the adjustment and fixing part when the wedge is installed. It is possible to fix the wedge, and since a plurality of the wedges are installed in close contact with the upper block or the support block, the load is concentrated on the wedge of any one or part of the plurality of wedges when the bridge top plate flows It is characterized in that it can be prevented.

Description

FRICTION PENDULUM TYPE SEISMIC ISOLATION SUPPORT WITH FINE TUNED WEDGE

The present invention relates to a friction pendulum type seismic isolation bearing having a fine-adjustable wedge, and more particularly, it is possible to prevent the vibration transmitted along the pier from being transmitted to the bridge deck when an earthquake occurs, and to be generated on the bridge deck. When the bridge deck and the pier are separated by the negative reaction force, it can prevent the connection part of the bridge deck and the pier from being damaged. This can be prevented, and the wedge can be installed by finely adjusting the position of the wedge so that the wedge and the restraint object provided in the plurality of connection parts are arranged in close contact with each other, so that when the bridge top plate and the pier are spaced apart, any one of the plurality of wedges Or it relates to a friction pendulum-type seismic isolating bearing having a fine-adjustable wedge that can prevent a load from being concentrated on a portion of the wedge.

In general, a bridge seat device is a device that transmits an impact load acting on the upper part of a bridge to a lower structure and absorbs the impact, and is a structurally important element in the durability and safety of the entire bridge structure.

Such a bridge seat device is implemented by various devices and methods, and recently, when constructing a bridge, it statically absorbs relative displacement due to temperature change, wind, and impact such as support, or horizontal force of the bridge top plate, thereby smoothly improving the seismic function of the bridge. In order to further extend the durability and lifespan, a spherical-type pedestal is installed between the bridge deck and the pier.

The above-mentioned spherical-type bridge seat apparatus has been proposed in Utility Model Registration No. 20-0398506 "Spherical-type bridge seat apparatus".

Briefly looking at the configuration of the spherical-type sitting device, it consists of a structure in which a sliding plate is coupled between an upper plate including a locking part and a lower plate including a groove in the inner center and wedges on both sides.

In addition, a side block for preventing negative reaction force is coupled to the wedge of the lower plate, and this side block is coupled to the space between the locking part and the locking part formed on the upper plate to limit the behavior of any one side has been

The spherical-type sitting device having the above configuration has a structure in which a sliding plate including an inner rubber pad can be replaced, so it is very practical.

The sliding plate replacement operation of the spherical-type pedestal device releases the coupling of the side block coupled to the wedge of the lower plate, and at the same time lifts the bridge top plate through the bridge lifting jack to remove the upper plate.

This is because it is difficult to replace the sliding plate when there is no operation of removing the upper plate due to interference between the engaging portion of the upper plate and the wedge formed on the lower plate.

On the other hand, when the removal operation of the upper plate is completed as described above, the replacement operation is completed by removing the existing sliding plate and then combining the new sliding plate.

However, when replacing the sliding plate through the replacement method as described above, the time to raise the bridge top plate must be made in a very narrow place for a very short time, and, in addition, the upper side up to a height that does not cause interference between the engaging part and the wedge Since the plate has to be raised, there is a problem that the working time is long along with the risk of working.

In order to solve this problem, Korean Patent Registration No. 10-0643015 (October 31, 2006) has proposed a "maintainable spherical-type pedestal seat device".

The basic configuration of the registered patent is similar to the registered utility model described above.

However, by dividing the locking part formed on the upper plate from the upper plate and then fastening it through bolts, interference with the wedge does not occur, so that even if there is no raising of the bridge upper plate through the lifting jack or the lifting operation is in progress It works to shorten the working time by allowing it to be raised to a low height.

The background technology of the present invention is disclosed in Republic of Korea Patent Publication No. 10-1401548 (Notice on May 29, 2014, title of invention: Seating device).

Since the bridge device according to the prior art does not have a separate technical configuration for adjusting the distance between the wedge and the bridge device that limits the behavior of the bridge deck, a plurality of wedges installed at the connection part of the bridge top plate and the pier are restrained objects. Since it is difficult to install to maintain a constant distance from the pier, if the bridge deck and the pier are separated by an earthquake or negative reaction force, the load may be concentrated on any one or part of the plurality of wedges and the wedge or the connecting part may be damaged. have.

Therefore, there is a need to improve it.

The present invention can prevent the vibration transmitted along the pier from being transmitted to the bridge deck when an earthquake occurs, and when the bridge deck and the pier are separated by the negative reaction force generated on the bridge deck, the connection part between the bridge deck and the pier It is possible to prevent damage, and it is possible to prevent the bridge top plate from being spaced apart more than necessary by the wedge installed at the connection part of the bridge top plate and the pier, and to keep the wedge provided in a plurality of connection parts and the restraint object in close contact with each other. Friction having a fine-adjustable wedge that can prevent the load from being concentrated on any one or part of a plurality of wedges when the bridge top plate and the pier are spaced apart because the wedge can be installed by finely adjusting the position of the wedge to be placed It aims to provide a pendulum type seismic isolation bearing.

The present invention, the upper block for supporting the bridge deck; a support block installed on the pier to support the upper block and the bridge top plate; a flow support part interposed between the upper block and the support block so that the support block and the upper block are in close contact with each other so as to be spaced apart; Limiting the flow amount of the upper block so as to limit the flow of the bridge top plate by the flow support part within a specific range, is installed in any one of the upper block or the support block, opposite the other one of the upper block or the support block wedges positioned to be; And the upper block or the support block and the wedge are installed in close contact so that the wedge to limit the flow direction of the upper block or the support block by the wedge to closely connect the wedge to the upper block or the support block. After a fine adjustment is performed so that the wedge and the upper block or the support block maintain a constant distance, after the wedge is connected in a slidable state by temporarily coupling the adjustment and fixing part when the wedge is installed. It is possible to fix the wedge, and since a plurality of the wedges are installed in close contact with the upper block or the support block, the load is concentrated on the wedge of any one or part of the plurality of wedges when the bridge top plate flows It is characterized in that it can be prevented.

In addition, the flow support unit of the present invention is interposed between the upper block and the support block, the flow block having a curved surface; a curved groove provided in the support block so that the flow block is movably seated; and a friction member interposed between the fluid block and the upper block, or between the fluid block and the support block, to prevent the upper block, the fluid block, or the support block from being abraded by friction. do it with

In addition, the upper block is integrally installed on the bottom surface of the bridge upper plate of the present invention, and the welding heat generated when the upper block and the bridge upper plate are integrally connected by welding is prevented from being transmitted to the friction member A sliding plate made of a stainless material is installed on the bottom surface of the upper block to do so, a barrier layer is applied between the sliding plate and the upper block, and the barrier layer includes heat-resistant paint or heat-resistant fiber.

In addition, the adjustment fixing portion of the present invention, an extension block extending from the upper block; and a first sliding hole formed in the wedge so that the first fastening member passes therethrough, and formed in a long hole shape so that the first fastening member is slidably fastened, wherein the first fastening member is connected to the first sliding hole part. When inserted and temporarily coupled to the extension block, the wedge is connected in a slidable state along the first fastening member, and after placing the wedge to maintain a constant distance with the upper block or the support block while moving the wedge forward or backward By completely coupling the first fastening member, the wedge is coupled to the upper block or the support block while maintaining a constant distance.

In addition, the adjustment fixing portion of the present invention, extending from the upper block, a first adjustment block provided with a first inclined portion; a second adjustment block bent from the wedge so as to overlap the first adjustment block and having a second inclined portion slidably seated on the first inclined portion; and a second sliding hole formed in the second control block and formed in a long hole shape so that the second fastening member slidably penetrates, and inserting the second fastening member into the second riding hole to allow the first When the adjustment block is temporarily coupled, the wedge is connected in a slidable state along the second fastening member, and while sliding the wedge along the first inclined portion and the second inclined portion, the wedge is the upper block or the support block. After arranging to maintain a constant distance from the second fastening member, it is characterized in that the wedge is coupled to the upper block or the support block while maintaining a constant distance.

In addition, the present invention further comprises a flow limiter for preventing the upper block from flowing more than necessary by restricting the vertical flow of the wedge when the bridge top plate is moved and the upper block is spaced apart from the horizontal direction. do it with

In addition, the flow limiting part of the present invention protrudes from the support block, and when the wedge moves upward past the upper end of the support block, it interferes with the wedge and includes a negative reaction force key to limit the flow of the wedge characterized in that

In addition, the present invention is characterized in that it further comprises a separation sensing unit for displaying the separation amount so that the operator can visually confirm the degree to which the bridge top plate is separated from the pier.

In addition, the separation sensing unit of the present invention, is installed on the upper block, the scale portion is provided with a scale; and a needle member installed on the support block to face the scale part, and when the upper block is spaced apart from the horizontal direction or moves in a straight line, the end of the needle member is spaced apart from the zero point of the scale to the degree of separation of the bridge top plate And it is characterized in that the degree of movement can be confirmed.

In addition, the adjustment fixing portion of the present invention, an extension block extending from the upper block; a bent block extending by being bent from the wedge so as to be adjacent to the extension block; a first fastening member passing through the bending block to be fastened to the extension block to fix the wedge; and the upper block or the support block and the wedge are interposed between the bent block and the extension block to maintain a constant distance between the wedge while moving the wedge forward or backward, and the wedge collides with the upper block or the support block and a spacer member for preventing the shock generated when it is transmitted through the wedge, and it is possible to constantly adjust the distance between the wedge and the upper block or the support block while changing the number of the spacer members do it with

1 is a cross-sectional view showing a friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to a first embodiment of the present invention.
2 is a fire resistant structural diagram of a friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to the first embodiment of the present invention.
3 is a view showing a separation sensing unit of a friction pendulum type seismic isolation bearing having a fine-adjustable wedge according to the first embodiment of the present invention.
4 is a state diagram showing a separation sensing unit of a friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to the first embodiment of the present invention.
5 is a view showing an arrangement state of a friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to the first embodiment of the present invention.
6 is a plan sectional view showing a friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to the first embodiment of the present invention.
7 is a cross-sectional view showing a friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to a second embodiment of the present invention.
8 is a cross-sectional view showing a friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to a third embodiment of the present invention.
9 is a view showing the embossing member of the friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to a fourth embodiment of the present invention.
10 is a view showing a buffer part of a friction pendulum type seismic isolation bearing having a fine adjustment wedge according to a fifth embodiment of the present invention.
11 is an exploded perspective view showing a buffer part of a friction pendulum type seismic isolation bearing having a fine-adjustable wedge according to a sixth embodiment of the present invention.
12 is an exploded perspective view showing a buffer part of a friction pendulum type seismic isolation bearing having a fine-adjustable wedge according to a seventh embodiment of the present invention.
13 is a cross-sectional view showing a friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to an eighth embodiment of the present invention.
14 is an enlarged view showing the spacing adjusting part of the friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to an eighth embodiment of the present invention.

Hereinafter, an embodiment of a friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to the present invention will be described with reference to the accompanying drawings.

In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of explanation.

In addition, the terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to intentions or customs of users and operators.

Therefore, definitions of these terms should be made based on the content throughout this specification.

1 is a cross-sectional view showing a friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to a first embodiment of the present invention, and FIG. It is a fire-resistance structural diagram of a letter-shaped seismic isolation bearing, and FIG. 3 is a view showing a separation sensing unit of a friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to the first embodiment of the present invention.

In addition, FIG. 4 is a state diagram showing the separation sensing part of the friction pendulum type seismic isolation bearing having a fine adjustment wedge according to the first embodiment of the present invention, and FIG. 5 is a fine adjustment type according to the first embodiment of the present invention. The arrangement state of the friction pendulum type seismic isolation bearing having a wedge is shown, and FIG. 6 is a plan sectional view showing the friction pendulum type earthquake isolation bearing having a fine adjustment wedge according to the first embodiment of the present invention.

1 to 6, the friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to an embodiment of the present invention includes an upper block 14 supporting the bridge top plate 10, and an upper block 14. and the support block 16 installed on the pier 12 to support the bridge top plate 10, and the upper block 14 and the support block 16 so that the support block 16 and the upper block 14 are in close contact with each other so as to be spaced apart. ) to limit the flow direction of the upper block 14 to limit the flow of the bridge top plate 10 by the flow support part 30 and the flow support part 30 in a specific direction, and the upper block 14 or A wedge 50 is installed in any one of the support blocks 16 and is disposed opposite to the other one of the upper block 14 or the support block 16, and the wedge to the upper block 14 or the support block 16 (50) includes an adjustment fixing part 70 that is connected to the upper block 14 or the support block 16 by precisely adjusting the position of the wedge 50 so that it is placed in close contact.

Therefore, when the bridge deck plate 10 flows and the upper block 14 is spaced apart from the horizontal direction, the bridge deck plate 10 and the pier 12 are spaced apart within a certain range by the operation of the flow support part 30, and the bridge deck plate ( It is possible to prevent the connection between 10) and the pier 12 from being damaged, and since the operation of the flow support part 30 is restricted in a certain direction by the wedge 50, the bridge top plate 10 flows more than necessary. it can be prevented

A plurality of flow support parts 30 are provided between the bridge top plate 10 and the plurality of piers 12 , and a wedge is provided between the upper block 14 and the support block 16 to limit the flow direction of the flow support part 30 . (50) is installed, while the position of the wedge 50 is minutely moved so that a plurality of wedges 50 are arranged at a constant distance to the restraint object when the wedge 50 is installed, a plurality of wedges 50 are each It can be installed to keep the same distance from the restrained object.

The wedge 50 of this embodiment is installed in the extension block 72 that is installed to extend in the downward direction from the side surface of the upper block 14, is arranged to extend in the inner direction of the pier 12 from the extension block, and supports Since it is disposed opposite to the side of the block 16, the technical configuration constrained by the wedge 50 becomes the support block 16, and the wedge 50 fixed to the upper block 14 is combined with the bridge top plate 10. Since it is interfered by the support block 16 while flowing, the flow amount of the bridge deck 10 is limited in a certain direction.

The upper block 14 is integrally installed on the lower surface of the bridge top plate 10, and the lower surface of the upper block 14 has a groove formed concavely toward the upper side, and a sliding plate 36b made of a stainless material is installed, the sliding plate A barrier layer 36a is applied between the 36b and the upper block 14 .

This is to prevent the welding heat generated when the upper block 14 and the bridge top plate 10 are integrally connected by a welding operation from being transmitted to the first friction member 36 constituting the flow support part 30, The barrier layer 36a is made of heat-resistant paint, heat-resistant fiber, or the like.

The flow support part 30 of this embodiment is interposed between the upper block 14 and the support block 16, the flow block 32 having a curved surface, and the support block so that the flow block 32 is movably seated. The curved groove part 34 provided in (16) and the flow block 32 and the support block 16 or between the support block 16 and the upper block 14 are interposed, the upper block 14, the flow block 32 or a first friction member 36 and a second friction member 38 for preventing the support block 16 from being worn by friction.

Since the groove formed on the bottom surface of the upper block 14 has a greater curvature than the curved groove portion 34 formed on the upper surface of the support block 16 , the flow block interposed between the upper block 14 and the support block 16 . (32) is formed in an elliptical shape forming a convex curved surface with a relatively small curvature on the bottom surface and a gentle curved surface on the upper surface.

Therefore, when vibration is transmitted along the pier 12 by an external force such as an earthquake, the support block 16 integrally installed on the pier 12 may flow, and at this time, the support block 16 centered on the flow block 32 ( As the 16) and the upper block 14 flow, it is possible to prevent the vibration transmitted along the pier 12 from being transmitted to the bridge top plate 10 .

In addition, it is possible to prevent the connecting portion between the pier 12 and the bridge top plate 10 from being deformed or damaged by the vibration transmitted through the pier 12 .

The wedge 50 of this embodiment is installed by the adjustment fixing part 70 on the extension block 72 extending downward from the side surface of the upper block 14, and a pair of wedges 50 are opposed to each other so that the upper block ( 14), the flow direction is restricted so that the upper block 14 does not flow in the direction in which the wedge is installed because it is installed on one side and the other side.

At this time, since the wedge 50 of this embodiment is installed such that a pair of wedges 50 are maintained on both sides of the support block 16 to maintain a fine angle, respectively, by the adjustment fixing part 70, the bridge top plate 10 will flow. At this time, since the wedge 50 flows finely in the installed direction, the bridge top plate 10 flows finely in the wedge-installed direction, and can move within a certain range only in the direction in which the wedge is not installed.

The adjustment fixing part 70 of this embodiment is formed on the wedge 50 so that the extension block 72 extending from the upper block 14 and the first fastening member 74 pass through, the first fastening member 74 ) includes a first sliding hole portion 76 formed in a long hole shape so as to be slidably fastened.

A plurality of first sliding hole portions 76 are formed at regular intervals at the outer end of the wedge 50 , and the first fastening member 74 is first sliding in a state in which it is disposed in close contact with the lower end of the extension block 72 . When it is fastened to the bottom surface of the extension block 72 through the hole 76 , the wedge 50 is connected to the lower end of the extension block 72 .

Therefore, when installing the wedge 50 at the lower end of the extension block 72, the inner end of the wedge 50 is arranged to maintain a constant interval on the side surface of the support block 16, and the first fastening member through the first sliding hole After inserting and temporarily coupling the wedge 50 to the support block 16 side while maintaining a constant distance, while checking the gap between the wedge 50 and the support block 16, the first fastening member is extended to the extension block 72 can be coupled to

Even if a plurality of wedges 50 are installed by the operation as described above, each wedge 50 can be installed on the side surface of the support block 16 while maintaining the same distance, so that the flow in the bridge deck 10 is When a load is applied to the wedge 50, a uniform load is distributed and transmitted to the plurality of wedges 50, so that it is possible to effectively limit the flow of the bridge top plate 10, and any of the plurality of wedges 50 It is possible to prevent the load from being concentrated on one or a portion of the wedge 50 , thereby preventing the wedge 50 from being deformed or damaged.

The seismic isolation bearing of this embodiment is supported by a plurality of piers 12 installed in multiple portions of the bridge top plate 10 and supporting the bridge deck plate 10, as shown in FIGS. 5 and 6, one About 30 earthquake isolation bearings supporting the bridge top plate 10 are installed, and in the earthquake isolation bearing installed in the center of the bridge top plate 10, four wedges 50 are installed and the support block 16 is installed on the four sides of the support block 16. Each wedge 50 is installed to maintain a small gap of about 5 mm to prevent the flow of the upper block 14, the fixed end support 100 is installed.

In addition, among a plurality of seismic isolation bearings installed on the bridge top plate 10, the seismic isolation bearing disposed on the same line as the fixed end bearing 100 is a one-way bearing that allows the flow of the upper block 14 in only one direction ( 110) is installed, and the one-way support 110 is applied to the seismic isolation support disposed on two straight lines formed in a '+' shape from the fixed end support 100 .

In addition, since the wedge 50 is not installed in the rest of the seismic isolation bearings where the fixed end bearing 100 and the one-way bearing 110 are not installed, the upper block 14 is supported movably in both directions. is installed

As described above, the fixed end support 100 is installed in the central part of the bridge deck plate 10, and the center line extending from the central part of the bridge top plate 10 in the longitudinal direction of the bridge deck plate 10 and the bridge top plate 10 A one-way support 110 is installed on the center line extending in the width direction from the central portion so that the upper block 14 can flow in the same direction as the extension direction of the center line, respectively.

Therefore, when a separation occurs between the bridge deck plate 10 and the pier 12 as the bridge deck plate 10 expands or contracts due to seasonal changes, when vibration is transmitted from the pier 12 due to the occurrence of an earthquake, and a vehicle When the bridge deck plate 10 and the pier 12 are spaced apart, such as when the bridge deck plate 10 and the pier 12 are spaced apart due to a negative reaction force formed by the bridge deck plate 10, the bridge deck plate 10 When the upper block 14 integrally provided in the spaced apart while sliding along the flow block 32, the flow block 32 is slid along the curved groove of the support block 16 and spaced apart, the bidirectional support 130 and The one-way support 110 supports the bridge top plate 10 and the pier 12 to be spaced apart within a certain range, and the one-way support 110 and the fixed end support 100 support the bridge deck plate 10 and the pier 12 ) so that the spaced range is limited within a certain range, it is possible to prevent the connection part between the bridge top plate 10 and the pier 12 from being damaged.

In addition, the present embodiment further includes a separation sensing unit 80 for displaying the separation amount so that the operator can visually confirm the degree to which the bridge top plate 10 is separated from the pier 12 .

The separation sensing unit 80 of this embodiment is installed on the upper block 14, the graduations 82 having graduations, and the needle member installed in the support block 16 so as to face the graduations 82. (84).

Therefore, when the upper block 14 is spaced apart from the horizontal direction or moves linearly, the end of the needle member 84 is spaced apart from the zero point of the scale, so that the separation and movement of the bridge top plate 10 can be checked.

As described above, since the scale part 82 installed on the upper block 14 and the needle member 84 installed on the support block 16 are disposed to face each other, it is resistant to vibration transmitted from a vehicle passing through an earthquake or a bridge. When the bridge top plate 10 is spaced apart from the pier 12 by this, the end of the needle member 84, which was directed to the zero point of the scale, is spaced upward or downward, indicating the degree to which the bridge deck plate 10 is spaced apart.

In addition, as the expansion joint installed on the bridge deck 10 expands or contracts according to the change of season, a linear motion of the bridge deck 10 forward or backward occurs. At this time, the needle member 84 moves away from the zero point. By checking the distance, it is possible to determine the amount of movement of the bridge deck 10 .

The scale of this embodiment is arranged at regular intervals along the longitudinal direction of the upper block 14 from the zero point, and the first scale 82a for measuring the forward or backward linear motion distance of the bridge top plate 10, and the upper block It is provided while maintaining a constant interval in the vertical direction of (14), and includes a second scale (82b) that can check the amount of separation of the bridge top plate (10) by measuring the degree of rise or fall of the needle member (84).

In this embodiment, the first scale 82a and the second scale 82b are simultaneously provided on the panel or sheet forming the scale portion 82 , and the needle member 84 extending from the support block 16 is the first Since the scale (82a) and the second scale (82b) are disposed opposite to each other, the position of the needle member 84 can be confirmed to check the distance and the amount of movement of the bridge top plate 10 at the same time.

In the needle member 84 of this embodiment, the first needle 85, the second needle 86, and the third needle 87 are arranged so as to maintain a constant interval, so that the three needle members 84 are scaled at the same time. It is arranged opposite to the bridge top plate 10, it is possible to accurately check the spaced angle.

In addition, the first needle 85, the second needle 86, and the third needle 87 may be formed in a fork shape by connecting the lower ends, and the first needle 85, the second needle 86 and the third needle 87 When the three needles 87 are integrally connected, they are installed on the support block 16 by the submerging support 88 for supporting the needle member 84 .

The support block 16 of this embodiment is made of a quadrangle as shown in FIG. 6, and in the sitting device of this embodiment, the wedge 50 is disposed on the four sides of the support block 16 to face each fixed end. A support 100, a one-way support 110 in which a wedge 50 is disposed to face each other on two opposite sides of the four sides of the support block 16, and a two-way support 130 in which the wedge 50 is not installed ) can be achieved.

The plurality of pedestal devices installed on the lower surface of the bridge top plate 10 may include a fixed end support 100, a one-way support 110, or a two-way support 130, and the bridge head installed in the center of the bridge top plate 10 The teeth are installed as a one-way support 110 so as to be able to flow in the longitudinal direction of the bridge top plate 10 .

In addition, a plurality of pedestal devices arranged in the central part of the bridge deck 10 at intervals in the width direction are installed as a one-way support 110 so as to be able to flow in the width direction of the bridge top plate 10 .

One pedestal device installed in the middle of the bridge deck 10 is installed as a fixed end support 100 that restricts both directions of flow by four wedges 50, so that the bridge deck 10 is installed by vehicle traffic. When it flows, the bridge deck 10 is allowed to flow within a certain range, and when vibration is transmitted from the pier 12 due to the occurrence of an earthquake, the vibration transmitted along the pier 12 is transmitted to the bridge deck 10 can be prevented.

7 is a cross-sectional view showing a friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to a second embodiment of the present invention.

7, the adjustment fixing part 170 of the friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to the second embodiment of the present invention extends from the upper block 14, and the first inclined part ( 172a) is provided with a first adjustment block 172, and a second inclined portion ( A second adjustment block 174 having a 172b) and a second sliding hole portion 176 formed in the second adjustment block 174 and formed in an elongated shape so that the second fastening member 178 slidably penetrates therethrough. includes

The first adjustment block 172 of this embodiment is provided with a first inclined portion 172a which is inclined in the lateral direction, and the second adjustment block 174 formed by bending upward from the inner end of the wedge 50 has the second A second inclined portion 172b having the same or similar angle to the first inclined portion 172a is provided.

Therefore, when the second adjustment block 174 is seated on the first inclined portion 172a of the first adjustment block 172 by the second fastening member 178, the second adjustment block 174 is the first inclined portion 172a. ) and the second inclined portion 172b is arranged to slide in the downward direction.

Therefore, while sliding the first adjusting block 172 and the second adjusting block 174, the end of the wedge 50 is placed in close contact with the side of the support block 16, and then the second fastening member 178 is fastened to the wedge ( The end of the 50) can be coupled to the wedge 50 in a state of maintaining a constant distance to the side of the support block 16.

At this time, as the first inclined portion 172a and the second inclined portion 172b are sliding with each other, the second fastening member 178 in a pre-coupled state without being completely coupled to each other slides along the second sliding hole portion 176. After adjusting the position of the wedge 50 with the pair of wedges 50 maintaining a constant distance on both sides of the support block 16, the second fastening member 178 is completely coupled to the pair of wedges 50 ) can be installed on both sides of the support block 16 while maintaining the same distance.

8 is a cross-sectional view showing a friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to a third embodiment of the present invention.

8, the friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to the present invention is vertical of the wedge 50 when the bridge top plate 10 flows and the upper block 14 is spaced apart from the horizontal direction. It further includes a flow restrictor for restricting the flow in the direction to prevent the upper block 14 from flowing more than necessary.

Therefore, when the bridge top plate 10 flows upward by the negative reaction force generated by vehicle traffic, the wedge 50 is prevented from flowing upward so that the upper block 14 and the bridge deck plate 10 flow upward. it can be prevented

The flow limiting part of this embodiment protrudes from the support block 16, and when the wedge 50 is moved upward past the upper end of the support block 16, it interferes with the wedge 50 to limit the flow of the wedge 50 It includes a sub-reaction force key (90).

As described above, the negative reaction force key 90 interferes with the end of the wedge 50 so that the end of the wedge 50 does not flow upward when the bridge top plate 10 and the upper block 14 flow upward. Thus, it is possible to prevent the upper block 14 and the bridge top plate 10 from flowing upward.

9 is a view showing the embossing member of the friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to a fourth embodiment of the present invention.

Referring to Figure 9, the flow block 32 of this embodiment is provided with an embossing member (32a) that maintains a constant interval and protrudes a plurality of pieces to increase the friction coefficient between the friction member 38 and the flow block 32. When the flow block 32 slides along the curved groove portion 34 of the support block 16 by the flow of the bridge top plate 10, a plurality of embossing members 32a interfere with the friction member 38 while the flow block ( 32) will reduce the sliding speed and moving distance.

Therefore, it is possible to prevent the bridge device from being damaged as the flow block 32 slides more than necessary by the vibration applied to the bridge top plate 10 or the vibration transmitted along the pier 12 .

10 is a view showing a buffer part of a friction pendulum type seismic isolation bearing having a fine adjustment wedge according to a fifth embodiment of the present invention.

Referring to FIG. 10 , the first sliding hole portion 76 of this embodiment includes a buffer portion 77 interposed between the first fastening member 74 and the first sliding hole portion 76 to absorb impact, so that the bridge top plate is provided. When (10) flows and the first fastening member 74 moves along the first sliding hole part 76, the first fastening member 74 collides with the inner wall of the first sliding hole part 76, and the first fastening member (74) or the first sliding hole portion 76 can be prevented from being damaged.

The buffer portion 77 of this embodiment is provided on the inner wall of the first sliding hole portion 76 so as to cover the inner wall of the elastic sheet 77a and the elastic sheet 77a installed at the inner wall end of the first sliding hole 76. and a metal sheet 77b.

As described above, since the elastic sheet 77a and the metal sheet 77b are integrally connected and installed on the inner wall of the first sliding hole portion 76, the first fastening member 74 slides while the end of the first sliding hole portion 76. If it collides after moving up to, the first fastening member 74 collides with the metal sheet 77b, and then the elastic sheet 77a is compressed to absorb the shock.

In addition, the buffer portion 77 of this embodiment may be installed at both ends of the first sliding hole portion 76, and the elastic sheet 77a is interposed between a pair of metal sheets 77b to form a first sliding hole portion ( 76) can be installed.

In addition, the buffer part 77 of this embodiment is installed on the end of the wedge 50 or the side of the support block 16 so as to be interposed between the end of the wedge 50 and the side of the support block 16, the wedge 50 It includes a buffer member 52 that offsets the outer wall generated while the end of the support block 16 collides.

Therefore, as the bridge top plate 10 flows, the end of the wedge 50 and the support block 16 are prevented from colliding, and as the bridge top plate 10 and the pier 12 are spaced apart, the end of the wedge 50 is a support block The buffer member 52 is formed long along the side of the support block 16 to prevent the end of the wedge 50 and the side of the support block 16 from being worn when sliding along the side of the 16. can

11 is an exploded perspective view showing a buffer part of a friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to a sixth embodiment of the present invention, and FIG. 12 is a fine-adjustable wedge according to a seventh embodiment of the present invention. It is an exploded perspective view showing the buffer part of the friction pendulum type seismic isolation bearing.

11 and 12, the buffer part 77 according to the sixth embodiment of the present invention is provided with a support panel 74a for supporting the bottom surface of the first sliding hole part 76, and the support panel 74a ) is formed with a long portion 74b through which the first fastening member 74 slidably passes, so after inserting the elastic sheet 77a and the metal sheet 77b into the first sliding hole portion 76, the wedge 50 When the first fastening member 74 is fastened by adhering the support panel 74a to the bottom surface, the elastic sheet 77a and the metal sheet 77b are supported by the support panel 74a and the elastic sheet 77a from the wedge 50. ) and the metal sheet 77b can be prevented from being separated.

In addition, in the buffer unit 77 according to the seventh embodiment of the present invention, a stepped portion 76a is formed on the upper portion of the first sliding hole portion 76, and the elastic sheet 77a and the metal sheet 77b are on the upper portion. Since the protruding sheet 77c protruding in the lateral direction is provided, when the elastic sheet 77a and the metal sheet 77b are inserted into the first sliding hole portion 76, the protruding sheet 77c is engaged with the stepped portion 76a. It is possible to prevent the elastic sheet (77a) and the metal sheet (77b) from being separated from the first sliding hole (76).

In addition, the buffer portion 77 of this embodiment, the elastic sheet (77a) and the metal sheet (77b) may be formed by alternately stacking, a plurality of elastic sheets (77a) without the metal sheet (77b) may be formed by stacking. and a plurality of metal sheets 77b may be stacked without an elastic sheet 77a.

Since this can be easily changed and implemented by those skilled in the art who recognize the technical configuration of the present embodiment, detailed drawings and descriptions of other embodiments will be omitted.

13 is a cross-sectional view showing a friction pendulum-type seismic isolation bearing having a fine-adjustable wedge according to an eighth embodiment of the present invention, and FIG. It is an enlarged view showing the spacing adjusting part of the letter-shaped seismic isolation bearing.

13 and 14, the adjustment fixing part 270 of this embodiment is bent from the wedge 50 so as to be adjacent to the extension block 272 extending from the upper block 14, and the extension block 272, The extended bending block 277, the first fastening member 274 passing through the bending block 277 and being fastened to the extension block 272 to fix the wedge 50, and the wedge 50 while moving forward or backward Interposed between the bending block 277 and the extension block 272 to maintain a constant distance between the upper block 14 or the support block 32 and the wedge 50, the wedge 50 is the upper block 14 Alternatively, it includes spacers 276 and 278 for preventing the shock generated when the support block 32 collides from being transmitted through the wedge 50 .

Therefore, when fixing the wedge 50 to the upper block 14, the wedge 50 and the support block ( 16) can be adjusted uniformly, and when the position of the wedge 50 is determined, the wedge 50 can be fixed to maintain a constant distance from the support block 16 by fastening the first fastening member 274. there will be

The spacing members 276 and 278 of this embodiment include a metal panel 276 made of a metal material and an elastic panel 278 interposed between the plurality of metal panels 276, so a plurality of metal panels 276 and A plurality of elastic panels 278 may be alternately interposed in the gap between the extension block 272 and the flex block 277 to adjust the gap between the extension block 272 and the flex block 277, and the spacing member 276 , 278) and the extension block 272 or the flex block 277 by placing the metal panel 276 on the outer wall and rubbing the extension block 272 or the flex block 277 is rubbed, the spacer members (276, 278) wear can be prevented.

Accordingly, it is possible to prevent the vibration transmitted along the pier from being transmitted to the bridge deck when an earthquake occurs, and when the bridge deck and the pier are separated by the negative reaction force generated on the bridge deck, the connection part of the bridge deck and the pier is damaged. It is possible to prevent the bridge top plate from being spaced apart more than necessary by the wedge installed at the connection part of the bridge top plate and the pier, and the wedge provided in a plurality of connection parts and the restraint object are placed in close contact with each other. Friction Jin having a fine-adjustable wedge that can prevent the load from being concentrated on any one or part of a plurality of wedges when the bridge top plate and the pier are spaced apart because the wedge can be installed by adjusting the position of the wedge as finely as possible It is possible to provide a shape seismic isolation bearing.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and various modifications and equivalent other embodiments are possible by those of ordinary skill in the art to which the present invention pertains. will understand

In addition, although the friction pendulum-type seismic isolation bearing having a fine-adjustable wedge has been described as an example, this is only an example, and the seismic isolation bearing of the present invention is also applied to products other than the friction pendulum-type seismic isolating bearing having a fine-adjustable wedge. this can be used

Therefore, the true technical protection scope of the present invention should be defined by the following claims.

10: bridge deck 12: pier
12a: column member 14: upper block
16: support block 30: floating support part
32: flow block 34: curved groove part
36: first friction member 38: second friction member
50: wedge 52: buffer member
70, 170: adjustment fixing part 72: extension block
74: first fastening member 76: sliding hole part
78: connection plate 80: separation sensing unit
82: scale part 82a: first scale
82b: second scale 84: needle member
85: first needle 86: second needle
87: third needle 88: immersion support
90: negative reaction force key

Claims (10)

an upper block supporting the bridge deck; a support block installed on the pier to support the upper block and the bridge top plate; a flow support part interposed between the upper block and the support block so that the support block and the upper block are in close contact with each other so as to be spaced apart; Limiting the flow amount of the upper block so as to limit the flow of the bridge top plate by the flow support part within a specific range, is installed in any one of the upper block or the support block, opposite the other one of the upper block or the support block wedges positioned to be; And the upper block or the support block and the wedge are installed in close contact so that the wedge to limit the flow direction of the upper block or the support block by the wedge to closely connect the wedge to the upper block or the support block. It includes a government, wherein the flow support unit is interposed between the upper block and the support block, the flow block having a curved surface; a curved groove portion provided in the support block so that the flow block is movably seated; and a friction member interposed between the fluid block and the upper block, or between the fluid block and the support block, to prevent the upper block, the fluid block, or the support block from being worn by friction, The isolation bearing is installed in multiple portions of the bridge top plate 10 and supported by a plurality of the piers 12 supporting the bridge top plate 10, and the earthquake that is installed in the center of the bridge top plate 10 In the isolation support, the four wedges 50 are installed so that the wedges 50 are installed on the four sides of the support block 16 to maintain an interval, respectively, and a fixed end to prevent the flow of the upper block 14 . A bearing 100 is installed, and the seismic isolation bearing disposed on the same line as the fixed end bearing 100 is provided with a one-way bearing 110 that allows the flow of the upper block 14 in only one direction, and the The one-way support 110 is applied to the seismic isolation support disposed on two straight lines formed in a '+' shape from the fixed end support 100, and the fixed end support 100 and the one-way support 110 ), the rest of the seismic isolation bearing is not installed with the wedge 50, so the upper block 14 is supported movably in both directions. In the shape seismic isolation bearing,
The flow block 32 is provided with an embossing member 32a which protrudes at a constant distance and increases the friction coefficient between the friction member 38 and the flow block 32,
The adjustment fixing unit,
an extension block extending from the upper block; and
and a first sliding hole formed in the wedge so that the first fastening member penetrates, and formed in a long hole shape so that the first fastening member is slidably fastened;
Since the first sliding hole portion 76 is provided with a buffer portion 77 interposed between the first fastening member 74 and the first sliding hole portion 76 to absorb an impact, the bridge top plate 10 flows. and the first fastening member 74 collides with the inner wall of the first sliding hole part 76 when the first fastening member 74 moves along the first sliding hole part 76, and the first fastening member (74) or the first sliding hole 76 can be prevented from being damaged,
The buffer part 77 has a stepped part 76a formed on the upper portion of the first sliding hole part 76, and protrudes laterally on the elastic sheet 77a and the metal sheet 77b of the buffer part. Since the sheet 77c is provided, when the elastic sheet 77a and the metal sheet 77b are inserted into the first sliding hole portion 76, the protruding sheet 77c is engaged with the stepped portion 76a and the A friction pendulum type seismic isolation bearing having a fine-adjustable wedge, characterized in that it can prevent the elastic sheet (77a) and the metal sheet (77b) from being separated from the first sliding hole part (76).


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