KR101287944B1 - Sliding elastic supporting apparatus with restraint member restraining shearing deformation of elastic body - Google Patents

Abstract

PURPOSE: A bridge sliding elastic support including a constraining member suppressing shear deformation of an elastic body is provided to smoothly accommodate movement rates of an upper structure and to suppress vertical displacement of a structure caused by the excessive shear deformation of the elastic body. CONSTITUTION: A bridge sliding elastic support including a constraining member suppressing shear deformation of an elastic body comprises an upper flange plate (110), a lower flange plate (120), an elastic body (130), a constraining member (140), and sliding members (151,152). The upper flange plate is connected to an upper structure of a bridge, and the lower flange plate is connected to a lower structure of the bridge. The elastic body is installed on between the upper flange plate and the lower flange plate in order to fix a lower end plate (132) to the lower flange plate. The constraining member is installed inside the elastic body in a column shape and constrains the elastic body in order to prevent the shear deformation. The sliding members are installed between the upper flange plate and the elastic body and slide between both sides.

Description

SLIDING ELASTIC SUPPORTING APPARATUS WITH RESTRAINT MEMBER RESTRAINING SHEARING DEFORMATION OF ELASTIC BODY}

The present invention relates to an elastic bearing for a bridge, and in particular, by providing a restraining member of a simple form, by inducing the elastic body to slide without shear deformation at a point where the relative displacement of the upper structure is large with respect to the lower structure such as both end regions of the long bridge. The bridge is provided with a restraining member that smoothly accommodates the amount of movement of the superstructure, while restraining the shear deformation of the elastic body to prevent the structure from being oversized and economically lost due to excessive shear deformation of the elastic body. It relates to a sliding elastic bearing for.

In general, between the bridge girder constituting the upper structure of the bridge and the pier constituting the lower structure, it receives the vertical load acting on the upper structure and the relative displacement caused by seasonal temperature change, wind, earthquake, etc. An elastic bearing is installed to accommodate the shear displacement in the horizontal direction to extend the service life of the bridge.

The elastic bearing plays an important role in improving the durability of the bridge by absorbing various loads applied to the upper structure of the bridge, that is, the load of the bridge itself and the impact load and noise of the vehicle.

A typical structure of such an elastomeric bearing is shown in FIG.

Referring to FIG. 1, an elastic support 1 for a bridge according to the prior art includes an upper plate 2 fixed with an anchor to an upper structure 5 and a lower plate 3 fixed with an anchor to a bridge 6, and It is composed of an elastic body (4) installed between the lower plates (2, 3) and the reinforcing plate is disposed at equal intervals therein. Therefore, when the vertical load is applied, the elastic body 4 expands and exerts a buffering force and resistance, and when the horizontal load occurs, the elastic body 4 is shear-wound to about 150% of its thickness, thereby resisting the horizontal load. will be.

In addition, the elastic support 1 is provided with upper and lower wedges 7 and 8 to allow horizontal displacement in a specific direction but limit horizontal displacement in other directions. At this time, the bridge support elastic support 1 shown in Figure 1 is a one-way elastic support can move only in the direction in which the upper and lower wedges (7, 8) is not installed, the upper and lower wedges (7) Since the wedges 7 and 8 are caught from each other in the direction in which 8 is installed, the movement is limited. Although not shown in the drawings, wedges may be installed in all directions from the elastic bearing 1, in which case the horizontal displacement in all directions is limited as a fixed elastic bearing.

However, such a function of limiting the displacement in the horizontal direction in the one-way elastic bearing or the fixed elastic bearing is exhibited only in normal times, and in the case of a large external force that threatens the safety of the bridge itself, such as an earthquake, the wedges 7 and 8 By dropping as the) breaks, the elastic bearing 1 receives a larger shear deformation.

As described above, the elastic bearing 1 should be formed to allow the relative displacement of the alternating or pier 6 and the upper structure 5, so that it is installed in a structure capable of elastic deformation and elastic recovery by an elastic material. It is common.

On the other hand, as the elongation or contraction of the superstructure 5 occurs due to temperature change, a relative displacement occurs between the alternating or pier 6 and the superstructure 5, and this relative displacement occurs over the entire section of the bridge. It does not occur uniformly.

For example, when the upper structure 5 is elongated (thermal expansion) due to the high temperature in the summer, there is little occurrence of relative displacement between the pier 6 and the upper structure 5 located near the center of the plurality of pier 6, A very large relative displacement occurs between the alternating ends of the bridge and the superstructure 5.

This is because the upper structure 5 causes elongation deformation toward both ends relative to the center portion, and the same problem occurs even when shrinkage occurs due to low temperature in winter.

However, in the related art, the elastic support 1 having the same structure is uniformly applied without considering that the relative displacement between the alternation, the pier 6 and the upper structure 5 is different for each section of the bridge. Therefore, the relative displacement caused by the expansion, seismic load or wind load of the superstructure due to temperature change could not be effectively controlled.

That is, since the superstructure (5) is installed by placing the elastic support (1) having the same structure on the alternating and pier (6) uniformly, in the case of both ends of the bridge and the pier (6) and As the relative displacement between the upper structures 5 is large, breakage of the elastic support 1 occurs frequently.

In particular, due to excessive shear deformation of the elastic body 4, the upper structure 5 is displaced up and down, causing severe deformation of the upper structure, in order to prepare for the elastic support (1) and the structure is designed to enlarge, Economic losses were inevitable.

Conventionally, in order to solve the shear deformation problem of the excessive elastic support, a sliding surface may be made and applied to the upper surface of the elastic body. However, when the vertical load increases or the friction coefficient increases, the elastic body does not slide on the sliding surface and excessive shearing occurs. In some cases, the bearings may be deformed and the bearings may be damaged and seriously affecting the structure.

Therefore, there is an urgent need to develop a technology capable of efficiently coping with the shift or the relative displacement between the pier 6 and the superstructure 5 caused by the expansion, seismic load, wind load, etc. of the superstructure.

Accordingly, the present invention has been proposed to solve the conventional problems as described above, and an object of the present invention is to induce the elastic body to slide without shear deformation at a point where the relative displacement of the upper structure relative to the lower structure is large. The present invention provides a sliding elastic support for a bridge having a restraining member capable of smoothly accommodating an amount of movement and preventing breakage and up and down displacement of the support caused by excessive shear deformation of the elastic body.

In order to achieve the above object, a sliding elastic support for a bridge according to the technical idea of the present invention is an elastic support installed between a lower structure and a superstructure causing relative displacement therefrom, and an upper portion coupled to the upper structure. A flange plate; A lower flange plate coupled to the lower structure; An elastic body installed between the upper flange plate and the lower flange plate, and fixed to one of the upper flange plate and the lower flange plate; A sliding member installed between the other one of the upper flange plate and the lower flange plate to which the elastic body is not fixed and the elastic body to slide between the elastic body; And a constraining member connected between the upper end plate and the lower end plate in the elastic body to restrain the elastic displacement from shearing by restraining the relative displacement therebetween, thereby inducing sliding by the sliding member. It is characterized by technical configuration.

Here, one end of the restraining member is fixed to one of the upper end plate and the lower end plate of the elastic body, and the other end of the restraining member, one end of the restraining member of the upper end plate and the lower end plate of the elastic body. It may be characterized in that inserted into the insertion hole formed to pass through the other one that is not fixed with a clearance allowing vertical deflection.

In addition, one end of the restraining member is fixed to one adjacent to the upper flange plate and the lower flange plate in a state penetrating one of the upper end plate and the lower end plate of the elastic body, the other end of the restraining member And, one end of the restraining member of the upper end plate and the lower end plate of the elastic body may be inserted with a free space to allow vertical sag in the insertion hole formed in the form of the other one is not fixed.

In addition, the other end portion of the restraining member is further provided with a negative reaction force prevention portion formed in a form protruding along the circumferential direction, one of the upper flange plate and the lower flange plate located near the other end of the restraining member to prevent the negative reaction force It may be characterized in that the receiving portion for receiving the portion and the engaging portion that extends from the lower side to the negative reaction prevention portion accommodated in the receiving portion.

In addition, one end of the restraining member is fixed to any one of the upper end plate and the lower end plate of the elastic body, and the other end of the restraining member, one end of the restraining member of the upper end plate and the lower end plate of the elastic body. It may be characterized in that it is inserted with a free space allowing vertical deflection in the insertion groove formed in the other one not fixed.

In addition, one end of the restraining member is fixed to one adjacent to the upper flange plate and the lower flange plate in a state penetrating one of the upper end plate and the lower end plate of the elastic body, the other end of the restraining member One end of the restraint member of the upper end plate and the lower end plate of the elastic body may be inserted with a free space allowing vertical deflection in the insertion groove formed in the other one which is not fixed.

In addition, the elastic body may be characterized in that the air hole for communicating the free space and the outside air is provided.

In addition, the restraining member may be provided with a plurality.

In addition, the elastic body is provided with a deformation space formed to the left and right the restraining member may be characterized in that the elastic body allows the shear deformation in the left and right directions.

In addition, the deformation space may be formed across the entire elastic body.

In addition, the one of the upper flange plate and the lower flange plate in which the elastic body is not fixed is formed along the front and rear directions near the left and right sides of the elastic body so as to walk the elastic body shear deformation in the left and right directions but perpendicular to the left and right directions It may be characterized in that the pair of guide bar is further provided to guide the sliding in the front and rear direction.

In addition, the surface facing the elastic body and the guide bar may be characterized in that the stainless steel plate and the flat sliding bearing for reducing friction, respectively.

On the other hand, the sliding elastic bearing for the bridge according to the present invention, the upper flange plate coupled to the upper structure; A lower flange plate coupled to the lower structure; An elastic body installed between the upper flange plate and the lower flange plate, and fixed to one of the upper flange plate and the lower flange plate; A sliding member installed between the other one of the upper flange plate and the lower flange plate to which the elastic body is not fixed and the elastic body to slide between the elastic body; The elastic body is installed in a form spanning between the upper end plate and the lower end plate inside the elastic body, and is installed to be rotatable only in the left and right direction about the rotation axis to allow the elastic body to be sheared while rotating in the left and right direction, but the front and rear direction In the technical configuration may be characterized in that the rotation is suppressed to include a rotation restraining member that restrains the elastic body from shear deformation to induce sliding by the sliding member.

Herein, the rotation restraining member may be coupled to any one of the upper and lower end plates of the elastic body, the rotation shaft fixed with the longitudinal direction in the longitudinal direction, and the base having one end fixed to the rotation shaft. It is rotatably coupled and the other end may be characterized in that it comprises a rotating body that spans the other one of the upper end plate and the lower end plate is not coupled to the base.

On the other hand, the sliding elastic bearing for the bridge according to the present invention, the upper flange plate coupled to the upper structure; A lower flange plate coupled to the lower structure; An elastic body installed between the upper flange plate and the lower flange plate, and fixed to one of the upper flange plate and the lower flange plate; A sliding member installed between the other one of the upper flange plate and the lower flange plate to which the elastic body is not fixed and the elastic body to slide between the elastic body; The elastic body is installed to support the elastic body in the vicinity of the outer side of the elastic body, and is installed to be rotatable only in the left and right direction around the rotation axis to allow the elastic body to be sheared while rotating in the left and right direction, but the rotation is performed in the front and rear directions. It can be characterized in that it comprises a rotation restraining member which is suppressed to restrain the elastic body from being sheared and induces sliding by the sliding member.

Here, the rotation restraining member is coupled to any one of the rotating shaft fixed in the longitudinal direction of the front and rear, the upper flange plate and the lower flange plate to secure the rotating shaft, and one end is rotatable to the rotating shaft It may be characterized in that it comprises a rotating body coupled to the other end is coupled to one of the upper end plate and the lower end plate of the elastic body opposite to the base.

Sliding elastic support for a bridge according to the present invention, it is possible to induce sliding without the shear deformation of the elastic body by a simple restraining member provided only inside the elastic body. As a result, even when the relative displacement of the upper structure with respect to the lower structure is large, such as the area of both ends of the long bridge bridge, it smoothly accommodates the excessive amount of movement of the upper structure, while shearing in the case of a large vertical load or an elastic bearing having a large friction coefficient By inducing sliding without deformation, it is possible to prevent breakage of the elastic support due to excessive shear deformation of the elastic body or restraining vertical displacement of the structure, thereby preventing oversizing and economic loss of the structure.

In addition, the present invention can induce sliding by selectively allowing the shear deformation of the elastic body in the required direction by the configuration having a deformation space inside the elastic body and restrained from shear deformation in the other direction.

In addition, the present invention can induce the sliding by selectively allowing the shear deformation of the elastic body in the required direction by the configuration having a rotational restraint member of a simple form, and restraining not to shear deformation in the other direction.

In addition, the present invention can sufficiently accommodate the relatively small product even if the relative displacement of the upper structure with respect to the lower structure, such as the area of both ends of the long bridge.

BRIEF DESCRIPTION OF THE DRAWINGS Fig.
2a and 2b is a state of use of the sliding elastic support according to the first embodiment of the present invention.
Figure 3 is an exploded perspective view of the sliding elastic support according to the first embodiment of the present invention.
Figure 4 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic support according to the first embodiment of the present invention.
5 is a plan view of the sliding elastic support according to the first embodiment of the present invention.
Figure 6 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic support according to a second embodiment of the present invention.
7 is a plan view of the sliding elastic support according to a second embodiment of the present invention.
Figure 8 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic support according to a third embodiment of the present invention.
Figure 9 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic support according to a fourth embodiment of the present invention.
Figure 10 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic support according to a fifth embodiment of the present invention.
Figure 11 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic bearing according to the sixth embodiment of the present invention.
12 is a longitudinal sectional view for explaining the configuration of the sliding elastic support according to the seventh embodiment of the present invention.
13 is a plan view of the sliding elastic support according to the seventh embodiment.
Figure 14 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic support according to an eighth embodiment of the present invention.
15 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic support according to the ninth embodiment of the present invention.
Figure 16 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic bearing according to the tenth embodiment of the present invention.
Figure 17 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic bearing according to the eleventh embodiment of the present invention.
Figure 18 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic bearing according to the twelfth embodiment of the present invention.
19 is a plan view of the sliding elastic support according to a twelfth embodiment of the present invention.

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

2a and 2b is a state diagram used in the sliding elastic support according to the first embodiment of the present invention.

As shown, the sliding elastic support 100 according to the embodiment of the present invention includes both end regions (A1, A2) having a large relative displacement of the upper structure, such as the upper plate to the substructure, such as alternating or pier in the bridge. It can be installed over the whole area, and even if the elastic body has a tendency to cause shear deformation due to the relative displacement of the upper structure, the shear deformation of the elastic body is suppressed so that simple sliding can be induced to secure a damping effect due to frictional force. It is composed. The present invention is such a configuration, it is possible to overcome the limitation that the relative displacement of the upper structure and the lower structure is large, the movement amount can not be accommodated smoothly. For reference, in the conventional method, which only depended on the shear deformation of the elastic body, the height and the cross section of the elastic support were largely increased to accommodate the movement amount of the superstructure in the region of large relative displacement, which was not preferable in terms of efficiency and economy. In addition, in the case of the conventional sliding elastic bearing, when the vertical load increases or the friction coefficient increases, the sliding does not occur and the elastic body is excessively sheared, which seriously affects the damage of the bridge bearing and the stability of the structure.

Hereinafter, the configuration of the sliding elastic support for the bridge according to the embodiments of the present invention will be described in detail.

[First Embodiment]

3 is an exploded perspective view of the sliding elastic support according to the first embodiment of the present invention, Figure 4 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic support according to the first embodiment of the present invention. 5 is a plan view of the sliding elastic support according to the first embodiment of the present invention.

As shown, the sliding elastic support according to the first embodiment of the present invention is the upper flange plate 110 coupled to the upper structure of the bridge, the lower flange plate 120 coupled to the lower structure of the bridge, and the upper An elastic body 130 installed to fix the lower end plate 132 to the lower flange plate 120 between the flange plate 110 and the lower flange plate 120, and installed inside the elastic body 130 in the form of a column. Constraining member 140, and the sliding member (151, 152) is provided between the upper flange plate 110 and the elastic body 130 to slide between them.

In the first embodiment of the present invention, the restraining member 140 restrains the elastic body 130 so as not to be sheared, thereby playing a key role of inducing sliding by the sliding members 151 and 152. To this end, the constraining member 140 is made of a rigid body that is not easily deformed, and has a columnar shape inside the elastic body 130 and is installed in the vertical direction as described above, so that the upper end plate of the elastic body 130 ( 131 and the lower end plate 132 is connected across. Here, the lower end of the restraining member 140 is fixed to the lower end plate 132 of the elastic body 130 (or may be fixed to the lower flange plate 120 through the lower end plate 132), The elastic body 130 is inserted into and spanned through the insertion hole 131a formed to penetrate the upper end plate 131. In addition, the upper end of the restraining member 140 is not inserted into the insertion hole 131a and is inserted with the clearance space 131b upward. The clearance 131b is to allow vertical deflection of the upper flange plate 110 and the elastic body 130 caused by the load applied from the upper side. The free space 131b corresponds to an essential configuration, and if there is no free space 131b, the load applied from the upper side is not absorbed by the elastic body 130 and is transmitted as it is through the restraining member 140 made of steel. While the restraining member 140 according to the present invention is buckled, or excessive concentrated load acts on the concrete or the lower support member of the lower support, causing a fatal damage such as damage to the concrete or the lower support member of the lower support.

As such, the present invention is characterized in that the elastic body 130 is formed by a simple restraining member 140 which suppresses relative displacement between the upper end plate 131 and the lower end plate 132 in the elastic body 130. It is configured to induce sliding by the sliding members (151, 152) while restraining from shear deformation.

Note that the constraining member 140 made of a rigid body is strictly distinguished from a damping core such as a lead rod or tin rod that dissipates energy while being plastically deformed and installed inside the elastic body 130. They may be similar in shape to the restraining member 140, but may be said to be completely different from the materials and materials used, the purpose of installation, and the behavior.

In the case of lead or tin core, the seismic member 140 of the present invention absorbs seismic energy while deforming like an elastic bearing, while the restraining member 140 of the present invention constrains the shear deformation of the elastic bearing to cause slippage on the sliding surface of the upper surface of the elastic bearing. It is installed to

When the constraining member 140 made of a rigid body is provided in this way, the upper structure of the bridge is relatively displaced with respect to the lower structure, and the elastic body 130 is primarily caused by the sliding action of the sliding members 151 and 152 when the upper flange plate 110 moves. ), And the secondary load acts at a predetermined level or more, or foreign matter or dust is caught on the sliding surfaces of the sliding members 151 and 152, thereby increasing the friction coefficient, thereby causing shear deformation to the elastic body 130. Even if it has a tendency to cause the restraining member 140 is to restrain the shearing deformation by thoroughly restraining the elastic body 130 as a result can be expected a dual effect of inducing the sliding of the sliding members (151,152).

On the other hand, the sliding members (151, 152) to the sliding between each other between the upper flange plate 110 and the elastic body 130 serves to induce friction attenuation. To this end, the sliding members 151 and 152 may be configured by combining various materials in a pair. In the first embodiment, the stainless steel plate 151 coupled to the lower surface of the upper flange plate 110 and the elastic body ( The combination of the Teflon plate 152 coupled to the upper surface of 130. According to this configuration, even if the upper structure of the bridge is relatively displaced with respect to the lower structure such that the upper flange plate 110 is displaced along the upper structure, the stainless steel plate 151 and the Teflon plate 152 slide to each other and the excessive upper portion. It can accommodate the movement of the structure. In this process, the friction damping effect due to the contact between the stainless steel plate 151 and the Teflon plate 152 can be seen.

The elastic body 130 is installed between the upper flange plate 110 and the lower flange plate 120, the rubber 134 having an elastic force and a plurality of insert plates 133 disposed equally up and down space therein. It is provided. The upper end and the lower end are provided with an upper end plate 131 and a lower end plate 132 having a thicker thickness than the insert plate 133. The lower end plate 132 is fixed to the lower flange plate 120, the upper end plate 131 is fixed to the upper flange plate 110, instead of contacting so as to slide through the sliding members (151, 152). In the center thereof, an insertion hole 131a is formed so that the upper end of the restraining member 140 is inserted and spanned.

The elastic body 130 having such a configuration generally supports a person to which a vertical load is applied. In addition, the elastic body 130 has a tendency to shear deformation when a horizontal load is applied, in particular the vertical load of the upper structure is increased or the stainless steel plate 151 and the Teflon plate 152 is in contact with each other When the friction coefficient of the sliding surface is increased, the horizontal load is applied because the sliding of the sliding members 151 and 152 does not occur smoothly, and thus has a greater tendency to cause shear deformation. Of course, in all these cases, the restraining member 140 restrains the elastic body 130 to suppress shear deformation.

On the other hand, the sliding elastic bearing according to the present invention is possible in other embodiments modified in various forms, will be described below.

[Second Embodiment]

Figure 6 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic support according to a second embodiment of the present invention, Figure 7 is a plan view of the sliding elastic support according to a second embodiment of the present invention.

As shown, the second embodiment of the present invention is characterized in that a plurality of restraining members 140 are provided inside the elastic body 130 as compared with the first embodiment described above. However, although shown in the drawing is provided with the four restraining members 140, the number may be changed.

According to the configuration in which the plurality of restraining members 140 are provided in one elastic body 130 as described above, even when the cross-sectional area of the elastic body 130 is widened, the number of the restraining members 140 is increased instead of increasing the cross-sectional area of the restraining member 140. By increasing the shear deformation of the elastic body 130 can be suppressed without a hitch.

[Third Embodiment]

8 is a longitudinal sectional view for explaining the configuration of the sliding elastic support according to a third embodiment of the present invention.

As shown in the drawing, the third embodiment of the present invention has a through hole 131a formed in the center of the upper end plate 131 of the elastic body 130 as compared with the first embodiment. An insertion groove 131c is formed on a lower surface of the upper end plate 131. Even in this case, a clearance 131b is provided above the restraining member 140 in the insertion groove 131c to allow vertical sag of the upper flange plate 110.

As such, even when the insertion groove 131c is formed in the upper end plate 131 of the elastic body 130 instead of the insertion hole 131a, there is no difference in the configuration in which the upper end of the restraining member 140 is inserted and spanned.

[Fourth Embodiment]

9 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic support according to a fourth embodiment of the present invention.

As shown, the fourth embodiment of the present invention is characterized in that the air hole 115 is formed in the upper end plate 131 as compared with the first embodiment described above. The air hole 115 communicates the outside air with the free space 131b formed above the restraining member 140 in the insertion hole 131a. The air hole 115 is formed to reach the outside air while avoiding the place where the upper structure is located from the free space 131b.

According to such a configuration, it is possible to smoothly discharge the air existing in the free space 131b when the upper flange plate 110 is vertically sag.

Such an air hole 115 may be formed in the upper end plate 131 as shown in the figure and may also be formed in the lower surface of the upper flange plate 110. In addition, the air hole 115 may be formed in the lower end plate 132 or the lower flange plate 120 according to the position where the free space 131b is formed. Such an air hole 115 is preferably applied to all cases where the free space 131b is present in the above-described or later embodiments.

[Fifth Embodiment]

10 is a longitudinal sectional view for explaining the configuration of the sliding elastic support according to a fifth embodiment of the present invention.

As shown, the fifth embodiment of the present invention is compared with the first embodiment described above, the elastic body 130 is fixed to the lower flange plate 120 and the upper and upper flange plate 110 of the elastic body 130 On the contrary, the elastic member 130 is fixed to the upper flange plate 110 and the sliding members 151 and 152 are installed between the lower portion of the elastic body 130 and the lower flange plate 120. It is characterized by.

Accordingly, the upper end of the restraining member 140 is fixed to the upper end plate 131 of the elastic body 130, and the lower end of the restraining member 140 penetrates the lower end plate 132 of the elastic body 130. It is inserted in the insertion hole 132a formed in one shape with a free space 132b for sagging. The stainless steel plate 151 of the sliding members 151 and 152 is coupled to the upper surface of the lower flange plate 120, and the teflon plate 152 is coupled to the lower surface of the elastic body 130.

According to this configuration, when the upper structure relative displacement with respect to the lower structure of the bridge, the elastic body 130 and the restraint member 140, as well as the upper flange plate 110, as well as the upper structure moves, but the difference in the difference While the shear deformation of the 130 is suppressed, there is no significant difference in inducing sliding by the sliding members 151 and 152.

[Sixth Embodiment]

11 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic support according to the sixth embodiment of the present invention.

As shown, the sixth embodiment of the present invention is similar to the fifth embodiment in that the elastic body 130 is fixed to the upper flange plate 110, but the upper end of the restraining member 140 is the elastic body 130. It is characterized in that it is fixed to the upper flange plate 110 in a state penetrating the upper end plate 131 of.

In this case, although there is a disadvantage in that the insertion hole 131a should be additionally processed in the upper end plate 131 of the elastic body 130, there is an advantage that the restraining member 140 can be more stably fixed.

[Seventh Embodiment]

12 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic support according to the seventh embodiment of the present invention, Figure 13 is a plan view of the sliding elastic support according to the seventh embodiment.

As shown, the seventh embodiment of the present invention is characterized in that the deformation space (130a) formed to right and left the restraining member 140 in the interior of the elastic body 130 compared to the first embodiment described above. It is done.

As described above, the deformation space 130a formed on the left and right sides of the restraint member 140 serves to release the restraint by the restraint member 140 when the elastic body 130 tends to be sheared in the left and right directions. Allow the elastic body 130 to shear in the lateral direction. On the other hand, in the front and rear direction, the restraining member 140 still restrains the elastic body 130 to induce sliding while suppressing shear deformation.

(However, the left and right directions referred to in the seventh embodiment and other embodiments below are directions of relative concepts introduced for convenience of description in order to indicate a direction orthogonal to the front and rear directions mentioned later, and are limited to any one in the bridge. Make sure it is not meant to refer to a direction.)

In addition, in the seventh exemplary embodiment of the present invention, a pair of guide bars 160 formed along the front and rear directions to the left and right sides of the elastic body 130 are installed on the upper flange plate 110. The guide bar 160 walks so that the elastic body 130 is sheared in left and right directions, but guides so as to slide in front and rear directions to generate friction attenuation. Here, a stainless steel plate 161 and a planar sliding bearing 162 are installed on the facing surfaces of the elastic body 130 and the guide bar 160 to reduce friction.

[Example 8]

14 is a longitudinal sectional view for explaining the configuration of the sliding elastic support according to an eighth embodiment of the present invention.

As shown, the eighth embodiment of the present invention has a slight difference in the configuration for providing the deformation space 130a as compared with the seventh embodiment described above. That is, in the seventh exemplary embodiment, the deformation space 130a penetrates through the center of the upper end plate 131 of the elastic body 130 to the lower surface of the upper flange plate 110, but in the eighth exemplary embodiment The deformation space 130a does not penetrate the upper end plate 131 of the elastic body 130 and reaches only to the middle thereof.

[Example 9]

15 is a longitudinal sectional view for explaining the configuration of the sliding elastic support according to the ninth embodiment of the present invention.

As shown, the ninth embodiment of the present invention is characterized in that the deformation space 130a is formed completely across the elastic body 130 along the left and right directions as compared with the seventh embodiment described above. Accordingly, even in the case of the guide bar 160, the middle bar is provided as two divided objects spaced apart to correspond to the deformation space 130a.

As described above, the configuration according to the ninth embodiment further extends the range in which the elastic body 130 is sheared in left and right directions as compared with the seventh embodiment described above, and in the front and rear directions, the elastic body 130 is still restrained and sheared. Sliding is induced by suppressing deformation, but the shear deformation of the elastic body 130 is allowed to be freely made in the left and right directions.

[Example 10]

16 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic bearing according to the tenth embodiment of the present invention.

As shown, the tenth embodiment of the present invention is characterized in that the negative force preventing portion 140a is further provided at the upper end of the restraining member 140 as compared with the seventh embodiment described above.

The negative reaction force preventing part 140a has a wider cross-sectional area at the upper end of the restraining member 140 and is formed to protrude along the circumferential direction. Accordingly, the upper flange plate 110 includes a receiving portion 115a, which is a space for receiving the negative reaction force preventing part 140a, and a catching part that is in contact with a lower side of the negative reaction force preventing part 140a. 115 is provided. In addition, the upper flange plate 110 is preferably made of a combination of the upper object (110a) and the lower object (110b) to facilitate the formation of the receiving portion (115a) and the locking portion (115).

As described above, according to the configuration of the tenth exemplary embodiment, the upper flange plate 110 is stably held by the negative reaction force to be stably held by the negative reaction force prevention part 140a formed at the upper end of the restraining member 140. Therefore, it is possible to prevent the damage of the structure due to the reaction force.

[Example 11]

17 is a longitudinal sectional view for explaining the configuration of the sliding elastic support according to the eleventh embodiment of the present invention.

As shown, the eleventh embodiment of the present invention is rotatable in the left and right directions instead of the restraining member 140 that is completely fixed inside the elastic body 130 as compared with the previous embodiments, the elastic body 130 It is characterized in that it is provided with a rotation restraining member 170 inside the elastic body 130 to induce the sliding by allowing the shear deformation of the elastic body 130 is impossible to rotate in the front and rear direction to suppress the shear deformation of the elastic body 130.

The rotation restraint member 170 is coupled to a rotation shaft 172 having a longitudinal direction in the longitudinal direction, a base 173 coupled to the lower end plate 132 of the elastic body 130 to fix the rotation shaft 172, A lower end portion is rotatably coupled to the rotation shaft 172 and an upper end portion is formed of a rotating body 171 having a columnar shape that spans the upper end plate 131 of the elastic body 130.

In the eleventh embodiment, unlike the seventh to ninth embodiments described above, the deformation space 130a is formed inside the elastic body 130 by the simple configuration including the rotation restraining member 170 which is rotatable in the horizontal direction. It is possible to allow the shear deformation of the elastic body 130 in the required direction even if not provided. However, sliding can be induced by suppressing shear deformation in the front-rear direction.

[Twelfth Example]

18 is a longitudinal cross-sectional view for explaining the configuration of the sliding elastic support according to the twelfth embodiment of the present invention, Figure 19 is a plan view of the sliding elastic support according to the twelfth embodiment of the present invention.

As shown, in the twelfth embodiment of the present invention, the rotation restraining member 170 is not the inside of the elastic body 130, that is, the front and rear of the elastic body 130 compared to the eleventh embodiment described above. Characterized in the configuration installed in.

To this end, the rotation restraining member 170 is coupled to the rotary shaft 172 to the longitudinal direction in the longitudinal direction, the base 173 is coupled to the lower flange plate 120 to fix the rotary shaft 172, the lower end portion It includes a rotating body 171 is rotatably coupled to the rotating shaft 172 and the upper end is coupled to the upper end plate 131 of the elastic body 130. Here, the outer surface of the upper end plate 131 of the elastic body 130 and the upper end plate 131 of the elastic body 130 protrudes outwards to be coupled to the upper end of the rotating body 171 of the rotating body 171. A support 131f coupled with the upper end is provided.

In the case of the twelfth embodiment, the elastic body 130 is different from the seventh to ninth embodiments described above by the simple configuration including the rotation restraining member 170 which is rotatable in the left and right directions as in the eleventh embodiment described above. It is possible to allow the shear deformation of the elastic body 130 in the required direction even without the deformation space (130a) inside. However, sliding can be induced by suppressing shear deformation in the front-rear direction.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is clear that the present invention can be suitably modified and applied in the same manner. Therefore, the above description does not limit the scope of the present invention, which is defined by the limitations of the following claims.

110: upper flange plate 120: lower flange plate
130: elastic body 131: upper end plate
132: lower end plate 133: insert plate
134: elastic rubber 140: restraining member
151, 161: stainless steel 152: teflon plate
160: guide bar 162: plain sliding bearing

Claims (15)

delete In the elastic support is installed between the lower structure and the upper structure causing relative displacement thereto,
An upper flange plate coupled to the upper structure;
A lower flange plate coupled to the lower structure;
An elastic body installed between the upper flange plate and the lower flange plate, and fixed to one of the upper flange plate and the lower flange plate;
A sliding member installed between the other one of the upper flange plate and the lower flange plate to which the elastic body is not fixed and the elastic body to slide between the elastic body;
It is configured to include a restraining member that is connected across the upper end plate and the lower end plate in the elastic body to restrain the elastic body from shear deformation by restraining the relative displacement therebetween, thereby inducing sliding by the sliding member.
One end of the restraint member is fixed to one of the upper end plate and the lower end plate of the elastic body, and the other end of the restraint member is one end of the restraint member of the upper end plate and the lower end plate of the elastic body. Inserted into the insertion hole formed in the form of the other through the other one, leaving a clearance allowing vertical deflection,
The elastic body is a sliding elastic support for a bridge, characterized in that provided with an air hole for communicating the free space and the outside air. In the elastic support is installed between the lower structure and the upper structure causing relative displacement thereto,
An upper flange plate coupled to the upper structure;
A lower flange plate coupled to the lower structure;
An elastic body installed between the upper flange plate and the lower flange plate, and fixed to one of the upper flange plate and the lower flange plate;
A sliding member installed between the other one of the upper flange plate and the lower flange plate to which the elastic body is not fixed and the elastic body to slide between the elastic body;
It is configured to include a restraining member that is connected across the upper end plate and the lower end plate in the elastic body to restrain the elastic body from shear deformation by restraining the relative displacement therebetween, thereby inducing sliding by the sliding member.
One end of the restraining member is fixed to one located near one of the upper and lower flange plates while penetrating one of the upper end plate and the lower end plate of the elastic body, and the other end of the restraining member is the The upper end plate and the lower end plate of the elastic body is inserted with a free space to allow vertical sag in the insertion hole formed in the form that penetrates the other one that is not fixed,
The elastic body is a sliding elastic support for a bridge, characterized in that provided with an air hole for communicating the free space and the outside air. The method according to claim 2 or 3,
The other end of the restraining member is further provided with a negative force preventing portion formed in a shape protruding along the circumferential direction, the one of the upper flange plate and the lower flange plate located near the other end of the restraining member to receive the negative force preventing portion Sliding portion for the bridge, characterized in that the engaging portion extending from the lower side to the negative reaction prevention portion accommodated in the receiving portion is provided. In the elastic support is installed between the lower structure and the upper structure causing relative displacement thereto,
An upper flange plate coupled to the upper structure;
A lower flange plate coupled to the lower structure;
An elastic body installed between the upper flange plate and the lower flange plate, and fixed to one of the upper flange plate and the lower flange plate;
A sliding member installed between the other one of the upper flange plate and the lower flange plate to which the elastic body is not fixed and the elastic body to slide between the elastic body;
It is configured to include a restraining member that is connected across the upper end plate and the lower end plate in the elastic body to restrain the elastic body from shear deformation by restraining the relative displacement therebetween, thereby inducing sliding by the sliding member.
One end of the restraint member is fixed to one of the upper end plate and the lower end plate of the elastic body, and the other end of the restraint member is one end of the restraint member of the upper end plate and the lower end plate of the elastic body. Is inserted with a clearance allowing vertical deflection in the insertion groove formed in the other one,
The elastic body is a sliding elastic support for a bridge, characterized in that provided with an air hole for communicating the free space and the outside air. Sliding elastic support for a bridge, characterized in that. In the elastic support is installed between the lower structure and the upper structure causing relative displacement thereto,
An upper flange plate coupled to the upper structure;
A lower flange plate coupled to the lower structure;
An elastic body installed between the upper flange plate and the lower flange plate, and fixed to one of the upper flange plate and the lower flange plate;
A sliding member installed between the other one of the upper flange plate and the lower flange plate to which the elastic body is not fixed and the elastic body to slide between the elastic body;
It is configured to include a restraining member that is connected across the upper end plate and the lower end plate in the elastic body to restrain the elastic body from shear deformation by restraining the relative displacement therebetween, thereby inducing sliding by the sliding member.
One end of the restraining member is fixed to one located near one of the upper and lower flange plates while penetrating one of the upper end plate and the lower end plate of the elastic body, and the other end of the restraining member is the One end of the restraining member is inserted with a free space allowing vertical deflection in the other one of the upper end plate and the lower end plate of the elastic body which is not fixed,
The elastic body is a sliding elastic support for a bridge, characterized in that provided with an air hole for communicating the free space and the outside air. delete The method according to any one of claims 2, 3, 5, and 6,
The restraint member is a sliding elastic support for a bridge, characterized in that provided with a plurality. In the elastic support is installed between the lower structure and the upper structure causing relative displacement thereto,
An upper flange plate coupled to the upper structure;
A lower flange plate coupled to the lower structure;
An elastic body installed between the upper flange plate and the lower flange plate, and fixed to one of the upper flange plate and the lower flange plate;
A sliding member installed between the other one of the upper flange plate and the lower flange plate to which the elastic body is not fixed and the elastic body to slide between the elastic body;
It is configured to include a constraining member connected between the upper end plate and the lower end plate in the elastic body to restrain the elastic body from shear deformation by restraining relative displacement therebetween, thereby inducing sliding by the sliding member.
Sliding space is provided inside the elastic body is provided with a deformation space formed to the left and right the restraining member to allow the elastic body to be sheared in the left and right directions. 10. The method of claim 9,
The deformation space is a sliding elastic support for the bridge, characterized in that formed across the elastic body. 11. The method according to claim 9 or 10,
One of the upper flange plate and the lower flange plate in which the elastic body is not fixed is formed along the front-rear direction in the vicinity of the left and right sides of the elastic body so that the elastic body is sheared in the left-right direction, but is orthogonal to the left-right direction. A sliding elastic support for a bridge, characterized in that the guide bar is further provided to guide the sliding in the direction. In the elastic bearing installed between the lower structure in the bridge and the upper structure causing relative displacement thereto,
An upper flange plate coupled to the upper structure;
A lower flange plate coupled to the lower structure;
An elastic body installed between the upper flange plate and the lower flange plate, and fixed to one of the upper flange plate and the lower flange plate;
A sliding member installed between the other one of the upper flange plate and the lower flange plate to which the elastic body is not fixed and the elastic body to slide between the elastic body;
The elastic body is installed in a form spanning between the upper end plate and the lower end plate inside the elastic body, and is installed to be rotatable only in the left and right direction about the rotation axis to allow the elastic body to be sheared while rotating in the left and right direction, but the front and rear direction Sliding elastic support for the bridge is configured to include a rotation restraining member to restrain the rotation is inhibited so as not to shear deformation by inducing sliding by the sliding member. The method of claim 12, wherein the rotation restraint member,
The rotating shaft fixed in the longitudinal direction in the longitudinal direction, the base coupled to any one of the upper end plate and the lower end plate of the elastic body to fix the rotating shaft, one end is rotatably coupled to the rotating shaft and the other end Sliding elastic support for a bridge, characterized in that it comprises a rotating body that spans the other of the upper end plate and the lower end plate is not coupled to the base. In the elastic bearing installed between the lower structure in the bridge and the upper structure causing relative displacement thereto,
An upper flange plate coupled to the upper structure;
A lower flange plate coupled to the lower structure;
An elastic body installed between the upper flange plate and the lower flange plate, and fixed to one of the upper flange plate and the lower flange plate;
A sliding member installed between the other one of the upper flange plate and the lower flange plate to which the elastic body is not fixed and the elastic body to slide between the elastic body;
The elastic body is installed to support the elastic body in the vicinity of the outer side of the elastic body, and is installed to be rotatable only in the left and right direction around the rotation axis to allow the elastic body to be sheared while rotating in the left and right direction, but the rotation is performed in the front and rear directions. Sliding elastic support for a bridge is configured to include a rotation restraining member that is suppressed to restrain the elastic body from shear deformation to induce sliding by the sliding member. The method of claim 14, wherein the rotation restraint member,
The rotating shaft fixed in the longitudinal direction in the longitudinal direction, the base coupled to any one of the upper flange plate and the lower flange plate to fix the rotating shaft, one end is rotatably coupled to the rotating shaft and the other end is the elastic body Sliding elastic support for a bridge, characterized in that it comprises a rotary body coupled to one of the upper end plate and the lower end plate of the opposite end from the base.

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