KR101317464B1 - Sliding elastic supporting apparatus for bridge and using the same sliding supporting method - Google Patents

Abstract

The present invention relates to a sliding elastic support for a bridge and a sliding support method using the same, in which the elastic body does not shear deformation in the longitudinal direction of the bridge 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. By inducing sliding, it is possible to suppress breakage caused by excessive shear deformation of the elastic body and vertical displacement of the structure, and to prevent the enlargement of the structure and the economic loss.
The present invention, the upper plate coupled to the upper structure, the lower plate coupled to the lower structure, the elastic body provided between the upper plate and the lower plate, and reduce the frictional resistance between each other between the upper plate and the elastic body sliding between each other Shear member to guide so as to, and a pair of elastic shear displacement is installed in the lower plate near the front and rear sides of the elastic body to induce the sliding by the sliding member by blocking in the middle when the elastic body causes shear deformation in the longitudinal direction of the bridge It is comprised with the suppression member.

Description

SLIDING ELASTIC SUPPORTING APPARATUS FOR BRIDGE AND USING THE SAME SLIDING SUPPORTING METHOD}

The present invention relates to an elastic bearing for a bridge, and in particular, by inducing the elastic body to slide in the longitudinal direction of the bridge without shear deformation at a point where the longitudinal relative displacement of the upper structure is large with respect to the lower structure such as both end regions of the long bridge. The present invention relates to a sliding elastic bearing for bridges and a sliding support method using the same, capable of smoothly accommodating a moving amount of the upper structure and preventing the structure from being oversized and economically lost due to excessive shear deformation of the elastic body. .

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, it is sometimes applied by making a sliding surface on the upper surface of the elastic body, but when the vertical load increases or the friction coefficient increases, the elastic body is excessively sheared without slipping on the sliding surface. 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.

Therefore, the present invention has been proposed to solve the conventional problems as described above, the object of the present invention is the long direction of the bridge at the point where the longitudinal long relative displacement of the superstructure with respect to the lower structure, such as both ends of the long bridge Sliding bridges and elastic sliding support for the bridge that can accommodate the movement of the upper structure smoothly by inducing the elastic body to slide without shear deformation, while preventing the damage and up and down displacement of the bearing caused by excessive shear deformation of the elastic body To provide a support method.

In order to achieve the above object, the sliding elastic bearing for a bridge according to the technical idea of the present invention is an upper structure such as an upper structure such as a lower structure such as an alternating or pier in a bridge and a relative displacement in the longitudinal and unidirectional directions of the bridge. An elastic support provided between, the upper plate coupled to the upper structure; A lower plate coupled to the lower structure; An elastic body provided between the upper plate and the lower plate; And a sliding member installed between the upper plate and the elastic body and guided to slide between the upper plate and the elastic body, and installed at the front and rear sides of the elastic body in the lower plate, respectively, so that the elastic body shears in the longitudinal direction of the bridge. The technical configuration is characterized by further comprising a pair of elastic shear displacement inhibiting member for inducing the sliding by the sliding member by blocking in the middle when the deformation occurs.

Here, the upper plate is provided on the left side and the right side, respectively, and has an upper and lower width extending downwards to the left side and the right side of the upper end of the elastic body is formed along the longitudinal direction, when the upper structure relative displacement in one direction It may be characterized in that it is further provided with a pair of guide members to induce the shear deformation of the elastic body while being caught by the elastic body.

The sliding member may be a stainless steel plate coupled to a lower surface of the upper plate, and a teflon plate coupled to an upper surface of the elastic body.

In addition, the elastic body may be characterized in that the rubber and the iron plate is laminated, or the high damping rubber and the iron plate are laminated.

In addition, a core made of lead or tin may be further installed at the center of the elastic body.

In addition, the lower plate may be further provided with another pair of elastic shear displacement suppressing members respectively installed near the left and right sides of the elastic body to suppress unidirectional shear deformation of the elastic body.

In addition, the elastic shear displacement suppressing member is a rectangular horizontal body that is coupled in close contact with the lower plate horizontally, and is coupled to the upper surface of the horizontal body, but is erected in the form of a vertical wall at a point close to the elastic body of the upper surface of the horizontal body. It may be characterized by having a combination of the vertical body to have an "L" shape.

In addition, the elastic shear displacement suppressing member is a rectangular horizontal body that is coupled in close contact with the lower plate horizontally, and is coupled to the upper surface of the horizontal body, but is erected in the form of a wall perpendicular to the point away from the elastic body of the upper surface of the horizontal body. It may be characterized in that the vertical body and the combination of the rectangular auxiliary horizontal body is horizontally coupled to the upper end of the inner wall close to the elastic body in the vertical body to have a "c" shape.

In addition, a portion of the upper plate and the lower plate facing each other are installed so as to intersect, and is installed along the longitudinal direction parallel to the guide member, usually the unidirectional direction of the upper plate by the unidirectional relative displacement of the upper structure Limiting the horizontal movement, when an impact such as an earthquake may be characterized in that the upper wedge and the lower wedge is further provided to absorb the shock while being broken by the impact.

On the other hand, the sliding elastic support for the bridge of the present invention, in the elastic support provided between the lower structure such as the alternating or pier in the bridge and the upper structure such as the top plate causing relative displacement in the longitudinal and unidirectional direction of the bridge, An upper plate coupled to the upper structure; A lower plate coupled to the lower structure; An elastic body provided between the upper plate and the lower plate; A sliding member installed between the upper plate and the elastic body and guided to slide between the upper plate and the elastic body; A pair is installed near the left and right sides of the elastic body, the upper and lower ends are coupled to the upper end plate and the lower end plate to suppress the relative displacement between the upper and lower portions of the elastic body, thereby suppressing the longitudinal shear deformation of the elastic body It can be characterized by the technical configuration that is configured to include an elastic shear displacement suppressing member of.

Here, it is installed near the front axis and the rear side of the elastic body, the upper end and the lower end is coupled to the upper end plate and the lower end plate to suppress the relative displacement between the upper and lower parts of the elastic body, the other to suppress the unidirectional shear deformation of the elastic body It may be characterized in that the pair of elastic shear deformation suppression member is further provided.

In addition, the elastic shear displacement suppressing member may be characterized in that the arcuate panel is formed in an arcuate shape in which the upper end and the lower end is in close contact with the side of the elastic body corresponding to the outer convex.

In addition, the elastic shear displacement suppressing member may be characterized in that the pair of turnbuckles cross diagonally to the side of the elastic body.

In addition, the elastic shear displacement suppressing member is installed to maintain a constant interval as a whole with respect to the side of the corresponding elastic body, the upper end and the lower end in the vertical direction to accommodate the displacement in the vertical direction while maintaining the gap by the bolt The bolt hole is formed long in the longitudinal direction, it may be characterized in that the spaced apart panel to be coupled to the upper end plate and the lower end plate of the elastic body.

Meanwhile, the supporting method of the present invention is a supporting method for supporting between a lower structure such as alternating or pier in a bridge and an upper structure such as a top plate causing relative displacement thereto, and the relative displacement is higher than that in an intermediate region of the bridge. The elastic support for the bridge that allows sliding in the longitudinal direction is installed in both end regions that are generated in the large direction, and the non-sliding elastic support that causes only the shear deformation of the elastic body without sliding in the intermediate region where the relative displacement occurs relatively small. The installation can be characterized by its technical configuration.

Bridge sliding elastic support according to the present invention and the sliding support method using the same by the combination of the sliding member, the guide member and the elastic shear displacement inhibiting member allows only the sliding without the shear deformation of the elastic body in the longitudinal relative displacement of the upper structure, Even when the relative relative displacement of the superstructure is large with respect to the substructure, such as the area of both ends of the long bridge, it accommodates excessive movement of the superstructure smoothly. Sliding can be induced without shear deformation to prevent damage to the bearing caused by excessive shear deformation of the elastic body or up and down displacement of the structure, thereby preventing oversizing and economic loss of the structure.

 In addition, the present invention enables shear deformation in the elastic body in a unidirectional direction where the relative displacement is smaller than that in the longitudinal direction of the bridge, thereby making it possible to effectively cope with unidirectional relative displacement.

In addition, the present invention can sufficiently accommodate the longitudinal relative displacement of the superstructure with respect to the substructure, such as both end regions of the long bridge, even with relatively small products.

In addition, the present invention is further provided by the upper wedge and the lower wedge, limiting the unidirectional horizontal movement of the upper plate by the unidirectional relative displacement of the upper structure in normal times, and when the shock occurs, such as earthquake, the impact is broken while breaking It can absorb effectively.

BRIEF DESCRIPTION OF THE DRAWINGS Fig.
Figure 2 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 partial perspective view for explaining the configuration of the sliding elastic support according to the first embodiment of the present invention.
Figure 5 is a longitudinal longitudinal cross-sectional view for explaining the configuration of the sliding elastic bearing according to the first embodiment of the present invention.
Figure 6 is a unidirectional longitudinal sectional view of the sliding elastic support according to the first embodiment of the present invention.
7 is an operation of the sliding elastic support according to the first embodiment of the present invention.
Figure 8 is a longitudinal longitudinal cross-sectional view for explaining the configuration of the sliding elastic support according to a second embodiment of the present invention.
Figure 9 is a longitudinal longitudinal cross-sectional view for explaining the configuration of the sliding elastic bearing according to the third embodiment of the present invention.
10 and 11 are longitudinal longitudinal cross-sectional views for explaining the configuration of the sliding elastic support according to a third modified embodiment of the present invention.
12 is a longitudinal longitudinal cross-sectional view for explaining the configuration of the sliding elastic support according to a fourth embodiment of the present invention.
Figure 13 is a longitudinal longitudinal cross-sectional view for explaining the configuration of the sliding elastic support according to a fourth embodiment of the present invention.
14 is a partial perspective view for explaining the configuration of the sliding elastic support according to a fifth embodiment of the present invention.
15 is a partial perspective view for explaining the configuration of the sliding elastic support according to a sixth embodiment of the present invention.
16 is a partial perspective view for explaining the configuration of the sliding elastic support according to the seventh embodiment of the present invention.
17 is a partial perspective view for explaining the configuration of the sliding elastic support according to an eighth embodiment of the present invention.
18 is a partial perspective view for explaining the configuration of the sliding elastic bearing according to the ninth embodiment of the present invention.
19 is a partial perspective view for explaining the configuration of the sliding elastic bearing according to the tenth embodiment of the present invention.
20 is a partial perspective view for explaining the configuration of the sliding elastic bearing according to the eleventh embodiment of the present invention.
Figure 21 is a longitudinal longitudinal cross-sectional view for explaining the configuration of the sliding elastic bearing according to the twelfth embodiment of the present invention.
Figure 22 is a longitudinal longitudinal cross-sectional view for explaining the configuration of the sliding elastic bearing according to the thirteenth embodiment of the present invention.
Figure 23 is a longitudinal longitudinal cross-sectional view for explaining the configuration of the sliding elastic bearing according to the fourteenth embodiment of the present invention.
24 is a longitudinal longitudinal cross-sectional view for explaining the structure of the sliding elastic bearing according to the fifteenth embodiment of the present invention.

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

[First Embodiment]

2 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 an embodiment of the present invention is mainly applied to both end regions (A1, A2) of the large relative displacement of the upper structure, such as the top plate to the substructure, such as alternating or pier in the bridge. When the relative displacement occurs in the longitudinal direction of the bridge, it is basically configured to slide, but is configured to induce sliding by suppressing the shear deformation of the elastic body even if the elastic body has a tendency to cause shear deformation. The present invention can overcome the limitation that the relative displacement of both end regions A1 and A2, such as a long bridge, is large and does not accommodate the movement amount smoothly. In order to accommodate the displacement of superstructures in areas with large relative displacements, the height and cross-section of the elastic bearings were greatly increased, which was not desirable in terms of efficiency and economic efficiency, and in the case of the conventional sliding elastic bearings, the vertical load was increased. In addition, if the friction coefficient is increased, the sliding does not occur and the elastic body is excessively sheared, which seriously affects the bridge support failure and the stability of the structure.)

On the other hand, the conventional non-sliding elastic support 10 may be provided in the intermediate regions P1, P2, P3, and P4 in which the relative displacement of the upper structure in the bridge is relatively small.

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

3 is an exploded perspective view of the sliding elastic support according to the first embodiment of the present invention, Figure 4 is a partial perspective view for explaining the configuration of the sliding elastic support according to the first embodiment of the present invention, Figure 5 is a present invention Longitudinal longitudinal cross-sectional view for explaining the configuration of the sliding elastic bearing according to the first embodiment of Figure 6 is a unidirectional longitudinal cross-sectional view of the sliding elastic bearing according to the first embodiment of the present invention. 7 is an operation 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 plate 110 coupled to the upper structure of the bridge, the lower plate 120 coupled to the lower structure of the bridge, and the upper plate ( It comprises an elastic body 130 installed between the 110 and the lower plate 120, a sliding member (111, 112), a pair of guide member 140, and a pair of elastic shear displacement suppressing member 150. .

In the first embodiment of the present invention by the cooperative action of the sliding member (111, 112) and the guide member 140 in the longitudinal direction (x) in the upper plate coupled to the upper structure of the bridge without the shear deformation of the elastic body 130 Allow 110 to slide, but in one direction y, the elastic member 130 causes shear deformation while the guide member 140 is caught by the elastic body 130. Note that, even when the elastic body 130 has a tendency to cause shear deformation in the longitudinal direction (x), the elastic body shear displacement suppressing member 150 installed on the front and rear sides of the elastic body 130 is the elastic body 130. ) By directly blocking the shear deformation to induce a longitudinal (x) sliding of the upper plate 110 so that the shear deformation of the elastic body (x) does not occur in the longitudinal direction (x) of the bridge in any case do.

Hereinafter, the configuration of the sliding elastic support according to the first embodiment of the present invention with reference to each of the components in more detail.

First, the sliding members 111 and 112 reduce the frictional resistance between the upper plate 110 and the elastic body 130 to induce sliding between each other. To this end, the sliding members 111 and 112 may be configured by combining various materials in a pair. In the first embodiment, the stainless steel plate 111 and the elastic body 130 coupled to the lower surface of the upper plate 110 are provided. It is made of a combination of Teflon plate 112 coupled to the upper surface of. According to this configuration, even if the upper structure 91 of the bridge is relatively displaced with respect to the lower structure 92 so that the upper plate 110 is displaced along the upper structure 91, the stainless steel plate 111 and the teflon plate 112 are fixed. Sliding occurs between these two to accommodate the excessive displacement of the superstructure.

The guide member 140 is respectively installed at the upper left side and the post of the upper plate 110, and has a form of a rail protruding downward along the longitudinal direction (x). The degree that the guide member 140 protrudes downward is suitable as long as it crosses around the left side and the right side of the upper end of the elastic body 130.

As a result, the guide member 140 has no influence on the elastic body 130 as shown in FIG. 7 when the upper structure 91 of the bridge causes relative displacement in the long direction x. That is, when the upper structure 91 of the bridge causes a relative displacement in the longitudinal direction (x) with respect to the lower structure 92, the guide member 140 formed along the longitudinal direction (x) on the left and right of the elastic body 130 ) Does not cause any interference or restraint on the elastic body 130.

On the other hand, the guide member 140 acts to cause shear deformation on the elastic body 130 while being caught by the upper end of the elastic body 130 when the upper structure 91 of the bridge causes a relative displacement in one direction (y). .

 The elastic shear displacement suppressing member 150 is for suppressing the longitudinal (x) shear deformation of the elastic body 130, respectively installed on the front and rear sides of the elastic body 130 and is formed in the shape of a rectangular wall. Thus, even when the elastic body 130 has a tendency to cause shear deformation in the longitudinal direction (x), the elastic shear displacement inhibiting member 150 blocks the elastic body 130 directly in the vicinity to force the shear deformation. By suppressing, the long direction (x) sliding of the upper plate 110 is induced. Here, the elastic shear displacement inhibiting member 150 allows the upper end portion to reach the upper end plate 131a region of the elastic body 130 so as to effectively suppress the shear deformation of the elastic body.

When the elastic shear displacement inhibiting member 150 is provided, the upper structure 91 of the bridge is relatively displaced in the longitudinal direction (x) so that the stainless steel plate 111 and the teflon plate are primarily moved when the upper plate 110 moves. The mutual sliding action of 112 permits the movement of the upper structure 91 and the upper plate 110 while suppressing the shear deformation of the elastic body 130. Secondly, the vertical load acts above a certain level or the sliding surface Even if the elastic body 130 has a tendency to cause shear deformation due to the movement of the upper plate 110 due to the foreign matter or dust, and the friction coefficient is increased, the elastic shear deformation inhibiting member 150 is the elastic body 130. By blocking the middle of the stainless steel plate 111 and the Teflon plate 112 can be expected a dual effect of inducing mutual sliding.

The elastic body 130 is provided between the upper plate 110 and the lower plate 120, and is provided with a rubber 132 having an elastic force and a plurality of steel sheets 131c disposed at equal intervals vertically therein. . At the top and bottom of the steel plate 131c, the upper end plate 131a and the lower end plate which are slightly thicker than the other steel plates 131c for the coupling between the upper plate 110 and the lower plate 120 131b).

The elastic body 130 having such a configuration generally supports vertical loads, and resists horizontal loads with shear deformations that are displaced larger in the direction of load on the upper and lower ends when horizontal loads are applied. . However, in the present invention, even if the upper plate 110 moves in the longitudinal direction (x) due to the relative displacement (x) of the upper structure 91 of the bridge, the stainless steel plate 111 and the Teflon plate 112 mutually The horizontal load is applied to the elastic body 130 to the minimum while sliding in the minimum.

However, when the vertical load of the upper structure 91 is increased or the friction coefficient of the sliding surface is increased, the elastic body 130 does not smoothly slide between the stainless steel plate 111 and the Teflon plate 112. A horizontal load is applied to the rod, which tends to cause shear deformation. Of course, in this case, as described above, the elastic shear displacement inhibiting member 150 blocks the shear deformation of the elastic body 130 on the way.

Meanwhile, when the upper structure 91 of the bridge is relatively displaced in one direction (y) and the upper plate 110 moves in one direction (y), the stainless steel plate 111 and the teflon plate 112 tend to slide. Although the guide member 140 is applied to the horizontal load while the upper end of the elastic body 130 to cause the shear deformation.

For reference, in the elastic body 130 of the present invention, a high-damping elastic body having an improved energy absorption capability in the event of an earthquake may be used, and the core 133 made of high purity lead to lower the shear deformation of the elastic body 130 may be vibrated. It can also employ | adopt in addition to an energy absorber. However, it is not necessary to employ the core 133, and it is a matter that can be selected according to the situation in which the elastic support of the present invention is installed.

According to the first embodiment of the present invention as described above, the upper structure 91 of the bridge by the combination of the sliding member (111, 112) and the guide member 140 in the longitudinal direction relative to the lower structure 92 ( Even if excessive relative displacement is caused by x), it is possible to smoothly accommodate the movement amount of the upper structure 91 due to the relative displacement without shear deformation of the elastic body 130 as shown in FIG. 7. On the other hand, when the upper structure 91 causes a relative displacement in one direction (y), by inducing the shear deformation of the elastic body 130 it can be prepared for the impact due to earthquakes.

On the other hand, the sliding elastic bearing according to the present invention can be modified embodiments having various types of elastic shear displacement suppressing member for suppressing the shear deformation of the elastic body 130, will be described continuously.

[Second Embodiment]

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

As shown, the second embodiment of the present invention is unlike the first embodiment in which the elastic shear displacement suppression member 150 is coupled to the lower plate 120 by welding 151, the elastic shear displacement suppression member 150 is coupled to the lower plate 120 by fastening the bolt 152. As such, when the elastic shear displacement suppressing member 150 is coupled to the lower plate 120 by fastening the bolt 152, the elastic shear displacement suppressing member 150 may be easily replaced to maintain and repair.

[Third Embodiment]

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

As shown, the third embodiment of the present invention is that the elastic shear displacement suppressing member 150 is installed to suppress the longitudinal (x) shear deformation of the elastic body 130, the horizontal body 150a and the vertical body 150b It is characterized by consisting of a).

Here, the horizontal body (150a) is provided in a rectangular plate shape that is coupled in close contact with the lower plate 120 horizontally, the vertical body (150b) is coupled to the upper surface of the horizontal body (150a), the horizontal body ( It is erected in the form of a vertical wall at a point close to the elastic body 130 of the upper surface of 150a). As described above, the elastic shear deformation suppressing member 150 formed by the coupling of the horizontal body 150a and the vertical body 150b has an “L” shape.

As such, the elastic shear displacement inhibiting member 150 having the configuration of the “L” shape has a high resistance to suppress the shear displacement of the elastic body 130 compared to the volume.

On the other hand, according to the third embodiment, it can be seen that the coupling of the lower plate 120 and the horizontal body 150a and the coupling of the horizontal body 150a and the vertical body 150b are all made by welding 151. . However, by modifying the method, a modified configuration is possible as in the following modified example.

10 and 11 are longitudinal longitudinal cross-sectional views for explaining the configuration of the sliding elastic support according to a third modified embodiment of the present invention.

As shown, in the modified third embodiment, at least a portion of the elastic shear displacement inhibiting member 150 is coupled by fastening the bolt 152.

In FIG. 10, the coupling of the lower plate 120 and the horizontal body 150a is performed by fastening the bolt 152, and the coupling of the horizontal body 150a and the vertical body 150b is performed by welding 151. You can see it done. In addition, in FIG. 11, the coupling between the lower plate 120 and the horizontal body 150a and the coupling between the horizontal body 150a and the vertical body 150b are all achieved by fastening the bolts 152.

As such, when the elastic shear displacement suppressing member 150 is partially or entirely coupled by fastening the bolts 152, there is an advantage in that partial replacement work for maintenance and repair is facilitated.

[Fourth Embodiment]

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

As shown, the fourth embodiment of the present invention is that the elastic shear displacement suppressing member 150 is installed to suppress the longitudinal (x) shear deformation of the elastic body 130, the horizontal body 150a and the vertical body 150b In addition, it is characterized by consisting of the auxiliary horizontal body (150c).

Here, the horizontal body (150a) is provided in a rectangular plate shape that is coupled in close contact with the lower plate 120 horizontally, the vertical body (150b) is coupled to the upper surface of the horizontal body (150a), the horizontal body ( The upper surface of the 150a) is erected in the form of a vertical wall at a point far from the elastic body 130. In addition, the auxiliary horizontal body 150c is horizontally coupled to the upper end of the inner wall close to the elastic body 130 in the vertical body 150b. Here, the auxiliary horizontal body 150c is provided at a height at which the upper end plate 131a of the elastic body 130 is installed to block the upper end plate 131a when shearing the elastic body 130.

The elastic shear displacement suppressing member 150 having such a configuration has an advantage of high resistance to suppress the shear displacement of the elastic body 130 as compared to the volume of the third embodiment.

Meanwhile, according to the fourth embodiment, the lower plate 120 and the horizontal body 150a are coupled, the horizontal body 150a and the vertical body 150b are coupled, and the vertical body 150b and the auxiliary horizontal body 150c are combined. Coupling of the lower plate 120 and the horizontal body (150a) of the coupling, the coupling of the vertical body (150b) and the auxiliary horizontal body (150c) is made by the bolt 152, the horizontal body (150a) ) And the vertical body 150b are coupled to the weld 151. However, by changing the method, it is possible to modify the configuration as in the following modified example.

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

As shown, in the fourth modified embodiment, the lower plate 120 and the horizontal body 150a are coupled, the horizontal body 150a and the vertical body 150b are coupled, and the vertical body 150b is assisted. The coupling of the lower plate 120 and the horizontal body 150a, the coupling of the horizontal body 150a and the vertical body 150b, and the vertical body 150b and the auxiliary horizontal body 150c during the coupling of the horizontal body 150c. The combination of the two) characterized in that made by fastening the bolt 152.

In addition, although not shown through the drawings, the lower plate 120 and the horizontal body 150a are coupled, the horizontal body 150a and the vertical body 150b are coupled, and the vertical body 150b and the auxiliary horizontal body ( All of the joining of 150c) may be made by welding.

On the other hand, the present invention can be various embodiments according to the shape and arrangement of the elastic shear displacement suppression member 150, and will be described below these various embodiments.

[Fifth Embodiment]

14 is a partial perspective 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 the elastic shear displacement inhibiting member 150 is installed on the front and rear sides of the elastic body 130, respectively, the shape of the elastic body 130 in the form of a wall having a rectangular cross section It is characterized by being provided in plural on the front side and plural on the back side.

As described above, according to the fifth embodiment of the present invention, the elastic shear displacement inhibiting member 150 may be provided in the form of a plurality of walls on the front and rear sides of the elastic body, respectively.

[Sixth Embodiment]

15 is a partial perspective view for explaining the configuration of the sliding elastic support according to the sixth embodiment of the present invention.

As shown, in the sixth embodiment of the present invention, the elastic shear displacement inhibiting member 150 is installed at the front and rear sides of the elastic body 130, respectively. It is characterized in that the number is provided in the form of a wall of the column shape having an elliptical cross section.

As such, in the present invention, the elastic shear displacement inhibiting member 150 may be formed in a wall shape having a circular column or an elliptical column cross section.

[Seventh Embodiment]

16 is a partial perspective view for explaining the configuration of the sliding elastic support according to the seventh embodiment of the present invention.

As shown, in the seventh embodiment of the present invention, the elastic shear displacement suppressing member 150 is installed at the front and rear sides of the elastic body 130, respectively, and the elastic body 130 in the form of a column having a circular cross section or an elliptical cross section. A plurality of the front side and a plurality of the rear side is characterized in that it is provided.

As described above, according to the seventh exemplary embodiment of the present invention, the elastic shear displacement inhibiting member 150 may be provided in the form of a plurality of round pillars on the front and rear sides of the elastic body, respectively.

[Example 8]

17 is a partial perspective view for explaining the configuration of the sliding elastic support according to the eighth embodiment of the present invention.

As shown, the eighth embodiment of the present invention is a one-way (y) shear of the elastic body 130 in addition to the elastic shear displacement inhibiting member 150 for suppressing the longitudinal (x) shear deformation of the elastic body 130 An elastic shear displacement suppressing member 160 for suppressing deformation is installed on the left and right sides of the elastic body 130, respectively. In addition, in the present embodiment, the elastic shear displacement suppressing member 150 is provided in the form of a wall having a rectangular cross section, and a plurality of elastic shear shear suppressing members 150 are provided in the adjacent front, rear, left, and right directions of the elastic body 130.

According to this configuration, when the upper structure 91 is displaced in the longitudinal direction (x), the elastic shear displacement inhibiting member 150 installed in the front and rear of the vicinity of the elastic body 130 is the shear deformation of the elastic body 130 On the other hand, when the substructure of the bridge is relatively displaced in one direction (y), the elastic shear displacement inhibiting member 150 installed on the left and right adjacent to the elastic body 130 is the shear deformation of the elastic body 130 Block it.

In addition, when the upper structure 91 is relatively displaced in the unidirectional y, the elastic body 130 causes shear deformation in the unidirectional y and when the upper structure 91 reaches a predetermined point, It is blocked by the elastic shear displacement suppressing member 150 installed on the right side so that no further shear deformation is made. In this case, however, the guide member 140 should be removed.

[Example 9]

18 is a partial perspective view for explaining the configuration of the sliding elastic support according to the ninth embodiment of the present invention.

As shown, according to the ninth embodiment of the present invention, the elastic shear displacement suppressing member 150 is installed at the front, rear, left, and right sides of the elastic body 130, respectively, and is installed in each direction. All of the 150 are in the form of a wall having a rectangular cross section, characterized in that a plurality of the plurality of front and rear, a plurality of the rear side, a plurality of the left side, a plurality of the right side.

18, the elastic shear displacement suppressing member 150 is shown to be arranged in each direction two, but may be configured to have three or more in each direction. In this case, the guide member 140 should be removed.

[Example 10]

19 is a partial perspective view for explaining the configuration of the sliding elastic bearing according to the tenth embodiment of the present invention.

As shown, in the tenth embodiment of the present invention, the elastic shear displacement inhibiting member 150 is installed in the front, rear, left, and right sides of the elastic body 130, respectively, having a circular cross section or an elliptical cross section. Furnace is provided with a single number in each direction.

As such, in the present invention, the elastic shear displacement inhibiting member 150 may be provided in the form of a circular column or an elliptical column. In this case, however, the guide member 140 should be removed.

[Example 11]

20 is a partial perspective view for explaining the configuration of the sliding elastic bearing according to the eleventh embodiment of the present invention.

As shown, in the eleventh embodiment of the present invention, the elastic shear displacement inhibiting member 150 is installed at the front, rear, left, and right sides of the elastic body 130, respectively, and has a circular cross section or an elliptical cross section. It is characterized in that a plurality of the front side, a plurality of rear side, a plurality of left side, a plurality of on the right side of the elastic body 130 is provided. In this case, however, the guide member 140 should be removed.

[Twelfth Example]

Figure 21 is a longitudinal longitudinal cross-sectional view for explaining the configuration of the sliding elastic bearing according to the twelfth embodiment of the present invention.

As shown, the twelfth embodiment of the present invention is the top and bottom of the elastic body 130 in at least one of the pair of the front side and the rear side of the elastic body 130, the other of the left side and the right side It is characterized in that the elastic shear displacement suppressing member 170 is provided to suppress the relative displacement between.

As the elastic shear displacement inhibiting member 170, it is shown in FIG. 21 as being provided with an arcuate steel plate closely coupled to the side of the elastic body 130. Here, the arcuate steel plate is fastened to the upper end plate 131a and the lower end plate 131b of the elastic body 130 to form a flat plate 170b formed at the upper end and the lower end thereof. Except for the flat plate portion 170b, the remaining portion is formed as an arch portion 170a formed to be convex outwardly.

Thus, when the elastic shear displacement suppressing member 170 is provided with an arcuate steel plate having an arch portion 170a, the horizontal relative of the upper structure 91 is basically allowed while allowing vertical relative displacement between the upper and lower portions of the elastic body 130. In the displacement, the shear deformation of the elastic body 130 is suppressed to induce the sliding of the upper plate 110. In addition, an inner space is provided inside the arch portion 170a of the elastic shear displacement suppressing member 170 to accommodate the elastic body 130 even if it is expanded convexly to the side while receiving a vertical load.

The elastic shear displacement inhibiting member 170 provided with the arcuate steel plate as described above is provided to be in close contact with the front and rear surfaces of the elastic body 130, or to be in close contact with the left and right sides of the elastic body 130. It may be provided or in close contact with all of the front side, rear side, left side, right side of the elastic body 130.

[Thirteenth Embodiment]

Figure 22 is a longitudinal longitudinal cross-sectional view for explaining the configuration of the sliding elastic bearing according to the thirteenth embodiment of the present invention.

As shown, the thirteenth embodiment of the present invention is the top and bottom of the elastic body 130 in at least one of the pair of the front side and the rear side of the elastic body 130, the other of the left side and the right side An elastic shear displacement inhibiting member 180 that suppresses horizontal horizontal relative displacement, and characterized in that it is provided with a turnbuckle that crosses the diagonal of the corresponding elastic body 130 in the diagonal direction.

The elastic shear displacement suppressing member 180 provided with the turnbuckle is coupled to the upper end and the lower end of the elastic body 130 to the upper end plate 131a and the lower end plate 131b of the elastic body 130, and each turnbuckle has a length for adjusting the length. The regulator 181 is installed. In the case of such a turnbuckle, the horizontal relative displacement of the upper structure 91 of the bridge while allowing vertical relative displacement between the upper and lower portions of the elastic body 130, such as the elastic shear displacement inhibiting member 170 provided with the arcuate steel plate described above. In this case, the shear deformation of the elastic body 130 is suppressed to induce sliding of the upper plate 110. In addition, as in the twelfth embodiment, the elastic body 130 may be expanded to some extent because the elastic body 130 is in an open state except for a portion through which the elastic shear displacement inhibiting member 180 provided by the turnbuckle passes. Have some time to spare.

The elastic shear displacement suppressing member 180 provided with the turnbuckle as described above is provided on the front side and the rear side of the elastic body 130, or is provided on the left and right sides of the elastic body 130, or the elastic body It may be provided on all of the front side, rear side, left side, right side of 130.

[Example 14]

Figure 23 is a longitudinal longitudinal cross-sectional view for explaining the configuration of the sliding elastic bearing according to the fourteenth embodiment of the present invention.

As shown, the fourteenth embodiment of the present invention is the top and bottom of the elastic body 130 in at least one of the pair of the front side and the rear side of the elastic body 130, the other of the left side and the right side As the elastic shear displacement suppressing member 190 to suppress the relative displacement between the, characterized in that the steel panel is provided to maintain a constant interval as a whole without being in close contact with the side of the corresponding elastic body 130. To this end, the upper end and the lower end of the elastic shear displacement suppressing member 190 provided with the steel panel by a relatively long bolt 191, the upper end plate 131b and the lower end plate 131b of the elastic body 130. It is preferable that the bolt holes of the steel panel are pre-machined in the form of bolt holes of the long length in the vertical direction, in order to allow vertical displacement.

As described above, even in the case of the elastic shear displacement inhibiting member 190 of the fourteenth embodiment, which is provided as a stainless steel panel that is uniformly spaced with respect to the elastic body 130, the relative displacement between the upper and lower portions of the elastic body 130 is suppressed. When the relative displacement of the upper structure 91 of the bridge is to suppress the shear deformation of the elastic body 130 to induce the sliding of the upper plate (110). In addition, as in the twelfth embodiment, even if the elastic body 130 is expanded to some extent by the separation space formed between the elastic shear displacement inhibiting member 190 and the elastic body 130, the elastic body 130 can be sufficiently accommodated.

[Example 15]

24 is a longitudinal longitudinal cross-sectional view for explaining the structure of the sliding elastic bearing according to the fifteenth embodiment of the present invention.

As shown, the fifteenth embodiment of the present invention is characterized by having an upper wedge 160a and a lower wedge 160a installed along the longitudinal direction x in parallel with the guide member 140.

The upper wedge 160a and the lower wedge 160b are provided on opposite surfaces of the upper plate 110 and the lower plate 120, respectively, and the lower end of the upper wedge 160a and the upper end of the lower wedge 160b. Are installed to cross each other in the vicinity.

When the upper wedge 160a and the lower wedge 160b are provided, the unidirectional (y) relative displacement of the upper structure 91 is normally limited, and in the event of an impact such as an earthquake, the unidirectional direction of the upper structure 91 of the bridge (y) ) It is broken by relative displacement and absorbs shock. However, even in the case of the fifteenth embodiment, the relative displacement in the long direction (x) of the upper structure 91 does not change, while smoothly accommodating the movement amount of the upper structure 91.

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 plate 111: stainless steel plate
112: teflon plate 120: lower plate
130: elastic body 140: guide member
150,170,180,190: elastic shear displacement inhibiting member
160a, 160b: wedge

Claims (15)

In the elastic support provided between the substructures such as the alternating or pier in the bridge and the upper structure such as the upper plate which causes relative displacement in the long and unidirectional direction of the bridge,
An upper plate coupled to the upper structure; A lower plate coupled to the lower structure; A lower end portion is fixed to the lower plate between the upper plate and the lower plate, and a rubber, an upper end plate and a lower end plate respectively installed at an upper end portion and a lower end portion inside the rubber, and the upper portion inside the rubber An elastic body made up of a plurality of steel plates spaced apart from the end plate and the lower end plate; A sliding member installed between the upper plate and the elastic body and guided to slide between the upper plate and the elastic body,
A pair of elastic shear displacement inhibiting members are installed in the lower plate, respectively, near the front side and the rear side of the elastic body to induce sliding by the sliding member by intercepting when the elastic body causes shear deformation in the longitudinal direction of the bridge. Further provided, wherein the elastic shear displacement suppressing member is a sliding elastic support for a bridge, characterized in that formed in the height that can block the upper end plate when the elastic body causes the shear deformation. The method of claim 1,
It is provided on the left side and the right side of the upper plate, respectively, and is formed along the longitudinal direction with an upper and lower width extending downward to the left side and the right side of the upper end of the elastic body, when the upper structure is relatively displaced in one direction. Sliding elastic support for a bridge, characterized in that the pair is further provided with a guide member for inducing shear deformation of the elastic body. The method of claim 1,
The sliding member is a stainless steel plate coupled to the lower surface of the upper plate and the sliding elastic support for the bridge, characterized in that the Teflon plate coupled to the upper surface of the elastic body. The method of claim 1,
The elastic body, the rubber and the iron plate is laminated, or high elastic rubber and the steel plate is a sliding elastic support for the bridge, characterized in that the lamination. 5. The method of claim 4,
The center of the elastic body is a sliding elastic support for a bridge, characterized in that a core made of lead or tin is further installed. The method of claim 1,
The lower plate is provided on the left and right sides of the elastic body, respectively, a pair of elastic shear displacement inhibiting member for restraining the one-way shear deformation of the elastic body further comprises a bridge elastic support. The method of claim 1,
The elastic shear displacement inhibiting member is a vertical horizontal body that is in close contact with the lower plate and coupled horizontally, and vertically coupled to the upper surface of the horizontal body, but is formed in a vertical wall form at a point close to the elastic body of the horizontal body. Sliding elastic bearing for the bridge, characterized in that the combination consisting of a sieve to have an "L" shape. The method of claim 1,
The elastic shear displacement inhibiting member is a vertical horizontal body that is in close contact with the lower plate and coupled horizontally, and the vertical body is coupled to the upper surface of the horizontal body and erected in a vertical wall form at a point far from the elastic body of the upper surface of the horizontal body. And a sieve and a quadrangular auxiliary horizontal body coupled horizontally to the upper end of the inner wall close to the elastic body in the vertical body so as to have a "c" shape. 3. The method of claim 2,
A part of the upper plate and the lower plate are installed so as to intersect with each other from each other, and are installed along the longitudinal direction in parallel with the guide member, and in general, unidirectional horizontal movement of the upper plate by unidirectional relative displacement of the upper structure. Limiting and, when an impact such as an earthquake, the upper wedge and the lower wedge is further provided to absorb the impact while being broken by the shock, characterized in that the sliding elastic support for the bridge. In the elastic support provided between the substructures such as the alternating or pier in the bridge and the upper structure such as the upper plate which causes relative displacement in the long and unidirectional direction of the bridge,
An upper plate coupled to the upper structure;
A lower plate coupled to the lower structure;
An elastic body provided between the upper plate and the lower plate;
A sliding member installed between the upper plate and the elastic body and guided to slide between the upper plate and the elastic body;
A pair is installed near the left and right sides of the elastic body, the upper and lower ends are coupled to the upper end plate and the lower end plate to suppress the relative displacement between the upper and lower portions of the elastic body, thereby suppressing the longitudinal shear deformation of the elastic body Sliding elastic support for a bridge comprising an elastic shear displacement suppressing member of the. The method of claim 10,
Another pair which is installed near the front axis and the rear side of the elastic body, the upper end and the lower end are coupled to the upper end plate and the lower end plate to suppress the relative displacement between the upper and lower parts of the elastic body, thereby suppressing the unidirectional shear deformation of the elastic body. Sliding elastic support for bridges, characterized in that the elastic shear displacement suppression member of the further provided. The method of claim 10,
The elastic shear displacement inhibiting member is a sliding elastic support for a bridge, characterized in that the upper end and the lower end is in close contact with the side of the corresponding elastic body and the remaining portion is an arched panel formed in an arcuate convex outward. The method of claim 10,
The elastic shear displacement suppressing member is a sliding elastic support for a bridge, characterized in that a pair of turnbuckles that cross in the diagonal direction to the side of the elastic body. The method of claim 10,
The elastic shear displacement suppressing member is installed to maintain a constant interval as a whole with respect to the side of the corresponding elastic body, the upper end and the lower end is coupled to the upper end plate and the lower end plate of the elastic body while maintaining the gap by bolts Sliding elastic support for a bridge, characterized in that the spaced apart panel. As a supporting method for supporting between substructures such as shifts or piers in bridges and superstructures such as top plates causing relative displacement thereto,
Claim 1 to 14, the sliding elastic support for the bridge of any one of claims 1 to 14 to allow the sliding in the longitudinal direction is provided in both end regions where the relative displacement occurs in the longitudinal direction compared to the intermediate region of the bridge,
And a non-sliding elastic support for causing only shear deformation of the elastic body without sliding in an intermediate region where the relative displacement occurs relatively small.

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