KR100879364B1 - Bearing system for bridge - Google Patents

Abstract

A bridge bearing system is provided to correspond effectively to the relative displacement between an abutment or a pier and a superstructure caused by the expansion and contraction of a superstructure, seismic load, wind load, etc. A bridge bearing system includes a supporting apparatus installed between an abutment or a pier and a superstructure to allow the relative displacement between an abutment(10) or a pier(20) and a superstructure(30), wherein a sliding bearing apparatus(100) allowing sliding is installed to a spot with the relatively large relative displacement, and an elastic bearing apparatus(200) allowing elastic deformation without allowing sliding is installed to a spot with the relatively small relative displacement.

Description

Bridge Support System {BEARING SYSTEM FOR BRIDGE}

TECHNICAL FIELD The present invention relates to the field of civil engineering, and in particular, to a system for efficiently installing a support of a bridge.

1 is a view for explaining the concept of a conventional bridge bearing.

The bridge is composed of the alternating 10, the pier 20, the upper structure 30 (girder, top plate, etc.), the alternating 10 by the contraction, wind load, earthquake load, etc. of the upper structure 30 due to temperature changes Alternatively, relative displacement occurs between the bridge 20 and the superstructure 30.

The supporting device 1 by the bridge support is such that the shift 10 or the pier 20 and the superstructure 30 are allowed to allow the relative displacement of such an alternating 10 or the pier 20 and the superstructure 30. Refers to the structure installed between).

2 and 3 are views for explaining in more detail the structure associated with the support device (1).

The upper portion of the supporting device 1 is coupled to the bottom surface of the upper structure 30 by placing the upper plate 40, the lower portion of the supporting device 1 by placing the lower plate 50, alternating 10 or piers 20 ) To the top (coping) of the

As described above, the supporting device 1 should be formed to allow relative displacement of the alternating 10 or the pier 20 and the upper structure 30, as shown in FIGS. 2 and 3 by the elastic material. It is common to be installed in a structure capable of elastic deformation and elastic recovery (elastic support).

On the other hand, as the elongation or contraction of the upper structure 20 occurs due to the temperature change, a relative displacement occurs between the alternating 10 or the bridge 20 and the upper structure 30, the relative displacement is the front of the bridge It does not occur consistently over the interval.

For example, when the upper structure 30 is stretched (thermally expanded) due to a high temperature in summer, there is almost no relative displacement between the pier 20a and the upper structure 30 in the center of the plurality of bridges 20. A very large relative displacement occurs between the shift 10 and the superstructure 30 which are both ends of the.

This is because the upper structure 30 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, without considering that the relative displacement between the shift 10, the bridge 20, and the upper structure 30 is different for each section of the bridge, the support device 1 having the same structure is uniformly provided. As it has been applied, it has been pointed out as a problem in that the above relative displacement caused by the expansion of the superstructure due to the temperature change, the seismic load or the wind load is not considered effectively.

That is, as shown in Figure 1, since the support device 1 of the same structure is placed on the alternating 10 and the piers 20 by using the method of installing the upper structure 30, Only in both ends of the bridge, as the relative displacement between the shift 10 and the upper structure 30 is large, breakage of the supporting device 1 occurs frequently, which makes the yield probability of all members constant. It has been problematic in that it is contrary to the basic purpose of efficient civil design.

The present invention has been made to solve the above problems, the bridge support system for efficiently responding to the relative displacement between the shifts, bridge piers and the superstructure caused by the expansion, seismic load, wind load of the superstructure, etc. Its purpose is to provide.

The present invention, in order to allow the relative displacement of the alternating 10 or pier 20 and the superstructure 30 in order to achieve the object as described above, the alternating 10 or pier 20 and the superstructure ( In the bridge support system including the support device 1 provided between 30), the sliding support device 100 which allows sliding is provided in the point where the said relative displacement generate | occur | produces relatively large, The said relative displacement At a point where relatively small occurs, the bridge support system is characterized in that the elastic support device 200 is installed to allow elastic deformation without allowing sliding.

The sliding support device 100 is preferably installed between the shift 10 and the upper structure (30).

The elastic support device 200 is preferably installed between the central piers 20a and the upper structure 30 of the plurality of piers 20.

The elastic support device 200 is preferably installed between the plurality of bridge piers 20 and the upper structure (30).

The sliding support device 100 is preferably a one-way sliding support device (100a) that allows only one-way driving in the axial direction.

The one-way sliding support device (100a) is the elastic support device 200 mounted on the upper surface of the lower plate 50 installed on the top of the alternating (10) or piers (20); A lower guide pin part 111 protruding along the axial direction on the upper surface of the elastic support device 200; It is preferable to include; an upper guide groove portion 112 formed to insert the lower guide pin portion 111 on the lower surface of the upper plate 40 installed on the lower portion of the upper structure (30).

The one-way sliding support device (100a) is the upper guide pin portion 121 protruding along the axial direction on the lower surface of the upper plate 40 installed on the lower portion of the upper structure (30); The elastic support device which is mounted on the upper surface of the lower plate 50 installed on the upper portion of the alternating 10 or the piers 20, and the lower guide groove portion 122 is formed to be inserted into the upper guide pin portion 121 ( 200); preferably.

An end portion of the lower guide pin portion 111 or the upper guide pin portion 121 is larger than the other portion, and the bottom of the upper guide groove portion 112 or the lower guide groove portion 122 is formed larger than the other portion. It is preferable.

The one-way sliding support device (100a) is a guide pin portion 131 protruding along the axial direction on the lower surface of the upper plate 40 installed on the lower portion of the upper structure (30); And the elastic support device 200 mounted on an upper surface of the lower plate 50 installed on the alternating portion 10 or the pier 20 so as to be guided by the inner regions of the both side guide pin portions 131. desirable.

The guide jaw portion 141 protruding outward is formed on both sides of the elastic support device 200, and the two guide pin portions 131 cover the guide jaw portion 141 to guide the both side guide pin portions 131. It is preferable to further include an engaging portion 142 extending inwardly.

The elastic support device 200 is a rubber body main body 210; Exposed steel sheet 220 is mounted so as to be exposed to the upper and lower portions of the main body 210;

The elastic support device 200 preferably further includes a plurality of steel sheets 230 inserted in a laminated structure inside the main body 210.

The present invention provides a bridge support system that can efficiently cope with the relative displacement between the shifts, bridge piers and the superstructure generated by the expansion, seismic load, wind load, etc. of the superstructure.

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

As shown in Figures 4 and 5, the present invention basically provides for alternating 10 or pier 20 and superstructure 30 to allow relative displacement of alternating 10 or pier 20 and superstructures. It relates to a bridge support system including a support device (1) provided between (30).

In the bridge supporting system according to the present invention, in particular, at a point where the relative displacement occurs relatively large, a sliding support device 100 allowing sliding is installed, and at a point where the relative displacement occurs relatively small, sliding is performed. It is characterized in that the elastic support device 200 is installed to allow elastic deformation without allowing.

That is, as described above, since the relative displacement does not occur uniformly over the entire section of the bridge, the supporting system of the entire bridge by applying the support structure of the structure different from each other according to the size of the relative displacement, It is uplifted.

As such, when the sliding support device 100 is applied to a point where the relative displacement occurs relatively large, the upper structure 30 supported by the sliding support device 100 may slide even if the relative displacement occurs large. According to the sliding drive of the device 100 has an effect that the damage of the support device is prevented.

However, in the case of applying the sliding support device 100 over the entire section of the bridge, there is an advantage that can prevent the damage to the support device as above, but this is the upper structure 30 on the shift 10, the bridge 20 ) Is a structure that is merely a mounting, there is a disadvantage that the structure is too fragile against lateral loads such as earthquake load and wind load.

Therefore, it is desirable to provide resistance against the above earthquake load and wind load by providing the elastic support device 200 that does not allow sliding at the point where the relative displacement occurs relatively small.

In general, the point where the relative displacement between the shift 10, the bridge 20 and the upper structure 30 occurs most is the portion where the shift 10 and the upper structure 30 corresponding to both ends of the bridge meet. In this case, the smallest point of relative displacement may be referred to as the portion where the center pier 20a and the superstructure 30 correspond to the center portion of the bridge.

Therefore, the sliding support device 100 is preferably installed between the shift 10 and the upper structure 30, the elastic support device 200 is the center of the plurality of piers 20 of the piers 20a and the upper structure It is preferable that it is provided between 30.

In the case of the remaining bridge 20 and the upper structure 30, an appropriate supporting device may be used according to the result of the structural analysis, but if there is no risk of damage due to relative displacement, as shown in FIG. Preferably, the elastic support device 200 is applied to all the piers 20 in terms of structural stability.

However, the above embodiment is only an example of the most common case, in the actual bridge design, the point where the relative displacement is large and small may vary depending on the variables such as the position of the expansion joint, in this case the structure analysis As a result, it is necessary to install the sliding support device 100 at the point where the actual relative displacement is large, and to install the elastic support device 200 at the point where the relative displacement is small.

Hereinafter, specific embodiments of the structure of the elastic support device 200 will be described.

Basically, the elastic support device 200 may be any structure that allows elastic deformation without allowing the sliding drive between the piers 20 and the upper structure 30.

The elastic support device 200, as shown in Figure 10, the body of the rubber material 210; It may be implemented by a structure including a; exposed steel sheet 220 mounted to be exposed to the upper and lower portions of the main body 210.

Here, the exposed steel sheet 220 has an advantage to strongly implement the coupling structure with the upper plate 40, the lower plate 50.

In addition, in the case where the structure further includes a plurality of steel sheets 230 inserted in a laminated structure inside the main body 210 of the elastic support device 200, while enabling the elastic drive to excellent rigidity overall bridge structure It has the advantage of contributing to the structural stability.

Hereinafter, specific embodiments of the structure of the sliding support device 100 will be described.

Basically, the sliding support device 100 may be any structure as long as it enables a sliding drive between the shift 10, the pier 20, and the upper structure 30.

However, as shown in Figures 6 to 9, when taking the structure of the one-way sliding support device 100a that allows only one-way driving in the axial direction, the resistance to lateral loads such as earthquake load, wind load can be increased. It is preferable in that it is.

This one-way sliding support device (100a) is, as shown in Figure 6, the elastic support device 200 mounted on the upper surface of the lower plate 50 installed on the top of the alternating 10 or piers 20; A lower guide pin 111 protruding along the axial direction on the upper surface of the elastic support device 200; It may be implemented by a structure comprising a; upper guide groove 112 formed to be inserted into the lower guide pin 111 on the lower surface of the upper plate 40 installed on the lower portion of the upper structure (30).

In this case, since the lower guide pin 111 is driven while receiving the guide of the upper guide groove 112, one-way driving of the sliding support device 100a is possible.

In addition, the reason for applying the elastic support device 200 to the core portion of the sliding support device (100a) is to cause the deformation caused by the relative displacement of the vertical structure to occur smoothly.

The one-way sliding support device (100a) is, as shown in Figure 7, the upper guide pin portion 121 protruding along the axial direction on the lower surface of the upper plate 40 installed on the lower portion of the upper structure 30; The elastic support device 200 is mounted on the upper surface of the lower plate 50 installed on the upper portion of the alternating 10 or the piers 20, and the lower guide groove portion 122 is formed so that the upper guide pin portion 121 is inserted into the upper surface. It may be implemented by a structure including;

In this case, since the upper guide pin portion 121 is driven while receiving the guide of the lower guide groove portion 122, the one-way driving of the sliding support device 100a is possible.

However, in the case of taking the same structure as in the above embodiments, a situation may occur in which the upper structure 30 is separated from the upper side of the supporting device due to sag or rising phenomenon due to uneven settlement.

In order to prevent this, as shown in Figure 7, the end of the lower guide pin portion 111 or the upper guide pin portion 121 is formed larger than the other portion, the upper guide groove portion 112 or lower guide groove portion 122 It is preferable that the bottom of the shape take a structure formed larger than the other parts.

The one-way sliding support device (100a), as shown in Figure 8, both side guide pins 131 protruding along the axial direction on the lower surface of the upper plate 40 installed on the lower portion of the upper structure 30; It is implemented by a structure including; an elastic support device 200 mounted on the upper surface of the lower plate 50 installed on the upper portion of the alternating 10 or the piers 20 to be guided by the inner region of the both side guide pin portion 131. May be

In this case, since the elastic support device 200 is driven while receiving the guides of both guide pins 131, the one-way driving of the sliding support device 100a is possible.

In addition, in the case of the present embodiment, as described above, in order to prevent the phenomenon that the upper structure 30 is separated from the upper side of the support device, as shown in Figure 9 is formed to protrude outward on both sides of the elastic support device 200 The guide jaw portion 141 is formed, and both the guide pin portions 131 cover the guide jaw portion 141 so that the guide pin portions 131 may have a structure further including a locking portion 142 extending inwardly. desirable.

Since the above has been described only with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention, as is well known, should not be construed as limited to the above embodiments, the present invention described above It will be said that both the technical idea and the technical idea which together with the base are included in the scope of the present invention.

1 to 3 relates to a conventional bridge support system,

1 is an overall configuration diagram.

2 and 3 are cross-sectional views of the support device.

4 to 10 relates to the bridge support system according to the present invention,

4 is a configuration diagram of the first embodiment.

5 is a configuration diagram of a second embodiment.

6 is a sectional view of a first embodiment of a one-way sliding support device;

7 is a sectional view of a second embodiment of a one-way sliding support device.

8 is a sectional view of a third embodiment of a one-way sliding support device.

9 is a sectional view of a fourth embodiment of a one-way sliding support device.

19 is a cross-sectional view of one embodiment of the elastic support device.

** Description of the symbols for the main parts of the drawings **

1: support device 10: shift

20: pier 30: superstructure

40: upper plate 50: lower plate

100: sliding support device 100a: one-way sliding support device

111: lower guide pin portion 112: upper guide groove portion

121: upper guide pin portion 122: lower guide groove portion

131: both side guide pin portion 141: guide jaw portion

142: locking portion 200: elastic support device

210: body 220: exposed steel sheet

230: multiple steel sheets

Claims (12)

Supporting device 1 is installed between the alternating 10 or pier 20 and the superstructure 30 to allow relative displacement of the alternating 10 or pier 20 and the superstructure 30. In a bridge support system comprising: At the point where the relative displacement occurs relatively large, a sliding support device 100 for allowing sliding is installed, At the point where the relative displacement occurs relatively small, the bridge support system, characterized in that the elastic support device 200 is installed to allow the elastic deformation without allowing the sliding. The method of claim 1, The sliding support device 100 is a bridge support system, characterized in that installed between the alternating (10) and the upper structure (30). The method of claim 2, The elastic support device 200 is a bridge support system, characterized in that installed between the pier (20a) and the upper structure of the center of the plurality of bridges (20). The method of claim 3, The elastic support device 200 is a bridge support system, characterized in that installed between the plurality of bridge piers (20) and the upper structure (30). The method of claim 1, The sliding support device 100 Bridge supporting system, characterized in that the one-way sliding support device (100a) that allows only one-way driving in the axial direction. The method of claim 5, The one-way sliding support device (100a) The elastic support device 200 mounted on the upper surface of the lower plate 50 installed on the upper portion of the alternating 10 or piers 20; A lower guide pin part 111 protruding along the axial direction on the upper surface of the elastic support device 200; An upper guide groove 112 formed to insert the lower guide pin 111 into a lower surface of the upper plate 40 installed below the upper structure 30; Bridge support system comprising a. The method of claim 5, The one-way sliding support device (100a) An upper guide pin portion 121 protruding along a throttling direction on a lower surface of the upper plate 40 installed below the upper structure 30; The elastic support device which is mounted on the upper surface of the lower plate 50 installed on the upper portion of the alternating 10 or the piers 20, and the lower guide groove portion 122 is formed to be inserted into the upper guide pin portion 121 ( 200); Bridge support system comprising a. The method according to claim 6 or 7, An end portion of the lower guide pin portion 111 or the upper guide pin portion 121 is larger than the other portion, and the bottom of the upper guide groove portion 112 or the lower guide groove portion 122 is formed larger than the other portion. Bridge support system, characterized in that. The method of claim 5, The one-way sliding support device (100a) Both side guide pin portions 131 protruding along the axial direction on a lower surface of the upper plate 40 installed on the lower portion of the upper structure 30; The elastic support device 200 mounted on the upper surface of the lower plate 50 installed on the upper portion of the alternating 10 or the pier 20 so as to be guided by the inner region of the both side guide pin portion 131; Bridge support system comprising a. The method of claim 9, The guide jaw portion 141 protruding outward is formed on both sides of the elastic support device 200, The both guide pins 131 cover the guide jaw portion 141 so that the guide jaw portion 141, the bridge guide system, characterized in that it further comprises a locking portion 142 extending inwardly formed. The method according to any one of claims 1 to 7, 9 or 10, The elastic support device 200 Rubber body 210; An exposed steel plate 220 mounted to be exposed to the upper and lower portions of the main body 210; Bridge support system comprising a. The method of claim 11, The elastic support device 200 Bridge supporting system, characterized in that it further comprises a plurality of steel sheets (230) inserted in a laminated structure inside the main body (210).

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