KR101002232B1 - Installation method of construction of bridge bearing where shear resistance equipment for aseismic reinforcement was adherent and this - Google Patents

Abstract

PURPOSE: A bridge support with a shear-resistant device for earthquake resistance and an installing method thereof are provided to ensure the safety of the bridge against the earthquake without a further earthquake-resistant unit since the resistance force sufficient to the horizontal seismic force, which is applied to the bridge in case of earthquake, is obtained. CONSTITUTION: A bridge support with a shear-resistant device for earthquake resistance consists of an upper plate, a lower plate, a shear-resistant device(100), a support(200), a horizontal-force resisting/supporting plate(300) and a rib connecting bolt(400). An inserting protrusion, which is downwardly protruded with a given depth, is formed on the center of the bottom of the upper plate, which consists of a square steel plate. Support grooves are upwardly formed on the center of the top of the lower plate at given intervals. The shear-resistant device consists of negative reaction resistance anchor bolts are fixed across the support grooves simultaneously with being inserted into the support grooves of the inserting protrusion.

Description

Installation method of construction of bridge bearing where shear resistance equipment for aseismic reinforcement was adherent and this}

The present invention relates to a bridge bearing with a seismic reinforcing shear resistance device and a method for installing the same, and in particular, the upper structure, which is installed on the lower structure of the bridge, reduces its bearing capacity when the left and right vibrations occur due to an earthquake, etc. The present invention relates to a bridge bearing with a seismic reinforcement shear resistance device and a method for installing the same, which are resistant to moments acting to prevent falling of the upper structure, as well as effectively preventing damage and destruction of the lower structure.

In general, when constructing bridges, both ends of the top plate are statically absorbed due to seasonal changes in temperature, wind, earthquake, etc. Between the bridge and the bridge there are several bridge bearings.

Bridge bearings applied to bridges include pot bearings, rubber bearings, and spherical bearings.These bridge bearings include bridge types, vertical and horizontal loads, displacements, The bridge bearing is selected according to various factors such as the amount of rotation and the friction coefficient of the bearing.

In particular, the bridge support of the movable form is selected in preparation for the construction of the bridge deck by the temperature change according to the season. The movable support consists of a fixed end, one-way and two-way movable support, and is fixed to one end of the bridge deck. It is provided with a stage, and on one side, a support in one direction and a bidirectional movable form is installed corresponding to the expansion and contraction of the bridge deck according to the design criteria.

However, when the bridge deck as described above is used for the bridge deck where the seismic design is not reflected, the seismic force acting in the horizontal direction is concentrated on the bridge support, resulting in the destruction of the bridge support, the detachment and collapse of the roof plate during the earthquake. There is a possibility of enormous loss of life and property damage.

Therefore, in the case where earthquake is expected to occur, bridges without seismic design are highly concerned about earthquake damage. Therefore, if the capacity of existing bridge bearings and seismic bearings is insufficient, it is necessary to improve the seismic performance of bridges. When designing the damper, viscous fluid damper, impact transmission device and fall prevention device, to ensure the seismic safety, proper seismic reinforcement work should be done.

Here, when looking at the conventional seismic reinforcement method, a method of replacing the existing bridge support using a bridge support with earthquake resistance is widely practiced, but at this time, due to the enormous construction cost due to the entire replacement of the bridge support to the existing bridge as a whole Not only does it cost a lot of economic burden to apply, but it is inevitable to damage the structure due to the need to raise the existing bridge deck to remove the existing bridge bearing, completely remove the bridge bearing, and then reinstall the bridge bearing. have.

That is, the conventional seismic reinforcing method raises the bridge deck, breaks up a part of the bridge bridge by dismantling the buried bridge support, and then a viscous fluid damper and shock transmission device, which is a seismic bridge support and damper in the crushed space, or prevents falling out. After arranging the device, by installing concrete and installing the installation part of the seismic bridge bearing, it causes tremendous obstacles due to the enormous budget to supplement the seismic performance with respect to the existing bridge and the prolonged construction and vehicle control due to the construction. There is a problem.

Accordingly, the present invention has been made to solve the problems described above, the upper structure is resisted by the support when the vibration is caused by a small earthquake, when the earthquake more than a certain magnitude, the support and shear resistance device and the negative reaction resistance To provide a bridge bearing with seismic reinforcement shear resistance device and its installation method to reduce the seismic force acting on the substructure by attenuating the seismic energy by anchor bolts and to effectively prevent damage and destruction of the substructure. There is this.

Bridge bearing with a seismic reinforcing shear resistance device according to the present invention for achieving the above object is made of a rectangular steel plate as a whole and at the same time the top plate formed with an insertion protrusion protruding downward in the middle of the lower surface, The lower plate is formed of a rectangular steel plate as a whole and at the same time in the middle of the upper surface, and the support plate is formed at a certain interval upward, and the sub-protrusion force is inserted into the support groove of the lower plate and fixed across the support groove at the same time. Shear resistance device consisting of a resistance anchor bolt; A base inserted into each of the upper and lower plates on the left and right sides with respect to the negative reaction resistance anchor bolt of the shear resistance device; A horizontal force resistance support plate which is welded to both sides of the lower surface of the lower plate and has a constant width and height; Characterized in that it consists of a rib connecting bolt fixedly installed across the horizontal force resistance support plate.

In addition, the bridge bearing installation method with a seismic reinforcement shear resistance device according to the present invention for achieving the above object is made of a rectangular steel plate as a whole between the lower portion of the upper structure and the upper portion of the lower structure at the same time in the middle of the lower surface An upper plate formed with an insertion protrusion protruding downward at a constant thickness, a lower plate formed with a rectangular steel plate as a whole, and having a support groove formed at regular intervals upward in the middle of the upper surface, and an insertion protrusion of the upper plate supporting the lower plate. A shear resistance device comprising a reaction force resistance anchor bolt inserted into the groove and fixed across the support yaw groove; A base inserted into each of the upper and lower plates on the left and right sides with respect to the negative reaction resistance anchor bolt of the shear resistance device; A horizontal force resistance support plate which is welded to both sides of the lower surface of the lower plate and has a constant width and height; It characterized in that the bridge bearing is attached to the seismic reinforcement shear resistance device consisting of a rib connecting bolt fixedly installed across the horizontal force resistance support plate.

As described above, the bridge bearing with a seismic reinforcement shear resistance device according to the present invention and the installation method thereof have the following effects.

First, in the seismic design of the bridge, the existing seismic design is converted into a seismic design to construct a bridge bearing with a seismic reinforcement shear resistance device which is designed in a manner corresponding to the horizontal force insufficient in the bridge support. Overcoming the uneconomical problems caused by the installation of expensive base isolation, there is an effect that the cost is reduced.

Second, the present invention can increase the structural resistance horizontal force by mounting a variety of bridge support to the shear resistance device, to ensure sufficient resistance to the horizontal earthquake force applied to the pier at the time of earthquake, so that the bridge against earthquake without additional seismic reinforcement There is an advantage to ensure the safety of the entire bridge.

Third, when the relative displacement occurs in the upper structure and piers due to creep, shrinkage, temperature change, seismic force or wind load, the present invention can be stretched in the longitudinal direction of the upper structure by a bridge bearing with a shear resistance device for seismic reinforcement. The transverse movement can be constrained to effect the appropriate transfer of load to the piers.

Fourth, in the present invention, when the upper structure is stretched in the longitudinal direction by the horizontal force, the longitudinal load is concentrated on the bridge support, which is a fixed substructure of the center portion of the bridge, so as to share the horizontal horizontal force as well as the longitudinal direction with the fixed bridge support. By doing so, there is an effect that can improve the load bearing capacity of the fixed bridge receiving along the transverse direction and the longitudinal direction.

Fifth, the present invention supports the horizontal force acting in the lateral direction of the bridge with a sufficient safety coefficient, and allows the movement of the upper structure in the longitudinal direction to facilitate the extension and contraction of the bridge, and to break the bridge by seismic force It is effective to prevent the local concentration of stress because it is accurately guided during the longitudinal movement of the superstructure.

Sixth, the present invention has an effect that can prevent the upper structure from falling or overturning the bridge support or pier without a separate fall prevention device by using a negative reaction resistance anchor bolt when fixing the lower plate on the bridge and alternating coping. have.

1 is a perspective view showing a fixed end bridge bearing with a seismic reinforcement shear resistance device according to the present invention,
Figure 2 is a front view showing a fixed end bridge bearing with a seismic reinforcement shear resistance device according to the present invention,
Figure 3 is a side view showing a fixed end bridge bearing with a seismic reinforcement shear resistance device according to the present invention,
Figure 4 is a plan view showing a fixed end bridge bearing with a seismic reinforcement shear resistance device according to the present invention,
5 is an exploded perspective view illustrating a fixed end bridge bearing with a seismic reinforcing shear resistance device according to the present invention;
Figure 6 is a perspective view showing a top plate of a fixed end bridge bearing with a seismic reinforcement shear resistance device according to the invention,
7 is a front view showing the upper plate of the fixed-end bridge bearing with a seismic reinforcement shear resistance device according to the present invention,
8 is a side view showing the top plate of the fixed-end bridge bearing with a seismic reinforcement shear resistance device according to the present invention;
9 is a plan view showing a top plate of a fixed end bridge bearing with a seismic reinforcement shear resistance device according to the present invention;
10 is a perspective view showing a bottom plate of the fixed-end bridge bearing with a seismic reinforcement shear resistance device according to the present invention,
11 is a front view showing the lower plate of the fixed-end bridge bearing with a seismic reinforcement shear resistance device according to the invention,
12 is a side view showing the lower plate of the fixed-end bridge bearing with a seismic reinforcement shear resistance device according to the present invention;
Figure 13 is a plan view showing the lower plate of the fixed-end bridge bearing with a seismic reinforcement shear resistance device according to the present invention,
Figure 14 is a perspective view showing the support of the fixed end bridge bearing with a seismic reinforcement shear resistance device according to the present invention,
15 is a cross-sectional view showing the installation state of the fixed-end bridge bearing with a seismic reinforcement shear resistance device according to the present invention;
16 is a perspective view showing a one-way movable end bridge bearing with a seismic reinforcement shear resistance device according to the present invention;
17 is a front view showing a one-way movable end bridge bearing with a seismic reinforcing shear resistance device according to the present invention,
18 is a side view showing a one-way movable end bridge bearing with a seismic reinforcement shear resistance device according to the present invention;
19 is a plan view showing a one-way movable end bridge bearing with a seismic reinforcement shear resistance device according to the present invention;
20 is an exploded perspective view illustrating a one-way movable end bridge bearing with a seismic reinforcing shear resistance device according to the present invention;
Figure 21 is a perspective view showing a top plate of the one-way movable end bridge bearing with a seismic reinforcement shear resistance device according to the present invention,
Figure 22 is a front view showing a top plate of the one-way movable end bridge bearing is attached to a shear resistance device for seismic reinforcement according to the present invention,
Figure 23 is a side view showing the top plate of the one-way movable end bridge bearing is attached to a shear resistance device for seismic reinforcement according to the present invention;
24 is a plan view showing a top plate of the one-way movable end bridge bearing with a seismic reinforcement shear resistance device according to the present invention;
25 is a perspective view showing a lower plate of the one-way movable end bridge bearing with a seismic reinforcement shear resistance device according to the present invention;
26 is a front view showing a lower plate of the one-way movable end bridge bearing with a seismic reinforcement shear resistance device according to the present invention;
Figure 27 is a side view showing the lower plate of the one-way movable end bridge bearing with a seismic reinforcement shear resistance device according to the present invention;
28 is a plan view showing a lower plate of the one-way movable end bridge bearing with a seismic reinforcement shear resistance device according to the present invention;
29 is a perspective view showing the support of the one-way movable end bridge bearing with a seismic reinforcement shear resistance device according to the present invention;
30 is a cross-sectional view showing an installation state of the one-way movable end bridge bearing is attached to a shear resistance device for seismic reinforcement according to the present invention.

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

[Fixing stage]

1 is a perspective view showing a fixed end bridge bearing with a seismic reinforcement shear resistance device according to the present invention, Figure 2 is a front view showing a fixed end bridge bearing with a seismic reinforcement shear resistance device according to the present invention. 3 is a side view showing a fixed end bridge bearing with a seismic reinforcing shear resistance device according to the present invention, Figure 4 is a fixed end bridge bearing with a seismic reinforcing shear resistance device according to the present invention. 5 is an exploded perspective view illustrating a fixed end bridge bearing with a seismic reinforcing shear resistance device according to the present invention.

As shown in these drawings, the bridge bearing with a seismic reinforcing shear resistance device according to the present invention is made of a rectangular steel plate 112 as a whole and at the same time the insertion protrusion 116 protruding downward in the middle of the lower surface ) Is formed of the upper plate 110 and the lower plate 120 formed of a rectangular steel plate 122 as a whole and at the same time upwardly at regular intervals in the center of the upper surface of the lower plate 120 and the upper plate 100. Shear resistance device 100 consisting of a negative reaction resistance anchor bolt 130 is inserted into the support groove 126 of the lower plate 120 and is fixed across the support groove 126 between the insertion protrusion 112 of the lower plate 120 and ; A support 200 inserted between the upper and lower plates 110 and lower plates 120 on the left and right sides with respect to the negative reaction resistance anchor bolt 130 of the shear resistance device 100; A horizontal force resistance supporting plate 300 which is installed on both sides of the lower surface of the lower plate 120 and has a predetermined width and height; Rib connection bolt 400 is fixedly installed across the horizontal force resistance support plate (300).

That is, the bridge bearing (B) with a seismic reinforcement shear resistance device according to the present invention, as shown in Figures 1 to 5, shear resistance device 100, negative reaction resistance anchor bolt 130, support 200 ), The horizontal force resistance support plate 300 and the rib connection bolt 400 is a device made of organically coupled.

Here, the shear resistance device 100 is made of a rectangular steel plate 112 as a whole, and at the same time the top plate 110 is formed with an insertion protrusion 116 protruding downward in a constant thickness in the center of the lower surface, and the rectangular steel plate as a whole The lower plate 120 and the insertion protrusion 112 of the upper plate 100 are formed of the support plate 126 and the support plate 126 is formed at regular intervals upward in the center of the upper surface, and the support groove of the lower plate 120. At the same time it is made of a negative reaction resistance anchor bolt 130 is inserted into the (126) and is fixedly installed across the support groove 126.

That is, the shear resistance device 100 is an upper plate 110, the lower plate 120 and the negative reaction resistance anchor bolt 130 is an organic coupling device.

Here, the top plate 110, as shown in Figures 6 to 9, made of a T-shape as a whole, a plurality of bolt holes 114 in a rectangular steel plate 112 with a predetermined width and thickness at regular intervals Perforations are formed, a protrusion 116 is formed to protrude downwardly at a constant height in the center of the steel plate 112, the protruding portion 116 is a structure in which the perforations 118 are formed.

In addition, the lower plate 120, as shown in Figures 10 to 13, is made of an inverted T shape as a whole, a plurality of bolt holes 124 in the rectangular steel sheet 122 with a predetermined width and thickness at regular intervals Perforations are formed, the support groove 126 is formed so as to protrude from both sides to a constant height upward from the center of the steel plate 122, the support groove 126 is a structure in which the garden hole 128 is formed perforated.

Here, the support groove 126 is composed of a one-way movable end of the open shape of the front and rear open or a closed end of the closed shape of the front, rear, left and right.

In addition, the negative reaction resistance anchor bolt 130 is inserted into the support groove 112 of the upper plate 100 is inserted into the support groove 126 of the lower plate 120 and fixed across the support groove 126. .

On the other hand, the bearing 200 is composed of any one of the elastic bearing, the port bearing, the spherical bearing, the base isolation bearing, the damping bearing, as shown in Figure 14, the negative reaction resistance anchor bolt of the shear resistance device ( 130 is fixed between the upper and lower plates 110 and 120 on the left and right sides.

In addition, the horizontal force resistance support plate 300 is made of a rectangular steel sheet 310, the bolt hole 312 is formed in the center of the steel plate 310 is formed in a perforated structure.

Then, the rib connecting bolt 400 is fixedly installed across the horizontal force resistance support plate (300).

Bridge bearing (B) with a seismic reinforcement shear resistance device according to the present invention made of a configuration as described above is the shear resistance device 100 and the support (200) when the upper structure (G) is vibrated by a small earthquake ), And in the event of a large-scale earthquake over a certain level, the support recess 126 and the protrusion 116 attenuate the seismic energy to reduce the moment acting on the substructure P, thereby causing damage and destruction of the substructure 400, It has the effect of effectively preventing falling.

Hereinafter, the installation of the bridge support with a seismic reinforcement shear resistance device according to the present invention having the configuration as described above will be described.

15 is a cross-sectional view showing a state of installation of a fixed-end bridge bearing with a seismic reinforcement shear resistance device according to the present invention.

As shown in this figure, the bridge bearing installation method with a seismic reinforcement shear resistance device according to the present invention, between the lower portion of the upper structure (G) and the upper portion of the lower structure (P), generally rectangular steel sheet 112 At the same time, the top plate 110 is formed with an insertion protrusion 116 protruding downwardly at a constant thickness in the middle of the lower surface, and a rectangular steel plate 122 as a whole, and at a certain interval upward at the center of the upper surface. The lower plate 120 having the support recess 126 and the insertion protrusion 112 of the upper plate 100 are inserted into the support recess 126 of the lower plate 120 and fixed across the support recess 126. Shear resistance device 100 consisting of a negative reaction resistance anchor bolt 130 is installed; A support 200 inserted between the upper and lower plates 110 and lower plates 120 on the left and right sides with respect to the negative reaction resistance anchor bolt 130 of the shear resistance device 100; A horizontal force resistance supporting plate 300 which is installed on both sides of the lower surface of the lower plate 120 and has a predetermined width and height; Rib connection bolt 400 is fixedly installed across the horizontal force resistance support plate 300, the upper plate 110 is made of a T-shaped as a whole, a plurality of rectangular steel plate 112 a certain width and thickness The two bolt holes 114 are formed at regular intervals, and a protrusion 116 is formed to protrude downwardly at a constant height in the center of the steel plate 112, and a long hole 118 is drilled in the protrusion 116. Is formed, the lower plate 120 is made of an inverted T shape as a whole, a plurality of bolt holes 124 are formed in a rectangular steel plate 122 at regular intervals at a predetermined interval, and formed of the steel plate 122 A support recess 126 is formed to protrude from both sides at a constant height upward from the center, and the support recess 126 is formed with a perforated hole 128, and the support recess 126 is open or front open or backward. Closed closure Consisting of, the support 200 is composed of any one of the elastic support, port support, spherical support, base isolation support, damping support, the horizontal force resistance support plate 300 is made of a rectangular steel sheet 310, In the middle of the steel plate 310 is installed a bridge bearing (B) is attached with a shear resistance device for seismic reinforcement formed with a bolt hole 312 is formed.

At this time, the horizontal force resistance support plate 300 and the rib connecting bolt 400 is embedded in the lower structure (P).

[One-way movable end]

16 is a perspective view showing a one-way movable end bridge bearing with a seismic reinforcement shear resistance device according to the present invention, Figure 17 is a one-way movable end bridge bearing with a seismic reinforcement shear resistance device according to the present invention. 18 is a side view showing a one-way movable end bridge bearing with a seismic reinforcing shear resistance device according to the present invention, Figure 19 is a one-way movable end with a seismic reinforcement shear resistance device according to the present invention. 20 is an exploded perspective view illustrating a one-way movable end bridge bearing with a seismic reinforcing shear resistance device according to the present invention.

As shown in these drawings, the bridge bearing with a seismic reinforcing shear resistance device according to the present invention is made of a rectangular steel plate 112 as a whole and at the same time the insertion protrusion 116 protruding downward in the middle of the lower surface ) Is formed of the upper plate 110 and the lower plate 120 formed of a rectangular steel plate 122 as a whole and at the same time upwardly at regular intervals in the center of the upper surface of the lower plate 120 and the upper plate 100. Shear resistance device 100 consisting of a negative reaction resistance anchor bolt 130 is inserted into the support groove 126 of the lower plate 120 and is fixed across the support groove 126 between the insertion protrusion 112 of the lower plate 120 and ; A spherical bearing 200 inserted between the upper and lower plates 110 and lower plates 120 on the left and right sides with respect to the negative reaction resistance anchor bolt 130 of the shear resistance device 100; A horizontal force resistance supporting plate 300 which is installed on both sides of the lower surface of the lower plate 120 and has a predetermined width and height; Rib connection bolt 400 is fixedly installed across the horizontal force resistance support plate (300).

That is, the bridge bearing (B) with a seismic reinforcement shear resistance device according to the present invention, as shown in Figure 16 to 20, shear resistance device 100, negative reaction resistance anchor bolt 130, spherical bearing (200), the horizontal force resistance support plate 300 and the rib connecting bolt 400 is a device consisting of organically coupled.

Here, the shear resistance device 100 is made of a rectangular steel plate 112 as a whole, and at the same time the top plate 110 is formed with an insertion protrusion 116 protruding downward in a constant thickness in the center of the lower surface, and the rectangular steel plate as a whole The lower plate 120 and the insertion protrusion 112 of the upper plate 100 are formed of the support plate 126 and the support plate 126 is formed at regular intervals upward in the center of the upper surface, and the support groove of the lower plate 120. At the same time it is made of a negative reaction resistance anchor bolt 130 is inserted into the (126) and is fixedly installed across the support groove 126.

That is, the shear resistance device 100 is an upper plate 110, the lower plate 120 and the negative reaction resistance anchor bolt 130 is an organic coupling device.

Here, the top plate 110, as shown in Figures 21 to 24, is made of a T-shaped as a whole, a plurality of bolt holes 114 in the rectangular steel plate 112 at a constant width and thickness at regular intervals Perforations are formed, a protrusion 116 is formed to protrude downwardly at a constant height in the center of the steel plate 112, the protruding portion 116 is a structure in which the perforations 118 are formed.

In addition, the lower plate 120, as shown in Figures 25 to 28, is made of an inverted T shape as a whole, a plurality of bolt holes 124 in the rectangular steel plate 122 at a constant width and thickness at regular intervals Perforations are formed, the support groove 126 is formed so as to protrude from both sides to a constant height upward from the center of the steel plate 122, the support groove 126 is a structure in which the garden hole 128 is formed perforated.

Here, the support groove 126 is composed of an open one-way movable end of the front and rear open.

In addition, the negative reaction resistance anchor bolt 130 is inserted into the support groove 112 of the upper plate 100 is inserted into the support groove 126 of the lower plate 120 and fixed across the support groove 126. .

Meanwhile, as shown in FIG. 29, the spherical bearing 200 is disposed between the upper plate 110 and the lower plate 120 on the left and right sides based on the negative reaction resistance anchor bolt 130 of the shear resistance device 100. Insert is fixed.

In addition, the horizontal force resistance support plate 300 is made of a rectangular steel sheet 310, the bolt hole 312 is formed in the center of the steel plate 310 is formed in a perforated structure.

Then, the rib connecting bolt 400 is fixedly installed across the horizontal force resistance support plate (300).

Bridge bearing (B) with a seismic reinforcement shear resistance device according to the present invention made of a configuration as described above is the shear resistance device 100 and the support (200) when the upper structure (G) is vibrated by a small earthquake ), And the rib connection bolt 400 attenuates the seismic energy to reduce the moment acting on the substructure P in the event of a large earthquake more than a certain amount to effectively prevent damage and destruction of the substructure P. It has an effect.

Hereinafter, the installation of the bridge support with a seismic reinforcement shear resistance device according to the present invention having the configuration as described above will be described.

30 is a cross-sectional view showing an installation state of the one-way movable end bridge bearing with a seismic reinforcement shear resistance device according to the present invention.

As shown in this figure, the bridge bearing installation method with a seismic reinforcement shear resistance device according to the present invention, between the lower portion of the upper structure (G) and the upper portion of the lower structure (P), generally rectangular steel sheet 112 At the same time, the top plate 110 is formed with an insertion protrusion 116 protruding downwardly at a constant thickness in the middle of the lower surface, and a rectangular steel plate 122 as a whole, and at a certain interval upward at the center of the upper surface. The lower plate 120 having the support recess 126 and the insertion protrusion 112 of the upper plate 100 are inserted into the support recess 126 of the lower plate 120 and fixed across the support recess 126. Shear resistance device 100 consisting of a negative reaction resistance anchor bolt 130 is installed; A spherical bearing 200 inserted between the upper and lower plates 110 and lower plates 120 on the left and right sides with respect to the negative reaction resistance anchor bolt 130 of the shear resistance device 100; A horizontal force resistance supporting plate 300 which is installed on both sides of the lower surface of the lower plate 120 and has a predetermined width and height; Rib connection bolt 400 is fixedly installed across the horizontal force resistance support plate 300, the upper plate 110 is made of a T-shaped as a whole, a plurality of rectangular steel plate 112 a certain width and thickness The two bolt holes 114 are formed at regular intervals, and a protrusion 116 is formed to protrude downwardly at a constant height in the center of the steel plate 112, and a long hole 118 is drilled in the protrusion 116. Is formed, the lower plate 120 is made of an inverted T shape as a whole, a plurality of bolt holes 124 are formed in a rectangular steel plate 122 at regular intervals at a predetermined interval, and formed of the steel plate 122 A support groove 126 is formed to protrude from both sides at a constant height upward from the center, and the support hole 126 is formed with a perforated hole 128, and the support groove 126 is open and closed. The horizontal force Wherein the support plate 300 to install the bolt holes 312 is perforated in advance STEEL the shear resistance device attached to bridge bearings (B) formed in the center of the made of a steel plate 310 on the square, the plate (310).

At this time, the horizontal force resistance support plate 300 and the rib connecting bolt 400 is embedded in the lower structure (P).

100: shear resistance device 110: top plate
112: steel plate 114: bolt hole
116: protrusion 118: long hole
120: lower plate 122: steel sheet
124: bolt hole 126: support groove
128: gardener 130: negative reaction resistance anchor bolt
200: support 300: horizontal force resistance support plate
310: steel plate 312: bolt hole
400: rib connection bolt 500: socket connection bolt
510: socket 520: washer
530: bolt
B: Bridge bearing with shear resistance device for seismic reinforcement
G: superstructure P: substructure

Claims (12)

The top plate 110 is formed of a rectangular steel plate 112 as a whole and at the same time the insertion protrusion 116 is formed to protrude downwardly in the middle of the lower surface, and
The lower plate 120 made of a rectangular steel plate 122 as a whole and at the same time in the center of the upper surface at a predetermined interval upward, the support plate groove 126 is formed,
Shear consisting of a negative reaction resistance anchor bolt 130 is inserted into the support protrusion 112 of the upper plate 100 is inserted into the support groove 126 of the lower plate 120 and fixed across the support groove 126. A resistance device 100;
A support 200 inserted between the upper and lower plates 110 and lower plates 120 on the left and right sides with respect to the negative reaction resistance anchor bolt 130 of the shear resistance device 100;
A horizontal force resistance supporting plate 300 which is installed on both sides of the lower surface of the lower plate 120 and has a predetermined width and height;
Bridge bearing with a seismic reinforcement shear resistance device, characterized in that consisting of a rib connecting bolt 400 is fixed across the horizontal force resistance support plate 300. The method of claim 1,
The upper plate 110 is made of a T-shape as a whole, a plurality of bolt holes 114 are formed in a rectangular steel plate 112 at regular intervals and formed at a predetermined interval, and downward in the center of the steel plate 112 Protruding portion 116 is formed so as to protrude to a certain height, the bridge 116 is a bridge bearing with a seismic reinforcement shear resistance device characterized in that the long hole 118 is formed perforated. The method of claim 1,
The lower plate 120 is formed in an inverted T shape as a whole, and a plurality of bolt holes 124 are formed in the rectangular steel plate 122 at regular intervals, and are formed in a perforated shape, upward from the center of the steel plate 122. The support groove groove 126 is formed to protrude from both sides to a predetermined height, the support groove groove 126 is a bridge bearing with a seismic reinforcement shear resistance device, characterized in that the garden hole 128 is formed perforated. The method according to claim 1 or 3,
The support groove 126 is a bridge bearing with a seismic reinforcement shear resistance device, characterized in that the front and rear open or closed type closed front, rear, left and right. The method of claim 1,
The bearing 200 is a bridge bearing with a seismic reinforcement shear resistance device, characterized in that consisting of any one of the elastic bearing, port bearing, spherical bearing, base isolation bearing, damping bearing. The method of claim 1,
The horizontal force resistance support plate 300 is made of a rectangular steel plate 310, the bridge bearing with a seismic reinforcement shear resistance device, characterized in that the bolt hole 312 is formed in the center of the steel plate (310). Between the lower part of the superstructure and the upper part of the substructure,
At the same time, the upper plate 110 is formed of a rectangular steel sheet 112 and the insertion protrusion 116 is formed to protrude downwardly at a constant thickness in the middle of the lower surface, and the rectangular steel sheet 122 as a whole. The lower plate 120 having the support groove 126 formed at a predetermined interval upward and the insertion protrusion 112 of the upper plate 100 are inserted into the support groove 126 of the lower plate 120 and at the same time support groove ( A shear resistance device (100) consisting of a negative reaction resistance anchor bolt (130) fixedly installed across the rod (126); A support 200 inserted between the upper and lower plates 110 and lower plates 120 on the left and right sides with respect to the negative reaction resistance anchor bolt 130 of the shear resistance device 100; A horizontal force resistance supporting plate 300 which is installed on both sides of the lower surface of the lower plate 120 and has a predetermined width and height; Bridge with a seismic reinforcement shear resistance device is installed, characterized in that the bridge bearing with a seismic reinforcement shear resistance device consisting of a rib connection bolt 400 is fixedly installed across the horizontal force resistance support plate 300 Support installation method. The method of claim 7, wherein
The upper plate 110 is made of a T-shape as a whole, a plurality of bolt holes 114 are formed in a rectangular steel plate 112 at regular intervals and formed at a predetermined interval, and downward in the center of the steel plate 112 Protruding portion 116 is formed so as to protrude to a certain height, bridge protrusion installation method with a seismic reinforcement shear resistance device, characterized in that the long hole 118 is formed in the protrusion 116 perforated. The method of claim 7, wherein
The lower plate 120 is formed in an inverted T shape as a whole, and a plurality of bolt holes 124 are formed in the rectangular steel plate 122 at regular intervals, and are formed in a perforated shape, upward from the center of the steel plate 122. A support recess groove 126 is formed so as to protrude from both sides to a certain height, the support recess groove 126 is a bridge bearing installation method with a seismic reinforcement shear resistance device, characterized in that the garden hole 128 is formed perforated. The method according to claim 7 or 9,
The support recess 126 is a bridge bearing installation method with a seismic reinforcement shear resistance device, characterized in that the front and rear open or closed, closed type is blocked. The method of claim 7, wherein
The support 200 is a bridge bearing installation method with a seismic reinforcement shear resistance device, characterized in that consisting of any one of the elastic bearing, port bearing, spherical bearing, base isolation bearing, damping bearing. The method of claim 7, wherein
The horizontal force resistance support plate 300 is made of a rectangular steel sheet 310, the bridge bearing with a seismic reinforcement shear resistance device is installed, characterized in that the bolt hole 312 is formed in the center of the steel plate 310 Method.

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