KR20030075361A - Complex bridge bearing for reinforcement and earthquake-resistant - Google Patents

Abstract

PURPOSE: A composite bridge seat system for reinforcing earthquake-proof is provided to prevent damage or accidents at a collision of the upper plate and the girder from excessive lateral force to the bridge by restricting breakage of the upper structure against earthquake. CONSTITUTION: A composite bridge seat system is arranged on a pier to support a beam, and composed of a fixed board(100) installed in the upper center of the pier by an anchor bolt, assembling support pieces(120) installed in the fixing part of the fixed board and faced to each other, an elastic pad(200), a stainless steel sheet(210), an elastic pad(220) and a protection steel plate(230) stacked between assembling pieces, and an elastic pad(300) mounted to the assembling support pieces. A couple of hooks(310) are fixed in the assembling support pieces, and fitting grooves(301) are longitudinally formed in upper and lower parts of the elastic pad. Upper and lower hooks are inserted to upper and lower fitting grooves of the elastic pad.

Description

Composite bridge for earthquake-resistant reinforcement {COMPLEX BRIDGE BEARING FOR REINFORCEMENT AND EARTHQUAKE-RESISTANT}

The present invention relates to a seismic reinforcement composite bridge device, which can prevent the upper structure is destroyed by the seismic force transmitted through the lower structure of the bridge, the collision of the top plate and the girder due to the excessive lateral force generated in the direction perpendicular to the bridge axis of the bridge The present invention relates to a seismic reinforcement composite stabilization device for preventing damage and falling accidents.

1 to 6 are views of a conventional composite bridge device, a plan view and a side view of a long span bridge showing an example of a long span bridge constructed by the conventional method in Figures 1 and 2, the composite by the conventional method in Figure 3 Some exploded perspective views showing the structure of the stabilization device are respectively shown, and FIG. 4 is an exemplary view in which all the span ends of the short span beams connected to each other are movable ends, and FIG. Exemplary views showing the case of the fixed end are shown, respectively, Figure 6 is a cross-sectional view taken along the line AA of Figure 4 showing an example of the use of a conventional synthetic teaching device.

As shown in the drawing, the conventional synthetic stabilization device (S) is a spherical fixed substrate 10 that is fixed to the anchor bolt 11 in the upper middle portion of the pier (1), and the fixed substrate 10 The seat body is installed between the two fastening support pieces 20, 20 'and the fastening support pieces 20, 20' which are installed to face each other inside the fixing part of the mounting body and is seated on the upper surface of the fixing substrate 10 It consists of 30.

The anti-separation pieces 12 and 12 'of a predetermined height are installed in the front and rear intermediate portions of the fixed substrate 10 so as to protrude in parallel. ) And the rainwater discharge grooves 13 are formed at both sides of the upper middle of the upper surface of the substrate 10, and the epoxy injection grooves 14 having a predetermined width and depth are arranged in a lattice shape on the bottom surface thereof. Epoxy injected through the injection groove 14 increases the adhesion between the substrate 10 and the upper surface of the pier 1, and also allows the fixing substrate 10 to be seated.

The fastening support pieces 20 and 20 'installed on the upper surface of the fixed substrate 10 are bent to have an L-shaped cross section and fastened through the long holes 22 formed in the lower fastening piece portion 21. T-beam or PC beam (2-1) (2-2) between each upper support piece (23) which is fastened and fixed to the fixed substrate (10) by several bolts (25) and thus installed in parallel with each other. Both sides of the span end portions 2a and 2a 'of the back can be inserted and supported or guided together, and they are inserted into both sides of the upper side of the support piece 23 of the two fastening support pieces 20 and 20'. When one side span end 2a or 2a 'of both beams 2-1 and 2-2 to be installed is the fixed end F, the span end 2a or 2a' of the beam and the fastening support piece 20 Fastening bolt holes 24 for connecting and fixing the respective support piece portions 23 of the 20 'are respectively formed.

On the other hand, between the two fastening support pieces (20, 20 '), that is, the main body 30 is seated on the upper surface of the fixed substrate 10, the concave-convex portions 31a, 32a are mutually opposed to the inner surface It is composed of a dust-resistant rubber 33 made of a material such as neoprene rubber, which is sandwiched between the upper and lower plate material 31, 32 made of a corrosion-resistant alloy, such as stainless steel formed, and the upper and lower plate material 31, 32 is pressed. On the upper surface of the upper plate 31, the bottom faces of the span ends 2a and 2a 'of the beams 2-1 and 2-2 can be placed together.

In the drawings, reference numerals 40 and 40 'denote span ends of both beams when the span ends 2a and 2a' of the two beams 2-1 and 2-2 are installed as the movable ends M. 2a) shows a connecting plate for interconnecting the plurality of fixing bolts 41 with each other.

In connecting and combining existing bridge spans in the form of short spans by using the composite bridge device configured as described above, the beams (2-l) (2-2) and the upper plate of the two short spans are well known by using a hydraulic jack. 3-1) (3-2) is raised to a certain height, the existing bridge installed between the span end (2a) (2a ') and the top of the pier (1) of each beam (2-1) (2-2) After removal of the device, the span end portions 2a and 2a 'of both beams 2-1 and 2-2 and a plurality of connecting plates 40 and 40' having a predetermined size as shown in Figs. Fastening and fixing by means of the fixing bolt 41 of the two beams (2-1) (2-2) integrally connected, and then the composite teaching device (S) in the upper middle portion of the pier (1) located below the connection portion Fixing the fixed substrate 10 of the anchor plate 11 with an anchor bolt 11 and injecting epoxy resin through the epoxy injection hole 14 on the bottom thereof, thereby stably installing the fixed substrate 10 on the upper surface of the piers 1. In addition, the body 30 on the upper surface of the substrate 10 And both fastening support pieces 20 and 20 'are connected to each other so that the gap between the support piece portions 23 is connected to both beams 2-1 and 2-' with the connecting plates 40 and 40 '. It has a width substantially equal to the width of the span end portions 2a and 2a 'of 2).

When both beams 2-1 and 2-2 are connected in this way, the raised hydraulic jack is lowered to lower the connected beams 2-1 and 2-2 and the upper plate 3-1 and 3-2. By making the connecting portion of each beam (2-1) (2-2) is to be seated together on the upper surface of the alternating body 30 of the synthesized teaching device (S), and both sides thereof between the support piece 23 1, 2, 4 and 6 is to be composed of the short-span beam as shown in Figure 1, in this state, the bridge top plate (3-1) (3-) in which the existing expansion joint portion is removed 2) By filling and packing the gaps between them, they are synthetically deformed into bridges in the form of long spans.

As described above, the span ends 2a and 2a 'of both beams 2-1 and 2-2, which are connected and synthesized in the form of a long span, are firmly fastened by the connecting plates 40 and 40'. The lower end of each span end portion 2a, 2a 'is seated together on the upper surface of the main assembly 30 of the synthetic teaching device S, and both sides of the connecting portion are each supporting piece portion of the fastening support pieces 20, 20' ( Since it is sandwiched between 23 and supported, when the bridge deck 3 and the beam (2-1) (2-2) is expanded or contracted can be smoothly guided along the upper surface of the bridge main body 30, such a beam The upper and lower plate members 31 and 32 are made of a corrosion resistant alloy such as stainless steel, and the anti-vibration rubber 33 is interposed between the plate members 31 supporting the span end. As a result, it is possible to absorb and mitigate shocks applied during the passage of the vehicle without being corroded by rain or the like, so that the function of the required bridge can be smoothly and stably performed. It is possible to extend its service life.

In the above construction example, all of the span ends 2a and 2a 'of each of the beams 2-1 and 2-2 are movable ends, but the span ends 2a' of the one side beam 2-2 are one example. ) Is a fixed end, the fixed end side span end 2a 'in a state in which both beams 2-1 and 2-2 are separated from each other without using the connecting plates 40 and 40' as shown in FIG. ) Only one side beam (2-2) by connecting and fixing only with a bolt 26 fastened through each of the fastening bolt holes 24 formed on one side of the support piece portion 23 of each fastening support piece (20, 20 '). Can be set as the fixed end and the other end 2a as the movable end.

Synthetic bridge device for the existing bridges as described above had a problem that the seismic safety is lowered due to the lack of countermeasures against the earthquake.

The present invention was devised to solve the conventional problems as described above, it is possible to prevent the upper structure is destroyed by the seismic force transmitted through the lower structure of the bridge, and by generating excessive lateral force in the direction perpendicular to the bridge axis of the bridge An object of the present invention is to provide a seismic reinforcing composite teaching device that can prevent damage and falling accidents caused by collision of the top plate and girder.

1 to 6 is a view related to the conventional synthetic teaching device,

1 and 2 are a plan view and a side view of a long span bridge showing an example of a long span bridge constructed by a conventional method.

Figure 3 is a partially exploded perspective view showing the configuration of a synthetic teaching device according to the conventional method.

4 and 5 are a plan view showing a construction example of a conventional composite stabilization device, Figure 4 is an exemplary view in the case where all the ends of the span of the short span beam is interconnected. 5 is an exemplary view showing a case in which the span end portion of the mutually recognized short span beam is a movable end and a fixed end.

6 is a cross-sectional view taken along the line A-A of Figure 4 showing an example of the use of the conventional synthetic teaching device.

7 to 10 is a view showing a composite teaching device for seismic reinforcement according to the present invention,

Figure 7 is a perspective view of a seismic reinforcement composite teaching apparatus.

Figure 8 is a plan view of a seismic reinforcement composite teaching apparatus.

Figure 9 is a side view of the seismic strengthening composite teaching device.

Figure 10 is a longitudinal sectional view of the seismic strengthening composite teaching device.

<Description of Symbols for Main Parts of Drawings>

1: Pier 100: Fixed board

110: anchor bolt 120: fastening support piece

200, 220, 300: elastic pad 210: stainless steel sheet

230: protective steel 301: locking groove

310: hook

In order to achieve the object as described above, the seismic reinforcement composite bridge device according to the present invention has severe damage due to the collision of the upper plate and the girder due to excessive lateral force generation in the direction perpendicular to the bridge axis of the bridge during the earthquake. Since falling accidents occur frequently, in order to prepare for seismic force in the perpendicular direction of the axial shaft, an elastic pad such as a neoprene rubber pad is introduced inside the L-type fastening support pieces to absorb shocks, and to prevent P-type seismic waves (up and down). In order to prevent the damage caused by installing a synthetic elastic pad including an elastic pad, such as a rubber pad is configured to relax the upper structure by the seismic force coming through the substructure of the bridge by relaxing the impact.

More specifically, the seismic reinforcement composite stabilizing device according to the present invention includes a fixed substrate fixed to the anchor bolt at the upper middle portion of the pier, both fastening support pieces installed to face each other inside the fixed portion of the fixed substrate, and these An elastic pad, a stainless steel plate, an elastic pad and a protective steel sheet, which are sequentially stacked between the fastening support pieces, and an elastic pad attached to the inner surfaces of both fastening support pieces, are configured.

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

7 to 10 is a view showing a seismic reinforcement composite teaching apparatus according to the present invention, Figure 7 is a perspective view of the seismic reinforcement composite teaching apparatus, Figure 8 is a plan view of the seismic reinforcement synthetic teaching apparatus, Figure 9 The side view of the seismic reinforcement composite teaching apparatus is shown, respectively, Figure 10 is a longitudinal cross-sectional view of the seismic reinforcement composite teaching apparatus.

As shown in the figure, the seismic reinforcement composite bridge device according to the present invention is disposed on the bridge (1) in the conventional composite bridge device for supporting the beam (B), the anchor bolt in the upper middle portion of the bridge (1) The fixed substrate 100 fixedly installed by the 110, both fastening support pieces 120 which are installed to face each other inside the fixed part of the fixed substrate 100, and are sequentially laminated between the fastening support pieces 120. And an elastic pad 200, a stainless steel plate 210, an elastic pad 220, and a protective steel plate 230, and elastic pads 300 attached to inner surfaces of both of the fastening support pieces 120. do.

Both fastening support pieces 120 installed on the upper surface of the fixing substrate 100 are each bent to have an L-shaped cross section, and several bolts 125 fastened through the long holes 122 formed in the lower support piece part 121. Fastening bolt is fastened to the upper surface of the pier (1) together with the fixed substrate 100, and the fastening bolt 126 is fastened to both sides of the upper support piece portion 123 of these fastening support piece 120 The balls 124 are formed, respectively, and a plurality of reinforcing pieces 127 are fixed at predetermined intervals between the lower support piece 121 and the upper support piece 123 of both fastening support pieces 120.

In addition, in attaching the elastic pads 300 to the inner surfaces of the both fastening support pieces 120, the locking grooves 301 are formed in the longitudinal direction on the upper and lower surfaces of the elastic pads 300, and both the fastening support pieces ( A pair of hooks 310 are fixed to the inner surface of the 120 to attach the upper and lower locking grooves 301 of the elastic pad 300 to the upper and lower hooks 310.

As described above, the seismic reinforcement synthetic teaching apparatus of the present invention is constructed like the existing synthetic teaching apparatus as described above, and an elastic pad 300 such as a rubber pad is attached to the inner surfaces of both L-type fastening support pieces 120. Therefore, the shock absorbed by the seismic force in the perpendicular direction of the axial shaft, and the elastic pad 200, 220, such as neoprene rubber pad on the inner bottom surface of both L-type fastening support pieces 120 between the stainless steel plate ( Since the protective layer 230 is laminated on the uppermost layer and laminated through the 210, the damage caused by the P-type seismic waves (the seismic waves acting in the vertical direction) can be prevented.

Accordingly, the present invention can prevent the superstructure from being destroyed by the seismic force transmitted through the substructure of the bridge, the upper plate and the girder due to the excessive lateral force generated in the direction perpendicular to the bridge axis of the bridge during the earthquake in the vicinity of the bridge device of the concrete bridge It is possible to prevent serious damages and failures caused by collisions.

The present invention as described above allows the existing short span bridges to be easily synthesized and deformed into long span bridges, and is generated by uneven settlement by integrating individual bridges separately installed in each span section into an integrated bridge device. It can solve the eccentricity, and can extend the service life of the bridge device, can prevent the destruction of the superstructure by the seismic force transmitted through the bridge substructure, and the earthquake near the bridge device of the concrete bridge Due to the excessive lateral force generated in the direction perpendicular to the bridge axis of the city bridge, there is an advantage that the bridge can be used safely by preventing serious damages and falling accidents caused by collision of the top plate and the girder.

Claims (2)

In the conventional composite bridge device disposed on the bridge (1) to support the beam (B), the fixing substrate 100 is fixed to the anchor bolt 110 in the upper middle portion of the bridge (1), and the fixing thereof Both fastening support pieces 120 that are installed to face each other inside the fixing part of the substrate 100, and elastic pads 200, stainless steel plates 210, and elastic layers that are sequentially stacked and installed between the fastening support pieces 120. A pad (220) and a protective steel plate (230), seismic reinforcement composite stabilization apparatus comprising a resilient pad (300) attached to the inner surfaces of both fastening support pieces (120). The method of claim 1, wherein the pair of hooks 310 are fixed to the inner surfaces of both fastening support pieces 120, and the locking grooves 301 are formed in the longitudinal direction on the upper and lower sides of the elastic pad 300. The upper and lower locking grooves 301 of the elastic pad 300 are fitted to the upper and lower hooks 310 to be coupled to each other.