KR100724596B1 - Earthquake-proof reinforcement shock relaxation system of bridge structure - Google Patents

Abstract

The present invention relates to a shock absorbing device for seismic reinforcement of a bridge structure, and more specifically, to a seismic structure of a bridge structure to improve seismic performance by installing in an existing bridge structure that does not secure sufficient seismic performance through seismic evaluation. The present invention relates to a shock absorber for advanced steel.

According to the present invention, a shock absorbing device for seismic reinforcement of a bridge structure according to the present invention is provided as a shock absorbing device that prevents a fall of an upper structure of a bridge from an external shock such as an earthquake. It is achieved by being composed of a buffer means for offsetting the vibration transmitted from the piers to the alternating by itself so as to intersect, and a fixing means rotatably coupled to both ends of the buffer means, and anchored to the girder, piers, alternating do.

Girder, Bridge, Pier, Shift, Anchor

Description

Earthquake-proof reinforcement shock relaxation system of bridge structure

1 is an embodiment showing that the shock-absorbing device for seismic reinforcement of the bridge structure according to the present invention is mounted on the "I" type girder and pier or alternating of the prestressed concrete bridge.

 Figure 2 is a partially enlarged view showing the interior of the shock absorbing means according to the present invention.

Figure 3 is an embodiment showing that the fixing means applied to the shock-absorbing device for the seismic reinforcement of the bridge structure according to the present invention is mounted on the piers, shifts.

Figure 4 is another embodiment showing that the shock-absorbing device for seismic reinforcement of the bridge structure according to the present invention is mounted on the "I" type girder and pier or alternating of the prestressed concrete bridge.

5 to 7 are various embodiments showing that the shock-absorbing device for seismic reinforcement of the bridge structure according to the present invention is mounted to the BOX type girder and the pier or alternating of the steel box bridge.

8 to 9 is another embodiment showing that the box-type girder and the pier to the alternating of the shock-absorbing device for seismic reinforcement of the bridge structure according to the present invention.

10 to 11 is another embodiment showing that the shock absorber applied in Figures 8 to 9 is applied to the bridge of the prestress box.

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

10: girder 20, 30: pier, shift

40: buffer means 42, 44: both ends

50: fixing means 60: slab

The present invention relates to a shock absorbing device for seismic reinforcement of a bridge structure, and more specifically, to a seismic structure of a bridge structure to improve seismic performance by installing in an existing bridge structure that does not secure sufficient seismic performance through seismic evaluation. The present invention relates to a shock absorber for advanced steel.

For example, in Korea, about 70% of bridges scattered on roads prescribed by the Road Act were designed and constructed before the seismic design standards were enacted, and many of them would not be reasonably considered. It is estimated.

Therefore, in order to reduce the risk of earthquake disasters in Korea, it is very important to improve the seismic performance of existing bridges as well as the seismic design of new bridges.

There are two known methods that designers can choose to improve the seismic performance of these bridges.

First, it is a conventional reinforcement system to enhance the strength of the structure to meet the required strength. Second, it is an earthquake protective system that reduces the required strength by using an earthquake isolation system or energy dissipation system. In particular, this method may not be applicable to all structures or all environments, but may be another alternative to improve economics over existing reinforcement methods.

As another known example, various designs have been devised to improve seismic performance as a kind of seismic power reduction system, and to install shock absorbers between piers to improve seismic performance. However, the reliability of the effect was also questioned.

The present invention has been made to solve this problem, the object of the present invention is a girder (girder) and pier applied to various reinforced concrete bridge (RC), prestressed concrete bridge (PSC), steel concrete bridge (S / T), etc. In addition, the present invention provides an impact relief device for seismic reinforcement of a bridge structure that is installed between shifts to protect the bridge from an external impact such as an earthquake.

In one preferred embodiment, the shock-absorbing device for seismic reinforcement of a bridge structure according to the present invention is a hydraulic jack or an elastic body that overcomes the above-mentioned problems and withstands a repetitive load of 100 tons or more for performing a buffering action from external impacts. The buffer means provided therein is hinged between the piers or the alternating girders.

In the shock absorbing means of the present invention, cross-to-horizontally coupled between the piers, the shift and the girder, and a fixing means for fixing the shock absorbing means between the piers, the shift and the girder is hinged to the end of the shock absorbing means.

Other objects and effects of the present invention will become apparent from the following detailed description, and the detailed description and examples showing the preferred embodiments of the present invention do not limit the scope of the present invention.

The present invention for achieving the above object, as a shock-absorbing device for preventing the fall of the upper structure of the bridge from an external impact such as earthquake, is installed so as to cross each other on the girder and the bridge of the upper part of the bridge to the bridge to the bridge A shock absorbing means for canceling the vibration transmitted from itself and a fixing means rotatably coupled to both ends of the shock absorbing means and anchored in the girder, the pier, and the alternating portion are achieved.

In addition, the girder of the upper portion of the bridge is characterized in that any one applied to the tee bridge, steel box bridge, steel plate bridge, prestressed box bridge, prestressed concrete bridge, ramen bridge.

In addition, the shock absorbing means is provided with an actuating portion operable therein, the actuating portion is characterized in that any one of the hydraulic oil to the spring, rubber material is installed to generate an elastic repulsive force.

In addition, the fixing means is composed of a fixing bracket which is mounted on one side of the pier or alternating, the gerber, the buffer means is hinged rotatably, and an anchor bolt fixing the fixing bracket to the pier or alternating, the gerber. It is characterized by.

In addition, the girders applied to the bridge of the steel box type, prestressed concrete, prestressed box is characterized in that the buffer means is located between the fixing bracket of the fixing means and the wall of the girder.

Hereinafter, one preferred embodiment according to the present invention will be described in detail with reference to the accompanying drawings. First, like reference numerals designate functionally identical or similar parts throughout the drawings.

Figure 1 is an embodiment showing that the shock-absorbing device for seismic reinforcement of the bridge structure according to the present invention is mounted on the "I" type girder of the pre-stressed concrete bridge and the pier or alternating, Figure 2 is a buffer means according to the present invention Figure 3 is an enlarged view, Figure 3 is an embodiment showing that the fixing means applied to the shock-absorbing device for the seismic reinforcement of the bridge structure according to the present invention is mounted on the bridge, alternating, Figure 4 is a bridge structure according to the present invention Shock-absorbing device for seismic reinforcement of the other is shown to be mounted on the pier or alternating bridge and "I" type girder of prestressed concrete bridge.

1 to 4, the shock absorbing device for the seismic reinforcement of the bridge structure according to the present invention is a shock absorbing device to prevent the fall of the upper structure of the bridge from an external impact such as earthquake, the girder 10 of the bridge And the buffer means 40 which self-cancels the vibration transmitted from the pier 20 to the bridge 30 by intersecting each other on the bridge 20 to the bridge 30 of the bridge and the buffer means 40. It is rotatably coupled to both ends (42, 44), and includes a fixing means (50) anchored in the girder (10) to the pier (20), alternating (30).

As shown in Figure 1, the bridge according to the present invention is largely divided into high-level structure and upper structure, the upper structure is a part constituting the main body of the bridge, directly supporting the vehicle and train passing through the bridge, etc. , The substructure supports the superstructure, serves to transfer the load from the superstructure to the ground and consists of the pier 20, the alternating 30 and the foundation.

In particular, the girder 10 located between the slab 60 directly supporting the vehicle, the train, and the like, the pier 20, and the shift 30 receives all the loads of the slab 60 in turn.

Therefore, when an external shock such as an earthquake is transmitted to the piers 20 to 30, the slab 60 always includes the risk of overturning.

At this time, in order to protect the slab 60 from shaking of the pier 20 to the alternating 30 due to the external impact, the impact transmitted from the pier 20 to the alternating 30 may be blocked from being transmitted to the slab 60. It can be seen that.

To this end, it is installed between the various girders 10 and the piers 20 to the alternating 30 to apply the shock absorbing means 40 to offset the impact.

The shock absorber 40 divides the transmitted vibration into a vector, and moderates or re-relaxes the vibration on one side, thereby delivering the minimum vibration to the slab 60.

As shown in Figure 2, the shock absorbing means 40 according to the present invention has an operating portion 46 is formed therein, it is a constant against external force, such as hydraulic oil to spring, rubber material to mitigate the external impact there It contains a buffer material that can generate elastic repulsion.

The buffer material to be applied to the present invention should be designed to withstand repeated loads between 10 and 1000 tons, have a restoring force that can be immediately restored to external shocks, and have longitudinally extending ends 42 and 44. Formed.

The external shock may be transmitted from the pier 20 to the alternating 30 to the girder 10, but the transmission may be re-delivered back to the shock absorbing means 40, and may be directly transmitted to the shock absorbing means 40, thereby transferring the pier 20 to the pier 20. The external shock transmitted from the shift 30 is immediately canceled out.

Referring again to FIGS. 1 and 4, it can be seen that the slab 60 receives less external shock since the external shock transmitted or re-delivered is substantially canceled by the shock absorbing means 40.

Such a shock absorbing means 40 may be implemented in various embodiments, and may be preferably a combination of the forms shown in FIGS. 1 and 4.

The shock absorbing means 40 should naturally be fixed to the girder 10 from the piers 20 to the alternating 30.

1 to 3 show such a fixing means 50, as shown in the fixing means 50 is pier 20 to the alternating 30, one side of the gerber 10, the buffer A fixing bracket 52 to which the means 40 is pivotally hinged, and an anchor bolt 54 for fixing the fixing bracket 52 to the piers 20 to the alternating 30 and the gerber 10. consist of.

The fixing bracket 52 is located on one side of the pier 20 to the alternating 30 and the gerber 10, and in order to fix the fixed bracket 52, the pier 20 to the alternating 30 and the gerber 10 are firmly secured by the anchor bolt 54. ).

The shock absorbing means 40 is hingedly rotatably coupled to the fixing bracket 52. This is because the shock absorbing means 40 must be rotated by a predetermined angle in accordance with the external shock to prevent damage to the shock absorbing means 40, and the rotated shock absorbing means 40 returns to maintain its original state.

In other words, when the rotation is impossible to be fixed, the shock absorbing means 40 due to vibration is broken at both ends 42 and 44 of the shock absorbing means 40 by the breaking force.

Again, how the fixing means 10 is embedded in the pier 20 to the alternating 30 and the gerber 10 will be described.

First, the fixing bracket 52 is located on one side of the piers 20 to the alternating 30 and the gerber 10, and the non-contraction mortar is poured to the bottom of the fixing bracket 52 to a predetermined depth.

At this time, the reinforcing steel should be installed in the non-shrink mortar, reinforcing steel should be crossed with the reinforcement of the existing piers 20 to 30, the gerber 10.

This is to increase the coupling force of the fixing means 10 is a natural and can be applied to vary the size, depth depending on the state of the bridge.

An anchor bolt 44 may be driven to the upper side of the fixing bracket 10, or as shown in the drawing, the anchor bolt 44 may be preinstalled on the fixing bracket 10 to pour the non-contraction mortar.

Therefore, since the buffer means 40 is firmly coupled to the bridges 20 to 30 and the gerber 10, external shocks may be prevented from being transmitted to the slab 60 of the bridge.

Next will be described in detail each embodiment and the effects according to the buffer means 40, the fixing means 50 is applied to a variety of bridges as described above.

As shown in FIG. 1, the vibration transmitted by the earthquake or the like is re-transmitted to the pier 20, the alternate 30.

The retransmitted vibration vibrates the pier 20, the alternating 30, and the vibration is transmitted to the slab 60 via the girder 10.

At this time, the buffer means 40 according to the present invention is directly installed in the pier 20, the alternating 30 receives the re-transmitted vibration immediately.

Therefore, the vibration transmitted to the slab 60 and the vibration transmitted to the shock absorbing means 40 are divided in the vector direction, and the vibration propagating in the vector direction is naturally canceled because the vibration is partially canceled by the shock absorbing means 40. It can be seen that

In more detail, it can be seen that the buffer means 40 installed in the horizontal direction as shown in FIG. 4 can further cancel the vibration by receiving the aforementioned vibration in the vector direction again.

Therefore, the vibration transmitted to the slab 60 is fine, so the bridge is safe from earthquakes.

5 to 7 are various embodiments showing that the shock-absorbing device for seismic reinforcement of a bridge structure according to the present invention is mounted on a pier or alternating box with a box-type girder of a steel box bridge, as described above. It is possible to prevent the external shock from being transmitted to the slab 60 by installing one or more shock absorbing means 40 and the fixing means 50 in the 20 to 30 shifts.

This is also applied to the girder 10 is installed in various forms, it can be seen that the transmitted vibration is largely canceled due to the various installation forms of the buffer means (40).

8 to 9 is another embodiment showing that the shock-absorbing device for the seismic reinforcement of the bridge structure according to the present invention is mounted to the BOX type girders of the steel box bridge and the pier or alternating, the various girders 10, the buffer means ( 40 is located at least one between the fixing bracket 52 of the fixing means 50 and the wall of the girder 10.

This is to more easily prevent the external shock is transmitted to the girder 10, by applying hydraulic, spring, rubber material to the buffer means 40 is applied to block the external shock is transmitted to the girder 10. do.

In addition, it can be seen that the shock absorbing means 40 as shown in Figures 1 to 4 can be further offset the transmission of vibration.

10 to 11 show that the shock absorbing device applied to Figs. 8 to 9 is applied to the bridge of the prestress box, this also has the effect of blocking the external shock to the slab (60).

And as can be seen in the various embodiments as described above the external shock is transmitted to the slab 60 can be seen that the device is sufficient as a seismic installation according to the earthquake or the like is blocked.

This invention can be implemented in other various forms, without deviating from the mind or main characteristic. For this reason, the above-described embodiments are merely examples in all respects and should not be interpreted limitedly. The scope of the present invention is shown by the scope of the claims, and is not limited by the specification text. Again, all variations and modifications belonging to the equivalent scope of the claims are within the scope of the present invention.

In the present invention, it goes without saying that various other modifications are possible. For example, if necessary, all the above-described embodiments may be combined. In addition, a hydraulic jack having a piston and a cylinder may be applied to the shock absorbing means 40 operated by hydraulic pressure.

Accordingly, all modifications existing within the spirit and scope of the present invention are included in the claims.

As described in detail above, according to the shock absorbing device for the seismic reinforcement of the bridge structure according to the present invention, it is applied to a variety of reinforced concrete bridge (RC), prestressed concrete bridge (PSC), steel concrete bridge (S / T) It is installed between girders, bridges and shifts to protect the bridges from external shocks such as earthquakes to prevent or delay the fall of the slabs of bridges, reduce the impact of bridges, and distribute the impact of bridges or shifts. can do. As a result, the seismic reliability of the bridge is significantly improved when the bridge is repaired by the seismic data.

Claims (5)

As a shock mitigation device to prevent the fall of the bridge superstructure from external shocks, Cushioning means for offsetting vibrations transmitted from the bridges to the bridges by installing the girder of the bridges and the bridges or the bridges of the bridges to cross each other; Fastening means rotatably coupled to both ends of the shock absorbing means and anchored to the girder, the pier, and the shift; The girder of the upper part of the bridge is composed of any one applied to the tee bridge, steel box bridge, steel plate bridge, prestressed box bridge, prestressed concrete bridge, ramen bridge, The buffer means, There is an actuating part formed therein, The operating unit is installed any one of hydraulic oil to the spring, rubber material to generate an elastic repulsive force, The fixing means, A fixed bracket mounted on one side of a pier or alternating and a gerber, the buffer means being hinged rotatably; It comprises a; anchor bolt for fixing the fixing bracket to the pier or alternating, Gerber; The girder applied to the bridge of the steel box type, prestressed concrete, prestressed box, the shock absorbing device for the seismic reinforcement of the bridge structure, characterized in that the buffer means is located between the fixing bracket of the fixing means and the wall of the girder. delete delete delete delete

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