KR102053112B1 - Method of structure aseismic reinforcement using reinforcing Fibers - Google Patents

Abstract

The present invention relates to a seismic reinforcement method of a structure using reinforcing fiber. According to the present invention, the seismic reinforcement method of a structure using reinforcing fiber comprises: a first step of fixing an injection pipe on an outer circumferential surface of a structure; a second step of wrapping reinforcing fiber; a third step of installing fiber reinforcement panels; and a fourth step of injecting an epoxy resin for adhesion into an injection hole of the injection pipe towards the reinforcing fiber positioned between the fiber reinforcement panels and the structure to integrally synthesize the structure, the reinforcing fiber, and the fiber reinforcement panels. Therefore, when the epoxy resin for adhesion discharged through discharge holes from the lowermost discharge hole to the uppermost discharge hole is filled to the position of a corresponding discharge hole when performing injection work of the epoxy resin for adhesion, minute pressure acts on the reinforcing fiber and the fiber reinforcement panels. The epoxy resin for adhesion is discharged from the upper discharge hole by the acting pressure to disperse the pressure acting on the reinforcing fiber and the fiber reinforcement panels below to prevent deformation of the reinforcing fiber and the fiber reinforcement panels below. Since the gaps between the structure, the reinforcing fiber, and the fiber reinforcement panels are uniformly filled, the injection work of the epoxy resin for adhesion can be performed by a single job to reduce work costs.

Description

Method of structure aseismic reinforcement using reinforcing Fibers}

The present invention is capable of repairing general cracks of structures such as piers or pillars of buildings, and reinforcing structures having seismic resistance to withstand vibration by integrally combining reinforcing fibers, fiber reinforced panels and structures. The present invention relates to a seismic reinforcing method for structures using reinforcing fibers capable of shortening air.

In general, since structures such as piers or pillars of buildings are exposed to the outside, cracks may be generated or broken by vibrations applied from the outside, such as an earthquake, after a long time after construction. Due to corrosion, the strength of the structure is weakened.In particular, structures installed in water (lake or seawater) are not only affected by the above problems, but also erosion by water flow and salt in the case of seawater. The strength is weakened more severely.

In particular, the structure is weakened due to the above problems are very likely to occur due to the earthquake damage is urgently required to repair, reinforcement and seismic reinforcement.

Conventionally, in order to solve the above problems, reinforcement by adding concrete mortar to the part where the part of the structure has fallen due to the cracking part or corrosion of the structure, or reinforcing and fixing the steel plate wrapped around the structure There is a method of reinforcing by injecting an epoxy resin, but this also could not produce an excellent reinforcing effect due to problems such as corrosion occurs in the iron plate.

Conventional structures for seismic reinforcement to solve this problem is to install a high-strength fibers and panels and a method of reinforcing by injecting an adhesive epoxy resin between the structure and the panel.

However, in the case of the seismic reinforcement method of the existing structure including the prior art, when the epoxy resin injection for bonding in a single operation, the reinforcing fibers and fiber reinforcement panel burst due to the pressure of the injected epoxy resin, and some sections There was a problem in that the filling of the epoxy resin is not made.

In order to prevent this, the conventional adhesive epoxy resin injection operation is to inject and cure a small amount of the adhesive epoxy resin between the structure and the panel, and change the position to inject and cure a small amount of the adhesive epoxy resin between the structure and the panel. As a method, it takes a break for the curing of the adhesive epoxy resin, and the position to inject the adhesive epoxy resin has to be changed, so that the injection of the epoxy resin for the adhesive is continuously performed (without a break for curing in one place. There is a problem in that the operation cost increases because the air is lengthened by performing the dividing in multiple steps.

The present invention has been invented to solve the above problems, an object of the present invention is the reinforcing fiber and fiber reinforcement panel burst due to the pressure of the adhesive epoxy resin injected during the epoxy resin injection operation, epoxy in some sections It is to provide a seismic reinforcing method of the structure using a reinforcing fiber to prevent the problem of filling the resin, and to reduce the operating cost by reducing the air.

Seismic reinforcement method of the structure using the reinforcing fiber of the present invention to achieve the above object, the injection pipe formed with a plurality of discharge holes and the injection hole in the same direction as the axial direction of the structure, such as a pillar or pillar of the building A first step of fixing to an outer circumferential surface of the structure; Wrapping a reinforcing fiber on an outer circumferential surface of the structure; A third step of installing a fiber reinforcement panel to surround a circumference of the wrapped reinforcing fiber; And by injecting an adhesive epoxy resin into an injection hole of the injection tube to the reinforcing fiber side positioned between the fiber reinforcement panel and the structure, so that the adhesive epoxy resin is discharged into the discharge hole of the injection tube, and the structure, the reinforcing fiber and And a fourth step of integrally synthesizing the fiber reinforcement panels.

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The first step is to form an injection tube insertion groove into which the injection tube is inserted into the outer peripheral surface of the pier in the same direction as the axial direction of the piers, and inserting the injection tube into the injection tube insertion groove fixed do.

In the first step, the lower part of each injection tube is connected through a connection tube, and the adhesive epoxy resin injected through one of the injection holes is dispersed into each injection tube through the connection tube. And is discharged through the discharge holes of the injection pipes.

The plurality of discharge holes of the injection tube is formed at equal intervals and characterized in that the size of the discharge hole is reduced from the lower side to the upper side.

The plurality of discharge holes of the injection tube is formed in the same size, characterized in that the distance between the discharge holes from the lower side toward the upper side.

According to the present invention has the following effects.

First, the injection tube is fixed to a structure such as a bridge or a pillar of a building, the reinforcing fibers are wrapped to a predetermined thickness along the periphery of the structure, and then the fiber reinforcement panels are installed on the outside, and the adhesive pipe is attached through the injection tube. By injecting and curing epoxy resins, reinforcing fibers, fiber reinforcement panels and structures are integrated to allow general crack repair of structures, and to prevent neutralization due to various pollutions, to prevent erosion by water flow, and to prevent corrosion by salt. Not only can the strength and durability be improved, but the performance can be improved so that the structure can receive more load than the original load, and the structure can be reinforced with seismic resistance to withstand vibration. have.

When the epoxy resin is injected, the adhesive epoxy resin discharged through each discharge hole from the discharge hole located at the lowermost side to the discharge hole located at the top thereof is filled up to the position of the corresponding discharge hole, reinforcing fibers and fiber reinforcement. A slight pressure acts on the panel, and the applied pressure discharges the epoxy resin from the upper discharge hole to dissipate the pressure acting on the reinforcing fiber and fiber reinforcement panel on the lower side. It is possible to prevent the deformation of the panel and to evenly fill the voids between the structure, the reinforcing fibers and the fiber reinforcement panel, so that there is no need to change the position where the adhesive epoxy resin is injected, and a breaker for curing the adhesive epoxy resin. The adhesive epoxy resin can be injected continuously without any Since it can be carried out up, the work cost can be reduced.

Figure 1 shows a first step of the seismic reinforcement method of a structure using a reinforcing fiber according to the present invention.
Figure 2 shows a second step of the seismic reinforcement method of the structure using the reinforcing fiber according to the present invention.
Figure 3 shows a fifth step of the seismic reinforcement method of the structure using a reinforcing fiber according to the present invention.
4 is a cross-sectional view taken along line AA ′ of FIG. 1.
FIG. 5 is a sectional view taken along line BB ′ of FIG. 2.
Figure 6 shows the injection pipe of the seismic reinforcement method of the structure using the reinforcing fiber according to the present invention.
Figure 7 shows the injection pipe of the seismic reinforcement method of the structure using the reinforcing fiber according to the present invention.
Figure 8 shows a connector of the seismic reinforcement method of the structure using the reinforcing fiber according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings, but the well-known technical parts will be omitted or compressed for brevity of description.

Seismic reinforcement method of the structure using the reinforcing fiber according to the present invention is a reinforcing method to wrap and reinforce the reinforcing fiber 200 around the structure 10, such as a pillar or pillar of the building.

1 to 8, the first step (S100) to the fifth step (S500) of the seismic reinforcing method of the structure using the reinforcing fiber according to the present invention will be described.

The first step (S100) is a step of fixing at least one or more injection tube 100 on the outer peripheral surface of the structure 10 in the same direction as the axial direction of the structure 10 to be reinforced.

Referring to Figure 1, the first step (S100) is to form at least one injection tube insertion groove (1J) on the outer circumferential surface of the structure 10 in the same direction as the axial direction of the structure 10 to be reinforced, Each injection tube insertion groove (1J) can be fixed by inserting a plurality of discharge holes (H) and the injection tube 100 is formed in the injection hole (I) at the bottom.

The injection tube 100 is provided with a circular or polygonal tube, and an injection hole I through which the epoxy resin 400 for injection is injected is formed at the lowermost side, and the injection tube 100 is formed from an upper side of the injection hole I. A plurality of discharge holes (H) for discharging the adhesive epoxy resin 400 injected into the injection hole (I) to the upper side of the) is formed, the size of the plurality of discharge holes (H), discharge holes (H) The interval D between may be provided differently, and will be described in detail below.

Referring to FIG. 8, the lower part of each injection tube 100 is connected through a connection pipe 110 and an adhesive epoxy resin injected through one injection hole I of the injection pipes 100. 400 is distributed to each injection pipe 100 through the connection pipe 110 is discharged through the discharge holes (H) of the injection pipe (100).

Then, the adhesive epoxy resin 400 is injected into the injection hole (I) of the injection tube 100 is discharged through the discharge hole (H) of the injection tube 100 is evenly distributed around the structure 10 In order to spread, the injection tube 100 is provided with at least two, the injection tube insertion groove (1J) may be formed at least two, in the following the injection tube 100 and the injection tube insertion groove (1J) are each 4 Explain that the dog is prepared.

Referring to Figure 2, the second step (S200) is a step of wrapping the reinforcing fiber 200 on the outer peripheral surface of the structure (10).

At this time, the reinforcing fibers 200 prepared in advance over the entire circumference of the structure 10 to be reinforced are tightly wrapped (wrap) and fixed without gaps to a predetermined thickness.

In addition, the wrapping of the reinforcing fiber 200 is performed manually by workers.

In addition, the reinforcing fiber 200 is provided with a fiber roving cloth, glass fiber, Kevlar fiber, aramid fiber, carbon fiber, or the like.

Referring to FIG. 3, a third step S300 and a fourth step S400 will be described.

The third step (S300) is a step of installing the fiber reinforcement panels (310a, 310b) to wrap the circumference of the wrapped reinforcing fibers 200.

Here, the fiber reinforcement panels (310a, 310b) can be manufactured in a form corresponding to the structure 10, such as circular or square, the fiber reinforcement panels (310a, 310b) are connected to each other a pair of the outer peripheral surface of the structure (10) It is arranged to wrap.

In more detail, after the pair of fiber reinforcement panels 310a and 310b are installed in close contact with the structure 10 around the structure 10 to the outside of the reinforcing fiber 200 wrapped in the structure 10, the joint portion ( 320) to seal it.

In more detail, when the adhesive epoxy resin 400 is injected into the injection hole I of the injection pipe 100, the epoxy resin 400 for adhesion to the other injection pipes 100 is connected through the connection pipe 110. Injected, the adhesive epoxy resin 400 is evenly injected into the periphery of the structure 10 through the discharge holes (h1, h2 ~ hn) of the injection pipe 100, the discharge hole (h1) located at the lowermost side The adhesive epoxy resin 400 discharged through each of the discharge holes h1 and h2 to hn from the discharge hole hn located at the top thereof is filled up to the position of the corresponding discharge hole h1, and the reinforcing fiber 200 And a small pressure is applied to the fiber reinforcing panels 310a and 310b, and the adhesive epoxy resin 400 is discharged from the discharge hole h2 located next by the applied pressure to fill the voids at the upper side, and the lower side. The reinforcing fiber 200 located in the lower side by dissipating the pressure acting on the reinforcing fiber 200 and the fiber reinforcement panel (310a, 310b) A fiber-reinforced epoxy resin panel (400) for continuously bonded in a state (310a, 310b) is not deformed is injection.

Referring to FIG. 6, when the adhesive epoxy resin 400 is injected into the injection hole I, first, the adhesive epoxy resin 400 is formed through the discharge hole h1 formed above the injection hole I. When the adhesive epoxy resin 400 discharged and discharged between the structure 10 and the reinforcing fiber 200 reaches the position of the discharge hole h1, the adhesive epoxy resin injected into the injection hole I ( 400 is discharged through the discharge hole (h2) is located along the inside of the injection pipe 100, and then located, to the position of the discharge hole (h1) between the structure 10 and the reinforcing fiber 200 Filled epoxy resin 400 is a small amount of pressure of the epoxy resin 400 for the action, the adhesive epoxy resin 400 is discharged to the discharge hole (h2) located in the next upper portion to fill the voids in the upper And, the pressure of the adhesive epoxy resin 400 is not applied to the discharge hole (h1) in the lower reinforcing fiber 200 and The pressure is not applied to the fiber reinforcement panels (310a, 310b) is a continuous injection of the epoxy resin 400 for adhesion in a state that does not deform.

This continuous injection of adhesive epoxy resin 400 reduces the pressure of the adhesive epoxy resin 400 applied to the reinforcing fibers 200 and the fiber reinforcement panels (310a, 310b).

Therefore, the problem of breaking the reinforcing fibers 200 and the fiber reinforcement panels 310a and 310b by the pressure of the injected epoxy resin 400 can be prevented, and when the epoxy resin 400 is injected, It is not necessary to change the position in which the adhesive epoxy resin 400 is injected, it is possible to continuously inject the adhesive epoxy resin 400 without a break for curing the epoxy resin 400, the adhesive epoxy resin ( 400) The injection operation can be performed in a single operation, so that the air can be shortened.

In addition, the seismic reinforcing method of the structure using the reinforcing fiber according to the present invention includes a lapping step (R100) for wrapping the reinforcing fiber 200 on the outer circumferential surface of the structure 10, such as a pier or a pillar of a building; An installation step (R200) of installing fiber reinforcement panels 310a and 310b to surround the circumference of the wrapped reinforcing fiber 200; And injecting the adhesive epoxy resin 400 into the reinforcing fiber 200 located between the fiber reinforcing panels 310a and 310b and the structure 10, and then the structure 10, the reinforcing fiber 200 and the fiber reinforcing panel 310a, Synthesis step (R300) to integrally synthesize 310b); may be made.

Here, the wrapping step (R100) and the installation step (R200) is the same as the second step (S200) and the third step (S300) described above, a detailed description thereof will be omitted.

And, in the synthesis step (R300), the position where the adhesive epoxy resin 400 is injected is not changed, the adhesive epoxy resin 400 may be continuously injected to the reinforcing fiber 200 side without a break for curing. .

6 and 7, the injection pipe 100 according to the first and second embodiments will be described.

First, referring to FIG. 6, the injection pipe 100 according to the first embodiment will be described. A plurality of discharge holes h1, h2 ˜ hn of the injection pipe 100 are formed at equal intervals D and are provided on the lower side. The size of the discharge hole (h1, h2 ~ hn) is reduced from the upper side.

In the case of the injection pipe 100 according to the first embodiment, the amount of the adhesive epoxy resin 400 is discharged through the discharge holes (h1, h2 ~ hn) toward the upper side of the injection pipe 100 structure 10 A lot of adhesive epoxy resin 400 is discharged from the lower side of the structure, the adhesive epoxy resin 400 is discharged to the discharge hole (h2 ~ hn) located in the upper by the pressure of the discharged adhesive epoxy resin 400 structure 10, the gap between the reinforcing fiber 200 and the fiber reinforcement panel (310a, 310b) can be tightly filled, the adhesive epoxy resin applied to the reinforcing fiber 200 and the fiber reinforcement panel (310a, 310b) Since the pressure of 400 may be reduced, the operation of injecting the epoxy resin 400 for bonding may be performed more safely than in the related art.

Referring to the injection pipe 100 according to the second embodiment with reference to Figure 7, the plurality of discharge holes (H) of the injection pipe 100 is formed of the same size, discharge holes (H) from the lower side toward the upper side The distance between the distance (d1, d2 ~ dn) is characterized in that the distance.

In the case of the injection pipe 100 according to the second embodiment, the distance between the discharge holes (H) toward the upper side of the injection pipe 100 becomes far, so that the epoxy resin for the adhesive on the lower side of the structure 10 ( 400 is discharged a lot, the adhesive epoxy resin 400 is discharged to the discharge hole (H) located in the upper by the pressure of the discharged epoxy resin 400 discharged structure 10, reinforcing fibers 200 and fibers The gap between the reinforcing panels 310a and 310b can be tightly filled, and the pressure of the adhesive epoxy resin 400 applied to the reinforcing fibers 200 and the fiber reinforcing panels 310a and 310b can be reduced. Compared with the conventional injection epoxy resin 400 can be carried out more safely.

In addition, the injection pipe 100 has a distance (d1, d2 ~ dn) between the discharge holes farther from the lower side to the upper side, the size of the discharge hole (h1, h2 ~ hn) is reduced from the lower side to the upper side It is provided so that, the epoxy resin 400 for the injection operation can be carried out more safely.

As a result, the seismic reinforcement method of the structure using the reinforcing fiber according to the present invention is formed by inserting the injection pipe inserting groove (1J) in the structure 10, such as a pillar of the bridge or building, inserting and fixing the injection pipe 100, Wrap the reinforcing fiber 200 to a predetermined thickness along the periphery of the structure 10 and install the fiber reinforcement panels (310a, 310b) on the outside, the adhesive epoxy resin 400 through the injection pipe 100 By injecting and curing, the reinforcing fibers 200, the fiber reinforcing panels 310a and 310b, and the structure 10 are integrated, and general crack repair is possible, and neutralization due to various pollution, prevention of erosion and salt by water flow By preventing the corrosion and increasing the strength of the structure 10 to improve the performance (load resistance) to improve the durability, as well as to strengthen the structure 10 having a seismic resistance to withstand vibrations Can be.

In addition, during the injection operation of the adhesive epoxy resin 400, the adhesive epoxy resin 400 is evenly injected into the circumference of the structure 10 through the discharge holes (h1, h2 ~ hn) of the injection pipe 100 , The adhesive epoxy resin 400 discharged through each of the discharge holes h1, h2 to hn from the discharge hole h1 located at the bottom to the discharge hole hn located at the uppermost end is located at the position of the corresponding discharge hole. As it rises, a slight pressure acts on the reinforcing fibers 200 and the fiber reinforcing panels 310a and 310b, and discharges the adhesive epoxy resin 400 from the upper discharge holes h2 to hn under the applied pressure to the lower side. By dissipating the pressure acting on the reinforcing fibers 200 and the fiber reinforcing panels 310a and 310b, the deformation of the reinforcing fibers 200 and the fiber reinforcing panels 310a and 310b located on the lower side can be prevented, and the structure ( 10), since the voids between the reinforcing fibers 200 and the fiber reinforcing panels 310a and 310b are uniformly filled, the adhesion epoch It is possible to prevent the problem that the reinforcing fibers 200 and the fiber reinforcement panels 310a and 310b are damaged by the resin 400, and the operation of injecting the epoxy resin 400 for bonding may be performed in a single operation. It can shorten the work cost.

As described above, although the detailed description of the present invention has been made by the embodiments, it is understood that the present invention is limited to the above embodiments only because the above-described embodiments have only been described with reference to preferred examples of the present invention. It should not be understood that the scope of the invention should be understood as the claims and equivalents described below.

10: structure (pier, pillar of the building) 100: injection pipe 110: connector
200: reinforcing fibers 310a, 310b: fiber reinforcement panel
400: adhesive epoxy resin

Claims (6)

A first step of fixing an injection tube having a plurality of discharge holes and an injection hole formed at a lower portion thereof in the same direction as an axial direction of a structure such as a pillar or a pillar of a building to an outer circumferential surface of the structure;
Wrapping a reinforcing fiber on an outer circumferential surface of the structure;
A third step of installing a fiber reinforcement panel to surround a circumference of the wrapped reinforcing fiber; And
The structure, the reinforcing fibers and fibers by injecting the adhesive epoxy resin into the injection hole of the injection pipe to the reinforcing fiber side located between the fiber reinforcement panel and the structure to discharge the adhesive epoxy resin into the discharge hole of the injection pipe. And a fourth step of integrally synthesizing the reinforcement panels.
Seismic reinforcement method of structure using reinforcing fiber.
delete The method of claim 1,
In the first step, an injection tube insertion groove into which the injection tube is inserted is formed on the outer circumferential surface of the structure in the same direction as the axial direction of the structure, and the injection tube is inserted into the injection tube insertion groove and fixed. doing
Seismic reinforcement method of structure using reinforcing fiber.
The method of claim 1,
In the first step, the lower portion of each injection tube is connected through a connection tube,
The adhesive epoxy resin injected through one of the injection pipes is distributed to each injection pipe through the connection pipe is characterized in that the discharge through the discharge holes of the injection pipes
Seismic reinforcement method of structure using reinforcing fiber.
The method of claim 4, wherein
The plurality of discharge holes of the injection tube is formed at equal intervals and characterized in that the size of the discharge hole is reduced from the lower side to the upper side
Seismic reinforcement method of structure using reinforcing fiber.
The method of claim 4, wherein
The plurality of discharge holes of the injection tube is formed in the same size, characterized in that the distance between the discharge holes from the lower side toward the upper side is further away
Seismic reinforcement method of structure using reinforcing fiber.

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