KR101253089B1 - A structure and method of underwater construction repair - Google Patents

Abstract

The present invention relates to a structure and reinforcement method for reinforcing the underwater installation structure that can be easily installed even when the steel reinforcement can be rotated, even when the work structure is not provided in the reinforcement underwater installation structure, the underwater installation structure according to the present invention The reinforcing structure is installed at a predetermined interval from the underwater installation structure, the FRP wall plate portion surrounding the underwater installation structure; A plurality of steel reinforcement parts installed in a space between the FRP wall plate part and the underwater installation structure at a predetermined interval from the FRP wall plate part and made of steel to reinforce the FRP mold; And a rotation coupling part configured to rotatably couple one side of the steel reinforcement part to an inner surface of the FRP wall plate part.

Description

Structure and reinforcement method for reinforcement of underwater installation structure {A STRUCTURE AND METHOD OF UNDERWATER CONSTRUCTION REPAIR}

The present invention relates to a structure and a reinforcing method for reinforcing the underwater installation structure, more specifically, the steel reinforcing portion can be rotated, the underwater installation structure that can be easily installed even when the work space is not provided in the reinforcement underwater installation structure A reinforcing structure and a reinforcing method.

In the process of building a bridge, a method of making a bridge using a well filling method using a well is used to make a bridge.

In general, the type of wells used in the well filling method is to use a sheet metal formwork. In other words, the basic well formwork formwork is divided into inner sheet metal formwork and outer sheet metal formwork to be made of metal iron plate, and it is functioned as a tension member by maintaining an angle between the inner sheet metal formwork and the outer sheet metal formwork and maintaining a constant interval. Designed to withstand

In case of pier construction by the well filling method, the inner steel sheet formwork is completely buried in concrete because the bridge structure is made by filling concrete between the inner and outer steel formwork.

In the case of using a metal sheet formwork, the external steel sheet form is oxidized little by little (about 0.9 mm) in water every year, and the thickness erosion phenomenon becomes intensified, and there is a disadvantage of accelerating concrete corrosion over time. Particularly, in the water source water, these formwork forms an oxidizing effect, releasing a large amount of harmful substances containing iron, becoming a pollution source of the water source, and as the corrosion progresses, the strength of the pier structure gradually decreases, reducing the safety of the pier. have.

Therefore, when the degradation of the safety due to the immersion or scour of the structure due to oxidation or concrete corrosion is found to reinforce the underwater structure. In general, the reinforcement method for bridge foundation underwater structures has been dependent on the formwork of steel plate and the underwater concrete.

Specifically, in the case of the bridge foundation well, in the initial construction stage, it is used to form the filled concrete using the iron formwork and to make the structure through the curing process. It is being repaired by placing iron plate formwork and placing underwater concrete again.

The dry work method and the underwater work method are used to repair the foundation wells and underwater structures made using the sheet metal formwork. Both work methods install the sheet metal formwork, sheet pile, or cladding to cure concrete. After the work is finished, there is a problem in that the iron sheet formwork, sheet pile or temporary barriers have to be dismantled.

Therefore, the inventor of the present invention has developed and patented a foundation well reinforcement method using a FRP mold that is integrated with the foundation well without removing after curing the concrete in order to overcome the disadvantage of the repair method using such a sheet metal formwork.

In the case of the repairing method using the FRP mold, after assembling the FRP mold in a work space, such as a step formed by a foundation well, it is constructed by lowering it into water. However, in certain cases, as shown in FIG. 1, there is a case where the underwater installation structure 10 does not have a working space such as a step of a well. In this case, as shown in Figure 1, a separate assembly table (1) for assembling the FRP frame 20, the assembly operation proceeds after installing in the underwater installation structure.

By the way, in the case of the conventional FRP mold 20 has a structure that is installed in the space between the base well and the FRP mold 20 is fixed to the expanded state of the steel reinforcement portion serving as a tension member. Therefore, in the case of the reinforcement method using the conventional FRP mold 20, as shown in Figure 1 to prevent the interference between the steel reinforcement portion and the workbench 1 of the expanded state, the underwater installation structure 10 and the FRP mold ( 20) there is a problem that excessive gaps are made between.

The technical problem to be solved by the present invention is to provide a structure and reinforcing method for reinforcing the underwater installation structure that can be easily constructed even when the steel reinforcement can be rotated, even when the work structure is not provided in the reinforcement underwater installation structure.

The structure for reinforcing the underwater installation structure according to the present invention for achieving the above technical problem, is installed spaced apart from the underwater installation structure at a predetermined interval, FRP wall plate portion surrounding the underwater installation structure; A plurality of steel reinforcement parts installed in a space between the FRP wall plate part and the underwater installation structure at a predetermined interval from the FRP wall plate part and made of steel to reinforce the FRP mold; And a rotation coupling part configured to rotatably couple one side of the steel reinforcement part to an inner surface of the FRP wall plate part.

In the present invention, the FRP wall plate portion, FRP plate forming an outer surface of the FRP wall plate portion; It is preferable that the inner surface of the FRP plate is fixed, the square steel pipe to maintain the strength of the FRP wall plate portion.

And it is preferable that the rotation coupling portion is a hinge that rotatably connects one side of the square steel pipe and the steel reinforcement portion.

In addition, the structure for reinforcing the underwater installation structure of the present invention, is installed in the rectangular steel pipe, the temporary fixing portion for temporarily fixing the steel reinforcing part in close contact with the FRP wall plate in the folded state of the steel reinforcement; It is preferable.

In addition, the structure for reinforcing the underwater installation structure of the present invention, the steel reinforcement is preferably further provided with a connecting portion for connecting and fixing the one side of the plurality of steel reinforcement in a state unfolded perpendicular to the FRP wall plate.

In addition, the structure for reinforcing the underwater installation structure of the present invention, it is preferable that the anti-rotation unit for preventing the rotation of the rotation coupling portion in the expanded state of the steel reinforcement portion is further provided.

The structure for reinforcing the underwater installation structure of the present invention is provided with a rotation coupling part that can fold or unfold the steel reinforcement, so that the reinforcing structure can be easily assembled even when there is no work space such as a base well step in the reinforcement underwater installation structure. It has the advantage of being installed.

1 is a diagram illustrating an installation state of a reinforced water installation structure.
2 is a view showing an assembled state of the structure for reinforcing the underwater installation structure according to an embodiment of the present invention.
3 is a view showing a state in which the steel reinforcing portion of the structure for reinforcing the underwater installation structure according to an embodiment of the present invention unfolded.
Figure 4 is a view showing a folded state of the steel reinforcement of the structure for reinforcing underwater installation structure according to an embodiment of the present invention.
5 is a view showing a state in which the connection portion coupled to the steel reinforcement of the structure for reinforcing underwater installation structure according to an embodiment of the present invention.
6 is a view showing a state in which the structure for reinforcing the underwater installation structure according to an embodiment of the present invention is installed in the underwater installation structure.

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

Underwater installation structure reinforcement structure 100 according to the present embodiment, as shown in Figures 3 and 4, including the FRP wall plate 110, steel reinforcement portion 120 and the rotation coupling portion 130 .

First, the FRP wall plate 110 forms the overall shape of the reinforcing structure 100, which is a component that forms the outer surface of the reinforcing structure 100 that is generally in the shape of a cylinder, an elliptical cylinder, or a square cylinder. Specifically, as shown in FIG. 3, the FRP wall plate part 110 includes an FRP plate 112 and a square steel pipe 114 fixed to the FRP plate 112. The square steel tube 114 is preferably fixed to the FRP plate 112 is integrally coupled by FRP coating. Therefore, the FRP wall plate 110 has a very strong strength by the square steel pipe 114, has the advantage that can withstand the side pressure.

Meanwhile, in the present embodiment, the FRP wall plate part 110 is formed of a plurality of FRP wall plate parts forming a cylindrical, elliptical, or square cylinder shape in an assembled state, as shown in FIG. It is preferable because it can be done.

Specifically, the FRP wall plate part 110, as shown in Figure 3, is formed in a structure having a bent portion 116, the corner of the FRP plate 112 is bent inward, such a bent portion 116 Is in contact with the bent portion of the neighboring FRP wall plate parts, is to connect the bent portion by the fastening member 118 to connect. To this end, as shown in FIG. 3, the bent portion 116 is preferably provided with a fastening hole for fastening the fastening member 118. And when the FRP wall plate part is connected to the gap is completely filled by coating the FRP, FRP wall plate 110 is completed.

Next, the steel reinforcement part 120 is installed in the space between the FRP wall plate 110 and the underwater installation structure 10 in a state spaced apart from the FRP wall plate 110 by a predetermined interval, and made of steel It is a component for reinforcing the structure 100 for use. The steel reinforcement part 120 serves as a tension member between the FRP wall plate 110 and the underwater installation structure 10 in the state in which the reinforcing structure 100 is completed and poured to concrete.

Specifically, the steel reinforcement portion 120 is installed a plurality of spaced apart a predetermined interval, as shown in Figure 3 to have a sufficient strength and structural stability seats, has a grid structure or the like. One side of the steel reinforcement part 120 is firmly coupled to the square steel pipe 114 by a method such as welding or bolting. In addition, the other side of the steel reinforcement portion 120 is firmly coupled to the side of the underwater installation structure 10, as shown in Figure 6 in the state installed in the underwater installation structure.

Next, as shown in FIG. 3, the pivot coupling part 130 is a component that rotatably couples one side of the steel reinforcement part 120 to an inner surface of the FRP wall plate part 110. Specifically, in the present embodiment, the rotation coupling part 130 may be configured as a hinge for rotatably connecting one side of the square steel pipe 114 and the steel reinforcement part 120, and in addition to the steel reinforcement part 120. ) Can be implemented in a variety of structures that can be rotated.

As shown in FIG. 3, the steel reinforcement part 120 may be maintained in an extended state by the rotation coupling part 130, or may be maintained in a folded state as illustrated in FIG. 4. In particular, during assembly, the steel reinforcement part 120 is kept in a folded state, and assembling is completed, the reinforcing structure 100 is shown in FIG. 6 while being lowered into the water where the underwater installation structure 10 is installed. As described above, the steel reinforcement part 120 is rotated in an unfolded state so that the other end of the steel reinforcement part 120 contacts and contacts the outer surface of the underwater installation structure 10.

When the rotation coupling unit 130 is provided in this way, in the process of assembling the reinforcing structure 100 maintains the folded state of the steel reinforcement unit 120, the work table (1) temporarily installed in the underwater installation structure (10) Despite the presence of the reinforcing structure 100 itself will be able to assemble and construct the reinforcing structure 100 at the interval that should have with the underwater installation structure (10).

If there is no rotation coupling unit 130, the reinforcing structure 100 has a problem that can be assembled in an excessively spaced state from the underwater installation structure 10 as much as the space of the worktable (1).

Underwater installation structure reinforcement structure 100 according to the present embodiment is preferably further provided with a connecting portion 140. As shown in FIG. 5, the connection part 140 connects one side of the plurality of steel reinforcement parts 120 to prevent and fix a component that is prevented from being moved or moved from the installed position of each steel reinforcement part 120. to be. The connection part 140 is made of steel, and is coupled to the steel reinforcement part 120 by various methods such as welding or bolting.

Meanwhile, it is preferable that the temporary fixing part 150 is further provided in the structure 100 for reinforcing the underwater installation structure according to the present embodiment. As shown in FIG. 3, the temporary fixing part 150 is installed in the square steel pipe 114, and as shown in FIG. 4, the steel reinforcing part 120 is folded in a state where the steel reinforcing part 120 is folded. 120 is a component for temporarily fixing in a state in close contact with the FRP wall plate 110. When the steel reinforcement part 120 is temporarily fixed by the temporary fixing part 150 in a folded state, the steel reinforcement part 120 is unnecessarily rotated during the assembly process and the construction process of the reinforcing structure 100. Can be prevented to increase the efficiency of the work.

In addition, the underwater installation structure reinforcing structure 100 according to the present embodiment may be further provided with an anti-rotation unit (not shown). The anti-rotation part is a component that prevents the rotation of the pivot coupling part 130 in a state where the steel reinforcement part 120 is extended.

The steel reinforcement portion 120 is fixed to the position of the unfolded state by the above-described connection portion 140. However, during the construction of the connecting portion 140, the steel reinforcement portion 120 must be maintained in a fully extended state, that is, perpendicular to the FRP wall plate portion 110. However, since the rotation coupling part 130 is coupled to freely rotate the steel reinforcement part 120, the unfolded state of the steel reinforcement part 120 may be changed in the working process.

Therefore, in order to prevent the change in the position of the steel reinforcement portion 120, the anti-rotation portion is required to prevent the rotation of the steel reinforcement portion 120 in the fully extended state. The specific structure of the anti-rotation part may vary.

Hereinafter, the installation and construction process of the structure for reinforcing the underwater installation structure according to the present embodiment.

First, the work table 1 is installed at a suitable height of the underwater installation structure 10.

Next, each part of the FRP wall plate 110 is connected to each other. In this case, the steel reinforcement part 120 maintains a folded state and is fixed so as not to move by the temporary fixing part 150.

Next, after the FRP wall plate 110 is assembled in the form of a perfect cylinder, oval or square cylinder, the FRP wall plate 110 is lowered by a certain height. Then, the steel reinforcement part 120 installed on the lowermost layer is rotated in an unfolded state, and then the connection part 140 is constructed to fix the steel reinforcement part 120. Of course, the position of the steel reinforcement portion 120 can be fixed while constructing the connection portion 140 using the anti-rotation part.

When the construction of the connection portion 140 for the steel reinforcement portion 120 of the lowermost layer is completed, the FRP wall plate 110 is lowered again to perform the construction of the connection portion for the steel reinforcement portion 120 of the upper layer. Do the same.

After the installation of the reinforcing structure is completed in this way, the worktable 1 is removed and concrete is poured into the space between the reinforcing structure 100 and the underwater installation structure 10 to finish the work.

100: structure for reinforcing underwater installation structure according to an embodiment of the present invention
110: FRP wall plate 120: steel reinforcement
130: rotating coupling portion 140: connecting portion

Claims (6)

An FRP wall plate unit installed spaced apart from the underwater installation structure at a predetermined interval and surrounding the underwater installation structure;
A plurality of steel reinforcement parts installed in a space between the FRP wall plate part and the underwater installation structure at a predetermined interval from the FRP wall plate part and made of steel to reinforce the FRP mold;
Underwater installation structure reinforcement structure comprising a; rotatable coupling portion for rotatably coupling one side of the steel reinforcement portion to the inner surface of the FRP wall plate. According to claim 1, The FRP wall plate portion,
An FRP plate forming an outer surface of the FRP wall plate portion;
An inner surface of the FRP plate is fixed, the steel pipe to maintain the strength of the FRP wall plate portion; reinforcing structure for underwater installation structure comprising a. The method of claim 2, wherein the rotation coupling unit,
Underwater installation structure reinforcement structure, characterized in that the hinge rotatably connecting the one side portion of the steel pipe and the reinforcing steel reinforcement. The method of claim 3,
And a temporary fixing part installed in the rectangular steel pipe and temporarily fixing the steel reinforcing part in a state of being in close contact with the FRP wall plate in a folded state of the steel reinforcing part. The method of claim 3,
Underwater installation structure reinforcing structure reinforcing structure, characterized in that the steel reinforcement portion is further provided with a connection portion for connecting and fixing the one side of the plurality of steel reinforcement portion in a state extending in the vertical state with the FRP wall plate. The method of claim 5,
Underwater installation structure reinforcement structure, characterized in that the anti-rotation further provided to prevent the rotation of the rotating coupling portion in the expanded state of the steel reinforcement portion.

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