KR101219510B1 - Concrete Reinforcing Fabric Belt and Concrete Structure Reinforcing Method using thereof - Google Patents

Abstract

The present invention is a woven fiber layer 110 woven to have a predetermined width and thickness; An adhesive reinforcing groove 120 formed along a length direction of the woven fiber layer 110 on one surface of the woven fiber layer 110; And a step portion 130 formed along the longitudinal direction of the woven fiber layer 110 at left and right ends of the woven fiber layer 110, wherein the step portion 130 is a step at the left end and the right end. It relates to a concrete structure reinforcement method using a reinforcing fiber belt, characterized in that the forming surface is opposite to each other.

Description

Reinforcing fiber belt and concrete structure reinforcing method using the same

The present invention relates to a method for reinforcing a surface of a concrete structure using a reinforcing fiber belt provided with an adhesive reinforcing groove part on one side to improve adhesiveness.

As a unique reinforcing method of the concrete structure reinforcing method, there is a steel plate adhesive reinforcing method, and the reinforcing method using the fiber sheet is a reinforcing method using a carbon fiber sheet, glass fiber sheet, aramid fiber sheet.

In addition, there is a carbon fiber reinforcing plate, aramid fiber reinforcing plate, glass fiber reinforcing plate reinforcement method produced by arranging the reinforcing fibers in one direction.

The steel plate bonding reinforcement method can cause considerable difficulty in maintenance after construction due to the high risk of corrosion when the heavy weight of the steel sheet and the target structure are in contact with moisture.

Existing carbon fiber sheet, glass fiber sheet, aramid fiber sheet, etc. are very lightweight and have excellent tensile strength but are woven in a relatively wide width to reinforce the column member. By constraining, the ductility of the pillar member is improved, which prevents the collapse of the building in case of an earthquake.) The connection part of the sheet is generated every time it is attached, and because of the wide relationship, the sheet is pulled tightly during construction. It is difficult to do.

Therefore, a large number of loosely attached parts of the fiber sheet at the construction site are generated, and when the earthquake occurs, these loose parts hardly help the ductile reinforcement of the pillar member to be reinforced. In addition, the fiber sheet is supplied to the site in the factory impregnated with the resin in advance or impregnated with the resin immediately before the operation in the field, in this case, the resin used is not flame-retardant is not secured after the reinforcement construction separate flame retardant treatment. There is a problem that it is necessary. In other words, even if the fiber sheet itself is flame retardant, impregnated resin is exposed to the surface of the reinforcing surface, thereby making it difficult to secure flame retardancy. In addition, as shown in FIG. 3 (a), the overlapping chip portion protrudes to the surface, making it difficult to secure smoothness, and the peeling phenomenon of the overlapping chip portion is likely to occur.

Lapping reinforcement of column member using unidirectional carbon fiber reinforcing plate, aramid fiber reinforcing plate, glass fiber reinforcing plate is based on the stiffness peculiar to fiber reinforcing plate and the variety of column members (circular column, prisms, etc.). There is a considerable difficulty in constructing and meeting tension and adhesion at the same time. This problem occurs equally when constructing tunnels, box structures, beams or girders, angles or curved walls, even if they are not columns.

Therefore, it is possible to solve problems such as lack of continuity and loose construction of reinforcement, brittle fracture due to lack of ductility of reinforcement, securing flame retardancy of reinforcement, preventing end peeling of reinforcement. Development of reinforcement materials and reinforcement methods is urgent.

The object of the present invention created to solve the above problems is as follows.

First, it is an object of the present invention to provide a fiber belt for reinforcing concrete structures woven to have a cross section provided with an adhesive reinforcing groove portion on one surface.

Second, a concrete structure that is provided at each of the left and right ends of the fiber belt so that the stepped portion of the adjacent fiber belt is engaged with each other to prevent the joint surface from protruding to maintain smoothness and to prevent the overlapping or lifting of the overlapped portion. It is another object of the present invention to provide a reinforcing fiber belt.

Third, to provide a new reinforcement method using a flame-retardant fiber belt and does not require a separate flame-retardant treatment after reinforcement by preventing the adhesive synthetic resin is exposed to the surface of the fiber belt during reinforcement construction another object of the present invention It is done.

Fourth, it is another object of the present invention to provide a separate fixing means to the end and the curved portion of the fiber belt to prevent peeling of the end and the curved portion.

Fifth, another object of the present invention is to provide a reinforcing method that can expect a semi-permanent soft reinforcing effect by providing a means for preventing the aging of the polyester fiber seat belt or synthetic resin adhesive due to direct sunlight.

The technical configuration of the present invention for achieving the above object is as follows.

The present invention relates to a fiber belt used for reinforcement of a concrete structure, the woven fiber layer 110 woven to have a predetermined width and thickness in the longitudinal direction of the woven fiber layer 110 on one surface of the woven fiber layer 110 Adhesion reinforcement groove 120 formed along; And a step portion 130 formed along the longitudinal direction of the woven fiber layer 110 at left and right ends of the woven fiber layer 110, wherein the step portion 130 is a step at the left end and the right end. The forming surfaces are opposite to each other.

In addition, the present invention relates to a concrete structure reinforcement method using a reinforcing fiber belt, the first step of applying a synthetic resin adhesive to the surface of the concrete structure to be reinforced columnar shape; A second step of wrapping the reinforcing fiber belt around the column so that the adhesive reinforcing groove portion 120 of the reinforcing fiber belt is in contact with the synthetic resin adhesive; A reinforcing fiber in which one end of both ends of the first ∪ bolt 210 is wrapped by one lap by passing the first ∪ bolt 210 outward from the inner side of the starting end of the reinforcing fiber belt overlapping the reinforcing fiber belt in which one lap is made. A third step of protruding to the surface of the belt and fastening the first nut 215; A fourth step of continuously wrapping the reinforcing fiber belt along the column such that the stepped portions 130 formed at the left end and the right end of the neighboring reinforcing fiber belt are engaged with each other; And, before the final lapping is completed to penetrate the second ∪ bolt 220 from the inner side of the reinforcing fiber belt to the outside so that both ends of the second 돌출 bolt 220 protrudes to the surface of the reinforcing fiber belt is wrapped. And a fifth step of fastening the second nut 225 after the second lapping bolt 220 passes through the end end of the reinforcing fiber belt in which the final lapping is completed.

Technical effects of the configuration of the present invention are as follows.

First, by providing a fiber belt for reinforcing concrete structures woven to have a cross-section with an adhesive reinforcing groove on one surface can improve the bonding strength with the synthetic resin adhesive during reinforcement construction.

Second, the stepped portion is provided at each of the left and right ends of the fibrous belt, so that the stepped portions of the neighboring fibrous belts are engaged with each other so that the surface of the joint is not protruded, thereby maintaining smoothness and preventing the overlapping or lifting of the overlapped portion.

Third, the use of flame-retardant fiber belt and the surface of the fiber belt during the reinforcement construction is not exposed to the adhesive synthetic resin so that the construction is easy because no separate flame-retardant treatment is required after reinforcement.

Fourth, it is possible to prevent peeling of the end and the curved portion by providing separate fixing means to the end and the curved portion of the fiber belt.

Fifth, it is possible to expect a permanent soft reinforcing effect by applying silica sand on the surface of the fiber belt to prevent aging of the fiber belt or synthetic resin adhesive due to direct sunlight.

1 shows various cross-sectional structures of reinforcing fiber belts.
Figure 2 is a specific embodiment of the reinforcing fiber belt.
Figure 3 shows (a) the overlapped cross-sectional structure at the time of construction using a conventional fiber sheet, (b) shows the overlapped cross-section structure at the time of construction using the reinforcing fiber belt of the present invention.
4 shows the structure of the first shock bolt 210 and the first nut 215, or the second shock bolt 220 and the second nut 225, the lower pressure plate 250 and the upper pressure plate 260. It shows the case where it is used together.
5 shows a process of reinforcing a column-shaped reinforcement concrete structure.
6 shows a process of applying silica sand.
7 shows (a) a step of reinforcing the inner edge of a tunnel or box structure, and (b) a step of reinforcing a beam.
8 shows a process for reinforcing a wall.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

1 shows various cross-sectional structures of reinforcing fiber belts used to reinforce concrete structures.

The woven fiber layer 110 of the reinforcing fiber belt is woven to have a predetermined width and thickness, in the specific embodiment of the present invention used a reinforcing fiber belt woven with polyester fibers.

On one side surface of the woven fiber layer 110, an adhesive reinforcing groove 120 is formed along the longitudinal direction of the woven fiber layer 110. The adhesive reinforcement groove 120 is filled with a synthetic resin adhesive during the reinforcement work to strengthen the adhesive force. The woven fiber layer 110 is preferably flame retardant (防 炎) to ensure that the flame retardancy of the surface is reinforced. The flame retardant treatment is made of a general flame retardant treatment method of woven fibers, and thus a detailed description thereof will be omitted.

Steps 130 are formed at the left and right ends of the woven fiber layer 110 along the longitudinal direction of the woven fiber layer 110, respectively. As shown in 3 (b), the stepped portions 130 of neighboring reinforcing fiber belts are engaged with each other so that the overlapped portions do not protrude to the surface, thereby maintaining smoothness and preventing peeling of the overlapped portions. When the step portion 130 is not provided, as shown in FIG. 3 (a), the overlapped portion is lifted up, so that smoothness cannot be maintained and peeling phenomenon of the overlapped portion is likely to occur.

This reinforcing fiber belt is supplied to the construction site in the form of a roll as shown in Figure 2 is to be made reinforcement work.

Hereinafter will be described a concrete structure reinforcement method using a reinforcing fiber belt.

4 shows the structure of the first shock bolt 210 and the first nut 215, or the second shock bolt 220 and the second nut 225, the lower pressure plate 250 and the upper pressure plate 260. The case where it is used together is shown. The structures of the first bolts 210 and the second bolts 220 are the same, and the structures of the first nuts 215 and the second nuts 225 are also the same.

One. First Embodiment

FIG. 5 sequentially shows a process of reinforcing a column-shaped reinforcement concrete structure, and FIG. 6 finally shows a process of applying silica sand to a surface of a reinforcing fiber belt.

(0) Stage 0

As a background pretreatment process performed before the first step, plastering or putty work is performed on the surface of the concrete structure to be reinforced to fill the damaged concrete surface to improve smoothness. When curing of the newly filled concrete surface is completed, use a grinder or dust collector to remove foreign substances from the surface.

(1) Step 1

A step of applying a synthetic resin adhesive on the surface of the concrete structure to be reinforced columnar shape. Synthetic resin adhesive is a one-component synthetic resin, or a two-component synthetic resin after the metering and mixing, using a blender to fully mix and then apply a synthetic resin adhesive evenly using a rubber spatula, etc. on the surface of the concrete structure to be reinforced.

(2) Step 2

The adhesive reinforcing groove 120 of the reinforcing fiber belt is a process of wrapping the reinforcing fiber belt around the column so as to contact the synthetic resin adhesive.

(3) Step 3

The first ∪ bolt 210 penetrates from the inner side of the starting end of the reinforcing fiber belt overlapped with the reinforcing fiber belt to which the lap is made (see FIG. 5 (a)), and both sides of the first ∪ bolt 210 are formed. The end is projected to the outer surface of the reinforcing fiber belt made of one round wrap and the first nut 215 is fastened (see Fig. 5 (b)).

As shown in the figure, it is preferable to use the lower pressure plate 250 and the upper pressure plate 260 together, the lower pressure plate 250 is installed on the inner side of the starting end of the reinforcing fiber belt and the upper pressure plate 260 is one wheel. When the first nut 215 is fastened to the outer surface of the reinforced reinforcing fiber belt, the reinforcing fiber belt is pressed and fixed between the lower pressure plate 250 and the upper pressure plate 260 to lift the starting end of the reinforcing fiber belt. And peeling phenomenon can be prevented.

(4) Step 4

The reinforcing fiber belt is continuously wrapped along the column such that the stepped portions 130 formed at the left end and the right end of the neighboring reinforcing fiber belt are engaged with each other (see FIG. 5 (c)).

As such, when the step portions 130 are engaged with each other, the overlapped portions do not protrude as shown in FIG. 3 (b), thereby maintaining smoothness and effectively preventing lifting or peeling of the overlapped portions.

This lapping operation is performed by pulling the reinforcing fiber belt taut, so that the synthetic resin adhesive penetrates well into the adhesive reinforcing groove 120 of the reinforcing fiber belt to strengthen the adhesive force. If necessary, the surface of the reinforcing fiber belt is evenly compressed using a separate spatula with lapping.

Thus, the flame retardancy of the finished reinforcing fiber belt surface can be maintained when using the flame-retardant reinforcing fiber belt so that the synthetic resin adhesive only abuts on the inner surface of the reinforcing fiber belt without impregnating the entire reinforcing fiber belt.

(5) Step 5

Before the final lapping is completed, the second ∪ bolt 220 is penetrated from the inner side of the reinforcing fiber belt to the outside so that both ends of the second ∪ bolt 220 protrude to the surface of the reinforcing fiber belt in which the lapping is done (Fig. 5 (c)), the second nut 225 is passed through the end of the end of the reinforcing fiber belt of the final wrapping is fastened to the second nut 225 (see Fig. 5 (d)). In this case, the lower pressure plate 250 and the upper pressure plate 260 may be installed together, similarly to the first n bolt 210 and the first nut 215. In this way, the second end bolt 220 and the second nut 225 are also provided at the end of the reinforcing fiber belt to prevent lifting or peeling of the end of the reinforcing fiber belt.

(6) Step 6

After applying a thin coating of high viscosity synthetic resin on the surface of the reinforcing fiber belt, the lapping is completed.

When the silica sand is applied in this way, it is possible to prevent the aging of the fiber belt or the synthetic resin adhesive due to direct sunlight and a permanent soft reinforcing effect.

2. Second Embodiment

7 shows (a) a step of reinforcing the inner edge of a tunnel or box structure, and (b) a step of reinforcing a beam.

(0) Stage 0

As a background pretreatment process performed before the first step, plastering or putty work is performed on the surface of the concrete structure to be reinforced to fill the damaged concrete surface to improve smoothness. When curing of the newly filled concrete surface is completed, use a grinder or dust collector to remove foreign substances from the surface.

(1) Step 1

A step of applying a synthetic resin adhesive on the surface of the concrete structure to be reinforced. Synthetic resin adhesive is a one-component synthetic resin, or a two-component synthetic resin after the metering and mixing, using a blender to fully mix and then apply a synthetic resin adhesive evenly using a rubber spatula, etc. on the surface of the concrete structure to be reinforced.

(2) Step 2

The adhesive reinforcing groove 120 of the reinforcing fiber belt attaches the reinforcing fiber belt cut to a predetermined length so as to contact the synthetic resin adhesive and installs the first pressure plate 310 on one end surface of the reinforcing fiber belt and is embedded in the concrete structure. Fix using one anchor bolt 315.

The inner surface of the first pressure plate 310 in contact with the reinforcing fiber belt is formed with a saw blade-shaped uneven portion to press the reinforcing fiber belt more firmly.

(3) Step 3

By pulling the other end of the reinforcing fiber belt and in close contact with the surface of the concrete structure to be reinforced, the second anchor plate 320 is installed on the other end surface of the reinforcing fiber belt and the second anchor bolt 325 is embedded in the concrete structure. Fix it. In this process, the surface of the reinforcing fiber belt is pressed evenly so that the synthetic resin adhesive penetrates sufficiently into the adhesive reinforcing groove 120 of the reinforcing fiber belt. This compression may involve tapping the surface evenly using plastic (or wood) or rubber mallets.

The inner surface of the second pressure plate 320 in contact with the reinforcing fiber belt is formed with a saw blade-shaped uneven portion to press the reinforcing fiber belt more firmly.

In the third step, an additional pressure plate 350 is installed between the first pressure plate 310 and the second pressure plate 320 before the second pressure plate 320 is installed in the process of pulling the reinforcing fiber belt, and is further embedded in the concrete structure. The process of fixing using the anchor bolt 355 may be included. That is, by selectively using such an additional anchor bolt 355 in the corner portion of the surface bent as shown in Fig. 7 (a) or (b) to make the reinforcing fiber belt more securely attached to the surface of the concrete structure to be reinforced and reinforced fiber belt Lifting and peeling phenomenon can be prevented.

The inner surface of the additional pressure plate 350 in contact with the reinforcing fiber belt to form a saw blade-shaped uneven portion to press the reinforcing fiber belt more firmly.

(4) Step 4

By repeating the second step and the third step sequentially, the stepped portions 130 formed at the left end and the right end of the neighboring reinforcing fiber belts are engaged with each other so that the overlapping portions as shown in FIG. 3 (b) do not protrude. The smoothness is maintained and effectively prevents the lifting or peeling of the overlapped portion.

(5) Step 5

After applying a thin coating of high viscosity synthetic resin on the surface of the reinforcing fiber belt is attached to the surface of the reinforcing fiber belt evenly coated silica sand to attach.

In other words, after applying a thin coating of high-viscosity synthetic resin on the surface of the reinforcing fiber belt, the lapping is completed, it is evenly applied to the surface of the reinforcing fiber belt by applying more than 5 relatively thick silica sand.

When the silica sand is applied in this way, it is possible to prevent the aging of the fiber belt or the synthetic resin adhesive due to direct sunlight and a permanent soft reinforcing effect.

3. Third Embodiment

8 shows a process for reinforcing a wall.

(0) Stage 0

As a background pretreatment process performed before the first step, plastering or putty work is performed on the surface of the concrete structure to be reinforced to fill the damaged concrete surface to improve smoothness. When curing of the newly filled concrete surface is completed, use a grinder or dust collector to remove foreign substances from the surface.

(1) Step 1

A step of applying a synthetic resin adhesive on the surface of the concrete structure to be reinforced. Synthetic resin adhesive is a one-component synthetic resin, or a two-component synthetic resin after the metering and mixing, using a blender to fully mix and then apply a synthetic resin adhesive evenly using a rubber spatula, etc. on the surface of the concrete structure to be reinforced.

(2) Step 2

The step portion 130 formed on the left end and the right end of the adjacent reinforcing fiber belt by attaching a plurality of reinforcing fiber belts cut to a predetermined length in order so that the adhesive reinforcing groove 120 of the reinforcing fiber belt contacts the synthetic resin adhesive. By interlocking with each other so that the overlapping portions are not protruded as shown in FIG. 3 (b) and smoothness is maintained, and the lifting or peeling phenomenon of the overlapping portions is effectively prevented.

(3) Step 3

The third pressure plate 330 covering the entire end surface of one end of the reinforcing fiber belt is attached to cross the one end surface of the reinforcing fiber belt, and fixed by using the third anchor bolt 335 that is embedded in the concrete structure ( 8).

The third pressure plate 330 is made long to cross the entire reinforcement area, the inner surface contacting the reinforcing fiber belt to form a saw blade-shaped uneven portion to press the reinforcing fiber belt more firmly.

(4) Step 4

A fourth anchor bolt installed across the other end surface of the reinforcing fiber belt and being embedded in the concrete structure by installing a fourth pressure plate 340 covering the entire surface of the other end of the reinforcing fiber belt while pulling the other end of the reinforcing fiber belt. 345) (see FIG. 8). In this case, evenly press the surface of the reinforcing fiber belt evenly so that the synthetic resin adhesive penetrates sufficiently into the inside of the adhesive reinforcing groove 120 of the reinforcing fiber belt. This compression may involve tapping the surface evenly using plastic (or wood) or rubber mallets.

(5) Step 5

After applying a thin coating of high viscosity synthetic resin on the surface of the reinforcing fiber belt is attached to the surface of the reinforcing fiber belt evenly coated with silica sand.

When the silica sand is applied in this way, it is possible to prevent the aging of the fiber belt or the synthetic resin adhesive due to direct sunlight and a permanent soft reinforcing effect.

Although the present invention has been described with reference to specific embodiments of the present invention as described above, the scope of protection of the present invention is not necessarily limited to these embodiments, and various design changes and notifications are made within the scope of not changing the technical gist of the present invention. In the case of addition or deletion of technology, and simple numerical limitations, it is obvious that the scope of the present invention is included.

110: woven fiber layer
120: adhesive reinforcing groove
130: stairs
210: first bolt
215: First nut
220: second bolt
225: second nut
250: lower pressure plate
260: upper pressure plate
310: first pressure plate
315: first anchor bolt
320: second pressure plate
325: second anchor bolt
330: third pressure plate
335: Third anchor bolt
340: fourth pressure plate
345: fourth anchor bolt
350: additional pressure plate
355: additional anchor bolt

Claims (11)

Woven fiber layer 110 woven from polyester fibers to have a predetermined width and thickness;
An adhesive reinforcing groove 120 formed along a length direction of the woven fiber layer 110 on one surface of the woven fiber layer 110; And
Stepped portions 130 formed along the longitudinal direction of the woven fiber layer 110 at left and right ends of the woven fiber layer 110;
Is further included, the woven fiber layer 110 is flame retardant (防 炎), the step portion 130 is a reinforcing fiber belt, characterized in that the step forming surface of the left end and the right end is opposite to each other. Regarding the method for reinforcing concrete structures using the reinforcing fiber belt according to claim 1,
A first step of applying a synthetic resin adhesive on the surface of the column-shaped reinforcement target concrete structure;
A second step of wrapping the reinforcing fiber belt around the column so that the adhesive reinforcing groove portion 120 of the reinforcing fiber belt is in contact with the synthetic resin adhesive;
A reinforcing fiber in which one end of both ends of the first ∪ bolt 210 is wrapped by one lap by passing the first ∪ bolt 210 outward from the inner side of the starting end of the reinforcing fiber belt overlapping the reinforcing fiber belt in which one lap is made. A third step of protruding to the surface of the belt and fastening the first nut 215;
A fourth step of continuously wrapping the reinforcing fiber belt along the column such that the stepped portions 130 formed at the left end and the right end of the neighboring reinforcing fiber belt are engaged with each other; And
Before the final lapping is completed, the second ∪ bolt 220 penetrates from the inner side of the reinforcing fiber belt to the outside so that both ends of the second ∪ bolt 220 protrude to the surface of the reinforcing fiber belt in which the lapping is made, and the final lapping is performed. A fifth step of fastening the second nut 225 after the second ∪ bolt 220 penetrates the end of the finished reinforcing fiber belt;
Concrete structure reinforcement method using a reinforcing fiber belt, characterized in that comprising a. In claim 2,
A sixth step of applying a thin coating of high viscosity synthetic resin to the surface of the reinforcing fiber belt after the lapping is completed and evenly applying silica sand to the surface of the reinforcing fiber belt;
Concrete structure reinforcement method using a reinforcing fiber belt, characterized in that it further comprises. Regarding the method for reinforcing concrete structures using the reinforcing fiber belt according to claim 1,
A first step of applying a synthetic resin adhesive to the surface of the concrete structure to be reinforced;
The adhesive reinforcing groove 120 of the reinforcing fiber belt attaches the reinforcing fiber belt cut to a predetermined length so as to contact the synthetic resin adhesive and installs the first pressure plate 310 on one end surface of the reinforcing fiber belt and is embedded in the concrete structure. A second step of fixing using one anchor bolt 315;
By pulling the other end of the reinforcing fiber belt and in close contact with the surface of the concrete structure to be reinforced, the second anchor plate 320 is installed on the other end surface of the reinforcing fiber belt and the second anchor bolt 325 is embedded in the concrete structure. A third step of fixing; And
A fourth step of sequentially repeating the second step and the third step so that the stepped portions 130 formed at the left end and the right end of the neighboring reinforcing fiber belt are engaged with each other;
Concrete structure reinforcement method using a reinforcing fiber belt, characterized in that comprising a. 5. The method of claim 4,
A fifth step of applying a thin film of high viscosity synthetic resin on the surface of the reinforcing fiber belts to which the attachment is completed, and then evenly applying silica sand to the surface of the reinforcing fiber belts;
Concrete structure reinforcement method using a reinforcing fiber belt, characterized in that it further comprises. 5. The method of claim 4,
In the third step, the additional pressure plate 350 is installed between the first pressure plate 310 and the second pressure plate 320 in the process of pulling the reinforcing fiber belt and fixed by using an additional anchor bolt 355 that is lodged in the concrete structure. Concrete structure reinforcement method using a reinforcing fiber belt, characterized in that the process is included. Regarding the method for reinforcing concrete structures using the reinforcing fiber belt according to claim 1,
A first step of applying a synthetic resin adhesive to the surface of the concrete structure to be reinforced;
The step portion 130 formed on the left end and the right end of the adjacent reinforcing fiber belt by attaching a plurality of reinforcing fiber belts cut to a predetermined length in order so that the adhesive reinforcing groove 120 of the reinforcing fiber belt contacts the synthetic resin adhesive. A second step of engaging with each other;
The third pressure plate 330 covering the entire end surface of one end of the reinforcing fiber belt is attached to cross the one end surface of the reinforcing fiber belt and fixed by using a third anchor bolt 335 that is embedded in the concrete structure. Step 3; And
A fourth anchor bolt installed across the other end surface of the reinforcing fiber belt and being embedded in the concrete structure by installing a fourth pressure plate 340 covering the entire surface of the other end of the reinforcing fiber belt while pulling the other end of the reinforcing fiber belt. A fourth step of fixing using 345;
Concrete structure reinforcement method using a reinforcing fiber belt, characterized in that comprising a. In claim 7,
A fifth step of applying a thin film of high viscosity synthetic resin on the surface of the reinforcing fiber belts to which the attachment is completed, and then evenly applying silica sand to the surface of the reinforcing fiber belts;
Concrete structure reinforcement method using a reinforcing fiber belt, characterized in that it further comprises. In any one of claims 2 to 8,
Step 0 to improve the smoothness by performing a plastering or putty work on the surface of the concrete structure to be reinforced before performing the first step and to remove foreign substances on the surface by using a grinder or dust collector;
Concrete structure reinforcement method using a reinforcing fiber belt, characterized in that it further comprises.
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