KR20200126671A - Concrete Column Structures Reinforcing Method Using Reinforced Steel Plate - Google Patents

Abstract

The present invention relates to a seismic, fireproof, repairing and reinforcing method for a concrete column structure using a spacing reinforcement member and an external reinforcement steel plate, which can very facilitate construction. According to a preferred embodiment of the present invention, the seismic, fireproof, repairing and reinforcing method for a concrete column structure comprises the following steps: (a) forming a fixing groove; (b) forming an anchor hole having a predetermined depth; (c) inserting a socket anchor into the anchor hole; (d) filling mortar in the fixing groove and installing the spacing reinforcement member in the fixing groove so that the other end portion of the socket anchor is inserted into a through hole of the spacing reinforcement member; (e) applying mortar; (f) successively installing a pair of external reinforcement steel plates at regular intervals in a longitudinal direction of the concrete column structure; and (g) fastening a bolt to the socket anchor at the outside of an overlapping section of the pair of external reinforcement steel plates.

Description

Concrete Column Structures Reinforcing Method Using Reinforced Steel Plate for seismic, fireproof, repair and reinforcement of concrete column structures using spaced reinforcing members and external reinforcing steel plates

The present invention relates to a seismic, fireproof, repair, and reinforcement method of a concrete column structure using a spaced reinforcing member and an external reinforcing steel plate, and more particularly, a socket anchor and a spaced reinforcing member are installed on each side of the concrete column structure. By securing a space for placing mortar on the outside of the column structure, placing the mortar, reinforcing the outer surface of the concrete column structure with an external reinforcing steel plate, and bolting it to the socket anchor to easily secure a space for placing mortar. Reinforcing channels and external reinforcing steel plates are constrained by socket anchors to provide excellent strength and rigidity, but also for seismic, fireproof, repair, and reinforcement methods of concrete column structures using spaced reinforcing members and external reinforcing steel plates that make construction very easy. About.

There was a problem in that the load-bearing capacity and durability were deteriorated due to deterioration due to the increase in the service life of the structure, neutralization of concrete due to the effects of disasters, delamination due to material separation, and generation of cracks due to structural causes.

In recent years, demands for seismic reinforcement of structures are increasing not only for structural repair and reinforcement due to increased strength of existing structures and deterioration of durability due to environmental problems, but also due to aging of structures or reinforcement of seismic regulations.

As a background technology of the present invention, there is Patent Registration No. 1618252 "Fiber Reinforced Plastic (FRP) Reinforcement Device and Reinforcement Method of Structure Using the Same" (Patent Document 1). In the background art, a FRP core 10 in which a plurality of fiber bundles 1 in the form of a roving are arranged and a resin is impregnated as a whole from one end to the other to have a bar shape; An anchor mount (20) in the form of a circular rod or polygonal rod formed by arranging a plurality of fiber bundles (1) in the form of roving and impregnating with resin, formed perpendicular to the FRP core (10); And an anchor 30 inserted and fixed together with the anchor mount 20 in a hole H formed in a structure to be reinforced by being a tubular body coupled to surround the outer surface of the anchor mount 20; The anchor 30 is a fiber reinforcement, characterized in that it is made of any one of a tubular body made of metal, a tubular body made by impregnating resin in a fiber bundle, and a tubular body made by rolling a composite material sheet containing fibers into a tubular shape. Using a plastic (FRP) reinforcing device, (a) spraying resin together with fibers on the surface of the structure to be reinforced to construct a first fiber reinforcement coating layer 50; (b) a structure reinforcement method comprising the step of covering the first fiber reinforcement coating layer 50 by inserting the anchor 30 of the fiber reinforced plastic (FRP) reinforcing device into the hole H of the structure Suggests.

However, the above background technology is to install a fiber-reinforced plastic (FRP) reinforcement device by spraying resin together with fibers on the surface of the structure. However, by applying it to the surface of the structure, it is susceptible to damage due to slip and impact from the external environment. there was.

Patent Registration No. 1618252 "Fiber-reinforced plastic (FRP) reinforcement device and reinforcement method of structure using the same"

The present invention is to solve the above problems, by installing a socket anchor and a spaced reinforcing member on each side of a concrete column structure to secure a space for placing mortar on the outside of the concrete column structure to place the mortar, and use an external reinforcing steel plate. By reinforcing the outer surface of the concrete column structure and then bolting it to the socket anchor, space for mortar placement can be easily secured, and both the reinforcing channel and the external reinforcing steel plate are constrained by the socket anchor for excellent strength and rigidity. The purpose is to provide seismic, fireproof, repair, and reinforcement methods of concrete pillar structures using spaced reinforcing members and external reinforcing steel plates that make the construction very easy.

The present invention comprises the steps of: (a) forming a fixing groove by cutting to a predetermined depth so that a pair of each side in the width direction of the concrete column structure is separated by a predetermined distance and configured in a lengthwise direction; (b) forming an anchor hole having a predetermined depth at a predetermined interval in the length direction in the central portion of the width direction of the fixing groove; (c) inserting a socket anchor, which is filled with a filler material from one end to the center in the shape of an empty tube and has a thread formed on the inner circumferential surface from the other end to the center, into the anchor hole so that the other end protrudes for a predetermined length; (d) A horizontal plane through which through holes are drilled at regular intervals in the longitudinal direction, an insertion surface extending in a direction perpendicular to the rear surface of the horizontal plane on both sides in the width direction of the horizontal plane, and a direction opposite to the insertion surface so as to be parallel to the insertion surface at the outer end of the insertion surface. A spaced reinforcing member consisting of a spaced surface extending over a horizontal plane for a certain distance and a support surface extending in a right angle direction from the outer end of the spaced surface is filled with a mortar in the fixing groove, and the socket anchor is placed in the through hole of the spaced reinforcing member. Installing in the fixing groove so that the end is inserted; (e) applying mortar to the support surface on the outer surface of the concrete column structure; (f) A pair of external reinforcing steel plates having a C-shaped cross section consisting of a reinforcement part in the shape of a certain length plate and a coupling part extending in a right angle direction from both ends of the reinforcement part and through a coupling hole at regular intervals in the longitudinal direction at the outer end. A pair of external reinforcing steel plates are placed at regular intervals in the length direction of the concrete column structure so that the other end of the socket anchor penetrates the coupling hole so that the end of the socket anchor is exposed to the outside so that the coupling holes are matched on both sides of the structure. Installing in succession; (g) fastening bolts to socket anchors outside the overlapping section of a pair of external reinforcing steel plates; seismic resistance, fire resistance, and repair of concrete column structures using spaced reinforcing members and external reinforcing steel plates, comprising: , We want to provide a reinforcement method.

In addition, in step (c), a plurality of slits are formed on the other end of the socket anchor, and in step (g), a spaced reinforcing member and an external reinforcing steel plate are formed so that the slit part is opened when the bolt is fastened. It is intended to provide seismic, fireproof, repair and reinforcement methods of used concrete pillar structures.

In addition, in step (c), the socket anchor is to provide a seismic, fireproof, repair, and reinforcement method of a concrete column structure using a spaced reinforcing member and an external reinforcing steel plate, characterized in that a rubber ring is formed on the inner circumferential surface where the thread is formed. do.

In addition, in step (c), the socket anchor is a seismic, fireproof, repair and reinforcement method of a concrete column structure using a spaced reinforcing member and an external reinforcing steel plate, characterized in that the other end of the socket anchor is bent outward to form a flange part. Want to provide.

In addition, in step (d), the seismic and fire resistance of a concrete column structure using a spaced reinforcing member and an external reinforcing steel plate, characterized in that at least one reinforcing bar is formed in the longitudinal direction between the horizontal surface and the support surface of the spaced reinforcing member. , To provide repair and reinforcement methods.

In addition, in step (d), the outer end where the insertion surface of the spaced reinforcing member and the spaced surface meet is cut to have an unevenness to form an uneven reinforcing member and a concrete column structure using an external reinforcing steel plate. , Fireproof, repair, and reinforcement methods are provided.

In addition, in step (d), seismic, fireproof, and repair of a concrete column structure using a spaced reinforcing member and an external reinforcing steel plate, characterized in that a plurality of through-holes are formed to simultaneously penetrate the insertion surface and the spaced surface of the spaced reinforcing member. , We want to provide a reinforcement method.

In addition, in step (f), the separation reinforcing member and the concrete column structure using the external reinforcing steel plate, characterized in that the overlapping section of a pair of vertically adjacent external reinforcing steel plates is configured to be positioned in a staggered direction, We want to provide repair and reinforcement methods.

In addition, in step (f), the outer reinforcing steel plate on the other side of the external reinforcing steel plate has a coupling jaw formed in the overlapping section so that its cross-section is extended to the outside, so that the inside of the coupling jaw is on the top of the coupling portion of the external reinforcing steel plate on one side. It is intended to provide a seismic, fireproof, repair, and reinforcement method of a concrete column structure using a spaced reinforcing member and an external reinforcing steel plate, characterized in that the surfaces are in close contact with each other.

The seismic, fireproof, repair, and reinforcement method of a concrete column structure using the separation reinforcing member and the external reinforcing steel plate of the present invention is to place mortar on the outside of the concrete column structure by installing socket anchors and separation reinforcing members on each side of the concrete column structure. By placing mortar by securing space, reinforcing the outer surface of the concrete column structure with an external reinforcing steel plate, and then bolting it to the socket anchor to easily secure a space for mortar placement. There is a very useful effect of making the reinforcement steel sheet constrained so that it has excellent strength and stiffness while making construction very easy.

The following drawings attached to the present specification illustrate preferred embodiments of the present invention, and serve to further understand the technical idea of the present invention together with the detailed description of the present invention, so the present invention is limited to the matters described in the accompanying drawings. It is limited and should not be interpreted.
1 to 8 are cross-sectional views sequentially showing the seismic, fireproof, repair, and reinforcement method of a concrete column structure using a spaced reinforcing member and an external reinforcing steel plate of the present invention.
9 is a partially exploded perspective view of FIG. 8 and a perspective view of a combined state.
10 is a perspective view of another embodiment of FIG. 9B.
11A is a perspective view and a cross-sectional view of the socket anchor of the present invention.
Figure 11b is a cross-sectional view of another embodiment of the socket anchor of the present invention.
12 is a perspective view of a reinforcing channel and various modifications of the present invention.
13 is a diagram showing an embodiment of a bolt used in the present invention.

In the following, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the disclosed embodiments are illustrative for a clear understanding of the present invention, and the present invention is not limited thereto.

Hereinafter, the technical configuration of the present invention will be described in detail according to a preferred embodiment.

1 to 8 are cross-sectional views sequentially showing seismic, fire resistance, repair, and reinforcement methods of a concrete column structure using a spaced reinforcing member and an external reinforcing steel plate of the present invention, and FIG. 9 is a partial exploded perspective view of FIG. It is a perspective view of the combined state.

The seismic, fireproof, repair, and reinforcement methods of a concrete column structure using the spaced reinforcing member and the external reinforcing steel plate of the present invention will be described in detail in order of construction with reference to the drawings.

The seismic, fireproof, repair, and reinforcement method of the concrete column structure using the spaced reinforcing member and the external reinforcing steel plate of the present invention is, first, as shown in FIG. 1, a pair of constant in the center of each side in the width direction of the concrete column structure 10 The fixed groove 11 is formed by cutting to a certain depth so as to be separated by a distance and configured in a lengthwise direction (a).

Each side of the concrete column structure 10 is spaced a certain distance from the central part in the width direction to form a pair of fixing grooves 11. In this case, only the fixing groove 11 may be formed in the concrete pillar structure 10, and the outer surface of the concrete pillar structure 10 may be cut to a predetermined thickness.

A pair of fixing grooves 11 are formed in the entire length direction at the central portion in the width direction of each side of the concrete column structure 10, and such fixing grooves 11 are spaced reinforcing members 30 in step (d) to be described later. It is configured to attach.

The shape of the fixing groove 11 is formed by cutting to a certain depth so that the spaced surface 33 and the support surface 34 formed overlapping the spaced reinforcing member 30 can be inserted at the same time, and the cutting depth and width are varied. The insertion surface 32 is inserted into the fixing groove 11 and the concrete column structure 10 and the external reinforcing steel plate 40 to be described later as much as the spaced surface 33 protruding from the fixing groove 11 40') to form a space in which mortar is placed.

In particular, since the horizontal surface 31 of the spaced reinforcing member 30 is located between the fixing grooves 11, a certain section of the central part in the width direction of each side of the concrete column structure 10 is fixed so that the horizontal surface 31 is seated. It is also possible to cut to the depth and form fixing grooves 11 on both sides of the cut portion so that the horizontal surface 31 of the reinforcing channel 30 does not protrude further from the outer surface of the concrete column structure 10 to the outside.

Thereafter, as shown in FIG. 2, an anchor hole 12 having a predetermined depth is formed at a predetermined interval in the length direction in the central portion in the width direction of the fixing groove 11 (b).

The anchor hole 12 allows the socket anchor 20 to be inserted, and is formed to a predetermined depth according to the length of the socket anchor 20 so that the socket anchor 20 can be inserted.

Thereafter, as shown in FIG. 3, the socket anchor 20 is inserted into the anchor hole 12 to temporarily couple the socket anchor 20 (c).

The socket anchor 20 may be re-installed by removing the socket anchor 20 as necessary when installing the spaced reinforcing member 30 in a step to be described later by fixing only the position without a separate coupling means.

Figure 11a is a perspective view and a cross-sectional view of the socket anchor of the present invention, Figure 11b is a cross-sectional view of another embodiment of the socket anchor of the present invention.

As shown in Fig. 11a (b), the socket anchor 20 is a tube shape with an empty inside so that a variety of known fillers 121 such as epoxy are filled from one end to the center, and threads are on the inner circumferential surface from the other end to the center. So that it is formed, the bolts are easily combined.

Such a socket anchor 20 is to be inserted into the anchor hole 12 so that the other end of the socket anchor 20 protrudes from the anchor hole 12 for a predetermined length, and in the step to be described later, the socket anchor 20 is used to reinforce the separation. Allows the member 30 to be coupled.

In particular, as shown in Fig. 11a(a), the socket anchor 20 has a plurality of slits 26 formed at the other end, so that the slit 26 portion is formed when the bolt 50 is fastened in step (g). It is possible to increase the coupling force by allowing them to be coupled so that they are wider, and as shown in FIG. 11B, the socket anchor 20 has a rubber ring 27, preferably an inelastic rubber ring, formed on the inner circumferential surface where the thread is formed, so that the bolt 50 is fastened. You can increase the cohesion of the city.

In addition, as shown in Fig. 11a (c), the socket anchor 20 has a flange portion 28 that extends by bending the other end outward, so that the flange portion 28 when the socket anchor 20 is installed The inner side of the outer reinforcing steel plates 40 and 40 ′ may serve to hold the external reinforcing steel plates 40 and 40 ′ to prevent separation of the external reinforcing steel plates 40 and 40 ′.

Thereafter, as shown in FIGS. 4 and 5, the spaced reinforcing member 30 is installed in the fixing groove 11 (d).

12 is a perspective view of a reinforcing channel and various modifications of the present invention.

As shown in Figure 12a, the spaced reinforcing member 30 is a horizontal surface 31 through which the through hole 311 is passed at regular intervals in the longitudinal direction, and a right angle direction of the rear surface of the horizontal surface 31 on both sides of the horizontal surface 31 in the width direction. The insertion surface 32 extending in the direction of the insertion surface 32 and a separation surface extending to pass a predetermined distance through the horizontal surface 31 in the opposite direction of the insertion surface 32 so as to be parallel to the insertion surface 32 at the outer end of the insertion surface 32 ( 33) and a support surface 34 extending in a right angle direction from the outer end of the separation surface 33.

The through hole 311 is configured to match the spacing of the anchor hole 12, and extends in a right angle direction on both sides of the horizontal surface 31 in the width direction so that the insertion surface 32 is formed to have a U-shaped cross section. At this time, at the outer end of the insertion surface 32, a separation surface 33 is formed so as to extend in a direction opposite to the insertion surface 32 so as to overlap the insertion surface 32, and the mating surface 32 inserted into the fixing groove 11 ) Is inserted at the same time and serves to reinforce, and at the same time, the separation surface 33 is formed to extend to pass a certain distance through the horizontal surface 31 so that the concrete column structure 10 and the external reinforcing steel plate 40, 40' Separate the distance to form a space where mortar is placed.

At this time, by extending in a right angle direction from the outer end of the separation surface 33 to form the support surface 34, the support surface 34 can support the inner surface of the external reinforcing steel plates 40, 40'. have.

In order to install such a spaced reinforcing member 30, a mortar 13 is injected between the fixing groove 11 and the anchor hole 12 and the outer surface of the socket anchor 20, and the spaced reinforcing member 30 is installed. .

At this time, the other end of the socket anchor 20 is inserted into the through hole 311 of the spaced reinforcing member 30 so that the outer end of the socket anchor 20 is exposed to the outside. In this case, the socket anchor 20 may be configured to further protrude outward at a portion where the position of the overlapping section (d) of the external reinforcing steel plates 40 and 40 ′ is formed.

In this way, the other end of the socket anchor 20 is inserted into the through hole 311 of the spaced reinforcing member 30 so that the spaced reinforcing member 30 is coupled to the concrete column structure 10 by the socket anchor 20. Thus, it is possible to stably install the spaced reinforcing member 30 in the fixing groove 11.

In particular, the spaced reinforcing member 30 is configured with one or more reinforcing bars 60 in the longitudinal direction between the horizontal surface 31 and the support surface 34 of the spaced reinforcing member 30, as shown in FIGS. 5 and 6 Thus, it may be positioned inside the mortar 13 between the spaced reinforcing member 30 and the outer surface of the concrete column structure 10 to serve as a reinforcing bar.

In addition, as in FIG. 12B, the outer end where the insertion surface 32 and the separation surface 33 of the separation reinforcing member 30 meet is cut to have irregularities to form the irregularities 321 or as in FIG. 12C. , Shear force of the mortar 13 when inserted into the U-shaped groove 11 by forming a plurality of through holes 322 to simultaneously penetrate the insertion surface 32 and the separation surface 33 of the separation reinforcing member 30 Can be made to resist.

Thereafter, as shown in FIG. 6, the mortar 13 is applied to the entire outer surface of the concrete column structure 10 (e).

Such work is carried out to reinforce the outer surface of the external reinforcing steel plate 40 (40') and the concrete pillar structure 10, and to attach the external reinforcing steel plate 40, 40' to the concrete pillar structure 10. And, it is applied to a thickness up to the support surface 34 of the spaced reinforcing member 30.

Thereafter, as shown in FIGS. 7 and 9, a plurality of external reinforcing steel plates 40 and 40 ′ are installed so as to be continuous in the longitudinal direction of the concrete column structure 10 (f).

As shown, the external reinforcing steel plates 40 and 40 ′ extend in a right angle direction from both ends of the reinforcing part 41 and the reinforcing part 41 in the shape of a certain length plate, and the coupling holes at the outer ends at regular intervals in the longitudinal direction. Consisting of a coupling portion 42 formed through a through hole 421 to have a C-shaped cross section, a pair of external reinforcing steel plates 40 and 40 ′ are inserted and coupled at both sides of the concrete column structure 10, respectively, At this time, the pair of external reinforcing steel plates 40 and 40 ′ overlap the coupling portion 42 in the concrete column structure 10 to form an overlapping section d.

At this time, the overlapping section (d) is such that the coupling holes 421 and 421 of the coupling portion 42 of the external reinforcing steel plates 40 and 40 ′ on both sides are matched, and the other end of the socket anchor 20 Through the coupling holes 421 and 421 so that the end of the socket anchor 20 is exposed to the outside, the reinforcing member 30 spaced apart from the socket anchor 20 and a pair of external reinforcing steel plates 40 and 40 ′ ) Is simultaneously bound and combined.

Such a pair of vertically adjacent external reinforcing steel plates 40 and 40' may be installed so that the overlapping section d is aligned in the vertical direction, as in FIG. 9, and vertically adjacent, as in FIG. The overlapping section (d) of the pair of external reinforcing steel plates 40 and 40 ′ is configured to be positioned in a staggered direction, so that the strength of the coupling portion may be increased.

Finally, as in FIGS. 8 and 9, the bolt 50 is fastened to the socket anchor 20 from the outside of the pair of external reinforcing steel plates 40 and 40' overlapping section d (g ).

In this way, by fastening the bolt 50 to the socket anchor 20 exposed to the outside of the pair of external reinforcing steel plates 40, 40', the overlapping section d, the socket anchor 20 is a spaced reinforcing member The socket anchor 20 is expanded and coupled by the bolt 50 while simultaneously penetrating the through hole 311 of 30 and the coupling hole 421 of the pair of external reinforcing steel plates 40 and 40'. Make it possible.

In addition, the outer reinforcing steel plate 40' on the other side of the external reinforcing steel plates 40 and 40' has a coupling jaw 48 formed in the overlapping section (d) so that its cross-section extends to the outside. A phenomenon in which the inner surface of the coupling jaw 48 is in close contact with the upper portion of the coupling portion 42 of the reinforcing steel plate 40 so that the inner surface of the concrete column structure 10 is excited due to the overlapping of the coupling portion 42 You can also try to prevent it.

13 is a diagram showing an embodiment of a bolt used in the present invention.

The bolt 50 used herein may be a variety of known bolts, and in the present invention, as shown in FIG. 13, in particular, a headless bolt made of only a body without a head is used, so that the external reinforcing steel plates 40 and 40 ′ ), the bolt 50 may not protrude outward.

The seismic, fireproof, repair and reinforcement method of a concrete column structure using the spaced reinforcing member and the external reinforcing steel plate of the present invention as described above is to install socket anchors and spaced reinforcing members on each side of the concrete column structure to the outside of the concrete column structure. By securing a space for placing mortar in, placing mortar, reinforcing the outer surface of the concrete column structure with an external reinforcing steel plate, and then bolting it to the socket anchor to easily secure a space for mortar placement, and reinforced with a socket anchor. There is a very useful effect of constraining both the channel and the external reinforcing steel plate so that it has excellent strength and rigidity while making it very easy to construct.

Until now, the present invention has been described in detail with reference to the presented embodiments, but those of ordinary skill in the art can make various modifications and modifications without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The present invention is not limited by such modifications and variations of the invention, but is limited by the claims appended below.

10: concrete column structure
11: Fixed groove
12: anchor hole
121: filler
13: mortar
20: socket anchor
30: separation reinforcing member
31: horizontal plane
311: through hole
32: insertion side
33: separation surface
34: support surface
40, 40': external reinforcement plate
41: reinforcement part
42: coupling hole
421: coupling hole
50: bolt
60: rebar
d: overlapping section

Claims (9)

(a) forming a fixing groove 11 by cutting to a predetermined depth so that a pair of each side in the width direction of the concrete column structure 10 is separated by a predetermined distance and configured in a lengthwise direction;
(b) forming an anchor hole 12 having a predetermined depth at a predetermined interval in the length direction at the center portion in the width direction of the fixing groove 11;
(c) Anchor hole 12 so that the inner circumference of the socket anchor 20 is filled with a filler 121 from one end to the center in a hollow tube shape, and a thread is formed on the inner circumferential surface from the other end to the center. Inserting in );
(d) a horizontal surface 31 through which the through-hole 311 passes at regular intervals in the longitudinal direction, and an insertion surface 32 extending in a direction perpendicular to the rear surface of the horizontal surface 31 from both sides in the width direction of the horizontal surface 31, At the outer end of the insertion surface 32, the separation surface 33 extending so as to pass a predetermined distance through the horizontal surface 31 in the opposite direction of the insertion surface 32 so as to be parallel to the insertion surface 32, and the separation surface 33 A spaced reinforcing member 30 consisting of a support surface 34 extending in a right angle direction from the outer end is filled with a mortar 13 in the fixing groove 11, and a socket anchor in the through hole 311 of the spaced reinforcing member 30 Installing in the fixing groove 11 so that the other end of (20) is inserted;
(e) applying the mortar 13 to the support surface 34 on the outer surface of the concrete column structure 10;
(f) a fixed length plate-shaped reinforcing portion 41 and a coupling portion 42 extending in a right angle direction from both ends of the reinforcing portion 41 and having coupling holes 421 through the outer ends at regular intervals in the longitudinal direction. A pair of external reinforcing steel plates 40 and 40 ′ having a C-shaped cross section,
The coupling portion 42 is overlapped so that the coupling holes 421 and 421 at both sides of the concrete column structure 10 are matched to form an overlapping section (d), and the other end of the socket anchor 20 is a coupling hole 421 Installing a pair of external reinforcing steel plates 40 and 40' in succession at regular intervals in the length direction of the concrete column structure 10 so that the ends of the socket anchors 20 are exposed to the outside through 421;
(g) fastening the bolt 50 to the socket anchor 20 from the outside of the pair of external reinforcing steel plates 40, 40', the overlapping section (d); Seismic, fireproof, repair, and reinforcement methods of concrete column structures using members and external reinforcing steel plates. The method according to claim 1,
In step (c),
The socket anchor 20 has a plurality of slits 26 formed at the other end thereof,
In step (g),
The seismic, fireproof, repair, and reinforcement method of a concrete column structure using a spaced reinforcement member and an external reinforcing steel plate, characterized in that the bolt 50 is joined so that the slit 26 part is opened when fastening. The method according to claim 1,
In step (c),
The socket anchor 20 is a seismic, fireproof, repair, reinforcement method of a concrete column structure using a spaced reinforcing member and an external reinforcing steel plate, characterized in that a rubber ring 27 is formed on the inner circumferential surface of which the thread is formed. The method according to claim 1,
In step (c),
The socket anchor 20 is a seismic, fireproof, repair, and reinforcement method of a concrete column structure using a spaced reinforcing member and an external reinforcing steel plate, characterized in that the other end is bent outward and extended flange 28 is formed. The method according to claim 1,
In step (d),
A concrete pillar structure using a spaced reinforcing member and an external reinforcing steel plate, characterized in that at least one reinforcing bar 60 is formed in the longitudinal direction between the horizontal surface 31 and the support surface 34 of the spaced reinforcing member 30 Seismic, fireproof, repair, reinforcement method The method according to claim 1,
In step (d),
Using a spaced reinforcing member and an external reinforcing steel plate characterized in that the outer end where the insertion surface 32 and the spaced surface 33 of the spaced reinforcing member 30 meet is cut to have unevenness to form an uneven part 321 Seismic, fireproof, repair and reinforcement of concrete column structures. The method according to claim 1,
In step (d),
A plurality of through-holes 322 are formed in the insertion surface 32 and the separation surface 33 of the separation reinforcing member 30 so as to simultaneously penetrate the concrete column structure using a separation reinforcing member and an external reinforcing steel plate. Seismic, fireproof, repair, reinforcement method. The method according to claim 1,
In step (f),
Seismic resistance of a concrete column structure using a spaced reinforcing member and an external reinforcing steel plate, characterized in that the overlapping section (d) of a pair of vertically adjacent external reinforcing steel plates 40 and 40' is located in a staggered direction , Fireproof, repair, reinforcement method. The method according to claim 1,
In step (f),
Of the external reinforcing steel plates 40 and 40 ′, the external reinforcing steel plate 40 ′ on the other side has a coupling protrusion 48 formed in the overlapping section (d) so that its cross section is extended to the outside, and the external reinforcement steel plate on one side The seismic, fireproof, and repair of concrete pillar structures using a spaced reinforcement member and an external reinforcing steel plate, characterized in that the inner surface of the coupling jaw 48 is in close contact with the upper portion of the coupling portion 42 of (40). Reinforcement method.

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