KR102092952B1 - A seismic pocket bracket structures of infilled square framed type strengthened by level-gap plates and sleeve-cap anchors - Google Patents

Abstract

The present invention provides a seismic reinforcing method for a pocket bracket door-type frame with a level gap plate and a sleeve anchor cap. A newly installed reinforcing vertical column member of a pocket bracket door-type frame is not tightly attached to an existing vertical column to allow minimization installation construction without a vertical error if a large separation distance is created and divide a load by a base plate role during a seismic resistance movement therebetween. The pocket bracket door-type frame manufactured at a factory can be constructed around a drilled anchor hole to be conveniently integrated into an existing structure by a sleeve anchor cap installed in the drilled hole for the purpose of local ground pressure cracks or reinforcement. A pocket bracket is formed to reuse an existing reinforced concrete water wall connecting a gap between vertical columns as a structure reinforcement member to effectively resist end bending moment transferred to the columns. Poured concrete leakage can be prevented by an anchor strength hairpin for leakage prevention installed in an anchor insertion hole formed on the outside of the newly installed reinforcing vertical column member. Synthesis resistance with concrete can be provided by fixed point formation.

Description

A seismic pocket bracket structures of infilled square framed type strengthened by level-gap plates and sleeve-cap anchors}

The present invention relates to a seismic reinforcement method that is installed on the inside of two existing vertical columns of a building and one or more water walls connecting them, and in particular, a new reinforced vertical column member of a pocket bracket door frame is not in close contact with the existing vertical column. In the case of separation distance, it is possible to share the load as a base plate when the seismic resistance between them is minimized with installation and installation without vertical errors, and a local shiatsu crack or cracks in the factory-made pocket bracket door frame around the perforated anchor hole side. For the purpose of reinforcement, the sleeve anchor cap installed in the perforated hole can be conveniently and integrally constructed in the existing structure, and the existing reinforced concrete water wall connecting between the vertical pillars is formed into a pocket bracket to be recycled as a structural reinforcement member and delivered to the pillar. It can effectively resist the end bending moment, and newly reinforced Pocket with gap level plate and sleeve anchor cap to prevent leakage of pour concrete with leakage-resistant anchor body rigid hairpin installed in the anchor insertion hole formed on the outer side of the columnar member and to exhibit concrete and synthetic resistance by forming a fixed point It relates to a method for seismic reinforcement of a bracket door frame.

In general, in order to reinforce an existing building, a steel frame is installed on a reinforced concrete structure (RC) and a mortar is poured to integrate the reinforced concrete structure and the steel frame. As described above, many techniques have been proposed to improve the seismic performance of a building through the installation of a steel frame. However, the techniques presented so far have a problem in that the construction is complicated and the satisfactory seismic performance cannot be obtained.

Moreover, when the existing facilities are removed to install the steel frame in the column-side water wall opening in the existing concrete structure, a vertical error in the column is largely generated. Conventionally, since the anchor body is installed without filling the gap of the vertical error part, there is a limit in increasing the seismic performance due to the lack of integrity when installing the steel frame.

As a background technology of the present invention, as a domestic registration patent registration number 1150392, "joint structure and joining method of seismic reinforcing steel structure" (Patent Document 1) has been proposed. In the background art, the present invention relates to a joint structure of a steel structure for seismic reinforcement, and includes an existing structure composed of a pillar or a beam; Reinforcing bars respectively installed by epoxy resin in a plurality of holes drilled in the wall of the existing structure; A concrete adhesive applied to the wall surface of the existing structure to strengthen the adhesion between the mortar and the wall surface; An H-shaped steel installed by welding so that the reinforcing bar penetrates the wall surface of the existing structure and has a plurality of reinforcing stud bolts; A mesh or iron plate provided in a form surrounding the outer circumference of the H-beam, including between the wall surface of the existing structure and the H-beam; It characterized in that it comprises a; mortar poured by the mesh or iron plate to enhance the efficiency of seismic reinforcement by strengthening the binding force between the existing concrete structure and the steel structure for seismic reinforcement.

However, the above background technology had to install a number of stud bolts, and can be separated from the existing structure during an earthquake by an indirect coupling method with the existing structure, so that it is difficult to enhance the seismic reinforcement effect and difficult to reinforce the foundation. In addition, in the background art, no technical alternative is proposed to integrally install the steel frame in the case where a vertical error occurs largely in the pillar portion on the side of the water wall opening portion of the existing concrete structure.

Domestic registered patent registration number 1150392

The present invention minimizes vertical error when the new reinforced vertical column member of the pocket bracket door frame is not in close contact with the existing vertical column and has a vertical separation, and distributes the load as a base plate when seismic resistance between them is installed. It is possible to construct a factory-made pocket bracket door-shaped frame around the perforated anchor hole side through a sleeve anchor cap installed in the perforated hole for the purpose of local acupressure cracking or reinforcement. To reuse the existing reinforced concrete water wall connecting the structure as a structural reinforcement member, it can form a pocket bracket to effectively resist the end bending moment transmitted to the pillar, and an anchor for preventing leakage installed in the anchor insertion hole formed on the outside of the newly reinforced vertical pillar member Prevent leakage of pouring concrete with a sieve rigid hairpin Number and it is an object of the pocket frame providing a gate-form bracket seismic reinforcement method having a level gap plate and the anchor sleeve so that the concrete cap and the combined resistance exhibited by forming the fixed point.

A method of seismic reinforcement of a pocket bracket door frame having a gap level plate and a sleeve anchor cap according to a preferred embodiment of the present invention includes: (a) a new reinforcement reinforcement member upper joining bracket at the bottom and an end water wall reinforcement pocket bracket at the bottom; Removing a predetermined section of both ends of the water wall through cutting and crushing to install a new reinforcement vertical column member; (b) Gap level plates are fixed with reinforcing adhesives on the upper and lower inner surfaces of the left and right pillars in contact with the water wall opening to form parallel vertical reference planes with no vertical error between the newly reinforced vertical pillar members and the gap level plates. Laying step; (c) Temporarily install the new reinforced vertical column member to contact the gap level plate installed at the upper and lower sides of the vertical column, and connect the new reinforced reinforcement member made of H-shaped steel between the opposite new reinforced vertical column members. Then, after forming a plurality of rows of anchor holes at predetermined intervals in the vertical column on the same axis as the anchor insertion hole of the newly reinforced vertical column member, the injection agent is injected into the anchor hole and the anchor body is inserted into the anchor hole through the anchor insertion hole. Installing; (d) An anchor body for leak prevention is inserted into a newly reinforced vertical column member and screwed and fastened to the anchor body located on the same line to fix and install the newly reinforced vertical column member into a vertical column, and the injection hole is inserted into the vertical column. After filling the pouring concrete, the back filler is filled between the vertical pillar and the new reinforcement vertical pillar member, and the inside of the square space formed between the bracket for the upper connection of the new reinforcement member and the new reinforcement member and the existing structure Filling the pour concrete; (e) Position the male wall stiffeners facing each other between the pocket brackets for the end wall wall reinforcement of the newly reinforced vertical column members facing each other, and fix them through the bolt connection to the end wall wall reinforcement pocket brackets. Filling and placing the pouring concrete between the inside and between the water wall and the water wall reinforcement 50; (f) the step of arranging the water wall reinforcing material and the water wall reinforcing member coupling bolts through the double row at regular intervals on the water wall and joining the bolts with bolt fasteners at both ends.

In addition, in the step (c), it is characterized in that the sleeve anchor cap is preferentially inserted into the gap level plate side anchor hole and then the anchor body is inserted into the anchor hole through the sleeve anchor cap on the gap level plate side.

In addition, in the step (c), the sleeve anchor cap is formed of a cylindrical shape, or is characterized in that it is provided with a flat head locking jaw at the rear end.

In addition, in the step (c), it is characterized in that the sleeve anchor cap is further installed in the column-side anchor hole existing in the section where the gap level plate is not installed.

In addition, the newly reinforced floor reinforcement member of step (c) is characterized in that it is installed in a state assembled and connected to the newly reinforced vertical pillar member.

According to the method of seismic reinforcement of a pocket bracket door frame having a gap level plate and a sleeve anchor cap of the present invention, there is an inclination or a large vertical error in both vertical pillars in contact with the male wall opening of the existing structure, thereby overcoming the gap S To install the new reinforced vertical column member, install the gap level plate on the upper and lower two sides of the vertical column, and then use the sleeve anchor cap to combine the new reinforced vertical column member without vertical error. Structure formation is possible.

In addition, by installing a sleeve anchor cap on the anchor hole perforated on the gap level plate side, when an external force such as an earthquake acts, it prevents local acupressure cracking around the anchor hole or rigidly reinforces the perforated hole, thereby strengthening the existing structure and the newly reinforced vertical column members. It has the advantage of securing integrity.

In addition, an anchor body rigid hairpin for leak prevention is fastened to the end of the anchor body embedded in the existing structure by screwing, but the anchor body for leak prevention is rigid to prevent leakage of pouring concrete due to the anchor insertion hole drilled in the new reinforced vertical pillar member. By welding joints using the leak-proof plate of the hairpin, the anchor insertion hole is sealed and the anchor body is continuously fixed to the new reinforced vertical column member side.

In addition, an n-shaped end wall wall reinforcement pocket bracket is provided at the area where the new reinforced vertical column member meets the male wall so that the male wall connecting the two vertical columns is integrated with the new reinforced vertical column member to directly transmit and resist the parental moment. By covering a part of the end of the water wall, the water wall reinforcement material and cast concrete can actively resist the end bending moment during an earthquake, improving seismic performance.

The following drawings attached in the present specification are intended to 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 only described in the accompanying drawings. It is not limited and should not be interpreted.
1 is a perspective view of an installation of a pocket bracket door frame installed in a water wall opening of a water wall of an existing building according to the present invention.
Figure 2a is a front view of Figure 1;
Figure 2b is an enlarged cross-sectional view of AA line of Figure 2a.
Figure 2c is an enlarged cross-sectional view taken along line BB of Figure 2b.
Figure 3 is a gap level plate applied to the present invention is installed in the upper and lower positions on the inner surface side of the pillar.
4 is an installation state diagram of a newly reinforced vertical column member after installation of the gap level plate of FIG. 3;
Figure 5 is an exploded perspective view of separating the gap level plate, sleeve anchor cap and the anchor body for preventing leakage from the newly reinforced vertical column member applied to the present invention.
Fig. 6 is a state diagram in which a gap level plate applied to the present invention is installed on one outer surface of a pillar.
Figure 7 is a perforated state diagram of the pillar-side anchor hole through a newly reinforced vertical column member according to the present invention.
8 is a state diagram of a sleeve anchor cap and an anchor body installed on a gap level plate according to the present invention.
FIG. 9 is a state diagram of pouring concrete into a newly reinforced vertical column member after a rigid hairpin for preventing leakage is fastened to a gap level plate side anchor body according to the present invention.
10 is an enlarged view of main parts of FIG. 9.
Figure 11 is a horizontal and vertical arrangement of the pocket bracket door-shaped frame consisting of a newly reinforced vertical column member and a newly reinforced member in accordance with the present invention.

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

The present invention provides a method for seismically reinforcing an existing structure (10) having a water wall (102) in the water wall opening (101). The seismic structure of the existing structure 10 made in this way, as shown in FIGS. 1 to 2, newly reinforced pillar members (in the upper and lower locations of the left and right vertical columns 12 and 12 on the water wall opening portion 101) 30) The gap level plate 20 is installed to overcome errors inclination or verticality with more than 50 mm. The gap level plate 20 is used to secure the verticality when the new reinforcement pillar member 30 is mounted, and subsequently installed as a reinforcement steel plate for synthesis with the back filler 26 within a large separation distance (S) of 50 mm or more. While maintaining the coupling gap of the sleeve anchor cap 29, it realizes the same function as the base plate that simultaneously resists external forces, and also when the sleeve anchor cap 29 is inserted and mounted, in the vicinity of the anchor hole drilled in the existing structure 10 By preventing local acupressure cracking or inserting and reinforcing a perforated hole into the interior, a synthetic uniformity within a separation distance between the vertical pillar 12 of the existing structure 10 and the newly reinforced pillar member 30 is secured.

In addition, through the gap level plate 20, the sleeve anchor cap 29 and the anchor body 25 are installed on the vertical pillar 12 side of the existing structure, and the anchor body rigid hairpin for preventing leakage at the end of the anchor body 25 By tightening (28), the newly reinforced pillar member 30 has a structure that is integrated with the vertical column 12 side.

The anchor body 25 is continuously installed from the existing structure 10 to the newly reinforced vertical pillar member 30 for the purpose of synthesizing, such as a shear key composite anchor. At this time, one side has an anchor fastening female screw cylindrical portion 281 and the other side has a leak-preventing head plate 282, and an anchor body rigid hairpin 28 for preventing leakage is combined with the anchor body 25, and a newly reinforced vertical column member 30 is provided. The anchor body 25 is welded to form a fixed point, and the anchor body 25 is welded and fixed to the fixed point embedded in the existing structure 10 and the newly reinforced pillar member 30 to continuously form the side of the newly reinforced pillar member 30. It is possible to effectively implement the shear resistance.

In addition, the upper end between the newly reinforced vertical pillar members 30 and 30 is connected to and reinforced with a newly reinforced reinforcement member 40, and reinforced with pour concrete and water wall reinforcement 50 on the side of the water wall 102 to increase seismic performance. It is done.

Here, the new reinforcement reinforcing member 40 uses an H-shaped steel, but is coupled to the existing structure 10 using a conventional method of integrating using an anchor body 25.

A method for seismically reinforcing the existing structure 10 having the water wall 102 in the water wall opening portion 101 according to the present invention will be sequentially described.

Water wall opening side Water wall  Remove some

First, as shown in Figure 3, a certain section of both ends of the water wall 102 forming the reinforced concrete structure on the water wall opening portion 101 side is removed through cutting and crushing. This is for the integral installation with the newly reinforced vertical column member (30). Here, as shown in Figures 2 and 4, the newly reinforced vertical column member 30 has a rectangular hollow cross section and has a plurality of rows of anchor insertion holes 301b and a pour concrete injection hole 301c at the top, vertical column 301, vertical column. Newly reinforced reinforcement member joined to the top of the part 301 Bracket 302 for the upper connection, has a pour concrete injection pocket (303a) and is joined to the lower end of the vertical column 301 pocket bracket for the end wall reinforcement ( 303).

At this time, it is preferable that a plurality of shear connectors 304 that are joined to the lower end of the newly reinforced vertical pillar member 30 are installed inside the pour-in concrete pouring pocket 303a of the end-wall reinforcement pocket bracket 303. 2a)

The pocket bracket 303 for reinforcing the end wall of the newly reinforced vertical column member 30 is a steel-coupling bonding device intended to directly transfer resistance to the end bending moment between the pillar member and the horizontal member, and has a predetermined length n-type bracket shape, but has a water wall 102 ) Not only reinforced by overlapping on both ends, but also reinforces the existing water wall 102 by fastening the water wall reinforcement 50 and the coupling bolt 70 to realize the role of a seismic reinforcing material and is integrated with effective resistance to the end bending moment Can be secured.

Gap level plate installation

Then, as shown in FIGS. 3 and 6, the gap level plate 20 is fixed to the upper and lower inner surfaces of the left and right vertical columns 12 and 12, respectively, which are in contact with the water wall opening 101, with a reinforcing adhesive 22. Let it go. In this way, since the gap level plate 20 is installed at the upper and lower locations, a side-by-side vertical reference plane X having no vertical error between the newly reinforced vertical column member 30 and the gap level plate 20 is at the gap level plate 20. Will be done.

The gap level plate 20 has an anchor hole 121 to be drilled at a certain depth to the vertical column 12 through the newly reinforced vertical column member 30 as shown in FIG. 7 and the vertical surface of the newly reinforced vertical column member 30. It serves to make it perpendicular. Epoxy mortar may be used as the reinforcing adhesive 22. Here, the reinforcing adhesive 22 performs a concrete reinforcing function around the anchor hole 121 to be formed on the side of the gap level plate 20 along with the role of fixing the gap level plate 20 on the vertical column 12 side. Column-side gap level plate 20 may be made of a steel plate. The column side gap level plate 20 has a plurality of gap level plate holes 201 for insertion of the anchor body 25 to be described later. The gap level plate hole 201 may be circular, but the slot shape shown to accommodate the installation error of the anchor hole is preferable.

sleeve Anchor cap  And Anchor body  install

Next, as shown in FIGS. 4 and 8, the newly reinforced vertical column member 30 is temporarily installed to contact the gap level plate 20 installed at the upper and lower positions of the vertical column 12, and the new reinforced vertical column member ( 30 and 30) connect the new reinforcement reinforcement member 40 made of H-beam.

At this time, the new reinforcement reinforcement member 40 is connected to the bracket 302 for the upper connection of the newly reinforced reinforcement member through a bolt connection to the plate. In addition, the new reinforcement reinforcement member 40 is fixed to the existing structure 10 by installing a double row anchor body 25 on the horizontal floor beam 13 on the side of the existing structure 10 as shown in FIG. At this time, the sleeve anchor cap 29 may be installed in the anchor hole 131.

Thereafter, a plurality of rows of anchor holes 121 are formed at predetermined intervals in the vertical column 12. At this time, the anchor hole 121 is made by inserting a drilling drill into the anchor insertion hole 301b formed in the vertical section of the newly reinforced vertical column member 30.

Then, the injection agent 24 is injected into the anchor hole 121 to insert and install the anchor body 25. The anchor body 25 is continuously installed from the existing structure 10 to the newly reinforced vertical column member 30 for the purpose of synthesizing, such as a shear key composite anchor. The anchor body 25 is formed with a thread on the outer circumferential surface of the entire stem, but a thread may be formed only on the front end and the rear end. At this time, the sleeve anchor cap 29 is preferentially inserted into the gap level plate 20 side anchor hole 121 on the gap level plate 20 side, and then the anchor body 25 is anchored through the sleeve anchor cap 29. It is inserted and installed in 121. 5 and 9, the sleeve anchor cap 29 may be formed in a cylindrical shape or a flat head engaging jaw 291 may be further formed at the rear end of the cylindrical shape. As such, the sleeve anchor cap 29 is installed in the anchor hole 121 to prevent local acupressure cracking or rigid reinforcement at the entrance of the anchor hole 121.

Here, the sleeve anchor cap 29 may be further installed in the anchor hole 121 on the vertical column 12 side existing in the section where the gap level plate 20 is not installed.

New reinforcement Vertical pillar member  install

Next, as shown in FIG. 9, the anchor body rigid hairpin 28 for preventing leakage is inserted through the anchor insertion hole 301b of the newly reinforced vertical column member 30 and screwed to the anchor body 25 to be tightened. Therefore, the newly reinforced vertical column member 30 is welded to the newly reinforced vertical column member 30 together with the screwing of the anchor body 25 and the leak-free anchor body rigid hairpin 28 to form a fixed column ( It is fixedly installed on the 12) side.

Then, the pouring concrete 39 is filled through the injection hole 301a into the vertical column 12.

Before or after the filling of the pour concrete 39, the back filler 26 is filled and filled to fill the floating gap between the rear faces between the vertical pillar 12 and the newly reinforced vertical pillar member 30.

In advance, the anchor body rigid hairpin 28 for preventing leakage is fastened to the anchor body 25 to the anchoring female screw cylindrical portion 281 and at the same time welded to the newly reinforced vertical column member 30 with a leak-proof head plate 282. By forming a fixed point, shear resistance is effectively implemented.

Thereafter, as shown in FIG. 2C, the pour concrete 80 is filled into the square space formed between the new reinforcement member upper joining bracket 302, the new reinforcement member 40, and the existing structure 10. As described above, the pouring concrete 80 is synthesized in the bracket 302 for upper joining of the newly reinforced reinforcement member and the newly reinforced reinforcement member 40, thereby enhancing the seismic ability by reinforcing the horizontal floor beam 13.

Water wall reinforcement  Installation and Pour concrete Filling

Next, as shown in FIGS. 1 and 2, the wall reinforcements 50 and 50 facing each other between the pocket brackets 303 and 303 for end wall reinforcement of the newly reinforced vertical column members 30 and 30 facing each other are shown. Position it.

Subsequently, the end brackets 303 and 303 and the wall stiffeners 50 and 50 are overlapped with a steel plate and fixed through bolt bonding, and the inner and water walls of the pocket brackets 303 and 303 for the wall stiffening of the ends wall ( 102) and the pouring concrete 60 is filled and placed between the water wall reinforcement 50.

Therefore, the water wall 102 is synthesized in the pour concrete 60 and is integrated with the newly reinforced vertical column member 30. At this time, the pour concrete 60 is synthesized with a plurality of shear connecting materials 304 and more firmly integrated into the newly reinforced vertical column member 30.

Water wall reinforcement Water wall  Combination

Then, as shown in Figure 2b, the wall wall reinforcement member 50 and the wall wall 102 are arranged through the wall wall reinforcement coupling bolt 70 through double row at regular intervals to be coupled with the bolt fastener 72. Therefore, the water wall reinforcing material 50 is integrated into the water wall 102 and the pouring concrete 60 by the water wall reinforcing member coupling bolt 70 to enhance the seismic reinforcing effect by reinforcing the water wall 102.

According to the seismic reinforcing method of the pocket bracket door-shaped frame, which is synthesized integrally with a gap-level plate and a pocket bracket installed on two or more water walls connecting the two vertical columns of the present invention as described above, the water wall opening portion 101 of the existing structure 10 ), After installing the gap level plate 20 on each of the two outer surfaces of the vertical columns 12 in contact with each other, a new reinforced vertical column member 30 is installed to allow vertically error-free construction.

In addition, a sleeve anchor cap 29 is installed in the gap level plate 20 side anchor hole 121 to prevent cracking of the anchor hole 121 due to external force, thereby reducing the existing structure 10 and the newly reinforced vertical column member ( 30) It is advantageous to secure the integrity of the liver.

In addition, since the new reinforcement vertical column member 30 is installed by fastening the anchor body rigid hairpin 28 for leak prevention to the anchor body 25 installed on the existing structure 10, the anchor body rigid hairpin 28 for leak prevention is provided. The anchor insertion hole (301b) located is sealed to prevent leakage when pouring pour concrete into the newly reinforced vertical column member (30), as well as the newly reinforced vertical column member (30) by the anchor body rigid hairpin (28) for leak prevention. Sufficient shear resistance can be exerted by forming a fixed point on the side.

In addition, the seismic performance of the existing structure 10 is improved by having a structure in which the water wall 102 is integrally synthesized with the newly reinforced vertical column member 30 and effectively resists the end bending moment by the water wall reinforcement material 50 and pour concrete. do.

On the other hand, the installation of the pocket bracket door-shaped frame 100 in the existing structure 10 can be continuously constructed through vertical arrangement and horizontal arrangement as shown in FIG. 11.

The present invention has been described in detail with reference to the presented embodiments, but those skilled in the art can make various modifications and modified inventions 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 modified and modified inventions, but is limited by the appended claims.

20: gap level plate
25: anchor body
28: anchor body rigid hairpin for leak prevention
29: sleeve anchor cap
30: New reinforcement vertical column member
40: New reinforcement reinforcement
50: Water wall reinforcement

Claims (5)

In the method for seismically reinforcing the existing structure 10 with the water wall 102 in the water wall opening portion 101,
(a) The both ends of the water wall 102 for the installation of the new reinforcement vertical pillar member 30 having a new reinforcement reinforcement member upper joining bracket 302 at the bottom and a pocket bracket 303 for reinforcement of the end wall at the bottom Removing the section through cutting and crushing;
(b) Gap level plates 20 are fixed with reinforcement adhesive 22 to the upper and lower inner surfaces of the left and right vertical pillars 12 and 12, respectively, which are in contact with the water wall opening 101, thereby forming a new reinforced vertical pillar member ( 30) and forming a side-by-side vertical reference plane (X) with no vertical error between the gap level plate (20);
(c) The newly reinforced vertical column members 30 are temporarily installed to contact the gap level plates 20 installed at the upper and lower sides of the vertical columns 12, and of the newly reinforced vertical column members 30 and 30 facing each other. The upper end is connected to a new reinforcement reinforcement member 40 made of H-shaped steel, and a plurality of rows of anchors are arranged at predetermined intervals in a vertical column 12 in the same axis as the anchor insertion hole 301b of the newly reinforced vertical column member 30. After forming the hole 121, injecting the injection agent 24 into the anchor hole 121 and inserting the anchor body 25 into the anchor hole 121 through the anchor insertion hole 301b;
(d) By inserting a rigid hairpin 28 for preventing leakage into the newly reinforced vertical column member 30, screw fastening to the anchor body 25 located on the same line to tighten the newly reinforced vertical column member 30 into a vertical column ( After being fixedly installed in 12), after filling the pouring concrete 39 through the injection hole 301a into the inside of the vertical column 12, the rear surface between the vertical column 12 and the rear surface of the newly reinforced vertical column member 30 Filling the filling material 26, and filling the pour concrete 80 into the square space formed between the new reinforcement member upper joining bracket 302 and the new reinforcement member 40 and the existing structure 10 Step and;
(e) Between the end brackets 303 and 303 of the end wall wall reinforcement of the newly reinforced vertical column members 30 and 30 facing each other, the wall brackets 50 and 50 facing each other are placed to face each other. (303 and 303) is fixed through bolt bonding, and the inside of the end brackets 303 and 303 for wall reinforcement and between the water wall 102 and the water wall reinforcement 50 is filled with pour concrete 60 Step and;
(f) a step of placing the water wall reinforcement coupling bolts 70 through the double row at regular intervals on the water wall reinforcement 50 and the water wall 102 to be coupled with bolt fasteners 72 at both ends; Seismic reinforcement method for door bracket frame with gap level plate and sleeve anchor cap. According to claim 1,
In the step (c), the sleeve anchor cap 29 is preferentially inserted into the gap level plate 20 side anchor hole 121 on the side of the gap level plate 20, and then the anchor body 25 is inserted into the sleeve anchor cap ( 29) Pocket bracket door frame seismic reinforcement method having a gap level plate and a sleeve anchor cap, characterized in that it is inserted and installed in the anchor hole (121). According to claim 1,
In step (c),
Sleeve anchor cap (29) is composed of a cylindrical shape, or a cylindrical plate with a gap level plate and a sleeve anchor cap, characterized in that the flat head locking jaw (291) is provided at the rear end. According to claim 1,
In step (c),
A pocket having a gap level plate and a sleeve anchor cap, characterized in that a sleeve anchor cap 29 is further installed in the anchor hole 121 on the vertical column 12 side existing in the section where the gap level plate 20 is not installed. Seismic reinforcement method for bracket door frame. According to claim 1,
The step (e) of the newly reinforced floor reinforcement member 40 is a newly reinforced vertical column member 30, which is installed in an assembled state, characterized by being installed in a gap level plate and sleeve anchor cap with shear composite integrated outer square door shape Outframe seismic reinforcement method.

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