KR102246708B1 - Seismic retrofit construction method of masonry wall - Google Patents

Abstract

The present invention relates to a seismic reinforcement construction method of a masonry wall which has excellent constructability and economic efficiency since a masonry wall can be firmly fixed on a building structure without removing the masonry wall or filling epoxy by fixing an end of a fixing pin for seismic reinforcement, of which one end and the other end are inserted into an anchor hole of the structure and a penetration hole of the masonry wall, in the anchor hole by a fixing spring. According to the present invention, the seismic reinforcement construction method of a masonry wall is to reinforce a masonry wall previously constructed on the outside of a building structure and reinforces and constructs the masonry wall in a seismic manner by using a masonry wall seismic reinforcement structure comprising: a fixing pin for seismic reinforcement installed through a penetration hole formed on the masonry wall, wherein one end thereof is inserted into an anchor hole formed on the front surface of the building structure, and the other end thereof is fixed on the penetration hole of the masonry wall; and a fixing spring inserted into the anchor hole and provided between the inner circumferential surface of the anchor hole and the outer circumferential surface of the fixing pin for seismic reinforcement to fix the fixing pin for seismic reinforcement in the anchor hole.

Description

Seismic retrofit construction method of masonry wall}

In the present invention, the end of the seismic reinforcement fixing pin, which is inserted into the anchor hole of the building structure and the through hole of the masonry wall, is fixed inside the anchor hole by a fixing spring, so that the masonry wall without removing masonry or filling epoxy It is about the seismic reinforcement construction method of masonry walls, which can be firmly fixed to the structure, and thus has excellent workability and economy.

Recently, many buildings have been damaged due to a major earthquake in Korea. In particular, most of the unreinforced masonry buildings were built before seismic design was introduced, and are vulnerable to earthquakes and are often deteriorated.

In addition, in the existing masonry building, stucco walls are constructed to be spaced apart from the building structure by stacking stucco bricks outside the reinforced concrete-joined building structure, and insulation is constructed between the building structure and the stucco wall. In this case, since the stucco is structurally separated from the building structure, reinforcement is urgent because there is a risk of an accident due to the fall, fall, or collapse of the stucco when an earthquake occurs.

Therefore, various construction methods have been developed for seismic reinforcement of external stucco walls.

For example, there is a technology that prevents the masonry wall from overturning by removing some of the masonry bricks at regular intervals and installing brackets and angles. However, in the above technology, since the masonry brick must be newly reinstalled in an empty space after removing the masonry brick, the construction is cumbersome, requires a lot of time, and there is a risk of the masonry wall falling or collapsing during the masonry brick demolition work.

In addition, there is a technology in which a masonry wall is drilled without removal of the masonry wall, an anchor hole is formed in the structure, and then a fixing pin is inserted to fix the fixing pin in the anchor hole of the structure with epoxy. However, in the above technology, the anchor hole must be filled with epoxy first before insertion of the fixing pin, but it is not easy to fill the anchor hole formed in the structure spaced apart from the rear surface of the masonry wall. In addition, it is difficult to ensure that the epoxy is properly filled, making it difficult to secure structural stability.

KR 10-2107066 B1

In order to solve the above problems, the present invention does not require removal of the masonry brick, and it is possible to fix the masonry wall to the structure without filling the epoxy, so that the construction is excellent and an economical seismic reinforcement method of the masonry wall is provided.

The present invention according to a preferred embodiment is for reinforcing a masonry wall previously constructed on the outside of a building structure, and is installed through a through hole formed in the masonry wall, and one end is inserted into an anchor hole formed in the front of the building structure. , The other end is a seismic reinforcement fixing pin fixed to the through hole of the masonry wall; And a fixing spring inserted into the anchor hole and provided between the inner circumferential surface of the anchor hole and the outer circumferential surface of the seismic reinforcing fixing pin to fix the seismic reinforcing fixing pin inside the anchor hole. It relates to a masonry wall seismic reinforcement construction method using a masonry wall seismic reinforcement structure consisting of, (a) forming a through hole by drilling the masonry wall; (b) drilling an anchor hole by drilling a building structure at a location corresponding to the through hole; (c) inserting a fixed spring into the anchor hole; And (d) penetrating the seismic reinforcement fixing pin through the through hole of the masonry wall and inserting and fixing it into the fixing spring of the anchor hole. It provides a masonry wall seismic reinforcement construction method, characterized in that consisting of.

In the present invention according to another preferred embodiment, a screw is formed on the front outer circumferential surface of the seismic reinforcing fixing pin, and in the step (d), inserting and fixing the seismic reinforcing fixing pin into the fixing spring of the anchor hole by rotation It provides a masonry wall seismic reinforcement construction method, characterized in that.

In the present invention according to another preferred embodiment, a friction fixing pipe is provided at the rear outside of the seismic reinforcing fixing pin, and in the step (d), the seismic reinforcing fixing pin is formed of the masonry wall by the friction fixing pipe. It provides a seismic reinforcement construction method of a masonry wall, characterized in that fixed in the through hole.

The present invention according to another preferred embodiment provides a masonry wall seismic reinforcement construction method, characterized in that the friction fixing pipe is formed to be tapered so that the diameter of the outer circumferential surface decreases toward the front.

In the present invention according to another preferred embodiment, the rear of the seismic reinforcing fixing pin is formed with a tapered expansion portion so that the diameter increases toward the rear, and a plurality of incision grooves cut in the longitudinal direction are formed at the rear of the friction fixing tube. It provides a masonry wall seismic reinforcement construction method characterized in that the.

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According to the present invention, it is for reinforcing the masonry wall previously constructed on the outside of the building structure, and one end and the other end of the seismic reinforcement fixing pin are inserted into the anchor hole of the building structure and the through hole of the masonry wall, respectively, and fixed. It is possible to provide a seismic reinforcement construction method of a masonry wall in which the end of the seismic reinforcement fixing pin is fixed inside the anchor hole by a fixing spring between the seismic reinforcement fixing pin and the seismic reinforcement fixing pin.

Accordingly, by using a plurality of seismic reinforcing fixing pins that are spaced apart from each other up, down, left and right, the masonry walls installed spaced apart from the front of the building structure can be firmly fixed to the building structure, so it is possible to prevent the masonry walls from falling in the event of an earthquake.

In addition, there is no need to remove the masonry brick, and since the epoxy injection process is omitted, workability and economy are excellent.

1 is a cross-sectional view showing a seismic reinforcing structure of a masonry wall.
2 is a perspective view showing a coupling relationship between a fixing spring and a fixing pin for seismic reinforcement.
Figure 3 is a perspective view showing a coupled state of the fixing spring and the fixing pin for seismic reinforcement.
4 is a perspective view showing a state in which a plurality of seismic reinforcing fixing pins are installed.
Figure 5 is a perspective view showing a seismic reinforcement fixing pin provided with a tool insertion groove.
6 is a cross-sectional view showing a state in which a tapered friction fixing pipe is coupled to a fixing pin for seismic reinforcement.
7 is a perspective view showing a friction fixing tube in which an incision groove is formed.
8 is a perspective view showing a coupling relationship between a friction fixing pipe having an incision groove and a seismic reinforcing fixing pin provided with an expanding part.
9 is a view showing a step-by-step process for the present invention masonry wall seismic reinforcement construction method.

Hereinafter, the present invention will be described in detail according to the accompanying drawings and preferred embodiments.

1 is a cross-sectional view showing a seismic reinforcing structure of a masonry wall. And Figure 2 is a perspective view showing the coupling relationship between the fixing spring and the seismic reinforcement fixing pin, Figure 3 is a perspective view showing the coupling state of the fixing spring and the seismic reinforcement fixing pin, Figure 4 is a plurality of seismic reinforcement fixing It is a perspective view showing a state in which a pin is installed. 5 is a perspective view showing a seismic reinforcing fixing pin provided with a tool insertion groove.

As shown in Figs. 1 to 4, the masonry wall seismic reinforcement structure is for reinforcing the masonry wall 2 previously constructed on the outside of the building structure 1, and through holes formed in the masonry wall 2 ( 21) to be installed through, one end is inserted into the anchor hole 11 formed in the front of the building structure (1), the other end is a seismic reinforcement fixing pin fixed to the through hole 21 of the masonry wall (2) ( 3); And it is inserted into the inside of the anchor hole 11 and is provided between the inner circumferential surface of the anchor hole 11 and the outer circumferential surface of the seismic reinforcement fixing pin 3 to insert the seismic reinforcement fixing pin 3 into the anchor hole 11 A fixed spring 4 to be fixed to the; It characterized in that it consists of.

The present invention does not require removal of the masonry brick, it is possible to fix the masonry wall (2) to the building structure (1) without epoxy filling, excellent workability and to provide an economical masonry wall seismic reinforcement construction method.

The seismic reinforcement structure of the masonry wall uses a plurality of seismic reinforcement fixing pins (3) that are spaced apart from each other up, down, left and right, and the masonry wall (2) spaced apart from the front of the already constructed building structure (1) is incorporated into the building structure ( By fixing it to 1), it prevents the masonry wall 2 from falling in the event of an earthquake.

The building structure 1 is a reinforced concrete structure.

To this end, a through hole 21 is formed in the front masonry wall 2, and an anchor hole 11 is formed in the building structure 1 at a corresponding position.

The seismic reinforcing fixing pin 3 penetrates the through hole 21 of the masonry wall 2 and the front end is inserted and fixed into the anchor hole 11, and the rear end is in the through hole 21 of the masonry wall 2 It is fixed.

The fixed spring 4 is provided in the anchor hole 11 of the building structure 1.

The fixing spring 4 is fitted between the outer circumferential surface of the seismic reinforcement fixing pin 3 and the inner circumferential surface of the anchor hole 11, and the fixing pin 3 for seismic reinforcement is firmly in the anchor hole 11 by friction. To be fixed.

Accordingly, it is possible to fix the seismic reinforcement fixing pin 3 without injecting epoxy into the anchor hole 11.

Therefore, the difficult epoxy injection process can be omitted, simplifying the construction and greatly shortening the construction period. In addition, it is possible to exhibit a uniform fixing power because there is no effect due to the epoxy state of charge.

The fixed spring 4 may be a metal or non-metal spring.

As shown in FIGS. 2 and 3, a screw 31 may be formed on the front outer circumferential surface of the seismic reinforcing fixing pin 3.

In order to insert the fixed spring 4 into the anchor hole 11, the outer diameter of the fixed spring 4 must be smaller than the inner diameter of the anchor hole 11.

In this case, if the seismic reinforcing fixing pin 3 is a rod shape, it may be difficult to insert the seismic reinforcing fixing pin 3 into the fixing spring 4.

Therefore, if the screw 31 is formed on the front outer circumferential surface of the seismic reinforcement fixing pin 3, it is possible to easily enter the inside of the fixing spring 4 while rotating the seismic reinforcement fixing pin 3.

In addition, since the screw 31 penetrates the inner circumferential surface of the fixing spring 4, a more robust fixing force can be exhibited.

The screw 31 may be formed by turning the outer circumferential surface of the seismic reinforcement fixing pin 3 in the form of a round bar.

It is preferable that the front of the seismic reinforcement fixing pin 3 be sharpened so that the front end of the seismic reinforcement fixing pin 3 can easily enter the inside of the fixing spring 4.

As shown in FIG. 5, in order to insert the seismic reinforcement fixing pin 3 into rotation, a tool insertion groove 32 so that a tool such as a screwdriver or a wrench can be inserted and rotated at the rear end of the seismic reinforcement fixing pin 3 ) Can be formed.

As shown in Figs. 2 and 3, a friction fixing pipe for fixing the seismic reinforcement fixing pin 3 in the through hole 21 of the masonry wall 2 outside the rear of the seismic reinforcement fixing pin 3 5) may be further provided.

In order to insert the seismic reinforcing fixing pin 3 through the through hole 21 of the masonry wall 2, the inner diameter of the through hole 21 must be larger than the outer diameter of the seismic reinforcing fixing pin 3.

Accordingly, a separate member for fixing the rear end of the seismic reinforcing fixing pin 3 to the masonry wall 2 is required.

To this end, a method of fixing by fastening a nut after protruding a part of the rear end of the seismic reinforcing fixing pin 3 to the outside of the masonry wall 2 may be considered. However, in this case, the fixing pin 3 and the nut for seismic reinforcement are exposed to the outside of the masonry wall 2, so that the appearance is poor, and there is a concern that pedestrians may be hurt.

Therefore, the rear end of the seismic reinforcement fixing pin (3) can be fixed in the through hole (21) of the masonry wall (2) without protruding the rear end of the masonry wall (2). The friction fixing tube (5) can be put on.

The friction fixing pipe 5 may be made of a synthetic resin material such as PVC.

The rear end of the seismic reinforcing fixing pin 3 may be forcibly fitted into the friction fixing pipe 5, and the friction fixing pipe 5 may be forcibly fitted into the through hole 21 to be fixed.

The seismic reinforcing fixing pin 3 and the friction fixing pipe 5 can be inserted to be recessed into the through hole 21, and the recessed space is made to be simmered.

Accordingly, there is no part protruding to the outside of the masonry wall 2, so that the factors that hinder the appearance and safety can be eliminated.

6 is a cross-sectional view showing a state in which a tapered friction fixing pipe is coupled to a fixing pin for seismic reinforcement.

As shown in FIG. 6, the friction fixing pipe 5 may be formed to be tapered so that the diameter of the outer circumferential surface decreases toward the front.

The friction fixing pipe 5 must be inserted into the through hole 21 while being coupled to the rear end of the seismic reinforcing fixing pin 3. However, in this case, if there is no gap between the friction fixing pipe 5 and the through hole 21, the friction fixing pipe 5 cannot enter the through hole 21 and slides from the seismic reinforcement fixing pin 3 for seismic reinforcement. Only the fixing pin 3 may be inserted into the through hole 21.

To prevent this, the front outer diameter of the friction fixing pipe 5 may be formed smaller than the size of the through hole 21 so that the friction fixing pipe 5 can be easily inserted into the through hole 21.

Further, by forming the front of the friction fixing pipe 5 to be tapered, it is firmly fixed with the masonry wall 2, and the fixing force can be increased as the masonry wall 2 receives a load outward.

When a force to conduct conduction acts on the masonry wall (2), a friction protrusion (not shown) is formed on the inner circumferential surface of the friction fixing pipe (5) to prevent the seismic reinforcement fixing pin (3) from falling out from the friction fixing pipe (5). Can be.

Alternatively, a stepped portion 33 is formed on the seismic reinforcing fixing pin 3, and a locking ring 51 protrudes inward at the entrance of the friction fixing pipe 5, so that the locking ring 51 is formed with a stepped portion 33 ) Can also be configured.

7 is a perspective view showing a friction fixing pipe in which an incision groove is formed, and FIG. 8 is a perspective view showing a coupling relationship between a friction fixing pipe in which an incision groove is formed and a seismic reinforcing fixing pin provided with an expanding part.

7 and 8, the rear of the seismic reinforcing fixing pin 3 is formed with a tapered expansion portion 34 so that the diameter increases toward the rear, and at the rear of the friction fixing pipe 5 A plurality of cut grooves 52 cut in the longitudinal direction may be formed.

The outer diameter of the friction fixing pipe 5 is formed smaller than the inner diameter of the through hole 21 so that the friction fixing pipe 5 can be easily inserted into the through hole 21 without resistance, but the rear of the seismic reinforcing fixing pin 3 The diameter may be enlarged, and a plurality of cut grooves 52 cut in the longitudinal direction may be formed at the rear of the friction fixing pipe 5.

In this case, the front of the friction fixing pipe 5 may have an inner diameter less than the outer diameter of the seismic reinforcing fixing pin 3 so that the seismic reinforcing fixing pin 3 is forcibly fitted and fixed. And the rear of the friction fixing pipe 5 is opened by the expansion portion 34 of the seismic reinforcement fixing pin 3 and is sandwiched between the through hole 21 and the expansion portion 34 to exert a frictional force.

That is, if the front of the seismic reinforcement fixing pin 3 is inserted into the friction fixing pipe 5 as shown in Fig. 8(a), the rear of the seismic reinforcement fixing pin 3 is expanded as shown in Fig. 8(b). The rear portion of the friction fixing pipe 5 is enlarged by the neck portion 34 so that a friction force can be exerted between the through hole 21 and the enlarged diameter portion 34.

9 is a view showing a step-by-step process for the present invention masonry seismic reinforcement construction method.

The present invention relates to a method of seismic reinforcement construction of a masonry wall using the seismic reinforcement structure of the masonry wall described above with reference to FIGS. 1 to 8.

In the seismic reinforcement construction method of the masonry wall of the present invention, first, (a) the masonry wall 2 is drilled to penetrate through the through hole 21 (Fig. 9 (a)).

In the step (a), the through hole 21 is formed by drilling the masonry brick of the masonry wall 2.

A plurality of through holes 21 may be formed so as to form a lattice shape by being spaced apart from each other in a vertical or horizontal direction.

Next, (b) the anchor hole 11 is drilled by drilling the building structure 1 at the position corresponding to the through hole 21 (FIG. 9(b)).

An anchor hole 11 is drilled into the building structure 1 by inserting a drill through the through hole 21 formed in the masonry wall 2.

When an insulating material (not shown) is provided between the masonry wall 2 and the building structure 1, the anchor hole 11 is formed through the insulating material.

And (c) insert the fixing spring 4 into the anchor hole 11 (Fig. 9 (c)).

The fixed spring 4 passes through the through hole 21 of the masonry wall 2 and is inserted into the anchor hole 11.

Finally (d) through the through hole 21 of the masonry wall 2, the seismic reinforcement fixing pin 3 is passed through and inserted and fixed into the fixing spring 4 of the anchor hole 11 (Fig. 9). Of (d)).

The front end of the seismic reinforcement fixing pin 3 through the through hole 21 of the masonry wall 2 is inserted into the fixing spring 4 in the anchor hole 11 to be fixed.

Accordingly, since the fixing spring 4 is located between the outer circumferential surface of the seismic reinforcing fixing pin 3 and the inner circumferential surface of the anchor hole 11, the seismic reinforcing fixing pin 3 is placed in the anchor hole 11 by friction. Fix it firmly.

In steps (c) and (d), the fixing spring 4 and the fixing pin 3 for seismic reinforcement may be separately inserted into the anchor hole 11.

In some cases, after inserting a part of the front end of the seismic reinforcement fixing pin (3) in the rear of the fixing spring (4), the fixing spring (4) using the fixing pin (3) for seismic reinforcement is inserted into the anchor hole (11). After inserting into the seismic reinforcement fixing pin (3) can be continuously pushed in so that the seismic reinforcement fixing pin (3) is completely inserted into the fixing spring (4).

A screw 31 is formed on the front outer circumferential surface of the seismic reinforcement fixing pin 3, and in the step (d), the fixing spring of the anchor hole 11 by rotating the seismic reinforcement fixing pin 3 ( 4) It can be inserted and fixed inside.

When the screw 31 is formed on the front outer circumferential surface of the seismic reinforcement fixing pin 3, it is possible to easily enter the inside of the fixing spring 4 while rotating the seismic reinforcement fixing pin 3.

A friction fixing pipe 5 is provided outside the rear of the seismic reinforcing fixing pin 3, and in the step (d), the seismic reinforcing fixing pin 3 is masonry wall ( It may be fixed in the through hole 21 of 2).

A friction fixing pipe 5 is provided on the rear and outer side of the seismic reinforcing fixing pin 3, so that the rear end of the seismic reinforcing fixing pin 3 is not protruded to the outside of the masonry wall 2 It can be fixed in the through hole 21.

1: building structure
11: Anchor hole
2: masonry wall
21: through hole
3: Seismic reinforcement fixing pin
31: screw
32: tool insertion groove
33: stepped part
34: enlarged neck
4: fixed spring
5: friction fixing tube
51: locking ring
52: incision groove

Claims (8)

It is to reinforce the masonry wall (2) previously constructed on the outside of the building structure (1), and is installed through the through hole (21) formed in the masonry wall (2). It is inserted into the anchor hole 11 formed in, the other end is a seismic reinforcement fixing pin 3 fixed to the through hole 21 of the masonry wall (2); And it is inserted into the inside of the anchor hole 11 and is provided between the inner circumferential surface of the anchor hole 11 and the outer circumferential surface of the seismic reinforcement fixing pin 3 to insert the seismic reinforcement fixing pin 3 inside the anchor hole 11 Fixed spring (4) fixed to the; It relates to a masonry wall seismic reinforcement construction method using a masonry wall seismic reinforcement structure,
(a) piercing the masonry wall (2) to form a through hole (21) through;
(b) drilling the anchor hole 11 by drilling the building structure 1 at the position corresponding to the through hole 21;
(c) inserting a fixing spring (4) into the anchor hole (11); And
(d) penetrating the seismic reinforcement fixing pin (3) through the through hole (21) of the masonry wall (2) and inserting and fixing it into the fixing spring (4) of the anchor hole (11); Masonry wall seismic reinforcement construction method, characterized in that consisting of.
In claim 1,
A screw 31 is formed on the front outer circumferential surface of the seismic reinforcing fixing pin 3,
In the step (d), the seismic reinforcement fixing pin (3) is inserted and fixed into the fixing spring (4) of the anchor hole (11) by rotation.
In claim 1,
A friction fixing pipe 5 is provided on the rear outside of the seismic reinforcement fixing pin 3,
In the step (d), the seismic reinforcement fixing pin (3) is fixed in the through hole (21) of the masonry wall (2) by the friction fixing pipe (5).
In paragraph 3,
The friction fixing pipe (5) is a masonry wall seismic reinforcement construction method, characterized in that the tapered so that the diameter of the outer circumferential surface decreases toward the front.
In paragraph 3,
The rear of the seismic reinforcing fixing pin (3) is formed with a tapered expansion portion (34) so as to increase in diameter toward the rear, and a plurality of incision grooves (52) cut in the longitudinal direction at the rear of the friction fixing pipe (5). ) The masonry wall seismic reinforcement construction method, characterized in that formed. delete delete delete

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