KR102274464B1 - Seismic retrofit structure of masonry wall using anchor pipe and construction method thereof - Google Patents

Abstract

The present invention relates to a seismic retrofit structure of a masonry wall using an anchor pipe, which can facilitate easier construction and ensure uniform construction quality by allowing an anchor bolt to press an adhesive filled in an anchor pipe so that the anchor pipe and an anchor hole are filled therewith when the anchor bolt is inserted into the anchor pipe of which front and rear parts are inserted and installed in the anchor hole of a structure and the through hole of a masonry wall, respectively, and a construction method thereof. The seismic retrofit structure of a masonry wall using an anchor pipe, which reinforces a masonry wall pre-constructed outside a building structure, comprises: an anchor pipe formed of pipe-shaped stainless steel with open front and rear parts, and passing through a through hole formed in the masonry wall so that the front part is inserted into an anchor hole formed in the front surface of the structure, and the rear part is located in the through hole; an anchor bolt inserted into the anchor pipe; and an adhesive filled in the entire inside of the anchor pipe and the anchor hole.

Description

Seismic retrofit structure of masonry wall using anchor pipe and construction method thereof

The present invention fills the inside of the anchor tube and the anchor hole by pressing the adhesive filled in the anchor bolt with the anchor bolt when inserting the anchor bolt into the anchor tube, in which the front and rear are inserted into the anchor hole of the structure and the through hole of the masonry wall, respectively. As such, it relates to an earthquake-resistant reinforcement structure for a masonry wall using an anchor pipe that is easy to construct and can ensure a uniform construction quality, and a construction method thereof.

In recent years, as the frequency and intensity of earthquakes increase in Korea, the scale of damage to buildings is also increasing. In particular, during the Pohang earthquake in 2017, many accidents occurred due to the fall of the external stucco bricks.

In the event of an earthquake, the laws stipulated the requirements for seismic design of non-structural materials that could threaten human safety due to overturning or falling off in the event of an earthquake, and the related seismic design implementation confirmation procedures were prepared.

Specifically, in KDS 41 17 "Seismic Design Standards for Buildings", it is compulsory to design the seismic resistance of external decorative bricks, etc.

However, most of the conventional non-reinforced masonry buildings were built before the introduction of seismic design, and are vulnerable to earthquakes and are often outdated.

In addition, the existing masonry building is constructed to be spaced apart from the building structure by stacking stucco bricks on the outside of the reinforced concrete building structure, but an insulating material is disposed in the space between them. However, in this case, since the stucco brick is structurally separated from the building structure, there is a risk of safety accidents due to the overturning, dropping or collapse of the stucco wall during an earthquake, so reinforcement is urgently needed.

Accordingly, the front masonry wall (2) by penetrating the masonry wall to form a through hole (11) in the concrete wall (1), filling the through hole (11) with an epoxy resin, and inserting and fixing the anchor bolt (4) A technology for fixing the to the concrete wall (1) has been developed (FIG. 1, Patent Registration No. 10-0922386).

In this prior art, it is necessary to inject an epoxy resin into the through hole before the anchor bolt construction, but it was not easy to inject the epoxy into the through hole of the concrete wall located inside the masonry wall and the concrete wall spaced apart. In addition, it is difficult to check whether the epoxy is properly filled, so there is a limit to securing the construction quality of the anchor bolt.

In order to solve the above problems, the present invention provides an earthquake-resistant reinforcement structure for a masonry wall using an anchor pipe that is easy to construct and can secure a uniform construction quality in reinforcing a masonry wall constructed outside a building structure with an anchor bolt, and It is intended to provide a construction method thereof.

The present invention according to a preferred embodiment is for reinforcing a masonry wall previously constructed on the outside of a building structure, which is formed of tubular stainless steel with an open front and back, penetrates a through hole formed in the masonry wall, and the front is the structure An anchor pipe inserted into the anchor hole formed in the front of the, and the rear is located in the through hole; An anchor bolt inserted into the inside of the anchor tube; and an adhesive filled in the entire inner length of the anchor tube and the anchor hole; Doedoe, the front outer circumferential surface of the anchor tube is provided from the front end of the anchor tube in a plurality of rows to be spaced apart from each other along the circumference of the anchor tube, the groove formed in the longitudinal direction of the anchor tube only within the anchor hole section of the structure, the groove portion A masonry wall seismic reinforcement structure using an anchor pipe, characterized in that the adhesive is filled in, and a first injection hole through which the adhesive filled in the anchor pipe is injected into the groove is formed at the end of the anchor hole entrance side of the groove part to provide.

The present invention according to another preferred embodiment is a masonry using an anchor pipe, characterized in that the head portion is formed at the end of the masonry wall side of the anchor bolt, and the head portion is formed at the end of the masonry wall side of the anchor tube. Provides an earthquake-resistant reinforcement structure for the wall.

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The present invention according to another preferred embodiment provides an earthquake-resistant reinforcement structure for a masonry wall using an anchor pipe, characterized in that a second injection hole is formed in the anchor pipe within the through-hole section of the masonry wall.

The present invention according to another preferred embodiment is a masonry wall seismic reinforcement structure using an anchor tube, characterized in that a cutout cut in the longitudinal direction of the anchor tube is formed on the front outer peripheral surface of the anchor tube within the anchor hole section of the structure. to provide.

The present invention according to another preferred embodiment provides an earthquake-resistant reinforcement structure for a masonry wall using an anchor pipe, characterized in that the front inner circumferential surface of the anchor pipe is provided with a pressurizing part having an enlarged thickness of the anchor pipe to the inside.

The present invention according to another preferred embodiment is for constructing a masonry wall seismic reinforcement structure using the anchor pipe, comprising the steps of: (a) drilling a reinforcing position of the masonry wall to form the through hole; (b) forming the anchor hole by perforating the front surface of the structure at a position corresponding to the through hole; (c) inserting the anchor tube so that the front is inserted into the anchor hole through the through hole, and the rear is located in the through hole; (d) injecting an adhesive into the inner front section of the anchor tube; and (e) inserting an anchor bolt into the anchor tube so that the adhesive fills the anchor hole inside, and a part of the adhesive is discharged to the rear end of the anchor tube; It provides a construction method of a masonry wall seismic reinforcement structure using an anchor pipe, characterized in that it comprises a.

In the present invention according to another preferred embodiment, a countersunk head-shaped head portion is formed at the end of the masonry wall side of the anchor bolt, and in the step (e), the anchor tube hits the head portion of the anchor bolt inserted into the anchor tube. It provides a construction method of a masonry wall seismic reinforcement structure using an anchor pipe, characterized in that the head portion is formed by expanding the end of the masonry wall side.

According to the present invention, there are the following effects.

First, in reinforcing the masonry wall constructed outside the building structure with anchor bolts, the anchor bolt is inserted into the anchor tube installed so that the front and rear are inserted into the anchor hole of the structure and the through hole of the masonry wall, respectively. It is possible to provide an earthquake-resistant reinforcement structure for a masonry wall using an anchor pipe that can easily fill the inside of an anchor pipe and an anchor hole by pressing an adhesive inside, and a construction method thereof.

Second, when inserting the anchor bolt into the anchor tube, it is possible to visually confirm that the adhesive inside the anchor tube is pushed by the anchor bolt and flows out of the anchor tube, so it is easy to check whether the adhesive inside the anchor tube is filled to secure the reliability of construction quality can do.

Third, since the anchor bolt and adhesive inside the anchor pipe constitute one seismic reinforcing member, not only the masonry wall is firmly fixed to the structure, but the entire seismic reinforcing member acts as a shear reinforcing material, effectively resisting lateral displacement.

1 is a cross-sectional view showing a conventional anchor reinforcement method applied to a masonry wall.
Figure 2 is a cross-sectional view showing a masonry wall seismic reinforcement structure using the anchor pipe of the present invention.
3 is a perspective view showing a coupling relationship between an anchor pipe and an anchor bolt;
4 is an enlarged cross-sectional view showing a head portion and an expanded tube portion.
Figure 5 is a cross-sectional view showing an anchor hole portion of the structure to which the present invention is applied.
Figure 6 is a perspective view showing an anchor pipe in which the first injection hole is formed.
7 is a perspective view showing an anchor tube in which a cutout is formed.
Fig. 8 is a cross-sectional view showing an anchor pipe in which a pressing part is formed.
Figure 9 is a cross-sectional view showing a step-by-step process for the construction method of the masonry wall seismic reinforcement structure using the present invention anchor pipe.
Fig. 10 is a cross-sectional view showing a process of forming a pipe expansion part;

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

Figure 2 is a cross-sectional view showing the seismic reinforcement structure of the masonry wall using the anchor tube of the present invention, Figure 3 is a perspective view showing the coupling relationship between the anchor tube and the anchor bolt.

As shown in Figs. 2 and 3, the masonry wall seismic reinforcement structure using the anchor pipe of the present invention is for reinforcing the masonry wall 2 that has been previously constructed on the outside of the building structure 1, and the front and rear pipes are open. The front is inserted into the anchor hole 11 formed on the front surface of the structure 1 through the through hole 21 formed in the masonry wall 2 and formed of stainless steel, and the rear is the through hole 21 ) located in the anchor tube (3); An anchor bolt (4) inserted into the inside of the anchor tube (3); and an adhesive (5) filled in the entire inner length of the anchor tube (3) and the anchor hole (11); It is characterized in that it is composed of

The present invention provides an earthquake-resistant masonry wall using an anchor pipe that is easy to construct and can secure a uniform construction quality in reinforcing the masonry wall 2 built outside the building structure 1 with an anchor bolt 4 An object of the present invention is to provide a reinforcing structure and a construction method thereof.

The structure (1) may be a reinforced concrete wall or a masonry wall (2).

A through hole 21 is formed in the masonry wall 2 spaced apart from the front surface of the structure 1 .

An anchor hole 11 is formed on the front surface of the structure 1 at a position corresponding to the through hole 21 .

The anchor pipe 3 is formed in a tubular shape with an open front and rear, and the front is inserted through the through hole 21 to be inserted into the anchor hole 11 , and the rear is installed to be located in the through hole 21 .

The anchor pipe 3 connects the structure 1 and the masonry wall 2 to serve as a passage for the adhesive 5 to be described later.

An anchor bolt 4 is inserted and installed in the anchor tube 3 , and an adhesive 5 is injected into the anchor tube 3 .

The adhesive (5) is injected over the entire inner length of the anchor tube (3).

In addition, the adhesive 5 is injected into the anchor hole 11 through the open front end of the anchor tube 3 to fix the anchor tube 3 in the anchor hole 11 .

The adhesive 5 may be an epoxy resin or the like.

Since the anchor pipe 3 extends to the front of the masonry wall 2 , it is easy to inject the adhesive 5 to the anchor hole 11 side through the anchor pipe 3 .

In addition, when the anchor bolt (4) is inserted into the anchor tube (3), the adhesive (5) injected into the anchor tube (3) is pushed by the anchor bolt (4) and flows out to the outer end of the anchor tube (3) can be visually confirmed. Accordingly, since it is possible to confirm that the adhesive 5 is completely filled in the anchor tube 3 , it is possible to secure the reliability of the construction quality.

In addition, an anchor bolt 4 is provided as a core material in the anchor tube 3 , and an adhesive 5 is filled in the anchor tube 3 to constitute one earthquake-resistant reinforcing member.

Accordingly, it is possible to effectively resist lateral displacement between the masonry wall 2 and the structure 1 by firmly fixing the masonry wall 2 to the structure 1 and the entire seismic reinforcing member acting as a shear reinforcement.

The anchor pipe 3 and the anchor bolt 4 are preferably formed of a metal material having excellent strength and rigidity, and more preferably formed of stainless steel having excellent corrosion resistance and durability.

A protrusion may be formed on the outer peripheral surface of the anchor tube 3 in order to improve the adhesion of the anchor tube 3 itself.

The front end of the anchor tube 3 may be configured to be tapered so that the width becomes narrower toward the front so that the anchor tube 3 can be easily inserted into the through hole 21 and the anchor hole 11 .

The anchor bolt 4 may also be configured to have a tapered front end to facilitate insertion into the anchor tube 3 .

4 is an enlarged cross-sectional view showing a head portion and an expanded tube portion.

As shown in FIG. 4 , a head portion 41 is formed at the end of the anchor bolt 4 on the masonry wall 2 side, and the head portion at the end of the anchor tube 3 on the masonry wall 2 side. (41) can be configured such that the extended pipe portion 31 is formed.

In order to fix the masonry wall 2 to the anchor bolt 4 , the masonry wall 2 side end of the anchor bolt 4 , that is, the outer end, may be formed with a head portion 41 with an enlarged cross section.

The head part 41 is supported on the front surface of the masonry wall 2 to fix the masonry wall 2 with an anchor bolt 4 .

In addition, in the present invention, since the anchor pipe 3 and the anchor bolt 4 exert a supporting force together, the outer end of the anchor pipe 3 is also expanded in the same shape as the inner surface of the head 41. 31) can be formed so as to be in close contact with the front surface of the masonry wall (2).

The head portion 41 may be formed in a flat head shape, and the expanded tube portion 31 may be configured in a shape corresponding to the flat head shaped head portion 41 .

The anchor bolt 4 and the anchor pipe 3 are fixed inside the anchor hole 11 of the structure 1 by the adhesive 5, and the masonry wall 2 is formed by the head part 41 and the expansion pipe part 31 ) and can be fixed to the anchor bolt (4).

For the safety or aesthetics of the user, the outer surface of the head portion 41 is located inside the front surface of the masonry wall 2 so that the head portion 41 of the anchor bolt 4 does not protrude to the outside of the masonry wall 2 . It is preferable to form it so that it is located.

In this case, the caulking compound 7 is installed on the outer surface of the head part 41 to keep the front surface of the masonry wall 2 smooth and to prevent the exposure of the head part 41 and the anchor pipe 3 . have.

As shown in FIG. 4 , a second injection hole 34 may be formed in the anchor pipe 3 within the section of the through hole 21 of the masonry wall 2 .

In order to support the masonry wall 2 by fixing the anchor bolt 4 more firmly to the masonry wall 2, an adhesive 5 is formed between the through hole 21 of the masonry wall 2 and the anchor pipe 3 ) is preferred.

Since the anchor hole 11 formed in the structure 1 is closed at one end, it is easy to fill the adhesive 5 through the open end of the anchor tube 3 . On the other hand, the through hole 21 of the masonry wall 2 is open front and back, so it is not easy to separately fill the adhesive 5 .

Therefore, by forming the second injection hole 34 in the anchor tube 3 within the section of the through hole 21 of the masonry wall 2, the adhesive 5 filled in the anchor tube 3 is applied to the anchor bolt ( 4) Upon insertion, it may flow out of the anchor tube 3 through the second injection hole 34 and be filled in the through hole 21 .

Since the inlet side of the through hole 21 is closed by the head portion 41 and the expansion tube 31 of the anchor bolt 4 and the inside of the through hole 21 is open, the closed chamber inside the through hole 21 . For one filling, the second injection hole 34 is preferably formed on the inlet side of the through hole 21 .

5 is a cross-sectional view showing an anchor hole portion of the structure to which the present invention is applied.

3 and 5, the groove portion 32 in the longitudinal direction of the anchor tube 3 is recessed in the front outer peripheral surface of the anchor tube 3 only within the section of the anchor hole 11 of the structure 1 can be formed.

When the anchor bolt (4) is inserted, the adhesive (5) filled in the anchor tube (3) is pushed to the outside to fill the inside of the anchor hole (11). In this case, when the adhesive 5 flows out of the anchor hole 11, the space between the anchor tube 3 and the anchor hole 11 may not be tightly filled, so the inner diameter of the anchor hole 11 and the anchor tube ( 3) It is desirable to minimize the gap between the exteriors.

However, when the space between the anchor pipe 3 and the anchor hole 11 is not sufficient as described above, it is difficult to fill the space with the adhesive 5 .

Therefore, when the groove portion 32 recessed to a predetermined depth inside the anchor tube 3 is formed only within the section of the anchor hole 11 , the adhesive 5 leaked out of the anchor tube 3 is removed from the groove portion 32 . By filling the anchor tube (3) can be firmly fixed in the anchor hole (11).

That is, by forming the groove portion 32 only within the section of the anchor hole 11 , the adhesive 5 is allowed to flow to the outside of the anchor tube 3 , while at the entrance of the anchor hole 11 , the anchor tube 3 is outside the anchor hole 11 . Since there is no play, it is possible to minimize leakage of the adhesive 5 to the outside of the anchor hole 11 .

The groove portion 32 may be provided from the front end of the anchor tube 3 in a plurality of rows spaced apart from each other along the circumference of the anchor tube 3 .

In other words, the groove portion 32 protrudes into the anchor tube 3 .

At this time, by forming the diameter of the anchor bolt (4) somewhat larger than the inner diameter of the protrusion of the anchor tube (3), the anchor bolt (4) can be configured to be press-fitted in the anchor tube (3).

In this case, the outer circumferential surface of the anchor bolt 4 is caught by the inner protrusion caused by the groove portion 32 of the anchor tube 3 and is firmly fixed.

In addition, when the anchor bolt 4 is inserted, the anchor tube 3 is deformed to the outside while the anchor bolt 4 presses the groove portion 32 of the anchor tube 3, so the anchor tube 3 and the anchor hole 11 This adhesion can be more firmly fixed.

A thread is formed on the outer circumferential surface of the anchor bolt 4 so that the anchor bolt 4 can more easily enter the inside of the anchor tube 3 and at the same time increase the adhesive force between the anchor bolt 4 and the adhesive 5 . It is possible.

A tool insertion groove is formed in the head part 41 for rotation penetration of the anchor bolt 4, and the anchor bolt 4 is rotated in the anchor tube 3 by coupling the tool to the tool insertion groove. ) can be inserted.

Figure 6 is a perspective view showing an anchor pipe in which the first injection hole is formed.

As shown in FIG. 6 , at the end of the anchor hole 11 inlet side of the groove portion 32 , the adhesive 5 filled in the anchor tube 3 is injected into the groove portion 32 , a first injection hole ( 33) may be formed through.

In order to smoothly inject the adhesive 5 filled in the anchor tube 3 into the groove portion 32 of the outer peripheral surface of the anchor tube 3, the first injection is performed at the end of the anchor hole 11 inlet side of the groove portion 32. A ball 33 may be formed.

Accordingly, since the adhesive 5 is injected from both sides of the groove 32 through the open end of the anchor tube 3 and the first injection hole 33 , the adhesive 5 is tightly filled in the anchor hole 11 . It is possible.

7 is a perspective view showing an anchor tube in which a cutout is formed.

As shown in FIG. 7 , a cutout 35 cut in the longitudinal direction of the anchor tube 3 is formed on the front outer peripheral surface of the anchor tube 3 within the anchor hole 11 section of the structure 1 . can be

In order to stably fix the anchor tube 3 to the inside of the anchor hole 11 by the adhesive 5 , a cutout 35 may be formed instead of the groove 32 .

The cutout 35 is formed in the anchor hole 11 section, and the adhesive 5 flows out of the anchor tube 3 through the cutout 35 to be filled in the anchor hole 11 . .

The cutouts 35 may be provided in a plurality of rows to be spaced apart along the circumference of the anchor tube 3 .

8 is a cross-sectional view showing an anchor tube in which a pressing part is formed.

As shown in Figure 8, the front inner peripheral surface of the anchor tube (3) may be provided with a pressing portion (36) with an enlarged thickness of the anchor tube (3) to the inside.

The anchor tube (3) may be provided with a pressing portion (36) formed thick by reducing the inner diameter of the front portion.

Accordingly, when the anchor bolt 4 is inserted into the anchor tube 3 and the anchor bolt 4 enters the section of the pressing part 36, the front of the anchor tube 3 opens outward and the anchor hole 11 It can be firmly fixed within.

9 is a cross-sectional view showing a step-by-step process for the construction method of the masonry wall seismic reinforcement structure using the anchor pipe of the present invention.

The construction method of the masonry wall seismic reinforcement structure using the anchor pipe of the present invention relates to a method for constructing the masonry wall seismic reinforcement structure using the anchor pipe of the present invention described above with reference to FIGS. 2 to 8 .

In the construction method of the masonry wall seismic reinforcement structure using the anchor pipe of the present invention, first (a) drilling a reinforcement position of the masonry wall 2 to form the through hole 21 (FIG. 9 (a)).

In step (a), the through hole 21 is formed by drilling the masonry wall 2 according to the reinforcing position of the masonry wall 2 .

The reinforcing position may be a plurality of places so as to form a grid shape vertically, horizontally and vertically.

Next, (b) the front surface of the structure 1 at a position corresponding to the through hole 21 is drilled to form the anchor hole 11 (FIG. 9 (b)).

By inserting a drill through the through-hole 21 drilled in step (a), the anchor hole 11 is drilled to a predetermined depth in the front surface of the building structure 1 .

When the heat insulating material 6 is provided between the masonry wall 2 and the structure 1, the anchor hole 11 is formed through the heat insulating material 6 .

And (c) the front is inserted into the anchor hole 11 through the through hole 21, and the rear is inserted into the anchor tube 3 to be located in the through hole 21 (Fig. 9 (c)) ).

That is, the anchor pipe 3 is inserted through the through hole 21 of the masonry wall 2 so that the front end of the anchor pipe 3 is positioned inside the anchor hole 11 .

At this time, in consideration of the construction error of the masonry wall 2 and the construction error of the depth of the anchor hole 11, the anchor pipe 3 may be formed longer than the required construction length. After the anchor pipe (3) is constructed, the portion protruding to the outside of the masonry wall (2) can be cut on site.

Then, (d) the adhesive (5) is injected into the inner front section of the anchor tube (3) (FIG. 9 (d)).

In step (d), the adhesive 5 is injected into the anchor tube 3 .

At this time, the amount of the injected adhesive 5 is adjusted in consideration of the volume of the anchor bolt 4 to be inserted into the anchor tube 3 .

Since the anchor tube 3 is continuously formed from the anchor hole 11 of the structure 1 to the through hole 21 of the masonry wall 2, it is easy to inject the adhesive 5 into the anchor tube 3 . In addition, it is possible to prevent the adhesive 5 from leaking into the space between the masonry wall 2 and the structure 1 .

Finally (e) by inserting the anchor bolt 4 into the inside of the anchor pipe 3, the adhesive 5 fills the inside of the anchor hole 11, while the adhesive 5 is part of the rear end of the anchor pipe 3 to be discharged (FIG. 9(e)).

According to the insertion of the anchor bolt (4), a part of the adhesive (5) filled in the anchor tube (3) is filled in the anchor hole (11) through the open front end of the anchor tube (3), and the adhesive (5) The other part is moved to the masonry wall (2) side through the anchor tube (3) to fill the space between the anchor tube (3) and the anchor bolt (4) over the entire length of the anchor tube (3).

The operator can confirm that the adhesive 5 is tightly filled by visually observing the leakage of the adhesive 5 toward the rear end of the anchor pipe 3 , that is, the masonry wall 2 side end side.

10 is a cross-sectional view illustrating a process of forming a pipe expansion part.

A countersunk head-shaped head part 41 is formed at the end of the masonry wall 2 side of the anchor bolt 4, and the anchor bolt 4 inserted into the anchor tube 3 in the step (e). By hitting the head portion 41 of the anchor tube 3 to expand the end of the masonry wall 2 side, the head portion 41 can be configured so that the expansion tube portion 31 is formed.

The expansion pipe part 31 formed at the outer end of the anchor pipe 3 to accommodate the head part 41 of the anchor bolt 4 may be formed in advance when the anchor pipe 3 is manufactured.

However, in the case of cutting and using the anchor pipe 3 on site or cutting the anchor pipe 3 protruding to the outside of the masonry wall 2 after the anchor pipe 3 is constructed, it is difficult to form the expansion pipe 31 in advance.

Therefore, the lower surface of the head part 41 of the anchor bolt 4 is formed in a slanted countersunk shape, and the anchor bolt is installed in the anchor pipe 3 installed as shown in FIG. 10 (a) as shown in FIG. 10 (b). After inserting (4), by hitting the anchor bolt 4, the head portion 41 of the anchor bolt 4 presses the end of the anchor tube 3, so that the end of the anchor tube 3 is widened and the tube expansion part 31 ) can be formed.

1: Structure 11: Anchor hole
2: masonry wall 21: through hole
3: Anchor pipe 31: Expansion part
32: groove 33: first injection hole
34: second injection hole 35: cutout
36: pressing part 4: anchor bolt
41: head part 5: adhesive
6: Insulation material 7: Caulking compound

Claims (9)

It is for reinforcing the masonry wall (2) previously constructed on the outside of the building structure (1),
The front and rear are formed of open tubular stainless steel and penetrate through the through hole 21 formed in the masonry wall 2, and the front is inserted into the anchor hole 11 formed on the front of the structure 1, and the rear is An anchor pipe (3) located in the through hole (21);
An anchor bolt (4) inserted into the inside of the anchor tube (3); and
Adhesive (5) filled in the inside of the anchor hole (11) and the entire length of the inner length of the anchor tube (3); is composed of
On the outer peripheral surface of the front of the anchor tube (3), a groove portion (32) recessed in the longitudinal direction of the anchor tube (3) is formed only within the section of the anchor hole (11) of the structure (1) along the circumference of the anchor tube (3). It is provided from the front end of the anchor tube 3 in a plurality of rows spaced apart from each other, the groove portion 32 is filled with the adhesive 5, and the anchor hole 11 entrance side end of the groove portion 32 has an anchor tube (3) A masonry wall seismic reinforcement structure using an anchor pipe, characterized in that the first injection hole (33) through which the adhesive (5) filled therein is injected into the groove (32) is formed.
In claim 1,
A head portion 41 is formed at the end of the anchor bolt 4 on the masonry wall 2 side, and the head portion 41 is hung at the end of the anchor tube 3 on the masonry wall 2 side. 31) is a masonry wall seismic reinforcement structure using an anchor pipe, characterized in that it is formed.
delete delete In claim 1,
A masonry wall seismic reinforcement structure using an anchor pipe, characterized in that a second injection hole (34) is formed in the anchor pipe (3) within the section of the through hole (21) of the masonry wall (2).
In claim 1,
An anchor tube, characterized in that the incision 35 cut in the longitudinal direction of the anchor tube (3) is formed on the front outer peripheral surface of the anchor tube (3) within the section of the anchor hole (11) of the structure (1) The seismic reinforcement structure of the masonry wall using
In claim 6,
A masonry wall earthquake-resistant reinforcement structure using an anchor pipe, characterized in that a pressing part 36 having an enlarged thickness of the anchor pipe 3 is provided on the front inner circumferential surface of the anchor pipe (3).
It is for constructing an earthquake-resistant reinforcement structure of a masonry wall using the anchor pipe according to claim 1,
(a) drilling a reinforcement position of the masonry wall (2) to form the through hole (21);
(b) forming the anchor hole 11 by drilling the front surface of the structure 1 at a position corresponding to the through hole 21;
(c) inserting the anchor tube 3 through the through hole 21 so that the front is inserted into the anchor hole 11 and the rear is located in the through hole 21;
(d) injecting an adhesive (5) into the inner front section of the anchor tube (3); and
(e) Inserting the anchor bolt 4 into the anchor tube 3 so that the adhesive 5 fills the anchor hole 11, while a part of the adhesive 5 is discharged to the rear end of the anchor tube 3 to become; Construction method of a masonry wall seismic reinforcement structure using an anchor pipe, characterized in that it comprises a.
In claim 8,
At the end of the masonry wall (2) side of the anchor bolt (4), a countersunk head-shaped head part (41) is formed,
In step (e), the head portion 41 of the anchor bolt 4 inserted into the anchor tube 3 is hit to enlarge the end of the masonry wall 2 side of the anchor tube 3 to the head portion ( 41) A construction method of a masonry wall earthquake-resistant reinforcement structure using an anchor pipe, characterized in that the expanded pipe part 31 is formed.

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