KR102442142B1 - Seismic retrofit method of masonry wall - Google Patents

Abstract

The present invention relates to a seismic retrofit method of a masonry wall, which can insert a control pipe into an anchor hole formed in a building structure and insert an anchor bolt so that front and rear ends thereof are provided inside the control pipe and inside a through hole of the masonry wall, respectively, to accurately maintain the construction depth of the anchor bolt in a simple manner, thereby securing uniform quality. The seismic retrofit method for reinforcing a masonry wall constructed to be spaced apart from the exterior of a building structure comprises the steps of: (a) forming a through hole by drilling a reinforcement position of a masonry wall; (b) forming an anchor hole by drilling afront surface of a structure at a position corresponding to the through hole; (c) installing a control pipe, which has a cutout formed in the front accommodated in the anchor hole in a longitudinal direction and has a plurality of nodal grooves formed on the outer circumferential surface, through the through hole so that the front is inserted into the anchor hole to bring the front end into close contact with an end of the anchor hole, and the rear is located in the through hole; (d) injecting the front section of the inside of the control pipe with an anchor liquid; (e) inserting an anchor bolt into the control pipe through the through hole so that a front end of the anchor bolt is provided inside the control pipe and the rear end protrudes than the control pipe, wherein the rear end is located on a side inward of the outer surface of the masonry wall by a depth; and (f) filling the through hole with mortar to close the through hole.

Description

Seismic retrofit method of masonry wall

According to the present invention, after inserting the control pipe into the anchor hole formed in the building structure, the anchor bolt is inserted so that the front end and the rear end are provided in the inside of the control pipe and the through hole of the masonry wall, respectively, so that the construction depth of the anchor bolt is accurately measured in a simple way. It is about the seismic reinforcement method of the masonry wall that can be maintained to ensure uniform quality.

In recent years, as the frequency and intensity of earthquakes increase in Korea, the magnitude of damage to buildings due to earthquakes is increasing. In particular, during the Pohang earthquake in 2017, there were many accidents where the exterior stucco bricks fell off.

In the event of an earthquake, the obligations for seismic design of non-structural materials that could threaten human safety due to overturning or falling off in the event of an earthquake were stipulated in the Act, and procedures for checking whether the relevant seismic design was implemented or not were prepared.

Specifically, in KDS 41 17 "Seismic Design Standards for Buildings", it is compulsory to design seismic-resistance for exterior stucco bricks.

However, most of the conventional non-reinforced masonry buildings were built before the introduction of seismic design, and they are vulnerable to earthquakes and are often outdated. In addition, the existing masonry building is constructed by stacking stucco bricks on the outside of a reinforced concrete building structure to be spaced apart from the building structure, but by arranging an insulating material in the space between them. However, since these stucco bricks are 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, a through hole 11 is formed in the concrete wall 1 by penetrating the masonry wall 2, and an epoxy resin is filled in the through hole 11, and then an anchor bolt 4 is inserted and fixed to the front masonry wall. A technology for fixing (2) to the concrete wall (1) has been developed (FIG. 1, Patent Registration No. 10-0922386).

In the above registration technique, an epoxy resin is injected into the through hole in advance before the construction of the anchor bolt. However, since the masonry wall and the concrete wall are spaced apart from each other, it is not easy to inject the epoxy resin into the through hole of the concrete wall located inside. In addition, it is difficult to check whether the epoxy resin is properly filled, so there is a limit to securing the construction quality of the anchor bolt.

To improve this problem, in Patent Registration No. 10-1851646, a through hole and a through hole are formed in the outer wall and the masonry wall, respectively, and the anchor sleeve is first installed inside the through hole through the through hole, and then the anchor bolt is inserted into the anchor sleeve. .

However, in the above registration technique, since the support washer part at the rear end of the anchor bolt is exposed to the outside of the masonry wall, there is a risk of corrosion of the support washer part and is a factor impairing the aesthetics of the masonry wall. In addition, when the support washer part at the rear end of the anchor bolt is cut and used, it is difficult to adjust the construction depth of the anchor bolt when a construction error occurs depending on the drilling depth of the through hole, the smoothness of the outer wall, the thickness difference of the insulating material, etc.

In order to solve the above problems, the present invention provides a masonry that is easy to construct and accurately maintains the construction depth of the anchor bolt in reinforcing the masonry wall constructed on the outside of the building structure with anchor bolts to ensure uniform quality. To provide a wall seismic reinforcement method.

The present invention according to a preferred embodiment is for reinforcing a masonry wall spaced apart from the outside of a building structure, comprising the steps of: (a) drilling a reinforcing position of the masonry wall to form a through hole; (b) forming an anchor hole by perforating the front surface of the structure at a position corresponding to the through hole; (c) the front end of the anchor hole is inserted into the front end of the anchor hole through the through hole through the through hole of the adjustment tube in which a longitudinal cutout is formed in the front to be accommodated in the anchor hole, and a plurality of knurled grooves are formed on the outer circumferential surface. and installing the rear side to be located in the through hole; (d) injecting an anchor solution into the inner front section of the control tube; (e) inserting an anchor bolt into the inside of the control tube through the through hole, the front end of the anchor bolt is provided inside the control tube, the rear end protrudes from the control tube, and the rear end is inside the outer surface of the masonry wall by a certain depth Installing to be located in the; and (f) filling the through-hole with mortar to close the through-hole; It provides a masonry wall earthquake-resistant reinforcement method, characterized in that it consists of.

In the present invention according to another preferred embodiment, in the step (e), after the anchor bolt is inserted, the anchor solution is injected into the through hole so that the rear of the adjusting tube and the area where the anchor bolt protrudes from the adjusting tube are located inside the through hole. It provides a masonry wall earthquake-resistant reinforcement method, characterized in that it is fixed.

In the present invention according to another preferred embodiment, in step (c), the outer diameter is larger than the inner diameter of the adjusting tube and protruding from the front end of the rod-shaped body portion and the body portion smaller than the inner diameter of the through hole, the outer diameter is smaller than the inner diameter of the adjusting tube Using a tool for adjustment tube composed of an insertion part, after inserting the insertion part of the tool for adjustment tube into the rear end of the adjustment tube, the adjustment tube is inserted into the anchor hole by pressing the tool for the adjustment tube. do.

In the present invention according to another preferred embodiment, the step (e) comprises a rod-shaped body portion having an outer diameter greater than the inner diameter of the through hole and a pressing portion having an outer diameter smaller than the inner diameter of the through hole to protrude from the front end of the main body. It provides an earthquake-resistant reinforcement method for a masonry wall, characterized in that the anchor bolt is inserted to a certain depth by pressing the rear end of the anchor bolt with the pressing part of the anchor bolt tool.

The present invention according to another preferred embodiment provides a masonry wall earthquake-resistant reinforcement method, characterized in that a vertical groove is formed in the longitudinal direction of the anchor bolt on the outer peripheral surface of the anchor bolt.

delete

The present invention according to another preferred embodiment provides a masonry wall seismic reinforcement construction method, characterized in that the pressure protrusion for pressing the anchor bolt is formed protruding from the inner circumferential surface of the control tube.

According to the present invention, after inserting the control pipe into the anchor hole formed in the building structure, the anchor bolt is inserted and fixed so that the front end and the rear end are provided inside the control pipe and inside the through hole of the masonry wall, respectively. It is possible to provide an earthquake-resistant reinforcement method for a masonry wall that can be easily supported and reinforced with anchor bolts.

In particular, since the control tube is continuously provided from the anchor hole of the spherical body to the through hole of the masonry wall, it is easy to inject the anchor solution into the control tube.

In addition, since the length of the entire anchor structure can be adjusted according to the overlapping length of the adjusting pipe and the anchor bolt, the engagement length of the anchor bolt and the masonry wall regardless of the drilling depth of the anchor hole, the distance between the structure and the masonry wall, the smoothness of the front surface of the structure, etc. can be kept constant.

In addition, when the anchor bolt is inserted into the control tube using an anchor bolt tool, the front end of the main body part of the anchor bolt tool is caught on the front of the masonry wall to accurately maintain the construction depth of the anchor bolt, so uniform quality can be secured. do.

1 is a cross-sectional view showing a conventional anchor reinforcement method.
2 to 7 is a view showing a step-by-step process for the present invention masonry wall seismic reinforcement construction method.
8 is a cross-sectional view showing a state in which the control tube and the anchor bolt are installed.
9 is a perspective view illustrating a coupling relationship between a tool for an adjustment tube and an adjustment tube.
10 is a perspective view showing the coupling relationship between the anchor bolt tool and the anchor bolt.
Fig. 11 is a cross-sectional view showing an anchor bolt installation state by means of an anchor bolt tool.
Fig. 12 is a perspective view showing a control tube;

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

2 to 7 are views showing the step-by-step process for the seismic reinforcement method of the masonry wall of the present invention. And Figure 8 is a cross-sectional view showing a state in which the adjustment tube and the anchor bolt are installed.

2 to 7, the present invention masonry wall seismic reinforcement method is for reinforcing the masonry wall 2 spaced apart from the outside of the building structure (1), (a) the masonry wall (2) forming a through hole 21 by drilling a reinforcing position of the (b) forming an anchor hole 11 by drilling the front surface of the structure 1 at a position corresponding to the through hole 21; (c) the front end is inserted into the anchor hole 11 through the through hole 21 so that the front end is in close contact with the end of the anchor hole 11, and the rear end is positioned within the through hole 21. ) to insert; (d) injecting an anchor solution (B) into the inner front section of the control tube (3); (e) the anchor bolt 4 is inserted into the adjustment tube 3 through the through hole 21 so that the front end of the anchor bolt 4 is provided inside the adjustment tube 3, and the rear end is the adjustment tube (3) protruding than, installing the rear end to be located inside a predetermined depth from the outer surface of the masonry wall (2); and (f) filling the through hole 21 with mortar (M) to close the through hole 21; It is characterized in that it is composed of

In the present invention, in reinforcing the masonry wall (2) spaced apart from the outside of the building structure (1) with the anchor bolt (4), the construction is easy and the construction depth of the anchor bolt (4) is accurately maintained to ensure uniform construction quality This is to provide a masonry wall seismic reinforcement method that can secure

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

On the front surface of the structure (1), a masonry wall (2) as a stucco wall is constructed to be spaced apart from the structure (1).

A heat insulating material 5 may be installed in the space between the structure 1 and the masonry wall 2 .

In the present invention, first (a) drilling a reinforcing position of the masonry wall 2 to form a through hole 21 (FIG. 2).

A plurality of reinforcing positions of the masonry wall 2 may be arranged to form a lattice shape vertically and horizontally.

Next, (b) the front surface of the structure 1 at a position corresponding to the through hole 21 is drilled to form an anchor hole 11 (FIG. 3).

In step (b), a tool such as a drill is inserted through the through hole 21 drilled in step (a) to form an anchor hole 11 perforated in the front surface of the building structure 1 .

When the heat insulating material 5 is provided between the masonry wall 2 and the structure 1 , the anchor hole 11 is formed through the heat insulating material 5 .

And (c) the front end is inserted into the anchor hole 11 through the through hole 21 so that the front end is in close contact with the end of the anchor hole 11, and the rear end is located in the through hole 21. 3) is inserted (Fig. 4).

That is, by inserting the control pipe 3 through the through hole 21 of the masonry wall 2 , the front end of the control pipe 3 is inserted into the anchor hole 11 .

The control tube 3 has a front end in close contact with the inner end of the anchor hole 11 , and a rear end positioned inside the through hole 21 .

The length of the control pipe 3 is formed to be shorter than the length from the anchor hole 11 to the through hole 21, so that the rear end of the control pipe 3 is spaced a predetermined distance from the outside front of the masonry wall 2 to the inside. to be provided in the designated location.

Then, (d) injecting the anchor solution (B) into the inner front section of the control tube (3) (FIG. 5).

In step (d), the anchor solution (B) is injected into the control tube (3) through the open rear end of the control tube (3).

As the anchor solution (B), an epoxy resin or the like may be used.

The control tube 3 is continuously provided from the anchor hole 11 of the structure 1 to the through hole 21 of the masonry wall 2 . Therefore, it is easy to inject the anchor liquid (B), and it is possible to prevent the anchor liquid (B) from leaking into the space between the masonry wall (2) and the structure (1).

And (e) by inserting the anchor bolt 4 into the inside of the control tube 3 through the through hole 21, the front end of the anchor bolt 4 is provided inside the control tube 3, and the rear end is adjusted It is installed so that it protrudes from the pipe 3, and the rear end is located inside the outer surface of the masonry wall 2 by a predetermined depth (FIG. 6).

In the step (e), the anchor bolt 4 is inserted into the control tube 3 .

At this time, the front end of the anchor bolt (4) is provided inside the control tube (3).

The rear end of the anchor bolt 4 protrudes to the outside of the control pipe 3 , and is located inside the outer surface of the masonry wall 2 by a predetermined depth.

As shown in FIG. 8 , between the anchor hole 11 and the through hole 21 , there is a first section L ₁ in which only the adjustment tube 3 is provided, the adjustment tube 3 and the anchor bolt 4 are provided. It can be divided into an overlapping second section (L ₂ ) and a third section (L ₃ ) in which only the anchor bolt 4 is provided.

The length of the entire anchor structure can be adjusted according to the overlapping length (length of L ₂ ) in which the adjusting tube 3 and the anchor bolt 4 overlap.

Accordingly, the engagement length of the anchor bolt 4 and the masonry wall 2 is adjusted regardless of the drilling depth of the anchor hole 11, the spacing between the structure 1 and the masonry wall 2, the smoothness of the front surface of the structure 1, etc. can be kept constant.

The rear end of the anchor bolt 4 does not protrude to the outside of the masonry wall 2 and is located inside a predetermined depth from the outer front surface of the masonry wall 2, so there is no fear of corrosion or damage to the aesthetics.

On the other hand, according to the insertion of the anchor bolt (4), a part of the anchor solution (B) filled in the adjustment tube (3) is introduced into the anchor hole (11) through the open front end of the adjustment tube (3) to the anchor hole ( 11) Fix the control tube (3) to the structure (1) by filling the inside.

In addition, the remaining part of the anchor solution (B) is filled around the anchor bolt (4) in the inside of the adjustment tube (3) to fix the front of the anchor bolt (4) with the adjustment tube (3).

The anchor solution (B) inside the control pipe (3) flows out to the rear end of the control pipe (3) by the insertion of the anchor bolt (4), and the rear of the anchor bolt (4) is fixed inside the through hole (21) .

Finally (f) the through-hole 21 is filled with mortar (M) to close the through-hole 21 (FIG. 7).

In a state where the rear end of the anchor bolt 4 is accommodated in the through hole 21 , the through hole 21 is filled with mortar (M) to close the through hole 21 . Accordingly, the anchor bolt 4 is not exposed to the front surface of the masonry wall 2, so there is no risk of corrosion, and the aesthetics is not impaired.

As shown in FIG. 8, in the step (e), after the anchor bolt 4 is inserted, the anchor solution B is injected into the through hole 21 to the rear of the control tube 3 and the anchor bolt ( 4) may allow the portion protruding from the control tube 3 to be fixed inside the through hole 21 .

In the present invention, the front of the control tube (3) is fixed inside the structure (1), the rear of the anchor bolt (4) is fixed inside the masonry wall (2). At this time, the masonry wall 2 is supported by the structure 1 by overlapping the control tube 3 and the anchor bolt 4 by a predetermined length and fixing it.

Here, in order to fix the anchor bolt 4 to the inside of the masonry wall 2 by the anchor liquid (B), in the step (d), the anchor liquid (B) is sufficiently filled in the inside of the control tube (3) and , by pressurization of the anchor bolt (4), the anchor solution (B) inside the control tube (3) can be introduced to the through hole (21) through the open rear of the control tube (3). However, since the material cost of the anchor solution (B) is high, the economical efficiency is lowered when the amount of the anchor solution (B) is increased.

Therefore, the anchor solution (B) injected into the control tube (3) in step (d) fixes the control tube (3) to the structure (1) and also adjusts the front end of the anchor bolt (4) to the control tube (3). ) Inject only the amount that is fixed inside.

And the anchor solution (B) for fixing the rear end of the anchor bolt (4) inside the through hole (21) can be separately injected through the through hole (21) after construction of the anchor bolt (4). Accordingly, it is possible to minimize the amount of the anchor solution (B) is economical.

9 is a perspective view illustrating a coupling relationship between a tool for an adjustment tube and an adjustment tube.

As shown in FIG. 9 , in step (c), the outer diameter of the control tube 3 is larger than the inner diameter of the control tube 3 and smaller than the inner diameter of the through hole 21, the rod-shaped body portion 61 and the body portion 61. Using the tool for the adjustment tube (6) which protrudes from the front end and is composed of an insertion portion (62) whose outer diameter is smaller than the inner diameter of the adjustment tube (3), the insertion portion (62) of the tool for adjustment tube (6) is inserted into the adjustment tube ( After inserting into the rear end of 3), the adjustment tube 3 may be inserted into the anchor hole 11 by pressing the tool 6 for the adjustment tube.

The control tube 3 must be completely inserted into the anchor hole 11 so that the front end is closely attached to the inner end of the anchor hole 11 (FIG. 4).

However, since the total length of the adjustment tube 3 is formed shorter than the length from the anchor hole 11 to the through hole 21 , it is not easy to push the adjustment tube 3 to the inner end of the anchor hole 11 . not.

Accordingly, the adjustment tube 3 may be inserted using the tool 6 for the adjustment tube.

The tool 6 for the adjustment tube is provided with an insertion part 62 protruding from the front end of the rod-shaped body part 61 .

The main body portion 61 of the tool 6 for the adjustment tube is formed to have an outer diameter smaller than the inner diameter of the through hole 21 , so that it is possible to enter the through hole 21 .

The insertion part 62 is formed to have an outer diameter smaller than the inner diameter of the adjustment tube 3 and can be inserted into the rear end of the adjustment tube 3 .

After inserting the insertion part 62 of the tool 6 for the adjustment tube into the rear end of the adjustment tube 3, press the tool 6 for the adjustment tube to push the adjustment tube 3 to the inner end of the anchor hole 11. can be put

A tool fixing portion 63 formed in a hexagonal cross section may be provided at the rear end of the body portion 61 of the tool for the adjustment tube 6 to be fixed to the electric drill.

Figure 10 is a perspective view showing the coupling relationship between the anchor bolt tool and the anchor bolt, Figure 11 is a cross-sectional view showing the installation state of the anchor bolt by the anchor bolt tool.

As shown in FIGS. 10 and 11 , in step (e), the outer diameter of the rod-shaped body portion 71 and the front end of the main body portion 71 are larger than the inner diameter of the through hole 21, and the outer diameter Using the anchor bolt tool 7 composed of a pressing portion 72 smaller than the inner diameter of the through hole 21, the rear end of the anchor bolt 4 as the pressing portion 72 of the anchor bolt tool 7 is used. By pressing the anchor bolt 4 can be inserted to a certain depth.

The anchor bolt 4 overlaps the control pipe 3 at a predetermined length in the front, and protrudes to the rear of the control pipe 3 at the front of the masonry wall 2, that is, at the entrance of the through hole 21. housed deep inside.

At this time, when the distance between the rear end of the anchor bolt 4 and the front surface of the masonry wall 2 is kept constant, sufficient anchoring force between the anchor bolt 4 and the masonry wall 2 can be secured.

Accordingly, the anchor bolt tool 7 can be used so that the anchor bolt 4 is installed at the correct position.

The anchor bolt tool 7 is provided with a pressing portion 72 protruding from the front end of the rod-shaped body portion 71 .

The body portion 71 of the anchor bolt tool 7 has an outer diameter larger than the inner diameter of the through hole 21 . Therefore, the main body 71 does not enter the through hole 21, but is caught on the front surface of the masonry wall 2 (FIG. 11).

The pressing part 72 is formed to have an outer diameter smaller than the inner diameter of the through hole 21 so that it is possible to enter the through hole 21 .

By pressing the rear end of the anchor bolt 4 with the pressing part 72 of the tool 7 for the anchor bolt, the anchor bolt 4 can be inserted into the adjustment tube 3 and the through hole 21 . When the anchor bolt 4 is inserted to a certain depth, the front end of the main body 71 of the anchor bolt tool 7 is caught on the front surface of the masonry wall 2 and does not advance any more. And the depth into which the anchor bolt 4 is inserted from the front surface of the masonry wall 2 is accurately maintained as long as the length of the pressing part 72 .

It is preferable that the length of the pressing part 72 is the same as the depth at which the rear end of the anchor bolt 4 is inserted from the front surface of the masonry wall 2 .

The anchor bolt 4 can be inserted into the control tube 3 by striking the anchor bolt tool 7 with a rubber hammer or rotating it with an electric drill.

A tool fixing part 73 formed in a hexagonal cross section may be provided at the rear end of the body part 71 of the tool 7 for anchor bolts to be fixed to an electric drill (FIG. 10).

As shown in FIG. 10 , a vertical groove 41 may be formed on the outer peripheral surface of the anchor bolt 4 in the longitudinal direction of the anchor bolt 4 .

In the present invention, the rear of the anchor bolt 4 is fixed inside the through hole 21 of the masonry wall 2 to support the masonry wall 2 .

Therefore, a vertical groove 41 can be formed at a predetermined depth along the longitudinal direction of the anchor bolt 4 on the outer circumferential surface of the anchor bolt 4 so that the anchor bolt 4 can be firmly fixed to the masonry wall 2 . have.

When the anchor solution (B) is sufficiently filled in the vertical groove (41), the anchor bolt (4) is more firmly fixed to the masonry wall (2).

The vertical groove 41 may be formed only on the rear side of the anchor bolt 4 , or may be formed over the front or the entire length of the anchor bolt 4 .

12 is a perspective view showing a control tube;

As shown in FIGS. 4 and 12 , a cut-out 31 is formed in the longitudinal direction of the adjustment tube 3 at the front of the adjustment tube 3 accommodated in the anchor hole 11 , and the adjustment tube A plurality of knurled grooves 32 may be formed on the outer peripheral surface of (3).

Adjustment tube (3) in front of the adjustment tube (3) so that the anchor liquid (B) injected into the adjustment tube (3) is discharged into the anchor hole (11) by pressurization of the anchor bolt (4) The cutout 31 may be formed along the longitudinal direction.

The anchor solution (B) is discharged to the outside of the control tube (3) through the cutout (31) by the pressure of the anchor bolt (4) to fill the inside of the anchor hole (11).

A plurality of knurled grooves 32 may be formed to be spaced apart from each other on the outer peripheral surface of the front side of the control pipe 3 in order to firmly fix the control pipe 3 to the inside of the anchor hole 11 .

As shown in FIG. 12 , a pressing protrusion 33 for pressing the anchor bolt 4 may protrude from the inner circumferential surface of the control tube 3 .

The anchor bolt 4 is disposed so that the front end is spaced apart from the inner end of the anchor hole 11 , and the rear end is spaced apart from the front of the masonry wall 2 to overlap the control tube 3 by a predetermined length.

At this time, the position of the anchor bolt 4 may be somewhat flexible until the anchor solution B is hardened.

Therefore, it is possible to protrude the pressing protrusion 33 to the inside of the control tube 3 so that the position of the anchor bolt 4 can be temporarily fixed until the anchor solution B is hardened. A plurality of the pressing protrusions 33 may be formed along the longitudinal direction of the control tube 3 , and are fixed by pressing the outer peripheral surface of the anchor bolt 4 .

1: Structure 11: Anchor hole
2: masonry wall 21: through hole
3: Adjuster 31: Incision
32: node groove 33: pressing protrusion
4: anchor bolt 41: vertical groove
5: Insulation material 6: Tool for adjusting pipe
61: body part 62: insertion part
63: tool fixing part 7: anchor bolt tool
71: body portion 72: pressurized portion
73: tool fixing part B: anchor solution
M: mortar

Claims (7)

It is for reinforcing the masonry wall (2) spaced apart from the outside of the building structure (1),
(a) drilling a reinforcing position of the masonry wall (2) to form a through hole (21);
(b) forming an anchor hole 11 by drilling the front surface of the structure 1 at a position corresponding to the through hole 21;
(c) a control pipe 3 having a cutout 31 formed in the longitudinal direction at the front accommodated in the interior of the anchor hole 11 and a plurality of knurled grooves 32 formed on the outer circumferential surface of the through hole ( 21) through which the front is inserted into the anchor hole 11 so that the front end is in close contact with the end of the anchor hole 11, and the rear is installed so that it is located in the through hole 21;
(d) injecting an anchor solution (B) into the inner front section of the control tube (3);
(e) the anchor bolt 4 is inserted into the adjustment tube 3 through the through hole 21 so that the front end of the anchor bolt 4 is provided inside the adjustment tube 3, and the rear end is the adjustment tube (3) protruding than, installing the rear end to be located inside a predetermined depth from the outer surface of the masonry wall (2); and
(f) filling the through hole 21 with mortar (M) to close the through hole 21; A masonry wall earthquake-resistant reinforcement method, characterized in that it consists of.
In claim 1,
In the step (e), after the anchor bolt 4 is inserted, the anchor solution B is injected into the through hole 21 so that the rear of the adjustment tube 3 and the anchor bolt 4 are connected to the adjustment tube 3 A seismic reinforcement method for a masonry wall, characterized in that the protruding portion is fixed inside the through hole (21).
In claim 1,
In the step (c), the outer diameter is adjusted by protruding from the front end of the rod-shaped body part 61 and the body part 61 whose outer diameter is larger than the inner diameter of the adjusting tube 3 and smaller than the inner diameter of the through hole 21 . After inserting the insertion part 62 of the adjustment tube tool 6 into the rear end of the adjustment tube 3 using the tool 6 for the adjustment tube composed of an insertion portion 62 smaller than the inner diameter of the tube 3 , Seismic reinforcement construction method for a masonry wall, characterized in that the adjustment tube (3) is inserted into the anchor hole (11) by pressing the tool (6) for the adjustment tube.
In claim 1,
In step (e), the outer diameter is larger than the inner diameter of the through hole 21, the rod-shaped body portion 71 and the body portion 71 to protrude from the front end of the pressure smaller than the inner diameter of the through hole (21) By using the anchor bolt tool 7 composed of the part 72, the rear end of the anchor bolt 4 is pressed with the pressing part 72 of the anchor bolt tool 7, and the anchor bolt 4 is moved to a certain depth. A masonry wall earthquake-resistant reinforcement method, characterized in that it is inserted into a
In claim 1,
A masonry wall earthquake-resistant reinforcement method, characterized in that a vertical groove (41) is formed in the longitudinal direction of the anchor bolt (4) on the outer peripheral surface of the anchor bolt (4).
delete In claim 1,
A masonry wall earthquake-resistant reinforcement method, characterized in that a pressing protrusion (33) for pressing the anchor bolt (4) is protruded from the inner circumferential surface of the control pipe (3).

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