KR102307873B1 - Masonry wall buffer device of pillars and construction method thereof - Google Patents

Abstract

The present invention relates to a masonry wall buffer device for preventing a short column effect generated in a building including a pillar and a masonry waist-high wall. The masonry wall buffer device capable of improving the ductility of a pillar according to the present invention comprises: a fixed plate installed on the pillar; a supporting plate installed on one end of the masonry waist-high wall spaced by a predetermined distance from the pillar and supporting the masonry waist-high wall; and an elastic member installed between the fixed plate and the supporting plate, capable of expanding and contracting in a horizontal direction and preventing the masonry waist-high wall from overturning. If the masonry wall buffer device capable of improving the ductility of a pillar according to an embodiment of the present invention is installed between a pillar and a masonry waist-high wall, an upper link member and a lower link member are expanded and contracted by the deformation or movement of the pillar, thereby preventing the short column effect of the pillar by the masonry waist-high wall when an earthquake occurs. In addition, according to the masonry wall buffer device capable of improving the ductility of a pillar according to an embodiment of the present invention, a pair of fixed arms of the fixed plate are fixed firmly to a pillar by the upper link member and the lower link member and a tension member, and a pair of supporting arms of the supporting plate are fixed firmly to a masonry waist-high wall, thereby preventing the masonry waist-high wall from overturning.

Description

Masonry wall buffer device of pillars and construction method thereof that can improve the ductility of pillars

The present invention relates to an earthquake-resistant structure of a building, and more particularly, a masonry wall shock absorber capable of improving the ductility of a column capable of improving the seismic performance of a building in which a masonry waist wall is installed between a column and a column, and a construction method thereof is about

In general, reinforced concrete structures such as apartment houses and schools are composed of moment-resisting frames made of beams and columns.

Buildings using moment-resisting frames use masonry walls using blocks or bricks when dividing internal spaces or installing external walls.

For example, in a school building, the spans between individual classrooms are completely filled with masonry walls (masonry filling walls), and only the lower part of the exterior walls are filled with masonry walls (masonry waist walls) for light and ventilation.

An example of a building including a masonry waist wall and a column is shown in FIG. 1 .

1 is a view showing a pillar and a masonry waist wall of a conventional building.

Referring to FIG. 1 , one end of the masonry waist wall 110 is in close contact with one side of the pillar 100 . A window seat 120 is installed on the upper end of the masonry waist wall 110 , and a window 130 is installed on the window seat 120 .

A building having such a structure can provide light and ventilation through the window 130 installed on the masonry waist wall 110 .

However, the masonry waist wall 110 installed between the pillars 100 and the pillars may constrain the horizontal movement of the pillars 100 when an earthquake occurs, thereby inducing shear destruction of the pillars 100 due to the short casting effect.

Therefore, in order to prevent shear destruction of the pillar 100 due to the short-cast effect, the masonry waist wall 110 should not be installed. However, since it is difficult to completely dismantle the masonry waist wall 110 due to the use of the building, even in the case of a building in which the masonry waist wall 110 is installed, shear destruction of the pillar 100 due to the short-cast effect is prevented and the earthquake-resistant performance of the building There is a need for a method that can satisfy

The present invention was devised in view of the above problems, and even in a building using a masonry waist wall, it is possible to improve the ductility ability of the column that can satisfy the earthquake-resistance performance of the building by preventing the shear destruction of the column due to the short column effect. It relates to a masonry wall shock absorber and its construction method.

The object of the present invention as described above is,

In the masonry wall shock absorber installed in a building including a pillar and a masonry waist wall,

a fixing plate installed on the pillar;

a support plate installed at one end of the masonry waist wall spaced apart from the pillar by a predetermined distance and supporting the masonry waist wall; and

A masonry wall shock absorber capable of improving the ductility of a pillar, comprising a; is installed between the fixed plate and the support plate, is stretchable in the horizontal direction, and prevents the masonry waist wall from being overturned. This can be achieved by providing

At this time, the elastic member, the upper link member formed of a two-section link; and a lower link member formed of a two-fold link and installed symmetrically with the upper link member under the upper link member.

In addition, the fixing plate includes an upper fixing bracket and a lower fixing bracket, the support plate includes an upper support bracket and a lower support bracket, and the upper link member is a first upper link; and a second upper link having one end rotatably connected to one end of the first upper link and the other end rotatably connected to the upper support bracket, wherein the lower link member has the other end connected to the lower fixing bracket. The first lower link is rotatably installed; and a second lower link having one end rotatably connected to one end of the first lower link and the other end rotatably connected to the lower support bracket.

In addition, the masonry wall shock absorber capable of improving the ductility of the column according to another embodiment of the present invention may further include a tension member installed in parallel with the column between the upper link member and the lower link member. .

The object of the present invention as described above is,

installing the masonry waist wall to be spaced apart from the pillar by a predetermined distance;

installing a fixing plate on the pillar;

installing a support plate at one end of the masonry waist wall facing the pillar;

installing an upper link member and a lower link member between the fixing plate and the masonry waist wall; and

Installing a tension member between the upper link member and the lower link member; can be achieved by providing a construction method of a masonry wall shock absorber capable of improving the ductility of the column, characterized in that it includes.

When the masonry wall shock absorber capable of improving the ductility of the column according to an embodiment of the present invention having the structure as described above is installed between the column and the masonry waist wall, the upper link member by deformation or movement of the column in the horizontal direction And since the lower link member expands and contracts, when an earthquake occurs, the effect of shortening the column by the masonry waist wall can be prevented.

In addition, according to the masonry wall shock absorber capable of improving the ductility of the column according to an embodiment of the present invention, a pair of fixed arms of the fixed plate are firmly fixed to the column by the upper link member, the lower link member, and the tension member. Since the pair of support arms of the support plate are firmly fixed to the masonry waist wall, it is possible to prevent the masonry waist wall from being overturned.

1 is a view showing a pillar and a masonry waist wall of a conventional building;
2 is a partial front view showing a part of a building in which a masonry wall shock absorber capable of improving the ductility of a column according to an embodiment of the present invention is installed between the column and the masonry waist wall;
3 is a partial plan view of a building in which a masonry wall shock absorber capable of improving the ductility of the column shown in FIG. 2 is installed;
4 is a partial cross-sectional view of a building in which a masonry wall shock absorber capable of improving the ductility of the column shown in FIG. 2 is installed;
5 is a perspective view showing a masonry wall shock absorber capable of improving the ductility of the column according to an embodiment of the present invention;
6 is a view showing another example of a fixing plate used in the masonry wall shock absorber that can improve the ductility of the column according to an embodiment of the present invention;
7A to 7C are views for explaining a construction method of a masonry wall shock absorber capable of improving the ductility of a column according to an embodiment of the present invention;

Hereinafter, embodiments of the masonry wall shock absorber capable of improving the ductility of the column according to the present invention and its construction method will be described in detail with reference to the accompanying drawings.

It should be understood that the embodiments described below are illustratively shown to help the understanding of the present invention, and the present invention may be implemented with various modifications different from the embodiments described herein. However, in the following description of the present invention, if it is determined that a detailed description of a related known function or component may unnecessarily obscure the gist of the present invention, the detailed description and specific illustration thereof will be omitted. In addition, the accompanying drawings are not drawn to scale in order to help understanding of the invention, but dimensions of some components may be exaggerated.

2 is a partial front view showing a part of a building in which a masonry wall shock absorber capable of improving the ductility of a column according to an embodiment of the present invention is installed between the column and the masonry waist wall. 3 is a partial plan view of a building in which a masonry wall shock absorber capable of improving the ductility of the column shown in FIG. 2 is installed, and FIG. 4 is a masonry wall shock absorber capable of improving the ductility of the column shown in FIG. 2 is installed. It is a partial cross-sectional view of a building. 5 is a perspective view illustrating a masonry wall shock absorber capable of improving the ductility of a column according to an embodiment of the present invention.

Hereinafter, the masonry wall shock absorber 1 capable of improving the ductility of the column according to an embodiment of the present invention will be described in detail with reference to FIGS. 2 to 5 .

2 to 4, the building in which the masonry wall shock absorber 1 capable of improving the ductility of the column according to an embodiment of the present invention is installed may include the column 100 and the masonry waist wall 110. can

The pillar 100 may be formed of a reinforced concrete structure. Although only one pillar 100 is shown in FIGS. 2 to 4 , a pillar may also be installed at the opposite end of the masonry waist wall 110 (not shown).

The masonry waist wall 110 is installed to be spaced apart from the pillar 100 by a predetermined distance. Specifically, one end of the masonry waist wall 110 is spaced apart from one side of the pillar 100 by a predetermined distance.

The masonry waist wall 110 may be formed by masonry. For example, the masonry waist wall 110 includes an inner masonry waist wall 111 facing the interior, an exterior masonry waist wall 112 facing the outdoors, and an inner masonry waist wall 111 and an external masonry waist wall 112 ) may include a heat insulator 113 installed between.

At the upper end of the masonry waist wall 110 , a window seat 120 may be installed. A window 130 may be installed on the upper surface of the window seat 120 .

Between the pillar 100 and one end of the masonry waist wall 110, it is possible to prevent the masonry waist wall 110 from being inverted in the front-rear direction, and when the pillar 100 is deformed or moved by a horizontal force when an earthquake occurs , a masonry wall shock absorber 1 that can be expanded or contracted according to the deformation or movement of the pillar 100 may be installed.

The masonry wall shock absorber 1 may include a fixed plate 10 , a support plate 20 , and a telescopic member 30 .

The fixing plate 10 may be installed on the pillar 100 . For example, the fixing plate 10 is fixed to the pillar 100 and may be formed to be deformed or moved integrally with the pillar 100 . The fixing plate 10 may be formed to have the same length as the height of the masonry waist wall 110 .

The support plate 20 may be installed at one end of the masonry waist wall 110 spaced apart from the pillar 100 by a predetermined distance so as to support the masonry waist wall 110 . The support plate 20 may be formed to have the same length as the height of the masonry waist wall 110 .

The elastic member 30 is installed between the fixed plate 10 and the support plate 20, and when the horizontal deformation or movement of the column 100 occurs due to an earthquake, it can be deformed or moved integrally with the column 100. formed to be In addition, the elastic member 30 is formed to support the masonry waist wall 110 to prevent the masonry waist wall 110 from being overturned.

3 and 5 , in the present embodiment, the fixing plate 10 is formed in an approximately 'C' shape. Specifically, the fixing plate 10 may include a pair of fixing arms 11 vertically protruding from both ends of the fixing plate 10 .

A pair of fixing arms 11 of the fixing plate 10 are inserted into a pair of fixing grooves 101 formed on one side of the pillar to fix the fixing plate 10 to the pillar. To this end, a pair of fixing grooves 101 having a shape and size corresponding to the pair of fixing arms 11 of the fixing plate 10 may be formed on one side of the pillar 100 .

In addition, when the pair of fixing arms 11 of the fixing plate 10 are inserted into the pair of fixing grooves 101 of the pillar, the force acting on the fixing plate 10 in the direction perpendicular to the pillar 100, that is, the masonry waist Resistance to forces attempting to overturn the wall 110 may be increased.

A fixing bracket may be provided on the front surface of the fixing plate 10 , that is, on the surface opposite to the surface from which the pair of fixing arms 11 protrude. One end of the elastic member 30 may be connected to the fixing bracket. The fixing bracket may include an upper fixing bracket 13 and a lower fixing bracket 15 provided to be spaced apart from each other by a predetermined distance in the vertical direction.

The fixing plate 10 and the fixing brackets 13 and 15 may be formed of a metal such as an iron plate.

The support plate 20 is formed in an approximately 'C' shape. Specifically, the support plate 20 may include a pair of support arms 21 vertically protruding from both ends of the support plate 20 . One end of the masonry waist wall 110 is inserted between the pair of support arms 21 of the support plate 20 .

To this end, the interval between the pair of support arms 21 may be formed to be the same as the thickness of the masonry waist wall 110 . Then, since one end of the masonry waist wall 110 is inserted in close contact between the pair of support arms 21 , the support plate 20 can be firmly coupled to one end of the masonry waist wall 110 . Accordingly, the support plate 20 having a pair of support arms 21 can prevent the masonry waist wall 110 from being overturned.

A support bracket may be provided on the front surface of the support plate 20 , that is, on the surface opposite to the surface from which the pair of support arms 21 protrude. The other end of the elastic member 30 may be connected to the support bracket. The support bracket may include an upper support bracket 23 and a lower support bracket 25 provided to be spaced apart by a predetermined distance in the vertical direction.

The support plate 20 may be formed of the same material as the fixing plate 10 . For example, the support plate 20 and the support brackets 23 and 25 may be formed of a metal such as an iron plate.

The elastic member 30 is installed between the support plate 20 and the fixed plate 10 , is stretchable in a horizontal direction, and is formed to prevent the masonry waist wall 110 from being overturned.

For example, the elastic member 30 may include an upper link member 40 and a lower link member 50 .

The upper link member 40 may be formed as a two-fold link including two links. Specifically, the upper link member 40 may include a first upper link 41 and a second upper link 42 . The first upper link 41 and the second upper link 42 may have the same shape, and one end of the first upper link 41 and the second upper link 42 may be rotatably connected to each other.

The first upper link 41 and the second upper link 42 are formed in a narrow bar shape with a long length. A through hole into which the rotation pin 43 can be inserted is formed at one end of each of the first upper link 41 and the second upper link 42 .

Accordingly, when the rotation pin 43 is inserted and coupled into the through hole formed at one end of the first upper link 41 and the through hole formed at one end of the second upper link 42 , the first upper link 41 and the second The upper links 42 may rotate relative to each other.

The other end of the first upper link 41 is rotatably connected to the upper fixing bracket 13 of the fixing plate 10 . The upper fixing bracket 13 has a through hole 13a (see FIG. 7B ) into which the fixing pin 44 can be inserted. Therefore, when the fixing pin 44 is inserted into the through hole formed at the other end of the first upper link 41 and the through hole 13a of the upper fixing bracket 13, the first upper link 41 is connected to the upper fixing bracket. It can be rotated about (13).

The other end of the second upper link 42 is rotatably connected to the upper support bracket 23 of the support plate 20 . The upper support bracket 23 is formed with a through hole 23a (see FIG. 7B ) into which the support pin 45 can be inserted. Therefore, when the support pin 45 is inserted into the through hole formed in the other end of the second upper link 42 and the through hole 23a of the upper support bracket 23, the second upper link 42 is connected to the upper support bracket. It can be rotated about (23).

The first upper link 41 and the second upper link 42 do not form a straight line, and may be installed to be convex toward the upper part, that is, the window seat 120 installed on the upper end of the masonry waist wall 110 . That is, the upper link member 40 may be installed in an approximately inverted V-shape.

In addition, the upper end of the upper link member 40 may be installed so as not to contact the window seat 120 . The distance between the upper end of the upper link member 40 and the window seat 120 may be determined so that the upper end of the upper link member 40 does not contact the window seat 120 when an earthquake occurs.

The lower link member 50 may have the same structure as the upper link member 40 and may be installed between the fixing plate 10 and the support plate 20 so as to be symmetrical with the upper link member 40 .

Specifically, the lower link member 50 may be formed as a two-fold link including two links. For example, the lower link member 50 may include a first lower link 51 and a second lower link 52 . The first lower link 51 and the second lower link 52 may have the same shape, and one end of the first lower link 51 and the second lower link 52 may be rotatably connected to each other.

The first lower link 51 and the second lower link 52 are formed in a narrow bar shape with a long length. A through hole into which the rotation pin 53 can be inserted is formed at one end of each of the first lower link 51 and the second lower link 52 .

Accordingly, when the rotation pin 53 is inserted and coupled into the through hole formed at one end of the first lower link 51 and the through hole formed at one end of the second lower link 52 , the first lower link 51 and the second The lower links 52 may rotate relative to each other.

The other end of the first lower link 51 is rotatably connected to the lower fixing bracket 15 of the fixing plate 10 . A through hole 15a (see FIG. 7b ) into which the fixing pin 54 can be inserted is formed in the lower fixing bracket 15 . Accordingly, when the fixing pin 54 is inserted into the through hole formed in the other end of the first lower link 51 and the through hole 15a of the lower fixing bracket 15, the first lower link 51 is the lower fixing bracket. It can be rotated about (15).

The other end of the second lower link 52 is rotatably connected to the lower support bracket 25 of the support plate 20 . The lower support bracket 25 is formed with a through hole 25a (see FIG. 7B ) into which the support pin 55 can be inserted. Therefore, when the support pin 55 is inserted into the through hole formed at the other end of the second lower link 52 and the through hole 25a of the lower support bracket 25, the second lower link 52 is connected to the lower support bracket. It can be rotated about (25).

The first lower link 51 and the second lower link 52 do not form a straight line, and may be installed to be convex toward the floor surface FL on which the masonry waist wall 110 is installed. That is, the lower link member 50 may be installed in a substantially V-shape.

In addition, the lower end of the lower link member 50 is installed so as not to contact the bottom surface (FL) on which the masonry waist wall 110 is installed. The distance between the lower end of the lower link member 50 and the floor surface FL may be determined so that the lower end of the lower link member 50 does not contact the floor surface FL when an earthquake occurs.

When the upper link member 40 and the lower link member 50 are installed between the fixing plate 10 installed on the pillar 100 and the support plate 20 installed on the masonry waist wall 110 as described above, an earthquake occurs Since the upper link member 40 and the lower link member 50 can expand and contract according to the horizontal deformation or movement of the pillar 100, the effect of shortening the pillar 100 by the masonry waist wall 110 can be prevented. have.

In addition, the fixed plate 10 is fixed to the pillar 100 by a pair of fixed arms 11 , and the support plate 20 is fixed to the masonry waist wall 110 by a pair of support arms 21 . , it is possible to prevent the masonry waist wall 110 from being overturned.

2 and 5 , the masonry wall shock absorber 1 may further include a tension member 60 installed between the upper link member 40 and the lower link member 50 .

The tension member 60 may be installed parallel to the pillar 100 . In other words, the tension member 60 may be installed substantially perpendicular to the floor surface FL on which the masonry waist wall 110 is installed.

The tension member 60 may be installed to apply a constant tensile force between the upper end of the upper link member 40 and the lower end of the lower link member 50 . When a predetermined tensile force is applied to the upper link member 40 and the lower link member 60 by installing the tension member 60 between the upper end of the upper link member 40 and the lower end of the lower link member 50, the fixed plate (10) and the support plate (20) can be firmly fixed to the pillar (100) and the masonry waist wall (110).

To this end, one end of the tension member 60 is connected to the rotation pin 43 connecting the first upper link 41 and the second upper link 42 , and the other end is connected to the first lower link 51 and the second upper link 42 . It may be connected to a rotation pin 53 connecting the lower link 52 . To this end, pin holes into which the rotation pins 43 and 53 can be inserted may be formed at both ends of the tension member 60 .

The tension member 60 may be formed of a steel bar having rigidity, a steel wire, a steel plate having a narrow width and a long length, and the like.

As described above, when the masonry wall shock absorber 1 according to an embodiment of the present invention is installed between the pillar 100 and the masonry waist wall 110, the upper portion is caused by the horizontal deformation or movement of the pillar 100. Since the link member 40 and the lower link member 50 are stretched and contracted, when an earthquake occurs, it is possible to prevent the effect of shortening the column 100 by the masonry waist wall 110 .

In addition, a pair of fixed arms 11 of the fixed plate 10 by the upper link member 40 , the lower link member 50 , and the tension member 60 are firmly fixed to the post 100 , and the support plate 20 ) of the pair of support arms 21 are firmly fixed to the masonry waist wall 110, it is possible to prevent the masonry waist wall 110 from being overturned.

In the above, the case where the fixing plate 10 is fixed to one surface of the pillar 100 by a pair of fixing arms 11 has been described, but the fixing method of the fixing plate 10 is not limited thereto. The fixing plate may be fixed to the column by bolts or the like.

6 is a view showing another example of a fixing plate used in the masonry wall shock absorber capable of improving the ductility of the column according to an embodiment of the present invention.

Referring to FIG. 6 , the fixing plate 10 ′ is formed in a rectangular flat plate and may include a plurality of fixing holes 19 penetrating the fixing plate 10 ′. A plurality of fixing holes 19 may be formed so that anchor bolts or bolts 18 can be inserted.

Accordingly, a plurality of anchor bolts or a plurality of bolts 18 may be inserted into the plurality of fixing holes 19 to fix the fixing plate 10 ′ to one side of the pillar 100 . When the fixing plate 10 ′ is fixed to the pillar 100 , when the pillar 100 is deformed or moved due to an earthquake, the fixing plate 10 ′ may be integrally deformed or moved together with the pillar 100 .

Fixing brackets 13 and 15 may be provided on the front surface of the fixing plate 10 ′, that is, on the surface opposite to the surface facing the pillar 100 . One end of the elastic member 30 may be connected to the fixing bracket. The fixing bracket may include an upper fixing bracket 13 and a lower fixing bracket 15 provided to be spaced apart by a predetermined distance in the vertical direction.

Hereinafter, a construction method of the masonry wall buffer 1 capable of improving the ductility of the column according to an embodiment of the present invention will be described in detail with reference to FIGS. 7A to 7C .

7A to 7C are views for explaining a construction method of a masonry wall shock absorber capable of improving the ductility of a column according to an embodiment of the present invention.

First, as shown in FIG. 7A , the masonry waist wall 110 is installed to be spaced apart from the pillar 100 by a predetermined distance. At this time, the distance between the pillar 100 and one end of the masonry waist wall 110 is determined so that the masonry wall shock absorber 1 can be installed.

Next, a pair of fixing grooves 101 (see FIG. 3 ) are formed on one surface of the pillar 100 to install the fixing plate 10 .

Next, as shown in FIG. 7b , a pair of fixing arms 11 of the fixing plate 10 are inserted into the pair of fixing grooves 101 of the pillar to install the fixing plate 10 on the pillar 100 .

Next, the support plate 20 is installed at one end of the masonry waist wall 110 facing the pillar 100 . At this time, as shown in FIG. 3 , one end of the masonry waist wall 110 is inserted between the pair of support arms 21 of the support plate 20 .

Next, as shown in FIG. 7C , an upper link member 40 and a lower link member 50 are installed between the fixing plate 10 and the masonry waist wall 110 .

Specifically, the first upper link 41 by inserting the fixing pin 44 into the through hole of the other end of the first upper link 41 of the upper link member 40 and the through hole 13a of the upper fixing bracket 13 . is installed to rotate with respect to the upper fixing bracket (13). On the other hand, by inserting the support pin 45 into the through hole of the other end of the second upper link 42 and the through hole 23a of the upper support bracket 23, the second upper link 42 is connected to the upper support bracket 23. installed to rotate with respect to

In addition, by inserting the fixing pin 54 into the through hole of the other end of the first lower link 51 of the lower link member 50 and the through hole 15a of the lower fixing bracket 15, the first lower link 51 is It is installed to rotate with respect to the lower fixing bracket (15). Meanwhile, by inserting the support pin 55 into the through hole of the other end of the second lower link 52 and the through hole 25a of the lower support bracket 25 , the second lower link 52 is connected to the lower support bracket 25 . installed to rotate with respect to

Next, a tension member 60 is installed between the upper link member 40 and the lower link member 50 . Specifically, the rotation pin 43 is formed in the through hole of one end of the first upper link 41 of the upper link member 40 , the through hole of one end of the second upper link 42 , and the pin hole of the tension member 60 . ) to connect. In addition, a through hole at one end of the first lower link 51 of the lower link member 50 , a through hole at one end of the second lower link 52 , and a rotation pin 53 in the pin hole of the tension member 60 . Insert and connect Then, the upper end of the upper link member 40 and the lower end of the lower link member 50 may be connected by the tension member 60 .

According to the masonry wall shock absorber 1 capable of improving the ductility ability of the pillar according to an embodiment of the present invention as described above, the pillar 100 by the short column effect in a building using the masonry waist wall 110 It is possible to satisfy the seismic performance of the building by preventing the shear failure of the building.

In addition, the masonry wall shock absorber 1 capable of improving the ductility of the column according to an embodiment of the present invention can prevent the masonry waist wall 110 from being overturned.

In the above, the present invention has been described by way of example. The terms used herein are for the purpose of description and should not be construed in a limiting sense. According to the above contents, the present invention can be variously modified or modified. Accordingly, unless otherwise stated, the present invention may be freely practiced within the scope of the claims.

One; masonry wall buffer 10; fixed plate
11; fixed arm 13; upper fixing bracket
15; lower fixing bracket 20; support plate
21; support arm 23; upper support bracket
25; lower support bracket 30; elastic member
40; upper link member 41; first top link
42; second upper link 43; rotating pin
50; lower link member 51; first sub link
52; second lower link 53; rotating pin
60; Tensile member 100; Pillar
110; masonry waist wall 120; window seat

Claims (5)

In the masonry wall shock absorber installed in a building including a pillar and a masonry waist wall,
a fixing plate installed on the pillar;
a support plate installed at one end of the masonry waist wall spaced apart from the pillar by a predetermined distance and supporting the masonry waist wall; and
It includes; a telescopic member installed between the fixed plate and the supporting plate, stretchable in a horizontal direction, and preventing the masonry waist wall from being overturned,
The elastic member,
an upper link member formed as a two-section link and installed so as not to contact the window seat of the building;
a lower link member formed of a two-section link and installed under the upper link member so as not to contact the floor surface of the building symmetrically with the upper link member; and
and a tension member installed parallel to the pillar between the upper link member and the lower link member.
The fixing plate includes an upper fixing bracket and a lower fixing bracket,
The support plate includes an upper support bracket and a lower support bracket,
The upper link member,
a first upper link having the other end rotatably installed on the upper fixing bracket; and
a second upper link having one end rotatably connected to one end of the first upper link and the other end rotatably connected to the upper support bracket;
The lower link member,
a first lower link having the other end rotatably installed on the lower fixing bracket; and
a second lower link having one end rotatably connected to one end of the first lower link and the other end rotatably connected to the lower support bracket;
When an earthquake occurs, the masonry wall shock absorber capable of improving the ductility of the column, characterized in that the upper link member and the lower link member expand and contract.

delete delete delete installing a masonry waist wall to be spaced apart from the pillars of the building by a certain distance;
installing a fixing plate on the pillar;
installing a support plate at one end of the masonry waist wall facing the pillar;
installing an upper link member and a lower link member between the fixing plate and the masonry waist wall; and
Including; installing a tension member between the upper link member and the lower link member;
The upper link member is formed as a two-section link and is installed so as not to contact the window seat of the building,
The lower link member is formed as a two-section link, and is installed under the upper link member so as not to contact the floor surface of the building symmetrically with the upper link member,
The fixing plate includes an upper fixing bracket and a lower fixing bracket,
The support plate includes an upper support bracket and a lower support bracket,
The upper link member,
a first upper link having the other end rotatably installed on the upper fixing bracket; and
a second upper link having one end rotatably connected to one end of the first upper link and the other end rotatably connected to the upper support bracket;
The lower link member,
a first lower link having the other end rotatably installed on the lower fixing bracket; and
a second lower link having one end rotatably connected to one end of the first lower link and the other end rotatably connected to the lower support bracket;
When an earthquake occurs, the construction method of the masonry wall shock absorber capable of improving the ductility of the column, characterized in that the upper link member and the lower link member expand and contract.

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