KR102408782B1 - Seismic Reinforcing Apparatus For Bricks Wall and Constructing Method Using The Same - Google Patents

Abstract

According to an embodiment of the present invention, the seismic reinforcement device for a masonry wall is a space formed between the upper end of the masonry wall and the lower end of the slab, which is constructed by sequentially stacking bricks in the vertical space formed between the column and the ceiling slab. One or more first reinforcing frames installed along the longitudinal direction of the masonry wall, inclined upward with respect to the upper end of the masonry wall, and having a first through-hole penetrated in the width direction, and the upper end of the masonry wall At least one second reinforcing frame, the first reinforcing frame and the second reinforcing frame, and the first reinforcing frame and one or more second reinforcing frames, the second through-holes are formed in the width direction by being inclined downward as a reference, and alternately spaced apart from the first reinforcing frame a reinforcing frame having a connecting frame for connecting them, respectively, and movable in the longitudinal direction by an external force; A horizontal frame installed in the separation space and disposed on one side of the reinforcing frame, one end connected to the upper end of the first reinforcing frame, one end connected to the other end of the horizontal frame, and the other end connected to the lower end of the first reinforcing frame a moving frame connected and having a vertical frame through which a moving hole is formed in the width direction; a rod-shaped support bar having one end fixed to the pillar through the first through-hole, the second through-hole and the moving hole, and having a screw thread formed at the other end; and a moving nut screwed to the other end of the support rod to transmit the external force to the reinforcing frame by rotation.

Description

Seismic Reinforcing Apparatus For Bricks Wall and Constructing Method Using The Same

The present invention relates to a seismic reinforcement device for a masonry wall and a construction method using the same, and more particularly, to a masonry wall seismic reinforcement for supporting and reinforcing a masonry wall receiving an out-of-plane load by stably adhering the upper part of the masonry wall to a slab. It relates to an apparatus and a construction method using the same.

In general, a reinforced concrete structure is a structure in which columns and beams are rigidly joined, and the space is horizontally divided through a slab, and the plane is divided vertically using a masonry wall. Here, the slab is a cast-in-place concrete structure and is integrally formed with the columns and beams when they are constructed.

On the other hand, the masonry wall functions as a partition wall that separates the rooms by sequentially stacking bricks or concrete blocks during interior construction after the completion of the frame. Accordingly, a gap is generated between the slab and the masonry wall after construction.

At this time, since the gap between the masonry wall and the slab is usually filled with mortar, the masonry wall is not integrated with the frame and is very vulnerable to lateral forces acting in the in-plane or out-of-plane direction.

As a result, in the event of an earthquake, etc., the masonry wall is highly likely to overturn or collapse, causing personal injury. Therefore, it is urgent to develop seismic reinforcement technology for masonry walls as well as earthquake-resistant reinforcement technology for structural members including frames.

Republic of Korea Patent Publication No. 10-2011-0046079 (2011.05.04.)

The problem to be solved by the present invention is a seismic reinforcement device for a masonry wall, which can prevent the masonry wall from being easily overturned or collapsed by a force acting horizontally such as an earthquake load when an earthquake occurs by fixing the upper part of the masonry wall in close contact with a slab, and It provides the construction method used.

Another problem to be solved by the present invention is to strengthen the density of mortar between the masonry wall and the slab to prevent the masonry wall from easily overturning or collapsing due to a force acting horizontally, such as an earthquake load, when an earthquake occurs. To provide an apparatus and a construction method using the same.

Still other problems to be solved by the present invention will become more apparent from the following detailed description and drawings.

According to an embodiment of the present invention, the seismic reinforcement device for a masonry wall is a space formed between the upper end of the masonry wall and the lower end of the slab, which is constructed by sequentially stacking bricks in the vertical space formed between the column and the ceiling slab. One or more first reinforcing frames installed along the longitudinal direction of the masonry wall, inclined upward with respect to the upper end of the masonry wall, and having a first through-hole penetrated in the width direction, and the upper end of the masonry wall One or more second reinforcing frames, the first reinforcing frame and the second reinforcing frame, and the first reinforcing frame and one or more second reinforcing frames, the second reinforcing frame is formed with an inclination downward as a reference, second through-holes are formed in the width direction, and are alternately spaced apart from the first reinforcing frame a reinforcing frame having a connecting frame for connecting them, respectively, and movable in the longitudinal direction by an external force; A horizontal frame installed in the separation space and disposed on one side of the reinforcing frame, one end connected to the upper end of the first reinforcing frame, one end connected to the other end of the horizontal frame, and the other end connected to the lower end of the first reinforcing frame a moving frame connected and having a vertical frame through which a moving hole is formed in the width direction; a rod-shaped support bar having one end fixed to the pillar through the first through-hole, the second through-hole and the moving hole, and having a screw thread formed at the other end; and a moving nut screwed to the other end of the support rod to transmit the external force to the reinforcing frame by rotation.

In addition, the connection frame includes a third reinforcing frame connecting the upper end of the first reinforcing frame and the upper end of the second reinforcing frame, and a third reinforcing frame connecting the lower end of the second reinforcing frame and the lower end of the first reinforcing frame 4 It may be provided with a reinforcing frame. The third reinforcing frame and the fourth reinforcing frame may be alternately disposed with each other.

Here, the seismic reinforcing device for the masonry wall may further include an elastic pad coupled to the upper end of the third reinforcing frame and having an elastic force.

And, the seismic reinforcement device for the masonry wall, is installed on the front surface of the separation space, the front auxiliary plate for sealing a part of the front surface of the separation space; And it is installed on the rear surface of the separation space, the rear auxiliary plate for sealing a part of the rear surface of the separation space; may further include.

Here, the reinforcing frame and the moving frame divide the spaced space into a plurality of mortar spaces, and the mortar space may be filled with mortar.

According to another embodiment of the present invention, a construction method using an earthquake-resistant reinforcement device for a masonry wall includes: a first step in which the reinforcement frame, the movable frame, the support rod and the movable nut are installed in the spaced space; a second step in which the front auxiliary plate is installed on the front side of the separation space; a third step of filling the mortar space with mortar; a fourth step in which the rear auxiliary plate is installed on the rear side of the separation space; and a fifth step of applying an external force to the reinforcing frame by the moving nut.

Here, the fifth step is preferably a step of moving the moving frame by the rotation of the moving nut.

And, the construction method of the seismic reinforcement device for the masonry wall, following the fifth step, a sixth step of filling the remaining space with the mortar in the space other than the mortar space of the separation space; may further include.

The earthquake-resistant reinforcement device for a masonry wall according to the present invention and a construction method using the same have the following effects.

First, there is an advantage in that the upper part of the masonry wall is fixed in close contact with the slab to prevent the masonry wall from being easily overturned or collapsed by a force acting horizontally, such as an earthquake load, when an earthquake occurs.

Second, there is an advantage in that the density of the mortar between the masonry wall and the slab is strengthened to prevent the masonry wall from easily overturning or collapsing due to a force acting horizontally, such as an earthquake load, when an earthquake occurs.

1 is a perspective view of a seismic reinforcement device for a masonry wall according to an embodiment of the present invention.
2 is a view showing a state in which the earthquake-resistant reinforcement device for a masonry wall according to an embodiment of the present invention is installed on the masonry wall.
3 to 5 are views showing a construction method using the earthquake-resistant reinforcement device for a masonry wall according to an embodiment of the present invention.

Since the present invention can have various changes and can have various embodiments, specific embodiments are illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention. In describing each figure, like reference numerals have been used for like elements.

Terms such as first, second, A, and B may be used to describe various elements, but the elements should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component. and/or includes a combination of a plurality of related listed items or any of a plurality of related listed items.

When a component is referred to as being “connected” or “connected” to another component, it may be directly connected or connected to the other component, but it is understood that other components may exist in between. it should be On the other hand, when it is said that a certain element is "directly connected" or "directly connected" to another element, it should be understood that the other element does not exist in the middle.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present application, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

1 is a perspective view of a seismic reinforcement device for a masonry wall according to an embodiment of the present invention. 5 is a view showing a construction method using an earthquake-resistant reinforcement device for a masonry wall according to an embodiment of the present invention.

1, the earthquake-resistant reinforcement device 1 for a masonry wall according to this embodiment is for fixing the upper portion of the masonry wall 20 in close contact with the slab 30, the reinforcement frame 40, the moving frame 50 , a support rod 60 , a movable nut 70 , an elastic pad 80 , and may include a front auxiliary plate (not shown) and a rear auxiliary plate (not shown).

The masonry wall 20 is constructed by sequentially stacking bricks in the vertical space formed between the column 10 and the ceiling slab 30 of the structure. At this time, a spaced space C is formed between the upper end of the masonry wall 20 and the lower end of the slab 30 , and the spaced space C is usually filled with mortar. A mortar layer S may be formed on the upper end of the masonry wall 20 .

The reinforcing frame 40 is installed in the separation space C, and is disposed along the longitudinal direction of the masonry wall 20 . The reinforcing frame 40 has a vertical cross section of a rhombic shape. The reinforcing frame 40 may be moved horizontally along the longitudinal direction of the masonry wall 20 by an external force. In this case, the reinforcing frame 40 may increase the pressure acting in the vertical direction while contracting (the height is increased while the width is decreased). By doing this, it is possible to strengthen the adhesion between the slab 30 and the tissue wall 20 .

The reinforcing frame 40 includes a first reinforcing frame 41 , a second reinforcing frame 42 and a connection frame (not shown).

The first reinforcing frame 41 has a plate shape and is inclined upward with respect to the upper end of the masonry wall 20 . The first reinforcing frame 41 has a first through-hole 41a formed to pass through in the width direction. The second reinforcing frame 42 has a plate shape and is inclined downward with respect to the upper end of the masonry wall 20 . The second reinforcing frame 42 is formed with a second through-hole 42a penetrating in the width direction. The first reinforcing frame 41 and the second reinforcing frame 42 are alternately spaced apart from each other.

The connection frame (not shown) connects the first reinforcing frame 41 and the second reinforcing frame 42 to each other, and may include a third reinforcing frame 43 and a fourth reinforcing frame 44 .

The third reinforcing frame 43 connects the upper end of the first reinforcing frame 41 and the upper end of the second reinforcing frame 42 . The third reinforcing frame 43 may be in close contact with the slab 30 or may be in close contact with the slab 30 through the elastic pad 80 .

The fourth reinforcing frame 44 connects the lower end of the second reinforcing frame 42 and the lower end of the first reinforcing frame 41 . The fourth reinforcing frame 44 may be disposed on the upper end of the masonry wall 20 .

The third reinforcing frame 43 and the fourth reinforcing frame 44 may be alternately disposed with each other.

The first reinforcing frame 41 , the second reinforcing frame 42 , the third reinforcing frame 43 , and the fourth reinforcing frame 44 may be integrally connected. In this case, the reinforcing frame 40 may be made of a bendable material.

The moving frame 50 may be connected to the reinforcing frame 40 to transmit an external force to the reinforcing frame 40 . The moving frame 50 is installed in the separation space (C). The moving frame 50 is disposed on one side of the reinforcing frame 40 .

The moving frame 50 includes a horizontal frame 51 and a vertical frame 52 . One end of the horizontal frame 51 and the vertical frame 52 is coupled to each other to have a 'L' shape.

One end of the horizontal frame 51 is connected to the upper end of the first reinforcing frame 41 . The other end of the horizontal frame 51 is connected to one end of the vertical frame (52).

The other end of the vertical frame 52 is connected to the lower end of the first reinforcing frame 41 . The vertical frame 52 has a moving hole 52a formed through it in the width direction.

3 and 4, the reinforcing frame 40 and the moving frame 50 may divide the spaced space C into a plurality of mortar spaces. This mortar space is preferentially filled with mortar.

The support rod 60 has a straight line (line, wire, etc.) and one end passes through the moving hole 51a, the first through hole 41a, and the second through hole 42a sequentially to a predetermined position (for example, a pillar). etc.) is fixed. A screw line may be formed at the other end of the support rod 60 to enable screw coupling.

The moving nut 70 is coupled to the other end of the support rod 60 through a center hole (not shown). A screw line may be formed in the center hole (not shown). The moving nut 70 may transmit an external force (horizontal force) to the moving frame 50 by horizontal movement. Specifically, the moving nut 70 may transmit the external force to the moving frame 50 by being screwed with the support rod 60 and horizontally moved by rotation.

The elastic pad 80 has an elastic force and is coupled to the upper end of the third reinforcing frame 43 . The elastic pad 80 is disposed between the slab 30 and the third reinforcing frame 43 to elastically support the slab 30 and the third reinforcing frame 43 .

The front auxiliary plate (not shown) is installed on the front of the separation space (C). The front auxiliary plate (not shown) serves to seal a part of the front surface of the separation space (C) so that the mortar does not leak to the outside of the separation space (C) during mortar construction of the separation space (C).

A rear auxiliary plate (not shown) is installed on the rear side of the separation space (C). The rear auxiliary plate (not shown) serves to seal a part of the rear surface of the separation space (C) so that the mortar does not leak to the outside of the separation space (C) during mortar construction of the separation space (C).

A plurality of insertion protrusions (not shown) may be formed at the lower end of the reinforcing frame 40 in the longitudinal direction of the masonry wall 20 .

A rail (not shown) in which an insertion groove (not shown) is formed may be installed at the upper end of the tissue wall 20 or the mortar layer (S).

The insertion protrusion (not shown) may be slidably inserted into the insertion groove (not shown) of the rail. Accordingly, the reinforcing frame 40 can be moved or contracted along the rail (not shown).

On the other hand, an insertion groove (not shown) is formed in the longitudinal direction of the tissue wall 20 at the upper end of the mortar layer (S), and the insertion protrusion (not shown) is in the insertion groove (not shown) of the mortar layer (S). It may also be inserted slideably.

Hereinafter, a construction method using the earthquake-resistant reinforcement device for a masonry wall according to this embodiment will be described with reference to FIGS. 2 to 5 .

First, referring to FIG. 2 , the earthquake-resistant reinforcement device 1 for a masonry wall is installed in the separation space (C). Specifically, the reinforcing frame 40, the moving frame 50, the support rod 60 and the moving nut 70 are installed in the separation space (C). At this time, the elastic pad 80 may be attached to the upper end of the third reinforcing frame 43 .

For example, one end of the support rod 60 is moved through the moving hole 51a of the moving frame 50 , the first through hole 41a of the first reinforcing frame 41 and the second through hole of the second reinforcing frame 42 . The holes 42a are sequentially penetrated and fixed at a predetermined position (eg, a column, etc.). Then, the moving nut 70 is coupled or fitted to the other end of the support rod 60 . In this case, the dust reinforcement device 1 for the masonry wall may be assembled in the separation space (C) or assembled from the outside and installed in the separation space (c).

Next, the front auxiliary plate (not shown) is installed on the front of the separation space (C).

Next, the mortar is preferentially filled in the mortar space in which the reinforcement frame 40 and the moving frame 50 divide the space C into a plurality of spaces.

Next, the rear auxiliary plate (not shown) is installed on the rear side of the separation space (C). By doing so, the front and rear surfaces of the mortar space can be sealed.

Next, the external force is transmitted to the reinforcing frame 40 through the moving frame 50 by rotating the moving nut 70 . In this case, the reinforcing frame 40 may increase the pressure acting in the vertical direction while contracting (the height is increased while the width is decreased). By doing this, it is possible to enhance the adhesion between the slab 30 and the tissue wall 20 as well as increase the density of the mortar.

Next, the mortar is filled in the remaining spaces except for the mortar space among the separation spaces (C).

Next, after the mortar is sufficiently dried, the front auxiliary plate (not shown) and the rear auxiliary plate (not shown) are separated (removed) from the separation space (C).

As a result, the seismic reinforcement device for masonry wall according to the present invention and the construction method using the same not only fix the upper part of the masonry wall in close contact with the slab, but also strengthen the density of the mortar between the masonry wall and the slab so that it is horizontally similar to the seismic load when an earthquake occurs. It is possible to prevent the masonry wall from being easily overturned or collapsed by the applied force.

Although the present invention has been described in detail through preferred embodiments, other types of embodiments are also possible. Therefore, the spirit and scope of the claims set forth below are not limited to the preferred embodiments.

1: Seismic reinforcement for masonry wall 10: Column
20: masonry wall 30: slab
40: reinforcing frame 41: first reinforcing frame
41a: first through portion 42: second reinforcing frame
42a: second through portion 43: third reinforcing frame
44: fourth reinforcement frame 50: moving frame
51: horizontal frame 52: vertical frame
52a: moving hole 60: support bar
70: moving nut 80: elastic pad
C: Separation space M: Mortar

Claims (7)

It is installed along the longitudinal direction of the masonry wall in a space formed between the upper end of the masonry wall constructed by sequentially stacking bricks in the vertical space formed between the column and the ceiling slab and the lower end of the slab, and the upper end of the masonry wall At least one first reinforcing frame in which an inclination is formed in an upward direction based on a first through hole in the width direction, and a second through hole is formed in a downward direction with respect to the upper end of the masonry wall in the width direction. At least one second reinforcing frame is formed and alternately spaced apart from the first reinforcing frame, and a connecting frame connecting the first reinforcing frame and the second reinforcing frame, respectively, in the longitudinal direction by an external force. Reinforcement frame movable with;
A horizontal frame installed in the separation space and disposed on one side of the reinforcing frame, one end connected to the upper end of the first reinforcing frame, one end connected to the other end of the horizontal frame, and the other end connected to the lower end of the first reinforcing frame a moving frame connected and having a vertical frame through which a moving hole is formed in the width direction;
A rod-shaped support bar having one end fixed to the pillar through the first through-hole, the second through-hole and the moving hole, and having a screw thread formed at the other end; And
A moving nut screwed to the other end of the support rod to transmit the external force to the reinforcing frame by rotation; includes,
The connection frame is
a third reinforcing frame connecting the upper end of the first reinforcing frame and the upper end of the second reinforcing frame, and the third reinforcing frame and the lower end of the second reinforcing frame and the lower end of the first reinforcing frame provided with a fourth reinforcing frame connecting the
An elastic pad having an elastic force is coupled to the upper end of the third reinforcing frame, an earthquake-resistant reinforcement device for a masonry wall. delete It is installed along the longitudinal direction of the masonry wall in a space formed between the upper end of the masonry wall constructed by sequentially stacking bricks in the vertical space formed between the column and the ceiling slab and the lower end of the slab, and the upper end of the masonry wall At least one first reinforcing frame in which an inclination is formed in an upward direction based on a first through hole in the width direction, and a second through hole is formed in a downward direction with respect to the upper end of the masonry wall in the width direction. At least one second reinforcing frame is formed and alternately spaced apart from the first reinforcing frame, and a connecting frame connecting the first reinforcing frame and the second reinforcing frame, respectively, in the longitudinal direction by an external force. Reinforcement frame movable with;
A horizontal frame installed in the separation space and disposed on one side of the reinforcing frame, one end connected to the upper end of the first reinforcing frame, one end connected to the other end of the horizontal frame, and the other end connected to the lower end of the first reinforcing frame a moving frame connected and having a vertical frame through which a moving hole is formed in the width direction;
A rod-shaped support bar having one end fixed to the pillar through the first through-hole, the second through-hole and the moving hole, and having a screw thread formed at the other end; And
a movable nut screwed to the other end of the support rod and capable of transmitting the external force to the reinforcing frame by rotation;
A front auxiliary plate installed on the front surface of the separation space and sealing a part of the front surface of the separation space; And
A seismic reinforcement device for a masonry wall including; a rear auxiliary plate installed on the rear surface of the separation space and sealing a part of the rear surface of the separation space. 4. The method of claim 3,
The reinforcing frame and the moving frame divide the spaced space into a plurality of mortar spaces,
The mortar space is filled with mortar, a seismic reinforcement device for masonry walls. In the construction method using the earthquake-resistant reinforcement device for a masonry wall according to claim 4,
A first step of installing the reinforcing frame, the moving frame, the support rod and the moving nut in the separation space;
a second step in which the front auxiliary plate is installed on the front side of the separation space;
a third step of filling the mortar space with mortar;
A fourth step of installing the rear auxiliary plate on the rear side of the separation space; And
A construction method using a seismic reinforcement device for masonry walls, including; a fifth step of applying an external force to the reinforcement frame by the moving nut. 6. The method of claim 5,
The fifth step is
A construction method using a seismic reinforcement device for a masonry wall, which is a step of moving the moving frame by rotation of the moving nut. 6. The method of claim 5,
The construction method of the earthquake-resistant reinforcement device for the masonry wall,
Following the fifth step, a sixth step of filling the remaining space with the mortar in the space other than the mortar space of the separation space; further comprising, a construction method using a seismic reinforcement device for a masonry wall.

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