KR102300605B1 - Seismic resistance structure for preventing falldown of masonry partition walls - Google Patents

Abstract

The present invention relates to a structure for preventing the overturning of a seismic masonry partition wall, wherein a plurality of lines of vertical reinforcers having an upper part fixed to a lower part of an upper horizontal member are installed on both sides of a masonry partition wall, and a strap-shaped reinforcement plate is installed between adjacent vertical reinforcers to be brought into tight contact with a side of the partition wall, and, as a result, the structure can prevent the overturning of the partition wall in case of an earthquake and minimize influence onto an existing structure to secure structural stability. According to the present invention, the structure for preventing the overturning of a seismic masonry partition wall, which is installed on a masonry partition wall constructed in an existing framework, comprises: a plurality of vertical reinforcers provided on both sides of the partition wall to support the partition wall and having an upper part fixed to a lower part of an upper horizontal member; and a strap-shaped reinforcement plate provided transversely between adjacent vertical reinforcers to be brought into tight contact with a side of the partition wall and having both ends fixed to the vertical reinforcers. The vertical reinforcers comprise: a pair of side plates; a front plate connecting outer sides of the pair of side plates; and a side joint plate vertically bent from the inside of the side plates to a side to be brought into tight contact with the strap-shaped reinforcement plate. Accordingly, the vertical reinforcers and the strap-shaped reinforcement plate are fixed to the partition wall through a second coupling bolt penetrating the side joint plate, the strap-shaped reinforcement plate and the partition wall.

Description

Seismic resistance structure for preventing falldown of masonry partition walls

The present invention installs a plurality of rows of vertical reinforcing bars whose upper ends are fixed to the lower part of the upper horizontal member on both sides of the masonry partition wall. It is about an earthquake-resistant masonry partition wall prevention structure that can prevent wall overturning and secure structural stability by minimizing the impact on existing structures.

In a reinforced concrete ramen-like structure composed of columns and beams, there are many cases in which masonry walls are constructed as partition walls for each room division.

These masonry partition walls are usually constructed in a simple filling method between columns. In addition, the structure is very weak in the out-of-plane direction of the masonry wall as it is often constructed only to the ceiling height without being filled up to the upper slab.

In particular, KDS 41 17 "Seismic Design Standards for Buildings" also stipulates that a partition wall with a height of 1.8 m or more or a partition wall connected to a ceiling material must be supported lateral to the building structure, and the lateral support is stipulated to control the displacement of the upper part of the partition wall.

However, the masonry partition wall is vulnerable to out-of-plane loads and is spaced apart from the upper structure, so structural reinforcement is required to control the displacement of the upper part of the partition wall.

In addition, the seismic design standards for buildings require that, when the partition wall is made of masonry, seismic slits are installed to prevent it from affecting adjacent columns or to design in consideration of the interaction with structural elements.

However, existing partition walls are often constructed to fill the entire width of the Ramenzo frame without seismic slits, so an in-plane load may affect surrounding structures such as columns.

US 10-0959218 B1

In order to solve the above problems, the present invention is to prevent the overturning of the masonry partition wall when an earthquake occurs, and to provide a structure for preventing the fall of the masonry partition wall for earthquake resistance that can secure structural stability by minimizing the effect on the existing structure.

The present invention according to a preferred embodiment is installed on a masonry partition wall constructed inside an existing frame, provided on both sides of the partition wall to support the partition wall, and the upper end is fixed to the lower portion of the upper horizontal member. reinforcement; and a band-shaped reinforcing plate provided in the transverse direction between the adjacent vertical reinforcing bars to be in close contact with the side surfaces of the partition wall, both ends of which are fixed to the vertical reinforcing bars; The vertical reinforcement is composed of a pair of side plates, a front plate connecting the outside of the pair of side plates, and a side bonding plate that is vertically bent from the inside of the side plate to the side and is in close contact with the band-shaped reinforcement plate. , It provides an earthquake-resistant masonry partition wall overturn prevention structure, characterized in that the vertical reinforcement and the belt-type reinforcement plate are fixed to the partition wall by a second fastening bolt penetrating the side junction plate, the belt-shaped reinforcement plate, and the partition wall.

The present invention according to another preferred embodiment is provided with a vertically bent end junction plate at the end of the band-shaped reinforcing plate, and the end junction plate is fixed to the side of the vertical reinforcement by a first fastening bolt. Provides a wall overturn prevention structure.

delete

The present invention according to another preferred embodiment is earthquake-resistant masonry, characterized in that the vertical reinforcement is composed of an upper guide tube and a lower guide tube provided to be spaced apart from each other and a connector connecting the upper guide tube and the lower guide tube The partition wall provides an anti-tipping structure.

The present invention according to another preferred embodiment is a seismic masonry partition wall for earthquake-resistant structure, characterized in that the upper and lower ends of the connector are inserted into the upper guide tube and the lower guide tube, respectively, to interconnect the upper guide tube and the lower guide tube provides

The present invention according to another preferred embodiment is characterized in that the connector is composed of an upper junction coupled to the upper guide pipe, a lower junction coupled to the lower guide pipe, and a viscoelastic rubber provided between the upper junction and the lower junction. It provides an earthquake-resistant masonry partition wall with a fall prevention structure.

The present invention according to another preferred embodiment provides an earthquake-resistant masonry partition wall overturn prevention structure, characterized in that the lower end of the vertical reinforcement is fixed to the upper surface of the floor slab.

The present invention according to another preferred embodiment is provided on both sides of the partition wall to support the partition wall, the lower end of which is fixed to the upper surface of the floor slab, a plurality of rows of lower vertical reinforcement is further provided. Provides a wall overturn prevention structure.

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

First, by installing a plurality of rows of vertical reinforcement on both sides of the masonry partition wall constructed inside the existing frame, and fixing the upper end to the lower part of the upper horizontal member, when an out-of-plane load is applied to the partition wall, Upper displacement can be limited.

Second, by installing the belt-shaped reinforcing plate between the adjacent vertical reinforcing bars to be in close contact with the side of the partition wall, it is possible to prevent overturning or collapse by supporting the masonry partition wall between the adjacent vertical reinforcing bars. In addition, it is possible to effectively reinforce the masonry partition wall while minimizing the installation location of the vertical reinforcement.

Third, since the vertical reinforcement and the strip-shaped reinforcement plate form a lattice shape as a whole, the rigidity of the partition wall itself is not significantly increased, thereby preventing an increase in stress in the surrounding structure and effectively preventing the partition wall from falling, thereby securing structural stability.

1 is a perspective view showing an embodiment of the present invention earthquake-resistant masonry partition wall fall prevention structure.
Figure 2 is a perspective view showing the coupling relationship between the vertical reinforcement and the strip reinforcement plate.
3 is a cross-sectional view showing the earthquake-resistant masonry partition wall fall prevention structure of the present invention.
Figure 4 is a perspective view showing another embodiment of the present invention seismic masonry partition wall fall prevention structure.
Figure 5 is a perspective view showing the coupling relationship of the vertical reinforcement.
Figure 6 is a perspective view showing a vertical reinforcement provided with viscoelastic rubber.
7 is a perspective view showing an embodiment in which the vertical reinforcement is fixed to the upper surface of the floor slab;
8 is a perspective view showing an embodiment provided with a lower vertical reinforcement.

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

1 is a perspective view showing an embodiment of the present invention earthquake-resistant masonry partition wall overturn prevention structure.

As shown in FIG. 1, the earthquake-resistant masonry partition wall fall prevention structure of the present invention is installed on the masonry partition wall 2 constructed inside the existing frame 1, and is provided on both sides of the partition wall 2 a plurality of rows of vertical reinforcements (3) having an upper end fixed to the lower portion of the upper horizontal member (13) to support the partition wall (2); and a band-shaped reinforcing plate 4 provided in the transverse direction between the adjacent vertical reinforcing bars 3 to be in close contact with the side surfaces of the partition wall 2 and having both ends fixed to the vertical reinforcing bars 3; It is characterized in that it is composed of

An object of the present invention is to provide a structure for preventing the fall of the masonry partition wall (2) for earthquake resistance, which can secure structural stability by preventing the overturning of the masonry partition wall (2) and minimizing the effect on the existing structure.

The present invention prevents the overturn of the masonry partition wall (2) by installing it on the masonry partition wall (2) constructed inside the existing frame (1).

1 and the like, the existing frame 1 is composed of a vertical member 11, such as a column or wall, as an embodiment, a floor slab 12, and an upper horizontal member 13, such as an upper slab or beam.

The seismic masonry partition wall fall prevention structure for the present invention is configured to include a strip-shaped reinforcing plate (4) provided in the transverse direction between a plurality of rows of vertical reinforcement (3) and adjacent vertical reinforcement (3).

The vertical reinforcement 3 is provided in a plurality of rows on both sides of the partition wall 2 to support the partition wall 2, and the upper end is fixed to the lower portion of the upper horizontal member 13, such as an upper layer slab or beam.

To this end, a fixing plate 30 fixed to the upper horizontal member 13 by an anchor bolt may be provided at the upper end of the vertical reinforcement 3 .

The vertical reinforcement 3 is provided in a plurality of rows outside the upper portion of the partition wall 2 to prevent the partition wall 2 from being overturned in an out-of-plane direction.

The vertical reinforcement 3 is provided on both sides of the partition wall 2 and is configured to be in close contact with the upper side surface.

Accordingly, when an out-of-plane load is applied to the partition wall 2 , the upper displacement of the partition wall 2 can be limited by the cantilever behavior of the vertical reinforcement 3 .

The band-shaped reinforcing plate 4 is provided in the transverse direction between the adjacent vertical reinforcing spheres (3).

The band-shaped reinforcing plate (4) is in close contact with the side of the partition wall (2), and both ends are fixed to the vertical reinforcing device (3).

The strip-shaped reinforcing plate 4 can be configured as a steel strip having a certain width.

The band-shaped reinforcing plate (4) supports the masonry partition wall (2) between the adjacent vertical reinforcing bars (3) to prevent overturning or collapse.

Accordingly, it is possible to effectively reinforce the masonry partition wall 2 while minimizing the installation location of the vertical reinforcement 3 .

On the other hand, when the self-rigidity of the partition wall 2 is excessively increased due to reinforcement of the partition wall 2 , the stress of structures around the partition wall 2 may increase when an earthquake occurs. Accordingly, in the present invention, the rigidity of the partition wall 2 itself is improved by connecting the vertical reinforcement 3 in the vertical direction in the transverse direction to form a lattice shape as a whole using a band-shaped reinforcement plate 4 having relatively small bending rigidity. It was designed to prevent the overturn of the partition wall 2 effectively while preventing the increase in stress of the surrounding structures by not increasing it significantly.

A plurality of the band-shaped reinforcing plates 4 may be provided so as to be vertically spaced apart from each other.

Figure 2 is a perspective view showing the coupling relationship between the vertical reinforcement and the band-shaped reinforcement plate, Figure 3 is a cross-sectional view showing the earthquake-resistant masonry partition wall fall prevention structure for the present invention.

2 and 3, the end of the band-shaped reinforcing plate 4 is provided with an end junction plate 41 bent vertically, the end junction plate 41 is the side of the vertical reinforcement (3) It may be fixed by the first fastening bolt (B _{1 ).}

The band-shaped reinforcing plate (4) can be fixed to the vertical reinforcing tool (3) by welding or the like. However, in this case, a lot of air is consumed, and there is a risk of fire due to work with a fire in the room.

Therefore, the end of the band-shaped reinforcing plate 4 is vertically bent to form an end junction plate 41, and the end junction plate 41 is fixed _{to the side of the vertical reinforcement 3 with a first fastening bolt (B 1 ).} can do. In this case, it is possible to facilitate the bonding of the vertical reinforcing tool 3 and the belt-shaped reinforcing plate 4, and it is possible to secure work safety by omitting on-site welding work.

In addition, when an in-plane load is applied to the partition wall 2 , rotational deformation occurs at the bent portions of the band-shaped reinforcing plate 4 and the end junction plate 41 , and energy dissipation is possible.

As shown in FIG. 3 , the vertical reinforcement 3 includes a pair of side plates 31 , a front plate 32 connecting the outside of the pair of side plates 31 , and the side plate 31 . It consists of a side bonding plate 33 that is vertically bent from the inside of The second fastening bolts (B ₂ ) can be configured to be fixed to the partition wall (2) by the vertical reinforcement (3) and the strip-shaped reinforcement plate (4).

When an out-of-plane load is applied to the masonry partition wall 2 in either direction, the partition wall 2 is supported only by the vertical reinforcement 3 on either side of the vertical reinforcement 3 on both sides of the partition wall 2 .

In this case, the cross-sectional size of the vertical reinforcement (3) and the size of the fixing plate (30) are excessively large because the overturned load must be supported by only one vertical reinforcement (3), and the anchor bolt for fixing the fixing plate (30) The number will also increase.

Therefore, when an out-of-plane load is applied to the partition wall 2, it is preferable to connect the vertical reinforcement 3 on both sides to each other so that the vertical reinforcement 3 on both sides can support the load.

To this end, the vertical reinforcement 3 is composed of a pair of side plates 31 and a front plate 32 connecting the outside of the pair of side plates 31, so that the partition wall 2 is open in a U-shape. In order to form a cross-section and fix the vertical reinforcement 3 to the partition wall 2, the inner side of the side plate 31, that is, the end of the partition wall 2 side, is bent outward, which is the side junction plate 33. can form.

The vertical reinforcing holes 3 on both sides of the partition wall 2 are fixed to each other by _{the second fastening bolts B 2 passing through the side bonding plate 33 .}

In addition, since the partition wall 2 is fixed to the vertical reinforcement 3, the vertical reinforcement 3 bears stress against the in-plane displacement of the partition wall 2, and vertical members at both ends of the partition wall 2 The load applied to (11) can be reduced.

In addition, the band-shaped reinforcing plate 4 is fixed to the vertical reinforcing tool 3 using the second fastening bolt (B _{2 ).} That is, both the vertical reinforcement 3 and the strip-shaped reinforcement plate 4 are fixed to the partition wall 2 by the second fastening bolt (B _{2 ), enabling rapid construction.}

In order to increase the workability while preventing the rigidity of the partition wall 2 from being excessively increased by the belt-shaped reinforcement plate 4, only the end portion of the belt-shaped reinforcement plate 4 is fixed to the partition wall 2, and the middle part is It is preferable not to fix it separately.

When the end junction plate 41 is formed on the band-shaped reinforcing plate 4, the end junction plate 41 is inserted into the open side of the vertical reinforcement 3 so that the end junction plate 41 is a side plate 31 It may be configured to be in close contact with the inner surface. In this case, since the junction is not exposed, the appearance can be simply formed.

At this time, the first fastening bolt (B ₁ ) may be fastened through the side plate 31 of the vertical reinforcement 3 and the end junction plate 41 of the belt-shaped reinforcement plate 4 .

For absorbing construction errors, the bolt hole to which the first fastening bolt (B ₁ ) is fastened can be formed as a long hole with a long length in the horizontal direction.

Figure 4 is a perspective view showing another embodiment of the present invention seismic masonry partition wall fall prevention structure, Figure 5 is a perspective view showing the coupling relationship of the vertical reinforcement.

As shown in Figures 4 and 5, the vertical reinforcement 3 is an upper guide tube 34 and a lower guide tube 35 and the upper guide tube 34 and the lower guide which are provided to be vertically spaced apart from each other. It can be configured as a connector 36 for connecting the tube (35).

The length of the vertical reinforcement 3 may vary depending on the distance between the upper end of the partition wall 2 and the upper horizontal member 13 or the height of the partition wall 2 .

Accordingly, the length of the vertical reinforcement 3 should be configured differently for each site.

In addition, since the vertical reinforcement 3 supports the conduction load of the partition wall 2 by a cantilever motion, a greater bending moment acts toward the end of the upper horizontal member 13 side. However, if the cross section is set based on this moment, the amount of steel for the remaining part is excessively required, which is uneconomical.

Therefore, the vertical reinforcement 3 is an upper guide pipe 34 and a lower guide pipe 35 and a connector ( 36) can be divided into

The upper guide tube 34 and the lower guide tube 35 maintain the same length and adjust the length of the connector 36 to adjust the overall length of the vertical reinforcement 3 .

If necessary, the thickness of the upper guide tube 34 may be made thicker than the thickness of the lower guide tube 35 to effectively resist the upper bending moment.

As shown in FIG. 5 , the connector 36 has an upper end and a lower end inserted into the upper guide tube 34 and the lower guide tube 35 , respectively, to connect the upper guide tube 34 and the lower guide tube 35 to each other. can connect

In order to smoothly adjust the length of the vertical reinforcement 3, both ends of the connector 36 may be inserted into the upper and lower guide tubes 34 and 35 to enable sliding movement.

Accordingly, the length of the vertical reinforcement 3 can be easily adjusted by adjusting the overlapping length of the connector 36 by being inserted into the upper and lower guide tubes 34 and 35 .

The connector 36 and the upper and lower guide tubes 34 and 35 may be coupled to each other through _{a first fastening bolt (B 1} ) for fixing the end joining plate 41 of the band-shaped reinforcing plate 4 .

6 is a perspective view showing a vertical reinforcement provided with viscoelastic rubber.

As shown in FIG. 6 , the connector 36 includes an upper joint 361 coupled to the upper guide pipe 34 , a lower joint 362 coupled to the lower guide pipe 35 , and the upper joint It may be composed of a viscoelastic rubber 363 provided between the 361 and the lower joint 362 .

When displacement occurs in the partition wall 2 due to earthquakes, etc., the effect on the surrounding frame can be minimized by absorbing vibration of the partition wall 2 and dissipating energy. Similarly, it is possible to absorb energy due to vibration of the surrounding frame and prevent it from being transmitted to the partition wall (2).

To this end, the upper junction 361 is coupled to the lower portion of the upper guide pipe 34 , the lower junction 362 is coupled to the upper part of the lower guide pipe 35 , and the upper junction 361 and the lower junction are coupled to each other. When the relative displacement of the sphere 362 occurs, the connector 36 may be configured such that energy is dissipated by shear deformation of the viscoelastic rubber 363 provided between the upper and lower junctions 361 and 362 .

Since the viscoelastic rubber 363 is capable of dissipating energy against omnidirectional displacement, it is possible to absorb energy not only in the out-of-plane direction but also in the in-plane direction of the partition wall 2 .

The connector 36 may be configured by vertically separating the viscoelastic rubber 363 according to the length, and positioning the intermediate plate 364 therebetween to connect the upper and lower viscoelastic rubber 363 .

7 is a perspective view showing an embodiment in which the vertical reinforcement is fixed to the upper surface of the floor slab.

As shown in FIG. 7 , the lower end of the vertical reinforcement 3 may be fixed to the upper surface of the floor slab 12 .

When the thickness of the partition wall 2 is thick and the weight is large, it may be difficult to support the load in the out-of-plane direction of the partition wall 2 only by the cantilever behavior of the vertical reinforcement 3 .

Therefore, by extending the vertical reinforcement 3 to the floor slab 12 and fixing it to the floor slab 12, both ends can be supported.

The band-shaped reinforcing plate 4 may be provided to connect the upper end and the lower end of the adjacent vertical reinforcing sphere 3 , respectively.

8 is a perspective view showing an embodiment provided with a lower vertical reinforcement.

As shown in FIG. 8, a plurality of rows of lower vertical reinforcement 5 are provided on both sides of the partition wall 2 to support the partition wall 2, and the lower end is fixed to the upper surface of the floor slab 12. More may be provided.

When the height of the partition wall 2 is high, the lower vertical reinforcement 5 may be installed at the lower portion in the same manner as the vertical reinforcement 3 to support the partition wall 2 from the top and bottom at the same time.

The lower vertical reinforcement (5) has a lower end fixed to the upper surface of the floor slab (12).

The lower vertical reinforcement (5) is preferably provided at the same position as the vertical reinforcement (3) on a plane.

A band-shaped reinforcing plate 4 is also provided in the transverse direction between the adjacent lower vertical reinforcing holes 5 to be in close contact with the side surface of the partition wall 2 .

The band-shaped reinforcing plate (4) is capable of fixing both ends to the vertical reinforcing member (3).

1: Existing frame 11: Vertical member
12: floor slab 13: upper horizontal member
2: Partition wall 3: Vertical reinforcement
30: fixed plate 31: side plate
32: front panel 33: side junction panel
34: upper guide tube 35: lower guide tube
36: connector 361: upper joint
362: lower joint 363: viscoelastic rubber
364: middle plate 4: band-shaped reinforcing plate
41: end junction plate 5: lower vertical reinforcement
B ₁ : 1st fastening bolt B ₂ : 2nd fastening bolt

Claims (8)

To be installed on the masonry partition wall (2) constructed inside the existing frame (1),
A plurality of rows of vertical reinforcement (3) provided on both sides of the partition wall (2) to support the partition wall (2), the upper end being fixed to the lower portion of the upper horizontal member (13); and
a band-shaped reinforcing plate 4 provided in the transverse direction between the adjacent vertical reinforcing bars 3 to be in close contact with the side surfaces of the partition wall 2, both ends of which are fixed to the vertical reinforcing bars 3; is composed of
The vertical reinforcement 3 is vertically bent laterally from the inside of the pair of side plates 31, the front plate 32 connecting the outside of the pair of side plates 31, and the side plate 31, _{A second fastening bolt (B 2} ) composed of a side bonding plate 33 in close contact with the band-shaped reinforcing plate 4, and penetrating the side bonding plate 33, the belt-shaped reinforcing plate 4 and the partition wall (2). The earthquake-resistant masonry partition wall overturn prevention structure, characterized in that the vertical reinforcement (3) and the belt-type reinforcement plate (4) are fixed to the partition wall (2) by
In claim 1,
The end of the band-shaped reinforcing plate 4 is provided with an end junction plate 41 bent vertically, the end junction plate 41 is attached to the side of the vertical reinforcement 3 by a first fastening bolt (B ₁ ) An earthquake-resistant masonry partition wall, characterized in that it is fixed.
delete In claim 1,
The vertical reinforcement 3 includes an upper guide tube 34 and a lower guide tube 35 provided to be vertically spaced apart from each other, and a connector 36 connecting the upper guide tube 34 and the lower guide tube 35 . Seismic masonry partition wall for earthquake-resistant, characterized in that consisting of a fall prevention structure.
In claim 4,
The connector 36 is for earthquake resistance, characterized in that the upper and lower ends are inserted into the upper guide tube 34 and the lower guide tube 35, respectively, to interconnect the upper guide tube 34 and the lower guide tube 35 The masonry partition wall is an anti-fall structure.
In claim 5,
The connector 36 includes an upper junction 361 coupled to the upper guide pipe 34, a lower junction 362 coupled to the lower guide pipe 35, and the upper junction 361 and the lower junction ( 362), the earthquake-resistant masonry partition wall conduction prevention structure, characterized in that it consists of a viscoelastic rubber (363) provided between.
In claim 1,
The lower end of the vertical reinforcement (3) is fixed to the upper surface of the floor slab (12).
In claim 1,
It is provided on both sides of the partition wall (2) to support the partition wall (2), the lower end of which is fixed to the upper surface of the floor slab (12), characterized in that it further comprises a plurality of rows of lower vertical reinforcement (5) Jinyong masonry partition wall overturn prevention structure.

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