KR102294580B1 - Wire shear wall structure for earthquake retrofit - Google Patents

Abstract

The present invention relates to a wire shear wall structure for seismic reinforcement, for this purpose, a wire fixing member fixed to each of four outer corners of beams and columns constituting the shear wall of a building structure; Steel wire that is fixed in a number of shapes and reinforces columns and beams; and a tension adjusting means coupled to each of the steel wires to adjust the tension; the wire fixing member is formed on one side of the block body so as to fasten and fix the rectangular block body and each of the steel wires. Consisting of a plurality of fastening holes, each block body is vertically fixed to four outer corners of beams and columns so that the steel wire is connected to the "X" tension by expanding the contact area in the pulling direction of the steel wire to make it more stable It is characterized in that it is configured to reinforce the shear wall.

Description

Wire shear wall structure for seismic reinforcement {WIRE SHEAR WALL STRUCTURE FOR EARTHQUAKE RETROFIT}

The present invention relates to a wire shear wall structure for seismic reinforcement, and more particularly, it is possible to reinforce the shear wall by installing a plurality of steel wires in an "X" shape without damage to the existing shear wall, and also to a column with a steel wire A wire shear wall structure for seismic reinforcement in which vibration damping means are installed in the opening of the shear wall of the beam in a “+” shape to absorb and offset vibration energy transmitted in the four-axis direction to improve the seismic performance of the reinforced shear wall will be.

In general, existing building structures such as low-rise buildings with six stories or less and school buildings do not have an earthquake-resistant design to safely protect the building structure from earthquakes. As expected, the need to reinforce building structures to resist seismic loads has been raised.

In Korea, earthquake-resistance-related regulations have been revised since the application of earthquake-resistance regulations to the Building Act in 1988. Since these seismic design rules are applied to new buildings, buildings constructed before the introduction of seismic design rules were not only designed and constructed without considering the effects of earthquakes, but also suffered a lot of deterioration and damage due to the increase in public service life. It is considered that the seismic performance may not be properly exhibited.

The proportion of buildings that did not reflect seismic design was found to be about 80% of the total building, which was quite large.

In the event of an unexpected earthquake in such a building, not only direct damage from collapse and damage, but also enormous economic and social losses due to reconstruction are expected. In particular, in case of damage to important national facilities, the economic and social loss to the country as a whole is enormous.

Accordingly, the Fire and Disaster Prevention Administration supplemented the earthquake-related regulations stipulated in the “Natural Disaster Countermeasures Act” and drafted the “Earthquake Disaster Countermeasures Act” to promote seismic reinforcement for important national facilities to meet the seismic design standards. It is time to conduct multi-faceted research on seismic reinforcement methods for existing buildings and facilities, as evaluation and subsequent reinforcement or supplementation are recommended.

Unlike the earthquake-resistant design method applied to new buildings, the seismic reinforcement method requires reinforcement of existing buildings or facilities, so it is necessary to consider usability, economic feasibility, and constructability. Therefore, it is necessary to select an appropriate method.

Among them, as a method for seismic suppression or seismic reinforcement of an existing structure, a method of installing a reinforcement structure or the like for seismic damping and seismic reinforcement inside an opening of a structure made of beams and columns is mainly used.

However, in the prior art, as in the bonding structure and bonding method of the vibration damper installation frame (registration number: 10-1026106), in order to install the frame in the opening, a fastening hole is formed in the opening and a plurality of anchor bolts are fastened to the fastening hole. Damage to the existing structure was inevitable.

The structure fastened with these anchor bolts is difficult to construct, takes a lot of construction time, and has problems in that the shear load of the concrete structure is concentrated on the anchor bolt, resulting in breakage of the anchor bolt and damage to the existing concrete structure.

In addition, the frame assembled with anchor bolts had a small displacement and was weak against external impact.

Korean Patent Registration No. 1026106

The present invention was devised in view of the above problems, and the first object of the present invention is to reinforce the shear wall by tensioning a plurality of steel wires in an "X" shape without damaging the existing shear wall. To provide a wire shear wall structure for

A second object of the present invention is to provide a vibration damping means in the form of "+" in the openings of the shear walls of columns and beams together with steel wire to absorb and offset vibration energy transmitted in the four axial directions to improve the seismic performance of the reinforced shear wall. An object of the present invention is to provide a wire shear wall structure for seismic reinforcement that can be raised.

According to the features for achieving the above object, the first invention relates to a wire shear wall structure for earthquake-resistant reinforcement, and for this purpose, a wire fixed at four outer corners of beams and columns constituting the shear wall of a building structure, respectively a member; and a steel wire fixed to each of the wire fixing members in an "X" shape to reinforce columns and beams; and a tension adjusting means coupled to each of the steel wires to adjust the tension; the wire fixing member is formed on one side of the block body so as to fasten and fix the rectangular block body and each of the steel wires. Consisting of a plurality of fastening holes, each block body is vertically fixed to four outer corners of beams and columns so that the steel wire is connected to the "X" tension by expanding the contact area in the pulling direction of the steel wire to make it more stable It is characterized in that it is configured to reinforce the shear wall.

In the second invention, in the first invention, a rail groove for guiding the vibration damping means and preventing the separation of the vibration damping means is formed inside the square opening of the pillar and the beam, and the rail groove has a "+" shape in the center of the opening. It is characterized in that the vibration damping means is further installed.

In the third invention, in the second invention, the vibration damping means is for canceling the vibration displacement in the four-axis direction, and four link connectors connected by links in a "+" shape, and the free end of each link connector tube It characterized in that it consists of a damping cylinder inserted into the, and a support means coupled to the support rod of the damping cylinder and seated in the rail groove.

In the fourth invention, in the third invention, the support means is rotatably coupled to the end of the support rod and is composed of a roller rolled on the rail groove or a friction block slidably coupled to the rail groove.

According to the wire shear wall structure for seismic reinforcement of the present invention, damage to the existing building structure can be minimized by fixing the wire fixing member in the form of a block to the groove formed in the concrete wall by force fitting, thus structural damage to the columns and beams has the effect of preventing

In addition, since it is made only of steel wire and wire fixing member, the construction period is greatly shortened and the construction cost is very low.

In addition, by installing vibration damping means in the form of “+” in the openings of the shear wall of columns and beams together with steel wire, it absorbs and offsets the vibration energy transmitted in the four-axis direction, thereby improving the seismic performance of the reinforced shear wall. .

1 is a block diagram of a wire shear wall structure for seismic reinforcement according to a first embodiment of the present invention;
2 is a configuration diagram of a wire shear wall structure for earthquake-resistant reinforcement according to a second embodiment of the present invention;
3 is a configuration diagram showing the vibration damping means extracted from FIG. 1;
FIG. 4 is a perspective view of FIG. 3 ;

The following objects, other objects, features and advantages of the present invention will be readily understood through the following preferred embodiments in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms.

Rather, the embodiments introduced herein are provided so that the disclosed subject matter may be thorough and complete, and that the spirit of the present invention may be sufficiently conveyed to those skilled in the art.

The embodiments described and illustrated herein also include complementary embodiments thereof.

As used herein, the singular also includes the plural unless specifically stated otherwise in the phrase. As used herein, the terms 'comprise' and/or 'comprising' do not exclude the presence or addition of one or more other components.

Hereinafter, the present invention will be described in detail with reference to the drawings. In describing the specific embodiments below, various specific contents have been prepared to more specifically explain and help the understanding of the invention. However, a reader having enough knowledge in this field to understand the present invention can recognize that it can be used without these various specific details. In some cases, it is mentioned in advance that parts that are commonly known and not largely related to the invention in describing the invention are not described in order to avoid confusion in describing the invention.

Hereinafter, the wire shear wall structure for seismic reinforcement according to the present invention will be described in detail together with the accompanying drawings.

1 is a block diagram of a wire shear wall structure for seismic reinforcement according to a first embodiment of the present invention.

As shown in FIG. 1, in the first embodiment, a wire shear wall for seismic reinforcement that minimizes damage to the building structure and reinforces the shear wall made of columns and beams to prevent the building structure from being damaged by an external force such as an earthquake of the structure 100 .

The wire shear wall structure 100 for such seismic reinforcement is largely composed of three parts, which is composed of a wire fixing member 10 , a steel wire 20 and a tension adjusting means 21 .

The wire fixing member 10 is fixed to the four outer corners of the beam 300 and the pillar 200 of the building structure for tension installation of the steel wire 20 in an "X" shape.

The wire fixing member 10 is configured to minimize damage to the existing building structure by forming a separate groove in the concrete wall, fixing it with an interference fit, and then finishing it with mortar.

The wire fixing member 10 is composed of a rectangular block body 11 and a plurality of fastening holes 12 formed on one surface of the block body 11 .

At this time, the block body 11 is fixed in the longitudinal direction, which is to increase the contact area in the pulling direction of the steel wire 20 to form a more stable shear wall when the steel wire 20 is connected to the "X" tension. is one configuration.

Here, the number of wire fastening holes 12 formed in the block body 11 may vary according to the area of the shear wall.

The steel wire 20 is fixed to the fastening hole 12 of each wire fixing member 10 in an "X" shape to reinforce the distortion of the pillar 200 and the beam 300 .

At this time, each of the steel wires 20 is further connected to a tension adjusting means 21 for adjusting the tension, and this tension adjusting means 21 is made of a turnbuckle so that the tension of the steel wire can be adjusted more easily.

On the other hand, the steel wires 20 fastened and fixed in different directions have different height differences so as not to be intertwined with each other, which is possible by varying the thickness of a pair of block bodies 11 among the two pairs of block bodies 11 . .

The wire shear wall structure 100 for the earthquake-resistant reinforcement of the first embodiment described above is possible because the block body does not damage the building structure, so the work is possible without the concrete wall being demolished. In addition, since it is made only of steel wire and wire fixing member, the construction period is greatly shortened and the construction cost is very low.

In addition, in another embodiment, the anchor bolt is fixed on the outer surface of the column without the block body, and after fixing the anchor bolt by weaving a steel wire, it can be constructed in an "X" shape by wrapping the column.

Figure 2 is a configuration diagram of a wire shear wall structure for seismic reinforcement according to a second embodiment of the present invention, Figure 3 is a configuration diagram showing the vibration damping means extracted from Figure 1, Figure 4 is a perspective view of Figure 3.

As shown in Figures 2 to 4, the second embodiment includes the first embodiment, but is configured to further include a vibration damping means 30 to offset the vibration of the building structure due to an earthquake.

To this end, a rail groove 40 for guiding the vibration damping means 30 and preventing the separation of the vibration damping means 30 is recessed inside the square opening 400 of the pillar 200 and the beam 300 .

The vibration damping means 30 is to attenuate vibration displacement caused by longitudinal/lateral loads, and is installed in the center of the opening 400 in a “+” shape.

The vibration damping means 30 is for offsetting vibrational displacement in the four-axis direction, and includes four link connecting tubes 31 that are linked in a "+" shape, and the free end of each of the link connecting tubes 31 . It is composed of a damping cylinder 32 inserted into the , and a support means coupled to the support rod 321 of the damping cylinder 32 and seated in the rail groove 40 .

Here, the support means may be composed of a roller 33 that is rotatably coupled to the end of the support rod 321 and rolled on the rail groove 40, as shown in FIG. 3, and in another example, the rail groove 40 It may be composed of a friction block (not shown) that is slidably coupled to the .

In the case of configuring the friction block, it may be configured by further coupling a friction plate (not shown) to the rail groove 40 .

In this vibration damping means 30, four damping cylinders 32 flowing along the rail groove 40 around the link connection pipe 31 distribute the seismic load, and also the pillar 200 and the beam 300 ), the vibration energy transmitted in the four-axis direction can be absorbed and offset to improve the seismic performance of the reinforced shear wall.

Since the vibration damping means 30 is combined with the steel wire 20, it is possible to double the seismic performance according to the structural safety of the building structure by the steel wire 20.

The embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiment of the present invention and do not represent all the technical spirit of the present invention, so various equivalents that can be substituted for them at the time of the present application It should be understood that there may be variations and examples.

10: wire fixing member 11: block body 12: fastening hole
20: steel wire 21: tension control means
30: vibration damping means 31: link connection pipe 32: damping cylinder
321: support rod 33: roller
40: rail groove
100: wire shear wall structure for seismic reinforcement
200: column 300: beam 400: opening

Claims (4)

Wire fixing members 10 each fixed to the outer corners of the beam 300 and the pillar 200 constituting the shear wall of the building structure in four places;
Steel wire 20 for reinforcing the pillar 200 and the beam 300 by being fixed to each of the wire fixing members 10 in an "X"shape; and
Tension adjusting means 21 for adjusting the tension by being coupled to each of the steel wires 20;
The wire fixing member 10 is a rectangular block body 11, and a plurality of fastening holes 12 formed on one surface of the block body 11 so as to fasten and fix each steel wire 20. ,
Each of the block body 11 is fixed in the longitudinal direction to the four outer corners of the beam 300 and the pillar 200, and the steel wire 20 is connected to the "X" tension in the tension of the steel wire 20. It is constructed to reinforce a more stable shear wall by expanding the contact area in the direction.
A rail groove 40 for guiding the vibration damping means 30 and preventing the separation of the vibration damping means 30 is recessed inside the square opening 400 of the pillar 200 and the beam 300,
Wire shear wall structure for seismic reinforcement, characterized in that the rail groove (40) is further provided with a vibration damping means (30) in the form of "+" in the center of the opening 400.


delete According to claim 1,
The vibration damping means 30 is for offsetting vibration displacement in the four-axis direction, and includes four link connecting tubes 31 that are linked in a "+" shape, and at the free end of each of the link connecting tubes 31 . A wire shear wall structure for seismic reinforcement, characterized in that it consists of a damping cylinder (32) to be inserted, and a support means coupled to the support rod (321) of the damping cylinder (32) and seated in the rail groove (40).
4. The method of claim 3,
The support means is earthquake-resistant, characterized in that it is rotatably coupled to the end of the support rod (321) and is composed of a roller (33) rolled on the rail groove (40) or a friction block slidingly coupled to the rail groove (40) Wire shear wall structures for reinforcement.

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