KR20190112346A - Curtain wall apparatus having improved earthquake impact wave resistance - Google Patents

Abstract

According to the present invention, a curtain wall apparatus comprises: an outer frame (100); a first inner frame (110) provided inside the outer frame (100) to absorb and disperse shock waves applied to the outer frame (100); and a first shock wave attenuation unit (120) connected to the outer frame (100) and the first inner frame (110) to attenuate shock waves applied to the outer frame (100) and transmit the same to the first inner frame (110). The first shock wave attenuation unit (120) includes: a cylinder portion (121); a piston head (122) and a piston rod (123); and a first spring (124) and a second spring (125) provided in the cylinder portion (121). According to the present invention, the curtain wall apparatus can absorb and attenuate shock waves such as seismic waves very efficiently.

Description

Curtain wall device with improved resistance to seismic waves {CURTAIN WALL APPARATUS HAVING IMPROVED EARTHQUAKE IMPACT WAVE RESISTANCE}

The present invention relates to a curtain wall device, and more particularly to a curtain wall device with improved resistance to various shock waves, such as seismic waves.

Curtain wall means that the load acting on the building in the structure made of reinforced concrete, steel frame, etc. is to be supported only by the frame made of pillars, beams, slabs, etc., and the outer wall is a non-bearing wall that does not bear the load.

Such curtain walls are mechanized and can be manufactured in a factory, so quality control is easy, and the external wall can be lightened. Besides, the curtain wall can produce a beautiful appearance according to the materials used. In particular, most of the high-rise buildings are currently constructed by this method.

However, in the situation where the curtain wall is used in a variety of modern high-rise buildings, safety problems against earthquakes of high-rise buildings are being highlighted.

On the other hand, Patent Document 1 discloses a curtain wall frame having a strength reinforcement and a heat insulation structure, but only such curtain wall frame structure has a limit that is insufficient to improve resistance to various seismic waves.

Accordingly, there is an urgent need for the development of a technology in which a curtain wall, which is a non-bearing exterior wall of a building, can be sufficiently firmly maintained against earthquakes of various strengths.

Patent Document 1: Republic of Korea Patent Registration No. 10-1692286 (2017.01.03)

Accordingly, the present invention has been found to provide a curtain wall device having improved resistance to seismic waves by using a plurality of shock wave absorbing members and shock wave attenuators to provide a curtain wall device having improved resistance to seismic waves. The invention has been completed based on this.

Accordingly, one aspect of the present invention is to provide a curtain wall device with improved resistance to seismic waves.

Curtain wall device according to an embodiment of the present invention is a beam-shaped outer frame 100 having an open end (101, 102) on one side; A first inner frame (110) provided inside the outer frame (100) and absorbing and dispersing shock waves applied to the outer frame (100) and having an empty beam shape; The first shock wave attenuator 120 is provided between the outer frame 100 and the first inner frame 110 to attenuate the shock wave applied to the outer frame 100 to the first inner frame 110. ); A carbon fiber frame 200 provided to be fitted in a shape corresponding to each of the open ends 101 and 102 of the outer frame 100 and made of high strength carbon fiber; A first shock wave absorbing member 310 provided at the center of the carbon fiber frame 200 to be in contact with the carbon fiber frame 200 and absorbing and attenuating the transmitted shock wave; A first connection member 400 having one end coupled to the first shock wave absorbing member 310; A second connection member 500 having one end fitted to the other end of the first connection member 400 and having an extension 510 at the other end on the left and right sides thereof; Two glass is arranged in parallel spaced apart in parallel with one end of the multilayer glass 600 is provided to be fitted between the expansion portion 510 and the carbon fiber frame 200; A second shock wave absorbing member 320 provided between the multilayer glass 600 and the expansion part 510 to absorb and attenuate the transmitted shock wave; A third shock wave absorbing member 330 provided between the multilayer glass 600 and the carbon fiber frame 200 to absorb and attenuate the transmitted shock wave; A fourth shock wave absorbing member 340 provided between two glasses constituting the multilayer glass 600 to absorb and attenuate the transmitted shock wave; And between the fourth shock wave absorbing member 340 and the other end of the first connection member 400, and both ends thereof contact the second shock wave absorbing member 320 and the third shock wave absorbing member 330, respectively. And a fifth shock wave absorbing member 350 that absorbs and attenuates the transmitted shock wave. The first shock wave damping unit 120 is coupled to one side of the outer frame 100 and formed of a wall and filled with a fluid therein. A cylinder portion 121 having a fluid passage 1211 through which the fluid can move; A piston head 122 provided to reciprocate along an inner wall of the cylinder 121 in the cylinder 121; A piston rod 123 coupled to the piston head 122 at one side of the cylinder portion 121 and a first inner frame 110 at the outside of the cylinder portion 121; A first spring 124 provided inside the cylinder portion 121 and having one end coupled to one side of the piston head 122 and the other end coupled to one inner side of the cylinder 121; And a second spring 125 provided inside the cylinder portion 121 and having one end coupled to the other side of the piston head 122 and the other end coupled to the inside other side of the cylinder portion 121. have.

The curtain wall device according to another embodiment of the present invention wraps around the first spring 124 or the second spring 125 so that the first spring 124 or the second spring 125 does not come into contact with the fluid. Is coupled to the piston head 122 and the other side may be provided with a spring protection pocket portion (C) coupled to one side or the other side inside the cylinder portion 121.

In the curtain wall device according to another embodiment of the present invention, if the first spring 124 is a tension spring, the second spring 125 is also a tension spring, if the first spring 124 is a compression spring the first spring The two springs 125 may also be configured as compression springs.

In the curtain wall device according to another embodiment of the present invention, the shock wave transmitted between the cylinder portion 121 and the outer frame 100 or between the piston rod 123 and the first inner frame 110. Shock wave dispersion unit 126 for dispersing in various directions is provided, the shock wave dispersion unit 126 is a case portion (1261); A plurality of shock wave dispersion barriers 1262 provided to be connected across the inner wall of the case 1261 to disperse the transmitted shock waves; And a shock wave attenuation unit 1263 provided between the plurality of shock wave dispersion partitions 1262 to convert and transmit the shock waves into vibration energy.

In the curtain wall device according to another embodiment of the present invention, the shock wave damping unit (1263) comprises a unit case (12631); Two shock wave damping spring members (12632) provided in the unit case (12631); A vibration weight (12633) connected between the two shock wave damping spring members (12632) to convert the wave energy of the shock wave into vibration energy of the weight to attenuate it; And shock wave absorbing pads 12264 provided on both sides of the unit case 12613 and contacting an inner wall of the case part 1261.

In the curtain wall device according to another embodiment of the present invention, the first inner frame 110 inside the second absorbs and distributes the shock wave transmitted from the first inner frame 110, the inside of the second hollow beam shape An inner frame 112; And a second connection between the first inner frame 110 and the second inner frame 112 to attenuate the shock wave transmitted to the first inner frame 110 and to transmit the shock wave to the second inner frame 112. Shock wave attenuator 130; may be provided.

In the curtain wall device according to another embodiment of the present invention, inside the outer frame 100 absorbs and distributes the shock waves transmitted from the outer frame 100 and the first inner frame 110 and the inside is empty A third inner frame 113 having a beam shape; The third shock wave attenuator 140 is provided between the outer frame 100 and the third inner frame 113 to attenuate the shock wave applied to the outer frame 100 to the third inner frame 113. And a fourth shock wave attenuator 150 connected between the first inner frame 110 and the third inner frame 113 to attenuate the transmitted shock wave.

In the curtain wall device according to another embodiment of the present invention, the second shock wave absorbing member 320, the third shock wave absorbing member 330, the fourth shock wave absorbing member 340 and the fifth shock wave absorbing member 350 May be formed integrally.

The curtain wall device according to the present invention has the advantage of having excellent resistance to various seismic waves, and thus has the advantage of significantly improving the durability of the curtain wall device.

1 is a vertical sectional view of a curtain wall according to an embodiment of the present invention.
2 is a cross-sectional view schematically showing the internal configuration of the first shock wave attenuator 120 provided in the curtain wall according to an embodiment of the present invention.
3 is a cross-sectional view schematically illustrating an internal configuration of the first shock wave attenuator 120 provided with the shock wave dispersion unit 126 according to another embodiment of the present invention.
4 is a cross-sectional view schematically illustrating an internal configuration of the shock wave dispersion unit 126.
5 is a cross-sectional view schematically showing a detailed configuration of the shock wave attenuation unit 1263.
FIG. 6 illustrates a second inner frame 112, a third inner frame 113, a second shock wave attenuator 130, a third shock wave attenuator 140, and a fourth shock wave attenuation according to another embodiment of the present invention. It is a vertical cross-sectional view of the curtain wall provided with the part 150.

Before describing the invention in more detail, the terms or words used in the specification and claims are not to be limited to their usual or dictionary meanings, and the concept of terms is appropriately described to best explain the invention. It should be interpreted as meanings and concepts in accordance with the technical spirit of the present invention based on the principle that it can be defined. Therefore, the configuration of the embodiments described herein is only one preferred example of the present invention, and does not represent all of the technical idea of the present invention, various equivalents and modifications that can replace them at the time of the present application It should be understood that there may be

Hereinafter, the configuration of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

1 is a vertical cross-sectional view of a curtain wall according to an embodiment of the present invention, Figure 2 schematically shows the internal configuration of the first shock wave attenuator 120 provided in the curtain wall according to an embodiment of the present invention It is a cross section.

Referring to Figures 1 and 2, the curtain wall device according to an embodiment of the present invention is a beam-shaped outer frame 100 having an open end (101, 102) on one side; A first inner frame (110) provided inside the outer frame (100) and absorbing and dispersing shock waves applied to the outer frame (100) and having an empty beam shape; The first shock wave attenuator 120 is provided between the outer frame 100 and the first inner frame 110 to attenuate the shock wave applied to the outer frame 100 to the first inner frame 110. ); A carbon fiber frame 200 provided to be fitted in a shape corresponding to each of the open ends 101 and 102 of the outer frame 100 and made of high strength carbon fiber; A first shock wave absorbing member 310 provided at the center of the carbon fiber frame 200 to be in contact with the carbon fiber frame 200 and absorbing and attenuating the transmitted shock wave; A first connection member 400 having one end coupled to the first shock wave absorbing member 310; A second connection member 500 having one end fitted to the other end of the first connection member 400 and having an extension 510 at the other end on the left and right sides thereof; Two glass is arranged in parallel spaced apart in parallel with one end of the multilayer glass 600 is provided to be fitted between the expansion portion 510 and the carbon fiber frame 200; A second shock wave absorbing member 320 provided between the multilayer glass 600 and the expansion part 510 to absorb and attenuate the transmitted shock wave; A third shock wave absorbing member 330 provided between the multilayer glass 600 and the carbon fiber frame 200 to absorb and attenuate the transmitted shock wave; A fourth shock wave absorbing member 340 provided between two glasses constituting the multilayer glass 600 to absorb and attenuate the transmitted shock wave; And between the fourth shock wave absorbing member 340 and the other end of the first connection member 400, and both ends thereof contact the second shock wave absorbing member 320 and the third shock wave absorbing member 330, respectively. And a fifth shock wave absorbing member 350 that absorbs and attenuates the transmitted shock wave. The first shock wave damping unit 120 is coupled to one side of the outer frame 100 and formed of a wall and filled with a fluid therein. A cylinder portion 121 having a fluid passage 1211 through which the fluid can move; A piston head 122 provided to reciprocate along an inner wall of the cylinder 121 in the cylinder 121; A piston rod 123 coupled to the piston head 122 at one side of the cylinder portion 121 and a first inner frame 110 at the outside of the cylinder portion 121; A first spring 124 provided inside the cylinder portion 121 and having one end coupled to one side of the piston head 122 and the other end coupled to one inner side of the cylinder 121; And a second spring 125 provided inside the cylinder portion 121 and having one end coupled to the other side of the piston head 122 and the other end coupled to the inside other side of the cylinder portion 121.

As exemplarily shown in FIG. 1, the beam-shaped outer frame 100 constituting the curtain wall device according to the embodiment of the present invention is made of a metal material such as steel, high strength aluminum, or stainless steel. It may have a vertical pillar shape with an empty inside and one side open.

The outer frame 100 serves as a skeleton constituting the curtain wall device, and is directly connected to the bearing wall supporting the load of the building, and various impacts such as seismic waves applied to the bearing wall of the building are directly applied to the curtain wall. It is the part delivered first.

Each of the open ends 101 and 102 of the outer frame 100 is provided to be fitted to each other in a shape corresponding to the shape of these ends, the carbon fiber frame 200 made of high-strength carbon fiber is coupled.

The carbon fiber frame 200 serves to block the shock wave of the bearing wall directly transmitted through the outer frame 100 to the multilayer glass 600, which will be described later, and is made of high-strength carbon fiber according to the external temperature change It is possible to effectively prevent the occurrence of dimensional deformation due to shrinkage or expansion, in particular by adopting a high-strength carbon fiber material has the advantage that can significantly reduce the overall weight of the curtain wall.

On the other hand, when the carbon fiber frame 200 is applied, shock waves such as earthquake waves are generated in the bearing wall and then transmitted to the carbon fiber frame 200 through the outer frame 100, shock and vibration waves generated in various directions It has the advantage of absorbing very efficiently and significantly blocking the transmission of wavelengths.

A center of the carbon fiber frame 200 is provided in contact with the carbon fiber frame 200 is provided with a first shock wave absorbing member 310 to absorb and attenuate the transmitted shock wave.

The first shock wave absorbing member 310 may be manufactured by melting and injecting high-strength carbon fiber and urethane rubber.

The first shock wave absorbing member 310 has a function of absorbing and attenuating a portion of the shock wave transmitted from the carbon fiber frame 200.

The first connection member 400 is fastened to one end of the first shock wave absorbing member 310 by a screw coupling penetrating to the carbon fiber frame 200.

The first connecting member 400 may be formed integrally with the second connecting member 500 to be described later, but between the second connecting member 500 and the carbon fiber frame 200 depending on the thickness of the multilayer glass to be installed. The first connection member 400 and the second connection member 500 may be separately formed to be fitted to each other so as to adjust the spacing.

On the other hand, the other end of the first connection member 400 is provided with a second connection member 500, one end of which is fitted to the other end of the first connection member 400, the other end of the second connection member 500 Expansion unit 510 is provided to the left and right.

The expansion portion 510 is provided to sandwich the laminated glass 600 to be described later between the carbon fiber frame 200.

Between the expansion part 510 and the carbon fiber frame 200, two layers of glass 600 are arranged in parallel and spaced apart.

The multilayer glass 600 is installed to secure a view of the non-bearing exterior wall of the building and to increase the insulation effect.

On the other hand, the inside of the outer frame 100 is provided with a first inner frame 110 having a hollow beam shape in order to absorb and distribute the shock wave applied to the outer frame 100.

Like the outer frame 100, the first inner frame 110 may be made of a metal material such as steel, high strength aluminum, or stainless steel.

The first inner frame 110 is configured in a hollow beam shape, and unlike the outer frame 100, it is preferable that the first inner frame 110 does not have an opening on its side except for an upper end and a lower end.

On the other hand, between the outer frame 100 and the first inner frame 110, the first shock wave attenuator 120 to attenuate the shock wave applied to the outer frame 100 to transmit to the first inner frame 110. ) Is provided with a connection.

2 is a cross-sectional view schematically illustrating an internal configuration of the first shock wave attenuator 120.

The first shock wave attenuation portion 120 is composed of a hydraulic cylinder and a spring member coupled thereto.

Referring to FIG. 2, the first shock wave damping unit 120 is specifically a cylinder 121, a piston head 122, a piston rod 123, a first spring 124, and a second spring 125. It is configured to include).

The cylinder portion 121 is formed in a hollow cylindrical shape, the through-hole is formed on one side so that the piston rod 123 can reciprocate sliding, the periphery of the through-hole to prevent the fluid from coming out to the outside The second packing member (P2) for the purpose is provided.

On the other hand, a fluid passage 1211 is provided inside the wall constituting the cylinder portion 121 to allow the fluid filled in the cylinder portion 121 to move, and fluid is introduced into or discharged from both ends of the fluid passage 1211. The fluid inlet / outlet holes E1 and E2 are formed so as to be possible.

The piston head 122 is provided inside the cylinder part 121 to reciprocate along the inner wall of the cylinder part 121, and the piston head 122 is disposed between the inlet / outlet holes E1 and E2. Round trip.

On the other hand, the circumferential surface of the piston head 122 is provided with a first packing member (P1) to prevent fluid from leaking between the circumferential surface of the piston head 122 and the inner wall of the cylinder portion 121.

The piston rod 123 is coupled to the piston head 122, one side of the piston rod 123 is coupled to the piston head 122 in the cylinder portion 121 and the other side of the piston rod 123 It is coupled to the first inner frame 110 from the outside of the cylinder portion 121.

However, the configuration in which the places where the cylinder portion 121 and the piston rod 123 are respectively coupled with each other should be interpreted as falling within the technical scope of the present invention.

For example, the cylinder 121 and the outer frame 100 are coupled, and the piston rod 123 and the first inner frame 110 are coupled, as well as the cylinder 121 and the first inner frame 110. ) Is coupled and the configuration of the piston rod 123 and the outer frame 100 is also to be interpreted as falling within the scope of the present invention.

As described above, where the cylinder 121 and the piston rod 123 are coupled to each other may be changed, the second shock wave attenuator 130, the third shock wave attenuator 140, and the fourth shock wave attenuator ( The same applies to 150).

On the other hand, the inside of the cylinder portion 121 is provided with a first spring 124 and the second spring 125 consisting of a tension spring or a compression spring.

In particular, when the first spring 124 and the second spring 125 is the tension spring, the second spring 125 is also a tension spring, and the first spring 124 is a compression spring. The second spring 125 is also characterized in that it is composed of a compression spring.

As such, the first spring 124 and the second spring 125 are configured to be the same as the tension spring or the compression spring to each other, thereby exhibiting the effect that the seismic waves can be attenuated very efficiently during the vibration of the curtain hole due to the seismic waves.

One end of the first spring 124 is coupled to one side of the piston head 122 and the other end is coupled to an inner side of the cylinder portion 121.

One end of the second spring 125 is coupled to the other side of the piston head 122 and the other end is coupled to the inside of the cylinder portion 121.

In FIG. 2, for example, when the first spring 124 and the second spring 125 are compression springs, when the piston head 122 is moved to the left by the vibration of the seismic wave, the piston head 122 is left. The energy causing the movement to the air is consumed by the hydraulic pressure generated by the fluid moving slowly through the fluid passage 1211, and at the same time, it is consumed by the elastic energy accumulation by the compression of the first spring 124. By the energy, the piston head 122 is forced to move to the right again.

On the other hand, the piston head 122 as described above is a time for forming a force for moving to the right again, and at this time, the time that the waveform direction of the energy that causes the piston head 122 to move to the left is changed to the opposite direction Since it is different, the energy of the earthquake wave is further attenuated by the divergence of the accumulated elastic energy of the spring.

This principle works the same in the second spring 125 located on the right side of the cylinder, and the shock wave attenuation principle such as seismic waves even when both the first spring 124 and the second spring 125 are constituted by a tension spring. The same applies.

That is, shock waves, such as seismic waves transmitted to the first shock wave attenuator 120 are consumed due to the hydraulic pressure generated by the fluid and compression or expansion of the first spring 124 and the second spring 125 are attenuated very efficiently. .

In particular, when the first spring 124 and the second spring 125 is a compression spring, the efficiency of attenuation is further increased than in the case of the tension spring.

On the other hand, the curtain wall device of the present invention, the spring protection to surround the first spring 124 or the second spring 125 so that the first spring 124 or the second spring 125 is not in contact with the fluid. Pocket portion (C) may be further provided.

One side of the spring protection pocket portion (C) is coupled to the piston head 122 and the other side is coupled to one side or the other side inside the cylinder portion 121.

The spring protection pocket portion (C) may be made of a flexible material.

On the other hand, between the multilayer glass 600 and the expansion portion 510 is provided with a second shock wave absorbing member 320 to absorb and attenuate the transmitted shock wave, the multilayer glass 600 and the carbon fiber frame 200 A third shock wave absorbing member 330 for absorbing and attenuating the shock waves transmitted therebetween is provided, and the fourth shock wave absorbing member 340 for absorbing and attenuating the shock waves transmitted between the two glasses constituting the multilayer glass 600. Is provided, and both ends of the fourth shock wave absorbing member 340 and the other end of the first connection member 400 in contact with the second shock wave absorbing member 320 and the third shock wave absorbing member 330, respectively And a fifth shock wave absorbing member 350 for absorbing and attenuating the transmitted shock wave.

The second shock wave absorbing member 320, the third shock wave absorbing member 330, the fourth shock wave absorbing member 340, and the fifth shock wave absorbing member 350 may be separately configured or all of them may be integrally formed. .

The second shock wave absorbing member 320, the third shock wave absorbing member 330, the fourth shock wave absorbing member 340, and the fifth shock wave absorbing member 350 are manufactured by melting and injecting high-strength carbon fiber and urethane rubber. It is possible to do

Curtain wall device of the present invention is additionally fitted to the expansion portion 510 of the second connecting member 500 has a function to allow the configuration of the remaining curtain wall device except the laminated glass 600 to be protected from the outside of the building. Exposed cover member 800 may be included.

In addition, the curtain wall device of the present invention can apply the sealant 700 to block outside air or moisture from leaking into the gap between the curtain wall device.

3 is a cross-sectional view schematically illustrating an internal configuration of the first shock wave attenuator 120 provided with the shock wave dispersion unit 126 according to another embodiment of the present invention.

4 is a cross-sectional view schematically illustrating an internal configuration of the shock wave dispersion unit 126.

In the curtain wall device according to another embodiment of the present invention, the shock wave transmitted between the cylinder portion 121 and the outer frame 100 or between the piston rod 123 and the first inner frame 110. Shock wave dispersion unit 126 for dispersing in various directions is provided.

Thus, by providing the shock wave dispersion part 126, it is possible to especially attenuate the transverse wave among seismic waves.

The shock wave dispersion unit 126 may include a case part 1261; A plurality of shock wave dispersion barriers 1262 provided to be connected across the inner wall of the case 1261 to disperse the transmitted shock waves; And a shock wave attenuating unit 1263 provided between the plurality of shock wave dispersion partitions 1262 to convert and transmit the shock wave into vibration energy.

The case part 1261 may be made of an aluminum material or a high strength carbon fiber material.

The shock wave dispersion partition wall 1262 is provided to be connected across the inner wall of the case 1261 and has a function of absorbing or dispersing the transmitted shock wave.

5 is a cross-sectional view schematically showing a detailed configuration of the shock wave attenuation unit 1263.

Referring to FIG. 5, the shock wave damping unit 1263 may include a unit case 12613; Two shock wave damping spring members (12632) provided in the unit case (12631); A vibration weight (12633) connected between the two shock wave damping spring members (12632) to convert the wave energy of the shock wave into vibration energy of the weight to attenuate it; And shock absorbing pads 12264 provided on both sides of the unit case 12613 and in contact with an inner wall of the case part 1261.

In particular, the vibration weight 12633 shown in FIG. 5 is subjected to continuous vibration movement by the shock wave damping spring members 12432 provided at both sides when energy is transmitted from the outside, and the energy transmitted through the vibration movement is It can be consumed very quickly.

FIG. 6 illustrates a second inner frame 112, a third inner frame 113, a second shock wave attenuator 130, a third shock wave attenuator 140, and a fourth shock wave attenuation according to another embodiment of the present invention. It is a vertical cross-sectional view of the curtain wall provided with the part 150 and the like.

Referring to FIG. 6, the curtain wall device according to another embodiment of the present invention absorbs and distributes shock waves transmitted from the first inner frame 110 to the inside of the first inner frame 110, and has a hollow beam. A second inner frame 112 having a shape; And a second connection between the first inner frame 110 and the second inner frame 112 to attenuate the shock wave transmitted to the first inner frame 110 and to transmit the shock wave to the second inner frame 112. Shock wave attenuator 130; is provided.

In addition, the curtain wall device according to another embodiment of the present invention absorbs and distributes the shock waves transmitted from the outer frame 100 and the first inner frame 110 in the outer frame 100 and the inside is empty A third inner frame 113 having a beam shape; The third shock wave attenuator 140 is provided between the outer frame 100 and the third inner frame 113 to attenuate the shock wave applied to the outer frame 100 to the third inner frame 113. And a fourth shock wave attenuator 150 connected between the first inner frame 110 and the third inner frame 113 to attenuate the transmitted shock wave.

As such, the second inner frame 112 and the second shock wave attenuator 130 or the third inner frame 113 and the third shock wave attenuator 140 and the fourth shock wave attenuator 150 additionally provided by the seismic wave It is possible to more effectively prevent the curtain wall from being damaged by external shock waves such as the back.

100: outer frame 101, 102: open end
110: first internal frame 112: second internal frame
113: third internal frame 120: first shock wave attenuator
130: second shock wave attenuator 140: third shock wave attenuator
150: fourth shock wave attenuation portion 121: cylinder portion
1211: fluid passage 122: piston head
123: piston rod 124: first spring
125: second spring C: spring protection pocket
E1: fluid inlet / outlet hole E2: fluid inlet / outlet hole
P1: first packing member P2: second packing member
126: shock wave dispersion portion 1261: case portion
1262: shock wave dispersion bulkhead 1263: shock wave attenuation unit
12631: unit case 12632: shock wave damping spring member
12633: vibration weight 12634: shock wave absorption pad
200: carbon fiber frame 310: first shock wave absorbing member
320: second shock wave absorbing member 330: third shock wave absorbing member
340: fourth shock wave absorbing member 350: fifth shock wave absorbing member
400: first connecting member 500: second connecting member
510: expansion portion 600: laminated glass
700: sealant 800: cover member

Claims (8)

An outer frame 100 having a beam shape having an open end 101 and 102 at one side thereof;
A first inner frame (110) provided inside the outer frame (100) and absorbing and dispersing shock waves applied to the outer frame (100) and having an empty beam shape;
The first shock wave attenuator 120 is provided between the outer frame 100 and the first inner frame 110 to attenuate the shock wave applied to the outer frame 100 to the first inner frame 110. );
A carbon fiber frame 200 provided to be fitted in a shape corresponding to each of the open ends 101 and 102 of the outer frame 100 and made of high strength carbon fiber;
A first shock wave absorbing member 310 provided at the center of the carbon fiber frame 200 to be in contact with the carbon fiber frame 200 and absorbing and attenuating the transmitted shock wave;
A first connection member 400 having one end coupled to the first shock wave absorbing member 310;
A second connection member 500 having one end fitted to the other end of the first connection member 400 and having an extension 510 at the other end on the left and right sides thereof;
Two glass is arranged in parallel spaced apart in parallel with one end of the multilayer glass 600 is provided to be fitted between the expansion portion 510 and the carbon fiber frame 200;
A second shock wave absorbing member 320 provided between the multilayer glass 600 and the expansion part 510 to absorb and attenuate the transmitted shock wave;
A third shock wave absorbing member 330 provided between the multilayer glass 600 and the carbon fiber frame 200 to absorb and attenuate the transmitted shock wave;
A fourth shock wave absorbing member 340 provided between two glasses constituting the multilayer glass 600 to absorb and attenuate the transmitted shock wave; And
It is provided between the fourth shock wave absorbing member 340 and the other end of the first connection member 400 and both ends are in contact with the second shock wave absorbing member 320 and the third shock wave absorbing member 330, respectively. And a fifth shock wave absorbing member 350 for absorbing and attenuating the shock wave.
The first shock wave attenuator 120
A cylinder portion 121 having one side coupled to the outer frame 100 and configured as a wall, and having a fluid filled therein and having a fluid passage 1211 through which the fluid can move; A piston head 122 provided to reciprocate along an inner wall of the cylinder 121 in the cylinder 121; A piston rod 123 coupled to the piston head 122 at one side of the cylinder portion 121 and a first inner frame 110 at the outside of the cylinder portion 121; A first spring 124 provided inside the cylinder portion 121 and having one end coupled to one side of the piston head 122 and the other end coupled to one inner side of the cylinder 121; And a second spring 125 provided inside the cylinder portion 121 and having one end coupled to the other side of the piston head 122 and the other end coupled to the inside other side of the cylinder portion 121. Curtain wall device with improved resistance. The method according to claim 1,
The first spring 124 or the second spring 125 surrounds the first spring 124 or the second spring 125 so that the first spring 124 or the second spring 125 is not in contact with the fluid, one side is coupled to the piston head 122 and the other side is Curtain wall device is improved resistance to seismic waves provided with a spring protection pocket portion (C) coupled to one side or the other side inside the cylinder portion 121. The method according to claim 1,
If the first spring 124 is a tension spring, the second spring 125 is also a tension spring,
If the first spring (124) is a compression spring, the second spring (125) is also a compression spring curtain wall device with improved resistance to seismic waves. The method according to claim 1,
The shock wave dispersion unit 126 is provided between the cylinder unit 121 and the outer frame 100 or between the piston rod 123 and the first inner frame 110 to distribute the shock wave in various directions. ,
The shock wave dispersion unit 126 is
Case portion 1261;
A plurality of shock wave dispersion barriers 1262 provided to be connected across the inner wall of the case 1261 to disperse the transmitted shock waves; And
And a shock wave attenuating unit (1263) provided between the plurality of shock wave dispersion barriers (1262) to convert and transmit shock waves transmitted into vibration energy. The method according to claim 4,
The shock wave attenuation unit 1263 is
Unit case 12613;
Two shock wave damping spring members (12632) provided in the unit case (12631);
A vibration weight (12633) connected between the two shock wave damping spring members (12632) to convert the wave energy of the shock wave into vibration energy of the weight to attenuate it; And
And shock absorbing pads (12634) provided on both sides of the unit case (12631) and in contact with the inner wall of the case part (1261). The method according to claim 1,
Inside the first inner frame 110
A second inner frame 112 which absorbs and distributes the shock wave transmitted from the first inner frame 110 and has a hollow beam shape; And
A second shock wave provided between the first inner frame 110 and the second inner frame 112 to attenuate the shock wave transmitted to the first inner frame 110 to be transmitted to the second inner frame 112. Attenuator 130; Curtain wall device having improved resistance to seismic waves. The method according to claim 1,
Inside the outer frame 100
A third inner frame 113 which absorbs and distributes shock waves transmitted from the outer frame 100 and the first inner frame 110 and has an empty hollow beam shape;
The third shock wave attenuator 140 is provided between the outer frame 100 and the third inner frame 113 to attenuate the shock wave applied to the outer frame 100 to the third inner frame 113. ; And
And a fourth shock wave attenuator (150) connected between the first inner frame (110) and the third inner frame (113) to attenuate the transmitted shock waves. The curtain wall device having improved resistance to seismic waves. The method according to claim 1,
Curtain wall device with improved resistance to seismic waves formed integrally with the second shock wave absorbing member 320, the third shock wave absorbing member 330, the fourth shock wave absorbing member 340 and the fifth shock wave absorbing member 350 .

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