KR102298959B1 - An earthquake-proof and impact-proof apparatus for window frames - Google Patents

Abstract

The present invention relates to a shock absorbing and seismic apparatus for window frames, and more specifically, to a reinforcement structure installed in a space of the window frames installed in a building to absorb an external shock (tensile force, compression force, and the like due to earthquake or building shaking) transmitted to the window frames to protect the window frames from external force. The shock absorbing and seismic apparatus for the window frames of the present invention comprises: two or more unit frames (10) configured to include a main body (100), a shock absorbing unit (200), and an installation unit (300); an absorption unit connecting body (20); and a unit frame connecting body (30).

Description

An earthquake-proof and impact-proof apparatus for window frames

The present invention relates to a shock absorption and earthquake-resistant device for window frames, and more particularly, external shocks (tensile force, compression force, etc., due to earthquake or building shaking) installed in the space of the window frame installed in a building and transmitted to the window frame It is a technology related to a reinforcing structure that absorbs and protects the window frame from external forces.

In the 21st century, due to the development of architectural technology, an unimaginable number of high-rise buildings are being built compared to the past.

In general, high-rise buildings are built by applying not only height but also architectural aesthetics, so they do not simply exist as a part of the buildings built in the city, but are landmarks that represent and symbolize the city in which they are built. It functions as a

However, when a high-rise building is constructed, the risk of safety accidents increases, and once a safety accident occurs, not only a large amount of human life and property damage, but also environmental pollution due to pollution due to the nature of high-rise buildings adversely affects the surroundings. It is important to prevent accidents from occurring.

On the other hand, recently constructed high-rise buildings tend to have large windows so that residents can enjoy the outside view of the building.

At this time, an external shock (tensile force, compression force, etc. due to earthquake or building shaking) is transmitted to the window frame by an earthquake or shaking of the building itself. The building collapses as the building fails to absorb it.

In particular, buildings naturally shake by external forces such as wind and have natural frequencies.

When an earthquake occurs and the natural frequency of a building matches that of the seismic wave, a resonance phenomenon occurs, which amplifies the shaking of the building and, in severe cases, leads to the collapse of the building. The Taco Bridge incident and the earthquake of the Techno Mart building at Gangbyeon Station in Seoul in Korea are famous.

Therefore, in order to prevent the resonance of the building, it is legal to install vibration damping devices in each building of a certain size or larger, and the vibration damping devices have a disadvantage that the installation cost is high.

Therefore, the present invention is installed in the space part of the window frame installed in the building to double absorb the external shock (tensile force, compression force, etc. due to earthquake or building shaking) transmitted to the window frame to protect the window frame from external forces and at the same time to protect the building from external forces. We would like to propose a technology for a reinforcing structure that protects a window frame that is inexpensive and has a simple structure from external forces to prevent the resonance phenomenon of

The following are prior art related to this.

1. Republic of Korea Patent Publication No. 10-1368312 Seismic reinforcing structure of structure by damper bonding 2. Republic of Korea Patent Publication No. 10-1909198 seismic reinforcement steel frame 3. Republic of Korea Patent Publication No. 10-1920417 Reinforced Concrete Frame Seismic Reinforcement Structure

The present invention is to solve the problems of the prior art,

The present invention is a reinforcing structure installed in the space of a window frame installed in a building to protect the window frame from external force by absorbing the external shock (tensile force, compressive force, etc. due to earthquake or building shaking) transmitted to the window frame in a double layer. intended to provide

In order to achieve the above object, the shock absorbing and seismic device for a window frame of the present invention is,

A main body 100, which is a L-shaped H-shaped steel configured to include flanges 120 formed in parallel to both ends of the web 110 and the web 110, and;

At least one shock absorbing part 200 that is coupled to the inner flange 120 of the main body 100 to absorb an external shock;

It includes a link body 310 having one end coupled to the outer flange 120 of the body 100 diagonally at the edge, and an installation angle 320 having a L-shaped cross-section to which the other end of the link body 310 is diagonally coupled. at least two or more unit frames 10 configured to include an installation unit 300 and;

an absorption unit connector 20 formed inside a U-shaped or frame-shaped structure formed by two or more unit frames 10 and to which the shock absorption unit 200 of the unit frame 10 is connected;

It includes a unit frame connector 30 for connecting and coupling the unit frames 10,

When two unit frames 10 are combined by the unit frame connector 30, a C-shaped structure is formed, and when four unit frames 10 are combined, a frame-type structure is formed.

The present invention is a reinforcing structure that is installed in the space of a window frame installed in a building and absorbs an external shock (tensile force, compressive force, etc. due to earthquake or building shaking) transmitted to the window frame to protect the window frame from external force. It provides the effect of preventing damage to windows and buildings caused by resonance.

1 is an overall configuration diagram of the present invention;
Figure 2 is an example of the installation of the present invention 1
3 is an exemplary installation view of the present invention 2
4 is a block diagram of the present invention;
5 is an exploded view of the present invention;
6 is a detailed configuration diagram of the main body of the present invention;
7 is a detailed configuration diagram of the shock absorber of the present invention
Figure 8 is a detailed configuration diagram of the brace of the present invention 1
9 is a detailed configuration diagram of the brace of the present invention 2
10 is a detailed configuration diagram of the brace of the present invention 3
11 is a detailed configuration diagram of the absorption part connector of the present invention
12 is a detailed configuration diagram of a unit frame connecting body of the present invention;

An embodiment of the present invention will be described in detail with reference to the accompanying drawings 1 to 12.

1 to 3, the shock absorbing and seismic device for a window frame of the present invention (hereinafter 'the present invention') is installed in the space part 2 of the window frame installed in a building and transmitted to the window frame ( Since it is a reinforcing structure formed in a C-shape (see Fig. 2) or a frame-type (see Fig. 3) to protect the window frames from external forces by double absorbing tensile and compressive forces caused by earthquakes or building shaking, the external force transmitted to the window frames It is an invention that primarily prevents the damage of windows and doors and absorbs the external force transmitted to the window frame so that the building resonance phenomenon does not occur secondaryly by the external force.

Referring to FIGS. 4 and 5 , the present invention (1) provides at least two or more unit frames 10 configured to include a main body 100, a shock absorbing part 200, and an installation part 300 and an absorbing part connection body. (20) and a unit frame connecting body (30) is configured.

Specifically, the shock absorption and seismic device for a window frame of the present invention, as shown in Figures 4 and 5,

A main body 100, which is a L-shaped H-shaped steel configured to include flanges 120 formed in parallel to both ends of the web 110 and the web 110, and;

At least one shock absorbing part 200 that is coupled to the inner flange 120 of the main body 100 to absorb an external shock;

It includes a link body 310 having one end coupled to the outer flange 120 of the body 100 diagonally at the edge, and an installation angle 320 having a L-shaped cross-section to which the other end of the link body 310 is diagonally coupled. at least two or more unit frames 10 configured to include an installation unit 300 and;

an absorption unit connector 20 formed inside a U-shaped or frame-shaped structure formed by two or more unit frames 10 and to which the shock absorption unit 200 of the unit frame 10 is connected;

It includes a unit frame connector 30 for connecting and coupling the unit frames 10,

When two unit frames 10 are combined by the unit frame connector 30, a C-shaped structure is formed, and when four unit frames 10 are combined, a frame-type structure is formed.

When two unit frames 10 configured to include the body 100, the shock absorbing unit 200, and the installation unit 300 are coupled by the unit frame connecting body 30, as shown in FIG. 2, a C-shape is formed and installed in the space portion 2 formed in the window frame, and when four unit frames 10 are combined by the unit frame connecting body 30, as shown in FIG. 3, the frame-type reinforcing structure is It is formed and installed in the space part 2 formed in the window frame to absorb external shock (tensile force, compression force, etc. due to earthquake or building shaking) transmitted to the window frame to protect the window frame from external forces.

Referring to FIG. 6 , the body 100 is a kind of H-shaped steel formed in a L-shape, and includes a web 110 , a flange 120 , and a coupling groove 130 .

Referring to the upper enlarged view of FIG. 6 , the web 110 points to the central portion of the H-beam, and the flange 120 points to a portion developed at both the upper and lower sides of the H-beam. That is, parallel flanges 120 are formed at both upper and lower ends of the web 110 around the vertical web 110 to constitute the H-shaped body 100 .

In addition, the body 100, which is an H-shaped steel, is a bent shape in a L shape, and the two bodies 100 are coupled by the unit frame connecting body 30 to form a C-shaped reinforcing structure or four main bodies 100 . are combined to form a frame-like reinforcing structure.

At this time, when the main body 100 is installed in the space portion 2 of the window frame installed in the building, an external shock is continuously transmitted to the main body 100 through the window frame, and the main body 100 passes through the window frame. The empty space between the inner flange 120 and the outer flange 120 of the main body 100 may be filled with a filler for stably absorbing the transmitted external shock.

That is, as shown in the lower enlarged view of FIG. 6 , the first installation frame 121 is formed inside the inner flange 120 and the outer flange 120 of the main body 100 , respectively, and both sides of the web 110 . When the filler 40 is filled in (the empty space between the inner flange 120 and the outer flange 120), the first installation frame 121 functions as a skeleton supporting the filler 40, and the filler 40 is a window and door. It absorbs an external shock transmitted to the body 100 through the frame.

The filler 40 may be an elastic shock absorber or concrete. In particular, when concrete is used as a filler, the strength of the body 100 is improved compared to the shock absorber made of an elastic material, so that it has a strong impact resistance to withstand external force. has On the other hand, when a shock absorber made of an elastic material is used as a filler, it has a disadvantage that it is slightly inferior in terms of improving the strength of the main body 100 withstanding external force than concrete, but has a superior advantage than concrete in terms of shock absorbing power of external force. Therefore, the filler 40 may be selected according to the site situation in which the reinforcing structure of the present invention is installed.

Referring to FIG. 6 , a plurality of coupling grooves 130 are formed in the inner flange 120 of the main body 100 formed in the L-shape, and the coupling groove 130 includes a first shock absorbing part 200 to be described later. The coupling protrusion 211 formed on the shock absorbing rod 210 is inserted and coupled.

Here, the reason for forming the plurality of coupling grooves 130 is to allow the insertion position of the coupling protrusions 211 to be inserted and coupled to the coupling groove 130 to be freely adjusted so that the main body corresponds to the direction of the external force transmitted from the window frames. (100) and the first shock-absorbing rod 210 is to be able to freely adjust the coupling position.

As shown in FIG. 1 , the shock absorbing part 200 is coupled to the inner flange 120 of the main body 100 to absorb external shock, and at least one inner flange of the main body 100 . It is coupled to 120 and absorbs external shock (tensile force, compressive force, etc. due to earthquake or building shaking) transmitted from the window frame, as shown in FIG. 7 , the first shock absorbing rod 210, shock absorption It is configured to include a tube 220 and a second shock-absorbing rod 230 .

Referring to FIG. 7 , one side of the first shock absorbing rod 210 is coupled to the inner flange 120 of the main body 100 , and the other end is inserted into the shock absorbing tube 220 to the shock absorbing tube 220 . It is coupled to the shock absorbing spring 221 installed inside.

The first shock absorbing rod 210 is coupled to the inner flange 120 and the shock absorbing spring 221 of the main body 100, and when an external force is transmitted by an external shock, the lower figure of FIG. As such, it is pushed into the shock absorbing tube 220, and in this process, the shock is absorbed (buffered).

At this time, in order to freely adjust the coupling position of the main body 100 and the first shock-absorbing rod 210 in response to the direction of the external force transmitted from the window frame, there is a coupling protrusion on one end of the first shock-absorbing rod 210 . (211) is formed.

The coupling protrusion 211 of the first shock absorbing rod 210 is inserted and coupled to any one of the plurality of coupling grooves 130 formed in the inner flange 120 of the body 100 to be in a state as shown in FIG. 1 .

The reason for forming the plurality of coupling grooves 130 in the inner flange 120 of the body 100 is to determine the insertion position of the coupling protrusion 211 of the first shock-absorbing rod 210 inserted and coupled to the coupling groove 130 . This is so that the coupling position of the main body 100 and the first shock-absorbing rod 210 can be freely adjusted in response to the direction of the external force transmitted from the window frame by allowing it to be freely adjusted.

Referring to FIG. 7 , the shock absorbing tube 220 has a tubular configuration in which a shock absorbing spring 221 is inserted.

At this time, one side of the first shock absorbing rod 210 is inserted into one side of the shock absorbing tube 220 and coupled to the shock absorbing spring 221 , and the second shock is connected to the other side of the shock absorbing tube 220 . One side of the absorbing rod 230 is inserted and coupled to the shock absorbing spring 221 .

The first shock-absorbing rod 210 is coupled to one side of the shock-absorbing spring 221 , and the second shock-absorbing rod 230 is coupled to the other side, so that an external force caused by an external shock is applied to the first shock-absorbing rod 210 . When transmitted through the , it absorbs external shocks through compression and tension processes.

Referring to FIG. 7 , the second shock-absorbing rod 230 is also configured to absorb an external force transmitted together with the first shock-absorbing rod 210 , and the second shock-absorbing rod 230 has one side connected to the absorber. It is coupled to the sieve 20 , and the other side is inserted into the shock absorbing tube 220 and coupled to the shock absorbing spring 221 installed inside the shock absorbing tube 220 .

When the second shock-absorbing rod 230 is coupled to the absorber connecting body 20 and the shock-absorbing spring 221 and an external force is transmitted by an external shock, as shown in the lower figure of FIG. 7 by the external force, It is pushed to the inside of the shock absorbing tube 220, and in this process, the shock is absorbed (buffered).

At this time, in order to freely adjust the coupling position of the absorber connecting body 20 and the second shock-absorbing rod 230 in response to the direction of the external force transmitted from the window frame, one end of the second shock-absorbing rod 230 has A male screw 231 to which the coupling nut is fastened is formed.

The male screw 231 of the second shock-absorbing rod 230 is inserted into or fastened to the guide long hole 24 that is the fastener 22 formed around the absorber connecting body 20 as shown in FIG. 11 . The sphere 22 is inserted into any one of the plurality of coupling spheres 23 and is in a state as shown in FIG. 1 . 1 , the fastener 22 is shown as a plurality of fasteners 23 .

The reason for forming a plurality of coupling spheres 23 or guide elongated holes 24 that are fasteners 22 on the periphery of the absorbent connecting body 20 is inserted into a plurality of couplers 23 or guide elongated holes 24 . The insertion position of the male screw 231 of the second shock-absorbing rod 230 can be freely adjusted to correspond to the direction of the external force transmitted from the window frame, the absorber connecting body 20 and the second shock-absorbing rod 230 In order to be able to freely adjust the bonding position of the

The installation part 300 is configured to support the body 100 and the shock absorbing part 200 to be installed in the space part 2 formed in the window frame of the building as shown in FIGS. 2 and 3, and the link body 310 and It is configured to include an installation angle (320).

Referring to FIG. 8 , the link body 310 is formed of a steel material having a constant thickness and area, and as shown in FIG. 1 , one end of the link body 310 is formed in an L-shape outside of the main body 100 . The flange 120 is diagonally coupled to the edge, and the other end of the link body 310 is coupled to the installation angle 320 .

At this time, in order to reinforce the supporting force against the external force transmitted from the outside, the link body 310 moves from one end to which the main body 100 is coupled to the other end to which the installation angle 320 is coupled, as shown in FIG. 8 . The size of the cross-section is gradually formed to become larger as it goes on.

On the other hand, the link body 310, which is a steel material having a certain thickness and area, is composed of one plate-shaped plate 311 as shown in FIG. 8 or, as shown in FIG. 9, a plate-shaped plate 311. Two sheets can be configured to be spaced apart parallel to each other.

When the link body 310 is formed of one plate 311 , as shown in FIG. 8 , second installation frames 312 are respectively formed on both sides of the plate 311 , and the The filler 40 is filled on both sides to absorb the external shock transmitted through the window frame.

That is, the second installation frame 312 functions as a skeleton supporting the filler 40 , and the filler 40 absorbs an external shock transmitted to the installation unit 300 through the window frame.

The filler 40 may be an elastic shock absorber or concrete. In particular, when concrete is used as a filler, the strength of the installation part 300 is improved compared to the shock absorber made of an elastic material, so that it has a strong impact resistance to withstand external force. It has disadvantages. On the other hand, when a shock absorber made of an elastic material is used as a filler, it has a disadvantage that it is slightly inferior in terms of improving the strength of the installation part 300 that withstands external force than concrete, but has a superior advantage than concrete in terms of shock absorbing power of external force. Therefore, the filler 40 may be selected according to the site situation in which the reinforcing structure of the present invention is installed.

In addition, when the link body 310 is formed of two plates 311 spaced apart in parallel to each other, as shown in FIG. 9 , the two plates 311 are formed to be spaced apart by a predetermined distance, and two plates spaced apart from each other. A second installation frame 312 is formed on the inner surface of the 311, and the filler 40 is filled between the two plates 311 spaced apart from each other to absorb the external shock transmitted through the window frame.

In addition, the link body 310 may be formed of a single prismatic steel pipe having an inner space instead of the plate-shaped plate 311 as shown in FIG. It can also be made to absorb external shock transmitted through the frame.

As shown in FIGS. 2 and 3, the installation angle 320 is formed to have a L-shaped cross section as shown in FIGS. 8 and 9 so that the inner surface is coupled to the link body 310, and the outer surface is coupled to the window frame, The main body 100 is supported to be installed in the space portion 2 of the window frame.

1, 2, and 3, the absorbing part connecting body 20 is formed inside a structure formed in a U-shape or a frame shape by combining two or more unit frames 10 to form a plurality of shock absorbing parts ( 200) is a configuration that is connected and coupled.

Referring to FIG. 11 , the absorbing part connecting body 20 includes a connector body 21 having a hollow rectangular frame shape and a male screw formed at the tip of the second shock absorbing rod 230 of the shock absorbing part 200 ( 231 is configured to include a fastener 22 formed on the circumferential surface of the connector body 21 so that it can be inserted therethrough.

At this time, the fastener 22 formed on the circumferential surface of the connector body 21 is a plurality of coupling holes 23 through which the male screw 231 formed at the tip of the second shock-absorbing rod 230 is inserted therethrough, or a predetermined length. It may be a guide long hole 24 of

In particular, when the fastener 22 is a plurality of couplers 23 , the plurality of couplers 23 are formed at the positions of the plurality of coupling grooves 130 formed in the inner flange 120 of the body 100 . It is formed on the circumferential surface of the connector body 21 at a position corresponding to .

Referring to FIG. 1 , the shock absorbing unit 200 is installed horizontally at a predetermined position between the main body 100 and the absorbing unit connecting body 20 in order to absorb the external shock transmitted from the window frame.

The installation position of the shock absorbing part 200 installed between the main body 100 and the absorbing part connecting body 20 needs to be adjusted so that the installation position can correspond to the direction of the external force transmitted from the window frame, and free shock absorption For adjusting the installation position of the part 200 , the plurality of coupling holes 23 , which are the fasteners 22 , correspond to the formation positions of the plurality of coupling grooves 130 formed in the inner flange 120 of the body 100 . It is to be formed on the circumferential surface of the connector body 21 at a position where

After the installation position of the shock absorbing part 200 is determined, when the male screw 231 formed at the tip of the second shock absorbing rod 230 is inserted through any one of the plurality of couplers 23 into the coupler 23 . By fastening the fastening nut to the male screw 231 , the shock absorbing part 200 is fixedly supported by the absorbing part connecting body 20 .

In addition, as a configuration for adjusting the installation position of the shock absorbing part 200 free even when the fastener 22 is a guide long hole 24 of a certain length, after the installation position of the shock absorbing part 200 is determined, a certain When the male screw 231 formed on the tip of the second shock-absorbing rod 230 is inserted through a predetermined position of the long guide hole 24 that is the length, the shock absorbing unit 200 is absorbed by fastening the coupling nut to the male screw 231 . It is to be fixedly supported by the auxiliary connector 20 .

The unit frame connecting body 30 is a configuration for connecting and coupling the unit frames 10, and as shown in FIGS. 1, 2 and 3, a single coupling plate, which is an integrated connecting body that couples the unit frames 10 without mutual spacing. Alternatively, as shown in FIG. 12, the unit frames 10 may be spaced apart from each other by a predetermined interval and may be a detachable connector capable of absorbing an external shock.

A case in which the unit frame connecting body 30 of the present invention is a detachable connecting body capable of absorbing an external shock while spacing the unit frames 10 at a predetermined interval will be described.

Referring to FIG. 12 , the unit frame connector 30 has an opening formed therein, and the first and second connectors 31 and 32 having a built-in spring and one side are inserted into the first connector 31 and the other The side is configured to include a connecting rod 33 inserted into the second connecting body 32 .

The first connecting body 31 is coupled to the main body 100 of any one unit frame 10 among the two unit frames 10 connected to each other by welding or bolting, and the main body 100 of the other unit frame 10 is connected to each other. ), the second connector 32 is coupled to each other by welding or bolting, and when both sides of the connecting rod 33 are respectively inserted through the openings formed in the first and second connectors 31 and 32, they are interconnected as shown in FIG. 12 . The two unit frames 10 are coupled in a state spaced apart from each other by a predetermined interval.

The two unit frames 10 in a state spaced apart from each other as described above are springs in which the connecting rod 33 is built in the first and second connecting bodies 31 and 32 by an external shock when an external shock is transmitted from the window frame. The two unit frames 10 that are spaced apart from each other while pressing are close to each other, and the distance between them becomes smaller. In this process, external impact is absorbed by the unit frame connecting body 30 .

After all, in the present invention, the external shock is provided by the unit frame connecting body 30, which is a detachable connecting body that allows the above-described shock absorbing unit 200 and the unit frame 10 to be spaced apart by a predetermined interval and to absorb an external shock. It will be absorbed twice.

Although the technical idea of the present invention has been described together with the accompanying drawings, the preferred embodiment of the present invention is illustratively described and does not limit the present invention. In addition, it is a clear fact that anyone with ordinary skill in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

1: Shock absorption and seismic device for window frame
2: space part
10: unit frame
20: absorption part connection body
30: unit frame connector
40: filler
100: body
200: shock absorber
300: installation part

Claims (10)

A shock absorbing and earthquake-resistant device for window frames, comprising:
A main body 100, which is a L-shaped H-shaped steel configured to include flanges 120 formed in parallel to both ends of the web 110 and the web 110, and;
At least one shock absorbing part 200 that is coupled to the inner flange 120 of the main body 100 to absorb an external shock;
One end of the link body 310 is coupled to an oblique angle at the edge of the outer flange 120 of the main body 100, and the other end of the link body 310 includes an installation angle 320 having a L-shaped cross section to which it is diagonally coupled. at least two or more unit frames 10 configured to include an installation unit 300 and;
an absorption unit connector 20 formed inside a U-shaped or frame-shaped structure formed by two or more unit frames 10 and to which the shock absorption unit 200 of the unit frame 10 is connected;
It includes a unit frame connector 30 for connecting and coupling the unit frames 10,
When two unit frames 10 are combined by the unit frame connector 30, a C-shaped structure is formed, and when four unit frames 10 are combined, a frame-shaped structure is formed,

The shock absorbing unit 200,
A first shock absorbing rod 210 having one side coupled to the inner flange 120 of the main body 100 and the other side coupled to the shock absorbing spring 221 installed inside the shock absorbing tube 220, and;
A tubular shock absorbing tube 220 into which a shock absorbing spring 221 is inserted and installed, and
It includes a second shock absorbing rod 230 coupled to one side of the absorbing part connecting body 20, and the other side coupled to the shock absorbing spring 221 installed inside the shock absorbing tube 220,

In order to freely adjust the coupling position of the main body 100 and the first shock-absorbing rod 210 in response to the direction of the external force transmitted from the window frame,
A coupling protrusion 211 is formed at the distal end of the first shock-absorbing rod 210,
A plurality of coupling grooves 130 are formed in the inner flange 120 of the main body 100 so that the coupling protrusions 211 formed at the front end of the first shock-absorbing rod 210 can be inserted and coupled,

In order to freely adjust the coupling position of the absorbing part connecting body 20 and the second shock absorbing rod 230 corresponding to the coupling position of the main body 100 and the first shock absorbing rod 210,
A male screw 231 to which a coupling nut is fastened is formed at the distal end of the second shock-absorbing rod 230 in contact with the absorber connecting body 20,

The absorption part connecting body 20,
A connector body 21 in the shape of a rectangular frame with a hollow formed therein;
and a fastener 22 formed on the circumferential surface of the connector body 21 so that the male screw 231 formed at the tip of the second shock absorbing rod 230 of the shock absorbing part 200 can be inserted therethrough,
The fasteners 22 formed on the peripheral surface of the main body 21 of the connector are a plurality of guide holes 24 of a certain length.
The method according to claim 1,
A first installation frame 121 is formed in the inner side of the inner flange 120 and the outer flange 120 of the body 100, respectively, and the inner flange 120 and the outer flange 120, which are both sides of the web 110, are The empty space is filled with a filler 40 to absorb the external shock transmitted through the window frame,
The filler 40 is a shock absorbing and seismic device for window frames, characterized in that the shock absorbing material or concrete of an elastic material.
delete delete delete The method according to claim 1,
The link body 310 of the installation part 300 is a window frame, characterized in that the cross-sectional size is gradually formed from one end to which the main body 100 is coupled to the other end to which the installation angle 320 is coupled. shock absorber and seismic device.
The method according to claim 1,
The link body 310 of the installation part 300 is formed of one plate-shaped plate 311 or two plate-shaped plates 311 are formed to be spaced apart in parallel to each other. seismic device.
8. The method of claim 7,
When the link body 310 is formed of one plate 311,
A second installation frame 312 is formed on both sides of the plate 311, and a filler 40 is filled on both sides of the plate 311 to absorb an external shock transmitted through the window frame,
When the link body 310 is formed of two plates 311,
The two plates 311 are formed to be spaced apart from each other by a predetermined distance, and a second installation frame 312 is formed on each inner surface of the two plates 311 spaced apart from each other, and between the two plates 311 spaced apart from each other. is filled with a filler 40 to absorb the external shock transmitted through the window frame,
The filler 40 is a shock absorbing and seismic device for window frames, characterized in that the shock absorbing material or concrete of an elastic material.
The method according to claim 1,
The link body 310 of the installation part 300 is formed of a prismatic steel pipe, and a filler 40 is filled in the prismatic steel pipe to absorb external shock transmitted through the window frame,
The filler 40 is a shock absorbing and seismic device for window frames, characterized in that the shock absorbing material or concrete of an elastic material.
delete

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