KR102183010B1 - An insulation curtain wall system having seismic performance - Google Patents

Abstract

The present invention relates to an insulation curtain wall system having an earthquake-resistant performance, which is able to install a buffer member which is able to buffer in a space divided by separating a curtain wall frame, to secure an earthquake-resistant performance through a flow space, to integrate a heat exchange blocking material, and to display insulation capacity. As such, the present invention relates to the insulation curtain wall system which comprises: a mainframe which protrudes from a central unit on one side, has a plurality of insertion grooves having an insertion space in an internal side, and has a first hanging ring formed on an upper end and a lower end on one side; a buffer gasket which has an insertion bump on one end to be inserted into and engaged with the insertion groove; a mounting frame which has second hanging rings engaged with the first hanging ring formed on an upper end and a lower end on one end, and has a pair of first rolling bumps formed by protruding from a central unit on the other end by being supported by the buffer gasket; a heat exchange blocking material which has hanging groove units formed on both ends, and is inserted into the first rolling bump on one end to be engaged with the mounting frame; and a cap frame which has a pair of second rolling bumps formed by protruding from one end to be engaged with the hanging groove unit formed on the other end of the heat exchange blocking material. Between the first hanging ring and the second hanging ring is formed a flow space to allow the upward and downward flow between the two.

Description

Insulation curtain wall system with seismic performance {AN INSULATION CURTAIN WALL SYSTEM HAVING SEISMIC PERFORMANCE}

The present invention relates to an insulated curtain wall system having seismic performance, and in detail, a buffer member capable of acting as a buffer is installed in the separated space through the separation of the curtain wall frame, securing the seismic performance through the flow space, and thermal barrier material It relates to an insulated curtain wall system having seismic performance that can exhibit thermal insulation performance through integration of

As the frequency and intensity of earthquakes increase in Korea, there is an urgent need to develop curtain walls that can satisfy dynamic seismic performance criteria similar to earthquake waves for curtain walls, which are non-structural exterior materials of buildings.

According to the Meteorological Administration, the frequency of earthquakes in Korea is gradually increasing, and it has been rapidly increasing since 2016, and it is reported that more than 200 earthquakes occur at a time. In addition, earthquakes of 3 or more have occurred across the country in recent years, and the earthquakes in Gyeongju and Pohang have the greatest frequency.

The largest earthquake in Korea was an intensity of 5.8, which occurred in Gyeongju in September 2016, and the second was an intensity of 5.4, which occurred in Pohang in November 2017, and earthquakes with an intensity of 5.0 or higher occur frequently.

In this situation, seismic design and seismic structure technology are applied to the main structural parts of the building, so that they are prepared and managed, but the curtain walls and windows, which are non-structural elements, have not been sufficiently considered for earthquake resistance. Such curtain walls and windows are deformed when an earthquake occurs, and there is a concern that secondary damage to people and property may occur due to the fall of glass or accessories due to vibration.

In addition, for the insulation performance of the curtain wall, heat transfer of the curtain wall frame must be blocked. To this end, a heat cross-blocking material is installed on the curtain wall frame. Is occurring.

In addition, when installing the curtain wall, the window is mounted after the curtain wall frame is installed. In order to secure a space for installing the window, there is an inconvenience of disassembling a part of the curtain wall frame or installing a glass window before assembling a part. And at this time, the risk of safety accidents existed due to the poor support structure for the windows.

Korean Patent Registration No. 10-1891645 (2018.08.20.)

The present invention has been created to solve the above problems, and an object of the present invention is to provide an insulating curtain wall system having seismic performance capable of exhibiting seismic performance by absorbing vibrations caused by earthquakes.

Another object of the present invention is to provide an insulating curtain wall system having a seismic performance that blocks a heat transfer path by separating the curtain wall frame by a heat insulating member.

Still another object of the present invention is to provide an insulating curtain wall system having seismic performance in which a glass window can be easily mounted after the curtain wall frame is installed.

According to the features of the present invention for achieving the object as described above, the present invention relates to an insulating curtain wall system having seismic performance, wherein a plurality of insertion grooves protruding from a central portion of one side and having an insertion space inward are formed, and one side A main frame having a first locking ring formed at the upper and lower ends; At one end, a buffer gasket having an insertion protrusion inserted into and coupled to the insertion groove is formed; First, a mounting frame having a second locking ring engaged with the first locking ring is formed at the upper and lower ends, supported by the buffer gasket, and a pair of first rolling protrusions protruding from the center of the other end; A thermal barrier member having locking grooves formed at both ends and inserted into the first rolling protrusion at one end and coupled to the mounting frame; And a cap frame having a pair of second rolling protrusions protruding so as to be coupled to a locking groove formed at the other end of the thermal crossing member at one end, and between the first locking ring and the second locking ring in a vertical direction. It is characterized in that it has a flow space to enable flow.

In addition, a plurality of buffer protrusions are formed at the other end of the buffer gasket to prevent slipping of the mounting frame.

At this time, the buffer protrusions of the buffer frame may have gripping protrusions at the upper and lower ends so as to surround the upper and lower ends of the facing portion of the mounting frame and securely grip it.

On the other hand, the cap frame has an inner cap having the pair of second rolling protrusions formed at the other end, bent to one end at a distance from the glass surface, and formed with a bent portion extending, and a front end of one end extending bent of the inner cap And an outer cap having an inserted fastening groove formed therein and an extension supporting portion extending toward a side portion of the inner cap extending bent.

In addition, a blocking cap may be inserted into the fastening groove of the outer cap to surround the tip of one end of the inner cap and block heat transfer between the outer cap and the inner cap.

According to the present invention, there is an advantage in that the safety of the curtain wall is increased by absorbing vibrations caused by earthquakes to exhibit seismic performance.

And according to the present invention, there is an advantage in that the heat insulation performance is improved by blocking the heat transfer path by separating the curtain wall frame by the heat insulating member.

In addition, according to the present invention, not only is it easy to install the window after the curtain wall frame is installed, but the initial window can be stably supported, so that a safety accident that may occur when the window is mounted can be prevented.

1 is a cross-sectional view showing a profile of a curtain wall system according to the present invention;
2 is an exploded view for showing the configuration of a curtain wall system according to the present invention,
3 is a cross-sectional view for explaining the seismic performance of the curtain wall system according to the present invention,
4 is a cross-sectional view for explaining the insulation performance of the curtain wall system according to the present invention,
5 is a cross-sectional view for explaining the ease of construction of the curtain wall system according to the present invention.

Hereinafter, an insulating curtain wall system having seismic performance according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view showing a profile of a curtain wall system according to the present invention, and FIG. 2 is an exploded view showing a configuration of a curtain wall system according to the present invention.

As shown, the curtain wall system according to the present invention largely includes a main frame 10, a buffer gasket 20, a mounting frame 30, a thermal barrier material 40, and a cap frame 50.

The main frame 10 is a frame having a rectangular cross section, and is empty inside, and has an insertion groove 11 and a first hook 12 at one side. A plurality of the insertion grooves 11 protrude from the central portion of one side and have an insertion space inward, and in the present embodiment, two are formed.

In addition, the first locking ring 12 is formed to protrude from the upper and lower ends of one side, and is formed in an approximately'a' shape.

In addition, a support protrusion 13 capable of supporting the reinforcing material R is formed in the inner space of the main frame 10. Due to this support protrusion, the reinforcing member R can be simplified and jamming to the assembly bracket can be prevented.

The buffer gasket 20 serves to securely mount the mounting frame 30 to the main frame 10, and has an insertion protrusion 21 inserted into the insertion groove 11 at one end and the insertion protrusion 21 at the other end. A plurality of buffer protrusions 22 for preventing slipping of the mounting frame 30 are formed. The buffer protrusion 22 may have various configurations, and in this embodiment, it is exemplified that it is configured in the form of a plurality of protrusions formed in parallel in one direction.

In addition, the buffer protrusions 22 of the buffer frame may have gripping protrusions 23 at the upper and lower ends so as to surround the upper and lower ends of the facing portion of the mounting frame 30 and securely grip it.

Mounting frame 30 is to perform a function of absorbing seismic force while the glass window G and its supporting structure are moved within a predetermined range with respect to the main frame 10. For this purpose, the first locking ring 12 ) Is formed with a second locking ring (31). That is, the second locking ring 31 is fitted to the first locking ring 12, and since the flow space S is provided between the first locking ring 12 and the second locking ring 31, the flow space It is possible to flow in the vertical direction with each other through the structure, so that when seismic force is applied, it moves within the flow space (S) and absorbs seismic force, thereby preventing deformation of the support structure and damage to the glass window (G). Here, the'up-down direction' is for explaining based on a curtain wall frame in which the glass window G is installed in the vertical direction as shown in FIG. 1, and if the glass window G is a curtain wall frame installed in the horizontal direction Is changed to'horizontal direction'.

And the mounting frame 30 is supported by the buffer gasket 20 when it is coupled to the first locking ring 12, and is normally coupled to the first locking ring 12 despite the presence of the above flow space. Maintain the position.

In addition, a pair of first rolling protrusions 32 protruding so as to fix one end of the thermal crossing member 40 to be described below are formed at the center of the other end of the mounting frame 30.

The heat cross-blocking material 40 is made of a material capable of blocking heat conduction such as polyamide, and locking grooves 41 are formed at both ends and inserted into the first rolling protrusion 32 at one end, and the mounting frame 30 Is coupled to, and is inserted into the second rolling protrusion 52 of the inner cap 51 at the other end to be coupled to the cap frame 50.

The cap frame 50 is to support the glass window G along with the main frame 10 and the mounting frame 30, and protrudes to be coupled to the locking groove 41 formed at the other end of the thermal barrier member 40 at one end. A pair of formed second rolling protrusions 52 are formed.

The cap frame 50 includes an inner cap 51 in which the pair of second rolling protrusions 52 is formed at the other end, and a bent portion 53 extending at one end is bent at a distance from the glass surface, and An outer cap in which a fastening groove 55 into which the tip of one end extending bent of the inner cap 51 is inserted is formed, and an extension support portion 56 extending toward the side of the inner cap 51 is formed ( 54).

Here, through a configuration in which the inner cap 51 is bent at one end with a distance from the glass surface, even if the inner cap 51 is mounted on the thermal barrier member 40, interference does not occur in the mounting operation of the glass surface. Therefore, it is possible to mount the window glass (G) in a state where the inner cap 51, which is a structure, is stably installed, so that not only the installation of the glass window (G) is easy, but also the initial window (G) can be stably supported. G) Safety accidents that may occur during installation can be prevented.

And when the outer cap 54 is mounted on the inner cap 51, the inner cap 54 not only prevents shaking of the outer cap 54, but also prevents direct heat exchange between the outer cap 54 and the inner cap 51. A blocking cap 57 is provided that surrounds the tip of one end of the cap 51 and is inserted into the fastening groove 55 of the outer cap 54. The blocking cap 57 is also preferably made of a material capable of blocking heat exchange, and may be made of, for example, polyamide.

At this time, in order to prevent separation of the blocking cap 57 and the fastening groove 55 from the inner cap 51, an insertion tip 53a having a relatively increased cross-section is formed at the tip of the inner cap 51 It is desirable to be. In addition, it is preferable that the blocking cap 57 has an inner groove corresponding to the shape of the insertion tip 53a.

Next, a configuration and operation for exerting the main performance of the insulating curtain wall system having seismic performance according to the present invention will be described.

First, as shown in FIG. 3, when the first locking ring 12 of the main frame 10 and the second locking ring 31 of the mounting frame 30 are coupled to exhibit seismic performance, there is A flow space (S) is formed so that it can flow in a vertical direction (as shown in Fig. 3) through the flow space (S). When seismic force is applied, the flow space (S) moves in the direction of the arrow in Fig. 3 By absorbing seismic force, deformation of the support structure and damage to the glass window (G) are prevented.

In addition, since the thermal barrier material 40 is generally made of a polyamide material, even if the window G swings due to an earthquake and contacts the thermal barrier material 40, damage to the glass window G is prevented.

Next, as indicated by the thick dotted line in FIG. 4, in this embodiment, the main frame 10 and the mounting frame 30 side and the cap frame 50 side are separated by a heat cross-blocking material to exhibit heat insulation performance. Block the heat transfer path of In addition, heat transfer between the outer cap 54 and the inner cap 51 by inserting the blocking cap 57 into the fastening groove 55 of the outer cap and inserting the tip of one end of the inner cap 51 into the blocking cap 57 Is blocked. In this way, the heat insulation performance in the present embodiment can be further improved through the structure of blocking the heat transfer path in multiple stages.

On the other hand, construction convenience and safety, as shown in Figure 5, can be achieved by the present embodiment configured to be convenient to mount the glass window (G) on the curtain wall system. That is, through the configuration in which the inner cap 51 is bent at one end with a distance from the glass surface, even if the inner cap 51 is mounted on the heat-intersecting material 40, it does not interfere with the mounting operation of the glass surface. ) Is not only easy to install, but also the initial glass window (G) can be stably supported, so it is possible to prevent safety accidents that may occur when the window (G) is installed.

The rights of the present invention are not limited to the embodiments described above and are defined by what is described in the claims, and that a person with ordinary knowledge in the field of the present invention can make various modifications and adaptations within the scope of the rights described in the claims. It is self-evident.

10: main frame 11: insertion groove 12: first hook
20: buffer gasket 21: insertion protrusion 22: buffer protrusion
23: gripping protrusion
30: mounting frame 31: second locking ring 32: first rolling protrusion
40: thermal intersecting material 41: locking groove
50: cap frame 51: inner cap 52: second rolling protrusion
53: bent portion 53a: insertion tip
54: outer cap 55: fastening groove
56: extension support 57: blocking cap
S: flow space
G: glass window
R: reinforcement

Claims (5)

A main frame 10 having a plurality of insertion grooves 11 protruding from the central portion of one side and having an insertion space inwardly and having a first locking ring 12 formed at one upper and lower end;
At one end, a buffer gasket 20 having an insertion protrusion 21 inserted into and coupled to the insertion groove 11 is formed;
First, at the upper and lower ends, a second locking ring 31 is formed to be engaged with the first locking ring 12, supported by the buffer gasket 20, and a pair of first rolling protrusions 32 protruding at the center of the other end are formed. A mounting frame 30;
A heat intersecting member 40 having locking grooves 41 formed at both ends thereof and inserted into the first rolling protrusion 32 at one end and coupled to the mounting frame 30;
A cap frame 50 having a pair of second rolling protrusions 52 protruding so as to be coupled to the locking groove 41 formed at the other end of the thermal crossing member 40 at one end is formed; includes,
Insulated curtain wall system having seismic performance, characterized in that it has a flow space (S) between the first hook (12) and the second hook (31) so as to be able to flow in the vertical direction.
The method of claim 1,
Insulated curtain wall system having seismic performance, characterized in that a plurality of buffer protrusions (22) are formed at the other end of the buffer gasket (20) to prevent slipping of the mounting frame (30).
The method of claim 2,
Insulation curtain wall system having seismic performance, characterized in that the buffer protrusions 22 of the buffer gasket have gripping protrusions 23 at the upper and lower ends so as to firmly grip the upper and lower ends of the facing portion of the mounting frame 30 .
The method of claim 1,
The cap frame 50 includes an inner cap 51 in which the pair of second rolling protrusions 52 is formed at the other end and a bent portion 53 is formed that is bent and extended at one end at a distance from the glass surface,
An outer cap in which a fastening groove 55 into which the tip of one end extending bent of the inner cap 51 is inserted is formed, and an extension support portion 56 extending toward the side of the inner cap 51 is formed ( 54) Insulated curtain wall system having seismic performance, characterized in that it comprises.
The method of claim 4,
In the fastening groove 55 of the outer cap 54, a blocking cap 57 is inserted that surrounds the tip of one end of the inner cap 51 and blocks heat transfer between the outer cap 54 and the inner cap 51. Insulation curtain wall system having seismic performance, characterized in that.

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