KR102255116B1 - Combination structure of curtain wall for earthquake resistant - Google Patents

Abstract

The present invention relates to an earthquake proof coupling structure of a curtain wall installed at a coupling part of the curtain wall, comprising: a structural body unit which is installed in an indoor portion of a building structure, and in which a fitting recess is formed at the center of an outdoor portion and hooking recesses are formed at both ends of the fitting recess; a support unit fixedly supported in the fitting recess by fit-coupling; a propping unit installed to be spaced at one side of the support unit (20) for supporting the lower part of a glass plate; and an earthquake proof unit coming in contact with and buffering the lower part of the glass plate. Therefore, the present invention prevents damage or separation of the glass plate due to vibration or impact during an earthquake by installing the earthquake proof unit in the propping portion of the propping unit to buffer the glass plate.

Description

Seismic coupling structure of curtain wall {COMBINATION STRUCTURE OF CURTAIN WALL FOR EARTHQUAKE RESISTANT}

The present invention relates to a seismic coupling structure of a curtain wall, and more particularly, to a seismic resistance of a curtain wall installed at a coupling portion of a curtain wall that connects a horizontal portion installed in a horizontal direction between vertical portions installed adjacent to each other. It relates to the bonding structure.

In general, a curtain wall is a structure installed to support vertical/horizontal loads applied to the building from the outside on the frame of pillars and beams, which are the main structures of the building. It refers to a frame structure, and generally includes a horizontal frame and a vertical frame, and a glass wall made of a multi-layered glass is installed through an adapter member mounted to these frames.

In recent years, as architectural structures have become high-rises, curtain walls are widely used to construct the exterior walls of buildings. Curtain wall refers to a non-bearing partition wall that does not support a load. In order to reduce heat energy loss in terms of energy efficiency, it is essential to develop a curtain wall of high insulation and high airtightness.

However, since these curtain walls are mainly used for high-rise building structures, it is difficult to construct and install horizontal and vertical frames on site, and assembly is not easy, and for a more beautiful appearance, almost the entire surface of the outer wall is treated with a glass finish. Therefore, not only the heat insulation and airtightness are not excellent, but also the cost of cooling and heating increases due to this, and there are various problems such as condensation.

In particular, curtain walls are typically made of plastic or aluminum as the material for windows and doors, but plastics have excellent thermal insulation performance, but the material itself has the disadvantages of large expansion and contraction, weak strength, and low ignition temperature and toxic gas emissions in case of fire. As such, its use is limited.

Therefore, in a situation in which the size of the window is inevitably larger as the recent building structure becomes ultra-high and dense, aluminum with high strength, less expansion and contraction, excellent durability, and higher ignition temperature than existing PVC will be excellent, but the thermal conductivity is high It has the disadvantage of large heat loss due to convection.

However, since a separate seismic system is not applied to the conventional curtain wall, when an external force such as external shock, shaking, vibration, or earthquake is transmitted to a conventional window, for example, when subjected to a horizontal load, the glass will not break. Or the frame is damaged.

In addition, seismic design is applied to new buildings before construction, and a method of reinforcing the entire building is used, but this method is complicated and expensive, and the seismic performance of the curtain wall itself is limited. There are limits to preventing breakage.

In general, a curtain wall is a structure installed to support vertical and horizontal loads applied to the building from the outside on the frame of pillars and beams, which are the main structures of the building. It refers to a frame structure, and generally includes a horizontal frame and a vertical frame, and a glass wall made of a multi-layered glass is installed through an adapter member mounted to these frames.

As the material of the curtain wall as described above, a metal plate, glass, block, and precast concrete are used. Such curtain walls are often used in high-rise or high-rise buildings, and light materials are used to reduce the load. In recent years, due to the characteristics of glass, that is, transparency, openness, reflectivity, and relatively light weight, multi-layered glass is widely used as a curtain wall.

The use of aluminum for the curtain wall frame is to reduce the load, and aluminum has a problem in absorbing vertical/horizontal displacement and inter-floor displacement of a building due to wind and earthquakes as well as high extrusion cost.

In addition, such curtain walls are widely applied and installed in high-rise or high-rise buildings. In particular, in buildings with a height of 100m or more, scaffolding is difficult to assemble, so a method of attaching prefabricated exterior wall panels is often used. Construction is a structural part that composes the outer circumferential wall of a building, and the outer circumferential wall is formed by a method of attaching the curtain wall structure with fasteners fixed to the slab.

The curtain wall can be produced in a factory so that it can be rationalized by mass production and can be produced as a standardized panel. In particular, it also shows a functional configuration for exterior decoration that represents the exterior of a building.

That is, even by external forces such as wind pressure and earthquake, relative displacement between the two adjacent layers, that is, inter-layer displacement, is irregularly generated, which causes serious adverse effects on the outer wall panel of the curtain wall structure.

However, since the entire load of the curtain wall structure is supported by the anchor connecting hardware fixed on the slab, there has been no research on wind pressure and vibration caused by earthquakes or efforts to improve the seismic performance. The occurrence of earthquakes with a high degree of earthquakes requires seismic performance windows in the curtain wall field as well.

In particular, in the conventional curtain wall, since the exposed bar is configured to support the load of the glass using a separate support structure installed on the upper side of the horizontal frame, a space is formed on the lower side of the glass to conduct heat conduction by convection, so the insulation performance is improved. There is a disadvantage in that the internal structure is complicated and the construction is complicated, and the construction cost is increased because a separate insulation structure must be taken to prevent this.

In addition, when an earthquake occurs, the torsion shock or shock wave through the frame is directly transmitted to the glass, so that the glass without elastic force is damaged, or the support structure that fixes the glass is deformed, so that the glass may fall off or be damaged, so there is a disadvantage in safety.

Korean Patent Registration No. 10-2082734 (February 28, 2020) Korean Patent Registration No. 10-1848854 (April 13, 2018) Korean Patent Registration No. 10-1848857 (April 13, 2018)

The present invention was conceived to solve the conventional problems as described above, and a curtain wall capable of preventing breakage or separation of the glass plate due to vibration or impact during an earthquake by installing an earthquake-resistant part on the support part of the support to buffer the glass plate. Its purpose is to provide a seismic coupling structure.

In addition, the present invention can be applied to curtain walls such as cap bars and the like while facilitating coupling between the support part and the finish by closing the outdoor part of the support part by engaging and coupling the finish part to the outdoor part of the support part. Another object is to provide a seismic coupling structure for a curtain wall that is present.

In addition, the present invention is provided with a locking piece, a supporting piece and a supporting protrusion as a supporting part, thereby facilitating the locking between the structure part and the supporting part, and at the same time reinforcing the supporting force for the lower part and the side of the glass plate. Another object is to provide a bonding structure.

In addition, the present invention provides an intermediate piece, a lower body piece, an upper body piece, a coupling groove, and a support groove as an earthquake-resistant part, thereby facilitating the coupling between the support part and the earthquake-resistant part, and at the same time buffering the lower and side surfaces of the glass plate together to prevent an earthquake. Another object is to provide a seismic coupling structure of a curtain wall that can improve seismic performance and reinforce support for glass plates in case of fire.

In addition, the present invention distributes shocks or vibrations concentrated only on a part of the support and earthquake-resistant parts to a plurality of points by protruding a plurality of buffer pieces that are in line or point contact with the lower part of the glass plate to support buffering and support from the upper part of the upper body piece. Another object is to provide a seismic coupling structure of a curtain wall capable of improving seismic performance and impact resistance by buffering it.

The present invention for achieving the above object is a seismic coupling structure of the curtain wall installed on the coupling portion of the curtain wall, installed on the indoor portion of the building structure, the fitting groove is formed in the center of the outdoor portion, the A structure portion 10 having locking grooves formed at both ends of the fitting grooves; A support part 20 which is coupled to the outdoor part of the structure part 10 and is fixedly supported by fit-to-fit in the fitting groove; A support part 30 which is engaged with the locking groove of the structure part 10 and is spaced apart from one side of the support part 20 to support the lower part of the glass plate; It characterized in that it comprises a; fit and coupled to the circumferential portion of one end of the support portion 30, the earthquake-resistant portion 40 to contact and buffer the lower portion of the glass plate.

In addition, the present invention is fitted to the outdoor portion of the support portion 20 is coupled, the closing portion 50 for closing the outdoor portion; characterized in that it further comprises.

The support part 30 of the present invention includes a locking piece engaged with the locking groove of the structure part 10; And a support piece extending at one end of the locking piece to support a lower portion of the glass plate. The support part 30 of the present invention further comprises a support protrusion that is bent on an outdoor portion of the support piece to support a side surface of the glass plate.

The earthquake-resistant part 40 of the present invention comprises: an intermediate piece for buffering by contacting and supporting the tip of the support part 30; A lower body piece extending from the lower portion of the intermediate piece to support and support the lower surface of the support portion 30 to buffer; An upper body piece extending over the upper portion of the intermediate piece and supporting the upper surface of the support portion 30 to buffer the upper body portion; And a coupling groove formed between the lower body piece and the upper body piece, and into which the support part 30 is fitted.

The earthquake-resistant part 40 of the present invention further comprises a support groove bent at an outdoor portion of the coupling groove to support the support part 30. The seismic part 40 of the present invention further comprises a buffer piece protruding from a plurality of upper portions of the upper body piece to support buffering by in line or point contact with the lower portion of the glass plate.

As described above, the present invention provides an effect of preventing breakage or separation of the glass plate due to vibration or impact during an earthquake by installing an earthquake-proof part on the support part of the support part to buffer the glass plate.

In addition, by closing the outdoor part by fastening and coupling the finishing part to the outdoor part of the support part, it is possible to close the outdoor part of the support part to facilitate the connection between the support part and the finish part, and at the same time, it has the effect that can be applied to curtain walls such as cap bars. to provide.

In addition, by providing a locking piece, a supporting piece, and a supporting protrusion as a supporting part, it is possible to facilitate engaging between the structure part and the supporting part, and at the same time, it provides an effect of reinforcing the supporting force for the lower and side surfaces of the glass plate.

In addition, by providing the middle piece, the lower body piece, the upper body piece, the coupling groove and the support groove as the seismic part, it facilitates the coupling between the support part and the seismic part, and at the same time buffers the lower and side surfaces of the glass plate together to improve seismic performance in case of an earthquake. It improves and provides the effect of reinforcing the support for the glass plate in case of fire.

In addition, by forming a plurality of cushioning pieces protruding from the upper part of the upper body piece to support buffering by line or point contact with the lower part of the glass plate, shock or vibration concentrated only in the support part and the earthquake-proof part is distributed to a plurality of points and buffered. It provides an effect that can improve seismic performance and impact resistance.

1 is a block diagram showing a seismic coupling structure of a curtain wall according to an embodiment of the present invention.
Figure 2 is a cross-sectional view showing a seismic coupling structure of the curtain wall according to an embodiment of the present invention.
3 is a block diagram showing a support portion and a seismic portion of the seismic coupling structure of the curtain wall according to an embodiment of the present invention.
Figure 4 is an exploded view showing the support and the earthquake-resistant portion of the seismic coupling structure of the curtain wall according to an embodiment of the present invention.
Figure 5 is a cross-sectional view showing another example of the seismic coupling structure of the curtain wall according to an embodiment of the present invention.
6 is a cross-sectional view showing another example of a support portion and a seismic portion of the seismic coupling structure of the curtain wall according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a configuration diagram showing a seismic coupling structure of a curtain wall according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing the seismic coupling structure of the curtain wall according to an embodiment of the present invention, and Figure 3 is the present invention Fig. 4 is an exploded view showing the support part and the seismic part of the seismic coupling structure of the curtain wall according to an embodiment of the present invention, Figure 5 is a cross-sectional view showing another example of the seismic coupling structure of the curtain wall according to an embodiment of the present invention, Figure 6 is a different support and the seismic part of the seismic coupling structure of the curtain wall according to an embodiment of the present invention It is a cross-sectional view showing an example.

As shown in Figures 1 to 4, the seismic coupling structure of the curtain wall according to the present embodiment, the structure portion 10, the support portion 20, the support portion 30, the earthquake-resistant portion 40 and the closing portion 50 ), which is installed in the vertical direction and is installed at the coupling part of the curtain wall such as a hidden bar and a cap bar that connects the horizontal part 200 installed in the horizontal direction between the vertical parts 100 installed adjacent to each other. It is a seismic coupling structure.

The structure part 10 is a frame member that is installed on the indoor part of the building structure and has a fitting groove formed in the center of the outdoor part and a locking groove formed at both ends of the fitting groove, respectively, the structure 11, the fitting groove 12 , Consisting of a locking groove (13).

The structure 11 is a structure installed on an interior part of a building structure, is made of a frame having a square cross section, and is made of a metal material such as aluminum to constitute a frame installed on the interior part of a curtain wall.

The fitting groove 12 is a fitting member that is formed in the center of the outdoor part of the structure 11 and is fitted with the support part 20, and the fixing jaws protrude from both ends of the fitting groove 12 to form the support part 20 Is fixed and supported here.

The locking groove 13 is a groove member that is recessed at both ends of the outdoor portion of the structure 11 to engage the receiving portion 30, and is recessed inwardly at both ends of the fitting groove 12 to support the receiving portion 30 One end of) is engaged and fixed.

The support part 20 is a support member that is coupled to the outdoor part of the structure part 10 and is fixedly supported by fitting and coupling into the fitting groove 12 of the structure part 10, and consists of a support body, a fitting protrusion, and a coupling protrusion. .

The support is a fixed support member that is coupled to one of the outdoor parts of the structure part 10, and is inserted in multiple stages by pressing the crimping pieces protruding from both ends of the indoor part of the support while being fitted to the fitting 12. Fitted and fixed.

The fitting protrusion is a coupling member protruding from the interior portion of the support body, and is fitted and coupled to the fitting groove 12 of the structure portion 10 to fix and support the support body to the outdoor portion of the structure portion 10.

The coupling protrusion is a coupling member protruding from the outdoor portion of the support, and is fitted and coupled to the fixing groove formed on the indoor portion of the closing portion 50 to fix the closing portion 50 to the outdoor portion of the support.

The support part 30 is a support member that is engaged and coupled to the locking groove of the structure part 10 and is spaced apart from one side of the support part 20 to support the lower part of the glass plate, as shown in FIGS. 4 and 5. It consists of a piece (31), a support piece (32), a support protrusion (33).

The locking piece 31 is a locking member that is engaged with the locking groove 13 of the structure part 10, and is inserted obliquely into the locking groove 13 of the structure part 10 and is engaged by rotation downward. Or is inserted by sliding in the longitudinal direction and engaged with it, and fixedly supported by compression of a pressing piece formed on the outdoor portion of the locking groove 13.

The support piece 32 is a support member extending at one end of the locking piece 31 to support the lower portion of the glass plate 300, and is preferably formed in a flat plate shape to support the lower portion of the glass plate 300.

The support protrusion 33 is a protrusion member that is bent at the outdoor portion of the support piece 32 to support the side surface of the glass plate 300, and supports one side of the glass plate 300 by the support protrusion 33 The lower portion of the glass plate 300 is supported by the support piece 32 to minimize separation and vibration of the glass plate 300 during an earthquake.

The seismic part 40 is an earthquake-resistant member that is fitted to the circumference of one end of the support part 30 to contact the lower part of the glass plate 300 to buffer the shock or vibration. It is made of a member, and as shown in Figs. 4 to 6, it consists of an intermediate piece 41, a lower body piece 42, an upper body piece 43, a coupling groove 44, and a buffer piece 45.

The intermediate piece 41 is a buffer member that supports and buffers one end of the outdoor part of the receiving part 30, and buffers the tip of the outdoor part of the receiving piece 32 of the receiving part 30 to buffer the receiving piece 32 Is buffered in the horizontal direction.

The lower body piece 42 is a buffer member that extends to the lower portion of the intermediate piece 41 to support and support the lower surface of the support part 30 to buffer the lower surface of the support piece 32 of the support part 30. By buffering, the support piece 32 is buffered in the vertical direction.

The upper body piece 43 is a buffer member that extends on the upper portion of the intermediate piece 41 to support and support the upper surface of the support part 30 to buffer the upper surface of the support piece 32 of the support part 30. By buffering, the support piece 32 is buffered in the vertical direction.

The coupling groove 44 is a groove member formed between the lower body piece 42 and the upper body piece 43 so that the support piece 32 of the support portion 30 is fitted and coupled, and the outside of the coupling groove 44 Of course, it is possible that the support groove 44a is bent upward so that the support protrusion 33 of the support part 30 is fitted and supported at the site.

The buffer piece 45 is a buffer member protruding from the upper part of the upper body piece 43 to support buffering by making a line contact or point contact with the lower portion of the glass plate 300. A plurality of vibrations or shocks concentrated only at some points of the support part 30 and the earthquake-proof part 40 by buffering at a point can be distributed to improve seismic performance and shock resistance, while maintaining durability for a long period of time.

The finishing part 50 is a finishing member that is engaged and coupled to the outdoor part of the support part 20 to close the outdoor part of the support part 20, and is combined so that a coupling protrusion protruding from the outdoor part of the support part 20 is coupled. A groove is formed in the interior.

As described above, according to the present invention, by installing an earthquake-proof part on the support part of the support part to buffer the glass plate, it is possible to prevent damage or separation of the glass plate due to vibration or impact during an earthquake.

In addition, by closing the outdoor part by fastening and coupling the finishing part to the outdoor part of the support part, it is possible to close the outdoor part of the support part to facilitate the connection between the support part and the finish part, and at the same time, it has the effect that can be applied to curtain walls such as cap bars. to provide.

In addition, by providing a locking piece, a supporting piece, and a supporting protrusion as a supporting part, it is possible to facilitate engaging between the structure part and the supporting part, and at the same time, it provides an effect of reinforcing the supporting force for the lower and side surfaces of the glass plate.

In addition, by providing the middle piece, the lower body piece, the upper body piece, the coupling groove and the support groove as the seismic part, it facilitates the coupling between the support part and the seismic part, and at the same time buffers the lower and side surfaces of the glass plate together to improve seismic performance in case of an earthquake. It improves and provides the effect of reinforcing the support for the glass plate in case of fire.

In addition, by forming a plurality of cushioning pieces protruding from the upper part of the upper body piece to support buffering by line or point contact with the lower part of the glass plate, shock or vibration concentrated only in the support part and the earthquake-proof part is distributed to a plurality of points and buffered. It provides an effect that can improve seismic performance and impact resistance.

The present invention described above may be implemented in various other forms without departing from the technical idea or main characteristics thereof. Therefore, the above embodiments are merely illustrative in all respects and should not be interpreted as limiting.

10: structure part 20: support part
30: support portion 40: earthquake-proof portion
50: end

Claims (7)

As a seismic coupling structure of the curtain wall installed on the coupling part of the curtain wall,
A structure part 10 installed on an indoor part of a building structure, having a fitting groove formed at the center of the outdoor part, and having locking grooves at both ends of the fitting groove;
A support part 20 which is coupled to the outdoor part of the structure part 10 and is fixedly supported by fit-to-fit in the fitting groove;
A support part 30 which is engaged with the locking groove of the structure part 10 and is spaced apart from one side of the support part 20 to support the lower part of the glass plate;
Including; an earthquake-resistant part 40 that is fitted and coupled to the circumference of one end of the support part 30 to contact and buffer the lower part of the glass plate
The seismic part 40,
An intermediate piece for buffering by contacting and supporting the tip of the support part 30;
A lower body piece extending from the lower portion of the intermediate piece to support and support the lower surface of the support portion 30 to buffer;
An upper body piece extending over the upper portion of the intermediate piece and supporting the upper surface of the support portion 30 to buffer the upper body portion;
A coupling groove formed between the lower body piece and the upper body piece to which the support part 30 is fitted; And
And a buffer piece protruding from the upper portion of the upper body piece to support buffering by line or point contact with the lower portion of the glass plate. The method of claim 1,
The seismic coupling structure of the curtain wall, characterized in that it further comprises a; a closing portion (50) that is engaged and coupled to the outdoor portion of the support portion (20) to finish the outdoor portion. The method of claim 1,
The support part 30,
A locking piece engaged with the locking groove of the structure part 10; And
Seismic coupling structure of the curtain wall comprising a; support piece extending to support the lower portion of the glass plate at one end of the locking piece. The method of claim 3,
The support part 30,
A support protrusion bent on the outdoor portion of the support piece to support the side surface of the glass plate; a seismic coupling structure of a curtain wall, characterized in that it further comprises delete The method of claim 1,
The seismic part 40,
A support groove bent in the outdoor portion of the coupling groove to support the support portion 30; the seismic coupling structure of the curtain wall further comprising. delete

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