KR102213519B1 - Window frame with seismic function - Google Patents

Abstract

The present invention relates to a window sash having an aseismic function. The window sash comprises: horizontal frames with first guide grooves; and vertical frames installed in a direction perpendicular to the horizontal frames, and having second guide grooves. Connecting brackets having fitting grooves formed on the front thereof are coupled to the first and second guide grooves of the horizontal and vertical frames in a sliding manner, insulating material is fitted and fixed to the fitting grooves so that the edge of glass is covered by the insulating material. When vibration occurs in a building due to an earthquake, the glass covered by the insulation material is slid in a vibration direction while the connecting brackets are slid horizontally and vertically along the first and second guide grooves, and thus the impact applied to the glass is reduced. According to the present invention, the window sash allows the connecting brackets to reduce the impact applied to the glass while moving the glass, fixed to be covered by the insulating material, in response to the vibration direction while the connecting brackets are slid laterally and vertically along the first guide grooves of the horizontal frames and the second guide grooves of the vertical frames, and can prevent damage to the glass to block fragments of the glass from flying down a building, thereby significantly reducing a damage rate. In addition, the window sash allows the glass, having moved in response to the vibration direction, to return to the original position by the elastic force of a finishing material (for example, silicone) for finishing the space between the insulating material and the glass, thereby preventing the glass from being detached from the insulating material.

Description

Window frame with seismic function

The present invention relates to a window frame, and more particularly, by inserting and fixing an insulating material covering the glass to the connection bracket, and sliding the connection bracket into the first and second guide grooves of the horizontal frame and the vertical frame, earthquake It relates to a window frame having a seismic function that mitigates the vibration shock applied to the glass while the connection bracket flows to the left, right or up and down when it occurs.

In general, as a building becomes taller or higher, it is required to reduce its own weight and reduce weight.

The reduction in weight of such high-rise buildings leads to a reduction in construction cost by shortening the construction period, materials used, and time, and the most common method of realizing this is a quick and easy curtain wall construction.

Curtain wall refers to a non-bearing wall of a building that functions to protect occupants from the external environment without supporting the building's load. The vertical load applied to the building and the horizontal load caused by wind or earthquake are supported by a frame made of columns and beams, and the curtain wall acts as a curtain to protect the occupants of the building from the external environment.

These curtain walls are constructed by erecting vertical and horizontal curtain wall structures and inserting a glass wall between the curtain wall structures, and the method of enclosing the exterior wall of the building with glass walls and curtain wall windows is concrete or other exterior finishes. Compared to finishing with materials, it is relatively inexpensive, so its use is gradually increasing.

Recently, national policies such as energy saving and efficiency are applied to buildings, and energy efficiency grade certification of buildings is being carried out. As the conventional curtain wall is applied to modern buildings where the window area ratio increases, the energy restrictions and limitations are gradually increasing. .

Patent Document 1 discloses that a window frame having a conventional seismic structure has an inner frame in which both ends are closely stacked to each other to form a concave groove formed on the front side thereof, and one end is inserted into the coupling groove of the inner frame and has one end in front of the coupling groove. It consists of an inner connector exposed to and an insulating material that is fastened to surround the inner connector and covers the edge of the glass.

Here, the inner frame includes an inner bent end bent at one end and positioned in the inner direction, and an outer bent end bent so as to be stacked on the entire surface of the inner bent end and positioned to face the outer direction.

And, in a state in which the inner and outer bent ends are stacked and adhered to each other, they flow according to the external impact applied to the inner frame to provide elastic force.

In other words, when vibration is generated on the inner frame due to an earthquake or a shock is applied to the inner frame due to an external shock, the inner and outer bent ends slide in one direction or the other direction, or correspond to the vibration direction of the building. As they flow to face each other or shift in opposite directions facing each other, it mitigates the vibration of the building and prevents damage or damage to the inner frame.

However, Patent Document 1 as described above is that when vibration occurs in the building due to an earthquake, the front end of the inner connector exposed to the front of the coupling groove is bent or distorted, and the side of the glass is damaged by pressing or hitting the side of the glass, or As the glass is separated from the insulating material fixed to the inner connector due to the sudden shape deformation of the glass, glass or glass fragments may fall under the building, causing secondary damage.In particular, the installation direction of the glass may be changed as the inner connector bends. There is a problem that the reliability of the product is deteriorated because it is twisted, and there is a trouble of replacing or maintaining the inner connector that supports the glass.

KR 10-2082734 B1

The present invention is to solve the above-described problems, and an object of the present invention is to provide a horizontal frame having a first guide groove, which is installed in a direction orthogonal to the horizontal frame to form a second guide groove. A frame is provided, and a connecting bracket having a fitting groove formed in the front of the first and second guide grooves of the vertical and horizontal frames is slidably coupled, and an insulating material is inserted into the fitting groove, so that the frame of the glass is wrapped around the insulating material and covered. By doing so, when vibration occurs in the building due to earthquake, the connecting bracket slides horizontally and vertically along the first and second guide grooves, so that the glass wrapped in the insulating material slides along the vibration direction, thereby reducing the impact applied to the glass. It is to provide a window frame that has a seismic function to mitigate.

In order to achieve the object of the present invention as described above, the window frame having a seismic function according to the present invention is fixedly installed on the open upper and lower surfaces of the building in a hollow tubular shape, and facing each other in the front, but along the longitudinal direction. A horizontal frame having a first guide groove formed horizontally; A vertical frame fixedly installed on the left and right sides of the building in the shape of a hollow tubular body, and having a second guide groove formed vertically along the length direction while facing each other on the front side; A connection bracket slidingly coupled to the first and second guide grooves of the horizontal frame and the vertical frame, moving horizontally and vertically, and forming a fitting groove on the front side; It is fitted into the fitting groove of the connection bracket, the glass is in close contact with both sides of the insulating material to cover the edge of the glass; characterized by consisting of.

In the window frame having a seismic function according to the present invention, the connection bracket is formed relatively shorter than the length of the horizontal frame, the horizontal bracket coupled to the first guide groove of the horizontal frame to flow in the horizontal direction; And a vertical bracket formed to correspond to the length of the vertical frame and coupled to the second guide groove of the vertical frame to flow in a vertical direction.

In the window frame having a seismic function according to the present invention, the vertical bracket has a long hole formed long in a long direction in a front surface corresponding to the second guide groove, and the long hole has one end passing through the long hole, 2 It is fastened through the guide groove, the other end is engaged in the long hole, characterized in that the fastening member for fixing the vertical bracket to the vertical frame is coupled.

In the window frame having a seismic function according to the present invention, the connection bracket is hooked to the first and second guide grooves on the rear surface to prevent the connection bracket from being separated from the first and second guide grooves. It is characterized in that the bending protrusion is further formed.

According to the present invention, while the connection bracket slides left, right, and up and down along the first guide groove of the horizontal frame and the second guide groove of the vertical frame, while flowing the glass fixed to be wrapped in the insulation material to correspond to the vibration direction. , Glass is prevented from being damaged by mitigating the impact applied to the glass, and this glass breakage prevents glass fragments from scattering under the building, reducing the incidence of damage significantly. Glass is returned to its original position by the elastic force of the finishing member (e.g., silicone) that closes between the insulation material and the glass, so there is no fear that the glass may be separated from the insulation material. There is no hassle to do so, and it has the advantage of improving the reliability of the product.

1 is a perspective view showing a window frame having a seismic function according to the present invention.
Figure 2 is an exploded perspective view of Figure 1;
Figure 3 is a perspective view showing a state in which the horizontal bracket is separated from the horizontal frame of the window frame having a seismic function according to the present invention.
Figure 4 is a perspective view showing a state in which the vertical bracket is separated from the vertical frame of the window frame having a seismic function according to the present invention.
5 is a cross-sectional view showing a state in which a horizontal bracket is coupled to a horizontal frame of a window frame having a seismic function according to the present invention.
6 is a cross-sectional view showing a state in which a vertical bracket is coupled to a vertical frame of a window frame having a seismic function according to the present invention.

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

1 to 6, the horizontal frame 100 is fixedly installed on the upper and lower surfaces of the building in the shape of a hollow tubular body, and facing each other in the front, but a first guide groove 101 formed horizontally along the length direction. ) To form.

The horizontal frame 100 is installed in a direction orthogonal to the vertical frame 200.

The horizontal frame 100 supports a load applied to the horizontal bracket 100.

The first guide groove 101 guides the horizontal bracket 301 of the connection bracket 300 to move horizontally to the left and right.

The horizontal frame 100 is such that the bending protrusion 304 of the connection bracket 300 is engaged with the first guide groove 101, so that the connection bracket 300 is separated from the first guide groove 101. Prevent it from becoming.

The vertical frame 200 is fixedly installed on the left and right sides of the building in the shape of a hollow tubular body, and forms a second guide groove 201 that is opposite to each other on the front side and is vertically formed along the length direction.

The vertical frame 200 is installed in a direction orthogonal to the horizontal frame 100.

The second guide groove 201 guides the vertical bracket 302 of the connection bracket 300 to vertically move up and down.

The vertical frame 200 is such that the bending protrusion 304 of the connection bracket 300 is engaged with the second guide groove 201, so that the connection bracket 300 is separated from the second guide groove 201. Prevent it from becoming.

The connection bracket 300 is slidably coupled to the first and second guide grooves 101 and 201 of the horizontal frame 100 and the vertical frame 200 to move horizontally and vertically, and insert a fitting groove 300a on the front side. To form.

The connection bracket 300 moves the insulating material 400 covering the edge of the glass G up, down, left, and right, thereby reducing the impact applied to the glass G.

The connection bracket 300 is formed relatively shorter than the length of the horizontal frame 100, is coupled to the first guide groove 101 of the horizontal frame 100, and a horizontal bracket 301 flowing in the horizontal direction , It is formed to correspond to the length of the vertical frame 200, is composed of a vertical bracket 302 that is coupled to the second guide groove 201 of the vertical frame 200 to flow in the vertical direction.

The horizontal bracket 301 supports and supports the load of the glass G.

The horizontal bracket 301 horizontally moves the glass G to the left and right.

The vertical bracket 302 vertically moves the glass G up and down.

The vertical bracket 302 forms a long hole 302a formed long in a long direction in a front surface corresponding to the second guide groove 201.

The long hole 302a is vertically moved up and down with respect to the fastening member 303 to limit the moving distance of the vertical bracket 302 coupled to the second guide groove 201.

The long hole 302a is prevented from being caught on the outer surface of the fastening portion 303a of the fastening member 303 and moving downward by a predetermined distance or more.

In the long hole 302a, one end passes through the long hole 302a and is fastened through the second guide groove 201, and the other end is caught in the long hole 302a, so that the vertical bracket 302 is attached to the vertical frame. The fastening member 303 fixed to the 200 is coupled.

The fastening member 303 is formed at one end of the fastening part 303a through-fastened to the second guide groove 201 and the fastening part 303a to be caught around the long hole 302a of the vertical bracket 302 It consists of a fixed head (303b).

The fastening portion 303a is formed relatively smaller than the diameter of the long hole 302a, and the head portion 303b is formed relatively larger than the diameter of the long hole 302a.

The connection bracket 300 is caught in the first and second guide grooves 101 and 201 on the rear surface, so that the connection bracket 300 is separated from the first and second guide grooves 101 and 201. To further form a bending protrusion 304 to prevent.

The bending protrusion 304 is caught in the first and second guide grooves 101 and 201 to guide the connection bracket 300 to move up, down, left and right, and at the same time, the connection bracket 300 This prevents separation from the first and second guide grooves 101 and 201.

The insulating material 400 is fitted into the fitting groove 300a of the connection bracket 300, and the glass G is in close contact with both sides to cover the edge of the glass G.

It is preferable that the heat insulating material 400 is formed to extend in a long direction.

The length of the insulating material 400 is preferably formed to be proportional to the width of the glass (G).

The heat insulating material 400 and the glass (G) are connected by a finishing member (S) having an elastic material (eg, silicone) is closed.

The heat insulating material 400 is formed of a polyamide material, and blocks heat or cold air from outside air from being transmitted to the connection bracket 300.

A window frame having a seismic function according to the present invention configured as described above is used as follows.

First, horizontal frames 100 are fixed symmetrically to each other on the upper and lower surfaces of the open rim of the building, and vertical frames 200 are fixed and installed symmetrically to each other on both sides so as to be perpendicular to the horizontal frame 100. .

In addition, the horizontal bracket 301 of the connection bracket 300 is slidably coupled to the first guide groove 101 of the horizontal frame 100, and the vertical bracket is connected to the second guide groove 201 of the vertical frame 200. By sliding the 302, the horizontal bracket 301 and the vertical bracket 302 are exposed to the front end of the horizontal frame 100 and the vertical frame 200.

At this time, the horizontal bracket 301 is formed relatively shorter than the length of the horizontal frame 100, is located in the center of the horizontal bracket 301, and, the vertical bracket 301 is the vertical frame ( It is formed to correspond to the length of 100) and is located in the center of the vertical bracket 302.

In addition, the horizontal bracket 301 and the bending protrusion 304 formed on the rear surface of the vertical bracket 302 are locked and fixed to the first and second guide grooves 101 and 201, and the horizontal bracket 301 and Prevents the vertical bracket 302 from being separated from the first and second guide grooves 101 and 201.

Here, the vertical bracket 302 forms a long hole 302a in the front surface corresponding to the second guide groove 201, and through-fastening the fastening member 303 through the long hole 302a, the vertical bracket ( The 302 may be firmly fixed to the second guide groove 201 of the vertical frame 200.

At this time, the fastening member 303 is composed of a fastening part 303a and a head part 303b, and passing the fastening part 303a through the long hole 302a so as to penetrate through the second guide groove 201, The head 303b is fixed to the periphery of the long hole 302a of the vertical bracket 302, so that the vertical bracket 302 is fixed to the vertical frame 200.

Subsequently, by forcibly inserting the insulating material 400 into the fitting groove 300a formed in the horizontal bracket 301 and the vertical bracket 302 of the connection bracket 300, the insulating material 400 is applied to the horizontal bracket 301 and The vertical bracket 302 is exposed to the front end.

At this time, the horizontal bracket 301 and the vertical bracket 302 are in close contact with the both sides and the top and bottom surfaces of the glass G to the heat insulating material 400 exposed to the front end, and in that state, the horizontal bracket 301 and the vertical bracket A finishing member (eg, silicone) is applied to the gap between 302 and the insulating material 400 to fill the gap.

Then, the edge surface of the glass (G) is in close contact with the insulating material 400, the side surface of the glass (G) is covered by the insulating material 400.

When a vibration shock caused by an earthquake occurs in a building in which a window frame having a seismic function is installed as described above, the vibration of the glass G supported in close contact with the insulating material 400 formed of polyamide material is 1 to the insulating material 400. The difference is absorbed, but the horizontal bracket 301 and the vertical bracket 302 are slidingly moved along the first guide groove 101 and the second guide groove 201, respectively, to alleviate the impact applied to the glass (G). .

That is, while the horizontal bracket 301 is horizontally moved along the first guide groove 101, the insulating material 400 in close contact with the upper and lower surfaces of the glass G is horizontally moved to the left and right, and accordingly, the glass (G) is horizontally moved integrally with the heat insulating material 400, so that left and right shaking applied to the glass G is alleviated by the horizontal bracket 301.

Then, the vertical bracket 302 vertically moves along the second guide groove 201 to vertically move the insulating material 400 in close contact with both sides of the glass G up and down, and accordingly, the glass G ) Is vertically moved integrally with the heat insulating material 400, so that the upper and lower shaking applied to the glass G is alleviated by the vertical bracket 302.

In particular, the long hole 302a formed in the vertical bracket 302 is moved up and down with respect to the fastening member 303 through-fastened to the second guide groove 201, and at this time, the upper end of the long hole 302a Alternatively, the lower end is caught by the fastening portion 303a of the fastening member 303, so that the vertical bracket 302 is blocked from flowing over a predetermined distance up and down.

Here, the finishing member (S) closing between the insulating material 400 and the glass (G) is formed of a material having elasticity, so that the glass (G) is the vertical bracket 302 and the horizontal bracket 301 It guides so that the gap between the insulating material 400 and the glass G is expanded and then restored to its original state while flowing up, down, left, and right.

Therefore, the horizontal bracket 301 and the vertical bracket 302 move horizontally and vertically along each of the first guide groove 101 and the second guide groove 201 at the same time, while the impact applied to the glass G By mitigating, the glass G is prevented from being damaged by impact.

As described above, the connection bracket 300 is coupled to the horizontal frame 100 and the vertical frame 200 so as to be movable horizontally and vertically, and an insulating material 400 that wraps and covers the edge of the glass G in the connection bracket 300 ) By fitting and fixing, the connection bracket 300 slides left, right and up and down along the first guide groove 101 of the horizontal frame 100 and the second guide groove 201 of the vertical frame 200 While the glass (G) fixed so as to be wrapped around the insulating material 400 flows to correspond to the vibration direction, the impact applied to the glass (G) is alleviated to prevent the glass (G) from being damaged, and this glass (G) Damage prevention significantly reduces the incidence of damage by blocking the scattering of glass (G) fragments under the building.

The window frame having a seismic function according to the present invention described above is not limited to the above-described embodiment, and those of ordinary skill in the field to which the present invention pertains without departing from the gist of the present invention claimed in the following claims. It has the technical spirit to the extent that anyone can change it in various ways.

100: horizontal frame 101: first guide groove
200: vertical frame 201: second guide groove
300: connection bracket 300a: fitting groove
301: horizontal bracket 302: vertical bracket
302a: long hole 303: fastening member
303a: fastening part 303b: head
304: bending protrusion 400: insulation
G: Glass S: Finishing member

Claims (4)

A horizontal frame 100 having a hollow tubular shape and fixedly installed on the open upper and lower surfaces of the building and forming a first guide groove 101 opposite to each other in the front but horizontally formed along the longitudinal direction;
It is a vertical frame 200 that is fixedly installed on the left and right sides of the building in a hollow tubular shape and has a second guide groove 201 that is opposite to each other in the front but is vertically formed along the length direction;
The connecting bracket 300 is slidably coupled to the first and second guide grooves 101 and 201 of the horizontal frame 100 and the vertical frame 200, moves horizontally and vertically, and forms a fitting groove 300a on the front side. );
An insulating material 400 that is fitted into the fitting groove 300a of the connection bracket 300 and covers the rim of the glass G so that the glass G is in close contact with both sides thereof;
Consists of,
The connection bracket 300,
A horizontal bracket 301 formed relatively shorter than the length of the horizontal frame 100 and coupled to the first guide groove 101 of the horizontal frame 100 to flow in a horizontal direction;
It is formed to correspond to the length of the vertical frame 200, is coupled to the second guide groove 201 of the vertical frame 200 and flows in a vertical direction, and the front surface corresponding to the second guide groove 201 A vertical bracket 302 having a long hole 302a formed long in the long direction; And
One end of the long hole 302a passes through the long hole 302a and is fastened through the second guide groove 201, and the other end is caught in the long hole 302a, so that the vertical bracket 302 is attached to the vertical frame. A window frame having a seismic function, characterized in that the fastening member 303 fixed to the 200 is coupled. delete delete The method of claim 1,
The connection bracket 300,
A bent protrusion 304 that is caught in the first and second guide grooves 101 and 201 on the rear surface and prevents the connection bracket 300 from being separated from the first and second guide grooves 101 and 201 Window frame having a seismic function, characterized in that further formed.

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