KR20140136654A - Balcony System Window - Google Patents

Abstract

A balcony system window according to an aspect of the present invention comprises: an outer window including a lower fixed window formed on the lower part to block the outside air, an upper fixed window formed on the upper part of the lower fix window and formed in the half of the horizontal length, a sunshade mounted to the outdoor side of the upper fixed window to form a hollow layer, and a slide window capable of moving to the indoor side of the upper fixed window; an inner window to dually block a heat bridge with the outer window by providing a first inner window formed in the inner surface of the outer window and a second inner window capable of moving to the indoor side of the first inner window; and an azone dividing the outer window and the inner window and forming an insulation line.

Description

Balcony System Window {Balcony System Window}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a balcony system window, and more particularly, to a balcony system window using a window provided on a balcony as a lift-up sliding window to prevent heat bridging between outdoor and indoor.

Generally, apartment houses, multi-family houses, multi-family residences, etc., have a balcony (or veranda) built in front or back, or both front and back, for each household. Also, in general buildings, a balcony for the surrounding view is installed.

In addition, as the enforcement ordinance of the Building Code has recently been revised, it is possible to legally expand the apartment balconies, thereby increasing the interest of builders and consumers in extending the balconies. Accordingly, the market demand of the improved window system . Here, the system window means a window that can be opened or closed in a slightly open or tilted manner in addition to simply opening by a sliding door.

Therefore, window makers have introduced double and triple window systems to develop insulation windows that reinforce insulation and condensation.

These insulating windows have been developed for insulation and soundproofing, and are widely used in residential apartments, houses or offices. Such a heat insulating window is generally composed of a window frame which is partially fixed on a wall and a window frame which is coupled to the window frame and moves in a predetermined range. Aluminum or PVC is used as the material thereof, and an air layer having a low thermal conductivity is formed in the interior thereof to increase the heat insulation efficiency and to form a heat bridge block for heat insulation on a window frame or a window frame. In particular, aluminum-made windows are essential for public buildings because they do not emit harmful gases even in the event of a fire, and they are widely used in luxury homes.

However, the aluminum window is made of aluminum having high thermal conductivity, so that even if an air layer is formed in the aluminum window, the inside and outside heat can easily be transmitted.

It is an object of the present invention to provide a balcony system window which is installed on a balcony and blocks thermal conductivity of an aluminum window with a high thermal conductivity.

According to an aspect of the present invention, there is provided a window system for a balcony system, the window system comprising: a lower fixture window formed at a lower portion thereof to block outside air; a top fix window formed at an upper portion of the lower fixture window, An outer window provided on an outdoor side surface of the upper fix window to form a hollow layer, an outer window having a slide window movable toward the indoor side of the upper fix window, a first inner window formed on an inner surface of the outer window, And a second window which is movable to the inside of the window, the window being separated from the window by the double window, and the azon for distinguishing the window from the window and for forming the adiabatic line.

The upper fix window may include the azon at a portion where the upper fix window is coupled with the frame to form an adiabatic line.

A gasket may be formed on the upper fix window and the slide window to prevent outside air from entering the window through the window.

At the lower end of the outdoor side of the slide window, a polyamide pipe may be provided along the horizontal length direction for blocking outdoor and outdoor bridges.

Each of the inner windows may be formed of a double window frame for interrupting heat bridging with the outdoor side and may include polyamide between the window frames.

When the inner window is closed, a portion where the first inner window and the second inner window are in contact may be provided so as to intersect with each other to increase the heat insulation effect.

A hollow frame formed on an air layer formed between the outer window and the inner window, the hollow frame being separated from the outdoor frame and the inner window; And an indoor frame divided by the indoor unit.

The outdoor frame may include an auxiliary frame having a rail on which the slide window moves, the auxiliary frame fixing the bottom fix window.

According to the window system of a balcony system according to the present invention, azon and polyamide are provided in a frame of an aluminum window to prevent the occurrence of heat bridging between the outdoor and the indoor, thereby preventing heat insulation and condensation.

1 is a front view showing a window of a balcony system according to an embodiment of the present invention;
2 is a longitudinal sectional view showing a window of a balcony system according to an embodiment of the present invention;
Figs. 3 to 4 are longitudinal sectional views showing end portions of a longitudinal sectional view shown in Fig. 2; Fig.
Fig. 5 is a longitudinal sectional view showing the subframe of the longitudinal sectional view shown in Fig. 2; Fig.
6 is a cross-sectional view illustrating a window of a balcony system according to an embodiment of the present invention;
Figs. 7 to 8 are cross-sectional views showing the ends of the cross-sectional view shown in Fig. 6; Fig.
Figure 9 is a cross-sectional view of the subframe of the cross-sectional view shown in Figure 6;
10 is an exemplary view showing simulation analysis results of modeling a window system of a balcony system according to an embodiment of the present invention.

Hereinafter, a window system of a balcony system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a front view showing a window of a balcony system according to an embodiment of the present invention.

As shown in FIG. 1, a window system of a balcony system according to an embodiment of the present invention includes an outdoor window 100 to prevent outdoor air from entering the balcony, an inner window 200 to prevent indoor air from being released to the interior, And a frame 300 for fixing the inner window 200 and the inner window 100.

As shown in (a) of FIG. 1, the window 100 may include a lower fixture window 110, and an upper fixture window 120 and a lower fixture window 120, (Not shown).

The lower fixture window 110 may be fixed without movement and a separate frame 300 may be formed at the center of the lower fixture window 110 in the horizontal direction to divide the lower fixture window 110.

The upper fixture window 120 formed in a half of the horizontal direction of the upper fixture window 120 may be installed on the left or right side as viewed from the front as shown in FIG.

The slide window 130 may be formed as a lift-up sliding window that is lifted up to move to the inside of the upper fix window 120.

The inner window 200 includes a first inner window 210 formed as an outer side surface and a second inner window 210 formed as a slide window 130 and sliding on the rear surface of the first inner window 210 as shown in FIG. 220).

The frame 300 may be formed of a high thermal aluminum that can prevent local heat loss and minimize the occurrence of condensation.

FIG. 2 is a longitudinal sectional view showing a window system of a balcony system according to an embodiment of the present invention, FIGS. 3 to 4 are longitudinal sectional views showing end portions of the vertical sectional view shown in FIG. 2, Fig. 7 is a longitudinal sectional view showing an auxiliary frame of Fig.

As shown in FIGS. 2 to 5, the balcony system window according to an embodiment of the present invention includes an outdoor window 100 for blocking the outside air, an inner window (not shown) formed on the inner side of the window 100, 200 and a frame 300 for fixing the window 100 and the window 200.

The balcony window system is formed on the balcony, and the window 100 is in contact with the outdoor air outside, so that a heat insulation line should be formed to prevent outdoor air from entering the room.

The upper and lower fixtures 100 and 110 may include a lower fixture window 110 and a lower fixture window 110. The upper fixture window 120 is formed on the lower fixture window 110, An eyelash 140 provided on the outdoor side of the window 120 to form a hollow layer and a slide window 130 movable toward the indoor side of the upper fix window 120. [

The lower fixture window 110 may be formed as a double window to prevent the outside air from entering the interior.

The lower portion of the lower fixture window 110 is fixed to the frame 300 and may include a lower fixture window frame 111 to prevent external air from entering the interior. The upper portion of the lower fixture window 110 may be inserted into the lower portion of the auxiliary frame 340 shown in FIG.

The upper fix window 120 may be fixed to the upper portion of the auxiliary frame 340 and the outer side of the upper fix window 120 may have an ornamental window 140, A hollow layer may be formed between the shading films 140.

The upper fix window 120 may include the upper fix window frame 121 for fixing the window and the azimuth 400 for forming the heat insulation line may be formed at a portion where the upper fix window frame 121 and the frame 300 are connected. May be provided. The azon 400 may be inserted as a heat insulating material made of polyurethane to improve the heat conduction rate of the frame 300.

For example, if the azon 400 is not formed between the upper fixture window 120 and the frame 300, the frame 300 and the upper fixture window 120 may be separated from the frame 300, There is a possibility that a thermal bridging phenomenon occurs between the upper fixtures 120 and condensation may occur. Therefore, it is possible to improve the heat conduction rate of the frame 300 by providing the azon 400 to block the thermal bridging between the frame 300 and the upper fixture window 120.

In addition, the upper fixture window 120 may include a gasket 900 to prevent outside air from entering by the window.

In addition, the upper fixture window frame 121 may be provided with a polyamide 500, which is a thermal bridge member, to block heat bridges on both sides. The upper fixture window frame 121 is provided with the polyamide 500 on the upper and lower sides so that an air layer is formed between each of the polyamides 500 to prevent the occurrence of a thermal bridge phenomenon between the upper fixture window frames 121 .

The slide window 130 has a function of raising the window so as to slide on the rail 1000 for opening and closing the window. When the lever 1100 is turned upward after the window is closed, the window is down so that the window and the window frame are completely When the lever 1100 is turned downward, the window can be lifted up a little, and the window can be opened in a state in which the window can be opened laterally.

The slide window 130 may include a gasket 900 between the window and the slide window frame 131 for fixing the window of the slide window 130 to prevent outside air from entering the window.

As shown in FIG. 5, a polyamide PVC 600 may be provided to prevent the indoor and outdoor bridging phenomenon by the auxiliary frame 340 and the slide window 130 have.

The inner window 200 may include a first inner window 210 formed on the inner surface of the inner window 100 to block thermal bridging of the inner window 100, And a second inner window 220 may be provided.

The first inner window 210 may be formed with an interval between the outer window 100 and the air layer, and may be formed as a lift-up sliding window as the slide window 130. In addition, the first inner window 210 may include a first inner window frame 211 for fixing the glass. The first inner window frame 211 is provided with a pivot 800 on an inner side surface thereof to prevent the frame 300 from being thermally bridged. The PS 800 may be provided on the inner side of the first inner window frame 211 to prevent a thermal bridging between the frames 300 due to polystyrene.

The first inner window frame 211 includes a polyamide 500 therein to prevent the first inner window frame 211 from generating a thermal bridge.

In addition, the first inner window 210 may be formed as a double window to enhance the heat insulating effect.

The second inner window 220 is movable toward the inner side of the first inner window 210 and is formed as a lift-up sliding window in the same manner as the slide window 130 and the first inner window 210, . ≪ / RTI > The second inner window 220 may be spaced from the first inner window 210 by a predetermined distance so as not to interfere with the movement of the first inner window 210 and the second inner window 220. In addition, the second inner window 220 may include a second inner window frame 221 for fixing the glass. As in the case of the first inner window 200, the second inner window frame 221 is provided with a pivot 800 on the inner side thereof to prevent the frame 300 from being thermally bridged. The PS 800 may be provided on the inner side of the inner side of the second inner window frame 221 to prevent a thermal bridging between the frames 300 due to polystyrene. Therefore, it is possible to prevent the thermal bridging phenomenon from occurring due to the window frame due to the pieces 800 provided on the inner side surfaces of the first inner window frame 211 and the second inner window frame 221.

The second inner window frame 221 is provided with a polyamide 500 in the same manner as the first inner window frame 211 to prevent the second inner window frame 221 from generating heat bridges have.

The frame 300 includes an outdoor frame 330 formed on the outdoor side and fixing the outdoor window 100 and an outdoor window 330 separated from the outdoor window 330 by the azon 400, A hollow frame 320 formed in an air layer formed between the hollow frame 320 and the inner frame 310 separated from the hollow frame 320 by the polyamide 500.

The outdoor frame 330 may be formed on the outdoor side to fix a part of the outdoor side of the lower fixture window 110 and may secure the eyelashes 140 to the upper end of the outdoor frame 330 . The aluminum frame 300 may be used for the structural stability and the hollow layer at the portion where the wing film 140 and the outdoor frame 330 are in contact with each other. In addition, an upper portion of the outdoor frame 330 may partially fix the upper portion of the upper fixture window 120.

The hollow frame 320 is formed between the outdoor frame 330 and the indoor frame 310 so that an air layer is formed therein to cause the outdoor frame 330 and the indoor frame 310 to cross- Can be blocked.

The lower end of the hollow frame 320 is divided by the outdoor frame 330 and the azon 400 to prevent the thermal bridge generated by the outdoor frame 330 from being transmitted to the hollow frame 320 .

The upper end of the hollow frame 320 may be separated from the lower end by a polyamide 500 and the polyamide 500 may include an upper gasket 910 to form a heat insulating line. The upper gasket 910 is formed at a position where the upper fixture window 120 is in contact with the polyamide 500 to prevent thermal crosslinking due to a part of the upper side of the upper fixture window 120, The upper gasket 910 may be formed to have the same thickness as the end line of the polyamide 500 to the upper end of the outdoor frame 330.

The hollow frame 320 may be separated from the hollow frame 320 by a polyamide 500 so as to secure a thermal bridge between the hollow frame 320 and the outdoor side. 130 for moving the inner window 200 and a rail 1000 for moving the inner window 200.

The interior of the indoor frame 310 may be provided with a pivot 800 for preventing cross-over with the frame 300. The shaft 800 may protrude toward the inner window 200 to cover the inner window 200 when the inner window 200 is closed. In addition, the inner frame 310 may form the protrusion 1200 so that the PS 800 can be fixed.

5, the frame 300 is fixed to the lower fixture window 110 at a lower portion thereof, and the upper fixture window 120, the canopy 140, and the slide window 130 can be moved A frame 340 may be provided. The auxiliary frame 340 may be provided with a polyamide 500 to prevent heat conduction on the outdoor side. The polyamide 500 is formed to have a length up to the upper fix window 120 and the slide window 130 in order to prevent the thermal bridge from being generated by the upper fix window 120 and the slide window 130 .

For example, if the length of the polyamide 500 is only the upper fix window 120 or the slide window 130, the upper fix window 120 and the auxiliary frame 340 may prevent the slide window 130 The polyamide 500 which does not transmit heat may be formed in a length from the upper fix window 120 to the slide window 130 so that the upper fix window 120 and the slide window 130 130 and the auxiliary frame 340 can be prevented from occurring.

FIG. 6 is a cross-sectional view showing a window of a balcony system according to an embodiment of the present invention, FIGS. 7 to 8 are cross-sectional views showing end portions of the cross-sectional view shown in FIG. 6, and FIG. 9 is a cross- Fig.

6 to 9, a window system of a balcony system according to an embodiment of the present invention includes an outer window 100 for blocking the outside air, an inner window (not shown) formed on the inner side of the window 100, 200 and a frame 300 for fixing the window 100 and the window 200.

6 is a cross-sectional view illustrating the bottom fix window 110 and the inner window 200 of the window 100. As shown in FIG. In addition, the frame 300 may represent a side view when the inner window 200 is closed.

The lower fixture window 110 may be formed as a double window to prevent the outside air from entering the interior. The lower fixture window 110 is fixed to the frame 300 and the lower fixture window 110 is fixed to the frame 300 to prevent heat from being transmitted to the lower fixture window 110. [ Of the present invention.

The lower fixture window 110 may be divided by an intermediate frame 350 formed perpendicular to the half of the horizontal length of the window. The lower fixture window 110 is installed on a balcony, and the middle frame 350 can be installed so as to prevent it from being shaken or damaged by a draft.

For example, in the absence of the intermediate frame 350, the bottom fix window 110 installed on the balcony may not be fixed and may be shaken or broken by the draft. The lower fixture window 110 is supported by the side surface of the frame 300 and the intermediate frame 350 with the intermediate frame 350 perpendicular to the half of the longitudinal direction of the lower fixture window 110, So as not to be shaken or broken.

The inner window 200 may include a first inner window 210 formed on the inner surface of the inner window 100 to block thermal bridging of the inner window 100, And a second inner window 220 may be provided.

When the first inner window 210 and the second inner window 220 are closed to the frame 300, a portion of the first inner window 210 and the second inner window 220, which are in contact with each other, 700 may be provided.

The first inner window 210 and the second inner window 220 are formed in the same shape so that when the first inner window 210 and the second inner window 220 are closed, (700) are coupled to each other to prevent the outside wind or the wind from moving.

The first inner window 210 and the second inner window 220 may be provided with a pivot 800 to prevent thermal bridging between the first inner window 210 and the second inner window 220, The window frame of the outdoor unit 220 is divided into the outdoor and the indoor by the polyamide 500, thereby securing the heat insulation performance.

The frame 300 shown in FIG. 6 is a side frame 300 and includes an outdoor frame 330 formed on the outdoor side and fixing the window 100, and a frame 330 interposed between the window 100 and the window 200 A hollow frame 320 formed on the air layer formed on the hollow frame 320 and an indoor frame 310 divided by the hollow frame 320 and the polyamide 500.

A heat insulating line may be formed between the outdoor frame 330 and the hollow frame 320 by a polyamide 500. The polyamide 500 may be heated by the lower fixture window 110 The size of the polyamide 500 may be greater than the thickness of the lower fixture window 110. [

In addition, the PVR 700 may be provided to align the insulation line adjacent to the lower fix window 110 rather than the polyamide 500, and the PVR 700 may include the polyamide 500).

The hollow frame 320 may be divided into the outdoor frame 330 and the polyamide 500. The hollow frame 320 may have a predetermined length so as to be in contact with the first inner window 210 when the first inner window 210 is opened, The inner frame 310 and the polyamide 500 may be separated from each other to prevent heat from being transferred by the second inner window 220 when the inner frame 220 is closed. In addition, the hollow frame 320 may protrude from the rail 1000 to prevent heat from being transmitted to the first inner window 210 when the first inner window 210 is closed.

A rail 1000 can be protruded from the indoor frame 310 to prevent heat from being transmitted to the second inner window 220 when the second inner window 220 is closed, The pawls 800 may be provided to prevent heat bridge with the frame 300.

The middle frame 350 may be formed of the inner frame 310 and the hollow frame 320 and the inner frame 310 and the hollow frame 320 may be separated from each other by the azon 400 . The azon (400) can prevent the heat bridge by the lower fixture window frame (111).

FIG. 10 is an exemplary view showing simulation analysis results of modeling a window system of a balcony system according to an embodiment of the present invention.

As shown in FIG. 10, a window system of a balcony system according to an embodiment of the present invention is formed of an aluminum frame 300, and has a high thermal conductivity and a larger heat loss than other materials.

As shown in FIG. 10, the balcony system window prevents heat bridging so that the heat outside the balcony does not enter the room, thereby enhancing the heat insulation effect.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Those skilled in the art, who understands the spirit of the present invention, can readily suggest other embodiments by adding, changing, deleting, adding, or the like of components within the scope of the same idea, I would say.

100: in window 110: bottom fix window
120: upper fix window 130: slide window
140: Shade 200:
210: first inner window 220: second inner window
300: frame 310: indoor frame
320: hollow frame 330: outdoor frame
340: auxiliary frame 350: intermediate frame
400: Azone 500: Polyamide
600: polyamide pvc 700: pvv-seed
800: PAS 900: Gasket
910: upper gasket 1000: rail
1100: lever 1200: projection

Claims (16)

An upper fixation window formed on an upper portion of the lower fixture window in a horizontal direction, an eyelash provided on an outdoor side surface of the upper fixture window to form a hollow layer, An outer window having a slide window movable toward the indoor side of the upper fixture window,
A first inner window formed on the inner surface of the outer window and a second inner window movable toward the indoor side of the first window,
And a frame having an azon for separating the outer window and the inner window and forming an insulating line.
The method according to claim 1,
Wherein the upper fix window includes the azon at a portion coupled to the frame to form an insulating line.
3. The method of claim 2,
And a gasket is formed on the upper fix window and the slide window to prevent outside air from entering the window through the window.
The method according to claim 1,
Wherein the slide window is provided at the lower end thereof with a polyamide pipe along the horizontal longitudinal direction for blocking outdoor and outdoor bridging.
The method according to claim 1,
Wherein each of the inner windows comprises a window frame for blocking heat exchange with the outdoor side, and a polyamide between the window frames.
6. The method of claim 5,
Wherein a portion of the first inner window and the second inner window which are in contact with each other when the inner window is closed is provided to intersect the outer surface of the first inner window and the second inner window to increase the heat insulation effect.
The method according to claim 1,
The frame includes an outdoor frame formed on the outdoor side and fixing the outdoor window,
A hollow frame divided by the outdoor frame and the azon and formed in an air layer formed between the outer window and the inner window;
And an indoor frame divided by the hollow frame and the polyamide.
8. The method of claim 7,
Wherein the outdoor frame includes an auxiliary frame having a rail on which the slide window is fixed and fixing the bottom fix window.
An upper fixation window formed on an upper portion of the lower fixture window in a horizontal direction, an eyelash provided on an outdoor side surface of the upper fixture window to form a hollow layer, An outer window having a slide window movable toward the indoor side of the upper fixture window,
A first inner window formed on the inner surface of the outer window and a second inner window movable toward the indoor side of the first window,
A frame having an azon for separating the outer window and the inner window and forming an adiabatic line,
A balcony system window which is joined to an inside side surface of the frame and includes a polystyrene to prevent heat bridging through the frame and to increase the heat insulation.
10. The method of claim 9,
Wherein the upper fix window includes the azon at a portion coupled to the frame to form an insulating line.
11. The method of claim 10,
And a gasket is formed on the upper fix window and the slide window to prevent outside air from entering the window through the window.
10. The method of claim 9,
Wherein the slide window is provided at the lower end thereof with a polyamide pipe along the horizontal longitudinal direction for blocking outdoor and outdoor bridging.
10. The method of claim 9,
Wherein each of the inner windows comprises a window frame for blocking heat exchange with the outdoor side, and a polyamide between the window frames.
14. The method of claim 13,
Wherein a portion of the first inner window and the second inner window which are in contact with each other when the inner window is closed is provided to intersect the outer surface of the first inner window and the second inner window to increase the heat insulation effect.
10. The method of claim 9,
The frame includes an outdoor frame formed on the outdoor side and fixing the outdoor window,
A hollow frame divided by the outdoor frame and the azon and formed in an air layer formed between the outer window and the inner window;
And an indoor frame divided by the hollow frame and the polyamide.
16. The method of claim 15,
Wherein the outdoor frame includes an auxiliary frame having a rail on which the slide window is fixed and fixing the bottom fix window.

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