KR20130025695A - Windows and doors of building - Google Patents

Abstract

PURPOSE: A window for a building is provided to block heat transfer between a sash frame and a concrete wall by using a heat transfer blocking member having a low heat conductivity, thereby improving heat insulation property, and preventing water leakage due to rainwater. CONSTITUTION: A window for a building includes a concrete wall(20), a window(10), a heat transfer blocking member(100), and a downspout. The concrete wall, which is an external wall of the building, is penetrated in order to install the window. The heat transfer blocking member between the sash frame(14) of the window and the concrete wall lowers heat conductivity in order to prevent a heat bridge from being generated between the sash frame of the window and the concrete wall. The downspout installed outside the sash frame prevents water, which flows along the window, from permeating among the sash frame, the heat transfer blocking member, and the concrete wall.

Description

Windows and doors of building}

The present invention relates to a building window part, and more particularly, by blocking heat transfer between the chassis frame and the concrete wall of the building window part, to ensure excellent thermal insulation performance of the building even when the indoor and outdoor temperature deviation is large, as well as the chassis The present invention relates to a building window part for preventing leakage of water into a room and pollution by preventing rainwater from entering between a frame and a concrete wall.

Generally, residential buildings such as apartments, officetels, and detached houses, as well as office buildings, are provided with windows and doors for ventilation and mining.

In addition, recently, by increasing the heating and cooling efficiency by improving the thermal insulation performance, the construction of the building to minimize the energy consumption is being encouraged, accordingly to install a heat insulating material on the wall to increase the heat insulation effect.

Insulation methods of buildings include insulation, breakdown, and external insulation methods, which induce thermal bridges due to the breakage of insulation materials.In recent years, building energy performance is in line with the trend of low carbon green growth in the country. In order to improve the performance of the thermal insulation method to improve the energy performance of buildings and to prevent thermal bridges by installing thermal insulation on the outer surface of the concrete wall after the foundation work, a lot of trends are being applied.

On the other hand, the window portion is installed in a set size to penetrate through the wall of the building, the window portion 10 is a window 12 that can be sliding or opening and closing, as shown in Figure 1, the window 12 Consists of supporting the opening and closing as well as the chassis frame 14 is installed to be supported on the concrete wall (20). In this case, the heat insulating material 30 is installed only on the outer surface of the concrete wall 20 except for the window portion 10, and thus the concrete wall 20 ensures thermal insulation performance even when the indoor and outdoor temperature deviations are large. Done.

Here, as the chassis frame 14 supporting the window is pushed and fixed to the wall 20 made of concrete by a coupling means such as concrete nails, the window portion 10 is fixed and installed with respect to the wall 20. .

However, the chassis frame 14 of the window portion 10 is mostly formed of a metal material such as aluminum, the chassis frame of such aluminum material has a high thermal conductivity, which adversely affects the thermal insulation performance of the interior of the building.

For example, when indoor heating is performed in winter, the outdoor temperature is low and the indoor temperature is relatively high. The chassis frame 14 of the window unit 10 maintains the outdoor cold outdoor temperature by high thermal conductivity. By absorbing and transferring it to the concrete wall 20, the indoor air is affected by the cold outside air, on the contrary, the warm air of the room is exposed to the chassis frame of the window 10 having a high thermal conductivity through the concrete wall 20 ( 14) as it is delivered as it is released to the outside, there is a problem that the heat insulating performance of the room is lowered.

In addition, when indoor cooling is performed in the summer, the outdoor temperature is high and the indoor temperature is relatively low. The chassis frame 14 of the window 10 has a high thermal conductivity, which is used to control the temperature of the outdoor hot air. As it is absorbed as it is delivered to the concrete wall 20, the indoor air is affected by the hot air, on the contrary, the indoor cold air is the chassis frame of the window 10 having a high thermal conductivity through the concrete wall 20 As it is transmitted to 14 as it is released to the outside, there was a problem that the thermal insulation performance of the room is also reduced.

That is, when the chassis frame 14 of the window 10 is in direct contact with the concrete wall 20 as described above, there was a problem that the thermal insulation performance of the building is reduced.

In addition, when it rains, a problem of water leakage occurs, such as rainwater flowing along the outer surface of the window 10, seeps between the chassis frame 14 and the wall 20, and between the heat insulating material 30 and the wall 20. As a result, there was a problem of contamination such as mold gas.

The present invention has been made in view of the above problems, by providing a heat transfer blocking member having a low thermal conductivity between the chassis frame and the concrete wall of the window portion, to provide a building window portion installation structure for building insulation is very excellent. The purpose is.

In addition, an object of the present invention is to provide a building window for preventing the leakage of rain water flowing through the outer surface of the window portion permeates into the room or the leakage between the insulation and the wall.

Building windows and doors according to the present invention for achieving the above object, the concrete wall forming the outer wall surface of the building; A window portion installed through the concrete wall; A heat transfer blocking member having a predetermined thickness interposed in the chassis frame and the concrete wall of the window unit to lower the thermal conductivity of each other; It is installed to be inclined downward from the outer surface of the chassis frame characterized in that it further comprises a drip tray for preventing the water flowing through the window portion penetrates between the chassis frame and the heat transfer blocking member and the heat transfer blocking member and the wall.

In this case, the drip tray is composed of a coupling portion fixed and coupled to the outer surface of the chassis frame by a coupling means, an inclined portion formed to be inclined downward from the coupling portion, and a drop induction portion extending in a vertical direction from the inclined portion. It is preferable.

Here, the coupling portion of the drip tray is composed of a first coupling portion and a second coupling portion parallel to each other, the first coupling portion is in close contact with the outer surface of the chassis frame, the second coupling portion is formed inside the chassis frame It may be inserted into the groove and fixed.

As described above, according to the building window unit according to the present invention, the heat transfer blocking member having a low thermal conductivity is installed between the chassis frame and the concrete wall of the window unit, thereby blocking the thermal bridge between the chassis frame and the concrete, the heat insulation effect is very excellent. The effect is provided.

In addition, the present invention also provides the effect of preventing the leakage of rain water flowing through the outer surface of the window portion permeates into the room, or infiltrate between the insulation and the wall.

1 is a cross-sectional view showing a relationship in which the windows and doors are installed in a conventional building.
Figure 2 is an exploded cross-sectional view showing a heat transfer blocking structure for building windows and doors according to the first embodiment of the present invention.
3 is a cross-sectional view of the combination of FIG.
Figure 4 is an exploded cross-sectional view showing the relationship between the drip tray installed in the building window portion of Figure 2;
5 is a cross-sectional view of the combination of FIG.
Figure 6 is an exploded cross-sectional view showing a heat transfer blocking structure for building windows and doors according to a second embodiment of the present invention.
7 is a cross-sectional view of the combination of FIG.
8 is an exploded cross-sectional view showing a relationship between the drip tray installed in the building window part of FIG.
9 is a cross-sectional view of the combination of FIG.
Figure 10 is an enlarged cross-sectional view showing another structure in which the drip tray is coupled to the chassis frame in the first and second embodiments of the present invention.

<First Embodiment>

FIG. 2 is an exploded cross-sectional view illustrating a heat transfer blocking structure of the building window part according to the first embodiment of the present invention, and FIG.

For reference, in describing the first embodiment of the present invention, the same parts as in the prior art will be described with the same reference numerals.

As shown, the heat transfer blocking structure of the building windows and doors according to the first embodiment of the present invention, the concrete wall 20 constituting the outer wall surface of the building, and the windows and windows installed through the concrete wall 20 ( 10).

Here, the window portion 10 is composed of a sliding window or a sliding window 12, and the chassis frame 14 made of aluminum to support the window 12 to be opened and closed.

Between the chassis frame 14 and the concrete wall 20 of the window 10, there is a heat transfer blocking member 100 of a predetermined thickness to lower the thermal conductivity of each other, the heat transfer blocking member 100 is a thermal conductivity It is desirable that this very low timber be applied. Of course, if the heat transfer blocking member 100 is made of a material having a low thermal conductivity, such as rubber material, synthetic resin material in place of wood may be applied to anything.

In addition, the outer insulation material 30 is provided on the outer surface of the concrete wall 20 and the outer surface of the heat transfer blocking member 100 and the chassis frame 14.

As such, when the heat transfer blocking member 100 is installed between the chassis frame 14 of the window portion 10 and the concrete wall 20, the chassis frame 14 and the concrete wall 20 of the window portion 10 are installed. By blocking the heat transfer, even if the indoor and outdoor temperature deviation is large, the thermal insulation is further improved.

For example, when indoor heating is performed in winter, the outdoor temperature is low and the indoor temperature is relatively high. At this time, the chassis frame 14 of the window 10 has the same temperature as the cold outdoor air due to high thermal conductivity. Even if absorbed, the cold air is not transmitted to the concrete wall 20 by the heat transfer blocking member 100 installed between the concrete walls 20, so that the indoor air is not affected by the cold outside air, and the indoor warm air Since the heat transfer is blocked by the heat transfer blocking member 100 through the concrete wall 20 and is not transmitted as it is to the chassis frame 14 of the window 10 having high thermal conductivity, the warmth of the room is not released to the outside. Therefore, the thermal insulation performance of the room is maintained.

On the contrary, when indoor cooling is performed in the summer, the outdoor temperature is high and the indoor temperature is relatively low. At this time, the chassis frame 14 of the window 10 has a high thermal conductivity, thereby reducing the outdoor hot temperature. Even if it is absorbed as it is, the heat is not transmitted to the concrete wall 20 by the heat transfer blocking member 100 installed between the concrete walls 20, so that the indoor air is not affected by hot outside air, and also the indoor cold The heat is blocked by the heat transfer blocking member 100 through the concrete wall 20 so that the air is not transferred to the chassis frame 14 of the window 10 having high thermal conductivity as it is not discharged to the outside of the room. As a result, the thermal insulation performance of the room is maintained.

As such, the chassis frame 14 of the window portion 10 is not in direct contact with the concrete wall 20, but the heat transfer blocking member 100 is installed therebetween, thereby improving the thermal insulation performance of the building.

On the other hand, Figure 4 is an exploded cross-sectional view showing the relationship between the drip tray installed in the building windows and doors according to the first embodiment of the present invention, Figure 5 is a cross-sectional view of FIG.

As shown, the drip tray 200 is inclined downward from the outer surface of the chassis frame 14 of the window portion.

The drip tray 200 includes a coupling portion 202 fastened by a coupling means in a direction perpendicular to an outer surface of the chassis frame 14, and an inclined portion 206 extending downwardly from an end of the coupling portion 202. And a drop induction part 204 extending from the end of the inclined part 206.

Therefore, when rain falls and the rainwater flows down along the outer surface of the window 10, rainwater flows down the inclined portion 206 along the engaging portion 202 of the drip tray 200. Rainwater flowing through the portion 206 falls again through the drop induction portion 204 in the vertical direction, the rainwater between the chassis frame 14 and the heat transfer blocking member 100, the heat insulating material 30 and the heat transfer blocking member ( Between 100, between the heat insulator 30 and the wall 20, do not penetrate between the heat transfer blocking member 100 and the wall 20 to prevent leakage and prevent contamination of the heat transfer blocking member 100.

Second Embodiment

FIG. 6 is an exploded cross-sectional view illustrating a heat transfer blocking structure of a building window and door unit according to a second embodiment of the present invention, and FIG. 7 is a cross-sectional view of the coupling of FIG. 6.

In describing the second embodiment of the present invention, the same parts as in the first embodiment will be described with the same reference numerals, and repeated description thereof will be omitted.

As shown, in the heat transfer blocking structure of the building window portion according to the second embodiment of the present invention, the entire surface of the heat transfer blocking member 100 is not in contact with the concrete wall 20, only a part of one surface is in contact As a result, the heat shield between the chassis frame 14 and the concrete wall 20 of the window 10 is made more secure.

In the second embodiment of the present invention, the outer heat insulating material 30 having the cutout portion 36 inwardly formed to have the vertical surface 32 and the horizontal surface 34 on the inner surface of the end portion thereof is applied. Part of one surface of the heat transfer blocking member 100 is in close contact with and fixed to the horizontal surface 34 of the cutout 36, and one side of the surface of the heat transfer blocking member 100 is the concrete wall 20. The surface contact is made.

In addition, the outer surface of the heat transfer blocking member 100 and the chassis frame 14 is in close contact with and fixed to the vertical surface 32 of the cutout portion 36 of the outer heat insulating material 30.

At this time, only one part of the surface of the heat transfer blocking member 100, not the entire surface, is adhered to and fixed to the concrete wall 20, thereby being supported by the heat transfer blocking member 100 and the heat transfer blocking member 100. Since the support force of the window 10 may be lowered, the heat transfer blocking member 100 is preferably fixed and installed with the concrete wall 20 by the L-shaped bracket (110).

That is, as shown in Figures 4 and 5, the horizontal surface 114 of the A-shaped bracket 110 is coupled to the heat transfer blocking member 100 by a coupling means such as concrete nails, The vertical surface 112 is coupled to the outer surface of the concrete wall 20 by a coupling means such as concrete nails, so that only one surface of the heat transfer blocking member 100 is in surface contact with the concrete wall 20. It can be fixed and installed.

Even in the case of the heat transfer blocking structure of the building window portion according to the second embodiment of the present invention, as in the first embodiment, the chassis frame 14 of the window portion 10 is not in direct contact with the concrete wall 20. Without the heat transfer blocking member 100 installed therebetween, the effect of the thermal insulation performance of the building is improved is the same, the operation relationship for this will be omitted.

However, in the case of the heat transfer blocking structure of the building windows and doors according to the second embodiment of the present invention, the entire surface of the heat transfer blocking member 100 is not in contact with the concrete wall 20, and only a part of one surface of the building is contacted. Since the heat shield between the chassis frame 14 and the concrete wall 14 of the window 10 is made more securely, it is possible to exhibit more improved thermal insulation performance than in the first embodiment.

On the other hand, Figure 8 is an exploded cross-sectional view showing the relationship between the drip tray installed in the building window portion according to the second embodiment of the present invention, Figure 9 is a cross-sectional view of FIG.

As shown, the drip tray 200 is inclined downward from the outer surface of the chassis frame 14 of the window portion.

The drip tray 200 includes a coupling portion 202 fastened by a coupling means in a direction perpendicular to an outer surface of the chassis frame 14, and an inclined portion 206 extending downward from an end of the coupling portion 202. And a drop guide portion 204 extending from the end of the inclined portion 206.

Therefore, when rain falls and the rainwater flows down along the outer surface of the window 10, rainwater flows down the inclined portion 206 along the engaging portion 202 of the drip tray 200. Rainwater flowing through the portion 206 falls back down through the drop induction portion 204 in the vertical direction, so that the rainwater is between the chassis frame 14 and the heat transfer blocking member 100, the heat transfer blocking member 100 and the heat insulating material ( Between 30), between the heat insulating material 30 and the wall 20, the heat transfer blocking member 100 and the wall 20 does not penetrate the leakage is prevented as well as prevention of contamination of the heat transfer blocking member 100 is made.

On the other hand, Figure 10 is an enlarged cross-sectional view showing another structure in which the drip tray is coupled to the chassis frame in the first and second embodiments of the present invention.

In the first embodiment and the second embodiment of the present invention, the drip tray 200 is coupled to the outer surface of the chassis frame 14 to be in direct contact with the coupling means, the coupling portion 202 and the chassis of the drip tray 200 Rainwater may penetrate between the outer surfaces of the frame 14.

Accordingly, the coupling part 202 of the drip tray 200 is installed in duplicate, but the first coupling part 202a is in close contact with and fixed to the outer surface of the chassis frame 14, and the parallel second coupling part 202b is provided. By forming a groove (not shown) inside the chassis frame 14 to be inserted and fixed in the groove, it is possible to more completely block the leakage of rain water.

Technical ideas described in the embodiments of the present invention as described above may be implemented independently, or may be implemented in combination with each other. In addition, the present invention has been described through the embodiments described in the drawings and the detailed description of the invention, which is merely exemplary, and those skilled in the art to which the present invention pertains have various modifications and equivalent other embodiments. It is possible. Accordingly, the technical scope of the present invention should be determined by the appended claims.

10: window part 12: window
14: chassis frame 20: concrete wall
30: outer insulation 32: vertical plane
34: horizontal plane 36: incision
100: heat transfer blocking member 110: bracket
112: vertical plane 114: horizontal plane
200: drip tray 202: coupling portion
202a: first coupling portion 202b: second coupling portion
204: drop guide portion 206: inclined portion

Claims (3)

A concrete wall forming an outer wall of the building;
A window portion installed through the concrete wall;
A heat transfer blocking member having a predetermined thickness interposed between the window frame chassis frame and the concrete wall to block thermal bridges;
And a drip tray for preventing the water flowing through the window portion from being inclined downward from the outer surface of the chassis frame and permeating between the chassis frame, the heat transfer blocking member, and the heat transfer blocking member and the wall.
The method of claim 1,
The drip tray,
A coupling part fixed and coupled to the outer surface of the chassis frame by a coupling means;
An inclined portion formed obliquely downward from the coupling portion;
Building windows, characterized in that consisting of a drop induction portion extending in the vertical direction from the inclined portion.
The method of claim 2,
The coupling portion of the drip tray is composed of a first coupling portion and a second coupling portion parallel to each other, the first coupling portion is in close contact with the outer surface of the chassis frame, the fixed portion, the second coupling portion in the groove formed inside the chassis frame Building windows, characterized in that inserted, fixed.

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