KR102190913B1 - Aluminum sliding window for improving airtight and heat insulation - Google Patents

Abstract

The present invention provides an eccentric installation of a door car provided at the lower part of the sliding window from the vertical insulation line of the window to the interior side, and a block-type insulation member, which is an insulation foam material, is provided between the profiles constituting the interior and exterior surfaces of the window. It relates to an aluminum sliding window that can improve airtightness and thermal insulation performance by blocking heat transfer by applying as.
The present invention for realizing this, the window frame 110; An outdoor side window 120 coupled to the outdoor side of the window frame 110; And the indoor side of the window frame 110 is coupled to overlap with the outdoor side window 120 so as to be slidably opened and closed; including, but a door roller provided below the indoor side window panel 130 (140) is characterized in that it is installed in the installation groove 131 provided to be eccentric to the indoor side in the vertical insulation line leading to the glass of the window frame 110 and the indoor side window 130, and the indoor side window 130. .

Description

Aluminum sliding window for improving airtight and heat insulation

The present invention relates to an aluminum sliding window, and more particularly, to an aluminum sliding window capable of improving airtightness and insulation performance by installing a door roller provided at the lower part of the sliding window so as to be eccentrically installed from the vertical insulation line of the window to the interior. .

In general, buildings are provided with windows for the purpose of controlling access, lighting or ventilation.

Depending on the opening and closing method, windows are divided into sliding, opening, and fixed types, and according to the material forming the window frame and window frame, it is divided into wooden windows, PVC (Poly Vinyl Choride) windows, and aluminum windows.

On the other hand, wood windows are difficult to mass-produce due to cumbersome work such as molding due to the nature of the material, whereas PVC windows and aluminum windows are relatively simple molded by the injection method to facilitate mass production, so most of the recent windows are made of PVC windows or aluminum windows. do.

In this case, aluminum windows are not only smooth in mass production, but also have the advantage of having a beautiful appearance due to their intrinsic texture, but the product unit cost is significant, and in particular, there is a problem in that the heat transfer rate is higher than that of PVC windows and the insulation performance is deteriorated.

In order to solve the problem of lowering the insulation performance of aluminum windows, as shown in FIG. 1, poly(polypropylene) is provided in the upper and lower portions between the outdoor profile 11 and the indoor profile 13 forming the frame 10 for manufacturing a window frame or window. A technique for combining a bar-shaped insulating member 15 made of polyamid material has been proposed.

In this case, since the bar-shaped heat insulating member 15 blocks heat transfer between the outdoor profile 11 and the indoor profile 13, the heat insulation performance of aluminum windows can be improved to some extent.

However, when the width of the thermal insulation member 15 in the bar shape as described above is increased to a certain level (30 mm) or more, cracks occur and are easily damaged, so application is limited. In particular, there is a problem in that heat is transferred by convection and radiation in the space between the upper bar-type heat insulating member 15 and the lower bar-type heat-insulating member 15, resulting in poor heat insulation performance.

In addition, in the conventional window, the glass 21 and the window pane 23, and the insulation line in the vertical direction leading to the window frame 25 are not aligned in line. That is, as the empty space (S) for installing the sliding window door roller is formed in the insulation line, there is a structural problem that the insulation performance is inevitably deteriorated.

The related prior art is the Republic of Korea Utility Model No. 20-0433491 (announcement date: 2006.12.13).

The present invention was conceived to solve the above-described problem, and installed the door car provided in the lower part of the sliding window so as to be eccentrically installed from the vertical insulation line of the window to the interior side, and insulate between the profiles constituting the interior and exterior sides of the window. The purpose of this is to provide an aluminum sliding window that can improve airtightness and insulation performance by blocking heat transfer by applying a block-type insulation member, which is a foam material, as an insulation bridge.

Aluminum sliding window according to the present invention for implementing the object as described above, the window frame frame; An outdoor side window coupled to the outdoor side of the window frame frame; And an indoor side window that is coupled to overlap with the outdoor side window so as to be opened and closed on the indoor side of the window frame frame, wherein the door car provided under the interior side window frame includes the window frame frame and the indoor side window frame, and It characterized in that it is installed in the installation groove provided eccentrically to the indoor side in the vertical insulation line leading to the glass of the side window.

The present invention according to the configuration as described above, while installing the door rail provided in the lower portion of the sliding window to be eccentric from the vertical insulation line of the window to the interior, and between the profiles constituting the interior and exterior of the window, the insulating foam material As the block-type insulating member is applied as an insulating bridge, heat transfer between the profiles can be effectively blocked by the material properties and voids of the insulating member.

In addition, there is an advantage of improving the airtightness and insulation performance of windows and doors by applying a multi-sealing structure in a manner in which a plurality of gaskets and airtight members are interposed in the gap between the window sill constituting the vertical insulation line and the window frame frame.

1 is a side cross-sectional view showing a state in which a bar-shaped insulating member is applied to a conventional aluminum window,
2 is an interior elevation view of an aluminum sliding window according to the present invention,
3 is a cross-sectional view taken along line I-I' of FIG. 2;
Figure 4 is an enlarged microscope photograph showing the pore particles of the heat insulating member according to the present invention,
5 is a detailed view of part'A' of FIG. 3;
6 is a perspective view of a connection member and a heat insulating member formed integrally according to the present invention,
7 is a cross-sectional view taken along line II-II' of FIG. 2;
8 is a detailed view of part'B' of FIG. 3;
9 is a test result data showing the insulation performance of the aluminum window according to the present invention.

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

Here, in adding reference numerals to elements of each drawing, it should be noted that the same elements are marked with the same numerals as much as possible, even if they are indicated on different drawings.

2 is an interior elevation view of an aluminum sliding window according to the present invention, and FIG. 3 is a cross-sectional view taken along line II′ of FIG. 2.

2 and 3, the aluminum sliding window 100 with improved airtightness and insulation performance according to a preferred embodiment of the present invention is coupled to the outdoor side of the window frame 110 and the window frame 110 The outdoor window panel 120 and the indoor side window panel 130 which is coupled to overlap with the outdoor window panel 120 on the indoor side of the window frame 110 to be opened and closed by sliding, the lower part of the indoor window panel 130 The door roller 140 provided in the window frame 110 and the indoor side window panel 130 and the vertical insulation line L leading to the glass of the indoor side window panel 130 are installed in the installation groove 131 provided to be eccentric to the indoor side. It features.

The configuration of the present invention will be described in detail as follows.

Profiles P constituting the interior and exterior surfaces of the window frame 110, the outdoor side window 120, and the indoor side window 130, respectively, are formed of aluminum. In this case, a block-type heat insulating member 200 made of a heat insulating foam material may be coupled between the facing surfaces of the profile P. The heat insulating member 200 is formed of a polyurethane material, has a void (see FIG. 4), and has a block shape.

The heat insulating member 200 may be directly coupled between the profiles (P), but through a connection member 210 coupled to face each other on opposite surfaces of the profile (P) for a solid coupling of the heat insulating member 200 It is preferred to be combined.

Referring to FIG. 5, the connection member 210 is formed of a polyamide material. In addition, the connecting member 210 is provided with a protrusion 211, and a groove P1 is provided on the opposite surface of the profile P so that the protrusion 211 of the connecting member 210 can be coupled. The groove P1 may be provided therebetween through the structure of the upper wing and the lower wing.

That is, after the protrusion 211 is inserted into the groove P1, the upper wing and the lower wing bite the protrusion 211 by pressing and fix it, thereby maintaining a solid coupling state of the profile P and the connecting member 210. have. A plurality of grooves P1 having such a structure may be spaced apart from each other above and below the opposite surface of the profile P.

On the other hand, the connecting member 210 is a high-strength material compared to the insulating member 200, which is an insulating foam material. That is, by applying a coupling method in which the connecting member 210 is interposed between the heat insulating member 200 and the profile P, it is possible to assemble solid between the components.

More specifically, the heat insulating member 200 is a PU hardened foam that increases the strength of the edges and has the same density to the center. It can be mixed and processed, including liquid polyols, isocyanates and other additives. The heat insulating member 200 is made of a high heat insulating material, and once cured, there is no deformation due to temperature change (experiment at -50 to 115°C).

In this case, the basic physical properties of the heat insulating member 200 include a thermal conductivity of 0.03 to 0.08 W/mK, an elastic modulus of 800 to 1200 MPa, a tensile strength of 5 to 7 MPa, and a pore size of 80 to 150 μm. It is desirable to be configured.

By using the block-type insulating member 200 made of the above basic physical properties as an insulating bridge for aluminum windows, it is possible to improve the thermal insulation performance of the window by blocking heat transfer between the interior and exterior profiles P. In addition, it is possible to improve the wind pressure performance of windows and doors by allowing them to have a certain strength.

The heat insulating member 200 may be manufactured through a separate manufacturing process and then manufactured in a manner in which the groove 201 is coupled to the protrusion 211 of the connecting member 210, but it is shown in FIG. 6 for convenience of the manufacturing process. As shown, it is preferable to integrally form a heat insulating member 200 between the connecting members 210 through foam molding of urethane foam in a state in which a pair of connecting members 210 are inserted to face each other in the mold. .

Referring again to FIGS. 3 and 7, the window frame 120 and 130 constituted of at least one pair in the window frame 110 may all be configured as sliding windows, but in the present invention, the airtightness and insulation of the window 100 In order to improve performance, the outdoor side window 120 coupled to the outdoor side of the window frame 110 is composed of a fixed window, and the indoor side window 130 is on the indoor side rail 111 of the window frame 110. It is preferable to configure a sliding window that can be opened and closed by sliding.

In this case, the door roller 140 provided on the bottom of the interior window 130 may be installed in the installation groove 131 provided to be eccentric from the insulation line L to the interior (see FIG. 3).

That is, in order not to have an empty space in the insulation line L of the window, the installation groove 131 for installing the door roller 140 should not be located on the same vertical line of the insulation line L. Therefore, by installing the door car 140 eccentrically from the insulation line (L) to the interior side as in the present invention, it is possible to improve the insulation performance of the window. The interior window panel 130 may be configured by a lift-sliding method.

Referring to FIG. 8, a gasket 135 is provided on the bottom of the indoor window 130 to keep airtight by blocking a gap between the window frame 110 constituting the vertical insulation line L and the indoor window 130. Can be. A plurality of gaskets 135 may be installed in a structure spaced apart from each other along the width direction of the interior and exterior, and accordingly, the airtight performance of the window 100 may be improved.

In addition, an airtight member 137 may be installed on the inner circumferential surface of the window frame 110 to maintain airtightness by contacting the outdoor side of the indoor window panel 130 when the indoor window panel 130 is closed. .

The aluminum sliding window 100 matching the vertical insulation line according to the present invention of the above configuration, as shown in the insulation performance test result of FIG. 9, the window frame 110 and the indoor side window panel 130, and the indoor side The insulation performance of the window 100 can be improved by matching the insulation line L leading to the glass 133 coupled to the window panel 130 to eliminate empty space.

In particular, as the block-type insulating member 200, which is an insulating foam material, is applied as an insulating bridge between the profiles P constituting the interior and exterior surfaces of the window 100, the material properties and voids of the insulating member 200 Accordingly, heat transfer between the profiles can be effectively blocked.

Specifically, the window 100 according to the present invention has a heat transmission rate (Uf) of less than 1.0W/㎡·K as a result of the measurement, and has a thermal insulation performance compared to the case where the heat transmission rate (Uf) of conventional windows is mostly 2.5W/㎡·K or more. You can see that it has improved.

In addition, a plurality of gaskets 135 and an airtight member 137 are interposed in the gap between the window frame 110 and the window panel 130 constituting the vertical insulation line (L). The airtight performance can be improved.

In the above, the present invention has been illustrated and described with reference to specific preferred embodiments, but the present invention is not limited to the above-described embodiments, and various changes and modifications can be made without departing from the spirit of the present invention.

100: aluminum sliding window 110: window frame frame
111: rail 120: outdoor side window
130: interior window 131: installation groove
133: glass 135: gasket
137: airtight member 140: door car
200: insulation member 201: groove
210: connecting member 211: protrusion
L: Insulation line P: Profile
P1: Home

Claims (9)

A window frame 110;
An outdoor side window 120 coupled to the outdoor side of the window frame 110; And
Including; the indoor side of the window frame 110 is coupled to overlap with the outdoor side window 120 so as to slide open and close the indoor side window 130;
The door roller 140 provided below the interior window panel 130,
It is installed in the installation groove 131 eccentrically provided to the indoor side in the vertical insulation line leading to the glass of the window frame 110 and the indoor window panel 130, and the indoor window panel 130,
Between the facing surfaces of the profile P constituting the interior and exterior surfaces of the window frame 110 and the window panes 120 and 130, respectively, a connection member 210 made of polyamide material is used to form an insulating foam material. Block-type insulation member 200 is installed,
On the inner and outer surfaces of the connecting member 210, a plurality of protrusions 211 are formed to protrude in a state spaced apart from each other along the longitudinal direction, and a protrusion 211 formed on the inner surface of the connecting member 210 Is fitted into the recessed groove 201 on the surface of the heat insulating member 200, and the protrusion 211 formed on the outer surface of the connecting member 210 protrudes on the opposite surface of the profile P, and the center It is fitted into the recessed groove (P1),
The outdoor-side window panel 120 is a fixed window, and at the bottom of the indoor side window panel 130, the vertical insulation line (L) closes the gap between the window frame 110 and the indoor window panel 130 to maintain airtightness. A pair of gaskets 135 are installed spaced apart in the width direction,
The gasket 135 is connected to each other while blocking the gap between the profile (P) and the connecting member 210 by being coupled to the bottom surface of the profile (P) and the bottom surface of the connecting member 210, respectively. Aluminum sliding windows that let you.
delete The method of claim 1,
The heat insulating member 200,
Aluminum sliding windows, characterized in that the foamed polyurethane (Polyurethane) material.
The method of claim 3,
The heat insulating member 200,
Aluminum sliding window, characterized in that the thermal conductivity is 0.03 ~ 0.08W/mK, the elastic modulus is 800 ~ 1200MPa, the tensile strength is 5 ~ 7MPa, and the pore size is 80 ~ 150㎛.
delete delete delete delete The method of claim 1,
On the inner circumferential surface of the window frame 110,
An aluminum sliding window further comprising an airtight member (137) that contacts the outdoor side of the indoor window (130) and maintains airtightness by blocking a gap between the indoor window (130).

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