KR102280618B1 - Complex Window - Google Patents

Abstract

The present invention provides a composite window.
The composite windows include at least a pair of windows that are slidably installed on a window frame, and a windbreak that is vertically coupled to the window frames, and is provided at portions where the windows overlap each other in a closed state. The windbreak frame includes a chamber provided to be positioned in a space between the windows facing each other in a closed state, and a thermal barrier material inserted into the chamber.

Description

Complex Window

The present invention relates to a composite window, and more particularly, to a composite window with improved insulation performance and work performance.

Recently, as buildings become taller and the proportion of windows occupying the function and exterior of the building increases, the demand for a beautiful exterior when viewing the building from the outside is also increasing in the exterior design part. Accordingly, the basic framework of windows is a synthetic resin material that has the advantage of heat radiation and dew condensation, and preference for composite windows made of metal (aluminum, etc.), which is a beautiful material, is increasing.

However, the windshield applied to these composite windows is generally formed of a metal material, and since no insulating material to block the thermal bridge is inserted into the windshield itself, heat loss from the indoor to the outdoor occurs by the metal windshield. There was a problem with performance degradation.

Also, due to this, the temperature of the surface of the windshield is lowered, and there is a disadvantage in that condensation or freezing occurs in the windows. In this case, since it is necessary to additionally combine the window frame or the insulator inside the window frame separately from the windbreak frame during the window construction, workability and constructability are deteriorated, and there is a problem in that the insulation performance differs depending on the skill of the contractor.

On the other hand, in the case of a window to which a composite material for bonding a metal cover to a conventional synthetic resin window is applied, a glass fixing frame (GB, glazing bead) for fixing the glass to the metal cover is configured to be coupled. However, in this case, when the glass is fixed to the window sill, an impact is transmitted to the glass fixing frame by an external force such as wind pressure, which may cause a problem that the metal cover is separated from the window sill.

The present invention has been devised to solve the above-described problems, and to minimize heat loss from indoors to outdoors to improve the insulation performance of windows and doors, and to provide a composite window that prevents the occurrence of condensation and icing on the surface of the windshield. aim to

In addition, an object of the present invention is to provide a composite window with improved workability since it does not require a process of separately assembling a heat cross-blocking material to a windbreak when constructing a window.

In order to achieve the above object, the composite window according to the present invention includes at least a pair of windows that are installed to be slidably open and closed on a window frame, and are vertically coupled to the window, and in a portion where the windows overlap in the closed state. a chamber provided to be positioned in a space between the windows facing each other in a closed state, the windshield being inserted into the chamber to minimize the flow of internal and external heat through the windshield Including thermal barrier material.

As described above, the composite windows according to the present invention are provided with a windshield provided with a thermal barrier material integrally, so that heat loss from indoors to the outdoors through the windshield can be minimized, thereby improving the thermal insulation performance of windows and doors. In addition, since the windshield can be formed of different materials to prevent heat transfer and increase the surface temperature of the windshield, it is possible to prevent condensation and icing on the windows and doors.

In addition, since the present invention is integrally provided with the thermal barrier material in the windbreak frame, workability can be improved because a process of assembling the thermal barrier material separately in the windbreak frame is not required during window and door construction.

1 is an elevation view showing the elevation of a window to which the present invention is applied.
Figure 2 is a cross-sectional view showing a section AA of Figure 1;
Figure 3 is a view showing a manufacturing process of the external windshield of Figure 2;
4 is a view showing a cross-section of a window according to a comparative example of the present invention.
Figure 5 is an exploded cross-sectional view showing a state in which the cover member is separated from the window of Figure 2;
Figure 6 is a view showing a process of coupling the cover member of Figure 5 to the window.
7 is a simulation result of testing the thermal insulation effect of the embodiment according to the present invention.
8 is a simulation result of testing the thermal insulation effect of the comparative example shown in FIG.

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

First, the embodiments described below are embodiments suitable for understanding the technical characteristics of the present invention windows. However, the present invention is not limited to the embodiments described below, or the technical features of the present invention are not limited by the described embodiments, and various modifications are possible within the technical scope of the present invention.

1 and 2 , the composite window 100 according to an embodiment of the present invention includes a window sill 200 and a windshield 300 .

The window sill 200 is installed to be slidably opened and closed on the window frame 101 and may be provided in at least one pair. For example, the changjjak 200 may be provided as a pair as in the embodiment shown in FIG. 1 , and hereinafter, the case provided as a pair will be described as an example, but the present invention is not limited thereto, and the changjjak 200 is 3 or more. may be provided.

The windbreak frame 300 is vertically coupled to the changjjak 200, and is provided at the overlapping portions of the adjacent changjjak 200 that are engaged in a closed state. Specifically, in the sliding window, the portion where the first and second sashes 210 and 220 intersect in the closed state in which two or more spearheads 200 are closed is called a closing stand, and the windshield 300 is a sash at the fastening portion. It may be vertically coupled to 200 . At this time, the windshield 300 is provided on each window jap 200 and is formed to overlap each other in the closed state, thereby blocking the flow of air and heat through the gap between the adjacent window sills 200 .

The windshield 300 according to the present invention includes a chamber 331 and a thermal barrier material 332 . The chamber 331 is provided to be positioned in a space between the changjjak 200 facing each other in a state where the changjjak 200 is closed. In addition, the heat cross-blocking material 332 is inserted into the chamber 331 to minimize the flow of heat through the windshield 300 . Here, the thermal barrier material 332 may be a polyurethane-based material, expanded polypropylene (EPP), expanded polystyrene (EPS), extruded expanded polystyrene, expanded vinyl acetate (EVA), expanded polyethylene (PE), etc., but is not limited thereto. , It is applicable as long as it is a material that can block heat or cold air transmitted through the windshield.

As described above, the windshield 300 applied to the present invention is provided with a heat cross-blocking material 332 integrally. Accordingly, it is possible to minimize the heat loss from the indoor to the outdoor through the windbreak 300 and to prevent the inflow of cold air from the outdoors to improve the insulation performance of the windows. In addition, since it is possible to increase the surface temperature of the windbreak frame 300 by preventing the movement of heat through the thermal barrier material 332 , it is possible to prevent condensation and icing on the windows and doors.

In addition, since the present invention is integrally provided with the thermal barrier material 332 in the windbreak frame 300, it does not require a process of assembling the thermal barrier material 332 to the windbreak frame 300 separately when constructing windows and doors, so workability can be improved. there is.

Specifically, the changjjak 200 may include a first changjjak 210 and a second changjjak 220 disposed on the indoor side of the first changjjak 200 . And the windshield 300 may include an outer windshield 310 coupled to the first windowpane 210 and an inner windshield 350 coupled to the second windowpanel 220 . Here, the chamber 331 may be provided to be formed integrally with the external windshield 310 to be disposed in a space between the first and second windows 210 and 220 facing each other in a closed state.

Changjak 200 according to the present invention is made of a synthetic resin material such as PVC, it is possible to improve the insulation performance. In addition, the external windshield 310 may be formed of a metal material such as aluminum, and may improve the aesthetics of the appearance of the windows and doors by forming the exterior of the metal material together with the metal cover member 400 to be described later. The inner windshield 350 may be formed of the same material or a different material as that of the outer windshield 310, but is preferably formed of a synthetic resin material, which is a different material, to improve thermal insulation performance and the inner tube made of the same material as the window sill 200. can be implemented. As described above, the window according to the present invention may be a composite window 100 made of a metal material and a synthetic resin material, and the heat cross-blocking material 332 is formed on the external windbreak frame 310 made of a metal material to effectively block the flow of heat.

However, the material of the window frame 200, the outer windshield 310, and the inner windshield 350 applied to the present invention is not limited to the above-described example, and various modifications are possible if the thermal insulation performance can be improved.

More specifically, the external windshield 310 may include a first coupling part 320 and a first insertion part 330 . The first coupling part 320 may be coupled to one end of the outer windbreak frame 310 in the sliding movement direction of the first changjjak 210 , and a first coupling protrusion 321 is formed and fitted to the changjjak 200 . can be combined.

The first insertion part 330 may be bent and extended from the first coupling part 320 , and may be coupled to a surface of the first window jap 210 facing the second window jap 220 . A chamber 331 may be formed in the first insertion part 330 .

Specifically, the chamber 331 includes a first cut-out 331a elongated in the vertical direction to form an opening on the surface facing the first window sill 210 , and an opening on the surface facing the second window sill 220 . It may include a second cutout 331b long cut in the vertical direction. Accordingly, as shown in FIG. 2 , the first insertion part 330 is formed intermittently around the heat cross-blocking material 332 , thereby effectively blocking the flow of heat. In particular, when the external windshield 310 is made of a metal material with high thermal conductivity (eg, aluminum), the heat transfer path may be inhibited through the heat cross-blocking material 332 , and thus the flow of heat may be more effectively blocked.

3 shows a process of integrally forming the thermal cross-blocking material 332 on the external windbreak frame 310 . As in the illustrated embodiment, a second cut-out 331b is formed in the chamber 331 of the first insertion section 330 (FIG. 3(a)), and a heat-crossing barrier material ( After filling 332) (FIG. 3(b)), the first cutout 331a may be formed by post-processing (FIG. 3(c)). However, the method of inserting the thermal barrier material 332 into the chamber 331 is not limited to the embodiment shown in FIG. 3 .

The inner windshield 350 includes a second coupling part 360 and a second insertion part 370 . The second coupling portion 360 may be coupled to the end of the sliding movement direction of the second windowjal 220 , and a second coupling protrusion 361 may be formed. And the second insertion part 370 is bent and extended from the second coupling part 360 , and is provided to be positioned in the space between the second changjjak 220 and the first changjjak 210 , and the first inserting part 330 and Together, it is possible to block a gap in the space between the windowsill 200 .

Meanwhile, the first insertion part 330 may include a gasket insertion groove 333 and a first gasket 334 . The gasket insertion groove 333 may be formed at an end of the chamber 331 in a direction opposite to the direction toward the first coupling part 320 . The first gasket 334 may be provided to be in contact with the inner windbreak frame 350 inserted into the gasket insertion groove 333 and coupled to the second window sill 220 . A second gasket 371 may be fixed to an end of the second insertion part 370 of the inner windshield 350 . Here, the first gasket 334 and the second gasket 371 may be made of a material having low thermal conductivity, such as a rubber material. The flow of air and heat between the outer windshield 310 and the inner windshield 350 may be blocked by the first gasket 334 and the second gasket 371 .

Also, the first insertion part 330 may include a mohair insertion groove 335 and a first mohair 336 . As an example, the mohair insertion groove 335 may be provided in a direction from the chamber 331 toward the first coupling part 320 , and the first mohair 336 is inserted into the mohair insertion groove 335 and is inserted into the window sill 200 . You can keep the space between them private. A screw member 337 for fixing the external windbreak frame 310 to the window sill 200 may be fastened to the inside of the mohair insertion groove 335 . Also, the second mohair 372 may be fixed to the second insertion part 370 . The first mohair 336 and the second mohair 372 may airtight between the outer changjjak 210 and the inner changjjak 220 .

In Figure 4, as a comparative example, instead of having the chamber 331 and the heat-crossing barrier material 332 in the external windshield 310, the conventional insulating material 332a is separately installed between the external windshield 310 and the window sill 200. An assembled example is shown.

When the heat insulating material 332a is separately installed as in the comparative example of FIG. 4 , the heat cross-blocking material 332 is not inserted into the external windbreak frame 310 itself, so the heat escapes from the inside to the outside through the external windshield 310 . Heat loss may occur, or cold air from the outside may flow into the room, and this may cause condensation or icing on the windows and doors due to a decrease in the surface temperature of the external windshield 310 . In addition, since the process of assembling the insulating material 332a is separately required when constructing a window, there may be a problem in that constructability and workability are deteriorated.

In order to solve this problem, the present invention shown in FIG. 2 can minimize heat loss through the external windshield 310 and improve workability by integrally forming the heat cross-blocking material 332 on the external windshield 310. there is.

Meanwhile, referring to FIGS. 5 and 6 , the present invention may further include a cover member 400 . The cover member 400 is provided to cover the outer surface 201 of the window jap 200 and may be fitted to the window jap 200 . Here, the window sill 200 may be formed of a synthetic resin material and the cover member 400 may be formed of a metal material. The cover member 400 may be formed of the same metal as the external windshield 310 to implement an appearance of the same material. The windows and doors according to the present invention can improve both insulation performance, structural performance, and aesthetics of appearance by implementing windows and doors made of a composite material using a synthetic resin material and a metal material.

The cover member 400 according to the present invention may be coupled to both the first changjjak 210 and the second changjjak 220 . 5 and 6, a case in which the cover member 400 is installed on the first window sill 210 is described as an example, but the configuration and coupling method of the cover member 400 are the first window sill 210 and the second window sill 220. All are the same. 400 ′ in FIG. 2 is a cover member coupled to the second window sill 220 .

Specifically, the window glass 200 has an outer surface 201 that is a surface facing the outside, a first surface 202 perpendicular to the outer surface 201 and a locking groove 202a is formed, and the first surface 202 in the opposite direction. It may include a second surface 203 facing toward the fitting groove (203a) is formed.

In addition, the cover member 400 may include a cover plate 410 that covers the outer surface 201 and a first bent portion 420 and a second bent portion 430 that are bent and extended from the cover plate 410 . there is. The first bent portion 420 may be bent at one end of the cover plate 410 and formed with a locking protrusion 421 fitted into the locking groove 202a. In addition, the second bent portion 430 may be bent at the other end of the cover plate 410 and a fitting protrusion 431 fitted into the fitting groove 203a may be formed.

In addition, the second surface 203 is in the direction toward the outer surface 201 of the fitting protrusion 431 to guide the fitting protrusion 431 to the fitting groove 203a when the cover member 400 is coupled to the window sill 200. An inclined surface 203b may be formed. Specifically, the inclined surface 203b may be formed to be inclined in a direction toward the first surface 202 from the fitting groove 203a toward the outer surface 201 . When the cover member 400 is coupled to the window sill 200 by the inclined surface 203b, the fitting protrusion 431 is easily guided into the fitting groove 203a, thereby improving assembly. Here, in the window glass 200, a glass insertion groove into which the glass member G is inserted may be formed, and the fitting groove 203a may be formed adjacent to the glass insertion groove.

Specifically, referring to the coupling process shown in FIG. 6 , an outer window jap 210 having a locking groove 202a and a fitting groove 203a is prepared (FIG. 6(a)), and the blocking stone of the cover member 400 is provided. After inserting the group 421 into the locking groove 202a, the cover member 400 is rotated around the locking groove 202a (FIG. 6 (b)), and the fitting projection 431 is inserted into the fitting groove 203a. can be inserted into At this time, the fitting protrusion 431 can be easily inserted into the fitting groove 203a by sliding on the inclined surface 203b (FIG. 6(c)).

Here, the fitting groove (203a) is formed to be biased toward the glass insertion groove, and even if a small amount of the sealant (S) is applied after the glass member (G) is installed in the glass insertion groove, the sealant (S) is not applied to the glass member (G) It may be applied to the cover member 400 as well as 200 . That is, the cover member 400 may be fixed once more by the sealant (S). As described above, since the sealant S has a structure that is adhered to both the cover member 400 and the window sill 200 at once, as the cover member 400 and the window sill 200 are made of different materials, shrinkage and expansion or external It is possible to prevent the cover member 400 from being separated from the window sill 200 due to the impact.

Meanwhile, a test example for verifying the effect of the external windshield 310 applied to the present invention is shown in FIGS. 7 and 8 . 7 is a simulation result of testing the thermal insulation effect of the embodiment according to the present invention, and FIG. 8 is a simulation result of testing the thermal insulation effect of the comparative example shown in FIG. 4 .

In the test, the indoor temperature was 20 °C and the outdoor temperature was 0 °C, and the glass member (G) installed on the surface (point B) of the first insertion part 330 of the external windshield 310 and the windowpane 200 at the same point. ) of the indoor surface (point C) was measured.

As a result of the test, the temperature of the point B of the comparative example (FIG. 8) was measured to be 3.2 °C, the temperature of the point C was measured to be 11.0 °C, and the thermal transmittance (Uf) of the window glass 200 in the closed state was measured to be 2.43 W/m ² K. On the other hand, in the embodiment according to the present invention (Fig. 7), the temperature of point B was 4.9 ℃, the temperature of point C was 11.4 ℃, and the thermal transmittance (Uf) of the window in the closed state was 2.35 W/m ² K. was measured.

Therefore, when the external windbreak frame 310 in which the heat cross-blocking material 332 of the present invention is integrated is applied, heat transfer from indoors to the outdoors can be minimized to improve thermal insulation performance, and the surface temperature of the windshield 300 can be increased. It could be verified that there was an excellent effect of preventing the occurrence of condensation or freezing.

As described above, the composite windows according to the present invention are provided with a windshield provided with a thermal barrier material integrally, so that heat loss from indoors to the outdoors through the windshield can be minimized, thereby improving the thermal insulation performance of windows and doors. And since it is possible to increase the surface temperature of the windshield by preventing the movement of heat, it is possible to prevent the occurrence of dew condensation and freezing.

In addition, since the present invention is integrally provided with the thermal barrier material in the windbreak frame, workability can be improved because a process of assembling the thermal barrier material separately in the windbreak frame is not required during window and door construction.

As mentioned above, specific embodiments of the present invention have been described above, but the spirit and scope of the present invention are not limited to these specific embodiments, and those described in the claims by those of ordinary skill in the art to which the present invention pertains Various modifications and variations are possible without changing the gist of the present invention.

100: composite windows
101: window frame
200: window
201: exterior
202: first side
202a: jamming groove
203: second side
203a: fitting groove
203b: slope
210: first window
220: second window
300: windshield
310: external windshield
320: first coupling part
321: first coupling protrusion
330: first insertion part
331: chamber
331a: first incision
331b: second incision
332: thermal barrier material
332a: conventional insulation
333: gasket insertion groove
334: first gasket
335: mohair insertion groove
336: first mohair
337: screw member
350: internal windshield
360: second coupling part
361: second coupling protrusion
370: second insertion part
371: second gasket
372: second mohair
400: cover member
410: cover plate
420: first bent part
421: stumbling block
430: second bent part
431: fitting projection
G: glass member
S: sealant

Claims (8)

The window sill is installed on the window frame to be slidably opened and closed, and includes a first sash disposed on the outdoor side and a second sash disposed on the indoor side and formed of a synthetic resin material; and
A windbreak frame coupled in a vertical direction to the window sill, provided at a portion where the window slats overlap in a closed state, and having an external windshield formed of a metal material coupled to the first window sill;
The outer windshield is provided to be positioned in a space between the windows facing each other in the closed state of the windows, the open chamber; and a first insert comprising a; and a heat cross-blocking material integrally provided in the chamber;
The first insertion part
a gasket insertion groove formed at one end of the chamber; and
It further comprises a; mohair insertion groove formed at the other end of the chamber,
The thermal cross-blocking material is a composite window that is inserted between the gasket insertion groove and the mohair insertion groove. delete According to claim 1,
The outer windshield further comprises a first coupling portion coupled to the end of the sliding movement direction of the first window,
The first insertion part is bent and extended from the first coupling part, and is provided to be coupled to a surface of the first window jap facing the second window jap,
The gasket insertion groove is formed at an end of the chamber in a direction opposite to the first coupling portion, and the mohair insertion groove is formed at an end of the chamber in a direction toward the first coupling portion. delete According to claim 1,
Composite windows and doors that are provided to cover the outer surface of the windows and further include a cover member fitted to the windows. 6. The method of claim 5,
The window jar includes an outer surface that is a surface facing the outdoor side, a first surface perpendicular to the outer surface and having a locking groove, and a second surface facing the opposite direction of the first surface and having a fitting groove,
The cover member includes a cover plate for covering the outer surface, a first bent portion bent at one end of the cover plate and formed with a locking protrusion fitted into the locking groove, and bent at the other end of the cover plate and into the fitting groove. A composite window including a second bent part having a fitting protrusion to be fitted. 7. The method of claim 6,
The second surface is a composite window in which an inclined surface is formed in a direction toward the outer surface of the fitting protrusion to guide the fitting protrusion to the fitting groove when the cover member is coupled to the window sill. 7. The method of claim 6,
The fitting groove is a composite window formed adjacent to the glass insertion groove of the window.

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