KR20180043240A - Insulation Structure of a Sliding Window System with Aluminium Sash - Google Patents

Abstract

The present invention relates to an insulation structure of a sliding window system. More specifically, the present invention relates to a profile structure of a window frame (window mounting frame) and a moving window (window frame) constituting a sliding window system of an aluminum sash structure having high thermal conductivity, so that two insulation structure lines are formed between an outer frame and an inner frame. By doing so, it is possible to greatly improve a heat insulation function and a condensation prevention function.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sliding window system for an aluminum chassis,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a moving window insulating structure of a sliding window system, and more particularly, to a sliding window system having an aluminum chassis structure, which improves the profile sectional structure of a window frame (window mounting frame) To a heat insulating structure of a sliding window system of an aluminum chassis structure which can greatly improve the dew condensation preventing function.

Looking at the most common configuration of a sliding window system (such as a glass window panel installed inside) and a window frame (annularly installed in a building wall and having a window installed therein) constituting a sliding window system, A window frame provided with a rail guide (guide rail, guide way) serving as a guide when the window slides is annularly installed on the wall of the building, and a roller is installed outside the frame so that the window can move smoothly along the guide rail installed on the window frame And a window having a sectional structure in which a panel such as a glass or a plate is installed inside the frame is provided inside the window frame.

However, in such a general and simple structure, it is generally difficult to expect high quality performance for soundproofness, airtightness (windproof), watertightness, insulation, and wind resistance. To compensate for this, It is possible to improve the performance by attaching the sealing member of the windshield rubber gasket. However, due to the limit of the sealing method, the sealing effect by the sealing member such as windshield or windshield rubber is not high, There is a disadvantage that it is difficult to maintain the performance continuously as the wear or abrasion proceeds.

In order to compensate for the disadvantages of the sliding window system of the general structure described above, an open and close structure of a 'lift & sliding method' (simply, an 'LS method') is proposed as one of the prior arts developed The sealing of the upper gap between the lower portion of the moving window 4 and the upper portion of the window frame 1 can be achieved by using a moving window The upper sealing member 3u provided on the upper frame of the movement window 4 is spaced apart from the upper guide rail 1a provided below the upper portion of the window frame 1 and is moved 4) is lowered, the upper sealing member 3u comes into contact with the upper guide rail 1a to be sealed.

1 and 2, and an enlarged view of the 'R' portion and an enlarged view, respectively, the portion between the longitudinal window frame and the window frame in the longitudinal direction is divided into two portions, When the lateral sliding is completed and the window is completely closed, the side sealing member 4s such as the rubber gasket is pressed to have the airtightness.

However, in the case of such an open / close structure, the principle of achieving sealing at the bottom, the side and the top in one window, and the sealing direction, that is, the sealing manner are different from each other and are incompatible, It is difficult to secure a perfect sealing performance at the corner of the upper guide rail 1a. Further, the sealing at the upper portion of the window is required to ensure the hermeticity only by a weak force that the upper sealing member 3u is elastically brought into close contact with the upper guide rail 1a. It is difficult to achieve sealing, and in particular, it is difficult to block heat transfer inside and outside through the upper guide.

In addition, as an example of a prior art in which window frames and window frames are made of aluminum material in constructing such a sliding sliding window system of the LS system, as shown in FIGS. 3 to 5, And a heat-shrinkable barrier material 1c made of a synthetic resin for interconnecting the inner frame 1a and the outer frame 1b of the building frame 1. Inside the window frame 1 annularly installed on the building wall, A sliding window system (2) in which a fixed window (2) and a movable window (4) are installed, which includes inner frames (2a, 4a) and outer frames (2b, 4b) Is commonly used.

3 is a top view of the moving window 4 in a state of being slidably closed and opened, and FIG. 4 is a front view of the sliding window 4 as shown in the upper part of FIG. The upper sealing member 3u and the lower sealing member 3b are in contact with the thermal bridge member 1c in the middle of the window frame 1 while the moving window 1 is moved downward, 5 shows a state in which the moving window 1 is lifted to the upper portion of the roller 4r in a state in which the moving window 4 is slid opened (door unlocking operation is performed) as shown in the lower part of FIG. 3 The state in which the upper sealing member 3u and the lower sealing member 3b are not in contact with the heat bridge member 1c in the middle of the window frame 1 is shown in a state of AA 'in Fig.

4 and 5, the insulated wire "INS " connecting the heat bridge member 4c provided at the center of the movement window 4 and the heat bridge member 1c provided at the center of the window frame 1 is substantially straight 4 and 5, the heat bridge member 1c provided at the center of the window frame 1 is formed so as to have an outer air ("air " And the roller 4r is installed in the inner frame 4a of the lower frame of the transfer window 4, it can be seen that the thermal insulation effect But it is rather disadvantageous to provide the support rigidity due to the disconnection of the frame supporting the roller 4r. In addition, as shown in Fig. 3 K-K 'line The moving window 4 is formed by connecting an outer frame 4b made of an aluminum material, a thermal bridge member 4c made of an intermediate synthetic resin material, and an inner frame 4a made of aluminum, . It is impossible to provide a separate rigid frame capable of improving the longitudinal stiffness of the entire frame constituting the movable window 4, and thus there is a problem that there is no means for sufficiently providing durability against wind pressure in the case of enlarging a window.

As a new technique proposed to overcome the disadvantage of the sliding window system having the open / close structure of the 'LS system' so far described as a new technology, a sliding window system of a sliding window system of an aluminum chassis structure, which was filed by the applicant of the present application and patented, 10, 2013), and US 2015/0052819 A1 (Feb. 26, 2015) of Korean Patent Registration No. 10-1402940, PCT Publication No. WO 2013/151293 A1 (Oct. And the like.

Hereinafter, a moving window installation structure of a sliding window system of an aluminum chassis structure having the configuration disclosed in the above application will be described as another prior art (Prior Art II) to be improved in the present invention.

According to the drawings disclosed in the publications of the above applications (for example, FIG. 21 of the registration document of Korean Patent Registration No. 10-1402940, WO 2013/151293 Al and US 2015/0052819 A1), the moving window is in a state of sliding sliding Quot; INS "like the insulated structure (single line) shown in the cross-sectional view along the line A-A 'in FIG. 6B in a cross-sectional view (here, ),

And a first thermal bridge member 100c1 made of a synthetic resin and interconnecting the inner frame 100a and the outer frame 100b having a high thermal conductivity and having a high thermal conductivity. The first thermal bridge member 100c1 is installed annularly on the building wall, A window frame 100 on which a rail guide is installed; And

The window frames 200a and 300a and the outer frames 200b and 300b having high thermal conductivity are stacked as window frames 200g and 300g, A fixing window 200 and a moving window 300 including a heat-shading barrier 200c and 300c for a window frame made of synthetic resin and interconnecting them;

Is made of an aluminum material having a first heat shielding end and a sealing member 100s which can be made of, for example, synthetic resin, and is provided in an annular shape in the transfer window closing region inside the outer frame 100b of the window frame 100 A sealing frame 100d for a moving window provided to connect between the inner frame 100a and the outer frame 100b; And

The movable window 300 is provided at the lower portion of the movable window 300 so as to provide sliding movement in the longitudinal direction of the rail guide 100r of the window frame 100 of the movable window 300 for sealing the movable window sealing frame 100d. And a roller device 400 installed separately from the rollers 300,

A second thermal bridge member 100c2 made of a synthetic resin material is provided to interconnect the moving window sealing frame 100d connected to the outer frame 100b and the inner frame 100a in a heat transfer cut-off manner, The inner frame 100a, the outer frame 100b, the movable window sealing frame 100d and the inner frame 100a are arranged so that the inner frame 100a, the moving window sealing frame 100d, 100c2, and 100c to form a short-circuited heat air layer 300i in the interior of the sliding window system.

6A and 6B, when the inner frame 100a and the outer frame 100b constituting the window frame 100 are connected to each other by heat transfer interception, A first heat bridge member 100c1 made of synthetic resin and installed so as to interconnect with each other by a heat transfer cut-off method, and a heat shielding method for interconnecting the moving window sealing frame 100d connected to the outer frame 100b and the inner frame 100a The inner frame 100a, the outer frame 100b, the moving window sealing frame 100d, and the inner frame 100c2 are arranged so that the installation directions of the second thermal bridge members 100c2, 100a are annularly connected to each other through the thermal bridge members 100c1, 100c2, and 100c to form a short-circuited heat air layer 300i therein, A connection structure of a movable window sealing frame 100d and an outer frame 100b forming an external first vertical connection structure so as to reach the interior of the building from the outside of the window as shown in FIG. The thermal bridge member 300c, the second heat shield and the sealing member 310s, the first heat shield, and the sealing member 100s (not shown) are provided between the connection structure of the movement window 300 and the inner frame 100a, ("INS") formed of the first thermal bridge member 100c2, the thermal short-circuiting air layer 300i and the first thermal bridge member 100c1 is constructed to provide a high thermal efficiency, The dew condensation phenomenon of the aluminum chassis at the time of occurrence of the high temperature difference of the aluminum chassis is prevented.

However, even when the short-circuited heat air layer 300i is formed as described above, if the difference between the temperature of the outer frame 100b and the temperature of the moving frame sealing frame 100d and the temperature of the inner frame 100a is large, Since the outer side portion of the inner frame 100a is difficult to completely block the outer environment unlike the inner side portion, the thermal insulation effect and the dew condensation prevention effect Is not easy to achieve.

One side of the second heat bridge block 100c2 made of a synthetic resin and installed to interconnect the moving window sealing frame 100d and the inner frame 100a in a heat transfer cut-off manner is connected directly to the inner frame 100a A structure that is indirectly connected to the inner frame 100a through a connection body portion indicated by a reference numeral 100k in the drawing may be adopted as shown in enlarged view in FIGS. 6a and 6b, The sealing frame 100d for a moving window and the connecting body 100k are integrally formed by aluminum extrusion including a connecting part and the sealing frame 100d for a moving window is integrally formed as shown in Figure 6C, A synthetic resin material (liquid polyurethane) is injected into the connecting portion between the first and second connecting members 100k and 100k to form the second insulating bridge member 100c2, A sealing frame (100d) for alumni, the second thermal bridges the barrier material (100c2), and a connecting body portion (100k) is create a connected state.

The sealing frame 100d for the moving window, the second thermal bridge member 100c2 and the connecting body 100k connect the connecting body 100k of the connecting body to the inner frame 100a and fastening screws 100ks This fastening screw 100ks sequentially passes through the sealing frame 100d for the moving window, the second thermal bridge member 100c2, the connecting body 100k and the inner frame 100a, And a sealing frame cap 100d-cap for the moving window is additionally assembled so that the fastening screw 100ks covers the through-hole 100d-hole formed through the sealing window 100d for the moving window. There is a serious problem that the synthetic wastewater material is considerably damaged in the process of penetrating the head portion of the fastening screw 100ks completely through the second heat bridge block 100c2 in the through-hole fastening process.

Also, in the prior art (Prior art II) described with reference to FIGS. 6A to 6C, in the process of completely passing the head portion of the short fastening screw 100ks through the second thermal bridge member 100c2, the second thermal bridge member 100c2 is formed (Prior Art IIa) as shown enlarged in FIGS. 7A and 7B can be used in order to avoid a situation where considerable damage is caused to the synthetic water-repellent material of FIG. 6A and FIG. of the fastening screw (100ks) instead of by the use of a long length of the fastening screw (100ks-L) shown in Fig. 7a and 7b the outer frame (100d), a second thermal bridges the barrier material (100c2), connected to a body portion (100k), and by at the same time it entered through the inside of the frame (100a) by adding the head of the connected fastening sikidoe fastening screw (100ks-L) so as to be fixed in the outer frame (100d) additional heads of the fastening screws (100ks-L) a second thermal bridges the barrier material (100c2) Do not penetrate The second thermal bridge block 100c2 is prevented from breaking down and is also easier in terms of work difficulty, so that it is frequently applied in the actual construction situation. However, in such a fastening structure, heat conduction is generated between the outer frame 100d and the inner frame 100a through the long-length fastening screw 100ks-L , which is fastened through the members, .

As described above, according to the prior art window having a structure in which one insulated wire ("INS") is provided between the members disposed in the window Inside and the members exposed in the external environment, In the case of the system, a part (ⓜ) adjacent to the members (ⓞ) disposed on the out side of the window and exposed to the external environment among the members disposed on the inside of the window (Inside) The heat conduction is performed, and as a result, the desired heat insulation effect at the time of designing can not be achieved properly.

Korean Patent Registration No. 10-1402940 (2014.06.27) WO 2013/151293 A1 (Oct. 10, 2013). U.S. Patent Application Publication No. US 2015/0052819 A1 (Feb.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the prior art and its modifications, and it is an object of the present invention to improve the profile sectional structure of a window installation frame and a window frame in which a sliding window of an aluminum chassis structure is installed, And it is an object of the present invention to provide a thermal insulation structure of a sliding window system of an aluminum chassis structure which can minimize the possibility of thermal insulation breakage that may occur in actual commercialization and construction steps.

As a means for achieving the above-mentioned technical object,

A window frame comprising an inner frame of aluminum having a high thermal conductivity and an outer frame and a first thermal barrier of synthetic resin which interconnects the inner frame and the outer frame and is installed annularly on the building wall and provided with a rail guide in the lateral direction above the floor;

A window frame movably installed inside the window frame, the window frame being a window frame for supporting a window panel such as a window pane, the window frame comprising: an inner frame of aluminum having a high thermal conductivity; an outer frame; A transfer window including a transfer window; And

A window frame made of a synthetic resin material and made of an aluminum material having a first heat shielding end and a sealing member provided on the front side so as to be in contact with the moving window and is provided in an annular shape in a transfer window closing area inside an outer frame of the window frame, And a sliding window sealing frame provided so as to connect between the outer frame and the outer frame,

A second heat bridge block made of a synthetic resin material is additionally installed to interconnect the moving frame for a moving window connected to the outer frame and the inner frame in a heat transfer cut-

The inner frame, the outer frame, the movable window sealing frame, and the inner frame are annularly connected to each other through the thermal bridge block so that the inner frame, the inner frame, In a heat insulating structure of a sliding window system of an aluminum chassis structure in which a heat insulating air layer is formed,

The inner frame part is divided into an outer side inner frame part disposed in contact with the heat insulating air layer and an inner side inner frame part disposed inside the inner side frame part and a synthetic resin And a third thermal bridge member made of a material is additionally provided so that two thermal insulating structure lines are formed between the outer frame and the inner frame, thereby providing a thermal insulation structure for a sliding window system of an aluminum chassis structure.

According to the present invention, the profile section structure of the window frame and the window frame in which the sliding window of the aluminum chassis structure is installed is improved so that two insulating structure lines are formed between the outer frame and the inner frame, And it is possible to improve the convenience of the construction by allowing the inner insulation structure line to be maintained even if the outer insulation structure line is broken out of the two insulation structure lines through the manufacturing and assembling process of the window frame frame Effect is also provided.

1, 2, and 3 are diagrams illustrating a general configuration of a sliding window system.
FIG. 4 and FIG. 5 are diagrams showing a non-stop window system according to a conventional lift-and-slide method; FIG.
6A shows a sliding window system of an aluminum chassis according to the prior art shown in FIG. 21 (WO 2013/151293 A1, FIG. 22, US 2015/0052819 A1) of Korean Patent Registration No. 10-1402940 II is an enlarged view of a state in which a moving window is slid in a sealed state.
6B shows a sliding window system according to the prior art shown in FIG. 21 (WO 2013/151293 A1, FIG. 22, US 2015/0052819 A1) of Korean Patent Registration No. 10-1402940 II is an enlarged view of a heat insulating structure (single line) portion in a state where a moving window is slid in a sealing manner.
FIG. 6C is a view illustrating a process of forming a connection frame for a movable window sealing frame, a second heat bridge block, and a connection body in an aluminum chassis structure according to a related art, and joining the connection frame to the inner frame.
FIGS. 7A and 7B are diagrams showing a state in which a single wire is broken (Prior Art IIa) due to a construction problem in a sliding window system of an aluminum chassis structure according to the prior art shown in FIGS. 6A and 6B.
FIG. 8A is a cross-sectional view illustrating a heat insulation structure in a sliding window system of an aluminum chassis structure according to an embodiment of the present invention, showing a state before the sliding window is sealed slid (Unsealed State); FIG.
FIG. 8B is a cross-sectional view showing a heat insulating structure in a sliding window system of an aluminum chassis structure according to an embodiment of the present invention, and shows a state in which a moving window is in a sealed state (sealed state)
FIG. 9 is a cross-sectional view of a sliding window system of an aluminum chassis structure according to an embodiment of the present invention, showing a state in which a moving window is opened; FIG.
FIG. 10 is a cross-sectional view of a sliding window system of an aluminum chassis structure according to a further embodiment of the present invention, in which a side wall of a moving window frame itself is provided with an additional thermal insulation structure through a lateral heat- Lt; RTI ID = 0.0 > flexure < / RTI >
11 is a sectional view taken along the line A-A 'in Fig. 8A.
12 is a sectional view taken along line A-A 'in FIG. 8B.
13 is a sectional view taken along the line B-B 'in Fig.
FIG. 14 is a longitudinal sectional view of a sliding window system of an aluminum chassis structure according to an embodiment of the present invention, in which two insulation structure lines (single line) are generated; FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

First, the insulation structure of the sliding window system of the aluminum chassis structure according to the preferred embodiment of the present invention illustrated in FIGS. 8A to 14 and its moving window installation structure are as follows.

8A is a cross-sectional view illustrating a heat insulating structure of a sliding window system of an aluminum chassis structure according to an embodiment of the present invention, showing a state (a: Unsealed State) before a moving window is slid and FIG. And FIG. 9 shows a state in which the moving window is slid to the right (toward the fixed window) and the window itself is opened to the outside. FIG. 11 is a sectional view taken along line A-A 'in FIG. 8A, FIG. 12 is a sectional view taken along line A-A' in FIG. 8B, and FIG. 13 is a sectional view taken along line B-B 'in FIG.

In other words, as shown in the drawings, the sliding window system of the aluminum chassis structure according to the present invention basically comprises an aluminum frame 100a and an outer frame 100b having high thermal conductivity and a synthetic resin material A window frame 100 comprising a first thermal bridge member 100c1 of the first bridge 100c1 installed in an annular shape on a building wall and having a rail guide 100r horizontally installed on an upper portion of a bottom surface thereof;

A window member movably installed inside the window frame 100 and serving as a window frame 300g for supporting a window panel 300g such as a windshield, an inner frame 300a and an outer frame 300b made of aluminum and having a high thermal conductivity, A transfer window 300 including a first thermal bridge member 300c for a window frame of a synthetic resin material to be connected; And

And a sealing member (100s), which is made of a synthetic resin material and is provided to be in sealing contact with the moving window, is provided on the front surface of the window frame (100) And a sliding window sealing frame (100d) provided to connect between the inner frame (100a) and the outer frame (100b), the sliding window system comprising:

A second thermal bridge member 100c2 of a synthetic resin material is additionally installed to interconnect the moving window sealing frame 100d connected to the outer frame 100b and the inner frame 100a in a heat transfer cut-

The inner frame 100a, the outer frame 100b, the moving window sealing frame 100d, and the first and second thermal bridge members 100c1 and 100c2 are arranged so that the installation directions of the first thermal bridge member 100c1 and the second thermal bridge member 100c2 are orthogonal to each other, And a heat shielding air layer (300i) is formed in the inner frame (100a) by annularly connecting the inner frame (100a) with the heat shielding material (100c1, 100c2: 100c)

The inner frame 100a is divided into an outer side inner frame part 100a-out and an inner side inner frame part 100a-in which are disposed in contact with the heat insulating air layer 300i, A third thermal bridge member 100ah of a synthetic resin material is additionally installed to interconnect the inner frame part 100a-out and the inner frame part 100a-in by a heat transfer cut-off method, INS-out " and "INS-in" are formed between the heat insulating structures 100a and 100a of the sliding window system.

Briefly, in a heat insulating structure of a sliding window system of an aluminum chassis structure,

Sectional profile of a window frame constituting a sliding window system of an aluminum chassis structure having a high thermal conductivity is divided and formed by an outer frame 100b and an inner frame 100a and a sectional profile of the window frame is formed between the outer frame 100b and the inner frame 100a The heat bridge block 100c1 is inserted and connected to each other in a heat train manner,

The inner frame 100a is divided into an outer side inner frame part 100a-out and an inner side inner frame part 100a-in on the inner side, and the outer side inner frame part 100a-out and the inner side inner frame part 100a- A heat bridge member 100ah of a synthetic resin material is additionally installed so as to interconnect the heat sinks 100a-in by a heat transfer cut-

Two insulated structure lines ("INS-out" and "INS-in") are formed between the outer frame 100b and the inner frame 100a.

One side of the second heat bridge member 100c2 made of a synthetic resin material for interconnecting the moving window sealing frame 100d and the inner frame 100a is directly connected to the inner frame 100a Instead, a structure may be adopted in which the inner frame 100a is indirectly connected to the inner frame 100a through a connecting body portion indicated by a reference numeral 100k in the drawing, that is, the inner frame 100a itself is provided with a first heat terminal and a seal As a means for solving the problem that it is difficult to extrude integrally so as to have a complicated shape capable of accommodating the member 100s and the second heat bridge block 100c2, the first heat shield and the sealing member 100s and An indirect mounting structure using a separate connecting body portion 100k having a shape capable of accommodating the second thermal bridge block 100c2 may be provided. In order to achieve such indirect mounting structure, As described with reference to FIG. 6C in the description of the related art, first, the sealing frame 100d for a moving window and the connecting body 100k are integrally formed by aluminum injection, including a connecting part, and the sealing frame for a moving window 100d (Liquid polyurethane) is injected into the connecting portion between the connecting window portion 100k and the connecting body portion 100k to form the second insulating bridge member 100c2, and then the connecting portion is removed to form the sliding window sealing frame 100d, The second window frame 100c2 and the connecting body portion 100k are connected to each other so that the connecting window 100k2 and the connecting body portion 100k are connected to each other. The connecting body portion 100k is connected to the inner frame 100a and fixedly coupled with the fixing screw 100ks-L through the fixing screw 100ks-L . The fixing screw 100ks- Thermal barrier The head portion of the fastening screw 100ks-L is fixed in the sealing frame 100d for the moving window while sequentially passing through the connecting body 100c2, the connecting body 100k and the inner frame 100a, and the fastening operation is performed .

In the case of adopting a heat insulating structure in which two insulating structural lines ("INS-out" and "INS-in") are formed according to a preferred embodiment of the present invention, The connecting body portion 100k of the connecting body formed by connecting the sealing window frame 100d for the moving window, the second thermal bridge member 100c2 and the connecting body portion 100k is connected to the inner frame 100a and using a short length of the fastening screw (100ks) instead of the long length of the fastening screw (100ks-L) to the outer frame (100d), a second thermal bridges the barrier material (100c2), connected to a body portion (100k), and the inner frame (100a ( 100ks-L ) which is fastened through the members by being fastened in such a manner that the fastening screws ( 100ks-L ) passing through the fastening screws ( 100ks-L) ) ≪ / RTI > Out of the two insulation structure lines ("INS-out "and" INS-in ") between the outer frame 100d and the inner frame 100a by means of the second insulation bridge 100c2 Even if some deterioration occurs in the heat insulating function of the "INS-out") (or even if some damage to the heat insulating function occurs by causing the head portion to break the second heat bridge block by using the shortening screw 100ks ) (INS-in) generated by the third thermal bridge member 100ah provided to mutually connect the inner frame part 100a-out and the inner side inner frame part 100a-in in a heat transfer cut- () Can be continuously maintained, so that even if a certain degree of heat conduction is made to the portion (j) adjacent to the members (j) exposed to the external environment, the inner side of the window Member disposed (In Side) (ⓘ) are third thermal bridges the barrier material (100ah) itgie is formed separated from the part (ⓜ) adjacent the member (ⓞ), which is exposed to the outside environment, resulting in design time, desired insulation effect by And thus it is possible to secure the high level of insulation performance demanded by various architectural, environmental, and energy-related regulations that have been strengthened in recent years, and also to provide excellent effects in preventing condensation.

On the other hand, the inner side heat insulating rescue provided by the third thermal bridges the barrier material (100ah) is provided for interconnecting between the outer portion inside the frame part (100a-out) and the inner portion inside the frame part (100a-in) to the heat transfer block scheme ("INS-in"), the effect of the heat insulation function is achieved by the connection body portion 100k between the movable window sealing frame 100d, the second thermal bridge member 100c2, and the inner frame 100a, A structure in which a sealing window sealing frame 100d, a second thermal bridge member 100c2, and an inner frame 100a are directly connected to each other by fastening screws passing through these members, without a separate connecting body, It can also be exercised naturally.

The above-described embodiment relates to an improvement of a heat insulation structure formed mainly by members related to a window frame 100 in a heat insulation structure of a sliding window system of an aluminum chassis structure. According to a further preferred embodiment of the present invention, In addition to the structure, there is additionally provided an improvement to the insulation structure of the window frame, in particular of the window frame of the window, which is already provided in the moving window 300 in the sliding window system of the aluminum frame structure according to the prior art Which is disposed on the outer side of the window panel 300g located between the inner frame 300a and the outer frame 300b of the moving window 300 and is provided with a frame supporting frame 300d A first column for a moving window so as to interconnect the outer frames 300b in a heat- ("INS-out") from the Outside Side of the Window to the Inside Side of the Building (INS-out) is installed, and separately from the Window Panel Out support frame part 300d-out and the inner side support frame part 300d-in that support the inner side support frame part 300d-out in the outer side support frame part 300d-out, And a second heat bridge member 300dh for a moving window made of a synthetic resin so as to interconnect the inner support frame part 300d and the inner side support frame part 300d-in by a heat transfer cut-off method.

14, the second window member for thermal windowing 300dh is provided with a third thermal bridge member 300dh provided for the additional thermal insulation between the outer frame 100d of the window frame 100 and the inner frame 100a described above, INS-in "from the outside of the window to the inside of the building (IN Side) together with the barrier material 100ah .

However, such a mobile window use the second thermal bridges the barrier material (300dh) is a 3 jungyuri structure as shown in the figure that applied will be easy, for the second jungyuri structure alternatively include this moving window use of a second thermal bridges the barrier material (300dh) The moving window orthogonal direction moving device 500 can be positioned at the center of the window by minimizing the width (thickness) of the moving window orthogonal direction moving device 500 so that the force required for the operation of the opening and closing operation driving part for the sealing sliding movement by the moving window orthogonal direction moving device 500 So as not to cause a great increase disadvantage.

Thereby, the connection structure of the moving window sealing frame 100d and the outer frame 100b, which form an external first up-and-down connection structure, from the outside of the window to the inside of the building, The second heat shielding member and the sealing member 310s for the window frame of the moving window 300 and the first heat shielding member and the sealing member ("INS-out"), which is formed of a first thermal bridge member 100s, a second thermal bridge member 100c2, a thermal barrier air layer 300i, and a first thermal bridge member 100c1, A supporting frame 300d for supporting the window panel 300g of the window panel 300 in the frame direction is divided into an outer supporting frame part 300d-out and an inner supporting frame part 300d-in inside thereof, moving window use interconnecting a heat transfer block scheme a second thermal bridges the barrier material (300dh) and Hitting the outer frame (100d) and inner frame (100a), the third thermal bridges secondary inner insulation rescue formed of a barrier material (100ah) ( "INS-in ") are provided for additional thermal insulation between the window frame 100, windows The system can be constructed over the entire system, thus providing a high thermal efficiency in the heat insulating structure of the sliding window system of the aluminum chassis structure, and also preventing the condensation of the aluminum chassis in the case of high temperature difference inside and outside the window .

10, the moving frame constituting the moving window orthogonal direction moving device 500 is moved to the inside pocket 300d1 (see Figs. 11 to 13) of the supporting frame 300d of the moving window 300 And a stiffener mounting cover 300d3 which is additionally provided adjacent to a side pocket 300d2 provided to extend from the movable window 300 to the opening / It is preferable that the lateral flexural stiffness stiffener 320 is inserted so as to reinforce the flexural rigidity in the longitudinal direction (up-and-down direction), whereby the moving window 300 exhibits a high wind-resistant property.

As a window member provided inside the window frame 100, a fixing window 200 may be provided separately from the moving window 300 described above. In addition, a window frame 200g such as a glass window may be provided as a window frame 200g And may include an aluminum frame 200a and an outer frame 200b having high thermal conductivity and a thermal bridge member 200c for a piling frame made of a synthetic resin that interconnects the inner frame 200a and the outer frame 200b.

In a preferred embodiment of the present invention having such a heat insulating structure, in the case of the sliding window system of the aluminum chassis structure shown in the accompanying drawings, in addition to the general sliding movement opening / closing function of the moving window, (Sealing sliding) in the sealing frame 100d (the direction of movement in which the rail guide is orthogonal to the rail guide), this configuration is only a configuration related to one application example of the present invention, And the detailed description thereof will be omitted. The specific constitution and operation states of the above-mentioned compounds can be referred to the aforementioned Korean Patent Registration No. 10-1402940 (WO 2013/151293 A1 and US 2015/0052819 A1), the contents of which are incorporated herein by reference .

- A roller device (400) separated from the moving window (300) at a lower portion of the moving window (300) to provide a sliding movement of the window frame (100) in a direction perpendicular to the longitudinal direction of the rail guide (100r).

A second heat shield and a sealing member 310s which are provided on the rear surface of the movement window 300 by separating the movement window 300 from the roller device 400 and can be made of a material having elasticity such as synthetic rubber, Of the moving window (300) so as to perform sealing sliding movement in an orthogonal direction across the rail guide (100r) so as to be in contact with the first heat shield and the sealing member (100s) of the moving window sealing frame (100d) 300d) of the moving window orthogonal direction moving device (500).

- While the moving window (300) performs the sealing sliding movement in the perpendicular direction across the rail guide (100r) by the operation of the moving window orthogonal direction moving device (500), the vertical force is not applied to the roller device And the upper surface of the roller device 400 is moved so that the movement window 300 and the roller device 400 can be integrally moved while the movement window 300 is moved along the longitudinal direction of the rail guide 100r. The upper surface of the roller device 400 and the lower surface of the moving window 300 are moved to allow the rolling movement of the lower frame 300d of the moving window 300, An orthogonal direction sliding unit 600 provided between the lower surfaces of the frame 300d.

Meanwhile, the window frame 100 constituting the sliding window system to which the present invention is applied is annularly installed on the open wall surface of the building, and the rail guide 100r is installed laterally on the floor surface to smoothly move the window 300 The rail guide 100r may include a central rail 110 on which a bottom surface of the roller device 400 directly under the moving window 300 is directly contacted. The auxiliary guide rail 120 may further include an auxiliary guide rail 120 protruding from the plane of the central rail 110. The auxiliary guide rail 120 may be provided to guide the roller device 400 Can be inserted into the groove.

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, Of the right.

100: window frame
100a: inner frame, 100b: outer frame
100c (100c1, 100c2): thermal bridge material (first thermal bridge material, second thermal bridge material)
100ah : Third thermal barrier material
100d: Sealing frame for moving window, 100r: Rail guide
300: moving window, 300g: window panel
300a: inner frame, 300b: outer frame
300c: first breaking bridge for strip frames
300d: Support frame
300 dh : second heat bridge block for moving window

Claims (9)

And a first thermal bridge member 100c1 made of a synthetic resin and interconnecting the inner frame 100a and the outer frame 100b having a high thermal conductivity and having a high thermal conductivity. The first thermal bridge member 100c1 is installed annularly on the building wall, A window frame 100 on which a rail guide 100r is installed;
A window member movably installed inside the window frame 100 and serving as a window frame 300g for supporting a window panel 300g such as a windshield, an inner frame 300a and an outer frame 300b made of aluminum and having a high thermal conductivity, A transfer window 300 including a first thermal bridge member 300c for a window frame of a synthetic resin material to be connected; And
And a sealing member (100s), which is made of a synthetic resin material and is provided to be in sealing contact with the moving window, is provided on the front surface of the window frame (100) And a sliding window sealing frame (100d) provided to connect between the inner frame (100a) and the outer frame (100b), the sliding window system comprising:
A second thermal bridge member 100c2 of a synthetic resin material is additionally installed to interconnect the moving window sealing frame 100d connected to the outer frame 100b and the inner frame 100a in a heat transfer cut-
The inner frame 100a, the outer frame 100b, the moving window sealing frame 100d, and the first and second thermal bridge members 100c1 and 100c2 are arranged so that the installation directions of the first thermal bridge member 100c1 and the second thermal bridge member 100c2 are orthogonal to each other, And a heat shielding air layer (300i) is formed in the inner frame (100a) by annularly connecting the inner frame (100a) with the heat shielding material (100c1, 100c2: 100c)
The inner frame 100a is divided into an outer side inner frame part 100a-out and an inner side inner frame part 100a-in which are disposed in contact with the heat insulating air layer 300i, A third thermal bridge member 100ah of a synthetic resin material is additionally installed to interconnect the inner frame part 100a-out and the inner frame part 100a-in by a heat transfer cut-off method, INS-out "and" INS-in "are formed between the heat insulating structures 100a and 100a. The method according to claim 1,
One side of the second thermal bridge member 100c2 made of a synthetic resin and installed to interconnect the moving window sealing frame 100d and the inner frame 100a in a heat transfer breaking manner is connected to the inner frame 100k through the connection body 100k 100a of the sliding window system of the aluminum chassis structure. 3. The method according to claim 1 or 2,
The frame 300b is installed outside the window panel 300g positioned between the inner frame 300a and the outer frame 300b of the moving window 300 and is provided between the frame supporting frame 300d and the outer frame 300b, A first thermal bridge member 300c for a moving window is provided so as to interconnect with each other,
A support frame 300d for supporting the window panel 300g in the frame direction is separated from the outer support frame part 300d-out and the inner support frame part 300d-in inside thereof, and the outer support frame part 300d- And a second heat bridge member 300dh for a moving window made of a synthetic resin material is additionally installed to interconnect the inner support frame part 300d-out and the inner support frame part 300d-in through a heat transfer cut- Insulation structure of system. The method of claim 3,
A connecting structure of a moving window sealing frame 100d and an outer frame 100b forming an external first up-and-down connecting structure from the outside of the window to the inside of the building IN side, Between the connecting structure of the moving window 300 and the inner frame 100a forming the connecting structure,
The first heat shielding member 300c, the second heat shielding and sealing member 310s, the first heat shielding and sealing member 100s, the second heat shielding member 100c2, ("INS-out"), which is formed by the first thermal bridge member 300i and the first thermal bridge member 100c1,
Said moving window use the second thermal bridges the barrier material (300dh) is the third thermal bridges the barrier material (100ah) and deobuleoseo outside (Out of windows provided for additional thermal insulation between the outer frame (100d) and inner frame (100a) of the window frame (100) INS-in "from the side of the building to the inside of the building (IN Side) to the inside of the building (IN Side). 5. The method of claim 4,
And the second window bridge for thermal shutdown 300dh is applied to a triple- glazed structure. 5. The method of claim 4,
Wherein a lateral flexural rigid stiffener 320 is inserted and installed to reinforce the longitudinal bending rigidity of the movement window 300. [ In a heat insulating structure of a sliding window system of an aluminum chassis structure,
Sectional profile of a window frame constituting a sliding window system of an aluminum chassis structure having a high thermal conductivity is divided and formed by an outer frame 100b and an inner frame 100a and a sectional profile of the window frame is formed between the outer frame 100b and the inner frame 100a The heat bridge block 100c1 is inserted and connected to each other in a heat train manner,
The inner frame 100a is divided into an outer side inner frame part 100a-out and an inner side inner frame part 100a-in on the inner side, and the outer side inner frame part 100a-out and the inner side inner frame part 100a- A heat bridge member 100ah of a synthetic resin material is additionally installed so as to interconnect the heat sinks 100a-in by a heat transfer cut-
And two insulation structure lines ("INS-out" and "INS-in") are formed between the outer frame 100b and the inner frame 100a. . 8. The method of claim 7,
The window frame 300g is installed outside the window panel 300g located between the inner frame 300a and the outer frame 300b constituting the moving window 300 installed in the window frame 100 constituting the sliding window system, A first thermal bridge member 300c for a moving window is provided so as to interconnect the first frame 300d and the outer frame 300b in a heat transfer cut-off manner,
A support frame 300d for supporting the window panel 300g in the frame direction is separated from the outer support frame part 300d-out and the inner support frame part 300d-in inside thereof, and the outer support frame part 300d- And a second heat bridge member 300dh for a moving window made of a synthetic resin material is additionally installed to interconnect the inner support frame part 300d-out and the inner support frame part 300d-in through a heat transfer cut- Insulation structure of system. 9. The method of claim 8,
A connecting structure of a moving window sealing frame 100d and an outer frame 100b forming an external first up-and-down connecting structure from the outside of the window to the inside of the building IN side, Between the connecting structure of the moving window 300 and the inner frame 100a forming the connecting structure,
The first heat shielding member 300c, the second heat shielding and sealing member 310s, the first heat shielding and sealing member 100s, the second heat shielding member 100c2, ("INS-out"), which is formed by the first thermal bridge member 300i and the first thermal bridge member 100c1,
Said moving window use the second thermal bridges the barrier material (300dh) is the third thermal bridges the barrier material (100ah) and deobuleoseo outside (Out of windows provided for additional thermal insulation between the outer frame (100d) and inner frame (100a) of the window frame (100) INS-in "from the side of the building to the inside of the building (IN Side) to the inside of the building (IN Side).

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