KR102409996B1 - Insulation Structure of a Sliding Window System with Aluminium Sash - Google Patents

Abstract

The present invention relates to a moving window insulation structure of a sliding window system, and more particularly, by improving the profile cross-sectional structure of a window frame (window installation frame) and a moving window (window frame) constituting a sliding window system of an aluminum chassis structure with high thermal conductivity. It relates to a thermal insulation structure of a sliding window system of an aluminum chassis structure that can significantly improve a thermal insulation function and a condensation prevention function by forming two insulating structural lines between an outer frame and the inner frame.

Description

{Insulation Structure of a Sliding Window System with Aluminum Sash}

The present invention relates to a moving window insulation structure of a sliding window system, and more particularly, the insulating function and It relates to an insulating structure of a sliding window system of an aluminum chassis structure that can significantly improve the anti-condensation function.

Looking at the most common configuration of window frames (panels such as glass windows are installed inside) and window frames (installed in an annular shape on the wall of a building and installed inside) that make up sliding window systems such as Miseogi windows and Miseogi doors, A window frame with rail guides (guide rail, guide way) that acts as a guide when the window slides is installed in an annular shape on the wall of the building, and a roller is installed on the outside of the frame so that the moving window can move smoothly along the guide rail installed on the window frame And it has a structure in which a window pane having a cross-sectional structure in which a panel such as glass or plate is installed inside the frame is installed inside the window frame.

However, in such a general and simple structure, it is usually difficult to expect good performance in terms of sound insulation, airtightness (windproof), watertightness, heat insulation, and wind pressure resistance. The performance can be improved by attaching the sealing member of the windproof rubber gasket, but due to the limitation of the sealing method, the sealing effect by the sealing member such as a windshield or windproof rubber is not high, and the sealing member is deformed over time There is a disadvantage that it is difficult to maintain continuous performance as this comes or wears out.

On the other hand, the opening and closing structure of the 'Lift & Sliding method' ('Lift & Sliding method', simply 'LS method') is proposed as one of the prior art developed to compensate for the shortcomings of the sliding window system of the general structure described above. Although it has been widely utilized up to now, the sealing of the upper gap between the lower part of the moving window 4 and the window frame 1 is understood when comparing the 'U' partial enlarged views of FIGS. 1 and 2, respectively, the moving window ( When 4) is lifted and slidably moved, the upper sealing member 3u installed on the upper frame of the moving window 4 is spaced apart from the upper guide rail 1a installed downward on the upper part of the window frame 1, and the moving window ( 4) is lowered, the upper sealing member 3u comes into contact with the upper guide rail 1a to achieve sealing.

On the other hand, the part between the longitudinal frame of the window frame and the longitudinal frame of the movable window 4 is as understood when comparing the enlarged view of the 'L' part and the 'R' part of FIGS. 1 and 2, respectively. When the lateral sliding is completed and the windows are completely closed, the side sealing member 4s such as a rubber gasket is pressed to have sealing properties.

However, in the case of such an opening and closing structure, since the principle and sealing direction, that is, the sealing method, are different from each other to achieve sealing in the lower portion, the side, and the upper portion of a single window, and there is no integrity, the window and the window frame in which different sealing methods are encountered It is not easy to secure the perfect sealing performance in the corner of It is difficult to achieve sealing, and in particular, there is also a problem in that it is difficult to block internal and external heat transfer through the upper guide.

In addition, as an example of the prior art (Prior Art) of configuring the window frame and the window sill with an aluminum material in configuring the sliding window system of the LS method, as shown in FIGS. 3 to 5, an aluminum material with high thermal conductivity of the inner frame (1a) and the outer frame (1b) of the window frame (1), which is made of a synthetic resin material including a thermal barrier material (1c) interconnecting them, and is installed in an annular shape on the wall of the building, inside the aluminum material with high thermal conductivity A sliding window system in which a fixed window (2) and a moving window (4) are installed, including the inner frame (2a, 4a) and the outer frame (2b, 4b) and the heat-crossing insulating material (2c, 4c) made of synthetic resin interconnecting them This is commonly used.

3 is a cross-sectional view of the sliding closed and opened state of the moving window 4 is shown up and down, as shown in the upper part of FIG. As the moving window 1 moves downward, the sealing state while the upper sealing member 3u and the lower sealing member 3b are in contact with the thermal barrier material 1c in the middle of the window frame 1 is the AA' cross-sectional state in FIG. 5, as shown in the lower part of FIG. 3, the moving window 1 is lifted and moved to the upper part of the roller 4r in the sliding-open state (the door unlocking operation is performed), as shown in the lower part of FIG. A state in which the upper sealing member 3u and the lower sealing member 3b are brought into non-contact with the thermal barrier material 1c in the middle of the window frame 1 is shown in the cross-sectional state A-A' in FIG. 3 .

Here, referring to FIGS. 4 and 5 , the insulation line (“INS”) connecting the thermal barrier material 4c installed in the center of the moving window 4 and the thermal barrier material 1c installed in the center of the window frame 1 is almost straight. As it is formed close to the direction, the length of the insulation wire (“INS”) itself is formed short, and moreover, the heat-blocking material 1c installed in the center of the window frame 1 is provided with external air (“air”) as shown in FIGS. 4 and 5. ") has a direct contact structure, so the effect of insulation between the inside and outside of the window is very limited, and also the insulation effect is It has a structure that has no choice but to dispose the thermal barrier material 4c adjacent to it in order to maintain Looking at the materials constituting the movable window 4 along the K-K' line, from the outside toward the inside, an aluminum outer frame 4b, a synthetic resin heat insulating material 4c in the middle, and an aluminum inner frame ( 4a) to form a connection. Since a separate rigid frame that can improve the longitudinal rigidity of the entire frame constituting the moving window 4 cannot be installed, when the window is enlarged, there is a problem that there is no means to sufficiently provide durability against wind pressure.

As a new technology proposed to primarily overcome the shortcomings of the 'LS system' sliding window system with an opening and closing structure described so far, the applicant of the present application applied for and patented "moving window of the sliding window system of the aluminum chassis structure" Installation structure" is the registration publication of Korean Patent Registration No. 10-1402940 (June 27, 2014), PCT Publication No. WO 2013/151293 A1 (Oct. 10, 2013), and US 2015/0052819 A1 (Feb. 26, 2015) etc. are disclosed.

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

According to the drawings disclosed in the publications of the above applications (eg, FIG. 21 of the Korean Patent Registration No. 10-1402940, FIG. 22 of WO 2013/151293 A1 and US 2015/0052819 A1), the moving window is sealed and slid ( Sealed State) in a longitudinal cross-sectional view along the line A-A' in a cross-sectional view (attached herein to Fig. 6a), such as an insulating structure (insulation wire) shown in Fig. 6b herein ) to provide

It consists of an inner frame 100a and an outer frame 100b made of an aluminum material with high thermal conductivity, and a first heat-blocking material 100c1 made of a synthetic resin material that interconnects them, and is installed in an annular shape on the wall of the building, and is installed on the upper part of the floor in the transverse direction Window frame 100 to which the rail guide is installed; and

As a window member installed inside the window frame 100, an inner frame 200a, 300a and an outer frame 200b, 300b made of an aluminum material having high thermal conductivity as a window frame supporting a window panel 200g, 300g such as a glass window. And a fixed window 200 and a movable window 300 comprising a thermal cross-blocking material (200c, 300c) for the window frame frame of synthetic resin material for interconnecting them;

It is made of an aluminum material having a first heat-blocking and sealing member 100s that can be made of, for example, synthetic resin material on the front side, and is provided in an annular shape in the moving window closing area inside the outer frame 100b of the window frame 100, , A sealing frame for a movable window provided to connect between the inner frame 100a and the outer frame 100b (100d); and

The movable window ( 300) is made including a roller device 400 that is installed separately from, and

A second heat-crossing barrier material 100c2 made of synthetic resin is installed to interconnect the sealing frame 100d for the movable window connected to the outer frame 100b and the inner frame 100a in a heat transfer blocking method, but the first heat-crossing barrier material (100c1) and the installation direction are arranged to be orthogonal to each other, and the inner frame 100a, the outer frame 100b, the sealing frame 100d for the movable window, and the inner frame 100a by turning around the heat cross-blocking material (100c1, 100c2: 100c) provides a movable window installation structure of the sliding window system of the aluminum chassis structure, characterized in that it is connected in an annular shape so that the heat-blocking air layer 300i is formed therein.

In the movable window installation structure of the sliding window system of the aluminum chassis structure configured as described above, as shown in FIGS. 6A and 6B , the inner frame 100a and the outer frame 100b constituting the window frame 100 are blocked from heat transfer. The first thermal barrier material 100c1 made of synthetic resin, which is installed to interconnect in this way, the sealing frame 100d for the movable window connected to the outer frame 100b, and the inner frame 100a are interconnected in a heat transfer blocking method. By arranging the installation directions of the second heat-cross insulation material 100c2 made of a synthetic resin material to be installed so as to be orthogonal to each other, the inner frame 100a, the outer frame 100b, the sealing frame for the movable window 100d, and the inner frame ( 100a) is connected in an annular shape through the heat cross-blocking materials 100c1, 100c2: 100c to form a heat-blocking air layer 300i therein, thereby leading to the inside of the building from the outside of the window as shown in FIG. 6b. The connection structure of the sealing frame 100d and the outer frame 100b for the moving window forming the primary upper and lower connection structure of the outside, and the moving window 300 and the inner frame 100a forming the secondary upper and lower connection structure of the inside Between the structures, the thermal barrier material for the window frame of the moving window 300 (300c), the second heat blocking and sealing member (310s), the first heat blocking and sealing member (100s), the second heat blocking material (100c2), the heat blocking The air layer 300i and the heat insulation line (“INS”) formed of the first thermal barrier material 100c1 are constructed to provide high thermal insulation efficiency, and the aluminum chassis in the case of a high temperature difference inside and outside the windows. Condensation is also prevented.

However, even when the heat-blocking air layer 300i is formed in this way, when the difference between the temperature of the outer frame 100b and the sealing frame 100d for the moving window and the temperature of the inner frame 100a is large, the heat-blocking air layer ( While there is a certain limit in effectively blocking the heat conduction itself through 300i), the outer part of the inner frame 100a is difficult to completely block the external environment unlike the inner part, so the perfect insulation effect and anti-condensation effect as intended There is a problem that it is not easy to achieve.

On the other hand, one side of the second thermal barrier material 100c2 made of synthetic resin is installed to interconnect the sealing frame 100d for the moving window and the inner frame 100a in a heat transfer blocking method, instead of being directly connected to the inner frame 100a. In the drawings, a structure indirectly connected to the inner frame 100a through the connecting body portion shown by the reference numeral '100k' in the drawing may be adopted as enlarged in FIGS. 6A and 6B, such an indirect installation structure As shown in FIG. 6c in order to achieve A synthetic resin material (liquid polyurethane) is injected into the connection between the body and the connection body 100k to form the second thermal barrier material 100c2, and then the connection is removed, and the sealing frame 100d for the moving window, the second thermal bridge A state in which the blocking material 100c2 and the connecting body portion 100k are connected is created.

The sealing frame 100d for the moving window, the second heat-crossing material 100c2, and the connecting body 100k connect the connecting body 100k of the connecting body to the inner frame 100a and tighten the fastening screw 100ks . The fastening screws ( 100ks ) pass through the sealing frame (100d) for the moving window, the second heat-blocking material (100c2), the connecting body part (100k), and the inner frame (100a) while sequentially passing through the fastening operation. The sealing frame cap 100d-cap for the moving window is additionally assembled so that the fastening screw 100ks passes through the sealing frame 100d for the moving window and covers the through-hole 100d-hole. In the process of through-fastening, the head of the fastening screw 100ks completely penetrates the second heat-blocking material 100c2, causing a serious problem in that the synthetic material is significantly damaged.

In addition, in the process in which the head of the short fastening screw 100ks completely penetrates the second heat-crossing material 100c2 in the prior art (Prior Art II) described through FIGS. 6A to 6C, the second heat-crossing material 100c2 is formed. In order to avoid a situation in which the synthetic material is significantly damaged, a modified use case (Prior Art IIa) as enlarged in FIGS. 7A and 7B can be used, according to which the short length shown in FIGS. 6A and 6B is used. By using the long-length fastening screw 100ks-L shown in FIGS. 7A and 7B instead of the fastening screw 100ks of And by fastening the inner frame 100a through and fastening the connection, the head of the fastening screw 100ks- L is fixed in the outer frame 100d, so that the head of the fastening screw 100ks-L is the second heat-blocking material 100c2. Since it is much easier in terms of work difficulty as well as preventing the destruction of the second heat-crossing barrier material 100c2, the case of such construction is frequent in the actual construction situation. However, in such a fastening structure, heat conduction occurs between the outer frame 100d and the inner frame 100a through a long-length fastening screw 100ks-L fastened through the members to cause damage to the insulation function. will indicate the problem.

As described above, a window according to the prior art having a structure in which one insulation line (“INS”) is provided between the members (ⓘ) disposed on the inner side of the window and the members (ⓞ) exposed to the external environment In the case of the system, among the members (ⓘ) disposed on the inner side of the window (ⓘ), the part (ⓜ) adjacent to the members (ⓞ) that is disposed on the outer side of the window and exposed to the external environment (ⓜ) is to some extent There is a problem in that heat conduction occurs, and consequently, the desired insulation effect at the time of design cannot be properly achieved.

Korean Patent Registration Publication No. 10-1402940 (June 27, 2014) WO 2013/151293 A1 (10/10/2013). US Patent Publication US 2015/0052819 A1 (2015.2.26)

The present invention is to solve the problems of the prior art and its modified use cases, and the technical problem of the present invention is to significantly improve the insulation function by improving the profile cross-sectional structure of the window installation frame and the window frame in which the sliding windows of the aluminum chassis structure are installed. It is to provide an insulating structure of a sliding window system of an aluminum chassis structure that can not only improve the product, but also minimize the possibility of thermal insulation failure that may occur during the actual production stage and construction stage.

The present invention is a means for achieving the above-described technical problem,

A window frame comprising an inner frame and an outer frame made of aluminum with high thermal conductivity, and a first heat-blocking material made of synthetic resin interconnecting them, installed in an annular shape on the wall of the building, and having rail guides installed on the upper part of the floor in the transverse direction;

A window member movably installed inside the window frame, as a window frame supporting a window panel such as a glass window, an inner frame and an outer frame made of an aluminum material with high thermal conductivity, and a synthetic resin material for interconnecting the window frame A moving window comprising a; and

It is made of a synthetic resin material and is made of an aluminum material having a first heat-blocking and sealing member provided in contact with and sealing the moving window on the front side, and is provided in an annular shape in the moving window closing area inside the outer frame of the window frame, the inner frame A sliding window system comprising a sealing frame for a movable window provided to connect between and the outer frame,

A second thermal barrier material made of synthetic resin is additionally installed to interconnect the sealing frame for the moving window connected to the outer frame and the inner frame in a heat transfer blocking method,

The installation directions of the first thermal barrier material and the second thermal barrier material are arranged to be perpendicular to each other, and the inner frame, the outer frame, the sealing frame for the movable window, and the inner frame are connected in an annular shape through the thermal barrier material by turning one turn. In the insulating structure of the sliding window system of the aluminum chassis structure in which a thermal barrier air layer is formed therein,

The inner frame is formed to be separated into an outer inner frame part disposed in contact with the sealing frame for the moving window and the heat-blocking air layer and an inner inner frame part on the inner side thereof, and heat transfer is blocked between the outer inner frame part and the inner inner frame part To provide an insulating structure of a sliding window system of an aluminum chassis structure, characterized in that a third heat-blocking material made of synthetic resin is additionally installed so that two heat-insulating structural lines are formed between the outer frame and the inner frame so as to be interconnected in this way .

According to the present invention, by improving the profile cross-sectional structure of the window installation frame and the window sill frame in which the sliding windows of the aluminum chassis structure are installed, two insulating structure lines are formed between the outer frame and the inner frame, thereby improving the insulation function and the function of preventing condensation In addition, through the manufacturing and assembling process of the window frame frame, even if the outer insulation structure line is destroyed among the two insulation structure lines, the inner insulation structure line can be maintained continuously, thereby improving the convenience of construction. effect is provided.

1, 2, and 3 are views of the general configuration of the sliding window system.
4 and 5 is a view showing a window system Miseogi according to the conventional lift and sliding method.
6a is a sliding window system (Prior Art) of an aluminum chassis structure according to the prior art shown in FIG. In Ⅱ), an enlarged view of the moving window in a sealed state (Sealed State).
6b is a sliding window system (Prior Art) of an aluminum chassis structure according to the prior art shown in FIG. As a longitudinal sectional view of Ⅱ), it is an enlarged view of the insulating structure (insulation wire) in a state in which the moving window is sealed and slid.
FIG. 6c is a view illustrating a process of forming a connecting body of a sealing frame for a moving window, a second heat-blocking material, and a connecting body portion in an aluminum chassis structure according to the prior art and coupling the same to the inner frame; FIG.
7A and 7B are views showing a state in which the insulation line is destroyed (Prior Art IIa) due to a construction problem in the sliding window system of the aluminum chassis structure according to the prior art shown in FIGS. 6A and 6B.
Figure 8a is a cross-sectional view showing the insulating structure in the sliding window system of the aluminum chassis structure according to an embodiment of the present invention, a view showing the state (Unsealed State) before the moving window is sealing sliding.
Figure 8b is a cross-sectional view showing the heat insulation structure in the sliding window system of the aluminum chassis structure according to an embodiment of the present invention, a view showing the moving window sealing slid state (Sealed State)
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 an open state of the moving window.
10 is a cross-sectional view of a sliding window system of an aluminum chassis structure according to an additional embodiment of the present invention, wherein an additional insulating structure is provided on the side portion of the moving window window frame itself through a side heat shield for the window frame frame, and wind pressure resistance is improved. A drawing showing a state in which side bending rigid reinforcement is additionally installed on the moving window for this purpose.
11 is a cross-sectional view taken along line A-A' of FIG. 8A.
12 is a cross-sectional view taken along line A-A' of FIG. 8B.
13 is a cross-sectional view taken along line B-B' of FIG. 9;
14 is a longitudinal cross-sectional view of a sliding window and door system of an aluminum chassis structure according to an embodiment of the present invention, showing a state in which two heat insulation structure lines (insulation lines) are generated.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. However, the present invention may be embodied in several different forms and is not limited to the embodiments described herein.

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

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

That is, the sliding window system of the aluminum chassis structure according to the present invention is basically, as shown in the drawings described above, an inner frame 100a and an outer frame 100b made of aluminum with high thermal conductivity and a synthetic resin material interconnecting them. A window frame 100 comprising a first heat cross-blocking material 100c1 of the annular installed on the wall of the building and having a rail guide 100r installed on the upper part of the floor in the transverse direction;

As a window member movably installed inside the window frame 100, as a window frame supporting a window panel 300g such as a glass window, the inner frame 300a and the outer frame 300b of an aluminum material having high thermal conductivity and the mutual a movable window 300 comprising a first heat cross-blocking material 300c for a window frame frame made of a synthetic resin material to be connected; and

It is made of a synthetic resin material and is made of an aluminum material having a first heat-blocking and sealing member 100s provided to seal in contact with the moving window on the front side, and is made of an aluminum material in the outer frame 100b of the window frame 100. The moving window closing area A sliding window system provided in an annular shape and provided with a sealing frame (100d) for a movable window provided to connect between the inner frame (100a) and the outer frame (100b),

A second heat-blocking material 100c2 made of synthetic resin is additionally installed to interconnect the sealing frame 100d for the movable window connected to the outer frame 100b and the inner frame 100a in a heat transfer blocking method,

Arranged so that the installation directions of the first thermal barrier material 100c1 and the second thermal barrier material 100c2 are perpendicular to each other, the inner frame 100a, the outer frame 100b, the moving window sealing frame 100d; And in the insulating structure of the sliding window system of the aluminum chassis structure in which the inner frame 100a is connected in an annular shape through the heat cross-blocking materials 100c1, 100c2: 100c by turning one turn, and the heat-blocking air layer 300i is formed therein. ,

The inner frame (100a) is placed in contact with the sealing frame (100d) for the moving window and the heat-blocking air layer (300i) and the outer inner frame part (100a-out) and the inner inner inner frame part (100a-in) on the inside Separately formed, and a third thermal barrier material made of synthetic resin ( 100ah ) is additionally installed to interconnect between the outer inner frame part (100a-out) and the inner inner frame part (100a-in) in a heat transfer blocking method. Provides an insulating structure of a sliding window system of an aluminum chassis structure, characterized in that two insulating structure lines (“INS-out” and “INS-in”) are formed between the frame 100b and the inner frame 100a do.

More simply, in the insulating structure of the sliding window system of the aluminum chassis structure,

The cross-sectional profile of the window frame constituting the sliding window system of the aluminum chassis structure having high thermal conductivity is divided into an outer frame 100b and an inner frame 100a, and between the outer frame 100b and the inner frame 100a. By inserting the heat cross-blocking material (100c1) to connect in a mutual heat-blocking method, and

The inner frame 100a is separated into an outer inner frame part 100a-out and an inner inner inner frame part 100a-in thereof, and the outer inner frame part 100a-out and the inner inner frame part are formed. (100a-in) by additionally installing a thermal cross-blocking material ( 100ah ) made of synthetic resin to interconnect the heat transfer blocking method,

An insulating structure is provided, characterized in that two insulating structure lines (“INS-out” and “INS-in”) are formed between the outer frame 100b and the inner frame 100a.

Here, one side of the second heat-blocking material 100c2 made of synthetic resin is installed to interconnect the sealing frame 100d for the moving window and the inner frame 100a in a heat transfer blocking method is directly connected to the inner frame 100a Instead, a structure indirectly connected to the inner frame 100a through the connecting body portion shown by the reference numeral '100k' in the drawing may be adopted, in other words, the inner frame 100a itself is the first heat-blocking and sealing As a means for solving the problem that it is difficult to integrally extrude the member 100s and to have a complex shape that can accommodate the second heat-blocking material 100c2, the first heat-blocking and sealing member 100s and An indirect installation structure using a separate connection body portion 100k having a shape that can accommodate the second heat cross-blocking material 100c2 may be provided. In order to achieve such an indirect installation structure, in the prior art description As described with reference to 6c, first, the sealing frame 100d for the moving window and the connecting body 100k are integrally molded through aluminum injection including the connecting portion, and the moving window sealing frame 100d and the connecting body portion ( 100k), a synthetic resin material (liquid polyurethane) is injected into the connection part to form the second heat-blocking material 100c2, and then the connection is removed to remove the sealing frame for a moving window (100d), the second heat-blocking material (100c2), and Connection body part 100k of the connector formed by making the connection body part 100k connected, and the sealing frame 100d for the moving window, the second heat-blocking material 100c2, and the connection body part 100k being connected The part is connected to the inner frame 100a and the fastening screw 100ks-L is penetrated to be fixedly coupled. In the sealing frame 100d for the moving window while sequentially passing through the connecting body portion 100k, and the inner frame 100a, its The head portion of the fastening screw ( 100ks-L ) is fixed, so that the fastening operation is made.

According to a preferred embodiment of the present invention, in the case of adopting a heat-insulating structure such that two heat-insulating structure lines ("INS-out" and "INS-in") are formed, indirectly by such a connection body portion 100k In order to achieve the installation structure, the connecting body portion 100k of the connecting body formed by connecting the sealing frame 100d for the moving window, the second heat-crossing material 100c2, and the connecting body portion 100k is connected to the inner frame 100a. And using a long-length fastening screw ( 100ks-L ) instead of a short-length fastening screw ( 100ks ), the outer frame ( 100d ), the second heat-blocking material ( 100c2 ), the connecting body part ( 100k ), and the inner frame ( 100a ) ), and a long-length fastening screw ( 100ks-L ) that penetrates through the members and is fastened by constructing a connection and fixing method so that the head of the fastening screw ( 100ks-L ) is fixed in the sealing frame (100d) for the moving window (100ks-L) ) generated by the second thermal barrier material 100c2 from among the two heat insulating structure lines (“INS-out” and “INS-in”) between the outer frame 100d and the inner frame 100a by heat conduction generated through Even if some damage to the insulation function of the outer insulation structure line (“INS-out”) occurs (or using a short-length fastening screw ( 100ks ), the head part destroys the second heat-insulating material, resulting in partial damage to the insulation function. Even), the inner insulation structure line generated by the third heat cross-blocking material 100ah provided to interconnect between the outer inner frame part 100a-out and the inner inner frame part 100a-in in a heat transfer blocking manner By allowing the internal and external insulation function by ("INS-in") to be continuously maintained, even if a certain degree of heat conduction is achieved up to the part (ⓜ) adjacent to the members (ⓞ) exposed to the external environment, the window The members (ⓘ) disposed on the inside (In Side) are protected from the external environment by the third heat-blocking material ( 100ah ). Since it is formed separately from the part (ⓜ) adjacent to the exposed members (ⓞ), it is possible to properly achieve the desired insulation effect at the time of design. It is possible to secure a high level of thermal insulation performance, and also provides an excellent effect in preventing condensation.

On the other hand, the inner heat insulation structure line provided by the third heat-blocking material 100ah provided to interconnect between the outer inner frame part 100a-out and the inner inner frame part 100a-in in a heat transfer blocking manner The effect of the insulation function by ("INS-in") is, the sealing frame 100d for the moving window, the second heat-blocking material 100c2, and the inner frame 100a described above by way of example, the connection body portion 100k) Instead of the indirect connection method provided with Of course, it can also be demonstrated.

The above-described embodiment relates to the improvement of the thermal insulation structure mainly formed by the members related to the window frame 100 member in the insulating structure of the sliding window system of the aluminum chassis structure. In addition to the structure, improvements are additionally provided for the insulation structure of the window frame, particularly the window frame of the moving window, and these additional improvements have already been provided to the moving window 300 in the sliding window system of the aluminum chassis structure according to the prior art. As a thermal barrier material for a window frame of a moving window, it is installed on the outer side of the window panel 300g positioned between the inner frame 300a and the outer frame 300b constituting the moving window 300, and the frame supporting frame 300d and The first outer insulation structure line (“INS -out") is installed, and the support frame 300d for supporting the window panel 300g in the rim direction separately from the outer support frame part 300d-out and the inner support frame part ( 300d-in), and a second thermal barrier material for moving windows made of synthetic resin ( 300dh ) to interconnect between the outer support frame part 300d-out and the inner support frame part 300d-in in a heat transfer blocking method ) is preferably additionally installed.

Accordingly, as shown in FIG. 14 , the second thermal bridge barrier material 300dh for the movable window is a third thermal bridge provided for additional insulation between the outer frame 100d and the inner frame 100a of the window frame 100 described above. Together with the barrier material ( 100ah ), a second inner insulation structure line (“INS-in”) is created from the outside of the window to the inside of the building (IN Side).

However, such a second thermal barrier material for moving windows ( 300dh ) will be easily applied to the triple glass structure as shown in the drawings . By minimizing the width (thickness) so that the moving window orthogonal moving device 500 can be located in the center of the window, the force required for the operation of the opening/closing operation driving unit for sealing sliding movement by the moving window orthogonal moving device 500 It is desirable not to cause this greatly increased disadvantage.

As a result, the connection structure of the sealing frame 100d and the outer frame 100b for the movable window forming an external primary vertical connection structure from the outside of the window to the inside of the building, and the movable window forming a secondary vertical connection structure of the interior Between the connection structure of 300 and the inner frame 100a, a first heat-blocking material 300c, a second heat-blocking and sealing member 310s, a first heat-blocking and sealing member for the window frame of the movable window 300 ( 100s), the second thermal barrier material 100c2, the thermal barrier air layer 300i, and the first thermal barrier material 100c1 to build a primary outer insulation structure line (“INS-out”), as well as to build a moving window The support frame 300d for supporting the window panel 300g of 300 is separated into an outer support frame part 300d-out and an inner support frame part 300d-in therebetween. A second thermal barrier material for moving windows ( 300dh ) interconnected in a heat transfer blocking method, and a third thermal barrier material ( 100ah ) provided for additional insulation between the outer frame (100d) and the inner frame (100a) of the window frame (100) The formed secondary inner insulation structural line (“INS-in”) is built throughout the window system, thus providing high thermal insulation efficiency in the insulating structure of the sliding window system of the aluminum chassis structure, and also high The effect of preventing dew condensation on the aluminum chassis in the case of temperature difference is also exhibited.

Also here, as shown in FIG. 10, the moving frame constituting the moving window orthogonal moving device 500 is the inner pocket 300d1 of the support frame 300d of the moving window 300; see FIGS. 11 to 13. ) to the inside of the reinforcing material pocket formed by the reinforcing material installation cover 300d3 additionally installed adjacent to the side pocket 300d2 provided to extend from the moving window 300 to the opening/closing operation driving unit on the side of the moving window 300, It is preferable that the side bending rigidity reinforcing material 320 is inserted and installed to reinforce the longitudinal direction (up and down longitudinal direction) bending rigidity, so that the movable window 300 exhibits high wind pressure resistance.

On the other hand, as a window member installed inside the window frame 100, a fixed window 200 may be provided separately from the moving window 300 described above. The inner frame 200a and the outer frame 200b made of an aluminum material having high thermal conductivity and a thermal barrier material 200c for a window frame made of a synthetic resin interconnecting them may be included.

In the case of the sliding window system of the aluminum chassis structure shown in the accompanying drawings as a preferred embodiment according to the present invention having such a thermal insulation structure, the moving window of the moving window 300 in addition to the general sliding opening/closing function of the moving window An additional configuration is provided as follows for sealing (sealing sliding; moving direction orthogonal to the rail guide) for the sealing frame 100d, but this configuration is only a configuration related to one application example of the present invention. Since it is not a configuration that limits the scope of rights, a detailed description thereof will be omitted. For its specific configuration and operating state, reference may be made to the contents of Korean Patent Registration No. 10-1402940 (WO 2013/151293 A1 publication and US 2015/0052819 A1 publication) described above, these contents are incorporated herein by reference. .

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

- A second heat-blocking and sealing member 310s that is provided on the rear surface of the moving window 300 by separating the moving window 300 from the roller device 400 and can be made of a material having elasticity, for example, synthetic rubber. The lower frame of the moving window 300 ( 300d) of the moving window orthogonal direction moving device 500 installed in the inner pocket (300d1).

- While the moving window 300 performs the sealing sliding movement in the orthogonal direction crossing the rail guide 100r by the operation of the moving window orthogonal moving device 500, the vertical component force does not apply to the roller device 400 In addition, while the moving window 300 is moved along the longitudinal direction of the rail guide 100r, the upper surface of the roller device 400 so that the moving window 300 and the roller device 400 can proceed integrally. The upper surface of the roller device 400 and the lower part of the moving window 300 to allow only a movement displacement perpendicular to the moving direction of the rail guide 100r of the lower frame 300d of the moving window 300 and to guide the rolling movement with respect to An orthogonal sliding unit 600 provided between the lower surfaces of the frame 300d.

On the other hand, the window frame 100 constituting the sliding window system to which the present invention is applied is installed in an annular shape on the open wall of the building, and the rail guide 100r is installed on the upper part of the floor in the transverse direction to smoothly move the window 300 . There is a sliding opening and closing movement in the lateral direction (along the rail guide travel direction), the rail guide 100r may include a central rail 110 in direct contact with the bottom surface of the roller device 400 under the moving window 300, It may further include an auxiliary guide rail 120 protruding from the plane of the central rail 110, and to prevent the left/right swing of the roller apparatus 400, the auxiliary guide rail 120 guides the roller apparatus It can be inserted into the groove.

Although preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention as defined in the following claims are also provided. is within the scope of the

100: window frame
100a: inner frame, 100b: outer frame
100c (100c1, 100c2): heat-crossing barrier material (first heat-crossing barrier material, second heat-crossing barrier material)
100ah : 3rd thermal barrier material
100d: sealing frame for moving windows, 100r: rail guide
300: moving window, 300g: window panel
300a: inner frame, 300b: outer frame
300c: first thermal barrier for window frame
300d: support frame
300dh : Second heat-crossing barrier for moving windows

Claims (9)

It consists of an inner frame 100a and an outer frame 100b made of aluminum and a first heat-blocking material 100c1 made of synthetic resin that interconnects them, is installed in an annular shape on the wall of the building, and is a rail guide on the upper part of the floor in the transverse direction. (100r) is installed the window frame 100;
A window member movably installed inside the window frame 100, as a window frame supporting a window panel 300g, such as a glass window, an aluminum inner frame 300a and an outer frame 300b, and a synthetic resin interconnecting them Moving window 300 comprising a first heat-crossing barrier material (300c) for the window frame of the material; and
It is made of a synthetic resin material and is made of an aluminum material having a first heat-blocking and sealing member 100s provided to seal in contact with the moving window on the front side, and is made of an aluminum material in the outer frame 100b of the window frame 100. The moving window closing area A sliding window system provided in an annular shape and provided with a sealing frame (100d) for a movable window provided to connect between the inner frame (100a) and the outer frame (100b),
A second heat-blocking material 100c2 made of synthetic resin is additionally installed to interconnect the sealing frame 100d for the movable window connected to the outer frame 100b and the inner frame 100a in a heat transfer blocking method,
Arranged so that the installation directions of the first thermal barrier material 100c1 and the second thermal barrier material 100c2 are perpendicular to each other, the inner frame 100a, the outer frame 100b, the moving window sealing frame 100d; And in the insulating structure of the sliding window system of the aluminum chassis structure in which the inner frame 100a is connected in an annular shape through the heat cross-blocking materials 100c1, 100c2: 100c by turning one turn, and the heat-blocking air layer 300i is formed therein. ,
The inner frame (100a) is placed in contact with the sealing frame (100d) for the moving window and the heat-blocking air layer (300i) and the outer inner frame part (100a-out) and the inner inner inner frame part (100a-in) on the inside Separately formed, and a third thermal barrier material made of synthetic resin ( 100ah ) is additionally installed to interconnect between the outer inner frame part (100a-out) and the inner inner frame part (100a-in) in a heat transfer blocking method. The insulating structure of the sliding window system of the aluminum chassis structure, characterized in that the two insulating structure lines (“INS-out” and “INS-in”) are formed between the frame 100b and the inner frame 100a. According to claim 1,
One side of the second thermal barrier material 100c2 made of synthetic resin, which is installed to interconnect the sealing frame 100d for the moving window and the inner frame 100a in a heat transfer blocking method, is connected to the inner frame 100k through the connecting body portion 100k. Insulation structure of the sliding window system of the aluminum chassis structure, characterized in that it is indirectly connected to 100a). 3. The method of claim 1 or 2,
It is installed on the outside of the window panel 300g positioned between the inner frame 300a and the outer frame 300b constituting the movable window 300, and blocks heat transfer between the edge support frame 300d and the outer frame 300b. The first thermal barrier material 300c for the moving window is installed to interconnect in this way, and
The support frame 300d for supporting the window panel 300g in the rim direction is separated into an outer support frame part 300d-out and an inner support frame part 300d-in therein, and the outer support frame part ( 300d-out) and the inner side support frame part (300d-in) to interconnect in a heat transfer blocking method, a second thermal barrier material for moving windows made of synthetic resin ( 300dh ) is additionally installed. Insulation structure of the system. 4. The method of claim 3,
The connection structure of the sealing frame (100d) and the outer frame (100b) for a movable window forming an external primary vertical connection structure from the outside of the window to the inside of the building (IN Side), and the secondary vertical connection of the inside Between the moving window 300 and the connection structure of the inner frame (100a) forming a connection structure,
A first heat-blocking material 300c, a second heat-blocking and sealing member 310s, a first heat-blocking and sealing member 100s, a second heat-crossing blocking material 100c2, a heat-blocking air layer for the window frame of the movable window 300 (300i), and a primary outer insulation structural line (“INS-out”) formed of the first thermal barrier material 100c1 is built, and
The second thermal barrier material for the moving window ( 300dh ) is the third thermal barrier material ( 100ah ) provided for additional insulation between the outer frame 100d and the inner frame 100a of the window frame 100 together with the outside (Out) of the window. Side) to the inside of the building (IN Side), the insulation structure of the aluminum sash structure sliding window system, characterized in that it creates a second inner insulation structural line ("INS-in"). 5. The method of claim 4,
The insulating structure of the sliding window system of the aluminum chassis structure, characterized in that the second heat-crossing barrier material for the moving window ( 300dh ) is applied to the triple glass structure. 5. The method of claim 4,
Insulation structure of the sliding window system of the aluminum chassis structure, characterized in that the side bending rigidity reinforcement 320 is inserted and installed to reinforce the longitudinal bending rigidity of the movable window 300. In the insulating structure of the sliding window system of the aluminum chassis structure,
The cross-sectional profile of the window frame constituting the sliding window system of the aluminum sash structure is divided into an outer frame 100b and an inner frame 100a, and a thermal barrier material is formed between the outer frame 100b and the inner frame 100a ( 100c1) is inserted to connect in a mutual thermal blocking method, and
The inner frame 100a is separated into an outer inner frame part 100a-out and an inner inner inner frame part 100a-in thereof, and the outer inner frame part 100a-out and the inner inner frame part are formed. (100a-in) by additionally installing a thermal cross-blocking material ( 100ah ) made of synthetic resin to interconnect the heat transfer blocking method,
Insulation structure of a sliding window system of an aluminum chassis structure, characterized in that two insulating 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,
It is installed on the outside of the window panel 300g positioned between the inner frame 300a and the outer frame 300b constituting the movable window 300 installed in the frame 100 of the window frame constituting the sliding window system, and is a frame supporting frame (300d) and the outer frame (300b) to interconnect between the heat transfer blocking method, the first heat-crossing barrier material (300c) for the moving window is installed, and
The support frame 300d for supporting the window panel 300g in the rim direction is separated into an outer support frame part 300d-out and an inner support frame part 300d-in therein, and the outer support frame part ( 300d-out) and the inner side support frame part (300d-in) to interconnect in a heat transfer blocking method, a second thermal barrier material for moving windows made of synthetic resin ( 300dh ) is additionally installed. Insulation structure of the system. 9. The method of claim 8,
The connection structure of the sealing frame (100d) and the outer frame (100b) for a movable window forming an external primary vertical connection structure from the outside of the window to the inside of the building (IN Side), and the secondary vertical connection of the inside Between the moving window 300 and the connection structure of the inner frame (100a) forming a connection structure,
A first heat-blocking material 300c, a second heat-blocking and sealing member 310s, a first heat-blocking and sealing member 100s, a second heat-crossing blocking material 100c2, a heat-blocking air layer for the window frame of the movable window 300 (300i), and a primary outer insulation structural line (“INS-out”) formed of the first thermal barrier material 100c1 is built, and
The second thermal barrier material for the moving window ( 300dh ) is the third thermal barrier material ( 100ah ) provided for additional insulation between the outer frame 100d and the inner frame 100a of the window frame 100 together with the outside (Out) of the window. Side) to the inside of the building (IN Side), the insulation structure of the aluminum sash structure sliding window system, characterized in that it creates a second inner insulation structural line ("INS-in").

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