KR20240015051A - Windows with improved bonding structure of insulation to improve insulation performance - Google Patents

Abstract

The present invention relates to a window with an improved bonding structure of insulation materials to improve insulation performance.
More specifically, the first upper coupling groove is formed in the upper inner direction, the second upper coupling groove is formed in a shape facing the first upper coupling groove, the first lower coupling groove is formed in the lower inner direction, and the first upper coupling groove is formed in the lower inner direction. A window frame including a second lower coupling groove formed in a shape facing the first lower coupling groove; an upper insulating material configured to be coupled to the first upper coupling groove and the second upper coupling groove; And a lower insulating material configured to be coupled to the first lower coupling groove and the second lower coupling groove. According to the present invention, the upper insulation material is coupled to the first upper coupling groove and the second upper coupling groove of the window frame, and the lower insulation material is coupled to the first lower coupling groove and the second lower coupling groove of the window frame, so that the window This has the effect of improving insulation performance by reducing the efficiency of heat transfer through the frame.

Description

Windows with improved bonding structure of insulation materials to improve insulation performance {WINDOWS WITH IMPROVED BONDING STRUCTURE OF INSULATION TO IMPROVE INSULATION PERFORMANCE}

The present invention relates to a window with an improved bonding structure of insulation materials to improve insulation performance.

More specifically, the upper insulation material is coupled to the first upper coupling groove and the second upper coupling groove of the window frame, and the lower insulation material is coupled to the first lower coupling groove and the second lower coupling groove of the window frame, so that the window This relates to a window with an improved bonding structure of insulation materials to improve insulation performance by reducing the efficiency of heat transfer through the frame.

In general, a non-standing window includes an upper window frame and a lower window frame arranged at a certain distance in the vertical direction on the wall of a building such as a house, a left window frame and a right window frame supporting the upper window frame between the upper window frame and the lower window frame, and It consists of a window frame that is installed to be movable left and right in the inner space of a square window frame composed of upper, lower, left, and right window frames, and has glass placed in the middle.

These non-glazed windows include a single window structure using two window frames, a double window structure using four window frames, a double window structure in which single windows or double window structures are arranged in the vertical direction, and a middle window structure in which the middle window structure is arranged in the left-right or horizontal direction. It is classified into a double-linked structure that overlaps in the direction.

In addition, the miseogi window is made of synthetic resin or aluminum alloy. Aluminum insulated glass windows have the advantage of having excellent strength by using an aluminum alloy profile, but there is a problem with insufficient insulation performance due to heat exchange.

Therefore, in order to improve the insufficient insulation performance, a separate insulation material is installed in the aluminum non-glazed window to prevent outdoor heat or cold air from entering the room through the window frame, or indoor hot or cold air from being discharged to the outdoors. It can be.

Meanwhile, aluminum has a density of 2.7 [g/cm3], a specific heat of 0.9 [J/g ℃], and a thermal conductivity of about 204 [W/m K] at a standard temperature of 20 ℃. This thermal conductivity can be expressed as a thermal transmittance, which is a value divided by the thickness of the insulation member.

Aluminum's thermal conductivity is the second highest after gold, silver, and copper. Therefore, polyamide, polyurethane, etc., which have relatively low thermal conductivity or thermal transmittance, that is, high thermal resistance and suitable material properties for windows, are used as materials for the insulation members of aluminum alloy-based insulated non-glazed windows.

As one of the technologies related to this, a triple insulation structure miseogi window is disclosed in Korean Patent Publication No. 10-1616317.

Figure 1 is a diagram showing a conventional triple insulation structure miseogi window.

According to the attached Figure 1, the conventional triple insulated structure micro-window surrounds the front, rear and side edges of the glass with a pair of opposing glass frames, and this pair of glass frames is connected with a connecting insulating material. By installing a roller unit at the bottom of the glass frame, the connection insulation material disconnects the outdoor glass frame from the indoor glass frame, allowing cold or heat to flow into the room or outdoors through the glass frame. The aim is to provide a sliding window equipped with an insulating member that blocks radiation.

However, in the prior art, the lower coupling part of the cover insulation material 500, which is configured to be coupled to the lower part of the glass frame 200, is structured so that only the upper part is fixed, not the upper and lower parts, to the glass frame 200. , there is a problem that after the cover insulation material 500 is coupled to the glass frame 200, it may be removed in an unintended situation by the user.

Republic of Korea Patent Publication 10-1616317 (2016.04.22.) Republic of Korea Patent Publication 10-1243416 (2013.03.07.)

The present invention was developed to solve the above problem, and the problem to be solved by the present invention is that the upper insulation material is coupled to the first upper coupling groove and the second upper coupling groove of the window frame, and the first lower coupling groove of the window frame To provide a window with an improved bonding structure of the insulation material to improve insulation performance by lowering the efficiency of heat transfer through the window frame by configuring the lower insulation material to be coupled to the coupling groove and the second lower coupling groove. there is.

In order to solve the above problems, a window with an improved coupling structure of insulation materials for improving insulation performance according to the present invention has a first upper coupling groove formed in the upper inner direction, and is formed in a shape facing the first upper coupling groove. A window frame including a second upper coupling groove, a first lower coupling groove formed in a lower inner direction, and a second lower coupling groove formed in a shape facing the first lower coupling groove; an upper insulating material configured to be coupled to the first upper coupling groove and the second upper coupling groove; and a lower insulating material configured to be coupled to the first lower coupling groove and the second lower coupling groove, wherein the window frame includes a pair of first upper protrusions protruding from an upper part of the window frame, and the first upper protrusion. A pair of first lower protrusions that protrude from the lower part of the protrusion and form the first upper coupling groove and the second upper coupling groove together with the pair of first upper protrusions, and a pair of first lower protrusions that protrude from the lower part of the window frame. It includes a second upper protrusion and a pair of second lower protrusions that protrude from a lower part of the second upper protrusion and form the first lower coupling groove and the second lower coupling groove together with the pair of second upper protrusions, In the window frame, the second upper protrusion is formed to be inclined downward, and the second lower protrusion is formed to be inclined upward, so that the lower insulation material configured to be coupled to the first lower coupling groove and the second lower coupling groove is the window frame. It is made of a structure that does not deviate in the upper and lower directions, and the lower insulating material is formed to protrude from the lower part of the lower insulating body in a shape corresponding to the first lower coupling groove and the second lower coupling groove. A lower coupling protrusion configured to be inserted into the first lower coupling groove and the second lower coupling groove, a first hair groove formed in the inner direction from the lower part of the lower insulation body, and the first hair groove in the lower part of the lower insulation body It includes a second hair groove formed in a shape facing the lower coupling protrusion, a protruding body protruding from the lower insulating body, an upper fastening protrusion protruding upward from the protruding body, and a lower part from the protruding body. It includes a lower fastening protrusion that protrudes in the direction and an extension fastening protrusion that extends from the protrusion body and the lower fastening protrusion and is formed in a shape to surround a part of the second lower protrusion, and the first hair groove and the second hair groove is formed to have a size that is at least smaller than the size of the lower coupling protrusion, and is configured to be formed at a height corresponding to the height of the lower coupling protrusion, and the lower insulating material is formed to protrude from the lower part of the lower insulating body to form the first It is characterized in that it includes a protrusion configured to surround at least a portion of the lower coupling groove and the second lower coupling groove.

According to the window with an improved coupling structure of insulation materials for improving insulation performance according to the present invention, the upper insulation material is coupled to the first upper coupling groove and the second upper coupling groove of the window frame, and the first lower coupling groove of the window frame By being configured to couple the lower insulation material to the second lower coupling groove, there is an effect of improving insulation performance by reducing the efficiency of heat transfer through the window frame.

According to the present invention, the first upper coupling groove and the second upper coupling groove of the window frame are composed of a pair of first upper projections and a pair of first lower projections, and a pair of first upper projections and a pair of first lower projections. Since the protrusions are configured to fix the upper insulation material at the top and bottom, there is an effect of preventing the upper insulation material from being separated from the window frame.

According to the present invention, the first lower coupling groove and the second lower coupling groove of the window frame are comprised of a pair of second upper protrusions and a pair of second lower protrusions, and a pair of second upper protrusions and a pair of second lower protrusions. Since the protrusions are configured to fix the lower insulation material at the top and bottom, there is an effect of preventing the lower insulation material from being separated from the window frame.

According to the present invention, the second upper protrusion is formed to be inclined downward and the second lower protrusion is formed to be inclined upward, so that the lower insulating material configured to be coupled to the first lower coupling groove and the second lower coupling groove is formed on the upper part of the window frame without the user's intention. And it has the effect of being configured to prevent it from deviating in the downward direction.

According to the present invention, a first hair groove is formed in the inner direction from the lower part of the lower insulating body, and a second hair groove is formed in a shape facing the first hair groove, so that the mohair is coupled to the first hair groove and the second hair groove. By being configured to do so, there is an effect of preventing foreign substances, etc. from flowing into the gap between the window frame and the window frame when used.

According to the present invention, the first hair groove and the second hair groove formed in the lower insulating body are formed in a size smaller than the size of the upper coupling protrusion and are formed at a position corresponding to the lower coupling protrusion, so that the first hair groove and the second hair groove are formed in the lower insulating body. There is an effect of forming a second hair groove to prevent partial strength reduction of the lower insulating material.

According to the present invention, a protrusion is formed to protrude from the lower part of the lower insulation body and is configured to surround at least a portion of the first lower coupling groove and the second lower coupling groove, thereby increasing the coupling area of the window frame and the lower insulation material coupled to the window frame. This has the effect of preventing noise caused by external factors such as wind.

According to the present invention, one or more partition walls are formed in the lower insulating material to protrude from the lower insulating body in both directions and are configured to partition the space between the window frame and the lower insulating material, thereby forming a space between the window frame and the lower insulating material. There is an effect of improving insulation performance by forming the space between the upper and lower insulation materials into the shape of a plurality of compartments.

Figure 1 is a view showing a conventional triple insulation structure miseogi window.
Figure 2 is a view showing a window with an improved bonding structure of insulation materials to improve insulation performance according to the present invention.
Figure 3 is a view showing an embodiment of a window with an improved bonding structure of insulation materials for improving insulation performance according to the present invention.
Figure 4 is a view showing the manufacturing state of a window with an improved bonding structure of insulation materials for improving insulation performance according to the present invention.
Figure 5 is a view showing a window partition with an improved bonding structure of insulation materials to improve insulation performance according to the present invention.

Since the present invention can be modified in various ways and can have various embodiments, specific embodiments will be illustrated in the drawings and described in detail. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

When a component is said to be "connected" or "connected" to another component, it is understood that it may be directly connected to or connected to the other component, but that other components may exist in between. It should be.

On the other hand, when it is mentioned that a component is “directly connected” or “directly connected” to another component, it should be understood that there are no other components in between.

The terms used in this specification are merely used to describe specific embodiments and are not intended to limit the invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, terms such as “comprise” or “have” are intended to designate the presence of features, numbers, processes, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, processes, operations, components, parts, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as generally understood by a person of ordinary skill in the technical field to which the present invention pertains. Terms defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and should not be interpreted as having an ideal or excessively formal meaning unless explicitly defined in the present application. No.

Hereinafter, the present invention will be described in more detail with reference to the attached drawings. Prior to this, the terms or words used in this specification and claims should not be construed as limited to their usual or dictionary meanings, and the inventor should appropriately define the concept of terms in order to explain his or her invention in the best way. Based on the principle of definability, it must be interpreted with meaning and concept consistent with the technical idea of the present invention. In addition, if there is no other definition in the technical and scientific terms used, they have meanings commonly understood by those skilled in the art to which this invention pertains, and the gist of the present invention is summarized in the following description and accompanying drawings. Descriptions of known functions and configurations that may be unnecessarily obscure are omitted. The drawings introduced below are provided as examples so that the idea of the present invention can be sufficiently conveyed to those skilled in the art. Accordingly, the present invention is not limited to the drawings presented below and may be embodied in other forms. Additionally, like reference numerals refer to like elements throughout the specification. It should be noted that like elements in the drawings are represented by like symbols wherever possible.

The present invention is configured such that the upper insulation material is coupled to the first upper coupling groove and the second upper coupling groove of the window frame, and the lower insulation material is coupled to the first lower coupling groove and the second lower coupling groove of the window frame, thereby forming a window frame. This relates to a window with an improved bonding structure of insulation materials to improve insulation performance by reducing the efficiency of heat transfer through the window.

Hereinafter, with reference to the attached drawings, a window with an improved bonding structure of insulation materials for improving insulation performance according to the present invention will be described in detail.

Figure 2 is a view showing a window with an improved bonding structure of insulating materials for improving thermal insulation performance according to the present invention, and Figure 3 is a view showing an embodiment of a window with an improved bonding structure of insulating materials for improving thermal insulation performance according to the present invention. 4 is a view showing the manufacturing state of a window with an improved bonding structure of insulating materials for improving thermal insulation performance according to the present invention, and FIG. 5 is a partition wall of a window with an improved bonding structure of insulating materials for improving thermal insulation performance according to the present invention. This is a drawing showing .

According to the accompanying FIGS. 2 to 5, the window with an improved combination structure of insulation materials for improving insulation performance of the present invention includes a window frame 100, an upper insulation material 200, and a lower insulation material 300.

The window with an improved bonding structure of insulating materials for improving the insulation performance of the present invention refers to a window that opens and closes by sliding to the side. When one pair of windows is slid in the direction of the other pair of windows, the window opens and closes. As the window of the other pair overlaps with each other, the position of the slid pair of windows is opened.

The window frame 100 includes a first upper coupling groove 110 formed in the upper inner direction, a second upper coupling groove 120 formed in a shape facing the first upper coupling groove 110, and a lower inner side. It includes a first lower coupling groove 130 formed in a direction and a second lower coupling groove 140 formed in a shape facing the first lower coupling groove 130.

The window frame 100 is configured to be able to slide while installed on the window frame by combining glass, etc., and depending on the implementation environment, a plurality of slide rollers 10 are installed at the lower part of the window frame 100. It may be installed so that the window frame 100 can be easily slid and moved.

On the other hand, the window frame 100 can be applied in different shapes depending on whether it is for double glazing, double glazing, single glazing, or triple glazing, and the detailed shape is improved by improving the bonding structure of the insulating material to improve the insulating performance of the present invention. Depending on the location and purpose for which the window is installed, it can be modified and applied to any extent.

In addition, the window frame 100 includes a pair of first upper protrusions 150 protruding from the upper part of the window frame 100 and a pair of first upper protrusions 150 protruding from a lower part of the first upper protrusion 150. Together with the first upper protrusion 150, a pair of first lower protrusions 160 forming the first upper coupling groove 110 and the second upper coupling groove 120 may be included.

The pair of first upper protrusions 150 and the pair of first lower protrusions 160 are configured to fix the upper insulating material 200 at the upper and lower portions, and the upper insulating material 200 may be removed without the user's intention. This is to ensure that (200) does not deviate from the window frame (100) in the upper or lower direction.

At this time, in the window frame 100, the first upper protrusion 150 is formed to be inclined downward and the first lower protrusion 160 is formed to be inclined upward, so that the first upper coupling groove 110 and the second upper coupling groove 100 are formed to be inclined upward. The upper insulation material 200 configured to be coupled to the coupling groove 120 may be structured so that it does not deviate from the upper and lower directions of the window frame 100.

That is, the first upper protrusion 150 is formed to be inclined downward and the first lower protrusion 160 is formed to be inclined upward, so that the upper part is configured to be coupled to the first upper protrusion 150 and the first lower protrusion 160. By increasing the contact area between the window frame 100 and the upper insulation material 200 while preventing the insulation material 200 from being removed even in the inner direction of the window frame 100, the sliding movement or wind of the window frame 100 It is designed to reduce vibration or noise caused by external factors such as.

In addition, the window frame 100 includes a pair of second upper protrusions 170 protruding from the lower part of the window frame 100 and a pair of second upper protrusions 170 protruding from the lower part of the second upper protrusion 170. A pair of second lower protrusions 180 forming the first lower coupling groove 130 and the second lower coupling groove 140 may be included along with the second upper protrusion 170.

The pair of second upper protrusions 170 and the pair of second lower protrusions 180 are configured to fix the lower insulating material 300 at the upper and lower portions, and the lower insulating material 300 may be removed in a state not intended by the user. This is to ensure that (300) does not deviate from the window frame (100) in the upper or lower direction.

At this time, in the window frame 100, the second upper protrusion 170 is formed to be inclined downward and the second lower protrusion 180 is formed to be inclined upward, so that the first lower coupling groove 130 and the second lower The lower insulation material 300 configured to be coupled to the coupling groove 140 may be structured so that it does not deviate in the upper and lower directions of the window frame 100.

That is, the second upper protrusion 170 is formed to be inclined downward and the second lower protrusion 180 is formed to be inclined upward, so that the lower part is configured to be coupled to the second upper protrusion 170 and the second lower protrusion 180. By increasing the contact area between the window frame 100 and the lower insulation material 300 while preventing the insulation material 300 from being removed even in the inner direction of the window frame 100, the sliding movement or wind of the window frame 100 It is designed to reduce vibration or noise caused by external factors such as.

The upper insulation material 200 is configured to be coupled to the first upper coupling groove 110 and the second upper coupling groove 120.

The upper insulation material 200 is installed on the window frame 100 and is configured to prevent outdoor cold air from entering the room or indoor cold or warm air from being discharged to the outdoors through the window frame 100.

The upper insulation material 200 may be made of polyamide or polyurethane, etc., which have relatively low thermal conductivity or thermal transmittance, but depending on the implementation environment, any material that has high thermal resistance and is measured to have relatively low thermal conductivity or thermal transmittance can be changed. can be applied.

The lower insulation material 300 is configured to be coupled to the first lower coupling groove 130 and the second lower coupling groove 140.

The lower insulation material 300 is installed on the window frame 100 and is configured to prevent outdoor cold air from entering the room or indoor cold or warm air from being discharged to the outdoors through the window frame 100.

The lower insulation material 300 may be made of polyamide or polyurethane, etc., which have relatively low thermal conductivity or thermal transmittance, but depending on the implementation environment, any material that has high thermal resistance and is measured to have relatively low thermal conductivity or thermal transmittance can be changed. can be applied.

In the lower insulating material 300, a lower insulating body 310 is formed, protruding from the lower part of the lower insulating body 310 in a shape corresponding to the first lower coupling groove 130 and the second lower coupling groove 140. A lower coupling protrusion 320 configured to be inserted into the first lower coupling groove 130 and the second lower coupling groove 140, and a first hair groove formed in the inner direction from the lower part of the lower insulating body 310. (330) and a second hair groove 340 formed in a shape facing the first hair groove 330 at the lower part of the lower insulating body 310 may be included.

That is, the lower insulation material 300 is configured to have a first hair groove 330 and a second hair groove 340 formed in the inner direction from the lower part of the lower insulation body 310 so that the mohair 20 is coupled, When a window with an improved bonding structure of the insulating material for improving the insulation performance of the present invention is combined with a window frame and used, the window frame and the window with the improved bonding structure of the insulating material for improving the heat insulating performance of the present invention enter the room through the gap. It may be configured to prevent foreign substances, etc. from entering.

In addition, the mohair 20 coupled to the first hair groove 330 and the second hair groove 340 has at least the By being configured to have a length that can be in contact with the rail 40 formed on the window frame 30, the rail of the window frame 30 can be used to dispose of foreign substances, etc. on the rail 40 of the window frame 30. 40) and can be configured to prevent outside air from entering through the gap between them.

The lower coupling protrusion 320 includes a protruding body 321 protruding from the lower insulating body 310, an upper coupling protrusion 322 protruding upward from the protruding body 321, and the protruding body 321. ) and a lower fastening protrusion 323 that protrudes downward from the protrusion body 321 and the lower fastening protrusion 323 and is formed in a shape that surrounds a portion of the second lower protrusion 180. Protrusions 324 may be included.

At this time, the upper fastening protrusion 322 and the lower fastening protrusion 323 that protrude from the protruding body 321 are formed to protrude obliquely from the protruding body 321 at a predetermined angle and form the lower part with respect to the window frame 100. It may be configured to improve the bonding strength of the insulation material 300.

In addition, the extension fastening protrusion 324 is configured to protrude in a shape surrounding the second lower protrusion 180, so that the bonding force of the lower insulation material 300 to the window frame 100 can be improved.

The first hair groove 330 and the second hair groove 340 are formed at least in a size smaller than the size of the lower coupling protrusion 320, and are formed at a position corresponding to the position of the lower coupling protrusion 320. It can be configured as follows.

In other words, the first hair groove 330 and the second hair groove 340 are formed in the lower insulating body 310 and are configured to be formed at the same height as the lower coupling protrusion 320, thereby forming the first hair groove 340. It may be configured to prevent a decrease in the strength of the lower insulation material 300 due to the formation of the first hair groove 330 and the second hair groove 340 and to prevent vibration due to friction with the window frame 30. .

In the lower insulating material 300, a protrusion 350 is formed to protrude from the lower part of the lower insulating body 310 and is configured to surround at least a portion of the first lower coupling groove 130 and the second lower coupling groove 140. ) may be included.

The protrusion 350 is configured to surround at least a portion of the first lower coupling groove 130 and the second lower coupling groove 140 and forms a lower insulating material coupled to the window frame 100 and the window frame 100. It is configured to improve the coupling area of 300, and is configured to prevent vibration and noise generation due to external factors such as sliding movement or wind of the window frame 100.

The shape of the protrusion 350 can be modified to protrude as long as it is configured to improve the combined area of the window frame 100 and the lower insulation material 300 coupled to the window frame 100.

Meanwhile, the window with an improved coupling structure of insulation materials for improving insulation performance according to the present invention includes the pair of first upper protrusions 150 and the lower insulation material ( By being configured to allow processing of the pair of second lower protrusions 180, which are configured to fix the lower part of the window frame 100, at a time, the upper insulation material 200 and the lower insulation material for the window frame 100 ( 300) manufacturing efficiency can be improved.

For example, the pair of first upper protrusions 150 of the window frame 100 are spread upward, and the upper insulation material 200 is attached to the pair of first lower protrusions 160 of the window frame 100. is disposed, the pair of second lower protrusions 180 of the window frame 100 are spread downward, and the lower insulation material 300 is attached to the pair of second upper protrusions 170 of the window frame 100. In the arranged state, it is configured to move along the conveyor belt and pass between the processing rollers 60 installed at the upper and lower parts, so that the upper insulation material 200 and the lower insulation material 300 are installed on the window frame 100. It can be.

More specifically, in a state where the upper insulation material 200 is disposed on a pair of first lower protrusions 160 and the lower insulation material 300 is disposed on a pair of second upper protrusions 170, the window When the frame 100 moves along the conveyor belt and passes between the processing rollers 60 installed at the upper and lower portions, a pair of first upper protrusions 150 spread in the upper direction are formed on the processing rollers 60. ) is pressed and folded downward to fix the upper insulation material 200 to the window frame 100, and a pair of second lower protrusions 180 extending in the downward direction are connected to the processing roller 60. It may be configured to be pressed and folded upward to secure the lower insulation material 300 to the window frame 100.

That is, the window with an improved bonding structure of insulation materials for improving insulation performance according to the present invention has an upper insulation material 200 and a lower insulation material 300 configured to be coupled to the window frame 100. Rather than being coupled through a slide movement along the longitudinal direction, the upper insulation material ( After the 200) and the lower insulation material 300 are disposed, the pair of first upper protrusions 150 and the pair of second lower protrusions 180 are configured to be pressed and folded to be combined, so that the window frame 100 The manufacturing efficiency of the upper insulation material 200 and the lower insulation material 300 can be improved.

Meanwhile, the lower insulating material 300 of the present invention includes one or more pieces that protrude from the lower insulating body 310 in both directions and are configured to partition the space between the window frame 100 and the lower insulating material 300. A partition wall 360 may be included.

The partition wall 360 is configured to improve the insulation performance of the upper insulation material 200 by dividing the space formed between the window frame 100 and the lower insulation material 300 into a plurality of compartments. It can be.

More specifically, the partition wall 360 divides the space between the window frame 100 and the lower insulation material 300 into a plurality of compartments and prevents heat transfer between each compartment, thereby preventing the lower insulation material 300 from being easily transferred. ), the combination structure of the insulation material for improving the insulation performance of the present invention can be configured to improve the insulation performance of the improved window.

According to the present invention, the upper insulation material is coupled to the first upper coupling groove and the second upper coupling groove of the window frame, and the lower insulation material is coupled to the first lower coupling groove and the second lower coupling groove of the window frame, It has the effect of improving insulation performance by reducing the efficiency of heat transfer through the window frame.

In the above description, various embodiments of the present invention have been presented and explained, but the present invention is not necessarily limited thereto, and those skilled in the art will understand various embodiments without departing from the technical spirit of the present invention. It can be seen that branch substitution, transformation, and change are possible.

10: Slide roller 20: Mohair
30: window frame 40: rail
50: conveyor belt 60: processing roller
100: window frame
110: first upper coupling groove 120: second upper coupling groove
130: first lower coupling groove 140: second lower coupling groove
150: first upper protrusion 160: first lower protrusion
170: 2nd upper protrusion 180: 2nd lower protrusion
200: Upper insulation material
300: Lower insulation material
310: Lower insulation body
320: Lower joining protrusion
321: Protrusion body 322: Upper fastening protrusion
323: Lower fastening protrusion 324: Extension fastening protrusion
330: 1st hair home 340: 2nd hair home
350: protrusion 360: bulkhead

Claims (1)

A first upper coupling groove 110 formed in the upper inward direction, a second upper coupling groove 120 formed in a shape facing the first upper coupling groove 110, and a first lower coupling formed in the lower inward direction. A window frame 100 including a groove 130 and a second lower coupling groove 140 formed in a shape facing the first lower coupling groove 130;
An upper insulator 200 configured to be coupled to the first upper coupling groove 110 and the second upper coupling groove 120; and
A lower insulating material 300 configured to be coupled to the first lower coupling groove 130 and the second lower coupling groove 140;
includes,
In the window frame 100,
A pair of first upper protrusions 150 protruding from the upper part of the window frame 100, and a pair of first upper protrusions 150 protruding from a lower part of the first upper protrusion 150. A pair of first lower protrusions 160 forming the first upper coupling groove 110 and the second upper coupling groove 120, and a pair of second upper protrusions protruding from the lower part of the window frame 100. (170) and the second upper protrusion 170 are protruding from the lower part of the pair of second upper protrusions 170 and form the first lower coupling groove 130 and the second lower coupling groove 140. It includes a pair of second lower protrusions (180),
The window frame 100 is,
The second upper protrusion 170 is formed to be inclined downward, and the second lower protrusion 180 is formed to be inclined upward, so that it is coupled to the first lower coupling groove 130 and the second lower coupling groove 140. The lower insulating material 300 has a structure that does not deviate from the upper and lower directions of the window frame 100,
In the lower insulation material 300,
The lower insulating body 310 is formed to protrude from the lower part of the lower insulating body 310 in a shape corresponding to the first lower coupling groove 130 and the second lower coupling groove 140, and the first lower coupling groove ( 130) and a lower coupling protrusion 320 configured to be inserted into the second lower coupling groove 140, a first hair groove 330 formed in the inner direction from the lower part of the lower insulation body 310, and the lower insulation body A second hair groove 340 is formed in a shape facing the first hair groove 330 at the lower part of 310,
In the lower coupling protrusion 320,
A protruding body 321 protruding from the lower insulating body 310, an upper fastening protrusion 322 protruding from the protruding body 321 in an upward direction, and a lower part protruding from the protruding body 321 in a downward direction. It includes a fastening protrusion 323 and an extension fastening protrusion 324 that extends from the protruding body 321 and the lower fastening protrusion 323 and is formed in a shape to surround a portion of the second lower protrusion 180,
The first hair groove 330 and the second hair hair groove 340,
It is formed to be at least smaller than the size of the lower coupling protrusion 320 and is configured to be formed at a height corresponding to the height of the lower coupling protrusion 320,
In the lower insulation material 300,
Characterized in that it includes a protrusion 350 that protrudes from the lower part of the lower insulating body 310 and is configured to surround at least a portion of the first lower coupling groove 130 and the second lower coupling groove 140. A window with an improved bonding structure of insulation materials to improve insulation performance.