KR102643297B1 - Curtain wall with double insulation structure - Google Patents

Abstract

The curtain wall includes a window member, an internal frame provided on one side of the window member, a first thermal bridge blocking member provided between the internal frame and the window member, and a second thermal bridge configured to engage the first thermal bridge blocking member on the opposite side of the internal frame. It includes a blocking member, and a first gasket between the first thermal bridge blocking member and the window member, respectively, where the first thermal bridge blocking member and the first gasket may be configured to close the gap between the internal frame and the window member.

Description

Curtain wall with double insulation structure}

The present disclosure relates to curtain walls, and specifically to curtain walls having a double insulation structure.

Curtain Wall refers to the outer wall of a partition that does not support a load, and in Korean architectural terminology, it is called a non-load-bearing partition wall. In a curtain wall structure, only the frame of columns and beams, which are the main structure of the building, supports the vertical load applied to the building and the horizontal load caused by wind or earthquakes, and the wall simply acts as a curtain to divide the space.

The problem to be solved is to provide a curtain wall with improved thermal insulation performance.

The problem to be solved is to provide a curtain wall with improved airtightness.

The problem to be solved is to provide a curtain wall that is easy to install.

However, the problem to be solved is not limited to the above disclosure.

In one aspect, a window member; an internal frame provided on one side of the window member; a first thermal bridge blocking member provided between the inner frame and the window member; a second thermal bridge blocking member configured to be coupled to the first thermal bridge blocking member on the opposite side of the internal frame; And a first gasket between the first thermal bridge blocking member and the window member, wherein the first thermal bridge blocking member and the first gasket are configured to close the gap between the inner frame and the window member. Months may be provided.

The second thermal bridge blocking member includes a first coupling protrusion extending along a first direction intersecting the arrangement direction of the first thermal bridge blocking member and the second thermal bridge blocking member, and a second direction intersecting the first direction. It includes a second coupling groove extending along, and the first thermal bridge blocking member may include a first coupling groove coupled to the first coupling protrusion, and a second coupling protrusion inserted into the second coupling groove. .

The first gasket includes a third coupling groove and a fourth coupling groove disposed adjacent to the first thermal bridge blocking member, and the first thermal bridge blocking member includes a third coupling protrusion inserted into the third coupling groove. And, the second thermal bridge blocking member is inserted into the fourth coupling groove and is spaced apart from the third coupling protrusion along a first direction intersecting the arrangement direction of the first thermal bridge blocking member and the second thermal bridge blocking member. It may include a fourth coupling protrusion.

an external frame provided on the other side of the window member; a third thermal bridge blocking member coupled to the external frame between the external frame and the window member; a second gasket configured to close the gap between the external frame and the window member between the third thermal bridge blocking member and the window member; It may include; a coupling screw that penetrates the third thermal bridge frame and is coupled to the second thermal bridge frame.

The present disclosure can provide a curtain wall with improved thermal insulation performance.

The present disclosure can provide a curtain wall with improved airtightness.

The present disclosure can provide a curtain wall that is easy to install.

However, the effect of the invention is not limited to the above disclosure.

1 is a perspective view of a curtain wall according to example embodiments.
FIG. 2 is a cross-sectional view showing portion AA of FIG. 1.
FIG. 3 is a cross-sectional view of FIG. 2 with the first and second coupling screws excluded.
Figure 4 is a cross-sectional view showing the first thermal bridge blocking member.
Figure 5 is a cross-sectional view showing the second thermal bridge blocking member.
Figure 6 is a cross-sectional view showing the first gasket.
Figure 7 is a cross-sectional view showing the external frame, the third thermal bridge blocking member, and the second gasket.
Figures 8 and 9 are test reports showing the performance of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings. In the following drawings, the same reference numerals refer to the same components, and the size of each component in the drawings may be exaggerated for clarity and convenience of explanation. Meanwhile, the embodiments described below are merely illustrative, and various modifications are possible from these embodiments.

Hereinafter, the term “on” may include not only what is directly above in contact but also what is above without contact.

Singular expressions include plural expressions unless the context clearly dictates otherwise. Additionally, when a part is said to “include” a certain component, this means that it may further include other components, rather than excluding other components, unless specifically stated to the contrary.

1 is a perspective view of a curtain wall according to example embodiments. FIG. 2 is a cross-sectional view showing portion AA of FIG. 1. FIG. 3 is a cross-sectional view of FIG. 2 with the first and second coupling screws excluded. Figure 4 is a cross-sectional view showing the first thermal bridge blocking member. Figure 5 is a cross-sectional view showing the second thermal bridge blocking member. Figure 6 is a cross-sectional view showing the first gasket. Figure 7 is a cross-sectional view showing the external frame, the third thermal bridge blocking member, and the second gasket.

Referring to FIGS. 1 to 7 , a curtain wall 10 may be provided. The curtain wall 10 may include a plurality of window members 110 and a frame member 1000 provided between the plurality of window members 110. The plurality of window members 110 may be arranged along the first direction DR1. However, the arrangement direction of the plurality of window members 110 is illustrative. In another example, the plurality of window members 110 may move in at least one direction selected from the second direction DR2 that intersects the first direction DR1 or a combination of the first direction DR1 and the second direction DR2. It can be arranged according to .

The frame member 1000 may include an inner frame 120, an outer frame 210, which will be described later, and various components provided between the inner frame 120 and the outer frame 210. The frame member 1000 may extend along the third direction DR3 except for the first coupling screw 150, the second coupling screw 240, and the support member 170. For brevity of explanation, the curtain wall 10 of the present disclosure is described based on a pair of window members 110 spaced apart from each other along the first direction DR1. The spirit of the invention according to the description below can also be applied to window members 110 and frame members 1000 that have different directions.

A pair of window members 110 may be spaced apart from each other along the first direction DR1. Each of the pair of window members 110 may include a plurality of glass plates 112 and connecting portions 114. The plurality of glass plates 112 may be arranged along the second direction DR2. Although three glass plates 112 are shown, this is exemplary. In another example, the plurality of glass plates 112 may be composed of two or four or more glass plates. In other example embodiments, each of the pair of window members 110 may be configured to include one glass plate. In example embodiments, the area between the plurality of glass plates 112 may be a vacuum. In other example embodiments, the area between the plurality of glass plates 112 may be filled with gas (eg, air or argon gas). Connection portions 114 may be provided between the plurality of glass plates 112, respectively. The connecting portions 114 may be configured to seal the area between the plurality of glass plates 112 and maintain the gap between the plurality of glass plates 112. The plurality of glass plates 112 may be spaced apart from each other by connecting portions 114.

The frame member 1000 may include an inner frame 120, an outer frame 210, and various components provided between the outer frame 210 and the outer frame 210. The internal frame 120 may be provided inside an object (eg, a building) where the curtain wall 10 is installed. The internal frame 120 may have a tubular shape extending along the third direction DR3. Although the cross-section of the inner region defined by the inner frame 120 is shown to be square, this is merely illustrative. The inner frame 120 may include aluminum or aluminum alloy. The length of the internal frame 120 along the second direction DR2 may be longer than the length along the first direction DR1. Accordingly, the inner frame 120 can secure sufficient space inside the inner frame 120 while minimally covering the pair of window members 110. As the space inside the internal frame 120 becomes larger, the insulation characteristics of the curtain wall 10 can be improved. The inner frame 120 may include first spacers 122 in an area adjacent to the pair of window members 110 . The first spacers 122 may be configured to form insulating spaces 150 between the internal frame 120 and the first thermal bridge blocking member 130, which will be described later.

A first thermal bridge blocking member 130 may be provided between the inner frame 120 and the pair of window members 110. The first thermal bridge blocking member 130 may extend along the first direction DR1. The first thermal bridge blocking member 130 may be configured to lower the heat transfer rate between spaces (eg, indoor space and outdoor space of a building) spaced apart from each other with the curtain wall 10 therebetween. The insulation characteristics of the curtain wall 10 may be improved by the first thermal bridge blocking member 130. The first thermal bridge blocking member 130 may be made of a material with excellent thermal insulation properties. For example, the first thermal bridge blocking member 130 may include polyamide-based resin, polyvinyl chloride (PVC), and combinations thereof. A pair of gripping protrusions 131 may be provided at both ends of the first thermal bridge blocking member 130 along the first direction DR1. A pair of gripping protrusions 131 is used to allow an operator to use the first thermal bridge blocking member 130 before the first thermal bridge blocking member 130 is coupled to the internal frame 120 by first coupling screws 150 to be described later. ) may be configured to facilitate close contact with the internal frame 120 while holding it. Even after the frame member 1000 and the window members 110 are coupled, the pair of gripping protrusions 131 may be exposed between the inner frame 120 and the window members 110.

The first thermal bridge blocking member 130 may include second spacers 132 provided adjacent to the internal frame 120. The second spacers 132 may form insulating spaces 150 between the internal frame 120 and the first thermal bridge blocking member 130. The second spacers 132 may be configured to directly contact the internal frame 120. When the second spacers 132 directly contact the internal frame 120, the first spacers 122 may directly contact the first thermal bridge blocking member 130. Some of the insulating spaces 150 may be formed between the first spacer 122 and the second spacer 132 that are immediately adjacent to each other. For example, among the insulation spaces 150, the outermost insulation spaces 150 located along the first direction DR1 may be provided between the first spacer 122 and the second spacer 132. . The number of second spacers 132 is not limited and may be determined as needed. In example embodiments, the insulating spaces 150 may be filled with air. The insulating spaces 150 can reduce the heat transfer rate between spaces (for example, the indoor space and outdoor space of a building) that are spaced apart from each other with the curtain wall 10 in between. Accordingly, the insulation properties of the curtain wall can be improved.

The first thermal bridge blocking member 130 may include a pair of first coupling grooves 133. A pair of first coupling grooves 133 may be provided adjacent to a pair of window members 110 . A pair of first coupling grooves 133 may be provided to face a second thermal bridge blocking member 140, which will be described later. One of the pair of first coupling grooves 133 may have a concave shape along the first direction DR1, and the other may have a concave shape along a direction opposite to the first direction DR1. The pair of first coupling grooves 133 may be configured to stably couple the first thermal bridge blocking member 130 and the second thermal bridge blocking member 140, which will be described later.

The first thermal bridge blocking member 130 may include a pair of second coupling protrusions 134. A pair of second coupling protrusions 134 may be provided between a pair of first coupling grooves 133 and a pair of window members 110, respectively. The pair of second coupling protrusions 134 may extend from the pair of first coupling grooves 133 toward the pair of window members 110 . For example, the pair of second coupling protrusions 134 may extend along the second direction DR2. A pair of second coupling protrusions 134 are each inserted into a pair of second coupling grooves 144 to be described later, thereby stably coupling the first thermal bridge blocking member 130 and the second thermal bridge blocking member 140. can do.

The first thermal bridge blocking member 130 may include a pair of third coupling protrusions 135. The pair of third coupling protrusions 135 may protrude inward from the pair of gripping protrusions 131. The pair of third coupling protrusions 135 may extend from the pair of gripping protrusions 131 toward the second thermal bridge blocking member 140, which will be described later. For example, the pair of third coupling protrusions 135 may extend along the first direction DR1. The pair of third coupling protrusions 135 may each be inserted into the second coupling grooves 162 of the pair of first gaskets 160, which will be described later.

The second thermal bridge blocking member 140 may be provided on the opposite side of the internal frame 120 with the first thermal bridge blocking member 130 interposed therebetween. The second thermal bridge blocking member 140 may extend along the first direction DR1. The second thermal bridge blocking member 140 reduces the heat transfer rate between spaces (for example, the indoor space and the outdoor space of a building) spaced apart from each other with the curtain wall 10 in between, and the bonding force with other components. It can be configured to increase. For example, the second thermal bridge blocking member 140 may include aluminum or an aluminum alloy.

The second thermal bridge blocking member 140 may include a pair of first coupling protrusions 142. A pair of first coupling protrusions 142 may be provided at both ends of the second thermal bridge blocking member 140 along the first direction DR1. For example, the pair of first coupling protrusions 142 may extend along the first direction DR1. A pair of first coupling protrusions 142 may be provided in an area adjacent to the inner frame 120 of the second thermal bridge blocking member 140. The pair of first coupling protrusions 142 may each be inserted into the pair of first coupling grooves 133 of the first thermal bridge blocking member 130. Accordingly, the first thermal bridge blocking member 130 and the second thermal bridge blocking member 140 can be stably coupled.

The second thermal bridge blocking member 140 may include a pair of second coupling grooves 144. A pair of second coupling grooves 144 may be provided in an area adjacent to the pair of window members 110 in the second thermal bridge blocking member 140. For example, the pair of second coupling grooves 144 may extend along the second direction DR2. The second thermal bridge blocking member 140 may include a pair of protrusions 145 that define a pair of second coupling grooves 144 . However, it is illustrative that the pair of second coupling grooves 144 are defined by the pair of protrusions 145. In another example, the second thermal bridge blocking member 140 may have a structure configured to define a pair of second coupling grooves 144 rather than a pair of protrusions 145 .

The second thermal bridge blocking member 140 may include a pair of fourth coupling protrusions 146. The pair of fourth coupling protrusions 146 may be configured to face the pair of third coupling protrusions 135 of the first thermal bridge blocking member 130. Each of the pair of fourth coupling protrusions 146 may protrude toward the immediately adjacent third coupling protrusion 135 among the pair of third coupling protrusions 135 . For example, the pair of fourth coupling protrusions 146 may extend along the first direction DR1. The pair of fourth coupling protrusions 146 may each be inserted into the fourth coupling grooves 164 of the pair of first gaskets 160, which will be described later. The curtain wall 10 of the present disclosure includes not only the first thermal bridge blocking member 130 but also the second thermal bridge blocking member 140, so it may have improved thermal insulation properties.

The second thermal bridge blocking member 140 may include a coupling screw receiving portion 148. The second coupling screw receiving portion 148 may be coupled with the second coupling screw 240, which will be described later. For example, the coupling screw receiving portion 148 may include a groove corresponding to the thread of the second coupling screw 240. The coupling screw receiving portion 148 may extend toward the external frame 210. For example, the second coupling screw receiving portion 148 may extend along the second direction DR2.

The internal frame 120, the first thermal bridge blocking member 130, and the second thermal bridge blocking member 140 may be coupled by a first coupling screw (150). A pair of first engaging screws 150 is shown, but this is exemplary. The number of first coupling screws 150 may be determined as needed. In order to couple the first coupling screw 150 to the inner frame 120, the first thermal bridge blocking member 130, and the second thermal bridge blocking member 140, the inner frame 120, the first thermal bridge blocking member 130 ), and the second thermal bridge blocking member 140 must be aligned in a position to be screwed. Fixing and screwing together all three different components by hand is not easy even for skilled workers. The first thermal bridge blocking member 130 and the second thermal bridge blocking member 140 of the present disclosure have a first coupling groove 133 - a first coupling protrusion * and a second coupling protrusion * even before being screwed together by the first coupling screw 150. The coupling groove 144 can be stably coupled to the second coupling protrusion 134. Accordingly, the screw coupling operation of the internal frame 120, the first thermal bridge blocking member 130, and the second thermal bridge blocking member 140 can be easily performed. Furthermore, since the first thermal bridge blocking member 130 includes a plurality of gripping protrusions 131, the screw coupling operation of the first thermal bridge blocking member 130 and the second thermal bridge blocking member 140 can be easily performed. You can.

A pair of first gaskets 160 may be provided between the first thermal bridge blocking member 130 and the pair of window members 110. The pair of first gaskets 160 may block the area between the first thermal bridge blocking members 130. For example, the pair of first gaskets 160 may directly contact the first thermal bridge blocking member 130 and the pair of window members 110. The pair of first gaskets 160 may include a material that has a low heat transfer rate and the required elasticity. For example, the pair of first gaskets 160 may include thermoplastic rubber, thermosetting rubber, or silicone. The pair of first gaskets 160 may be configured to reduce the heat transfer rate between spaces (eg, indoor space and outdoor space of a building) that are spaced apart from each other with the curtain wall 10 in between.

The pair of first gaskets 160 may each include a pair of second coupling grooves 162. A pair of second coupling grooves 162 may be provided in an area adjacent to the first thermal bridge blocking member 130. The pair of second coupling grooves 162 may face the pair of third coupling protrusions 135 so that the pair of third coupling protrusions 135 are inserted.

The pair of first gaskets 160 may each include fourth coupling grooves 164. The pair of fourth coupling grooves 164 may be disposed on opposite sides of the pair of second coupling grooves 162, respectively. The third coupling groove 162 and the fourth coupling groove 164, which are immediately adjacent to each other, may be spaced apart from each other along the first direction DR1. A pair of fourth coupling grooves 164 may be provided in an area adjacent to the second thermal bridge blocking member 140. The pair of fourth coupling grooves 164 may face the pair of fourth coupling protrusions 146 so that the pair of fourth coupling protrusions 146 are inserted.

The third coupling protrusion 135 and the fourth coupling protrusion 146, which are immediately adjacent to each other, may be inserted into the third coupling groove 162 and the fourth coupling groove 164, respectively, which are immediately adjacent to each other. Accordingly, the pair of first gaskets 160 can be stably coupled to the first thermal bridge blocking member 130 and the second thermal bridge blocking member 140.

Each of the pair of first gaskets 160 may include a pair of first airtightness improvement protrusions 166 . The pair of first airtightness improvement protrusions 166 may be provided in areas adjacent to the pair of window members 110 of the pair of first gaskets 160 . The pair of first airtightness improvement protrusions 166 may directly contact the pair of window members 110 . The pair of first airtightness improvement protrusions 166 may be configured so that the pair of first gaskets 160 and the pair of window members 110 have a large contact area. Airtightness between the pair of first gaskets 160 and the pair of window members 110 may be improved by the pair of first airtightness improvement protrusions 166. The shape of the pair of first airtightness improvement protrusions 166 may be determined as needed. The second thermal bridge blocking member 140 and the third thermal bridge blocking member 220 may be screwed together by the second coupling screw 240, which will be described later. As the coupling by the second coupling screw 240 becomes stronger, the airtightness between the pair of first gaskets 160 and the pair of window members 110 can be improved.

Generally, the area between the window member 110 and the internal frame 120 can be filled using a sealant. For example, silicone-based sealants can be used. When using a sealant, after combining the frame member 1000 with the plurality of window members 110, separate manpower, time, and cost are required for sealant work. Since the first gasket* of the present disclosure is configured to block the area between the window member 110 and the internal frame 120, a separate sealant process may not be required. Accordingly, less manpower, time, and cost may be required.

The external frame 210 may be provided on the outside of the object (eg, building) where the curtain wall 10 is installed. The outer frame 210 and the inner frame 120 may be spaced apart from each other along the second direction DR2. The external frame 210 may have a cover shape extending along the third direction DR3. For example, the external frame 210 includes a horizontal portion 210a extending along the first direction DR1 and a pair of vertical portions extending along the second direction DR2 from both ends of the horizontal portion 210a. It may include cattails 210b. The outer frame 210 may include aluminum or aluminum alloy.

A pair of vertical portions 210b may each include a pair of blocking protrusions 212. The pair of blocking protrusions 212 may be configured to prevent the third thermal bridge blocking member 220, which will be described later, from moving toward the horizontal portion 210a. The pair of blocking protrusions 212 may be configured to protrude inside the external frame 210 . For example, the pair of blocking protrusions 212 may extend along the first direction DR1 and contact the third thermal bridge blocking member 220 along the second direction DR2.

The pair of vertical portions 210b may each include a pair of fifth coupling protrusions 214. The pair of fifth coupling protrusions 214 may be configured to be respectively fitted into a pair of fifth coupling grooves 222 of the third thermal bridge blocking member 220, which will be described later. Accordingly, the coupling force between the external frame 210 and the third thermal bridge blocking member 220 may be improved. The pair of fifth coupling protrusions 214 may be configured to protrude inside the external frame 210 . For example, the pair of fifth coupling protrusions 214 may extend along the first direction DR1.

A third thermal bridge blocking member 220 may be provided inside the external frame 210. The third thermal bridge blocking member 220 may have a shape extending along the first direction DR1. The third thermal bridge blocking member 220 may be configured to lower the heat transfer rate between spaces (eg, indoor space and outdoor space of a building) spaced apart from each other with the curtain wall 10 therebetween. The insulation characteristics of the curtain wall 10 may be improved by the third thermal bridge blocking member 220. The third thermal bridge blocking member 220 may be made of a material with excellent thermal insulation properties. For example, the third thermal bridge blocking member 220 may include polyamide-based resin, polyvinyl chloride (PVC), and combinations thereof.

The third thermal bridge blocking member 220 may include a pair of fifth coupling protrusions 214 and a pair of fifth coupling grooves 222 respectively facing each other. The pair of fifth coupling grooves 222 may be configured to each accommodate a pair of fifth coupling protrusions 214. Accordingly, the coupling force between the third thermal bridge blocking member 220 and the external frame 210 can be improved.

The third thermal bridge blocking member 220 may include sixth coupling protrusions 224. The sixth coupling protrusions 224 may be provided in an area adjacent to the pair of window members 110 . One of the sixth coupling protrusions 224 may be provided adjacent to one of the pair of window members 110 . The other pair of sixth coupling protrusions 224 may be provided adjacent to the other one of the pair of window members 110 . The sixth coupling protrusions 224 may be respectively inserted into the sixth coupling grooves 232 of the second gaskets 230, which will be described later.

The third thermal bridge blocking member 220 may include a fitting groove 226. The fitting groove 226 may be provided in the central portion of the third thermal bridge blocking member 220. The fitting groove 226 may be open along the second direction DR2. The fitting groove 226 may be configured to accommodate the support member 170, which will be described later. A pair of protrusions are shown defining the fitting groove 226, but this is illustrative. In another example, the third thermal bridge blocking member 220 defines a fitting groove 226 but may have a structure other than a pair of protrusions.

A pair of second gaskets 230 will be provided between the outer frame 210 and the pair of window members 110 and between the third thermal bridge blocking member 220 and the pair of window members 110. You can. The pair of second gaskets 230 may be spaced apart from each other along the first direction DR1. The pair of second gaskets 230 may include a material that has a low heat transfer rate and the required elasticity. For example, the pair of second gaskets 230 may include thermoplastic rubber, thermosetting rubber, or silicone. The pair of second gaskets 230 may be configured to reduce the heat transfer rate between spaces (eg, indoor space and outdoor space of a building) spaced apart from each other with the curtain wall 10 in between.

The pair of second gaskets 230 may include sixth coupling grooves 232. The sixth coupling grooves 232 may be provided in areas adjacent to the third thermal bridge blocking member 220 of the pair of second gaskets 230. Each of the pair of second gaskets 230 may include a pair of sixth coupling grooves 232. The pair of sixth coupling grooves 232 may be configured so that a pair of sixth coupling protrusions 224 adjacent thereto are respectively inserted. The sixth coupling grooves 232 may be configured to extend along the first direction DR1.

A support member 170 may be provided between the pair of window members 110. The support member 170 may be provided between the engaging screw receiving portion 148 and the third thermal bridge blocking member 220. The support member 170 may be penetrated by the second coupling screw 240. The support member 170 may be configured to support the second coupling screw 240. The support member 170 may be inserted into the fitting groove 226 of the third thermal bridge blocking member 220. The fitting groove 226 may be configured to fix the position of the support member 170 along the first direction DR1. The support member 170 may be prevented from moving along the first direction DR1 by the fitting groove 226 . For example, support member 170 may include aluminum or aluminum alloy.

The second coupling screw 240 may be configured to penetrate the third thermal bridge blocking member 220 and the support member 170 and be screwed to the coupling screw receiving portion 148. The relative positions of the third thermal bridge blocking member 220, the support member 170, and the second thermal bridge blocking member 140 may be fixed by the second coupling screw 240. The distance between the second thermal bridge blocking member 140 and the third thermal bridge blocking member 220 may be adjusted depending on the tightening strength of the second coupling screw 240. When the second coupling screw 240 is relatively tightly tightened, the second thermal bridge blocking member 140 and the third thermal bridge blocking member 220 may be relatively close to each other. The pair of first gaskets 160 and the pair of second gaskets 230 may be in relatively strong contact with the pair of window members 110 . Airtightness between the pair of first gaskets 160 and the pair of second gaskets 230 and the pair of window members 110 can be improved. When the second coupling screw 240 is relatively weakly tightened, the second thermal bridge blocking member 140 and the third thermal bridge blocking member 220 may be relatively far apart. The pair of first gaskets 160 and the pair of second gaskets 230 may be in relatively weak contact with the pair of window members 110 . Airtightness between the pair of first gaskets 160 and the pair of second gaskets 230 and the pair of window members 110 may be relaxed. In exemplary embodiments, the degree of tightening of the second coupling screw 240 is determined by the pair of first gaskets 160, the pair of second gaskets 230, and the pair of window members 110. It can be decided to have the required confidentiality. The present disclosure provides a curtain wall 10 in which a frame member 1000 and a plurality of window members 110 are combined using first gaskets 160 and second gaskets 230 without a separate sealant process. It can be. Accordingly, less manpower, time, and cost may be required.

The present disclosure can provide a curtain wall 10 with improved thermal insulation performance. For example, the curtain wall 10 may have an insulation performance of 0.9 W/m ² K or less. The present disclosure can provide a curtain wall with improved airtightness. The present disclosure can provide a curtain wall that is easy to install.

Figures 8 and 9 are test reports showing the performance of the present invention.

Referring to Figures 8 and 9, the 2013-KEPL-0493-B report of the window insulation test and window airtightness test conducted by the Korea Energy Performance Research and Development Institute is confirmed. As shown in the drawing of FIG. 9, this report relates to the present invention. As shown in Figure 8, the heat transmittance of the present invention is 0.876 W/(m ² K), so it satisfies the green technology standard of heat transmittance of 0.9 or less. Furthermore, the confidentiality of the present invention was secured at level 1.

The above description of embodiments of the technical idea of the present disclosure provides examples for explaining the technical idea of the present disclosure. Therefore, the technical idea of the present disclosure is not limited to the above embodiments, and various modifications and changes can be made by combining the above embodiments by those skilled in the art within the technical idea of the present disclosure. This possibility is obvious.

10: curtain wall 110: window member
120: Internal frame 130: First thermal bridge blocking member
140: second thermal bridge blocking member 150: first coupling screw
160: first gasket 170: support member
210: External frame 220: Third thermal bridge blocking member
230: second gasket

Claims (4)

a window member extending along a first direction;
An outer frame and an inner frame respectively provided on one side and the other side of the window member arranged along a second direction intersecting the first direction; provided between the inner frame and the window member, one at both ends A pair of first engaging grooves each including a pair of gripping protrusions and having a concave shape along the first direction and a direction opposite to the first direction, and each between the pair of first engaging grooves and the window member. A first thermal bridge blocking member including a pair of second coupling protrusions provided;
As long as it is configured to engage with the first thermal bridge blocking member on the opposite side of the internal frame, and is configured to extend along the first direction and a direction opposite to the first direction, respectively, to engage with the pair of first coupling grooves, respectively. Defining a pair of first engaging protrusions, a pair of second engaging grooves having a concave shape along the second direction to engage each of the pair of second engaging protrusions, and the pair of second engaging grooves. a second thermal bridge blocking member including a pair of protrusions;
A pair of first gaskets each provided between the first thermal bridge blocking member and the window member to close the gap between the first thermal bridge blocking member and the window member;
a third thermal bridge blocking member coupled to the external frame between the external frame and the window member;
a pair of second gaskets respectively provided between the third thermal bridge blocking member and the window member to close the gap between the external frame and the window member; and
Includes a coupling screw that penetrates the third thermal bridge blocking member and is coupled to the second thermal bridge blocking member, wherein each of the pair of first gaskets has a third coupling disposed adjacent to the first thermal bridge blocking member. It includes a groove and a fourth engaging groove, and includes an airtightness improvement protrusion configured to contact the window member,
The first thermal bridge blocking member includes a pair of third coupling protrusions each inserted into the third coupling groove of the pair of first gaskets,
A pair of grooves are provided between the pair of third engaging protrusions and the pair of second engaging protrusions into which the pair of first gaskets are respectively inserted,
Among the pair of gripping protrusions and the pair of first coupling grooves, the gripping protrusion and the first coupling groove are immediately adjacent to each other, and the gripping protrusion and the first coupling groove are immediately adjacent to each other among the pair of grooves. are located on opposite sides of each other with the groove immediately adjacent to the
The second thermal bridge blocking member is a curtain wall including a fourth coupling protrusion that is inserted into the fourth coupling groove of each of the first gaskets on the one side and is spaced apart from the third coupling protrusion along the first direction.



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