KR102396158B1 - Vacuum panel, building material and door haing this - Google Patents

Abstract

It is an object of the present invention to provide a vacuum panel with improved thermal insulation performance and sound insulation performance. an enclosure 110 forming a vacuum space 270; a vacuum exhaust port 115 formed to pass through the vacuum space 270 of the housing 110 to the outside; A coupling means 120 for coupling the first member 100 and the second member 105 to each other may be included.

Description

Vacuum panel, building material and door equipped therewith

The present invention relates to a vacuum panel, and more particularly, to a vacuum panel having excellent thermal insulation and soundproofing performance by forming a vacuum in a vacuum space, a building material and a door having the same.

Patent Document 001 relates to a high-performance vacuum insulation panel with improved heat blocking and wind pressure resistance, and more specifically, by configuring a vacuum insulation material and an H-shaped mold therebetween, it is possible to minimize the use of adhesives and binders as well as vacuum It is possible to improve the heat exchange characteristics at the joint between the insulation materials and the vacuum insulation materials, and to form a packing configured to cover the entire exterior of the H-shaped mold and the vacuum insulation material to improve the manufacturing quality and heat blocking and wind pressure resistance It provides a technology for a high-performance vacuum insulation panel with improved performance.

Patent Document 002 relates to a vacuum insulation panel and a getter compound suitable therefor. The vacuum insulation panel is a metal container filled with a getter compound composed of a moisture absorbent and a gas absorbent individually or mixed, and glass fiber, rice straw, barley straw, wood flour, etc. Provided is a technology for manufacturing inner core materials applied individually or in combination, wrapped together in an aluminum-coated polymer material for vacuum packaging, and vacuum-sealed.

Patent Document 003 relates to a vacuum panel defect evaluation device, and more specifically, it is possible to effectively determine whether the vacuum panel is defective by measuring the degree of swelling of one side of the defective vacuum panel using a chamber, a laser unit, and a control unit. It provides a technology related to a vacuum level defect evaluation device of a vacuum panel that can be used.

Patent Document 004 relates to a building insulation material having a built-in vacuum insulation panel and a building using the same, the building insulation material comprising: a built-in groove forming body made of a material having elasticity and having a panel built-in groove formed on the inside of the edge; The vacuum insulation panel positioned in the panel embedded groove of the built-in groove forming body, and the vacuum insulation panel coupled to the panel built-in groove of the built-in groove forming body prevents the vacuum insulation panel from being exposed to the outside and is made of a material that absorbs shock It is configured to include a built-in groove blocker for absorbing the impact applied in the direction of the insulation panel, and this building insulation material is a vacuum insulation panel by the built-in groove forming body made of a material having elasticity to absorb the impact from the outside and the built-in groove blocker. In this enclosed form, the vacuum insulation panel is protected from impact from the outside, and heat loss through the vacuum insulation panel and the vacuum insulation panel is prevented, so damage to the vacuum insulation panel is minimized during or after construction for insulation. It provides a technology that ensures excellent thermal insulation performance.

KR 10-2019-0083138 A (published on July 11, 2019) KR 10-1386938 B1 (registration number April 14, 2014) KR 10-1139315 B1 (Registration date April 17, 2012) KR 10-1243695 B1 (Registration date Mar. 08, 2013)

It is an object of the present invention to provide a vacuum panel with improved thermal insulation performance and sound insulation performance, a building material and a door having such a vacuum panel.

The vacuum panel 10 of the present invention includes a housing 110 in which the first member 100 and the second member 105 are coupled to each other to form a vacuum space 270 on the inside; a vacuum exhaust port 115 formed on one side of the housing 110 and communicating to the outside in the vacuum space 270; A coupling means 120 for coupling the first member 100 and the second member 105 to each other may be included.

In the vacuum panel 10 of the present invention, the first member 100, a first flat member 125; a first side member 130 formed in a thickness direction from an edge of the first planar member 125; A first flange 135 extending outwardly from the outer surface of the first side member 130 may be included.

The vacuum panel 10 of the present invention may include a support portion 170 disposed in the vacuum space 270 and preventing deformation of the housing 110 by vacuum pressure.

The vacuum panel 10 of the present invention may include a valve means 200 coupled to the housing 110 to open and close the vacuum exhaust port 115 .

The vacuum panel 10 of the present invention may include a vacuum suction tube 210 connected to the vacuum exhaust port 115 and extending to the outside of the housing 110 .

The vacuum panel 10 of the present invention, the housing 110 may include a coating layer 240 formed on the outer surface or the inner surface.

The building material 101 of the present invention, the vacuum panel 10; Concrete 245 formed on the outside of the housing 110 to a set thickness may be included.

The door 285 of the present invention, the vacuum panel 10; a door panel 265 in which the vacuum panel 10 is disposed; A heat insulating material 260 interposed between the vacuum panel 10 and the door panel 265 may be included.

In the present invention, it is possible to provide a vacuum panel excellent in sound insulation and heat insulation effect by forming a vacuum in the vacuum space through the vacuum exhaust port formed in the housing, and through the vacuum space.

In the present invention, it is possible to effectively prevent the deformation of the housing during vacuum formation by configuring the support inside the vacuum panel.

In the present invention, a check valve is configured on the vacuum exhaust port side of the vacuum panel, and this check valve can automatically and quickly block the exhaust port after vacuum is formed.

In the present invention, a vacuum state can be stably maintained by connecting a vacuum suction pipe to the vacuum exhaust port, evacuating the inside through the suction pipe, and then pressing and closing it.

In the present invention, the vacuum level can be stably maintained by coating the entire vacuum panel with a metal or rubber material.

In the present invention, concrete of a set thickness is formed on the outside of the vacuum panel, and a heat insulating material is interposed therebetween, so that it can be utilized as a heat insulating building material.

In the present invention, the vacuum panel is configured inside the door panel, and the heat insulating material is interposed between the vacuum panel and the door panel to improve the insulation and sound insulation performance.

The above-mentioned effects according to the embodiments of the present invention are not limited to the described content, and further include all the effects predictable from the specification and drawings.

1 is a cross-sectional view of a building to which a vacuum panel according to the present invention is applied;
2 is an exploded side view of a vacuum panel according to the present invention;
3 and 4 are partial cross-sectional views of a vacuum panel according to the present invention;
5 is an internal side view and a perspective view of a vacuum panel according to the present invention;
6 is a front view of a vacuum panel according to the present invention;
7 and 8 are partial cross-sectional views of a vacuum panel according to the present invention;
9 is a side view of a vacuum panel according to the present invention;
10 is a side view and a partial detailed cross-sectional view of a vacuum panel according to the present invention;
11 is a perspective view and a cross-sectional view of a building material according to the present invention;
12 is a perspective view and a cross-sectional view of a door according to the present invention.

Hereinafter, the most preferred embodiment of the present invention will be described in detail in order to explain in detail enough that a person of ordinary skill in the art to which the present invention pertains can easily carry out the present invention.

Reference numbers provided in the above examples are not limited to the numbers provided, and may be applied to other examples. An equivalent object corresponds to an object exhibiting the same purpose and effect as the configuration presented in this embodiment.

[Embodiment 1-1] The present invention relates to a vacuum panel 10, wherein the first member 100 and the second member 105 are coupled to each other to form a vacuum space 270 therein. ; a vacuum exhaust port 115 formed on one side of the housing 110 and communicating to the outside in the vacuum space 270; It may include a; coupling means 120 for coupling the first member 100 and the second member 105 to each other.

Due to the strengthening of domestic insulation standards, there was a problem that the workability deteriorated as the thickness and weight of the insulation material increased. To solve this problem, a vacuum insulation material with a thickness of 12 to 30 mm can be used. The vacuum insulation material prevents radiation and convection of heat, so the thermal insulation efficiency is good, and the workability is good as it is light in weight.

In the present invention (refer to FIGS. 1 and 2), a vacuum space is formed inside the housing, and a vacuum exhaust port for forming a vacuum is formed in the housing. In addition, the housing is formed by combining two first and second members, a coupling means for coupling them may be configured.

[Embodiment 1-2] The present invention relates to a vacuum panel. In Embodiment 1-1, the first member 100 and the second member 105 may be made of a plastic material.

[Embodiment 1-3] The present invention relates to a vacuum panel. In Embodiment 1-1, the first member 100 and the second member 105 may have a box shape in a state in which they are coupled to each other. there is.

[Embodiment 1-4] The present invention relates to a vacuum panel. In Embodiment 1-1, the coupling means 120 may include at least one of bolts/screws, clamps, and fusion bonding.

[Example 1-5] The present invention relates to a vacuum panel. In Example 1-1, the housing 110 may have a rectangular parallelepiped shape.

In the present invention (refer to FIGS. 1 and 2), the vacuum panel has a plate shape having a set thickness, and has an overall rectangular parallelepiped structure. In addition, the vacuum panel may be made of a plastic material. The coupling means for coupling the first member and the second member may include one selected from a bolt and a screw, a clamp, and a fusion bonding, but is not limited thereto.

[Embodiment 2-1] The present invention relates to a vacuum panel. In Embodiment 1-1, the first member 100 includes a first planar member 125; a first side member 130 formed in a thickness direction from an edge of the first planar member 125; A first flange 135 extending outwardly from the outer surface of the first side member 130; may include.

[Embodiment 2-2] The present invention relates to a vacuum panel. In Embodiment 2-1, the second member 105 includes a second planar member 140 corresponding to the first planar member 125. ); a second side member 145 formed from the edge of the second planar member 140 in the thickness direction and corresponding to the first side member 130; A second flange 150 extending outward from the outer surface of the second side member 145 and corresponding to the first flange 135 may be included.

In the present invention (refer to FIGS. 3 and 4), the first and second members have a bowl shape, and the first and second flanges formed on the edges are surface-coupled to form a vacuum space inside, and the vacuum exhaust port includes the first, It is preferably formed on one of the two members.

As shown, the vacuum panel is composed of a first member and a second member, the first member is composed of a first planar member, a first side member, and a first flange, and the second member is a second planar member; It is composed of a second side member and a second flange to form a rectangular parallelepiped.

Overall, the first and second planar members are arranged at a set interval, the first and second side members are integrally formed on these edges, respectively, and the first and second flanges formed on the first and second side members are surface-coupled to each other and they can be joined with bolts/nuts, clamps, or fusion bonding.

[Embodiment 2-3] The present invention relates to a vacuum panel. In Embodiment 2-2, the outer surface of the first side member 130 and the inner surface of the second side member 145 overlap each other. A portion 275 may be included.

In the present invention (refer to FIGS. 3 and 4), in the vacuum panel, a first side member is formed at the edge of the first planar member of the first member in the width direction, and the first flange is lateral to the middle part of the first side member The set distance is extended by Here, the first side member has a structure in which a set distance is further extended toward the lower surface of the first flange.

Similarly, the outer surface of the first side member and the inner surface of the second side member may have overlapping portions that are surface-coupled to each other, and the first and second flanges may be surface-coupled to each other. This overlapping portion and the surface coupling structure are configured, sealing properties and robustness can be improved.

[Embodiment 2-4] The present invention relates to a vacuum panel. In Embodiment 2-3, the outer surface of the first side member 130 and the inner surface of the second side member 145 have inclined surfaces corresponding to each other. 280 may be formed.

[Embodiment 2-5] The present invention relates to a vacuum panel. In Embodiment 2-4, based on the inner surface of the first side member 130, the outer surface of the first side member 130 has a thickness It may be formed to be inclined so that it becomes thin.

In the present invention (refer to FIG. 4), inclined surfaces are respectively formed on the inner surface and the outer surface to which the first side member and the second side member are surface-coupled. The inclined surface may be formed in a structure in which the thickness of the first side member becomes thinner, and in the process of the first and second side members being coupled to each other, the inclined surface slides to improve the sealing structure, and the coupling structure may be strengthened .

[Embodiment 2-6] The present invention relates to a vacuum panel. In Embodiment 2-2, at least one sealing 160 is provided between the first side member 130 and the second side member 145. can be formed.

[Embodiment 2-7] The present invention relates to a vacuum panel. In Embodiment 2-2, at least one of a gasket and a seal is interposed between the first flange 135 and the second flange 150. can

In the present invention (refer to FIGS. 3 and 4), a seal may be formed between the first side member and the second side member on which the inclined surface is formed, and this seal may be formed in the form of an O-ring, and may be formed in the form of a gasket. may be In addition, a gasket or a seal may be formed in a portion where the first and second flanges are surface-coupled, and the first and second flanges may be fused to each other to form a sealing structure.

[Embodiment 2-8] The present invention relates to a vacuum panel. In Embodiment 2-2, the first side member 130 and the first flange 135 are It is continuously formed along the edge, and the second side member 145 and the second flange 150 may be continuously formed along the edge of the second planar member.

In the present invention (refer to FIGS. 2, 3, and 4), the first member and the second member have a rectangular bowl shape, and the first and second side members are continuously arranged along the edges of the first and second planar members. The first and second flanges formed along the edges of the first and second side members are respectively surface-coupled to each other to form a vacuum space.

[Example 3-1] The present invention relates to a vacuum panel, and in Example 1-1,

It is disposed in the vacuum space 270, the support portion 170 for preventing the deformation of the housing 110 by the vacuum pressure; may include.

[Embodiment 3-2] The present invention relates to a vacuum panel. In Embodiment 3-1, the support portion 170 includes a first supporter 175 disposed on the inner surface of the first member 100; A second support 180 disposed on the inner surface of the second member 105 may be included.

In the present invention (refer to FIG. 5), the support portion is disposed in the vacuum space of the housing, to prevent physical deformation of the housing during vacuum formation, and to improve the overall rigidity of the vacuum panel.

First, the first support of the support may be fixed to the inner surface of the first member, the second support may be fixed to the inner surface of the second member, and the first and second supports are disposed with a gap or disposed in contact with each other. can be

[Embodiment 3-3] The present invention relates to a vacuum panel. In Embodiment 3-2, the first supports 175 are arranged at intervals set in the first direction, and the second supports 180 may be arranged at intervals set in the second direction.

[Embodiment 3-4] The present invention relates to a vacuum panel. In Embodiment 3-2, the first support 175 and the second support 180 may be alternately disposed.

[Example 3-5] The present invention relates to a vacuum panel. In Example 3-5, a first coupling groove 185 is formed in the first support 175, and the second support 180 is formed. A second coupling groove 190 is formed in the first and second coupling grooves 185 and 190 are coupled to each other, so that the first support 175 and the second support 180 can be coupled to each other in a lattice form. .

In the present invention (see FIG. 5 ), the first support has a plate shape and is arranged side by side at a set interval, and the second support also has a plate shape and is arranged side by side at a set interval. The first and second supports may be vertically staggered from each other.

In addition, a first coupling groove is formed in the first support, a second coupling groove is formed in the second support, and the first and second defective grooves are inserted and coupled in a state where the first and second supports are staggered to be more firmly can be configured.

[Embodiment 3-6] The present invention relates to a vacuum panel. In Embodiment 3-2, a flow hole 195 is formed at a set position of the first support 175 or the second support 180 . can be

In the present invention (refer to FIG. 5), flow holes are formed in the first and second supports. These flow holes, when exhausting the internal air to the outside through the vacuum exhaust port, quickly exhaust the air in the internal grid space to increase the degree of vacuum. can be improved

[Embodiment 4-1] The present invention relates to a vacuum panel, and in Embodiment 1-1, a valve means 200 coupled to the housing 110 to open and close the vacuum exhaust port 115; includes; can do.

In the present invention (see Fig. 6), in order to discharge the internal air of the enclosure to the outside, a vacuum exhaust port is formed, and a valve means for opening and closing the vacuum exhaust port is configured. This valve means discharges the internal air to the outside and can perform the function of an opening/closing mechanism for maintaining a vacuum.

[Embodiment 4-2] The present invention relates to a vacuum panel. In Embodiment 4-1, the valve means 200 may include a check valve 201 .

[Embodiment 4-3] The present invention relates to a vacuum panel. In Embodiment 4-1, the valve means 200 may include an on-off valve 202 .

[Embodiment 4-4] The present invention relates to a vacuum panel. In Embodiment 4-2, the valve means 200 may be built into the valve space 205 formed by the housing 110. .

In the present invention (see FIG. 6), the valve means may include at least one of a check valve and an on/off valve.

Here, the check valve prevents the outside air from being sucked into the inside while allowing the inside air to be discharged to the outside, and the opening/closing valve is blocked by the user after the vacuum is formed to effectively maintain the vacuum state. In the present invention, a valve space in which a check valve or an on/off valve is built-in is formed on the edge side of the housing, which prevents the valve means from protruding to the outside.

[Example 5-1] The present invention relates to a vacuum panel. In Example 1-1, a vacuum suction pipe 210 connected to the vacuum exhaust port 115 and extending to the outside of the housing 110; may include

[Embodiment 5-2] The present invention relates to a vacuum panel. In Embodiment 5-1, the vacuum suction tube 210 may include a closing part 215 closed by pressing or fusion.

[Embodiment 5-3] The present invention relates to a vacuum panel. In Embodiment 5-2, the closing parts 215 may be formed with two or more set intervals.

In the present invention (see FIG. 7), a vacuum suction tube for forming a vacuum is formed in the housing, and the user exhausts the air of the vacuum space through the vacuum suction tube to the outside, thereby forming a vacuum inside.

In the present invention, the vacuum suction tube is formed of a flexible rubber material, and after vacuum is formed, the vacuum suction tube may be compressed or fused to form a closed part, and such a closed part is composed of two or more at a set interval to effectively maintain the degree of vacuum. there is.

[Embodiment 5-4] The present invention relates to a vacuum panel. In Embodiment 5-1, a receiving groove 220 may be formed in the housing 110 to accommodate the vacuum suction tube 210 .

[Example 5-5] The present invention relates to a vacuum panel. In Example 5-4, the vacuum exhaust port 115 is formed on an inner surface of the receiving groove 220, and the vacuum suction pipe 210 may be disposed inside the receiving groove 220 .

[Embodiment 5-6] The present invention relates to a vacuum panel. In Embodiment 5-6, a separation preventing protrusion 225 may be formed in the receiving groove 220.

In the present invention (refer to FIGS. 8 and 9), a receiving groove is formed on the outer surface of the housing, and a vacuum suction pipe is disposed in the receiving groove. One end of the vacuum suction tube communicates with the interior of the housing through the inner surface of the receiving groove, and the other end is disposed in the receiving groove, so that the vacuum suction tube does not protrude to the outside.

In addition, a separation prevention projection is formed along the inner edge of the receiving groove, and the separation prevention projection prevents the vacuum suction tube from being separated to the outside.

[Example 5-7] The present invention relates to a vacuum panel, and in Examples 5-6, the filling member 230 for filling the accommodation groove 220 may be included.

[Example 5-8] The present invention relates to a vacuum panel. In Examples 5-6, the filling member 230 may include at least one of urethane, rubber, and an adhesive.

[Example 5-9] The present invention relates to a vacuum panel, and in Examples 5-6, a cover member 235 for covering the receiving groove 220 may be included.

[Example 5-10] The present invention relates to a vacuum panel. In Examples 5-6, the cover member 235 may have a film shape.

In the present invention (refer to FIGS. 8 and 9), the air inside the enclosure is discharged to the outside through the vacuum suction pipe, a closing part is formed in this vacuum suction pipe, the vacuum suction pipe is arranged inside the receiving groove, and the inside of the receiving groove is filled The member is filled. Such a filling member may improve the sealing effect and also improve the heat insulation effect. In addition, the receiving groove is blocked by a cover member, the cover member may have a film shape, and may have a tape structure as an embodiment.

[Embodiment 6-1] The present invention relates to a vacuum panel. In Embodiment 1-1, the housing 110 may include a coating layer 240 formed on an outer surface or an inner surface.

[Example 6-2] The present invention relates to a vacuum panel. In Example 6-1, the coating layer 240 may be made of a metal material.

[Example 6-3] The present invention relates to a vacuum panel. In Example 6-1, the coating layer 240 may include a urethane material.

In the present invention (see FIGS. 8 and 9), after the inside of the enclosure is formed in a vacuum state, a separate coating layer may be formed on the outside of the enclosure. Such a coating layer may be formed of a metal material or coated with a urethane material. In addition, such a coating layer can improve the sealing performance and maintain a beautiful external shape.

[Embodiment 7-1] The present invention relates to a building material 101 having a vacuum panel, the vacuum panel 10 according to the embodiment 1-1; Concrete 245 formed on the outside of the vacuum panel 10 to a set thickness; may include.

[Embodiment 7-2] The present invention relates to a building material having a vacuum panel. In Embodiment 7-1, the concrete 245 has a coupling groove 505 formed on one side and a coupling groove 505 formed on the other side, and the It may include a coupling protrusion 510 formed to correspond to the coupling groove 505 .

In the present invention (see FIG. 11), after forming the inside of the enclosure in a vacuum state, and coating the outside of the enclosure with urethane, concrete of a set thickness may be further formed on the outside. After the concrete is formed in the housing, it can be used as a building material like bricks.

In addition, coupling grooves and coupling protrusions are formed on one side of the concrete, and the shape and skeleton of the building can be completed by coupling them to each other.

[Embodiment 7-3] The present invention relates to a building material having a vacuum panel, and in Embodiment 7-1, it includes a heat insulating material 260 disposed between the housing 110 and the concrete 245 can do.

[Embodiment 7-4] The present invention relates to a building material having a vacuum panel. In Embodiment 7-3, the heat insulating material 260 may include at least one of glass wool, mineral wool, and PE foam. can

In the present invention (see FIG. 11 ), a heat insulating material may be further formed between the enclosure and the concrete, and such a heat insulating material may improve the insulation performance of the overall building material and reduce the impact that the insulation material itself exerts on the vacuum panel. There is no limitation on the material used as the insulating material, but glass wool, mineral wool, or pe foam may be used, and it is preferable to have a set thermal insulation performance and flame retardant performance.

[Embodiment 8-1] The present invention relates to a door 285 made of a vacuum panel, comprising: a vacuum panel 10 according to Embodiment 1-1; a door panel 265 in which the vacuum panel 10 is disposed; and a heat insulating material 260 interposed between the vacuum panel 10 and the door panel 265 .

In the present invention (see Fig. 12), the outside of the door is composed of a door panel, and a vacuum panel is disposed inside the door panel. In addition, a heat insulating material may be disposed between the vacuum panel and the door panel to improve heat insulation performance and sound insulation performance.

[Embodiment 8-2] The present invention relates to a vacuum panel. In Embodiment 8-1, the door panel 265 may be made of a metal material.

[Embodiment 8-3] The present invention relates to a vacuum panel. In Embodiment 8-1, the heat insulating material 260 may include at least one of glass wool, mineral wool, and PE phone.

[Embodiment 8-4] The present invention relates to a vacuum panel. In Embodiment 8-1, the vacuum panel 10 may be combined with each other to constitute a plurality of vacuum panels.

In the present invention (see FIG. 12 ), the door panel is formed of a metal plate having a flame retardant performance, and a heat insulating material is interposed between the vacuum panel and the door panel. It is possible to prevent the vacuum panel from shaking inside the door panel, to prevent the vacuum panel from being damaged, and to prevent the noise generated by the shaking of the vacuum panel.

10: vacuum panel 101: building material
100: first member 105: second member
110: enclosure 115: vacuum exhaust port
120: coupling means 125: first planar member
130: first side member 135: first flange
140: second planar member 145: second side member
150: second flange 275: overlapping portion
160: sealing 165: gasket
170: support 175: first support
180: second support 185: first coupling groove
190: second coupling groove 195: flow hole
200: valve means 205: valve space
210: vacuum suction pipe 215: closed part
220: receiving groove 225: escape prevention projection
230: filling member 235: cover member
240: coating layer 245: concrete
260: insulation 265: door panel
270: vacuum space 280: inclined surface
285: door 505: coupling groove
510: bonding protrusion

Claims (8)

In the vacuum panel (10),
A housing 110 in which the first member 100 and the second member 105 are coupled to each other to form a vacuum space 270 therein;
a vacuum exhaust port 115 formed on one side of the housing 110 and communicating to the outside in the vacuum space 270;
coupling means 120 for coupling the first member 100 and the second member 105 to each other;
a vacuum suction pipe 210 connected to the vacuum exhaust port 115 and extending to the outside of the housing 110; including,
The first member 100 includes a first planar member 125;
a first side member 130 formed in a thickness direction from an edge of the first planar member 125;
Includes; a first flange 135 extending outwardly from the outer surface of the first side member 130;
The second member 105 includes a second planar member 150 corresponding to the first planar member 125;
a second side member (145) formed from the edge of the second planar member (140) in the thickness direction and corresponding to the first side member (130);
and a second flange 150 extending outwardly from the outer surface of the second side member 145 and corresponding to the first flange 135;
The plurality of side members,
an overlapping portion 275 in which an outer surface of the first side member 130 and an inner surface of the second side member 145 overlap each other;
and inclined surfaces 280 corresponding to the outer surface of the first side member 130 and the inner surface of the second side member 145.
The outer surface of the first side member 130,
It is formed to be inclined so that the thickness is thin based on the inner surface of the first side member 130,
The housing 110 is
Includes; receiving groove 220 for accommodating the vacuum suction tube 210 on the inside;
The vacuum exhaust port 115,
It is formed on the inner surface of the receiving groove 220,
A vacuum panel including; a plurality of separation prevention protrusions 225 protruding at a predetermined height inside the receiving groove 220 .
delete According to claim 1,
A vacuum panel comprising a; is disposed in the vacuum space 270, the support portion 170 for preventing the deformation of the housing 110 by the vacuum pressure.
According to claim 1,
A vacuum panel comprising a; valve means (200) fastened to the housing (110) to open and close the vacuum exhaust port (115).
delete According to claim 1,
The housing 110 is a vacuum panel comprising a; a coating layer 240 formed on the outer surface or the inner surface.
In the building material 101,
A vacuum panel (10) according to claim 1;
Concrete (245) formed to a set thickness on the outside of the vacuum panel (10); Construction material comprising a.
In the door (285),
A vacuum panel (10) according to claim 1;
a door panel 265 in which the vacuum panel 10 is disposed;
A door comprising a; a heat insulating material (260) interposed between the vacuum panel (10) and the door panel (265).

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