KR101789089B1 - Vacuum Insulation Panel - Google Patents

Abstract

According to an aspect of the present invention, there is provided a vacuum thermal insulation panel comprising: a first reinforcing plate of a plate-like shape and a lattice shape made of a metal or a non-ferrous metal; a plate-like shape of a metal or a non-ferrous metal material spaced apart from the first reinforcing plate by a predetermined distance; A plurality of spacers provided between the first reinforcing plate and the second reinforcing plate to keep the first reinforcing plate and the second reinforcing plate at regular intervals; And a discharge protrusion protruding from one surface of the vacuum cover and discharging air inside the vacuum cover by a vacuum pump, wherein the vacuum cover covers the outer surface to maintain a space between the plate and the second reinforcing plate in a vacuum state, .

Description

[0001] Vacuum Insulation Panel [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vacuum insulation panel, and more particularly, to a vacuum insulation panel capable of preventing a change in external shape of a panel due to air discharge and sealing the interior thereof in a vacuum state by a simple method.

Recognizing that minimizing environmental costs is a core competitiveness of companies and countries, energy efficient design is essential for all buildings. Furthermore, intense technological competition is taking place globally to preempt technologies that can realize zero-energy buildings that do not depend on external energy. Today, after recommending energy conservation, such as certification of eco-friendly buildings, energy efficiency rating, insulation performance standards for window and wall are strengthened.

In addition, considering the fact that the introduction of the total energy consumption system of buildings is not only implemented yet, but also the plan is to make zero energy buildings mandatory, the environmentally friendly and green industry is a high value-added industry, It is recognized that technologies must be secured.

It is known that the prevention of energy loss of buildings can realize more than 50% of total energy saving through insulation of building envelope and insulation of windows. Building envelope insulation and window insulation are considered the most important in energy conservation of buildings.

Insulation of buildings is essential for building energy conservation, so insulation is used to insulate buildings. Conventional materials used for building insulation include foamed polyurethane foam, styrofoam, glass wool, etc. However, vacuum insulation panels (VIPs) and aerogels, which are more excellent in thermal insulation performance, have been proposed .

The insulation performance of vacuum insulation panels filled with core materials such as glass fiber is estimated to be more than 16 times that of glass fiber and more than ten times that of foam polyurethane foam and styrofoam.

The structure of the vacuum insulation panel has a structure in which a thin metal plate or acid-resistant plastic is used as a shielding material for maintaining the degree of vacuum in the interior, and a core material for holding the panel shape is filled to maintain the internal vacuum. As the core material for maintaining the panel shape, organic or inorganic powders, fibers, or polymer resin molded bodies are used. Specifically, core materials such as glass wool and fumed silica are used. As time passes, there is a problem that the vacuum of the vacuum insulating panel is broken due to the pressure rise due to the gas generated from the core material itself .

In addition, after the evacuation operation, the air is sealed so as not to be re-introduced into the air inlet. The air inlet is formed of solder glass and is sealed while being melted at a high temperature.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a vacuum insulating panel in which the external shape is not deformed even if air inside the panel is discharged.

Still another object of the present invention is to provide a vacuum insulating panel which can simplify the manufacturing process by sealing air while discharging it.

According to an aspect of the present invention, there is provided a vacuum thermal insulation panel comprising: a first reinforcing plate having a plate shape and a lattice shape made of a metal or a non-metal material; Or a lattice-shaped second reinforcing plate made of a non-ferrous metal material, and a plurality of second reinforcing plates provided between the first reinforcing plate and the second reinforcing plate to keep the first reinforcing plate and the second reinforcing plate at a predetermined interval A vacuum cover covering the outer surface of the vacuum cleaner in order to maintain a space between the first gusset plate and the second gusset in a vacuum state; And a discharge protrusion for discharging the discharge protrusion.

The first reinforcing plate and the second reinforcing plate, which are formed in a plate shape, can be highly reflective treated by attaching a silver nano coating or a silver foil on one surface facing each other to enhance the radiation insulation effect of the vacuum insulation panel.

The vacuum cover includes a first cover formed to have a larger area than the first reinforcing plate and surrounding the first reinforcing plate, and a second cover accommodating the second reinforcing plate inside and being joined to the first cover And at least one of soldering, welding, and an inorganic binder may be used to bond the first cover and the second cover to each other.

Wherein the second cover includes a cover portion coupled to an outer surface of the second reinforcing plate, a side portion extending from the side surface of the cover portion toward the first cover side, As shown in Fig.

The plurality of vacuum heat insulating panels may be provided with a heat insulating material in order to increase the heat insulating performance at the joining portions where the respective bonding portions overlap each other so that the bonding portions overlap each other.

The vacuum cover includes a first reinforcing plate which is spaced apart by a predetermined distance from the spacer, a receiving cover which is opened at an upper portion to receive the second reinforcing plate inward, And at least one of soldering, welding, and an inorganic binder may be used to adhere the receptacle cover and the top plate to each other.

The vacuum cover may be highly reflective-treated by attaching a silver coating or a silver foil to the inner side surface of the first reinforcing plate and the second reinforcing plate which are formed in a lattice form to enhance the radiating heat insulating effect of the vacuum insulating panel.

When the air inside the vacuum cover is discharged by the vacuum pump, the discharge protrusion may compress or weld the outer surface of the discharge protrusion by utilizing a compressor.

According to the vacuum adiabatic panel of the present invention, since the first reinforcing plate and the second reinforcing plate are spaced apart from each other by the spacers within the vacuum cover, the appearance of the vacuum cover does not change even if the air of the vacuum cover is discharged.

In addition, the vacuum pump can be used to simplify the manufacturing process by discharging and sealing the air inside the vacuum cover.

1 is a perspective view illustrating a vacuum adiabatic panel according to an embodiment of the present invention;
FIG. 2 is a sectional view of the vacuum insulating panel shown in FIG. 1. FIG.
3 is an exploded perspective view showing the vacuum adiabatic panel shown in Fig.
4 is a cross-sectional view showing a state in which a vacuum insulating panel according to an embodiment of the present invention is sealed.
FIG. 5 is a cross-sectional view illustrating a state in which a plurality of vacuum insulating panels are coupled to each other according to an embodiment of the present invention. FIG.
6 is a sectional view showing a vacuum adiabatic panel according to another embodiment of the present invention.
7 is an exploded perspective view showing the vacuum insulation panel shown in Fig.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, it is needless to say that the present invention is not limited to these embodiments and can be modified into various forms.

In the drawings, the same reference numerals are used for the same or similar parts throughout the specification. In the drawings, the thickness, the width, and the like are enlarged or reduced in order to make the description more clear, and the thickness, width, etc. of the present invention are not limited to those shown in the drawings.

Hereinafter, a vacuum insulated panel according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. Hereinafter, a method of manufacturing a vacuum insulating panel will be described in detail.

1 is a perspective view showing a vacuum adiabatic panel according to an embodiment of the present invention, FIG. 2 is a sectional view showing the vacuum adiabatic panel shown in FIG. 1, and FIG. 3 is an exploded perspective view showing a vacuum adiabatic panel shown in FIG. to be.

1 to 3, the vacuum insulating panel 10 according to an embodiment of the present invention includes a first reinforcing plate 100 of a plate shape and a lattice shape made of a metal or a non-metal material, A second reinforcing plate 200 having a plate shape and a lattice shape made of a metal or a non-ferrous metal material spaced apart from the plate 100 by a predetermined distance and a second reinforcing plate 200 formed between the first reinforcing plate 100 and the second reinforcing plate 200 A plurality of spacers 300 installed on the first reinforcing plate 100 and the second reinforcing plate 200 to maintain a predetermined gap between the first reinforcing plate 100 and the second reinforcing plate 200, A vacuum cover 400 which surrounds the outer surface of the vacuum cover 400 in order to maintain a space between the vacuum cover 400 and the vacuum cover 400; And a discharge protrusion 500 for discharging the discharge protrusion 500.

Since the first reinforcing plate 100 and the second reinforcing plate 200 are made of a metal material and a non-ferrous metal and are accommodated in the vacuum cover 400, when the air inside the vacuum cover 400 is discharged by the vacuum pump, It is possible to prevent the outer shape of the cover 400 from being deformed.

The first gusset plate 100 and the second gusset plate 200 are formed in a plate shape and a lattice shape, and a vacuum layer 110 can be formed on the inner side while maintaining a predetermined gap.

When the first reinforcing plate 100 and the second reinforcing plate 200 are formed in a plate shape, in order to enhance the radiant heat insulating effect of the vacuum insulating panel 10, the inner side surfaces of the vacuum cover 400 and the first reinforcing plate 100 and the second reinforcing plate 200 may be attached to a surface facing each other with a reflection material such as a silver nano coating or a silver foil to perform a high reflection treatment.

In order to form the vacuum layer 110, a plurality of spacers 300 may be provided between the first reinforcing plate 100 and the second reinforcing plate 200. The spacer 300 may be formed in various shapes such as a circular shape and a square shape so that the first reinforcing plate 100 and the second reinforcing plate 200 can be spaced apart from each other. 2 gussets 200 can be formed in a vacuum state.

Although not shown, the plurality of spacers 300 may be formed in a long side surface of the first reinforcing plate 100 and the second reinforcing plate 200 to form the vacuum layer 110.

The spacers 300 may be provided on the first reinforcing plate 100 and the second reinforcing plate 200 so as to stack the second reinforcing plate 200 after the spacers 300 are installed at a predetermined interval on the first reinforcing plate 100, The spacer 300 may be formed of a metal material or a non-ferrous metal material and may be installed between the first and second reinforcing plates 100 and 200 by using soldering, welding, or an inorganic binder.

The vacuum cover 400 is provided with a spacer 300 between the first and second reinforcing plates 100 and 200 so that the first and second reinforcing plates 100 and 200 bonded to each other are received therein. It can be installed so as to surround the outer side.

The vacuum cover 400 includes a first cover 410 formed to have a larger area than the first reinforcing plate 100 and surrounding the first reinforcing plate 100 and a second cover 410 surrounding the second reinforcing plate 200 And a second cover 420 bonded to the first cover 410.

The first cover 410 may be provided on the outer side of the first reinforcing plate 100 to surround the first reinforcing plate 100 and protrude from the outer surface of the first cover 410.

At this time, the discharge protrusion 500 may be provided with the discharge hole 120 in the first reinforcing plate 100 at the same position as the position protruding from the first cover 410.

The first cover 410 is formed to have a larger area than the first reinforcing plate 100, and the first reinforcing plate 100 may be provided at the center of the first cover 410.

The second cover 420 may be joined to the outer surface of the central part to which the first gusset 100 is bonded to form the inside of the first cover 410 and the second cover 420 in a vacuum state.

The second cover 420 includes a cover portion 421 coupled to the outer surface of the second reinforcing plate 200 and a side surface portion 422 extending from the side surface of the cover portion 421 toward the first cover 410 And a bonding portion 423 extending from the side surface portion 422 to the outer surface to be adhered to the first cover 410.

The cover 421 is coupled to the outside of the second reinforcing plate 200 to prevent the outer shape from being deformed by the second reinforcing plate 200. The first cover 410 ) Side surface portion 422 may be coupled.

The first reinforcing plate 100 and the second reinforcing plate 200 can be accommodated in the cover portion 421 and the side surface portion 422 and the first reinforcing plate 100 and the second reinforcing plate 200 can be accommodated. The vacuum layer 110 may be formed by a spacer 300 maintaining a predetermined gap.

The adhesive portion 423 may extend outward from the end of the side surface portion 422 and one side of the adhesive portion 423 may be adhered to the first cover 410. The adhesive portion 423 is bonded to the first cover 410 using at least one of soldering, welding, and an inorganic binder to prevent air from entering the vacuum insulating panel 10 from the outside.

When the first reinforcing plate 100 and the second reinforcing plate 200 are formed in a lattice form, the first reinforcing plate 100 And the inner side surface of the vacuum cover 400 contacting with the second gusset 200 and surrounding the outside can be subjected to a high reflection treatment by attaching a reflective material such as a silver coating or a silver foil.

Since the inner side surface of the vacuum cover 400 and the surfaces of the first reinforcing plate 100 and the second reinforcing plate 200 facing each other are highly reflective processed, the function of the radiating and insulating member can be improved and the heat insulating effect can be enhanced.

Referring to FIG. 4, the discharge protrusion 500 to be described next protrudes outward from one surface of the first cover 410, and the air inside the vacuum cover 400 can be discharged by the vacuum pump 510.

At this time, the vacuum pump 510 may be formed by various pumps such as a compressor, and a hose may be connected to the discharge protrusion 500 to discharge the air inside the vacuum cover 400 to the outside.

The discharge protrusions 500 are provided inside the vacuum cover 400 by the vacuum pump 510 so that the air between the first and second reinforcing plates 100 and 200 is discharged from the first reinforcing plate 100 And is discharged from the discharge hole 120 to the outside by the vacuum pump 510 through the discharge protrusion 500 so that the inside can be formed in a vacuum state.

In order to seal the inside of the vacuum cover 400 formed in a vacuum state by the vacuum pump 510, the air inside the vacuum cover 400 is discharged by the vacuum pump 510 and the air outside the discharge cover 500 The side surface can be compressed by using the compressor 520.

For example, in general, the method of manufacturing the vacuum insulating panel 10 and the vacuum glass has a drawback in that it is manufactured in a vacuum chamber or subjected to a complicated process. The vacuum cover 510 discharges the air inside by the vacuum pump 510 and discharges the air inside the vacuum pump 510 without stopping the vacuum pump 510 when the vacuum pump 510 is in a vacuum state, Can be compressed by the compressor 520 and sealed. Therefore, air is not introduced into the vacuum cover 400, but is sealed during the discharge, so that the vacuum state can be maintained without introducing air into the vacuum cover 400.

The compressor 520 may be formed of various devices capable of compressing the discharge protrusions 500 on the outer surface, such as a press machine.

5 is a cross-sectional view illustrating a plurality of vacuum adiabatic panels coupled to each other according to an embodiment of the present invention.

5, in order to couple a plurality of vacuum thermal insulating panels 10 to each other, a plurality of vacuum thermal insulating panels 10 may be staggered to each other.

Both sides of each vacuum thermal insulation panel 10 may have a shape in which the first cover 410 and the second cover 420 are adhered to each other and protrude from both sides.

The first cover 410 protruding from both sides of each vacuum thermal insulating panel 10 and the adhesive portion 423 of the second cover 420 may be arranged to be offset from each other in order to couple the plurality of vacuum thermal insulating panels 10 to each other. have.

At this time, when the plurality of vacuum thermal insulating panels 10 are coupled to each other, heat bridging phenomenon may occur due to the joining portions, which may deteriorate the heat insulating performance, so that the heat insulating material 600 may be provided at the joining portions.

Hereinafter, a vacuum insulation panel according to another embodiment of the present invention will be denoted by the same reference numerals as those of the vacuum insulation panel according to the above-described embodiment, and a detailed description thereof will be omitted.

FIG. 6 is a cross-sectional view of a vacuum adiabatic panel according to another embodiment of the present invention, and FIG. 7 is an exploded perspective view of the vacuum adiabatic panel shown in FIG.

6 and 7, the vacuum cover according to another embodiment of the present invention includes the first reinforcing plate 100 and the second reinforcing plate 200, which are spaced apart by the spacers 300, And a top plate 440 joined to an upper portion of the cover opened to keep the vacuum cover 400 in a vacuum state can be provided .

The receiving cover 430 may be received after the first reinforcing plate 100 and the second reinforcing plate 200, which are spaced apart by the spacers 300, are combined. The receiving cover 430 is opened at the upper part and the receiving space 431 is formed at the inner side so that the first reinforcing plate 100 and the second reinforcing plate 200 are installed to be spaced apart from each other. 431).

The top plate 440 may be bonded to the receiving cover 430 to seal the vacuum cover 400 after the first and second gussets 100 and 200 are received therein.

At least one of soldering, welding, and an inorganic binder may be used to adhere the receiving cover 430 and the top plate 440 to each other.

Although the vacuum insulated panel according to one embodiment of the present invention has been described above, the spirit of the present invention is not limited to the embodiments disclosed herein. Those skilled in the art, who understands the spirit of the present invention, can readily suggest other embodiments by adding, changing, deleting, adding, or the like of components within the scope of the same idea, I would say.

100: first reinforcing plate 200: second reinforcing plate
300: spacer 400: vacuum cover
500: ejection projection

Claims (8)

A first reinforcing plate having a plate shape and a lattice shape made of a metal or a non-metal material;
A second reinforcing plate of a plate shape and a lattice shape made of a metal or a non-ferrous metal material spaced apart from the first reinforcing plate by a predetermined distance,
A plurality of spacers provided between the first reinforcing plate and the second reinforcing plate to maintain the first reinforcing plate and the second reinforcing plate at a predetermined interval,
A vacuum cover for covering an outer surface of the first reinforcing plate to maintain a space between the first reinforcing plate and the second reinforcing plate in a vacuum state,
And a discharge protrusion protruding from one surface of the vacuum cover and discharging air inside the vacuum cover by a vacuum pump,
Wherein the vacuum cover has a larger area than the first reinforcing plate and surrounds the first reinforcing plate,
And a second cover which houses the second reinforcing plate inside and is joined to the first cover,
The second cover includes a cover portion coupled to an outer surface of the second reinforcing plate,
A side surface extending from the side surface of the cover portion to the first cover surface,
And an adhesive portion extending from the side surface portion to the outer side surface and adhered to the first cover,
Each of the adhesive portions provided on the second cover adjacent to each other is staggered to be overlapped with each other,
Characterized in that a heat insulating material is provided on a joining part where each of the bonding parts are joined to improve the heat insulating performance.
The method according to claim 1,
Wherein the first reinforcing plate and the second reinforcing plate formed in a plate-like shape are highly reflective treated by attaching a silver-nano coating or a silver foil to one side of the first reinforcing plate and the second reinforcing plate facing each other for enhancing the radiant heat insulation effect of the vacuum insulation panel. panel.
delete delete delete The method according to claim 1,
The vacuum cover includes a first reinforcing plate which is spaced apart by a predetermined distance from the spacer, a receiving cover which is opened at an upper portion to receive the second reinforcing plate,
And an upper plate adhered to an upper portion of the accommodating cover opened at an upper portion thereof to maintain the vacuum cover in a vacuum state,
Wherein at least one of soldering, welding, and an inorganic binder is used to adhere the accommodating cover and the top plate to each other.
The method according to claim 1,
The vacuum cover is characterized in that the inner surface of the first reinforcing plate and the second reinforcing plate, which are formed in a lattice form to enhance the radiating and insulating effect of the vacuum adiabatic panel, are highly reflective treated by attaching a silver nano coating or a silver foil Vacuum insulation panels.
The method according to claim 1,
Wherein the discharge protrusion compresses and welds the outer surface of the discharge protrusion by using a compressor when the air inside the vacuum cover is discharged by the vacuum pump.

Images