KR101810457B1 - Insulation glass panel for refrigerator - Google Patents

Abstract

The present invention provides a vacuum insulating glass panel for a refrigerator. Wherein the vacuum insulating glass panel for a refrigerator comprises: a pair of heat insulating glasses arranged at a predetermined gap from each other by a plurality of spacers provided inside; And a sealing part which hermetically seals the opening between the pair of the heat insulating glasses so that the space between the pair of heat insulating glasses forms a vacuum space at the rim of the pair of heat insulating glasses. Accordingly, the vacuum space formed between the heat insulating glasses can be sealed in multiple by using the sealing parts made of different materials, thereby improving the vacuum degree and the heat insulating performance of the vacuum space.

Description

{INSULATION GLASS PANEL FOR REFRIGERATOR}

The present invention relates to a vacuum insulating glass panel for a refrigerator, and more particularly, to a vacuum insulating glass panel for a refrigerator, in which a vacuum space formed between insulating glass is sealed by using multiple sealing parts made of different materials, To a vacuum insulating glass panel for a refrigerator which can improve performance.

Typically, a refrigerator is a device used to freeze food stored at a low temperature for a certain period of time, and a refrigeration cycle device for generating cold air is generally installed in the device.

Therefore, since the refrigerator having the refrigeration and refrigeration functions has a temperature lower than a predetermined temperature, it is necessary to provide a heat insulation function so that the temperature inside the refrigerator is not affected by the external temperature environment.

Conventionally, a heat insulating foam is used to perform the above-mentioned heat insulating function.

Here, the refrigerator has a wall constituting the main body, and partition walls partitioning the freezing chamber and the refrigerating chamber, and the heat insulating foam is formed by foaming the inner space of the wall and the partition walls in the inner space.

Accordingly, the foamed heat insulating foam can lower the heat transfer rate at which external heat is transferred to the internal space of the refrigerator.

However, when the heat insulating foam is foamed inside the wall as described above, the foam itself, which is foamed by a change in the external environment for a long period of time, may be deformed such as shrinkage, have. As a result, the heat insulating function of the heat insulating foam itself can not be performed, thereby causing the refrigerating performance of the refrigerator to deteriorate.

In order to solve the problem of the above-mentioned heat insulating foam itself, a vacuum layer is buried in the wall of the refrigerator and effectively blocks the heat transmission, and the heat transferred from the wall of the refrigerator flows to the inner wall side It is desired to develop a heat insulating panel capable of improving the heat insulating performance by minimizing the heat transferred to the outside while being flowed, thereby improving the refrigeration performance of the refrigerator.

Further, in the case of providing a vacuum layer including a gas layer, development of a thermal insulation panel capable of preventing the gas in the gas layer from penetrating into the vacuum layer and improving the internal vacuum degree and the heat insulation performance is also demanded.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a method and a device for sealing a vacuum space formed by a heat insulating glass by using multiple sealing parts made of different materials, And to improve the heat insulation performance of the vacuum insulating glass panel for a refrigerator.

In a preferred aspect, the present invention provides a vacuum insulating glass panel for a refrigerator.

Wherein the vacuum insulating glass panel for a refrigerator comprises: a pair of heat insulating glasses arranged at a predetermined gap from each other by a plurality of spacers provided inside; And a sealing part which hermetically seals the opening between the pair of the heat insulating glasses so that the space between the pair of heat insulating glasses forms a vacuum space at the rim of the pair of heat insulating glasses.

Here, it is preferable that the sealing portion is disposed between the pair of heat insulating glasses to hermetically seal the space between the pair of heat insulating glasses.

The sealing portion includes an outer sealing portion and an inner sealing portion.

Here, the outer sealing portion is sandwiched between a pair of heat insulating glasses along the rim of the pair of heat insulating glass, and is made of a non-conductive material, and the inner sealing portion is formed in the vacuum It is preferable that the heat insulating member is sandwiched between the pair of heat insulating glasses in the space, and is made of a metal material.

Here, the outer sealing portion and the inner sealing portion may be in close contact with each other.

It is preferable that the inner sealing portion includes a brazing material selected from the group consisting of silver and copper and a pair of nickel plating layers disposed on the upper and lower sides of the brazing material and closely adhered to the outer surface between the pair of the heat insulating glasses.

It is preferable that the inner sealing portion is a thin metal plate.

On the other hand, the sealing portion may be disposed between the pair of heat insulating glasses and the outer peripheral surface of the pair of heat insulating glasses to seal the space between the pair of heat insulating glasses.

Here, the sealing portion includes an outer sealing portion and an inner sealing portion.

Here, the outer sealing part is made of a non-conductive material that is in close contact with the outer surface of the rim of the pair of the heat-insulating glass to seal the space between the pair of the heat-insulating glass, and the inner sealing part is formed on the inner side It is preferable that it is sandwiched between the pair of heat insulating glasses in the vacuum space, and is made of a metal material.

Preferably, the inner sealing portion is in close contact with a portion of the outer sealing portion.

It is preferable that the inner sealing portion includes a brazing material selected from the group consisting of silver and copper and a pair of nickel plating layers disposed on the upper and lower sides of the brazing material and closely adhered to the outer surface between the pair of the heat insulating glasses.

It is preferable that the inner sealing portion is a thin metal plate.

In the present invention, the vacuum space formed between the heat insulating glasses is sealed in multiple by using sealing parts made of different materials, so that the degree of vacuum and the heat insulation performance of the vacuum space can be improved.

1 is a plan view showing a vacuum insulated glass panel for a refrigerator according to a first embodiment of the present invention.
2 is a cross-sectional view showing an example of a sealing portion in the first embodiment of FIG.
3 is a cross-sectional view showing another example of the sealing portion in the first embodiment of FIG.
4 is a plan view showing a vacuum insulated glass panel for a refrigerator according to a second embodiment of the present invention.
5 is a cross-sectional view showing an example of a sealing portion in the second embodiment of FIG.
6 is a cross-sectional view showing another example of the sealing portion in the second embodiment of FIG.

Hereinafter, a vacuum insulating glass panel for a refrigerator of the present invention will be described with reference to the accompanying drawings.

≪ Embodiment 1 >

The vacuum insulating glass panel 200 of the present invention can be embedded in the outer wall or the inner wall of the refrigerator body (not shown) and can be adopted as a wall of another apparatus requiring heat insulation.

Referring to FIGS. 1 and 2, the vacuum insulating glass panel 200 of the present invention includes a pair of heat insulating glasses 210. The pair of the heat insulating glasses 210 are arranged with a predetermined clearance up and down. Spacers 220 having a predetermined length are disposed between the pair of heat insulating glasses 210.

The upper and lower ends of the spacers 220 support the inner surfaces of the pair of the heat insulating glasses 210, respectively. Accordingly, the clearance of the space between the pair of the heat insulating glasses 210 can be determined by the length of the spacers 220.

The vacuum insulating glass panel 200 of the present invention may be configured such that the openings between the pair of heat insulating glasses 210 at the edges of the pair of heat insulating glasses 210 are multi- And has an airtight sealing portion 300.

2 and 3 show an example of the sealing part 300 according to the present invention.

2 and 3, the sealing part 300 includes an outer sealing part 310 and an inner sealing part 320, which are made of different materials.

The outer sealing part 310 of the sealing part 300 is fitted in the opening of the pair of the heat insulating glasses 210 along the rim of the pair of the heat insulating glasses 210 and is made of a non-conductive material. Here, the pair of heat insulating glass 210 is composed of an upper heat insulating glass 210a and a lower heat insulating glass 210b.

Here, the outer surface of the outer sealing part 310 and the outer surface of the pair of the heat insulating glasses 210 may follow the same line.

The outer sealing part 310 may be an epoxy sealant.

The inner sealing part 320 is sandwiched between the pair of the heat insulating glasses 210 in the vacuum space VL so as to be positioned inside the outer sealing part 310 and is made of a metal material.

Preferably, the inner sealing portion 320 is disposed in close contact with the outer sealing portion 310.

Here, the inner sealing part 320 may be formed of a multi-layered metal layer. The multilayered metal layer is composed of a silver / copper-based brazing material 321 formed at a predetermined thickness in the center and a nickel-plated layer 322 formed at the upper and lower ends of the silver / copper brazing material 321 to a predetermined thickness.

The thickness t1 of the outer sealing part 310 and the thickness t2 of the inner sealing part 320 may be equal to each other and the thickness t2 of the inner sealing part 320 made of metal The thickness t1 of the outer sealing portion 310 may be greater than the thickness t1.

Here, the inner sealing portion made of metal may have a thickness of 5 to 500 mu m.

The inner sealing portion 320 formed of the metal layer as described above is in close contact with the inner surface of the outer sealing portion 310 to serve as a partition wall of the metal. The outer sealing part 310 is disposed on the outer surface of the inner sealing part 320 so as not to protrude to the outside of the heat insulating glass 210.

That is, the sealing part 300 of the present invention can double seal the vacuum space VL and seal the vacuum space VL with the inner sealing part 320, which is a substantially metallic partition wall.

Accordingly, by using the inner sealing portion 320 as a sealing member that is directly exposed to the vacuum space VL and hermetically sealed, it is possible to effectively prevent the external gas from penetrating into the vacuum space VL . Further, although not shown in the drawing, it can prevent the gas from leaking to the outside when used in a gas-tight panel such as an inert gas other than the vacuum space (VL).

In addition, since the inner sealing portion 320 according to the present invention is formed of a metal layer having different thermal expansion coefficients stacked along the lateral direction, if the nickel plating layer 322 is exposed to a temperature environment above a certain level, It may expand into a room. Accordingly, the inner surface of the pair of the heat insulating glasses 210 is formed with an adhesion force equal to or higher than a certain level to the upper surface or the lower surface of the nickel plating layer 322, thereby improving the airtightness of the vacuum space VL.

Fig. 3 shows another example of the sealing portion 301 according to the present invention.

Referring to FIG. 3, the sealing part 301 includes an outer sealing part 310 and an inner sealing part 320 ', which are made of different materials.

The outer sealing part 310 of the sealing part 301 is fitted to the opening of the pair of the heat insulating glass 210 along the rim of the pair of the heat insulating glass 210 and is made of a nonconductive material.

Here, the outer surface of the outer sealing part 320 'and the edge surfaces of the pair of the heat insulating glasses 210 may follow the same line.

The outer sealing part 310 may be an epoxy sealant.

The inner sealing part 320 'is sandwiched between the pair of the heat insulating glasses 210 in the vacuum space VL so as to be positioned inside the outer sealing part 310, and is made of a metal material.

Preferably, the inner sealing portion 320 'is disposed in close contact with the outer sealing portion 310. Of course, the inner sealing portion 320 'may be spaced apart from the inner surface of the outer sealing portion 310 by a certain distance.

Here, the inner sealing portion 320 'is a metal plate of one sheet metal.

The thickness t1 of the outer sealing portion 310 and the thickness t2 'of the inner sealing portion 320' may be equal to each other or the thickness t2 'of the inner sealing portion 320' May be thinner than the thickness t1 of the outer sealing portion 310 by a certain thickness.

The inner sealing portion 320 'made of the metal plate is in close contact with the inner surface of the outer sealing portion 310 and serves as a barrier or barrier for the metal. The outer sealing part 310 is disposed so as not to protrude from the outer surface of the inner sealing part 320 'to the outside of the heat insulating glass 210.

That is, the sealing portion 301 of the present invention can double seal the vacuum space VL and seal the vacuum space VL with the inner sealing portion 320 ', which is a substantially metallic partition wall .

Accordingly, by using the inner sealing portion 320 'as a sealing member which is directly exposed to the vacuum space VL and hermetically sealed, it is possible to effectively prevent the external gas from being infiltrated into the vacuum space. Further, this can prevent the gas from leaking to the outside when it is used in a gas-tight panel such as an inert gas other than the vacuum space (VL).

Further, since the inner sealing part 320 'according to the present invention is installed upright in the vacuum space VL of the pair of the heat insulating glasses 210, when exposed to a temperature environment above a certain level, have. Accordingly, the inside surfaces of the pair of the heat insulating glasses 210 are formed with a certain level of adhesion with the upper and lower surfaces of the inner sealing portion 320 ', which is a metal plate, to improve airtightness.

As described in the first embodiment, an inner sealing portion 320 ', such as a partition made of a metal material, is formed at the opening between the pair of the heat insulating glasses 210 at the edges of the pair of insulating glass 210, The outer sealing portion 310 formed of an epoxy-based sealant sealingly seals the space VL and closely adheres to the outer surface of the inner sealing portion 320 'seals the vacuum space VL.

Accordingly, the vacuum space VL can be sealed in multiple by the sealing portion 301 having the same shape as the partition wall of different material.

≪ Embodiment 2 >

The vacuum insulating glass panel 201 of the present invention shown in FIG. 6 can be embedded in an outer wall or an inner wall of a refrigerator body (not shown) and can be adopted as a wall of another apparatus requiring heat insulation.

4 and 5, the vacuum insulating glass panel 201 of the present invention includes a pair of heat insulating glasses 210. The pair of the heat insulating glasses 210 are arranged with a predetermined clearance up and down. Spacers 220 having a predetermined length are disposed between the pair of heat insulating glasses 210.

Since the spacers 220 are the same as those described above, they are omitted.

The vacuum insulating glass panel 201 of the present invention is characterized in that the space between the pair of heat insulating glasses VL is sealed so that the space between the pair of insulating glass sheets 210 forms a vacuum space VL, (302).

5 shows an example of the sealing part 302 in the second embodiment of the present invention.

5, the sealing part 302 includes an inner sealing part 320 disposed at an opening between the pair of the heat insulating glasses 210, and an inner sealing part 320 disposed at an outer side of the edges of the pair of the heat insulating glasses 210. [ And an outer sealing part 310 'for sealing the opening between the pair of the heat insulating glasses 210.

The outer sealing part 310 'is closely attached along the outer surface of the rim of the pair of the heat insulating glasses 210 to seal the space between the pair of the heat insulating glasses 210 with a non-conductive material. Preferably an epoxy-based silane.

The inner sealing part 320 is sandwiched between the pair of the heat insulating glasses 210 in the vacuum space VL so as to be located inside the outer sealing part 310 'and is made of a metal material.

Here, the inner sealing part 320 may be in close contact with a part of the inner surface of the outer sealing part 310 '.

Here, the inner sealing part 320 may be formed of a multi-layered metal layer. The multilayered metal layer is composed of a silver / copper-based brazing material 321 formed at a predetermined thickness in the center and a nickel-plated layer 322 formed at the upper and lower ends of the silver / copper brazing material 321 to a predetermined thickness.

Here, the thickness t1 'of the outer sealing portion 310' may be the same as the thickness t2 of the inner sealing portion 320, and the thickness t2 of the inner sealing portion 320, May be thicker than the thickness t1 'of the outer sealing portion 310'.

The inner sealing portion 320 formed of the metal layer as described above is in close contact with the inner surface of the outer sealing portion 310 'to serve as a partition wall of the metal. The outer sealing part 310 'is arranged to protrude from the outer surface of the inner sealing part 320 to the outside of the heat insulating glass 210.

That is, the sealing portion 302 of the present invention can double seal the vacuum space VL and seal the vacuum space VL with the inner sealing portion 320, which is a substantially metallic partition wall.

Particularly, the outer sealing portion 310 'has a height corresponding to a height difference between the pair of the heat insulating glasses 210, and the inner side thereof is sealed with the space between the pair of the heat insulating glasses 210, And is in close contact with the outer surface of the rim of the pair of heat insulating glass (210). Accordingly, the outer sealing part 310 'is formed so as to protrude from the rim of the pair of heat insulating glasses 210.

This is because when the heat is transferred from the upper heat insulating glass 210a to the lower heat insulating glass 210b, the heat flowing along the upper heat insulating glass 210a flows along the outer sealing part 310 ' Since the length of the outer sealing portion 310 'is longer than the predetermined length, the heat dissipation time can be increased. Accordingly, the heat in the lower side heat insulating glass 210b transmitted through the outer sealing part 310 'may be lower than the heat in the upper side heat insulating glass 210a.

Accordingly, the vacuum insulating glass panel 201 according to the present invention can improve the heat insulating performance by making the heat flow rate lower than a certain level.

6 shows another example of the sealing portion 303 in the second embodiment of the present invention.

Referring to FIG. 6, the sealing part 303 includes an outer sealing part 310 'and an inner sealing part 320', which are made of different materials.

The outer sealing part 310 'is substantially the same as the example described in the example shown in FIG. 6, and thus the description thereof will be omitted.

The inner sealing part 320 'is sandwiched between the pair of the heat insulating glasses 210 in the vacuum space VL so as to be positioned inside the outer sealing part 310', and is made of a metal material.

Preferably, the inner sealing portion 320 'is disposed in close contact with the outer sealing portion 310'. Of course, the inner sealing portion 320 'may be disposed at a certain distance from the inner surface of the outer sealing portion 310'.

Here, the inner sealing portion 320 'is a metal plate of one sheet metal.

The thickness t1 'of the outer sealing part 310' and the thickness t2 'of the inner sealing part 320' may be the same or may be the same as the thickness t2 'of the inner sealing part 320' t2 'may be thinner than the thickness t1' of the outer sealing portion 310 'by a certain thickness.

The inner sealing portion 320 'made of the metal plate is in close contact with the inner surface of the outer sealing portion 310' to serve as a partition wall of the metal. The outer sealing part 310 'is disposed so as not to protrude from the outer surface of the inner sealing part 320' to the outside of the heat insulating glass 210.

That is, the sealing portion 303 of the present invention can double seal the vacuum space VL and seal the vacuum space VL with the inner sealing portion 320 ', which is a substantially metallic partition wall .

Accordingly, by using the inner sealing portion 320 'as a sealing member which is directly exposed to the vacuum space VL and hermetically sealed, it is possible to effectively prevent the external gas from being infiltrated into the vacuum space. Further, this can prevent the gas from leaking to the outside when it is used in a gas-tight panel such as an inert gas other than the vacuum space (VL).

In addition, since the inner sealing portion 320 'according to the present invention is formed of a metal layer having different thermal expansion coefficients stacked along the lateral direction, when exposed to a temperature environment above a certain level, the pair of nickel plating layers 322 is finely It may be expanded into upper and lower rooms. Accordingly, the inner surface of the pair of heat insulating glasses 210 can have a certain degree of adhesion with the upper or lower surface of the nickel plated layer 322 to improve airtightness.

As described in the second embodiment, an inner sealing portion 320 ', such as a partition made of a metal, is provided at the opening between the pair of the heat insulating glasses 210 at the rim of the pair of heat insulating glasses 210, The outer sealing portion 310 'made of an epoxy-based sealant which is disposed on the outer surface of the inner sealing portion 320' to seal the vacuum space VL in a primary sealing manner is in contact with the outer surface of the inner sealing portion 320 ' Seal it.

Accordingly, the vacuum space VL can be sealed in multiple by the sealing part 303 having the same shape as the partition wall of different material.

In addition, since the outer sealing part 310 'is in close contact with the edge surfaces of the pair of the heat insulating glasses 210 and protrudes outward to form a heat dissipating path through which heat can flow, The heat is radiated to the outside through the sealing part 310 'to a certain extent, and the heat transfer rate can be reduced to a certain level or less to improve the heat insulating performance.

200: Insulating glass panel
210: Insulating glass
210a: upper side multi-layered glass
210b: Lower side insulating glass
220: Spacer
300, 301, 302:
310, 310 ': outer sealing part
320, 320 ': inner sealing portion
321: silver / copper braze
322: Nickel plated layer
VL: Vacuum layer
SA: Support area

Claims (11)

A pair of heat insulating glasses spaced apart from each other by a plurality of spacers provided inside; And
And a sealing part for sealing the openings between the pair of the heat insulating glasses to form a vacuum space so that the space between the pair of the heat insulating glasses forms a vacuum space at the rim of the pair of heat insulating glasses,
Wherein the sealing portion has an outer sealing portion and an inner sealing portion,
Wherein the outer sealing portion is formed as an epoxy-based sealant and is fitted in contact with the outer surface of the inner sealing portion between the pair of the heat insulating glass along the rim of the pair of the heat insulating glass, An outer edge surface and an outer surface of the inner sealing portion,
Wherein the inner sealing portion is located inside the outer sealing portion and is sandwiched between the pair of the heat insulating glasses so as to form the vacuum space on the inside and is made of a metal material and the thickness of the outer sealing portion is 5 to 500 [ And the thickness of the inner sealing part is equal to the thickness of the outer sealing part. delete delete delete The method according to claim 1,
The inner sealing portion
And a pair of nickel plated layers disposed on the upper and lower sides of the brazing material to closely contact the outer surfaces of the pair of the heat insulating glasses. The method according to claim 1,
Wherein the inner sealing portion is a metal plate of a thin plate. delete delete delete delete delete

Images