KR20120048425A - Vacuum insulation for refrigerator having a transparent spacers - Google Patents

Abstract

PURPOSE: An insulation unit for a refrigerator having transparent spacers is provided to prevent the increase of the internal pressure of a vacuum layer by preventing gas from being emitted from spacers arranged inside the vacuum layer. CONSTITUTION: An insulation unit for a refrigerator having transparent spacers comprises multiple insulation glasses(110), spacers, and sealing units(200). The insulation glasses are arranged at uniform intervals. The spacers are made of a transparent material and arranged between the insulation glasses to support the insulation glasses. The sealing units seal the gaps between the insulation glasses along the edges of the insulation glasses.

Description

Insulation unit for refrigerators with transparent spacers {VACUUM INSULATION FOR REFRIGERATOR HAVING A TRANSPARENT SPACERS}

The present invention relates to a heat insulating unit for a refrigerator, and includes a refrigerator having transparent spacers that can prevent an internal pressure increase of a vacuum layer or a gas layer formed between the heat insulating glasses, and improve transparency and heat insulating performance of the heat insulating unit itself. It relates to a thermal insulation unit for.

Typically a refrigerator is a device used to freeze or store food at a low temperature for a period of time, and a refrigeration cycle device that generates cold air is generally installed inside the device.

Therefore, since the refrigerator having the freezing and refrigerating functions as described above achieves a predetermined temperature or less than the outside temperature, the refrigerator must be provided with an insulation function so that the temperature inside the refrigerator is not affected by the external temperature environment.

In general, in order to perform the thermal insulation function, a conventional thermal insulation foam was used.

Here, the refrigerator includes a wall constituting the main body and partition walls partitioning the freezer compartment and the refrigerating compartment, and the insulation foam is formed by foaming the inner space of the wall and the partition walls in the inner space.

Accordingly, the foamed thermal insulation foam can lower the heat transfer rate of the external heat is transferred to the internal space of the refrigerator.

However, in the case of foaming the insulating foam inside the wall as described above, the foamed foam itself may be deformed, such as shrinkage caused by the external environmental change for a long time, and this causes a problem that its thermal insulation function is considerably reduced. have. Accordingly, there is a problem that is the main cause of lowering the refrigeration performance of the refrigerator as it does not perform the heat transfer prevention function of the insulating foam itself.

In order to solve the above problems of the insulating foam itself, it is buried in the wall of the refrigerator, forming a vacuum layer in the buried space to effectively block the heat transfer, and the heat transferred from the wall of the refrigerator flows to the inner wall side. Therefore, there is a demand for the development of a heat insulating material capable of effectively lowering the heat transfer rate.

In addition, when the heat insulating material includes a vacuum layer including a gas layer therein, the transparency of the gas layer or the vacuum layer becomes an important factor in reducing the heat transfer rate. Therefore, the development of the heat insulating material which can improve transparency while reducing the heat transfer rate in the heat insulating material provided with a vacuum layer is calculated | required.

The present invention has been made to solve the above problems, an object of the present invention is to prevent the release of gas from the spacers disposed in the vacuum layer formed between the insulating glass, to prevent the internal pressure rise inside the vacuum layer An insulation unit for a refrigerator having transparent spacers can be provided.

In addition, the present invention is to provide a heat insulating unit for a refrigerator having a transparent spacer that can improve the transparency of the heat insulating unit itself constituting the vacuum layer and reduce the thermal conductivity to improve the heat insulating performance.

In addition, another object of the present invention is to hermetically seal the vacuum layer or the gas layer formed between the insulating glass using sealing parts made of different materials, thereby maintaining the vacuum degree in the vacuum layer and preventing gas leakage in the gas layer. It is to provide an insulation unit for a refrigerator that can improve the insulation performance.

In a preferred aspect, the present invention provides a heat insulating unit for a refrigerator having transparent spacers.

The insulating unit for a refrigerator having the transparent spacers includes a plurality of insulating glasses arranged to be spaced apart from each other; A plurality of spacers disposed at a plurality of positions between the insulating glasses, made of a transparent material, and supporting the insulating glasses to achieve the clearance; And a sealing part sealing a gap between the insulating glasses along an edge of the insulating glasses.

Here, it is preferable that the said spacer consists of either acrylic resin or epoxy resin.

Each of the spacers may be formed of a support body formed of a transparent material having an upper end supporting an inner side of one of the insulating glasses and a lower end supporting an inner side of the other of the insulating glasses.

Here, the support body may be formed in a concave shape inward.

In addition, the spacers are preferably included in the breaking pressure range of 30 to 60gf.

In addition, the number of the spacers, the insulating glass forms a pair, it is preferable to form a 100 to 300 per unit area of the pair of insulating glass.

On the other hand, the sealing unit, by sealing the gap between the insulating glass in multiple to seal the space between the insulating glass, it can support the insulating glass in multiple.

Here, the sealing portion is made of a non-conductive material, the sub sealing portion is provided in the gap between the main sealing portion disposed in the gap between the insulating glass and the insulating glass so as to be disposed inside the main sealing portion along the edge portion. It is preferable to provide a sealing part.

The sub-sealing portion may be a glass protrusion protruding from the insulating glass, or may be made of a metal material, and may be a metal guide provided to be bonded to an inner surface of the insulating glass.

The main sealing part may form a first height along the upper and lower sides, and the sub sealing part may form a second height smaller than or equal to the first height by a predetermined height along the upper and lower sides.

The present invention has the effect of preventing the gas discharge from the spacers disposed in the vacuum layer formed between the insulating glass, to prevent the internal pressure rise inside the vacuum layer.

In addition, the present invention has the effect of improving the transparency of the heat insulating unit itself to form a vacuum layer and to reduce the thermal conductivity to improve the heat insulating performance.

In addition, the present invention by multiple hermetically by using a sealing portion made of a different material between the vacuum layer or the gas layer formed between the insulating glass, to maintain the degree of vacuum in the vacuum layer and to prevent gas leakage in the gas layer to insulate performance Has the effect to improve.

1 is a cross-sectional view showing a heat insulating unit for a refrigerator having transparent spacers of the present invention.
2 is an enlarged cross-sectional view showing an insulating unit to which an example of a spacer according to the present invention is applied.
3 is an enlarged cross-sectional view showing a heat insulation unit to which another example of a spacer according to the present invention is applied.
4 is an enlarged cross-sectional view showing a heat insulation unit to which another example of a spacer according to the present invention is applied.
5 is an enlarged cross-sectional view showing a heat insulation unit to which another example of a spacer according to the present invention is applied.
6 is an enlarged cross-sectional view showing a heat insulation unit to which another example of a sealing part according to the present invention is applied.
7 is an enlarged cross-sectional view showing a heat insulation unit to which another example of a sealing part according to the present invention is applied.
8 is an enlarged cross-sectional view showing a heat insulation unit to which another example of a sealing part according to the present invention is applied.
9 is another cross-sectional view showing a heat insulating unit for a refrigerator having transparent spacers of the present invention.
10 is another cross-sectional view showing a heat insulating unit for a refrigerator having transparent spacers of the present invention.

Hereinafter, with reference to the accompanying drawings, it will be described the heat insulating unit for a refrigerator of the present invention.

1 and 2, the heat insulation unit 100 of the present invention is provided between a plurality of heat insulation glasses 110 spaced apart from each other by spacers 120 and an edge portion of the heat insulation glasses 110. It has a sealing part 200 for sealing and supporting multiple gaps.

The insulating glasses 110 have a predetermined thickness and are made transparent.

The spacers 120 will be described in detail.

The spacers 120 have a predetermined length and are installed between the insulating glasses 110 to support the inner surfaces of the insulating glasses 110. Therefore, the insulating glasses 110 form a predetermined gap up and down with each other.

Spacers 120 in the present invention is made of a transparent material. Preferably, when the insulating glass 110 is transparent, the transparent material of the insulating glass 110 is preferably made of the same material, and preferably made of a material having low thermal conductivity.

As a result, the upper and lower insulating glass (110a, 110b) is installed in the space, that is, installed in the vacuum layer (VL), and is transparent, because the thermal conductivity is low, from the upper insulating glass (110a) to the lower insulating glass (110b) The thermal conductivity delivered can be reduced below a certain level. Accordingly, the spacers 120 may improve thermal insulation performance of the thermal insulation unit 100 by lowering the thermal conductivity.

As the transparent material is formed, transparency of the entire insulation unit 100 may be improved.

In addition, the spacers 120 according to the present invention may use either a transparent acrylic resin or a transparent epoxy resin.

Since the spacers 120 are arranged in the space between the pair of insulating glasses 110 as shown in FIG. 1 to support the insulating glasses 110, the spacers 120 must have a minimum breaking pressure.

Preferably, the spacers 110 according to the present invention preferably have a breaking pressure range of 10 to 70 gf, and have a breaking pressure range of 30 to 60 gf so as to be adopted in the refrigerator body and the door to withstand external shocks. It is desirable to.

In addition, the spacers 120 support the pair of insulating glasses 110 in the vacuum layer VL in a predetermined number. Preferably, the number of 100 to 300 pieces per unit area of the pair of insulating glasses 110 may be provided.

The spacers 120 in the present invention support the insulating glasses 110 in a state where the upper and lower ends thereof are bonded to respective inner surfaces of the pair of insulating glasses 110.

Referring to FIG. 3, in the present invention, the upper and lower ends of the spacers 120 may be fitted into fitting grooves 111 formed on the inner surfaces of the insulating glasses 110, respectively.

That is, a plurality of fitting grooves 111 may be formed at predetermined positions on the inner surfaces of the pair of insulating glasses 110.

The upper and lower ends of the spacers 120 made of a transparent material may be fitted into and fixed to the fitting grooves 111 of the upper insulating glass 110a and the fitting grooves 111 of the lower insulating glass 110b, respectively. .

Accordingly, the spacers 120 may be prevented from being twisted by an external impact at a supported position, and further, the pair of insulating glasses 110 may be stably supported by a set support watch.

In addition, as the spacers 120 are stably supported at the set position as described above, the sealing part 200 for sealing the gap between the pair of edges of the insulating glass 110 also includes the insulating glasses 110. The gap between can be reliably sealed.

In addition, referring to Figure 4, the spacers 120 according to the present invention is made of a transparent material, and also made of a support body having a predetermined length. Here, the support body is preferably made of acrylic resin or epoxy resin.

In addition, the support body may have a concave circumferential shape by having a concave surface 121 inward.

Accordingly, the spacer 120 illustrated in FIG. 3 may be reduced as much as the volume V is concave, compared to the spacer 120 having the linear circumferential shape illustrated in FIG. 2.

Conversely, when the spacers 120 shown in FIG. 3 are installed between the pair of insulating glasses 110, the internal space of the vacuum layer VL is the spacers 120 shown in FIG. 2. It is possible to increase a predetermined space in accordance with the installed vacuum layer (VL).

Therefore, the present invention may increase the space volume of the vacuum layer (VL) for the purpose of heat insulation by increasing a predetermined space without reducing the number of spacers 120, thereby increasing the heat insulation effect.

On the other hand, with reference to Figure 1 will be described as an example that the insulating glass 110 is a pair of insulating glass (110a, 110b) disposed respectively up and down. Here, the pair of insulating glass 110 may be divided into an upper insulating glass (110a) and a lower insulating glass (110b).

In addition, the spacers 120 configured as described above support inner surfaces of each of the upper and lower insulating glasses 110a and 110b.

Here, the sealing part 200 according to the present invention is inserted into the gap between the pair of insulating glass 110 along the edge portion of the pair of insulating glass 110.

The sealing part 200 may be inserted into a gap between the pair of insulating glasses 110 to seal multiplely from the outside so that the space between the insulating glasses 110 forms a vacuum layer VL.

Here, the configuration of the sealing unit 200 will be described.

The sealing part 200 according to the present invention includes a main sealing part 210 along the outermost edge part of the pair of insulating glasses 110 and an inner side of the main sealing part 210, preferably a pair of heat insulating parts. It consists of the sub-sealing part 220 provided in the space exposed between the glass 110 or the vacuum layer VL.

Here, the main sealing portion 210 is made of any one of acrylic, epoxy or Eve. That is, the main sealing portion 210 is made of a non-conductive material.

In addition, the sub-sealing unit 220 is made of a metal material.

In particular, the sub-sealing unit 220 is installed to be in close contact with the inner surface of the main sealing unit 210 in the vacuum layer (VL).

2 to 5 show various examples including the above example of the sub-sealing portion according to the present invention.

FIG. 2 is an enlarged cross-sectional view illustrating part A of FIG. 1, and shows an example in which the sub sealing part 220 is in close contact with the inner surface of the main sealing part 210 and protrudes from the insulating glass 110 in relief.

The sub-sealing unit 200 may be made of glass (see FIG. 2) or may be made of metal (see FIG. 7). In the former case, the insulating glass 110 may be etched to protrude to the outside, and in the latter case, the metal may be formed by bonding the glass to a predetermined position on the inner surface of the insulating glass 110.

The main sealing part 210 forms a first height H1 having a predetermined length up and down, and each of the upper and lower ends of the main sealing part 210 has an inner surface of each of the pair of insulating glass 110. Adheres to and adheres to Therefore, the main sealing part 210 itself serves to seal the gap between the pair of insulating glass 110 and at the same time serves to support the insulating glass 110 along the edge portion of the insulating glass 110. can do.

In addition, the sub-sealing unit 220 is disposed in a space between the pair of insulating glass 110 and is in close contact with the inner surface of the main sealing unit 210. Here, the second height H2 of the sub-sealing unit 220 may be lower than the first height H1. That is, the length of the sub-sealing part 220 in the vertical direction is shorter than the length of the main sealing part 210 in the vertical direction.

Here, the sub-sealing portion 220 as described above is made of glass (see FIG. 2) or metal (see FIG. 7).

In the former case, the sub-sealing portion 220 protrudes from the inner surface of the lower insulating glass 110b to form a second height H2 upward. Here, the sub-sealing portion 220 which is the protruding glass may be formed to protrude (as embossed) from the lower insulating glass 110b through an etching process.

Accordingly, as shown in FIG. 2, an exposure gap HG is formed between the main sealing part 210 and the sub sealing part 220 due to the first and second heights H1 and H2.

Therefore, in the present invention, the main sealing portion 210 sealing the gap between the pair of insulating glass 110 and bonding them is a pair of insulating glass by the sub-sealing portion 220 disposed in close contact with the inner surface ( It may not be entirely exposed to the vacuum layer (VL) formed in the space between 110. That is, in the main sealing part 210, only an open space of the exposure gap HG is exposed to the vacuum layer VL.

Accordingly, the vacuum layer VL formed in the space between the insulating glasses 110 may not be exposed to the outside by the sub-sealing unit 220 and the main sealing unit 210, so that the vacuum degree may be efficiently maintained. Can be.

6 illustrates an example in which two sub-sealing parts 221 are formed to be in close contact with the inner surface of the main sealing part 210.

Referring to FIG. 6, the sub-sealing portion 221 is embossed to form a predetermined length from the inner side surface of the upper insulating glass 110a, and also has a predetermined length from the inner side surface of the lower insulating glass 110b positioned at the bottom thereof. It is embossed to form. Here, the overall length of the two sub-sealing portions 221 divided up and down is a length corresponding to the second height H2 mentioned above. Here, the total height of the sub-sealing portion 221 is H2 sum of H2a and H2b.

Here, a predetermined exposure gap HG is formed between the two sub-sealing parts 221. The second height H2 of the sub sealing part 221 divided into two is formed to be lower than the first height H1 of the main sealing part 210.

Therefore, in the present invention, the main sealing portion 210 sealing the gap between the pair of insulating glass 110 and bonding them is a pair by the two divided sub-sealing portion 221 disposed in close contact with the inner surface. It may not be entirely exposed to the vacuum layer (VL) formed in the space between the insulating glass 110. That is, in the main sealing part 210, only an open space of the exposure gap HG is exposed to the vacuum layer VL.

Accordingly, since the vacuum layer VL formed in the space between the insulating glasses 110 may not be exposed to the outside by the sub sealing part 221 and the main sealing part 210, the vacuum degree is maintained efficiently. Can be.

Of course, the second height HG of the sub-sealing parts 220, 221, and 222 illustrated in FIGS. 2 and 7 may be the same as the first height H1 of the main sealing part 210.

That is, the upper and lower ends of the sub-sealing unit 200 mentioned in FIG. 2 may be in close contact with inner surfaces of the upper and lower insulating glasses 110a and 110b. In this case, the upper end of the sub-sealing portion 200 which is embossed in the lower insulating glass (110b) is preferably bonded to the inner surface of the upper insulating glass (110a) through a separate adhesive.

In addition, the two sub-sealing portion 221 divided in FIG. 6 may be formed so that the ends thereof abut each other on the upper side and the lower side, preferably the ends of the two sub-sealing portion 221 abut It is good to be bonded by a separate adhesive.

In addition, the sub-sealing portion 222 made of the metal mentioned in FIG. 7 and having a height of H2 from the inner side surface of the lower side insulating glass 110b is bonded to the inner side surface of the lower side insulating glass 110b through a separate adhesive agent. do.

Accordingly, the pair of insulating glass 110 by the sealing portion 200, 201, 202 of the present invention can be supported in multiple, as well as the inner space (vacuum layer (VL)) can be multiplely sealed along the edge portion thereof. have.

2 and 6 refer to the sub-sealing portions 220 and 221 which are glass protrusions that are embossed on the insulating glass 110.

More specifically, FIG. 7 shows that the sub-sealing portion 222 made of metal is in close contact with the inner side of the main sealing portion 210 made of a non-conductive material. have.

Referring to FIG. 7, the sub sealing part 222 of the present invention may be made of a metal material. Although not shown in the drawing, the metal material 222 may be formed of a solder material of silver / copper and a plating layer of a metal such as nickel is further formed on top and bottom thereof, or may be made of a single metal.

As described above with reference to FIG. 2, the sub-sealing part 222 of the metal material has a second height H2, and the second height H2 is the first height H1 of the main sealing part 210. It is formed lower than a certain height. Therefore, a predetermined exposure gap HG is formed between the upper end of the sub sealing part 222 and the inner side surface of the upper insulating glass 110. The exposure gap HG exposes a portion of the inner surface of the main sealing part 210 to the vacuum layer VL.

Of course, the upper and lower ends of the metallic sub-sealing part 222 may be bonded to each of the inner surfaces of the pair of insulating glass 110 while being in close contact with the inner surface of the main sealing part 210. That is, the sub sealing part 222 may serve as a metal guide.

Accordingly, the pair of insulating glass 110 by the sealing portion 200, 201, 202 of the present invention can be supported in multiple, as well as the inner space (vacuum layer (VL)) can be multiplely sealed along the edge portion thereof. have.

FIG. 8 may be in a state in which the upper and lower ends of the main sealing unit 210 are in close contact with the inner surface of the pair of insulating glass 110. In this case, the first height H1 of the main sealing part 210 and the second height H2 of the sub sealing part 223 may be substantially the same.

Referring to FIG. 8, the sub sealing part 223 is made of the same material as the spacers 120 installed in the vacuum layer VL so that the insulating glasses 110 may achieve a predetermined gap.

That is, the spacers 120 may be formed of any one of an acrylic sealant, an epoxy sealant, and an EVA. Accordingly, the sub-sealing part 223 may also be made of the same material as the spacers 120. have.

Accordingly, the sub-sealing unit 223 may serve as a spacer guide.

According to an exemplary embodiment of the present invention, a gap between the insulating glasses 110 is formed along the edge portion of the insulating glasses 110 in which the sub-sealing parts 222 and 223 having the function of the metal guide or the spacer function form the vacuum layer VL. Since it is sealed and supported together with 210, the number of spacers 120 formed on the vacuum layer VL may be reduced to a predetermined value or less, and thus, the transparency of the thermal insulation unit 110 may be improved. There is this.

As described with reference to FIGS. 1 to 8, the sub-sealing parts 220, 221, and 222 according to the present invention may be arranged in close contact with only an inner side surface of the main sealing part 210 so as to be located in the vacuum layer VL, and the main sealing part. It may be arranged in close contact with only the outer surface of the portion 210, it may be arranged in close contact with both the inner surface and the outer surface of the main sealing portion 210.

Accordingly, the sealing parts 200, 201, and 202 of the main sealing part 210 and the sub sealing parts 220, 221, and 222 according to the present invention may prevent the vacuum layer VL formed between the insulating glasses 110 from leaking to the outside. In addition to being able to be hermetically sealed in multiple, there is an advantage in that the insulating glass 110 can be multiplely supported at the edge in multiple.

In addition, the main sealing portion 210 for sealing the gap between the edge portion of the insulating glass 110 to use the epoxy sealant, acrylic sealant and EVA, the heat flowing from the upper insulating glass (110a) main sealing When the heat flows through the unit 110, a predetermined heat may be induced to radiate to the outside. Accordingly, as the heat transferred to the lower insulating glass 110b achieves a predetermined temperature or less, the heat transfer rate may decrease, and the thermal insulation performance may be improved.

In addition, the sealing parts 200, 201, and 202 according to the present invention are not limited to the vacuum layer VL formed in the space between the insulating glasses 110, as shown in FIGS. 9 and 10. The same configuration may be used to seal the edge gaps of the insulating glasses 110 forming the gas layer GL.

As shown in FIG. 9, the heat insulating unit 100 of the present invention may form a double vacuum layer VL, and is disposed between edges of the insulating glass 110 forming the double vacuum layer VL. The gap may be multiplely sealed by the sealing parts 200, 201 and 202 according to the present invention, and the edge portion of the insulating glass 110 may be multiplely supported by the sealing parts 200, 201 and 202 according to the present invention.

In addition, a half mirror coating layer 10 having a predetermined thickness may be further formed on an inner surface of the insulating glass 110 on one side, and a low radiation coating layer 20 having a predetermined thickness on the inner surface of the insulating glass 110 on the other side. ) May be formed more selectively.

As shown in FIG. 10, the heat insulation unit 100 of the present invention may form one vacuum layer VL and one gas layer GL thereon, and the vacuum layer VL and the gas layer GL. The gap between the insulating glass 110 forming a) is multiplely sealed by the sealing parts 200, 201, 202 according to the present invention, the edge portion of the insulating glass 110 is multiplexed by the sealing parts 200, 201, 202 according to the present invention. It can be supported by.

In addition, a half mirror coating layer 10 having a predetermined thickness may be further formed on an inner surface of the insulating glass 110 on one side, and a low radiation coating layer 20 having a predetermined thickness on the inner surface of the insulating glass 110 on the other side. ) May be formed more selectively.

10: half mirror coating layer
20: low radiation coating layer
100: insulation unit
110: insulating glass
200, 201, 202: sealing part
210: main sealing part
220, 221, 222: sub sealing part
VL: vacuum layer
GL: Gas Layer

Claims (9)

A plurality of insulating glasses arranged at a predetermined gap from each other;
A plurality of spacers disposed at a plurality of positions between the insulating glasses, made of a transparent material, and supporting the insulating glasses to achieve the clearance; And
And a sealing portion for sealing a gap between the insulating glasses along the edges of the insulating glasses. The method of claim 1,
The spacer
Insulation unit for refrigerators having transparent spacers, characterized in that it is made of any one of acrylic resin and epoxy resin. The method of claim 1,
Each of the spacers,
The upper end is made of a support body made of a transparent material for supporting the inner surface of any one of the insulating glass, the lower end supporting the inner surface of the other of the insulating glass,
Insulation unit for a refrigerator having transparent spacers, characterized in that the support body is formed in a concave shape inwardly. The method of claim 1,
Insulation unit for a refrigerator having transparent spacers, characterized in that the spacers are included in the breaking pressure range of 30 to 60gf. The method of claim 1,
The number of spacers,
The insulating glass is a pair, and the insulating unit for a refrigerator having transparent spacers, characterized in that 100 to 300 per unit area of the pair of insulating glass. The method of claim 1,
The sealing unit,
Sealing the gap between the insulating glass in multiple to seal the space between the insulating glass, and to support the multiple insulating glass,
The sealing unit,
A main sealing part made of a non-conductive material and disposed in a gap between the insulating glasses along the edge part;
And a sub sealing part provided in a gap between the insulating glasses so as to be disposed inside the main sealing part. The method of claim 6,
The sub sealing unit,
And a glass protrusion protruding from the insulating glass. The method of claim 6,
The sub sealing unit,
Insulation unit for a refrigerator having a transparent spacer, characterized in that the metal guide is made of a metal material is bonded to the inner surface of the insulating glass. The method of claim 6,
The main sealing portion forms a first height along the top and bottom,
The sub-sealing unit is a heat insulating unit for a refrigerator having transparent spacers, characterized in that it forms a second height equal to or smaller than the first height along the top and bottom.

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