WO2015051997A1 - Refrigeration appliance with aerogel material - Google Patents

Abstract

The invention relates to a refrigeration appliance with a refrigeration compartment which is associated with the thermal insulation (110). According to the invention, said thermal insulation (110) comprises, in sections, an aerogel material (214).

Description

 Refrigerating appliance with airgel material

The invention relates to a refrigerator with a refrigeration compartment, which is associated with a thermal insulation. Refrigeration appliances, in particular designed as household appliances refrigerators are known and are used to housekeeping in households or in the catering sector to store perishable food and / or drinks at certain temperatures. Such refrigerators have a thermal insulation in order to reduce the energy consumption of the refrigerator. However, an increase in the thermal insulation leads to a reduction of the usable internal volume of the refrigeration device with external dimensions kept constant. Furthermore, such refrigerators increasingly include internals such as e.g. Ice cube makers, water dispensers or control / display electronics, which are installed in a refrigerator door of the refrigerator above. The result is bottlenecks in the thermal insulation of the refrigerator door, which are difficult enough thermally isolable areas. Low thermal insulation in these areas leads to increased energy consumption of the refrigerator due to the higher heat input in these areas and unwanted cooling of the outside of the refrigerator and possibly condensation, which may affect the functioning of electrical components and the durability of the refrigerator.

From US 4,444,821 and US 4,681,788 vacuum panels for thermal insulation of a refrigerator are known. However, only planar surfaces can be thermally insulated with such vacuum panels. Curved surfaces and / or contours are only very complex with vacuum panels and limited thermally isolable. Due to the vacuum required to achieve the high degree of isolation within the vacuum panel, the outer foil of the vacuum panel must not be damaged. It is therefore a high cost in the manufacturing process needed to exclude damage to the vacuum panel.

It is therefore the object underlying the invention to provide a refrigeration device with a thermal insulation that is easier to manufacture. This object is achieved by the subject matter having the features of the independent claim. Advantageous developments are subject of the dependent claims, the description and the drawings. The present invention is based on the recognition that by using an airgel material, easier-to-manufacture thermal insulation can be provided.

The object according to the invention is achieved by a refrigeration device having a refrigerating compartment, to which a thermal insulation is assigned, the thermal insulation having sections of an aerogel material. This achieves the technical advantage that the provision of airgel material in sections provides improved thermal insulation. An airgel material is understood as meaning a material in which an airgel is bound in a matrix material. The matrix material may be, for example, polyester fibers or glass fibers. Aerogels are understood as meaning highly porous solid bodies in which up to 99.98% of the volume consists of pores. Aerogels have a strong dentritic structure, that is, branching of partial chains with very many spaces in the form of open pores. These chains have contact points, so that ultimately results in the image of a stable, sponge-like network. Its aggregates have a fractal dimension, so they are self-similar to a certain extent. The pore size is in the nanometer range, and the inner surfaces can be exceptionally large at up to 1, 000 m ² / g. As a result, airgeleal thermal insulating material can be used. The thermal conductivity in air is in the range of 0.012 to 0.021 W / mK at room temperature.

According to one embodiment, the airgel material is mat-shaped. As a result, the technical advantage is achieved that the airgel material is easy to work to achieve a large-scale thermal insulation of a refrigeration compartment of a refrigerator. Thus, the processing of the airgel material is simplified. In a further advantageous embodiment, the airgel material is flexibly deformable. Thereby, the technical advantage is achieved that the airgel material can be easily adapted to eg curved surfaces and / or contours of a refrigeration compartment of the refrigerator during manufacture of the refrigerator. This simplifies the production again.

In a further advantageous embodiment, the airgel material silicate is based. This achieves the technical advantage that a chemically inert airgel material is used. Further, the melting point of a silicate-based airgel material is about 1200 ° C. Thus, the silicate-based airgel material can be processed particularly easily since it can be used at processing temperatures below below e.g. 300 ° C to 650 ° C will not be damaged. Therefore, silicate-based airgel material does not harm and does not react with the foam material when foaming a refrigerator to produce foam insulation. In a further advantageous embodiment, the airgel material is carbon-based. This achieves the technical advantage of using an easily available and easily processable airgel material.

In another embodiment, the airgel material is polymer-based. This achieves the technical advantage of using an easily available and easily processable airgel material.

In a further advantageous embodiment, the airgel material is arranged between an outer housing and an inner housing of the refrigeration device. As a result, the technical advantage is achieved that the airgel material is arranged in a space between an outer housing and an inner housing of the refrigerator thermally insulating.

According to a further advantageous embodiment, a connecting layer is arranged between the outer housing and the airgel material, which connects the outer housing with the airgel material materially. As a result, the technical advantage is achieved that the airgel material is connected by the connecting layer directly to the outer housing and no other connecting means, such as screws, must be used to connect the airgel material with the outer housing. As a result, the production is simplified.

In a further advantageous embodiment, a connecting layer is arranged between the outer housing and the airgel material, which connects the inner housing with the airgel material in a material-locking manner. This achieves the technical advantage that the airgel material is connected directly to the inner casing by the tie layer and no further connection means, such as e.g. Screws must be used to connect the airgel material with the inner housing. This also simplifies manufacturing.

In a further advantageous embodiment, the airgel material is arranged between a door outer housing and a door inner housing of a refrigerator door of the refrigeration device. As a result, the technical advantage is achieved that the airgel material is arranged in a space between a door inner housing and a door outer housing of the refrigerator door thermally insulating and thus improves the thermal insulation of the refrigerator door.

In a further advantageous embodiment, the refrigeration appliance door has a section with reduced door thickness, wherein the airgel material is arranged in the section with reduced door thickness. This achieves the technical advantage that the thermal insulation is improved there by the airgel material in the section with reduced door thickness.

In a further advantageous embodiment, a door installation is arranged in the section with reduced door thickness. As a result, the technical advantage is achieved that a refrigerator with additional internals, such. an ice cube maker, water dispenser and control / display electronics, or may be provided with parts of an ice cube maker, a water dispenser or a control / display electronics, without the thermal insulation is partially reduced.

In a further advantageous embodiment, the refrigeration appliance door has a section with a foam insulation. As a result, the technical advantage is achieved that the refrigerator door according to their door thickness a customized thermal Insulation, which is made uniform by the combination of the airgel material and foam insulation over the entire surface of the refrigerator door, so that form on the outside of the refrigerator door due to temperature differences no condensation surfaces. In a further advantageous embodiment, the airgel material is materially bonded to the foam insulation. As a result, the technical advantage is achieved that no additional fastening means, such as screws, are necessary in order to arrange the airgel material in the refrigerator door thermally insulating. The object of the invention is further achieved by an airgel material for such a refrigeration device. As a result, the technical advantage is achieved that the provision of sections of the airgel material provides improved thermal insulation. Embodiments will be explained with reference to the accompanying drawings. Show it:

Fig. 1 is a front view of a refrigerator, Fig. 2 is a schematic sectional view through a refrigerator door, and

Fig. 3 is a schematic sectional view through a wall portion of a

 Refrigeration device. 1 shows a refrigerator as an exemplary embodiment of a refrigeration device 100. According to one embodiment, the refrigerator serves, for example, for cooling food.

According to one embodiment, the refrigeration device 100 has an upper refrigerator door 102 and a lower refrigerator door 104 on its refrigeration device front side. With the upper refrigerator door 102, an upper refrigeration compartment opening 106 can be opened, which in the present embodiment is designed as a freezer compartment. With the lower one Refrigeration appliance door 104, a lower cooling compartment 108 can be opened, which is formed in the present embodiment as a cooling compartment.

According to one embodiment, the refrigeration device 100 has a thermal insulation 1 12, and both the upper refrigerator door 102 and the lower refrigerator door 104 have a thermal insulation 1 10 to minimize cold losses of the upper refrigeration compartment 106 and the lower refrigeration compartment 108.

The evaporator is designed as a heat exchanger, in which, after expansion, the liquid refrigerant is removed by absorbing heat from the medium to be cooled, i. Air inside the refrigerator, is evaporated.

The compressor is a mechanically driven component that draws refrigerant vapor from the evaporator and expels it at higher pressure to the condenser. The condenser is designed as a heat exchanger, in which, after compression, the vaporized refrigerant is released by heat release to an external cooling medium, i. the ambient air is liquefied.

The throttle body is a device for the continuous reduction of the pressure by reduction in cross section.

The refrigerant is a fluid used for heat transfer in the refrigeration system and which absorbs heat at low temperatures and lower pressure of the fluid and releases heat at higher temperature and pressure of the fluid, usually including changes in state of the fluid.

2 shows schematically the construction of the thermal insulation 110 of the upper refrigerator door 102 and the lower refrigerator door 104, respectively. The thermal insulation 110 according to one embodiment has a door outer housing 206 and a door inner housing 208. The outer door housing 206 is made of metal or plastic according to an embodiment, while according to one embodiment, the door inner housing 208 is made of plastic. The thermal Insulation 1 10 of the door, according to one embodiment, includes a first region 200, a second region 202, and a third region 204.

In both the first region 200 and the third region 204, foam insulation 212 is disposed between the outer door housing 206 and the inner door housing 208 to improve the thermal insulating properties of the refrigeration device 100, according to one embodiment.

In contrast, in the second section 202, according to one embodiment, a door installation 210 is arranged. According to one embodiment, the door installation 210 can be, for example, an ice cube maker, a water dispenser or an operating / display electronics of the refrigeration appliance 100, or parts of the ice cube maker, the water dispenser or the operating / display electronics of the refrigeration appliance 100. Through the door assembly 210, the thermal insulation 110 has a smaller thickness D in the second region 202 than in the first region 200 and the third region 204. In order to ensure the thermal insulation effect of the thermal insulation 1 10 over the entire surface of the upper refrigerator door 102 or lower refrigerator door 104, an airgel material 214 is disposed in the second region 202 between the door assembly 210 and the door inner housing 208. The airgel material 214 is understood as meaning a material in which an airgel is bound in a matrix material. The matrix material may be polyester fibers or glass fibers. Aerogels are understood as meaning highly porous solid bodies in which up to 99.98% of the volume consists of pores. Aerogels have a strong dentritic structure, that is, branching of partial chains with very many spaces in the form of open pores. These chains have contact points, so that ultimately results in the image of a stable, sponge-like network. Its aggregates have a fractal dimension, so they are self-similar to a certain extent. The pore size is in the nanometer range, and the inner surfaces can be exceptionally large at up to 1, 000 m ² / g. As a result, aerogels can be used, inter alia, as a thermal insulation or filter material. The thermal conductivity in air is in the range of 0.012 to 0.021 W / mK at room temperature. According to one embodiment, the airgel material 214 is in the form of a flexible mat 216 so that it can be adapted to curved and curved contours inside the upper refrigerator door 102 or the lower refrigerator door 104. The airgel material 214 is, in one embodiment, silicate, carbon, or polymer based.

The airgel material 214 has a better thermal insulation effect than the foam insulation 210, so that in spite of a smaller door thickness D between the outer door housing 206 and the door inner housing 208 in the second region 202 over the surface of the upper refrigerator door 102 or lower refrigerator door 104 substantially constant thermal Insulating effect is given. Thus, it is prevented that in the second region 202, in which the door assembly 210 is arranged, the outside door housing 206 cools excessively and condensation can form there. Further, the airgel material 214 does not reduce the thermal insulating effect in the second region 202.

In this case, the airgel material 214 is connected in a material-bonded manner to the door inner housing 208 in accordance with one embodiment. Further, the airgel material 214 may be foamed in forming the foam insulation 212 by foaming a gap between the outer door housing 206 and the inner door housing 208.

Fig. 3 shows schematically the structure of the thermal insulation 1 12 of the refrigeration device 100, i. the upper refrigeration compartment 106 and the lower refrigeration compartment 108.

The thermal insulation 12 according to one embodiment comprises an outer housing 300, a connection layer 302, the airgel material 214, a further connection layer 304 and the inner housing 306.

According to one embodiment, the outer housing 300 is made of metal or plastic.

The bonding layer 302 is, according to one embodiment, an adhesive or foam layer for establishing a material bond between the outer housing 300 and the airgel material 214. The second connection layer 304 is formed according to an embodiment as an adhesive or foam layer for the material connection of the inner housing 300 with the airgel material 214. The inner housing 306 is made of plastic according to one embodiment.

Thus, with the thermal insulation 1 12 a refrigeration device 100 is provided with an improved thermal insulation, so that with the same wall thickness improved thermal insulation is given, or with reduced wall thickness, an increase in the effective volume at constant outer dimensions of the refrigerator 100 is possible.

Thus, together with the thermal insulation 10, the refrigeration device 100 has improved thermal insulation and / or an increased useful volume with constant outside dimensions of the refrigeration device 100.

LIST OF REFERENCE NUMBERS

100 refrigeration unit

102 upper refrigerator door

104 lower refrigerator door

106 upper cold compartment

108 lower cold compartment

1 10 thermal insulation

1 12 thermal insulation

200 area

202 area

204 range

206 outside door housing

208 inner door housing

210 Türein construction

212 foam insulation

214 airgel material

216 flexible mat 300 outer casing

302 connection layer

304 connection layer

306 Inner housing D Door thickness

Claims

claims

1 . Refrigeration appliance (100) with a refrigeration compartment (106, 108), which is associated with a thermal insulation (1 10, 1 12), characterized in that the thermal insulation (1 10, 1 12) sections an airgel material (214).

2. Refrigerating appliance (100) according to claim 1, characterized in that the

Airgel material (214) is mat-shaped.

3. Refrigerating appliance (100) according to claim 1 or 2, characterized in that the

Airgel material (214) is formed flexibly deformable.

4. Refrigerating appliance (100) according to one of claims 1 to 3, characterized in that the airgel material (214) is silicate-based.

5. Refrigerating appliance (100) according to one of claims 1 to 3, characterized in that the airgel material (214) is carbon-based.

6. Refrigerating appliance (100) according to one of claims 1 to 3, characterized in that the airgel material (214) is polymer-based.

7. Refrigeration appliance (100) according to one of the preceding claims, characterized in that the airgel material (214) between an outer housing (300) and an inner housing (306) of the refrigeration device (100) is arranged.

8. Refrigerating appliance (100) according to claim 7, characterized in that between the outer casing (300) and the airgel material (214) a connecting layer (302) is arranged, which connects the outer casing (300) with the airgel material (214) cohesively.

9. Refrigerating appliance (100) according to claim 7 or 8, characterized in that between the inner housing (306) and the airgel material (214) a connecting layer (304) is arranged, which connects the outer housing (300) with the airgel material (214) materially ,

10. Refrigerating appliance (100) according to any one of the preceding claims, characterized in that the airgel material (214) between a door outer housing (206) and a door inner housing (208) of a refrigerator door (102, 104) of the refrigeration device (100) is arranged.

1 1. Refrigerating appliance (100) according to claim 10, characterized in that the

Refrigeration appliance door (102, 104) has a section (202) with reduced door thickness (D), wherein the airgel material in the section with the reduced door thickness (D) is arranged.

12. Refrigerating appliance (100) according to claim 1 1, characterized in that in the

Sections (202) with a reduced door thickness (D), a door assembly (210) is arranged.

13. Refrigerating appliance (100) according to claim 10, 1 1 or 12, characterized in that the refrigerator door (102, 104) has a portion (200, 204) with a foam insulation (212).

14. Refrigerating appliance (100) according to claim 13, characterized in that the

Airgel material (214) with the foam insulation (212) is firmly bonded.

15. airgel material (214) for a refrigeration device (100) according to any one of the preceding claims.