JP2020003210A - Vacuum heat insulation panel and refrigerator - Google Patents

Abstract

To provide a refrigerator using a vacuum heat insulation panel that can maintain heat insulation performance for a long term.SOLUTION: A vacuum heat insulation panel 50 includes: a core material 52; a first bag body 54 of which inside is decompressed and hermetically sealed while the core material 52 is stored; and a second bag body 56 of which inside is decompressed and hermetically sealed while the first bag body 54 of which inside is decompressed and hermetically sealed is stored, where the first bag body 54 is bonded to the second bag body 56. An outside surface of the first bag body 54 and an inside surface of the second bag body 56 are configured with the same material.SELECTED DRAWING: Figure 2

Description

  Embodiments of the present invention relate to a vacuum insulation panel and a refrigerator.

  Conventionally, refrigerators are configured by a cabinet filled with foam insulation between an outer box and an inner box, and form a storage room inside the cabinet. A vacuum insulation panel is provided instead of a part of the foam insulation material filled between the outer box and the inner box in order to reduce the amount or reduce the wall thickness of the cabinet and improve the volumetric efficiency inside the cabinet. Have been.

  This kind of vacuum insulation panel includes a core material and a bag body, as shown in Patent Document 1, for example. The core material is formed from glass wool or the like, which is a thin glass fiber cotton, and the bag body is formed from a laminated film bag having aluminum foil or the like. This vacuum insulation panel is configured such that a core material is accommodated in a bag, the inside of the bag is decompressed, the opening is closed, and the inside of the bag is kept in a decompressed state.

  However, if the bag is damaged when manufacturing the panel or assembling it into a cabinet, the outside air enters the inside of the bag and the heat insulating performance of the vacuum heat insulating panel is significantly deteriorated. In particular, if a hole is formed due to damage to the bag, even if the hole is a fine hole smaller than several μm, the amount of outside air that enters the inside of the bag is small, and the hole formed in the bag is Depending on the size, for example, over a long period of time, for example, from several tens of days to several months, a slow leak that gradually deteriorates the insulation performance of the vacuum insulation panel occurs, and finally the inside of the bag body becomes atmospheric pressure The heat insulation performance deteriorates remarkably. For this reason, even if sufficient heat insulation performance is confirmed at the time of manufacturing a vacuum heat insulation panel, since the heat insulation performance gradually deteriorates thereafter, it is difficult to ensure the reliability of the heat insulation performance over a long period of time.

JP 2005-106094 A

  Therefore, it is an object of the present invention to provide a refrigerator using a vacuum heat insulating panel capable of maintaining heat insulating performance for a long period of time.

The vacuum insulation panel according to the present embodiment includes a core material, a first bag body whose inside is depressurized and sealed with the core material housed therein, and an inner space where the first bag body whose inside is depressurized and sealed is housed. And a second bag body, which is hermetically sealed under reduced pressure, wherein the outer surface of the first bag body and the inner surface of the second bag body are provided in a vacuum insulation panel in which the first bag body and the second bag body are bonded. Are made of the same material.

  Further, the refrigerator of the present embodiment is a refrigerator including a heat insulating box provided with a vacuum heat insulating panel between an outer box and an inner box, wherein the vacuum heat insulating panel contains a core and the core. A first bag body whose inside is decompressed and sealed in a state, and a second bag body whose inside is depressurized and sealed while containing the first bag body whose inside is decompressed and sealed, The second bag body is adhered, and the outer surface of the first bag body and the inner surface of the second bag body are made of the same material.

It is sectional drawing of the refrigerator which concerns on 1st Embodiment. It is a principal part expanded sectional view of the vacuum heat insulation panel used for the refrigerator shown in FIG.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  As shown in FIG. 1, the refrigerator 10 of the present embodiment has a refrigerator 10 in which a heat insulating space is provided between an outer box 12 made of a steel plate and an inner box 14 housed inside the outer box 12 and forming a storage space. And a refrigeration cycle (not shown) is incorporated in the cabinet 18.

  On the heat-insulating space side of the outer box 12 and the inner box 14 forming the heat-insulating space, a thermoplastic adhesive is provided so that the vacuum heat-insulating panel 50 is not bent and is substantially flat along the outer box 12 and the inner box 14. (Hot melt) or the like. Further, in the cabinet 18, a gap may be generated at a place other than the vacuum insulation panel 50 in the insulation space. In this gap, a foam heat insulating material 20 made of urethane foam or the like, and a refrigerant pipe such as a heat radiating pipe constituting a part of a refrigeration cycle are arranged as necessary, and the outer box 12 and the inner box 14 are integrated. Is done. In particular, a part of a refrigerant pipe such as a heat radiation pipe is formed by forming a concave groove on the outer box 12 side of the vacuum heat insulating panel 50 and storing the refrigerant pipe in the concave groove. Therefore, in the vacuum insulation panel 50 arranged on the back and side surfaces of the refrigerator 10, the refrigerant pipe and the vacuum insulation panel 50 are configured to be in contact with each other.

  The storage space provided inside the cabinet 11 is partitioned by a heat insulating partition wall 22 into an upper refrigeration space and a lower refrigeration space. The refrigerating space is further vertically divided by a partition wall 24, a refrigerating room 26 having a plurality of stages of mounting shelves is provided in an upper space, and a vegetable room 28 in which a drawer-type storage container is arranged is provided in a lower space. ing. In the freezing space, an ice making room 30 equipped with an automatic ice maker having a relatively small volume and a small freezing room 32 are provided side by side, and a freezing room 34 is provided below it.

  FIG. 2 shows a cross section of an end portion of the vacuum heat insulating panel 50. The vacuum heat insulating panel 50 has a rectangular plate-shaped core material 52 formed according to the shape of a wall portion to which the vacuum heat insulating panel 50 is attached, and a second material for accommodating the core material 52. There is provided one bag body 54 and a bag-shaped second bag body 56 that houses the first bag body 54 in which the core material 52 is housed.

  The core material 52 is a material having a high heat insulating property, for example, an inorganic fiber such as glass wool or silica alumina, or a laminated material 52a made of an inorganic powder such as silica powder, for example, is transferred to an inner bag 52b made of a synthetic resin film such as polyethylene. After being stored, it is formed by compression hardening into a rectangular plate shape.

  The first bag body 54 includes a laminated film having a three-layer structure in which a surface protection layer 54a, a gas barrier layer 54b, and a heat welding layer 54c are sequentially laminated from the outside to the inside. The surface protective layer 54a is made of a synthetic resin that is relatively resistant to heat, such as polyethylene terephthalate. The gas barrier layer 54b is formed of a metal deposit (for example, an aluminum deposit obtained by depositing aluminum on a resin film) or a metal foil (for example, an aluminum foil). The heat welding layer 54c is made of, for example, a synthetic resin having a heat welding property such as high density polyethylene.

  The first bag body 54 is formed by superposing the heat-sealing layers 54c of the two laminated films facing each other, and pressing and heating the peripheral portion, whereby the two laminated films are heat-sealed and sealed to form an opening. Is formed in a bag shape having After the core material 52 is accommodated in the inside of the first bag 54 from the opening, the opening of the first bag 54 is hermetically sealed by heat welding while the inside is evacuated and decompressed.

  The peripheral portion of the first bag body 54 protrudes from the core 52 in order to thermally weld the two laminated films, and the protruding portion is bent at the edge of the core 52, and one of the laminated films The folded portion 62 is formed by superimposing the folded portion.

  The second bag body 56 includes a laminated film having the same configuration as the laminated film constituting the first bag body 54 in which the surface protection layer 56a, the gas barrier layer 56b, and the heat welding layer 56c are sequentially laminated from the outside to the inside. The two laminated films are heat-welded to form a bag having an opening by heat-sealing the two laminated films by pressing and heating the peripheral portions thereof so that the heat-welded layers 56c of the two laminated films are opposed to each other. Have been.

  The second bag body 56 accommodates the first bag body 54 in which the inside is depressurized and sealed in a state in which the core material 52 is accommodated, and then the opening of the second bag body 56 is evacuated and decompressed in the state. Sealed by heat welding.

  The peripheral portion of the second bag body 56 protrudes from the first bag body 54 containing the core material 52 in order to thermally weld the two laminated films, and the protruding portion of the first bag body 54 An edge portion is bent to form a folded portion 64 that is superimposed on one of the laminated films. In the present embodiment, the folded portion 64 provided on the second bag body 56 is overlapped with the folded portion 62 so as to cover the folded portion 62 provided on the first bag body 54 from the outside.

  In the second bag 56, the heat welding layer 56 c located on the inner surface thereof is bonded and fixed by the surface protection layer 54 a located on the outer surface of the first bag 54 housed inside the second bag 56 and the adhesive layer 58. Have been. At this time, the adhesive layer 58 is provided in a region where the folded portions 62 and 64 do not overlap.

Specifically, when the first bag 54 is accommodated in the second bag 56, an olefin-based, polyester-based, or urethane-based heat is applied between the first bag 54 and the second bag 56. Two heat-adhesive sheets containing a plastic adhesive (hot melt) are inserted so as to sandwich the first bag, and the opening of the second bag 56 is hermetically sealed by heat welding while the inside is depressurized as described above. After that, by heating the second bag body 56, an adhesive layer 58 for bonding the first bag body 54 and the second bag body 56 can be formed.
Note that the adhesive layer 58 does not need to be provided on all of the opposing surfaces of the first bag body 54 and the second bag body 56. If the second bag body 56 can be fixed to the first bag body 54, the adhesive layer 58 is partially provided. It may be provided.

  Further, the adhesive layer 58 for bonding the first bag body 54 and the second bag body 56 is not limited to the above-mentioned heat-adhesive sheet. For example, after the opening of the second bag body 56 is closed, It may be formed by welding, ultrasonic welding, laser welding, high frequency welding, or the like.

  Further, in the present embodiment, after the first bag 54 is accommodated inside the second bag 56, the first bag 54 and the second bag 56 are bonded with the double-sided adhesive tape, and then the inside is decompressed. By sealing the opening of the second bag body 56 in a state in which the first bag body 54 is accommodated, the first bag body 54 and the second bag body 56 are An adhesive layer 58 may be provided between them.

  In the present embodiment, the second bag 56 is attached to the adhesive layer 58 provided between the first bag 54 and the first bag 54 from the outside when the first bag 54 and the second bag 56 are bonded as necessary. It may be pressed toward.

  In the above-described embodiment, the case where the laminated film forming the first bag body 54 and the laminated film forming the second bag body 56 are formed of the same film has been described. The surface protection layer 54a, which is located on the outer surface of the second bag body 56 and forms an adhesive surface with the second bag body 56, is the same as the heat welding layer 56c, which is located on the inner surface of the second bag body 56 and forms the adhesive surface with the first bag body 54 A corona treatment may be applied to the surface protective layer 54a of the first bag 54 and the heat-sealing layer 56c of the second bag 56 which are made of a material or form an adhesive surface. Adhesion with the two bags 56 can be improved.

  In particular, when the first bag 54 and the second bag 56 are bonded to each other by heater welding, ultrasonic welding, laser welding, high frequency welding, or the like, the surface protection of the laminated film forming the first bag 54 is performed. When the layer 54a is made of the same synthetic resin as the heat-welding layers 54c and 56c, welding becomes easy, and the adhesiveness between the first bag 54 and the second bag 56 can be improved.

  In the refrigerator 10 of the present embodiment as described above, the vacuum heat insulating panel 50 provided in the heat insulating space of the cabinet 18 has the first bag body 54 for housing the core material 52 and the second bag body for housing the first bag body 54. The first bag 54 and the second bag 56 are sealed under reduced pressure, and the first bag 54 and the second bag 56 are double-sealed around the core 52 under reduced pressure. Therefore, even if one of the bags is damaged, the outside air does not enter the inside of the bag, and the heat insulating performance does not deteriorate.

  The vacuum insulation panel 50 has a relatively high rigidity core material 52 in which the second bag body 56 forming the outer surface thereof is fixed to the outer box 12 or the inner box 16 with an adhesive or a foam insulation material 20. Are integrated with the cabinet 18 so that the rigidity of the cabinet 18 can be increased.

  In addition, when the second bag 56 is not fixed to the first bag 54, when the second bag 56 is damaged and external air enters inside the second bag 56, the second bag 56 is stored in the first bag 54. The core material 52 thus fixed is not fixed to the outer box 12 or the inner box 16 and the rigidity of the cabinet 18 may be reduced. However, in the present embodiment, the first bag body 54 and the second bag body 56 are bonded to each other. Therefore, even if external air may enter the inside of the second bag body 56, the first bag body 54 and the core 52 existing inside the bag body remain in a state integrated with the cabinet 18. And the rigidity of the cabinet 18 does not decrease.

  Since the adhesive layer 58 is provided in a region that does not overlap with the folded portions 62 and 64, it is prevented that the folded portions 62 and 64 and the adhesive layer 58 overlap with each other in the vacuum heat insulating panel 50 to partially increase the thickness. it can.

  The vacuum insulation panel arranged on the back or side of the refrigerator 10 which comes into contact with a vacuum insulation panel such as a refrigerant pipe and which comes into direct contact with a member which may damage the vacuum insulation panel is a vacuum insulation panel which is double-sealed and pressure-reduced. A single vacuum heat insulation panel is used for a vacuum heat insulation panel to be disposed at a place where the vacuum heat insulation panel needs to be largely bent when the paste is applied, such as a ceiling surface or a bottom surface. Thus, the manufacturing cost of the refrigerator can be reduced as compared with the case where all vacuum insulation panels are double-sealed under reduced pressure.

  In addition, by vacuum-sealing a vacuum insulation panel having a size larger than that of a ceiling surface or a bottom surface such as a back surface or a side surface of the refrigerator 10 doubly, a large vacuum insulation panel having a size more easily damaged is provided. Damage can be more reliably prevented.

  Although the embodiments of the present invention have been described above, these embodiments are presented as examples and are not intended to limit the scope of the invention. These embodiments can be implemented in other various forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and their equivalents.

10 refrigerator, 12 outer box, 14 inner box, 18 cabinet, 20 foam insulation material, 22 heat insulation partition, 50 vacuum insulation panel, 52 core material, 52a laminated material, 52b inner bag, 54: first bag, 54a: surface protective layer, 54b: gas barrier layer, 54c: welding layer, 56: second bag, 56a: surface protecting layer, 56b: gas barrier layer, 56c: welding layer, 58: adhesive layer , 62: folded part, 64: folded part

Claims (2)

A core material, a first bag body whose inside is vacuum-sealed with the core material housed therein, and a second bag body whose inside is vacuum-sealed with the first bag body inside vacuum-sealed housed therein Wherein the first bag body and the second bag body are bonded to each other.
A vacuum insulation panel, wherein an outer surface of the first bag and an inner surface of the second bag are made of the same material. In a refrigerator having an insulating box body provided with a vacuum insulating panel between the outer box and the inner box,
The vacuum insulation panel includes a core material, a first bag body that is internally decompressed and sealed with the core material accommodated therein, and an interior that is decompressed and sealed with the first bag body interiorly decompressed and sealed therein. The first bag and the second bag are bonded together, and the outer surface of the first bag and the inner surface of the second bag are made of the same material. refrigerator.

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