JP2006090650A - Cooling storage - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a sufficient heat insulating effect causing no damage of a vacuum heat insulating panel without impairing the function of degassing holes required for on-site foaming in the case of disposing the vacuum heat insulating panel within a heat insulating partition wall between a storage chamber and a machine chamber. <P>SOLUTION: A bottom plate 44 forming a bottom wall 6A of a heat insulating box body 6 has a crank-shaped cross section, and the vacuum heat insulating panel 45 in the state of being positioned on a lower horizontal part 44A of the bottom plate 44 is stuck to the lower horizontal part 44A. A plurality of spacers 51 are fixed to the inner surface of an obliquely rising part 44B in a position to avoid the degassing holes 48. In this state, the bent upper part of the vacuum heat insulating panel 45 is stuck to the other faces of the spacers 51 and fixed so as not to close the degassing holes 48 in a state of floating from the obliquely rising part 44B. An inner box 3 is built in an outer box 2, and the bottom plate 44 is attached. An undiluted polyurethane solution is injected from a urethane injection port to fill the polyurethane foam heat insulating material 4 between the inner box 3 and the outer box 2. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a cooling storehouse provided with a heat insulating box having a vacuum heat insulating panel disposed between an outer box and an inner box.

Such a cooling storage is disclosed in, for example, Japanese Patent Application Laid-Open No. 2003-222466, but the vacuum heat insulation panel is directly formed on the inner surface of the outer plate that forms a heat insulation partition between the storage room and a machine room in which a compressor and the like are arranged. Paste.
JP 2003-222466 A

  However, when the vacuum heat insulation panel is directly attached to the inner surface of the outer plate forming the heat insulating partition, the outer plate is provided with a gas vent hole for degassing during on-site foaming. There was a problem that the hole was blocked. In addition, if the vacuum heat insulation panel is attached to the inner surface of the inner plate that forms the heat insulation partition wall, the burrs in the vent holes may damage the vacuum heat insulation panel during the subsequent assembly of the outer plate, breaking the vacuum. As a result, there is a problem that a sufficient heat insulating effect cannot be obtained.

  Therefore, in view of the above-described problems, the present invention provides a function of a vent hole necessary for in-situ foaming when a vacuum heat insulating panel is disposed in a heat insulating partition wall between a storage chamber and a machine room in which a compressor and the like are disposed. It is an object of the present invention to obtain a sufficient heat insulating effect without impairing the heat resistance and not damaging the vacuum heat insulating panel.

  For this reason, the first invention is a cooling storage cabinet provided with a heat insulation box having a vacuum heat insulation panel disposed between an outer box and an inner box, the vacuum heat insulation panel being attached to a machine room on the bottom wall of the storage body. It is characterized by being arranged via a spacer on the bottom plate forming the partition wall.

  Moreover, 2nd invention is a cooling storehouse provided with the heat insulation box which arrange | positioned the vacuum heat insulation panel between the outer box and the inner box, Comprising: The said vacuum heat insulation panel arrange | positions a storage chamber, a compressor, etc. It is characterized in that the outer plate forming a heat insulating partition wall with the machine room is disposed via a spacer.

  Furthermore, a third invention is a cooling storage cabinet provided with a heat insulation box having a vacuum heat insulation panel disposed between an outer box and an inner box, the vacuum heat insulation panel being compressed with the bottom wall of the storage body, the storage chamber, and the like. It is arranged so as to straddle a heat insulating partition wall with a machine room in which a machine or the like is disposed, and is disposed on an outer plate forming the heat insulating partition wall via a spacer.

  A fourth invention is a cooling storage room comprising a heat insulating box body in which a vacuum heat insulating panel is disposed between an outer box and an inner box and a foamed resin is filled between the outer box and the inner box. A vacuum heat insulation panel is bent, and one of the bent vacuum heat insulation panels is attached to the inner surface of the outer box, and the other of the bent vacuum heat insulation panels is attached to the inner surface of the outer box via a spacer. A gas vent hole is formed in the inner surface of the outer box around the spacer.

  A fifth aspect of the present invention is a cooling storehouse including a heat insulating box body in which a vacuum heat insulating panel is disposed between an outer box and an inner box, and a foamed resin is filled between the outer box and the inner box. A vacuum heat insulating panel is bent, and one of the bent vacuum heat insulating panels is attached to the inner surface of the outer box forming the bottom wall of the storage body, and the other of the bent vacuum heat insulating panels is a spacer. It is attached to the inner surface of the outer box which forms a partition wall with the machine room, and a gas vent hole is formed in the inner surface portion of the outer box around the spacer.

  According to the present invention, when the vacuum heat insulating panel is disposed in the heat insulating partition wall between the storage chamber and the machine room in which the compressor and the like are disposed, the function of the vent hole necessary for in-situ foaming is not impaired. A sufficient heat insulating effect can be obtained without damaging the vacuum heat insulating panel.

  The best mode for carrying out the present invention will be described below with reference to the drawings. In FIG. 1, the refrigerator 1 is comprised by the heat insulation box 6 formed by filling the foaming polyurethane heat insulating material 4 by the in-situ foaming method between the outer box 2 made from the steel plate opened ahead, and the inner box 3 made from a hard synthetic resin. Has been. And the inside of this heat insulation box 6 is divided into upper and lower parts by a partition plate 7 provided in the substantially central part, and the upper part of the partition plate 7 is a refrigeration chamber 8 maintained at a refrigeration temperature (about 5 ° C.). Yes.

  In addition, the lower part of the partition plate 7 is vertically divided by a heat insulating partition wall 9, and a space between the heat insulating partition wall 9 and the partition plate 7 is used as a vegetable room 17 for storing foods such as vegetables that are not to be dried. A lower part of the partition wall 9 is a freezer compartment 18 that is cooled to a freezing temperature (about minus 20 ° C.).

  A front opening of the refrigerating chamber 8 provided with the upper and lower shelves 21 is closed by a pivotable door 22, and a refrigerating cooler 23 and a cool air circulation blower 24 are placed at the back of the refrigerating chamber 8. A refrigeration chamber duct 25 in which is disposed is formed vertically.

  A cold air communication port 26 that connects the refrigerator compartment 8 and the vegetable compartment 17 is formed in the upper front portion of the vegetable compartment 17, and the front opening of the vegetable compartment 17 is closed openably and closably by a drawer-type door 27. The vegetable container 28 opened on the upper surface is attached to the back surface of the door 27. And after cooling the inside of the refrigerator compartment 8 blown in the refrigerator compartment 8 from the blower outlet 29 formed in the upper end part of the refrigerator compartment duct 25, the inside of the vegetable compartment 17 is cooled via the cold air communication port 26, Cooling is performed through a path of returning inside the cold room duct 25 through the cold air return port 30.

  A cooling chamber 32 is formed on the back of the freezer compartment 18 by a partition plate 31, and a refrigerating cooler 33 that constitutes a cooling device is disposed in the cooling chamber 32 and is located behind the freezer compartment 18. In addition, a blower 34 is installed above the refrigeration cooler 33.

  The front opening of the freezer compartment 18 is opened and closed by two upper and lower drawer type doors 35 and 36, and containers 37 and 38 opened on the upper surface are attached to the back surfaces of the doors 35 and 36, respectively. Yes.

  The cold air generated by the refrigeration cooler 33 is supplied into the freezer compartment 18 by the blower 34 through the outlet 39, cools the inside of the freezer compartment 18 and then returns to the cooling compartment 32 through the cold air return port 40. Cool by path.

  On the other hand, the bottom wall 6A of the heat insulating box 6 has a shape in which the rear part rises in a stepped manner, and a machine chamber 41 is formed below and behind the bottom wall 6A. In the machine room 41, a compressor 42 constituting a refrigeration cycle and a condenser 43 as a radiator are installed. In addition, because the bottom wall 6A has such a shape, the bottom of the freezer compartment 18 is also shaped so that the rear part rises, and the cooler 33 is positioned above the raised bottom wall 6A.

  With the above configuration, when the compressor 42 is operated, high-temperature and high-pressure gas refrigerant is discharged from the compressor 42, flows into the condenser 43, dissipates heat, is condensed, and the refrigerant discharged from the condenser 43 is After being depressurized by the capillary tube, it enters the coolers 33 and 23 to evaporate and is sucked into the compressor 42 again.

  The cold air cooled by the coolers 33 and 23 as described above is sucked by the operation of the upper blowers 34 and 24 and blown out from the outlets 29 and 39 into the refrigerator compartment 8 and the freezer compartment 18. The vegetable compartment 17 and the freezer compartment 18 are cooled.

  On the other hand, the bottom wall 6A of the heat insulating box 6 includes the inner box 3, a steel plate bottom plate 44, a vacuum heat insulating panel 45 and a polyurethane foam heat insulating material 4 disposed between the inner box 3 and the bottom plate 44. It consists of and.

  The vacuum heat insulation panel 45 is laminated from the inside with a heat-sealed seal layer such as a linear low-density polyethylene layer, a gas barrier layer made of a metal layer such as an aluminum foil, and a protective layer for impact relaxation made of a nylon layer. A gas barrier film with high gas barrier properties is folded back, and the two sides are brought into close contact with each other to form a bag (housing member), and in that state, a core material having a heat insulating performance that does not generate outgas is inserted. Then, after exhausting the gas inside the bag in a predetermined vacuum evacuation device to make a vacuum state, it is manufactured by welding the remaining one side of the heat welding layer to each other and sealing, It is bent and has a substantially L-shaped cross section.

  As shown in FIGS. 2 and 3, the bottom plate 44 has a crank shape in cross section, and is composed of a lower horizontal portion 44A, an obliquely rising portion 44B, and an upper horizontal portion 44C. Reinforcing beads 46 having an L shape in plan view are provided at the left end and the right end of the lower horizontal portion 44A, and the reinforcing beads 46 reinforce the flat lower horizontal portion 44A and bend the vacuum. It serves as a positioning member when one side of the panel 45 is attached to the lower horizontal portion 44A with, for example, a double-sided adhesive tape. In the obliquely rising portion 44B, two reinforcing beads 47 are formed at the left and right portions, and a gas vent hole 48 for venting gas at the time of on-site foaming is formed.

  And the said vacuum heat insulation panel 50 is affixed on the inner surface of the outer box 2 of the back surface and both sides | surfaces of the refrigerator compartment 8, the vegetable compartment 17, and the freezer compartment 18, and the top | upper surface of the refrigerator compartment 8. In addition, one side of the vacuum heat insulation panel 45 is attached to the lower horizontal portion 44A with, for example, a double-sided adhesive tape while being positioned on the lower horizontal portion 44A of the bottom plate 44, and at a position where the gas vent hole 48 is avoided. With a double-sided adhesive provided on the other surface of the spacer 51 in a state where a plurality of spacers (spacers) 51 formed of, for example, foam heat insulating material are fixed to the inner surface of the rising portion 44B via, for example, a tape with a double-sided adhesive. The other (upper part) of the vacuum heat insulation panel 45 bent on the tape is affixed, and is fixed so as not to block the gas vent hole 48 in a state where it floats from the obliquely rising portion 44B. That is, a gas vent hole 48 is formed in the inner surface portion of the bottom plate 44 around the spacer 51.

  As described above, the vacuum heat insulation panel 45 is attached to the inner surface of the outer box (the inner surface of the lower horizontal portion 44A of the bottom plate 44) filled with the foamed resin without providing a gas vent hole in the outer box, and the gas is supplied to the outer box. On the inner surface of the outer box (the inner surface of the obliquely rising portion 44B of the bottom plate 44), which is easier to manufacture if the vent hole is provided, a gas vent hole 48 is provided and a vacuum heat insulating panel 45 is disposed via the spacer 51. Therefore, the vacuum heat insulation panel 45 can be securely and securely attached, and the polyurethane foam heat insulating material can be wrapped evenly.

  That is, generally, when the vacuum heat insulating panel 45 is disposed between the outer box and the inner box, the gas venting hole of the outer box must be provided avoiding the arrangement area of the vacuum heat insulating panel. Will not turn well. Therefore, it is conceivable to provide a vent hole in the inner box, but this is insufficient. Therefore, it is conceivable to attach a vacuum heat insulation panel to the inner box. However, in this case, since the vacuum heat insulation panel is attached to the inner surface of the inner box having irregularities, the manufacture is troublesome. For this reason, the vacuum heat insulation panel 45 is provided as described above.

  In this way, the inner box 3 is assembled into the outer box 2 to which the refrigerant pipe or the like is attached, and the bottom plate 44 is assembled, and the opening is set downward in a predetermined foaming jig. Next, a polyurethane undiluted solution is injected from the urethane inlets opened on the left and right of the central portion of the outer box 2, and the foamed polyurethane heat insulating material 4 is filled between the inner box 3 and the outer box 2.

  Accordingly, the vacuum heat insulation panel 45 is disposed so as to straddle the bottom wall 6A of the heat insulation box 6, that is, the bottom wall forming the freezer compartment 18 and the partition wall between the freezer compartment 18 and the machine room 41, and the partition wall. Since the machine chamber 41 has a high temperature, the heat insulation effect is high, and the wall thickness of the heat insulation box 6 is reduced by arranging the spacer 51 on the obliquely rising portion 44B (outer plate) of the bottom plate 44 to be formed. And the effective volume of the refrigerator 1 can be expanded or the reduction of the power consumption of a cooling device can be aimed at.

  As described above, according to the present embodiment, when the vacuum heat insulating panel 45 is disposed in the heat insulating partition wall between the freezing chamber 18 and the machine chamber 41 in which the compressor 42 and the like are disposed, the gas necessary for on-site foaming is provided. Since the function of the vent hole 48 is not impaired and the vacuum heat insulating panel 45 can be prevented from being damaged by the burrs of the gas vent hole 48, a sufficient heat insulating effect can be obtained.

  Although the embodiments of the present invention have been described above, various alternatives, modifications, and variations can be made by those skilled in the art based on the above description, and the present invention is not limited to the various alternatives described above without departing from the spirit of the present invention. It includes modifications or variations.

It is a longitudinal cross-sectional view of a refrigerator. It is a top view of a baseplate. It is a side view which can cut the bottom plate of the state which attached the vacuum heat insulation panel vertically.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Refrigerator 4 Polyurethane heat insulating material 6 Heat insulation box 6A Bottom wall 41 Machine room 44 Bottom plate 44B Slope rising part 45 Vacuum heat insulation panel 48 Gas vent hole 51 Spacer

Claims (5)

  A cooling storage unit having a heat insulating box having a vacuum heat insulating panel disposed between an outer box and an inner box, wherein the vacuum heat insulating panel is a spacer on a bottom plate that forms a partition wall with a machine room on the bottom wall of the main body. A cooling storage, which is arranged via   A cooling storage box having a heat insulating box body in which a vacuum heat insulating panel is disposed between an outer box and an inner box, wherein the vacuum heat insulating panel includes a heat insulating partition wall between a storage room and a machine room in which a compressor and the like are disposed. A cooling storage, wherein the outer plate to be formed is arranged via a spacer.   A cooling storage unit having a heat insulating box having a vacuum heat insulating panel disposed between an outer box and an inner box, wherein the vacuum heat insulating panel is provided with a bottom wall of the storage body, a storage chamber, a compressor, and the like. A cooling storage, characterized in that it is disposed so as to straddle a heat insulating partition with a chamber and is disposed on an outer plate forming the heat insulating partition via a spacer.   A vacuum heat insulation panel is disposed between the outer box and the inner box, and the vacuum heat insulation panel is bent in a cooling storage room having a heat insulation box filled with foamed resin between the outer box and the inner box. And forming one of the bent vacuum heat insulation panels on the inner surface of the outer box and attaching the other of the bent vacuum heat insulation panels to the inner surface of the outer box via a spacer. A cooling storage box, wherein a gas vent hole is formed in an inner surface portion of the outer box in the periphery.   A vacuum heat insulation panel is disposed between the outer box and the inner box, and the vacuum heat insulation panel is bent in a cooling storage room having a heat insulation box filled with foamed resin between the outer box and the inner box. Forming and sticking one of the bent vacuum heat insulation panels to the inner surface of the outer box forming the bottom wall of the storage body, and the other of the bent vacuum heat insulation panels with a machine room via a spacer A cooling storage box, wherein the cooling box is attached to the inner surface of the outer box forming a partition wall, and a gas vent hole is formed in the inner surface portion of the outer box around the spacer.

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