JP2020091073A - Heat insulating box body and refrigerator including the same - Google Patents

Abstract

To suppress increase of a manufacturing cost.SOLUTION: In a heat insulating box body 18, a heat insulating case 40 is provided between an interior case 30 and an exterior case 60, and the heat insulating case 40 comprises side heat insulating boards 41L and 41R, an upper heat insulating board 42, a lower heat insulating board 43 and a rear heat insulating board 44, which cover side walls 32L, 32R, an upper wall 33, a lower wall 34, and a rear wall 31 of the interior case 30 from the outside. Consequently, the side heat insulating boards 41L, 41R, the upper heat insulating board 42, the lower heat insulating board 43, and the rear heat insulating board 44, which are formed in advance, are arranged outside the interior case 30, and assembled as the heat insulating case 40, and thus the heat insulating box body 18 can be manufactured.SELECTED DRAWING: Figure 4

Description

The present invention relates to a heat-insulating box and a refrigerator including the same.

Conventionally, in a heat insulation box body applied to a refrigerator or the like, a urethane heat insulating material is interposed in a space between an inner box (inner case) and an outer box (exterior case) so that the inside and the outside of the heat insulation box are separated from each other. Is insulated. For example, in the heat insulation box body described in Patent Document 1 below, a rigid urethane foam is foam-filled in the space between the inner box and the outer box.

Patent No. 3549453

However, in the heat insulating box body, as described above, since the rigid urethane foam is foam-filled in the space between the inner box and the outer box, equipment for foam-filling the urethane foam is required. In addition, after the urethane foam is filled, it is necessary to inspect whether or not the urethane foam is completely filled in the space between the inner box and the outer box. As a result, there is a problem that the manufacturing cost of the heat insulating box increases.

In view of the above facts, an object of the present invention is to provide a heat-insulating box that can suppress an increase in manufacturing cost and a refrigerator including the same.

One or more embodiments of the present invention include a rectangular parallelepiped box-shaped inner case having an opening, an outer case that is arranged outside the inner case and covers the inner case, and a door that opens and closes the opening. A skeleton portion that is provided between the inner case and the outer case and supports the inner case and the outer case; and a wall portion of the inner case that is provided between the inner case and the outer case. And a plurality of heat insulating boards that cover the above.

According to one or more embodiments of the present invention, the skeleton portion is a heat-insulating box body configured by a plurality of elongated frame members and having a rectangular parallelepiped frame shape.

In one or more embodiments of the present invention, the heat insulating board includes a base heat insulating panel forming a base portion of the heat insulating board, a vacuum heat insulating panel arranged on one side in a plate thickness direction of the base heat insulating panel, It is a heat insulation box configured to include a base heat insulation panel and a cushioning member that covers the vacuum heat insulation panel from both sides in the thickness direction.

One or more embodiments of the present invention is a heat insulating box body in which the base heat insulating panel is provided with a holding portion that engages with an outer peripheral portion of the vacuum heat insulating panel and holds the vacuum heat insulating panel. ..

In one or more embodiments of the present invention, the plurality of heat insulating boards are assembled in a rectangular parallelepiped box shape opened in the same direction as the opening direction of the interior case, and the heat insulating boards are provided on the outer peripheral portion thereof. When viewed from the thickness direction of the heat insulating board, at least one of a fitting convex portion protruding to the outside of the heat insulating board and a fitting concave portion opened to the outside of the heat insulating board is formed. In the heat insulating boards to be assembled with each other, the fitting convex portion is a heat insulating box body fitted inside the fitting concave portion.

In one or more embodiments of the present invention, the heat insulating board includes a vacuum heat insulating panel having one side attached to a wall portion of the interior case, and a cushioning member attached to the other side of the vacuum heat insulating panel. And a heat-insulating box body configured to include.

One or more embodiments of the present invention include a heat insulating box having the above-described configuration, and a refrigeration cycle configured to include a cooler arranged inside the heat insulating box, and cooling the inside of the heat insulating box. It is a refrigerator equipped with.

According to one or more embodiments of the present invention, an increase in manufacturing cost can be suppressed.

FIG. 1 is a vertical cross-sectional view (cross-sectional view taken along line 1-1 of FIG. 3) of a refrigerator to which a heat insulating box according to the present embodiment is applied. It is a plane sectional view (2-2 line sectional view of FIG. 3) of the refrigerator shown in FIG. It is a perspective view of a refrigerator to which the heat-insulating box according to the present embodiment is applied. It is a disassembled perspective view of the heat insulation box main body in the heat insulation box body shown by FIG. FIG. 5 is a perspective view showing an assembled state of a heat insulating case in the heat insulating box shown in FIG. 4. It is a disassembled perspective view which decomposed|disassembled the side heat insulation board which comprises the heat insulation case shown by FIG. It is a perspective view which shows the modification of the heat insulation box which concerns on this Embodiment. It is a disassembled perspective view which decomposed|disassembled the heat insulation box main body shown by FIG.

Hereinafter, the refrigerator 10 to which the heat insulating box 18 according to the present embodiment is applied will be described with reference to FIGS. 1 to 6. In addition, the arrow UP, the arrow FR, and the arrow RH that are appropriately shown in the drawings indicate the upper side, the front side, and the right side (one side in the width direction) of the refrigerator 10 (the heat insulating box 18). In the following description, when the vertical, front-rear, and left-right directions are described, the vertical direction, the front-rear direction, and the left-right direction of the refrigerator 10 (the heat-insulating box body 18) are indicated unless otherwise specified.

(About the entire refrigerator 10)
As shown in FIGS. 1 to 3, the refrigerator 10 is formed in a generally rectangular parallelepiped box shape extending in the vertical direction as a whole. Note that, in FIGS. 1 and 2, for convenience, only the urethane heat insulating panel 50 described later is hatched. The refrigerator 10 is configured as an indirect cooling type refrigerator, for example. That is, as shown in FIGS. 1 and 2, the refrigeration cycle is housed inside the refrigerator 10. Specifically, a refrigerator 11, a compressor 12, a condenser (not shown), and an expander (not shown) are provided at the rear of the refrigerator 10, and these are connected via a refrigerant tube 13. ing.

Then, when the compressor 12 operates, the refrigerant is compressed by the compressor 12 to have high temperature and high pressure, and the refrigerant is sent to the condenser. The refrigerant sent to the condenser is radiated, condensed, and liquefied. The refrigerant liquefied in the condenser becomes low temperature and low pressure in the expander, is vaporized, and is sent to the cooler 11. The refrigerant in the cooler 11 is heat-exchanged with the cool air in the cooler 11, and evaporates while absorbing heat to become a low-temperature gas and is sent to the compressor 12. Then, by repeating this cooling cycle, cold air that has undergone heat exchange in the cooler 11 is generated.
The generated cool air is circulated in the interior case 30 described later by the fan 14 provided at the rear portion of the refrigerator 10 and driven by a fan motor (not shown) to cool the interior case 30. ing.

Further, as also shown in FIG. 3, the refrigerator 10 includes a cooling unit portion 15 that constitutes a lower end portion of the refrigerator 10 and a heat insulating box body 18 that constitutes an upper portion of the refrigerator 10 and functions as a cold insulation portion. It is configured to include.

(About the cooling unit 15)
As shown in FIGS. 1 and 3, the cooling unit portion 15 is formed in a substantially rectangular tubular shape that is opened in the vertical direction, and constitutes the lower end portion of the refrigerator 10. The compressor 12 described above is housed inside the rear side of the cooling unit section 15.
In addition, a storage box 16 opened upward is provided inside the cooling unit section 15, and the storage box 16 is configured to be slidable in the front-rear direction. The inside of the storage box 16 is configured as a thawing chamber 16A. Thus, the storage box 16 is pulled out to the front side and the product to be defrosted is stored in the defrosting chamber 16A, so that the product to be defrosted can be thawed in the defrosting chamber 16A.

(About the insulation box 18)
As shown in FIGS. 1 to 3, the heat insulating box 18 is formed in a substantially rectangular parallelepiped box shape extending in the vertical direction as a whole, and is installed above the cooling unit section 15. Further, the projected area of the heat insulating box 18 as viewed from above substantially matches the projected area of the cooling unit portion 15. The heat insulating box body 18 has a substantially rectangular parallelepiped box-shaped heat insulating box body 19 that is open to the front side, and a door 70 that opens and closes an opening of the heat insulating box body 19. Further, as shown in FIG. 4, the heat insulating box body 19 is configured to include a skeleton frame 20 as a “skeleton portion”, an inner case 30, a heat insulating case 40, and an outer case 60. . Hereinafter, each structure of the heat insulating box 18 will be described.

<About skeleton frame 20>
The skeleton frame 20 constitutes the skeleton of the heat insulating box main body 19 and is formed in a rectangular parallelepiped frame shape extending in the vertical direction as a whole. Specifically, the skeleton frame 20 has twelve frame members 22 forming each side of the skeleton frame 20, and the frame member 22 is made of an angle steel material having an L-shaped cross section and a long shape. Has been done. The skeleton frame 20 is formed into a rectangular parallelepiped frame shape by joining both ends of the frame member 22 in the longitudinal direction.

Further, the opening portion at the front end of the skeleton frame 20 is configured as an opening insertion portion 20A, and the inside of the skeleton frame 20 is configured as a case housing portion 20B for housing an inner case 30 described later. Further, on the left and right side surfaces, the upper and lower surfaces, and the rear surface of the skeleton frame 20, windows 20C surrounded by the frame member 22 are formed.

<About the interior case 30>
The inner case 30 is made of a resin material and is formed in a substantially rectangular parallelepiped box shape having an opening 30A that is open to the front side. Specifically, the inner case 30 includes a rear wall 31 as a “wall portion” having a plate thickness direction in the front-rear direction, and a pair of left and right “wall portions” extending from both widthwise end portions of the rear wall 31 to the front side. 32L, 32R as "," the upper wall 33 as a "wall portion" extending from the upper end of the rear wall 31 to the front side, and the "wall portion" extending from the lower end of the rear wall 31 to the front side. And a lower wall 34 of The inner case 30 is formed by injection molding or the like, and the rear wall 31, the side walls 32L and 32R, the upper wall 33, and the lower wall 34 are integrally formed. Then, the interior case 30 is inserted into the case housing portion 20B from the opening insertion portion 20A of the skeleton frame 20 and fixed to the skeleton frame 20. Thereby, the interior case 30 is supported by the skeleton frame 20 in a state where the window portion 20C of the skeleton frame 20 is closed.

As shown in FIGS. 1 and 2, a resin cover plate 36 is provided at the rear end inside the inner case 30. The cover plate 36 is formed in a substantially rectangular plate shape having a plate thickness direction in the front-rear direction, and is fixed to the inner peripheral surface of the inner case 30 at a position not shown. As a result, the inside of the interior case 30 is partitioned into front and rear by the cover plate 36. Specifically, the front side portion inside the interior case 30 is configured as a cold storage chamber 30B, and the rear end portion inside the interior case 30 is configured as a device housing chamber 30C.

The above-described cooler 11 is arranged in a lower portion of the device housing chamber 30C in the inner case 30. Further, a pair of left and right case-side insertion holes 30D are formed through the rear end of the lower wall 34 of the interior case 30. The refrigerant pipe 13 that connects the cooler 11 and the compressor 12 is inserted through the case-side insertion hole 30D. Further, the above-described fan 14 is arranged at the upper end of the device housing chamber 30C. Further, a plurality of air supply holes 36A are formed through the upper end portion of the cover plate 36, and the plurality of air supply holes 36A are arranged side by side at a predetermined interval in the left-right direction. Further, a plurality of exhaust holes 36B are formed through the lower end of the cover plate 36, and the plurality of exhaust holes 36B are arranged side by side at a predetermined interval in the left-right direction. As a result, the cool air generated by the cooler 11 rises inside the device housing chamber 30C by the fan 14, passes through the air supply holes 36A, and flows out into the cold storage chamber 30B. Further, the cold air that has flowed into the cold storage chamber 30B flows out from the exhaust hole 36B into the device housing chamber 30C, where it is cooled again by the cooler 11. Thereby, the cool air is circulated in the interior case 30.

As shown also in FIG. 4, a plurality of (five in the present embodiment) reinforcing ribs 30E extending in the front-rear direction are formed on the outer surface of the upper wall 33 of the inner case 30, The reinforcing rib 30E is formed in a concave shape open to the upper side. In addition, a plurality of (five in the present embodiment) reinforcing ribs 30F extending in the front-rear direction are formed on the outer surface of the lower wall 34 of the interior case 30, and the reinforcing ribs 30F are located on the lower side. It is formed in a concave shape that is open to. Further, a plurality of (six in the present embodiment) reinforcing ribs 30G extending in the vertical direction are formed on the outer surface of the rear wall 31 of the interior case 30, and the reinforcing ribs 30G extend forward. It is formed in an open concave shape. As a result, the rigidity of each wall surface of the inner case 30 is strengthened, and the rigidity of the entire inner case 30 is strengthened.

On the left and right side walls 32L and 32R of the inner case 30, a plurality of (three in the present embodiment) shelf receivers 30H for supporting shelves and the like inside the inner case 30 are formed, respectively. The shelf receiver 30H is formed in a rib shape that extends in the front-rear direction while protruding inward in the width direction of the inner case 30. By placing the shelf on the shelf receiver 30H, the cold storage chamber 30B is divided into four spaces. Further, a flange portion 30J is formed in the opening of the interior case 30, and the flange portion 30J extends from the opening 30A of the interior case 30 to the outside of the interior case 30 with the front-back direction as the thickness direction. There is.

<Insulation case 40>
As shown in FIGS. 4 and 5, the heat insulating case 40 is formed in a substantially rectangular parallelepiped box shape that is open to the front side. Specifically, the heat insulating case 40 is a pair of side heat insulating boards 41L and 41R as the "heat insulating boards" that form the left and right side walls of the heat insulating case 40, and a "heat insulating board" that forms the upper wall of the heat insulating case 40. An upper heat insulating board 42, a lower heat insulating board 43 as a “heat insulating board” that constitutes a lower wall of the heat insulating case 40, and a rear heat insulating board 44 as a “heat insulating board” that constitutes a rear wall of the heat insulating case 40. It is configured to include.

Each heat insulating board (side heat insulating boards 41L and 41R, upper heat insulating board 42, lower heat insulating board 43, and rear heat insulating board 44) is formed in a substantially rectangular plate shape. Then, the sides of the heat insulating boards that intersect each other at a right angle are fitted to each other, and the heat insulating case 40 is assembled in a substantially rectangular parallelepiped box shape opened to the front side.
Specifically, each heat insulating board is opened to the outside of the heat insulating board and the fitting convex portion 45 protruding to the outside of the heat insulating board at the longitudinal intermediate portion of the side on which the other heat insulating board is assembled. At least one of the fitting recesses 46 is formed.
More specifically, the fitting convex portions 45 are formed on the upper side, the lower side, and the rear side of the side heat insulating boards 41L and 41R, respectively, in the longitudinal intermediate portions.
Further, fitting recesses 46 are formed in the longitudinal middle portions of the left side, right side, and rear side of the upper heat insulating board 42, respectively.
Further, fitting recesses 46 are formed in the middle portions in the longitudinal direction of the left side, the right side, and the rear side of the lower heat insulating board 43, respectively.
Further, fitting recesses 46 are formed in the longitudinal middle portions of the left and right sides of the rear heat insulating board 44, and a fitting convex portion 45 is formed in the longitudinal middle portions of the rear heat insulating board 44. Are formed respectively.

Then, in the heat insulating boards to be assembled with each other, the heat insulating boards are assembled by fitting the fitting convex portions 45 into the fitting concave portions 46.
Specifically, for example, three heat insulating boards, that is, an upper heat insulating board 42, a lower heat insulating board 43, and a rear heat insulating board 44 are attached to the left side heat insulating board 41L. Then, the fitting convex portion 45 formed on the upper side of the side heat insulating board 41L is fitted into the fitting concave portion 46 formed on the left side of the upper heat insulating board 42, and the side heat insulating board 41L and the upper heat insulating board 42 are assembled. It is attached. Further, the fitting convex portion 45 formed on the rear side of the side heat insulating board 41L is fitted into the fitting concave portion 46 formed on the left side of the rear heat insulating board 44, so that the side heat insulating board 41L and the rear heat insulating board 44 are separated from each other. It is assembled. Further, the fitting convex portion 45 formed on the lower side of the side heat insulating board 41L is fitted into the fitting concave portion 46 formed on the left side of the lower heat insulating board 43, and the side heat insulating board 41L and the lower heat insulating board 43 are assembled. It is attached.

Further, when the heat insulating case 40 is assembled, each heat insulating board is assembled outside the skeleton frame 20. That is, in the assembled state of the heat insulating case 40, the skeleton frame 20 is disposed adjacent to the inside of the heat insulating case 40, and the heat insulating case 40 is supported by the skeleton frame 20. Thereby, in the supporting state of the heat insulating case 40 of the skeleton frame 20, each window portion 20C of the skeleton frame 20 is closed by the heat insulating case 40, and the heat insulating case 40 is arranged at a position close to the outside of the interior case 30. There is.

Next, the structure of each heat insulating board will be described. Since the side heat insulation boards 41L and 41R, the upper heat insulation board 42, the lower heat insulation board 43, and the rear heat insulation board 44 have the same structure, the left side heat insulation board 41L of the left heat insulation board 41L will be described below. The structure will be described, and the description of the structures of the side heat insulating board 41R, the upper heat insulating board 42, the lower heat insulating board 43, and the rear heat insulating board 44 will be appropriately omitted.

As shown in FIG. 6, the side heat insulating board 41L includes a urethane heat insulating panel 50 as a "base heat insulating panel", a vacuum heat insulating panel 52, a pair of cushioning members 54, and a cover member 56. ing. The side heat insulation board 41L has a laminated structure in which a urethane heat insulation panel 50, a vacuum heat insulation panel 52, and a cushioning member 54 are laminated.

The urethane heat insulation panel 50 is configured as a rigid urethane foam molded into a substantially rectangular panel shape. The outer shape of the urethane heat insulating panel 50 is formed in a shape corresponding to the outer shape of the side heat insulating board 41L. Further, the thickness dimension of the urethane heat insulation panel 50 is set to 15 mm as an example, and the urethane heat insulation panel 50 constitutes the base portion of the side heat insulation board 41L. The outer peripheral portion of the urethane heat insulating panel 50 mainly constitutes the fitting convex portion 45 and the fitting concave portion 46 described above.

A plurality of (four in the present embodiment) holding ribs 50A as "holding portions" for holding a vacuum heat insulating panel 52 described later are integrally formed on each side of the outer peripheral portion of the urethane heat insulating panel 50. The holding rib 50A is projected to the right side (one side in the plate thickness direction of the urethane heat insulation panel 50 and the interior case 30 side), and is extended along the circumferential direction of the urethane heat insulation panel 50.

The vacuum heat insulation panel 52 is formed in a substantially rectangular panel shape with the left-right direction as a plate thickness direction as a whole. The outer shape of the vacuum heat insulating panel 52 is formed in a rectangular shape smaller than the outer shape of the urethane heat insulating panel 50. Further, the thickness of the vacuum heat insulating panel 52 matches the protruding amount of the holding rib 50A in the urethane heat insulating panel 50, and in the present embodiment, it is set to 10 mm as an example. The vacuum heat insulating panel 52 is arranged adjacent to one side of the urethane heat insulating panel 50 in the plate thickness direction, and each side of the outer peripheral portion of the vacuum heat insulating panel 52 engages with the holding rib 50A of the urethane heat insulating panel 50. ing. Thereby, the vacuum heat insulation panel 52 is held by the urethane heat insulation panel 50.

The vacuum heat insulation panel 52 has a hollow panel-shaped outer bag 52</b>A that forms the outer shell of the vacuum heat insulation panel 52. The outer bag 52A is made of gas barrier aluminum foil or the like. The inside of the outer bag 52A is a closed space, and the closed space is evacuated to maintain the closed space in a reduced pressure state or a vacuum state. Inside the outer bag 52A, glass wool or polyurethane foam as a core material is stored.

The cushioning member 54 is made of, for example, a cushion material made of foamed polyethylene, and is formed in a sheet shape with the left-right direction being the thickness direction. Further, the outer shape of the cushioning member 54 is substantially the same as the outer shape of the urethane heat insulating panel 50. Then, one cushioning member 54 is attached to the urethane heat insulating panel 50 from the right side, and the other cushioning member 54 is attached to the urethane heat insulating panel 50 and the vacuum heat insulating panel 52 from the left side. As a result, the side heat insulating board 41L has a laminated structure in which the urethane heat insulating panel 50 and the vacuum heat insulating panel 52 are sandwiched by the pair of cushioning members 54 in the thickness direction. Moreover, the thickness of the buffer member 54 is set to 3 mm as an example. It should be noted that when the outer case 60, which will be described later, is assembled to the skeleton frame 20, the outer case 60 causes the cushioning member 54 to be compressed and deformed in the thickness direction.

Like the cushioning member 54, the cover member 56 is made of, for example, a cushion material made of foamed polyethylene. The cover member 56 is formed in a substantially rectangular frame shape corresponding to the outer shape of the urethane heat insulating panel 50. The cover member 56 is attached to the outer peripheral portion of the urethane heat insulating panel 50, and the outer peripheral portion of the urethane heat insulating panel 50 is covered with the cover member 56.

Here, as shown in FIG. 1, in the lower heat insulating board 43, the vacuum heat insulating panel 52 has a rear end portion of the lower heat insulating board 43 (specifically, a portion facing the case side insertion hole 30D of the interior case 30 in the vertical direction). The position of the vacuum heat insulating panel 52 is set so that the vacuum heat insulating panel 52 is not placed in the position. That is, in a plan view, the vacuum heat insulating panel 52 is disposed so as to be displaced to the front side with respect to the case side insertion hole 30D of the interior case 30. Further, the urethane heat insulating panel 50 of the lower heat insulating board 43 has a board side insertion hole 50B formed therethrough at a position corresponding to the case side insertion hole 30D of the interior case 30. As a result, the inside of the device housing chamber 30C of the interior case 30 and the inside of the cooling unit portion 15 are communicated with each other through the case side insertion hole 30D and the board side insertion hole 50B. The refrigerant tube 13 that connects the cooler 11 and the compressor 12 is inserted through the case-side insertion hole 30D and the board-side insertion hole 50B.

<About the outer case 60>
As shown in FIGS. 1 to 4, the outer case 60 is made of a steel plate and is formed in a substantially rectangular box shape that is open to the front side and the lower side. The outer case 60 is assembled to the heat insulating case 40 so as to cover the heat insulating case 40 from the left and right sides, the upper side, and the rear side. As a result, the outer case 60 is supported by the skeleton frame 20 via the heat insulating case 40. Further, the exterior case 60 is in close contact with the cushioning members 54 of the side heat insulating boards 41L and 41R, the upper heat insulating board 42, and the rear heat insulating board 44 in the heat insulating case 40. As a result, the heat insulating case 40 is integrated with the skeleton frame 20 and the outer case 60 in a state of being sandwiched between them.

<About the door 70>
As shown in FIGS. 1 to 3, the door 70 is formed in a substantially rectangular plate shape with the front-rear direction being the plate thickness direction. The right end of the door 70 is rotatably connected to the heat insulating box body 19 via a hinge (not shown). Specifically, the door 70 is rotatably connected to the opening of the heat insulating box body 19 with the vertical direction as the axial direction. As a result, the opening portion 30A of the cold storage chamber 30B is opened and closed by the door 70.

A door heat insulation board 72 is provided inside the door 70, and the door heat insulation board 72 is configured similarly to each heat insulation board of the heat insulation case 40 in the heat insulation box body 19. Specifically, the door heat insulation board 72 includes a urethane heat insulation panel 50, a vacuum heat insulation panel 52 held by the urethane heat insulation panel 50, a pair of cushioning members 54 (not shown), and a cover member 56 (not shown). And are included. The door 70 has an interior panel 74 and an exterior panel 76, and the door 70 is assembled so that the door heat insulation board 72 is sandwiched between the interior panel 74 and the exterior panel 76.

(Action and effect)
Next, the operation and effect of this embodiment will be described.
The heat insulating box body 18 in the refrigerator 10 configured as described above has an inner case 30 formed in a rectangular parallelepiped box shape that is open to the front side, and the inside of the inner case 30 is configured as a cold room 30B. ing. An outer case 60 is provided outside the inner case 30, and the outer case 60 constitutes the outer shell of the heat insulating box body 18.

Here, a heat insulating case 40 is provided between the inner case 30 and the outer case 60. The heat insulating case 40 covers the side walls 32L and 32R, the upper wall 33, the lower wall 34, and the rear wall 31 of the interior case 30 from the outside, side heat insulating boards 41L and 41R, an upper heat insulating board 42, a lower heat insulating board 43, and The rear heat insulating board 44 is included. Therefore, the side heat insulation boards 41L and 41R, the upper heat insulation board 42, the lower heat insulation board 43, and the rear heat insulation board 44, which are formed in advance, are arranged on the outside of the interior case 30 and assembled as the heat insulation case 40, thereby forming a heat insulation box. The body 18 can be manufactured. Thereby, the heat insulating box body described in the background art, in which a space between the inner case and the outer case is foam-filled with a heat insulating material such as hard urethane foam (hereinafter, this heat insulating box body will be referred to as “comparative example heat insulating box body”). It is not necessary to have equipment for foaming and filling a heat insulating material such as rigid urethane foam. Further, it is not necessary to inspect whether or not a heat insulating material such as hard urethane foam is filled in the space between the inner case and the outer case as in the heat insulating box of the comparative example. Therefore, it is possible to suppress an increase in the manufacturing cost of the heat insulating box body 18 and eventually suppress an increase in the manufacturing cost of the refrigerator 10.

Further, the heat insulating case 40 is mainly composed of a vacuum heat insulating panel 52, and the vacuum heat insulating panel 52 has higher heat insulating performance than the foamed and filled hard urethane foam or the like used in the heat insulating box of the comparative example. .. Therefore, even if the wall thickness of the heat insulating case 40 is relatively thin, the heat insulating performance of the heat insulating case 40 can be made equal to that of the heat insulating box of the comparative example. Thereby, when the outer size of the heat insulating box 18 of the present embodiment and the outer size of the heat insulating box of the comparative example are the same, the volume ratio (storage volume/outer volume) of the heat insulating box 18 is the heat insulating box of the comparative example. It can be higher than the body volume ratio. Therefore, the refrigerator 10 having a high volume ratio can be provided.

Further, the skeleton frame 20 is provided between the inner case 30 and the outer case 60. Therefore, the rigidity of the heat insulating box body 18 can be ensured even if the respective heat insulating boards of the heat insulating case 40 cover the respective wall portions of the interior case 30.
That is, in the heat insulating box of the comparative example, the heat insulating material is foamed between the inner case and the outer case, so that the heat insulating material is integrally formed with the inner case and the outer case. For this reason, in the heat insulating box of the comparative example, the rigidity of the heat insulating box can be made relatively high.
On the other hand, in the heat insulating box 18 of the present embodiment, as described above, the heat insulating case 40 in which a plurality of heat insulating boards are assembled is provided between the inner case 30 and the outer case 60. Therefore, each heat insulating board of the heat insulating case 40 is not integrally formed with the inner case 30 and the outer case 60. Thereby, the rigidity of the heat insulating box 18 may be lower than that of the heat insulating box of the comparative example.
Here, in the heat insulating box body 18 of the present embodiment, the skeleton frame 20 is provided between the inner case 30 and the outer case 60. The inner case 30 is supported by the skeleton frame 20, and the outer case 60 is supported by the skeleton frame 20 via the heat insulating case 40. As a result, the skeleton frame 20 can ensure the rigidity of the entire heat insulating box body 19 (heat insulating box body 18) and, in turn, the rigidity of the refrigerator 10.

Further, the skeleton frame 20 is formed into a rectangular parallelepiped frame shape by joining a plurality of frame members 22 made of a long angle steel material. Therefore, the weight of the skeleton frame 20 can be reduced as compared with the case where the skeleton frame 20 is formed of a plurality of steel plates and formed into a rectangular parallelepiped box shape. Therefore, even if the skeleton frame 20 is provided in the heat insulating box 18, it is possible to reduce the weight of the heat insulating box 18 and further reduce the weight of the refrigerator 10.
Further, by forming the skeleton frame 20 into a rectangular parallelepiped frame shape, the skeleton frame 20 has a window portion 20C surrounded by a frame member 22. Therefore, by utilizing the window portion 20C of the skeleton frame 20, each heat insulating board can be arranged close to each wall portion of the interior case 30. As a result, it is possible to enhance the heat insulation effect of the heat insulation boards 30B in each heat insulation board.

In addition, each heat insulating board (side heat insulating boards 41L and 41R, upper heat insulating board 42, lower heat insulating board 43, and rear heat insulating board 44) is arranged on the urethane heat insulating panel 50 and one side of the urethane heat insulating panel 50 in the plate thickness direction. The vacuum heat insulating panel 52 and the urethane heat insulating panel 50 and the buffer member 54 sandwiching the vacuum heat insulating panel 52 from both sides in the thickness direction are included. Therefore, the vacuum heat insulating panel 52 having a high heat insulating effect can be provided on each heat insulating panel while the urethane heat insulating panel 50 functions as a reinforcing member for each heat insulating board. As a result, the thickness of each heat insulating board can be made relatively thin while suppressing the deformation of the vacuum heat insulating panel 52 by the urethane heat insulating panel 50. Therefore, it is possible to suppress the increase in size of the heat insulating box 18 and, in turn, suppress the increase in size of the refrigerator 10.

Further, the cushioning member 54 sandwiches the urethane heat insulation panel 50 and the vacuum heat insulation panel 52 from both sides in the thickness direction. Therefore, it is possible to prevent the powder generated from the urethane heat insulating panel 50 from scattering to the outside of each heat insulating board.
Further, in each heat insulating board, the cover member 56 covers the outer peripheral portion of the urethane heat insulating panel 50. Therefore, similarly to the above, it is possible to suppress the powder generated from the urethane heat insulating panel 50 from scattering to the outside of each heat insulating board.

The cover member 56 of each heat insulation board is made of a cushion material. Therefore, the cover member 56 forming the outer peripheral portion of each heat insulation board is configured to be expandable and contractible in the thickness direction thereof. Thereby, even if a dimensional error due to processing accuracy occurs in each heat insulating board constituting the heat insulating case 40, the dimensional error can be absorbed by the cover member 56 to assemble the heat insulating case 40. More specifically, even if a dimensional error occurs in each of the side heat insulating boards 41L and 41R, the upper heat insulating board 42, the lower heat insulating board 43, and the rear heat insulating board 44, the cover member 56 is deformed to deform the heat insulating boards. The heat insulating case 40 can be assembled in a state where the heat insulating boards are closely attached without any gap. Therefore, the heat insulating performance of the heat insulating case 40 can be effectively improved.

Further, the urethane heat insulating panel 50 is integrally formed with a holding rib 50A protruding to one side in the plate thickness direction. The vacuum heat insulating panel 52 is arranged on one side of the urethane heat insulating panel 50 in the plate thickness direction, the outer peripheral portion of the vacuum heat insulating panel 52 is engaged with the holding rib 50A, and the vacuum heat insulating panel 52 is held by the holding rib 50A. Has been done. Accordingly, the vacuum heat insulating panel 52 can be held by the urethane heat insulating panel 50 while the position of the vacuum heat insulating panel 52 with respect to the urethane heat insulating panel 50 is determined by the holding rib 50A. Therefore, the assembling property of each heat insulating board (side heat insulating boards 41L and 41R, upper heat insulating board 42, lower heat insulating board 43, rear heat insulating board 44) can be improved.

Further, at least one of the fitting convex portion 45 and the fitting concave portion 46 is formed on the outer peripheral portion of each heat insulating board (side heat insulating boards 41L and 41R, upper heat insulating board 42, lower heat insulating board 43, rear heat insulating board 44). ing. Then, by fitting the fitting convex portion 45 into the fitting concave portion 46 in the heat insulating boards to be assembled with each other, the heat insulating boards are assembled with each other, and the heat insulating case 40 is assembled outside the interior case 30. Thereby, the assembling property of the heat insulating case 40 can be improved.

Further, in the heat insulation box 18, a door heat insulation board 72 is arranged inside the door 70. Therefore, in the door 70 as well, similarly to the above, there is no need for equipment for foaming and filling a heat insulating material such as hard urethane foam. Therefore, it is possible to further suppress an increase in the manufacturing cost of the heat insulating box 18.

Further, the refrigerator 10 of the present embodiment is configured by the cooling unit portion 15 that constitutes the lower end portion of the refrigerator 10 and the heat insulating box body 18 that constitutes the upper portion of the refrigerator 10 and functions as a cold insulation portion. Therefore, by appropriately setting the vertical dimension of the heat insulating box 18, the refrigerators 10 having different capacities can be easily manufactured.

(Modification of the heat insulation box 18)
Next, a modified example of the heat insulating box 18 will be described with reference to FIGS. 7 and 8. The modified example of the heat insulating box 18 has the same configuration as that of the present embodiment except for the following points. Note that, in FIGS. 7 and 8, members configured in the same manner as in the present embodiment are designated by the same reference numerals. 7 shows a state in which the outer case 60 is removed from the heat insulating box body 19 of the heat insulating box body 18, and FIG. 8 shows a state in which the heat insulating box body 19 shown in FIG. 7 is disassembled.

As shown in these drawings, in the present modification, the frame member 22 of the skeleton frame 20 is made of a square steel material having a rectangular cross section and a hollow shape. Further, both longitudinal ends of each frame member 22 are connected by an angle 24 having an L-shaped plate shape, so that the skeleton frame 20 is formed in a rectangular parallelepiped frame shape (see enlarged portion A of FIG. 8). As a result, the rigidity of the skeleton frame 20 as a whole is increased.

Further, in this modification, the rear wall 31, the side walls 32L and 32R, the upper wall 33, and the lower wall 34 of the inner case 30 are separately formed, and the sides of these wall portions are joined to each other to form the inner case. 30 is formed in the shape of a rectangular parallelepiped box opened to the front side. As a result, the inner case 30 can be manufactured at a lower cost without manufacturing a large mold as compared with the case where the inner case 30 is integrally formed by injection molding or the like.

In addition, in this modification, in each of the heat insulating boards (the side heat insulating boards 41L and 41R, the upper heat insulating board 42, the lower heat insulating board 43, and the rear heat insulating board 44) constituting the heat insulating case 40 in the present embodiment, the inside ( The cushioning member 54, the urethane heat insulating panel 50, and the cover member 56 on the inner case 30 side are omitted. That is, these heat insulating boards are constituted by the vacuum heat insulating panel 52 and the outer cushioning member 54.
Further, these heat insulation boards are not assembled with each other, but are attached to the respective wall portions (rear wall 31, side walls 32L and 32R, upper wall 33, and lower wall 34) of the interior case 30.

The inner case 30 is housed and supported in the case housing portion 20B of the skeleton frame 20. In addition, each of the side heat insulating boards 41L and 41R, the upper heat insulating board 42, the lower heat insulating board 43, and the rear heat insulating board 44 is arranged in the window portion 20C of the skeleton frame 20 and is surrounded by the frame member 22. There is. Here, the thickness of each heat insulating board is set so that each heat insulating board does not project outward from the frame member 22 of the skeleton frame 20. That is, the thickness of each heat insulating board is set to be smaller than the length of each side of the frame member 22 as viewed in the longitudinal direction of the frame member 22.

Further, although not shown, the exterior case 60 is assembled to and supported by the skeleton frame 20 so as to cover the skeleton frame 20 from the left and right sides, the upper side, and the rear side.

Also in this modified example, the side heat insulating board 41L that covers the side walls 32L and 32R, the upper wall 33, the lower wall 34, and the rear wall 31 of the inner case 30 from the outside between the inner case 30 and the outer case 60. , 41R, an upper heat insulating board 42, a lower heat insulating board 43, and a rear heat insulating board 44. Therefore, the side heat insulation boards 41L and 41R, the upper heat insulation board 42, the lower heat insulation board 43, and the rear heat insulation board 44, which are formed in advance, are arranged on the outside of the inner case 30 and attached to the respective wall portions of the inner case 30. By doing so, the heat insulating box 18 can be manufactured. Therefore, also in the present modification, as in the present embodiment, there is no need for equipment for foaming and filling a heat insulating material such as rigid urethane foam. Therefore, an increase in the manufacturing cost of the heat insulating box 18 can be suppressed.

Further, the skeleton frame 20 is provided between the inner case 30 and the outer case 60. Therefore, also in this modification, the rigidity of the entire heat insulating box 18 can be ensured, as in the present embodiment.

In addition, in this modification, each heat insulating board (side heat insulating boards 41L and 41R, upper heat insulating board 42, lower heat insulating board 43, and rear heat insulating board 44) is configured by a vacuum heat insulating panel 52 and an outer cushioning member 54. At the same time, it is attached to each wall of the interior case 30 (rear wall 31, side walls 32L and 32R, upper wall 33, and lower wall 34). Therefore, it is possible to reduce the thickness of each heat insulating board while reinforcing each heat insulating board by the interior case 30. As a result, the capacity of the cold storage chamber 30B of the interior case 30 can be set to be larger than that in the present embodiment.

Further, in this modified example, in a state of being supported by the skeleton frame 20 of the interior case 30, each heat insulating board of the side heat insulating boards 41L and 41R, the upper heat insulating board 42, the lower heat insulating board 43, and the rear heat insulating board 44 has a skeleton. It is arranged in the window portion 20C of the frame 20. As a result, the heat insulating boards can be arranged by utilizing the window portion 20C of the skeleton frame 20. Therefore, the capacity of the cold storage chamber 30B of the interior case 30 can be set to be larger.

In the present embodiment, the skeletal frame 20 is provided inside the heat insulating case 40 (side heat insulating boards 41L and 41R, upper heat insulating board 42, lower heat insulating board 43, and rear heat insulating board 44). A skeleton frame configured similarly to the skeleton frame 20 may be provided on the outer side of the frame 40. That is, the skeleton of the heat insulating box 18 may have a double structure. As a result, the rigidity of the heat insulating box 18 can be further increased.

Further, in the present embodiment (including modified examples), the inner case 30 is made of a resin material, but the inner case 30 may be made of, for example, a stainless plate material or the like. Thereby, the antibacterial property of the interior case 30 can be improved. Moreover, the rigidity of the heat insulating box 18 can be effectively increased by the skeleton frame 20 and the interior case 30.

Further, although the heat insulating box 18 is applied to the refrigerator 10 in the present embodiment, the heat insulating box 18 may be applied to the freezer. In addition, the heat insulating box 18 may be applied to a cool box having no refrigeration cycle. In this case, the opening direction of the opening portion 30A of the inner case 30 may be appropriately changed in accordance with the installation direction of the freezer or the cool box.

18 Insulation box 20 Skeleton frame (skeleton part)
22 Frame member 30 Interior case 31 Rear wall (wall part of interior case)
32L side wall (wall part of interior case)
32R Side wall (wall of interior case)
33 Upper wall (wall of interior case)
34 Lower wall (wall of interior case)
41L side insulation board (insulation board)
41R Side insulation board (insulation board)
42 Upper insulation board (insulation board)
43 Lower insulation board (insulation board)
44 Rear insulation board (insulation board)
45 Fitting convex part 46 Fitting concave part 50 Urethane insulation panel (base insulation panel)
50A holding rib (holding part)
52 vacuum insulation panel 54 cushioning member 60 exterior case 70 door

Claims (7)

A rectangular parallelepiped box-shaped interior case having an opening,
An outer case that is arranged outside the inner case and covers the inner case,
A door that opens and closes the opening,
A skeleton portion provided between the inner case and the outer case and supporting the inner case and the outer case;
A plurality of heat insulating boards provided between the inner case and the outer case and covering the wall portion of the inner case from the outside,
Insulated box body with. The heat insulating box body according to claim 1, wherein the skeleton portion is formed of a plurality of elongated frame members and is formed in a rectangular parallelepiped frame shape. The insulation board is
A base heat insulation panel that forms the base of the heat insulation board,
A vacuum heat insulating panel arranged on one side in the plate thickness direction of the base heat insulating panel,
A cushioning member that covers the base heat insulating panel and the vacuum heat insulating panel from both sides in the thickness direction,
The heat insulation box body according to claim 1 or 2, which is configured to include. The heat insulating box body according to claim 3, wherein the base heat insulating panel is provided with a holding portion that engages with an outer peripheral portion of the vacuum heat insulating panel to hold the vacuum heat insulating panel. The plurality of heat insulating boards are assembled in a rectangular parallelepiped box shape opened in the same direction as the opening direction of the interior case,
In the outer peripheral portion of the heat insulating board, when viewed in the plate thickness direction of the heat insulating board, a fitting convex portion that is projected to the outside of the heat insulating board, and a fitting concave portion that is opened to the outside of the heat insulating board, At least one of the
The heat insulation box body according to any one of claims 1 to 4, wherein, in the heat insulation boards assembled with each other, the fitting protrusion is fitted inside the fitting recess. The insulation board is
A vacuum heat insulation panel, one side of which is attached to the wall of the interior case,
A cushioning member attached to the other side surface of the vacuum heat insulating panel,
The heat insulation box body according to claim 1 or 2, which is configured to include. An insulating box body according to any one of claims 1 to 6,
A refrigeration cycle configured to include a cooler arranged inside the heat insulating box, and cooling the inside of the heat insulating box,
Refrigerator equipped with.

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