TW201441566A - Method of manufacturing heat insulation box of refrigerator and refrigerator - Google Patents

Abstract

A refrigerator of the invention includes an outer cabinet, an inner cabinet arranged in interior of the outer cabinet, and vacuum insulating panels arranged between the outer cabinet and the inner cabinet, wherein the vacuum insulating panels abutting each other are configured in a manner of contacting each other at corner portions of the outer cabinet and the inner cabinet.

Description

Refrigerator heat insulating box manufacturing method and refrigerator

Embodiments of the present invention relate to a method of manufacturing a heat insulating box for a refrigerator and a refrigerator.

In recent years, in the heat insulating box of the refrigerator, a vacuum insulation panel is provided as a heat insulating material instead of the conventional foaming urethane or the like.

[Previous Technical Literature] [Patent Literature]

[Patent Document 1] Japanese Patent Laid-Open No. Hei 4-260780

[Patent Document 2] Japanese Patent Laid-Open No. Hei 6-147744

[Patent Document 3] Japanese Patent Laid-Open Publication No. 2006-90649

Generally, the vacuum insulation panel is formed in a plate shape. Therefore, the heat insulation box provided with the vacuum heat insulation board is considered as follows. In other words, first, each of the heat insulating walls constituting the heat insulating box is divided into a plurality of states, and then divided into a plurality of partitions. The hot wall is formed in a box shape.

However, the heat insulating box having such a configuration has the following problems. First, the outer contour of the heat insulating box includes an outer plate portion constituting an outer side surface of each heat insulating wall. Therefore, the outer contour of the heat insulating box is easy to generate a gap at the interface of each outer plate portion. Further, external moisture flows in from the gap, and there is a problem that adversely affects the inside of the heat insulating box.

Secondly, the heat insulating box having the above configuration is likely to have a gap at the corner portion of the heat insulating box which is a connecting portion of the heat insulating walls. Therefore, there is a possibility that the cold air in the refrigerator leaks from the gap and the heat insulating property of the heat insulating box is lowered.

Therefore, a method for manufacturing a heat insulating box for a refrigerator and a refrigerator which can reduce the interface of the outer panel portion and ensure the heat insulating performance of the corner portion of the heat insulating box are provided.

In the method for manufacturing a heat insulating box for a refrigerator according to the embodiment, the heat insulating wall body is manufactured by the following steps (1) to (3), wherein the heat insulating wall body includes a heat insulating wall of each of the heat insulating walls and The other two insulated walls on both sides of the insulating wall are connected to the remaining insulating wall body, and the heat insulating box of the refrigerator includes a left insulating wall. a right heat insulating wall, an upper heat insulating wall, a lower heat insulating wall, and a rear heat insulating wall, and the front surface is opened in a rectangular box shape, and each of the heat insulating walls has a vacuum insulation panel between the outer plate portion and the inner plate portion .

Step (1): using a flat plate-shaped plate member having a region corresponding to each of the heat insulating wall and the other two heat insulating walls, and the plate member corresponding to each of the outer plate portions The inner surface of the region is adhered to one surface of each of the vacuum insulation panels, and is adjacent to each boundary portion of the region corresponding to each of the outer panel portions An end portion of a vacuum insulation panel in the vacuum insulation panel is aligned with the boundary portion, and an end portion of the other vacuum insulation panel is separated from the boundary portion by a distance at which the plate member is at the boundary portion The minimum distance of the bending is such that one surface of each of the vacuum insulation panels is bonded to the region corresponding to each of the outer panel portions.

Step (2): Before or after the execution of the above step (1), the inner plate portion is adhered to a surface of the vacuum insulation panel bonded to the step (1) opposite to the one surface.

Step (3): After performing the above steps (1) and (2), the plate member is bent inward at the respective boundary portions.

The refrigerator according to the embodiment includes an outer case, an inner case provided inside the outer case, and a vacuum insulation panel provided between the outer case and the inner case. The adjacent vacuum insulation panels of the vacuum insulation panels are disposed such that the outer casing and the corners of the inner casing are in contact with each other.

1‧‧‧ refrigerator

2‧‧‧Insulation box

2S‧‧‧Insulation wall body

3‧‧‧ revolving door on the left

3a, 3b, 4a, 4b‧‧‧ hinges

4‧‧‧ revolving door on the right

5~8‧‧‧Withdrawal door

9, 9A, 9B‧‧‧ left wall

9U, 10U, 11U‧‧‧ one

9Ut, 9Ut1, 10Ut, 10Ut1‧‧‧ size

10, 10A, 10B‧‧‧ right heat insulation wall

11‧‧‧Upper insulation wall

11a‧‧‧ concave

11b‧‧‧ machine room

11c‧‧‧Mechanical room cover

12‧‧‧Bottom insulation wall

13‧‧‧Inside insulation wall

14, 111‧‧‧ outer box

14A‧‧‧ Left outer panel

14A1‧‧‧Equivalent to the area of the left outer panel

14Aa, 15As, 15Bs, 15Cs1, 15Cs2‧‧‧ bends

14A2‧‧‧Return section

14A3‧‧‧ Front surface

14B‧‧‧Right outer panel

14B1‧‧‧ is equivalent to the area of the right outer plate

14C‧‧‧Upper Board

14C1‧‧‧ is equivalent to the area of the upper outer plate

14D‧‧‧ Lower outer board

14E‧‧‧After the outer board

15, 112‧‧‧ inner box

15A, 15A2‧‧‧ left inner plate

15Aa‧‧‧Upper side plate

15Ab‧‧‧ lower side plate

15B‧‧‧Right inner panel

15C‧‧‧Upper Board

15C1‧‧‧Connecting Department

15C2‧‧‧ rib

15D‧‧‧Under the inner plate

15E‧‧‧ inside side panel

15u‧‧‧孔部

16, 130, 131, 132, 133‧‧ ‧ vacuum insulation panels

16A‧‧‧Left unit board

16Ag, 16Bg, 16Cg‧‧‧ outer surface

16B‧‧‧right unit board

16Bn, 16Cn‧‧‧ inner surface

16C‧‧‧Upper unit board

16E‧‧‧Rear unit board

17, 17a‧‧‧L

18‧‧‧Water Department

19‧‧‧Substrate

20‧‧‧ inclusion body

21‧‧‧ Front end connecting members

22,23,29‧‧‧soft tape

24‧‧‧Flame urethane

25‧‧‧Links for sheet members

25A, 25A2, 25B‧‧‧ joint parts for sheet members

25a‧‧‧ recess

25b, 31, 44b‧‧‧ Screw insertion hole

26‧‧‧ Fixtures

26a‧‧‧Flange

26c, 30c, 43a‧‧‧ Screw hole

27, 45, 62, 63, 99‧‧‧ screws

28‧‧‧Foam styrene

30‧‧‧Shelf support

30a‧‧‧ Body Department

30b‧‧‧Shelf Support

30d‧‧‧ fisheye hole

30e‧‧‧Fin

31a‧‧‧The Peripheral Department

32‧‧‧Threaded rivets

32a‧‧‧ screw head

33, 34‧‧‧ rail mounting tools

35, 36‧‧‧ partition wall support

37‧‧‧Back cover mounting

40a, 40b, 40c‧‧‧ shelf support

41a, 41b‧‧‧ rail mounting department

42a, 42b‧‧‧ partition wall support

43‧‧‧ Screw column

44, 46, 52b‧‧‧ reinforcing plate

44a‧‧‧Pin section fitting

51, 52, 53‧ ‧ ‧ beam members

52a‧‧‧ front surface spacer

52c‧‧‧Back compartment cover

52d, 74A, 74B, 74C1, 74C2, 151‧‧‧ insulation materials

54‧‧‧longitudinal members

55‧‧‧1st partition wall

56‧‧‧2nd partition wall

57, 80‧‧ ‧ cold room

58, 82‧‧ ‧ vegetable room

59‧‧‧Small freezer

60‧‧‧ ice making room

61, 81‧‧ ‧ freezer

64‧‧‧Evaporator

71,72‧‧‧Transfer roller

73‧‧‧Supply roller

75‧‧‧ board components

78‧‧‧Cold air duct

90, 91, 100, 101, 140‧‧‧ recessed parts

95, 141‧‧‧ Connecting parts

102‧‧‧Insulation box

113, 113M‧‧‧ metal plates

114, 124‧‧‧ top face

114A‧‧‧The inner surface of the top surface 114

115, 125‧‧‧ left side face

115A‧‧‧The inner surface of the left side face 115

115D, 116D‧‧‧Installation Department

116, 126‧‧‧ right side face

116A‧‧‧The inner surface of the right side face 116

117, 127‧‧‧ bottom part

117A‧‧‧The inner surface of the bottom portion 117

118, 119, 120‧‧ ‧ part of the mountain pleat line

121‧‧‧End of the side section 115

122‧‧‧End of the bottom portion 117

130C, 130F‧‧‧ left end

130D, 130G‧‧‧ right end

130M‧‧‧ inner surface of vacuum insulation panel 130

130N, 130H‧‧‧ recess of vacuum insulation panel 130

130K, 132K‧‧‧ end

Upper end of 131F‧‧

The inner side of the 131N‧‧‧ vacuum insulation panel 131

131R‧‧‧lower end of vacuum insulation panel 131

131T‧‧‧Upper end of vacuum insulation panel 131

132F‧‧‧The upper end of the vacuum insulation panel 132 on the right side

132G‧‧‧Bottom

132J, 132M‧‧‧ recess of vacuum insulation panel 132

132N‧‧‧ Inside of the vacuum insulation panel 132

132R‧‧‧lower end of vacuum insulation panel 132

132T‧‧‧Upper end

133C, 133F‧‧‧ left end

133D, 133G‧‧‧ right end

133M‧‧‧ inner surface of vacuum insulation panel 133

145‧‧‧ Relaxed part

150‧‧‧Shape section

155, 156‧‧‧ openings

170‧‧‧ core material

171‧‧‧ laminated film

172, 173‧‧ ‧ sealing part

199‧‧‧covering components

C, CN‧‧‧ corner

T‧‧‧ size

Ia, Ib, Ic, Id‧‧‧ integral molded goods

K1, K2‧‧‧ borders

P, V‧‧‧ arrows

Sa, Sb, Sc‧‧‧ sheet components

Sk‧‧‧ thickness size

Sk1‧‧‧ prescribed distance

SS‧‧‧ gap

W1, W2, W3‧‧‧ integrated

Ws‧‧‧ workbench

Fig. 1 is a perspective view of the refrigerator according to the first embodiment as seen from above.

Observe the perspective view of the heat insulation box from below.

Fig. 2 is a perspective view of the heat insulating box viewed from above.

Fig. 3 is a perspective view of the heat insulating box viewed from below.

Figure 4 is a cross-sectional plan view of the heat insulating box.

Fig. 5 is an exploded perspective view of the left heat insulating wall.

Fig. 6 is a perspective view of the upper inner plate portion as viewed from below.

Fig. 7 is a perspective view of the inner plate portion as viewed from above.

Fig. 8 is an enlarged view of a portion K of Fig. 4;

Fig. 9 is a cross-sectional plan view showing a corner portion of the left heat insulating wall and the rear side heat insulating wall.

Fig. 10 is a longitudinal sectional front view showing a corner portion of the left heat insulating wall and the upper heat insulating wall.

Figure 11 is an exploded perspective view of the fixture and the left inner panel

Fig. 12 is a perspective view showing a mounted state of the fixture with respect to the left inner panel portion.

Fig. 13 is a longitudinal sectional side view showing a state in which the fixture is mounted with respect to the left inner panel portion.

Fig. 14 is a vertical cross-sectional side view showing a state in which a connecting plate is attached to a fixture.

Fig. 15 is a cross-sectional plan view showing a connecting portion of the beam member and the left side heat insulating wall.

Figure 16 is a perspective view of the shelf support from the back.

Figure 17 is an exploded longitudinal cross-sectional side view of the shelf support, the left inner panel, and the screw.

Fig. 18 is a vertical cross-sectional side view showing a mounted state of the shelf support.

FIG. 19 is a perspective view of the heat insulating box of the refrigerator in the second embodiment as seen from below.

Fig. 20 is a perspective view of the heat insulating box viewed from above.

Fig. 21 is an exploded perspective view of the left heat insulating wall.

Figure 22 is a cross-sectional plan view of a corner portion of the left heat insulating wall and the rear heat insulating wall.

Figure 23 is a vertical cross-sectional side view of the support portion of the shelf.

Figure 24 is a vertical cross-sectional side view of the shelf support portion in a position different from that of Figure 23 .

Fig. 25 is an exploded perspective view of the shelf supporting portion and the reinforcing plate viewed from the back side.

Figure 26 is a vertical cross-sectional side view of the partition wall support portion.

Figure 27 is a perspective view of a partition support portion.

28 is a perspective view of the heat insulating box of the refrigerator according to the third embodiment as seen from above. Figure.

Fig. 29 is an exploded perspective view of the left heat insulating wall.

Fig. 30 is a longitudinal sectional side view showing a fourth embodiment of the shelf support member;

Figure 31 is a vertical cross-sectional side view showing the portion of the shelf support member in an exploded state.

Fig. 32 is a longitudinal sectional front view showing a heat insulating box according to a fifth embodiment;

Figure 33 is a cross-sectional plan view of the cutting line X33-X33 of Figure 32.

Fig. 34 is a vertical cross-sectional side view showing the integrated body of the right outer plate portion and the right unit plate in the manufacturing step.

Fig. 35 is a view for explaining application of an adhesive to a roll coating method.

Figure 36 is a diagram (part 1) showing the manufacturing steps.

Figure 37 is a diagram (part 2) showing the manufacturing steps.

Fig. 38 is a view (No. 3) showing a manufacturing step.

Fig. 39 is a view corresponding to Fig. 36 showing a sixth embodiment.

Fig. 40 is a view corresponding to Fig. 38.

Fig. 41 is a longitudinal sectional view showing a refrigerator according to a seventh embodiment.

Fig. 42(A) is a developed view showing the outer surface and the side surface of the metal plate constituting the outer casing.

Fig. 42 (B) is a perspective view showing an outer casing formed by bending a metal plate shown in Fig. 42 (A).

43(A) and 43(B) are views showing a schematic structure of a vacuum heat insulating panel.

Fig. 44 is a view showing an eighth embodiment;

Fig. 45 is a view showing a ninth embodiment.

Fig. 46 is a view showing a tenth embodiment.

47(A), 47(B), and 47(C) show the eleventh embodiment. Figure.

48(A), 48(B), and 48(C) are diagrams showing a twelfth embodiment.

49(A), 49(B), and 49(C) are diagrams showing another embodiment.

50(A) and 50(B) are diagrams showing another embodiment.

51(A), 51(B), and 51(C) are views showing a method of manufacturing the heat insulating box.

Hereinafter, the refrigerator will be described in various embodiments. In the respective embodiments, the substantially common portions are denoted by the same reference numerals, and the detailed description thereof will be omitted.

(First embodiment)

First, the refrigerator of the first embodiment will be described with reference to Figs. 1 to 18 . The refrigerator 1 shown in Fig. 1 includes a heat insulating box 2. An opening is formed in the front surface of the heat insulating box 2. On the front surface side of the heat insulating box 2, a revolving door 3 on the left side and a revolving door 4 on the right side, and a plurality of drawer doors 5 to 8 are provided. Each of the doors 3 to 8 has a heat insulating material (not shown) inside. That is, each of the doors 3 to 8 is a heat insulating door. The revolving door 3 on the left side is provided to be rotatable about a pair of upper and lower hinge portions 3a and 3b provided on the left side of the heat insulating box 2. The revolving door 4 on the right side is provided to be rotatable about a pair of upper and lower hinges 4a and 4b provided on the right side of the heat insulating box 2.

The heat insulating box 2 is configured by connecting the left heat insulating wall 9 , the right heat insulating wall 10 , the upper heat insulating wall 11 , the lower heat insulating wall 12 , and the back heat insulating wall 13 . Left side insulation The wall 9, the right heat insulating wall 10, the upper heat insulating wall 11, the lower heat insulating wall 12, and the rear heat insulating wall 13 are unit heat insulating walls, respectively.

As shown in FIGS. 2 and 3 , the heat insulating box 2 includes a beam member 51 , a beam member 52 , a beam member 53 , a stringer member 54 , a first partition wall 55 , and a second partition wall 56 . The cross member 51, the cross member 52, and the cross member 53 are provided in the lateral direction and the left and right edge portions of the front opening of the heat insulating box 2. The stringer member 54 is provided in a middle portion of the beam member 52 and the beam member 53 and is connected to the beam member 52 and the beam member 53 in the vertical direction. The first partition wall is for spacing the storage compartment and is provided on the rear side of the beam member 51. The second partition wall 56 is for partitioning the storage compartment and is provided on the rear side of the cross member 52.

The refrigerator 1 includes a refrigerator compartment 57 as a storage compartment, a vegetable compartment 58, a small freezer compartment 59, an ice making compartment 60, and a freezing compartment 61 inside the heat insulating box 2. The refrigerator compartment 57 is provided above the first partition 55. The vegetable compartment 58 is provided between the first partition 55 and the second partition 56. The small freezer compartment 59 is a space between the beam member 52 and the beam member 53, and is provided on the right side of the stringer member 54 as viewed from the front. The ice making chamber 60 is a space between the beam member 52 and the beam member 53, and is disposed on the left side of the stringer member 54 as viewed from the front. The freezing compartment 61 is provided below the small freezing compartment 59 and the ice making compartment 60.

The revolving door 3 and the revolving door 4 open or close the refrigerating chamber 57. The draw-out door 5 opens or closes the vegetable compartment 58. A vegetable container (not shown) is provided on the back side of the drawer door 5. The draw-out door 6 opens or closes the small freezer compartment 59. A frozen product storage container (not shown) is provided on the back side of the drawer door 6. The draw-out door 7 opens or closes the ice making chamber 60. An ice receiving container (not shown) is provided on the back side of the drawer door 7. The draw-out door 8 opens or closes the freezing compartment 61. There is an unillustrated on the back side of the draw-out door 8. The frozen product storage container shown.

The second partition wall 56 thermally insulates the vegetable compartment 58, the small freezer compartment 59, and the ice making compartment 60. The temperature difference between the vegetable compartment 58, the small freezer compartment 59, and the ice making compartment 60 is large. Therefore, the second partition wall 56 is formed of a heat insulating material such as foamed styrene or foaming urethane. On the other hand, the first partition wall 55 partitions the refrigerating chamber 57 from the vegetable compartment 58. The temperature difference between the refrigerating compartment 57 and the vegetable compartment 58 is relatively small. Therefore, the first partition 55 is made of, for example, a plate made of synthetic resin.

As shown in FIGS. 2 to 4, the heat insulating box 2 includes an outer box 14 and an inner box 15. The outer box 14 constitutes the overall outer contour of the heat insulating box 2. The outer casing 14 includes a left outer plate portion 14A, a right outer plate portion 14B, an upper outer plate portion 14C, a lower outer plate portion 14D, and a rear outer plate portion 14E which are differently configured. Each of the outer plate portions 14A, 14B, 14C, 14D, and 14E is made of a steel plate. The left outer plate portion 14A constitutes the left outer surface of the heat insulating box 2. The right outer plate portion 14B constitutes the right outer surface of the heat insulating box 2. The upper outer plate portion 14C constitutes the upper outer surface of the heat insulator 2. The lower outer panel surface 14D constitutes the lower outer surface of the heat insulating box 2. The rear outer panel portion 14E constitutes a rear outer side surface of the heat insulating box 2. The left outer plate portion 14A and the right outer plate portion 14B are configured to be bilaterally symmetrical.

The inner box 15 includes a plurality of different inner body portions, that is, five inner panel portions, that is, the left inner panel portion 15A, the right inner panel portion 15B, the upper inner panel portion 15C, the lower inner panel portion 15D, and the inner side. Plate portion 15E. The left inner panel portion 15A constitutes the left inner surface of the heat insulating box 2. The right inner plate portion 15B constitutes the right inner surface of the heat insulating box 2. The upper inner plate portion 15C constitutes an upper inner surface of the heat insulating box 2. The lower inner plate portion 15D constitutes the lower inner surface of the heat insulating box 2. The inner side inner panel portion 15E constitutes the inner side inner surface of the heat insulating box 2.

The left inner plate portion 15A and the right inner plate portion 15B are configured to be bilaterally symmetrical. The left inner plate portion 15A and the right inner plate portion 15B are each made of, for example, acrylonitrile-butadiene-styrene resin. A flat sheet member Sa of synthetic resin such as acrylonitrile-butadiene-styrene resin (ABS resin). In FIG. 5, the fixing member 26, the shelf support 30, the guide rail mounting tool 33, the rail mounting tool 34, the partition support 35, and the partition support 36 are attached to the sheet member Sa in advance. Said.

As also shown in Fig. 6, the upper inner plate portion 15C integrally includes an L-shaped portion 17 that bulges into the reservoir as a bent portion. The upper inner plate portion 15C is an integrally molded product 1a made of a synthetic resin such as an olefin resin. As also shown in Fig. 7, the lower inner plate portion 15D integrally includes the water receiving portion 18 as a bent portion. The lower inner plate portion 15D is an integrally molded product Ib made of a synthetic resin such as an olefin resin. The integrally molded product Ia and the integrally molded product Ib are formed by injection molding or vacuum forming.

The back side inner panel portion 15E includes a flat sheet member Sb made of synthetic resin. Further, the sheet member Sa and the sheet member Sb can be produced by extrusion molding, calender molding, or the like without using a molding die having a special shape. Further, the sheet member Sa and the sheet member Sb may be commercially available flat sheet members.

As shown in FIG. 4, the heat insulating box 2 includes a vacuum heat insulating panel 16. The vacuum insulation panel 16 is disposed between the outer casing 14 and the inner casing 15. The vacuum heat insulating panel 16 includes a left unit panel 16A and a right unit panel 16B which are different bodies, an upper unit panel 16C shown in FIG. 10, a lower unit panel (not shown), and a rear unit panel 16E. The left unit plate 16A, the right unit plate 16B, the upper unit plate 16C, the lower unit plate, and the rear unit plate 16E are unit plates. The basic configurations of the left unit plate 16A, the right unit plate 16B, the upper unit plate 16C, the lower unit plate, and the rear unit plate 16E are common. Therefore, the basic configuration of each unit panel will be described with reference to the left unit panel 16A.

As shown in FIGS. 8 and 9, the left unit panel 16A houses the substrate 19 in An envelope 20 is constructed by decompressing the inside of the envelope by vacuum evacuation. The base material 19 is formed by compressing and curing a laminated material of inorganic fibers such as glass wool to form a plate. The package body 20 includes a metal layer such as an aluminum vapor-deposited layer or an aluminum foil layer in order to obtain gas barrier properties. Each unit panel is generally referred to as a vacuum insulation panel.

As shown in FIG. 5, the left heat insulating wall 9 is a unit heat insulating wall, and includes a left outer plate portion 14A, a left inner plate portion 15A, and a left unit plate 16A. The left unit panel 16A is disposed between the left outer panel portion 14A and the left inner panel portion 15A. Further, the left unit panel 16A and the left outer panel portion 14A, and the left unit panel 16A and the left inner panel portion 15A are bonded together by an adhesive.

As shown in FIG. 8, the heat insulating box 2 includes a connecting member 21 for the front end. The distal end connecting member 21 has heat insulating properties and connects the outer box 14 and the front end portion of the inner box 15. In other words, the distal end connecting member 21 is provided at each of the front end portions of the left heat insulating wall 9 and the right heat insulating wall 10 . Further, each of the distal end connecting members 21 connects the front end portions of the left heat insulating wall 9 and the right heat insulating wall 10, respectively. The front end portion of the left heat insulating wall 9 and the front end portion of the right heat insulating wall 10 are bilaterally symmetrical. Therefore, the configuration of the left heat insulating wall 9 and the right heat insulating wall 10 will be described with reference to the left heat insulating wall 9 .

The left outer plate portion 14A has a bent portion 14Aa. The bent portion 14Aa is located at the front end portion of the left outer panel portion 14A, and is formed to be bent toward the left inner panel portion 15A by a portion extending forward of the left unit panel 16A. The bent portion 14Aa extends to the middle portion in the thickness direction of the left heat insulating wall 9 and does not enter the inside of the heat insulating box 2, that is, the storage chamber side. Thereby, the heat of the outer casing 14 which is the left outer plate portion 14A, that is, the heat of the outside air is suppressed from being transmitted into the storage chamber.

The heat insulating box 2 contains, for example, a soft tape 22 as a heat insulating material. material. The flexible tape 22 is provided in a space portion formed by the front end of the left unit panel 16A, the inner surface of the front end portion of the left outer panel portion 14A, and the inner surface of the distal end connecting member 21. Further, in place of the soft tape 22, foamed styrene may be used.

The right heat insulating wall 10 is also configured similarly to the left heat insulating wall 9 except for the left and right symmetry.

The upper heat insulating wall 11 is configured, for example, as follows. That is, as shown in FIGS. 2 and 10, the upper unit plate 16C is disposed between the upper inner plate portion 15C and the upper outer plate portion 14C, and the upper inner plate portion 15C is bonded to the upper unit plate 16C by an adhesive. Further, the foamed urethane 24 is filled between the upper unit plate 16C and the upper outer plate portion 14C and cured. As shown in FIG. 6, the upper inner plate portion 15C includes an integrally molded product Ia of synthetic resin, and integrally includes an L-shaped portion 17 that bulges into the interior of the reservoir as a bent portion. As shown in FIG. 2, the upper outer plate portion 14C also has an L-shaped portion 17a. Therefore, the entire rear portion of the upper heat insulating wall 11 protrudes downward. That is, the concave portion 11a is formed in the rear portion of the upper heat insulating wall 11. The machine room 11b is constituted by a space behind the concave portion 11a. A compressor or a condenser of the refrigeration cycle is disposed in the machine room 11b.

The interval between the upper unit plate 16C and the upper outer plate portion 14C shown in Fig. 10, that is, between the upper unit plate 16C and the upper outer plate portion 14C, and the portion filled with the foaming urethane 24 is smaller than the upper unit. The thickness of the plate 16C is smaller than the outer diameter of the piping of the refrigeration cycle such as a suction pipe. Thereby, the amount of the foamed urethane 24 used is reduced. Further, in the case of pulling the piping of the refrigeration cycle, the piping may be passed through a portion surrounded by the left end surface of the upper unit panel 16C, the upper end surface of the right unit panel 16A, and the corner portion of the upper outer panel portion 14C in the front-rear direction. Further, the machine room 11b is closed by the machine room cover 11c of Fig. 3.

As shown in FIG. 10, the left end portion of the upper outer plate portion 14C is away from the upper unit plate. The upper surface of the 16C is connected to the left outer plate portion 14A of the left heat insulating wall 9. Similarly, although not shown, the right end portion of the upper outer panel portion 14C is coupled to the right outer panel portion 14B of the right heat insulating wall 10 in a state of being separated from the upper surface of the upper unit panel 16C. The upper inner plate portion 15C has a coupling portion 15C1. The connecting portion 15C1 is provided at both left and right end portions of the upper inner plate portion 15C. The connecting portion 15C1 is for connecting the left inner panel portion 15A and the right inner panel portion 15B as the inner box side walls to the left and right side edge portions of the upper inner panel portion 15C. The front end portion of the coupling portion 15C1 on the left side is coupled to the left inner panel portion 15A by a coupling member (not shown). Similarly, the front end portion of the right connecting portion 15C1 is coupled to the right inner panel portion 15B by a coupling member (not shown).

Here, the connection portion 15C1 on the left side will be described, but the connection portion on the right side is configured in the same manner except for the left-right symmetry. As shown in FIG. 10, a rib 15C2 that protrudes upward is formed inside the front end portion of the coupling portion 15C1. For example, a soft tape 23 is inserted between the rib 15C2 and the left inner panel portion 15A as a heat insulating material leakage preventing member. The space surrounded by the left unit panel 16A, the upper unit panel 16C, and the connecting portion 15C1 from the upper portion to the corner portion of the upper unit panel 16C is filled with, for example, a foamed urethane 24V and cured as a heat insulating material. In this case, the soft tape 23 prevents leakage of the foaming urethane 24 when the foaming urethane 24 is filled.

The lower heat insulating wall 12 is a unit heat insulating wall, and includes a lower outer plate portion 14D, a lower inner plate portion 15D, and a lower unit plate (not shown). A lower unit plate (not shown) is provided between the lower outer plate portion 14D and the lower inner plate portion 15D. Further, the lower unit plate and the lower outer plate portion 14D, and the lower unit plate and the lower inner plate portion 15D are bonded by an adhesive. Further, the lower heat insulating wall 12 can also be configured such that the lower inner plate portion 15D is bonded to the lower unit plate, and the foamed amine base is filled between the lower unit plate and the lower outer plate portion 14D. The acid ester is allowed to cure. On the lower heat insulating wall 12, the lowermost portion of the water receiving portion 18 and the heat insulating box Body 2 is externally connected.

Further, the back side heat insulating wall 13 is also provided with a back side unit board 16E between the rear outer panel portion 14E and the back side inner panel portion 15E, and is bonded to each other by an adhesive. In this case, a structure obtained by appropriately filling and curing the foaming urethane may be added.

The integrally molded product Ia composed of an olefin resin, the integrally molded product Ib, that is, the upper inner plate portion 15C and the lower inner plate portion 15D are subjected to surface processing for roughening the surface of the bonding surface with the unit plate. Thereby, the adhesion between the bonding surface of the upper inner plate portion 15C and the lower inner plate portion 15D with the unit plate and the unit plate is improved. The sheet member Sa and the sheet member Sb composed of the ABS resin, that is, the left inner panel portion 15A, the right inner panel portion 15B, and the inner side inner panel portion 15E have good adhesion to the unit panel.

The connection structure of the left heat insulating wall 9 and the rear heat insulating wall 13 will be described with reference to Figs. 9 and 11 to 14 . As shown in FIG. 9 , the left heat insulating wall 9 and the back heat insulating wall 13 are connected by using the sheet member connecting plate 25 , the fixture 26 , and the like. The web member connecting plate 25 functions as a sheet member connecting member. The fixture 26 functions as a protruding portion that becomes a component different from the sheet member. Further, the connection between the right heat insulating wall 10 and the back heat insulating wall 13 is configured in the same manner as the connection structure between the left heat insulating wall 9 and the back heat insulating wall 13 in addition to the bilateral symmetry. Hereinafter, a configuration of connecting the left heat insulating wall 9 and the back heat insulating wall 13 will be described.

First, the fixture 26 will be described. The fixture 26 is made of a synthetic resin such as ABS resin. The fixture 26 is attached to the left heat insulating wall 9 and the rear heat insulating wall 13. Since the structure of the fixture 26 itself and the attachment structure of the fixture 26 are the same as the left heat insulation wall 9 and the rear heat insulation wall 13, the fixture 26 of the left heat insulation wall 9 is described. The fixture 26 is made of synthetic resin. As shown in Figure 11 and so on, the fixture The 26 has a rectangular shape that is slightly elongated and has a flange portion 26a and a screw hole portion 26c. The flange portion 26a is located on one end side of the fixture 26 and protrudes in the up-down direction. The screw hole portion 26c is a female screw and is formed from the other end surface of the fixture 26 toward the one end side.

The hole member 15u is formed in advance in the sheet member Sa which becomes the left inner plate part 15A. The hole portion 15u is formed by a vertically long rectangular through-sheet member Sa which is slightly larger than the outer shape of the fixture 26. The fixture 26 is bonded to the left unit panel 16A by, for example, an adhesive before the assembly of the left heat insulating wall 9. The fixture 26 is inserted into the hole portion 15u. Then, the left unit panel 16A is bonded to the back surface of the left inner panel portion 15A of the end surface on the left unit panel 16A side of the fixture 26 by an adhesive. In this case, the upper and lower flange-like portions 26a are sandwiched by the left inner plate portion 15A as a sheet member and the left unit plate 16A as a vacuum heat insulating plate. The fixture 26 is attached to the left heat insulating wall 9 and protrudes into the inner box 15. The fixing member 26 is provided at each of the upper and lower portions at the adjacent end portions of the left heat insulating wall 9 and the rear heat insulating wall 13.

As shown in FIGS. 2 and 3, the longitudinal dimension of the web member connecting plate 25 in the vertical direction is substantially the same length as the left inner panel portion 15A. As shown in FIG. 2, FIG. 3, and FIG. 9, the sheet member connecting plate 25 includes a recessed portion 25a and a screw insertion hole portion 25b. The recessed portion 25a is located at both end portions of the sheet member connecting plate 25 in the lateral direction, and is provided corresponding to each of the fixtures 26. As shown in FIG. 9, the screw insertion hole portion 25b is formed in a circular shape penetrating through the central portion of each recess portion 25a. The screw 27 passes through the screw insertion hole portion 25b from the inside of the reservoir, and is screwed into the screw hole portion 26c of the fixture 26. Thereby, the sheet member connecting plate 25 connects the left inner panel portion 15A of the left heat insulating wall 9 and the back inner panel portion 15E of the back side heat insulating wall 13. The sheet member connecting plate 25 is located at a corner of both sides of the refrigerating chamber 57, the vegetable compartment 58, the small freezer compartment 59, the ice making compartment 60, and the freezing compartment 61.

In addition, foamed styrene 28 and a soft tape 29 as a heat insulating material are interposed in the space of the back side space of the sheet member connecting plate 25.

Further, the piping of the refrigeration cycle may also pass through the portion of the foamed styrene 28 in Fig. 9 in the up and down direction.

As shown in FIGS. 1 and 5, the left heat insulating wall 9 and the right heat insulating wall 10 have a shelf support 30. The shelf support 30 is made of synthetic resin and functions as a protruding portion including components different from the sheet member. Since the left heat insulating wall 9 and the right heat insulating wall 10 have the same mounting structure of the shelf supporting device 30, the configuration and mounting structure of the shelf supporting device 30 of the left insulating wall 9 will be described with reference to FIGS. 16 to 18 . .

The shelf support 30 integrally includes a body portion 30a and a shelf support portion 30b. The main body portion 30a is formed in a plate shape that is long in the vertical direction. The shelf supporting portion 30b is provided to protrude from the front surface of the body portion 30a toward the inside of the library. The shelf supporting portion 30b is provided at three upper and lower portions of the main body portion 30a. The shelf support 30 includes a screw hole portion 30c and a fisheye hole 30d. The screw hole portion 30c is a female screw, and is provided from a surface on the opposite side of the inner portion of the main body portion 30a to a middle portion of the inside of the shelf support portion 30b. The screw hole portion 30c functions as a fastening member engagement portion. The fisheye hole 30d is a disk-shaped fisheye hole which is provided in correspondence with the screw hole portion 30c, and is formed in the peripheral portion of the opening of the screw hole portion 30c.

The left inner plate portion 15A of the left heat insulating wall 9 has a screw insertion hole portion 31 as a fastening member insertion hole portion. The screw insertion hole portion 31 is located at the left inner plate portion 15A at a portion corresponding to the refrigerating chamber 57, and is provided at three upper and lower portions. In addition, FIG. 17 shows one of the screw insertion hole portions 31 of the three portions of the screw insertion hole portion 31. When assembling the left heat insulating wall 9, first, the threaded rivet 32 as a fastening member is from the left inside. The back side of the plate portion 15A passes through the screw insertion hole portion 31, and is screwed into the screw hole portion 30c of the shelf support 30. Thereby, the shelf support 30 is fixed to the left inner panel portion 15A so as to protrude toward the inside of the inner box 15.

In this case, the left inner plate portion 15A is a sheet member, and thus a number of modifications are possible. Therefore, when the threaded rivet 32 is screwed into the frame support 30, the disk-shaped screw head 32a of the threaded rivet 32 deforms the peripheral portion of the screw insertion hole 31 of the left inner plate portion 15A in a disk shape (to the inside of the library) Bulging) until it contacts the fisheye hole 30d. As a result, in the assembled state of the left heat insulating wall 9 shown in FIG. 18, the peripheral edge portion 31a of the screw insertion hole portion 31 is separated from the left unit panel 16A. Further, the threaded rivet 32 does not protrude from the back surface of the left inner panel portion 15A toward the left unit panel 16A.

As shown in FIGS. 2, 3, and 5, the left heat insulating wall 9 and the right heat insulating wall 10 have a rail mounting tool 33 and a rail mounting tool 34. In addition, in FIG. 2, FIG. 3, and FIG. 5, only the rail mounting tool 33 and the rail mounting tool 34 which have the left side heat insulation wall 9 are shown. The rail mounting fixture 33 is provided on the inner side of the inner tank 15 of the vegetable compartment 58. The rail mounting tool 34 is provided on the inner side of the inner tank 15 in the freezing compartment 61. The rail mounting tool 33 and the rail mounting tool 34 are made of synthetic resin and function as a protruding portion including components different from the sheet member.

The rail mounting fixture 33 and the rail mounting fixture 34 are also attached to the left inner panel portion 15A of the left heat insulating wall 9 and the right inner panel portion 15B of the right heat insulating wall 10 by the same mounting structure as the shelf supporting tool 30. Further, the rail mounting tool 33 is used to mount a guide rail that can be supported by the vegetable container integrated with the drawer door 5. Further, the rail mounting tool 34 is used to mount a guide rail that can be retractably supported by the refrigerating product storage container integrated with the drawer door 8.

The left heat insulating wall 9 and the right heat insulating wall 10 include a partition wall support 35 and a partition wall support 36. The partition wall support 35 is provided on the inner surface side of the inner box 15 to support the first partition 55. The partition support 36 is for supporting the second partition 56. The partition supporting member 35 and the partition supporting member 36 are made of synthetic resin and function as a protruding portion including components different from the sheet member. The partition support members 35 and the partition support members 36 are attached to the left heat insulating wall 9 and the right heat insulating wall 10 by the same mounting structure as the fixture 26 .

Further, as shown in FIGS. 2 and 3, the back side heat insulating wall 13 has a back cover mounting tool 37. The back cover mount 37 is provided on an inner surface of the inner box 15, that is, an appropriate portion including the inner side inner panel portion 15E of the sheet member Sb. The back cover attachment 37 is made of synthetic resin and functions as a protruding portion including components different from the sheet member. The back cover attachment 37 is for attaching a back cover for shielding a duct or the like disposed in the front portion of the back side heat insulating wall 13. The back cover attachment 37 is attached by the same mounting structure as the fixture 26. Each of the heat insulating walls 9 to 13 is not filled with a foaming urethane between each inner plate portion and each unit plate.

As shown in FIG. 2, the evaporator 64 constituting the refrigeration cycle is provided in the inner side of the freezing compartment 61. The water receiving portion 18 is disposed below the evaporator 64. The water receiving portion 18 catches defrosting water or the like which is generated when the frost attached to the evaporator 64 is defrosted. Further, the defrosted water caught by the water receiving portion 18 is discharged from the water receiving portion 18 to the lower portion of the inner side heat insulating wall 13.

Next, a connection portion between the beam member 52 and the left heat insulating wall 9 and the right heat insulating wall 10 will be described with reference to Fig. 15 . Fig. 15 shows a connection portion between the beam member 52 and the left heat insulating wall 9. However, the configuration of the connection portion in the right heat insulating wall 10 is also bilaterally symmetrical and substantially the same configuration. The beam member 52 includes a front surface The front surface partitioning plate 52a, the reinforcing plate 52b, the back surface partitioning cover 52c, and the heat insulating material 52d. The left outer panel portion 14A of the left heat insulating wall 9 includes a front surface portion 14A3. The front end portion of the front surface portion 14A3 is folded back.

The front surface partitioning plate 52a is held by the reinforcing plate 52b and the folded-back portion 14A2 of the left outer plate portion 14A. That is, the end portion of the front surface partitioning plate 52a is in close contact with the back side of the folded-back portion 14A2. Further, the end portion of the reinforcing plate 52b is inserted into the back side of the front surface portion 14A3 of the left outer plate portion 14A. Further, the screw 62 is screwed into the screw hole of the reinforcing plate 52b by the front surface partitioning plate 52a and the folded-back portion 14A2. Further, the front surface partitioning plate 52a and the reinforcing plate 52b are integrated in advance by screws 63.

The back partition cover 52c is provided on the rear side of the front surface partitioning plate 52a. The heat insulating material 52d is housed inside the back surface partition cover 52c. The left and right edge portions of the front surface opening of the heat insulating box 2 are joined by the front surface partitioning plate 52a. That is, the left heat insulating wall 9 and the right heat insulating wall 10 are fixed via the front surface partitioning plate 52a. Therefore, the opening of the front surface of the heat insulating box 2 can be suppressed from being enlarged or reduced, and the storage chamber can be maintained in a rectangular parallelepiped shape.

Further, when the strength of the front surface partitioning plate 52a is high, the reinforcing plate 52b may not be provided. Further, the back surface partition cover 52c has a mounting portion that protrudes downward although not shown. Further, the attachment portion is screwed by the same fixture as the fixture 26.

According to the first embodiment, the left inner plate portion 15A and the right inner plate portion 15B of the inner box 15 include a flat sheet member Sa. The back side inner panel portion 15E includes a flat sheet member Sb. Therefore, when the left inner plate portion 15A, the right inner plate portion 15B, and the inner side inner plate portion 15E are manufactured, it is not necessary to form a mold, and the production is extremely simple, and the manufacturing cost can be reduced. In addition, the upper inner plate portion 15C and the lower inner plate portion 15D which are other portions of the inner casing 15 are integrally molded products obtained by using a mold, but the entire inner casing 15 is integrally molded by a large mold. The situation is easier to make, this In addition, the production cost can also be reduced. In short, the cost of the refrigerator 1 can be reduced.

In this case, at least a part of the left inner plate portion 15A, the right inner plate portion 15B, the upper inner plate portion 15C, the lower inner plate portion 15D, and the rear inner plate portion 15E may be included in the sheet member.

The inner box 15 includes a left inner panel portion 15A, a right inner panel portion 15B, an upper inner panel portion 15C, a lower inner panel portion 15D, and a rear inner panel portion 15E. In this case, the inner side inner panel portion 15E and the left inner panel portion 15A, and the inner side inner panel portion 15E and the right inner panel portion 15B are two inner panel portions adjacent to each other, and are divided by different sheet members. The sheet member connecting plate 25 is provided between the adjacent inner panel portions, that is, between the inner side inner panel portion 15E and the left inner panel portion 15A, and between the inner side inner panel portion 15E and the right inner panel portion 15B. The sheet member connecting plate 25 functions as a sheet member connecting member that connects the adjacent inner plate portions.

In this way, even if the inner side inner panel portion 15E and the left inner panel portion 15A and the inner side inner panel portion 15E and the right inner panel portion 15B each include a sheet member, the sheet member connecting plate 25 can be used as a different component. The rear inner panel portion 15E and the left inner panel portion 15A, and the rear inner panel portion 15E and the right inner panel portion 15B are easily coupled. As a result, the assembly of the heat insulating box 2 can be simplified.

The outer casing 14 includes a plurality of divided outer plate portions, and in this case, includes a left outer plate portion 14A, a right outer plate portion 14B, an upper outer plate portion 14C, a lower outer plate portion 14D, and a rear outer plate portion 14E. The inner box 15 includes a plurality of divided inner panel portions, and in this case, includes a left inner panel portion 15A, a right inner panel portion 15B, an upper inner panel portion 15C, a lower inner panel portion 15D, and a rear inner panel portion 15E. Among the plurality of inner panel portions, the left inner panel portion 15A, the right inner panel portion 15B, and the back inner panel portion 15E include a sheet member Sa and a sheet member Sb.

The vacuum insulation panel 16 includes a plurality of divided unit panels, and in this case, includes a left unit panel 16A, a right unit panel 16B, an upper unit panel 16C, and an unillustrated order. The bit plate and the back unit plate 16E. The left heat insulating wall 9 , the right heat insulating wall 10 , the upper heat insulating wall 11 , the lower heat insulating wall 12 , and the rear heat insulating wall 13 as a plurality of unit heat insulating walls are divided into outer and inner plates The divided unit plates are arranged between the units. The heat insulating box 2 is configured by connecting the unit heat insulating walls 9 to 13.

Thereby, the heat insulating box 2 which has the unit board as a vacuum heat insulation board can be assembled by assembling the heat insulation walls 9-13. Therefore, assembly of the heat insulating box 2 becomes easy. In the conventional configuration, the heat insulating box is constructed by assembling an undivided outer box and an inner box. Therefore, the conventional heat insulating box has a large body size and a large assembly work. However, in the present embodiment, it is possible to facilitate the group work in comparison with the conventional configuration.

In the inner box 15, the front end portion of the portion including the sheet member and the front end portion of the outer box 14 are joined by the distal end connecting member 21. Therefore, even if the inner box 15 includes the sheet member, it can be assembled by simply joining the outer box 14 by the distal end connecting member 21 as a different component.

The inner box 15 includes an L-shaped portion 17 as a bent portion and a water receiving portion 18. The L-shaped portion 17 is formed integrally with the upper inner plate portion 15C. The water receiving portion 18 is formed integrally with the lower inner plate portion 15D. Thereby, the L-shaped portion 17 or the water receiving portion 18 is formed by integral molding using a mold, and even if the L-shaped portion 17 or the water receiving portion 18 has a complicated shape, it can be easily formed.

The inner box 15 has a fixture 26. The fixture 26 is a member that is different from the sheet member Sa and the sheet member Sb and protrudes into the interior of the magazine. The fixture 26 is directly bonded to the left unit panel 16A by a bonding agent, for example, before the assembly of the left heat insulating wall 9. A hole portion 15u is formed in the sheet member Sa and the sheet member Sb. The fixture 26 is inserted into the hole portion 15u.

Thereby, the position of the fixture 26 in the sheet member of the inner box 15 can be determined by inserting the fixture 26 into the hole portion 15u. Further, the wall holders 35, 36 and the back cover attachment 37 are also the same mounting structure as the fixture 26. Therefore, the partition support 35, the partition support 36, and the back cover attachment 37 can be positioned similarly to the fixture 26.

Further, the fixture 26 may be inserted and adhered to the hole portion 15u of the sheet member from the back side at a stage before the left heat insulating wall 9 is assembled. Thereby, the fixture 26 and the sheet member can be processed in an integrated state. Therefore, when the unit heat insulating wall is assembled, the unit plate can be bonded to the integrated product of the fixture 26 and the sheet member, and assembly workability can be improved.

As shown in Fig. 13, the mounting surface of the fixture 26 of the unit panel 16A is recessed. Therefore, the sheet member Sa is attached without being bent.

If the unit plate portion 16A is bulged, the inner plate portion 15A also includes the sheet member Sa. Therefore, the inner plate portion 15A may be slightly deformed without being broken.

The fixture 26, the shelf support 30, the rail mount 33, the rail mount 34, the partition support 35, and the partition support 36 can also be commonly used for the heat insulation box of the refrigerator of different models.

The fixture 26 is directly bonded to the left unit panel 16A, the right unit panel 16B, and the rear unit panel 16E as vacuum insulation panels, and is fixed to each unit panel 16A, 16B, and 16E. Therefore, as the fixing tool 26 is inserted into each of the hole portions 15u of the left inner panel portion 15A, the right inner panel portion 15B, and the inner side inner panel portion 15E, the inner panel portions 15A, 15B, and 15E and the unit panel 16A can be formed. The alignment of 16B and 16E. In this case, the fixture 26 is made of an ABS resin having good adhesion. Therefore, the bonding strength between the fixture 26 and each unit panel can be improved.

The partition support 35, the partition support 36, and the back cover attachment 37 are also mounted in the same manner as the fixture 26. Therefore, the partition support 35, the partition support 36, and the back cover attachment 37 can also facilitate the alignment of the inner panel portions with the unit panels.

Further, the fixture 26 may be bonded to the left unit panel 16A, the right unit panel 16B, and the rear unit panel 16E via different members.

The fixture 26 has a flange portion 26a. The flange portion 26a is larger than the hole portion 15u. The flange-like portion 26a is sandwiched between the left inner plate portion 15A composed of the sheet member Sa, the right inner plate portion 15B, or the inner side inner plate portion 15E composed of the sheet member Sb and a unit plate corresponding thereto. .

Thereby, the flange-like portion 26a is locked around the hole portion 15u. Therefore, it is possible to prevent the fixture 26 from coming off the hole portion 15u. Further, the flange portion 26a can be adhered to the inner panel portion. Therefore, it is also possible to contribute to improvement in the strength of the inner panel portion to which the flange portion 26a is adhered. Further, the flange portion 26a is thin. Therefore, the flange portion 26a can be bent, and the curved flange portion 26a can be inserted into the hole portion 15u from the inside of the reservoir to enter between the inner plate portion and the unit plate.

The shelf support 30 is a protrusion that is a part different from the sheet member Sa and protrudes into the interior of the magazine. The sheet member Sa, that is, the left inner plate portion 15A and the right inner plate portion 15B has a screw insertion hole portion 31. The threaded rivet 32 as the fastening member passes through the screw insertion hole portion 31 from the back side of the sheet member Sa and is screwed into the shelf support 30. Thereby, the shelf support 30 is fixed to the front side of the sheet member Sa.

Thereby, the shelf support 30 as a component different from the sheet member Sa can be attached to the sheet member Sa by the threaded rivet 32 as a fastening member. In this case, it may be configured such that a rivet is used as the fastening. The member fastens the sheet member Sa and the shelf support 30.

The peripheral edge portion 31a of the screw insertion hole portion 31 is separated from the left unit panel 16A or the right unit panel 16B. Further, the head portion 32a of the threaded rivet 32 does not protrude from the peripheral edge portion 31a of the screw insertion hole portion 31 toward the respective unit plates 16A, 16B. Thereby, the screw head portion 32a does not protrude from the back surfaces of the inner plate portions 15A, 15B. Therefore, the screw head portion 32a does not contact the respective unit plates 16A, 16B. As a result, it is possible to prevent the package body 20 from being damaged by the screw head portion 32a contacting the unit plates 16A and 16B. Further, since the screw head portion 32a does not come into contact with the unit plates 16A, 16B, the adhesion of the left unit panel 16A to the left inner panel portion 15A and the adhesion of the right unit panel 16B to the right inner panel portion 15B are not separately hindered. Pick up.

Further, a disk-shaped fisheye hole 30d is formed in a peripheral portion of the opening of the screw hole portion 30c. Thereby, when the threaded rivet 32 is locked, the peripheral edge portion 31a of the screw insertion hole portion 31 in the sheet member Sa is deformed in the direction of the fisheye hole 30d, and is separated from the left unit panel 16A and the right unit panel 16B. Therefore, it is not necessary to specifically form the concave portion for accommodating the screw head portion 32a with the sheet member Sa.

Further, the rail mounting fixture 33 and the rail mounting fixture 34 are also mounted in the same manner as the shelf support 30. Therefore, the same effects as the shelf support 30 are exerted on the rail mounting fixture 33 and the rail mounting fixture 34. Further, the frame support 30, the rail attachment 33, and the rail attachment 34 (not shown) provided on the right heat insulating wall 10 also exhibit the same effects as the shelf support 30.

(Second embodiment)

The second embodiment will be described with reference to Figs. 19 to 27 . In the second embodiment, the structures of the left heat insulating wall 9A and the right heat insulating wall 10A are different from those of the left heat insulating wall 9A and the right heat insulating wall 10A of the first embodiment. In addition, since the left heat insulating wall 9A and the right heat insulating wall 10A are bilaterally symmetrical, the left insulating wall is 9A for explanation. In the left heat insulating wall 9A, the left inner panel portion 15A2 which is a part of the inner box 15 includes a shelf supporting portion 40a, a shelf supporting portion 40b, a shelf supporting portion 40c, a rail mounting portion 41a, a rail mounting portion 41b, and a partition wall. The support portion 42a and the partition wall support portion 42b serve as protruding portions. The left inner plate portion 15A2 includes integrally formed the shelf support portion 40a, the shelf support portion 40b, the shelf support portion 40c, the rail attachment portion 41a, the rail attachment portion 41b, the partition wall support portion 42a, and the partition wall support portion. The integrally molded product Ic of 42b. The integrally molded product Ic is formed by molding using a mold, for example, injection molding or vacuum forming.

The left inner plate portion 15A2 integrally has a sheet member connecting portion 25A2. The sheet member connecting portion 25A2 is provided at an end portion on the back side of the left inner panel portion 15A2. The sheet member connecting portion 25A2 functions as a sheet member connecting member for connecting the left inner panel portion 15A2 and the back inner panel portion 15E composed of the sheet member Sb. The sheet member connecting portion 25A2 is coupled to the back side heat insulating wall 13 by a fixture 26 attached to the back side inner panel portion 15E.

The shelf support portion 40a, the shelf support portion 40b, and the shelf support portion 40c are different in length from the rail attachment portion 41a and the rail attachment portion 41b in the front-rear direction. In other words, the length dimension of the rail attachment portion 41a and the rail attachment portion 41b in the front-rear direction is longer than the front-rear direction of the shelf support portion 40a, the shelf support portion 40b, and the shelf support portion 40c. On the other hand, the rail attachment portion 41a and the rail attachment portion 41b have the same cross-sectional shape as the shelf support portion 40a, the shelf support portion 40b, and the shelf support portion 40c, and have the same reinforcing structure. Therefore, the rail mounting portion 41a, the rail mounting portion 41b, the shelf supporting portion 40a, the shelf supporting portion 40b, and the shelf supporting portion 40c will be described with reference to the shelf supporting portion 40a.

As shown in FIGS. 22 to 25, the shelf supporting portion 40a is provided as one body. The left inner plate portion 15A2 of the molded product Ic protrudes so as to bulge in the inner direction of the interior. As shown in FIGS. 23 and 25, the shelf supporting portion 40a includes a screw column portion 43 and a screw hole portion 43a. The screw column portion 43 is provided at a part of the inner surface portion of the shelf supporting portion 40a. The screw hole portion 43 a is provided in the screw column portion 43 .

A reinforcing plate 44 made of, for example, a metal plate is provided as a reinforcing member between the shelf supporting portion 40a and the unit plate 16A. The reinforcing plate 44 has a shape along the inner surface of the shelf supporting portion 40a. The reinforcing plate 44 includes a column fitting portion 44a and a screw insertion hole portion 44b. The screw insertion hole portion 44b is provided inside the column portion surveying portion 44a. The reinforcing plate 44 is in close proximity to the inner surface portion of the shelf supporting portion 40a, and the screw 45 is passed through the screw insertion hole portion 44b. Further, the reinforcing plate 44 is attached to the inner surface of the shelf supporting portion 40a by screwing the screw 45 into the screw hole portion 43a of the shelf supporting portion 40a. In this manner, the reinforcing plate 44 reinforces the shelf supporting portion 40a.

The partition wall support portion 42a and the partition wall support portion 42b correspond to the partition wall support device 35 and the partition wall support member 36 of the first embodiment. As shown in FIG. 26 and FIG. 27, the partition wall support portion 42a and the partition wall support portion 42b are provided with a reinforcing plate 46 made of, for example, a metal plate as a reinforcing member. Thereby, the partition wall support portion 42a and the partition wall support portion 42b are reinforced by the reinforcing plate 46.

Further, the screwing of the reinforcing plate 44 and the reinforcing plate 46 may be performed as needed. For example, the reinforcing plate 44 and the reinforcing plate 46 may be fixed by a fixing instead of a screw. In short, the reinforcing plate 44 and the reinforcing plate 46 are disposed between the left unit plate 16A and the left inner plate portion 15A2, and the reinforcing plate 44 and the reinforcing plate 46 are used to reinforce the frame supporting portion 40a as the protruding portion and the shelf supporting portion 40b. The shelf support portion 40c, the rail attachment portion 41a, the rail attachment portion 41b, the partition wall support portion 42a, and the partition wall support portion 42b may be used.

In the second embodiment, the inner box 15 includes a shelf support portion 40a and a shelf plate. The support portion 40b, the shelf support portion 40c, the rail attachment portion 41a, the rail attachment portion 41b, and the partition wall support portion 42a and the partition wall support portion 42b serve as protruding portions that protrude into the interior of the reservoir. The left inner plate portion 15A2 includes integrally formed the shelf support portion 40a, the shelf support portion 40b, the shelf support portion 40c, the rail attachment portion 41a, the rail attachment portion 41b, the partition wall support portion 42a, and the partition wall support portion. The integrally molded product Ic of 42b. Further, the shelf supporting portion 40a, the shelf supporting portion 40b, the shelf supporting portion 40c, the rail mounting portion 41a, the rail mounting portion 41b, the partition supporting portion 42a, and the partition supporting portion 42b are respectively provided as vacuum insulation. The reinforcing plate 44 and the reinforcing plate 46, which are reinforcing members between the unit plate 16A of the plate and the integrally molded product Ic, are reinforced.

Thereby, the shelf support portion 40a, the shelf support portion 40b, the shelf support portion 40c, the rail attachment portion 41a, the rail attachment portion 41b, the partition wall support portion 42a, and the partition wall support portion 42b as the protruding portions are provided in one body. Molded product Ic. Therefore, the protrusions can be constructed without using different parts. Further, in the case of forming an integrally molded article, an olefin resin such as a polypropylene material having a slightly lower strength than the ABS resin is used in consideration of a low material cost, but the reinforcing plate 44 and the reinforcing plate 46 may be used. Make up for its lack of strength.

(Third embodiment)

The third embodiment will be described with reference to Figs. 28 and 29 . In the third embodiment, the configurations of the left heat insulating wall 9B and the right heat insulating wall 10B are different from those of the first embodiment and the second embodiment. Hereinafter, differences will be described. In this case, since the left heat insulating wall 9B and the right heat insulating wall 10B are bilaterally symmetrical, the left heat insulating wall 9B will be described.

In the third embodiment, the left inner panel portion 15A is divided into an upper side plate portion 15Aa and a lower side plate portion 15Ab as shown in Fig. 29 . Upper side plate portion 15Aa and lower side plate portion 15Ab Adjacent up and down. The upper side plate portion 15Aa is configured as an integrally molded product Id by, for example, injection molding or vacuum forming. Similarly to the second embodiment, the upper side plate portion 15Aa integrally includes 40a, 40b, and 40c as protruding portions. The left heat insulating wall 9B is connected to the back heat insulating wall 13 via the sheet member connecting portion 25A and the sheet member connecting portion 25B. The sheet member connecting portion 25A is a portion located in the refrigerating chamber 57, and is provided integrally with the upper side plate portion 15Aa as shown in Fig. 29 . The sheet member connecting portion 25B is a portion located in the vegetable compartment 58, the small freezer compartment 59, the ice making compartment 60, and the freezing compartment 61, and is configured as a separate component from the upper side plate portion 15Aa and the lower side plate portion 15Ab.

The lower side plate portion 15Ab includes a flat sheet member Sc. Similarly to the first embodiment, the lower side plate portion 15Ab includes the fixture 26, the rail mounting tool 33, the rail mounting tool 34, the partition wall support 35, and the partition wall support 36. The fixture 26, the rail mounting fixture 33, the rail mounting fixture 34, and the partition wall support 35, and the partition wall support 36 are projections including components different from the sheet member Sc. The attachment structure of the fixture 26, the rail attachment 33, the rail attachment 34, and the partition support 35 and the partition support 36 is the same as that of the first embodiment.

The upper side plate portion 15Aa is located in the refrigerating chamber 57 and constitutes the inner surface of the refrigerating chamber 57. The lower side plate portion 15Ab is positioned across the vegetable compartment 58, the small freezer compartment 59, the ice making compartment 60, and the freezing compartment 61, and constitutes the inner surfaces of the respective compartments. The first partition 55 is provided at a boundary portion between the upper side plate portion 15Aa and the lower side plate portion 15Ab.

According to the third embodiment, the left and right inner surfaces of the refrigerating chamber 57 include the upper side plate portion 15Aa as the integrally molded product Id. Therefore, the appearance of the inner surface of the refrigerating chamber 57 is good. That is, the inner surface of the refrigerating chamber 57 is easily visually recognized by the user when the revolving door 3 and the revolving door 4 are opened. Further, the protruding portion of the inner surface of the refrigerating chamber 57, that is, the shelf supporting portion 40a, the shelf supporting portion 40b, and the shelf supporting portion 40c are also easily rotated. When the door 3 and the revolving door 4 are opened, they are visually recognized by the user.

In this case, the shelf support portion 40a, the shelf support portion 40b, and the shelf support portion 40c, which are the protruding portions, are integrally molded with the integrally molded product Id formed by the mold, and thus are smoothly protruded from the upper plate portion 15Aa. Shape. Thereby, the overall appearance of the integrally molded product Id including the shelf supporting portion 40a, the shelf supporting portion 40b, and the shelf supporting portion 40c is improved, and the sanitary impression is also improved.

(Fourth embodiment)

The fourth embodiment will be described with reference to Figs. 30 and 31. In the third embodiment, the support member 30 includes the fin portion 30e, which is different from the first embodiment. The fin portion 30e is provided at a peripheral portion of the body portion 30a of the shelf support 30. The fin portion 30e is inclined toward the inner surface side of the inner box 15, that is, the left inner panel portion 15A side in FIGS. 30 and 31, and is elastically deformable.

The fin portion 30e is in close contact with the inner surface of the inner box 15 in the mounted state of the shelf support 30. Therefore, the gap between the inner surface of the inner box 15 and the shelf support 30 is covered by the fins 30e. In other words, when the screw rivet 32 is screwed into the screw hole portion 30c of the shelf support 30, the peripheral edge portion 31a of the screw insertion hole portion 31 of the left inner plate portion 15A is deformed. Therefore, there is a case where the screw insertion hole portion 31 is partially wrinkled, and there is a case where a gap is formed between the left inner plate portion 15A and the shelf support 30 due to the wrinkles. According to the fourth embodiment, the gap can be covered by the fin portion 30e.

(Fifth Embodiment)

The fifth embodiment will be described with reference to Figs. 32 to 38. In the fifth embodiment, as shown in FIGS. 32 and 33, the heat insulating box 2 is configured to include a left heat insulating wall 9, a right heat insulating wall 10, an upper heat insulating wall 11, a lower heat insulating wall 12, and a back side. The heat insulating wall 13 has a rectangular box shape with a front surface open. Each of the heat insulating walls 9 to 13 is on the outer plate portion 14A~ Each of the 14E and the inner plate portions 15A to 15E has a unit plate 16A to 16E as a vacuum heat insulating plate. In this case, the heat insulating wall body is formed by a heat insulating wall and two other heat insulating walls continuous with both sides of the heat insulating wall. In the present embodiment, the upper heat insulating wall 11 and the left heat insulating wall 9 and the right heat insulating wall 10 which are continuous with both sides of the upper heat insulating wall 11 constitute a heat insulating wall main body 2S in which the outer plate portion is continuous. In the heat insulating box 2, the upper portion of the interior is referred to as a refrigerating chamber 80, the intermediate portion is referred to as a freezing chamber 81, and the lower portion is referred to as a vegetable chamber 82.

A method of manufacturing the heat insulating box 2 will be described. First, the heat insulating wall main body 2S is manufactured as follows.

The integrated body 10U shown in FIG. 34 is formed on the right heat insulating wall 10, and the right unit plate 16B and the right inner plate portion 15B are joined by an adhesive. As shown in Fig. 35, the adhesive application method in this case is a coating method using a roll coating method. In the roll coating method, a pair of conveying rollers 71, 72 and a supply roller 73 are used. The supply roller 73 can be disposed in contact with one of the rollers 71, and one of the transport rollers 71 is supplied with an adhesive.

When the adhesive is applied to the inner surface 16Bn of the right unit panel 16B, the rollers 71 to 73 are rotated in the direction indicated by the arrow while the right unit panel 16B is sandwiched between the pair of transport rollers 71 and 72. . In this manner, the supply roller 73 supplies the adhesive to the entraining side between the supply roller 73 and the transport roller 71. Further, the transport roller 71 applies the adhesive supplied from the supply roller 73 to the inner surface 16Bn of the right unit panel 16B, and the pair of transport rollers 71, 72 transports the right unit panel 16B in the direction of the arrow of FIG. In this case, the inner surface 16Bn corresponds to a surface opposite to the outer surface 16Bg, that is, one surface. Further, the step of applying an adhesive to the inner surface 16Bn of the right unit panel 16B corresponds to the step (2).

After the adhesive is applied to the inner surface 16Bn of the right unit panel 16B, as shown in the figure As shown in FIG. 34, the right inner panel portion 15B is adhered to the inner surface 16Bn of the right unit panel 16B, whereby the unitary body 10U is manufactured. In this case, the right inner plate portion 15B has the bent portion 15Bs. The bent portion 15Bs is located at one end portion of the right inner panel portion 15B, and is formed by bending the one end portion in a direction opposite to the unit panel 16B at an angle of substantially 45 degrees. A heat insulating material 74B having a triangular cross section such as foamed styrene is provided on the back surface of the bent portion 15Bs. The heat insulating material 74B is bonded to the bent portion 15Bs and the unit panel 16B by, for example, an adhesive. Moreover, as shown in FIG. 36, the left inner plate portion 15A and the left unit plate 16A of the left heat insulating wall 9 are bonded together in the same manner as described above to constitute an integrated body 9U. Further, the left heat insulating wall 9 also includes a bent portion 15As and a heat insulating material 74A similarly to the right heat insulating wall 10.

Moreover, as shown in FIG. 36, the upper inner plate portion 15C and the upper unit plate 16C of the upper heat insulating wall 11 are bonded together in the same manner as described above to constitute the integrated body 11U. The upper inner plate portion 15C has a bent portion 15Cs1, a bent portion 15Cs2, a heat insulating material 74C1, and a heat insulating material 74C2 at both end portions of the upper inner plate portion 15C.

The upper outer plate portion 14C of the upper heat insulating wall 11 , the left outer plate portion 14A of the left heat insulating wall 9 , and the right outer plate portion 14B of the right heat insulating wall 10 include a single plate member 75 . When the upper heat insulating wall 11, the left heat insulating wall 9, and the right heat insulating wall 10 are manufactured, as shown in FIG. 36, first, the flat plate member 75 is placed on the work table Ws. The plate member 75 has a flat shape before processing. In the plate member 75, a symbol 14C1 is indicated in a region corresponding to the upper outer plate portion 14C of the upper heat insulating wall 11, and a symbol 14A1 is indicated in a region corresponding to the left outer plate portion 14A of the left heat insulating wall 9, which corresponds to the right side partition. The area of the right outer plate portion 14B of the hot wall 10 is denoted by reference numeral 14B1.

The length of the upper unit panel 16C is set to be equal to or slightly shorter than the length of the region 14C1 corresponding to the upper outer panel portion. Further, the length of the upper inner plate portion 15C is set to be relative The length of the upper unit plate 16C is approximately "9Ut1 + 10Ut1". The bending portion 15Cs1 and the bending portion 15Cs2 which are the both ends of the upper inner plate portion 15C are larger than the boundary portion K1 and the boundary portion K2 by 9 Ut1 and 10 Ut1. The size 9Ut1 is approximately equal to the thickness 9Ut of the unitary piece 9U. Further, the size 10Ut1 is substantially equal to the thickness dimension 10Ut of the unitary body 10U.

The integrated body 11U corresponds to the upper heat insulating wall 11 . The unitary body 11U is bonded to the inner surface of the region 14C1 corresponding to the upper outer plate portion in such a manner that both ends of the unit plate 16C are located at the boundary portions K1 and K2. That is, the outer surface 16Cg of the upper unit panel 16C is bonded to the inner surface of the region 14C1 corresponding to the upper outer panel portion. In this case, the adhesive is preferably applied to either the outer surface 16Cg of the upper unit panel 16C or the inner surface of the region 14C1 corresponding to the upper outer panel portion by, for example, spraying.

The unitary body 10U corresponds to the right side heat insulating wall 10. The integrated body 10U is separated from the boundary portion K2 corresponding to the region 14C1 of the upper outer plate portion by a predetermined distance Sk1 and adhered to the inner surface of the region 14B1 corresponding to the right outer plate portion. In other words, the outer surface 16Bg which is one surface of the right unit panel 16B is bonded to the inner surface of the region 14B1 corresponding to the right outer panel portion at a position apart from the boundary portion K2 of the region 14C1 corresponding to the upper outer panel portion by a predetermined distance Sk1. In this case, the predetermined distance Sk1 is set to be equal to or slightly larger than the thickness dimension Sk of the upper unit panel 16C.

Further, the outer surface 16Ag of one surface of the left unit panel 16A is bonded to the inner surface of the region 14A1 corresponding to the left outer panel portion at a position separated by a predetermined distance Sk1 from the boundary portion K1 of the region 14C1 corresponding to the upper outer panel portion. In this case, the vacuum heat insulating panel on one of the adjacent unit panels 16A and 16C, for example, the upper unit panel 16C is disposed such that the end portion on the left unit panel 16A side coincides with the boundary portion K1. Moreover, the vacuum insulation board on the other side of the adjacent unit boards 16A, 16C, in this case The end portion of the left unit plate 16A disposed on the upper unit plate 16C side is separated from the boundary portion K1 by a predetermined distance Sk1.

Similarly, the vacuum heat insulating panel on one of the adjacent unit panels 16B and 16C, for example, the upper unit panel 16C is disposed such that the end portion on the right unit panel 16B side coincides with the boundary portion K2. Further, the vacuum heat insulating panel on the other side of the adjacent unit panels 16B and 16C, in this case, the end portion of the right unit panel 16B disposed on the upper unit panel 16C side is separated from the boundary portion K2 by a predetermined distance Sk1. Then, each of the unit plates 16A, 16B, and 16C is bonded to the regions 14A1, 14B1, and 14C1 corresponding to the respective outer plate portions. This step is equivalent to step (1). In this case, the predetermined distance Sk1 corresponds to the thickness dimension of the upper unit panel 16C. That is, the predetermined distance Sk1 is the minimum distance of the bendable plate member 75 at the boundary portion K1.

Next, as shown in FIG. 37, the plate member 75 is bent inward by 90 degrees at the boundary portion K1 and the boundary portion K2. This step is equivalent to step (3). At this time, the integrated body 9U and the integrated body 10U are separated from each of the boundary portions K1 and K2 by a predetermined distance Sk1. Therefore, the integrated body 9U and the integrated body 10U bend the plate member 75 at the respective boundary portions K1, K2 without touching the respective end portions of the unit panel 16C. As a result, the bending process of the plate member 75 can be performed without hindrance.

Further, the integrated body 9U and the integrated body 10U are separated by the distance Sk1 from the boundary portion K1 and the boundary portion K2. Therefore, when the plate member 75 is bent, the end faces of the integrated body 9U and the end faces of the integrated body 10U are respectively abutted or closely connected. The inner surface 16Cn of the end of the unit panel 16C. Thereby, the unit panel 16A, the unit panel 16C, and the unit panel 16B are continuous with each other, and a large space portion is not generated inside the corner portion of the boundary portion K1 portion and the boundary portion K2 portion. Further, similarly, in the boundary portion K2, a large space portion is not generated inside the corner portion of the boundary portion K2. Therefore, it can be reduced for the outside Heat leaks out.

Further, the respective ends of the upper inner plate portion 15C, that is, the bent portion 15Cs1 and the end portion of the bent portion 15Cs2 are separated from the boundary portion K2 and the boundary portion K1 by the sizes 9Ut1, 10Ut1. Therefore, when the region 14A1 corresponding to the left outer plate portion is bent by approximately 90 degrees with the boundary portion K1 as a fulcrum, the integral body 9U abuts against the end portion of the bent portion 15Cs2 and restricts the bending thereof. In the same manner, when the region 14B1 corresponding to the right outer plate portion is bent by approximately 90 degrees with the boundary portion K2 as a fulcrum, the integrated body 10U abuts against the end portion of the bent portion 15Cs1 to restrict the bending thereof. In this manner, the region 14A1 corresponding to the left outer panel portion and the region 14B1 corresponding to the right outer panel portion are prevented from being bent by 90 degrees or more. In this case, the bent portion 15Cs1 functions as a bent stopper corresponding to the region 14B1 of the right outer plate portion. Further, the bent portion 15Cs2 functions as a bent portion corresponding to the bent region 14A1 of the left outer plate portion. Thereby, the region 14A1 corresponding to the left outer plate portion and the region 14B1 corresponding to the right outer plate portion are bent at an appropriate angle with respect to the region 14C1 corresponding to the upper outer plate portion, and are 90 degrees in this case.

Thereafter, as shown in FIG. 38, the lower heat insulating wall 12 is attached to the heat insulating wall main body 2S so as to close the opening of the left heat insulating wall 9 and the right heat insulating wall 10 constituting the heat insulating wall main body 2S. At this time, one end portion of the lower outer plate portion 14D is coupled to the open end portion of the left outer plate portion 14A, and the other end portion of the lower outer plate portion 14D is coupled to the open end portion of the right outer plate portion 14B. Further, one end portion of the lower inner plate portion 15D abuts or approaches the bent portion 15As of the left inner plate portion 15A and the heat insulating material 74A, and the other end portion of the lower inner plate portion 15D abuts or approaches the right inner plate portion 15B. The bent portion 15Bs and the heat insulating material 74B.

Thereafter, as shown in FIG. 33, the rear heat insulating wall 13 is attached to the rear end portions of the heat insulating walls 9, 10, 11, and 12. Further, the sheet member connecting plate 25 and the foamed styrene 28 are respectively disposed inside the corner portions of the rear heat insulating wall 13 and the left heat insulating wall 9, And the inner side of the corner portion of the rear side heat insulating wall 13 and the right side heat insulating wall 10. In the inside of the web member connecting plate 25, in this case, the foamed styrene 28 is formed with a cold air flow passage conduit 78 that connects the refrigerating chamber 80 and the vegetable compartment 82.

Further, in the plate member 75, a portion corresponding to the boundary portion K1 and the boundary portion K2 in the portion corresponding to the bent portion 14Aa shown in FIG. 33 is cut into a V shape in advance so as not to hinder the bending of the plate member 75. About 90 degrees.

According to the fifth embodiment, the outer plate portion 14A, the outer plate portion 14B, and the outer plate portion 14C of the outer plate portions 14A to 14E are constituted by one plate member 75. Therefore, the outer plate portions 14A, 14B, and 14C are continuous without an interface, and the interface of the outer plate portion can be reduced. As a result, the use of the foaming urethane can be reduced, and moisture absorption from the outside of the heat insulating box 2 or leakage of cold air to the outside can be reduced.

Further, in the fifth embodiment, as shown in Fig. 36, the upper unit plate 16C of one of the adjacent unit plates 16A and 16C is substantially the same as the boundary portion K1 at the end on the left unit plate 16A side. The end portion on the right unit plate 16B side is disposed so as to substantially coincide with the boundary portion K2. The end portion of the left unit panel 16A on the upper unit panel 16C side is disposed apart from the boundary portion K1 by a predetermined distance Sk1. The end portion of the right unit panel 16B on the upper unit panel 16C side is disposed apart from the boundary portion K2 by a predetermined distance Sk1. The predetermined distance Sk1 is set to a minimum distance at which the plate member 75 can be bent at the boundary portion K1 and the boundary portion K2.

Therefore, when the plate member 75 of the unit plate 16A, the unit plate 16B, and the unit plate 16C is bent and bonded at the boundary portion K1 and the boundary portion K2, the inside of the corner portion of the boundary portion K1 and the boundary portion K2 does not form a large portion. space. In other words, the unit plate 16A, the unit plate 16C, and the unit plate 16B enter the corner portions of the boundary portion K1 and the boundary portion K2 with almost no gap, and as a result, heat leakage in the corner portions of the boundary portion K1 and the boundary portion K2 can be reduced. Out.

Further, according to the fifth embodiment, the adhesive is applied to each of the outer surfaces 16Ag, 16Bg, and 16Cg by a roll coating method. Therefore, a uniform adhesion of the adhesive layer can be performed.

(Sixth embodiment)

The sixth embodiment will be described with reference to Figs. 39 and 40 . The end portion of the unitary body 9U corresponding to the left heat insulating wall 9 on the side of the side heat insulating wall 11 is disposed so as to coincide with the boundary portion K1. The integrated body 11U corresponding to the upper heat insulating wall 11 is disposed such that the end portion on the left heat insulating wall 9 side is separated from the boundary portion K1 by a distance of 9 Ut1. In addition, the end portion of the integrated body 10U corresponding to the right heat insulating wall 10 on the side of the heat insulating wall 11 side is disposed so as to coincide with the boundary portion K2. The integrated body 11U corresponding to the upper heat insulating wall 11 is disposed such that the end portion on the side of the right heat insulating wall 10 is separated from the boundary portion K2 by a distance of 10 Ut1.

Then, one surface of the unit panel 16A of the unitary body 9U is bonded to the region 14A1 corresponding to the outer panel portion. Further, one surface of the unit panel 16B of the unitary body 10U is adhered to a region 14B1 corresponding to the outer panel portion. Further, one surface of the unit panel 16C of the unitary body 11U is adhered to a region 14C1 corresponding to the upper outer panel portion. The distance 9Ut1 is the minimum distance at which the plate member 75 can be bent at the boundary portion K1. Similarly, the distance 10Ut1 is the minimum distance at which the plate member 75 can be bent at the boundary portion K2.

In the sixth embodiment, the unit plate 16A, the unit plate 16C, and the unit plate 16B also enter the corner portions of the boundary portion K1 and the boundary portion K2 with substantially no gap, and are not formed inside the corner portions of the boundary portion K1 and the boundary portion K2. Large space department. As a result, heat leakage at the corners of the boundary portion K1 and the boundary portion K2 can be reduced.

Further, the combination of the three heat insulating walls constituting the heat insulating wall main body is not limited to the combination of the left heat insulating wall 9 and the upper heat insulating wall 11 and the right heat insulating wall 10 . For example, it may be a group of the left heat insulating wall 9 and the lower heat insulating wall 12 and the right heat insulating wall 10 The combination of the left heat insulating wall 9 and the rear heat insulating wall 13 and the right heat insulating wall 10 or the combination of the upper heat insulating wall 11 and the rear heat insulating wall 13 and the lower heat insulating wall 12 is variously changed.

The bent portions 15As, 15Bs, 15Cs1, and 15Cs2 are integrally formed with the respective inner plate portions 15A, 15B, and 15C, but may be formed of flat plates of different bodies, and the heat insulating material 74A and the heat insulating material are provided on the back surface of the flat plate. The heat insulating material of the materials 74B, 74C1, and 74C2 is finally attached to each corner portion as shown in Fig. 32.

As described above, according to the method of manufacturing the heat insulating box for a refrigerator according to the present embodiment, one of the plate members constitutes one heat insulating wall of the heat insulating wall and the outer plate portions of the other two heat insulating walls continuous on both sides thereof. Therefore, the interface of the outer plate portion can be reduced, and even if the composition is made of no foaming urethane or foaming urethane, moisture absorption from the outside can be effectively prevented. Further, the end portion of one of the vacuum insulation panels adjacent to each boundary portion of the region corresponding to each of the outer plate portions in the plate member is located substantially at the boundary portion, so that the other vacuum insulation panel is provided. The end portion is separated from the boundary portion, and the plate member in the boundary portion can be bent at a substantially minimum distance, and one surface of each vacuum insulation panel is adhered to a region corresponding to each outer panel portion. The vacuum heat insulating plate is allowed to enter the inside of the corner portion of one of the plate members substantially without any gap, and heat leakage is well prevented.

(Seventh Embodiment)

In the seventh embodiment, as shown in FIG. 41, the refrigerator 1 includes a heat insulating box 102. The heat insulation box 102 includes an outer box 111, an inner box 112, a plurality of vacuum insulation panels 130, a vacuum insulation panel 131, a vacuum insulation panel 132, and a vacuum insulation panel 133. The vacuum insulation panel 130, the vacuum insulation panel 131, the vacuum insulation panel 132, and the vacuum insulation panel 133 are disposed on Between the outer box 111 and the inner box 112. The vacuum heat insulating panel 130, the vacuum heat insulating panel 131, the vacuum heat insulating panel 132, and the vacuum heat insulating panel 133 are different members from each other. The insulated enclosure 102 includes four corners C. The corner C can also be referred to as a crotch or a corner.

The metal plate 113 shown in Fig. 42(A) is formed by bending, for example, a strip-shaped steel plate. The metal plate 113 includes a top surface portion 114, a left side surface portion 115, a right side surface portion 116, and a bottom surface portion 117. The top surface portion 114, the left side surface portion 115, the right side surface portion 116, and the bottom surface portion 117 function as an outer panel portion. The metal plate 113 is bent at 90 degrees in the mountain pleat portions 118, 119, and 120, respectively. The mountain pleat portion 118 is located between the top surface portion 114 and the left side surface portion 115. The mountain pleat portion 119 is located between the top surface portion 114 and the right side surface portion 116. The mountain pleat portion 120 is located between the right side portion 116 and the bottom portion 117.

After the metal plate 113 is bent at each of the ridge line portions 118, 119, and 120, the end portion 121 of the left side surface portion 115 and the end portion 122 of the bottom surface portion 117 are welded. Thereby, the metal plate 113 is configured as the outer case 111 of the vertically long shape shown in FIG. 42(B). The outer case 111 is a rectangular parallelepiped box shape having an opening 155 on the front and back sides and an opening 156. Further, the bottom surface portion 117 may be assembled separately from the top surface portion 114 and the left and right side surface portions 115 and 116.

The heat insulating box 102 includes a plate-shaped vacuum heat insulating panel 130, a vacuum heat insulating panel 131, a vacuum heat insulating panel 132, and a vacuum heat insulating panel 133. As shown in FIG. 42(A), the vacuum insulation panel 130 is bonded to the inner surface 114A of the top surface portion 114. The vacuum insulation panel 131 is adhered to the inner surface 115A of the left side surface portion 115. The vacuum insulation panel 132 is adhered to the inner surface 116A of the right side surface portion 116. The vacuum insulation panel 133 is adhered to the inner surface 117A of the bottom surface portion 117.

As shown in FIG. 41, the inner box 112 is vertically long like the outer box 111. Square shape box. The inner box 112 is disposed inside the outer box 111. The inner box 112 is made by molding, for example, plastic. The inner box 112 is smaller in size than the outer box 111 to enter the outer box 111. The inner box 112 includes a top surface portion 124, a left side surface portion 125, a right side surface portion 126, and a bottom surface portion 127. The top surface portion 124, the left side surface portion 125, the right side surface portion 126, and the bottom surface portion 127 function as an inner panel portion. Further, the top surface portion 124, the left and right side surface portions 125, 126, and the bottom surface portion 127 of the inner box 112 may not be a single body and may be different members.

As shown in FIG. 41, the top surface portion 124 of the inner box 112 is parallel to the top surface portion 114 of the outer box 111 and is opposite to the top surface portion 114 with a dimension T therebetween. The side surface portion 125 on the left side of the inner box 112 is parallel to the side surface portion 115 on the left side of the outer box 111, and is opposite to the side surface portion 115 with a dimension T therebetween. The side surface portion 126 on the right side of the inner box 112 is parallel to the side surface portion 116 on the right side of the outer box 111, and is opposite to the side surface portion 116 with a dimension T therebetween. The bottom surface portion 127 of the inner box 112 is parallel to the bottom surface portion 117 of the outer box 111, and is opposite to the bottom surface portion 117 with a dimension T therebetween. In this manner, the inner box 112 is disposed in the outer box 111 and has a gap of a dimension T between the outer box 111 and the inner box 112.

In FIG. 41, the X direction indicated by the arrow is set to the horizontal direction, and the Z direction indicated by the arrow is set to the vertical direction. The vacuum heat insulating panels 130 and 133 are provided such that the faces of the vacuum heat insulating panels 130 and 133 face the horizontal direction, that is, the horizontal direction. The vacuum heat insulating panels 131 and 132 are provided such that the faces of the vacuum heat insulating panels 131 and 132 face the vertical direction, that is, the vertical direction.

The heat insulating properties of the vacuum insulation panel 130, the vacuum insulation panel 131, the vacuum insulation panel 132, and the vacuum insulation panel 133 are sufficiently higher than those of the foamed polyurethane material. Therefore, in the case where the heat insulating box 102 is used as a heat insulating material compared to the case where the foamed polyurethane material is used, even the vacuum heat insulating panel 130, the vacuum heat insulating panel 131, and the vacuum are provided. The thickness of the heat insulating plate 132 and the vacuum heat insulating plate 133 is thin, and the necessary heat insulating performance can be ensured. Thus, the heat insulating box 102 can be used as a heat insulating material by using the vacuum heat insulating panel 130, the vacuum heat insulating panel 131, the vacuum heat insulating panel 132, and the vacuum heat insulating panel 133, so that the interval between the outer box 111 and the inner box 112 can be made small. . Therefore, when the outer size of the outer case 111 is made constant, the heat insulating box 102 can have a larger inner size of the inner case 112 than when a foamed polyurethane material is used as the heat insulating material. As a result, the storage volume of the heat insulating box 102 can be increased, and the capacity of the refrigerator 1 can be increased. In this case, the thickness of the vacuum insulation panel is, for example, 10 to 30 mm.

As shown in FIG. 41, the vacuum heat insulating material 130 is disposed in a gap between the top surface portion 124 of the inner box 112 and the top surface portion 114 of the outer box 111. The vacuum heat insulating material 131 is disposed in a gap between the side surface portion 125 on the left side of the inner box 112 and the side surface portion 115 on the left side of the outer box 111. The vacuum heat insulating material 132 is disposed in a gap between the side surface portion 126 on the right side of the inner box 112 and the side surface portion 116 on the right side of the outer box 111. The vacuum heat insulating material 133 is disposed in a gap between the bottom surface portion 127 of the inner box 112 and the bottom surface portion 117 of the outer box 111.

In the case of the present embodiment, the vacuum heat insulating panel 130, the vacuum heat insulating panel 131, the vacuum heat insulating panel 132, and the vacuum heat insulating panel 133 are bonded to the inner surface of the outer casing 111 by using an adhesive, but are not limited thereto. this. In other words, the vacuum insulation panel 130, the vacuum insulation panel 131, the vacuum insulation panel 132, and the vacuum insulation panel 133 may be disposed on the inner surface of the outer casing 111 without using an adhesive. Thereby, the subsequent replacement of the vacuum heat insulating panel 130, the vacuum heat insulating panel 131, the vacuum heat insulating panel 132, and the vacuum heat insulating panel 133 can be performed.

As shown in Fig. 41, the four corner portions C have the same configuration. In the vacuum heat insulating panel 131 disposed in the longitudinal direction, the upper end portion 131T is in contact with the inner surface 114A of the top surface portion 114, and the lower end portion 131R is in contact with the inner surface 117A of the bottom surface portion 117. Similarly, in the longitudinal direction of the vacuum insulation panel 132, the upper end portion 132T and the top surface portion 114 The inner surface 114A is in contact, and the lower end portion 132R is in contact with the inner surface 117A of the bottom surface portion 117.

Further, the faces of the respective end portions 131T, 131R, 132T, and 132R need not be in full contact, and at least a part of them may be in contact. Further, the upper end portions 131T, 132T of the vacuum heat insulating panels 131, 132 may also slightly leave the inner surface 114A of the top surface portion 114. For example, the upper end portions 131T and 132T of the vacuum heat insulating panels 131 and 132 may be located above the lower surface of the vacuum heat insulating panel 130, and preferably located above the middle portion of the vacuum heat insulating panel 130. The lower end portions 131R and 132R of the vacuum heat insulating panels 131 and 132 may be located below the upper surface of the vacuum heat insulating panel 133, and preferably located below the middle portion of the vacuum heat insulating panel 130.

In the vacuum heat insulating panel 130 disposed on the upper side in the lateral direction, the left end portion 130F is in contact with the inner side surface 131N of the vacuum heat insulating panel 131 disposed in the longitudinal direction, and the right end portion 130G is disposed inside the vacuum heat insulating panel 132 disposed in the longitudinal direction. Side 132N is in contact. Similarly, in the vacuum heat insulating panel 133 disposed on the lower side in the lateral direction, the left end portion 133F is in contact with the inner side surface 131N of the vacuum heat insulating panel 131 disposed in the longitudinal direction, and the right end portion 133G and the vacuum heat insulating layer disposed in the longitudinal direction are disposed. The inner side 132N of the plate 132 is in contact.

In this manner, the vacuum heat insulating plates 130 and 133 in the lateral direction are interposed between the vacuum heat insulating plate 131 in the longitudinal direction on the left side and the vacuum heat insulating plate 132 in the vertical direction on the right side. Thereby, the upper and lower corner portions C on the left side are filled with the vacuum heat insulating plates 131 on the left side in the vertical direction. Further, the upper and lower corner portions C on the right side are filled by the vertical vacuum insulation panel 132 on the right side. Therefore, since each corner portion C is filled with the vacuum heat insulating panel without a gap, the heat insulating performance in each corner portion C can be ensured, and air leakage can be suppressed. In other words, each of the corner portions C has a function of preventing vacuum leakage from the inside of the refrigerator 1 through the gap of the corner portion C and leaking to the outside of the outer casing 111. In addition, the rigidity in each corner C of the heat insulating box 102 can be improved. Sex.

As shown in FIGS. 43(A) and 43(B), the vacuum insulation panel 130, the vacuum insulation panel 131, the vacuum insulation panel 132, and the vacuum insulation panel 133 include a core material 70 and a laminated film. ) 171. The core material 170 is, for example, a sheet of glass wool. The laminate film 171 has a metal foil layer or a metal deposition layer and is excellent in moisture resistance and gas barrier properties. The vacuum heat insulating panel 130, the vacuum heat insulating panel 131, the vacuum heat insulating panel 132, and the vacuum heat insulating panel 133 are formed by laminating the core material 170 with a laminate film 171, and forming a vacuum structure therein, thereby maintaining, for example, Over 90% high vacuum space rate. The laminate film 171 includes one of the sealing portions 172 and the other sealing portion 173 of the sealing core 170. One of the sealing portions 172 and the other sealing portion 173 are formed, for example, by local heating.

(Eighth embodiment)

An eighth embodiment will be described with reference to Fig. 44. In addition, FIG. 44 shows the upper right corner portion C among the four corner portions C of the heat insulating box 102 in the eighth embodiment, but the other corner portion C is also configured similarly to the right upper corner portion C. As shown in FIG. 44, the sealing portion 173 of the vacuum heat insulating panel 130 is bent toward the inner surface 114A side of the top surface portion 114 of the outer casing 111, and is disposed in the concave portion 130N of the vacuum heat insulating panel 130. Similarly, the sealing portion 172 of the vacuum heat insulating panel 132 is bent toward the inner surface 116A side of the side surface portion 116 of the outer casing 111 and disposed in the concave portion 132M of the vacuum heat insulating panel 132. In this case, the sealing portion 172 and the sealing portion 173 are not bent toward the inner surface side of the inner box 112. The manner in which the sealing portion 172 and the sealing portion 173 are accommodated is also the same in the remaining three corner portions C.

The reason why the sealing portion 172 is bent and stored is described. The outer case 111 is made of a metal plate having a high rigidity, whereas the inner case 112 is made of rigidity. A plastic plate made of less than metal. If the sealing portion 172 and the sealing portion 173 are bent toward the inner box 112 side, the inner box 112 may be bulged inward by the thickness of the bent sealing portion 172 and the sealing portion 173. As a result, the inner box 112 becomes uneven, and the appearance is deteriorated.

Therefore, the sealing portion 172 and the sealing portion 173 are bent toward the outer case 111 side. Thereby, the inner box 112 can avoid the influence of the thickness of the bent sealing portion 172 and the sealing portion 173. Further, the bent sealing portion 172 and the sealing portion 173 are housed in the recess 130N and the recess 132N. Thereby, the outer case 111 can also avoid the influence of the thickness of the bent sealing portion 172 and the sealing portion 173. As a result, the outer casing 111 and the inner casing 112 can be made flat, and the inner casing 112 can be beautifully arranged with respect to the vacuum insulation panel 130, the vacuum insulation panel 131, the vacuum insulation panel 132, and the vacuum insulation panel 133. In this manner, the sealing portion 172 and the sealing portion 173 are bent and housed on the outer case 111 side, and are configured in any one of the vacuum heat insulating panel 130, the vacuum heat insulating panel 131, the vacuum heat insulating panel 132, and the vacuum heat insulating panel 133. The same is true in the middle.

In the second embodiment, the vacuum heat insulating panel 130, the vacuum heat insulating panel 131, the vacuum heat insulating panel 132, and the vacuum heat insulating panel 133 are disposed between the outer box 111 and the inner box 112, and the vacuum is filled in each corner portion C. Insulation board. Therefore, in the second embodiment, the heat insulating performance in each corner portion C can be ensured in the same manner as in the first embodiment. Further, a rectangular vacuum insulation panel is placed in advance on the back side of the heat insulating box 102.

(Ninth Embodiment)

Next, a ninth embodiment will be described with reference to Fig. 6 .

In the vacuum heat insulating panel 130 disposed on the upper side in the lateral direction, the left end portion 130C is in contact with the inner surface 115A of the left side surface portion 115 of the outer box 111, and the right end portion 130D is in contact with the inner surface 116A of the right side surface portion 116 of the outer box 111. Similarly, in the horizontal To the lower vacuum insulation panel 133, the left end portion 133C is in contact with the inner surface 115A of the left side surface portion 115 of the outer box 111, and the right end portion 133D is in contact with the inner surface 116A of the right side surface portion 116 of the outer box 111.

On the other hand, in the vacuum insulation panel 131 disposed on the left side in the longitudinal direction, the upper end portion 131F is in contact with the inner surface 130M of the upper vacuum insulation panel 130, and the lower end portion 131G and the inner surface of the lower vacuum insulation panel 133 are provided. 133M contact. Similarly, in the vacuum heat insulating panel 132 disposed on the right side in the longitudinal direction, the upper end portion 132F is in contact with the inner surface 130M of the upper vacuum insulation panel 130, and the lower end portion 132G and the inner surface 133M of the lower vacuum insulation panel 133 are provided. contact.

In this manner, the vacuum heat insulating panel 131 and the vacuum heat insulating panel 132 in the longitudinal direction are sandwiched between the upper horizontal vacuum heat insulating panel 130 and the lower horizontal vacuum heat insulating panel 133. Thereby, the left and right corner portions C on the upper side are filled with the vacuum heat insulating sheets 130 on the upper side in the lateral direction. Further, the left and right corner portions C on the lower side are filled with the vacuum heat insulating plate 133 on the lower side in the lateral direction. Therefore, since each corner portion C is filled with the vacuum heat insulating panel and has no space, the heat insulating performance in each corner portion C can be ensured, and air leakage can be suppressed. In other words, each of the corner portions C has a function of preventing vacuum leakage from the inside of the refrigerator 1 through the gap of the corner portion C and leaking to the outside of the outer casing 111. Further, the rigidity in each corner portion C of the heat insulating box 102 can be improved.

(10th embodiment)

The tenth embodiment will be described with reference to Fig. 46. In addition, FIG. 46 shows the upper right corner portion C among the four corner portions C of the heat insulating box 102 in the tenth embodiment, but the other corner portion C is also configured similarly to the right upper corner portion C. As shown in FIG. 46, the sealing portion 173 of the vacuum heat insulating panel 130 is bent toward the inner surface 114A side of the top surface portion 114 of the outer casing 111, and is disposed in the concave portion 130H of the vacuum heat insulating panel 130. Similarly, The sealing portion 172 of the vacuum heat insulating panel 132 is bent toward the inner surface 116A side of the side surface portion 116 of the outer casing 111 and disposed in the concave portion 132J of the vacuum heat insulating panel 132. In this case, the sealing portion 172 and the sealing portion 173 are not bent toward the inner surface side of the inner box 112. The storage manner of the sealing portion 172 and the sealing portion 173 is also the same in the remaining three corner portions C.

Thereby, the same operational effects as those of the above-described eighth embodiment can be obtained.

(Eleventh Embodiment)

An eleventh embodiment will be described with reference to Fig. 47. In the eleventh embodiment, the vacuum heat insulating panel 130, the vacuum heat insulating panel 131, the vacuum heat insulating panel 132, and the vacuum heat insulating panel 133 are constituted by an integrated body W1 that is continuously connected. The integrated body W1 is bonded to the inner surface 114A of the top surface portion 114, the inner surface 115A of the left and right side surface portions 115 and 116, the inner surface 116A, and the inner surface 117A of the bottom surface portion 117 to constitute an integral body W2. In other words, the integrated body W1 is formed by continuously connecting the vacuum insulation panels 130, 131, 132, and 133. In addition, the integrated body W2 means that the integrated body W1 is bonded to the respective inner surfaces 114A, 115A, 116A, and 117A.

The unitary body W2 includes a recessed portion 190 at three locations and a recessed portion 191 at two locations. The recessed portion 190 is located on the side of the integrated body W1, and is disposed at a position corresponding to the mountain pleat line portion 118, the mountain pleat line portion 119, and the mountain pleat line portion 120 of the unitary body W2. As shown in Fig. 47 (B), the cross section of each recessed portion 190 has a semicircular shape. The recessed portion 91 is provided at both end portions of the unitary body W1. The recessed portion 91 is formed in a circular shape in which the cross section is 1/4. The recessed portion 91 of the two portions is a semicircular cross section which is the same cross section as the recessed portion 90 by bending the integral body W1 so that the both end portions are butted. In this case, the vacuum insulation panel 130, the vacuum insulation panel 131, the vacuum insulation panel 132, and the vacuum insulation panel 133 are used than the vacuum insulation panel. The thin connecting portion 95 is formed continuously.

As a result, as shown in FIG. 47(C), when the integrated body W2 is bent at each of the mountain pleat portions 118, 119, and 120, the concave portion 90 of the three portions can be easily bent as a fulcrum. Therefore, the outer case 111 including the vacuum heat insulating panel 130, the vacuum heat insulating panel 131, the vacuum heat insulating panel 132, and the vacuum heat insulating panel 133 can be easily obtained. Further, the thickness of the connecting portion 95 of the three recessed portions 90 is thinner than the thickness of the vacuum heat insulating panel 130, the vacuum heat insulating panel 131, the vacuum heat insulating panel 132, and the vacuum heat insulating panel 133. Therefore, the vacuum heat insulating panel 130, the vacuum heat insulating panel 131, the vacuum heat insulating panel 132, and the vacuum heat insulating panel 133 can be easily bent at each corner portion C to form a box shape.

(12th embodiment)

A twelfth embodiment will be described with reference to Fig. 48. In the twelfth embodiment, the vacuum heat insulating panel 130, the vacuum heat insulating panel 131, the vacuum heat insulating panel 132, and the vacuum heat insulating panel 133 are mutually different members and are separated from each other. The vacuum insulation panel 130 is adhered to the inner surface 114A of the top surface portion 114. The vacuum insulation panel 131 is adhered to the inner surface 115A of the left side surface portion 115. The vacuum insulation panel 132 is adhered to the inner surface 116A of the right side surface portion 116. The vacuum insulation panel 133 is adhered to the inner surface 117A of the bottom surface portion 117. In this manner, the vacuum heat insulating panel 130, the vacuum heat insulating panel 131, the vacuum heat insulating panel 132, and the vacuum heat insulating panel 133 are bonded to the inner surface 114A, the inner surface 115A, the inner surface 116A, and the inner surface 117A, respectively, to constitute an integrated body W3. In other words, the integrated body W3 is obtained by bonding the vacuum heat insulating panel 130, the vacuum heat insulating panel 131, the vacuum heat insulating panel 132, and the vacuum heat insulating panel 133 to the inner surfaces 114A, 115A, 116A, and 117A.

The unitary body W3 has a recessed portion 100 of three portions and a recessed portion 101 of two portions. The recessed portion 100 is located on the side of the vacuum insulation panel 130, the vacuum insulation panel 131, the vacuum insulation panel 132, and the vacuum insulation panel 133, and is disposed on the integrated body The position of the mountain pleat line portion 118, the mountain pleat line portion 119, and the mountain pleat line portion 120 of W3. As shown in Fig. 48(B), the cross section of the recessed portion 100 has a substantially triangular shape. The recessed portion 101 is located on the side of the vacuum heat insulating panel 131 and the vacuum heat insulating panel 133, and is provided at both end portions of the unitary body W3. That is, the recessed portion 101 is provided at the end portion 121 on the left side and the end portion 122 on the right side. The recessed portion 101 is formed by forming the end portions of the vacuum heat insulating panel 131 and the vacuum heat insulating panel 133 in a sloped shape. The recessed portion 101 of the two portions is a triangular cross section which is the same cross section as the recessed portion 100 by bending the integral body W3 so that the both end portions are butted. In this case, at each end of each of the vacuum insulation panels 130, 131, 132, 133, the dimensions of the inner surface 114A, the inner surface 115A, the inner surface 116A, and the inner surface 117A side are longer than the inner surface 114A and the inner surface. 115A, the inner surface 116A, and the dimension of the opposite side of the inner surface 117A may be sufficient.

Thereby, the same operational effects as those of the eleventh embodiment can be obtained. Further, as shown in Fig. 48(C), the end portions of the adjacent vacuum insulation panels of the corner portion C, for example, the vacuum insulation panel 130 and the vacuum insulation panel 132 are in contact with each other at an angle of about 45 degrees to form a dome-shaped portion. 150. Thereby, at the corner portion C, the adjacent vacuum insulation panels can surely contact each other. Further, an additional heat insulating material 151 is disposed inside the dome portion 150. Thereby, in the meandering portion 150 of the corner portion C, if a gap is formed even if adjacent vacuum heat insulating plates are spaced apart, the gap formed by the corner portion C can be blocked by the heat insulating material 151. As a result, the heat insulating performance of the corner portion C can be ensured.

Another embodiment will be described with reference to Figs. 49(A) to 50(B). In another embodiment shown in FIG. 49(A), the recessed portion 140 is disposed between the adjacent vacuum insulation panels 130-133. The cross section of the recessed portion 140 is formed in a semicircular shape. The connection portion of the adjacent vacuum insulation panels, for example, the vacuum insulation panels 130, 132, becomes a thin connection portion 141. In this case, the thickness of the connecting portion 141 is also higher than that of the vacuum. The thickness of the heat shield is thin. Therefore, the vacuum heat insulating panel 130, the vacuum heat insulating panel 131, the vacuum heat insulating panel 132, and the vacuum heat insulating panel 133 can be easily bent at the corner portion C to form a box shape. In this case, the connecting portion 141 does not need to have a core material as long as the sealing portion 172 of the bag body enclosing the core material and the sealing portion 173 are connected.

In another embodiment shown in FIG. 49(B), adjacent vacuum insulation panels, for example, the vacuum insulation panel 130 and the vacuum insulation panel 132 are formed differently from each other. Further, a gap SS is formed in advance between the vacuum insulation panel 130 and the vacuum insulation panel 132. Therefore, as shown in FIG. 49(C), a gap SS is generated between the vacuum heat insulating panel 130 in the corner portion C, the end portion 130K of the vacuum heat insulating panel 132, and the end portion 132K. In this case, for example, when the vacuum heat insulating panel 130 in the lateral direction is moved in the direction of the arrow V to adjust the position, the position of the vacuum heat insulating panel 130 can be easily adjusted by using the gap SS prepared in advance.

In another embodiment shown in FIG. 11, adjacent vacuum insulation panels, such as vacuum insulation panel 130 and vacuum insulation panel 132, are formed differently from one another. Further, a gap SS is formed in advance between the vacuum insulation panel 130 and the vacuum insulation panel 132. Further, the vacuum insulation panel 130 and the vacuum insulation panel 132 are integrally covered by the laminate film 171. In this case, for example, when the vacuum insulation panel 132 in the longitudinal direction is moved in the direction of the arrow P to adjust the position, the slack portion 145 of the laminate film 171 can be sandwiched as shown in FIG. 50(B). Store it.

Next, a method of manufacturing the heat insulating box according to another embodiment will be described with reference to FIGS. 51(A) to 51(C). As shown in Fig. 51 (A), the vacuum heat insulating panel 130, the vacuum heat insulating panel 131, and the vacuum heat insulating panel 132 are attached to the metal plate 113M in advance. The recessed portion 90 is disposed between the adjacent vacuum insulation panels 130, 131, and 132. As shown in FIG. 51(B), the metal plate 113M is taken with the recessed portion 90 as a fulcrum. Bend. Thereby, the top surface portion 114, the left side surface portion 115, and the right side surface portion 116 are formed. The left side face 115 faces the right side face 116.

The bottom surface portion 117 of the vacuum heat insulating panel 133 on the bottom surface is sandwiched by the bottom surface portion 127. The bottom surface portion 117 is provided on a surface of the vacuum heat insulating panel 133 opposite to the inside of the reservoir. The bottom surface portion 127 is provided on the inner surface of the vacuum insulation panel 133. The bottom surface portion 117 is fixed to the mounting portion 115D of the left and right side surface portions 115 and 116 and the mounting portion 116D by screws 99. Thereby, as shown in FIG. 12(C), the heat insulating box 102 of the refrigerator including the outer box 111, the inner box 112, and the vacuum heat insulating panels 130-133 is obtained.

As shown in FIG. 12(C), the heat insulating box 102 has a covering member 199. The covering member 199 is located at the corner CN of the inner box 112 and covers the gap of the corner CN. The covering member 199 has a function as a holding member for holding the angle of the corner portion CN at 90 degrees, and a function of blocking the intrusion of light by the gap of the corner portion CN. By the function of the covering member 199 as the holding member, the top surface portion 124, the side surface portion 125, and the side surface portion 126 are prevented from being bent and the angle of 90 degrees cannot be maintained. The covering member 199 can form an electric wire, a pipe, a cold air passage, or the like inside thereof. The inner box 112 is composed of a plurality of plates.

Further, in the above-described respective embodiments, in the heat insulating box 102 shown in FIG. 42(B), the vacuum heat insulating panel attached to the opening portion 156 on the back side may form the outer box 111 or the inner box 112. It is disposed after being disposed in the outer box 111.

The refrigerator of the embodiment includes an outer box, an inner box disposed inside the outer box, and a vacuum insulation panel disposed between the outer box and the inner box. Adjacent vacuum insulation panels in each of the vacuum insulation panels are disposed such that the corners of the outer casing and the inner casing are in contact with each other. Thereby, the corner portion of the refrigerator is filled with the vacuum heat insulating panel, and therefore, the heat insulating performance of the corner portion can be ensured.

Each of the above embodiments can be used arbitrarily in combination. Moreover, the structure of the refrigerator 1 shown in FIG. 1 is an example, and arbitrary structure can be employ|adopted.

The embodiments of the present invention have been described, but the embodiments are presented as examples and are not intended to limit the scope of the invention. The various embodiments of the invention can be embodied in various other forms, and various omissions, substitutions and changes can be made without departing from the scope of the invention. The invention or its modifications are intended to be included within the scope of the invention and the scope of the invention.

102‧‧‧Insulation box

111‧‧‧Outer box

112‧‧‧ inner box

114, 124‧‧‧ top face

114A‧‧‧The inner surface of the top surface 114

115, 125‧‧‧ left side face

115A‧‧‧The inner surface of the left side face 115

116, 126‧‧‧ right side face

116A‧‧‧The inner surface of the right side face 116

117, 127‧‧‧ bottom part

117A‧‧‧The inner surface of the bottom portion 117

130, 131, 132, 133‧‧ ‧ vacuum insulation panels

130F‧‧‧Left end

130G‧‧‧Right end

The inner side of the 131N‧‧‧ vacuum insulation panel 131

131R‧‧‧lower end of vacuum insulation panel 131

131T‧‧‧Upper end of vacuum insulation panel 131

132N‧‧‧ Inside of the vacuum insulation panel 132

132R‧‧‧lower end of vacuum insulation panel 132

132T‧‧‧Upper end of vacuum insulation panel 132

133F‧‧‧Left end

133G‧‧‧Right end

C‧‧‧ corner

T‧‧‧ size

Claims (11)

A method for manufacturing a heat insulation box of a refrigerator, wherein the heat insulation box of the refrigerator comprises a left heat insulation wall, a right heat insulation wall, an upper heat insulation wall, a lower insulation wall, and a rear heat insulation wall, and is open to the front surface a rectangular box shape, and each of the heat insulating walls has a vacuum insulation panel between the outer panel portion and the inner panel portion, and the manufacturing method is to manufacture the heat insulating wall body by the following steps (1) to (3). The heat insulating wall body includes a heat insulating wall of each of the heat insulating walls and two other heat insulating walls continuous with both sides of the heat insulating wall, and then the remaining two heat insulating walls are connected to the above Insulation wall main body: Step (1): using a flat plate-shaped plate member including a region corresponding to each of the heat insulating wall and the other two heat insulating walls, wherein the plate member corresponds to the above One surface of each of the vacuum insulation panels is adhered to the inner surface of each of the outer panel portions, and one of the vacuum insulation panels adjacent to each boundary portion of the region corresponding to each of the outer panel portions is vacuum insulated The end of the plate coincides with the boundary portion, so that the end of the other vacuum insulation panel is from the above boundary Leaving a distance, the distance is a minimum distance at which the plate member can be bent at the boundary portion, and bonding one surface of each of the vacuum insulation panels to the region corresponding to each of the outer plate portions; step (2): Before or after the execution of the above step (1), the inner plate portion is adhered to the surface of the vacuum insulation panel bonded to the step (1) opposite to the one surface; the step (3): After the above steps (1) and (2), the plate member is bent inward at the respective boundary portions. The method for manufacturing a heat insulating box for a refrigerator according to the first aspect of the invention, wherein The step (1) is performed after the inner plate portion is adhered to the opposite surface by applying an adhesive to the opposite surface of each of the vacuum insulation panels by roll coating. A refrigerator includes a heat insulating box, the heat insulating box includes: an outer box; an inner box disposed inside the outer box; and a vacuum heat insulating plate disposed between the outer box and the inner box; Adjacent vacuum insulation panels in each of the vacuum insulation panels are disposed such that the corner portions of the heat insulation box are in contact with each other. The refrigerator according to claim 3, wherein at the corner portion, an end portion of the vacuum heat insulating material disposed adjacent to the horizontal direction and a vacuum heat insulating material provided in the longitudinal direction Side contact. The refrigerator according to claim 3, wherein at the corner portion, an end portion of the vacuum heat insulating material adjacent to the longitudinal direction of the vacuum heat insulating material and a vacuum heat insulating material provided in the lateral direction Side contact. The refrigerator according to claim 3, wherein the corner of the outer casing is formed by bending a continuous plate, and the adjacent vacuum insulation panels are connected by the thin connecting portion at the corner portion, or The corners are separated. The refrigerator according to claim 3, wherein an end portion of the adjacent vacuum insulation panel is in contact with the corner portion. The refrigerator according to claim 7, wherein the contact portion of the end portion of the adjacent vacuum insulation panel is provided with a heat insulating material material. The refrigerator according to claim 3, wherein the inner box is configured by combining a plurality of sheets, and an end portion of the plurality of sheets adjacent to the sheets is disposed at a corner portion of the corner portion connected by a thin connecting portion Or a portion of the adjacent vacuum insulation panel that is separated. The refrigerator according to any one of claims 3 to 5, wherein the vacuum heat insulating material comprises a core material and a film covering the vacuum heat insulating material, and a sealing portion of the film is disposed outside the above The inner surface side of the box. The refrigerator according to any one of claims 3 to 9, wherein the heat insulating box is constructed in such a manner that heat insulation is produced by the following steps (1) to (3) The wall main body, the heat insulating wall main body includes one heat insulating wall of each of the heat insulating walls constituting the heat insulating box body, and two other heat insulating walls continuous with both sides of the heat insulating wall, and thereafter, remaining The two heat insulating walls are coupled to the heat insulating wall main body: Step (1): using a flat plate-shaped plate member including a region corresponding to each of the heat insulating walls and the outer wall portions of the other two heat insulating walls And attaching one surface of each of the vacuum insulation panels to an inner surface of a region of the plate member corresponding to each of the outer panel portions, and the vacuum adjacent to each boundary portion of the region corresponding to each of the outer panel portions An end of one of the heat insulation panels is aligned with the boundary portion such that an end of the other vacuum insulation panel is separated from the boundary portion by a distance at which the panel member is bendable at the boundary portion Fold the minimum distance and glue one side of each of the above vacuum insulation panels to Corresponding to the outer region of each of said plate portions; Step (2): before or after the execution of the above step (1), bonding the inner plate portion to the surface opposite to the one surface of the vacuum insulation panels bonded in the step (1); and Step (3): After performing the above steps (1) and (2), the plate member is bent inward at the respective boundary portions.