JP7032025B2 - Storage - Google Patents

Description

The present invention relates to a storage.

Conventionally, as a storage, it is known that the internal space of a heat insulating box is partitioned by a partition wall to form two adjacent storage chambers (Patent Document 1 below). In Patent Document 1, the partition wall has a pair of front and rear mounting plates, the front mounting plate is mounted on the partition frame (frame), and the rear mounting plate is mounted on the inner surface of the heat insulating box body (main body of the cooling storage). The configuration to be used is described.

Patent No. 3411182

In the above configuration, when the mounting plate is attached to the mounting target (partition frame or heat insulating box body), if a dimensional error occurs between the mounting plate and the mounting target, the mounting plate is slightly bent and deformed. , It is necessary to absorb the dimensional error. In this case, it is necessary to perform the mounting work while bending and deforming the mounting plate, and there is a concern that workability may be reduced. Further, in the above configuration, another member (duct) is attached to the mounting plate, but if the mounting plate bends and deforms, the positional relationship between the other member and the mounting plate shifts, and the other member is used as the mounting plate. There is concern that it will be difficult to install.

The present invention has been completed based on the above circumstances, and an object of the present invention is to provide a storage capable of absorbing a dimensional error related to a member for fixing a partition wall.

In order to solve the above problems, the storage of the present invention has a box body having an opening, a longitudinal partition frame attached to the box body and partitioning the opening, and between the inner surface of the box body and the partition frame. A partition wall for partitioning the internal space of the box body into two spaces, a first bracket for attaching the partition wall to the partition frame, and a second bracket for attaching the partition wall to the inner surface are provided. At least one of the first bracket and the second bracket is detachably attached to the partition wall, and the attachment position to the partition wall can be changed with respect to the arrangement direction of the inner surface and the partition frame. It is characterized by being.

By changing the mounting position of one bracket with respect to the partition wall, the position of the partition wall can be adjusted with respect to the alignment direction of the inner surface and the partition frame, and the dimensional error that occurs between the other bracket and its mounting target can be absorbed. be able to. In addition, since one bracket is configured separately from the partition wall, it can be put inside the box in a separated state, and the box is compared with the case where the bracket is integrally formed with the partition wall. It is easy to put it inside the body and the workability at the time of assembly is good.

Further, the first bracket and the second bracket are provided on the space side surface of one of the two spaces in the partition wall, and are arranged on the one space side with respect to the partition wall. It may be provided with a cooler and a cooling duct attached to both the first bracket and the second bracket and partitioning the one space into a cooler chamber and a storage chamber for accommodating the cooler. can. By attaching the cooling duct to the first bracket and the second bracket, a cooler chamber can be formed between the cooling duct and the partition wall. In the above configuration, since it is possible to absorb the dimensional error that occurs between the other bracket and the mounting target thereof, it is not necessary to bend and deform both brackets to absorb the dimensional error when both brackets are mounted. If the first bracket and the second bracket are bent and deformed, the mounting location of the cooling duct in the first bracket and the second bracket may be displaced from the predetermined position, which may make it difficult to mount the cooling duct. Such a situation can be suppressed.

Further, the one bracket has a long hole long in the line-up direction, and is attached to the partition wall by a fastening member having a shaft portion inserted into the long hole, and the shaft is attached to the partition wall in the line-up direction. The length of the portion may be set to a value smaller than the length of the elongated hole. By making the hole through which the shaft portion of the fastening member is inserted a long hole long in the alignment direction, the mounting position of one bracket with respect to the partition wall can be changed in the alignment direction.

Further, it is possible that a protrusion is provided on the surface of the partition frame on the side of the first bracket, and the first bracket is formed with an insertion hole through which the protrusion is inserted. By inserting the protrusion into the insertion hole, the first bracket can be easily attached to the partition frame. Since the protrusion is inserted into the insertion hole, the position of the first bracket can be slightly adjusted in the front-rear direction with respect to the partition frame, and it is possible to absorb the dimensional error in the front-rear direction between the partition frame and the front bracket. be.

Further, the first bracket may be detachably attached to the partition wall, and a sealing material may be interposed between the partition wall and the partition frame. With the first bracket removed from the partition wall, the sealing material can be filled between the partition wall and the partition frame, and the situation where the first bracket interferes with the filling work can be suppressed.

According to the present invention, it is possible to provide a storage capable of absorbing a dimensional error related to a member for fixing a partition wall.

A perspective view of a cooling storage according to an embodiment of the present invention. Cross-sectional view showing the internal structure of the cooling storage (view from the front side) Front view showing a heat insulating box Cross-sectional view showing the internal structure of the cooling storage (view from above) Cross-sectional view showing the machine room and the cooler room on the left side An exploded perspective view showing the partition wall, front bracket and rear bracket Perspective view showing partition wall, front bracket and rear bracket Perspective view showing partition wall, front bracket and rear bracket Cross-sectional view showing the mounting structure of the front bracket and the rear bracket to the partition wall. A view of the partition wall, the plate portion 51 of the front bracket, and the plate portion 61 of the rear bracket as viewed from the right side. Cross-sectional view showing the mounting structure of the front bracket to the partition frame Cross-sectional view showing the mounting structure of the rear bracket to the plate material 11B (back surface 11A). Perspective view showing the cooling duct Cross-sectional view showing the mounting structure of the cooling duct to the front bracket and the rear bracket. Perspective view showing a comparative example

An embodiment of the present invention will be described with reference to FIGS. 1 to 15. In this embodiment, as shown in FIG. 1, a two-door horizontal (table type) cooling storage 10 is exemplified as a storage. As shown in FIG. 1, the cooling storage 10 includes a horizontally long heat insulating box 11 (box body), a machine room 12 arranged on the side (left side) of the heat insulating box 11, and a pair of heat insulating doors 13L and 13R. And a top plate 15 constituting the top surface of the cooling storage 10. In the following description, the heat insulating door 13 side is the front side, the side opposite to the heat insulating door 13 is the rear side, and the front-rear direction is the Y-axis direction. Further, the left-right direction when the cooling storage 10 is viewed from the front side is the left-right direction (X-axis direction) of the cooling storage 10, and the height direction of the cooling storage 10 is the Z-axis direction.

As shown in FIG. 2, the heat insulating box 11 is configured by filling a heat insulating material 18 such as a foamed resin between the exterior plate 16 and the interior plate 17. As shown in FIG. 4, the heat insulating box 11 is divided into two spaces 20L and 20R by a partition wall 19. The space 20L on the left side is a space constituting the freezing chamber 22 and the cooler chamber 23L, and the space 20R on the right side is a space constituting the refrigerating chamber 24 and the cooler chamber 23R. The cooler chamber 23L accommodates a cooler 26L for cooling the freezing chamber 22, and the cooler chamber 23R accommodates a cooler 26R for cooling the refrigerating chamber 24.

As shown in FIG. 3, the heat insulating box 11 has an opening 27 opened forward. At the center of the opening 27 in the left-right direction, a long longitudinal partition frame 28 (center pillar) in the vertical direction is arranged so as to be passed between the upper and lower inner peripheral surfaces. The partition frame 28 is attached to the heat insulating box 11 at both the upper and lower ends. As a result, the opening 27 is divided into two left and right openings 27L and 27R by the partition frame 28. The storage can be taken in and out of the freezing chamber 22 through the opening 27L on the left side, and the storage can be taken in and out of the refrigerating chamber 24 through the opening 27R on the right side. As shown in FIG. 4, the pair of heat insulating doors 13L and 13R are double doors, the heat insulating door 13L on the left side can open and close the opening 27L, and the heat insulating door 13R on the right side opens and closes the opening 27R. It is a possible configuration.

As shown in FIG. 2, the freezing chamber 22 and the cooler chamber 23L are separated by a cooling duct (outlet duct 29 and suction duct 30). A cooling fan 31 is housed in the cooler chamber 23L, and a drain pan 32 is arranged below the cooler 26L. When the cooling fan 31 is driven, the air in the freezing chamber 22 is sucked into the cooler chamber 23L from the suction port of the suction duct 30, and is cooled in the process of passing through the cooler 26L to become cold air, and then blown out. It is blown out to the freezer chamber 22 from the outlet of the duct 29. This cools the freezing chamber 22. In FIG. 2, the partition wall 19 is not shown.

As shown in FIG. 1, the cooling storage 10 includes a side panel 33 constituting the left side surface, and the machine room 12 is formed between the heat insulating box 11 and the side panel 33. As shown in FIG. 5, the machine room 12 houses a cooling unit 37 including a compressor 34, a condenser 35, and a condenser fan 36. The compressor 34 and the condenser 35 have a cooler 26L. It is connected to each of the 26Rs and constitutes a known cooling cycle.

The partition wall 19 is configured by foam-filling the heat insulating material 42 (see FIG. 11) inside the outer shell 41 (see FIG. 6) constituting the outer surface, and has heat insulating properties. The outer shell 41 is formed by, for example, forming a plurality of metal plates into a box shape. As shown in FIG. 4, the partition wall 19 is arranged between the inner surface 11A of the heat insulating box 11 (a part of the inner surface of the heat insulating box 11) and the partition frame 28. That is, the partition frame 28, the partition wall 19, and the back surface 11A are arranged in the front-rear direction. As shown in FIG. 6, the front side bracket 50 (first bracket) and the rear side bracket 60 (second bracket) are provided on the space 20R side surface 19A (the space side surface of one of the two spaces) in the partition wall 19. ) Is provided. As shown in FIG. 7, the partition wall 19 is attached to the partition frame 28 by the front bracket 50. Further, as shown in FIG. 8, the partition wall 19 is attached to the back surface 11A by the rear bracket 60.

As shown in FIG. 6, the front bracket 50 has a long plate shape in the vertical direction and a substantially U shape opened on the rear side. The front bracket 50 includes a plate portion 51 arranged to face the partition wall 19, a plate portion 52 arranged to face the partition frame 28, and a plate portion 53 to which a cooling duct 70 (described later) is attached. A plurality of elongated holes 51A (two in this embodiment) are formed in the plate portion 51 in the front-rear direction (the direction in which the inner surface and the partition frame are arranged). A mounting hole 21A is formed at a position facing the elongated hole 51A in the outer shell body 41 of the partition wall 19. As shown in FIG. 9, the shaft portion 55B of the screw 55A (fastening member) inserted through the elongated hole 51A is inserted through the mounting hole 21A. As a result, the front bracket 50 is screwed to the outer shell 41 by the screw 55A.

Further, as shown in FIG. 10, in the front-rear direction (Y-axis direction), the length (diameter of the shaft portion) of the shaft portion 55B of the screw 55A is smaller than the size of the elongated hole 51A. Therefore, the front bracket 50 (at least one of the first bracket and the second bracket) is detachably attached to the partition wall 19 by the screw 55A, and the attachment position to the partition wall 19 can be changed in the front-rear direction. It has become.

As shown in FIG. 6, a plurality of insertion holes 52A (4 in this embodiment) are formed in the plate portion 52. As shown in FIG. 11, a protrusion 28A projecting rearward is formed on the rear surface of the partition frame 28 (the surface of the partition frame on the first bracket side). The protrusion 28A is inserted through the insertion hole 52A. As a result, the plate portion 52 (front bracket 50) is positioned in the vertical and horizontal directions with respect to the partition frame 28. As shown in FIG. 11, a caulking material 43 (seal material) is provided between the outer peripheral end surface of the partition wall 19 and the surface facing the outer peripheral end surface (inner surface of the heat insulating box 11 or the rear surface of the partition frame 28). Is intervening. As shown in FIG. 11, the front surface of the partition wall 19 and the rear surface of the partition frame 28 are arranged at a distance from each other. Therefore, in the front-rear direction, the facing distance between the back surface 11A of the heat insulating box 11 and the rear surface of the partition frame 28 is set to a value slightly larger than the length of the partition wall 19. As a result, the partition wall 19 can be reliably arranged between the inner surface 11A of the heat insulating box 11 and the rear surface of the partition frame 28 even when a dimensional error occurs in the front-rear direction. After arranging the partition wall 19, the gap between the front surface of the partition wall 19 and the rear surface of the partition frame 28 is filled with the caulking material 43.

As shown in FIG. 6, the rear bracket 60 has a long plate shape in the vertical direction and a substantially U shape opened on the front side. The rear bracket 60 includes a plate portion 61 arranged to face the partition wall 19, a plate portion 62 arranged to face the back surface 11A of the heat insulating box body 11, and a plate portion 63 to which a cooling duct 70 (described later) is attached. , Equipped with. A plurality of elongated holes 61A (two in this embodiment) are formed in the plate portion 61 in the front-rear direction (the direction in which the inner surface and the partition frame are arranged). A mounting hole 25A is formed in the outer shell body 41 of the partition wall 19 at a position facing the elongated hole 61A. As shown in FIG. 9, the shaft portion 56B of the screw 56A (fastening member) inserted through the elongated hole 61A is inserted through the mounting hole 25A. As a result, the rear bracket 60 is screwed to the outer shell 41 (partition wall 19) by the screw 56A.

Further, as shown in FIG. 10, in the front-rear direction, the length of the shaft portion 56B of the screw 56A (diameter of the shaft portion) is smaller than the size of the elongated hole 61A. Therefore, the rear bracket 60 is detachably attached to the partition wall 19 by the screw 56A, and the attachment position to the partition wall 19 can be changed in the front-rear direction.

Further, as shown in FIG. 6, a plurality of insertion holes 62A (4 in this embodiment) are formed in the plate portion 62. As shown in FIG. 12, the shaft portion 57B of the screw 57A inserted through the insertion hole 62A is inserted into the mounting hole 11C formed in the plate material 11B (a part of the interior plate 17) constituting the back surface 11A. .. As a result, the rear bracket 60 is screwed to the plate material 11B by the screw 57A.

As shown in FIG. 4, the cooler 26R (cooler arranged on one space side) is arranged on the space 20R side (right side in FIG. 4) with respect to the partition wall 19. Further, as shown in FIG. 7, a drain pan 38 is arranged below the cooler 26R. Then, as shown in FIG. 4, a substantially plate-shaped cooling duct 70 is arranged so as to cover the cooler 26R from the side opposite to the partition wall 19. As a result, the space 20R (one space) is partitioned by the cooling duct 70 into the cooler room 23R and the refrigerating room 24 (storage room).

As shown in FIGS. 13 and 14, the cooling duct 70 is attached to both the plate portion 53 of the front bracket 50 and the plate portion 63 of the rear bracket 60. As shown in FIG. 6, a plurality of mounting holes 53A (three in the present embodiment) are formed in the plate portion 53, and a plurality of mounting holes 63A (three in the present embodiment) are formed in the plate portion 63. ing. As shown in FIG. 14, the side end portion 73 on the front side (lower side of FIG. 14) of the cooling duct 70 has an insertion hole 73A facing the mounting hole 53A. The shaft portion 71B of the screw 71 inserted through the insertion hole 73A is inserted into the mounting hole 53A. As a result, the side end portion 73 is screwed to the plate portion 53 by the screw 71.

As shown in FIG. 14, the side end portion 74 on the rear side of the cooling duct 70 has an insertion hole 74A facing the mounting hole 63A. The shaft portion 72B of the screw 72 inserted through the insertion hole 74A is inserted into the mounting hole 63A. As a result, the side end portion 74 is screwed to the plate portion 63 by the screw 72. Further, as shown in FIG. 13, the cooling duct 70 has a suction port 75 and an outlet 76. By driving a cooling fan (not shown) arranged in the cooler chamber 23R, the air in the refrigerating chamber 24 is sucked into the cooler chamber 23R from the suction port 75 and cooled in the process of passing through the cooler chamber 26R. The air becomes cold and then blown out from the outlet 76 to the refrigerator compartment 24. This cools the refrigerator compartment 24. Further, as shown in FIG. 14, the insertion holes 73A and 74A are elongated holes that are long in the front-rear direction (vertical direction in FIG. 14), and the length of the shaft portion 71B of the screw 71 (shaft portion) in the front-rear direction. The diameter) is set to a value smaller than the size of the insertion hole 73A, and the length (diameter of the shaft portion) of the shaft portion 72B of the screw 72 is set to a value smaller than the size of the insertion hole 74A. Therefore, the mounting position of the cooling duct 70 with respect to the front bracket 50 and the rear bracket 60 can be changed in the front-rear direction.

Next, the effect of this embodiment will be described. In the present embodiment, the mounting position of each of the front bracket 50 and the rear bracket 60 with respect to the partition wall 19 can be changed in the front-rear direction. Therefore, by changing the mounting position of the front bracket 50 or the rear bracket 60 with respect to the partition wall 19, the position of the partition wall 19 can be adjusted in the front-rear direction, which occurs between the front bracket 50 and the partition frame 28. It is possible to absorb dimensional errors or dimensional errors that occur between the rear bracket 60 and the back surface 11A. Further, since the front bracket 50 and the rear bracket 60 are formed separately from the partition wall 19, they can be put inside the heat insulating box 11 in a separated state. As a result, as shown in the comparative example of FIG. 15, it is easier to put the front bracket 5 and the rear bracket 6 inside the heat insulating box 11 as compared with the case where the front bracket 6 and the rear bracket 6 are integrally formed with the partition wall 19, and at the time of assembly. Workability is good.

Further, in the present embodiment, the heat insulating box body 11, the partition frame 28, and the partition wall 19 are each provided with a heat insulating material such as foamed resin. In this case, dimensional errors are likely to occur due to the shrinkage and expansion of the heat insulating material. In the present embodiment, the dimensional error can be absorbed by adjusting the mounting positions of the brackets 50 and 60 with respect to the partition wall 19, which is preferable.

Further, the front bracket 50 and the rear bracket 60 are provided on the surface 19A on the space 20R side of the partition wall 19, and the cooler 26R arranged on the space 20R side with respect to the partition wall 19 and the front bracket 50 and the rear side. A cooling duct 70, which is attached to both of the brackets 60 and divides the space 20R into a cooler chamber 23R and a refrigerating chamber 24, is provided. By attaching the cooling duct 70 to the front bracket 50 and the rear bracket 60, the cooler chamber 23R can be formed between the cooling duct 70 and the partition wall 19. In the present embodiment, since the dimensional error generated between the brackets 50 and 60 and the mounting target thereof can be absorbed, both brackets 50 and 60 are flexed and deformed in the front-rear direction when both brackets 50 and 60 are mounted to reduce the dimensional error. No need to absorb. If the bracket 50 or the bracket 60 is bent and deformed, the positions of the mounting points (mounting holes 53A and 63A) of the cooling duct 70 may be displaced from the predetermined positions, which may make it difficult to mount the cooling duct 70. , Such a situation can be suppressed.

For example, as shown in the comparative example of FIG. 15, when the front bracket 5 and the rear bracket 6 having an L shape are integrally formed with the partition wall 19, the front bracket 5 and the rear bracket 6 are used. It is necessary to absorb the dimensional error by bending and deforming in the front-back direction (Y-axis direction). If the brackets 5 and 6 are deformed, the mounting holes 5A and 6A for mounting the cooling duct 70 may be displaced from the predetermined positions, which may make it difficult to mount the cooling duct 70. However, in the present embodiment, there is a concern. , Such a situation can be suppressed.

Further, the front bracket 50 and the rear bracket 60 have elongated holes 51A and 61A, respectively, which are long in the front-rear direction, and are attached to the partition wall 19 by screws 55A and 56A inserted through the elongated holes 51A and 61A, respectively. In the front-rear direction, the length of the shaft portion 55B of the screw 55A is set to a value smaller than the length of the elongated hole 51A, and the length of the shaft portion 56B of the screw 56A is set to a value smaller than the length of the elongated hole 61A. It is set. By setting the holes through which the shaft portions 55B and 56B of the screws 55A and 56A are inserted to the elongated holes 51A and 61A, the mounting positions of the front bracket 50 and the rear bracket 60 with respect to the partition wall 19 can be changed in the front-rear direction. ..

Further, a protrusion 28A is provided on the surface of the partition frame 28 on the front bracket 50 side, and the front bracket 50 is formed with an insertion hole 52A into which the protrusion 28A is inserted. By inserting the protrusion 28A into the insertion hole 52A, the front bracket 50 can be easily attached to the partition frame 28. In the present embodiment, for example, after the protrusion 28A is inserted into the insertion hole 52A, the front bracket 50 is screwed to the partition wall 19. Since the protrusion 28A is inserted into the insertion hole 52A, the position of the front bracket 50 can be slightly adjusted in the front-rear direction with respect to the partition frame 28, and the dimensional error in the front-rear direction between the partition frame 28 and the front bracket 50 is absorbed. It is possible to do.

Further, the front bracket 50 is detachably attached to the partition wall 19, and a caulking material 43 is interposed between the partition wall 19 and the partition frame 28. With the front bracket 50 removed from the partition wall 19, the caulking material 43 can be filled between the partition wall 19 and the partition frame 28, and the situation where the front bracket 50 interferes with the filling work can be suppressed. .. In a state where the front bracket 50 is removed from the partition wall 19, for example, the caulking material 43 can be filled between the partition wall 19 and the partition frame 28 from the right side (space 20R side) of FIG.

In this embodiment, for example, as shown in FIG. 12, the partition wall 19 is fixed to the back surface 11A by the rear bracket 60 in a state where the back surface 11A and the partition wall 19 are in contact with each other, and the front bracket is used. By adjusting the front-rear position of the 50, the front bracket 50 can be attached to the partition frame 28 by absorbing the dimensional error in the front-rear direction. Further, when the back surface 11A is wavy due to the contraction or expansion of the heat insulating material 18, the partition wall 19 is moved forward with respect to the rear bracket 60 to move the partition wall 19 from the back surface 11A. It is possible to fix it in a slightly separated state.

Further, in the present embodiment, the dimensional error in the front-rear direction may be absorbed by changing the mounting position of one of the front bracket 50 and the rear bracket 60, and the mounting of both brackets 50 and 60 may be absorbed. The dimensional error in the front-rear direction may be absorbed by changing the position. Larger dimensional errors can be absorbed by changing the mounting positions of both brackets 50 and 60. Since the insertion holes 73A and 74A of the cooling duct 70 are long holes long in the front-rear direction, even if the distance between the brackets 50 and 60 changes in the front-rear direction as a result of absorbing the dimensional error, the cooling duct 70 is cooled. The duct 70 can be attached to both brackets 50 and 60.

<Other embodiments>
The present invention is not limited to the embodiments described above and the drawings, and for example, the following embodiments are also included in the technical scope of the present invention.
(1) In the above configuration, an example is provided in which one space is divided into two spaces arranged side by side as a partition wall, but the present invention is not limited to this. For example, one space may be divided into two spaces arranged one above the other as a partition wall. Further, the inner surface of the box body is not limited to the inner surface, and the arrangement direction of the inner surface of the box body and the partition frame is not limited to the front-rear direction.
(2) In the above embodiment, only one of the front bracket 50 and the rear bracket 60 may have a configuration in which the mounting position with respect to the partition wall 19 can be changed.
(3) In the above embodiment, a storage having a refrigerating room and a freezing room is exemplified, but the storage is not limited to this, as long as the storage has two spaces (for example, two storage rooms) partitioned by a partition wall. good.
(4) The fastening member is not limited to the screw and can be changed as appropriate. For example, bolts and nuts may be used as fastening members.
(5) In the above embodiment, the mounting position of the bracket with respect to the partition wall can be changed by forming a long hole in the bracket, but the present invention is not limited to this. For example, the mounting position of the bracket with respect to the partition wall may be changed by forming an elongated hole in the partition wall.

10 ... Cooling storage (storage), 11 ... Insulated box body (box body), 11A ... Back surface (inner surface of box body), 19 ... Partition wall, 19A ... Partition wall surface (one of the two spaces on the space side) 20 ... space inside the box, 20R ... space (one of the two spaces), 20L ... space (the other space of the two spaces), 23R ... cooler room, 24 ... refrigerating room 24 (storage room), 26R ... cooler (cooler arranged on one space side), 27 ... opening, 28 ... partition frame, 28A ... protrusion, 43 ... coking material (sealing material), 50 ... front bracket (First bracket), 51A, 61A ... Long hole, 52A ... Insertion hole (insertion hole through which a protrusion is inserted), 55A ... Screw (fastening member), 56A ... Screw (fastening member), 60 ... Rear bracket (1st bracket) 2nd bracket), 70 ... Cooling duct

Claims (4)

A box with an opening and
A long-shaped partition frame attached to the box body and partitioning the opening,
A partition wall arranged between the inner surface of the box body and the partition frame and partitioning the internal space of the box body into two spaces,
A first bracket for attaching the partition wall to the partition frame,
A second bracket, which is composed of a separate member from the first bracket and attaches the partition wall to the inner surface, is provided.
At least one of the first bracket and the second bracket is detachably attached to the partition wall, and the attachment position to the partition wall can be changed with respect to the arrangement direction of the inner surface and the partition frame. It ’s a storage room
The one bracket is arranged so as to face the partition wall, is connected to a first plate portion including an elongated hole long in the arrangement direction of the inner surface and the partition frame, and is connected to the first plate portion, and is connected to the partition. It has a frame or a second plate portion attached to the inner surface thereof, and has a second plate portion.
In a state where the second plate portion is attached to the partition frame or the inner surface, the first plate portion is inserted into the elongated hole and the attachment position of the first plate portion with respect to the partition wall is adjusted in the alignment direction. , A storage including a fastening member including a shaft portion for attaching the first plate portion to the partition wall. The one bracket is the first bracket.
The partition wall has a first end surface that abuts on the inner surface of the box body and a second end surface that faces the partition frame while maintaining a distance from the partition frame.
A sealing material is interposed between the second end surface of the partition wall and the partition frame.
The storage according to claim 1, wherein the first plate portion is arranged to face the sealing material together with the partition wall. The first bracket and the second bracket are provided on the space-side surface of one of the two spaces in the partition wall.
A cooler arranged on one of the space sides with respect to the partition wall,
The first claim or the second claim is provided with a cooling duct attached to both the first bracket and the second bracket and partitioning the one space into a cooler chamber and a storage chamber for accommodating the cooler. Storage. A protrusion is provided on the surface of the partition frame on the first bracket side.
The storage according to any one of claims 1 to 3, wherein the first bracket is formed with an insertion hole through which the protrusion is inserted.

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