阅读说明：本技术 磁性垫及冷却装置 (Magnetic pad and cooling device ) 是由 冈崎亨 南尾匡纪 瀬川彰继 浅井田康浩 川合文彦 高见文宣 于 2019-06-26 设计创作，主要内容包括：一种磁性垫及冷却装置,使绝热性能提高。冷却装置具有：绝热箱体,其具有在前方开口的收纳空间,并具有包围开口且面向前方的开口端面；箱门,其可打开、关闭开口地安装在绝热箱体；磁性垫,其在关闭开口的状态下安装在面向开口端面的箱门的内侧周缘部,并具有磁铁、保持磁铁的磁铁保持部、以及绝热片,该绝热片在磁铁与磁铁保持部之间,在箱门关闭开口的状态下,设置在磁铁的周面之内且箱门侧的侧部以及在关闭状态下面向宽度方向内侧的侧部。(A magnetic pad and a cooling device are provided to improve heat insulation performance. The cooling device comprises: a heat insulation box body having a storage space opened at the front and having an opening end face surrounding the opening and facing the front; a door mounted on the heat insulating cabinet to open and close the opening; and a magnetic pad which is attached to an inner peripheral edge portion of the door facing an end surface of the opening in a state where the opening is closed, and which has a magnet, a magnet holding portion for holding the magnet, and a heat insulating sheet which is provided between the magnet and the magnet holding portion, and which is provided inside a peripheral surface of the magnet and on a side portion of the door side in a state where the door is closed in the opening, and on a side portion of the door facing inward in a width direction in the closed state.)

1. A cooling device, comprising:

a heat insulation box body having a storage space opened at the front and having an opening end surface surrounding the opening and facing the front;

a door installed in the heat insulation box body to open and close the opening;

a magnetic pad attached to an inner peripheral edge portion of the door facing the opening end face in a state where the opening is closed,

the magnetic pad has:

a magnet;

a magnet holding portion that holds the magnet;

and a heat insulating sheet provided between the magnet and the magnet holding portion, the heat insulating sheet being provided on a side portion of the door side within a peripheral surface of the magnet in a closed state in which the door closes the opening, and the heat insulating sheet being provided on a side portion of the door side in the closed state.

2. The cooling apparatus according to claim 1,

a heat sink is disposed in the heat insulating box body, and the heat sink is located outside the magnet in the width direction in the closed state.

3. Cooling arrangement according to claim 1 or 2,

a curved surface portion is provided on the peripheral surface of the magnet between the door side portion and the door inner side portion.

4. The cooling apparatus according to claim 1,

the thermal insulation sheet is formed from a raw material containing xerogel or aerogel.

5. A magnetic mat, comprising:

a magnet;

a magnet holding portion that holds the magnet;

and a heat insulating sheet provided between the magnet and the magnet holding portion.

6. A cooling device, comprising:

a heat insulation box body having a storage space opened at the front and having an opening end surface surrounding the opening and facing the front;

a door installed in the heat insulation box body to open and close the opening;

the magnetic gasket of claim 1, which is provided at an inner peripheral edge portion of the door facing an end surface of the opening in a state where the opening is closed.

7. The cooling apparatus of claim 6,

the heat insulating sheet is provided on the peripheral surface of the magnet, and at least a surface facing the opening end surface is removed in a closed state where the door closes the opening.

8. Cooling arrangement according to claim 6 or 7,

the heat insulating sheet is arranged on the side part of the box door and the inner side part of the box in the peripheral surface of the magnet,

the side part of the box door is the part of the box door side,

the box inner side portion is a portion facing the inside in the width direction in the closed state.

9. The cooling apparatus of claim 8,

a heat sink is disposed in the heat insulating box body, and the heat sink is located outside the magnet in the width direction in the closed state.

10. The cooling apparatus of claim 8,

a curved surface portion is provided on the peripheral surface of the magnet between the door side portion and the door inside portion.

11. The cooling apparatus of claim 6,

the thermal insulation sheet is formed from a raw material containing xerogel or aerogel.

Technical Field

The present invention relates to a magnetic gasket and a cooling device having the magnetic gasket on a peripheral edge portion of an inner side of a box door.

Background

In a refrigerator, in order to insulate the inside of the refrigerator (hereinafter also referred to as "inside of the refrigerator") and maintain a low temperature, it is necessary to prevent cold air inside the refrigerator from leaking to the outside of the refrigerator or air outside from the outside of the refrigerator (hereinafter also referred to as "outside of the refrigerator") from invading into the refrigerator. Therefore, in a state where the door is closed, the opening end surface of the heat insulating box, which is the storage portion, and the peripheral edge portion of the door in contact with the opening end surface are required to be kept in close contact with each other along the entire periphery. In the refrigerator, a magnetic pad having flexibility is generally provided at a peripheral edge portion of an inner side of the door, and the heat insulating box body is brought into close contact with the door by a magnetic force of the magnetic pad in a state where the door is closed.

Since the refrigerator is continuously operated at ordinary times unlike other home appliances, the demand for energy saving performance of the refrigerator is very strong. Therefore, the magnetic pad is designed to reliably bring the heat insulating box body and the box door into close contact with each other along the entire circumference, and to prevent heat from being transferred from the magnetic pad into the box.

For example, there is disclosed a structure in which: by bringing the magnet of the magnetic pad attached to the door into direct contact with the opening end face of the heat insulating box body, the magnetic force (attraction force) acting on the opening end face is increased, and the door and the heat insulating box body are brought into more reliable close contact.

Fig. 7 is a sectional view of a main part showing a state in which the door disclosed in patent document 1 is in close contact with an opening end face of the heat insulating box body. The heat insulating box shown in fig. 7 is a refrigerator main body, and is composed of an outer box 70, an inner box 72, and a heat insulating material 71 filled between the outer box 70 and the inner box 72. A magnetic pad 60 is attached to a peripheral edge portion of the rear surface side (the side opposite to the opening end surface of the heat insulating box) of the door 50, and a flange portion 72a formed of a magnetic material is provided on a peripheral edge of the front surface (the opening end surface) of the outer box 70. By attracting the magnetic pad 60 to the flange portion 72a, the door 50 and the heat insulating box body are brought into close contact with each other via the magnetic pad 60. This effectively seals the door 50 and the outer box 70, and thermally isolates the storage chamber 80 (inside the box) from the outside. Further, heat transfer between the inside and outside of the box is suppressed by the heat insulating material 71 filled between the outer box 70 and the inner box 72. With the above configuration, the storage chamber 80 is maintained at a predetermined temperature.

The door 50 includes a door inner panel 51, a mounting groove 52, and a heat insulator 71, and a refrigerant pipe 90 is disposed in the heat insulating box body near the outer box 70.

Here, the magnetic pad 60 includes a magnet holding portion 61, a magnet 62, a mounting portion 63, and a bag portion 64 connecting the magnet holding portion 61 and the mounting portion 63.

The magnet holding portion 61 is not in the form of a bag into which a band-shaped magnet is inserted as in the conventional art, but has a コ -shaped cross section with one surface on the side of the heat insulating box being an attracting surface. The magnet holding portion 61 is integrally formed with a wedge-shaped protrusion from the コ -shaped bottom surface toward the magnet 62. The wedge-shaped protrusion is provided on the entire circumference of the magnetic pad 60.

The magnet 62 is housed in the magnet holding portion 61. In a state where the door is closed, the magnet 62 is disposed so that the outer flat surface 62a exposed from the magnet holding portion 61 faces the end surface of the opening end surface of the heat insulating box. Further, an insertion groove for narrowing an opening (entrance) is formed on the lower surface side of the magnet 62. The magnet 62 is attached so as not to be pulled out from the magnet holding portion 61 by being fitted into the fitting groove by the elasticity of the wedge-shaped protrusion of the magnet holding portion 61.

Two grooves 62b are provided on the outer flat surface 62a of the magnet 62, and the heat conduction is suppressed by the air layer of the grooves 62 b. Since the magnet 62 directly contacts the open end face of the heat insulating box, the magnetic force is not attenuated, and a sufficient attractive force can be obtained.

Further, a magnetic pad has also been disclosed (for example, see patent document 2) in which: in order to prevent the magnetic mat from penetrating the heat of the outside air from the outside of the box due to its heat conduction, the surface facing the outside of the box has a block-shaped heat insulating material. The magnetic pad has a hollow chamber and a magnet chamber located on the solid side and insulated from the hollow chamber, and has a block-shaped insulating material on the surface of the wall surface of the hollow chamber that contacts the outside air. With the above configuration, the heat conducted by the air and convection in the hollow chamber and the heat conducted by the magnetic pad itself are isolated by the heat insulating material, and the heat conduction into the tank is suppressed. Therefore, the cooling efficiency for cooling the inside of the heat insulating box can be improved.

In another conventional example, a magnetic pad structure has been disclosed (for example, see patent document 3) in which: an air layer is provided between the magnet and the magnet holding portion in order to prevent external heat from entering the box from the vicinity of the magnet of the magnetic pad of the box door. The refrigerator disclosed in patent document 3 includes: the refrigerator comprises a refrigerator main body, a refrigerator door and a magnetic pad positioned on the peripheral edge of the refrigerator door. The magnetic pad has: the door comprises a mounting portion mounted on the door, a magnet holding portion holding a magnet therein, and a flexible portion telescopically connecting the mounting portion and the magnet holding portion. The magnetic pad is characterized in that an air layer is formed between the magnet and the inner peripheral surface of the magnet holding portion inside the magnet holding portion.

Thus, the magnetic force of the attracting surface portion of the magnet can be maintained, the magnet can be miniaturized, and the heat conducted to the magnet can be reduced from penetrating into the box through the magnet maintaining portion.

Disclosure of Invention

The present invention has been made to solve the above-described problems of the prior art, and an object of the present invention is to improve the heat insulating performance of a magnetic mat and a cooling device.

Technical solution for solving technical problem

A cooling device according to an aspect of the present invention includes: a heat insulation box body having a storage space opened at the front and having an opening end surface surrounding the opening and facing the front; a door installed in the heat insulation box body to open and close the opening; and a magnetic pad which is attached to an inner peripheral edge portion of the door facing an end surface of the opening in a state where the opening is closed, and which has a magnet, a magnet holding portion, and a heat insulating sheet between the magnet and the magnet holding portion, wherein the magnetic pad is provided inside a peripheral surface of the magnet and on a side portion of the door side and on a side portion of the door facing a width direction inside in the closed state where the door is closed.

A magnetic mat according to one aspect of the present invention includes a magnet, a magnet holding portion for holding the magnet, and a heat insulating sheet provided between the magnet and the magnet holding portion.

A cooling device according to an aspect of the present invention includes: a heat insulation box body having a storage space opened at the front and having an opening end surface surrounding the opening and facing the front; a door installed in the heat insulation box body to open and close the opening; and a magnetic pad which is one aspect of the present invention and is attached to an inner peripheral edge portion of the door facing the opening end surface in a state where the opening is closed.

ADVANTAGEOUS EFFECTS OF INVENTION

According to the present invention, the magnetic mat can be used to improve the heat insulating performance.

Drawings

Fig. 1 is a perspective view of a refrigerator according to an embodiment of the present invention.

Fig. 2 is a view showing the structures of the heat insulating box body, the magnetic cushion, and the door portion in the refrigerator according to the present embodiment, and is a sectional view of a main portion taken along a plane a in fig. 1.

Fig. 3 is a diagram showing a structure of a magnetic pad in the refrigerator according to the present embodiment, and is a cross-sectional view taken in a direction perpendicular to a longitudinal direction.

Fig. 4 is a view showing a state in which the magnet and the heat insulating sheet are bonded to each other in the refrigerator according to the present embodiment, and is a cross-sectional view taken in a direction perpendicular to the longitudinal direction.

Fig. 5A is a diagram showing a model region of a simulation in which the amount of heat entering from the gasket peripheral portion is calculated.

Fig. 5B is an enlarged view of the magnet peripheral portion of the washer in the model region.

Fig. 5C is a graph showing the result of the simulation (amount of heat intrusion).

Fig. 6 is a sectional view showing a modification of the magnet in the refrigerator according to the present embodiment.

Fig. 7 is a cross-sectional view showing an example of a conventional gasket structure.

Description of the reference numerals

1 refrigerator (cooling device); 10 heat insulation box body; 10A open end face; 10a an outer case; 10b an inner box; 10c a heat insulating member; 10d a storage space; 11a refrigerating chamber; 12 a second freezing chamber; 13 an ice making chamber; 14 a first freezing chamber; 15 vegetable room; 20a box door; 20a outer plate of the door; 20b a door inner panel; 20c a thermal insulation member; 20d embedding the groove; 21 a right refrigerator door of the refrigerating chamber; 22 a left refrigerator door of the refrigerating chamber; 23 a second freezer compartment door; 24 ice making chamber door; 25 a first freezer compartment door; 26 vegetable room door; 30 a magnetic pad; 31, 311 magnets; 31a box inside side; 311a box inside end surface portion (box inside portion); 31b a door-side plane; 311b a door-side planar portion (door-side portion); 31c a box outer side surface; 311c curved surface portion; 31d outer side of the case; 311d box outer side end face part; 32 magnet holding parts; 33 an installation part; 34 a connecting part; 35 a heat insulating sheet; 40 heat dissipation pipes; c invading the heat quantity calculating part; m magnet peripheral part.

Detailed Description

Hereinafter, a magnetic pad and a refrigerator according to an embodiment of the present invention will be described with reference to the drawings. The embodiments described below are merely exemplary in principle, and various modifications and technical applications that are not explicitly described in the embodiments below are not excluded. In addition, various modifications may be made to the respective configurations of the embodiment without departing from the gist thereof. The respective configurations of the embodiments may be substituted or appropriately combined as necessary.

In all the drawings for describing the embodiments, the same reference numerals are used for the same main components in principle, and the description thereof may be omitted.

[1. Structure ]

Hereinafter, the side having the doors 21 to 26 will be referred to as the front side and the opposite side will be referred to as the rear side. The left and right sides are determined based on a forward and backward observation. Both the left and right directions are collectively referred to as a width direction. The direction approaching the width direction center CL is referred to as the width direction inner side, and the direction away from the width direction center CL is referred to as the width direction outer side.

[1-1. Structure of refrigerator ]

Next, referring to fig. 1, the overall structure of the refrigerator 1 will be described. Fig. 1 is a perspective view of a refrigerator 1 (cooling device) according to an embodiment of the present invention.

The refrigerator 1 has: the heat insulating box 10 has a storage space 10d (hereinafter referred to as "box interior") formed therein and an open front side, a plurality of doors 21 to 26 attached to the heat insulating box 10 so as to be openable and closable, and a magnetic pad 30 described later provided on an inner peripheral edge portion of the doors 21 to 26. The compartment 10d is partitioned by a partition (not shown) into a refrigerating compartment 11, a second freezing compartment 12, an ice-making compartment 13, a first freezing compartment 14, and a vegetable compartment 15.

The inner peripheral edge portions of the doors 21 to 26 are outer peripheral edges of surfaces facing the inside 10d of the cabinet in a state where the doors 21 to 26 are closed. Further, the inner peripheral edges of the doors 21 to 26 are portions facing the heat insulating box 10 and the opening end faces 10A (i.e., surfaces around the openings, see fig. 2) of the refrigerating compartment 11, the second freezing compartment 12, the ice making compartment 13, the first freezing compartment 14, and the vegetable compartment 15, which will be described later, with the magnetic mat 30 interposed therebetween in a state where the doors 21 to 26 are closed.

In the following description, the door 20 is referred to without distinguishing the doors 21 to 26.

Heat insulation box 10 has a refrigerating chamber 11 provided at the uppermost portion thereof, a second freezing chamber 12 and an ice-making chamber 13 provided in parallel at the lower portion of refrigerating chamber 11, a first freezing chamber 14 provided at the lower portion thereof, and a vegetable chamber 15 provided at the lowermost portion thereof.

In the present embodiment, refrigerating room 11, second freezing room 12, ice making room 13, first freezing room 14, and vegetable room 15 are provided as described above, but the present invention is not limited to the above configuration. It is of course possible to apply, without any limitation, to an apparatus for receiving and storing refrigerated goods, such as a refrigerator having only a refrigerating chamber, a refrigerator having only a freezing chamber, a refrigerator having a refrigerating chamber and a refrigerator having only one or more than three freezing chambers, and the like.

The refrigerating compartment 11, the second freezing compartment 12, the ice making compartment 13, the first freezing compartment 14, and the vegetable compartment 15 have openings as described above. A door 20 is provided in each opening. For example, the refrigerating room 11 has a rotatable refrigerating room right door 21 and a rotatable refrigerating room left door 22, and is configured to be opened in the left-right direction. A refrigerating compartment rack (not shown) and a refrigerating compartment box (not shown) are disposed inside the refrigerating compartment 11. Second freezing chamber 12, ice making chamber 13, first freezing chamber 14, and vegetable chamber 15 are drawer-type storage chambers, and second freezing chamber door 23, ice making chamber door 24, first freezing chamber door 25, and vegetable chamber door 26 are integrally provided.

The temperature of refrigerating room 11 is set to a refrigerating temperature range of about 1 to 5 ℃, which is a refrigerating temperature band of a temperature not freezing for refrigerating storage. The temperature of the vegetable compartment 15 is set to a range of about 2 to 7 ℃, which is the same refrigeration temperature zone as the refrigeration compartment 11 or a vegetable temperature zone set to a temperature slightly higher than the refrigeration temperature zone. First freezing chamber 14 is normally set to a temperature range of about-22 ℃ to-15 ℃ for cryopreservation, but may be set to a low temperature of about-30 ℃ to-25 ℃ for example when it is desired to further improve the cryopreservation state of the stored material.

The temperature of second freezing chamber 12 is set to the same freezing temperature zone as first freezing chamber 14 or a temperature zone slightly higher than the freezing temperature zone, i.e., a temperature range of-20 ℃ to-12 ℃. The ice making chamber 13 stores water supplied from a water storage tank (not shown) in the refrigerating chamber 11, and ice is made by an automatic ice maker (not shown) provided at an upper portion of the chamber.

The respective set temperature ranges of refrigerating room 11, second freezing room 12, ice making room 13, first freezing room 14, and vegetable room 15 are representative temperature ranges, and are not limited to the above temperature ranges, and may be set as appropriate according to the respective usage modes and the like.

The refrigerator 1 has a machine room (not shown). The machine chamber accommodates high-pressure side components of the refrigeration cycle, such as a compressor and a dryer that removes moisture. The refrigeration cycle is formed of a series of refrigerant flow paths including a compressor (not shown), a condenser (not shown), a capillary tube (not shown) as a decompressor, and a cooler (not shown) in this order. A hydrocarbon refrigerant, for example, isobutane is sealed in the refrigerant flow path as a refrigerant.

The configuration of the refrigeration cycle of the refrigerator 1 according to the present invention is not limited to the above configuration, and any configuration may be used as long as it generates cold air in a desired temperature range for refrigeration or freezing.

[1-2. Structure of the main portion and magnetic pad of refrigerator ]

Next, the main parts of the refrigerator 1 and the structure of the magnetic pad 30 will be described with reference to fig. 2 to 4. Fig. 2 is a view showing the structures of the heat insulating box 10, the magnetic cushion 30, and the door 20 in the refrigerator 1 according to the present embodiment, and is a sectional view of a main portion taken along a plane a indicated by a one-dot chain line in fig. 1. Fig. 3 is a diagram showing the structure of the magnetic pad 30 in the refrigerator 1 according to the present embodiment, and is a cross-sectional view (cross-sectional view) taken in a direction perpendicular to the longitudinal direction (extending direction of the magnetic pad 30). Fig. 4 is a view showing a state in which the magnet and the heat insulating sheet are bonded to each other in the refrigerator according to the present embodiment, and is a cross-sectional view cut in a direction perpendicular to the longitudinal direction.

As shown in fig. 2, the heat insulating box body 10 includes an outer box 10a made of a magnetic material (e.g., a steel plate), an inner box 10b molded from a resin such as an ABS resin, and a heat insulating member 10c foamed in a space between the outer box 10a and the inner box 10b and filled with a hard foamed urethane resin or the like.

In refrigerator 1, when refrigerating room 11 (see fig. 1) or the like is cooled, a part of outer box 10a may be cooled and frost may be formed on outer box 10 a. In order to prevent frost formation, as shown in fig. 2, a heat pipe 40 as a heat source is disposed inside the outer case 10 a.

The heat insulating member 10c is not limited to a resin such as a foamed urethane resin. As the heat insulating member 10c, a material having heat insulating properties such as a vacuum heat insulating material can be suitably used.

As shown in fig. 2, each door 20 includes a door outer plate 20a, a door inner plate 20b formed of, for example, ABS resin, and a heat insulating member 20c foamed in a space between the door outer plate 20a and the door inner plate 20b and filled with hard foamed urethane or the like. In each door 20, an insertion groove 20d for inserting and fixing the mounting portion 33 of the magnetic pad 30 is also formed by sinking the door inner panel 20 b.

The heat insulating member 20c is not limited to a resin such as foamed urethane, as in the heat insulating member 10c used in the heat insulating box 10. For example, a vacuum heat insulating material or the like may be used for the heat insulating member 20 c.

As shown in fig. 2, a magnetic cushion 30 made of soft resin such as polyvinyl chloride, for example, by extrusion molding is provided at the peripheral edge portion of each door 20 on the storage compartment side in order to seal the gap between the door 20 and the heat insulating box 10 and prevent leakage of cold air and intrusion of heat from outside air.

The magnetic pad 30 has: magnet 31 having flexibility, magnet holding portion 32, attachment portion 33, connection portion 34 connecting magnet holding portion 32 and attachment portion 33, and heat insulating sheet 35 provided on the peripheral surface of magnet 31.

The magnet holding portion 32 holds and incorporates the magnet 31. This magnet holding portion 32 is different from the magnet holding portion 61 of patent document 1 described with reference to fig. 7. Specifically, the magnet holding portion 32 covers the circumferential surface of the magnet 31 facing the opening end surface 10A of the heat insulating box 10 even when the door 20 is closed. That is, the magnetic pad 30 is configured such that the magnet 31 does not directly contact the opening end face 10A.

The mounting portion 33 is engaged with the insertion groove 20d provided in the door 20, and fixes the magnetic pad 30 to the door 20. The connecting portion 34 has flexibility and connects the magnet holding portion 32 and the mounting portion 33 to each other in an extendable and retractable manner. The heat insulating sheet 35 is provided on a surface excluding at least the "surface in contact with the opening end face 10A of the heat insulating box 10 via the magnet holding portion 32" among the surfaces of the magnets 31. The reason why the surface abutting the opening end face 10A is removed from the installation range of the heat insulating sheet 35 of the magnet 31 is that the magnetic force (attracting force) acting between the magnet 31 and the opening end face 10A is reduced by the presence of the heat insulating sheet 35. In addition, when the sealing property or the heat insulating property of the door 20 can be ensured to the minimum necessary, the heat insulating sheet 35 may be provided in a part of the surface of the magnet 31 which abuts on the opening end surface 10A.

The magnet holding portion 32, the mounting portion 33, and the connecting portion 34 are integrally formed by forming a soft resin such as polyvinyl chloride into a long belt shape. The magnet 31 is formed by mixing a magnet powder with synthetic rubber, for example, and therefore has flexibility.

Next, the structure of the magnetic pad 30 will be described in further detail with reference to fig. 3 and 4. In the refrigerator 1 of the present embodiment, the heat insulating sheet 35 is provided on both the box inside end surface portion 31a (box inside portion) and the box door side plane portion 31b (box door side portion) of the magnet 31 in a state where the magnet 31 is held by the magnet holding portion 32.

The case inner end surface portion 31a is a portion on the circumferential surface of the magnet 31 that is on the inner side in the width direction in the state where the door 20 is closed. The door-side planar portion 31b is a portion on the door 20 side on the circumferential surface of the magnet 31.

The thermal insulation sheet 35 may be a sheet containing at least one of xerogel and aerogel. For example, the heat insulating sheet 35 may be a sheet containing at least one of silica xerogel and silica aerogel in which nanofibers having a fiber diameter of 50nm or less are dispersed. The bulk density of the sheet carrying at least one of silica xerogel and silica aerogel is 100 to 250kg/m³And is relatively small. Further, since the sheet has fine pores densely smaller than the mean free path of air of 68nm, it has a characteristic of reducing heat conduction of solid and heat conduction due to air convection. Therefore, when the sheet has a thickness of about 0.1mm, the sheet has a low thermal conductivity such as a thermal conductivity of 0.02W/mK.In addition, even if a pressing force is applied to the sheet when the door 20 is closed, the heat insulating performance is less likely to be reduced, and as a result, deterioration of the magnetic pad 30 can be suppressed.

By providing the heat insulating sheet 35 between the magnet 31 and the magnet holding portion 32, and between the box inner side end surface portion 31a of the magnet 31 and the box door side flat surface portion 31b, the following effects can be obtained. It is possible to suppress heat from heat pipe 40 located on the outer side in the width direction than magnetic mat 30 from being transferred to magnet 31 and the inside of the heat insulating box 10 through outer box 10 a. Further, since heat insulating sheet 35 has sufficient heat insulating performance even with a thickness of about 0.1mm, magnet 31 does not need to be thinned by the thickness of heat insulating sheet 35. Therefore, the suction force to the heat insulating box 10 is not impaired, and the close contact property with respect to the entire periphery of the outer box 10a of the heat insulating box 10 can be ensured.

The above configuration can ensure the magnetic force (attracting force) acting between magnet 31 and opening end face 10A, and improve the heat insulation of magnet 31 portion at the lowest cost and to the maximum extent. This will be described with reference to fig. 5A to 5C.

Fig. 5A to 5C show the calculation of the amount of heat that penetrates from the outside of the refrigerator into the inside of the refrigerator at the peripheral portion of the magnetic mat 30 when the refrigerator is operated, by thermal fluid simulation, in the case where the heat insulating sheet 35 having a thickness of 0.1mm is provided on each peripheral surface of the magnet 31. Fig. 5A is a diagram showing a model region after the thermal fluid simulation. In the hot fluid simulation, the amount of heat that has entered the dotted line portion (entered heat amount calculating portion) C shown in fig. 5A is calculated. Fig. 5B is an enlarged view of the magnet peripheral portion M in fig. 5A. Fig. 5C is a table showing the results of calculation of the amount of heat intruded into the tank under each condition. Fig. 5C shows the degree of heat intrusion when the heat intrusion is 100 (first row) when there is no heat insulator 35 around the magnet 31, or when heat insulators 35 are provided on various peripheral surfaces.

In the case where the heat insulating sheet 35 is provided on the entire circumferential surface of the magnet 31 (second row in fig. 5C), the amount of heat entering the inside of the case is minimized. In this case, however, the heat insulating sheet 35 is provided with a thickness of 0.1mm on the surface that is in contact with the opening end face 10A of the heat insulating box 10 via the magnet holding portion 32. Therefore, magnet 31 and opening end face 10A are separated by 0.1mm, and the magnetic force (attracting force) is reduced. In order to compensate for the decrease in magnetic force by the thickness of the magnet, the thickness of magnet 31 needs to be increased by 44%, but it is not realistic to establish this configuration.

Further, there is no difference in the amount of heat of intrusion between the case where the heat insulating sheet 35 is provided (the third row in fig. 5C) excluding three surfaces (the case inside side surface 31a, the case outside side surface 31d, and the case door side flat surface 31b) of the surface abutting the opening end surface 10A of the heat insulating case 10 via the magnet holding portion 32, and the case where the heat insulating sheet 35 is provided (the fourth row in fig. 5C, the surfaces of 31a and 31b) excluding both surfaces (the case inside side surface 31a and the case door side flat surface 31b) of the case outside side surfaces 31C and 31 d. This means that the heat from the heat pipe 40 is suppressed from being transmitted to the magnet 31 through the outer box 10a of the heat insulating box body 10 and transmitted to the inside of the box, and therefore, the heat insulating sheet 35 is sufficiently provided on the side surface of the inside of the box and the plane surface of the side of the box door around the magnet 31. That is, it is most effective to provide the thermal insulation sheet 35 on both surfaces for low-cost production.

In addition, in the case where the installation surface of the heat insulating sheet is one surface (the door side flat surface 31b) (the fifth row in fig. 5C), there is no great difference in the amount of heat entering the box from the case where the heat insulating sheet 35 is not provided over the entire peripheral surface, and it is not a structure capable of improving the heat insulating property. Although not shown, the amount of heat that enters the inside of the box when the heat insulating sheet 35 is provided only on the surface of the box inner side surface 31a is similarly not greatly different from the case where the heat insulating sheet 35 is not provided on the entire peripheral surface.

Further, as the heat insulating sheet 35, a sheet in which a covering layer is provided on both sides of an aerogel layer formed by bonding aerogel particles with a rubber-based bonding material may be used. The heat insulating sheet has good flexibility and can be bent with a small radius of curvature because the aerogel particles are bonded with the rubber-based binder. In addition, although silica aerogel is used as the aerogel, it is preferable because low thermal conductivity is achieved. In addition, when the amount of the rubber-based bonding material added is increased, the flexibility of the thermal insulation sheet 35 can be improved, and the thermal conductivity of the thermal insulation sheet 35 tends to be increased. Therefore, it is preferable to reduce the amount of the rubber-based bonding material as much as possible.

As a method of disposing the heat insulator 35 between the magnet 31 and the magnet holding portion 32, as shown in fig. 4, the heat insulator 35 is bonded and fixed to the magnet 31 in advance, and then inserted into the magnet holding portion 32, whereby the heat insulator can be easily manufactured. However, the present invention is not limited to the above-described manufacturing method, and other known methods may be employed.

[2. Effect ]

(1) According to the embodiment of the present invention, by providing the heat insulating sheet 35 on the circumferential surface of the magnet 31, heat conduction from the magnet 31 to the magnet holding portion 32 can be suppressed without increasing the size of the magnet holding portion 32 and the magnetic pad 30. Therefore, the heat insulation property of the magnetic mat 30 can be improved, and the intrusion of heat into the tank 10d can be suppressed.

(2) Since the heat insulating sheet 35 is provided on the box inner side end surface portion 31a and the box door side flat surface portion 31b of the magnet 31, heat transfer from the box outer side to the magnet 31 and to the box inner 10d side can be effectively suppressed.

(3) Since heat insulating sheet 35 is not provided on the side of opening end face 10A of heat insulating box 10, the magnetic force applied to opening end face 10A by magnet 31 is not reduced. Therefore, the door 20 and the opening end face 10A of the heat insulating box 10 can be effectively attracted by the magnetic pad 30.

(4) Since the heat insulating sheet 35 is formed of a material containing xerogel or aerogel, the magnet holding portion can be made thinner and heat transfer into the case can be effectively suppressed as compared with the case where an air layer is provided.

[3. modification ]

(1) In the refrigerator 1 of the present embodiment, the heat insulating sheet 35 is disposed on both the door-side planar portion 31b and the box inner-side end surface portion 31a of the magnet 31, but the present invention is not limited to this. For example, the heat insulating sheet 35 may be further provided on the box outer side surface 31d of the magnet 31, that is, on the outer side in the width direction in a state where the door 20 is closed.

(2) Fig. 6 is a sectional view showing a modification of the magnet in the refrigerator 1 according to the present embodiment. The magnet 311 of the present modification is used in place of the magnet 31 in the magnetic pad 30 shown in fig. 2 and 3. The magnet 311 increases the radius of curvature of the heat insulating sheet 35 provided on the peripheral surface, and the heat insulating sheet 35 is likely to come into close contact with the magnet 311. Specifically, a curved surface portion 311c is provided between the door-side flat surface portion 311b and the box inner-side end surface portion 311a of the magnet 311, and the heat insulating sheet 35 is bent along the curved surface portion 311c, whereby the heat insulating sheet 35 and the magnet 311 are easily brought into close contact with each other.

By forming the curved surface portion 311c between the box door side flat surface portion 311b and the box inner side end surface portion 311a in this manner, the heat insulating sheet 35 can be brought into close contact along the outer peripheral surface of the magnet 311, and the heat insulating performance can be improved by the heat insulating sheet 35.

In this case, the radius of curvature of the curved surface portion 311c can be set as appropriate by the thickness and flexibility of the thermal insulation sheet 35. In general, when the radius of curvature is about the same as the thickness of the thermal insulation sheet 35, the thermal insulation sheet 35 can be bent along the curved surface portion 311 c. For example, in the case where the thermal insulation sheet is formed in a structure in which silica aerogel is uniformly embedded in the voids of the fiber sheet, a thickness of 0.1mm can be achieved. In the case of this thickness, the curvature radius of the curved surface portion 311c may be 0.1mm or more. The curved surface portion 311c may be, for example, a continuous curved surface portion extending from the center position in the width direction (the left-right direction in fig. 5) of the door-side flat surface portion 311b to the upper end portion of the box inner-side end surface portion 311 a.

In addition, when the heat insulating sheet 35 is also provided on the box outer end surface portion 311d, a curved surface portion may be provided between the box door side flat surface portion 311b and the box outer end surface portion 311 d.

Industrial applicability

The invention can help to save energy by improving the heat insulation performance between the heat insulation box body and the box door, and can be applied to various refrigerator fields for containing cold storage and frozen products.