The technical field relates to a heat-insulation box. In particular, the technical field relates to a structure of a partition part in heat-insulation boxes (e.g., refrigerators) that have multiple chambers.
Inside heat-insulation boxes (e.g., refrigerators) having multiple chambers, partition plates that are resin-molded products interiorly including heat-insulation materials, are provided, so as to partition the internal space into multiple chambers each having different environments (e.g., temperature and humidity), according to storage products such as foods.
Such partition plates are provided to improve strength of heat-insulation boxes. Design plates provided at open-part-sides of the partition plates are provided with front design surfaces, and edge sides that are folded vertically to the design surfaces, such that the design plate are formed in the shape of the letter “U.”
Moreover, in order to maintain packings provided on doors, and bodies of the boxes in a sealed state, it is required that the design plates are made of magnetic materials that magnets provided inside the packings will attach to. Furthermore, since the design plates have profound effects on improvements of strength of the refrigerators, inexpensive coated steel plates with high strength have been used for the design plates.
However, since design plates are formed of coated steel plates having excellent heat conductance, heat will be caused to flow from high-temperature zones outside the chambers to low-temperature zones inside the chambers. As a result, heat-insulation performance of the heat-insulation boxes will be deteriorated, and also, the design plates will be cooled to a temperature equal to or below a dew point of the outside air (i.e., the atmosphere around sites where the refrigerators are placed), thereby causing dew condensation.
In order to cope with the above-mentioned problem, a means for preventing occurrence of dew condensation is provided in a conventional refrigerator disclosed in JP-A-H4-103984.
The upper plate 26 and the lower plate 27 are provided on upper and lower sides, respectively, of a urethane-foam heat-insulation material 28 that has been injected through a backside part of the refrigerator so as to be encapsulated therein, and the heat-release pipes 22 for heat release in freezing cycles are provided somewhere between the front sides of the upper plate 26 and the lower plate 27. The heat-release pipes 22 are brought into contact with the design plate 25 via the heat-accumulation layer 23. A solid pliable heat-insulation material 24 made of a polystyrene foam or the like is provided at the front side of the refrigerator in order to prevent leakage of the urethane-foam heat-insulation material 23. When the urethane-foam heat-insulation material 28 is injected through the rear of the refrigerator, the heat-insulation material 24 is pressed by the design plate 25. Accordingly, the temperature is increased to a temperature equal to or higher than the dew point to prevent occurrence of the dew condensation.
Furthermore, a means for enhancing heat-insulation properties of refrigerators while simultaneously realizing prevention of occurrence of dew condensation, and enhancing strength of a partition plate is provided in a publication of Japanese Patent No. 2945553.
The heat-release pipes 32 are brought in contact with the design plate 35. Lateral faces of the design plate 35 do not come into direct contact with the upper plate 38 and the lower plate 39, although the lateral faces of the design plate are in direct contact with the upper and lower plates in JP-A-H4-103984. In Japanese Patent No. 294555, the design plate 35 comes into contact with the upper plate 33 and the lower plate 39 via protruding edge parts 35b such that the edge parts 35b surrounds the hard heat-insulation material 37, together with other members. Furthermore, leg-like edge sides 35c are also in contact with ribs 40 of the partition wall 36, thereby securing sufficient strength of the partition plate 31 and preventing occurrence of dew condensation, and, simultaneously, the hard heat-insulation material 37 is provided to enhance heat-insulation properties of the heat-insulation box.
However, based on the conventional refrigerator disclosed in JP-A-H4-10398 (depicted in
Furthermore, the solid pliable heat-insulation material 24, which is placed in the vicinity of the heat-release pipes 22 acting as heat-generation sources, is made of a polystyrene foam having a large heat conductivity (λ=about 0.040 W/(m·K)), and this heat conductivity is about twice the heat conductivity (λ=about 0.023 W/(m·K)) of the urethane-foam heat-insulation material 28. This aspect also deteriorates heat-insulation properties of the heat-release pipe 22, the edge parts 25a of the design plate, and the upper plate 26 and the lower plate 27 of the partition plate, and thus, causes deterioration in the heat-insulation performance of the heat-insulation box.
Furthermore, even based on the conventional refrigerator disclosed in the publication of Japanese Patent No. 2945553 (depicted in
Furthermore, in the same manner as JP-A-H4-103984, the solid pliable heat-insulation material 34, which is placed in the vicinity of the heat-release pipes 32 acting as heat-generation sources, is made of a polystyrene foam having a large heat conductivity, and this heat conductivity is about twice the heat conductivity of the urethane-foam heat-insulation material 33. This technical aspect also deteriorates heat-insulation properties of the heat-release pipes 32, the leg-like edge sides 35c of the design plate, the partition wall 36, and the upper plate 33 and the lower plate 39 of the partition plate, and thus, causes deterioration in the heat-insulation performance of the heat-insulation box.
The disclosure solves the above-described problems in the conventional arts. That is, an object of the disclosure is to provide a heat-insulation box that realizes prevention of occurrence of dew condensation in the vicinity of the partition plate, and that retakes it possible to suppress heat penetration into chambers of refrigerators through design plates.
In order to achieve the above object, according to an aspect of the disclosure, provided is a heat-insulation box, including: a heat-insulation-box main body that has a space; a door that seals the space; and a partition plate that partitions the space, wherein the partition plate includes (i) a design plate that is placed at a side of the door, (ii) a first plate part and a second plate part that are each provided at both edges of the design plate, (iii) a heat-insulation material that is located in a region surrounded by the design plate, the first plate part, and the second plate part, and (iv) a heat-insulation member that is placed in at least one of a gap between the design plate and the first plate part, and a gap between the design plate and the second plate part.
According to the disclosure, it becomes possible to realize prevention of occurrence of dew condensation around partition plates and to suppress heat penetration into chambers of refrigerators through design plates. Simultaneously, it becomes possible to prevent leakage of urethane foams to front sides of refrigerators during incorporation of the urethane-foam heat-insulation material. Thus, the disclosure makes it possible to improve heat-insulation performance of refrigerators.
Hereinafter, embodiments will be described with reference to the drawings.
The partition plate 1 divides the heat-insulated space into a first storage chamber 2 and a second storage chamber 3. For example, the first storage chamber 2 may be a refrigeration chamber, and the second storage chamber 3 may be a freezing chamber. The partition plate 1 is provided between storage chambers each having different temperature zones.
<Configuration of the Partition Plate 1>
In
The design plate 10 has a front part 10a that will appear at the front side of the refrigerator, and sidewall parts 10b that are bent by about 90° with respect to the front part 10a and that will be located inside the refrigerator.
Flexible composite heat-insulation materials 11 (heat-insulation members) are placed between the upper sidewall part 10b of the design plate 10 and the upper plate 6 (first plate part), and between the lower sidewall part 10b of the design plate 10 and the lower plate 7 (second plate part), and, is compressed and fixed therebetween. The first plate part 6, the heat-insulation materials 11, and the sidewall parts 10b of the design plate 10 are stacked in this manner. The heat-insulation members 11 are easily compressed.
The upper plate 6 (first plate part) and the lower plate 7 (second plate part) are L-shaped. Furthermore, a front part 6a and a front part 7a that are L-shaped are provided around front sides of the upper plate 6 (first plate part) and the lower plate 7 (second plate part), respectively. In addition, in order to prevent transmission of heat from the design plate 10 to the upper plate 6 (first plate part) and the lower plate 7 (second plate part), the design plate 10 is preferably connected to the upper plate 6 (first plate part) and the lower plate 7 (second plate part) only via the flexible composite heat-insulation materials 11 (heat-insulation members), as shown in dotted circles in
In addition, since the front sides of the upper plate 6 (first plate part) and the lower plate 7 (second plate part) are each provided with the L-shaped front part 6a and the L-shaped front part 7a, respectively, the flexible composite heat-insulation materials 11 (heat-insulation members) are not clearly visible to users at the front side of the refrigerator. As a result, the refrigerator can also maintain its aesthetic properties. Furthermore, a urethane-foam heat-insulation material 8 is filled into a space that are formed by the upper plate 6 (first plate part), the flexible composite heat-insulation materials 11 (heat-insulation members), the heat-release pipes 9 (heat-release parts), the design plate 10, and the lower plate 7 (second plate part).
As a result, the first plate part 6, the heat-insulation materials 11, sidewall parts 10b of the design plate 10, and the heat-release pipes 9 are stacked in the above configuration. In other words, these members are provided in alignment with each other. The heat-insulation materials 11 can block paths for heat transmission.
<Configuration of the Flexible Composite Heat-Insulation Materials 11 (Heat-Insulation Members)>
A flexible composite heat-insulation material 11 (heat-insulation member) shown in
The aerogel/fiber composite layer 11a is formed by combining an aerogel with a fiber structure (e.g., unwoven fabrics). Specifically, the aerogel/fiber composite layer 11a may be obtained in the following way: the fiber structure is soaked in an aerogel precursor, and an aerogel is produced from the aerogel precursor in the presence of the fiber structure, based on the supercritical drying, or an ordinary-pressure-based drying process.
Aerogels are a solid that has many fine pores with a very high porosity (preferably a porosity of 99% or higher). Particularly, aerogels are a material that has a structure in which bead-like particles of silicon dioxide or the like are joined together, and that has many voids on the scale of nanometers (e.g., 2-50 nm). In this manner, aerogels have nanometer-scale pores and lattice-shaped structures, and therefore, are capable of reducing mean free paths of gaseous molecules. Accordingly, heat conductance through gaseous molecules therein is very small even at ordinary pressure, and their heat conductivities are very small.
For the aerogel, for example, inorganic aerogels including oxides of metals such as silicon, aluminum, iron, copper, zirconium, hafnium, magnesium, and yttrium are preferably used, and silica aerogels including silicon dioxide are more preferably used.
The fiber structure reinforces the aerogel, and simultaneously serves as a reinforcing material or support that supports the aerogel. In order to obtain a flexible composite heat-insulation material, flexible woven fabrics, knitted fabrics, unwoven fabrics, etc. may be used for the fiber structure. As examples of materials for the fiber structure, organic fibers such as polyester fibers, and also, inorganic fibers such as glass fibers can be used.
Heat-insulation materials obtained in this way have a heat conductivity (λ=about 0.020 W/(m·K)) that is equal to or less than that of a urethane-foam heat-insulation material, and thus, have very high heat-insulation properties.
The fiber-only layers 11b include the above-described fiber structure, which does not include any aerogels. The fiber-only layers 11b preferably consist essentially of fiber materials. The fiber-only layers 11b are provided as elastic layers for the purpose of generation of elasticity in the flexible composite heat-insulation materials 11 (heat-insulation members) when the flexible composite heat-insulation materials 11 are compressed, and also for the purpose of alleviation of variations in the gap between the upper plate 6 (first plate part) and the design plate 10, and the gap between the lower plate 7 (second plate part) and the design plate 10 due to warpage or corrugation of the upper plate 6 (first plate part) and the lower plate 7 (second plate part).
In addition, the fiber-only layers 11b provided at the both sides each come into contact with the upper plate 6 and the design plate 10. Each of the fiber-only layers 11b is compressed by the adjacent plates. In this case, the fiber-only layers 11b are mainly compressed. However, heat conductivities of the heat-insulation materials 11 will almost not be changed, and the heat-insulation properties can be maintained, even when they are compressed, since contributions of the aerogel/fiber composite layers 11a to the heat conductivities are dominant.
The layer direction of the fiber-only layers 11b and the aerogel/fiber composite layer 11a is the same as the compressed direction.
With regards to the heat-insulation box configured in the above manner, a production method and effects thereof will be described below.
<Production of a Flexible Composite Heat-Insulation Material 11 (Heat-Insulation Member)>
The method for producing a flexible composite heat-insulation material 11 (heat-insulation member) includes: the following eight steps: (i) a sol-preparation step; (ii) an impregnation step; (iii) a lamination step; (iv) a gelatinization step; (v) an aging step; (vi) an aqueous acid solution-soaking step; (vii) a hydrophobization step; and (viii) a drying step. Each of the steps will be described below.
(i) Sol-Preparation Step
In the sol-preparation step, water glass or a high-molar-ratio silicate aqueous solution may be used as a starting material. In the case in which water glass is used as a starting material, sodium is removed from the water glass based on an ion-exchange resin or electrodialysis, and is acidified to thereby convert it into a sol. Then, a base serving as a catalyst is added to the sol, and is polymerized to produce a hydrogel. On the other hand, in the case in which a high-molar-ratio silicate aqueous solution is used as a starting material, an acid serving as a catalyst is added to the high-molar-ratio silicate aqueous solution, and thus, is polymerized to produce a hydrogel.
(ii) Impregnation Step
6.5 to 10 times the amount of the sol solution prepared in step (i) in terms of weight is poured to unwoven fabrics formed of PET, glass wool rock wool, or the like and that has a thickness of 0.2 mm to 1.0 mm, and thus, the unwoven fabrics are impregnated with the sol solution. For the impregnation method, the sol solution may be spread over a film or the like at a certain thickness in advance, and the unwoven fabrics may be overlaid thereon to cause the sol solution to penetrate into the unwoven fabrics.
(iii) Lamination Step
The layer structure will be described with reference to
At first, as shown in
(iv) Gelatinization Step
After step (iii), the sol is converted into a gel. A temperature for converting the sol into a gel (gelatinization temperature) is preferably from 20° C. to 90° C. If the gelatinization temperature is less than 20° C., a required amount of heat may not be conveyed to silicate monomers that serve as active species for the reaction. Therefore, in that case, growth of silica particles may not be promoted. Consequently, it may take a while until gelatinization of the sol sufficiently progresses. Furthermore, strength of the produced gel (aerogel) may be lower, the gel may significantly shrink during the drying step, and thus, an aerogel with desired strength may not be obtained.
On the other hand, if the gelatinization temperature exceeds 90° C., growth of silica particles may excessively be promoted. As a result, volatilization of water may rapidly be caused therein, and thus, a phenomenon in which water and the hydrogel are separated from each other may be observed. Accordingly, a volume of the resulting hydrogel may be reduced, and thus, any silica aerogels may not be obtained.
In addition, although the gelatinization time varies with the gelatinization temperature, and the aging time described below, a sum of the gelatinization time and the aging time is preferably from 0.1 hour to 12 hours. Furthermore, the gelatinization time is preferably from 0.1 hour to 1 hour in order to achieve an ideal balance between the performance (heat conductivities) and the production unit time.
If the gelatinization time is longer than 12 hours, reinforcement of the silica network would sufficiently proceed. However, if it takes a longer time for the aging step, not only the productivity would be impaired, but also shrinkage of the gel would be caused. Consequently, a bulk density of the gel may be increased, and therefore, the resulting flexible composite heat-insulation materials 11 (heat-insulation members) would have elevated heat conductivities, and this is not preferable.
By carrying out the gelatinization step in the above manner, strength and rigidity of walls of the hydrogel will be improved, and thus, a hydrogel that hardly shrinks during the drying step can be obtained. Furthermore, when the sol is solidified in form of a gel, the aerogel that has permeated the unwoven fabrics is solidified. As a result, all of the layers are combined so as to form a layer structure that includes the aerogel/fiber composite layer 11a and the fiber-only layers 11b, as shown in
(v) Aging Step
In the aging step, a skeleton of the gelatinized silica is reinforced to produce a hydrogel with a reinforced skeleton. The aging temperature is preferably from 50° C. to 100° C. If the aging temperature is less than 50° C., a dehydration/polycondensation reaction may relatively be slowed, and therefore, it may become difficult to sufficiently reinforce the silica network within a production unit time targeted in view of sufficient productivity.
If the aging temperature is higher than 100° C., water contained in the gel may excessively be evaporated, and therefore, shrinkage and drying of the gel may occur. As a result, the resulting gel may have an elevated heat conductivity.
The aging time is preferably from 0.1 hour to 12 hours, and is more preferably 0.1 hour to 1 hour in order to achieve an ideal balance between the performance (heat conductivities) and the production unit time.
If the aging time is longer than 12 hours, reinforcement of the silica network would sufficiently progress. However, if it takes a longer time for the aging step, not only the productivity may be impaired, but also shrinkage of the gel would be caused. Consequently, the bulk density may be increased, and therefore, there may be a problem in which the neat conductivity is elevated.
By carrying out the aging step within a range from 0.1 hour to 6 hours, the network of silica particles can sufficiently be reinforced while sufficient productivity is retained.
(vi) Aqueous Acid Solution-Soaking Step
The composite of the gel and the unwoven fabrics is soaked in aqueous hydrochloric acid (6 to 12 N), and then allowed to stand for 45 minutes or more at ordinary temperature (23° C.) to cause the composite to incorporate hydrochloric acid.
(vii) Hydrophobization Step
The composite of the gel and the unwoven fabrics is soaked, for example, in a mixture solution of octamethyltrisiloxane serving as a silylating agent, and 2-propanol (IPA; an alcohol), and reacted in a thermostatic chamber at 55° C. for 2 hours. When formation of polymethylsiloxane bonds starts, aqueous hydrochloric acid is discharged from the gel sheet, and the liquid phase is separated into two liquids (siloxane in the upper layer, and aqueous hydrochloric acid in the lower layer).
(viii) Drying Step
The composite of the gel and the unwoven fabrics is transferred to a thermostatic chamber at 150° C., and is dried for two hours (in case of ordinary-pressure drying).
Based on the above-described steps, the flexible composite heat-insulation materials 11 (heat-insulation members) are produced.
Production of the Partition Plate 1
A method for producing the partition plate 1 will be described with reference to
In
Subsequently, the upper plate 6 (first plate part) and the lower plate 7 (second plate part) of the partition plate 1 that has temporally been fixed onto the heat-insulation box are slightly stretched to the upward and downward directions, respectively, as shown by arrows (1) in
With regard to positional fixation of the assembled design plate 10, as shown in the perspective view of
Finally, a urethane-foam heat-insulation material 8 is poured into a space between the outer box 5 and the inner box 4, and a space between the upper plate 6 (first plate part) and the lower plate 7 (second plate part) in
In that case, as shown in
As a result, the heat-insulation material 8 is surrounded by the heat-insulation members 11, the design plate 10, the first plate part 6, and the second plate part 7.
<Effects Brought about by the First Embodiment>
As shown in
In particular, even when the flexible composite heat-insulation materials 11 (heat-insulation members) receive compression force (pressing force), and thus, shrink, their heat conductivities will not almost change.
The foamed-resin-made heat-insulation materials (COMPARATIVE EXAMPLE 1) exhibited a heat conductivity (λ) of 0.04 W/(m·k) at the initial phase. However, they showed a 76% increase in heat conductivity when a pressing force of 500 kPa was applied thereto.
The resin-made heat-insulation materials (COMPARATIVE EXAMPLE 2) exhibited a heat conductivity (λ) of 0.05 W/(m·K) at the initial phase. However, they showed a 45% increase in heat conductivity when a pressing force of 500 kPa was applied thereto.
On the other hand, the flexible composite heat-insulation materials 11 (EXAMPLE) showed only a 15% increase in heat conductivity when they were pressed at a pressing force of 500 kPa.
Thus, the flexible composite heat-insulation materials 11 (heat-insulation members) are suitable for compression-based fixation in spaces that are formed by the design plate 10, the upper plate 6 (first plate part), and the lower plate 7 (second plate part). That is, even when the flexible composite heat-insulation materials 11 (heat-insulation members) are compressed, the heat-insulation effects will not be deteriorated. The flexible composite heat-insulation materials 11 (heat-insulation members) are preferable as heat-insulation materials.
Furthermore, beside the capabilities of the flexible composite heat-insulation materials 11 (heat-insulation members) of being compressed and thus being fixed in spaces that are formed by the design plate 10, the upper plate 6 (first plate part), and the lower plate 7 (second plate part), the flexible composite heat-insulation materials 11 (heat-insulation members) are provided with the fiber-only layers 11b, which each have elasticity coping with variations in the spaces that are formed by the upper plate 6 (first plate part), the lower plate 7 (second plate part), and the design plate 10, as shown
Accordingly, it is unnecessary to utilize the polystyrene-foam-made heat-insulation material 34 (
Furthermore, according to the partition plate 1 in the first embodiment, a urethane-foam heat-insulation material 8 having high heat-insulation properties can be incorporated into areas in the vicinity of the heat-release pipes 19. Accordingly, it becomes possible to prevent heat penetration into the chamber from the heat-release pipes 19 through the upper plate 6 (first plate part) and the lower plate 7 (second plate part).
Furthermore, as shown in
In addition, although the flexible composite heat-insulation materials 11 (heat-insulation members) are provided in the two sites, a flexible composite heat-insulation material 11 may be provided at at least one of the sites.
A difference between the first embodiment and the second embodiment is that shapes of a design plate 1, an upper plate 61 (first plate part), and a lower plate 71 in
<Configurations of the Design Plate 15, the Upper Plate 61 (First Plate Part), and the Lower Plate 71 (Second Plate Part)>
In
That is, both of edges of the design plate 15 each have a double structure, and interior projections. The heat-insulation material is retained by the projections.
Steps (recessed parts) 61b and 71b are provided in the upper plate 61 (first plate part) and the lower plate 71 (second plate part), respectively, parallel to the design plate 10, such that the flexible composite heat-insulation materials 11 (heat-insulation materials) fit the respective steps (recessed parts) 61b and 71b.
In addition, the heat-insulation members may be fixed by not steps (recessed parts) but by two projection parts.
Additionally, in order to prevent heat transmission from the design plate 15 to the upper plate 61 (first plate part) and the lower plate 71 (second plate part), the design plate 15, the upper plate 61 (first plate part), and the lower plate 71 (second plate part) are preferably connected only via the flexible composite heat-insulation materials 11 (heat-insulation members), and gaps are preferably provided therebetween so that the edge parts 15a of the design plate 15, the upper plate 61 (first plate part), and the lower plate 71 (second plate part) do not come into direct contact with each other.
<Effects Brought about by the Second Embodiment>
Besides the effects mentioned in the first embodiment (e.g., dew-condensation-prevention effects, and effects to prevent heat penetration into chambers), it becomes possible to improve accuracy of positioning of the flexible composite heat-insulation materials 11 (heat-insulation members) in assembling the partition plate 1, since steps 61b and 71b are provided in the upper plate 61 (first plate part) and the lower plate 71 (second plate part), respectively, and the design plate 15 has the folded parts.
Additionally, since the design plate 15 has the folded parts as shown in
A difference between the first embodiment and the third embodiment is that shapes of a design plate 16, an upper plate 62 (first plate part), and a lower plate 72 (second plate part), and a method for producing a partition plate 1 (a method for incorporating the design plate 16 into a space between the upper plate 62 (first plate part) and the lower plate 72 (second plate part)) in the third embodiment differ from those in the first embodiment. Matters not mentioned in this embodiment are the same as those described for the first embodiment.
<Configuration of the Design Plate 16, the Upper Plate 62 (First Plate Part), and the Lower Plate 72 (Second Plate Part)>
In
In addition, in order to prevent heat transmission from the design plate 16 to the upper plate 62 (first plate part) and the lower plate 72 (second plate part), the design plate 16, the upper plate 62 (first plate part), and the lower plate 72 (second plate parts are preferably connected only via flexible composite heat-insulation materials 11 (heat-insulation members), and spaces are preferably provided therebetween such that the first step 16a, a hook return part 62a of the upper plate, and a hook return part 72a of the lower plate in the design plate 16 do not come into direct contact with each other.
<Production of the Partition Plate 1 (Method for Incorporating the Design Plate 16 into a Space Between the Upper Plate 62 (First Plate Part) and the Lower Plate 72 (Second Plate Part))>
<Effects Brought about by the Third Embodiment>
According to the third embodiment shown in
Furthermore, as shown in
A difference between the first embodiment and the fourth embodiment is that shapes of an upper plate 63 (first plate part) and a lower plate 73 (second plate part) in
<Effects Brought about by the Fourth Embodiment>
Besides the effects mentioned in the first embodiment (e.g., dew-condensation-prevention effects, and effects to suppress heat penetration to chambers), it becomes possible to produce the upper plate 63 (first plate part) and the lower plate 73 (second plate part) in a simple way. For example, the upper plate 63 (first plate part) and the lower plate 73 (second plate part) can be configured by using a flat plate as a base material.
Even based on such a simple production method, since the flexible composite heat-insulation materials 11 (heat-insulation members) are rigidly compressed and thus fixed in spaces that are formed by the upper plate 63 (first plate part), the lower plate 73 (second plate part), and the design plate 10, the internal urethane never leaks out.
Although it may be difficult to secure aesthetic properties, refrigerators according to this embodiment can be employed as refrigerators for which it is unnecessary to place an emphasis on aesthetic properties (e.g., on-premise, consumer-use or professional-use refrigerators).
Additionally, the above-described embodiments can be combined.
Furthermore, although both of the edges of the design plates 10 have the same shape in the above embodiments, either of the edges may be formed in one of the shapes described in the above embodiments. Alternatively, the edges may have different shapes in some embodiments.
A heat-insulation box according to the disclosure can be utilized for the purpose of improving heat-insulation performance of various cooling/heating apparatuses (consumer-use and professional-use refrigerators, wine cellars, etc.) that have a mechanism for partitioning a chamber space into multiple chamber having different temperature zones.
Number | Date | Country | Kind |
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2016-176089 | Sep 2016 | JP | national |
2017-103643 | May 2017 | JP | national |
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