JP3795615B2 - Heat insulation box - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a heat insulating box having a cooling and heating cycle used for applications such as a refrigerator, a freezer, a warmer, a cooler, and a food storage.
[0002]
[Prior art]
In recent years, higher performance of devices has been promoted from the viewpoint of energy saving. As a technique for improving the performance of the heat insulating box, it is important to improve the performance of the heat insulating material using the vacuum heat insulating technique.
Conventionally, a vacuum heat insulating panel is a vacuum heat insulating material often used for refrigerators and the like. The vacuum insulation panel is manufactured by covering a core material having a continuous structure such as rigid urethane foam made of open cells with a gas-barrier metal-plastic laminate film, etc., evacuating the inside, and then packing to form a panel. (For example, JP-A-7-293785). When this is used for a heat-insulating box such as a refrigerator, it has a double structure in which it is affixed to the inner surface of the container material of the box and foamed with urethane foam.
[0003]
In addition to the above-described vacuum heat insulation panel, there are heat insulation box bodies by vacuum exhaust (for example, JP-A-6-174186 and JP-A-7-148752). In these heat insulation boxes, a material having an independent structure or a communication structure is filled in the box, and a vacuum pump is used to keep the inside of the box in a vacuum state. In addition, there is a method in which a vacuum indicator is attached in order to ensure the heat insulation performance over time, and when the degree of vacuum deteriorates, the vacuum is exhausted again (Japanese Patent Laid-Open No. 7-148752).
[0004]
[Problems to be solved by the invention]
The vacuum insulation panel described above is manufactured by manufacturing a block of open-celled rigid urethane foam, cutting it into an arbitrary size, and vacuum-packing it with a vacuum exhaust system. Therefore, in order to combine with the usual foam insulation, it was necessary to manufacture separately. Furthermore, the process of affixing to the container of a heat insulation box is required, and it was not desirable in terms of productivity, workability, and cost. In addition, since the vacuum insulation panel and the foam insulation are used in combination, the insulation box partly has a portion without the vacuum insulation panel, and therefore there is a part where the performance of the vacuum insulation cannot be exhibited. There was a problem. Furthermore, since there is no means for recovering the degree of vacuum in the vacuum heat insulating panel over time, there is a problem in long-term reliability due to a decrease in heat insulating performance.
[0005]
Moreover, the heat insulation box by the above-mentioned vacuum exhaust does not require a separate manufacturing process or affixing process as in the case of the vacuum heat insulation panel, and the whole box can be made into vacuum insulation. As for long-term reliability, the degree of vacuum can be maintained or recovered by evacuation with a vacuum pump, which is reliable. However, in order to maintain heat insulation performance over time, electric energy is required to maintain heat insulation performance, such as evacuation using a vacuum pump or evacuation again after checking the degree of vacuum. In addition, there are problems with workability such as maintenance.
An object of the present invention is to provide a heat insulating box that solves the above-described problems.
[0006]
[Means for Solving the Problems]
The heat insulation box of the present invention comprises a gas shielding container filled with a heat insulator and the inside being in a decompressed state, a gas storage container filled with a gas absorbing material and connected to the gas shielding container, and a cooling system, The gas absorbing material is a physical absorbent; The gas storage container is the cooling system Endothermic part side And heat exchange And cooling or heating the heat insulation box by the cooling system. Is configured to do.
The heat insulating box of the present invention includes a gas shielding container filled with a heat insulating body and having a reduced pressure inside, a gas storage container filled with a gas absorbing material and connected to the gas shielding container, and a cooling system. And said The gas absorbing material is a chemical absorbent The above Gas storage container Said Heat exchange with the heat dissipation side of the cooling system And the heat insulation box is cooled or heated by the cooling system. .
[0007]
Another heat insulating box of the present invention includes a gas shielding container filled with a heat insulating body and having a reduced pressure inside, a gas storage container filled with a gas absorbing material and connected to the gas shielding container, and a cooling system. And the said gas storage container is arrange | positioned inside the said heat insulation box body heat-exchanged with the said cooling-heat system.
As a heat insulator filled in the gas shielding container of the heat insulation box, an excellent effect is obtained when the heat insulator has a communication structure.
Furthermore, a cooling system using a compressor or a cooling system using a thermoelectric conversion element can be used as the cooling system.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
By applying this invention, the heat insulation box excellent in heat insulation, energy saving, and maintainability is obtained. The reason is as follows.
As described above, the heat insulation box of the present invention has a cooling system, and vacuum insulation is achieved when the inside of the gas shielding container filled with the heat insulation is in a reduced pressure state. Since the gas storage container filled with the gas absorbing material communicates with the gas shielding container, the gas present in the gas shielding container and the gas components generated with time are confined in the gas storage container. As a result, the inside of the gas shielding container is in a reduced pressure state. According to the present invention, vacuum heat insulation can be obtained without exhausting with a vacuum pump, and a reduced pressure state can be maintained for a long period of time to maintain heat insulation performance.
[0009]
If the gas storage container is arranged so as to exchange heat with the cooling system, the absorption capacity of the gas absorbing material in the gas storage container is increased by heat absorption or heat dissipation from the cooling system, and the inside of the gas shielding container is efficiently A decompressed state can be maintained. When the gas absorbent material is a physical absorbent, if the gas storage container is configured to exchange heat with the endothermic part side of the cooling system, the gas storage container is cooled and the adsorption performance of the physical absorbent is improved. . In addition, when the gas absorbing material is a chemical absorbent, if the gas storage container is configured to exchange heat with the heat radiation part side of the cooling system, the gas storage container is heated and the chemical reaction of the chemical absorbent is performed. The gas immobilization performance is improved. Either configuration or both configurations can be used. In essence, either configuration may be used in combination with a plurality of gas-absorbing materials mainly using a physical or chemical absorbent.
[0010]
In addition, if a gas storage container is placed inside a heat insulating box whose heat is exchanged with the cooling system and the internal temperature is adjusted, the absorption capacity of the gas-absorbing material in the gas storage container is increased and the gas is efficiently shielded. The pressure-reduced state can be maintained in the sex container.
If the heat insulator to be filled in the gas shielding container of the heat insulating box is a communication structure, the pressure loss affecting the gas flow due to gas storage can be suppressed, and the decompressed state in the container can be efficiently maintained. .
Depending on the application of the heat insulation box by using a cooling system by compression, condensation, expansion, evaporation process using a compressor, an endothermic cooling system by a Peltier effect thermoelectric conversion element, or a heat insulation heat retention system as a cooling system. The structure of heat exchange with the gas storage container can be freely set.
Specific embodiments of the present invention will be described below.
[0011]
Embodiment 1
The structure of the heat insulation box in one Embodiment of this invention is shown in FIG. It is an example which is heat-exchanged with a gas storage container by the heat absorption part side of the cooling-heat system provided with the compressor.
This heat insulating box is from a cooling system including a gas shielding container 2 filled with a heat insulating body 3, a gas storage container 4 outside the box 1 and filled with a gas absorbing material 5, and a compressor 7. It is configured. The gas storage container 4 is connected to the gas shielding container 2 by a pipe 18 having an opening / closing stopper 6.
The cooling system includes a compressor 7 arranged outside the box, an evaporator 9 arranged inside the box, an evaporation side pipe 10 connecting the compressor 7 and the evaporator 9, and a suction pipe 11 to the compressor. , A condensing pipe 8 and a capillary pipe 17. Then, the refrigerant of the high-temperature and high-pressure gas discharged from the compressor 7 dissipates heat in the condensing pipe 8 to become a high-pressure supercooled liquid refrigerant, and becomes a low-pressure two-phase refrigerant through an expansion process such as a capillary tube or an expansion valve. The inside of the heat insulation box 1 is cooled by absorbing heat. Furthermore, heat is exchanged with the gas storage container 4 through the pipe 10 from the evaporator in an endothermic state to form a low-pressure heating gas refrigerant, which is sucked into the compressor 7.
[0012]
As the gas absorbing material 5, a physical absorbent is mainly used. Since the gas storage container 4 filled with the absorbent continues to be cooled by heat exchange with the cooling system, gas such as gas when filled with the heat insulator, air, and organic component gas generated over time is efficient. Then, it is adsorbed by the absorbent and stored in the gas storage container 4. As a result, the gas shielding container 2 is kept in a reduced pressure state for a long time.
[0013]
<< Embodiment 2 >>
FIG. 2 shows a heat insulating box configured to exchange heat with a gas storage container on the heat radiating unit side of a cooling system provided with a compressor.
The difference from Embodiment 1 of this heat insulating box is that the evaporation side pipe 10 is connected to the compressor 7, and the condensation pipe 8 connected to the discharge pipe 16 from the compressor exchanges heat with the gas storage container 4. It is. That is, a high-temperature high-pressure gas refrigerant is discharged from the compressor 7 and dissipates heat in the condenser tube 8 that exchanges heat with the gas storage container 4 to become a high-pressure supercooled liquid refrigerant. And it becomes a low-pressure two-phase refrigerant through an expansion process of the capillary tube 17 and the like, absorbs heat by the evaporator 9 and cools the inside of the heat insulating box 1. Thus, the refrigerant becomes low-pressure heated gas refrigerant and is sucked into the compressor 7.
In this example, a chemical absorbent is mainly used as the gas absorbing material 5. Since the gas storage container 4 filled with the chemical absorbent is kept heated by heat exchange with the cooling system, the chemical reaction is accelerated. Therefore, gases such as gas, air, and organic component gas generated over time when the heat shield is filled in the gas shielding container 2 are efficiently stored in the gas storage container 4. As a result, the gas shielding container 2 is kept in a reduced pressure state for a long time.
[0014]
In said Embodiment 1 and 2, although the heat exchange location of a gas storage container and a cooling-heat system is determined by relationship with a gas absorption material, it is not limited to this. An effect can be obtained by using a combination of a physical absorbent and a chemical absorbent as the gas absorbing material and cooling the gas storage container, and the structure is also the same when the gas storage container is heated. Also, using two types of gas storage containers, heat exchange is performed on the gas storage container filled with a physical absorbent as a gas absorbing material on the heat absorption part side, and the gas storage container filled with the chemical absorbent is heated on the heat radiation part side. An excellent effect can also be obtained by adopting a replacement configuration.
[0015]
<< Embodiment 3 >>
FIG. 3 shows a heat insulation box for refrigeration for heat exchange with the gas storage container on the heat absorption part side of the cooling system using the thermoelectric conversion element.
In this heat insulating box 1, a gas shielding container 2 is filled with a heat insulating body 3 having a communication structure. The gas storage container 4 filled with the gas absorbing material 5 is connected to the gas shielding container 2 through the gas permeable sheet 15. This cooling system is a cooling system using a Peltier effect thermoelectric conversion element including a heat absorbing portion 13 and a heat radiating portion 14. Since the gas storage container 4 is in contact with the heat-absorbing part 13 that cools the inside of the box body, by exchanging heat between them, the gas, air, and the time when the heat insulator is filled The generated gas such as organic component gas is efficiently stored in the gas storage container 4. As a result, the gas shielding container 2 is kept in a reduced pressure state for a long time.
[0016]
<< Embodiment 4 >>
FIG. 4 shows a heat insulating box body for heat insulation in which heat is exchanged with the gas storage container on the heat absorption part side of the cooling system by the thermoelectric conversion element.
Differences from the third embodiment are as follows. That is, the cooling system has a configuration in which the inside of the box is heated by a Peltier effect thermoelectric conversion element including the heat absorbing portion 13 and the heat radiating portion 14, and the gas storage container 4 disposed outside the box is also externally That is, the heat storage section 13 is in contact with the heat absorbing section 13 to exchange heat, and the gas storage container 4 is connected to the gas shielding container 2 by a pipe 18 having an opening / closing stopper 6. As in the third embodiment, the reduced pressure state is maintained for a long time in the gas shielding container 2.
[0017]
<< Embodiment 5 >>
FIG. 5 shows an example in which a gas storage container is arranged in a box that is cooled by a cooling system including a compressor.
This heat insulating box 1 is filled with a gas shielding container 2 and a gas absorbing material 5 filled with a heat insulating body 3 having a communication structure, and is connected to the gas shielding container 2 through a gas permeable sheet 15. It is comprised from the container 4 and the cooling-heat system. The cooling system includes a compressor 7, a condenser tube 8, a capillary tube 17, and an evaporator 9, and the inside of the heat insulating box 1 is cooled by absorbing heat with the evaporator 9. Since the gas storage container 4 filled with the gas absorbing material 5 is disposed inside the box 1 thus cooled, the gas storage container 4 is cooled in the box, and the gas is efficiently contained in the gas storage container 4. Stored in. As a result, the reduced pressure state is maintained in the gas shielding container 2 for a long time.
[0018]
In addition, the structure which makes the gas shielding container 2 and the gas storage container 4 communicate is the heat insulation body at the time of filling of the heat insulation body 3, such as connecting via piping, piping through an opening / closing stopper, or gas permeable material. 3 can be prevented from entering the gas storage container 4 and the gas shielding container 2 may be sufficiently filled.
Moreover, as a shape of the heat insulation box 1, in addition to a rectangular parallelepiped, a cylinder, a sphere, a vessel shape, or the like is arbitrary.
[0019]
Next, the manufacturing method of the heat insulation box of this invention is demonstrated using FIG.
First, before filling the gas shielding container 2 with the heat insulating body 3, the heat insulating box 1 in which the gas shielding container 2, the gas storage container 4, and the cooling system are disposed as shown in FIG. In this box body, the heat insulating body 3 is filled using the filling gas from the filling port 12 provided in the gas shielding container 2. Subsequently, the filling port 12 is sealed, and the inside of the gas shielding container 2 is brought into a reduced pressure state.
Next, several methods such as (1) and (2) can be considered as a method for decompressing the container.
(1) After evacuating the gas shielding container 2 to a certain degree of vacuum using a vacuum pump, the gas shielding container 2 communicates with the gas storage container 4 and remains in the gas shielding container 2. Gas is absorbed, the reduced pressure state is improved, and the reduced pressure state is maintained.
(2) After the filling of the heat insulating body 3 into the gas shielding container 2 with the filling gas is completed, the filling gas existing in the gas shielding container 2 is communicated with the gas shielding container 2 and the gas storage container 4. It is made to store in the gas storage container 4, the inside of the gas shielding container 2 is made into a pressure-reduced state, and a vacuum state is hold | maintained also with time. This method does not use a vacuum pump.
[0020]
In which process in the manufacturing process, the insulator 3 is filled, the inside of the gas storage container 2 is evacuated, or the gas storage container 4 is communicated with the gas shielding container 2. What is necessary is just to determine with the structure, such as the kind of body 3, the arrangement | positioning form of a cooling-heat system. In addition, the gas storage container 4 has two functions: reducing the pressure inside the gas shielding container 2 and maintaining the reduced pressure state. The difference between the methods (1) and (2) mentioned above is the difference between positively or auxiliaryly performing the function of reducing the pressure by the gas storage container 4. In addition, although the method of filling a heat insulating body into the manufactured gas shielding container is described here, you may fill a heat insulating body simultaneously when producing a gas shielding container.
Thereafter, by starting the cooling / heating cycle, the reduced pressure state is improved, and the storage of the gas in the gas storage container 4 is promoted.
By this manufacturing method, an excellent vacuum heat insulating box integrated with the container is obtained.
[0021]
The amount of the gas absorbing material to be filled in the gas storage container is generated when the vacuum pump is used for evacuation immediately after filling the heat insulator and the air component remaining in the gas shielding container or over time. What is necessary is just to be commensurate with the amount of the degassing component to come. In addition, when storing in a gas storage container, including the gas for filling the insulation, and reducing the pressure, the amount of absorbent that matches the amount of gas used for filling will remain in the gas shielding container. Add an amount of absorbent that is commensurate with the amount of air components and degassing components that are generated over time. As a result, the depressurized state can be maintained over a long period of time without using a vacuum pump. For this reason, the heat insulation box which acquired the reliability of high performance, energy saving, and heat insulation performance can be provided.
[0022]
Next, the constituent material of the heat insulation box of this invention is demonstrated in detail.
As the material of the gas shielding container, a material obtained by molding a metal material such as steel, copper, aluminum, and stainless steel, or an inorganic material such as glass or earthenware so that it can be kept in vacuum can be used. In addition, materials based on organic materials include high gas barrier properties such as fluorine resins such as Teflon, vinyl alcohol resins such as ethylene vinyl alcohol copolymer resins, acrylonitrile resins such as polyacrylonitrile, and vinylidene chloride resins. Polyamide resins such as nylon and polyester resins such as polyethylene terephthalate are used alone or in combination such as laminate. Furthermore, those obtained by performing metal foil, metal vapor deposition, silicon oxide or aluminum oxide vapor deposition on these resins to improve gas barrier properties are also preferable. By combining these, a container having a high gas shielding degree can be configured.
[0023]
As for the structure of the gas shielding container, the wall thickness of the container is filled with a heat insulator inside, so it is not necessary to maintain the compressive strength due to the decompressed state by itself, so a thin one can be used, It is not necessary to use a reinforcing material. At the time of filling the heat insulator, it is sufficient that the strength as a container is 1 kg or more per unit area. Therefore, the weight is reduced, and there are effects in terms of durability and cost. Although the wall thickness depends on the structure to be filled, a wall thickness of 1 mm or less and about 100 μm can be used sufficiently. These are processed and molded to have a gas shielding property to form a container structure.
As a heat insulator filled in the gas shielding container, those generally used as a heat insulator such as powder, fiber, foam and porous body can be applied. In particular, in order to perform evacuation and gas storage from a gas shielding container filled with a heat insulator, the heat insulator may be a closed cell body, but the communication structure has less gas pressure loss and can be executed in a shorter time. It is preferable because it is possible.
[0024]
The communication structure can be roughly classified into three material systems. First, inorganic powders such as silica, pearlite, and alumina, and various resin powders such as polyvinyl alcohol powder, polyurea xerogel, and polyurethane powder. Secondly, inorganic fibers, organic fibers and the like. Thirdly, there are foamed resin moldings, such as injection foam moldings such as polyurethane foam and polycarbodiimide foam, foamed particle moldings such as polystyrene foam and vinylidene chloride resin foam, etc. Is mentioned. Not only these but it can be used if it can be filled in the gas shielding container and a communication structure can be formed.
[0025]
As a gas component when filling a gas shielding container with a heat insulator, most of the air component is used. However, the number of gas components can be reduced, or a gas that can be stored more easily than air can be used. Therefore, the gas shielding container may be filled after being replaced with another gas, or only a specific filling gas may be used for filling. Examples of the filling gas include air components such as carbon dioxide, water vapor, oxygen, and nitrogen, organic compounds such as fluorocarbons, lower alcohols such as methanol and ethanol, hydrocarbons such as cyclopentane and butane, and inorganic gases such as sulfur hexafluoride. Can be used as a representative. However, the present invention is not limited to these, and a low-boiling point compound having a high gas or vapor pressure at normal temperature and pressure can be used. Moreover, these can also be used individually or in mixture. In particular, the filling gas is preferably one that is easily diffused, relatively easily adsorbed, or relatively easily chemically reacted, and carbon dioxide, water vapor, and oxygen are suitable. These may be generated as a filling gas by a chemical reaction in a gas shielding container to fill the communication structure, or the container may be physically filled in the communication structure. As the filling state of the filling gas, for example, in the case of carbon dioxide, various states such as a gas state, a liquefied state, and a supercritical liquefied state can be used, and may be selected depending on the communication structure to be filled.
[0026]
As a gas storage container, the same thing as a gas shielding container can be used. Preferably, in order to remove the gas in the gas storage container filled with the gas-absorbing material before being installed in the heat insulation box, there may be a case where treatment such as heating or decompression is performed, and a metal container is suitable. . About a gas storage container, when use of the heat insulation box of this invention is finished, it also has the characteristics that it can be easily removed and disassembled and can be separated and recovered. Further, the gas absorbing material inside the gas storage container can be regenerated and reused, and the configuration takes into consideration environmental problems related to disposal after use.
As the gas absorbing material filled in the gas storage container, in addition to the gas component in the container, an absorbent for the residual gas component and the temporally degassed component can be mixed and used. As the residual gas component, the air component is usually the most. Therefore, it is preferable that an absorbent such as nitrogen, oxygen, carbon dioxide, water vapor, and argon as air components is mixed. Further, the degassing component with time is an adsorbed gas component existing in the inner wall of the gas shielding container or the heat insulating body, and a gas component generated with time from the heat insulating body. The adsorbed gas component is an air component or the like, and the generated gas component is mostly carbon dioxide, water vapor, organic compound gas or the like.
[0027]
As a material that absorbs the gas component, a material that absorbs a gas physically or chemically can be used.
For example, as the carbon dioxide absorbing material, molecular sieves, zeolite, activated carbon, or the like can be used as a physical adsorbent. Chemical carbon dioxide fixing agents include metal inorganic compounds and organic compounds. Metal inorganic compounds include soda ash, sodium hydroxide, potassium hydroxide, calcium hydroxide, barium hydroxide, magnesium hydroxide and other metal hydroxides, calcium oxide, magnesium oxide and other metal oxides, potassium carbonate, sodium carbonate, etc. A typical example is a metal carbonate compound or the like that reacts with carbon dioxide to produce a metal carbonate compound or a metal hydrogen carbonate compound. Since these require water for the reaction or water is generated by the reaction, the optimum combination with the moisture adsorbent is also necessary for the selection of the adsorbent.
[0028]
Typical examples of carbon dioxide fixing agents by reaction with organic compounds include ethanolamine-based amine compounds and solid substances carrying free amino groups. Furthermore, an addition reaction to an epoxy compound can also be used because the reaction yield is high. Specifically, epoxy ethane, 1,2-epoxypropane, 1,2-epoxybutane, 2,3-epoxybutane, 1,2-epoxyhexane, 1,2-epoxyoctane, 3,4-epoxy-1 -Monofunctional and polyfunctional epoxy compounds such as propene, styrene oxide, cyclohexene oxide, glycidyl phenyl, perfluoropropylene oxide, glycidyl ester compounds such as acetic acid glycidyl ester, propionic acid glycidyl ester, adipic acid diglycidyl ester, phenyl glycidyl ether, Examples include general-purpose epoxy compounds such as glycidyl ether compounds such as trimethylsilyl glycidyl ether, resorcin diglycidyl ether, and aryl glycidyl ether.
In absorption of carbon dioxide by these epoxy compounds, an organic zinc compound, a magnesium-based catalyst, and various onium salt compounds are used in combination as a reaction catalyst, so that carbon dioxide is absorbed with high reaction selectivity.
[0029]
Specifically, as the reaction catalyst, a molar ratio of dialkyl zinc or dialkyl magnesium to a divalent active hydrogen compound such as water, primary amine, divalent phenol, aromatic dicarboxylic acid, or aromatic hydroxycarboxylic acid is 1: 1. Substances reacted in 1, zinc / gamma-alumina, zinc carbonate, zinc acetate, cobalt acetate, zinc chloride / tetrabutylammonium bromide and other organic zinc-based catalysts and inorganic catalyst combinations, triethylaluminum / Lewis base, diethyl Examples thereof include aluminum compound catalysts such as aluminum diethylamide and α, β, γ, δ-tetraphenylporfinato aluminum methoxide, and onium salt catalysts such as ammonium halide salts and phosphonium halide salts.
Further, as another organic compound for fixing carbon dioxide, cyclic imine compounds such as propylene imine, oxetane which is a 4-membered ring ether, 3-membered ring amine such as formaldehyde and methylaziridine, conjugated dienes such as butadiene and isoprene, propylene Examples thereof include sulfides, ethylene phenyl phosphites, mixtures of phosphites and aromatic primary amines or aromatic diamines, and mixtures of crown ethers, alkyl dihalides and metal dialkoxides.
[0030]
Next, as the moisture absorbing material, zeolite, molecular sieves, calcium chloride, calcium oxide, calcium sulfide, anhydrous magnesium sulfate, water absorbing polymer and other generally known moisture absorbing and moisture absorbing materials are used. be able to.
In addition, oxygen absorbers such as iron powder, anhydrous ferrous sulfate and other iron-based oxygen absorbers, titanium-based oxygen absorbers, magnesium-based oxygen absorbers, sarcomin-based cobalt complexes, and other general oxygen absorbers Can be used.
Further, as the nitrogen absorbing material, lithium, barium, titanium, a zirconium-based alloy, a lithium-barium-based alloy, or the like that is a getter material can be used.
Moreover, palladium fine powder etc. can be used as an absorber for hydrogen.
For rare gases such as argon, molecular sieves or the like can be used.
[0031]
Furthermore, various adsorbents such as activated carbon, molecular sieves, zeolite, silica, and alumina can be used for the organic gas component.
The absorbent material is not limited to the above-described absorbent material, and many of the absorbent materials have the ability to absorb a plurality of gas components, so it is necessary to determine the filling gas to be used. For example, it is possible to cope with all gas components by using a physical absorbent such as molecular sieves, zeolite, activated carbon and the like, and the absorption effect is improved by cooling by heat exchange with a cooling system. Moreover, about chemical absorbers, such as oxygen, a carbon dioxide, water, and nitrogen, an absorption effect improves by heating by heat exchange with a cold-heating system.
[0032]
Mixing these physical absorbents with chemical absorbents is also effective. For example, if a chemical absorbent is supported on a physical absorbent, the physically adsorbed gas will react more chemically, and the equilibrium state of gas adsorption / desorption will be constant. Therefore, the adsorption proceeds by the combined use with the chemical reaction. In this case, the effect is exhibited even if both are mixed.
If the activation process is carried out after the gas storage container 5 is filled with the gas-absorbing material 5 described above, the effect is further exhibited.
Note that the decompressed state maintained by the gas storage process is highly insulated like vacuum insulation where nothing is filled in the container because a fine space between bubbles and powder is formed in the gas shielding container. 10 to get performance ^-Five High vacuum below torr is not required. Depending on the structure of the insulator, the ultimate vacuum is from several torr to 10 ^-3 A sufficiently superior heat insulation performance can be obtained in a low vacuum to medium vacuum range of about torr. Since this vacuum region can be maintained by gas storage even in the long term, the reliability is high.
[0033]
Next, for connection between the gas shielding container and the gas storage container, piping may be used, the two may be separated by partition formation, or both containers may be connected by a material through which gas can pass. . For example, when piping is used, an open / close stopper can be used, and a general valve can be used as the open / close stopper. That is, it is effective to provide an open / close stopper in order to fill the gas-shielding container with the heat insulator to a sufficiently filled state and then to reduce the pressure. In the case of using an opening / closing stopper, the valve or the like may be opened after confirming the completion of molding, so that both processes can be completely separated in time. Moreover, when using the material which can pass gas, as a gas-permeable material, a general polymer sheet, a nonwoven fabric, etc. can be used. However, in the case of the polymer sheet, a material having a low density and a high gas permeability is selected instead of a material having a high gas barrier property, and polyester, polystyrene, polyolefin and the like are suitable.
[0034]
【Example】
Next, specific examples of the present invention will be described.
Example 1
A heat insulating box having the configuration of FIG. 1 was produced. The gas shielding container 2 was produced from a stainless steel plate having a thickness of 0.5 mm. Similarly to the gas shielding container 2, the stainless steel gas storage container 4 was connected by a stainless steel pipe 18. The pipe 18 has a valve 6. In the gas storage container 4, a gas absorbing material 5 made of molecular sieves, activated carbon, calcium chloride or the like is enclosed. The gas storage container comes into contact with the piping from the evaporator of the cold heat system to exchange heat, and is cooled to a temperature lower than room temperature.
The pearlite powder was poured into the container 2 from the filling port 12 and filled with the heat insulator 3 having a communication structure. Next, a vacuum pump was connected to the container 2 and the interior of the container was sealed under reduced pressure after evacuation. Thereafter, the valve 6 was opened, and the reduced pressure state was maintained in the gas storage container 4. When the ultimate vacuum was measured by attaching a vacuum gauge to the valve part, it was about 0.01 Torr, and it was confirmed that a vacuum heat insulating casing was manufactured. Furthermore, since the gas storage container 4 is cooled by heat exchange by starting the cooling system, the efficiency of gas absorption is improved, the degree of vacuum is improved to about 0.005 Torr, and the degree of vacuum is maintained. .
The heat insulation performance of this heat insulation box was able to realize a heat insulation performance about twice as high as the heat insulation performance in a state where pressure was not reduced. In addition, its performance could be maintained over the long term.
[0035]
Example 2
A heat insulating box having the structure shown in FIG. 2 was produced. A heat-insulating casing of a gas shielding container was constituted from an inner box and an outer box made of an iron plate of a laminated structure of an acrylic-butadiene-styrene resin and an aluminum foil laminate film. An iron gas storage container 4 was connected to the gas shielding container 2 through an iron pipe 18 having a valve 6. In the gas storage container 4, an epoxy compound, its addition reaction catalyst, a carbon dioxide fixing agent by a chemical reaction consisting of calcium hydroxide, and chloride for capturing water generated by the reaction of calcium hydroxide with carbon dioxide. Calcium and activated carbon for adsorption of residual organic component gas are mixed and sealed. Furthermore, the gas storage container 4 contacts the piping from the discharge port of the compressor 7 of the cooling system and is heat-exchanged to be heated to a temperature higher than room temperature.
[0036]
A urethane raw material consisting of a polyol, a urethane catalyst, a foam stabilizer, a foam breaker, water, and an isocyanate was injected into the container 2 from a filling port, and foam molding was performed with carbon dioxide by a reaction between water and isocyanate. This water-foamed urethane foam is hard, and bubbles are completely communicated by adding a foam breaker and filled with carbon dioxide. The container 2 filled with the urethane foam was cured at about 40 ° C. to completely form the resin of the urethane foam, and filled with a continuous structure having a foam strength of 1 kg or more per unit area. After that, by opening the valve, carbon dioxide in the bubbles was stored in the gas storage container 4, and the heat insulating casing was decompressed. By starting the refrigeration system, further decompression progressed. When the ultimate vacuum was measured by attaching a vacuum gauge to the valve unit 6, it was about 0.1 Torr or less, and it was confirmed that a vacuum heat insulating casing was manufactured.
The heat insulation performance of this heat insulation housing was about 1.8 times higher than the heat insulation performance in the state of being filled with carbon dioxide before the gas storage step.
[0037]
Example 3
A heat insulating box having the configuration of FIG. 3 was produced. A Peltier effect thermoelectric conversion element was provided in a refrigerated housing of a gas shielding container 2 made of a stainless steel plate having a thickness of 0.5 mm with the heat absorbing portion 13 inside the box. Then, the stainless steel gas storage container 4 was connected to the gas shielding container 2 through the gas permeable sheet 15. In the gas storage container 4, a gas absorbing material mainly composed of zeolite and zeolite supporting sodium hydroxide is enclosed. The gas storage container 4 comes into contact with the heat absorption part 13 of the thermoelectric conversion element, is cooled to a temperature lower than room temperature, and is cooled inside the heat insulating box.
[0038]
Crushing and pulverizing powder of urethane foam was injected into the gas shielding container 2 together with carbon dioxide gas from the filling port, and the heat insulating body 3 having a communication structure was filled. Next, a vacuum pump was connected to the gas shielding container 2, and after evacuation, the inside of the container was sealed under reduced pressure. Thereafter, the reduced pressure state was maintained by the gas storage container 4. The heat insulation performance of this heat insulation box was about twice as high as the heat insulation performance when not depressurized. Regarding the long-term performance, in the case of the configuration where the gas storage container is not connected, the performance decreased in several days, but the configuration of this example can maintain the performance for a long term. It was.
[0039]
Example 4
The heat insulation box of the structure of FIG. 4 was comprised by the material structure similar to Example 3. FIG. The gas storage container 4 is heat-exchanged by the heat absorption part 13 of the thermoelectric conversion element. Even with this configuration, high performance by vacuum insulation and long-term insulation performance can be obtained.
[0040]
Example 5
A heat insulating box having the configuration shown in FIG. 5 was produced. A stainless steel gas storage container 4 was connected to a gas shielding container 2 made of a stainless steel plate having a thickness of 0.3 mm through a nonwoven fabric 15. The gas storage container 4 is filled with a gas absorbing material composed of molecular sieves, activated carbon, and calcium chloride. The gas storage container part 4 is cooled in the box cooled by the evaporator 9 of the cooling system.
Porous silica powder was poured into the container 2 from the filling port and filled with the heat insulator 3 having a communication structure. A vacuum pump was connected to the container 2 and evacuated to about 5 Torr, and then the inside of the container was sealed under reduced pressure. When the ultimate vacuum was measured by attaching a vacuum gauge to the valve part of the container 2, it was about 0.01 Torr, and it was confirmed that a vacuum heat insulating casing was manufactured. Furthermore, since the heat exchange with the gas storage container unit 4 is started by starting the cooling system and the efficiency of adsorption by cooling is improved, the degree of vacuum is improved to about 0.005 Torr and the degree of vacuum is maintained. It was.
The heat insulation performance of this heat insulation box was able to realize a heat insulation performance about twice as high as the heat insulation performance in a state where pressure was not reduced. In addition, its performance could be maintained over the long term.
[0041]
【The invention's effect】
The present invention relates to a heat insulating box having a gas shielding container filled with a heat insulator and a gas storage container connected to the gas shielding container filled with a gas absorbing material for reducing the pressure of the gas shielding container. The body is combined with a cooling system that exchanges heat with the gas storage container, and the absorption capacity of the gas absorbing material in the gas storage container is increased by heat absorption or heat dissipation from the cooling system, so that the gas shielding container can efficiently The reduced pressure state can be maintained.
As described above, according to the present invention, it is possible to obtain a heat insulation box that is excellent in high heat insulation, long-term reliability, energy saving and maintenance properties related thereto.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of a heat insulating box in an embodiment of the present invention.
FIG. 2 is a cross-sectional view of a heat insulating box according to another embodiment of the present invention.
FIG. 3 is a cross-sectional view of a heat insulating box for refrigeration in another embodiment of the present invention.
FIG. 4 is a cross-sectional view of a heat insulation box for heat insulation in another embodiment of the present invention.
FIG. 5 is a cross-sectional view of a heat insulating box according to still another embodiment of the present invention.
[Explanation of symbols]
1 Insulation box
2 Gas shielding container
3 Insulator
4 Gas storage container
5 Gas-absorbing material
6 Opening and closing tap
7 Compressor
8 Condensation piping for refrigeration system
9 Cold system evaporator
10 Evaporation side piping of refrigeration system
11 Suction piping to the compressor
12 Insulation filling port
13 Endothermic part of thermoelectric conversion element
14 Heat dissipation part of thermoelectric conversion element
15 Gas permeable sheet
16 Discharge piping from the compressor
17 Capillary
18 pipes

Claims (6)

A gas shielding container filled with a heat insulator and having a reduced pressure inside, a gas storage container filled with a gas absorbing material and connected to the gas shielding container, and a heat insulation box comprising a cooling system ,
The gas absorbing material is a physical absorbent;
A heat insulating box configured such that the gas storage container exchanges heat with the heat absorption part side of the cooling system, and cools or heats the inside of the heat insulating box by the cooling system . A gas shielding container filled with a heat insulator and having a reduced pressure inside, a gas storage container filled with a gas absorbing material and connected to the gas shielding container, and a heat insulation box comprising a cooling system,
The gas absorbing material is a chemical absorbent ;
The gas storage vessel is heat radiating portion side and the heat exchanger of the cold system, and the constructed heat-insulating main body so as to cool or heat the heat-insulating main body by cold system. A gas shielding container filled with a heat insulator and having a reduced pressure inside, a gas storage container filled with a gas absorbing material and connected to the gas shielding container, and a heat insulation box comprising a cooling system ,
The heat insulation box which the said gas storage container was arrange | positioned inside the said heat insulation box exchanged with the said cooling system. The heat insulation box according to any one of claims 1 to 3 , wherein the heat insulator is a communication structure. The heat insulation box according to any one of claims 1 to 3 , wherein the cooling system is a cooling system including a compressor. The heat insulation box according to any one of claims 1 to 3 , wherein the cooling system is a system using a thermoelectric conversion element.

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