JPH048707B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to cooling containers. For more details,
The present invention relates to a cooling container that makes it easier to start a cooling operation.

[Traditional field]

The present inventor previously filed a patent application for a basic invention relating to a cooling method using soft calcined lime as an adsorbent (Japanese Patent Application No. 1983-225183).

[Problem that the invention seeks to solve]

The invention described in Japanese Patent Application No. 61-225183 is that under reduced pressure,
The present invention relates to a method for cooling an object to be cooled that comes into contact with the above-mentioned refrigerant, which comprises evaporating water contained in the refrigerant and adsorbing the evaporated water to soft calcined lime. An object of the present invention is to provide a cooling container that can more easily start a cooling operation using this direction.

[Means for solving problems]

The present invention consists of a refrigerant storage chamber, an adsorption chamber filled with soft calcined lime, an evaporation chamber, and a storage chamber for objects to be cooled. A cooling container that cools objects to be cooled in a storage chamber by adsorbing water vapor evaporated from a refrigerant absorption sheet in an evaporation chamber to soft calcined lime in an adsorption chamber, A closed opening is provided on the upper wall of the room, and the refrigerant storage chamber is divided into upper and lower parts by a diaphragm.The upper space has the same reduced pressure as the adsorption chamber and the evaporation chamber, and the lower space is filled with refrigerant. An opening closed with a thin film member is provided approximately in the center of the partition wall between the medium storage chamber and the evaporation chamber, and a rod for tearing the thin film member is provided approximately in the center of the side of the diaphragm filled with the refrigerant. A hollow pipe is provided for guiding the refrigerant to the refrigerant absorbing sheet from the torn thin film member extending from near the opening of the partition wall between the chamber and the evaporation chamber through the evaporating chamber to the vicinity of the refrigerant absorbing sheet. The present invention relates to a cooling container characterized by:

The present invention will be explained below with reference to the drawings.

The cooling container 1 of the present invention, as shown in FIG.
Mainly, the refrigerant storage chamber 8, the adsorption chamber 2 adjacent to the refrigerant storage chamber 8 filled with soft calcined lime 5, the evaporation chamber 3 adjacent to the adsorption chamber 2, and the It is composed of a cooled object storage chamber 4 for storing a cooled object 6. A closing opening 15 is provided in the upper wall 16 of the refrigerant storage chamber. Refrigerant storage chamber 8
The inside is partitioned into upper and lower parts by a diaphragm 12, the upper space has the same reduced pressure as the adsorption chamber and the evaporation chamber, and the lower space is filled with a refrigerant 14. As shown in FIG. 2, within the lower space is preferably a support 19 for holding the lowered diaphragm 12.
will be established. The support 19 can be, for example, a cylindrical or polygonal tube. A thin film member 1 is installed approximately in the center of the partition wall 13 between the refrigerant storage chamber 8 and the evaporation chamber 2.
An opening 9 closed with 0 is provided. diaphragm 12
A rod 11 for tearing the thin film member 10 is provided approximately at the center of the side filled with the coolant 14. The tip of the rod 11 is preferably substantially conical. Opening 9 in partition wall 13 between refrigerant storage chamber 8 and evaporation chamber 2
The above-mentioned refrigerant absorbing sheet 7 passes through the evaporation chamber from the vicinity.
A hollow pipe 17 is provided for guiding the cooling medium 14 from the torn thin film member 10 extending to the vicinity thereof to the cooling medium absorbing sheet 7. A refrigerant scattering prevention member 20 may also be provided at the end of the hollow pipe 17 on the refrigerant absorption sheet side. The coolant scattering prevention member 20 has, for example, a conical shape or a flat plate shape. Adsorption chamber 2 and evaporation chamber 3
The partition wall 18 between the cooling medium absorbing sheet 7 and the soft calcined lime 5 may be any material having holes that allow water vapor from the coolant absorption sheet 7 to reach the soft burnt lime 5, and for example, a wire mesh, a plastic sheet having holes, etc. can be used.

The soft burnt lime used in the present invention is, for example, limestone heated to about 800 to 1100°C under atmospheric pressure, preferably about 850 to 1050°C.
It can be obtained by firing at ℃. The quicklime thus obtained is porous and highly reactive because it releases CO ₂ while maintaining the volume of the raw limestone. Soft calcined quicklime is produced by heating CaCO ₃ or Ca(OH ₂ ) at approximately 300 to 800°C under reduced pressure or in the presence of a carrier gas such as N ₂ gas.
It can also be produced by heat treatment, preferably at a temperature of about 300 to 500°C. For example, CaO, which has a large specific surface area and is called an active powder described in Arai et al., Gypsum & Lime No. 178 (1982) p. 31-40, can also be used as soft burnt lime. The soft calcined quicklime can be used as a powder or can be granulated or molded and filled into the adsorption chamber 2. Furthermore, the adsorption chamber 2 may be filled with soft calcined quicklime wrapped in cloth, wire mesh, or the like that is permeable to water vapor.

Refrigerant 14 filled in refrigerant storage chamber 8
may contain water; for example, water itself may include prine containing salts such as sodium chloride and calcium chloride.

During use, when the upper space of the refrigerant storage chamber 8 reaches atmospheric pressure, the diaphragm 12 that partitions the interior of the refrigerant storage chamber 8 into an upper and lower section is pushed by the atmospheric pressure and moves downward, causing the rod 11 to move downward. It is capable of tearing the thin film member 10.

As the coolant absorbing sheet 7, any material can be used without particular limitation as long as it has water-retentive properties, and for example, a water-absorbing polymer can be used.

When in use, the sealing opening 15 is opened to release the reduced pressure in the upper space of the refrigerant storage chamber 8 to atmospheric pressure. When the upper space of the refrigerant storage chamber 8 becomes atmospheric pressure, the diaphragm 12 is pushed by the atmospheric pressure and moves downward, causing the rod 11 to break the thin film member 10. From the torn thin film member 10, the coolant 14 flows through the hollow pipe 17, reaches the coolant absorption sheet 7, and is absorbed by the absorption sheet 7. Adsorption chamber 2 and evaporation chamber 3
is pre-depressurized, e.g. 0.1~30torr, preferably 0.5
~20torr. Since the adsorption chamber 2 and the evaporation chamber 3 have been reduced in pressure in advance, water vapor evaporates from the refrigerant from the refrigerant absorption sheet 7 in the evaporation chamber 3 provided adjacent to the object storage chamber 4 . During evaporation, the water contained in the refrigerant absorbs the sensible heat of cooling the object to be cooled, thereby cooling the object 6 in the storage chamber 4 to be cooled. The generated water vapor is adsorbed by the soft calcined lime 5 in the adsorption chamber 2, and the adsorption chamber 2 and the evaporation chamber 3 are always maintained at a reduced pressure.

〔Effect of the invention〕

According to the present invention, the cooling operation can be easily started by the simple operation of opening the closed opening using a relatively simple device as described above. Furthermore, according to the present invention, a large amount of objects to be cooled can be cooled with a relatively small amount of adsorbent. Therefore, it is useful as a cooling system attached to containers for beer, wine, youth, soft drinks, cold drinks, etc.

[Brief explanation of drawings]

1 and 2 are cross-sectional views of the cooling container of the present invention, and FIG. 3 is a perspective cross-sectional view of the cooling container of the present invention with some parts omitted. 1... Cooling container, 2... Adsorption chamber, 3... Evaporation chamber, 4... Cooled material storage chamber, 5... Soft calcined quicklime,
6...Object to be cooled, 7...Cooling medium impregnated sheet, 8...
... Refrigerant storage chamber, 9 ... Opening, 10 ... Thin film member, 11 ... Rod, 12 ... Diaphragm, 1
3... Partition wall, 14... Refrigerant, 15... Closing opening, 16... Upper wall of refrigerant storage chamber, 17... Hollow pipe, 18... Partition wall, 19... Support, 20...
...Refrigerant scattering prevention member.

Claims (1)

[Scope of Claims] 1 Consists of a refrigerant storage chamber, an adsorption chamber filled with soft calcined lime, an evaporation chamber, and a storage chamber for objects to be cooled. A cooling container that cools objects to be cooled in a storage chamber for cooling objects by adsorbing water vapor evaporated from a refrigerant absorbing sheet in an evaporation chamber adjacent to the evaporation chamber to soft calcined lime in an adsorption chamber, A sealed opening is provided in the upper wall of the refrigerant storage chamber, the refrigerant storage chamber is divided into upper and lower parts by a diaphragm, and the upper space is at the same reduced pressure as the adsorption chamber and the evaporation chamber.
The lower space is filled with a refrigerant, and an opening closed with a thin film member is provided approximately in the center of the partition wall between the refrigerant storage chamber and the evaporation chamber, and an opening closed with a thin film member is provided approximately in the center of the side of the diaphragm filled with the refrigerant. A rod is provided to break the thin film member, and the coolant is cooled from the broken thin film member that extends from near the opening of the partition wall between the refrigerant storage chamber and the evaporation chamber through the evaporation chamber to the vicinity of the refrigerant absorption sheet. A cooling container characterized by being provided with a hollow pipe for leading to a medium absorption sheet. 2. The cooling container according to claim 1, wherein the tip of the rod is approximately conical. 3. The cooling container according to claim 1, wherein a refrigerant scattering prevention member is provided at the end of the hollow pipe on the refrigerant absorbing sheet side. 4. The cooling container according to claim 3, wherein the refrigerant scattering prevention member has a conical shape. 5. The cooling container according to claim 1, further comprising a support for holding the lowered diaphragm in the lower space of the refrigerant storage chamber. 6 Claim 5 in which the support is cylindrical
Cooling container as described in section.