JP4235151B2 - Storage - Google Patents

Description

The present invention relates to a reservoir with a temperature control unit, to a reservoir used specifically for transport.

Conventionally, as a storage used for transportation, a storage made of a foamed synthetic resin heat insulating container and a lid is generally used to cool the inside of the storage by putting solid carbon dioxide, a cooling agent, or the like. It is. There is also known an electronic temperature refrigerator in which a cooling / heating unit (corresponding to the temperature control unit of the present invention) is built in a heat insulating container to which an openable / closable lid is attached (for example, see Patent Document 1). There is also known a refrigerated warehouse that incorporates a cooling / heating device (corresponding to the temperature control unit of the present invention) in a lid that covers the opening of the heat insulating box (corresponding to the insulating container of the present invention) so as to be freely opened and closed. (For example, refer to Patent Document 2). Furthermore, there is also known a cool box in which a cooling device (corresponding to the temperature control unit of the present invention) is incorporated in a lid that covers the opening of the box (corresponding to the heat insulating container of the present invention) so as to be freely opened and closed ( For example, see Patent Document 3.)
JP 2000-304402 A Utility Model No. 2553022 JP 2001-311576 A

  However, in a warehouse that cools the interior with solid carbon dioxide or a cryogen, the solid carbon dioxide sublimes or the cryogen melts due to heat from the outside of the store or the warehouse, so the stored product can be stored for a long time. In such a case, there is a problem that it takes time and effort to replenish solid carbon dioxide and replace the cryogen. Further, when solid carbon dioxide is used, not only the amount of use becomes enormous by repeated use over a long period of time, but also gas carbon dioxide is generated by sublimation, which may increase the concentration of carbon dioxide in the atmosphere. Moreover, in the storage of patent documents 1 thru | or 3, although there is no these troubles or an environmental load, since the internal volume is decided beforehand, not only the storage more than an internal volume cannot be stored but storage itself. However, since it is relatively heavy and expensive, there is a problem in using it for transportation.

The present invention solves the above problems, thereby enabling long-term storage at low running costs, and to provide a storage box which can be set capacity relatively freely. Another object is to provide an inexpensive storage box relatively lightweight.

The storage according to claim 1 of the present invention is a heat insulating container having an opening and the heat insulating container detachably attached to the opening so as to close a part of the opening of the heat insulating container. And a main lid attached to close the other part of the opening, and the temperature regulation unit includes a sub lid having heat insulation, and the sub lid. consists temperature regulatory subunit provided in the lid, the temperature control sub-unit, together with the formed and a said sub-lid fitted in a through hole formed in the base and the Stirling refrigerator, the A temperature control apparatus has a temperature control action part thermally exposed to the interior space of the said heat insulation container .

The storage according to claim 2 of the present invention is the storage according to claim 1, wherein the temperature adjustment subunit has an attachment for attaching the temperature adjustment subunit to the lid .

Reservoir of claim 1 of the present invention, by configuring as described above, so that the temperature regulating effect of the temperature adjusting subunit thermally exposed to the internal space of the heat insulating container, before Symbol the temperature control unit that is independent of the cross heat capacity unit, said removably covered so as to close a portion of the opening of the insulated container, covered freely further open and close the Shufuta body to another part of the opening By setting it as a storage, the inside of this storage is cooled or heated. And if it is in the range in which the said temperature control unit is attached, since the said heat insulation container and the main cover body can be selected arbitrarily, the capacity | capacitance of a storage can be set comparatively freely. In addition, since the inside of the space surrounded by the heat insulating container and the lid is cooled or heated by the temperature adjusting unit, the storage object can be stored for a long time. Further, when the inside of the storage is cooled by the temperature control unit, since solid carbon dioxide or the like is not used, not only the running cost can be kept low, but also no carbon dioxide is generated, so the environmental load is kept low. Can do. Moreover, the said temperature control unit can be formed by fitting the base provided in the said temperature control subunit to the through-hole of the said sub cover body. Furthermore, since the inside of the storage is cooled by the Stirling refrigerator, not only can the inside of the storage be cooled to a very low temperature at a low running cost, but also the entire storage can be made relatively small and light. .

Moreover, since the storage according to claim 2 of the present invention is configured as described above, the temperature adjustment device is attached to the sub lid together with the temperature adjustment subunit by the attachment body. Not only can the adjustment unit be assembled easily, but also the temperature adjustment unit of various sizes can be easily obtained by making the temperature adjustment subunit common and attaching it to the sub lid body of various sizes. it can.

  Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. Reference numeral 1 denotes a storage, and the storage 1 includes a temperature control unit 2 and a heat insulating container 3.

  The temperature adjustment unit 2 includes a lid body 4 having a through hole 4 </ b> A formed substantially in the center and a temperature adjustment subunit 5. The lid 4 is integrally formed of a plate-like foamed synthetic resin having heat insulation properties, and the entire surface thereof is covered with an infrared reflecting film as an infrared reflecting layer. And the step part 4B is formed in the said through-hole 4A, The base 8 mentioned later of the said temperature control subunit 5 is mounted in this step part 4B. The temperature control subunit 5 includes a Stirling refrigerator 6 serving as a temperature control device, a casing 7 that houses the Stirling refrigerator 6, and a base 8 that supports the Stirling refrigerator 6 and the casing 7. Configured. The Stirling refrigerator 6 is inverted, and an endothermic heat sink 9 is attached to the endothermic portion 6B formed at the tip of the cylindrical portion 6A of the Stirling refrigerator 6, and the Stirling refrigerator 6 A heat sink 10 for exhaust heat is attached to the exhaust heat portion 6C formed at the base end of the cylindrical portion 6A of the machine 6 in a heat transfer manner. The heat sink 9 for heat absorption is attached so as to be exposed on the lower surface side of the base 8, and the heat sink 10 for exhaust heat is disposed in the casing 7. Further, the casing 7 is provided with an intake opening 7A at the lower part thereof and an attachment body 7B for fixing the temperature control subunit 5, and an exhaust opening 7C is provided at the upper part thereof. A fan 11 is attached to the opening 7C. A sealing member 12 is provided between the outer periphery of the exhaust heat sink 10 and the inner wall of the casing 7 to seal these gaps. Further, the base portion 8 has a through hole 8A formed at substantially the center thereof, and a step portion 8B is formed on the outer periphery thereof corresponding to the step portion 4B so that the base portion 8 fits into the through hole 4A. Has been. The inner diameter of the through hole 8A is formed larger than the outer diameter of the cylindrical portion 6A of the Stirling refrigerator 6, and the gap between the cylindrical portion 6A of the Stirling refrigerator 6 and the through hole 8A is as follows. It is sealed by a sealing member 13 made of foamed rubber or the like having heat insulation properties. The heat sink 9 for heat absorption is formed in a size that does not protrude from the lower outer periphery of the base 8. Further, in the vicinity of the heat sink 9 for heat absorption, a fan 14 for passing an air flow through the heat sink 9 for heat absorption is provided. The temperature adjusting operation portion A is constituted by the heat absorbing portion 6B of the Stirling refrigerator 6, the heat absorbing heat sink 9, and the fan 14. An operation unit 15 is provided on the front side of the casing 7, and a control circuit (not shown) is accommodated in the operation unit 15.

  The heat insulation container 3 includes a right wall 3A, a left wall 3B, a front wall 3C, a rear wall 3D, a bottom wall 3E, and a cover body 16 of the heat insulation container 3 itself as a second cover body. Each of the walls 3A, 3B, 3C, 3D, 3E and the lid 16 is integrally formed of a plate-like foamed synthetic resin having heat insulation properties, and the entire surface thereof is an infrared reflecting layer. It is covered with an infrared reflective film. The walls 3A, 3B, 3C, 3D, and 3E are covered with a cover body 17 made of an infrared reflecting film in the state where the walls 3A, 3B, 3C, 3D, and 3E are assembled as the heat insulating container 3. Then, one side of the lid body 16 is attached to the upper end of the cover body 17. In addition, with the above-described configuration, the heat insulating container 3 can be easily and inexpensively manufactured, and an arbitrary size can be easily and inexpensively manufactured.

  Next, the assembly procedure of the temperature control unit 2 of this embodiment is demonstrated. First, the temperature control subunit 5 is assembled. In detail, first, after attaching the heat sink 10 for exhaust heat to the heat exhaust part 6C of the Stirling refrigerator 6, the outer periphery between the heat absorption part 6B and the heat exhaust part 6C in the cylindrical part 6A is sealed. The member 13 is attached. Then, after attaching the sealing member 12 around the heat sink 10 for exhaust heat, the Stirling refrigerator 6 is housed in the casing 7 in a state where the Stirling refrigerator 6 is inverted. A fan 11 is attached to the exhaust opening 7 </ b> C of the casing 7. Then, the casing 7 in which the Stirling refrigerator 6 is accommodated is attached to the base portion 8 by the attachment body 7B, and the cylindrical portion 6A of the Stirling refrigerator 6 is passed through the through hole 8A of the base portion 8. At this time, the gap between the through hole 8A and the cylindrical portion 6A is sealed by the sealing member 13. Then, a heat sink 9 for heat absorption is attached to the heat absorption part 6B formed at the tip of the cylindrical part 6A of the Stirling refrigerator 6, and the fan 14 is attached in the vicinity of the heat sink 9. Further, the electrical wiring of the Stirling refrigerator 6, the fan 11 and the fan 14 is connected to the control circuit (not shown), and this control circuit is housed in the operation unit 15. As described above, the temperature control subunit 5 is assembled. The temperature adjusting subunit 5 assembled in this way is attached to the through hole 4A of the lid 4. That is, by fitting the base portion 8 into the through hole 4A so that the step portion 8B formed on the base portion 8 of the temperature control subunit 5 rides on the step portion 4B of the through hole 4A, the temperature is increased. The adjustment subunit 5 is attached to the lid body 4. At this time, as described above, since the heat sink 9 for heat absorption is sized so as not to protrude from the outer periphery of the lower portion of the base 8, the temperature adjustment subunit 5 is attached to the lid 4. At this time, the heat sink 9 for heat absorption does not interfere with the through hole 4A. Thus, since the temperature adjustment unit 2 is configured by attaching the temperature adjustment subunit 5 to the lid body 4, only the lid body 4 using the common temperature adjustment subunit 5 is used. The temperature control unit 2 having various sizes, that is, the temperature control unit 2 corresponding to the heat insulating container 3 having various sizes can be obtained. And although the said cover body 4 is covered with the said infrared reflective film, since it is integrally formed by the heat insulating plate-shaped foaming synthetic resin, the said cover body 4 of various magnitude | sizes is formed. Can be obtained easily and inexpensively. Thereby, the temperature control unit 2 can be manufactured at low cost.

  Next, the operation of this embodiment will be described. First, an object to be stored that has been refrigerated or frozen in a refrigerator or a freezer in advance is accommodated in the heat insulating container 3, and the temperature control unit 2 is attached to the opening 3 </ b> F of the heat insulating container 3. At this time, the temperature adjusting unit 2 is attached so that the heat sink 9 for heat absorption and the fan 14 are inside the heat insulating container 3. Then, the operation unit 15 is operated to operate the Stirling refrigerator 6 and the fans 11 and 14. Then, when the Stirling refrigerator 6 is operated, the endothermic part 6B has a low temperature and the exhaust heat part 6C has a high temperature. The heat absorption part 6B having a low temperature is heated from the heat sink 9 for heat absorption in thermal contact with the heat absorption part 6B, and further from the air in the interior space of the heat insulating container 3 where the heat sink 9 for heat absorption is exposed. And the deprived heat is moved to the exhaust heat section 6C. The heat transferred to the exhaust heat unit 6C is exhausted from the exhaust heat sink 10. In addition, since the air in the interior space of the heat insulating container 3 is passed through the heat sink 9 for heat absorption by the fan 14, the air in the heat insulating container 3 is uniformly and efficiently cooled by the Stirling refrigerator 6. Will be. Further, when the fan 11 is operated, outside air flows in from the intake opening 7A of the casing 7, and after the flowing outside air passes through the heat sink 10 for exhaust heat, the body 6D of the Stirling refrigerator 6 is used. It passes through the periphery, and is discharged out of the casing 7 through the exhaust opening 7C through the fan 11. At this time, the heat sink 10 for exhaust heat and the body 6D of the Stirling refrigerator 6 are cooled by the airflow formed by the fan 11. Thus, the to-be-stored object accommodated in the said heat insulation container 3 is cooled because the space in the store | warehouse | chamber of the said heat insulation container 3 is cooled. The heat insulating container 3 itself is made of a lightweight plate-like foamed synthetic resin and an infrared reflecting film, so that it is extremely lightweight and the temperature control unit 2 is also made of a plate-like foamed synthetic resin. By being comprised with the cover body 4 comprised with resin and an infrared reflective film, and the temperature control subunit 5 using the comparatively lightweight Stirling refrigerator 6, it is comprised comparatively lightweight. Accordingly, the entire storage 1 using the temperature control unit 2 can be configured to be relatively light. Further, by covering the periphery of the foamed synthetic resin plate material constituting the lid body 4 and the heat insulating container 3 with an infrared reflecting film, it is possible to prevent infrared rays, that is, heat from entering from the outside of the storage 1 into the storage. Therefore, not only can the inside of the storage 1 be efficiently cooled, but also it can be cooled to an extremely low temperature. In addition, when the storage 1 whose internal temperature is adjusted by the temperature adjustment unit 2 is transported by human power and cooling by the temperature adjustment unit 2 is not necessary, as shown in FIG. The opening 3F of the heat insulating container 3 may be closed by removing the lid 16 of the heat insulating container 3 itself.

  As described above, in the first embodiment of the present invention, the temperature adjusting subunit 5 having the Stirling refrigerator 6 as the temperature adjusting device is attached to the lid 4 having heat insulation, and this temperature adjusting subunit 5 The heat absorbing heat sink 9 constituting the temperature adjusting action portion A is thermally exposed to one surface side of the lid 4 to form the temperature adjusting unit 2, whereby the opening 3 </ b> F is closed by the temperature adjusting unit 2. The inside of the heat insulating container 3 of an arbitrary size can be cooled, and compared with solid carbon dioxide or a cold insulation agent that has been conventionally used, it is possible to store an article to be stored continuously for a long time. is there. In the first embodiment of the present invention, the lid body 4 is integrally formed of a plate-shaped foamed synthetic resin, so that the lid body 4 and thus the temperature control unit 2 as a whole are lightweight and inexpensive. In addition, the lid 4 can be easily configured in an arbitrary size. In the first embodiment of the present invention, the temperature adjusting subunit 5 is attached to the lid body 4 by the attachment body 7B, so that the Stirling refrigerator 6 can be connected to the temperature adjustment sub body by the attachment body 7B. Since the unit 5 is attached to the lid 4, not only the temperature control unit 2 can be easily assembled, but also the temperature control subunit 5 is shared and attached to the lid 4 of various sizes. Thus, the temperature control unit 2 having various sizes can be easily obtained. Further, since solid carbon dioxide or the like is not used for cooling the storage 1, not only the running cost can be kept low, but also the environmental load can be kept low because gaseous carbon dioxide is not generated. Moreover, 1st embodiment of this invention can make this heat insulation container 3 lightweight and cheap by forming the said heat insulation container 3 with a foaming synthetic resin, and this makes the said storage 1 whole lightweight and cheap. In addition, the heat insulating container 3 can be easily configured in an arbitrary size. In addition, in the first embodiment of the present invention, when the storage 1 whose interior is cooled by the temperature control unit 2 is transported manually, the temperature control unit 2 is not required to be cooled by the temperature control unit 2. Is removed, and the opening 3F of the heat insulating container 3 is closed by the lid 16 of the heat insulating container 3 itself, so that the entire storage 1 can be reduced in weight when transported manually. Furthermore, according to the first embodiment of the present invention, the temperature control device is a small and lightweight Stirling refrigerator 6 that can be cooled to a very low temperature with a small electric power, so that the inside of the storage 1 can be reduced at a low running cost. Can be cooled to a very low temperature, and the entire storage 1 can be made lightweight.

  Next, a second embodiment of the present invention will be described based on FIG. In addition, about the part which is common in said 1st embodiment, a common code | symbol is attached | subjected and the description is abbreviate | omitted. The temperature control unit 21 constituting the storage 20 is configured by a lid body 22 having a through hole 22A formed at a substantially central portion and a temperature control subunit 23. The lid 22 is integrally formed of a plate-like foamed synthetic resin having heat insulation properties, and the entire surface thereof is covered with an infrared reflecting film as an infrared reflecting layer. A step portion 22B is formed in the through hole 22A, and a base portion 25 of the temperature control subunit 23 to be described later is placed on the step portion 22B. The temperature control subunit 23 includes a Stirling refrigerator 6 as a temperature control device, a casing 24 that houses the Stirling refrigerator 6, and a base 25 that supports the Stirling refrigerator 6 and the casing 24. Configured. The Stirling refrigerator 6 is supported sideways, and an endothermic heat sink 27 is thermally transferred to the endothermic part 6B formed at the tip of the cylindrical part 6A of the Stirling refrigerator 6 via a heat transfer block 26. The heat sink 10 for exhaust heat is attached to the exhaust heat part 6C formed at the base end of the cylindrical part 6A of the Stirling refrigerator 6 in a heat transfer manner. The heat sink 27 for heat absorption is attached to be exposed on the lower surface side of the base 25, and the heat sink 10 for exhaust heat is disposed in the casing 24. The heat absorbing portion 6B and the heat transfer block 26 are covered with a heat insulating material 28 in the casing 24. The casing 24 is formed with an intake opening 24A on the cylindrical portion 6A side of the Stirling refrigerator 6, and the temperature adjusting subunit 23 is fixed to the lower portion of the casing 24. An attachment body 24B is provided, and an exhaust opening 24C is provided on the barrel 6D side of the Stirling refrigerator 6, and the fan 11 is attached to the opening 24C. Further, a through hole 24D for allowing the heat transfer block 26 to pass is formed in the lower portion of the casing 24 on the cylindrical portion 6A side of the Stirling refrigerator 6. A sealing member 12 is provided between the outer periphery of the heat sink 10 for exhaust heat and the inner wall of the casing 24 to seal these gaps. Further, the base portion 25 has a through hole 25A corresponding to the heat transfer block 26, and a step portion 25B is provided on the outer periphery of the base portion 25 so that the base portion 25 fits into the through hole 22A. It is formed corresponding to. The inner dimension of the through-hole 25A is formed larger than the outer dimension of the heat transfer block 26, and the gap between the heat transfer block 26 and the through-hole 25A is made of foamed rubber having heat insulating properties. Sealed by the formed sealing member 29. The heat sink for heat absorption 27 is formed in a size that does not protrude from the lower outer periphery of the base 25. Further, in the vicinity of the heat sink for heat absorption 27, a fan 14 for passing an air flow through the heat sink for heat absorption 27 is provided. The heat-absorbing part 6B of the Stirling refrigerator 6, the heat-transfer block 26, the heat-absorbing heat sink 27, and the fan 14 constitute a temperature adjusting action part B. An operation unit (not shown) is provided on the front side of the casing 24, and a control circuit (not shown) is accommodated in the operation unit.

  Next, the assembly procedure of the temperature control unit 21 of the present embodiment will be described. First, the temperature control subunit 23 is assembled. More specifically, first, after the heat sink 10 for exhaust heat is attached to the heat exhaust part 6C of the Stirling refrigerator 6, the heat transfer block 26 is attached to the heat absorber 6B of the cylindrical part 6A, and further the heat absorber 6B and the outer periphery of the heat transfer block 26 are covered with the heat insulating material 28 and the sealing member 29. Then, after the sealing member 12 is attached around the exhaust heat sink 10, the Stirling refrigerator 6 is housed in the casing 24 with the Stirling refrigerator 6 turned sideways. At this time, the heat transfer block 26 passes through the through hole 24D. Then, the fan 11 is attached to the exhaust opening 24C of the casing 24. Then, the casing 24 in which the Stirling refrigerator 6 is accommodated is attached to the base portion 25 by the attachment body 24B, and the heat transfer block 26 is passed through the through hole 25A of the base portion 25. At this time, the gap between the through hole 25A and the heat transfer block 26 is sealed by the sealing member 29. The heat absorbing heat sink 27 is attached to the lower end of the heat transfer block 26, and the fan 14 is attached in the vicinity of the heat sink 27. Further, the electrical wiring of the Stirling refrigerator 6, the fan 11, and the fan 14 is connected to the control circuit (not shown), and this control circuit is housed in the operation unit (not shown). As described above, the temperature control subunit 23 is assembled. The temperature adjusting subunit 23 assembled in this way is attached to the through hole 22A of the lid body 22. That is, the base portion 25 is fitted into the through hole 22A so that the step portion 25B formed on the base portion 25 of the temperature control subunit 23 is on the step portion 22B of the through hole 22A. The adjustment subunit 23 is attached to the lid body 22. At this time, as described above, since the heat sink 27 for heat absorption is sized so as not to protrude from the lower outer periphery of the base 25, the temperature adjustment subunit 23 is attached to the lid body 22. At this time, the heat sink for heat absorption 27 does not interfere with the through hole 22A. Thus, since the temperature adjustment unit 21 is configured by attaching the temperature adjustment subunit 23 to the lid body 22, only the lid body 22 using the common temperature adjustment subunit 23 is used. By changing the above, it is possible to obtain the temperature control unit 21 of various sizes, that is, the temperature control unit 21 corresponding to the heat insulation container 3 of various sizes. And although the lid 22 is covered with the infrared reflecting film, it is basically formed integrally with a heat-insulating plate-like foamed synthetic resin. Can be obtained easily and inexpensively. Thereby, the temperature control unit 21 can be manufactured at low cost.

  Next, the operation of this embodiment will be described. First, an object to be stored that has been refrigerated or frozen in a refrigerator or a freezer in advance is accommodated in the heat insulating container 3, and the temperature control unit 21 is attached to the opening 3 </ b> F of the heat insulating container 3. At this time, the temperature adjusting unit 21 is attached so that the heat sink 27 for heat absorption and the fan 14 are inside the heat insulating container 3. Then, the Stirling refrigerator 6 and the fans 11 and 14 are operated by operating the operation unit (not shown). Then, when the Stirling refrigerator 6 is operated, the endothermic part 6B has a low temperature and the exhaust heat part 6C has a high temperature. The heat absorbing portion 6B having a low temperature is formed in the heat transfer block 26 and the heat absorbing heat sink 27 that are in thermal contact with the heat absorbing portion 6B, and the inside of the heat insulating container 3 in which the heat absorbing heat sink 27 is exposed. Heat is taken from the air in the space, and the taken heat is moved to the exhaust heat unit 6C. The heat transferred to the exhaust heat unit 6C is exhausted from the exhaust heat sink 10. Since the air in the interior space of the heat insulating container 3 is passed through the heat sink 27 for heat absorption by the fan 14, the air in the heat insulating container 3 is uniformly and efficiently cooled by the Stirling refrigerator 6. Will be. Further, when the fan 11 is operated, outside air flows in from the intake opening 24A of the casing 24, and after the inflowing outside air passes through the exhaust heat sink 10, the body 6D of the Stirling refrigerator 6 is operated. It passes through the periphery and is discharged out of the casing 24 through the exhaust opening 24C and the fan 11. At this time, the heat sink 10 for exhaust heat and the body 6D of the Stirling refrigerator 6 are cooled by the airflow formed by the fan 11. Thus, the to-be-stored object accommodated in the said heat insulation container 3 is cooled because the space in the store | warehouse | chamber of the said heat insulation container 3 is cooled. The heat insulating container 3 itself is made of a lightweight plate-like foamed synthetic resin and an infrared reflecting film, so that it is extremely lightweight, and the temperature control unit 21 is also made of a plate-like foamed synthetic resin. By being comprised by the cover body 22 comprised with resin and an infrared reflective film, and the temperature control subunit 23 using the relatively lightweight Stirling refrigerator 6, it is comprised comparatively lightweight. Therefore, the entire storage 20 using the temperature control unit 21 can be configured to be relatively light. Further, by covering the periphery of the foamed synthetic resin plate material constituting the lid 22 and the heat insulating container 3 with an infrared reflecting film, it is possible to prevent infrared rays, that is, heat from entering from the outside of the storage 20 into the storage. Therefore, not only can the inside of the storage 20 be efficiently cooled, but it can also be cooled to an extremely low temperature.

  As described above, in the second embodiment of the present invention, the temperature adjustment subunit 23 having the Stirling refrigerator 6 as the temperature adjustment device is attached to the lid 22 having heat insulation, and the temperature adjustment subunit 23 is provided. The heat absorbing heat sink 27 constituting the temperature adjusting action part B is thermally exposed to one surface side of the lid body 22 to form the temperature adjusting unit 21, whereby the opening 3F is closed by the temperature adjusting unit 21. The inside of the heat insulating container 3 of an arbitrary size can be cooled, and compared with solid carbon dioxide or a cold insulation agent that has been conventionally used, it is possible to store an article to be stored continuously for a long time. is there. In the second embodiment of the present invention, the lid body 22 is integrally formed of a plate-shaped foamed synthetic resin, so that the lid body 22 and thus the temperature control unit 21 as a whole are light and inexpensive. In addition, the lid 22 can be easily configured in an arbitrary size. Further, in the second embodiment of the present invention, the temperature adjusting subunit 23 is attached to the lid body 22 by the attachment body 24B, so that the Stirling refrigerator 6 can be operated by the attachment body 24B. Since the unit 23 is attached to the lid body 22, the temperature control unit 21 can be easily assembled, and the temperature control subunit 23 can be shared and attached to the lid body 22 of various sizes. Thus, the temperature control unit 21 having various sizes can be easily obtained. Further, since solid carbon dioxide or the like is not used for cooling in the storage 20, not only the running cost can be kept low, but also the environmental load can be kept low because gaseous carbon dioxide is not generated. Moreover, 2nd embodiment of this invention can make this heat insulation container 3 lightweight and cheap by forming the said heat insulation container 3 with a foaming synthetic resin, and this makes the said storage 20 whole lightweight and cheap. In addition, the heat insulating container 3 can be easily configured in an arbitrary size. Further, according to the first embodiment of the present invention, when the storage 20 that has been internally cooled by the temperature adjustment unit 21 is transported manually, the temperature adjustment unit 21 is not required to be cooled by the temperature adjustment unit 21. Is removed, and the opening 3F of the heat insulating container 3 is closed by the lid 16 of the heat insulating container 3 itself, whereby the entire storage 20 can be reduced in weight when transporting manually. Furthermore, the second embodiment of the present invention is the Stirling refrigerator 6 that is small and light and can be cooled to a very low temperature with a small electric power, so that the inside of the storage 20 can be reduced at a low running cost. Not only can be cooled to a very low temperature, but also the entire storage 20 can be made lightweight.

  Next, a third embodiment of the present invention will be described with reference to FIG. In addition, about the part which is common in each said embodiment, a common code | symbol is attached | subjected and the description is abbreviate | omitted. Reference numeral 30 denotes a storage, and the storage 30 includes a temperature control unit 31 and a lid 32. The lid 32 is integrally formed of a plate-like foamed synthetic resin having heat insulation properties, and the entire surface thereof is covered with an infrared reflecting film as an infrared reflecting layer. The lid 32 is attached to an opening 33F of a heat insulating container 33, which will be described later, constituting the temperature adjustment unit 31 so as to be freely opened and closed. With the above-described configuration, not only can the lid 32 be easily and inexpensively manufactured, but an arbitrary size can be easily and inexpensively manufactured.

  The temperature adjustment unit 31 includes a heat insulating container 33 and a temperature adjustment subunit 23. The heat insulating container 33 includes a right wall 33A, a left wall 33B, a front wall (not shown), a rear wall 33D, and a bottom wall 33E. Each of the walls 33A, 33B, 33D, 33E and the front wall (not shown) are integrally formed of a plate-like foamed synthetic resin having heat insulation properties, and the entire surface is an infrared reflecting layer. It is covered with an infrared reflecting film. Each of the walls 33A, 33B, 33D, 33E and the front wall (not shown) is covered with a cover body 34 made of an infrared reflecting film in the state where the walls 33A, 33B, 33D, 33E are assembled as a heat insulating container 33. Further, a through hole 33G is formed in the right wall 33A, and a step portion 33H is formed in the through hole 33G, and the base portion 25 is fitted in the through hole 33G in the step portion 33H. Corresponding to the step portion 33H, a step portion 25B formed on the outer periphery of the base portion 25 of the temperature control subunit 23 abuts. The temperature control subunit 23 is in a posture in which the Stirling refrigerator 6 provided inside is upright, and the rest is the same as in the second embodiment.

  Next, an assembly procedure of the temperature adjustment unit 31 of the present embodiment will be described. First, the temperature control subunit 23 is assembled. Note that the assembly procedure of the temperature control subunit 23 is the same as that of the second embodiment, and thus the description thereof is omitted. The assembled temperature control subunit 23 is attached to a through hole 33G formed in the right wall 33A of the heat insulating container 33. That is, by fitting the base portion 25 into the through hole 33G so that the step portion 25B formed in the base portion 25 of the temperature control subunit 23 contacts the step portion 33H of the through hole 33G, A temperature control subunit 23 is attached to the heat insulating container 33. At this time, as described above, since the heat sink 27 for heat absorption is sized so as not to protrude from the outer periphery of the lower portion of the base 25, the temperature control subunit 23 is attached to the heat insulating container 33. At this time, the heat sink 27 for heat absorption does not interfere with the through hole 33G. In this manner, since the temperature adjustment unit 31 is configured by attaching the temperature adjustment subunit 23 to the heat insulation container 33, only the heat insulation container 33 using the common temperature adjustment subunit 23 is used. By changing the above, it is possible to obtain the temperature control unit 31 having various sizes, that is, the temperature control unit 31 corresponding to the lid 32 having various sizes. And although the said heat insulation container 33 is covered with the said infrared reflective film and the said cover body 34, each wall 33A, 33B, 33D, 33E of the said heat insulation container 33 and the front wall which is not shown in figure are each fundamentally Since the heat insulating plate-shaped foamed synthetic resin is integrally formed, the heat insulating containers 33 having various sizes can be obtained easily and inexpensively. Thereby, the temperature control unit 31 can be manufactured at low cost. In the present embodiment, the walls 33A, 33B, 33D, 33E and the front wall (not shown) of the heat insulating container 33 are independently formed, but they may be integrally formed. Even in this case, the heat insulating containers 33 having various sizes can be obtained easily and inexpensively.

  Next, the operation of this embodiment will be described. First, an object to be stored that has been refrigerated or frozen in a refrigerator or a freezer in advance is accommodated in the heat insulating container 33 of the temperature control unit 31, and the lid 32 is attached to the opening 33F of the heat insulating container 33. The operation of the temperature control subunit 23 is the same as that of the second embodiment, and the description thereof is omitted. The lid 32 itself is made of a lightweight plate-shaped foamed synthetic resin and an infrared reflecting film, so that it is extremely lightweight, and the temperature control unit 31 is also made of a plate-shaped foamed synthetic resin. By being comprised by the heat insulation container 33 comprised by resin and an infrared reflective film, and the temperature control subunit 23 using the comparatively lightweight Stirling refrigerator 6, it is comprised comparatively lightweight. Therefore, the entire storage 30 using the temperature control unit 31 can be configured to be relatively light. Further, by covering the periphery of the foamed synthetic resin plate material constituting the lid 32 and the heat insulating container 33 with an infrared reflecting film, it is possible to prevent infrared rays, that is, heat from entering from the outside of the storage 30 into the storage. Therefore, not only can the inside of the storage 30 be efficiently cooled, but it can also be cooled to a very low temperature.

  As described above, in the third embodiment of the present invention, the temperature control subunit 23 having the Stirling refrigerator 6 as the temperature control device is attached to the heat insulation container 33 having heat insulation properties. The heat adjustment heat sink 27 constituting the temperature adjustment action part B is thermally exposed to the inside of the heat insulation container 33 to form the temperature adjustment unit 31, so that the temperature adjustment having the heat insulation container 33 of an arbitrary size is achieved. The inside of the storage 30 formed by the unit 31 and the lid 32 that closes the opening 33F of the heat insulating container can be cooled. Compared with conventionally used solid carbon dioxide, a cooling agent, etc., A thing to be stored can be stored continuously for a long time. In the third embodiment of the present invention, since the heat insulating container 33 is formed of a foamed synthetic resin, the heat insulating container 33, and thus the temperature control unit 31 as a whole can be made lightweight and inexpensive. In addition, the heat insulating container 33 can be easily configured in an arbitrary size. In the third embodiment of the present invention, the temperature adjusting subunit 23 is attached to the heat insulating container 33 by a mounting body 24B, so that the Stirling refrigerator 6 can be moved by the mounting body 24B. Since the unit 23 is attached to the heat insulation container 33, the temperature adjustment unit 31 can be easily assembled, and the temperature adjustment subunit 23 can be shared and attached to the heat insulation container 33 of various sizes. Thus, temperature control units 31 of various sizes can be easily obtained. Further, since solid carbon dioxide or the like is not used for cooling in the storage 30, not only the running cost can be kept low, but also the environmental load can be kept low because gaseous carbon dioxide is not generated. Further, in the third embodiment of the present invention, the lid body 32 is made of foamed synthetic resin, so that the lid body 32 can be made lightweight and inexpensive, thereby making the entire storage 30 lightweight and inexpensive. In addition, the lid 32 can be easily configured in any size. Furthermore, by using the Stirling refrigerator 6 that is small and light and can be cooled to a very low temperature with a small electric power, the inside of the storage 30 can be cooled to a very low temperature with a low running cost. Instead, the entire storage 30 can be configured to be lightweight.

  Next, a fourth embodiment of the present invention will be described with reference to FIG. In addition, about the part which is common in said each embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted. Reference numeral 40 denotes a storage, and the storage 40 includes a temperature control unit 41, a main lid 42, and the heat insulating container 3.

  The temperature adjustment unit 41 includes a sub cover body 43 having a through-hole 43A formed substantially at the center, and a temperature adjustment subunit 5. The sub lid 43 is integrally formed of a plate-like foamed synthetic resin having heat insulation properties, and the entire surface thereof is covered with an infrared reflecting film as an infrared reflecting layer. The sub lid 43 is formed to have a size that closes a part of the opening 3F of the heat insulating container 3. A step 43B is formed in the through-hole 43A, and the temperature control subunit 23 corresponds to the step 43B so that the base 8 fits in the through-hole 43A in the step 43B. The base 8 of the temperature control subunit 5 is placed on the sub lid 43 by contacting the step 25B formed on the outer periphery of the base 25. In addition, since the said temperature control subunit 5 is common in 1st embodiment, the description is abbreviate | omitted.

  The main lid 42 is integrally formed of a plate-shaped foamed synthetic resin having heat insulation properties, and the entire surface thereof is covered with an infrared reflecting film as an infrared reflecting layer. The main lid 42 is attached to the opening 3F so as to be openable and closable so as to close the other part of the opening 3F of the heat insulating container 3 that is not closed by the temperature control unit 41. . With the above-described configuration, the main lid 42 can be easily and inexpensively manufactured, and an arbitrary size can be easily and inexpensively manufactured.

  Next, the assembly procedure of the temperature control unit 21 of the present embodiment will be described. First, the temperature control subunit 5 is assembled. Note that the assembly procedure of the temperature control subunit 5 is the same as that of the first embodiment, and thus the description thereof is omitted. The assembled temperature control subunit 5 is attached to the through hole 43A of the sub lid 43. That is, by fitting the base 8 into the through-hole 43A so that the step 8B formed on the base 8 of the temperature control subunit 5 rides on the step 43B of the through-hole 43A, The adjustment subunit 5 is attached to the sub lid 43. At this time, as described above, since the heat sink 9 for heat absorption is formed so as not to protrude from the outer periphery of the lower portion of the base 8, the temperature adjustment subunit 5 is attached to the sub lid 43. When attaching, the heat sink 9 for heat absorption does not interfere with the through hole 43A. Thus, since the temperature adjustment unit 41 is configured by attaching the temperature adjustment subunit 5 to the sub lid 43, the sub lid is formed using the common temperature adjustment subunit 5. By changing only 43, the temperature control unit 41 of various sizes, that is, the temperature control unit 41 corresponding to the heat insulation container 3 and the main lid 42 of various sizes can be obtained. And although the sub lid 43 is covered with the infrared reflective film, it is basically formed integrally with a heat insulating plate-shaped foam synthetic resin, so that the sub lids of various sizes can be used. 43 can be obtained easily and inexpensively. Thereby, the temperature control unit 41 can be manufactured at low cost.

  Next, the operation of this embodiment will be described. First, an object to be stored that has been refrigerated or frozen in a refrigerator or a freezer in advance is accommodated in the heat insulation container 3, and the temperature control unit 41 is opened in the heat insulation container 3 so as to close a part of the opening 3F. The main lid 42 is attached to the other part of the opening 3F so as to close the other part of the opening 3F that is not closed by the temperature adjustment unit 41, while being attached to the part 3F. At this time, the temperature adjusting unit 41 is attached so that the heat sink 9 for heat absorption and the fan 14 are inside the heat insulating container 3. Since the operation of the temperature control subunit 5 is the same as that of the first embodiment, the description thereof is omitted. And since the said heat insulation container 3 and the main cover body 42 are comprised by the lightweight plate-shaped foaming synthetic resin and the infrared reflective film, while being comprised extremely lightly, the said temperature control unit 41 is also a board. Is composed of a sub lid 43 composed of a foamed synthetic resin and an infrared reflective film, and a temperature control subunit 5 using a relatively lightweight Stirling refrigerator 6, so that it is relatively lightweight. Has been. Therefore, the entire storage 40 using the temperature adjustment unit 41 can be configured to be relatively light. Further, by covering the periphery of the foamed synthetic resin plate material constituting the main lid 41, the sub lid 42 and the heat insulating container 3 with an infrared reflecting film, infrared rays, that is, heat from the outside of the storage 40 to the inside of the storage 40 are stored. Is prevented from entering, so that not only the inside of the storage 40 can be efficiently cooled, but also it can be cooled to a very low temperature. Further, since the temperature adjustment unit 41 and the main lid 42 are provided independently, the lightweight main lid 42 can be provided with the temperature adjustment unit 41 attached to the opening 3F of the heat insulating container 3. By opening, the opening part 3F of the heat insulation container 3 which comprises the said storage 40 can be open | released easily, and a to-be-stored object can be accommodated or taken out easily.

As described above, in the fourth embodiment of the present invention, the temperature control subunit 5 having the Stirling refrigerator 6 as the temperature control device is attached to the sub lid 43 having heat insulation, and this temperature control subunit is provided. The heat absorbing heat sink 9 that constitutes the temperature adjusting action part 5 is exposed to one surface side of the sub lid 43 to form a temperature adjusting unit 41, so that the temperature adjusting unit 41 and the main lid 42 The inside of the heat insulating container 3 of any size that closes the opening 3F can be cooled, and compared with the solid carbon dioxide or the cooling agent that has been conventionally used, It can be stored. Further, in the fourth embodiment of the present invention, the sub lid 43 is integrally formed of a plate-shaped foamed synthetic resin, so that the sub lid 43, and thus the temperature control unit 41 as a whole is lightweight. Moreover, not only can the cost be reduced, but the auxiliary lid 43 can be easily configured to have an arbitrary size. Further, in the fourth embodiment of the present invention, the temperature adjusting subunit 5 is attached to the sub lid 43 by the attachment body 7B, so that the Stirling refrigerator 6 adjusts the temperature by the attachment body 7B. The sub-unit 5 is attached to the sub-lid 43 so that the temperature control unit 41 can be easily assembled, and the temperature control sub-unit 5 is used in common for the sub-cap 43 having various sizes. By attaching to the temperature control unit 41, it is possible to easily obtain temperature control units 41 of various sizes. In addition, since solid carbon dioxide or the like is not used for cooling the storage 40, not only the running cost can be kept low, but also no gaseous carbon dioxide is generated, so the environmental load can be kept low. Further, the base portion 8 is fitted into the through-hole 43A so that the step portion 8B formed in the base portion 8 of the temperature control subunit 5 rides on the step portion 43B of the through-hole 43A. The adjusting subunit 5 can be attached to the sub lid 43. Furthermore, by using the Stirling refrigerator 6 that is small and light and that can be cooled to a very low temperature with a small amount of power, the inside of the storage 40 can be cooled to a very low temperature at a low running cost. In addition, the entire storage 40 can be configured to be lightweight.

  In addition, this invention is not limited to the above embodiment, A various deformation | transformation is possible within the range of the summary of invention. For example, in each of the above embodiments, a Stirling refrigerator is used as the temperature control device, but other devices, for example, a thermo module using the Peltier effect may be used as shown in FIG. A heater may be used as shown in FIG. In each of the above embodiments, the temperature adjustment subunit is provided to be exposed from the lid, the sub lid, or the heat insulating container. However, the temperature adjustment subunit is provided in the lid, the sub lid, or the heat insulating container. You may comprise so that it may be accommodated. In the first embodiment, the second lid is attached to the heat insulating container, but the second lid may be independent of the heat insulating container.

  For example, in addition to selling a temperature control unit or a main lid and a temperature control unit that are detachably attached to the opening of the heat insulation container in advance, the heat insulation container and the temperature control unit, or the heat insulation container and the main lid It is also conceivable that the temperature control unit and the temperature control unit are sold separately, and the user uses any of the heat insulation container and the temperature control unit or the heat insulation container, the main lid, and the temperature control unit in combination.

It is sectional drawing of the store | warehouse | chamber using the temperature control unit which shows 1st embodiment of this invention. It is an expanded sectional view of the principal part same as the above. It is a right side view same as the above. It is a right side view of the state where the temperature control unit was removed and the second lid was attached. It is sectional drawing of the storage using the temperature control unit which shows 2nd embodiment of this invention. It is sectional drawing of the storage using the temperature control unit which shows 3rd embodiment of this invention. It is sectional drawing of the storage using the temperature control unit which shows 4th embodiment of this invention. It is sectional drawing of the storage using the temperature control unit which shows 5th embodiment of this invention. It is sectional drawing of the storage using the temperature control unit which shows 6th embodiment of this invention.

Explanation of symbols

1,20,30,40 Storage 2,21,31,41 Temperature control unit 3,33 Thermal insulation container 3F, 33F Opening 4,22,32 Lid 5,23 Temperature control subunit 6 Stirling refrigerator 6B Heat absorption part ( Temperature control section)
8 Base 9, 27 Heat sink for heat absorption
14 Fan (temperature control section)
16 Lid (second lid)
42 Main lid
43 Sub lid A, B Temperature control section

Claims (2)

An insulated container having an opening;
A temperature control unit that is detachably attached to the opening so as to close a part of the opening of the heat insulating container;
A main lid attached to close the other part of the opening,
The temperature control unit, and the sub cover body having a heat insulating property, made from temperature regulatory subunit provided in the sub-lid,
The temperature control subunit is configured to have a base portion and a Stirling refrigerator that are fitted into a through hole formed in the sub lid,
Reservoir temperature regulating device, characterized in that it comprises a temperature regulation acting portion that thermally exposed to the internal space of the insulated container. The storage according to claim 1, wherein the temperature adjustment subunit has an attachment body for attaching the temperature adjustment subunit to the sub lid .

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