JP2020038013A - Cooling device - Google Patents

Abstract

To provide a cooling device which achieves reduction of an amount of frost adhering to a cooling coil.SOLUTION: A cooling device 10 includes: a partition 16 for forming a first chamber 20a and a second chamber 20b into which a cooled object 30 is carried therein; a cooling coil 12 provided at the partition 16; and fans 14a, 14b provided at the first chamber 20a side of the cooling coil 12. The partition 16 controls airflow flowing from the second chamber 20b to the first chamber 20a so that the airflow passes through the cooling coil 12.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a cooling device.

  Patent Document 1 discloses a cooling device that cools an object to be cooled by circulating cool air with a cooling fan. This cooling device is a cooling device including a cooler provided on at least a side wall side of a room formed by a heat insulating box, a cooling room in front of the cooler, and a fan for flowing air in the cooling room. Then, the cooler and the cooling chamber are partitioned by a partition plate so that cool air is stored in the cooler, and the fan is arranged on the cooler side of the partition plate, and is provided on a partition plate in front of the fan. Has an opening, the size of the opening is larger than the diameter of the fan, and when the fan is viewed in the rotation axis direction of the fan, the fan is arranged in the opening, and there is an open space outside the fan, By the rotation of the fan, a discharge flow of cool air blown out from the cooler through the opening to the cooling chamber and a suction flow of cool air sucked from the cooling chamber through the opening to the cooler are generated, and the discharge flow and the suction flow are generated. Clash with each other and reduce the flow rate of cold air So as to suppress the frosting of the cooler, it is characterized by replacing the accumulated in cold air cooling chamber and the cooler cold air.

Patent Document 2 discloses a cooling device that has a simpler structure than a conventional cold air forced circulation system, can exhibit the same cooling performance, and can reduce the amount of frost on a cooler. I have. This cooling device includes a box formed of a heat insulating member, a cooler that cools air by heat exchange, a cooler room in which the cooler is housed inside the box, and an object to be cooled is housed. A partition plate partitioned into two compartments with a storage compartment and having an opening formed to connect these two compartments, and disposed in the cooler compartment, and the air cooled by the cooler is introduced into the storage compartment through the opening. And a fan to send in. The opening is larger than the diameter of the fan and, when viewed from the direction of the rotation axis of the fan, is arranged so that the opening surrounds the outer periphery of the fan with a gap therebetween. Is defined by 1.8 × π (R / 2) ² ≦ S ≦ 2.5 × π (R / 2) ² , and the distance between the boundary surface on the storage side of the opening and the frontmost portion of the fan is , 0 or more and 0.2R or less.

International Publication No. 2004/113807 International Publication No. 2005/124249

Here, in general, there is a demand for a cooling device in which the amount of frost adhering to the cooling coil is reduced.
An object of the present invention is to provide a cooling device in which the amount of frost adhering to a cooling coil is reduced.

  According to the first aspect of the present invention, a first chamber and a second chamber into which an object to be cooled is carried are formed inside, and an opening is provided to connect the first chamber and the second chamber. The cooling device includes a partition, a cooling coil disposed in the opening, and a first fan provided on a side of the cooling coil on the first chamber side.

  According to a second aspect of the present invention, in the first aspect of the invention, the partition is provided such that a gap from the second chamber to the first chamber does not substantially occur.

  According to a third aspect of the present invention, in the first aspect of the present invention, the partition controls an airflow from the second chamber to the first chamber to pass through the cooling coil.

  The invention described in claim 4 is the invention according to claim 2 or 3, further comprising a second fan that blows air to the object to be cooled in the second chamber.

  According to a fifth aspect of the present invention, in the invention of the fourth aspect, a first door for maintenance is provided in the first chamber, and the object to be cooled is carried in and out of the second chamber. Is provided.

  ADVANTAGE OF THE INVENTION According to this invention, the cooling device with which the amount of frost adhering to a cooling coil was reduced can be provided.

FIG. 1 is an explanatory diagram of a cooling device according to a first embodiment of the present invention. It is a top view showing arrangement of a fan and a cooling coil with which the same cooling device is provided. It is an explanatory view of a cooling device according to a second embodiment of the present invention.

  Next, embodiments of the present invention will be described with reference to the accompanying drawings to provide an understanding of the present invention. In the drawings, parts that are not relevant to the description may be omitted.

[First Embodiment]
The cooling device 10 according to the first embodiment of the present invention includes a partition plate 16, a cooling coil 12, fans 14a and 14b, and a fan 15, as shown in FIG.

The partition plate (an example of a partition) 16 is a member for forming an upper first chamber 20 a and a lower second chamber 20 b inside the cooling device 10. An opening in which the cooling coil 12 is disposed is provided at the center of the partition plate 16, and the opening connects the first chamber 20a and the second chamber 20b. The partition plate 16 has a gap from the second chamber 20b to the first chamber 20a so that an airflow that does not flow between the first chamber 20a and the second chamber 20b except for the opening is generated. The partition plate 16 can be controlled so that the airflow returning from the second chamber 20b to the first chamber 20a passes through the cooling coil 12 because the partition plate 16 is provided inside the inner wall so that there is no air flow. Here, "to prevent a gap leading from the second chamber 20b to the first chamber 20a from occurring" means that a design or manufacturing error is allowed, and that "a gap does not substantially occur.""Meaning".
Therefore, the inside of the cooling device 10 is divided into a first chamber 20a and a second chamber 20b into which the object 30 is carried, with the partition plate 16 and the cooling coil 12 interposed therebetween.
The partition plate 16 does not need to be formed of a single plate, and may be formed of a plurality of plate members.

The first chamber 20a is provided with a first door 22a for maintenance of the cooling coil 12 and the fans 14a and 14b.
The second chamber 20b is provided with a second door 22b for carrying in and out the object 30 to be cooled.

  The cooling coil 12 is disposed in an opening provided in the partition plate 16 so as to protrude below the partition plate 16, and can cool the surrounding air. The area of the cooling coil 12 in plan view is set to be larger than the area of all the fans 14a and 14b.

The fans 14a and 14b (an example of a first fan) are provided above and separated from the upper surface of the cooling coil 12 by a distance H1, respectively, and blow air downward so that the air cooled by the cooling coil 12 becomes second. To the lower part of the chamber 20b.
The fans 14a and 14b are arranged with an interval D1 therebetween.
Note that the number of fans is not limited to two.

  The fan 15 (an example of a second fan) is arranged such that the air blowing direction is the direction of the object 30 to be cooled. When the fan 15 blows air to the object to be cooled 30, the time until the object to be cooled 30 freezes is reduced.

Next, the operation of the cooling device 10 will be described.
In the cooling device 10, when the object 30 to be cooled is carried in from the second door 22b, the cool air is sent to the second chamber 20b by the fans 14a and 14b.
The cool air sent to the second chamber 20b returns to the first chamber 20a through the cooling coil 12 again. At this time, some of the cool air returns to the first chamber 20a through the gap between the fans 14a and 14b (see the portion A shown in FIG. 2), as indicated by the arrow in FIG.
The cool air returned to the first chamber 20a is cooled again by the fans 14a and 14b and the cooling coil 12, and is sent to the second chamber 20b.
The object to be cooled 30 is cooled in such an airflow, and is frozen while drying is suppressed.

The inventor conducted a test on such a cooling device 10 to clarify its performance.
The cooling device according to the comparative example is a cooling device obtained by removing the partition plate 16 from the cooling device 10. That is, the only difference between the cooling device 10 according to the present embodiment and the cooling device of the comparative example is the presence or absence of the partition plate 16.
In addition, in the cooling device according to the comparative example without the partition plate 16, the cool air sent to the second chamber 20 b by the fans 14 a and 14 b mainly passes through the place where the partition plate 16 was, and flows around the cooling coil 12. It returns to the first chamber 20a so as to go around.

(1) Amount of adhering frost In order to clarify that frost hardly adheres to the cooling coil 12 of the cooling device 10, the amount of water after the cooling operation at a refrigerator temperature of −25 ° C. was measured.
As a result of the measurement, the cooling device of the comparative example weighed 85 g, and the cooling device 10 weighed 21 g. That is, in the cooling device 10, the amount of frost adhered was reduced to about 1/4.

(2) Recovery characteristics of the internal temperature In order to clarify that the internal temperature recovery of the cooling device 10 is quick, the cooling operation is performed to the internal temperature of −25 ° C., and the second door 22b is opened to open the internal temperature. Was raised to 0 ° C., and the time from when the second door 22b was closed to when the internal temperature reached −25 ° C. was measured.
As a result of the measurement, the cooling device of the comparative example was 30 minutes, and the cooling device 10 was 15 minutes. That is, in the cooling device 10, the internal temperature returned twice as fast.

(3) Drying Characteristics of the Cooled Object 30 In order to clarify that the cooled object 30 is hardly dried by the cooling operation of the cooling device 10, the degree of drying of the cooled object 30 after the cooling operation was measured. The degree of drying was evaluated based on the ratio of the decrease in the weight of the object 30 before and after cooling.
As a result of the measurement, the cooling device of the comparative example had a weight reduction ratio of 12% and the cooling device 10 had a weight reduction ratio of 2.5%. That is, in the cooling device 10, the degree of drying was reduced to about 1/5, and drying was suppressed.

  As described above, according to the cooling device 10 according to the present embodiment, the frost is suppressed from adhering to the cooling coil 12, the recovery characteristic of the internal temperature is excellent, and the drying of the cooled object 30 is suppressed.

[Second embodiment]
Subsequently, a cooling device 50 according to a second embodiment of the present invention will be described.
The cooling device 50 is a so-called tunnel type freezer, and includes a partition plate 62, a cooling coil 52, fans 54a and 54b, fans 55a and 55b, fans 56a and 56b, and a conveyor 58, as shown in FIG.

The partition plate (an example of a partition) 62 is a member for forming an upper first chamber 70 a and a lower second chamber 70 b inside the cooling device 50. An opening in which the cooling coil 52 is disposed is provided at the center of the partition plate 62, and the opening connects the first chamber 70a and the second chamber 70b. In the partition plate 62, a gap is formed from the second chamber 70b to the first chamber 70a so that an airflow that does not flow between the first chamber 70a and the second chamber 70b except for the opening is generated. The partition plate 62 can be controlled so that the airflow returning from the second chamber 70 b to the first chamber 70 a passes through the cooling coil 52 because the partition plate 62 is provided inside the inner wall surface so as not to exist. Here, "to prevent a gap from the second chamber 70b to the first chamber 70a from occurring" means that an error in design or manufacturing is allowed, and that "a gap does not substantially occur.""Meaning".
Therefore, the interior of the cooling device 50 is divided into a first chamber 70a and a second chamber 70b in which the object to be cooled 80 is loaded on the conveyor 58 with the partition plate 62 and the cooling coil 52 interposed therebetween. .
The partition plate 62 does not need to be formed by a single plate, and may be formed by a plurality of plate members.

  The cooling coil 52 is disposed in an opening provided in the partition plate 62 so as to protrude below the partition plate 62, and can cool ambient air. The area of the cooling coil 52 in plan view is set to be larger than the area of all the fans 54a and 54b.

The fans 54a and 54b (an example of a first fan) are provided above and separated from the upper surface of the cooling coil 52 by a distance H2, respectively, and blow the air downward so that the air cooled by the cooling coil 52 becomes the second fan. Can be sent downward of the chamber 70b.
The fans 54a and 54b are arranged with an interval D2 therebetween.
Note that the number of fans is not limited to two.

  The fans 55a and 55b (an example of a second fan) are arranged at intervals along the transport path of the article 80 to be conveyed, and are set so that the air blowing direction is a direction crossing the transport path of the article 80 to be cooled. Have been. The fan 55a, 55b blows air to the object to be cooled 80, whereby the time until the object to be cooled 80 freezes is reduced.

The fans 56a and 56b are fans for suppressing the leakage of cool air in the refrigerator, and are provided on the entrance side and the exit side of the transport path of the object to be cooled 80, respectively.
The conveyor 58 can convey the object to be cooled 80 from the inlet of the cooling device 50 to the inside thereof and toward the outlet.

Next, the operation of the cooling device 50 will be described.
In the cooling device 50, the cool air is sent to the second chamber 70b by the fans 54a and 54b.
The cool air sent to the second chamber 70b returns to the first chamber 70a through the cooling coil 52 again. At that time, a part of the cool air returns to the first chamber 70a through the gap between the fan 54a and the fan 54b as shown by the arrow in FIG.
The cool air returned to the first chamber 70a is cooled again by the fans 54a and 54b and the cooling coil 52, and is sent to the second chamber 70b.
The object to be cooled 80 moves on the conveyor 58 from the entrance in such an airflow, is cooled, and is frozen while drying is suppressed.

  As described above, according to cooling device 50 of the present embodiment, since a tunnel-type freezer is configured, adhesion of frost to cooling coil 52 is suppressed and drying of cooled object 80 is suppressed. In this state, the object to be cooled 80 is efficiently frozen in large quantities.

  As described above, the embodiments of the present invention have been described, but the present invention is not limited to the above-described embodiments, and all changes in conditions that do not depart from the gist are within the scope of the present invention.

Reference Signs List 10 Cooling device 12 Cooling coils 14a, 14b Fan 15 Fan 16 Partition plate 20a First chamber 20b Second chamber 22a First door 22b Second door 30 Cooled object 50 Cooling device 52 Cooling coils 54a, 54b Fan 55a , 55b Fan 56a, 56b Fan 58 Conveyor 62 Partition plate 70a First chamber 70b Second chamber 80 Cooled object

  The present invention relates to a cooling device.

  Patent Document 1 discloses a cooling device that cools an object to be cooled by circulating cool air with a cooling fan. This cooling device is a cooling device including a cooler provided on at least a side wall side of a room formed by a heat insulating box, a cooling room in front of the cooler, and a fan for flowing air in the cooling room. Then, the cooler and the cooling chamber are partitioned by a partition plate so that cool air is stored in the cooler, and the fan is arranged on the cooler side of the partition plate, and is provided on a partition plate in front of the fan. Has an opening, the size of the opening is larger than the diameter of the fan, and when the fan is viewed in the rotation axis direction of the fan, the fan is arranged in the opening, and there is an open space outside the fan, By the rotation of the fan, a discharge flow of cool air blown out from the cooler through the opening to the cooling chamber and a suction flow of cool air sucked from the cooling chamber through the opening to the cooler are generated, and the discharge flow and the suction flow are generated. Clash with each other and reduce the flow rate of cold air So as to suppress the frosting of the cooler, it is characterized by replacing the accumulated in cold air cooling chamber and the cooler cold air.

Patent Document 2 discloses a cooling device that has a simpler structure than a conventional cold air forced circulation system, can exhibit the same cooling performance, and can reduce the amount of frost on a cooler. I have. The cooling device includes a box configured of a heat insulating member, a cooler that cools air by heat exchange, a cooler room in which the cooler is housed inside the box, and an object to be cooled is housed. A partition plate partitioned into two compartments with a storage compartment and having an opening formed to connect these two compartments, and disposed in the cooler compartment, and the air cooled by the cooler is introduced into the storage compartment through the opening. And a fan to send in. The opening is larger than the diameter of the fan and, when viewed from the direction of the rotation axis of the fan, is arranged so that the opening surrounds the outer periphery of the fan with a gap therebetween. Is defined by 1.8 × π (R / 2) ² ≦ S ≦ 2.5 × π (R / 2) ² , and the distance between the boundary surface on the storage side of the opening and the frontmost portion of the fan is , 0 or more and 0.2R or less.

International Publication No. 2004/113807 International Publication No. 2005/124249

Here, in general, there is a demand for a cooling device in which the amount of frost adhering to the cooling coil is reduced.
An object of the present invention is to provide a cooling device in which the amount of frost adhering to a cooling coil is reduced.

According to the first aspect of the present invention, a first chamber and a second chamber into which an object to be cooled is carried are formed inside, and an opening is provided to connect the first chamber and the second chamber. the partition has a cooling coil disposed in the opening, before SL provided in the first chamber, and a first fan for blowing air to the cooling coil, the partition is, said cooling coil Except for the arranged opening, an airflow is provided such that a gap from the second chamber to the first chamber does not substantially occur, and flows from the second chamber to the first chamber. Is a cooling device passing through the cooling coil .

According to a second aspect of the present invention, a first chamber and a second chamber into which the object to be cooled are carried are formed therein, and an opening is provided to connect the first chamber and the second chamber. A cooling coil disposed in the opening, through which an airflow from the first chamber to the second chamber and an airflow from the second chamber to the first chamber pass; A first fan that is provided in the first chamber and blows air to the cooling coil, wherein the partition is separated from the second chamber except for the opening where the cooling coil is disposed. This is a cooling device provided so that a gap leading to one chamber does not substantially occur.

The invention according to claim 3 is the invention according to claim 1 or 2 , further comprising a second fan that blows air to the object to be cooled in the second chamber.

  ADVANTAGE OF THE INVENTION According to this invention, the cooling device with which the amount of frost adhering to a cooling coil was reduced can be provided.

FIG. 1 is an explanatory diagram of a cooling device according to a first embodiment of the present invention. It is a top view showing arrangement of a fan and a cooling coil with which the same cooling device is provided. It is an explanatory view of a cooling device according to a second embodiment of the present invention.

  Next, embodiments of the present invention will be described with reference to the accompanying drawings to provide an understanding of the present invention. In the drawings, parts that are not relevant to the description may be omitted.

[First Embodiment]
The cooling device 10 according to the first embodiment of the present invention includes a partition plate 16, a cooling coil 12, fans 14a and 14b, and a fan 15, as shown in FIG.

The partition plate (an example of a partition) 16 is a member for forming an upper first chamber 20 a and a lower second chamber 20 b inside the cooling device 10. An opening in which the cooling coil 12 is disposed is provided at the center of the partition plate 16, and the opening connects the first chamber 20a and the second chamber 20b. The partition plate 16 has a gap from the second chamber 20b to the first chamber 20a so that an airflow that does not flow between the first chamber 20a and the second chamber 20b except for the opening is generated. The partition plate 16 can be controlled so that the airflow returning from the second chamber 20b to the first chamber 20a passes through the cooling coil 12 because the partition plate 16 is provided inside the inner wall so that there is no air flow. Here, "to prevent a gap leading from the second chamber 20b to the first chamber 20a from occurring" means that an error in design or manufacturing is allowed, and that "a gap does not substantially occur.""Meaning".
Therefore, the inside of the cooling device 10 is divided into a first chamber 20a and a second chamber 20b into which the object 30 is carried, with the partition plate 16 and the cooling coil 12 interposed therebetween.
The partition plate 16 does not need to be formed of a single plate, and may be formed of a plurality of plate members.

The first chamber 20a is provided with a first door 22a for maintenance of the cooling coil 12 and the fans 14a and 14b.
The second chamber 20b is provided with a second door 22b for carrying in and out the object 30 to be cooled.

  The cooling coil 12 is disposed in an opening provided in the partition plate 16 so as to protrude below the partition plate 16, and can cool the surrounding air. The area of the cooling coil 12 in plan view is set to be larger than the area of all the fans 14a and 14b.

The fans 14a and 14b (an example of a first fan) are provided above and separated from the upper surface of the cooling coil 12 by a distance H1, respectively, and blow air downward so that the air cooled by the cooling coil 12 becomes second. To the lower part of the chamber 20b.
The fans 14a and 14b are arranged with an interval D1 therebetween.
Note that the number of fans is not limited to two.

  The fan 15 (an example of a second fan) is arranged such that the air blowing direction is the direction of the object 30 to be cooled. When the fan 15 blows air to the object to be cooled 30, the time until the object to be cooled 30 freezes is reduced.

Next, the operation of the cooling device 10 will be described.
In the cooling device 10, when the object 30 to be cooled is carried in from the second door 22b, the cool air is sent to the second chamber 20b by the fans 14a and 14b.
The cool air sent to the second chamber 20b returns to the first chamber 20a through the cooling coil 12 again. At this time, some of the cool air returns to the first chamber 20a through the gap between the fans 14a and 14b (see the portion A shown in FIG. 2), as indicated by the arrow in FIG.
The cool air returned to the first chamber 20a is cooled again by the fans 14a and 14b and the cooling coil 12, and is sent to the second chamber 20b.
The object to be cooled 30 is cooled in such an airflow, and is frozen while drying is suppressed.

The inventor conducted a test on such a cooling device 10 to clarify its performance.
The cooling device according to the comparative example is a cooling device obtained by removing the partition plate 16 from the cooling device 10. That is, the only difference between the cooling device 10 according to the present embodiment and the cooling device of the comparative example is the presence or absence of the partition plate 16.
In addition, in the cooling device according to the comparative example without the partition plate 16, the cool air sent to the second chamber 20 b by the fans 14 a and 14 b mainly passes through the place where the partition plate 16 was, and flows around the cooling coil 12. It returns to the first chamber 20a so as to go around.

(1) Amount of adhering frost In order to clarify that frost hardly adheres to the cooling coil 12 of the cooling device 10, the amount of water after the cooling operation at a refrigerator temperature of −25 ° C. was measured.
As a result of the measurement, the cooling device of the comparative example weighed 85 g, and the cooling device 10 weighed 21 g. That is, in the cooling device 10, the amount of frost adhered was reduced to about 1/4.

(2) Recovery characteristics of the internal temperature In order to clarify that the internal temperature recovery of the cooling device 10 is quick, the cooling operation is performed to the internal temperature of −25 ° C., and the second door 22b is opened to open the internal temperature. Was raised to 0 ° C., and the time from when the second door 22b was closed to when the internal temperature reached −25 ° C. was measured.
As a result of the measurement, the cooling device of the comparative example was 30 minutes, and the cooling device 10 was 15 minutes. That is, in the cooling device 10, the internal temperature returned twice as fast.

(3) Drying Characteristics of the Cooled Object 30 In order to clarify that the cooled object 30 is hardly dried by the cooling operation of the cooling device 10, the degree of drying of the cooled object 30 after the cooling operation was measured. The degree of drying was evaluated based on the ratio of the decrease in the weight of the object 30 before and after cooling.
As a result of the measurement, the cooling device of the comparative example had a weight reduction ratio of 12% and the cooling device 10 had a weight reduction ratio of 2.5%. That is, in the cooling device 10, the degree of drying was reduced to about 1/5, and drying was suppressed.

  As described above, according to the cooling device 10 according to the present embodiment, the frost is suppressed from adhering to the cooling coil 12, the recovery characteristic of the internal temperature is excellent, and the drying of the cooled object 30 is suppressed.

[Second embodiment]
Subsequently, a cooling device 50 according to a second embodiment of the present invention will be described.
The cooling device 50 is a so-called tunnel type freezer, and includes a partition plate 62, a cooling coil 52, fans 54a and 54b, fans 55a and 55b, fans 56a and 56b, and a conveyor 58, as shown in FIG.

The partition plate (an example of a partition) 62 is a member for forming an upper first chamber 70 a and a lower second chamber 70 b inside the cooling device 50. An opening in which the cooling coil 52 is disposed is provided at the center of the partition plate 62, and the opening connects the first chamber 70a and the second chamber 70b. In the partition plate 62, a gap is formed from the second chamber 70b to the first chamber 70a so that an airflow that does not flow between the first chamber 70a and the second chamber 70b except for the opening is generated. The partition plate 62 can be controlled so that the airflow returning from the second chamber 70 b to the first chamber 70 a passes through the cooling coil 52 because the partition plate 62 is provided inside the inner wall surface so as not to exist. Here, "to prevent a gap from the second chamber 70b to the first chamber 70a from occurring" means that an error in design or manufacturing is allowed, and that "a gap does not substantially occur.""Meaning".
Therefore, the interior of the cooling device 50 is divided into a first chamber 70a and a second chamber 70b in which the object to be cooled 80 is loaded on the conveyor 58 with the partition plate 62 and the cooling coil 52 interposed therebetween. .
The partition plate 62 does not need to be formed by a single plate, and may be formed by a plurality of plate members.

  The cooling coil 52 is disposed in an opening provided in the partition plate 62 so as to protrude below the partition plate 62, and can cool ambient air. The area of the cooling coil 52 in plan view is set to be larger than the area of all the fans 54a and 54b.

The fans 54a and 54b (an example of a first fan) are provided above and separated from the upper surface of the cooling coil 52 by a distance H2, respectively, and blow the air downward so that the air cooled by the cooling coil 52 becomes the second fan. Can be sent downward of the chamber 70b.
The fans 54a and 54b are arranged with an interval D2 therebetween.
Note that the number of fans is not limited to two.

  The fans 55a and 55b (an example of a second fan) are arranged at intervals along the transport path of the article 80 to be conveyed, and are set so that the air blowing direction is a direction crossing the transport path of the article 80 to be cooled. Have been. The fan 55a, 55b blows air to the object to be cooled 80, whereby the time until the object to be cooled 80 freezes is reduced.

The fans 56a and 56b are fans for suppressing the leakage of cool air in the refrigerator, and are provided on the entrance side and the exit side of the transport path of the object to be cooled 80, respectively.
The conveyor 58 can convey the object to be cooled 80 from the inlet of the cooling device 50 to the inside thereof and toward the outlet.

Next, the operation of the cooling device 50 will be described.
In the cooling device 50, the cool air is sent to the second chamber 70b by the fans 54a and 54b.
The cool air sent to the second chamber 70b returns to the first chamber 70a through the cooling coil 52 again. At that time, a part of the cool air returns to the first chamber 70a through the gap between the fan 54a and the fan 54b as shown by the arrow in FIG.
The cool air returned to the first chamber 70a is cooled again by the fans 54a and 54b and the cooling coil 52, and is sent to the second chamber 70b.
The object to be cooled 80 moves on the conveyor 58 from the entrance in such an airflow, is cooled, and is frozen while drying is suppressed.

  As described above, according to cooling device 50 of the present embodiment, since a tunnel-type freezer is configured, adhesion of frost to cooling coil 52 is suppressed and drying of cooled object 80 is suppressed. In this state, the object to be cooled 80 is efficiently frozen in large quantities.

  As described above, the embodiments of the present invention have been described, but the present invention is not limited to the above-described embodiments, and all changes in conditions that do not depart from the gist are within the scope of the present invention.

Reference Signs List 10 Cooling device 12 Cooling coils 14a, 14b Fan 15 Fan 16 Partition plate 20a First chamber 20b Second chamber 22a First door 22b Second door 30 Cooled object 50 Cooling device 52 Cooling coils 54a, 54b Fan 55a , 55b Fan 56a, 56b Fan 58 Conveyor 62 Partition plate 70a First chamber 70b Second chamber 80 Cooled object

Claims (5)

A partition having therein a first chamber and a second chamber into which the object to be cooled is introduced, and an opening provided to connect the first chamber and the second chamber;
A cooling coil disposed in the opening,
A first fan provided on the side of the first chamber of the cooling coil. The cooling device according to claim 1,
The cooling device, wherein the partition is provided such that a gap from the second chamber to the first chamber does not substantially occur. The cooling device according to claim 1,
A cooling device, wherein the partition controls an airflow from the second chamber to the first chamber to pass through the cooling coil. The cooling device according to claim 2 or 3,
A cooling device further comprising a second fan for blowing air to the object to be cooled in the second chamber. The cooling device according to claim 4,
A first door for maintenance is provided in the first chamber;
A cooling device provided with a second door for carrying in and out the object to be cooled into and out of the second chamber;