JPH071141B2 - Cold storage - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (A) Field of Industrial Application The present invention relates to a cooling storage cabinet including two independent refrigeration cycles.

(B) Conventional technology A conventional cooling storage is generally equipped with one refrigeration cycle, as disclosed in, for example, Japanese Utility Model Publication No. 56-43670, in which case cooling is performed during defrosting operation. Stop and
Since the heater is energized to defrost the cooler, the temperature inside the refrigerator cannot be increased during this period.

As an improvement of such a conventional technique, Japanese Patent Application No. 61-51038 filed on March 7, 1986 constitutes two refrigeration cycles and defrosts a cooler of one refrigeration cycle. During the operation, the cooling operation of the other refrigeration cycle is performed to reduce the differential of the set temperature in the refrigerator.

(C) Problems to be Solved by the Invention As described above, what constitutes a two-system refrigeration cycle is
Although it is possible to avoid a significant temperature rise in the cold storage during defrosting operation, compared to a system that has one system of refrigeration cycle,
This leaves a problem that the inside temperature of the part corresponding to the side performing the cooling operation and the inside temperature of the part corresponding to the side performing the defrosting operation are not uniform.

Further, since the above-mentioned conventional technique uses the propeller fan for circulating the cool air, the discharge amount of the cool air from the discharge port varies depending on the rotation direction of the propeller fan. That is, if the fan rotates clockwise, more cool air is discharged to the left of the discharge port, and if the fan rotates counterclockwise, more cool air is discharged to the right of the discharge port. It was not possible to eliminate the uneven temperature inside the chamber caused by the direction of rotation of the fan.

(D) Means for Solving the Problems In order to solve the problems of the prior art, the present invention includes two independent refrigeration cycles, and corresponds to the evaporator of each refrigeration cycle and this evaporator. However, a pair of cooling units consisting of propeller fans for circulating cold air that rotate in the same direction are installed side by side in the upper part of the storage, and the fans of one cooling unit are stopped to perform the defrosting operation. A fan for the cooling unit is operated to perform the cooling operation, and a cover plate that covers the respective cooling units and forms a suction port facing the respective fans, and a cover plate that is continuous with the cover plate A unit cover composed of a back plate having a cool air passage formed at a distance from the back wall and an air outlet formed at the lower end is provided, and the cold air discharged from the cooling unit in the cooling operation state is defrosted in the cold air passage. At least a pair of flow dividing plates that divide the flow are provided on the side of the cooling unit in the operating state, and the flow dividing plates are cooling storages having different mounting angles according to the rotating direction of the fan.

(E) Action According to the cooling storage of the present invention, a part of the cold air discharged from the cooling unit (9) or (10) performing the cooling operation is defrosted by the action of the flow dividing plate (31A) or (32A). Cooling unit (10) or (9) operating
As a result, the uneven temperature distribution inside the refrigerator can be eliminated, and by making the mounting angles of the flow distribution plates (31A) and (32A) different, the rotation directions of the fans (12) and (20) It is possible to eliminate the variation in the discharge amount of the discharged cool air caused by.

(F) Example FIG. 1 is a front view of an essential part showing an internal structure of a cooling storage according to the present invention, and FIG. 2 is a longitudinal sectional view of an essential part of the cooling storage, where (1) is a front opening and closing. A storage main body having a heat insulating structure provided with a free door body (2), and a first condensing unit (3) that constitutes two independent refrigeration cycles on the outer wall of the main body (1). ) And a second condensing unit (4) are installed, and each of these units (3) and (4) is composed of an electric compressor (5), a condenser (6), a condenser air cooling fan (7), etc. Has been done.

On the other hand, in the upper rear part in the storage (8), together with the first condensing unit (3), a first cooling unit (9) that constitutes one refrigeration cycle and a second condensing unit (4) are provided. A second cooling unit (10) forming the other refrigeration cycle is arranged in parallel. The first cooling unit (9) comprises a first evaporator (11) and a first propeller fan (12) for circulation of the first cold air, which is installed in front of the first evaporator (11). Mouth (1
3) and a first cooling cover (15) having a blower outlet (14) formed below the rear of the evaporator (11), and a first defrost heater (16) provided below the evaporator (11). Further, below the heater (16), a tray (18) for guiding defrost water to the drainage passage (17) formed along the rear wall of the main body (1) is arranged. On the other hand, the second cooling unit (10) includes a second evaporator (19) and a second propeller fan for cold air circulation (20) installed in front of the second evaporator and rotating in the same direction as the first propeller fan (12). ), Which are covered by a second cooling cover (23) having a suction port (21) facing the front of the fan (20) and a blow-out port (22) below the rear of the evaporator (19), A second defrosting heater (24) is provided below the container (19), and a defrosting water tray (not shown) is further provided below the heater (24).

Thus, the first and second cooling units (9) and (10) are arranged in the communicating space (26) by the unit cover (25) that covers them. Unit cover (25)
Forms a large number of suction ports (27) facing the fans (12) and (20) on the upstream side of the suction ports (13) and (21) and cools the cooling covers (15) and ( 23) and a cover plate (25A) that extends rearward with a space between the cover plate (25A) and a blower outlet (14A) that extends downward from the rear end of the cover plate (25A) with a space between the cover and the back wall. ), (22) and the rear cold air passage (2
A rear plate (25B) that forms the air outlet (29A) at the lower end located downstream of the air outlets (14) and (22) while forming the air outlet 8)
And the air outlets (14) that extend forward from both end portions of the cover plate (25A) and the back plate (25B) at a distance from the inside wall of the refrigerator.
A pair of side plates (25C) having side cold air passages (30) communicating with (22) and outlets (29B) formed at the front and lower ends.
It is composed by.

Further, the cool air discharged from the air outlets (14) and (22) enters the rear cold air passage (28) through the air outlet (29) of the unit cover (25).
Three first flow distribution plates (31A), (31B) and (31C) corresponding to the first cooling unit (9) so that they are uniformly blown into the storage (8) from almost the entire area of (A); Three second flow distribution plates (32A), (32 corresponding to the second cooling unit (10)
B) and (32C) are attached to the back wall in the refrigerator, of which the first and second inner flow dividing plates (31A) and (32A) located inside
And the first and second middle diversion plates (31B) and (3
2B) is inclined inward toward the inside of the refrigerator, and the upper ends of the first and second inner flow distribution plates (31A) and (32A) and the upper end of the first middle flow distribution plate (31B) respectively correspond to the outlets (14) and The first and second external flow distribution plates (31) located close to (20) and located outside
C) and (32C) are inclined low toward the outside of the refrigerator. Furthermore, when the rotation direction of each of the propeller fans (12) and (20) is previously determined to be clockwise rotation, the first internal flow dividing plate (31A)
And, the inclination angle of the first middle diversion plate (31B) is more gentle than the inclination angles of the second inner diversion plate (32A) and the second middle diversion plate (32B), whereby the first inner diversion plate is formed. (31A) and the upper ends of the first middle diversion plate (31B), the first cooling cover (1
5) The air outlet (14) is deeply inserted in the horizontal direction and positioned so as to take in a large amount of cool air discharged from the air outlet (14), and the second inner diversion plate (32A) and the second middle diversion plate are provided. The upper end of (32B) is made to enter shallowly with respect to the horizontal direction of the air outlet (22) of the second cooling cover (23), and is positioned so as to take in a small amount of cool air discharged from the air outlet (22).

In addition, the cool air discharged from the outlets (14) and (22) also flows into the side cool air passage (30) through the outlet (29) of the unit cover (25).
A plurality of flow distribution plates (33) are attached to the inner side wall of the storage (8) so as to uniformly blow out from the storage (8) in the horizontal and vertical directions.

In the above configuration, the respective refrigeration cycles are alternately operated to cool the food in the storage (8),
In the cold air circulation operation at this time, as shown by an arrow in FIG. 2, the food is uniformly blown into the inside (8) to cool the food.

By the way, according to the present invention configured such that, when one refrigeration cycle is stopped and the defrosting operation is performed, the cooling operation is performed by the other refrigeration cycle.
The propeller fan (20) stops and the second defrost heater (24)
When the second evaporator (19) is defrosted,
The first cooling unit (9) in which the first propeller fan (12) is operating to perform cooling operation is the first evaporator (11).
The cool air that has been heat-exchanged with is discharged from the outlet (14) of the first cooling cover (15) to the rear cool air passage (28), and the discharged cool air flows through the rear cool air passage (28) and the side cool air passage (30). Store through each outlet (29A) and (29B) through (8)
It is blown out inside.

At this time, the first inner diversion plate (31A) and the first middle diversion plate (31B)
Is the second cooling unit (10) side that is performing the defrosting operation on the discharged cool air that is blown out from the air outlet (14) of the first cooling cover (15), as shown by the arrow (A) in FIG. Shunt into
It serves to positively guide a part of the discharged cool air toward the cool air passage (28) corresponding to the second cooling unit (10). As a result, the air outlet (29A) of the unit cover (25)
The partial blowout of cold air from the air is eliminated, and the outlet (29A)
The cold air can be blown into the storage (8) from almost the entire area.

On the other hand, when the first cooling unit (9) is performing the defrosting operation and the second cooling unit (10) is performing the cooling operation, as shown by the arrow (B) in FIG. By the action of the 2 inner diversion plate (32A) and the 2nd middle diversion plate (32B),
First, cool the cool air discharged from the outlet (22) of the cooling cover (23).
The cooling air passage (28) corresponding to the cooling unit (9), and as a result, similar to the above, the air outlet (29).
It is possible to eliminate the partial cold air blowing from A) and blow the cold air into the storage (8) from almost the entire area of the air outlet (29A).

By the way, since the rotation directions of the first and second propeller fans (12) and (20) are clockwise, the blowout port (14) of the first cooling cover (15) and the second cooling cover (23) are A large amount of discharged cool air blown out from the air outlet (22) is discharged to the left. That is, the first cooling unit (9)
When the second cooling unit (10) is in the cooling operation, the amount of cold air discharged from the air outlet (14) increases in the outside direction of the refrigerator, and when the second cooling unit (10) is in the cooling operation. )
The amount of cool air discharged from the inside is large in the inside direction.

Therefore, when the first cooling unit (9) is in the cooling operation state, by the first inner flow dividing plate (31A) and the first middle flow dividing plate (31B) that have deeply entered in the horizontal direction of the air outlet (14),
The cool air discharged from the air outlet (14) is supplied to the second cooling unit (1
0), so that a large amount of air is sent in the direction of the cold air passage (28) to correct the variation in the cold air discharge amount of the first cooling unit (9) caused by the rotation direction of the first propeller fan (12). , Unit cover (25) outlet (29
The variation of the cold air discharge amount from A) is remarkably solved by one layer.

On the other hand, when the second cooling unit (10) is in the cooling operation state, the second cooling unit (10) that is shallowly entered in the horizontal direction of the air outlet (22).
The inner cooling plate (32A) and the second middle cooling plate (32B) are used to cool the cool air discharged from the air outlet (22) into the first cooling unit (9).
The amount of cold air discharged from the second cooling unit (10) caused by the rotation direction of the second propeller fan (20) is corrected by feeding less air in the direction of the cold air passageway (28). Outlet (29A) of cover (25)
The variation in the discharge amount of cold air from the above is more significantly eliminated.

In the above-described embodiment of the present invention, the rotation of the first and second propeller fans (12) and (20) is clockwise, but when this is set counterclockwise, the first internal flow distributor ( 31A) and the first middle diversion plate (31B) are inclined more slowly than the second inner diversion plate (32A) and the second middle diversion plate (32B). Is to demonstrate.

(G) Effect of the Invention As described above, according to the present invention, when one cooling unit is performing the cooling operation, the other cooling unit is performing the defrosting operation. Each of the cooling units has a flow dividing plate that can prevent rising and that guides a part of the cool air discharged from the cooling unit that is performing the cooling operation to the cold air passage on the side of the cooling unit that is performing the defrosting operation. Since it is provided in the corresponding cool air passage, the blow-off cold air is prevented from being biased to one side, and the cool air can be blown into the storage from almost the entire area of the blowout port, and the first and second cold air circulating units that rotate in the same direction as each other. The variation in the amount of cold air discharged due to the rotation direction of the propeller fan can be corrected by changing the mounting angle of the flow distribution plate, and thus the variation in the extreme temperature distribution of the internal temperature can be reduced. This is a remarkable advantage that can be solved.

[Brief description of drawings]

FIG. 1 is a front view of an essential part showing an internal structure of a cooling storage according to the present invention, and FIG. 2 is a vertical sectional side view of an essential part of the cooling storage. ( 9 ) ... First cooling unit, ( 10 ) ... Second cooling unit, (11) ... First evaporator, (12) ... First cold air circulation fan, (19) ... Second Evaporator, (20) ... Second cold air circulation fan, ( 25 ) ... Unit cover, (25A) ...
… Cover plate, (25B) …… Rear plate, (27) …… Suction port, (2
8) …… Cold air passage, (29A) …… Blowout port, (31A) …… First internal diversion plate, (32A) …… Second internal diversion plate.

Claims (1)

[Claims] 1. A pair of cooling units, each having two independent refrigeration cycles, comprising an evaporator of each refrigeration cycle and a propeller fan for circulating cold air that corresponds to the evaporator and rotates in the same direction. Lined up in the upper part of the storage,
When the defrosting operation is performed by stopping the fan of one cooling unit, the fan of the other cooling unit is operated to perform the cooling operation, and each cooling unit is covered and each cooling unit is operated. A unit cover composed of a cover plate facing the fan and having a suction port, and a back plate which is continuous with the cover plate and forms a cool air passage at a distance from the back wall of the inside of the refrigerator and at the lower end of which a blowout port is formed. Provided in the cold air passage is at least a pair of flow dividing plates for dividing the cold air discharged from the cooling unit in the cooling operation state toward the cooling unit in the defrosting operation state, the flow dividing plates depending on the rotation direction of the fan. Cooling storage characterized by different mounting angles.