JP2022049851A - Cooling storage - Google Patents

Abstract

To provide a cooling storage which enables a drain tank to be installed without reducing an effective volume of a space within the cooling storage, such as a cold room.SOLUTION: A drain tank 20 is disposed in a space which is filled with a heat insulation material 17 formed of a foam resin and located between an outer case 16 and an inner case 15 of a heat insulation case body 14 (a body case 1). In the structure, an effective volume of a cooling chamber 2 is not reduced as seen in a conventional cooling storage, in which a drain tank is disposed in a cooling chamber 2 (an interior of the cooling storage), to secure the large effective volume of the cooling chamber 2.SELECTED DRAWING: Figure 1

Description

The present invention relates to a cooling cabinet such as a refrigerator or a showcase, and particularly to a drain tank arrangement structure for storing drain water discharged from an evaporator.

In the field of cooling, it is a well-known technique to provide a drain tank for temporarily storing drain water generated from an evaporator during a defrosting operation. For example, in the refrigerator of Patent Document 1, an evaporator (evaporator), a drain cover (evaporator) covering the lower surface of the evaporator, and a drain tank are arranged in a cooling chamber (refrigerator chamber). The drain tank is provided at the rear end of the drain cover.

In the refrigerator of Patent Document 2, a drain tank is arranged in the cooling chamber (refrigerating chamber). More specifically, a control box containing a damper thermostat is arranged at the upper end of the cooling chamber, and a drain tank (tank) is arranged above the control box.

Japanese Unexamined Patent Publication No. 10-132446 Jitsukosho 63-42295 Gazette

When the drain tank is arranged in the cooling chamber as in Patent Documents 1 and 2, it is inevitable that the effective volume of the cooling chamber is reduced by the capacity of the drain tank. Although it is possible to arrange the drain tank outside the refrigerator such as the back or side of the cooler, in that case, the drain tank protrudes from the back or side of the cooler.

An object of the present invention is to prevent the effective volume of the cooling chamber from being impaired by the installation of the drain tank in the cooling chamber.

The cooling cabinet according to the present invention includes a main body case 1 composed of a heat insulating box body 14, a cooling chamber 2 provided inside the main body case 1, and an evaporator 9 responsible for generating cold air supplied to the cooling chamber 2. The drain cover 11 that receives the drain water discharged from the evaporator 9, the drain tank 20 that stores the drain water, and the drain water that is provided between the drain cover 11 and the drain tank 20 and is received by the drain cover 11. A water receiving pipe 21 for flowing down to the drain tank 20 is provided. The heat insulating box 14 constituting the main body case 1 is a filling space between the outer box 16, the inner box 15 provided with a required facing gap inside the outer box 16, and both boxes 16 and 15. It is composed of a heat insulating material 17 made of a foamed resin filled therein. The drain tank 20 is characterized in that it is arranged in the filling space between the outer box 16 and the inner box 15 of the heat insulating box body 14.

A heat insulating material 17 is arranged between the inner box 15 and the drain tank 20.

The drain tank 20 includes a tank body 30 that opens upward, and the lower end of the pipe end portion of the water receiving pipe 21 faces the bottom wall of the tank body 30 via a gap E, and is inside the drain tank 20. The minimum water level of the drain water is set above the lower end of the pipe end portion of the water receiving pipe 21.

The evaporation container 22 for evaporating the drain water, the pump 23 for supplying the drain water in the drain tank 20 to the evaporation container 22, the pumping pipeline 24 provided between the evaporation container 22 and the drain tank 20, and the drain. A liquid level sensor 26 for detecting the water level of the drain water in the tank 20 is provided. Then, when the liquid level sensor 26 detects that the liquid level of the drain water in the drain tank 20 has reached a predetermined position, the pump 23 is activated and the drain water is pumped to the evaporation container 22. Has been done.

In the cooling chamber according to the present invention, since the drain tank 20 is arranged in the filling space of the heat insulating material 17 made of foamed resin between the outer box 16 and the inner box 15 of the heat insulating box body 14, the drain tank 20 is arranged in the cooling chamber 2 (storage). Unlike the conventional cooling cabinet in which the drain tank is arranged inside), the effective volume of the cooling chamber is not impaired, and the effective volume of the cooling chamber 2 can be made larger. Therefore, according to the present invention, it is possible to prevent the effective volume of the cooling chamber 2 from being impaired by the installation of the drain tank 20.

When the heat insulating material 17 is arranged between the inner box 15 and the drain tank 20, the heat insulating body 17 can insulate between the two 15 and 20, so that the heat of the external air insulates the drain tank 20 and the drain tank 20. It is possible to prevent the temperature inside the refrigerator from being inadvertently increased by suppressing the transmission to the inside of the refrigerator through the body 17 and the inner box 15.

If the minimum water level of the drain water in the drain tank 20 is set above the lower end of the pipe end portion of the water receiving pipe 21, the water level of the drain water in the drain tank 20 is of course the lowest if it is sufficiently high. Even at the water level, the drain water, the tank body 30, and the water receiving pipe 21 can function in the same manner as the drain trap. Therefore, it is possible to prevent the cold air inside the refrigerator from leaking to the outside of the refrigerator through the water receiving pipe 21 and the tank body 30, and further prevent the air outside the refrigerator from entering the inside of the refrigerator through the tank body 30 and the water receiving pipe 21. Can be prevented.

When the liquid level sensor 26 detects that the liquid level of the drain water in the drain tank 20 has reached a predetermined position, the pump 23 is activated and the drain water is pumped to the evaporation container 22. Then, only when the liquid level of the drain water in the drain tank 20 reaches a predetermined position due to the defrosting operation, the drain water can be supplied to the evaporation container 22 by the pump 23, so that the electric power is generated. It can be prevented from being wasted. Incidentally, when the pump is driven in a state where the cold insulation operation is restarted, the pump is driven regardless of the amount of drain water in the tank, which is wasteful. Since the drain water is pumped up to the evaporation container 22 every time the liquid level of the drain water in the drain tank 20 reaches a predetermined position, the drain water flowing down to the drain tank 20 does not overflow from the drain tank 20.

It is a vertical sectional side view of the main part of the cooling cabinet which concerns on embodiment of this invention. It is a vertical sectional side view of a cooling room. It is explanatory drawing which shows the cooling unit conceptually. It is a rear view of the main part which shows the drain tank accommodating structure. It is a top view of the main part which shows the transpiration structure. It is a perspective view which shows the drain tank accommodating structure. It is a top view which shows the ventilation / drainage structure of a drain pan.

(Example) FIGS. 1 to 7 show examples in which the cooler of the present invention is applied to a commercial refrigerator. The front-back, left-right, and up-down in this embodiment follow the crossing arrows shown in FIGS. 2, 5, and 7, and the notations of front-back, left-right, and up-down in the vicinity of the arrows. As shown in FIG. 2, the refrigerator includes a main body case 1 composed of a vertically long rectangular parallelepiped heat insulating box body 14. A refrigerating chamber (cooling chamber) 2 is formed inside the main body case 1. A pair of upper and lower door openings are formed in front of the main body case 1, and each door opening is provided with a door 3 for opening and closing the door openings. In FIG. 2, reference numeral 4 indicates a door receiving rail that separates the upper and lower door openings.

Inside the main body case 1, a cooling unit for supplying cold air to the refrigerating chamber 2 is provided. The cooling unit circulates with the compressor 6, the condenser 7, and the condenser fan 8 housed in the machine room 5 formed above the main body case 1, and the evaporator 9 arranged above the refrigerating room 2. It is composed of a fan 10, a drain cover 11 that covers the lower surface of the evaporator 9 and the circulation fan 10, and the like. The air in the refrigerating chamber 2 is sucked by the circulation fan 10, sent to the evaporator 9, cooled while passing through the evaporator 9, and blown into the refrigerator. Therefore, the suction port 12 is formed in the front portion of the drain cover 11, and the outlet 13 is formed in the rear portion of the drain cover 11. The drain cover 11 is inclined downward toward the rear portion of the main body case 1. A control box is provided in the front part of the machine room 5, and by operating a control button or the like provided on the control panel in front of the control box, the operation of each device constituting the cooling unit is operated via a control device (not shown). The state can be controlled to adjust the temperature state inside the refrigerator.

As shown in FIG. 1, the heat insulating box 14 constituting the main body case 1 is a foam filled in an inner box 15 and an outer box 16 made of a stainless steel plate and a filling space between the two 15 and 16. It is composed of a heat insulating body (heat insulating material) 17 made of resin. Inside the refrigerating chamber 2, four upper and lower tray shelves 18 are provided (see FIG. 2). When a refrigerator is used, the air in the refrigerator comes into contact with the refrigerant pipes and fins of the evaporator 9 to form frost, which adheres to the refrigerant pipes and fins. Therefore, the defrosting operation is performed at regular intervals to liquefy the frost adhering to the evaporator 9 and drain it as drain water. Further, during the cooling operation in the refrigerator, the water contained in the circulating air in contact with the refrigerant pipes and fins may be liquefied and dropped from the evaporator 9. In order to evaporate such drain water, the refrigerator of this embodiment is provided with an evaporative structure.

As shown in FIG. 4, the evaporation structure includes a drain tank 20 that temporarily stores drain water, a water receiving pipe 21 that inherits the drain water flowing from the drain cover 11 and causes the drain water to flow down to the drain tank 20, and a machine chamber 5. The evaporation container 22 housed in the evaporation container 22, the pump 23 and the pumping pipeline 24 for supplying the drain water in the drain tank 20 to the evaporation container 22, and the heating body 25 for heating and evaporating the drain water in the evaporation container 22. And a liquid level sensor 26 that detects the liquid level of the drain water in the drain tank 20. The heating body 25 is formed in the middle of the refrigerant pipe 7a on the inlet side of the condenser 7, and is housed in the inner bottom of the evaporation container 22. Therefore, when the drain water is pumped to the evaporation container 22 by the pump 23, the heating body 25 is immersed in the drain water.

In order to prevent the effective volume of the refrigerating chamber 2 from becoming small, the drain tank 20 is arranged inside the rear wall of the main body case 1 facing the inclined lower end side of the drain cover 11. That is, the tank accommodating portion 27 is arranged in the filling space between the inner and outer boxes 15 and 16 of the heat insulating box body 14 constituting the rear wall of the main body case 1, and the drain tank 20 is accommodated in the tank accommodating portion 27. ing. As shown in FIGS. 1 and 4, the drain tank 20 includes a tank body 30 that opens upward and a fastening seat 31 that is fixed to the upper part of the left and right side edges of the tank body 30. The left-right width of the tank accommodating portion 27 is set to be slightly larger than the left-right width of the tank main body 30. Further, as shown in FIG. 4, the overhang width of the fastening seat 31 is set to be larger than the left-right width of the tank accommodating portion 27. The water receiving pipe 21 is a plastic molding integrally provided with a water receiving portion 32 that inherits the drain water flowing down from the drain cover 11 and a drainage portion 33 that allows the drain water received by the water receiving portion 32 to flow down to the drain tank 20. It is made of goods, and the whole is embedded inside the heat insulating body 17, and the lower half of the drainage portion 33 is projected inside the tank accommodating portion 27. Similarly, the suction port side of the pumping pipe 24 is projected inside the tank accommodating portion 27.

The tank accommodating portion 27 is composed of an accommodating recess 35 that opens on the outer surface of the outer box 16 of the heat insulating box body 14 and an accommodating box 36 made of a stainless steel plate that is fitted and fixed in the accommodating recess 35. The front-rear thickness of the storage box 36 is set to be smaller than the front-rear thickness of the rear wall of the main body case 1, and the heat insulating body 17 is arranged between the rear wall of the inner box 15 of the heat-insulating box body 14 and the storage box 36. ing. As a result, it is possible to prevent the heat of the external air from being transmitted to the inside of the refrigerator through the storage box 36, the heat insulating body 17, and the inner box 15. Further, by fitting and fixing the storage box 36 in the storage recess 35, it is possible to prevent moisture from entering the gap between the outer box 16 and the heat insulating body 17. As shown in FIG. 4, the tank accommodating portion 27 is formed in a recess toward the right side of the rear wall of the main body case 1, and the water receiving pipe 21 is also arranged at a position deviated from the left and right center of the drain cover 11 to the right side. ing. Correspondingly, an outlet passage 28 for draining the drain water collected by the drain cover 11 to the water receiving pipe 21 is provided at a position closer to the right side of the inclined lower end of the drain cover 11, and cold air outlets are provided on the left and right sides of the outlet passage 28. 13 is formed (see FIG. 7).

The vertical facing distance L between the lower end of the drainage portion 33 and the inlet of the pumping pipeline 24 inside the storage box 36 and the bottom wall of the storage box 36 is set to be larger than the vertical height h of the drain tank 20. This is for easily assembling the drain tank 20 to the storage box 36 while avoiding the pumping pipe line 24 and the drainage portion 33 protruding into the tank housing portion 27. For example, the drain tank 20 is mounted on the storage box 36. After inserting the drain tank 20 into the box 36 along the bottom wall, the drain tank 20 is fastened to the outer box 16 with a screw 37 in a state where the drain tank 20 is lifted upward, so that the drain tank 20 is attached to the tank accommodating portion 27. However, it can be easily assembled. In the drain tank 20 in this state, the bottom wall of the tank body 30 faces the lower end of the drainage portion 33 (the lower end of the pipe end portion of the water receiving pipe 21) and the inlet of the pumping pipe line 24 via the gap E.

The refrigerator at the time of use performs a defrosting operation at regular intervals in order to remove frost adhering to the refrigerant pipes and fins of the evaporator 9 during the cooling operation. The frost liquefied during the defrosting operation is dropped from the evaporator 9 and collected by the drain cover 11, sent out from the outlet passage 28 to the water receiving pipe 21, and temporarily stored in the drain tank 20. When the liquid level sensor 26 detects that the liquid level of the drain water in the drain tank 20 has reached a preset liquid level, the liquid level sensor 26 outputs a detection signal to the control device. Upon receiving the detection signal, the control device activates the pump 23, whereby the drain water in the drain tank 20 is sent to the evaporation container 22, and the heating body 25 housed in the evaporation container 22 is immersed in the drain water. Will be done. In this state, when the cooling unit is switched to the cooling operation state, the high-temperature refrigerant pressurized in the compressor 6 is supplied to the condenser 7 via the heating body 25. Therefore, the drain water in the evaporation container 22 is directly heated by the heating body 25 while the high-temperature refrigerant passes through to raise the temperature, and eventually evaporates. As the drain water in the drain tank 20 is sent to the evaporation vessel 22 by the pump 23, the water level of the drain water gradually decreases, but when the water level of the drain water drops to the lowest water level, the liquid level sensor 26 Outputs a detection signal to stop the pump 23. The minimum water level is set slightly above the lower end of the drainage portion 33, and the lower end of the drainage portion 33 at the lowest water level (the lower end of the pipe end portion of the water receiving pipe 21 at the lowest water level) is always immersed in the drain water. It has become like.

According to the refrigerator of the present embodiment configured as described above, as compared with the conventional evaporation structure in which the drain water is transpired by the exhaust air of the condenser or the drain water is transpired by the conduction heat from the condenser. Since the heat of the compressed high-temperature refrigerant can be directly transferred to the drain water, the drain water in the evaporation container 22 can be transpired in a shorter time. Further, since the heat of the high-temperature refrigerant can be released from the heating body 25 provided in front of the condenser 7, the heat dissipation efficiency of the condenser 7 can be improved by that amount.

Further, according to the refrigerator of the present embodiment, since the drain tank 20 is arranged in the filling space of the heat insulating material 17 made of foamed resin between the outer box 16 and the inner box 15 of the heat insulating box body 14, the drain tank 20 is arranged in the refrigerating room 2. The effective volume of the refrigerating chamber is not impaired as in the conventional cooling cabinet in which the drain tank is arranged (inside the refrigerator), and the effective volume of the refrigerating chamber 2 can be further increased. A heat insulating body 17 is arranged between the inner box 15 and the drain tank 20 so that the heat insulating body 17 insulates between the two 15 and 20, so that the heat of the external air is generated between the drain tank 20 and the heat insulating body. It is possible to prevent the temperature inside the refrigerator from being inadvertently increased by suppressing the transmission to the inside of the refrigerator through the inner box 15 and the inner box 15.

Since the minimum water level of the drain water in the drain tank 20 is set above the lower end of the pipe end of the water receiving pipe 21, the drain water level in the drain tank 20 is not only sufficiently high, but also at the minimum water level. Also, the drain water, the tank body 30, and the water receiving pipe 21 can function in the same manner as the drain trap. Therefore, it is possible to prevent the cold air inside the refrigerator from leaking to the outside of the refrigerator through the water receiving pipe 21 and the tank body 30, and further prevent the air outside the refrigerator from entering the inside of the refrigerator through the tank body 30 and the water receiving pipe 21. Can be prevented.

The liquid level sensor 26 is arranged inside the drain tank 20, and the pump 23 is started and the drain is started in a state where the liquid level sensor 26 detects that the liquid level of the drain water in the drain tank 20 has reached a predetermined position. The water can be pumped into the evaporation container 22. According to this, when the liquid level of the drain water in the drain tank 20 reaches a predetermined position due to the defrosting operation, the drain water can be sent to the evaporation container 22 by the pump 23, so that electric power can be supplied. Can be prevented from being wasted. Incidentally, when the pump is driven in a state where the cold insulation operation is restarted, the pump is driven regardless of the amount of drain water in the tank, which is wasteful. Since the drain water is pumped up to the evaporation container 22 every time the liquid level of the drain water in the drain tank 20 reaches a predetermined position, the drain water flowing down to the drain tank 20 does not overflow from the drain tank 20.

Since the outlet passage 28 is provided at the lower end of the slope of the drain cover 11 and the outlet passage 13 for cold air is formed on the left and right sides of the outlet passage 28, the amount of space occupied by the outlet passage 28 is minimized, and the action of blowing out the cold air at the outlet 13 is minimized. Can be prevented from being obstructed by the exit passage 28. Therefore, the cold air can be effectively circulated without disturbing the flow discharge action of the drain water collected by the drain cover 11.

Since the facing distance L between the lower end of the drainage portion 33 inside the storage box 36 and the bottom wall of the storage box 36 is set to be larger than the vertical height h of the drain tank 20, the pumping water protruding inside the tank storage portion 27 The drain tank 20 can be assembled to the storage box 36 without any trouble while avoiding the pipeline 24 and the drainage portion 33, and by removing the screw 37 screwed into the outer box 16, the drain tank 20 can be reversed as described above. It can be separated from the tank accommodating portion 27 by the procedure of. Therefore, not only the drain tank 20 and the liquid level sensor 26 can be cleaned, but also the pumping pipe line 24 and the drainage unit 33 protruding inside the tank accommodating portion 27 can be easily maintained.

In addition to the above, the tank accommodating portion 27 is provided on the rear wall of the main body case 1, but it is not necessary to provide the tank accommodating portion 27 on one side wall of the main body case 1. In that case, it is advisable to bury the water receiving pipe 21 and the pumping pipe line 24 in the side wall formed by the tank accommodating portion 27. If necessary, the tank accommodating portion 27 may be formed so as to open on the rear surface and one side surface of the main body case 1. The heat insulating body 17 that insulates between the inner box 15 and the storage box 36 of the main body case 1 may be formed of a heat insulating material different from the foamed resin. The cooler may be a freezer / refrigerator provided with a freezer and a refrigerator, a freezer dedicated to use only in the freezing temperature zone, or a reach-in type cooler.

1 Main body case 2 Cooling room (refrigerating room)
9 Evaporator 11 Drain cover 14 Insulation box body 17 Insulation material (insulation body)
20 Drain tank 21 Water receiving pipe 22 Evaporation container 23 Pumping pump 24 Pumping pipe line 26 Liquid level sensor 30 Tank body E Gap

Claims (4)

The main body case (1) made of a heat insulating box (14) and
The cooling chamber (2) provided inside the main body case (1) and
The evaporator (9), which is responsible for generating the cold air supplied to the cooling chamber (2), and
A drain cover (11) that receives the drain water discharged from the evaporator (9), and
A drain tank (20) for storing drain water and
A water receiving pipe (21) provided between the drain cover (11) and the drain tank (20) to allow the drain water received by the drain cover (11) to flow down to the drain tank (20).
Equipped with
The heat insulating box body (14) constituting the main body case (1) includes an outer box (16) and an inner box (15) provided with a required facing gap inside the outer box (16). It is composed of a heat insulating material (17) made of foamed resin filled in the filling space between both boxes (16 and 15).
A cooling cabinet characterized in that the drain tank (20) is arranged in a filling space between the outer box (16) and the inner box (15) of the heat insulating box body (14). The cooler according to claim 1, wherein a heat insulating material (17) is arranged between the inner box (15) and the drain tank (20). The drain tank (20) is provided with a tank body (30) that opens upward.
The lower end of the pipe end portion of the water receiving pipe (21) faces the bottom wall of the tank body (30) via a gap (E).
The cooler according to claim 1 or 2, wherein the minimum water level of the drain water in the drain tank (20) is set above the lower end of the pipe end portion of the water receiving pipe (21). An evaporation container (22) for evaporating drain water and
A pump (23) that feeds the drain water in the drain tank (20) to the evaporation container (22), and
A pumping pipe (24) provided between the evaporation container (22) and the drain tank (20),
A liquid level sensor (26) that detects the water level of the drain water in the drain tank (20), and
Equipped with
When the liquid level sensor (26) detects that the liquid level of the drain water in the drain tank (20) has reached a predetermined position, the pump (23) is activated and the drain water is sent to the evaporation container (22). The cooler according to any one of claims 1 to 3, which is configured to be pumped.

Images