KR950010556B1 - Defrosting device for open show-case - Google Patents

Abstract

The method for defrosting the showcase, prevents the rapid increasing of the temperature of the inner showcase and minimizes the temperature difference of inner showcase after defrosting by changing the passage for circulating the defrosting air. The apparatus comprises the defrosting-air passing plate(24) mounted on the evaporator cover(18); first/second solenoid switches(19)(20) having the movable pieces(21)(22) for respectively isolating the suction air or discharged air; a defrost returning temperature sensor(6) mounted at the plate(24) and a defrost-air temperature sensor(23) mounted at a cooling air passing plate(13) for controlling the solenoid switches.

Description

Defrosting apparatus and method of refrigeration showcase

1 is a schematic representation of a typical refrigerated open showcase.

2 is a drive control circuit diagram of a typical refrigerated open showcase.

3 is a defrost / operation time chart of a typical refrigerated open showcase.

4 is a schematic representation of the present invention refrigeration showcase.

5 is a detail view of the "Q" part in FIG.

6 is a defrost control circuit diagram of the present invention.

7 is a defrost / operation time chart of the present invention refrigerated open showcase.

* Explanation of symbols for main parts of the drawings

1: Insulation Box 2: Compressor

3: condenser 4: evaporator

5: expansion valve 6: defrost return temperature sensor

7: evaporator input tube 8: condenser fan motor

9: evaporator fan motor 10: defrost water storage tank

11: drain pipe 12: defrost heater

13 cooling air passage plate 14 cooling air jet plate

15: air intake plate 16: display shelf

17: display door 18: evaporator cover

19: first solenoid switch 20: second solenoid switch

21: Movable piece for intake air blocking 22: Movable piece for blowing air block

23 defrost air temperature sensor 24 defrost air passage plate

100: frozen showcase RY1: defrost relay

RY2: Defrost return relay RY3: Defrost / operation auxiliary relay

RY4: Relay for solenoid control TM: Defrost timer

The present invention relates to a defrost air circulation system for changing the circulation passage of the defrost air during defrost of the evaporator of the refrigeration showcase, in particular to prevent the temperature rise in the high by the defrost operation, and to minimize the temperature difference in the showcase store after defrosting A defrosting apparatus and method for a refrigeration showcase.

1 is a schematic view of a general freeze-open showcase, as shown in the figure, the compressor 1 and the condenser 3 are connected to each other at the lower end of the insulating box 1, and the condenser 3 and the evaporator 4 are expanded valves. (5) and through the evaporator input tube (7), the condenser fan motor (8) is attached to the front of the condenser (3), in the internal configuration of the thermal insulation box (1), the expansion valve (5) and An evaporator cover 18 is installed at an upper end of the connected evaporator 4, and an evaporator fan motor 9 is installed on an inclined surface of the evaporator cover 18, and between the evaporator fan motor 9 and the evaporator 4. The defrost heater 12 is fixed to the cooling air passage plate 13 is fixedly installed on the upper rear side of the evaporator 4 to establish a circulation passage of the cooling air, and the inner upper front of the freezing showcase 100. The cooling air jet plate 14 is fixedly installed at the upper part of the evaporator fan motor 9. The air suction plate 15 is attached to the defrosting, and the defrosting return temperature sensor 6 is attached to the upper cooling air passage of the evaporator 4, and the lower end of the heat insulation box 1 is defrosted through the drain pipe 11. It is connected to the storage tank 10, the display shelf 16 is mounted inside the freezing showcase 100, the display door 17 is fixed to the front opening of the freezing showcase 100 is configured to be installed.

2 is a drive control circuit diagram of a general refrigeration open showcase, as shown therein, an evaporator fan motor 9 is connected to a power supply terminal, a defrost timer TM is connected to a defrost relay RY1, and a defrost return temperature sensor. (6) is connected to the defrosting return relay RY2, and the a contact switch RY11 of the relay RY1 is connected to the defrost / operation auxiliary relay RY3 via the b contact switch RY21 of the relay RY2. A contact switch RY31 of the relay RY3 is connected to the defrost heater 12, a b contact switch RY32 of the relay RY3 is connected to the compressor 2, and the relay RY3 is connected. The b contact switch RY33 of) is connected to the condenser fan motor 8, and the operation of the conventional open showcase configured as described above will be described with reference to FIG.

When power is supplied, the compressor 2, the condenser fan motor 8, including the evaporator fan motor 9 are driven, and at this time, the cooling operation is performed in the evaporator 4 by driving the compressor 2, As the air cooled by the evaporator 4 is circulated in the direction of the arrow by the rotation of the evaporator fan motor 9, the temperature inside the freezing showcase 100 is lowered.

Thereafter, when the above cooling operation is continued to reach the point where frost or ice is formed and adhered to the surface of the evaporator 4, the defrost timer TM is turned on to drive the defrost relay RY1, so that the a of the relay RY1 The contact switch RY11 is short-circuited, and at this time, the defrosting return temperature sensor 6 is still in the off state and remains open so that the defrosting return relay RY2 is also in the off state.

Accordingly, power is supplied to the defrosting / operation auxiliary relay RY3 through the a contact switch RY11 of the relay RY1 and the b contact switch RY21 of the defrosting return relay RY2 and driven to drive the relay RY3. A contact switch RY31 of () is short-circuited, and b contact switches RY32 and RY33 are opened. Therefore, while the defrost heater 12 starts to generate heat, the compressor 2 and the condenser fan motor 8 are placed in the driving stop state.

Accordingly, the frost or ice that has been attached to the evaporator 4 starts to melt, and when a predetermined time elapses from the frost or ice, the frost or ice is completely removed, and the discharge temperature of the evaporator 4 rises above the predetermined temperature by the defrosting action. When the defrosting return temperature sensor 6 is short-circuited, the defrosting return relay RY2 is driven so that the b contact switch ry21 of the relay RY2 is opened, which causes the defrosting / operation auxiliary relay RY3 to open. Since the a contact switch RY31 of the auxiliary relay RY3 is opened because it is turned off, the b contact switches RY32 and RY33 are short-circuited to stop driving of the defrost heater 12, while the compressor 2 ) And the operation of the condenser fan motor 8 is resumed.

The defrost / operation cycle forms the same time period as the third degree, and since the circulation of the defrost hot air proceeds in the same direction as the arrow of FIG. 1, the temperature inside the freezing showcase 100 rises immediately before the end of the defrost. .

As described above, in the conventional open showcase, in using the defrosting effect of heating the defrost heater to blow hot air to the heat generating surface of the evaporator, the hot hot air passing through the evaporator is circulated inside the showcase and the defrosting operation is performed. Hot air is constantly supplied to the inside of the showcase unnecessarily for a certain period of time, and furthermore, such a high temperature and low temperature cycle is repeatedly performed, which adversely affects the food stored in the interior.

The present invention has been made to prevent the rise in the internal temperature due to the circulation of hot air when defrosting the evaporator in order to solve such a conventional defect, will be described in detail with reference to the accompanying drawings.

4 is a schematic view of the refrigerator showcase of the present invention, as shown therein, the body is composed of a heat insulating box (1), and the compressor (2) and the condenser (3) are connected to each other at the bottom of the heat insulating box (1), The condenser 3 and the incremental barrier 4 are connected to an evaporator input tube 7 equipped with an expansion valve 5, and a condenser fan motor 8 is installed on the front side of the condenser 3. An evaporator cover 18 is fixedly installed on an upper end of the evaporator 4 connected to the expansion valve 5, and an evaporator fan motor 9 is fixedly installed on an inclined surface thereof, between the evaporator fan motor 9 and the evaporator 4. The defrost heater 12 is installed at the same time, and the defrost air passage plate 24 having a predetermined gap is fixedly installed on the upper portion of the evaporator cover 18, and the blowoff air is provided in the lower portion of the rear surface of the defrost air passage plate 24. A second solenoid switch 20 equipped with a shutoff movable piece 22 is installed, and the lower portion of the front surface of the defrost air passage plate 24 is provided. The first solenoid switch 19 having the suction air blocking movable piece 21 mounted thereon, and then installing the air suction plate 15 adjacent to the front part of the defrost air passage plate 24; In addition, the cooling air passage plate 13 is connected to the rear upper plate of the defrost air passage plate 24, and then the cooling air jet plate 14 is installed on the front plate front side of the defrost air passage plate 24. The defrost air temperature sensor 23 is installed at a predetermined portion of the air passage portion on the rear side of the cooling air passage plate 13, and the defrost return temperature sensor 6 is installed at a predetermined portion of the defrost air passage plate 24. Afterwards, the lower end of the heat insulation box 1 and the defrost water storage tank 10 are connected to each other through a drain pipe 11, and a display shelf 16 is installed inside the freezing showcase 100, and a front opening part is provided. Installed on the exhibition door 17 was configured.

6 is a defrost control circuit diagram of the present invention, as shown therein, after the evaporator fan motor 9 is connected to the power supply terminal, the defrost timer TM is connected to the defrost relay RY1, and the defrost return temperature sensor ( 6) is connected to the defrosting return relay RY2, the defrost air temperature sensor 23 is connected to the solenoid control relay RY4, and the a contact switch RY11 of the relay RY1 is connected to the relay RY2. The b contact switch RY21 is connected to the defrosting / driving auxiliary relay RY3, the a contact switch RY31 of the relay RY3 is connected to the defrosting heater 12, and the defrosting / driving auxiliary relay RY3 is connected. Is connected in common to the first solenoid switch 19 and the second solenoid switch 20 connected in parallel via the a contact switch RY41 of the solenoid control relay RY4. B contact switch RY32 of RY3 is connected to the compressor 2, and b of the relay RY3 is connected. It is constituted by connecting the switch point (RY33) to the condenser fan motor 8, According to this reference to FIG. 5 and FIG. 7 in conjunction with the accompanying action and effect of the present invention is configured to be described in detail as follows.

When power is supplied to the freezing showcase 100, the compressor 2, the condenser fan motor 8, including the evaporator fan motor 9, are driven, and at this time, the compressor 2 operates to cool the evaporator 4 by driving the compressor 2. In this case, the cooled air is circulated in the direction of the arrow in the furnace by the blowing action of the evaporator fan motor 9, the temperature inside the freezing showcase 100 is lowered below a predetermined temperature.

Thereafter, the cooling operation is continued and frost or ice, etc. are attached to the surface of the evaporator 4, whereby the cooling action is hindered. At this time, the frost is attached to the surface of the evaporator 4 to some extent. As soon as the defrost timer TM is operated, the defrost relay RY1 is driven, whereby the a contact switch RY11 of the relay RY1 is short-circuited, but at this time, the temperature around the evaporator 4 remains below a certain temperature. Therefore, the defrosting return temperature sensor 6 maintains the off state, that is, the open state, and the defrosting return relay RY2 also maintains the off state.

Accordingly, the defrosting relay RY1 is supplied with driving power to the defrosting / driving auxiliary relay RY3 through the a contact switch RY11 and the b contact switch RY21 of the defrosting return relay RY2, thereby relaying the relay RY3. And the defrost heater 12 is driven because the a contact switch RY31 of the relay RY3 is shorted, while the b contact switches RY32 and RY33 of the relay RY3 are opened. Since the state is maintained, the compressor 2 and the condenser fan motor 8 are placed in the stopped state.

Therefore, from this time, the air temperature in the refrigerator is gradually increased by the exothermic action of the defrost heater 12, and until the air is raised above a certain temperature, that is, the temperature is adversely affected in the food stored in the refrigerator. Since the defrost air temperature sensor 23 is kept open until the first and second solenoid switches 19 and 20 are not driven, the air is cooled in the evaporator 4 and the cooling air passage plate as described above. And the circulation path of the evaporator fan motor 9 (solid arrow direction in FIG. 4).

Subsequently, the defrosting air temperature sensor 23 operates as soon as the temperature of the circulating air is gradually raised due to the exothermic action of the defrosting heater 12 as time passes, and the solenoid control relay RY4 operates. Driven, thereby driving the first and second solenoid switches 19 and 20, respectively, to move the blowing air cutoff movable piece 22 in the " W " direction, so that the suction air cutoff movable piece 21 is moved. Since the air is moved in the "Z" direction, the defrost air cannot enter the inside of the refrigerator. That is, at this time, since the heated defrost air is circulated only through the air passage below the defrost air passage plate 24, the temperature rise in the freezer showcase 100 is suppressed.

Thereafter, when the temperature inside the freezing showcase 100 is further raised and the defrosting return temperature sensor 6 is short-circuited, the defrosting return relay RY2 is driven thereby, and thus the b contact switch RY21 of the relay RY2 is thereby driven. ) Is opened so that the defrost / driving assistance relay RY3 is turned off.

As a result, the a contact switch RY31 of the defrosting / driving auxiliary relay RY3 is opened to stop the drive of the defrost heater 12, and the b contact switches RY32 and RY33 of the relay RY3. The short circuit causes the compressor 2 and the condenser fan motor 8 to be driven again.

In addition, the switch RY34 of the relay RY3 is opened so that the first and second solenoid switches 19 and 20 are turned off, respectively, so that the blowing air cut-off movable piece 22 moves in the "X" direction. Then, the suction air blocking movable piece 21 is moved in the "Y" direction. That is, since the air is returned to its original position, the air cooled by the driving of the compressor 2 starts to circulate in the direction of the solid arrow in FIG. 4 so that the temperature in the refrigerator is maintained at a temperature below a predetermined constant temperature.

Thereafter, the operation / defrosting operation is repeated as described above, and a time chart thereof is shown in FIG. 7.

As described in detail above, the present invention can prevent the temperature in the refrigerator from being raised unnecessarily by reliably blocking the hot air supplied to the inside of the refrigeration showcase by using the solenoid switch at the end of the defrosting operation. It is effective to keep it to the maximum.

Claims (3)

After fixing the defrost air passage plate 24 having a predetermined gap on the upper part of the evaporator cover 18, the movable piece 21 for intake air blocking in the lower part before and behind the defrost air passage plate 24 is blown off. First and second solenoid switches 19 and 20 each equipped with an air shutoff movable piece 22 are respectively installed, and a defrost return temperature sensor 6 installed inside the defrost air passage plate 24 and cooling. The driving of the first and second solenoid switches 19 and 20 is controlled according to the sensed temperature by the defrost air temperature sensor 23 installed in the air passage plate 13, whereby the movable air blocking piece (21), the blowing air blocking movable piece 22 is opened or shielded so that the defrost air is circulated through the inside of the freezing showcase 100 or circulated only through the air passage below the defrost air passage plate 24. Defrosting apparatus of refrigeration showcase. The control circuit of the first and second solenoid switches 19 and 20 includes a defrost air temperature sensor 23 installed at a predetermined portion of the air passage portion of the rear side of the cooling air passage plate 13 to provide a solenoid control relay. The first solenoid switch 19 and the second solenoid switch (connected to RY4) and connected in parallel with the switch RY34 of the defrosting / driving assistance relay RY3 through the switch RY41 of the solenoid control relay RY4. A defrosting apparatus for a refrigerated showcase, characterized in that it is connected in common to 20). In the defrosting method of the refrigeration open showcase, the first step of starting the defrosting operation of the evaporator by using a heating means and stopping the cooling operation when the defrosting time is reached after the cooling operation is started, and the defrosting operation is started. After the defrost air temperature sensor detects that the internal temperature rises above a certain value, and at this time, it blocks the air flowing into the interior from the outside by using a solenoid and blocks the inflow of heated air into the interior. After the defrosting operation is started, the defrosting air temperature sensor detects that the defrosting air temperature around the defrosting air passage plate is raised above a predetermined temperature by stopping the driving of the heating means. It takes in air, resumes cooling operation, cools the external air that has flowed in and circulates it back The defrosting method of the frozen showcase comprising a third step of making.