KR890000765Y1 - A refrigerator - Google Patents

Abstract

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Description

Operation circuit when defrosting the refrigerator

1 is a conventional refrigerator circuit diagram.

2 is a circuit diagram of the present invention.

3 is a drive circuit diagram of a defrost heater and an electronic valve of the present invention.

4 is a cutaway view of the refrigerator.

* Explanation of symbols for main parts of the drawings

C ₁ , C ₂ , C ₃ , C ₄ : Capillary Tube 1: Fan motor

2: cooler 9: rapid cooler

3: accumulator 4: reverse displacement

7: differential pressure side 6: screwdriver

5: condenser H: heater

8, 10: Electron valve NG: NAND gate circuit

Q ₁ , Q ₂ , Q ₃ : Transistor

The present invention relates to a driving circuit for defrosting a refrigerator.

The cycle of the refrigerator is divided into normal operation, rapid freezing, and defrosting.In the case of defrosting to remove frost and defrost, the cooling cycle stops, which may cause food to be stored for a long time due to the temperature increase in the refrigerator. Maintaining a constant temperature was followed by many practical difficulties.

In view of the above, the present invention is intended to provide an operation circuit for defrosting a refrigerator that can be operated in the same manner as a conventional refrigerator circuit during normal operation and rapid freezing, and can perform a cooling operation simultaneously with a defrosting operation during defrosting. It consists of a refrigeration circuit through an electronic valve and an accumulator between the rapid cooler and the capillary tube so that the electronic valve is controlled by the output of the bimetal switch and the defrost timer.

When described in detail by the accompanying drawings as follows.

1 is a circuit diagram of a conventional refrigerator. In operation of a conventional refrigerator, a compressor (CM), a condenser (5), a dryer (6), a differential pressure valve (7), a capillary tube (C ₁ ), and a capillary tube (C) are shown. ₂ ) -Cooler (2) -Accumulator (3) -Reverse valve (4) -Compressor (CM) drive in this order. At this time, the solenoid valve 8 is cut off and the temperature controller 12 of FIG. The cold air of the cooler 2 is supplied to the quick freezer compartment, the freezer compartment and the refrigerating compartment depending on the temperature.

In addition, if the temperature controller 12 is set at the time of rapid freezing, the compressor (CM)-condenser (5)-dryer (6)-differential pressure valve (7)-capillary tube (C ₁ )-electron valve (8)-capillary tube (C ₃ ) -quick cooler (9) -capillary tube (C ₄ ) -cooler (2) -accumulator (3) -reverse valve (4) -compressor (CM) Is in a conductive state, and the rapid freezing chamber performs rapid freezing by the operation of the rapid cooler (9). Cooling cycle is stopped and only the defrost heater H is driven.

Therefore, in the conventional refrigerator, when the defrost heater H is driven during the operation of the refrigerator, a repetitive operation in which the temperatures of the freezer compartment and the refrigerator compartment are raised due to the stop of the cooling cycle is prevented from deteriorating food stored for a long time. It was not.

2 is a circuit diagram of the present invention condensing the refrigerant through the compressor (CM) and the condenser (5) to evaporate the heat generated during condensation in the brewer (6) and configured to flow through the differential pressure valve (7) 7) it is possible to keep the refrigerant in an equilibrium state.

In addition, the capillary tube (C ₁ ) (C ₂ ) (C ₃ ) (C ₄ ) is configured to control the amount of refrigerant flowing, and the refrigerant flowing in the accumulator 3 through the cooler 2 during normal refrigerator operation. Is accumulated to flow into the compressor (CM) through the reverse side flow (4) flowing in a constant direction to perform the cooling operation, during the rapid freezing capillary tube (C ₃ ) (C ₄ ) in the solenoid (8) consisting of a solenoid It is configured to drive the rapid cooler (9) through the defrosting and connected to the reverse side (4) through the electronic valve (10) and the accumulator (11) between the rapid cooler (9) and the capillary tube (C ₄ ) during defrosting The cooling circuit configured to be driven is configured to be driven.

Reference numeral 1 in the drawings is a fan motor.

3 is a driving circuit diagram of a defrost heater and an electronic valve (valve) of the present invention, in which the output of the bimetal switch S ₂ and the defrost timer output connected and opened according to the temperature are transmitted through a known NAND gate circuit NG. ₁ ) is configured to control (Q ₂ ) (Q ₃ ) so that the heater (H) and the solenoid (8) (10) can be driven through the triac (T ₁ ) (T ₂ ) (T ₃ ). After the quick freezing switch (S ₁ ) is configured to control the electronic valve (8) through the NAND gate circuit (NG) in the inverter (IN).

FIG. 4 is a cutaway view of a general refrigerator, in which the operation of the refrigerator and the rapid freezing of the refrigerator can be normally selected by the temperature controller 12, and the cooler 2 and the quick cooler 9 are shown.

The present invention configured as described above is driven as the same cooling cycle as the circuit of FIG. 1 during the operation and rapid freezing of a conventional refrigerator, but during defrosting, power is applied to the defrost heater H and the fan motor 1 In order to prevent the temperature rise of the freezer compartment, which is a problem during defrosting, while the driving is stopped and the defrosting operation is performed, the rapid cooler 9 is operated to perform the cooling operation with the rapid cooler 9 during defrosting.

Compressor (CM)-Condenser (5)-Dryer (6)-Differential pressure valve (7)-Capillary tube (C ₁ )-Electron valve (8)-Capillary tube (C ₃ )-Rapid cooler (9) )-Electronic valve (10)-Accumulator (11)-Reverse valve (4)-Operates the cooling cycle of the compressor (CM) to operate the defrost heater (H) during defrosting and the fan motor (1) is stopped so that It is to prevent the temperature rise of the freezer compartment even during defrosting by operating the rapid cooler (9) to increase the temperature to perform the cooling action.

As such, in the present invention, it is possible to control the driving of the solenoid valves 8 and 10 at the time of defrosting so that a separate cooling cycle can be operated. The solenoid valves 8 and 10 and the defrost heater H of FIG. Drive as

That is, in FIG. 3, when the power supply Vcc and the defrost timer output through the bimetal switch S ₂ are input to the input terminals 8 and 9 of the NAND gate circuit NG (that is, the defrost operation starts), the input terminal 8 The low potential signal is outputted to the output terminal 10 by the input of the (9), and the low potential signal of the output terminal 10 is input to the input terminals 12 and 13 to the output terminal 11. At the same time to output a high potential signal is applied to the input terminal (5) (6) to output a high potential status signal to the output terminal (4), and the low potential signal of the output terminal 10 is input terminal (2) ) Is applied to output the high potential state signal to the output terminal (3).

At this time, the power supply Vcc is applied to the input terminal 1 of the NAND gate circuit NG by the quick freezing switch S ₁ and then applied through the inverter IN. When the fast freezing is selected, the switch S ₁ is turned off. When it is turned on, the low potential state signal is applied to the input terminal 1, and when the rapid freezing is not selected, the switch S ₁ is turned off and the high potential state signal is applied to the input terminal 1.

As described above, when the power supply Vcc and the defrost timer signal through the bimetal switch S ₂ are applied, the output terminals 11, 4, and 3 of the NAND gate circuit NG are in a high potential state. A signal is output to turn on each transistor Q ₁ , Q ₂ , and Q ₃ to drive the triac T ₁ , T ₂ , and T ₃ so that the heater H and the electromagnetic valve 10 ( Since the power (AC) is applied to 8, the heater H generates heat and the electromagnetic sides 8 and 10 are all opened.

Therefore, the defrosting operation is performed by the heat of the heater H since the electromagnetic sides 8 and 10 are opened and the heater H is energized at the time of defrosting, and the temperature of the freezing chamber is increased by the defrosting operation. By operating the rapid cooler 9 with the opening of the 10, the rapid cooler 9 of the freezer compartment cools and prevents the temperature rise of the refrigerator compartment during defrosting.

After the defrosting operation is completed, when the bimetal switch S ₂ is opened, a low potential state signal is input to the input terminal 9, and a high potential state signal is output to the output terminal 10. At this time, the high potential state signal is an input terminal ( 5) Input to (6) and (12) and (13) to output low-potential status signal to output terminals (4) and (11) and at the same time, it is applied to input terminal (2) but quick freezing switch to input terminal (1) Since (S ₁ ) is turned off and applied as a high potential state signal, the output terminal 3 outputs a low potential state signal.

That is, when defrosting is completed in the state in which rapid freezing is not selected (switch S ₁ is turned off) and the bimetal switch S ₂ is turned off, the output terminals 3 and 4 of the NAND gate circuit NG are turned off. (11) turns off the transistors Q ₁ (Q ₂ ) (Q ₃ ) by outputting a low potential state signal, thereby turning off the triac (T ₁ ) (T ₂ ) (T ₃ ). Therefore, since the power source AC is not input to the H and the electromagnetic sides 8 and 10, the heater H does not generate heat and the electromagnetic sides 8 and 10 are closed.

Therefore, when the defrosting operation is completed, it is possible to perform the same cooling cycle as in the prior art.

However, when the defrosting operation is finished as described above, if the quick freezing switch (S ₁ ) is connected (that is, if the quick freezing is selected) after the power supply (Vcc) through the quick freezing switch (S ₁ ) through the inverter (IN) It is applied to the input terminal (1) at this time, the high potential state signal is applied to the output terminal 10 to the input terminal 2, but the low potential state signal is applied to the input terminal 1 is high The above state signal is output to turn on the transistor Q ₃ .

When the transistor Q ₃ is turned on, the triac T ₃ is turned on to open the electron valve 8 so that rapid cooling operation can be performed during defrosting.

As described above, the present invention operates in the same manner as the conventional cooling cycle during normal operation and rapid freezing of the refrigerator, so that the refrigerator circuit does not need to be greatly changed, and the defrost heater and the cooling cycle can be maintained at the same time during defrosting. Therefore, it is possible to prevent the temperature in the refrigerator from rising during defrosting, and thus it is possible to provide a driving meeting during defrosting of the refrigerator which can be preserved for a long time without deteriorating food.

Claims (1)

In a refrigerator circuit which performs normal operation and rapid freezing, the defrosting timer is configured to be connected between the rapid cooler 9 and the capillary tube C ₄ via the electromagnetic valve 10 and the accumulator 11 and connected to the reverse valve 4. A defrosting heater of the refrigerator configured to control the defrost heater (H) and the electronic valve (8) (10) in the NAND gate circuit (NG) by the output and the status signal of the bimetal switch (S ₂ ).