KR100237705B1 - Control method of operating for a refrigerator - Google Patents

Abstract

The present invention relates to a defrosting operation control method of a refrigerator to perform defrosting by using a blowing fan when the defrost heater is disconnected.

The constitution is a defrosting operation control method of a refrigerator for removing frost formed on an evaporator, wherein if it is determined that the defrosting operation starting condition is determined in the defrosting operation starting step of determining whether the defrosting operation start condition is satisfied, Defrost heater energization step of energizing the defrost heater provided for the purpose of removing the frost formed on the evaporator, evaporator temperature detection step of detecting the temperature of the evaporator after a predetermined time when the defrost heater is energized, the evaporator temperature detection If it is determined that the temperature detected in the step has not reached the preset temperature, the defrost heater is determined to be disconnected, and the blowing fan driving step of driving the blower fan installed for the purpose of circulating the high internal air is performed. Defrost completion reference temperature preset by detecting the temperature of the evaporator every cycle When the defrosting completion step of comparing and the defrosting decision step is determined that the temperature of the evaporator reaches a preset defrosting completion reference temperature, the refrigeration cycle operation of turning off the blower fan and driving the compressor to return to the normal refrigeration cycle operation. Characterized in that it comprises a step.

Description

Defrost operation control method of the refrigerator

The present invention relates to a method for controlling a defrosting operation of a refrigerator, and more particularly, to a method for controlling a defrosting operation of a refrigerator, which enables defrosting by using a blowing fan when the defrost heater is disconnected.

In general, the refrigerator utilizes the principle of latent heat of evaporation (heat of vaporization) in which a liquid refrigerant phase changes into a gaseous state and takes heat from the surroundings, which is performed in an evaporator provided in a storage compartment. In other words, the liquid refrigerant phase-changed while passing through the compressor, the condenser, and the capillary tube starts to evaporate to a low temperature as it enters the evaporator, thereby absorbing heat in the storage compartment and cooling the storage compartment. Due to the heat absorption in the evaporator, when the moisture contained in the air in the storage room contacts the surface of the evaporator, freezing occurs. The castle formed by the freezing phenomenon is wrapped around the surface of the evaporator to reduce the heat exchange capacity with the air in the storage compartment to lower the cooling power, the cooling power is lowered, the operating rate of the compressor rises more than necessary.

Therefore, the refrigerator is provided with a defrosting device and a defrosting operation for removing frost formed on the evaporator.

1 is a cross-sectional view showing a cold air flow of a general refrigerator having a defrosting device.

As shown in FIG. 1, the high air inside the refrigerator is cooled by the evaporator 1 and forcedly circulated by the blower fan 2 to the storage space 3. In other words, the evaporator 1 and the blowing fan 2 are installed in the rear wall 5 of the freezing chamber as a structure for this purpose, and the duct 5 for partitioning the storage space 3 is provided. The duct 5 induces a flow of cold air and discharges cold air into the storage space 3 through a plurality of discharge ports 6 installed in place of the duct 5. In addition, the internal air is circulated to the evaporator 1 in which the low pressure is formed by the blowing action of the blowing fan 2.

2 is a flowchart illustrating a defrosting operation of a conventional refrigerator.

As shown in Figure 2, the control unit of the refrigerator performs a compressor operation time integration step of integrating the operation time of the compressor during the operation of the compressor (S1).

In operation S2, the operation time T accumulated in the compressor operation time integration step S1 is read at a predetermined period, and a defrost operation determination step of determining whether the defrost operation condition is performed is compared with a preset operation time Ta (S2).

If it is determined that the accumulated time in the defrosting operation determination step (S2) has passed the preset operating time, the control unit stops the operation of the compressor and performs a heater energizing step of energizing the defrost heater for the purpose of performing the defrosting operation. (S3).

In addition, the control unit performs an evaporator temperature detection step of detecting the temperature of the evaporator every predetermined time during the heater energizing step (S4).

The controller performs a defrosting completion determination step of determining whether defrost is completed by comparing the temperature A detected in the evaporator temperature detection step S4 with a preset defrosting completion temperature B (S5).

When it is determined that the defrost is completed in the defrosting completion step (S5), the control unit performs a defrost heater energization off step of turning off the defrost heater.

In addition, the control unit performs a compressor operation step of circulating the refrigeration cycle normally by driving the compressor which has been stopped again (S7).

Thereafter, the control procedure of the controller is returned to the initial stage.

However, the conventional defrosting operation has the following problems.

That is, when the defrost heater is disconnected, the defrost of the evaporator is defrosted by the surrounding heat. As described above, since the defrosting determination is judged as defrosting only when the temperature of the evaporator reaches a preset temperature, the operation of the compressor is stopped until the defrosting is completed by miscellaneous heat around the evaporator when the defrost heater is disconnected. do. Therefore, in the case of the freezer, the compressor is stopped for 7 to 8 hours, such that all the stored products are melted.

The present invention has been made to solve the above-mentioned problems, the object of the present invention is to detect the energized state of the defrost heater in the defrost step, and if it is determined that the energized state of the defrost heater is defective, defrosting by the blowing fan by driving the blower fan It is to provide a defrosting operation control method of a refrigerator to be made.

Another object of the present invention is that if the defrosting operation is not performed smoothly due to the disconnection of the defrost heater, the defrosting is completed in a relatively short time by performing the defrosting using a blowing fan, so that the stored product can be restarted. It is to provide a defrosting operation control method of a refrigerator to prevent damage.

1 is a cross-sectional view showing a cold air flow of a conventional refrigerator,

2 is a flowchart illustrating a defrosting operation of a conventional refrigerator;

3 is a control block diagram of a refrigerator according to the present invention;

4 is a flowchart illustrating a defrosting operation of the refrigerator according to the present invention.

* Description of the symbols for the main parts of the drawings *

20: control unit 21: power supply

22: temperature setting section 23: high temperature detector

24: evaporator temperature detection unit 25: compressor operation time integration unit

28: blower fan 30: defrost heater

32: compressor

According to one aspect of the present invention, there is provided a defrosting operation control method of a refrigerator for removing frost formed on an evaporator, the defrosting operation starting step of determining whether defrosting operation is started; Defrost heater energizing step of energizing the defrost heater provided for the purpose of removing the frost formed on the evaporator, if it is determined that the defrost operation start condition in the defrost operation start determination step; An evaporator temperature detection step of detecting a temperature of the evaporator after a predetermined time when the defrost heater is energized; A blower fan driving step of driving a blower fan installed for the purpose of circulating high air by determining that the defrost heater is disconnected when it is determined that the temperature detected in the evaporator temperature detection step does not reach a preset temperature; Defrosting completion determination step of detecting the temperature of the evaporator every predetermined period when the blowing fan is driven and compared with a predetermined defrosting completion reference temperature; And a refrigeration cycle operation step of returning to a normal refrigeration cycle operation by turning off the blower fan and driving a compressor when it is determined that the temperature of the evaporator reaches a preset defrost completion reference temperature in the defrosting completion determination step. do.

Hereinafter, one preferred embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a control block diagram of a refrigerator according to the present invention, Figure 4 is a flow chart showing a defrost operation of the refrigerator according to the present invention.

As shown in Figure 3, the main components of the refrigerator according to the present invention, the control unit 20 for controlling the cooling operation and defrosting operation of the refrigerator as a whole, the desired temperature to maintain the temperature in the refrigerator compartment from the user A temperature setting section 22 to be set, an internal temperature detector 23 installed in the refrigerator for detecting a temperature in the refrigerator, a blower fan 28 for forced circulation of cold air generated from an evaporator provided in the refrigerator to generate cold air, Defrost heater 29 for removing frost formed on the evaporator, compressor 32 which forms an element of a refrigeration cycle together with the evaporator, and compressor operation time integrating unit 25 for accumulating the operating time of the compressor 32. And a power supply unit 21 for supplying driving power of the control unit 20.

The blowing fan 28 and the defrost heater 30 and the compressor 32 of the above-described components are controlled by the control unit 20. For this purpose, the blowing fan 28 and the defrost heater 30, and Relay switches RY1, RY2, and RY3 are provided at a power supply stage of the compressor 32, and a fan driver 27 and a defrost heater driver 29 for driving the relay switches RY1, RY2 and RY3, and a compressor. The drive circuit 31 is provided.

Hereinafter, the defrosting operation according to the present invention will be described with reference to the above-described components and FIG. 4.

As shown in FIG. 4, the control unit 20 of the refrigerator performs a compressor operation time integration step of integrating the operation time of the compressor during the operation of the compressor 32 through the compressor operation time integration unit 25 (S41).

In addition, the controller 20 reads the operation time accumulated in the compressor operation time integration step S41 at a predetermined period and performs a defrost operation determination step of determining whether the defrosting operation condition is compared with a preset operation time (S42). .

If it is determined that the accumulated time in the defrosting operation determination step (S42) has passed the preset operating time, the control unit 20 stops the operation of the compressor 32, and defrost heater 30 for the purpose of performing defrosting operation. Perform the heater energizing step of energizing (S43). That is, the controller 20 outputs a control signal to the compressor driving circuit 31 to turn off the relay switch RY3 provided at the power supply terminal of the compressor 32 to cut off the power supply to the compressor 32. In addition, the controller 20 outputs a control signal to the defrost heater driving unit 29 to turn on the relay switch RY2 provided at the power stage of the defrost heater 30 to energize the power supply to the defrost heater 29.

Thereafter, the control unit 20 outputs a control signal to the defrost heater driving unit 29 and simultaneously counts time to determine whether a predetermined time, for example, 30 minutes, has elapsed (S44). .

If it is determined that the predetermined time has elapsed in the predetermined time elapsed determination step (S44), the controller 20 performs an evaporator temperature detection step of detecting the temperature of the evaporator through the evaporator temperature detection unit 24 (S45). .

And the control unit 20 performs a temperature change determination step to determine whether the temperature of the evaporator detected in the evaporator temperature detection step (S45) has risen more than 5 ℃ compared to the temperature detected before defrost heater (S46). The temperature change determination step (S46) is for detecting the energized state of the defrost heater 29, the temperature rise of the evaporator is 5 ℃ due to the energization of the defrost heater 29 when the defrost heater 29 is normally energized. However, if the defrost heater 29 is not energized, that is, when the defrost heater 29 is not heated, the temperature of the evaporator may not rise above 5 ° C. in 30 minutes.

Therefore, when it is determined that the temperature rise is not more than 5 ° C. in the temperature change judging step S46, the control unit 20 performs the fan motor energization start step of performing defrost by driving the blower fan 28. (S47). That is, the control unit 20 outputs a control signal to the fan driving unit 27 to turn on the relay switch RY1 provided at the power stage of the blowing fan 28 to energize the power supply to the blowing fan 28. Let's do it. Therefore, the evaporator is defrosted by the air in the air forcedly circulated by the blower fan 28, which is usually performed in a shorter time than the defrosting caused by natural cooling in the air.

The control unit 20 performs an evaporator temperature sensing step of sensing the temperature of the evaporator at a predetermined cycle through the evaporator temperature detecting unit 24 (S48).

In addition, the control unit 20 performs a defrosting completion step of comparing the evaporator temperature (A) detected in the evaporator temperature detection step (S48) with a preset defrost completion reference temperature (B) (S49).

If the defrost completion determination step (S49) determines that the evaporator temperature detected in the temperature sensing step is greater than a preset defrosting completion reference temperature, the control unit 20 turns off the fan motor energization to turn off the energization of the blower fan 28. Perform the step (S50). However, if it is determined in the defrost completion determination step (S49) that the evaporator temperature (A) detected in the temperature detection step is smaller than a preset defrost completion reference temperature (B), the control unit 20 is the evaporator temperature detection step Rerun

When the fan motor energization off step S50 is completed, the controller 20 outputs a control signal to the compressor driving circuit 31 to turn on the relay switch RY3 provided at the power stage of the compressor 32. In operation S51, a compressor operation step of energizing power to the compressor 32 is performed. Thus, the refrigerator returns to the normal operating state.

In the temperature change determination step S46, when it is determined that the temperature rise of the evaporator is 5 ° C. or more, the controller 20 determines that the energization state of the defrost heater 30 is normal. That is, the control unit 20 performs an evaporator temperature detection step of detecting the evaporator temperature through the evaporator temperature detection unit 24 (S48).

In addition, the control unit 20 performs a defrosting completion step of comparing the evaporator temperature (A) detected in the evaporator temperature detection step (S48) with a preset defrost completion reference temperature (B) (S49).

When the defrost completion determination step (S49) determines that the evaporator temperature (A) detected in the temperature sensing step is larger than the preset defrosting completion reference temperature (B), the control unit 20 turns on the defrost heater 30. The defrost heater de-energization step of turning off the electricity is performed (S50).

However, if it is determined in the defrost completion determination step (S49) that the evaporator temperature (A) detected in the temperature detection step is smaller than a preset defrost completion reference temperature (B), the control unit 20 is the evaporator temperature detection step Rerun

When the defrost heater energization step S50 is completed, the control unit 20 outputs a control signal to the compressor driving circuit 31 to turn on the relay switch RY3 provided at the power stage of the compressor 32. In operation S51, a compressor operation step of energizing power to the compressor 32 is performed. Thus, the refrigerator returns to the normal operating state.

As described in detail above, according to the present invention, when the defrost is not performed due to the poor electricity supply of the defrost heater, the fan may be driven to perform defrost by forced circulation of high air. Therefore, if the defrosting operation is not performed smoothly due to the disconnection of the defrost heater, the defrosting is performed using a blowing fan to complete the defrosting in a relatively short time and to restart the freezing operation, thereby preventing damage to the stored goods. It provides the effect that it can.

Claims (1)

In the defrosting operation control method of the refrigerator for removing frost formed on the evaporator, Defrost operation start determining step of determining whether the defrost operation start condition; Defrost heater energizing step of energizing the defrost heater provided for the purpose of removing the frost formed on the evaporator, if it is determined that the defrost operation start condition in the defrost operation start determination step; An evaporator temperature detection step of detecting a temperature of the evaporator after a predetermined time when the defrost heater is energized; A blower fan driving step of driving a blower fan installed for the purpose of circulating high air by determining that the defrost heater is disconnected when it is determined that the temperature detected in the evaporator temperature detection step does not reach a preset temperature; Defrosting completion determination step of detecting the temperature of the evaporator every predetermined period when the blowing fan is driven and compared with a predetermined defrosting completion reference temperature; And a refrigeration cycle operation step of returning to a normal refrigeration cycle operation by turning off the blower fan and driving a compressor when it is determined that the temperature of the evaporator reaches a preset defrost completion reference temperature in the defrosting completion determination step. Defrost operation control method of the refrigerator.

Images