KR20040057156A - Defrosting control method for refrigerator - Google Patents

Abstract

PURPOSE: A defrosting control method of a refrigerator is provided to restrict unnecessary consumption of power by applying the long-time defrosting period in not detecting opening of the door, and to prevent increase of internal temperature of the refrigerator by calculating the optimal defrosting period according to the opening time of the door. CONSTITUTION: A control unit checks opening of a door of a refrigerator through a door switch, and counts opening time of the door for the refrigerator or the freezer compartment(200,203). The defrosting period is calculated by the control unit(206), and a defrosting heater is operated by a defrosting heater driving unit. If detected temperature of the defrosting sensor reaches the defrosting end temperature, the control unit outputs the stop signal to the defrosting heater driving unit to stop the defrosting heater(215). The control unit compares the accumulated freezing operation time with the defrosting period, and the defrosting heater operates if the freezing operation time reaches the reference value(221). The defrosting heater is controlled based on detected temperature of the defrosting sensor(227).

Description

Defrosting control method for refrigerator

The present invention relates to a refrigerator, and more particularly, to a defrosting control method of a refrigerator capable of variably controlling a time point for entering a defrosting operation according to a user's door opening time.

The refrigerator comprises a refrigeration cycle that generates cold air required by the compressor by operating the compressor and the fan until the internal temperature reaches the target temperature by comparing the internal temperature with the target temperature, and by operating the refrigeration cycle for a predetermined time. It is operated by the defrost cycle according to the drive of the defrost heater to remove frost formed on the evaporator.

As shown in FIG. 1, the defrosting operation for driving the defrost cycle is conventionally performed after a predetermined time elapses. That is, in the defrosting operation of the refrigerator, the defrosting heater is operated when the driving time according to the operation of the compressor is integrated (step 100), and when the operation time of the compressor accumulated in the 100th step satisfies a predetermined time set. While performing the defrosting operation (step 110).

The operation of the defrost heater according to step 110 is maintained until the sensing temperature of the defrost sensor reaches a predetermined value. When the temperature detected by the defrost sensor reaches a predetermined temperature (step 120), the operation of the defrost heater is switched off (step 130).

Then, the refrigeration cycle is driven again by the operation of the compressor.

As described above, the defrosting operation of the conventional refrigerator is performed only after the operation time of the compressor according to the operation of the refrigeration cycle satisfies a predetermined time. Therefore, in the conventional refrigerator, since the defrost heater operates irrespective of a use operation such as opening the door of the refrigerator, there is a problem in that sometimes the excessive heat generation state is sometimes not achieved in the defrost state.

Accordingly, an object of the present invention is to provide a defrost control method of a refrigerator for variably controlling a defrost cycle by detecting a refrigerator door opening time deeply related to the concept of evaporator in a refrigerator.

1 is an operation flowchart for defrost control of a conventional refrigerator;

2 is a defrost control configuration diagram in the refrigerator according to the present invention;

3 is an operation flowchart for the defrost control in the refrigerator according to the present invention.

Explanation of symbols on the main parts of the drawings

10 defrost sensor 20 door switch

30: memory 40: control unit

50: defrost heater driving unit 60: compressor driving unit

Defrost control method of the refrigerator according to the present invention for achieving the above object, the counting step of counting the refrigerator door opening time; A variable step of varying a defrost cycle by applying the counted door open time to a predetermined reference defrost time; When the compressor is driven by the variable defrost cycle, it comprises a control step of controlling the defrost operation.

The present invention further includes a sensing step of detecting whether a refrigerator door is opened, and when there is no refrigerator door open in the sensing step, when the compressor is driven for a predetermined reference defrost time, the defrosting operation is controlled. .

The counting step and the variable step are characterized in that the variable step changes in conjunction with the change of the counting step.

The variable step is characterized in that the defrost cycle is changed by further applying a specific coefficient to the door opening time.

Hereinafter, a defrosting control method of a refrigerator according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a control block diagram for controlling the defrost in the refrigerator according to the present invention.

The refrigerator of the present invention includes a door switch 20 for detecting a door opening of the refrigerator. The door switch 20 detects the opening and closing of the door and outputs a signal, and the signal is input to the controller 40. Therefore, the controller 40 detects the time that the door is opened based on the door open signal and the door close signal of the door switch 20.

In addition, the refrigerator of the present invention includes a defrost sensor 10 for detecting a time point for ending the defrosting operation. The defrost sensor 10 detects an evaporator temperature (evaporator pipe temperature), and when the evaporator temperature detected by the defrost sensor 10 reaches a predetermined temperature, the controller 40 determines that the defrosting operation is completed. Therefore, the detection temperature of the defrost sensor 10 is applied to the control unit 40, and the control unit 40 stores a reference temperature for determining the completion time of defrosting.

The defrost heater driving unit 50 for driving the defrost heater for the defrosting operation and the compressor driving unit 60 for driving the compressor for the freezing operation are provided. The defrost heater driving unit 50 and the compressor driving unit 60 are controlled by the control unit 40.

Reference numeral 30 designates a memory. In the present invention, the memory 30 is preset to calculate the reference temperature for determining the completion time of defrosting, the door opening time (P) detected to calculate the defrosting period, the calculated defrosting period, the variable defrosting period Saves various coefficient values such as basic defrost cycle time (T). And a control algorithm for controlling the defrosting operation according to an embodiment of the present invention is stored.

In addition to this, although not shown, for controlling the refrigeration cycle of the refrigerator, a high internal temperature sensor and a high internal fan for supplying cold air are provided.

Next, the defrosting operation control method of the refrigerator according to the present invention having the above configuration will be described in detail.

3 is an operation flowchart for the defrosting operation control of the refrigerator according to the present invention.

When power is supplied to the refrigerator, the controller 40 drives the compressor through the compressor driver 60 for a refrigeration operation according to a preset algorithm so as to generate cool air to be supplied in the refrigerator. The refrigerant compressed at a high temperature and high pressure in the compressor is supplied to the evaporator through a condenser, and the evaporator generates cold air to be supplied to the inside of the air through a heat exchange operation with the air circulating in the air.

The cold air generated in this way is supplied to the freezing chamber through the discharge port, and is provided to the cold air supply flow path side. The cold air provided in the cold air supply passage is supplied to the refrigerating chamber through the discharge port. The cold air supplied to the refrigerating compartment and the freezing compartment takes the heat contained in the food stored in the inside of the refrigerator, and after the temperature is raised, the cold air is fed back to the chamber equipped with the evaporator through the feedback flow path.

Immediately after the power is supplied as described above, after the initial operation for supplying the cold air in the air is made, the controller 40 senses the air temperature inside the high temperature sensor. Then, it is determined whether the detected internal temperature reaches the set temperature (target temperature) that is set.

If the current internal temperature is higher than the target temperature by the determination, the compressor is controlled to be continuously operated through the compressor driving unit 60 so as to continuously generate cold air. That is, in the above process, since the internal temperature does not reach the target temperature, cold air is required, and in this case, the compressor and the fan are controlled in an operating state.

However, according to the determination, when the current internal temperature reaches the target temperature, the control unit 40 controls the compressor driving unit 60 to the stopped state. At this time, since the temperature inside the refrigerator is sufficiently low, the cold air supply in the refrigerator is not required.

As a control process as described above, the control unit 40 operates the refrigeration cycle by operating the compressor driving unit 60 when the cold air supply is required. When the cold air supply is not required, the compressor is controlled to be stopped by the compressor driver 60.

In this way, the refrigeration cycle is driven while controlling the drive of the compressor on / off. The drive of the refrigeration cycle according to the above operation is repeatedly performed based on the high internal temperature, and the drive time of the compressor is continuously accumulated until defrosting operation is performed.

Meanwhile, the controller 40 calculates a variable defrost cycle according to an embodiment of the present invention while the control is performed, and performs control to determine the start point of the defrost operation according to the calculated defrost cycle. The defrost cycle described below is the total operating time of the compressor performed between the defrost operation and the defrost operation. That is, when the compressor operation time corresponding to the calculated defrost cycle reaches, the defrost operation is started.

First, the control unit 40 monitors whether the refrigerator door is opened through the door switch 20 during the freezing operation cycle (step 200), and counts the refrigerating compartment or freezing compartment door opening time P (step 203). ).

When the door opening is detected in step 200 and the door opening time is counted in step 203, the controller 40 calculates a defrost cycle in the current operation (step 206).

In the defrost cycle of step 206, the door opening time P is multiplied by the specific coefficient X based on the experimental value, and then the value is subtracted from the reference defrost cycle time T. The variable defrost period calculated as described above is changed every time the refrigerator door opening time is changed in step 203.

When the refrigeration operation time accumulated by the controller 40 reaches the variable defrost cycle calculated in the step 206, the controller 40 drives the defrost heater driving unit 50 to generate the defrost heater. Step 212).

That is, step 203 is a process of counting the door opening time of the refrigerator which is frequently associated with the conception of the refrigerator, and step 206 is a process of calculating a variable defrost cycle using the door opening time counted at the step 203. . Therefore, the variable of step 203 is directly connected to the variable of step 206.

The defrost heater driven in the second step 212 continuously generates heat until the evaporator temperature detected through the defrost sensor 10 reaches the defrost completion temperature. When the sensing temperature of the defrost sensor 10 reaches the defrost completion temperature, the defrost heater is stopped while the control unit 40 outputs a stop signal to the defrost heater driving unit 50 (step 215).

On the other hand, when the door opening of the refrigerator is not detected in step 200, the controller 40 determines whether the accumulated accumulated freezing operation time (step 218) reaches the defrost cycle time T set as a reference. When the freezing operation time reaches the reference defrost cycle time (T), the defrost heater generates heat (step 221).

The defrost cycle time T set in the step 221 is set to a relatively long time compared with the time set in the past. Therefore, frequent defrosting operation is prevented in a state where an operation such as opening of a refrigerator is not performed.

The defrost heater operated in the step 221 is controlled based on the detected temperature of the defrost sensor 10 (steps 224 and 227).

As described above, the defrosting control method of the refrigerator according to the present invention checks the door opening time of the refrigerator in consideration of the fact that when the door of the refrigerator is in the open state, internal humidification occurs as the external humid air enters the inside of the refrigerator. It is characterized in that the direct connection to the defrost cycle.

The defrosting control method of the refrigerator according to the present invention described above suppresses the generation of power consumption due to unnecessary defrosting operation by applying a long defrosting cycle when the refrigerator door is not opened. In addition, the present invention prevents high temperature rises by suppressing unnecessary defrosting operations.

In addition, the present invention can calculate the optimum defrosting cycle by applying the refrigerator door opening time directly associated with the in-frost implantation to the defrosting cycle.

Claims (4)

Counting the refrigerator door opening time; A variable step of varying a defrost cycle by applying the counted door open time to a predetermined reference defrost time; If the compressor is driven by the variable defrost period, the defrost control method of the refrigerator comprising a control step of controlling the defrost operation. The method of claim 1, Further comprising a detection step of detecting whether the refrigerator door has been opened, When the compressor is driven for a predetermined reference defrost time when there is no opening of the refrigerator door in the sensing step, the defrosting control method of the refrigerator, characterized in that for controlling the defrosting operation. The method according to claim 1 or 2, The counting step and the variable step, the defrosting control method of the refrigerator, characterized in that the variable step changes in conjunction with the change in the counting step. The method of claim 3, wherein In the variable step, the defrosting control method of the refrigerator, characterized in that for changing the defrost cycle by further applying a specific coefficient to the door opening time.