KR0160449B1 - Defrosting control method of a refrigerator - Google Patents

Abstract

The present invention provides two temperature sensors at a predetermined position separated from each other for the purpose of determining the completion time of defrosting during the defrosting function of the refrigerator, and controls the defrosting operation by comparing the temperature detection values detected by the two sensors. A method and apparatus are disclosed.

The present invention provides a defrost sensor unit comprising a first defrost sensor and a second defrost sensor for detecting the completion of defrosting, a sensor detecting circuit suitable for inputting a temperature measurement value sensed through the plurality of sensors to a microcomputer; A defrosting point arrives in a hardware configuration including a defrost heater installed around a cooler for heating and removing frost formed and a heater driving circuit for applying a heater driving signal to the defrost heater according to a control signal of a microcomputer. Determining whether the defrosting time has been reached in the determining step; energizing the defrost heater; determining whether the temperature detected by the first defrost sensor is equal to or greater than a predetermined limit temperature value; If the temperature detection value of the first defrost sensor exceeds the limit temperature in the step of comparing the defrost sensor with the limit temperature, the defrost heater If the temperature detection value of the first defrost sensor is less than the limit temperature in the step of stopping the energization and comparing the first defrost sensor and the limit temperature, the temperature detection value of the first defrost sensor and the temperature detection of the second defrost sensor Comparing the values, and comparing the temperature detection values of the first defrost sensor and the second defrost sensor, if the difference between the temperature detection values of the two sensors is greater than or equal to a predetermined value, returning to the previous step and continuing energizing the defrost heater. And stopping the energization of the defrost heater in a temperature sensing value comparison step of the first defrost sensor and the second defrost sensor, and returning the control operation of the refrigerator to normal operation. Provides a defrost control method.

Description

Defrost Control Method of Refrigerator

1 is a block diagram illustrating a hardware configuration according to the defrosting control method according to the prior art.

2 is a hardware block diagram for implementing the defrost control method of the present invention.

3 is a view illustrating a mounting position of a temperature sensor according to the present invention.

4 is a flowchart showing a defrost control method of the present invention.

* Explanation of symbols for main parts of the drawings

10: defrost control unit 11: the first defrost sensor

12: second defrost sensor 20: sensor detection circuit

30: microcomputer 40: heater driving circuit

50: Heater A: mounting position of the first defrost sensor

B: Second defrost sensor mounting position 100: Cooler

The present invention relates to a defrosting control method of a refrigerator, and more particularly, two temperature sensors are provided at predetermined positions separated from each other for the purpose of determining the completion time of defrosting during the defrosting function of the refrigerator. The present invention relates to a method of controlling the defrosting operation in preparation of the sensed temperature detection values.

Performing the defrosting control function of the conventional refrigerator is essential to remove frost that forms on the surface of the cooler during the cold air circulation process in the refrigerator. The defrosting point determined in consideration of the refrigerator door opening / closing cycle, the compressor operation rate, and the compressor driving time, etc. When the microcomputer arrives, the defrost heater is energized to melt the frost on the floor.

However, excessive heating of the heater in the cooling system may cause a rise in temperature in the refrigerator and consequently cause problems in the freshness of the refrigerated foods. Therefore, defrosting heaters can be stopped immediately after removing frosted food. It is very important to be able to determine exactly when to complete.

Determination of the completion time of defrosting based on the prior art as exemplified through FIG. 1 is performed by using a temperature sensor (so-called defrosting sensor) mounted at a predetermined position near the cooler of the refrigerator. As the defrosting is progressed after the heater is started, the temperature detected by the defrost sensor rises and the defrost sensor temperature sensing value reaches a predetermined defrost return temperature. Stop defrosting.

On the other hand, in the above defrosting control method as defined through the above, the position where the defrost sensor is mounted during the energization of the heater for defrosting is sensed that the frost is substantially removed and the temperature rises, but the central part of the cooler actually forms the frost. In spite of the large amount, there was a problem that residual ice often occurred, so that the causative factor that lowered the cooling system could not be effectively removed.

Therefore, the present invention provides another defrosting return temperature sensing sensor at a predetermined position on the cooler separate from the conventional defrosting sensor mounting position in addition to the normal defrosting sensor for determining the defrosting completion time in the refrigerator. The purpose is to enable accurate defrost control by performing the judgment.

In order to achieve the object as described above, the present invention is the first defrost sensor which is a temperature sensor sensor is installed at a predetermined position near the cooler for detecting the completion time of defrosting and is mounted at a predetermined position in the central portion on the cooler for detecting the completion of defrosting time. A defrost sensor unit comprising a second defrost sensor, which is another temperature detection sensor, a sensor detection circuit suitable for inputting a temperature measurement value detected through a plurality of sensors in the defrost sensor unit to a microcomputer, which will be described later, and a refrigerator. In a hardware configuration including a defrost heater installed around a cooler for heating and removing frost formed and a heater driving circuit for applying a heater driving signal to the defrost heater according to a control signal of a microcomputer, during a refrigerator normal operation. Determining whether the defrost point has arrived in consideration of various determinant determinants And, if it is determined in the determination step that the defrost time has arrived, the step of energizing the defrost heater, determining whether the temperature detected by the first defrost sensor is more than a predetermined limit temperature value, and the first defrost sensor and the limit When the temperature detection value of the first defrosting sensor exceeds the limit temperature in the step of comparing the temperature, stopping the energization of the defrost heater, and comparing the first defrost sensor and the limit temperature in the step of determining the temperature of the first defrost sensor When the temperature detection value is less than the limit temperature, comparing the temperature detection value of the first defrost sensor and the temperature detection value of the second defrost sensor and comparing the temperature detection values of the first defrost sensor and the second defrost sensor. If the difference between the temperature detection value is equal to or greater than a predetermined set value, returning to the previous step and continuing energizing the defrost heater, and comparing the temperature detection values of the first defrost sensor and the second defrost sensor. The difference does not exceed the set value and provides the predetermined step to stop the energization of the defrost heater, and refrigerators a defrost control method comprising the step of returning to control execution of the refrigerator to normal operation.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to specific features and effects of the present invention.

The hardware configuration for implementing the refrigerator defrosting control method of the present invention with reference to FIGS. 1 and 2 is as follows.

In FIG. 1 and FIG. 2, reference numeral 10 denotes a defrost sensor unit including one or a plurality of temperature sensing sensors for detecting the completion time of defrosting, and 11 denotes a temperature rising due to a heating action when performing a defrosting operation. A conventional defrost sensor (hereinafter referred to as a first defrost sensor) mounted at a predetermined position around the cooler for the purpose of the present invention, 12 is a central portion on the cooler for detecting a temperature change for the same purpose as the first defrost sensor according to the present invention. The second defrost sensor is additionally installed in a predetermined position, 20 is a micro-sensing temperature sensing data (T1) detected through the first defrost sensor and the temperature sensing data (T2) detected through the second defrost sensor to be described later. Sensor detection circuit for inputting to a computer suitably, 30 is a defrost control function implemented by contrasting the general control function of the refrigerator and the two defrost sensor values according to the present invention 40 is a microcomputer in charge of the heater, and the control unit transmits a control signal by energizing a defrost heater, which will be described later, to remove frost on the cooler under control of the microcomputer, or by stopping the heating of the heater when regeneration is completed. It is a drive circuit, 50 is a defrost heater which heats for the purpose of defrosting.

In FIG. 2, the microcomputer 30 determines the defrost time and, when the defrost time arrives, outputs a heater energization signal to the heater driving circuit 40 to apply power to the defrost heater 50 to perform a heating operation. .

In addition, the microcomputer 30 continuously monitors the temperature rise by the heater heating action as described above through the defrosting sensor unit during the defrosting function, and the first defrost sensor detecting temperature value T1 and the predetermined threshold reference temperature value ( Defrost completion time is determined through comparison with Tm) or comparison between the first defrost sensor detection temperature value T1 and the second defrost sensor detection temperature value T2, and outputs a defrost heater control signal accordingly. In charge of.

FIG. 3 is a diagram illustrating a position where the first defrost sensor 11 and the second defrost sensor 12 are mounted adjacent to the refrigerator cooler to implement defrost control according to the present invention.

Referring to FIG. 3, 100 denotes a cooler made of a water pipe, and arrows indicate coolant inlets and coolant outlets, respectively.

In addition, the A position refers to the position where the first defrost sensor is normally mounted, and the B position refers to the position at which the second defrost sensor for temperature sensing is additionally provided at a predetermined position in the center of the cooler.

In general, the degree of frost on the inside of the refrigerator is not the same depending on the location, mainly in the central portion of the cooler is the most severe frost is a site that is likely to cause residual ice even after performing normal defrosting operation.

Thus, defrosting at position B can be considered complete defrosting throughout the cooler.

In addition, as the defrost heater is heated and defrosting is performed during a certain defrosting time, the defrosting is more uniformly, and the difference between the detected temperature values between the first sensor and the second sensor is reduced.

Based on this principle, the present invention derives a difference value between the sensing temperature value of the first defrost sensor and the sensing temperature value of the second defrost sensor and determines whether the defrost is completed in consideration of these values.

As another aspect, in terms of the performance of the cooling system, the degree of frost formation at the center of the cooler is severe, and if the heating operation is continued until the degree of defrosting around the cooler and the degree of defrosting in the center are relatively even, the internal temperature of the cooling system is excessively increased. There is a risk of deterioration of the cooling system.

Therefore, it is necessary to control the energization of the heating by continuously checking whether the measured value of the general defrost temperature sensor is smaller than the temperature value set as the limit standard while considering the variation of the detection value between the two temperature sensors as described above.

An embodiment of the present invention that specifically applies the defrost control principles as described above will be described in detail with reference to FIG. 4.

4 is a flowchart illustrating a defrost control method according to the present invention for easy understanding.

According to the present invention, during normal operation of the refrigerator, the defrosting time is determined in consideration of the driving time and the like in the refrigerator door opening and closing operation and the compressor operation.

In consideration of the above-mentioned defrosting time determination factors, the refrigerator normal operation mode is continued until the defrosting function is started at the time when it is judged that some degree of frost is formed.

When the microprocessor 30 detects that the defrost point has arrived, the defrost heater 80 is energized by applying a heater energization control command via the heater driving circuit 40 to start the heating operation.

On the other hand, the first temperature detection value and the second temperature detection value detected by the first defrost sensor 11 and the second defrost sensor 12 in the defrost sensor unit 10 of the refrigerator microcomputer 30 It is memorized in advance.

As a next step, the first temperature detection value by the first defrost sensor 11 functioning as a conventional defrost sensor is compared with a threshold reference temperature value Tm preset in the microcomputer.

This is to exclude this in consideration of the risk that the heating action through the defrost process can have a substantial effect on the internal temperature.

In the comparison determination step, when it is determined that the heating operation is excessive because the temperature detection value T1 of the first defrost sensor exceeds the threshold reference temperature value Tm, the microcomputer 30 commands to stop the defrost heater energization. And return to normal operation mode of the refrigerator.

However, when it is confirmed in the comparison determination step that the temperature detection value T1 of the first defrost sensor does not exceed the threshold reference temperature value Tm, the process proceeds to the next step and the first defrost sensor temperature detection value T1 and By comparing the second defrost sensor temperature detection value (T2) to derive the difference between the two measurements.

When the temperature difference exceeds a predetermined reference error through the comparison step between the two defrost sensor temperature detection values, defrost is in progress and the degree of defrosting is not yet reported. Control to continue the function.

However, if the temperature difference is less than the predetermined reference setting error in the comparison step, the defrost has advanced considerably and the defrost function has been performed. Therefore, the microcomputer outputs a heater energization stop command to terminate the defrost function and the refrigerator normal operation mode. Execute control to return to.

According to the present invention as described above, in performing the defrosting function according to the conventional method, while comparing the detected temperature of a conventional single defrosting sensor with a preset reference temperature value, it is determined how far the defrosting has progressed and the defrosting is completed. Determination of the time point is provided with another temperature sensor for detecting the defrosting and used as a reference for determining the time of completion of defrosting by comparing the detected temperature values through the two defrosting sensors to realize more accurate defrosting control. An excellent defrosting control method is obtained which makes it possible to make the transition degree more uniform.

In addition, it saves unnecessary defrost power, and has the advantage of minimizing the increase in internal temperature that is inevitably involved in the defrost function.

Claims (2)

Determining a defrosting point during normal operation of the refrigerator, energizing the defrosting heater when it is determined that the defrosting point has arrived in the defrosting point determination step, and detecting the detected temperature value T1 of the first defrosting sensor and the second defrosting sensor. Comparing the subtracted value between the sensed temperature values T2 with a predetermined reference setting error? T and comparing the subtracted value between the temperature detection value of the first defrost sensor and the second defrost sensor with the reference set error. When the set error (ΔT) is exceeded, the method returns to the previous step and continues to maintain the heater energization, and the subtracted value is determined in the step of comparing the temperature detection value of the first defrost sensor and the second defrost sensor with the reference set error comparison step. The defrost control method of the refrigerator comprising the step of stopping the defrost heater is energized when the set error (△ T) or less. The method of claim 1, wherein after the defrost heater is energized, the sensing temperature value T1 of the first defrosting sensor is compared with a predetermined threshold reference temperature value, and the sensing temperature value ( If T1) is greater than or equal to the threshold reference temperature value T1, stopping the defrost heater and returning to the refrigerator normal operation mode, and comparing the detected first defrost sensor detection temperature with the detected temperature value T1 is the limit. The defrosting control method of the refrigerator further comprising transitioning to a comparison step of the first defrosting sensor and the second defrosting sensor temperature detection value if the reference temperature value is less than T1.