KR100488900B1 - Method for controlling defrost period of the refrigerator - Google Patents

Abstract

The present invention relates to a control method of a refrigerator defrost cycle, in particular, the control method of the present invention enters into a variable defrost mode when the compressor integration operation rate of the refrigerator exceeds a reference value for a predetermined time and is measured by a room temperature sensor of the refrigerator. It is determined whether the measured temperature exceeds the first temperature range, and when the measured temperature exceeds the first temperature range, the period for driving the defrost heater of the refrigerator is changed to the first period to operate the defrost heater, while the measured temperature If the temperature does not exceed the first temperature range is determined whether the measured temperature exceeds the second temperature range, if the measured temperature exceeds the second temperature range by changing the cycle of the defrost heater to the second period to operate the defrost heater, When the measured temperature does not exceed the second temperature range, the cycle of the defrost heater is changed to the third cycle to operate the defrost heater. Therefore, the present invention is to adjust the defrost cycle of the defrost heater in accordance with the refrigerator ambient temperature and the compressor operation rate or time of the refrigerator by varying the energy consumption generated by unnecessary defrost operation compared to the refrigerator which performs the defrost operation at regular intervals as before. You can save.

Description

TECHNICAL FOR CONTROLLING DEFROST PERIOD OF THE REFRIGERATOR}

The present invention relates to a method of controlling a refrigerator defrost cycle, and more particularly, to a method of controlling a refrigerator defrost cycle in which the defrost cycle varies according to the ambient temperature of the refrigerator and the operation rate of the refrigerator.

In general, a refrigerator is a device for storing food for a long time using the principle of latent heat of vaporization (vaporization heat) in which a liquid refrigerant phase changes into a gaseous state and takes heat from the surroundings. That is, the refrigerator generates cold air and supplies the cold air to the freezer compartment and the refrigerating compartment to maintain the inside of the refrigerator at a constant low temperature state.

The refrigerator structure includes a freezing compartment and a refrigerating compartment which are separated from each other to prevent cold air mixing. A cooling fan is provided on the rear wall of the freezer compartment and the refrigerating compartment, a cooler (evaporator) is installed on the rear wall and the main body, and a compressor is provided on the lower side of the refrigerator.

On the other hand, the refrigerator is provided with a defrost heater for melting ice, frost, etc. generated in the cooler. The defrost heater functions to maintain a stable state of cooling performance by generating heat at regular intervals to remove frost and the like attached to the surface of the cooler.

However, the refrigerator according to the prior art operates the defrost heater at regular intervals regardless of the ambient temperature of the refrigerator, and there is a problem in that unnecessary energy consumption occurs due to defrosting functions formed at regular intervals even if frost, ice, or frost does not occur in the cooler. there was.

An object of the present invention is to solve the problems of the prior art as described above by controlling the defrosting cycle of the defrost heater in accordance with the ambient temperature of the refrigerator and the compressor operation rate or time of the refrigerator, or by controlling the constant energy generated by unnecessary defrosting operation It is to provide a control method of the defrosting cycle of the refrigerator to save the consumption.

In order to achieve the above object, the present invention provides a method of controlling a defrost cycle of a refrigerator, the method comprising: determining whether a compressor integration operation rate of a refrigerator exceeds a reference value for a preset time, and a reference value for a compressor integration operation rate for a preset time When entering the variable defrost mode, determining whether the temperature measured by the room temperature sensor of the refrigerator exceeds the first temperature range, and if the measured temperature exceeds the first temperature range of the refrigerator Operating the defrost heater by varying a period for driving the defrost heater to a first period, determining whether the measured temperature exceeds the second temperature range when the measured temperature does not exceed the first temperature range, and the measured Operating the defrost heater by varying the period of the defrost heater to a second period when the temperature exceeds the second temperature range, and measured And operating the defrost heater by varying a cycle of the defrost heater to a third cycle when the temperature does not exceed the second temperature range.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a configuration diagram of a refrigerator for explaining a method of controlling a refrigerator defrost cycle according to the present invention. Referring to FIG. 1, a refrigerator to which a control method of the present invention is applied includes a room temperature sensor (RT-S) 10 that senses ambient room temperature, and a first driving signal for controlling a temperature inside a refrigerator (for driving a defrost heater). ) And a microprocessor 20 for outputting a second drive signal (for driving a compressor), a compressor 70 for supplying a high-temperature, high-pressure gaseous refrigerant, and a refrigerant of the compressor 70 to a condenser and a capillary tube (not shown). A cooler (not shown) for keeping the internal temperature at a low temperature by evaporating the refrigerant in a low temperature low pressure liquid state, a defrost heater 60 for melting ice, frost, etc. generated in the cooler, and a defrost heater ( The first driving part 40 and the second driving part 50 which drive the 60 and the compressor 70, respectively, are comprised. And the refrigerator according to the present invention is provided with a timer 30 for counting a predetermined time set in the microprocessor 20.

2 is a flowchart illustrating a method of controlling a refrigerator defrost cycle according to the present invention. 1 and 2, the control method of the refrigerator defrost cycle according to an embodiment of the present invention is as follows.

First, the microprocessor 20 of the refrigerator determines whether the integration operation rate of the compressor 70 driven by the second driver 50 exceeds a reference value for a predetermined time. (S10) For example, the compressor 70 It is judged if the integration operation ratio of) exceeds 45% for 2 hours. At this time, the set time (for example, 2 hours) is counted through the timer 30 and the microprocessor 20 calculates the integration operation rate of the compressor 70 based on the counted time.

As a result of the determination in S10, when the integration operation rate of the compressor 70 exceeds the above range, the microprocessor 20 enters the variable defrost mode, which is a control routine according to the present invention, and variably controls the refrigerator defrost cycle.

The microprocessor 20 determines whether the temperature measured by the RT-S 10, which is an indoor temperature sensor, is equal to or less than a first temperature range (eg, 15 ° C.). When the measured temperature is less than the first temperature range, the microprocessor 20 changes the cycle of the defrost heater 60 to the first driver 40 in the first cycle (DCT: Defrost Cycle Time) (for example, 20 hours). The defrost heater 60 is controlled to operate in the first cycle by transmitting the control signal. (S12 to S14)

As a result of the determination in S12, when the measured temperature of the RT-S 10 exceeds the first temperature range, the microprocessor 20 determines whether the measured temperature is less than or equal to the second temperature range (eg, 25 ° C.). When the measured temperature is less than or equal to the second temperature range, the microprocessor 20 transmits a signal in which the period of the defrost heater 60 is changed to the second period (for example, 16 hours) to the first driving unit 40 to defrost heater 60. ) Is controlled to operate in the second cycle. (S16 to S18)

In addition, as a result of the determination in S16, when the measured temperature of the RT-S 10 exceeds the second temperature range, the microprocessor 20 determines whether the measured temperature is less than or equal to the third temperature range (eg, 32 ° C). If the measured temperature is less than or equal to the third temperature range, the microprocessor 20 transmits a signal in which the cycle of the defrost heater 60 is changed to a third cycle (for example, 12 hours) to the first driving unit 40 to defrost heater 60. ) Is controlled to operate in the third cycle. (S20 to S22)

On the contrary, as a result of the determination of S20, when the measured temperature of the RT-S 10 exceeds the third temperature range, the microprocessor 20 changes the cycle of the defrost heater 60 to a fourth cycle (for example, 10 hours). The defrosting period of the defrost heater 60 is controlled by transmitting to the first driving unit 40. (S24)

On the other hand, if the integrated operation rate of the compressor 70 does not exceed the reference value for a predetermined time, the microprocessor 20 determines the total accumulated time of operation of the compressor 70 counted by the timer 30. It is determined whether the time exceeds 100 hours. When the cumulative operation time of the compressor 70 exceeds the time, the microprocessor 20 enters a defrost mode having a certain period and controls the defrost cycle of the defrost heater 60 as before. On the other hand, when the total cumulative time does not exceed the preset time, the microprocessor 20 enters the variable defrost mode according to the present invention and variably controls the defrost cycle of the defrost heater 60 as described above. S30)

Meanwhile, after the defrost heater 60 is operated by varying the cycle of the defrost heater 60 to the first cycle, the second cycle, or the third cycle (S14, S18, S22, S24), the microprocessor 20 performs a compressor ( It is determined whether the accumulated operation time of 70 exceeds the time of the variable period (S26). If the time exceeds the variable period, the microprocessor 20 enters the normal defrost mode in which the period of the defrost heater 60 is constant. By controlling the defrost heater 60 at a constant defrost cycle (S30) through the first driving unit 40, otherwise proceeds repeatedly from the initial stage.

Therefore, in the present invention, the lower the ambient temperature of the refrigerator measured by the room temperature sensor RT-S (10), the less moisture is introduced into the refrigerator, so less defrost occurs in the defrost heater (60). Press and hold. On the other hand, the higher the ambient temperature of the refrigerator, the greater the moisture inflow of the refrigerator, so much defrost occurs in the defrost heater 60, so that the defrost cycle of the defrost heater 60 is shortened to remove the defrost.

As described above, according to the present invention, the defrosting operation of the defrosting heater is variably adjusted or controlled at regular intervals according to the ambient temperature of the refrigerator and the compressor operation rate or time of the refrigerator. The energy consumption generated through the effect can be saved.

On the other hand, the present invention is not limited to the above-described embodiment, various modifications are possible by those skilled in the art within the spirit and scope of the present invention described in the claims to be described later.

1 is a configuration diagram of a refrigerator for explaining a method of controlling a refrigerator defrost cycle according to the present invention;

2 is a flowchart illustrating a method of controlling a refrigerator defrost cycle according to the present invention.

<Description of the code | symbol about the principal part of drawing>

10: RT-S (Room Temperature Sensor) 20: Microprocessor

30: timer 40: first drive unit

50: second drive unit 60: defrost heater

70: compressor

Claims (3)

In the method of controlling the defrost cycle of the refrigerator, Determining whether a compressor integration operation rate of the refrigerator exceeds a reference value for a preset time; Entering a variable defrost mode when the compressor integration operation rate exceeds a reference value for a preset time; Determining whether a temperature measured by an indoor temperature sensor of the refrigerator exceeds a first temperature range; Operating the defrost heater by varying a period for driving the defrost heater of the refrigerator to a first period when the measured temperature exceeds the first temperature range; Determining whether the measured temperature exceeds a second temperature range when the measured temperature does not exceed a first temperature range; Operating the defrost heater by varying a period of the defrost heater to a second period when the measured temperature exceeds a second temperature range; And And operating the defrost heater by changing the cycle of the defrost heater to a third cycle when the measured temperature does not exceed the second temperature range. The method of claim 1, further comprising: determining whether the total cumulative compressor operation time exceeds a predetermined time when the compressor integration operation rate does not exceed a reference value for a predetermined time, and wherein the total cumulative time exceeds a predetermined time. If the cycle of the defrost heater enters a constant normal defrost mode, otherwise the control method of the refrigerator defrost cycle further comprises the step of entering the variable defrost mode. The method of claim 1, wherein after the step of operating the defrost heater by varying a cycle of the defrost heater to a first cycle, a second cycle, or a third cycle, determining whether the accumulated compressor operation time exceeds the time of the variable cycle. And if the period of time exceeds the time, the cycle of the defrost heater enters a constant general defrost mode. Otherwise, the control method of the refrigerator defrost cycle further comprises repeating the process from the initial stage. .