KR101097976B1 - A method for controlling an operation of refrigerators - Google Patents

Abstract

The present invention relates to a refrigerator operation control method, comprising an inverter-type compressor to drive a compressor according to a signal for a temperature detected from a freezer compartment sensor (FS), and when the freezer compartment temperature is higher than a preset temperature, the freezer compartment sensor does this. A refrigerator operation control method of driving a compressor to sense and output a signal, and to lower the freezer temperature to a preset temperature in response to the signal, wherein a signal regarding the compressor driving temperature from a sensor detecting the freezer compressor driving temperature is generated. When the compressor is not started in response to the signal, the compressor waits for a preset time for cooling the compressor, and again checks whether the compressor is started after the elapse of time for cooling the compressor and checks the number of times the compressor has failed to start. Accumulate and refrigerate when the number of start-up failures of the compressor reaches a preset number It is configured to stop the high system, thereby preventing the performance degradation of the compressor due to excessive operation of the conventional compressor and to prevent the occurrence of fire, and also when the inverter is used automatically against the starting failure according to the temperature conditions of the compressor It can be easily recovered to improve the reliability of the product.

How to control refrigerator operation

Description

A METHOD FOR CONTROLLING AN OPERATION OF REFRIGERATORS}

       1 is an operation flowchart showing a driving control method according to the present invention.

The present invention relates to a refrigerator operation control method, and more particularly, to a refrigerator operation control method for controlling a compressor operation to be suitable for the load condition and startup state of the refrigerator during home refrigerator startup and operation.

In general, the cooling cycle of the refrigerator is adiabatic compression of the refrigerant by the compressor to release the heat through the condenser and capillary tube at a high pressure, liquefied and liquefied, then evaporated in the evaporator to cool the surrounding air, the cooled Consists of circulating air.

Conventionally, a refrigerator compressor is driven to cool when it is higher than a set temperature in response to a signal from a temperature sensor of a freezer compartment and a refrigerator compartment, and an induction motor is mainly used to drive such a compressor. The torque is large, but the rotational speed of the compressor driving motor can not be optimally changed according to the load of the refrigerator, and thus the refrigerator starting efficiency is not good.

On the other hand, in order to optimize the operation of the compressor according to the load variation of the refrigerator, an inverter is used to control the rotation speed of the compressor variably according to the load of the refrigerator to improve the starting efficiency of the refrigerator.

However, in the case of controlling the compressor driving motor using the inverter in this way, for example, the compressor may not start if the starting force is smaller than the pressure difference between the high pressure side and the low pressure side of the compressor. If there is a problem that can cause damage and fire of the compressor.

Accordingly, an object of the present invention is to provide a refrigerator operating method for controlling the compressor in accordance with the refrigerator load condition and the startup state by solving the problems caused during startup and normal operation of the refrigerator in a refrigerator using a conventional inverter compressor. .

Refrigerator operation control method of the present invention for achieving the above object is provided with an inverter-type compressor to drive the compressor according to the signal for the temperature detected from the freezer compartment sensor (FS), when the freezer compartment temperature is higher than the preset temperature The freezer sensor detects this, outputs a signal, and responds to the signal to control the refrigerator operation to lower the freezer temperature to a predetermined temperature. When the compressor does not start in response to the signal, the controller waits for a preset time for cooling the compressor, and again checks whether the compressor is started after the time for cooling the compressor, The number of start failures of It is configured to stop the refrigerator system if it is done.

In addition, when the start of the compressor fails, a preset short-term compressor start-up failure number for confirming the compressor start-up failure after a relatively short time wait is accumulated, and the accumulated short-term compressor start-up failure count reaches a preset number. In this case, after the preset relatively long time waiting period, the long-term compressor start failure count is accumulated, and when the accumulated long-term compressor start failure count reaches a preset number, the operation of the refrigerator driving system is terminated.

Hereinafter, with reference to the accompanying drawings showing an embodiment of the present invention will be described in detail the present invention.

1 is a view illustrating a refrigerator operating method through a compressor control according to a load condition of a refrigerator according to the present invention. In the flowchart of the refrigerator operating method of FIG. 1, the compressor of the refrigerator operates according to a signal for a temperature detected from the freezer compartment sensor FS. When the freezer compartment temperature is higher than a preset temperature, the freezer compartment sensor detects this signal. In step (1), the compressor is driven in response to the signal (step 2) to supply the refrigerant to the freezer compartment evaporator to lower the temperature of the freezer compartment.

The compressor starts running at 3000 rpm until the initial 10 seconds (steps 3 and 4), and then determines whether the freezer temperature detected by the freezer sensor in step 5 is higher than 3.5 ° C. above the temperature at which the compressor needs to be driven. If the temperature is higher than 3.5 ° C, the compressor driving speed is increased to 3600 rpm (step 6) to quickly lower the temperature of the freezer to a predetermined temperature, and when the temperature of the freezer reaches a predetermined temperature, the freezer temperature sensor is turned off (step 7 The compressor is then turned off (step 8).

In step 5, when the temperature detected by the freezer compartment sensor is higher than the preset compressor drive temperature within 3.5 ° C, the compressor drive speed is maintained at 3000 rpm (step 9), and the freezer compartment temperature of the refrigerator is set to a predetermined temperature. Once reached, the freezer sensor and compressor are turned off (steps 7, 8).

However, there is a case where the compressor does not start even though a signal for the compressor driving temperature from the freezer sensor is generated, which is higher than the pressure difference between the relatively high pressure side of the condenser side connected to the compressor and the relatively low pressure side of the evaporator side. It occurs when the driving force of the motor driving the compressor is small, for example, when the temperature of the compressor itself is increased, the pressure on the condenser side increases, and thus, when the pressure difference between the low pressure side on the evaporator side is excessive, the compressor It will not start.

In the case where the compressor is not driven in step 2 even though the freezer sensor generates a signal for the compressor driving temperature, a short time (for example, 5 minutes) during which the compressor is cooled by the cooling fan in the refrigerator machine room is usually used. After the elapsed time (step 10), in step 11, the short-term compressor start failure count (N) is accumulated by one.

In this case, if the compressor is not driven despite the signal from the freezer sensor due to excessive pressure difference on the high / low pressure side of the compressor due to excessive temperature rise of the compressor, a short time (for example, 5 minutes) for the cooling of the compressor is required. After the elapsed time, the compressor start failure count (N) is counted and the compressor is started. When the short run time (N) of these short compressors reaches six times, six short-term compressor start failures occur after at least 90 minutes. Steps 2, 10, and 11 are repeated until (N) becomes 6, and if there is a time elapse of 90 minutes, the number of long-term start-up failures T is counted.

That is, after the compressor driving signal of the freezer compartment sensor is generated, the number of long-term start failures T is checked (step 12). If T is not 3 in the step 12, the number of short-term compressor start-up failures (N) is checked (step 13). If N is not 6, the compressor is started within 5 minutes by checking whether the compressor operation is started in step 2. If it is not driven, the process of checking whether the compressor is not driven until N is 6 is repeated by adding 1 to the short-term compressor start failure number N (step 13). In step 13, if the short-term compressor start failure count N reaches 6, wait until 90 minutes have elapsed (step 14), and then add 1 to the long-term start-up failure number T and reset N to 0 (step). 15) If the long-term start-up failure number T is three, it is determined that the failure of the compressor is not caused by a pressure difference on the low / high pressure side due to an excessive temperature rise of the compressor, but a problem of another refrigerator system. The entire system is stopped and the user is informed of the need for after-sales service by the manufacturer with an alarm light or alarm signal (step 16).

As such, when an excessive pressure difference occurs due to a rise in the temperature of the compressor, the compression efficiency of the compressor is lowered. Nevertheless, if the compressor continues to operate as in the conventional refrigerator, the compressor may be overheated and a fire may occur. In accordance with the present invention, the process of steps 2, 10-16 is waited until the compressor is cooled, and then restarted, thereby preventing the compressor from deteriorating and improving the problems such as a fire caused by excessive driving.

According to the present invention, when an inverter is used, the refrigerator is automatically controlled so that the compressor can be cooled when the compressor is not started when an excessive pressure difference between the high pressure side and the low pressure side occurs due to excessive temperature rise of the compressor. If the compressor is not started due to other factors, the user can receive after-sales service to prevent the compressor from deteriorating due to excessive operation of the conventional compressor and to prevent the occurrence of fire. There is an advantage to improve the reliability of the product by being able to automatically and easily recover from the startup failure.

Claims (2)

It is equipped with an inverter compressor to drive the compressor according to the signal for the temperature detected from the freezer compartment sensor (FS), and when the freezer compartment temperature is higher than the preset temperature, the freezer compartment sensor detects this and outputs a signal, and responds to the signal. In the refrigerator operation control method for driving the compressor to lower the freezer temperature to a predetermined temperature, When a signal for the compressor drive temperature from the sensor for detecting the freezer compressor drive temperature is generated, if the compressor is not started in response to the signal, the compressor waits for a predetermined time for cooling the compressor, and After the elapse of time, check whether the compressor is started again, accumulate the number of failed startups of the compressor, and stop the refrigerator system when the number of failed startups of the compressor reaches a preset number of times. When the start of the compressor fails, when the predetermined number of short-term compressor start failures confirming the compressor start failure after a relatively short time wait, the accumulated short-term compressor start failure times reaches a preset number of times. And accumulating the long-term compressor startup failure count after a preset long-term waiting time, and terminating the refrigerator driving system when the accumulated long-term compressor startup failure number reaches a preset number. Operation control method. delete

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