KR100207090B1 - Refrigerator compressor control method - Google Patents

Abstract

According to the present invention, when the compressor is operated at the maximum rotational speed, if the outside temperature of the refrigerator measured by the microcomputer is higher than the preset outside temperature measured by the outside temperature sensor, the rotational speed of the compressor is maintained at the maximum rotational speed at regular intervals. When the compressor is operated at the minimum rotation speed, if the outside air temperature measured by the microcomputer is lower than the preset outside air temperature when the compressor is operating at the minimum rotation speed, The present invention relates to a method of controlling a compressor of a refrigerator in which the rotation speed is increased from the lowest rotation speed to the highest rotation speed at a predetermined time interval and returned to the lowest rotation speed after a predetermined time elapses.

By the compressor control method of the refrigerator according to the present invention, when the outside air temperature is high, such as summer, prevents overheating of the compressor by the long time operation at the maximum rotational speed of the compressor, when the outside air temperature is low, such as winter It is possible to reduce the decrease in the refrigerant circulation amount due to the operation.

Description

Compressor Control Method of Refrigerator

The present invention relates to a compressor control method of a refrigerator.

Conventional compressor compressor motor of the conventional refrigerator uses a single phase induction motor, single phase induction motor is characterized by constant speed operation. The single-phase induction motor has a constant rotational speed of the motor and cannot vary the rotational speed. Therefore, the compressor of the conventional refrigerator employing a single-phase induction motor has a disadvantage that it is not possible to change the compression capacity to adjust the appropriate compression capacity for various load conditions.

The rotation speed of the compressor motor of the refrigerator has a correlation with the compression ratio of the compressor and the flow of the refrigerant. Therefore, in the conventional variable capacity refrigerator, instead of the conventional single phase induction motor, the compressor motor uses a BLDC (BrushLess DC) motor. BLDC motor is characterized by being able to adjust the rotational speed (RPM) well and adjust the compression capacity of the compressor. The microcomputer of the refrigerator controls the compression capacity of the compressor by controlling the rotational speed of the BLDC motor by data input through various sensors. Hereinafter, a compressor using a BLDC motor will be referred to as a BLDC compressor.

In the conventional variable-capacity refrigerator, when the rotational speed of the BLDC compressor is appropriately changed according to the operating conditions, the BLDC compressor operates at the highest rotational speed and the lowest rotational speed, and has the following problems.

1 is a time chart when a conventional variable capacity refrigerator is operated at maximum or minimum rotation speed. Referring to FIG. 1, when the rotational speed (RPM) of the BLDC compressor motor is maintained at the highest speed for a long time (FIG. 1 (a)), the process of compression, condensation, expansion, and evaporation of the refrigerant is high because This effectively does not make the cooling effect is lowered and the efficiency of the BLDC compressor 60 is reduced. In addition, when the BLDC compressor is operated at the highest rotational speed for a long time, performance deterioration due to overheating of the BLDC compressor occurs.

On the contrary, if the rotational speed of the refrigerator BLDC compressor is maintained at the minimum rotational speed in the cold weather (Fig. 1 (b)), the flow rate of the refrigerant is slowed. When the BLDC compressor is operated at the lowest speed for a long time, the refrigerant circulation amount decreases.

The present invention is to solve the above problems, the rotational speed of the compressor of the refrigerator, in the cold and cold weather, to prevent the reduction of the compression rate and overheating of the compressor that occurs when maintaining the maximum and minimum rotation speed and to reduce the refrigerant circulation amount It is to provide a compressor control method of the refrigerator for reducing.

1 is a time chart of a conventional variable capacity refrigerator.

2 is a block diagram according to the present invention.

3 is a time chart according to the present invention.

4 is a flow chart according to the present invention.

* Explanation of symbols for the main parts of the drawings

10: outside temperature sensor 60: BLDC compressor

70: micom

The present invention for achieving the above object, the sensing step of detecting the rotational speed of the refrigerator compressor and the outside temperature of the refrigerator, the rotation speed determination step of determining whether the rotational speed detected in the sensing step is the set rotational speed of the refrigerator compressor, The set rotation when the outside temperature is out of the range of the outside temperature in the temperature comparison step. The control method of the refrigerator compressor comprising the step of periodically varying the number of revolutions of the compressor driven by the number.

According to the present invention, the microcomputer detects the rotational speed of the refrigerator compressor, and compares the refrigerator outdoor air temperature with the preset maximum outdoor air temperature at that time when the rotational speed is the highest rotational speed. After comparison, if the outside air temperature of the refrigerator is high, the rotation speed of the refrigerator compressor is lowered to the minimum rotation speed at a predetermined time interval and returned to the maximum rotation speed after a predetermined time. When the detected rotation speed is the minimum rotation speed, the microcomputer compares the refrigerator outdoor air temperature with the preset minimum outdoor air temperature. After comparison, if the outside temperature of the refrigerator is low, the rotation speed of the refrigerator compressor is increased to the maximum rotation speed at a predetermined time interval and then returned to the minimum rotation speed after a predetermined time.

Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings.

Referring to FIG. 2, the microcomputer of the refrigerator uses data input from various sensors to control the rotation speed of the BLDC compressor.

Outside temperature sensor 10 for measuring the outside temperature of the refrigerator, freezer temperature sensor 20 for measuring the temperature of the freezer compartment, refrigerating compartment temperature sensor 30 for measuring the temperature of the refrigerator compartment, door for checking the frequency of opening and closing the door Opening and closing detection sensor 40 and the like. The microcomputer 70 of the refrigerator controls the rotation speed (RPM) of the BLDC compressor 60 according to the input from the above-described various sensors and the user input of the refrigerator through the control input unit 50.

If it is determined that the microcomputer 70 is a high load according to various conditions, the microcomputer 70 maintains the rotational speed of the BLDC compressor 60 at the highest rotational speed. The maximum rotational speed of this embodiment is about 3800 RPM, and the above-described operation takes place mainly in the heat wave. When the rotational speed of the BLDC compressor is maintained at the maximum rotational speed, the refrigerant in the refrigerator is circulated smoothly to cool the inside of the refrigerator. However, when the BLDC compressor lasts for a long time at the maximum rotation speed, the flow rate of the refrigerant is high, so that the process of compression, condensation, expansion, and evaporation of the refrigerant is not effectively performed, thereby reducing the cooling effect and improving the efficiency of the BLDC compressor 60. Will fall. In addition, when the BLDC compressor is operated at the highest rotational speed for a long time, performance deterioration due to overheating of the BLDC compressor occurs. Thus, the rotational speed of the BLDC compressor is periodically dropped. The method is as follows.

First, the microcomputer 70 detects the rotation speed N and the outdoor temperature Ta of the BLDC compressor 60 (S100). Since the rotation speed N signal is output from the microcomputer 60 to the BLDC compressor 60, the microcomputer 70 examines the signal output from the microcomputer 70 itself. Then, it is determined whether the detected rotation speed (N) is the highest rotation speed N1 (3800 RPM) (S110). If the outside temperature and high load of the refrigerator is high, the rotation speed N becomes N1 (3800 RPM). Next, the microcomputer 60 compares the outside air temperature Ta of the refrigerator detected by the outside air temperature sensor 10 and the preset outside air threshold upper limit value Tb in the detection step S100 (S120). The outside air threshold upper limit value Tb is the maximum external temperature of the preset refrigerator. If the outside temperature Ta of the refrigerator detected by the microcomputer 60 through the outside temperature sensor 10 in the comparison step (S120) is greater than a preset outside threshold upper limit value (Tb), the BLDC compressor 60 operates in mode 1 ( S150a). As shown in Fig. 3A, the mode 1 operation S150a drives the BLDC compressor 60 at 3800 RPM, which is the highest rotation speed N1. Then, at a predetermined time interval during operation, the speed is lowered from 3800 RPM, the highest rotation speed N1, to 2000 RPM, the lowest rotation speed N2, and returned to the highest rotation speed N1 after a predetermined time elapses. The above operation prevents overheating of the BLDC compressor and increases the compression efficiency of the refrigerant.

However, it is determined that the microcomputer 70 has a low outside air temperature and a low load based on the measurement results of the temperature outside the refrigerator, the internal temperature of the refrigerator, and the opening / closing frequency of the refrigerator door through various sensors 10, 20, 30, and 40. The microcomputer 70 maintains the rotational speed of the BLDC compressor 60 at the lowest rotational speed. The minimum rotational speed of this embodiment is about 2000 RPM, and the above-described operation occurs mainly in a cold weather. If the rotational speed of the refrigerator BLDC compressor is maintained at the minimum rotational temperature during the cold weather, the flow rate of the refrigerant is slowed. When the BLDC compressor is operated at the lowest speed for a long time, the refrigerant circulation amount decreases. Thus, the rotational speed of the BLDC compressor is periodically increased. The method is as follows.

First, the microcomputer 70 detects the rotation speed N and the outdoor temperature Ta of the BLDC compressor 70 (S100). As described above, since the rotation speed N signal is output from the microcomputer 60 to the BLDC compressor 60, the microcomputer 70 detects the signal output from the microcomputer 70 itself. Then, it is determined whether the detected rotation speed (N) is the highest rotation speed N1 (3800 RPM) (S110), but if the low outside air temperature and low load, the rotation speed N does not become N1 (3800 RPM). If the rotation speed N is not N1 (3800 RPM) in step S110, it is determined whether N is N2 (2000 RPM) (S130). If the rotational speed N is N2 (2000 RPM) after the determination (S130), the microcomputer 60 detects the outside air temperature Ta and the preset outside air threshold lower limit value Tc of the refrigerator detected by the outside air temperature sensor 10 in the detection step S100. ) Will be compared (S140). The outside air threshold lower limit value Tc is the minimum external temperature of the preset refrigerator. If the outside temperature Ta of the refrigerator is less than the outside threshold lower limit value Tc in the comparison step S140, the BLDC compressor 60 is set to mode 2 operation S150c. As shown in Fig. 3B, the mode 2 operation S150c maintains the normal rotational speed of the BLDC compressor 60 at 2000 RPM, which is the minimum rotational speed N2. At a predetermined time interval during operation, the engine speed decreases from 2000 RPM, which is the minimum rotational speed N2, to 3800 RPM, which is the highest rotational speed N1, thereby reducing a decrease in refrigerant circulation and returning to the minimum rotational speed N2 after a predetermined time.

However, in the comparison step S120, when the outside temperature Ta of the refrigerator is less than the upper outside threshold Tb, the outside air temperature Ta of the refrigerator is greater than or equal to the outside threshold Tc in the comparison step S140. In this case, the BLDC compressor 60 is set to normal mode operation (S150b). Normal mode operation is performed when the rotational speed of the BLDC compressor is between the highest rotational speed N1 and the lowest rotational speed N2. The normal mode operation follows the control method of the compressor of the conventional variable capacity refrigerator.

The compressor control method of the refrigerator according to the present invention prevents overheating of the compressor due to long time operation at the maximum rotational speed of the compressor when the outdoor air temperature is high in the summer, and long-term at the minimum rotational speed when the outdoor air temperature is low, such as in winter. It is possible to reduce the decrease in the refrigerant circulation amount due to the operation.

Claims (3)

Detecting step of detecting the rotational speed of the refrigerator compressor and the outside air temperature of the refrigerator, A rotation speed determination step of determining whether the rotation speed detected in the detection step is a set rotation speed of the refrigerator compressor; A temperature comparison step of comparing the outside air temperature detected in the sensing step with a preset outside air threshold temperature value when the rotation speed is the set rotation speed in the rotation speed determining step, And periodically varying the rotation speed of the compressor operated at the set rotation speed when the outside air temperature is out of a range of the outside air threshold temperature value in the temperature comparison step. The method of claim 1, The control of the refrigerator compressor, characterized in that the compressor is driven at the minimum rotational speed at a predetermined cycle when the set rotational speed is the highest rotational speed of the compressor and the outside temperature is higher than the upper limit of the threshold temperature of the outside air in the rotation speed determination step Way. The method of claim 1, When the set speed is the minimum speed of the compressor and the outside temperature is lower than the lower limit of the outside temperature threshold temperature value in the rotation speed determination step of the refrigerator compressor, characterized in that the compressor is driven at the maximum rotation speed every predetermined cycle Control method.

Images