KR100238061B1 - Self-diagnosis method of a refrigerator - Google Patents

Abstract

The present invention relates to a self-diagnosis method of a refrigerator capable of diagnosing not only open and short breakdowns of the refrigerator sensor but also defective sensor characteristics and a failure of the compressor.

To this end, the present invention performs the disconnection and short circuit failure diagnosis of the refrigerator sensor at the initial power-on of the refrigerator, and then operates the compressor to change the temperature in the refrigerator to change the temperature of the refrigerator sensor. Diagnosing the presence or absence of characteristic defects, if all the sensors of the refrigerator does not cause a change in the output voltage even after the compressor has been operated for a predetermined time, the compressor is diagnosed as a failure.

Thus, according to the present invention, it is possible to prevent abnormal operation of the refrigerator due to a poor characteristic of the sensor.

Description

Self-diagnosis method of the refrigerator

The present invention relates to a self-diagnosis method of a refrigerator, and more particularly, to a self-diagnosis method of a refrigerator capable of diagnosing disconnection, short-circuit and poor characteristics of a refrigerator sensor, and failure of a compressor.

As is well known, a refrigerator is equipped with various sensors, for example, a freezer compartment evaporator temperature sensor, a refrigerator compartment evaporator temperature sensor, a freezer compartment temperature sensor, a refrigerator compartment temperature sensor, and the like. Such sensors sense the temperature and provide the detected temperature value to the microcomputer of the refrigerator control device as a control input value. 1 schematically shows the installation position of the refrigerator sensor, and FIG. 2 shows a connection connection relationship between the sensors and the microcomputer which is a refrigerator control device. Referring to Figure 1, reference numeral 1 is a freezer compartment temperature sensor; 2 is a freezer evaporator temperature sensor; 3 and 4 are refrigerator temperature sensors; 5 is a refrigerator evaporator temperature sensor; Each of 6,8 includes a freezer compartment evaporator and a refrigerator compartment evaporator; 7,9 each is a freezer compartment fan, a refrigerator compartment fan; 17 is a compressor; Here, it will be apparent to those skilled in the art that the refrigerating compartment evaporator 8 and the refrigerating compartment evaporator temperature sensor 5 are only applicable to the independent refrigeration refrigerator and will be excluded otherwise.

Referring to FIG. 2, one terminal of each sensor 1.. 5 is grounded, and the other terminal is connected in common with one terminal of the current limiting resistor R1 and one terminal of the voltage sharing resistor R2. Each of the other terminals of the current limiting resistor R1 is connected to a 5 volt electrostatic source, and each of the other terminals of the voltage distribution resistor R2 is connected to a corresponding input port P1.. P5 of the microcomputer 10.

In the refrigerator as described above, when commercial power (100 volts or 220 volts) is applied to the refrigerator, the microcomputer 10 performs a sensor self-diagnosis function, and when the sensor self-diagnosis function is performed, When a high signal, for example, a voltage signal of 4.8 volts or more is input to the sensor input port, or a low signal, for example, a voltage signal of 0.5 volts or less is input, the microcomputer 10 warns the refrigerator. The sensor failure is notified through the buzzer 12 or the light emitting lamp 14 of the display unit. That is, when a high signal is input to the corresponding input port of the microcomputer 10 associated with the sensor, the microcomputer 10 determines that the sensor is disconnected and outputs a sensor fault signal, and the microcomputer 10 of the microcomputer 10 associated with the sensor is output. When the low signal is input to the corresponding input port, the microcomputer 10 determines that the sensor is short-circuited and outputs a sensor failure signal. In FIG. 2, reference numerals D1 and D2 denote driver inverters for driving the buzzer 12 and the LEDs 14.

However, the self-diagnosis function of the refrigerator at the time of power on has only a problem of failing to detect the characteristic defect of the sensor because it diagnoses only the failure of the sensor due to disconnection or short circuit of the sensor. That is, in the conventional refrigerator, when the power-on self-diagnosis function of the refrigerator is poor in the characteristics of the sensor, for example, the sensor outputs a fixed constant voltage value regardless of temperature changes, the microcomputer determines that the sensor is normal. There is a problem that the normal operation of the refrigerator is not made because the failure signal is not output.

The present invention has been made to solve the above problems, to provide a self-diagnosis method of the refrigerator capable of diagnosing the disconnection (open), short circuit (short) and poor characteristics of the refrigerator sensor and the failure of the compressor. There is this.

1 is a conceptual view schematically showing an installation position of a temperature sensor of a general refrigerator;

2 is a hardware circuit diagram for achieving a method of self-diagnosis of the refrigerator according to the present invention;

3 is a flow chart of a self-diagnostic method of a refrigerator according to the present invention;

4A and 4B are circuit diagrams showing a voltage application form to a microcomputer according to disconnection and short circuit of the refrigerator sensor.

<Description of the symbols for the main parts of the drawings>

1: Freezer compartment temperature sensor 2: Freezer compartment evaporator temperature sensor

3,4: refrigerator compartment temperature sensor 5: refrigerator compartment evaporator temperature sensor

10 microcomputer 12 buzzer

14 light emitting lamp 17 compressor

Self-diagnosis method of the refrigerator according to the present invention to achieve the above object,

In the self-diagnosis method of the refrigerator having a plurality of sensors provided in each of the refrigerator compartment and the freezer compartment,

Powering on the refrigerator and checking output voltages of the sensors at this time;

If the output voltage of each sensor is above the predetermined voltage, the sensor is diagnosed as disconnection. If the output voltage of each sensor is below the predetermined voltage, the sensor is diagnosed as short circuit. Otherwise, the refrigerator is turned on to turn on the refrigerator. Driving;

If the compressor is on for a predetermined time, checking the output voltage of each sensor at this time and comparing the output voltage with the output voltage of each sensor checked at the power on;

If all output voltages of the respective sensors do not change as a result of the comparison in the above step, the compressor is diagnosed as a failure. Otherwise, there is a sensor that does not change the output voltage among the sensors and the temperature rise among the sensors. Determining whether there is a sensor in which an output voltage change occurs;

If there is a sensor in which the output voltage does not change in each of the sensors in the determination step, or there is a sensor in which the output voltage changes due to the temperature rise, the sensor is diagnosed as defective. Otherwise, all of the sensors Diagnosing that it is normal and operating the refrigerator normally; there is a feature in that it includes.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the self-diagnosis method of the refrigerator according to the present invention.

The self-diagnosis method of the refrigerator according to the present invention is capable of diagnosing disconnection, short-circuit and defect of the refrigerator sensor, and even the failure of the compressor, as shown in FIGS. 1 and 3. , Power on the refrigerator, wherein each sensor of the refrigerator, for example, a freezer compartment temperature sensor (1), a freezer compartment evaporator temperature sensor (2), a refrigerator compartment temperature sensor (3) (4), a refrigerator compartment evaporator temperature sensor ( Checking each output voltage of step 5) (S1) (S3); and when at least one of the sensors 1.5 outputs a predetermined voltage (eg, 4.8 volts) or more, If it is diagnosed as disconnection and at least one of the sensors 1.5 outputs less than a predetermined voltage (for example, 0.5 volt), the sensor is diagnosed as a short circuit. Otherwise, the compressor 17 Turning on the refrigerator to operate the refrigerator (S5) (S7) (S9); and, the compressor 17 If it is turned on for a predetermined time (for example, 10 minutes), the output voltage of each sensor (1..5) is checked at this time, and this output voltage is checked for each sensor (1..5) checked at the power-on of step S3. (S11) (S13) (S15) for comparing with the output voltage of &lt; RTI ID = 0.0 &gt; and &lt; / RTI &gt; Otherwise, it is determined whether or not there is a sensor in which the output voltage does not change in each sensor (1..5) and whether there is a sensor in which the output voltage changes due to a temperature rise in each sensor (1..5). (S17) (S19) (S21); and if there is a sensor in which the output voltage does not change in each sensor (1..5) in step S21, or there is a sensor in which the output voltage changes due to the temperature rise, Diagnose the sensor as defective, otherwise diagnose everything in each sensor (1..5) as normal It comprises a; step of normal operation Django (S23) (S25).

The operation of the self-diagnosis method of the present invention refrigerator configured as described above will be described with reference to FIGS.

It will be apparent to those skilled in the art that the algorithm of the self-diagnosis method of the present invention refrigerator shown in FIG. 3 is programmed and stored in the microcomputer 10 of the refrigerator, and implemented in the microcomputer 10.

Referring to FIG. 3, when commercial power is applied to the refrigerator (S1), the microcomputer 10 includes a freezer compartment temperature sensor 1, a freezer compartment evaporator temperature sensor 2, a refrigerator compartment temperature sensor 3, and 4 a refrigerator compartment evaporator. The input voltage to the corresponding input ports P1..P5 respectively associated with the temperature sensor 5, that is, the magnitude T1 of the voltage applied to each sensor is checked (S3). After checking the voltage across each sensor (hereinafter referred to as 'output voltage'), the microcomputer 10 checks that the output voltage T1 of each sensor 1.5 is greater than or equal to 4.8 volts. Check if it is or less than 0.5 volts (S5). If the sensor output voltage T1 input to the corresponding input port is 4.8 volts or more, since the sensor is disconnected as shown in FIG. 4A, almost all voltages of the 5-volt constant voltage power supply are input to the corresponding input port. The microcomputer 10 notifies the sensor of the disconnection failure through the buzzer 12 or the light emitting lamp 14 of the refrigerator display unit (S7). Here, it is mentioned as an embodiment of the present invention that the corresponding sensor (or the compressor mentioned below) is broken through the buzzer 12 or the light emitting lamp 14 of the refrigerator display unit, but this is a main part of the present invention. It will be apparent to those skilled in the art that various other embodiments may be possible. The same applies to the following.

If the sensor output voltage T1 input to the corresponding input port is 0.5 volts or less, this means that the sensor is shorted as shown in FIG. 4B so that almost all voltages of the 5-volt constant voltage power supply are applied to the resistor R1. Since no voltage is applied, the microcomputer 10 notifies the sensor of the short circuit failure through the buzzer 12 or the light emitting lamp 14 of the refrigerator display unit (S7).

As a result of diagnosing disconnection or short-circuit of each sensor (1..5) in the same manner as described above, when it is determined that each sensor (1..5) is not disconnected or short-circuited, the microcomputer (10) turns on the compressor (17). (ON) to operate the refrigerator (S9). When the time for which the refrigerator has been operated has elapsed for about 10 minutes, the microcomputer 10 checks the output voltage T2 of each sensor 1.5 after 10 minutes has elapsed (S11) (S13). Then, the microcomputer 10 outputs the output voltage T1 at the step S3 of each sensor 1.5 and the output voltage of each sensor 1.5 after 10 minutes of operation of the compressor 17. (T2) are compared, respectively (S15). If all the output voltages of each sensor (1..5) in step S15 is T1 = T2, that is, if there is no change in all output voltages of each sensor (S17), this means that the compressor 17 is not operating normally, so the temperature in the refrigerator The microcomputer 10 determines that the compressor 17 is out of order through the buzzer 12 or the light emitting lamp 14 of the refrigerator display unit, in operation S19.

If the output voltage of each sensor (1..5) in step S17 is not all T1 = T2, that is, if the compressor 17 is normally operated, the microcomputer 10 through the corresponding input port (P1..P5) In (1..5), it is diagnosed whether there is a sensor in which the output voltage does not change, and in each sensor (1..5), whether there is a sensor in which the output voltage changes due to the temperature rise in the refrigerator. If there is a sensor in which the output voltage does not change in each sensor (1..5) in step S21, it is because it does not detect the change in the internal temperature according to the normal operation of the compressor 17, that is, the sensor Since it is defective, the microcomputer 10 notifies the sensor of the characteristic failure through the buzzer 12 or the light emitting lamp 14 of the refrigerator display unit (S23). Similarly, if there is a sensor in which the output voltage changes in accordance with the temperature rise in each sensor (1..5) in step S21, this is because the compressor 17 is normally operated and the internal temperature of the refrigerator is not detected. Since the sensor is defective, the microcomputer 10 notifies the sensor that the sensor is defective through the buzzer 12 or the light emitting lamp 14 of the refrigerator display unit (S23).

If in step S21 a change in the output voltage corresponding to the operation of the compressor 17 occurs in each of the sensors 1.. 5, this is because all the sensors 1. 5 are normal, so that the microcomputer 10 ) Operates the refrigerator normally (S25).

Thus, according to the present invention, not only the disconnection and short circuit failure diagnosis of the sensor at the time of power-on of the refrigerator can be diagnosed, but also the failure of the characteristics of the sensor and the abnormality of the compressor can be diagnosed.

As described above, the self-diagnosis method of the refrigerator of the present invention provides an advantage of diagnosing not only disconnection and short-circuit failure of the refrigerator sensor, but also poor sensor characteristics and abnormality of the compressor. Therefore, according to the present invention, it is possible to prevent the abnormal operation of the refrigerator due to the defective characteristics of the sensor.

Claims (5)

In the self-diagnosis method of the refrigerator having a plurality of sensors provided in each of the refrigerator compartment and the freezer compartment, Powering on the refrigerator and checking output voltages of the sensors at this time; If the output voltage of each sensor is above the predetermined voltage, the sensor is diagnosed as disconnection. If the output voltage of each sensor is below the predetermined voltage, the sensor is diagnosed as short circuit. Otherwise, the refrigerator is turned on to turn on the refrigerator. Driving; If the compressor is on for a predetermined time, checking the output voltage of each sensor at this time and comparing the output voltage with the output voltage of each sensor checked at the power on; If all output voltages of the respective sensors do not change as a result of the comparison in the above step, the compressor is diagnosed as a failure. Otherwise, there is a sensor that does not change the output voltage among the sensors and the temperature rise among the sensors. Determining whether there is a sensor in which an output voltage change occurs; If there is a sensor in which the output voltage does not change in each of the sensors in the determination step, or there is a sensor in which the output voltage changes due to the temperature rise, the sensor is diagnosed as defective. Otherwise, all of the sensors Diagnosing that it is normal and operating the refrigerator normally. Self-diagnosis method of a refrigerator comprising a. The method of claim 1, wherein the plurality of sensors include a refrigerator compartment temperature sensor, a freezer compartment temperature sensor, a refrigerator compartment evaporator temperature sensor, and a freezer compartment evaporator temperature sensor. The method of claim 1, wherein the predetermined voltage or more is 4.8 volts or more. The method of claim 1, wherein the predetermined voltage is 0.5 volts or less. The method of claim 1, wherein the predetermined time is 10 minutes.

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