KR0143209B1 - Self-control diagnosis and its method - Google Patents

Abstract

The disclosed invention relates to a self-diagnosis apparatus and a method of a refrigerator. In the self-diagnosis method of a refrigerator for self-diagnosing a failure of a damper and a temperature sensing sensor, a part of the damper and a temperature sensing sensor are selectively selected. A first step of designating a desired inspection mode by operating a preset key among a shortcut inspection mode for checking and a normal inspection mode for checking all; A second step of determining whether the check mode specified by the first step is a short check mode or a normal check mode; If it is determined in the short-term check mode in the second step, to check the sensors individually, it is determined whether to fall within the detection temperature range of the sensor according to the voltage of the temperature detection signal input from the sensor, to diagnose whether there is a failure, Displaying a diagnosis result; And in case of determining the normal check mode in the second step, in order to check the damper, the initial opening / closing state of the damper is stored, and then a damper control signal is output to drive the damper, wherein the damper control signal is driven by the damper control signal. It is checked whether the damper is broken by comparing the open / closed state of the damper with the previously stored initial opening / closing state, and it is determined whether the opening time of the damper driven by the damper control signal exceeds a preset set time and the determination result. And a fourth step of checking the sensors by returning to the third step when the key signal for the sleep key is blinked after the corresponding lamp is flickered.

Description

Self Diagnosis Device and Method of Refrigerator

The present invention relates to a self-diagnostic apparatus and method of the refrigerator, and in particular, when the power is supplied to the refrigerator or when the fault is checked, the electric damper and the temperature sensing sensors are diagnosed by themselves, and the diagnosis results are displayed to quickly detect the fault. The present invention relates to a self-diagnosis apparatus and a method of a refrigerator so as to heal the blood.

In general, refrigerators have a basic function of refrigeration or freezing of stored foods by maintaining a high internal temperature at a set temperature. Recently, a refrigerator has a self-diagnosis function that checks a failure state of each component in addition to the refrigeration or freezing function. There is a situation.

However, in order to perform the self-diagnosis function for each component of the refrigerator, it is necessary to store the information on the characteristics and the failure factors of the components in advance and to detect the failure in preparation for the long time. Even if the self-diagnosis is performed by selectively designating only a specific part, in case of an actual fault, a fault check should be performed for each part. In view of this, the conventional refrigerator adopts a method of performing self-diagnosis only for a specific component or performs self-diagnosis for related components in normal operation, which requires cumbersome inspection work to find out a failure part when a failure occurs. There was a significant lack of practical self-diagnosis.

The present invention performs the self-diagnosis function to check the dampers and sensors that sense the temperature inside the refrigerator required to perform all the functions in the refrigerator, solves the technical problem of easily performing the fault check and repair during the self-diagnosis performance It is suggested.

An object of the present invention is to provide a self-diagnosis device for a refrigerator that enables the user to easily check the self-diagnosis and display the failure of the electric damper and the temperature sensing sensor when the refrigerator is started, and to quickly heal the failure part when the refrigerator occurs. In providing.

Another object of the present invention is to provide a self-diagnosis method of a refrigerator capable of quickly healing a failure site by starting to supply power to a refrigerator and diagnosing and displaying a failure of a damper or sensors according to a user's key operation.

1 is a block diagram of a self-diagnostic apparatus of the refrigerator according to the present invention.

Figure 2 is a flow chart illustrating a self-diagnosis method of the refrigerator according to the present invention.

* Explanation of symbols for main parts of the drawings

1: Microcomputer 2: Inspection mode selector

3: damper drive unit 4: damper state detection unit

5: Sensor unit 6: Lamp and alarm unit

An object of the present invention as described above is an electronic refrigerator having a damper that is opened and closed to introduce cold air into the refrigerating chamber and temperature sensing sensors for sensing the temperature in the refrigerator, wherein the damper and the temperature sensing sensors are subject to inspection. An inspection for outputting a key signal according to the operation of the lock key LK, having a short check mode for selectively checking a part of the inspection object and a normal check mode for checking all A mode selector; A damper opening / closing detection unit having a reed switch (RS) switched on or off in accordance with an open / closed state of the damper, and outputting a predetermined damper opening / closing detection signal according to the switching state of the reed switch (RS); A sensor unit provided with the temperature sensing sensors for detecting a high temperature inside each room provided in the refrigerator and resistors connected to each sensor, and outputting a temperature sensing signal having a predetermined voltage according to the sensing temperature detected by the sensors; In order to check the damper and the sensor in accordance with the check mode corresponding to the key signal from the check mode selection unit, the damper in accordance with the damper opening and closing detection signal input from the damper opening and closing detection unit and the sensor unit Inspecting the sensors according to the temperature detection signal for the corresponding sensor input from the sensor, outputting a damper control signal for controlling the open and close state of the damper when the damper check and display the results of the check on the damper and sensors A microcomputer for outputting a flashing control signal for alarming and an alarm control signal for alarming; A damper motor DM for driving the damper and a relay RY1 for applying a driving signal to the damper motor DM, and driving the damper motor DM by the damper control signal of the microcomputer. A damper driver for opening and closing the damper; And flashing a lamp corresponding to the damper and the sensor by the flashing control signal of the micom, and achieving the lamp and the alarm unit generating an alarm sound to alarm an abnormality of the damper and the sensor according to the alarm control signal of the micom. do.

Another object of the present invention as described above in the self-diagnostic method of the refrigerator for self-diagnosing the failure of the damper and the sensors for sensing the temperature inside the cold air inlet to the refrigerating chamber, the damper and the temperature sensing sensors A first step of designating a desired inspection mode by operating a preset key among a shortcut inspection mode for selectively checking a part of the information and a normal inspection mode for checking all of them; A second step of determining whether the check mode specified by the first step is a short check mode or a normal check mode; If it is determined in the short-term check mode in the second step in order to check the sensors openly, it is determined whether to fall within the detection temperature range of the sensor according to the voltage of the temperature detection signal input from the sensor to diagnose whether there is a failure. A third step of displaying a diagnosis result; And in case of determining the normal check mode in the second step, in order to check the damper, the initial opening / closing state of the damper is stored, and then a damper control signal is output to drive the damper, wherein the damper control signal is driven by the damper control signal. It is checked whether the damper is broken by comparing the open / closed state of the damper with the previously stored initial opening / closing state, and it is determined whether the opening time of the damper driven by the damper control signal exceeds a preset set time and the determination result. When the corresponding lamp is flashed and the key signal for the sleep key is inputted, the method returns to the third step to accomplish the fourth step of checking the sensors.

Hereinafter, a preferred embodiment of the present invention will be described in detail according to the accompanying drawings.

1 is a block diagram of a self-diagnosis apparatus for a refrigerator according to the present invention. As shown, the present invention is to check the damper and the temperature sensing sensors for detecting the high temperature inside the cold air inlet to the refrigerator, to check only the normal mode and the sensors to check the damper and the sensor sequentially A check mode selection unit 2 for selecting a short-term check mode, a damper opening / closing detection unit 4 for outputting a predetermined damper state signal according to the open / closed state of the damper, and a sensing temperature according to the sensing temperature A microcomputer for controlling an operation of displaying a fault part and an operation of generating an alarm sound by performing a check operation according to a sensor unit 5 for outputting a signal for each sensor and a check mode selected by the check mode selection unit 2. (1) and a lamp and an alarm unit (6) which, under the control of the microcomputer (1), flash a lamp corresponding to a failure site and generate an alarm sound.

The check mode selector 2 includes a transistor TR1 having a base connected to the output terminal PB4 of the microcomputer 1 through a resistor R1 and receiving about 12 volts of driving power through the collector. A diode D1 connected to the emitter terminal of the transistor TR1, a lock key LK connected to the diode D1 to select a short check mode and a normal check mode, and a lock key LK; The resistor R2 is connected to the input terminal PA6 of the microcomputer 1, and the control diode ZD1 and the resistor R3 having one end connected to the resistor R2 and the other end grounded.

The damper opening and closing detection unit 4 is connected to a driving power of about 5 volts and calls a reed switch RS for switching to an 'on' or 'off' state according to an open / closed state of the damper, and a driving power of about 5 volts. It is composed of a capacitor (C1) and a resistor (R4) which is input via a lex end and the base end is connected to the reed switch (RS) through a resistor (R5) and connected in parallel to the collector end and the emitter end, The damper opening and closing detection signal according to the switching state of the reed switch RS is output to the input terminal PB0.

The sensor unit 5 receives a driving power of about 5 volts through one end and senses a high internal temperature, and resistors R10, R11, R12, and R13 connected to the other end of a temperature sensing signal of a predetermined voltage according to the detected temperature. First to fourth sensors S1 to S4, the resistors R10, R11, R12, and R13 and the first to fourth outputs to the input terminals AN0, AN1, AN2, and AN3 of the microcomputer 10 through the controller. One side is connected between the fourth sensors S1 to S4, and the other side is formed of the divided resistors R6, R7, R8, and R9.

The damper driver 3 is a damper for opening and closing the damper by receiving a driving power through a power cord in accordance with the relay (RY1) is opened and closed in accordance with the damper control signal of the microcomputer (1) and the relay (RY1). The damper control is connected to a motor DM, a capacitor C1 connected between the damper motor DM and the relay RY1, and an output terminal PC5 of the relay RY1 and the microcomputer 1. The resistor R4 outputs a signal to the relay RY, a capacitor C3, and an inverter INV.

The lamp and the alarm unit 6 flashes a lamp corresponding to each damper or sensor according to the flashing control signal of the microcomputer 1 for a predetermined time, and generates an alarm sound through an alarm means according to the alarm control signal of the microcomputer 1. Occurs for a certain time.

The effect of the present invention having the configuration as described above will be described in detail.

The microcomputer 1 performs a check operation on the dampers and the sensors according to a pre-programmed control procedure when a power is applied to start the refrigerator, and the user selects the check mode selection unit to specify a check mode. The lock key (LK) of 2) should be operated. That is, the user operates the lock key LK in the 'off' state to check in the normal mode, while switching to the 'on' state by operating the lock key LK in the short mode. When the lock key LK is initially set to an 'off' state, the microcomputer 1 performs a check operation in a normal mode when performing the self-diagnosis.

The microcomputer 1 recognizes a check mode designated by the check mode selection unit 2 and performs a check operation according to the check mode. That is, when the microcomputer 1 is designated in the shortened mode, the microcomputer 1 determines whether the first to fourth sensors S1 to S4 have failed according to the temperature detection signal of the sensor unit 5, and the lamp blinks according to the determination result. Or control the alarm sound. On the other hand, when the microcomputer 1 is designated as the normal mode, the initial opening and closing state of the damper is first stored, and then the damper control signal is output to drive the damper, and then the open / closed state of the driven damper is compared with the stored initial opening and closing state. To check whether the damper is broken, and if the user operates a slip key not shown, the check operation for the damper is terminated, and whether the first to fourth sensors S1 to S4 of the sensor unit 5 are broken. Will be checked.

The microcomputer 1 recognizes the open / closed state of the damper according to the damper open / close detection signal inputted through the damper open / close detection unit 4 when checking the damper, and opens / closes the damper before outputting the damper control signal. The initial state in which the open / close state of the damper corresponding to the damper opening / closing detection signal inputted through the damper opening / closing detecting section 4 is already stored in a state in which the state is stored in a storage means such as a buffer, and then the damper control signal is output. The failure of the damper is recognized depending on whether the damper is open and closed. In addition, the microcomputer 1 receives the temperature sensing signals of the first to fourth sensors S1 to S4 input through the input terminals AN0 to AN3, and senses the temperature according to the voltage value of the received temperature sensing signal. It is determined whether the fault is in the range by determining the on or off state of the first to fourth sensors (S1 to S4). The microcomputer 1 outputs a flashing signal for flashing a corresponding lamp and generates an alarm control signal for generating an alarm sound when a failure occurs as a result of checking a damper or sensor according to the inspection mode. Will output

The damper driver 3 receives a damper control signal through the output terminal PC5 of the microcomputer 1, and the relay RY1 is opened and closed by the damper control signal, and the relay RY is opened and closed. The damper motor DM is driven. That is, when the relay RY1 is connected, power is applied to and driven by the damper motor DM through a power cord, and the damper is opened and closed accordingly.

The damper opening and closing detecting unit 4 switches the reed switch RS according to the opening and closing of the damper, and outputs a damper opening and closing signal to the input terminal B0 of the microcomputer 1 according to the switching state of the reed switch RS. )

Hereinafter, the self-diagnostic method of the refrigerator according to the present invention will be described in detail with reference to FIG.

If the user wants to perform the check operation in the short mode, the user operates the lock key LK of the check mode selection unit 2 in the 'on' state and the check if the check mode is to be performed in the normal mode. The lock key LK of the mode selector 2 is keyed to the 'off' state. In this state, the microcomputer 1 starts a self-diagnosis function in a state in which the user designates the check mode. First, the microcomputer 1 outputs the diagnosis start signal of the 'high' state to the base terminal of the transistor TR1 of the check mode selection unit 2 through the output terminal PB4 (step 200). Subsequently, the microcomputer 1 recognizes the on / off state of the lock key LK according to a signal input through the input terminal PA6 by turning on the transistor TR1 to determine a check mode designated by the user. (Step 201). In the short-term check mode in step 201, the first to fourth sensors S1 to S4 of the sensor unit 5 are checked in accordance with steps 202 to 205. If, in step 206 to step 219 to check whether or not the failure of the damper according to the step 202 to step 205 to check the failure of the sensor unit (5).

In detail, when the checking operation on the first sensor S1 is performed in the short-term check mode according to step 202, the microcomputer 1 senses the temperature of the first sensor S1 input through the input port AN0. The signal is input and the voltage of the received temperature sensing signal is analyzed (step 202a). Subsequently, the microcomputer 1 determines whether the analyzed voltage is equal to or higher than a maximum voltage corresponding to the case where the first sensor S1 is in an off state (step 202b). If it is less than the maximum voltage as a result of the determination in step 202b, it is determined whether or not the minimum voltage corresponding to the case where the first sensor S1 is on (step 202c). In the case where the determination result in step 202b is higher than the highest voltage or the determination result in step 202c is lower than the lowest voltage, the first sensor S1 may have a failure because it is out of the sensing temperature range of the first sensor S1. ) Is flashed (step 202d). Subsequently, the micom 1 generates an alarm sound to notify the failure of the first sensor S1 (step 202e).

On the other hand, when the determination result of step 202c is greater than the minimum voltage, since the first sensor S1 operates normally, the second sensor S2 is checked according to step 203. That is, the microcomputer 1 receives the temperature sensing signal of the second sensor S2 input through the input port AN1 and analyzes the voltage of the received temperature sensing signal (step 203a). Subsequently, the microcomputer 1 determines whether the analyzed voltage is equal to or higher than a maximum voltage corresponding to the case where the second sensor S2 is in an off state (step 203b). If it is less than the maximum voltage as a result of the determination in step 203b, it is determined whether or not the minimum voltage corresponding to the case where the second sensor S2 is on (step 203c). In the case where the determination result of the step 203b is higher than the highest voltage or the determination result of the step 203c is lower than the lowest voltage, the second sensor S2 occurs because a failure occurs outside the detection temperature range of the second sensor S2. ) Is flashed (step 203d). Subsequently, the microcomputer 1 generates an alarm sound to notify the failure of the second sensor S2 (step 203e).

On the other hand, when the determination result of step 203c is greater than the minimum voltage, the second sensor S2 is in a normal operation state, so the third sensor S3 is checked according to step 204. That is, the microcomputer 1 receives the temperature sensing signal of the third sensor S3 input through the input port AN2 and analyzes the voltage of the received temperature sensing signal (step 204a). Subsequently, the microcomputer 1 determines whether the analyzed voltage is equal to or higher than a maximum voltage corresponding to when the third sensor S3 is in an off state (step 204b). If it is less than the highest voltage as a result of the determination in step 204b, it is determined whether or not the minimum voltage corresponding to the case where the third sensor S3 is on (step 204c). If the result of the determination in step 204b is higher than the highest voltage or the result of the determination in step 204c is lower than the lowest voltage, the third sensor S3 may have a fault because the fault has occurred out of the sensing temperature range of the third sensor S3. ) Is flashed (step 204d). Subsequently, the micom 1 generates an alarm sound to notify the failure of the third sensor S3 (step 204e).

On the other hand, if it is greater than the minimum voltage as a result of the determination in step 204c, since the third sensor S3 is in a normal operation state, the fourth sensor S4 is checked according to step 205. That is, the microcomputer 1 receives the temperature sensing signal of the fourth sensor S4 input through the input port AN3 and analyzes the voltage of the received temperature sensing signal (step 205a). Subsequently, the microcomputer 1 determines whether the analyzed voltage is equal to or higher than a maximum voltage corresponding to the case where the fourth sensor S4 is in an off state (step 205b). If it is less than the maximum voltage as a result of the determination in step 205b, it is determined whether or not the minimum voltage corresponding to the case where the fourth sensor S4 is on (step 205c). If the result of the determination in step 205b is higher than the highest voltage or the result of the determination in step 205c is lower than the lowest voltage, the fourth sensor S4 is a fault because the fault occurs outside the detection temperature range of the fourth sensor S4. ) Is flashed (step 205d). Subsequently, the microcomputer 1 generates an alarm sound to notify the failure of the fourth sensor S4 (step 205e). On the other hand, if it is greater than the minimum voltage as a result of the determination of step 205c, the fourth sensor S4 is in a normal operation state and returns to the start step.

On the other hand, when the determination result check mode of step 201 is the normal check mode, the first step to the first to fourth sensors (S1 to S4) after checking whether the damper for the damper in accordance with steps 206 to 219 The check operation for In the following description, the operation of checking whether the damper is broken or not according to steps 206 to 219 will be described in order to avoid redundant description. That is, the microcomputer 1 receives the damper detection state signal of the damper opening and closing detection unit 4 through the input port PB0 and stores the initial opening and closing state of the damper in the buffer (step 206). Subsequently, the microcomputer 1 outputs a damper control signal through the output port PC5 to connect the relay RY1 of the damper driver 3 to drive the damper motor DM (step 207). Subsequently, when the damper is opened and closed as the damper motor DM is driven, the microcomputer 1 switches the reed switch RS of the damper opening / closing detection unit 4 so that the damper control signal is output and then the input port ( In step 208, it is determined whether the damper opening / closing state corresponding to the damper opening / closing state signal inputted through the PBO coincides with the initial opening / closing state of the damper already stored. As a result of the determination in step 208, when the damper is in an initial open state, for example, when the initial open state of the damper is open, it is determined whether the elapsed time required for closing by the damper has arrived (step 209). ). If the elapsed time of the determination result of step 209 does not arrive, the flow returns to step 207, whereas if the elapsed time of the determination of step 209 arrives, the damper continues to maintain the initial state, that is, the damper is broken. The flashing control signal is output to flash the lamp corresponding to the damper at a predetermined cycle, and the alarm control signal is output to generate an alarm sound (step 210). Subsequently, when the user operates the skip key for stopping the check operation of the damper by recognizing the failure of the damper by the blinking of the lamp and the alarm sound, the micom 1 checks whether a key signal corresponding to the skip key is input. Determination (step 211). If the skip key is not input as a result of the determination in step 211, the control unit returns to step 210 to continuously flash the lamp and generate an alarm sound while the damper is input if the skip key is input as a result of determination in step 211. In step 220a, the check operation is terminated and the check operation of the sensor unit 5 is performed.

On the other hand, when the determination result of step 208 does not match the initial opening and closing state of the damper, it is determined that the damper is in the driving state and whether the opening and closing state of the damper after driving matches the initial opening and closing state of the damper already stored (212). step). If it is determined in operation 212 that the initial damping state of the damper does not match after driving, the damper motor is driven by outputting a damper control signal in order to continue driving the damper (step 213). Subsequently, the microcomputer 1 determines whether the elapsed time required to open by driving the damper has arrived (step 214). If the elapsed time of the determination in step 214 does not arrive, the flow returns to step 212. If the elapsed time of the determination in step 214 arrives, the damper is not driven. In operation 215, the lamp corresponding to the damper blinks at a predetermined cycle by outputting a blinking control signal and generates an alarm sound by outputting an alarm control signal. Subsequently, when the user operates the skip key for stopping the check operation of the damper by recognizing the failure of the damper by the blinking of the lamp and the alarm sound, the micom 1 checks whether a key signal corresponding to the skip key is input. (Step 216). If the skip key is not input as a result of the determination in step 216, the lamp returns to step 215 to continuously flash the lamp and generate an alarm sound, whereas if the skip key is input as the determination result in step 216 In order to end the check operation of the damper and to perform the check operation on the sensor unit 5, the flow returns to step 202a.

On the other hand, when the damper is driven by the determination result of step 212, if the damper's opening / closing state coincides with the previously stored state of the damper, the driving time required to change the damper from the closed state to the open state is counted ( Step 217). Subsequently, the microcomputer 1 determines whether the counted time coincides with a preset time set to change the driving state of the damper (step 218). If the determination result of step 218 does not match the set time, the flow returns to step 217 to maintain the counting operation. If the determination result of step 218 does not match the set time, the driving of the damper is stopped. After clearing the buffer for storing the initial opening / closing state of the damper (step 219), the process returns to step 202a to perform the checking operation of the sensor unit 5.

As described above, the present invention performs self-diagnosis by using dampers and sensors for detecting internal temperature, which are essential to perform various functions in the refrigerator, so that the user can easily check the fault site, and thus heal in a short time. It is possible to detect whether the dampers and sensors defective in the manufacturing process has the effect of improving the reliability of the product more.

Claims (2)

An electronic refrigerator having a damper that is opened and closed to introduce cold air into a refrigerating chamber and a temperature sensing sensor that senses a temperature in a refrigerator, wherein the damper and the temperature sensing sensors are inspected and a part of the inspected object is selectively selected. A check mode selection unit including a lock key (LK) for selecting a short check check mode for checking and a normal check mode for checking all of the checks, and outputting a key signal according to the operation of the lock key (LK); A damper opening / closing detection unit having a reed switch (RS) switched on or off in accordance with an open / closed state of the damper, and outputting a predetermined damper opening / closing detection signal according to the switching state of the reed switch (RS); A sensor unit provided with the temperature sensing sensors for detecting a high temperature inside each room provided in the refrigerator and resistors connected to each sensor, and outputting a temperature sensing signal having a predetermined voltage according to the sensing temperature detected by the sensors; In order to check the damper and the sensor in accordance with the check mode corresponding to the key signal from the check mode selection unit, the damper in accordance with the damper opening and closing detection signal input from the damper opening and closing detection unit and the sensor unit Inspecting the sensors according to the temperature detection signal for the corresponding sensor input from the sensor, outputting a damper control signal for controlling the open and close state of the damper when the damper check and display the results of the check on the damper and sensors A microcomputer for outputting a flashing control signal for alarming and an alarm control signal for alarming; A damper motor DM for driving the damper and a relay RY1 for applying a driving signal to the damper motor DM, and driving the damper motor DM by the damper control signal of the microcomputer. A damper driver for opening and closing the damper; And a lamp and an alarm unit which flash a lamp corresponding to the damper and the sensors by the flashing control signal of the micom, and generate an alarm sound to alarm an abnormality of the damper and the sensors according to the alarm control signal of the micom. Self-diagnostic apparatus of the refrigerator, characterized in that. In the self-diagnosis method of the refrigerator for self-diagnosing the failure of the damper and the sensors for detecting the temperature inside the refrigerator, the short-term inspection for selectively checking a part of the damper and the temperature sensing sensors. A first step of designating a desired check mode by operating a preset key among the normal check modes for checking the mode and the whole; A second step of determining whether the check mode specified by the first step is a short check mode or a normal check mode; If it is determined in the short-term check mode in the second step, to check the sensors individually, it is determined whether to fall within the detection temperature range of the sensor according to the voltage of the temperature detection signal input from the sensor, to diagnose whether there is a failure, Displaying a diagnosis result; And in case of determining the normal check mode in the second step, in order to check the damper, the initial opening / closing state of the damper is stored, and then a damper control signal is output to drive the damper, wherein the damper control signal is driven by the damper control signal. It is checked whether the damper is broken by comparing the open / closed state of the damper with the previously stored initial opening / closing state, and it is determined whether the opening time of the damper driven by the damper control signal exceeds a preset set time and the determination result. And a fourth step of checking the sensors by returning to the third step when the corresponding lamp flashes and a key signal for the sleep key is input.