DE19844655A1 - Refrigeration appliance with self-checking facility for electrical component failure - Google Patents

Abstract

Critical electrical component parts such as the compressor or fan (34) are operated through a drive unit (33) controlled by a microprocessor (32) through an inverter, INV2, and relay , RY2. A checking circuit (35) tests the functionality of the component and signals the microprocessor.

Description

The present invention relates to a refrigerator and especially a refrigerator with a self-checking Device for checking whether different electrical Consumers do it right or not.

As shown in FIG. 2, an ordinary refrigerator has a body 1 that forms a cooling chamber 3 and a door 2 that is installed on the front of the body 1 .

A compressor 14 for compressing a refrigerant is installed in the rear lower part of the body 1 , and an evaporator 7 for generating cold air by evaporating the refrigerant supplied from the compressor 14 is installed in the upper part thereof. The evaporator 7 is installed in a chamber 6 formed by a cover 5 .

A blower 10 is installed on the front of the cover 5 . The fan 10 is fastened to the cover 5 by a holder 8 . A cold air grille 12 with a plurality of cold air discharge openings 13 is installed at the rear of the cooling chamber 3 .

As long as the compressor 14 is operating, the evaporator 7 generates cold air. The cold air is blown by the blower 10 so that it flows into the cold air grid 12 via a line, which is not shown. The cold air is then fed through the cold air discharge openings 13 to the cooling chamber 3 , as a result of which the foodstuffs stored in the cooling chamber 3 are cooled.

The cooling chamber 3 formed on the lower part of the body 1 , as shown in the figure, is used as a food freshness chamber, and a freezer chamber having a structure similar to the food freshness chamber is formed in the upper part of the body 1 . The freezer chamber, like the food freshness chamber, has an extra evaporator for generating cold air and an extra fan for blowing the cold air. In addition, lamps (not shown) are installed in the food freshness chamber and the freezer chamber, which are switched on when the door 2 is open.

In itself, the refrigerator has a variety of electrical consumers that are used to operate it, such as. B. the compressor 14 , the blower 10 and lamps that require an electrical power supply. Fig. 3 shows the circuit for driving the plurality of electrical loads.

The refrigerator has a key input part 16 for entering operating commands and a microprocessor 17 for controlling the electrical consumers 4 in accordance with the commands input into the key input part 16 . Furthermore, the refrigerator has a plurality of drive parts 18 , 19 and 20 which are controlled by the microprocessor 17 . The drive parts 18 , 19 and 20 are each connected to the electrical consumers 4 , such as. B. the compressor 14 and the blower 10 shown in FIG. 2.

The first drive part 18 consists of an inverter INV1 for inverting signals from the microprocessor 17 and a relay RY1 which is connected to the output terminal of the inverter INV1. The relay RY1 controls the current source AC connected to the electrical consumers 4 .

When the microprocessor 17 sends a control signal, the signal is inverted by the inverter INV1 and is then fed into the relay RY1. Then the relay RY1 is switched on and the electrical consumer 4 is supplied with electrical current from the current source AC. The electrical consumer 4 therefore begins to work.

The second drive part 19 and the third drive part 20 have the same structure as the first drive part 18 and their operation is also the same.

Even if the electrical consumers 4 are supplied with electrical current from the power source AC, the electrical consumers 4 cannot work properly due to a shutdown of their internal circuit or a malfunction of their peripheral circuits. However, since the electrical consumers 4 are not checked in such an ordinary refrigerator after the control signal for driving the electrical consumer 4 is generated, it is not possible to decide whether the electrical consumers 4 are operating regularly or not.

To solve the problem described above, in Japanese Patent No. 1993-79904 a refrigerator with a device to check whether the electrical Consumers work regularly or not, suggested. Of the  refrigerator disclosed in the Japanese patent a current transformer for detecting the current in one connected to the electrical consumers common power supply line flows, a Device to check whether the electrical consumer work regularly or not, based on the outcome of the Secondary coil of the current transformer, one Display device according to the respective electrical Consumers, and a device for switching off the Supply of electrical current to the electrical Consumers and to control the display device when the defect of the electrical consumer is recognized.

In this Japanese patent, however, the amount of in the electrical consumers flowing current through the Current transformer and many comparators detected, so that Structure of the circuit is complex and the Manufacturing costs increase.

The present invention has been proposed to problems described above in the prior art eliminate, and consequently it is a task of present invention, a refrigerator with a to provide self-checking facilities from a simple circuit is built and is able to check whether different electrical consumers are correct work or not.

To solve the above problem, the present one Invention a refrigerator ready with: a control section for generating a signal to control an operation an electrical consumer; a drive part for Driving the electrical consumer according to that Control unit signal; a recognition part with a Rectifier that works with the electrical consumer is connected in parallel, and a contactless switch, which is controlled by the rectifier, the  Detection part for recognizing whether the drive part powered electrical consumer works properly or does not serve; and a display part for displaying one of the result of the detection part.

Here the contactless switch is one of the rectifier optocoupler switched on / off.

The recognition part sends the result to the control part and the display part is controlled by the control part.

According to the present invention, the recognition part recognized whether an electrical consumer is working correctly or not, and the result of the detection is determined by the Display part shown. Thus, a user can Operating state of the electrical consumer easily determine. Furthermore, according to the present Invention of the structure of the self-checking device simple because the self-checking facility is just one Rectifier and a contactless switch.

An embodiment of the invention is shown below explained in more detail with reference to the drawing. Show it:

Fig. 1 is a block diagram of a control device of a refrigerator with a self-checking device according to the present invention;

Fig. 2 is a partially cutaway view of an ordinary refrigerator; and

Fig. 3 is a block diagram of a control device of a conventional refrigerator.

The present invention will be described below in detail with reference to the drawings. The parts that are the same as those in the conventional refrigerator shown in Fig. 1 are not described and are given the same reference numerals.

As shown in FIG. 1, the refrigerator has a key input part 30 for inputting operation commands, and a microprocessor 32 for controlling various electrical loads according to the input to the key input part 30 commands. Furthermore, the refrigerator has a plurality of drive parts 33 , 36 and 38 which are controlled by the microprocessor 32 . The drive parts 33 , 36 and 38 are each connected to the electrical consumers 34 , 36 a and 38 a, such as. B. the compressor 14 and the blower 10 , which are shown in Fig. 2.

Like the control device of the conventional refrigerator shown in FIG. 3, the first drive part 33 has an inverter INV2 for inverting a signal from the microprocessor 32 and a relay RY2 connected to the output terminal of the inverter INV2. The relay RY2 controls the current source AC connected to the electrical consumer 34 . The second drive part 36 and the third drive part 38 have the same structure as the first drive part 33 .

A first detection part 35 is connected to the electrical consumer 34 driven by the first drive part 33 . The first detection part 35 detects whether the electrical consumer 34 is operating regularly or not.

The first detection part 35 comprises a rectifier, which consists of a resistor R4 and a diode D1, and an optocoupler PT1 controlled by the rectifier. As shown in the figure, the optocoupler PT1 comprises a light-emitting diode and a phototriac. One end of the phototriac is connected to a power supply Vcc through a resistor R5, and the other end thereof is grounded. Resistor R5 is also connected to microprocessor 32 . When a current flows through the rectifier, the light emitting diode in the optocoupler PT1 emits light and the phototriac is thereby switched on. The light-emitting diode and the phototriac isolate the first drive part 33 and the first detection part 35 from one another, as a result of which the influence between the first drive part 33 and the first detection part 35 is eliminated. As a result, the detection is more precise.

The electrical consumer 36 a driven by the second drive part 36 is connected to a second detection part 37 , and the electrical load 38 a driven by the third drive part 38 is connected to a third detection part 39 . The second and third detection parts 37 and 39 also have the same structure as the first detection part 35 .

A display part 31 for displaying the results of the detection performed by the detection parts 35 , 37 and 39 is connected to the microprocessor 32 . The display part 31 consists of resistors R1, R2 and R3 and respectively connected light-emitting diodes LED1, LED2 and LED3. Each of the light emitting diodes LED1, LED2 and LED3 corresponds to each of the detection parts 35 , 37 and 39 .

Below is the operation of the refrigerator with the self-checking facility according to the present Invention described.

A user inputs various commands via the key input part 30 , such as e.g. B. a desired temperature for the cooling chamber 3rd The microprocessor 32 sends control signals to the respective drive parts 33 , 36 and 38 in order to control the electrical loads 34 , 36 a and 38 a in accordance with the command entered.

As long as the microprocessor 32 is not sending a control signal, the relay RY2 is switched off and the electrical consumers 34 , 36 a and 38 a are therefore not supplied with electrical current from the current source AC. In addition, with each of the electrical loads 34, 36 a and 38 connected diodes D1 also not supplied with electric current and therefore the phototriacs are turned off in the optical couplers PT1. As a result, each of the power supplies Vcc of the detection parts 35 , 37 and 39 feeds a high level signal to the terminals P ₁₁ , P ₁₂ and P _{13 of} the microprocessor 32 .

When the microprocessor 32 sends a high level signal to the first drive part 33 via the terminal P ₁₀ , the inverter INV2 inverts it to a low level signal and feeds the inverted signal into the relay RY2. Then the electrical consumer 34 is supplied with alternating current from the current source AC and begins to work. The alternating current fed into the electrical consumer 34 is also fed into the diode D1, which is connected in parallel with the electrical consumer 34 , whereby the phototriac in the optocoupler PT1 is switched on. As a result, the power supply Vcc in the first detection part 35 is grounded by the phototriac in the optocoupler PT1, and thereby a low level signal is input to the terminal P _{11 of} the microprocessor 32 .

Meanwhile, if the electrical consumer 34 for any reason such as. B. a malfunction of the relay RY2 does not work regularly, even if the control signal from the microprocessor 32 is sent correctly, the diode D1 is not supplied with current and therefore the phototriac in the optocoupler PT1 is switched off and a signal with a high level is in the terminal P _{11 of} the microprocessor 32 is fed by the power supply Vcc. As a result, the microprocessor 32 detects the malfunction of the electrical consumer 34 .

The microprocessor 32 sends a display signal to the display part 31 via the connection P _{03 in} order to switch on the first light-emitting diode LED1. The user can determine by the LED LED1 whether the electrical consumer 34 is working correctly or not.

The function of the second detection part 37 and the third detection part 39 is the same as that of the first detection part 35 . If the second and third detection parts 37 and 39 detect malfunctions of the corresponding electrical consumers 36 a and 38 according to the same function, the display part 31 consequently indicates this by means of the light-emitting diodes LED2 and LED3.

In the present embodiment, the diode D1 is connected in parallel with the electrical load 34 , but the diode D1 can be connected to an internal circuit of the electrical load 34 . According to such a construction, a malfunction of the electrical consumer 34 , which occurs when the electrical consumer 34 itself is malfunctioning, can be recognized.

Meanwhile, in the present embodiment, the Optocoupler PT1 used as a switch, which of the Rectifiers can be controlled, but there can be one Variety of contactless switches such. B. a ordinary contactless relay can be used.

According to the present invention, the Detection parts recognized whether different electrical Consumers work properly or not and the result the detection is indicated by the display part. Consequently  the user can see the operating state of the electrical Easily identify consumers. In addition, according to of the present invention, the structure of the self-checking Setup simple as the self-checking facility just a rectifier and a contactless one Has switch.

Claims (4)

1. Fridge with:
a control part ( 30 , 32 ) for generating a signal for controlling an operation of an electrical consumer ( 34 ; 36 a; 38 a);
a drive part ( 33 ; 36 ; 38 ) for driving the electrical consumer ( 34 ; 36 a; 38 a) in accordance with the signal of the control part ( 30 , 32 );
a detection part ( 35 ; 37 ; 39 ) with a rectifier (R4, D1) which is connected in parallel with the electrical load ( 34 ; 36 a; 38 a), and a contactless switch (PT1) which is connected by the rectifier (R4 , D1) is controlled, the detection part ( 35 ; 37 ; 39 ) being used to detect whether the electrical consumer ( 34 ; 36 a; 38 a) driven by the drive part ( 33 ; 36 ; 38 ) is operating correctly or not; and
a display part ( 31 ) for displaying a result determined by the recognition part ( 35 ; 37 ; 39 ). 2. The refrigerator of claim 1, wherein the contactless Switch on from the rectifier (R4, D1) optocoupler (PT1) is switched on / off.   3. A refrigerator according to claim 1 or 2, wherein the detection part ( 35 ; 37 ; 39 ) sends the result to the control part ( 30 , 32 ) and the display part ( 31 ) is controlled by the control part. 4. Refrigerator according to one of claims 1 to 3, wherein the display part ( 31 ) comprises a light emitting diode (LED1; LED2; LED3).