KR20000002696U - Refrigeration defrosting device - Google Patents

Abstract

The present invention relates to a defrosting operation apparatus of a refrigerator, and an object of the present invention is to provide a defrosting operation apparatus of a refrigerator capable of performing normal defrosting operation when an error occurs due to disconnection of a temperature fuse or defective contact of a relay. The present invention has a third relay (RY3) having one side connected to the power input terminal (AC) and the other side connected to the defrost heater (H), and a power state detection unit for detecting whether drive power is supplied to the defrost heater (H). 30 and the second relay RY2 are connected to drive the refrigerator P to perform the refrigeration and freezing operation according to the operation control program, and the defrost heater H is connected by connecting the first relay RY1 during the defrosting operation. The microcomputer that supplies the driving power to the defrost heater H by supplying driving power to the defrost heater H by connecting the third relay RY3 when the temperature sensor TH and the first relay RY1 are in an abnormal state. (20) is provided. Therefore, the present invention can perform a defrosting operation to heat the defrosting heater in accordance with the defrosting operation cycle is normal, there is an effect that can prevent the deterioration of the food stored by the incorrect defrosting operation.

Description

Refrigeration defrosting device

The present invention relates to a defrosting operation device of a refrigerator, and in particular, normal defrosting operation in case of an error due to disconnection of a temperature fuse or a failure of a contact of a relay by supplying and interrupting driving power through a separate switching element provided between a power input terminal and a defrost heater. It relates to a defrosting operation device of a refrigerator to perform.

In general, the electronic refrigerator performs defrosting operation to remove frost generated in the evaporator and performs refrigeration and freezing operation smoothly without deteriorating cooling efficiency. Such defrosting operation is performed according to an operation control program provided in the microcomputer. That is, the microcomputer controls the temperature inside the freezer compartment and the refrigerating compartment by driving the compressor in consideration of the temperature difference between the internal temperature sensed by the temperature sensor and the set temperature set by the user. At this time, the microcomputer accumulates the operation time according to the operation of the compressor using the built-in timer, and when the integration time reaches the defrost operation time, the decompression operation is performed by driving a defrost heater installed adjacent to the evaporator. An example is shown in FIG. 1.

1 is a configuration diagram of a defrosting operation apparatus of a refrigerator according to the prior art. As shown, the conventional defrosting operation apparatus of the refrigerator includes a first relay RY1 for supplying or cutting off driving power from the power input terminal AC to the defrosting heater H, and for shutting off the driving power when an overvoltage is introduced. A temperature fuse (F), a defrost heater (H) installed adjacent to the evaporator and generating heat during defrosting operation, and a temperature sensor (TH) for detecting a temperature of the evaporator by the heat of the defrost heater (H), The second relay RY2 for supplying the driving power from the power input terminal AC to the compressor P, the compressor P for discharging the refrigerant of high temperature and high pressure, and the operation control program for performing the refrigeration refrigerating operation. The compressor P is driven by connecting two relays RY2 and the operating time of the compressor is accumulated through an internal timer. When the set defrosting operation time is reached, the first relay RY1 is connected to the defrost heater H. To operate the defrosting operation Provided with a microcomputer 10 for control.

In the prior art having such a configuration, the microcomputer 10 drives the compressor P according to the temperature difference between the high internal temperature and the set temperature, circulates the refrigerant according to a normal refrigerant cycle, and adjusts the high internal temperature, while the compressor integrated in the timer. When the operation time of (P) reaches the preset defrosting operation time, the first relay RY1 is connected to start the defrosting operation. Accordingly, the defrost heater H receives the driving power through the first relay RY1 and the temperature fuse F and generates heat. When the defrost heater H generates heat and removes the frost formed on the evaporator, the microcomputer 10 recognizes the temperature of the evaporator through the temperature sensor TH and determines that the set evaporator temperature is reached. ) To stop the heating operation of the defrost heater (H). That is, the microcomputer 10 may perform the defrosting operation by controlling the opening / closing operation of the first relay RY1 connected between the power input terminal AC and the defrost heater H.

This conventional defrosting operation method will be described with reference to FIG. First, the microcomputer 10 determines whether the operation time of the compressor P accumulated through the internal timer is a set defrosting operation time (step 101). In step 101, when the integration time of the timer is not the defrosting operation time, the control unit returns to the start stage. When the integration time of the timer is the defrosting operation time, a predetermined relay control signal is applied to perform the defrosting operation. And the second relay RY2 are outputted to connect the first relay RY1 and the second relay RY2 is opened (step 102). Thereafter, the microcomputer 10 determines whether the temperature of the evaporator detected by the temperature sensor TH is greater than or equal to a set temperature of the evaporator set to stop the defrosting operation (step 103). In step 103, if the detected temperature of the evaporator is not equal to the set temperature of the evaporator, the process returns to step 102. If the detected evaporator temperature is equal to or larger than the set evaporator, the predetermined relay control signal is transmitted to the first relay RY1. The first relay RY1 is opened to stop the defrosting operation (step 104). Thereafter, the microcomputer 10 determines whether the set idle time has elapsed (step 105). If the set idle time has not elapsed, the microcomputer 10 performs the refrigeration and freezing operation according to the operation control program (step 106).

However, in the defrosting operation apparatus of the refrigerator according to the related art, when the driving power is not applied to the defrost heater H because the contact failure or the temperature fuse F of the first relay RY is disconnected, the microcomputer 10 is not recognized. The normal defrosting operation could not be performed. That is, the microcomputer 10 applies the relay control signal for starting the defrosting operation to the first relay RY1 and performs the defrosting operation until the temperature of the evaporator detected by the temperature sensor TH reaches the set temperature. In this case, natural defrosting is performed for a long time in a state in which the heating operation of the defrost heater TH is stopped due to an abnormal state of the first relay RY and the temperature fuse F. FIG. As a result, the microcomputer 10 performs the defrosting operation based on the temperature of the evaporator elevated by the natural defrosting through the temperature sensor TH, so that the stored foods in the refrigerator are melted or deteriorated by the natural defrosting.

The present invention is to solve the above problems, an object of the present invention is to provide a defrosting operation apparatus of the refrigerator to perform the normal defrosting operation in the event of an error due to disconnection of the temperature fuse or defective contact of the relay.

1 is a configuration diagram of a defrosting apparatus of a refrigerator according to the prior art,

2 is an operation flowchart showing a defrosting operation method applied to a defrosting operation apparatus of a refrigerator according to the prior art;

3 is a configuration diagram of a defrosting operation device of a refrigerator according to the present invention,

Figure 4 is an operation flow diagram showing a defrosting operation method applied to the defrosting operation apparatus of the refrigerator according to the present invention.

* Explanation of symbols for the main parts of the drawings *

10, 20: micom 30: power state detection unit

F: Temperature fuse H: Defrost heater

P: Compressor TH: Temperature Sensor

An object of the present invention as described above is a first relay connected to the power input terminal to supply and cut off the driving power, a temperature fuse connected to the first relay to cut off the power, a defrost heater that generates heat during defrost operation, and A temperature sensor that senses a temperature caused by the heating of the defrost heater, a second relay which is connected to a power input terminal separately from the first relay, and supplies and cuts off the driving power, and a compressor that receives the driving power through the second relay A defrosting operation apparatus of a refrigerator comprising: an opening / closing element connected to one side of the power input terminal and the other side of the defrost heater to supply or cut driving power to the defrost heater; A power state detection unit connected to a connection point of the switching element and the defrost heater to detect whether driving power is supplied to the defrost heater; And a first relay connected to the defrost heater during the defrosting operation, and a compressor connected to the second relay during the refrigeration operation to drive the compressor, and in accordance with the sensing operation of the power state detection unit. It is achieved by a microcomputer that recognizes the abnormal state of the first relay and controls the opening and closing operation of the switching element.

The present invention provides a switchgear between the power input terminal and the defrost heater in case a normal defrosting operation cannot be performed because the driving power is not applied to the defrost heater due to the disconnection of the temperature fuse connected to the power input terminal or the contact failure of the first relay. To prepare. These switching elements are operated in a connected state and an open state so as to supply or cut off driving power. In this embodiment, although a relay is used, a triac or thyristor capable of performing an equivalent function is provided. Can be used.

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

3 is a configuration diagram of a defrosting operation control apparatus for a refrigerator according to the present invention, the same reference numerals are assigned to the components having the same function as the conventional. As shown, the present invention is the first relay (RY1) for supplying or cutting off the driving power from the power input terminal (AC) to the defrost heater (H), and the temperature fuse (F) for cutting off the driving power when inflow of overvoltage And a defrost heater (H) installed adjacent to the evaporator and generating heat during defrosting operation, a temperature sensor (TH) for sensing the temperature of the evaporator by the heat of the defrost heater (H), and a power input terminal (AC). And a second relay RY2 for supplying the drive power from the compressor to the compressor P, and a compressor P for discharging the refrigerant having a high temperature and high pressure. In addition, the present invention is a power supply state that detects whether one side is connected to the power input terminal (AC) and the third relay (RY3) connected to the defrost heater (H) and the drive power supply to the defrost heater (H) In order to perform the refrigeration and freezing operation according to the operation control program, the detection unit 30 is connected to the second relay RY2 to drive the compressor P, and the first relay RY1 is connected to the defrost heater in the defrosting operation. In addition to supplying the driving power to H) and in the abnormal state of the temperature sensor TH and the first relay RY1, the driving power is supplied to the defrost heater H by connecting the third relay RY3. A microcomputer 20 is provided.

The power state detecting unit 30 includes a phototransistor PT including a light emitting unit and a light receiving unit, a resistor R connected to a light emitting unit of the phototransistor PT, and a diode D connected in series with the resistor R. ) When the driving power is input to the defrost heater H, the phototransistor PT has a power supply frequency (for example, 50 Hz or less) as a closed circuit is formed by the light emitting unit, the resistor R, and the diode D. The square wave corresponding to 60 Hz) is output to the microcomputer 20, but the driving wave is not output to the defrost heater H when the driving power is not input.

The microcomputer 20 recognizes that the square wave is input from the power state detection unit 30 to perform normal defrosting operation. If the square wave is not input from the power state detection unit 30, the microcomputer 20 performs normal defrosting operation. It is perceived as inoperable.

It describes the effect of the defrosting operation device of the refrigerator according to the present invention configured as described above.

The microcomputer 20 performs the refrigeration operation according to the pre-stored operation control program. That is, the microcomputer 20 drives the compressor P according to the temperature difference between the internal temperature detected by the internal temperature sensor and the set temperature set by the user. Controls the operation of adjusting the internal temperature. In addition, the microcomputer 20 accumulates the operation time of the compressor P using a timer provided therein, and stops the operation of the compressor P when the integration time reaches the defrosting operation time. The defrosting operation for driving the defrost heater H is performed. At this time, the microcomputer 20 outputs a predetermined relay control signal to the first relay RY1 and the second relay RY2 to connect the first relay RY1 and at the same time the second relay RY2. Will open. Accordingly, the defrost heater H generates heat by being supplied with driving power through the first relay RY1 and the temperature fuse F, and removes the frost formed on the evaporator. Thereafter, the microcomputer 20 supplies a driving power to the defrost heater H through the first relay RY1 to perform a defrosting operation, and thus the temperature of the evaporator detected by the temperature sensor TH1 is increased. When the temperature of the set evaporator reaches or when the driving time of the defrost heater H integrated in the timer is equal to or greater than the set defrosting operation time, a predetermined relay control signal is output to open the first relay RY1.

In addition, when the integration time of the timer reaches the defrosting operation time in a state in which the square wave is not input from the power state detection unit 30, the microcomputer 20 supplies the driving power through the third relay RY3. The defrosting operation is performed by supplying the defrost heater H. That is, when the driving power is not input to the defrost heater H due to the disconnection of the temperature fuse F or the contact failure of the first relay RY1, the microcomputer 20 outputs a predetermined relay control signal to the third relay. Output to (RY) to connect the third relay (RY). Accordingly, the defrost heater H receives the driving power from the power input terminal AC through the third relay RY and generates heat to remove defrost formed on the evaporator. The microcomputer 20 is an evaporator in which the temperature of the evaporator detected by the temperature sensor TH1 is set in a state in which driving power is supplied to the defrost heater H through the third relay RY3 to perform defrosting operation. When the temperature is reached or when the driving time of the defrost heater H integrated in the timer is equal to or greater than a predetermined time, a predetermined relay control signal is output to open the third relay RY1.

Hereinafter, the defrosting operation method according to the present invention will be described in detail with reference to FIG. 4.

First, the microcomputer 20 determines whether the operation time of the compressor P accumulated through the internal timer is a set defrosting operation time (step 201). As a result of the determination in step 201, when the integration time of the timer is not the defrosting operation time, the control unit returns to the start step, while when the integration time of the timer is the defrosting operation time, a predetermined relay control signal is applied to perform the defrosting operation. ) And the second relay RY2 are connected to each other to connect the first relay RY1 and to open the second relay RY2 (step 202). Thereafter, the microcomputer 20 determines whether the square wave corresponding to the power frequency of the driving power is input from the power state detection unit 30 (step 203). As a result of the determination in step 203, when there is no input of the square wave from the voltage state detecting unit 30, that is, the defrost heater H is disconnected due to the disconnection of the temperature fuse F or the contact failure of the first relay RY1. When no driving power is supplied to the controller, a predetermined relay control signal is output to the first relay RY1 and the third relay RY3 to open the first relay RY1 and at the same time the third relay RY3. (Step 204). As a result of the determination in step 203, when there is a square wave input from the voltage detector 30 or when step 204 is performed, the microcomputer 20 performs the defrosting operation of the temperature of the evaporator detected by the temperature sensor TH. It is determined whether or not the set temperature of the evaporator set to stop (step 205). As a result of the determination in step 205, if the detected temperature of the evaporator is not equal to the set temperature of the set evaporator, it is determined whether the driving time of the defrost heater H integrated in the timer is equal to or greater than the set time (step 206). As a result of the determination in step 206, if the driving time of the defrost heater H integrated in the timer is not more than the set time, the flow returns to step 202, while the driving time of the defrost heater H integrated in the timer is set. If the time exceeds or if the temperature of the evaporator detected in step 205 is greater than the set temperature of the set evaporator, the microcomputer 20 generates a predetermined relay control signal to cut off the driving power supplied to the defrost heater (H). The defrosting operation is stopped by outputting the first relay RY1 or the third relay RY3 (when an error occurs) and opening the first relay RY1 or the third relay RY3 (step 207). . Thereafter, the microcomputer 20 determines whether the set idle time has elapsed (step 208). If the set idle time has not elapsed as a result of the determination of step 208, the microcomputer 20 performs the refrigeration refrigerating operation according to the operation control program (step 209) and ends.

As described above, the present invention recognizes an error caused by the disconnection of the temperature fuse or the contact failure of the relay according to the state of the driving power supplied to the defrost heater, and supplies the driving power through a switch unit separately provided between the power input terminal and the defrost heater. Therefore, the defrosting operation of heating the defrost heater according to the defrosting operation cycle can be normally performed, thereby preventing the deterioration of the stored foods due to the incorrect defrosting operation.

Claims (3)

A first relay connected to a power input terminal to supply and cut off driving power, a temperature fuse connected to the first relay to cut off power, a defrost heater that generates heat during defrosting operation, and a temperature caused by heat of the defrost heater Defrosting apparatus of a refrigerator having a temperature sensor for sensing, a second relay connected to a power input terminal separately from the first relay to supply and cut off driving power, and a compressor supplied with driving power through the second relay To An opening and closing element connected at one side to the power input terminal and connected at the other side to the defrost heater to supply or cut driving power to the defrost heater; A power state detection unit connected to a connection point of the switching element and the defrost heater to detect whether driving power is supplied to the defrost heater; And In the defrosting operation, a first relay is connected to supply driving power to the defrost heater, and during a refrigeration operation, a second relay is connected to drive a compressor, and the temperature sensor and the And a microcomputer for recognizing an abnormal state of the first relay and controlling the opening and closing operation of the switching element. The apparatus of claim 1, wherein the switching element is a relay, a triac, or a thyristor. The refrigerator according to claim 1, wherein the power state detection unit comprises a phototransistor comprising a light emitting unit and a light receiving unit connected to the connection point, a resistor connected to the light emitting unit of the phototransistor, and a diode connected in series with the resistor. Defrosting device.