KR19980083069A - How to control the automatic ice maker of the refrigerator - Google Patents

Abstract

The present invention relates to a method of controlling an automatic ice maker of a refrigerator. An ice-making operation for intensively discharging strong cold air to a freezer compartment by supplying an appropriate amount of water to an ice-making container of an automatic ice maker; After depressing for 40 minutes, the compressor operation judging process determines whether the compressor is turned off twice in the ice making time, and if the compressor turns off twice during the ice making time as a result of judging from the compressor operation judging process, The first ice and water supply operation to separate water from the mold and supply water to the separated mold, and if the compressor determines that the compressor is not turned off twice during the ice-making period, Ice ice temperature determination process to determine whether the temperature is below 12.5 degrees below zero, and the result of judging from this ice making temperature determination process When the ice is judged to be below 12.5 degrees below zero, the ice is separated from the mold and the second ice and water supply process is provided to supply water to the separated mold to detect the number of times the compressor is turned off according to the ice making operation. When the number of times is two times, it is reported that the ice making operation is completed and the ice making operation is immediately performed without sensing the ice temperature, so that consumers can secure the reliability according to the operation of the ice maker.

Description

How to control the automatic ice maker of the refrigerator

The present invention relates to a method for controlling an automatic ice maker of a refrigerator. In particular, in an automatic ice maker installed in a freezer compartment, the compressor has an off frequency of 2 or more times for 2 hours and 40 minutes after water supply, or the temperature measured by an eye sensor (I) is below -12 ° C. The present invention relates to a method of controlling an automatic ice maker of a refrigerator which determines that the ice making operation is completed and performs the ice making operation quickly.

In general, as shown in FIG. 1, the refrigerator main body is insulated on all surfaces except the front surface and partitioned into the freezing compartment 14 and the refrigerating compartment 16 by the partition wall 12. 14) and the front doors of the refrigerating chamber 16 are provided with hinge shafts, respectively. The rear side of the freezer compartment 14 is provided with a cooler 22 that absorbs the surrounding heat to obtain a cooling effect, the upper portion of the freezer compartment 14 through the multi duct 26 mounted on the rear side of the freezer compartment 14. The refrigerator compartment circulation fan 28 to supply is provided. In addition, a circulation passage 34 having cold air suction ports 30 and 32 in the circumferential wall 12 between the freezing chamber 14 and the refrigerating chamber 16 to circulate the cold air of the freezing chamber 14 and the refrigerating chamber 16. 36 are formed, respectively.

That is, in the refrigerator having such a structure, the freezer compartment and the refrigerating compartment circulation fans 24 and 28 are driven to supply air cooled by the cooler 22 to the freezer compartment 14 and the refrigerating compartment 16, respectively. At this time, since the cold air is discharged from the rear side of the freezer compartment 14 and the refrigerating compartment 16 toward the front side, the food stored in the freezer compartment 14 and the refrigerating compartment 16 is frozen or kept fresh and the partition wall 12 The cold air suction ports 30 and 32 and the circulation passages 34 and 36 return to the cooler 22 side and continuously circulate.

Therefore, the freezer compartment 14 is maintained at -18 ℃ to be stored in a frozen state for a long time, the refrigerating chamber 16 is to be maintained at 0 ℃ to 9 ℃ to store up to fish or meat as well as vegetables. In addition, in the freezing chamber 14, an automatic ice maker is installed according to a product to make ice by a certain operation. Looking at the ice making process, an ice making operation for ice-making water supplied to an ice making machine by cold air, and this ice making operation Ice removal operation to remove ice frozen under a certain temperature in a constant ice making container, water supply operation to supply a predetermined amount of water to the ice making container again by this ice making operation, and an appropriate amount of water filled in the ice making container by this water supply operation. It consists of a water supply check operation process to detect the continually iteratively perform this operation. In this case, when the water supplied to the ice making machine of the automatic ice maker performs the ice making operation, the temperature of the ice measured by the eye sensor (I) is less than 2 hours and 40 minutes after the ice making operation is completed. If it is judged to be below 12.5 ℃, the next operation, the ice-making operation, is performed to prevent an error due to the ice-making operation without ice.

That is, in the control method of the conventional automatic ice maker, as shown in FIG. 2, the initialization state S21 to which the driving power of the refrigerator is applied proceeds to an appropriate amount supply determination step S22. Then, if it is determined that the appropriate amount of water is supplied to the ice making container of the automatic ice maker, as determined in the appropriate supply supply determination step (S22), the process proceeds to the ice making operation step (S23). At this time, in the ice making operation S23, cold air is intensively discharged toward the ice making container supplied with a predetermined amount of water, and the process proceeds to the ice making time determining step S24. Then, when it is determined that the ice making operation time has elapsed for 2 hours and 40 minutes as determined by the ice making time judging step (S24), the process proceeds to the ice temperature judging step (S25). Then, if it is determined in the ice temperature determination step (S25) that the temperature of the ice in the ice-making container is below 12.5 degrees below zero, it is to proceed to the ice-making operation step (S26). Therefore, in this ice-making operation (S26), the ice is removed from the ice-making vessel by axial rotation along with the operation of twisting the ice-making vessel and proceeds to the rewatering operation (S27). At this time, the rewatering operation step (S27) is to supply water to the empty ice making container and return to the appropriate water supply determination step (S22) to repeat the loop repeatedly.

On the other hand, if it is determined that the appropriate amount of water is not supplied to the ice making container as determined in the appropriate supply determination step (S22), the loop of the present ice making operation is terminated. In addition, if it is determined in the ice temperature determination step S25 that the ice temperature does not fall below 12.5 degrees, the ice making operation is terminated. When it is determined in the ice making time determination step S24 that the ice making operation time has not elapsed for 2 hours and 40 minutes, the process returns to the ice making operation S23 and repeats the loop.

However, in order to perform the deicing operation in the de-icing operation in the conventional automatic ice maker, the de-icing completion condition must be satisfied, that is, the ice making time satisfies the condition of the ice making temperature below minus 12.5 degrees after 2 hours and 40 minutes. Especially, in the summer, the door of the refrigerating compartment is frequently opened or the defrosting mode may not meet the ice making condition during the defrost mode operation. Therefore, even though the ice was sufficiently iced, there was a problem of stopping the operation of the automatic ice maker.

Therefore, the present invention has been devised to solve such a problem, and detects the on / off operation of the compressor for 2 hours and 40 minutes, which is an ice making time after supplying a certain amount of water to the automatic ice maker, and detecting the number of times the compressor is turned off twice. If the temperature of the ice detected by the eye sensor (I) is below 12.5 degrees, the automatic ice maker control method of the refrigerator can be recognized as the completion of the ice making operation and the ice making operation can be performed to maximize the ice making ability. The purpose is to provide.

In order to achieve the above object, the present invention provides an ice making operation for intensively discharging strong cold air to a freezer compartment by supplying an appropriate amount of water to an ice making container of an automatic ice making machine, and supplying the feed to the ice making container for 2 hours and 40 hours. Decompression process for determining whether the compressor is turned off twice in the ice making time after 2 minutes of deicing, and if it is determined that the compressor is turned off twice during the ice making time, the ice making is determined The first ice and water supply operation, which is separated from the container and supplies water to the ice making container, and when the compressor operation is judged not to be performed twice during the ice making period, as determined by the compressor operation determination process, the temperature of the iced ice is The ice making temperature judging process determines whether it is below 12.5 degrees below zero and the ice making resulted from this ice making temperature judging process. If the ice is less than 12.5 degrees, the ice is separated from the ice making container, and the second ice and water supply operation to supply water to the ice making container and the ice making temperature judging process determine that the ice is not below 12.5 degrees. If so, characterized in that the error message output process for displaying an error message according to the inability to make ice.

1 is a side cross-sectional view showing the configuration of a typical refrigerator.

Figure 2 is a flow chart showing the operation of the automatic ice maker installed in the refrigerator in general.

Figure 3 is a block diagram illustrating the operation of the automatic ice maker according to the present invention.

4 is a flowchart illustrating the operation of the automatic ice maker according to the present invention.

<Explanation of symbols for main parts of drawing>

1: microcomputer 2: f sensor

3: water supply detection unit 4: eye sensor

5: sensor 6: moving motor

7: water motor 8: F-pan

9: Al fan 10: Compressor

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

The configuration according to the present invention is largely as shown in Figure 3, the sensor unit for outputting a signal detected by the various sensors installed in the refrigerator, and receives the signals sensed from the sensor unit to perform the overall control of the refrigerator It consists of a microcomputer (1) and a variety of driving unit that is operated by receiving the driving power according to the control signal of the microcomputer (1).

Here, the sensor unit is installed in the freezer compartment of the F (F) sensor (2) for sensing the temperature, the R (5) sensor (5) installed in the upper right of the refrigerating compartment for detecting the temperature in the refrigerator, and the ice maker of the ice maker It consists of a water supply detection unit (3) for detecting the water supplied to the eye (I) sensor (4) installed in the ice making container of the ice maker to detect the temperature of the ice making.

In addition, the drive unit operates the compressor 9 to perform an operation by a refrigeration cycle according to the control signal of the microcomputer 1, and the freezer compartment to maintain an appropriate temperature by absorbing the internal temperature of the cooler according to the operation of the compressor 9. In the F (F) fan 8, the refrigerating chamber (R) fan (9) that operates to maintain the proper temperature, the water supply motor (7) that operates to supply water to the ice making vessel of the ice maker, and in the ice making vessel It consists of an ice motor 6 which operates to remove ice.

On the other hand, look at the operation of the air curtain refrigerator having such a configuration as follows.

First, as the power of the refrigerator is applied, the compressor 9 performs an operation according to the refrigeration cycle, and thus the cooler not shown absorbs heat in the refrigerator. In other words, the F fan 8 and the egg fan 9 are operated under a constant driving power in such a state that the air cooled by the cooler is supplied to each freezer compartment and the refrigerating compartment to maintain a constant temperature. As a result, the food in the refrigerator is stored and at the same time, the automatic ice maker installed at one side of the freezer compartment receives a certain amount of water and repeatedly performs the ice making operation, the ice making operation, and the water supply operation. It is stored in a container. That is, the water supply motor 7 is operated in accordance with the control signal of the microcomputer 1, thereby supplying water to the ice making container. At this time, the water supply detecting unit 3 detects the amount of water supplied to the ice making container and applies the signal to the microcomputer 1. Then, the microcomputer 1 stops the operation of the water supply motor 7 when it is determined that the proper amount of water is supplied by the signal output from the water supply detecting unit 3. As the compressor 10 and the F fan 8 are driven according to the predetermined control signal of the microcomputer 1, strong cold air is discharged to the ice maker, which is called an ice making operation. Here, the microcomputer 1 checks the time of the ice making operation and checks the number of times the compressor 10 is turned off when a predetermined time according to the ice making operation has elapsed. That is, when it is determined that the compressor 10 repeatedly turns on and off the operation twice during the 2 hours and 40 minutes of the ice making time, the microcomputer 1 reports that the ice making is completed and the ice motor 6 is completed. It is to apply a constant driving power to. In addition, if the compressor 10 is not turned off twice within the set time, the microcomputer 1 receives a predetermined value corresponding to the temperature of the ice detected by the eye I sensor 4. Therefore, the microcomputer 1 applies the driving power to the moving motor 6 when the temperature of the ice sensed by the I sensor 4 is less than or equal to 12 degrees below zero.

That is, the control method of the ice making operation of the refrigerator according to the present invention is as follows.

First, the initialization state (S1) to which the drive power of the refrigerator is applied proceeds to the appropriate supply determination step (S2). Then, if it is determined that the appropriate amount of water is supplied to the ice making container of the automatic ice maker, the determination is made in the appropriate supply supply determination step (S2). At this time, in the ice making operation (S3), the strong cold air is intensively discharged toward the ice making container supplied with a predetermined amount of water, and the ice making time determination step (S4) is performed. Then, if it is determined in the ice making time determination step S4 that the ice making operation time has elapsed for 2 hours and 40 minutes, the process proceeds to the compressor operation determining step S5. Therefore, if it is determined that the number of times the compressor has been turned off twice during the set time of the result determined in the compressor operation judging step S5, the process proceeds to the icing operation step S7. Then, in this ice operation step (S7) is to turn the ice making container with the ice making ice and rotate at the same time to remove the ice from the ice making container and proceed to the re-water supply operation step (S8). At this time, the rewatering operation step (S8) is to supply water to the empty ice making container and return to the appropriate water supply determination step (S2) to repeat the loop repeatedly.

On the other hand, if it is determined in the compressor operation determination step (S5) that the number of times of turning off the compressor within the set time is not two times, the process proceeds to the ice temperature determination step (S6). Then, if it is determined in the ice temperature determination step (S6) that the temperature of the ice in the ice making container is less than 12.5 degrees below zero, it proceeds to the ice-making operation (S7). In addition, if it is determined in the ice temperature determination step (S6) that the temperature of the ice detected by the eye sensor (I) is not less than 12 degrees below zero, the process proceeds to the error display step (S9) and the current automatic deicing state Will exit the loop.

On the other hand, if it is determined in the ice making time determination step S4 that the ice making time has not elapsed for 2 hours and 40 minutes, the process returns to the ice making operation S3 and repeats the loop. And if it is determined that the appropriate amount of water is not supplied to the ice making container of the automatic ice maker as determined in the appropriate supply supply determination step (S2) is to terminate the loop of the automatic ice making operation.

In the refrigerator equipped with the automatic ice maker, the ice maker may stop when the ice maker is not below 12.5 degrees even though the ice is sufficiently frozen during the frequent opening and closing of the door or during the defrost mode operation in summer. Detects as the number of times the compressor is off according to the ice making operation, and when the number is twice, the ice making operation is reported to be completed and the ice making operation is immediately performed without sensing the ice temperature, thereby allowing consumers to secure reliability according to the operation of the ice maker. It can be effective.

Claims (1)

De-icing operation of intensively discharging strong cold air to the freezer compartment by supplying the appropriate amount of water to the ice-making container of the automatic ice-making machine, and de-icing time after defrosting the water supplied to the ice-making container for 2 hours and 40 minutes. The compressor operation judging process for determining whether the compressor is turned off twice, and if the compressor turns off twice during the deicing time, the ice is separated from the ice making container. In the first ice and water supply operation of supplying water to the container and the determination operation of the compressor operation, if it is determined that the compressor is not turned off twice during the ice making operation, it is determined whether the temperature of the ice ice is below 12.5 degrees. Judging by the ice temperature judging process and the judging result of this ice temperature judging process, Second ice and water supply operation of separating the ice from the ice making container and supplying water to the separated ice making container, and if it is determined that the ice is not below 12.5 degrees below the ice temperature judging process, An automatic ice maker control method for a refrigerator, comprising: an error message output process for displaying an error message according to the incapacity.