KR100667211B1 - Apparatus and method of preventing an ice to be tangled for a refrigerator - Google Patents

Abstract

In the present invention, when the defrosting operation is completed and the next cooling operation is performed, or when the user's direct selection button is operated, the motor is rotated in the normal direction so that the ice extraction coil connected to the motor shaft is rotated alternately in the counterclockwise direction and the clockwise direction, You can shuffle the ice on the bottom.

Therefore, according to the present invention, it is possible to prevent the ice from tangling due to melting of a part of the surface of the ice due to the superheated heat, so that the ice is not entangled with the surrounding ice or the ice is not taken out for a long time. The ice can keep its original form and can improve the reliability of the product by allowing the ice to be taken out smoothly in response to the demand of the user.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a device for preventing ice tangle in a refrigerator,

1 is a block diagram of a refrigerator according to the related art,

2 is a block diagram of an apparatus for preventing ice entanglement of a refrigerator according to the present invention,

FIG. 3 is a sectional view showing the internal configuration of a large refrigerator to which the present invention is applied,

4A to 4C are flowcharts illustrating a method for preventing ice entanglement in a refrigerator according to the present invention.

Description of the Related Art [0002]

20: control unit 21: ice-

22: a detecting switch section 23: a temperature sensor section

24: dispenser part 25: defrost timer

26: Defrost heater driving unit 27:

28: step motor driving unit 29:

The present invention relates to an apparatus and a method for preventing ice entanglement in a refrigerator, and more particularly, to an apparatus and method for preventing ice entanglement in a refrigerator in which ice stored in a storage container is prevented from being entangled with each other by driving a motor for ice- will be.

Generally, in a refrigerator, an ice-maker for supplying ice-making water to an ice-making tray and making ice using cool air is installed in the freezing room, and a storage container for storing ice is provided.

In such a refrigerator, the iced ice is usually separated from the ice-making tray using an ice-making apparatus and stored in a storage container, and the water-supply, the ice-making and the ice-making are continuously performed until the storage container is filled with ice.

In addition, when the ice is directly taken out from the storage container by opening the door, the refrigerating efficiency is lowered due to the inconvenience and the outflow of cold air. Therefore, in order to easily draw ice stored in the storage container of the refrigerator, A take-out coil is provided and the coil is rotated by driving the motor to communicate with one side of the storage container, and the ice is pushed into the discharge passage formed on the door side and discharged.

Referring to FIG. 1, a conventional refrigerator includes a control unit 10 for controlling an operation of performing a cooling operation according to the internal temperature and extracting the ice cubes from the door. The controller 10 drives the compressor and the cooling fan according to the internal temperature of the freezer compartment and the refrigerating compartment sensed by the temperature sensor 13 to perform a normal cooling operation. As a result, the cold air generated by the evaporator is supplied to the inside of the refrigerator to keep the refrigerated and refrigerated food at a proper temperature. The control unit 10 turns off the compressor and the cooling fan and turns off the defrost heater driving unit 15 in the same manner as the defrosting operation of the defrosting heater 14 And the defrosting operation is performed in which the defrosting operation of the evaporator is removed by driving the defrost heater.

Meanwhile, when the ice-making is completed through the ice-making sensor unit 11, the controller 10 controls the ice-maker motor driving unit 16 to drive the ice-making motor, and the ice separated from the ice- . When the storage container is filled with ice and the ice-making switch unit 12 is operated, the controller 10 stops the ice-making operation.

When the ice extraction button 18 provided on the door side is operated to take out ice from the storage container, the control unit 10 controls the motor driving unit 17 to drive the ice extraction motor so that the ice extraction coil The ice is discharged to the outside of the door through the discharge passage formed on the door side. When the operation of the ice extraction button 18 is stopped, the control unit 10 stops driving the motor, so that the ice conveyed by the coil is no longer discharged from the storage container. Here, the motor uses a normal motor that is driven in one direction when the power is supplied and stops when the power supply is interrupted.

However, in the refrigerator according to the related art, a portion of the ice on the upper side of the storage container is melted due to the defrosting caused by the defrosting operation. When the cooling operation is performed after that, the melted ice and the surrounding ice are adhered to each other . As a result, they are unable to maintain their original shape and become larger in size as they are entangled with each other. This phenomenon becomes worse as the defrosting operation is performed more frequently. In addition, even when there is no operation for taking out the ice for a long time, the ice pieces are entangled with each other due to the characteristics of ice, and the ice is enlarged into a larger mass.

When the ice is attached to the top of the storage container, the ice detecting switch senses that the ice is filled up to the upper side. Therefore, the ice is stopped and the ice is not supplied to the storage container. There is a problem that the user's dissatisfaction is increased and the reliability of the product is lowered.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide an ice tangle prevention device for a refrigerator which can smoothly take out an ice by driving a motor in a forward and reverse direction, And a method.

According to another aspect of the present invention, there is provided an apparatus for preventing ice entanglement in a refrigerator, An ice extraction coil installed in the reservoir to be able to rotate forward and backward; A motor for rotating the ice extraction coil forward and backward; And the control unit controls the motor so as to rotate the ice extraction coil in the ice extraction mode and rotate the ice extraction coil counterclockwise or reverse in the ice entanglement prevention mode.

According to the present invention, the motor is a stepping motor.

According to the present invention, the ice tangle prevention mode is performed during the cooling operation after the defrosting operation is terminated or is performed by the user's selection.

The method for preventing ice entanglement of a refrigerator according to the present invention as set forth above is a refrigerator having an ice-making tray for ice making and a reservoir for storing ice, and an icemaker provided with an ice extraction coil rotatably installed in the reservoir, To the ice-making tray; An ice making step of performing ice making; An ice-making step of releasing ice-making-finished ice operation into the storage container; And an ice trapping prevention step for preventing ice trapping of the ice stored in the storage container by rotating the ice discharge coil in a direction opposite to the rotation direction of the ice pick-up,

According to the present invention, the ice tangle prevention step is performed during the cooling operation after the defrost operation is completed.

According to the present invention, the ice tangle prevention step is performed by a user's selection.

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

FIG. 2 is a block diagram of an apparatus for preventing ice entanglement of a refrigerator according to the present invention, and FIG. 3 is a sectional view showing the internal structure of a large refrigerator to which the present invention is applied.

As shown in the figure, the present invention is characterized in that the present invention includes a control unit 20 for controlling an operation of supplying ice-making water for de-icing and then de-icing, an operation of taking out ice and an operation of preventing ice tangling, An ice-making sensor unit 21 for detecting ice-making conditions, a ice-making switch unit 22 for detecting ice-filled state in the ice-making container, a temperature sensor unit 23 for sensing the temperature in the ice- An ice-making motor driving unit 27 for driving the ice-making motor so as to separate ice from the ice-making tray, and a stepping motor driving unit 28 for driving the stepping motor And an operation unit 29 provided with a selection button 29a that the user selects to prevent ice entanglement.

The ice making sensor unit 21 outputs an on or off signal to the controller 20 according to the ice making state of the ice making water supplied to the ice tray 31 through the water supply hose 35. The control unit 20 determines whether the ice-making state, that is, whether the ice-making is completed, according to the signal received from the ice-making sensor unit 21.

The ice-making switch unit 22 is provided with an ice-making switch 22a provided on the upper portion of the ice-making container 32. The ice-making switch 22a is turned on and off according to a state in which ice is filled in the ice- And outputs the signal to the controller 20. The control unit 20 determines that the ice is filled in the reservoir 32 according to the signal received from the ice-blocking switch unit 22. [

The temperature sensor unit 23 is provided at a proper position of the freezer compartment F provided on the left side of the refrigerator body to detect a room temperature of the freezer compartment and a temperature sensor for sensing the temperature inside the refrigerator compartment, And outputs a signal sensed by the temperature sensor to the control unit 20. The control unit 20 controls the temperature of the refrigerating room. The control unit 20 drives the compressor P and the cooling fan (not shown) according to the internal temperature sensed by the temperature sensor to perform the cooling operation.

The dispenser unit 24 includes an ice extraction lever 24a provided in the refrigerator door 31 so that the user operates the cup 36 and an ice extraction switch 24b which is turned on and off by the operation of the lever 24a And is for taking out ice when the user brings the cup 36 close to operate the lever 24a.

The defrost timer 25 integrates the operation time of the compressor P and outputs the result to the control unit 20. [ The control unit 20 compares the operation time of the compressor P accumulated through the defrost timer 25 with a predetermined defrost time and if it is the same, controls the defrost heater driving unit 26 to perform the defrosting operation, (Not shown) is turned on to perform an operation of periodically removing the impurities implanted in the evaporator.

The ice-maker motor driving unit 27 drives an ice-making motor 27a that rotates the ice-making tray 33 to drop the ice cubes into the storage container 32.

The step motor driving unit 28 drives the step motor 28a to rotate the ice extraction coil 34 in one direction so as to take out the ice stored in the reservoir 32 out of the door, The drive current is applied so that the ice take-in coil 34 can be reversely rotated in the reverse direction or rotated in the opposite direction for shuffling.

The step motor 28a is constituted by an annular stator having a plurality of salient poles directed toward the periphery of the rotor of the central part. The step motor 28a rotates clockwise or counterclockwise according to the order in which a drive current is applied to the coils wound on the salient pole, Thereby rotating the shaft 28b. An ice extraction coil 34 is connected to the motor shaft 28b and the ice extraction coil 34 rotates together with rotation of the motor shaft 28b.

This stepping motor 28a may be driven for ice ejection or may be driven to prevent ice entanglement.

When the user activates the ice extraction lever 24a with the cup 36 to take out the ice in the reservoir 32, the ice extraction switch 24b is turned on by the lever 24a and the control unit 20 ). At this time, the controller 20 controls the step motor driving unit 28 to rotate the step motor 28a in one direction in order to take out the ice in the reservoir 32, and by the rotation of the step motor 28a, The ice in the lower part of the storage container 32 is transferred to the ice extraction passage 37 and is taken out of the door and discharged into the cup 36 as the screw-shaped ice extraction coil 34 connected to the ice-

On the other hand, when the operation time of the compressor P reaches the defrosting time, the control unit 20 controls the defrost heater driving unit 26 to turn on the defrost heater to perform the defrosting operation to remove the frost on the evaporator When the defrosting operation is terminated, part of the surface of the upper ice of the ice accumulated in the reservoir 32 is melted by the superheating heat. Thereafter, in the process of performing the cooling operation due to the rise of the internal temperature, the melted ice and the surrounding ice surrounding the ice are tangled with each other.

Accordingly, the controller 20 starts to drive the compressor P to perform the cooling operation again after the defrosting operation is terminated. When the predetermined reference time elapses, the controller 20 drives the step motor 28a in the reverse direction. The step motor driving unit 28 is controlled so that the ice in the reservoir 32 can be shuffled when the melted ice is tangled with each other, that is, when the compressor P is driven for about 5 minutes, 28a in the counterclockwise direction and then makes two revolutions in the clockwise direction in a repetition number of times (for example, twice).

Of course, it is also possible to perform the ice tangle prevention operation by rotating the ice maker in the direction opposite to the rotation direction of the step motor 28a for about two to three times.

As the step motor 28a is driven in the forward and reverse directions, the ice extraction coil 34 connected to the motor shaft 28b also rotates alternately in both directions (clockwise and counterclockwise) so that the ice on the upper side and the ice on the lower side are mixed So that some melted ice and surrounding ice are not tangled with each other, and it is possible to maintain the shape of each ice while deicing.

In addition, in the present invention, when the user operates the select button 29a for preventing ice entanglement provided on the operation unit 29, the control unit 20, which receives the selection signal corresponding thereto, The step motor driving unit 28 may be controlled to forward and reverse the step motor 28a to mix the ice in the reservoir 32. [ In other words, when the temperature of the inside of the room rises due to frequent opening and closing of doors or the like, there is no ice extraction operation for a long period of time and ice of the storage container 32 is tangled with each other.

Hereinafter, an embodiment of a method for preventing ice entanglement of a refrigerator according to the present invention will be described with reference to Figs. 4A to 4C.

FIG. 4A is a flowchart showing a main routine showing the overall control operation of the refrigerator according to the present invention, in which a compressor P is driven to perform a cooling operation (S101), a cooling fan (not shown) (S102).

When the compressor P and the cooling fan are driven to perform the cooling operation, the controller 20 determines whether the incubating switch 22a is turned " on "to determine whether or not the reservoir 32 is full of ice (S103). As a result of the determination, if the detecting switch 22a is turned "on ", the process advances to step S107 without performing the ice making process. If the determining switch 22a is not" A valve (not shown) is opened to allow the ice-making water to be supplied to the ice-making tray 33 through the water supply hose 35 (S104). Then, the ice-making water supplied to the ice-making tray 33 is ice-cooled by circulation of cold air, and the controller 20 receives the signal of the ice-making sensor unit 21 and recognizes the ice-making state of the ice-making water (S105).

The control unit 20 that has received the "ON" signal from the ice-making sensor unit 21 after the ice-making is completed controls the ice-making motor driving unit 27 to drive the ice- And the ice cubes are dropped into the reservoir 32 (S106).

Next, the control unit 20 determines whether the operation time of the compressor P accumulated in the defrost timer 25 reaches a predetermined defrosting time (S107). If it is determined that the defrosting time has not been reached, the process returns to step S101 to continue the cooling operation. If the defrosting time has been reached, the control unit 20 controls the defrost heater driving unit 26 The defrosting operation is carried out until it is "turned on " to remove the frost cast on the evaporator (S108).

When such defrosting operation is completed, the ice tangle prevention routine (I) is performed. A part of the surface of the ice on the upper side of the storage container 32 is melted and flows due to the superheating heat caused by the driving of the defrost heater and the inside temperature rises due to the lapse of the predetermined rest period, The cooling fan is driven (S109).

The control unit 20 controls the defrost timer 25 to count the operation time of the compressor P by about 5 minutes, which is the reference time, (S110). The control unit 20 controls the stepping motor driving unit 28 to drive the stepping motor 28a in the forward and reverse direction to move the stepping motor 28a forward and backward And the ice take-out coil 34 connected to the motor shaft 28b of the step motor 28a rotates together to mix the entangled ice (S111).

After the step motor 28a has been normally rotated once or twice, the controller 20 determines whether the number of times the stepping motor 28a is driven coincides with a preset reference number (for example, twice) (S112) The number of times of driving is updated (S113). Thereafter, the routine returns to step S111 to drive the step motor 28a in forward and reverse directions. When the step motor 28a is repeatedly driven for forward and reverse, The control section 20 controls the step motor driving section 28 to stop the step motor 28a (S114).

As described above, the ice tangle prevention routine (I) of the main routine prevents ice tangles and allows the ice of the storage container 32 to be taken out smoothly out of the door.

On the other hand, an operation of taking out ice from the reservoir 32 during the operation of the refrigerator by the above-described steps will be described with reference to FIG. 4B.

When the user pushes the ice take-out lever 24a exposed to the outside of the freezing chamber door 31 by the cup 36 (S201), a signal is outputted from the ice take-out switch 24b connected to the lever 24a If the ice extraction switch 24b is not turned "on " as a result of the determination, the controller 20 returns to step S201. If it is determined that the ice extraction switch 24b is not" When the switch 24b is turned on, the control unit 20 controls the step motor driving unit 28 to drive the step motor 28a so that the ice in the reservoir 32 is transferred to the ice take- . The ice below the reservoir 32 is pushed out by the ice extraction coil 34 rotating together with the stepping motor 28a to be guided to the ice extraction passage 37 and discharged to the cup 36 ).

If the ice extraction switch 24b is not "off" as a result of the determination, the controller 20 determines whether the ice discharge switch 24b is turned " The control section 20 controls the step motor driving section 28 to stop the take-out operation of the ice when the ice take-out switch 24b is turned "off " And returns to the main routine after the step motor 28a is stopped (S205).

In the present invention, an ice tangle prevention routine (II) for performing, when the user operates the select button 29a for preventing ice tangle, provided in the operation unit 29, separately from the operation of the above-described main routine for preventing ice tangle, can do. This ice entanglement preventing routine (II) can be performed during the cooling operation or during the defrost operation.

The control unit 20 controls the step motor driving unit 28 to control the step motor 28a so that the user can control the step motor driving unit 28. In this case, And the ice take-out coil 34 connected to the motor shaft 28b of the step motor 28a rotates together to rotate the ice in the ice-making container 32 in the counter-clockwise direction (S302). The control unit 20 determines whether the number of times the stepping motor 28a is driven coincides with a preset reference number (for example, five times) (S303), and updates the number of times of driving if the number of times does not coincide with the reference number (S304) Subsequently, the routine returns to step S303 to drive the stepping motor 28a in the forward and reverse directions. When the stepping motor 28a is repeatedly driven for forward and reverse, the control unit 20 causes the stepping motor driving unit 28 to stop the stepping motor 28a (S305).

In the present invention as described above, when the defrosting operation is completed and the next cooling operation is performed, or when the user's direct selection button is operated, the motor is rotated forward and reverse to rotate the ice extraction coil connected to the motor shaft alternately counterclockwise and clockwise, You can mix the ice on the top and bottom of the ice.

Therefore, according to the present invention, a part of the surface of ice is melted due to the superheated heat, so that it is prevented that the ice tangles with the surrounding ice, or the ice is not entangled for a long time, The ice can keep its original form and can improve the reliability of the product by allowing the ice to be taken out smoothly in response to the demand of the user.

Claims (6)

A reservoir which is installed in the freezing room and stores the ice pieces which are ice-picked and released; An ice extraction coil installed in the reservoir to be able to rotate forward and backward; A motor for rotating the ice extraction coil forward and backward; And a control unit for controlling the motor so as to rotate the ice extraction coil in the ice extraction mode in the normal direction and to reverse or reverse the ice extraction coil in the ice trapping prevention mode. Device. The apparatus of claim 1, wherein the motor is a stepping motor. The method of claim 1, wherein the ice tangle prevention mode Wherein the defrosting operation is performed during a cooling operation after the defrosting operation is terminated or is performed by a user's selection. 1. A refrigerator comprising an ice-making tray for ice-making and a reservoir for storing ice, and an ice-maker provided in the reservoir, A water supply step of supplying ice-making water to the ice-making tray; An ice making step of performing ice making; An ice-making step of releasing ice-making-finished ice operation into the storage container; And an ice trapping prevention step of rotating the ice extraction coil in the reservoir in a direction opposite to the rotation direction of the ice pick-up to prevent entanglement of the ice stored in the reservoir, How to prevent ice tangle in a refrigerator. 5. The method of claim 4, wherein the ice tangle prevention step Wherein the defrosting operation is performed during a cooling operation after the defrosting operation is terminated. 5. The method of claim 4, wherein the ice tangle prevention step Wherein the controller is performed by a user's selection.

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