KR100531290B1 - Ice-maker & control method the same in refrigerator - Google Patents

Abstract

It is an object of the present invention to provide an automatic ice maker and an automatic ice maker control method of a refrigerator which allows the ejector for extracting ice to the outside from the automatic ice maker formed on the door side to be returned to its original position once operated.

To this end, the present invention is a semi-cylindrical ice making chamber having a substantially rectangular rectangular cross section, a control unit with a motor built in one end of the long direction of the ice making chamber, and is drawn out from the motor shaft of the control unit so that the long direction of the ice making chamber is provided. An ejector installed in the air, a first water overflow prevention portion extending to have an arcuate surface at one long side of the ice making chamber, a second water overflow prevention portion inclined downward at the other long side of the ice making chamber, and the extracted ice In the automatic ice maker of the refrigerator provided with the ice bank to be stored, the motor is capable of forward and reverse rotation, the ejector is formed with a plurality of ejector pins for taking out the ice, the second water overflow prevention unit one end pin detection sensor When the ejector pin rotated forward by the motor contacts the pin detection sensor of the second overflow prevention part, the motor rotates in reverse and the ejector pin returns to its original position. It provides an automatic ice maker in a refrigerator which comprises.

In addition, the present invention is a refrigerator provided with an automatic ice maker in the door,

A first step of setting the ejector to the initial position after the power is applied;

A second step of supplying the water to the ice making chamber and deicing the supplied water;

A third step of extracting the iced ice by rotating the motor forward;

And a fourth step of returning the ejector to the first step position by rotating the motor reversely.

Description

Automatic Ice Maker and Automatic Ice Maker Control Method {Ice-maker & control method the same in refrigerator}

The present invention relates to an automatic ice maker of a refrigerator, and more particularly, an automatic ice maker of the refrigerator which is mounted inside the refrigerator to make ice so that water does not overflow according to the movement of the door when the automatic ice maker is configured in the door of the refrigerator. And an ejector control method for the automatic ice maker.

In general, a refrigerator is divided into a freezer compartment and a refrigerating compartment. The refrigerator compartment maintains the freshness of food or vegetables by maintaining a temperature at 3 ° C. to 4 ° C., and the freezer maintains a temperature below 0 ° C. to freeze food. To be kept at.

Recently, refrigerators have added various functions for user convenience, and an automatic ice maker is one of such additional functions.

1 is a perspective view showing an example of an automatic ice maker 1 mounted in a freezer compartment of a conventional double door refrigerator, and FIG. 2 is a side cross-sectional view thereof.

As shown in the figure, the automatic ice maker 1 has an ice making chamber 11 in which ice is generated, and a water supply part 12 which is formed at one side of the ice making chamber 11 and supplies water to the ice making chamber 11. And a control unit 13 formed at the other side of the ice making chamber 11 and accommodated with a motor (not shown) and connected to a motor shaft of the control unit 13 to rotate the ice making chamber 11. It is formed to include an ejector 14 for taking out the ice ice in the ice bank (19).

Looking at the configuration of the automatic ice maker 1 in more detail, the rear portion of the automatic ice maker 1 is formed with a fastening portion 15 to fasten the automatic ice maker 1 to the freezer compartment of the refrigerator, the body of the ice making chamber (11) is formed. The ice-making chamber 11 is formed in a semi-cylindrical shape, and the partition protrusions 16 are formed at predetermined intervals so that ice is partitioned and taken out in the semi-cylindrical ice-making chamber.

In the control unit 13 formed on one side of the ice making chamber 11, as described above, a motor is built in and an ejector 14 is connected to the motor shaft. The ejector 14 has a shaft formed transverse to the center of the ice making chamber 11, and a plurality of ejector pins 14a are spaced apart by an interval partitioned in the ice making chamber 11 to an axis side of the ejector 14. ) Is formed. The ejector pin 14a is a means for ejecting the manufactured ice into the ice bank 19.

Next to the ejector pin 14a, a slide bar 17 is configured to allow the manufactured ice to slide down into the ice bank 19. Ice moved by the ejector pin 14a is placed on the slide bar 17 and then slides along the surface of the slide bar 17 to fall into the ice bank 19.

The heater 18 is attached to the bottom surface of the ice-making chamber 11. In order to move the manufactured ice, the ice making chamber surface and the ice should be separated. At this time, when the heater 18 operates to raise the temperature of the bottom surface of the ice making chamber 11, the ice in contact with the ice making chamber surface melts and ejects the ice ( 14) can be moved.

The conventional automatic ice maker as described above is located inside the freezer compartment and is usually fixed to a rear wall, a side wall, or the like in the freezer compartment. Most refrigerators equipped with such an automatic ice maker 1 are provided with a dispenser 21 so that the user can directly obtain the ice taken out without opening the refrigerator door.

The dispenser 21 is normally located in the door 2, the automatic ice maker 1 is located in the freezer compartment, there is a problem that the automatic ice maker 1 occupies a large volume inside the freezer compartment. That is, the automatic ice maker 1 includes not only an ice making chamber 11 but also an ice bank 19, wherein the ice bank 19 has an ice feeder (not shown) and ice crushing to transfer ice to the dispenser 21. Since devices (not shown) are installed, the volume thereof becomes large, thus occupying a lot of space in the freezer compartment.

In order to solve this problem, a refrigerator having an automatic ice maker 1 installed on the door 2 side has been developed.

Fig. 3 is a schematic perspective view showing an example of the automatic ice maker 1 installed on the door side, and Fig. 4 is a side cross-sectional view thereof.

As shown in the figure, the automatic ice maker 1 installed on the side of the door 2 is provided with water overflow prevention units 110 and 120 at both sides of the ice making chamber so that water is supplied to the automatic ice maker 1. It is comprised so that water may not overflow even if the door 2 is opened and closed.

In the automatic ice maker 1, the ejector 14 rotates and ejects the ice while extracting the iced ice. The ejector 14 is once again rotated to be iced again without being returned to its original position. There was a problem that can not take out.

The present invention has been made to solve the above-mentioned problems of the prior art, an automatic ice maker and an automatic ice maker of the refrigerator which allows the ejector for ejecting ice to the outside from the automatic ice maker formed on the door side to be returned to its original position once operated. Its purpose is to provide a control method.

In order to achieve the above object, the present invention provides an ice making chamber made of a semi-cylindrical shape having a substantially rectangular rectangular cross section, a control unit having a motor built in one end of the ice making chamber, and drawn out from a motor shaft of the control unit. An ejector installed in the long direction of the ice chamber, a first water overflow preventing portion extending to have an arc surface at one long side of the ice making chamber, a second water overflow preventing portion inclined downward at the other long side of the ice making chamber, In the automatic ice maker of the refrigerator equipped with an ice bank in which the extracted ice is stored,

The motor is capable of forward and reverse rotation, the ejector pins are formed to eject ice from the ejector, and a pin detection sensor is provided at one end of the second water overflow prevention part so that the ejector pin rotated forward by the motor is second. Provided is an automatic ice maker of the refrigerator characterized in that the motor is rotated in reverse contact with the pin detection sensor of the water overflow prevention unit to return the ejector pin to its original position.

In addition, the present invention is a refrigerator provided with an automatic ice maker in the door,

A first step of setting the ejector to the initial position after the power is applied;

A second step of supplying the water to the ice making chamber and deicing the supplied water;

A third step of extracting the iced ice by rotating the motor forward;

And a fourth step of returning the ejector to the first step position by rotating the motor reversely.

Hereinafter, the configuration and method of the present invention will be described in detail with reference to the accompanying drawings. For reference, prior to describing the structure and method of the present invention, in order to avoid duplication of description of the prior art reference will be referred to the same reference numerals.

5 is a perspective view showing a preferred embodiment of the automatic ice maker of the refrigerator according to the present invention, Figure 6 is a side cross-sectional view of FIG.

The automatic ice maker of the refrigerator according to the present invention includes an ice making chamber 100 in which ice is generated, and a water supply unit 12 which is formed at one side of the ice making chamber 100 in the long direction and supplies water to the ice making chamber 100. The controller 13 is formed on the other side in the long direction of the ice making chamber 100 and is connected to the motor shaft of the control unit 13 and the controller 13 accommodates a motor (not shown). The ice making chamber 100 is rotated. The ejector 14 having a pin 14a for extracting the ice deiced from the ice bank 19 and a first overflow protection part 110 formed at one long side of the semi-cylindrical ice making chamber 100. And a second water overflow prevention part 120 formed at the other long side portion and a pin detection sensor 200 attached to one end of the second water overflow prevention part 120.

The ice-making chamber 100 is formed in a semi-cylindrical shape, and the open upper surface has a rectangular shape having a long side portion 101 and a short side portion 102. The water supplied from the freezing chamber is frozen after the water is supplied into the ice making chamber 100 from the water supply part 12 formed at one side in the long direction of the ice making chamber 100, that is, the short side portion 102.

In the semi-cylindrical shape of the ice-making chamber 100, partition projections 16 are formed at predetermined intervals. The partition projection 16 is a means for allowing the ice to be iced to a certain size and to facilitate the separation of the ice when the ice is taken out.

A motor 13a is embedded in the control unit 13 formed at one side of the ice making chamber 100 in the longitudinal direction. An ejector 14 is provided on the shaft of the motor 13a, and the ejector 14 is provided with a plurality of ejector pins 14a in a direction orthogonal to the shaft. The ejector pins 14a are horizontally formed in the lateral direction of the ice making chamber 100 partitioned by the partition protrusions 16 described above, respectively, and serve to push the ice to the outside when the iced ice is taken out at a time.

The automatic ice maker 10 of the present invention is installed in the door 2 of the refrigerator. To this end, a fastening part 15 is formed in the long side portion 101 of the ice making chamber 100 so that the ice making chamber 100 can be detached from the refrigerator door 2.

As shown in the drawing, the long side part (hereinafter, referred to as the first long side part 101a) having the fastening part 15 is provided with a first water overflow prevention part 110 in which a cylindrical curved portion is partially extended. The first water overflow prevention unit 110 prevents the water contained in the ice making chamber 100 from flowing into the first long side portion 101a and simultaneously removes the frozen ice by forming the cross section in an arc shape. When the ice is easily taken out along the curved surface.

On the other long side portion (hereinafter referred to as the second long side portion 101b) that faces the first long side portion 101a, a second water overflow prevention portion 120 inclined downward is formed. The second water overflow prevention unit 120 is formed in a form that partially blocks the upper surface of the ice making chamber 100, and is formed of a flat panel so that ice is slid onto the surface of the second water overflow prevention unit 120. It falls to the bank 19.

In the automatic ice maker 10 according to the present invention, the pin detection sensor 200 is configured in the second water overflow prevention unit 110, and when the ejector pin 14a is detected by the pin detection sensor 200, the motor 13a. ) Is rotated in reverse direction, characterized in that the ejector 14 rotates in the reverse direction.

To this end, the motor 13a built in the control unit 13 employs a motor 13a capable of both forward and reverse rotation, and the controller for controlling the rotation of the motor 13a adjusts the rotation angle of the motor shaft. Thus, the ejector pin 14a, which is reversely rotated by the operation of the pin detection sensor 200, reaches the initial position.

Hereinafter, a method of controlling the automatic ice maker of the refrigerator according to the present invention will be described with reference to the flowchart of FIG. 7.

In the first step (S1) of the control method of the automatic ice maker of the refrigerator according to the present invention, when power is applied, the control unit controls the motor 13a so that the ejector 14 connected to the motor shaft is set to an initial position. As shown in the figure, the initial position refers to a position where the ejector pin 14a waits on the second water overflow prevention unit 120 side before the water is frozen.

In the second step S2, water is supplied into the ice making chamber 100 and iced water is supplied.

In the third step S3, when the ice making process is completed, the controller rotates the motor 13a forward, and ejects the ice iced by the ejector pin 14a while the ejector 14 connected to the motor shaft rotates.

In the fourth step S4, the ejector pin 14a, which is interlocked while the motor 13a rotates forward, contacts the pin detection sensor 200 of the second overflow controller 120, and the controller detects the pin detection sensor ( The operation of the motor 200 is read to instruct the motor 13a to rotate in reverse, and the position of the ejector pin 14a is returned to the position of the first step S1.

When the ejector pin 14a is set to the initial position, water is supplied back into the ice making chamber.

After performing the fourth step (S4) of the refrigerator automatic ice maker control method as described above, the ice bank is to detect the full state of ice, and if the ice bank is full of ice, after the ice bank is blocked the water supply to the interior of the ice making room (100) By preventing the malfunction of the refrigerator, it is preferable to prevent the waste of water.

The present invention provides an automatic ice maker on the door side, and in an automatic ice maker of a refrigerator that prevents water overflow, the ejector of the automatic ice maker can perform forward and reverse rotation so that the ejector can stand in its original position after the ice is taken out. do.

In addition, the control unit not only controls the direction of ejector rotation by the ejector pin detection sensor, but also measures the ice state of the ice bank to prevent unnecessary water waste by preventing water from being supplied to the ice making chamber when the ice bank is full of ice. have.

1 is a perspective view showing an example of an automatic ice maker mounted in a freezer compartment of a conventional double-door refrigerator

FIG. 2 is a cross-sectional view taken along line II of FIG.

Figure 3 is a schematic perspective view showing an example of an automatic ice maker installed on the door side of a conventional refrigerator

4 is a side cross-sectional view of FIG. 3

Figure 5 is a perspective view showing a preferred embodiment of the automatic ice maker of the refrigerator according to the present invention

FIG. 6 is a side sectional view of the FIG. 5 automatic ice maker;

7 is a flowchart illustrating a control method of an automatic ice maker of a refrigerator according to the present invention.

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

10: automatic ice maker 100: ice maker

110: first water overflow prevention portion 120: second water overflow prevention portion

12: water supply unit 13: control unit

13a: motor 14: ejector

14a: ejector pin 200: pin detection sensor

Claims (3)

A semi-cylindrical ice making chamber having a substantially rectangular rectangular cross section, a control part provided at one end in the long direction of the ice making room and having a built-in motor, an ejector drawn out from the motor shaft of the control part and installed in the long direction of the ice making room; A first water overflow prevention portion extending to have an arc-shaped surface on one side of the ice making chamber, a second water overflow prevention portion inclined downward on the other long side of the ice making chamber, and an ice bank in which the extracted ice is stored In the automatic ice maker of the refrigerator provided, The motor is capable of forward and reverse rotation, The ejector is formed with a plurality of ejector pins for taking out ice, One end of the second water overflow prevention unit is provided with a pin detection sensor, When the ejector pin rotated forward by the motor contacts the pin detection sensor of the second overflow prevention part, the motor rotates in reverse to return the ejector pin to its original position. A first step of setting the ejector to the initial position after the power is applied; A second step of supplying the water to the ice making chamber and deicing the supplied water; A third step of extracting the iced ice while the ejector rotates by rotating the motor forward; And a fourth step of returning the ejector to the first step position by rotating the motor in reverse from the control unit when the ejector contacts the pin detection sensor attached to one end of the ice making chamber. Control method The method of claim 2, Checking the state in which the ice bank is filled with ice after the fourth step; Blocking the water supply when the ice is full in the ice bank; Method for controlling the automatic ice maker of the refrigerator of claim 1 further comprising