KR20100082127A - Control methord of ice maker for refrigerator - Google Patents

Abstract

PURPOSE: A control method of an ice maker of a refrigerator is provided to improve entire ice-making quality by filling equal amount of water to a plurality of cells formed in an ice tray by rotating the ice tray in a set angle. CONSTITUTION: A control method of an ice maker of a refrigerator comprises the following steps. An ice tray is located in a horizontal state(S100). The water for icing is supplied to the ice tray inside(S200). The uniformed height is set while the water stored in cells of the ice tray overflows by the rotation of a motor(S300). Cool air for icing is supplied to the ice tray(S400). The ice in an ice bank locating at the bottom of the ice tray is detected(S500). The ice of the ice tray is separated by the rotation of the motor(S600).

Description

Control method of refrigerator ice maker {Control methord of ice maker for refrigerator}

The present invention relates to a control method of a refrigerator ice maker.

In general, a refrigerator is a home appliance that allows food to be stored at a low temperature in an interior storage space shielded by a door, and is stored by cooling the inside of the storage space using cold air generated through heat exchange with a refrigerant circulating in a refrigeration cycle. It is configured to keep foods in optimal condition.

Such refrigerators are gradually becoming larger and more multifunctional in accordance with the change of dietary life and the upgrading of products, and refrigerators with various structures and convenience devices have been released in consideration of user convenience.

And, for the user's convenience, an ice maker is provided for storing ice even inside the refrigerator. In general, the ice making apparatus may be mainly provided in the freezer compartment, and configured to have various forms.

Among various ice makers, there is an ice maker which ices iced ice by rotating an ice tray by driving a motor. The ice tray of such an ice making device is formed with a cell forming a plurality of partitioned spaces to make several ice at the same time. The water supplied for ice making is filled with the ice tray and frozen.

However, the ice maker having such a configuration has the following problems.

When water for ice making is supplied to the ice tray, when water is supplied from one side, water may not be sufficiently supplied to cells far from the water supply point in the process of filling the plurality of divided cells.

Therefore, some cells may be supplied with excessively high water, and some cells may be supplied with a small amount of water. For this reason, there is a problem that the size of the ice is not uniform, or some ice is significantly reduced in ice making, such as ice in a lump state.

An object of the present invention is to provide a control method of a refrigerator ice maker that allows a uniform amount of water to be accommodated in each of a plurality of cells provided to the ice tray by continuously rotating the set angle after the water supply of the ice tray.

A control method of a refrigerator ice maker according to an embodiment of the present invention includes a ice tray in which a plurality of divided cells are continuously arranged, and the ice tray is axially coupled with a motor to be iced by rotation. Setting the ice tray to a horizontal state [S100]; Supplying water for ice making to the inside of the ice tray [S200]; The water contained in the plurality of cells overflow by each other by the rotation of the motor to have a uniform height [S300]; Supplying cold air for ice making to the ice tray [S400]; Detecting ice in the ice bank under the ice tray [S500]; Ice ice of the ice tray by the rotation of the motor [S600];

In addition, the step S300, characterized in that the water is repeatedly rotated forward and backward by the set angle does not pour out of the ice tray.

In addition, the forward and reverse rotation angle of the ice tray is characterized in that it is set differently.

In addition, in the step S300, the ice tray is characterized by repeating one-way rotation and stop step by step up to the set angle at which water does not spill.

In addition, after the ice tray is rotated to a set angle, it is characterized in that it is rotated again in a horizontal state.

In addition, after the step S300, the step of setting the ice tray to the horizontal state again [S400] is characterized in that it further comprises.

According to the control method of the refrigerator according to the embodiment of the present invention, by rotating the ice tray by a set angle, a plurality of cells formed in the ice tray can be filled with a uniform amount of water.

Therefore, the size of the ice to be iced is not only uniform, it is possible to prevent the ice from tangling during ice making in the ice tray, it is possible to improve the overall ice making quality.

In particular, the set angle of the ice tray can be filled with water in a large number of cells more effectively through a method such as continuously repeating the forward and reverse rotation, or repeating the rotation and stop.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. However, it should be understood that the present invention is not limited to the embodiment shown in the drawings, and that other embodiments falling within the spirit and scope of the present invention may be easily devised by adding, .

1 is a side view schematically showing the configuration of an ice making apparatus according to an embodiment of the present invention, Figure 2 is a perspective view showing the structure of an ice tray according to an embodiment of the present invention.

Referring to these drawings, the ice making apparatus 1 according to the embodiment of the present invention includes a drive motor 200 and a child for rotating the ice tray 100 and the ice tray 100 in which water for ice making is collected and frozen. Ice bank 300 is stored in the ice iced from the stray 100, and the ice-covering member 400 for detecting whether the ice stored in the ice bank 300 is full.

In detail, the ice tray 100 is formed in a rectangular shape from above, and the upper surface is opened so that water for ice making can be stored. In addition, the ice tray 100 is formed with a plurality of cells 110 partitioning the ice tray 100.

As shown in FIG. 2, the cell 110 partitions the ice tray 100 so that a plurality of ice can be formed, and is formed to be recessed downward. The cells 110 are arranged in plural in the horizontal and vertical directions of the ice tray 100 and are formed to have a height lower than the circumferential height of the ice tray 100. Each of the cells 110 is formed in a rectangular shape when viewed from above.

On the other hand, the left and right (as shown in FIG. 1) of the ice tray 100, the center portion of both sides is axially coupled so that the ice tray 100 is rotatably mounted. In addition, one side of both sides of the ice tray 100 is connected to the driving motor 200.

That is, the rotation axis of the drive motor 200 is connected to the rotation center of any one of the left and right one side of the ice tray 100, the ice tray 100 is rotatable by the drive motor 200. . The drive motor 200 is composed of an electric motor capable of forward and reverse rotation.

On the other hand, the rotation axis of the drive motor 200 is not directly connected to the ice tray 100, the rotation center of the drive motor 200 and the ice tray 100 may be connected by a plurality of gear combinations. In this case, the drive motor 200 and the plurality of gears may be configured in one assembly form and may be combined with the ice tray 100.

The ice bank 300 is provided below the ice tray 100. The ice bank 300 is to store the ice ice iced in the ice tray 100 is formed in a box shape opened upward, the ice bank 300 is formed larger than the size of the ice tray 100.

Therefore, when the ice tray 100 is rotated by 180 ° by the driving motor 200, the ice tray 100 is twisted by interfering with an external one side, and each cell of the ice tray 100 ( Ice iced in the 110 can be stored falling to the ice bank (300).

Above the ice bank 300, the ice-covering member 400 for detecting the amount of ice stored in the ice bank 300 is provided. The ice-covering member 400 is formed in a lever shape and configured to be rotatable to check whether the ice bank 300 is full of ice.

When the ice bank 300 is determined to be full of ice by the ice detection member 400, the ice tray 100 does not rotate so that the ice is no longer iced.

The ice detection member 400 may not be formed in a lever shape and may be configured in a sensor manner so as to detect whether ice is stored in the ice bank 300.

Hereinafter, a process of mounting the ice making apparatus according to the present invention having the above configuration will be described in detail with reference to the accompanying drawings.

In order to make ice using the ice maker 1, power is first supplied to the ice maker 1. When power is supplied to the ice maker 1, the ice maker 1 detects an initial position of the ice tray 100 and sets it to a horizontal state.

In detail, in order to collect water in the ice tray 100, the ice tray 100 must be in a horizontal state, and for this purpose, the driving motor 200 is rotated after detecting the state of the ice tray 100. As a result, a horizontal state is formed such that the open surfaces of the cells face upward. [S100]

After the ice tray 100 is in a horizontal state, water for ice making is supplied to the ice tray 100 through a water supply pipe 500 disposed above the ice tray 100. In this case, the water supply pipe 500 is located on one side of the ice tray, and the water supplied through the water supply pipe 500 fills water from the cell at a position adjacent to the water supply pipe 500.

The total amount of water supplied to the ice tray 100 is supplied by an amount set to fill all of the plurality of cells 110 formed in the ice tray 100. The water supplied to the ice tray 100 is filled with water from the cell 110 at a position adjacent to the water supply pipe 500, and the adjacent cells 110 are crossed over each partition wall partitioning the cell 110. It will fill up. [S200]

When the water supply to the ice tray 100 is completed, a relatively large amount of water is supplied to the cell 110 close to the water supply pipe 500 among the plurality of cells 110, while the water supply pipe 500 and The cell 110 located at a far distance is supplied with a relatively small amount of water.

Therefore, in order to supply a predetermined amount of water to the plurality of cells 110, the ice tray 100 is rotated to return the water supplied to the ice tray 100 to the plurality of cells 110. Will be redistributed to

That is, after the water supply for ice making to the ice tray 100 is completed, the ice tray 100 is rotated by the driving of the driving motor 200. By rotating the ice tray 100, a plurality of cells 110 may be supplied with a uniform amount of water.

On the other hand, the ice tray 100 can be rotated in a variety of ways according to the rotation method of the drive motor 200, it is possible to supply a uniform amount of water to the plurality of cells 110 more effectively according to the rotation method. do. [S300]

Figure 4 is a side sectional view showing the rotation of the ice tray according to the first embodiment of the present invention.

Referring to the drawings, looking at the rotation method of the ice tray 100, the ice tray 100 is in a horizontal state when the water for ice making water supply. When the water supply to the ice tray 100 is completed, the ice tray 100 is rotated by an angle θ1 in the counterclockwise direction by the rotation of the driving motor 200.

At this time, the angle θ1 of the ice tray 100 is a predetermined angle to the maximum angle that the water inside the ice tray 100 does not overflow.

After the ice tray 100 rotates by θ1 angle in the counterclockwise direction, the driving motor 200 is rotated in reverse, and the ice tray 100 is rotated by θ2 in the clockwise direction again.

Of course, the angle θ1 of the ice tray 100 at this time is also a predetermined angle at a maximum angle at which the water inside the ice tray 100 does not overflow.

After the forward and reverse rotation of the ice tray 100 is completed, the driving motor 200 is rotated to detect the state of the ice tray 100 and become horizontal again.

In detail, when the ice tray 100 is rotated in the first clockwise direction, some of the water in the ice tray 100 exits the plurality of cells 110 and again rotates in the counterclockwise direction in the reverse direction. Will enter a plurality of cells (110). [S320]

At this time, the water contained in the ice tray by the shaking of the ice tray 100 may be redistributed again to the plurality of cells, the ice tray 100 is repeatedly reversed (clockwise and counterclockwise) As the water is supplied, the water of the water supplied to the inside and outside of the plurality of cells 110 is repeated. Therefore, after the repeated forward and reverse rotation of the ice tray 100 is finished, a uniform amount of water may be supplied to the entire plurality of cells 110.

In addition, the angles θ1 and θ2 at which the ice tray 100 rotates are different from each other, and the rotation angle at the forward and reverse rotation of the ice tray 100 also when the ice tray 100 is in the horizontal state. Can be set differently.

5 is a side sectional view showing the rotation of the ice tray according to the second embodiment of the present invention.

Referring to the drawings, referring to another rotation method of the ice tray 100, the ice tray 100 is supplied with water for ice making in a horizontal state. When the amount of water supplied to the ice tray 100 is completed, the ice tray 100 is rotated by the one-way rotation of the driving motor 200.

In detail, the ice tray 100 is rotated in the counterclockwise direction in the state that the water supply is completed. At this time, the ice tray 100 is repeated to rotate and stop at the same angle, the angle of the entire rotation is set to an angle such that the water of the ice tray 100 does not overflow.

In more detail, the ice tray 100 stops after rotating by θ3 angle in the counterclockwise direction. When the ice tray 100 is stopped after the rotation of the ice tray 100, the water contained in the plurality of cells 110 moves in and out of the plurality of cells 110 while being swung by inertia.

Then, the ice tray 100 is stopped again after rotating by θ3 angle in the counterclockwise direction. Therefore, the water contained in the plurality of cells 110 is allowed to enter and exit the inside and outside of the plurality of cells 110 while being swung again by inertia.

As described above, if the ice tray 100 is rotated by the set angle just before the water overflows after repeating rotation and stop 2-3 times or more consecutively at the same angle, the driving motor 200 is reversely rotated. The ice tray 100 is rotated clockwise until the horizontal state again.

Accordingly, the water supplied into the ice tray 100 may be redistributed by a uniform amount of water to each cell 110 while entering and exiting the plurality of cells 110.

Meanwhile, after a uniform amount of water is redistributed to the plurality of cells 110 and the ice tray 100 is kept horizontal again, cold air for ice making is supplied to the ice tray 100. do. When cold air is supplied to the ice tray 100 for a predetermined time, ice of a uniform size is formed in each cell 110. [S400]

When the formation of the ice on the ice tray 100 is completed, whether the ice stored in the ice tray 100 by the ice sensing member 400 is detected.

When the ice-covering member 400 is formed in a lever shape as shown, when the ice is formed in the ice tray 100, the ice-covering member 400 rotates to form the inside of the ice bank 300. The height of the stored ice is measured to determine whether or not the ice is full. [S500]

On the other hand, the ice formed on the ice tray 100 is selectively iced according to whether the ice detection member 400 determines.

In detail, when the ice detection member 400 determines that the amount of ice stored in the ice bank 300 is full, even if ice is formed in the ice tray 100, the ice tray 300 maintains the standby state without moving. do. That is, the ice tray 100 is not rotated to maintain a horizontal state.

On the other hand, when the ice sensing unit 400 determines that the ice bank 300 is not full ice, the ice of the ice tray 100 is iced. That is, the ice tray 100 is rotated by at least 180 ° by the rotation of the drive motor 200, the ice tray 100 is twisted by the rotation while lowering the ice formed in the ice tray 100 To fall. The ice dropped downward is received in the ice bank 300 to complete the ice.

After the ice is completed through such a process, the ice tray 100 is set in a horizontal state again, and the water for ice making is watered.

1 is a side view schematically showing the configuration of an ice making apparatus according to an embodiment of the present invention.

2 is a perspective view showing the structure of the ice tray according to an embodiment of the present invention.

Figure 3 is a block diagram sequentially showing the operation of the ice making apparatus according to an embodiment of the present invention.

Figure 4 is a side sectional view showing the rotation of the ice tray according to the first embodiment of the present invention.

5 is a side sectional view showing the rotation of the ice tray according to the second embodiment of the present invention.

Claims (6)

In the control method of the refrigerator ice making apparatus provided with an ice tray having a plurality of divided cells are arranged continuously, the ice tray is axially coupled to the motor and moved by rotation. Setting the ice tray in a horizontal state [S100]; Supplying water for ice making to the inside of the ice tray [S200]; The water contained in the plurality of cells overflow by each other by the rotation of the motor to have a uniform height [S300]; Supplying cold air for ice making to the ice tray [S400]; Detecting ice in the ice bank under the ice tray [S500]; Controlling ice of the ice tray by rotating the motor [S600]. The method of claim 1, In step S300, The control method of the refrigerator ice maker characterized in that the water is repeatedly rotated forward and backward by the set angle does not pour out of the ice tray. The method of claim 2, The forward and reverse rotation angles of the ice tray are set differently from each other. The method of claim 1, In step S300, The ice tray is a control method of a refrigerator ice maker, characterized in that by repeating one-way rotation and stop step by step until the set angle does not pour water. The method of claim 4, wherein And after the ice tray is rotated to a set angle, the ice tray is rotated back to a horizontal state. The method of claim 1, After performing the step S300, And controlling the ice tray to be in the horizontal state again (S320).

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