KR100820586B1 - Ice maker - Google Patents

Abstract

An icemaker is provided to preciously supply with a determinate quantity of water and to prevent water from overflowing of an ice making tray by accomplishing an exact detection of water supply with assistance of radio wave. An icemaker comprises an ice making device(52), a radio wave transmitter and receiver(90), and a controller for controlling the ice maker. The ice making device has an ice making tray(61) having an ice making space(61a) in which ice is made by pouring water and a water supplier to supply water to the ice making space. The controller controls the ice making device by determining the completion of water supply according to the received results generated from the radio wave transmitter and the receiver. The ice making tray is provided at the top thereof with an overflow protecting member that extends upward. A substrate panel is installed on the overflow protecting member.

Description

Automatic Ice Maker {Ice maker}

1 is a perspective view of an open freezer and a refrigerating compartment of a typical refrigerator;

2 is a perspective view showing an ice maker and an ice bank according to the prior art,

3 is an internal configuration diagram of a control unit of an ice maker according to the prior art,

4 is a perspective view of one embodiment of an automatic ice making apparatus according to the present invention;

5 is a cross-sectional view of an embodiment of an automatic ice making apparatus according to the present invention;

6 is a longitudinal sectional view of an embodiment of an automatic ice making apparatus according to the present invention;

7 is a block diagram illustrating main parts of an automatic ice making apparatus according to an embodiment of the present invention.

<Explanation of symbols on main parts of the drawings>

50: automatic ice maker 52: ice maker

61: ice tray 61a: ice tray

65: water supply valve 68: drive motor

69: temperature sensor 70: heater

72: radio wave transceiver for ice maker 73: ice maker transmitter

74: ice making receiver 80: ice bank

81: box 81a: storage space

90: radio wave transceiver for the ice bank 91: ice bank transmitter

92: ice bank receiver 102: control panel

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic ice making device for ice making, and more particularly, to an automatic ice making device that detects water supply amount or full ice using radio waves such as microwaves or millimeter waves.

Generally, an ice making apparatus is provided with an ice making space in which water is contained, and makes ice by cold air, and is attached to a refrigerating apparatus, such as a refrigerator.

1 is a perspective view of a freezer compartment and a refrigerating compartment of an ordinary refrigerator are opened.

In general, as shown in FIG. 1, a refrigerator cycle apparatus for freezing compartment F and a refrigerating compartment R is partitioned by a barrier 1 and cooling the freezer compartment F and a refrigerating compartment R to low temperature. A main body 2 mounted, a freezer compartment door 4 connected to the main body 2 to open and close the freezer compartment F, and a refrigerating compartment door connected to the main body 2 to open and close the refrigerating compartment R; 6) is configured to include.

The refrigeration cycle apparatus includes a compressor for compressing a low-temperature low-pressure gas refrigerant, a condenser in which the high-temperature and high-pressure refrigerant compressed by the compressor is radiated to outside air to condense, an expander for reducing the refrigerant condensed in the condenser, and the expander The refrigerant expanded in the evaporator is configured to evaporate by taking heat of air circulated from the freezing compartment (F) or the refrigerating chamber (R).

In recent years, an automatic ice making apparatus for ice-making by using cold air in the freezing chamber F and taking out to the outside is installed.

The automatic ice making apparatus is mounted on an inner upper portion of the freezing chamber F to make an ice maker 8 for ice-making water supplied with cold air in the freezing chamber F, and the ice iced in the ice maker 8 is iced and contained therein. On the ice bank 9 mounted inside the freezer compartment F, the dispenser 10 mounted on the freezer compartment door to take out ice to the outside without opening and closing the freezer compartment door 4, and on the ice bank 9 It is composed of an ice chute 11 for guiding the contained ice to fall to the dispenser (10).

2 is a perspective view showing an ice maker and an ice bank according to the prior art, Figure 3 is an internal configuration of the control unit of the ice maker according to the prior art.

The ice maker 8 has an ice making space 12a containing water for ice making, and an ice making tray 12 for making water into ice of a predetermined shape, and a water supply for supplying water to the ice making tray 12. 13, a temperature sensor (not shown) for measuring the temperature of the ice making tray 12, and a heater for heating the ice making tray 12 to separate the iced ice I from the ice making tray 12 (not shown). And a slider 14 provided to slide the ice I iced from the ice making tray 12 into the ice bank 9, and the ice I iced from the ice making tray 12. And an ejector 15 for sweeping up and moving with the slider 14 and an ice making control unit 16 for controlling operations of the heater, the ejector 15 and the like.

The ice tray 12 has partition walls 12b formed therein at predetermined intervals so that the ice I can be separated and produced and taken out.

The water supply unit 13 includes a water supply cup 13a for supplying water to the ice making space 12 of the ice making tray 12, a water supply hose 13b for supplying water to the water supply cup 13a, and the water supply. A water supply valve (not shown) which intercepts the water supplied to the hose 13b is included.

The ejector 15 is formed such that its axis 15a crosses the center of the ice making tray 12, and the ice 14 produced on the side of the axis 15a of the ejector 15 is moved by the slider 14. A plurality of ejector pins 15b is formed.

The control unit 16 includes a control panel 21 mounted with various electric components for controlling an automatic ice making device, a motor 24, a drive gear 25 arranged on a shaft of the motor 24, and The driven gear 25 includes a driven gear 26 meshed with the drive gear 25, connected to the shaft 15a of the ejector 15, and having a cam 27 protruding therefrom.

The control unit 16 includes a first arm lever 28 which rotates in association with the cam 27, a second arm lever 29, and a second arm lever that are connected to the first arm lever 28. And a detection sensor 30 fixed to the valve 29, a magnet 31 rotated with the rotation of the second arm lever 29, and a hall sensor 32 installed to detect the magnetic field of the magnet 31. It is configured by.

Both ends of the ice detection lever 30 are rotatably mounted at both sides of the ice maker 8 and are bent toward the outside of the ice maker 8 toward the bottom thereof.

The magnet 31 is installed in the extension part 30a of the sensing probe 30.

The control unit 16 detects a magnetic field detected by a change in the rotational position of the magnet 31 according to the rotation of the detection lever 30 to detect the magnetic field inside the ice bank 9. Detect.

Referring to the operation of the conventional automatic ice making device configured as described above are as follows.

First, the control panel 21 turns on and off the water supply valve for regulating the water for a predetermined time.

When the water supply valve is turned on, the water supply cup 13a contains water supplied through the water supply hose 13b, and the contained water is transferred to the ice making space 12a of the ice making tray 12.

Thereafter, the water contained in the ice making space 12a of the ice making tray 12 is cooled by heat exchange with the cold air or the ice making tray 12 in the freezer compartment.

Meanwhile, when the temperature of the ice making tray 12 detected by the temperature sensor (not shown) is lower than the set temperature, the control panel 21 determines that ice making is completed and turns on the heater (not shown).

The temperature of the ice making tray 12 is increased by turning on the heater, and the iced ice I is separated from the ice making tray 12 while starting to melt from the contacted portion of the ice making tray 12.

Thereafter, the control panel 21 rotates the pin 15b of the ejector 15 from the initial position to the icing position and outputs an icing start signal to the motor 24 to return to the initial position.

The motor 24 is driven by receiving an ice start signal, and the pin 15b of the ejector 15 simultaneously with the motor 24 is in contact with the ice at an initial position, and the ice tray 12 and the ice are If (I) is in a separated state, the ice (I) is rotated to the iced position while scooping up the ice and then returned to the initial position, and the ice (I) that has been raised is raised by the slider (14) and then the slider (14). Is guided to the ice bank 9.

On the other hand, since the ice I and the ice tray 12 are fixed, the pin 15b of the ejector 15 is not separated from the ice tray 12 and the ice I. It cannot return, and returns to the initial position.

In addition, if the set time has not elapsed after the output of the ice start signal, the control panel 21 determines that the ice is not completed, and the ejector 15 until the ice I is spread or the set time elapses. Drive 15 again so that pin 15b of &lt; RTI ID = 0.0 &gt;

Then, the control panel 21 detects whether the ice bank is full of ice according to the rotation of the ice sensor 30 and the detection result of the hall sensor 32, and if it is determined that the ice bank is not full, the water supply, De-icing, heating, ice-breaking, and ice-break detection are repeated, and if it is determined that the ice is full, the water supply and the subsequent water are stopped until it is determined that the ice is not full.

However, since the automatic de-icing device according to the prior art turns on and off the water supply valve for a predetermined time when water is supplied for ice making, too much water is supplied to the ice making space 12a according to the water pressure of the water supply source connected to the water supply hose 13b. The water may be overflowed to the outside of the ice making tray 12, a small amount of water may be watered and iced compared to the ice making space 12a, and the size of the ice may be uneven.

In addition, since the ice-breaking device 30 mechanically detects the ice-covering ice cube in the conventional ice-making device according to the prior art, the ice-covering lever 30 may pass between the ice and the ice, and an ice-covering detection error may occur. There is a problem that the detection lever 30 may be mechanically cornered.

The present invention has been made in order to solve the above problems of the prior art, the water supply to a certain amount of water by accurately detecting the amount of water supplied to the ice making tray as a radio wave to supply water to the outside of the ice making tray overflows or ice It is an object of the present invention to provide an automatic ice making apparatus capable of preventing the size of the surface from becoming uneven.

Another object of the present invention is to provide an automatic de-icing device that can accurately detect whether the ice is ejected by the ejector, and optimally detect the completion of the ice breaking to minimize the generation of heat heated by the heater to reduce energy.

Another object of the present invention to provide an automatic de-icing device that can accurately detect whether the ice bank is full of ice as a radio wave to prevent mechanical restraint and failure due to erroneous detection and freezing that may occur when mechanically detecting the ice. It is.

According to an aspect of the present invention, there is provided an automatic ice making apparatus including an ice making tray including an ice making tray in which an ice making space is filled and iced, and a water supply for supplying water to the ice making space; A radio wave transceiver for transmitting and receiving radio waves to the ice making space; And a controller for determining the completion of water supply according to the reception result of the radio wave transceiver to control the ice maker.

According to an aspect of the present invention, there is provided an automatic ice maker comprising: an ice maker including an ice making tray having an ice making space in which water is contained and iced, and an ice making mechanism which ices the ice ice in the ice making space; A radio wave transceiver for transmitting and receiving radio waves to the ice making space; And a controller configured to control the ice maker by determining completion of the ice according to the reception result of the radio transceiver.

The radio transceiver is installed to be located above the ice making space.

The radio transceiver includes an ice making transmitter which transmits radio waves to the ice making space, and an ice making receiving unit which receives radio waves reflected from the ice making space.

According to an aspect of the present invention, there is provided an automatic ice maker comprising: an ice maker including an ice maker tray having an ice maker space in which water is iced, and an ice maker which ices the ice ice in the ice maker tray; An ice bank having a storage space in which ice iced by the ice-breaking mechanism is stored; A radio wave transceiver for transmitting and receiving radio waves to the storage space; And a controller for controlling the ice maker by determining whether the ice is full according to the reception result of the radio transceiver.

The radio transceiver is installed to be located on one side wall of the ice bank.

The radio transceiver includes an ice bank transmitter for transmitting radio waves to the storage space and an ice bank receiver for receiving radio waves reflected from the storage space.

An automatic ice making apparatus according to the present invention includes an ice making tray having an ice making space in which water is contained and iced; A temperature sensor for sensing a temperature of the ice making tray; A heater installed to heat the ice tray; A water supply unit for supplying water to the ice making space; An ice making mechanism for ice-icing the ice iced in the ice making tray; A radio wave transceiver for an ice making tray for transmitting and receiving an electric wave to the ice making space; An ice bank having a storage space in which ice iced by the ice-breaking mechanism is stored; An ice bank radio transceiver for transmitting and receiving radio waves to the storage space; Determination of ice making is completed according to the detection result of the temperature sensor, at least one of the completion of water supply and the completion of the ice is determined according to the detection result of the ice-making transceiver, and the ice is determined according to the reception result of the ice bank transceiver. And a control unit for controlling the heater, the water supply unit, and the ice mechanism.

The water supply unit includes a water supply cup for supplying water to the ice making space, and a water supply hose for supplying water to the water supply cup; And a water supply valve controlled by the control unit to control the water supplied to the water supply hose.

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

4 is a perspective view of an embodiment of an automatic ice making apparatus according to the present invention, FIG. 5 is a cross-sectional view of an embodiment of the automatic ice making apparatus according to the present invention, and FIG. 6 is a longitudinal cross-sectional view of an embodiment of the automatic ice making apparatus according to the present invention. 7 is a block diagram illustrating main parts of an automatic ice making apparatus according to the present invention.

The automatic ice making apparatus 50 which concerns on a present Example consists of the ice maker 52 and the ice bank 80 largely.

The ice maker 52 and the ice bank 80 are installed in the freezer compartment or in the freezer compartment door 54.

The ice maker 52 includes an ice making tray 61 in which an ice making space 61 a having an upper surface is opened so that water can be supplied with water.

The ice tray 61 is formed with a plurality of partition protrusions 61b spaced apart by a predetermined interval so that a plurality of ice I can be separated and formed in the ice making space 61a, and a flat plate overflow protection portion 61c thereon. ) Is formed to extend upward.

The ice maker 52 includes a water supply 62 for supplying water to the ice making space 61a.

The water supply 62 includes a water supply cup 63 for supplying water to the ice making space 61a, and a water supply hose 64 for supplying water to the water supply cup; It includes a water supply valve 65 controlled by a control panel 102 to be described later to control the water supplied to the water supply hose (64).

The ice maker 52 includes an ice making mechanism 66 for icing ice iced in the ice making tray 61.

The ice making mechanism 66 includes an ejector 67 which actually spreads the ice iced in the ice making tray 61 and a driving motor 68 generating a driving force for rotating the ejector 67.

As shown in FIG. 5, the ejector 67 includes a shaft 67a disposed to cross the upper side of the ice making space 61a and a pin 67b protruding from the side surface of the shaft 67a. do.

The moving mechanism 66 may be directly connected to the shaft of the ejector 67 by the rotating shaft of the drive motor 68, may be connected via a power transmission mechanism such as a gear, or the like. The driving gear 68a is connected to the driven gear, and the driven gear 67c engaged with the driving gear 68a is limited to the shaft 67a of the ejector 67.

The ice maker 52 includes a temperature sensor 69 which senses the temperature of the ice making tray 61 as shown in FIG. 5, and as shown in FIG. 6, the ice making tray 61 when the ice I is taken out. ) And a heater 70 installed to heat the ice making tray 61 so as to separate the ice).

The ice maker 52 includes a radio wave transceiver 72 for an ice tray that transmits and receives radio waves to the ice making space 61a.

The ice tray transceiver 72 for an ice making tray includes an ice making transmitter 73 for transmitting radio waves to the ice making space 61a, and an ice making receiver for receiving an electric wave transmitted from the ice making transmitter 73 reflected in the ice making space 61a. 74).

The ice making transmitter 73 is a kind of radio wave transmitter that transmits a wave including microwaves and millimeter waves toward water or ice. It is also possible to be installed above the 61, it is also possible to be installed on the upper portion of the ice making tray 61, for example, the water overflow prevention portion (61c).

The ice making receiving unit 74 is different from the time received by reflecting from the water or ice depending on the height of the water or ice contained in the ice making tray 61, and is installed to be located in the reflection path of radio waves.

The ice-making tray radio transceiver 72 may be provided with the ice-making transmitter 73 and the ice-making receiver 74 independently, respectively, and are installed together on one substrate 75 (hereinafter, referred to as an ice tray). It is also possible.

On the other hand, the ice bank 80 is a box body 81 is formed with a storage space 81a having an upper surface open so that the ice iced from the ice maker 52, and rotatably disposed inside the box body 81 The auger 82 which transfers ice, and the bank motor 83 provided in the box 81 to rotate the auger 82 are included.

The ice bank 80 includes a grinding mechanism 84 mounted with a blade and provided opposite the motor 83 so as to crush and extract the ice transported by the auger 82.

The ice bank 80 is provided with an ice bank radio transceiver 90 for transmitting and receiving radio waves to the storage space 81a.

The ice bank radio wave transceiver 90 includes an ice bank transmitter 91 that transmits radio waves to the storage space 81a, and an ice that is transmitted from the ice bank transmitter 91 to receive radio waves reflected from the storage space 81a. Bank receiver 92 is included.

The ice bank transmitter 91 is a kind of radio transmitter which transmits radio waves including microwaves and millimeter waves toward water or ice, like the ice making transmitter 73, and moves from the upper side of the storage space 81a to the storage space 81a. It is also possible to be located above the box 81 so as to transmit radio waves, and one side of the box 81 to transmit the radio wave from one side wall of the storage space 81a toward the opposite side of the storage space 81a. Of course, it is also possible to be installed on the side.

The ice bank receiving unit 92 is different from the time received by reflecting from the water or ice according to the height of the water or ice contained in the ice making tray 61, and is installed to be located in the reflection path of radio waves.

The ice bank radio transceiver 90 may be provided with an ice bank transmitter 91 and an ice bank receiver 92 independently, and may be together on one substrate 93 (hereinafter referred to as an ice bank substrate). It is also possible to be installed.

On the other hand, the automatic ice making device 50 is provided with an ice making control unit 100 next to the ice making tray 61.

The temperature sensor 69 and the driving motor 68 are built in the ice making control unit 100, and the temperature sensor 69 is installed to contact the ice making tray 61, and the driving motor 68 is the ice making control unit 100. The fixing panel 101 mounted on the is installed.

Meanwhile, the ice making control unit 71 has a water supply valve of the heater 70 and the water supply 62 according to the detection result of the temperature sensor 69, the ice tray transceiver 72, and the ice bank transceiver 90. 65 and a control panel 102 for controlling the drive motor 68 of the ice mechanism 66 is provided.

The control panel 102 determines the ice making completion according to the detection result of the temperature sensor 69, and turns on the heater 70 when it is determined that the ice making is completed.

In addition, the control panel 102 determines at least one of water supply completion and icing completion according to the detection result of the ice-making radio transceiver 72.

Hereinafter, the control panel 102 determines the completion of the water supply according to the detection result of the ice-making radio wave transceiver 72 when water is supplied by the water supply 62, and determines the ice-making radio wave transceiver 72 of the ice-making transceiver when the water is iced by the ejector 67. The description will be limited to determining the completion of the ice according to the detection result.

The control panel 102 determines that the icing by the ejector 67 is completed, determines that the ice bank 80 is not full, turns on the water supply valve 65, and determines that the water supply is completed. Off).

The control panel 102 determines the full ice according to the reception result of the ice bank radio transceiver 90.

Reference numeral 78 denotes a slider having an inclined flat surface such that the ice spread by the ejector 62 slides into the ice bank 80 and the water contained in the ice making space 61a of the ice making tray 61 does not overflow. to be.

Looking at the operation of the present invention configured as described above are as follows.

First, the control panel 102 turns on the water supply valve 65, the water supply cup 63 contains water supplied through the water supply hose 64, and the contained water is an ice making space 61a of the ice making tray 61. ) And then gradually rises.

The control panel 102 controls the ice making transmitter 73 to propagate in the ice making transmitter 73, and the radio wave transmitted from the ice making transmitter 73 is reflected in the ice making space 61 a and received by the ice making receiver 74. The ice making receiver 74 outputs a reception result to the control panel 102.

The control panel 102 determines whether water is supplied using a time taken from the ice making transmitter 73 to the reception of the ice making receiver 74 after the radio wave is transmitted, and determines the water supply amount or the water supply level. For example, when it is determined that the time is shorter than the water supply start time, it is determined that water supply is started. When it is determined that the time is longer than the water supply completion time, it is determined that water is not supplied to the set water supply level or the water supply level. If it is determined that the water supply completion time is equal to or shorter than the water supply completion time, it is determined that water is supplied to the set water supply amount or the water supply water level (that is, water supply completion).

When it is determined that water supply is completed, the control panel 102 turns off the water supply valve 65.

On the other hand, the water contained in the ice making space 61a of the ice making tray 61 is cooled by heat-exchanging with cold air or ice making tray 61 in a freezer compartment.

Meanwhile, when the temperature of the ice making tray 61 sensed by the temperature sensor 69 becomes lower than the ice making completion set temperature, the control panel 21 determines that ice making is completed and turns on the heater 70, and the heater 70. The temperature of the ice making tray 61 is gradually increased by turning on, and the iced ice I is separated from the ice making tray 61 while starting to melt from the portion in contact with the ice making tray 61.

Thereafter, the control panel 102 rotates the pin 67b of the ejector 67 from the initial position A to the ice position B, and then starts moving to the driving motor 68 to return to the initial position A again. Output the signal.

When the drive motor 68 is driven, the pin 67b of the ejector 67 is in contact with the ice at the initial position A, and if the ice I is separated from the ice tray 61, the ice I is removed. Rotates to the ice position B after returning, and then returns to the initial position A, and the ice I is lifted up by the slider 78 and is then guided to the slider 78 to move the ice bank 80. It moves to the storage space 81a of the box 81.

On the other hand, since the ice I and the ice making tray 12 are fixed, the pin 67b of the ejector 67 does not separate the ice I from the ice making tray 61 and the ice I being separated. It cannot return, but returns to the initial position A.

As described above, when the pin 67b of the ejector 67 returns to the initial position A without the ice I spread, the control panel 102 returns the initial position of the pin 15b of the ejector 15. Re-drive the drive motor 68 to rotate again in A).

If the driving motor 68 is re-driven while the heater 70 is on, the ice I is separated from the ice making tray 12, and the pin 67b of the ejector 67 is the driving motor 68. Rotation of the ice (I) at the time of re-rotation to the ice position (B) and then returned to the initial position (A).

On the other hand, in the above ice-making operation, the control panel 102 controls the ice making transmitter 73 to propagate in the ice making transmitter 73, and the radio wave transmitted from the ice making transmitter 73 is reflected in the ice making space 61a. It is received by the ice making receiving unit 74, and the ice making receiving unit 74 outputs the reception result to the control panel 102.

 The control panel 102 determines the completion of the icing using the time taken for the radio wave to be received by the ice making receiver 74 after the radio wave is transmitted from the ice making transmitter 73. For example, if it is determined that the time is shorter than the ice making completion time, it is determined that ice making is not completed, and if it is determined that the time is equal to or longer than the ice making completion time, it is determined that ice making is completed.

The control panel 102 immediately turns off the heater 70 when it is determined that the ice is completed.

That is, the control panel 102 turns off the heater 70 at the moment when the ice I leaves the ice making space 61a of the ice making tray 61, and the power consumption of the heater 70 and the heater 70 Freezer load loss due to this is minimized.

Meanwhile, the ice iced from the ice making tray 61 is gradually filled in the storage space 81a formed in the box 81 of the ice bank 80, and the control panel 102 propagates in the ice bank transmitter 91. The ice making transmitter 91 is controlled so that the electric wave transmitted from the ice bank transmitter 91 is reflected in the storage space 81a and received by the ice bank receiver 82, and the ice bank receiver 82 controls the reception result. Output to panel 102.

The control panel 102 determines the completion of the icing using a time taken from the ice bank transmitter 91 to the reception by the ice bank receiver 92 after the radio wave is transmitted. For example, if it is determined that the time is longer than the ice time, it is determined that the ice bank 80 is not full, and if it is determined that the time is shorter than the ice time, it is determined that the ice bank 80 is full.

If it is determined that the ice is not full, the control panel 102 repeats the above water supply, ice making, heating, and ice breaking, and if it is determined that the ice is full, the control panel 102 stops the water supply and the subsequent water until it is determined that it is not full ice.

The automatic ice making device of the present invention configured as described above is provided with a radio transceiver for transmitting and receiving radio waves to the ice making space, the control unit determines the completion of the water supply according to the reception result of the radio transceiver, to determine the amount of water supplied to the ice tray The ability to accurately detect radio waves and to supply a certain amount of water provides the advantage of preventing water from overflowing outside of the ice making tray and uneven ice size.

In addition, the automatic ice making apparatus of the present invention is provided with a radio transceiver for transmitting and receiving radio waves to the ice making space, the control unit can determine the completion of the ice ice according to the reception result of the radio transceiver, and optimally detects the completion of the ice, the heater Since it can be turned off quickly, there is an advantage to reduce the energy by minimizing the heat generated by the heater.

In addition, the automatic ice making apparatus of the present invention is provided with a radio transceiver for transmitting and receiving radio waves to the storage space of the ice bank, when the control unit detects whether or not the full moon according to the reception result of the radio transceiver mechanically detects whether or not. It is possible to prevent mechanical restraints and failures due to freezing that may occur, and to prevent erroneous detection.

Claims (10)

 An ice maker including an ice making tray having an ice making space in which water is iced, and a water supply for supplying water to the ice making space; A radio wave transceiver for transmitting and receiving radio waves to the ice making space; A control unit for determining the completion of water supply according to a reception result of the radio wave transceiver to control the ice maker; The radio transceiver includes an ice making transmitter which transmits an electric wave to the ice making space and an ice making receiving unit which receives a radio wave reflected from the ice making space, wherein the ice making transmitter and the ice making receiver are installed together on one substrate. The ice tray is formed so that the water overflow prevention portion is extended upward, The one substrate is an automatic ice making device installed in the water overflow prevention unit. An ice maker including an ice making tray having an ice making space in which water is iced, and an ice making mechanism which ices the ice ice in the ice making space; A radio wave transceiver for transmitting and receiving radio waves to the ice making space; And a controller for controlling the ice maker by determining completion of the ice according to the reception result of the radio transceiver; The radio transceiver includes an ice making transmitter which transmits an electric wave to the ice making space and an ice making receiving unit which receives a radio wave reflected from the ice making space, wherein the ice making transmitter and the ice making receiver are installed together on one substrate. The ice tray is formed so that the water overflow prevention portion is extended upward, The one substrate is an automatic ice making device installed in the water overflow prevention unit. delete delete delete delete delete delete delete delete

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