KR0164749B1 - Automatic ice maker equipped with water supplying apparatus - Google Patents

Abstract

The present invention relates to an automatic ice maker for a refrigerator having a water supply control device to accurately supply the amount of water required by the ice maker.

When the automatic ice maker of the present invention is installed at the discharge port 96 of the water supply hose 95, the automatic ice maker further includes a water supply control device 100 having a temperature sensor 113 arranged to be movable up and down, thereby allowing the movement of water to fall. The water temperature is sensed by the temperature sensor 113 which is moved downward to the proper water level B of the ice making container 50 by energy, so that water can be stopped at the correct water level.

Description

Refrigerator automatic ice maker with water supply

1 is a longitudinal sectional view of a refrigerator in which a conventional automatic ice maker is installed.

2 is a longitudinal sectional view of a refrigerator provided with an automatic ice maker according to the present invention.

3 is a side view of the illustrated ice container of FIG.

4 is a partial perspective view of the ice making container for showing the action position of the water supply control device of the present invention.

5 is an exploded perspective view of the water supply control apparatus of the present invention.

* Explanation of symbols for main parts of the drawings

50: ice making container 70: ice storage container

80: water storage tank 90: water supply pump

95: water supply hose 100: water supply control device

110: moving member 112: sensor rib

112: sensor rib 113: temperature sensor

114: heating wire 115: water splash prevention rib

120: spring

The present invention relates to an automatic ice maker for a refrigerator, and more particularly, to an automatic ice maker for a refrigerator having a water supply control device for accurately supplying the amount of water required by the ice maker.

As shown in FIG. 1, a conventional refrigerator having an automatic ice maker includes a freezer compartment 3 and a refrigerating compartment 4 intersected by an intermediate partition 2 on a refrigerator body 1, and a freezer compartment 3 ) And the refrigerating chamber 4 are opened and closed by the freezing chamber door 5 and the refrigerating chamber door 6, respectively. A cooler 7 is installed at the rear of the freezer compartment 3 to generate cold air, and a cooling fan 8 is installed above the cooler 7 so that the generated cool air is supplied to the freezer compartment 3 and the refrigerating compartment 4. Forced circulation In order to guide the supply of cold air, the front plate 9 and the rear plate 10 are installed in front of the cooling fan 8, and the cold plate discharge port is provided in the front plate 9 to guide the supply of cold air to the freezer compartment 3. (11) is formed, the refrigeration chamber duct 12 is installed in the back plate 10 to guide the supply of cold air to the refrigerating chamber (4).

On the other hand, the freezing chamber (3) is provided with an automatic ice maker (20) for making ice using cold air generated in the cooler (7). As shown in FIG. 1, the conventional automatic ice maker 20 stores water in a plurality of concave grooves 21 'formed therein to make ice by using cold air of the freezing chamber 3 It is provided with the container 21 and the storage container 22 for storing the angular ice which the ice-making container 21 produced. In the refrigerating chamber 4, a water storage tank 23 and a water supply pump 24 for supplying water to the ice making container 21 are installed, and water in the water storage tank 23 is transferred to the ice making container 21. A water supply hose 25 for delivery is arranged from the water storage tank 23 of the refrigerating compartment 4 over the upper part of the ice making container 21 of the freezing compartment 3. A drive unit 26 is installed in front of the ice making container 21 to rotate the ice making container 21 to about 135 ° and to twist the falling ice to the ice storage container 22 when the ice making is completed.

In the automatic ice maker 20 configured as described above, the water supply, the ice making operation, and the ice making operation are automatically performed by a controller (not shown).

However, the conventional automatic ice maker 20 configured as described above has a disadvantage in that the amount of water supplied cannot be adjusted and supplied exactly as required by the ice maker 21. In more detail, when the ice making is completed, the control unit operates the driving unit 26 to rotate the ice making container 21 to about 135 ° and then twists the ice in the ice making container 21 to the ice storage container 22. (Iii), after the ice maker 21 is returned to its original position, the water supply pump 24 is operated to transfer the water in the water storage tank 23 to the ice maker 21 through the water supply hose 25. At this time, the amount of water delivered to the ice making container 21 is pre-programmed to supply water for a uniform time by the time required to fill the amount of water corresponding to the volume of the concave groove 21 'of the ice making container 21, If there is an angular ice that is not separated from the ice making container 21 during the ice-making operation, water is filled up by the volume occupied by the ice making water to fill the top of the ice making container 21 and overflows into the ice storage container 22. .

As a result, the ice cubes formed in the concave grooves 21 'of the ice-making container 21 are connected to each other to form one large ice mass, so that the ice-making operation is not performed properly. will be. In addition, by angling the ice cubes stored in the water storage container 22 is tangled with each other, when using this, there is a hassle to remove the attached ice cubes.

The present invention is to solve the above problems, the purpose of the automatic ice maker for refrigerators having a water supply control device capable of supplying the correct amount of water as required by the ice making container so that only ice of a certain size is always made. To provide.

The present invention for realizing the above object is provided with an ice making container and an ice storage container installed in the freezer compartment, a storage tank and a water supply pump installed in the refrigerating chamber, and a water supply hose which extends from the water storage tank to an upper portion of the ice making vessel. In one automatic ice maker, the automatic ice maker further comprises a water supply control device having a temperature sensor which is installed at the discharge port of the water supply hose and is arranged to move up and down. The water temperature is sensed by the temperature sensor which is moved downward to the appropriate level, characterized in that the water supply can be stopped at the correct water level.

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

Figure 2 shows the interior of the refrigerator equipped with an automatic ice maker according to the present invention. As shown in the drawing, the automatic ice maker according to the present invention includes an ice storage container 50 and a storage container 70 installed at one side of the freezing chamber 3 and a storage tank 80 and a water supply pump 90 installed in the refrigerating chamber 4. ), The water supply hose 95 is installed to extend from the water storage tank 80 to the upper portion of the ice making container 50, and the water supply control device 100 forming a feature of the present invention.

The water supply control device 100 is a moving member 110 which is fitted to the discharge port 96 of the water supply hose 95 and the spring 120 is installed between the discharge port 96 and the moving member 110. It is composed.

3 is a view showing the water supply control device 100 and the ice making container 50 of the present invention. The moving member 110 is provided with a hole 116 at the upper end thereof to be fitted into the discharge hole 96 of the water supply hose 95, and a spring holder 98 is installed at the lower end of the discharge hole 96 to provide the moving member ( The spring 120 is disposed between the upper end of the 110 and the spring holder 98. The movable member 110 is installed between the sensor ribs 112 extending vertically downward from the upper end and between the sensor ribs 112 and the discharge port 96 to prevent water from splashing on the sensor ribs 112. A water splash prevention rib 115 is provided. In the lower portion of the water splash prevention rib 115, the moving member 110 hits the falling water flowing out from the water supply hose 95 when water is supplied to the appropriate level B of the ice making container 50 (FIG. 4). The operation rib 111 which moves downward to the side is formed in the horizontal direction. At the lower end of the sensor rib 112 is attached a temperature sensor 113 for stopping the water supply by detecting the temperature of the water up to the appropriate water level (B).

The operation ribs 111 are disposed below the discharge port 96 so as to cover half of the water stream sprayed from the discharge port 96 to move the moving member 110 downward by dropping the water. However, the movable member 110 is supported by the elastic force of the spring 120 in the state that the water supply is not so that the lower end to which the temperature sensor 113 is attached is the upper end of the concave groove 51 formed in the ice making container 50. (A) (see Figure 4).

In addition, all the ice making vessels 50 are provided with a driving unit 60 for rotating the ice making vessels 50 by about 135 ° when the ice making is left, and then twisting and retracting the container 50. As shown in FIG. 4, the ice making container 50 has a plurality of concave grooves 51 arranged in two rows so that the concave grooves 51 are filled with water to be iced by cold air in the freezing chamber 3. . Grooved water passages 52 are formed in the front and rear directions of the concave grooves 51 and at both ends thereof so that water supplied from the water supply hose 95 passes through the water passages 52. ) Is filled. The lower end of the movable member 110 to which the temperature sensor 113 is attached is located at the upper end A of the concave groove 51 in a state where water is not supplied, and then the upper end of the concave groove 51 by the kinetic energy of water supply. It goes down to the proper water level (B) located between (A) and the lower part (C).

5 is an exploded perspective view of the water supply control device 100 of the present invention. The discharge hole 96 of the water supply hose 95 is fitted to the water supply hose 95 through a hole 116 formed at the upper end of the moving member 110. A spring holder 98 is provided at the discharge port to occupy the spring 120, and a locking jaw 97 is formed at the upper portion of the spring holder 98 to restrict downward movement of the movable member 110. It is. The locking jaw 97 is formed at a position coinciding with the distance that the moving member 110 moves to the proper water level B of the concave groove 51 by the drop of water.

The sensor ribs 112 and the water splash prevention ribs 115 extend vertically downward from the upper end of the moving member 110. The operation rib 111 extends in the transverse direction from the intermediate position of the water splash prevention rib 115 and is placed perpendicular to the water supply direction. A temperature sensor 113 is installed at the lower end of the sensor rib 112 to sense the temperature of the water filled up to the appropriate water level B to stop the water supply, and a hot wire 114 is wound around the temperature sensor 113. ) Will evaporate the water.

Referring to the effect of the water supply control device 100 of the present invention configured as described above are as follows.

First, in a state in which water is not supplied, the moving member 110 of the water supply control device 100 is positioned at the upper end portion A of the concave groove 51 of the ice making container 50 by a spring 120, and a temperature sensor. 113 detects a temperature of -15 ℃ to -21 ℃ the operating temperature range of the freezing chamber (3). When water is supplied at the time of initial operation in this state, or when the ice removal operation of the driving unit 60 is completed and the water is re-supplied to the ice making container 50 again, the water supply pump 90 operates to supply water to the ice making container 50. Filled up. As the water is discharged from the discharge port 96 of the water supply hose 95 and hits the operating rib 111 of the moving member 110, the moving member 110 is caught by the catching jaw 97 formed at the discharge hole 96. It moves downward until it is, in this state the temperature sensor 113 is located at the appropriate water level (B) in the concave groove 51 to wait for the water to be filled up to this position. Here, the temperature of the water in the water storage tank 80 located in the refrigerating chamber 4 maintains the temperature in the refrigerating chamber 4 0 ° C to + 7 ° C.

As the water supply continues, when the water fills up the lower end portion C of the concave groove 51 of the ice making container 50, the water is transferred to the other concave groove 51 through the water passage 52. When the water is filled up to the appropriate level B of the concave groove 51, the temperature sensor 113 is immersed in the water to increase the temperature and the controller (not shown) by the temperature rise of the water supply pump 90 The water supply is stopped by stopping the operation. Thereafter, as the moving member 110 moves upward to its original position by the restoring force of the spring 120, the temperature sensor 113 is placed on the upper end A of the concave groove 51, thereby It will not interfere with the ice moving. In addition, in order to prevent the water buried in the temperature sensor 113 is frozen by the cold air of the freezing chamber 3 and prevents accurate temperature sensing, the water wire 114 is operated for a predetermined time to operate the temperature sensor 113. To evaporate water.

As can be seen from the above, the automatic ice maker equipped with the water supply control device 100 according to the present invention can supply an appropriate amount of water at all times even if ice cubes remain in the ice making container 50 even after the ice making operation. It is possible to make separate ice cubes. Therefore, the user does not have to remove the ice cubes, and the freezing chamber is kept clean.

Claims (2)

Storage water storage and storage tank 80 installed in the refrigerating chamber (4), a water supply pump 90 for generating power to pump the water stored in the storage tank 80 to a constant water pressure, and the water supply pump ( 90 is installed in the freezing chamber (3) to store and store the water supplied by a constant water pressure to make ice, ice-making container 50 formed with a plurality of concave grooves 51, and ice made from the ice-making container (50) Drive unit for rotating the ice making container 50 so that the ice made in the ice making container 50 and the ice storage container 70 installed in the lower portion of the ice making container 50 to store the ( 60 and one end of the refrigerating chamber 4 so that the water stored in the water storage tank 80 is supplied by the pumping force of the feed water pump 90 to the ice making container 50 rotated by the driving unit 60. Is discharged when the other end is located at the top of the ice making container 50 An automatic ice maker for a refrigerator having a water supply control device including a water supply hose (95) connected thereto, wherein the water supply hose (95) is guided to the discharge port (96) of the water supply hose (95) to be moved. A hole 116 through which the discharge port 96 passes is formed on an upper surface thereof, and a sensor rib 112 is formed on a side thereof, and the water supply hose 95 is formed inside the sensor rib 112 by the sensor rib 112. A water splash prevention rib 115 is formed to prevent splashing of water so that the water discharged from the water splashes. An operating rib collided with the falling water discharged from the water supply hose 95 is formed at an inner lower portion of the water splash prevention rib 115. When the water is dropped into the movable member 110 and the operating rib 111 of the movable member 110, the lower end of the movable member 110 is the appropriate level B of the ice making container 50 (111). Control the lowering of the movable member 110 to descend only to the upper portion of the discharge port 96 When the movable member 110 is lowered to the proper water level B of the ice making container 50 by the locking jaw 97 protruding from the locking jaw 97, the water supply is stopped by detecting the temperature of the water. When the water supply is stopped by the temperature sensor 113 attached to the bottom of the sensor rib 112 of the moving member 110 and the detection signal of the temperature sensor 113, the moving member 110 is returned to its original position. The spring 120 and the spring 120 disposed on the outside of the discharge port 96 to restore, and the spring 120 generates an elastic force to support the lower end of the spring 120 so that the movable member 110 is restored to its original position. Refrigerator automatic ice maker with a water supply control device, characterized in that consisting of a spring holder 98 protruding below the discharge port (96). According to claim 1, Around the temperature sensor 113, characterized in that the heating wire 114 for evaporating the water so that the water buried in the temperature sensor 113 does not freeze by the cold air of the freezing chamber (3) is installed. Refrigerator automatic ice maker equipped with a water supply control device.