KR100199978B1 - Automatic ice maker - Google Patents

Abstract

The automatic ice maker includes an ice tray, a driving unit casing that houses the ice tray driving unit and supports the ice tray, and an ice container installed below the ice tray to receive the ice A lifting and supporting unit for supporting the driving unit casing so that the driving unit casing can move upward as the ice-making tray contacts the ice in the ice container, and a limit switch that is operated by contact with the driving unit casing when the driving unit casing rises over a predetermined range, . Thereby, an automatic ice maker is provided which can accurately determine whether or not the ice cubes are fully filled.

Description

Automatic Ice Machine

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic ice maker, and more particularly, to an automatic ice maker capable of detecting an ice-filled state of an ice container by configuring an ice tray to rise as it contacts ice in an ice container.

An automatic ice maker installed in a refrigerator or the like to automatically produce ice is provided with a device for automatically supplying water from a water supply device whenever necessary and stopping the ice making operation when a predetermined amount of ice is produced and stored and informing the outside of the ice making operation.

5 is a sectional view of a conventional automatic ice maker. The automatic ice maker has an ice-making tray 111 provided with a temperature sensor 112 on the floor. The ice-making tray 111 receives water from the water supply pipe 120 connected to the water supply pump 119 in a horizontal state, . The temperature sensor 112 provided in the ice-making tray 111 senses the temperature of the ice-making tray 111 and supplies the sensed temperature to a control unit (not shown). Based on the temperature sensing signal from the temperature sensor 112, And drives the ice-making driving unit 114 housed in the driving unit casing 100 when the temperature is lower than the set temperature. The ice tray driving unit 114 rotates the ice tray 111 in a predetermined direction to separate ice from the ice tray 111 and the separated ice is stored in the ice tray 115 installed below the ice tray 111 .

The ice-making tray 111, which has finished the ice-making process, returns to the original horizontal position in response to the return driving of the ice-making driving unit 114, feeds water again to the ice-making tray 111, and repeats the ice-making operation. Through this process, when the ice storage state in the ice container 115 is saturated, the ice-making detection lever 113 that comes in contact with ice rises, and the ice-making operation is stopped by the control unit that senses this.

In this conventional automatic ice maker, since the ice-full ice detection lever 113 is in contact with only some of the ice stored in the ice bin 115 below the ice-full ice detection lever 113, If the ice container 115 is not stored at a uniform height, measurement of whether or not the ice container 115 is full may not be accurately performed.

In addition, since the automatic ice maker can be installed in various devices having various structures, it is necessary to provide a variety of methods for the ice detector 115 of the ice container 115 for various applications.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide an automatic ice maker having a new type of full ice detection device capable of accurately detecting when ice storage state in an ice container is saturated.

1 is a perspective view of an automatic ice-

2 is a plan view of an automatic ice-

3 is a cross-sectional view of an automatic ice-

4 is a view showing an operation state of the automatic ice-maker according to the present invention,

5 is a sectional view of a conventional automatic ice maker.

DESCRIPTION OF THE REFERENCE NUMERALS

10: driving unit casing 11: ice-making tray

13: Temperature sensor 15: Ice container

17: guide projection 19: limit switch

21: outer casing 23: guide slot

According to the present invention, there is provided an automatic ice maker comprising an ice-making tray, a driving unit casing which houses the ice-making driving unit and supports the ice-making tray, and an ice container installed below the ice- A lifting and supporting unit for supporting the driving unit casing so that the driving unit casing can move upward as the ice-making tray contacts the ice in the ice container, and a limit switch that is operated by contact with the driving unit casing when the driving unit casing rises over a predetermined range, And an automatic ice maker.

Here, the elevation support portion may include a guide protrusion protruding from both sides of the drive casing, and a guide slot guiding the guide protrusion, and a control portion for stopping the ice making operation of the ice-making tray based on a signal from the limit switch . At this time, stop of the ice-making operation by the control unit can be implemented simply by stopping water supply to the ice-making tray.

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

FIG. 1 is a perspective view of an automatic ice maker according to the present invention, FIG. 2 is a sectional view, and FIG. 3 is a plan view. The automatic ice maker includes an ice tray (11) having an outer casing (21), an outer casing (21) in which ice making is performed and a temperature sensor (13) And an ice container 15 for receiving and storing the ice separated from the ice-making tray 11 is provided at a lower portion of the ice-making tray 11. The ice-

The guiding protrusions 17 protrude from both sides of the driving section casing 10 and the guiding slots 23 for guiding the guiding protrusions 17 are formed in the outer casing 21 adjacent to the driving section casing 10 , The driving unit casing 10 supports the ice-making tray 11 and is movable up and down along the guide slot 23. [ Near the upper portion of the guide slot 23, a limit switch 19 is provided which operates by contact with the guide projection 17 of the drive unit casing 10. [

The operation of the automatic ice maker according to this configuration is such that water is supplied to the ice tray 11 in a horizontal state to perform ice making and the temperature sensor 13 provided on the bottom of the ice tray 11 is driven to the ice tray 11 And transmits it to a control unit (not shown). The controller outputs a signal for performing the ice-making operation when the temperature is equal to or lower than the temperature set as the completion of the ice-making, based on the temperature sensing signal from the temperature sensor 13. Accordingly, the ice-making driving unit rotates the ice- . The ice-making tray 11 is vertically inverted by the ice-making driving unit and the ice is separated from the ice-making tray 11 on the basis of this.

The ice cubes separated from the ice-making tray 11 are stored in the ice container 15, and the ice-making tray 11, which has finished ice-making, rotates in the reverse direction in accordance with the return drive of the ice- And returns to the original horizontal state. When the ice tray 11 returns to its home position in a horizontal state, a position sensor (not shown) senses this and sends a signal to the control unit. In response to this, the controller supplies water to the ice tray 11 again, .

Ice is accumulated in the ice container (15) by repeating the ice-making operation, and the ice-making tray (11) in contact with the ice rises in accordance with the height of the stored ice. At this time, the driving unit casing 10 supporting the ice-making tray 11 also rises.

4 is a view showing a state in which the ice-making tray 11 moves upward in contact with the ice in the ice container 15 when the ice-making tray 11 rotates for ice-making. As shown in the drawing, when the ice-making tray 11 is almost vertical due to the rotation for ice-making, the position of the drive casing 10 becomes higher than the position when the ice-making tray 11 returns to the horizontal state. Therefore, as the ice stored in the ice container 15 is stretched, the driving unit casing 10 is raised as a whole while repeatedly rising and falling.

When the drive casing 10 reaches a predetermined height through such operation, the guide protrusion 17 of the drive casing 10 is brought into contact with the limit switch 19 provided near the top of the guide rail. The limit switch 19 is formed over a predetermined range so as to be in contact with the guide protrusion 17 of the drive unit casing 10 whose height changes in the ice-making operation of the ice-making tray 11 and the return operation. Since the height of the ice stored in the ice container 15 may be made uniform while the ice tray 11 is returned to the horizontal state, the height of the ice container 15 may be reduced. To accurately determine the full ice state of the ice container 15, 19 need to be continued for a predetermined period of time. Since the ice tray 11 is in contact with ice, the outer surface of the ice tray 11 is formed of a heat insulating material to ensure normal operation of the temperature sensor 13 provided on the ice tray 11.

The limit switch 19 sends a signal to the control unit while contacting the guide projection 17 of the drive unit casing 10. [ The control unit stops the supply of water to the ice-making tray 11 when the signal of the limit switch 19 continues for a predetermined time. As a result, ice production by the ice-making tray 11 is stopped.

When the water is supplied, the temperature of the ice-making tray 11 rises, but if the water is not supplied, the temperature rise does not occur. Therefore, the detected temperature of the temperature sensor 13 provided on the ice-making tray 11 does not exceed the predetermined temperature. Therefore, when the temperature sensor 13 provided in the ice-making tray 11 is at a certain temperature or lower, the controller can recognize that the ice-making tray 11 is free of water, and in this case, the ice-making operation is not performed.

When the signal from the limit switch 19 is maintained for a predetermined time, a notification device indicating that the ice cubes are full is installed in the ice container 15 so that the ice container 15 can be seen from the outside. If there is no signal from the limit switch 19 and the temperature of the temperature sensor 13 is maintained at a predetermined temperature or lower, the ice tray 11 is in a state where there is no water, So that the water supply tank can be seen to be free from water.

As described above, according to the present invention, there is provided an automatic ice maker capable of detecting when ice storage state in an ice container is saturated by using an ice-making tray rising in contact with ice in an ice container.

Claims (4)

1. An automatic ice maker comprising: an ice-making tray; a driving unit casing that houses the ice-making driving unit and supports the ice-making tray; and an ice container installed below the ice-making tray to receive the ice cubes; A lifting and supporting unit for supporting the driving unit casing so that the driving unit casing can move upward as the ice-making tray contacts the ice in the ice container; And a limit switch which is operated by contact with the drive unit casing when the drive section casing rises above a predetermined range. The method according to claim 1, Wherein the elevating support portion includes a guide projection projecting to both sides of the drive unit casing and a guide slot guiding the elevation of the guide projection. The method according to claim 1, Further comprising a controller for stopping the ice-making operation of the ice-making tray based on a signal from the limit switch. The method of claim 3, Wherein stopping of the ice-making operation by the control unit is performed by stopping water supply to the ice-making tray.