KR19990049551A - Automatic ice maker of the refrigerator - Google Patents

Abstract

The present invention provides an automatic ice maker of the refrigerator. When the ice is completed, it is turned off. When the ice making container returns to the ice making position, the ice container detects that the ice is in an ice state. If the ice container is not in ice, the ice container is in the on state. To prevent the ice-covering device comprising: a spiral ice-covering shaft cam formed in the axial direction on a portion of the outer peripheral surface of the output shaft for transmitting the driving force of the motor to the rotating shaft for rotating the ice making vessel; A movable lever having one end inserted into the ice sensing shaft cam to reciprocate in the axial direction according to the rotation of the output shaft; A sliding sensor lever fixedly connected to the other end of the movable lever via a connecting lever and a hinge vertically connected to the other end of the movable lever, the lower end of the movable lever being inserted into the ice bucket; And an ice detection switch on / off according to the position in which the movable lever reciprocates along the ice detection shaft cam.

Accordingly, the structure of the ice-covering device that detects the ice to stop the ice-making operation can be simplified, thereby reducing the manufacturing cost.

Description

Automatic ice maker of the refrigerator

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic ice maker such as a refrigerator, and more particularly to an automatic ice maker of a refrigerator capable of efficiently carrying out ice from an ice maker of the automatic ice maker.

In recent years, large-scale high-end refrigerators have built-in water dispensers that allow cold water or ice to be supplied without opening the doors of the refrigerators, and automatic ice machines that automatically make ice.

A schematic configuration of a conventional automatic deicing device for a refrigerator is shown in FIGS. 1 and 2. In FIG. 1, a freezing compartment 2, a refrigerating compartment 3, and an ice making compartment 4 are generally formed inside the refrigerator body 1, and the air cooled by the cooler 5 is an air fan. It is configured to be supplied through the cold air duct (7) or the like by (6).

The conventional automatic ice making apparatus includes an ice maker 10 installed in the ice making chamber 4 and a water supply device 20 installed in the refrigerating chamber 3. The ice maker 10 includes a drive unit 12 on which a control unit, a motor, or the like is installed, an ice maker 14 connected to the drive unit 12 through a rotation shaft, and a support frame for supporting the ice maker 14. (13) and the like. In the lower part of the ice-making container 14, the ice container 30 containing the made ice fragments is arrange | positioned.

The water supply device 20 is a device for supplying quantitative ice making water to the ice making container 14 of the ice maker 10. As shown briefly in FIG. 1, the water supply device 20 includes a water supply tank 22 storing a predetermined amount of water, a water support container 24 receiving a certain amount of water therefrom, and the water support container 24. It is composed of a feed water pump 26 for supplying the water of the () to the ice making container (14) and a water supply pipe (28) serving as a moving passage of water from the water supply pump 26 to the ice making container (14).

In addition, although not shown, various sensors for sensing the temperature or horizontal position of the ice making container 14 and the like are also included.

As shown in FIG. 2, the driving unit 12 of the ice maker 10 includes a circuit board 122 on which a control part including a microcomputer and the like is mounted. The motor 124 and the motor 124 are mechanical driving devices. It comprises a gear mechanism 126 for decelerating, amplifying and transmitting the motion of the) and an output shaft 128 for outputting the transmitted motion. In addition, a variety of sensor mechanisms are included for sensing a rotation state of the output shaft 128 to control a rotation operation of the ice making container 14 and the like. Figure 2 shows the ice detection lever 17, which is a lever for detecting whether the ice bucket 30 at the bottom is full.

The ice making container 14 is rotatably fixed to the support frame 13 around the rotating shaft 11 connected to the output shaft of the driving unit 12. The ice making container 14 includes a plurality of ice making cells, which are spaces in which water is formed and formed into ice, and a protrusion 16 is installed at one side thereof, and is subjected to a force by hitting a predetermined portion of the auxiliary plate 15 during rotation. The container 14 is twisted as a whole so that the ice can fall down.

The automatic ice making device 10, 20, 30 having such a configuration includes a motor after freezing the water supplied from the water supply tank 22 through the water supply pipe 28 in the ice making container 14 (ice making step). By rotating the ice making container 14 by the driving unit 12 to which the driving device is installed, the ice is rotated by reversing up and down (Icing step), and the cycle of storing the ice in the ice container 30 under the ice is repeated.

The state of the ice making container 14 in this ice making and the ice making step is shown in FIG. 3A and 3B, respectively. 3A shows that the ice making container 14 is in a horizontal state, which is a state in which water is supplied and ice is being processed for a predetermined time, and until just before the ice is started.

When the ice making process is completed by a temperature sensor, a timer, or the like, the motor 124 of the driving unit 12 is driven to rotate the rotating shaft 11, so that the ice making vessel 14 fixed to the rotating shaft 11 is 120, for example. Rotate by degrees (Figure 3b). When the rotation angle of the ice maker 14 reaches a predetermined angle (for example, 120), the protrusion 16 formed on one side thereof is caught by the contact portion 15a of the auxiliary plate 15, and the ice maker 14 is twisted as a whole. As a result, the ice accumulated in each ice-making cell of the ice-making container 14 is iced and falls into the ice container 30 below it.

In this ice step (FIG. 3B), the ice making container 14 is subjected to a rotational force that continues in one direction while stopped by the contacting portion 15a. After a predetermined time has elapsed, for example, 120 DEG in the opposite direction again. To the original horizontal position (FIG. 3A). Thus, prepare to start the next ice making cycle.

At this time, if the ice container 30 placed below the ice making container 14 is filled with ice (full ice state), no further ice making or ice making operation is required, and thus, the ice ice is required to control the ice making operation. This ice level is detected by the ice detection lever 17 as shown in the side view in FIG.

The ice sensing lever 17 is convex downward and is arranged to be inserted into the ice bucket 30. If the ice is not full, the lower end of the ice detection lever 17 is inserted into the ice container 30 as it is. Then, the contact projection 19 connected to the outer case of the drive unit 12 via the connecting lever 18 of the end side inserted into the hinge 17a so as to be rotatable, the contact portion of the ice sensing switch 125 is connected. The state of contact with 125a (ON state) is maintained. As described above, when the ice detection switch 125 is in the ON state, the ice making and the ice making operation are normally performed as described above.

4A and 4B also show how the ice detection switch 125 is operated during the ice breaking operation. That is, FIG. 4A is in the ON state where the contact protrusion 19 is stuck to the contact part 125a. When the moving operation is started, the motor 124 is driven and the output shaft 128 which receives the rotational force through the gear mechanism 126 starts to rotate. A part of the output shaft 128 protrudes the shaft cam 128a for sensing the ice. When the output shaft 128 is rotated and the ice making container 14 is inverted, as shown in FIG. 4B, the ice sensing shaft cam 128a lowers the connecting lever 18 to lower the contact protrusion 19. As a result, the ice detection switch 125 is turned off. At this time, the ice sensor lever 17 connected via the connecting lever 18 and the hinge 17a is raised as shown by the dashed-dotted line in FIG.

When the ice-making detection switch 125 is turned off, the ice-making operation is stopped, and the motor 124 reversely rotates so that the ice making container 14 returns to the horizontal position for original ice making. Then, the ice detection lever 17 is lowered, and the state is again as shown in FIG. 4A, and the ice detection switch 125 may be turned on.

By the way, if the ice container 30 is in full ice when the ice is completed, even if the ice making container 14 is returned to its original position, the ice detection lever 17 cannot be lowered while the lower end is in contact with the ice. The ice detection switch 125 is maintained in the OFF state. Then, even if the ice making is completed again after the ice making step, the ice making switch 125 is OFF, and thus the ice making operation is not performed.

Therefore, according to such an ice detection system, the automatic ice making device can be efficiently operated so that excessive ice fragments are not stored in the ice container 30.

However, in the above-described apparatus for detecting the ice of the automatic ice making device, the structure for detecting and controlling the vertical motion of the ice-covering lever 17 is complicated, and its size is large, which requires a lot of manufacturing cost, thereby reducing productivity. There was a problem.

Accordingly, an object of the present invention is to provide an automatic ice making device for a refrigerator, which is simply configured as a device capable of detecting that an ice container is in an ice state.

1 is a side cross-sectional view showing the internal structure of an automatic ice maker portion of a conventional refrigerator;

2 is a partial cross-sectional plan view showing an ice making unit portion of an automatic ice making device installed in a conventional refrigerator;

Figure 3a and 3b is a rear view showing the state during the ice making and ice-making container of the conventional ice making apparatus,

Figures 4a and 4b is a front view showing the state of the ice detection switch before and after the ice in the conventional ice making apparatus.

Figure 5 is a side view showing the state of the ice detection switch before and after the ice in the conventional ice making apparatus.

Figure 6 is a side view showing the state of the ice detection switch according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

1: refrigerator body 2: freezer

3: cold storage room 4: ice-making room

5: cooler 6: air fan

7: cold air duct 10: ice maker (conventional)

11: rotating shaft 12: drive part

122: circuit board (control unit) 124: motor

125: ice detection switch 126: gear mechanism

128: output shaft 128a: shaft cam for ice detection

225: ice detection switch 225a: movable wire

225b: connection portion 225c: fixed wire

228: output shaft 228a: shaft cam for detecting the ice

13: support frame 14: ice tray

15: auxiliary plate 15a: contact portion

16: protrusion 17: ice detection lever

18: connecting lever 19: contact projection

20: water supply device 22: water supply tank

24: water support container 26: water supply pump

28: water supply pipe 30: ice bucket

The automatic ice making apparatus of the refrigerator according to the present invention for achieving the above object is turned off when the ice making is completed, in the automatic ice making apparatus for inverting the ice making container and iced the ice making container in the ice tray under the ice making container. When the ice making container returns to the ice making position, the ice container detects that the ice container is in an ice state, and if the ice container is not full, the ice container is turned on. A spiral camshaft sensing shaft cam formed in the axial direction on a part of an outer circumferential surface of the output shaft for transmitting the driving force of the motor to the rotating shaft for rotating the ice making vessel; A movable lever having one end inserted into the ice sensing shaft cam to reciprocate in the axial direction according to the rotation of the output shaft; A sliding sensor lever fixedly connected to the other end of the movable lever via a connecting lever and a hinge vertically connected to the other end of the movable lever, the lower end of the movable lever being inserted into the ice bucket; And an ice making switch on / off according to a position in which the movable lever reciprocates along the shaft cam for ice detection.

In this case, the ice detection switch is configured to include a movable wire having one end fixed to the movable lever and reciprocating along the movable lever, and a fixed wire installed to be detached from and contacted according to the position of the movable wire. The structure of the ice-sensing device that detects and stops the ice-making operation can be simplified.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. Figure 6 is a side view showing the state of the ice detection switch according to an embodiment of the present invention.

Automatic deicing device of the refrigerator according to a preferred embodiment of the present invention, when de-icing is completed, as usual, automatic reversing the ice making container 14 and iced to store in the ice bucket 30 of the lower ice container (14) In the ice making apparatus, when the ice is completed, it is turned off, and when the ice making container 14 returns to the ice making position, the ice container 30 is detected as being in an ice state. In the case of the full ice, the configuration of the full ice detection device that keeps the off state from performing the next ice breaking operation is simplified.

The ice detection device may include an ice detection shaft cam 228a and a movable lever 219 formed on the output shaft 228, an ice detection lever 17, and an ice detection switch 225 vertically connected thereto. have.

As shown in FIG. 6, the shaft cam 228a for sensing the ice is provided on a part of the outer circumferential surface of the output shaft 228 for transmitting the driving force of the motor 124 to the rotation shaft 11 for rotating the ice making container 14. It is a spiral shaft cam formed in the axial direction. Unlike the conventional protruding shaft cam 128a, the outer circumferential surface of the output shaft 228 is concavely formed in a spiral shape in a wave. That is, the device slidably inserted into the ice sensing shaft cam 228a can reciprocate in its axial direction as the output shaft 228 rotates.

The movable lever 219 is a means for reciprocating in the axial direction in accordance with the rotation of the output shaft 228, one end is slidably inserted into the ice detection shaft cam 228a. The movable lever 219 is vertically connected to the ice detection lever 17 at one end thereof.

The ice detection lever 17 may be used in a form similar to that of the conventional ice detection lever 17 described with reference to FIG. 5, that is, a bottom end thereof protrudes downward and inserted into the ice container 30. However, one end of the ice detection lever 17 is fixedly connected via a connecting lever 218 and a hinge 17a that are vertically fixedly connected to the other end of the movable lever 219. Thus, the ice sensing lever 17 can rotate about the hinge 17a to reciprocate up and down. On the other hand, the motion by the rotation of the output shaft 228 causes the ice detection shaft cam 228a to move. It is driven through the sliding movable lever 219, and on the other hand, it can be blocked by ice chips stored in the ice bucket 30.

In addition, the ice detection switch 225 is configured to be on / off according to the position where the movable lever 219 reciprocates along the ice detection shaft cam 228a. The ice detection switch 225 may be configured as a micro switch which can be turned on / off while the driving lever 219 reciprocates.

According to a preferred embodiment, as shown in Figure 6, the ice detection switch 225 is fixed to the movable lever 219, one end of the movable wire 225a for reciprocating along the movable lever 219, and movable According to the position of the wire 225a may be configured to include a fixing wire (225c) is installed to be in contact with and separated therefrom. The movable wire 225a is connected to the fixed wire 225c through the connecting portion 225b, and the connecting portion 225b may include a device capable of outputting an electrical signal.

In the automatic ice making apparatus according to the preferred embodiment of the present invention having such a configuration, the operation of the ice sensing device will be described with reference to FIG. 6 as follows.

When it is detected that ice making is completed, it is checked whether the state of the ice detection switch 225 is on or off. If it is off, no ribbing is performed. If it is on, the ribbing is started. 6, the lower end of the ice detection lever 17 is at its lowest state, and the movable wire 225a of the ice detection switch 225 is in contact with the fixed wire 225c. .

The ice is started and the motor 124 is driven and the driving force is transmitted to the ice making container 14 via the output shaft 228. When the output shaft 228 is rotated, it is guided to the spiral ice detection shaft cam 228a, and the movable lever 219 is moved, and this movement is converted to the rise of the ice detection lever 17 through the hinge 17a. Thus, when the moving operation is completed, the movable wire 225a, which is fixed at one end to the movable lever 219 and moves together, is separated from the fixed wire 225c and the ice detection switch 225 is turned off.

When the ice is completed, the output shaft 228 is inverted. At this time, if the lower end of the ice detection lever 17 is prevented from falling by the ice cubes filling the ice container 30, the movable lever 219 connected thereto. ) Will not move. As a result, since the movable wire 225a does not move, the off state of the ice detection switch 225 is maintained so that the ice-breaking operation is not performed.

According to the configuration and operation of the icemaker of the refrigerator according to the embodiment of the present invention as described above, the structure of the ice-covering device that detects the ice and stops the ice-making operation can be simplified, thereby reducing the manufacturing cost.

While the invention has been shown and described in connection with specific preferred embodiments, it is understood in the art that the present invention may be variously modified, modified, applied and changed without departing from the spirit or the scope of the invention. Those skilled in the art can easily know.

Claims (2)

When the ice making is completed, the automatic ice making device that inverts and ices the ice making container 14 and stores it in the ice bucket 30 of the ice making container 14 is turned off when the ice making is completed, and then the ice making container 14 When the) is returned to the ice making position, the ice container 30 detects that the ice is in a full ice state, and when it is not full ice, the ice container 30 is in an on state. The sensing device is: A spiral ice detection shaft cam 228a formed axially on a part of an outer circumferential surface of the output shaft 228 for transmitting the driving force of the motor 124 to the rotation shaft 11 for rotating the ice making container 14; A movable lever 219 having one end inserted into the ice sensing shaft cam 228a and reciprocating in the axial direction according to the rotation of the output shaft 228; The ice detection lever (320) fixedly connected to the other end of the movable lever 219 via a connecting lever 218 and a hinge 17a vertically fixed, and having its lower end protruded downward and inserted into the ice container 30 ( 17); And An automatic ice making apparatus for a refrigerator, characterized in that the movable lever (219) comprises an ice detection switch (225) which is turned on / off according to the position of the reciprocating motion along the ice detection shaft cam (228a). According to claim 1, wherein the ice detection switch 225 is fixed to the movable lever 219, one end of the movable wire 225a for reciprocating along the movable lever 219, and according to the position of the movable wire 225a Automatic de-icing device of the refrigerator, characterized in that it comprises a fixed wire (225c) is installed to be in contact with and separated.