KR940002649Y1 - Ice-tray - Google Patents

Abstract

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Description

Automatic ice maker

1 to 4 show a first embodiment of the present invention.

1 is a perspective view of a main part seen from the back side.

2 is a cross-sectional view of the main part.

3 is a rear view showing the state of the ice tray upon rotation.

4 is a longitudinal sectional view of the refrigerator.

5 to 8 show a conventional example.

5 is equivalent to FIG.

6 is equivalent to FIG.

7 is equivalent to FIG. 3.

8 is a perspective view of a part of an ice making chamber seen from the front.

* Explanation of symbols for main parts of the drawings

1,14 Ice making room 2,16 Gas

3: output shaft 4,18: ice tray

5,19: support member 7: door

11: refrigerator body 12: freezer

13: refrigerating chamber 15: automatic ice maker

17: output shaft of the drive mechanism 18a: connection portion

18b: shaft 21: water supply tank

22: water supply pump 23: water supply equipment

24: side plate portion 25: the back plate portion

25a: holding part 25b: stopper

25c: engaging portion 25d: engaging hole

26: support piece 27: support

The present invention relates to an automatic ice making device capable of separating ice by rotating the ice tray and turning it upside down.

For example, as an automatic ice-making apparatus provided in the refrigerator with an automatic ice-making apparatus, there exist some shown to FIG. 5 thru | or FIG.

That is, when the base 2 is installed in the upper part of the ice making chamber 1 installed in the refrigerator main body, one end side of the ice making plate 4 is connected to the output shaft 3 of the drive mechanism which is not shown in this base 2. It is.

In addition, the shaft portion 4a on the other end side of the ice making plate 4 is freely rotated to the supporting member 5 forming a c-shape that surrounds the three directions of the ice making plate 4 attached to the base 2 described above. Is supported.

Then, water is supplied to the ice making plate 4 by a metal mechanism (not shown), and after ice making is completed, the ice making plate 4 is rotated in the direction of arrow A of FIG. 7 by the driving mechanism in the base 2. In this case, the ice is separated upside down (in the order of FIGS. 7A, 7B, and 7C) to separate the ice and receive the ice in a storage container not shown below.

At this time, the amount of rotation of the other end side of the ice making plate 4 is regulated by the spotter portion 5a protruding from the supporting member 5, and the ice is separated by twisting the ice making plate 4 as shown in FIG. 7C. It is supposed to be.

Then, a large gap S is provided between one edge of the ice making plate 4 and the supporting member 5 described above.

This is particularly true even when the user unconsciously puts his hand toward the side of the ice tray 4 in the original position rotation of the ice tray 4 after ice separation (in the order of FIGS. 7 (c), (b), and (a)). (Fig. 7B) In order to prevent hands from being caught between the ice making plate 4 and the supporting member 5, ice is sandwiched between the ice making plate 4 and the supporting member 5 at the same time. It also prevents the occurrence of trouble during the ice separation operation of the dish 4.

In recent years, in order to prevent the user from getting caught in the hand, as shown in FIG. 8, the door switch 6 is provided in the front part of the ice making chamber 1 to open and close the ice making chamber 1 as shown in FIG. When the door 7 is opened, it is also conceivable that the rotation of the ice making plate 4 can be stopped by the detection of the door switch 6.

In the above-described conventional method, it is necessary to put a large gap in order to prevent the fingers and ice from being sandwiched between the ice making plate 4 and the supporting member 5, and therefore, the supporting member 5 becomes large. However, there is an absurdity that the installation requires a large space.

In addition, when the leaf switch 6 is provided, it is possible to reliably prevent a finger from being inserted between the ice making plate 4 and the supporting member 5, but the electrical component boom such as the leaf switch 6 increases. At the same time, there is a problem that the circuit becomes complicated and the cost increases.

The present invention has been made in view of the above-described circumstances, and its purpose is to reduce the space by miniaturizing the support member, and at the same time, to provide automatic deicing that can inexpensively and reliably prevent a finger or ice from being caught between the ice tray and the support member. To provide a device.

The automatic ice making device of the present invention is characterized in that the support member is formed so as to be L-shaped as viewed from above, so that the upper surface of the ice making plate of both sides of the ice making plate opens the direction in which the ice is directed at the time of separate rotation.

According to the above-described apparatus, since the support member is L-shaped from the top, the support member is compact compared with the U-shape.

And since there is no support member in the side which the upper surface of an ice-making plate faces at the time of ice-separation rotation, even if a hand is put to the side of an ice-making plate at the time of ice-separation rotation of an ice-making plate, the ice-making plate returns to the original state. When the finger is not caught.

In addition, the ice separated from the ice tray is not caught.

Hereinafter, an embodiment in which the present invention is applied to a refrigerator with an automatic ice maker will be described with reference to FIGS. 1 to 4.

First, in FIG. 4, '11' is a refrigerator main body, in which a freezing chamber 12, a refrigerating chamber 13, an ice making chamber 14, and the like are formed, and the ice making chamber 14 is related to the present embodiment. An automatic ice maker 15 is provided.

This automatic ice making apparatus 15 is demonstrated.

'16' is a rectangular body, which is provided on the upper front side of the ice making chamber 14.

The base 16 has a drive gas made of a motor or the like not shown therein, and projects the output shaft 17 of the drive mechanism from the rear portion.

'18' is, for example, a positive ice making plate, which forms a thin rectangular container container with an open top, while at the same time making it possible to produce ice of a predetermined size with several small compartment partitions. It is.

And the connection part 18a which can be fitted to the above-mentioned output shaft 17 is made in the center of the upper width of the front surface which is the end side of the longitudinal direction of this ice-making plate 18, and the shaft part (in the other end side) 18b) is generally protruded.

Moreover, the protrusion piece 18c is formed in the left end part in FIG. 1 of the back part of the ice-making plate 18. As shown in FIG.

The deicing plate 18 is connected to the connecting portion 18a by being fitted to the output side 17 protruding from the base 16 described above, and at the same time, the support member 19 to which the shaft portion 18b is described later is freely provided. It is attached to the back side of the base 16 by being supported so that it can rotate.

As a result, the ice making plate 18 is rotated in the direction of the arrow b during the third period by the drive machine in the base 16 and is rotated in the third direction, and then reversed up and down. It is possible to rotate.

Further, '20' is an ice making container, and is provided to be accessible from a lower direction of the ice making plate 18.

In addition, as shown in FIG. 4, in the upper part of the refrigerating chamber 13 mentioned above, the water supply mechanism 23 which consists of a water supply tank 21, a water supply pump 22, etc. for supplying water to the ice-making plate 18 is provided. . By the way, the support member 19 mentioned above is demonstrated here.

The support member 19 is formed in an approximately L shape when viewed from the top of the side plate portion 24 and the back plate portion 25 extending at right angles from the tip of the side plate portion 24.

And the back board part 25 is formed in the shape which the lower left part was cut | disconnected looking into the back surface, and is supported by being inserted in the upper part of the cut part so that the above-mentioned axial part 18b of the ice-making plate 18 can rotate freely. A holding unit 25a is provided for the purpose.

Moreover, the right side of the cut | disconnected part stops the rotation amount on the back side of the said ice-making plate 18 by hooking the protrusion piece 18c of the above-mentioned ice-making plate 18, and the stopper part 25b for twisting the ice-making plate. )

In addition, the locking piece 25c protrudes from the back side at the lower left side of the above-mentioned holding part 25a, and the locking hole 25d is formed in the right side of the holding part 25a.

And, in the deep wall of the ice-making chamber 14 mentioned above, the support piece 26 corresponding to the locking piece 25c mentioned above, and the support body 27 of the stick shape corresponding to the locking hole 25d mentioned above are each It is installed.

The supporting member 19 configured as described above has the side plate portion 24 extending along the side portion on the right side in FIG. 1 of the above-described ice plate 18, and the back plate portion 25 has an ice plate (on the holding portion 25a). At the proximal end of the side plate portion 24 to the rear portion of the base 16 described above, the shaft portion 18b of the side plate portion 24 can be disposed behind the rear portion of the ice making plate 18 while being rotatably supported. Attached.

Therefore, the side of the left side of FIG. 1 in which the upper surface of the ice-making plate 18 faces at the time of ice-separation rotation among the both sides of the ice-making plate 18 is left open.

At this time, the support member 26 hangs while the support piece 26 is placed on the latching piece portion 25c, and the support member 27 in the form of a bar is fitted into the locking hole 25d, so that the support member 19 is It can be supported even in the deep wall of the ice-making chamber 14. Next, the operation of the hole described above will be described.

After the water is supplied to the ice making plate 18 and the ice making is completed, the ice making plate 18 is driven by the drive mechanism in the direction of arrow B as shown in the order of (a), (b) and (c) in FIG. Rotate to and upside down, separated ice is collected in the storage container (20).

At this time, as shown in FIG. 3C, the protrusion piece 18c of the ice making plate 18 is caught by the stopper portion 25c of the supporting member 19, and the rotation is regulated, but even after the front side of the ice making plate 18 is Since a slight amount of rotation is performed by the drive mechanism, the ice can be easily separated from the ice tray 18 by twisting the ice tray 18.

In this case, the torque acts as a force for deforming the support member 19, but this force is mainly to be received by the support piece 26 and the support 27 more broadly in the refrigerator body 11. Therefore, the ice making plate 18 can be twisted without deforming the supporting member 19.

After the ice separation is completed, the ice tray 18 is rotated in the original direction in the direction opposite to the arrow (c) described above, and the water supply is made again after the state of FIG.

This action is repeated to create ice automatically.

In addition, although the user unconsciously pushes his hand to the side of the ice making plate 18 at the time of the original position rotation of the ice making plate 18 after ice-separation, since the side of the ice making plate 18 is open, there is no danger. . It is also conceivable that the separated ice is excessively accumulated and a part of it is located in the rotation region of the ice making plate 18, but the ice is formed in the rotation region of the ice making plate 18 according to the rotation of the ice making plate 18. It is pushed out, and ice does not interfere with ice separation operation | movement.

Thus, according to this embodiment, since the upper surface of the ice-making plate 18 of both sides of the ice-making plate 18 is open | released without the support member 19 in the side which faces at the time of ice separation rotation, the ice-making plate 18 is carried out. Even if the user puts his hand on the side of the finger, the fingers are not caught and it is very safe.

In addition, since the ice separated from the ice making plate 18 is not sandwiched, there is no fear that a failure occurs in the ice making operation of the ice making plate 18 or the like.

In addition, the same shape as the conventional support member 5 is different from that in which a large gap s is provided between the ice making plates 4, and the support member 19 can be made into a small L shape. In addition, the space can be reduced by reducing the unnecessary space such as the conventional gap s.

In addition, since the support member 19 is downsized, the door switch 6 or the like for securing the stability is not required, so that the cost can be reduced.

In addition, in this embodiment, the support member 19 can also be supported by the support piece 26 and the support 27, more broadly, the refrigerator main body 11, so that the support member 19 does not have great rigidity. It is possible to secure sufficient torsion in the ice making plate 18 without deformation of the supporting member 19.

As will be apparent from the above description, the automatic ice making device of the present invention is formed so that the support member is substantially L-shaped as viewed from the top, so that the upper surface of the ice making plate is open to the side of the ice making plate facing at the time of ice separation rotation. In addition, the support member can be miniaturized, and the space can be reduced, and at the same time, it has an excellent effect of inexpensively preventing the finger and the ice from being caught between the ice making plate and the support member.

Claims (1)

The base 16 which has the ice-making plate 18 which has the connection part 18a at one end, and the shaft part 18b at the other end, and the drive mechanism which rotates the ice-making plate connected to the connection part of this ice-making plate, and this gas A support member 19 having a stopper portion 25b for supporting the shaft portion of the ice-making plate attached to the freely rotated portion and controlling the amount of rotation on the other end side of the ice-making plate to impart a torsional moment to the ice-making plate. An automatic ice making device for separating ice by applying a torsional moment to the ice making plate by rotating the ice making plate and turning the ice making plate upside down after completing the ice making in the ice making plate, wherein the supporting member is an ice making plate on both sides of the ice making plate. Automatic de-icing device, characterized in that the upper surface is formed in an approximately L-shape viewed from the top so as to open the shaft facing at the time of ice separation rotation.