KR19980018117U - Refrigerator automatic ice maker - Google Patents

Abstract

The present invention relates to a refrigerator automatic ice maker water supply amount adjusting device for adjusting the water supply amount to constantly supply the water supply into the automatic ice maker of the refrigerator, conventionally the refrigerator automatic ice maker water supply amount control device detects the moisture in the weighing tank on the weighing tank The amount of water supplied into the supply was not constant and was insufficiently supplied. As a result, after the end of ice making, a relatively small amount of ice was generated by one ice making operation due to poor ice making and poor ice size.

The present invention is to solve the problems as described above, the solution means of the present invention in the refrigerator automatic ice maker water supply amount adjusting device for supplying a certain amount of ice making water into the refrigerator automatic ice maker 45, the water supply pump 36 When the ice making water supplied from the weighing tank 58 to the ice maker 45 is filled to the full water position in the ice maker 45, the first water detection unit is energized and positioned on one side of the ice maker 45 to control the water supply amount. It provides a refrigerator automatic ice maker water supply control device, characterized in that it comprises a sensor 60, and the second moisture detection sensor 62 located on the other side of the ice maker (45).

Description

Refrigerator automatic ice maker

The present invention relates to a refrigerator automatic ice maker water supply control device for adjusting the water supply amount to constantly supply the water supply into the automatic ice maker of the refrigerator.

An example of a refrigerator equipped with an automatic ice maker in a conventional refrigerator is known from Korean Patent No. 95-3815, which is shown as shown in FIGS. 1 and 2.

That is, here, the freezer compartment 27, the refrigerating chamber 28, the ice-making chamber 32, etc. are formed in the inside of the refrigerator main body 21, The cold air cooled by the cooler 29 is each room | chambered by the fan 29a. It is supplied to (27), (28), and (32), The ice-making apparatus 4 of FIG. 2 is provided in this ice-making chamber 32. In FIG.

In the ice making apparatus 4, a box 50 forming a rectangular box shape is disposed at an upper portion of the ice making chamber 32, and an L-shaped support member 41 protruding rearward at one end of the back of the box 50. Is installed.

Inside the box 50, a drive mechanism 49 composed of a motor 48, a gear mechanism 47, and an output shaft 46 is provided, which drives the rotation of the motor 48. The mechanism 47 decelerates and delivers it to the output shaft 46.

In addition, an ice tray 45 is disposed inside the support member 41, which has a central front portion connected to the output shaft 46, and an opposite shaft central portion rotated to the supporting member 41 through the support shaft 42. It is supported so that it may be rotated by the output shaft 46. As shown in FIG.

In addition, the protrusion 43 is protruded at the rear portion of the ice making bowl 45, and when the ice making bowl 45 is rotated in the reverse direction, the protrusion 43 is brought into contact with the support member 41 to restrict the rotation thereof. In addition, the ice tray 45 forms a thin rectangular container shape with an upper surface open, and the inside is divided into a plurality of recesses 44 to make angled ice.

Meanwhile, water is supplied to the ice making bowl 45 by an ice making water supply device 39, and the ice making water supply device 39 includes an ice making water supply tank 37 disposed in a refrigerator and the ice making water. And a feed plate 36 for receiving water in the water supply tank 37 and a feed pump 36 for supplying water in the water tray 38 to the ice making bowl 45 through the feed pipe 35. An ice-making completion temperature detection temperature sensor is attached to detect that the water supplied to the ice making bowl 45 has become ice.

3 illustrates a water supply control device used in a conventional refrigerator automatic ice maker.

The water supply amount adjusting device is composed of a set of water detection sensors 54 adjacent to each other, and its lead wire 56 is connected to a microcomputer. The lower ends of each of the set of moisture detection sensors 54 are immersed in water in the weighing tank 58.

When the ice maker 45 finishes the ice-making operation, the ice maker 45 is inverted back to its original horizontal position by the operation of the drive mechanism 49. At the same time, the water supply pump 36 is operated to supply the water in the metering tank 58 into the iced ice maker 45.

When the feed pump 36 is operated, a large amount of water in the metering tank 58 is initially sucked by the high speed rotation of the pump. Accordingly, the amount of water in the metering tank 58 is reduced, and the lower end of the pair of water detection sensors 54 immersed in the water in the metering tank 58 is exposed to the upper surface of the water surface.

When the lower end of the set of moisture detection sensor 54 is exposed to the upper surface of the water, the operation of the water supply pump 36 is stopped by a signal of the microcomputer.

As the water in the metering vessel 58 decreases, the water retained in the drip tray 38 flows into the metering vessel 58. However, as described above, since the lower end of the water detection sensor 54 is exposed to the upper surface after a relatively short time after the initial operation of the water supply pump 36, the operation of the water supply pump 36 is stopped. Water in the drip tray 38 flows into the metering tank 58.

Accordingly, the operation of the water feed pump 36 is stopped in the state where sufficient water is not supplied into the ice maker 45. The water supplied into the ice maker 45 flows into each recess 44 through a plurality of channel grooves 45a formed therein. However, since the amount of water supplied into the ice maker 45 is small, the amount of water in the recesses 44 to be filled later in each of the recesses 44 to which the water is sequentially filled is initially determined by the recesses ( 44) less than the amount of water filled in.

As such, when a small amount of water is filled in the recess 44, an area of contact between the ice frozen in the ice maker 45 and the inner surface of the ice maker 45 after the end of the ice making becomes small. In the operation of the ice-making by torsion of the ice maker 45, ice ice-making action is poor. Accordingly, the amount of ice deicing at once is also reduced.

In addition, since the water supply control device 52 is located on the metering tank 58, the structure of the water supply control device 52 is complicated, so that assembly is difficult and maintenance is inconvenient during manufacture.

Therefore, an object of the present invention is to solve the conventional problems as described above, the present invention is to detect the moisture on the ice maker to stop the operation of the feed water pump after the deicing water is filled in each of the concave portion of the refrigerator automatic ice maker. It is to provide a water supply control device so that the ice of a certain size is easily iced.

According to the present invention for achieving the above object, the refrigerator automatic ice maker water supply adjusting device for supplying a predetermined amount of ice making water into the automatic refrigerator ice maker is filled with the ice maker water supplied to the ice maker from the measuring tank by the water pump to the full position in the ice maker And a first water detection sensor located on one side of the ice maker and a second water detection sensor located on the other side of the ice maker to control the amount of water supply when energized.

The refrigerator automatic ice maker water supply control device according to the present invention is also the first concave portion through which the first moisture detection sensor is first introduced ice-making water so that a predetermined amount of ice-making water flows into the plurality of concave portions of the ice maker that the ice-making water is sequentially introduced And the second moisture detection sensor is positioned on the final concave portion through which the ice making water finally flows.

1 is a cross-sectional view showing a portion of an automatic ice making room in a conventional refrigerator.

Figure 2 is a reference diagram showing an extract of the automatic ice making apparatus in FIG.

3 is a side view showing a water supply amount regulating device of a conventional automatic ice making device.

Figure 4 is a side view showing a water supply amount adjusting device of the automatic ice making apparatus according to the present invention.

* Explanation of Signs of Major Parts of Drawings *

36: feed pump 45: ice maker

58: weighing tank 60: first moisture detection sensor

62: second moisture detection sensor 64: first concave portion

66: final recess

Hereinafter, with reference to Figure 4 will be described a preferred embodiment of the present invention.

In FIG. 4, a water supply amount adjusting device of the automatic ice maker according to the present invention is located on the ice maker 45.

The first moisture detection sensor 60 is located on the first concave portion 64 from which the ice-making water from the feed pump 36 is first supplied among the plurality of concave portions 44 of the ice maker 45.

In addition, the second moisture detection sensor 62 is positioned on the final concave portion 66 through which the ice-making water is finally introduced from the water supply pump 36 among the plurality of concave portions 44 of the ice maker 45.

The first and second moisture detection sensors 60 and 62 are electrodes having a simple structure.

When the ice maker 45 is inverted to its original horizontal position after the iced ice is iced from the ice maker 45 in the same manner as the conventional art, the feed pump 36 is operated.

The water feed pump 36 sucks the ice making water retained in the metering tank 58 into its intake port 36a and discharges the ice making water into the first recess 64 of the ice maker 45 through the discharge port 36b. Discharge. In this way, the ice making water supplied into the initial concave portion 64 by the water supply pump 36 overflows from the initial concave portion 64 on each recess 44, 60, 66 of the ice maker 45. Through each of the channel grooves 45a (see FIG. 2) formed in the inlet, the concave portions 44, 60, and 66 are sequentially introduced into the recesses 44, 60, and 66.

When the ice making water that is sequentially introduced into the final concave portion 66 is filled to the level where the second water detecting sensor 62 is located, the second water detecting sensor 62 is connected to the ice making water. Contact. Accordingly, the second moisture detection sensor 62 is energized with the first moisture detection sensor 60 that is in contact with the ice making water in the first recess 64 on the first recess 64.

The operation of the water supply pump 36 is stopped by the energization signal between the first moisture detection sensor 60 and the moisture detection sensor 62 as described above.

On the other hand, the water supply replenishment lamp (not shown) when the power supply between the first moisture detection sensor 60 and the moisture detection sensor 62 is not made even after a predetermined time has elapsed after the water supply motor 36 is operated. Lights up to inform the user of the water supply.

As described above, the refrigerator automatic ice maker water supply control apparatus according to the present invention is a water supply pump after the water detecting sensors are positioned on the first recess and the final recess of the ice maker, respectively, and the ice maker is filled to the full water position in each recess of the ice maker. Since the operation is stopped, a constant amount of water is supplied into the automatic ice maker, which has an effect of facilitating the ice-making action after the ice making.

Refrigerator automatic ice maker water supply control device according to the present invention is also to supply a predetermined amount of ice in a plurality of recesses in the ice maker has the effect of providing a relatively large amount of ice in one ice making operation.

In the refrigerator automatic ice maker water supply control device according to the present invention, the first and second moisture detection sensors are simple electrodes, and are located on the ice maker, so that the structure of the water supply device is simple and is easy to assemble during manufacture. And the maintenance is easy to effect.

Claims (2)

In the refrigerator automatic ice maker water supply adjusting device for supplying a predetermined amount of ice making water into the refrigerator automatic ice maker 45, the ice maker 45 supplied from the metering tank 58 into the ice maker 45 by the water supply pump 36 is an ice maker 45. The first water detection sensor 60 is located on one side of the ice maker 45, and the second is located on the other side of the ice maker 45 so as to be filled to the full water position in the interior to control the water supply amount. Refrigerator automatic ice maker water supply control device comprising a water detection sensor (62). According to claim 1, wherein the first moisture detection sensor 60 is introduced to the ice-making water for the first time so that a predetermined amount of ice-making water flows into the plurality of recesses 44 of the ice maker 45 to be sequentially introduced ice-making water Refrigerator automatic ice maker water supply control device, characterized in that located on the first concave portion (64) and the second moisture detection sensor (62) is located on the final concave portion (66) to finally make the ice making water.