KR200283929Y1 - Freeze preventing structure of ice-making apparatus - Google Patents

Abstract

The present invention relates to an ice maker of a refrigerator, and an insulation is installed at the bottom of the ice maker cover and a storage container to prevent freezing by preventing water condensation on the front cover and the bottom of the ice maker due to the contact of external air according to the temperature difference when the refrigerator door is opened. It relates to a freezing prevention structure of the ice maker for the refrigerator.

The freezing prevention structure of the ice maker for a refrigerator according to the present invention is installed on the front of the ice maker cover 16, and the cover anti-icing unit (20, 40) for blocking heat transfer of the ice maker cover (16), and the storage container portion (14) Is installed in the lower portion of the storage container portion 14 is composed of a container freezing prevention unit 60 to block the heat transfer. Therefore, when the external high temperature air comes into contact with the front surface of the ice maker cover 16 and the lower surface of the storage container unit 14, the low temperature of the ice maker cover 16 and the storage container unit 14 may prevent the freezing means 20. 40, 60) is blocked by the transmission of the external air has the effect of preventing the contact of the external air into water droplets.

Description

FREEZE PREVENTING STRUCTURE OF ICE-MAKING APPARATUS}

The present invention relates to an ice maker of a refrigerator, and more particularly, to install a heat insulating material under the ice maker cover and the storage container part, and to contact the external air according to the temperature difference when opening the refrigerator door. It relates to a freezing prevention structure of an ice maker for a refrigerator to prevent freezing to prevent freezing.

In recent years, with the improvement of living standards and the preference for large and multifunctional refrigerators, refrigerators having a relatively large capacity and a combination of functions have been shown. Recently, a refrigerator with a freezer, a refrigerator, a dispensing device and an ice maker has been introduced. As demand increases, so does its function. With reference to the drawings showing the structure of a conventional composite refrigerator provided with an ice maker as described above.

1 is a schematic structural diagram of a conventional combined refrigerator with an ice maker. As shown, the ice maker 10 is installed on the upper side of the freezer compartment (1). The ice maker 10 has an ice making unit 12 that forms ice, and a storage container unit 14 is installed below the ice maker 10 to store the ice formed in the ice making unit 12.

On the other hand, the dispensing apparatus 2 is installed on the front surface of the freezing chamber door 1a, so that the user can easily take out the desired water or ice from the outside without opening the door 1a.

The ice maker 10 and the dispensing apparatus 2 are connected to a water supply source 4 (for example, a faucet) outside the refrigerator to receive water. That is, an external pipe 5a connected to the water supply source 4 outside the refrigerator is installed through the rear wall of the refrigerating chamber 3, and a filter 6 for water purification is installed at one side of the external pipe 5a to provide an external pipe 5a. To filter the incoming water. And, the other side of the water filter (6) is connected to the inner pipe (5b), the water supply valve (7) is provided at the end of the inner pipe (5b).

The water supply valve 7 serves to control the water supplied to the ice maker 10 and the dispense device 2. That is, an ice maker pipe 5c connected to the ice maker 10 is installed at one side of the water supply valve 7, and a dispense pipe 5d connected to the dispense device 2 is installed at the other side. In the middle of the dispensing pipe 5d, a water tank 8 for storing water supplied to the dispensing device 2 is provided. By being configured as described above, the water delivered from the external water supply source 4 can be delivered to the ice maker 10 and the dispense device 2, respectively.

Next, the structure of the ice maker will be described in more detail with reference to FIGS. 2 to 5. As shown in FIG. 2, an ice maker 10 is installed at one side of the freezing chamber 1, and the ice maker 10 has an ice maker 12 forming ice thereon, and a storage container portion below the ice maker 10. 14) is installed to store the ice produced by the ice making unit (12). Meanwhile, a conveyer 14a is mounted inside the storage container 14, and the conveyer 14a is connected to the shaft of the motor 18 installed outside the ice maker 10 to power the motor 18. It can rotate according to the transmission. In addition, the rotary blade (14b) is attached to the tip of the conveyor (14a) to transfer the ice in the storage container 14 to the front, according to the operation of the rotary blade (14b) dispensing device described above ice To (4).

Meanwhile, an ice maker cover 16 is installed on the front side of the ice maker 10. As shown in FIGS. 3 and 4, the ice maker cover 16 includes an ice maker cover 16a that protects the front surface of the ice maker 12 and a container cover that protects the front surface of the storage container unit 14. It consists of 16b, and forms the external appearance of the ice maker 10.

When the refrigerator is used, the inside of the refrigerator is adjusted to maintain a constant temperature and a constant state under the control of a microcomputer (not shown) located inside the refrigerator, but the environment outside the refrigerator is not constant. That is, when the user frequently opens the door, the ice maker cover 16 shown in FIGS. 3 and 4 is in direct contact with the outside air. In particular, when the refrigerator is used in a high temperature and high humidity environment, the high temperature and high temperature outside air is stuck to the ice maker cover 16 by the low temperature inside the refrigerator to form water droplets. In this case, when the door is closed again, the water droplets may freeze on the surface of the ice maker cover 16 due to the low temperature inside the refrigerator, in particular, the temperature of the ice making unit 12 that forms ice.

In addition, as shown in FIG. 5 as well as the ice maker cover 16, the same problem occurs in the lower surface (14c) of the storage container portion 14 for storing ice. That is, not only the ice maker cover 16 but also the lower surface 14c of the storage container unit 14 is exposed to external air as it is when the refrigerator door is opened. In addition, since the lower surface 14c of the storage container part 14 maintains a low temperature due to the ice being stored, water droplets form on the lower surface 14c of the storage container part 14 as the high temperature external air contacts. . In addition, the water droplets are frozen due to the low temperature inside the door (1a) in a closed state. Therefore, the frozen water droplets grow like icicles over time, which has not been a good visual appearance, and has been a field claim often raised by users.

The present invention is to solve the above problems, when the door is opened, even if the hot and humid outside air flowing into the interior from the outside of the refrigerator comes into contact with the bottom surface of the ice maker cover and the storage container, the cold heat of the ice maker is stored with the ice maker cover It is an object of the present invention to provide a freezing preventing structure of an ice maker for a refrigerator, which prevents freezing even when water droplets are prevented from being confined to the bottom of the container and the door is closed again.

1 is an internal schematic view showing a water supply structure of a refrigerator provided with an ice maker.

Figure 2 is a side cross-sectional view showing the internal structure of a conventional ice maker.

Figure 3 is a perspective view of an ice maker cover installed on the front of the conventional ice maker.

4 is a cross-sectional view taken along the line A-A of FIG.

5 is a front view showing a state of a storage container which is a component of a conventional ice maker.

Figure 6 is a side cross-sectional view of the ice maker cover according to the present invention.

7 is a front view showing a state of the storage container according to the present invention.

Explanation of symbols on the main parts of the drawings

10: ice maker 12: ice maker

14: storage container 16: ice maker cover

16a: upper cover 16b: lower cover

20: heat insulating material 30: heat insulating material cover

30a: screw 40: plate

50: rib 52: rib hole

60: lower plate 62: lower plate side wall

62a: hook

In order to achieve the above object, the freezing prevention structure of the ice maker for a refrigerator according to the present invention includes an ice making unit for forming ice; A storage container for storing the iced ice; An ice maker cover installed in front of the ice maker and the storage container; And a cover anti-icing part provided on the ice maker cover to block heat exchange between the ice maker cover and the outside air to prevent water contained in the outside air from freezing on the ice maker cover; It is installed on the outside of the storage container portion to block the heat exchange between the storage container and the outside air to prevent the water contained in the external air to freeze on the outer surface of the storage container; have.

Therefore, even when the high temperature air is in contact with the door opening, heat transfer to the ice maker cover or the storage container is blocked, thereby preventing freezing.

The cover freezing prevention part is installed on the front of the ice maker cover, the container freezing prevention part is installed under the storage container part, ribs are formed on both sides of the lower surface of the storage container part, and the container freezing prevention part is coupled to the rib.

Next, with reference to the drawings showing a preferred embodiment of the ice preventing structure of the refrigerator ice maker according to the present invention having the features as described above will be described in more detail. In the following description, the same structure as in the prior art will be described using reference numerals used in FIGS. 1 to 5.

First, Figure 6 is a side cross-sectional view of the ice maker cover according to the present invention. As shown, the outer structure of the basic ice maker cover 16 is similar to the conventional. That is, the ice maker cover 16 is located on the front of the ice making unit 12, the upper cover (16a) located on the upper side, forming the ice, the lower cover (16b) is located on the front of the storage container (14). do.

The heat insulating material 20 is attached to the outer surface of the upper cover 16a. The heat insulator 20 serves to block the low temperature heat transmitted from the ice making unit 12 inside the upper cover 16a, and any kind of heat insulator 20 may be used. For example, the most commonly used materials such as squirrel may be used. Then, the outer surface of the heat insulating material 20 is wrapped with the heat insulating material cover 30 and the upper and lower sides of the heat insulating material cover 30 are fixed to the upper cover 16a by using fixing members 30a such as screws. Of course, it will be possible to attach using an adhesive or the like instead of the screw 30a as described above. The reason for wrapping the heat insulator 20 with the heat insulator cover 30 as described above is to prevent the wet air outside the refrigerator from directly contacting the heat insulator 20 such as a squirrel. As described above, even when the outside air is contacted by attaching the heat insulator 20 to the front of the upper cover 16a, low temperature heat transfer transmitted from the ice making unit 12 is prevented by the heat insulator 20, so that water condensation and freezing are prevented. Can be prevented.

On the other hand, the front of the lower cover (16b) is also shown a structure that is attached to the heat insulating plate 40 for heat insulation, the heat insulating plate is also coupled to the front of the lower cover (16b) using a fixing member 40a, such as a screw. Let's do it. Of course, if the thermal insulation plate 40 attached to the lower cover 16b is also intended for thermal insulation, it may be any type, and the thermal insulation material 20 and the thermal insulation material attached to the front surface of the cover 16a may be used. It will also be possible to use an insulating cover 30 to wrap.

Next, the storage container unit 14 according to the present invention will be described with reference to FIG. 7. As shown, the reservoir 14 is a container for storing the ice iced in the ice maker 12. Ribs 50 are formed on both sides of the lower outer surface of the storage container 14. A plurality of coupling holes 52 are formed in the ribs, so that the lower plate 60 to be described below is coupled through the coupling holes 52.

In addition, a lower plate 60 coupled to the rib 50 is installed below the storage container portion 14. The lower plate 60 is to prevent the external wet air is in direct contact with the lower outer surface of the storage container 14, it will be preferably made of a material for thermal insulation. As described above in FIG. 6, the inner wrapper of the heat insulating material 20, such as a squirrel, may be used. Any material may be used as long as it is a material for heat insulating. The lower plate 60 is formed in a rectangular enclosure, and a plurality of protruding hooks 62a are formed on the upper sidewall 62 of the lower plate 60. The hook 62a is formed on the side wall 62 at a position corresponding to the coupling hole 52 of the rib 50 when the lower plate 60 is coupled to the rib 50 described above. do. Therefore, as the hook 62a is inserted into the coupling hole 52 of the rib 50, the lower plate 60 is combined with the rib 50 to protect the lower portion of the storage container part 14.

On the other hand, the combination of the lower plate 60 and the rib 50 may be configured differently than described above. That is, the upper sidewall 62 of the lower plate 60 and the rib 50 may be coupled using a screw or the like. In addition, since the lower plate 60 is primarily intended to prevent the external wet air contact with the lower outer surface of the storage container portion 14 to freeze directly, the structure for achieving the above object is the lower plate ( In addition to the combination of the 60 and the ribs 50, various things will be possible. That is, in another embodiment, as in the structure of the upper cover 16a described above with reference to FIG. 6, the heat insulating material 20 such as Schiropol is wrapped on the lower outer surface of the storage container 14, and the outer surface of the heat insulating material 20 is covered with the heat insulating material cover. Wrapping in 30 would be possible.

In addition, the heat insulating material 20 and the plate 40 attached to the front of the ice maker cover 16 described above and the lower plate 60 installed on the lower portion of the storage container 14 serve to block the temperature, so the thermal conductivity is very high. It is preferable to be made of a low material. That is, even when the external high temperature air is in contact with the heat insulating material 20, the plate 40, the lower plate 60, the materials are in contact with the outside by blocking the low temperature of the ice maker cover 16 and the storage container 14. The air does not change into water droplets due to temperature difference. Therefore, it is preferable to use a material having low thermal conductivity.

Next will be described the operation of the freezing prevention structure of the refrigerator ice maker according to the embodiment as described above.

The ice maker 10 is operated under the control of a microcomputer located inside the refrigerator. That is, when the ice stored in the storage container 14 is not ice, water is supplied to the ice making unit 12 through the water supply valve 8 to form ice in the ice making unit 12, and then the storage container unit. It is passed to (14), and the above process is performed until the ice is reached. In addition, the ice making unit 12 that forms ice maintains a temperature for forming the ice, that is, a temperature below zero, and the temperature below zero is transmitted over the entire ice making unit 12 by thermal conduction. In addition, the storage container unit 14 for storing ice also maintains a low temperature by the stored ice, and the sub-zero temperature is transmitted throughout the storage unit unit 14, so that the whole of the storage unit unit 14 Maintain a low temperature.

Accordingly, the outer surface of the ice maker cover 16 and the lower portion of the storage container unit 14 attached to protect the front surface of the ice making unit 12 and the front surface of the storage container unit 14 also have the ice making unit 12 and the storage container. The low temperature of the portion 14 is to maintain a low temperature.

On the other hand, when the user takes out items stored in the refrigerator or opens the door of the refrigerator to store new items, the outside air of the refrigerator flows into the refrigerator, where the inside of the refrigerator maintains a low temperature. The external air is kept at a relatively high temperature. When the high outside air flows into the refrigerator maintaining a low temperature as described above, the outside air is conventionally the front cover 16 and the storage container 14 of the wall surface or the ice maker 10 inside the refrigerator to maintain a low temperature. Contact with the lower outer surface of the) turns into water droplets due to the temperature difference. That is, since the lower outer surface of the ice maker cover 16 and the storage container part 14 remain exposed, when the refrigerator door is opened, the hot air introduced from the outside is exposed as it is, and thus the ice maker cover 16 and the storage are stored. Due to the low temperature of the lower outer surface of the container portion 14, the high temperature external air is cooled and turned into water droplets. In addition, the degree of condensation becomes more severe as the temperature of the outside air is higher than the internal temperature of the refrigerator and the content of moisture is higher. Therefore, in the hot and humid summer season, the number of times the refrigerator is used more and more water droplets are formed.

However, as described above, in the present case, when the refrigerator door is opened, ice preventing means is provided at the lower part of the ice maker cover 16 and the storage container portion 14 in which external air directly contacts. That is, the upper cover 16a forming the ice maker cover 16 is provided with a heat insulating material 20, the lower lower cover 16b is provided with a plate 40, and the lower plate below the storage container portion 14. 60 is provided. The ice preventing means (20, 40, 60) serves to prevent the low temperature of the lower part of the ice maker cover (16) and the storage container (14) to be transferred to the outside air, the outside air is the ice maker cover (16) Water drops do not form at the lower portion of the storage container 14 with.

In more detail, the high temperature external air introduced when the refrigerator door is opened is in contact with the front surface of the ice maker cover 16. In this case, since the heat insulating material 20 is attached to the upper cover 16a constituting the ice maker cover 16 and the plate 40 is attached to the lower cover 16b, the high temperature external air is applied to the heat insulating material 20 and the plate 40. Contact. On the other hand, the heat insulating material 20 and the plate 40 is made of a material having a low thermal conductivity and is in a state of blocking the low temperature indicated by the ice maker cover 16. Therefore, since the heat insulating material 20 and the plate 40 are not in a state of maintaining a low temperature transmitted from the ice maker 10, the contacted external air is not formed by water droplets. Similarly, since the lower plate 60 installed below the storage container part 14 also serves to block low temperature of the storage container part 14, external air contacted with water drops do not form. Therefore, even if the hot air or the external air containing moisture is in contact with the lower part of the ice maker cover 16 or the storage container 14, the water droplets are not formed by the freezing prevention means (20, 40, 60) refrigerator door If you close the ice will be prevented.

As described above, even if the hot and humid outside air flows into the refrigerator, the water droplets freeze as the water droplets are not formed at the lower part of the ice maker cover and the storage container by the ice preventing means according to the present invention.

Therefore, the conventional problem of aesthetic appearance due to freezing is solved, which has the advantage of increasing the reliability of the product to the consumer.

Claims (3)

An ice making unit for forming ice; A storage container for storing the iced ice; An ice maker cover installed in front of the ice maker and the storage container; And A cover anti-icing part provided on the ice maker cover to block heat exchange between the ice maker cover and the outside air to prevent moisture contained in the outside air from freezing on the ice maker cover; It is installed on the outside of the storage container portion of the refrigerator ice maker, characterized in that by blocking the heat exchange between the storage container and the outside air to prevent the moisture contained in the outside air to freeze on the outer surface of the storage container portion. Freezing prevention structure. 2. The structure of claim 1, wherein the cover anti-icing unit is installed at the front of the ice maker cover, and the container anti-icing unit is installed at a lower portion of the storage container unit. 3. The structure of claim 2, wherein ribs are formed on both sides of a lower surface of the storage container, and a container anti-icing unit is installed in combination with the ribs.