KR100713284B1 - Ice entangling preventing structure of ice bank for refrigerator - Google Patents

Abstract

The present invention relates to a refrigerator, and more particularly, to a structure for preventing ice agglomeration of an ice bank of a refrigerator that stores ice produced in an ice maker and grinds and supplies the ice to a size required by a user.

The ice agglomeration prevention structure of the ice bank of the refrigerator according to the present invention comprises an ice storage chamber for receiving the ice produced in the ice maker; And an ice pressurizing unit disposed in the ice storage chamber and pressurizing the ice accommodated in the ice storage chamber to separate the tangled ice.

According to the ice agglomeration prevention structure of the ice bank of the refrigerator according to the present invention, there is an advantage to prevent the ice agglomeration phenomenon in the ice storage chamber.

Ice bank, ice press, ice tray, separator

Description

Ice entangling preventing structure of ice bank for refrigerator}

1 is a perspective view of a refrigerator to which an ice tangle preventing structure of an ice bank of a refrigerator according to the present invention is applied.

FIG. 2 is a perspective view of the ice maker shown in FIG. 1. FIG.

3 is a perspective view of an ice bank to which the ice tangle preventing structure of the ice bank of the refrigerator according to the present invention is applied.

4 is a vertical sectional view of the ice bank of the refrigerator of the present invention according to II ′ of FIG. 1.

5 is a vertical cross-sectional view showing an operating state of the ice tangle preventing structure according to the present invention shown in FIG.

6 is a vertical cross-sectional view of an ice bank to which the ice tangle preventing structure according to another embodiment of the present invention is applied.

FIG. 7 is a perspective view illustrating the separator shown in FIG. 6. FIG.

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

5: ice maker 6: ice bank

31: casing 32: motor

33: rotation axis 34: feed section

35: rotating blade 36: fixed blade

37: ice grinder 50: ice storage chamber

60: ice receiving part 70: separator

The present invention relates to a refrigerator, and more particularly, to a structure for preventing ice agglomeration of an ice bank of a refrigerator that stores ice produced in an ice maker and grinds and supplies the ice to a size required by a user.

An ice maker is a device in which ice is produced, which is placed inside a refrigerator so that ice is manufactured to an appropriate size and supplied to a user. Recently, as the user's taste is advanced, the ice maker is fixedly mounted inside the refrigerator. In addition, an ice bank or an ice bin is a device that accommodates the ice produced in the ice maker, and is a device that allows the user to appropriately supply ice even when a large amount of ice is required.

In addition, the ice bank is generally formed with a storage compartment for storing a large amount of ice, a crusher for crushing the ice to a small size, and a transfer unit for transferring the ice stored in the storage compartment toward the crusher.

On the other hand, when a large amount of ice is accumulated in the storage chamber, ice entanglement may occur in the storage chamber. Here, the ice entanglement refers to a phenomenon in which ice is not entangled with each other and the ice is not transported by the transfer unit. As such, when the jam occurs, the user takes out the ice bank, manually crushes the ice, and then uses the ice bank again. And, even though the ice bank is not full of ice inside, the ice maker detects that the ice is full, there is a risk that the ice maker malfunctions.

In particular, when the ice maker and the ice bank are fixed to the door of the refrigerator, the space in which the ice bank can be installed is narrowed, so that the mutual contact between the ice stored in the ice bank increases, so that the ice The risk of sticking is increased. Therefore, the ice entanglement of the ice bank as described above occurs more often when the ice maker and the ice bank are fixed to the door of the refrigerator.

An object of the present invention is to improve the structure of the ice bank, to provide an ice agglomeration prevention structure of the ice bank of the refrigerator that can prevent the ice stored in the ice bank agglomeration between each other.

The ice agglomeration prevention structure of the ice bank of the refrigerator according to another embodiment according to the present invention comprises an ice storage chamber for receiving the ice produced in the ice maker; And an ice pressurizing unit disposed in the ice storage chamber and pressurizing the ice accommodated in the ice storage chamber to separate the tangled ice.
The ice receiving chamber may include an ice receiving portion at a lower side, and the height of the ice receiving portion may be lower than the pressing height of the ice pressing portion.
The ice pressurizing unit may be a conveying unit for transferring ice. In addition, the ice pressing unit may be an ice crusher for crushing the ice.
The ice crusher, the fixed blade disposed in the ice receiving chamber; And a rotating blade that crushes the ice while being rotated relative to the fixed blade and presses the ice contained in the ice receiving chamber to separate the tangled ice.

Ice tangle prevention structure of the ice bank of the refrigerator according to another embodiment of the present invention comprises an ice receiving chamber for receiving the ice produced in the ice maker; A transfer unit for transferring the ice by applying a transfer force to the ice contained in the ice accommodation chamber; And an ice receiving part which forms a lower side of the ice receiving chamber, and the height of the facing portion with the transfer part is lower than the transfer height of the transfer force of the transfer part.

Ice anti-tangling structure of the ice bank of the refrigerator according to another embodiment of the present invention includes an ice receiving chamber for receiving the ice produced in the ice maker, the lower portion of the ice receiving chamber; A transfer unit which transfers the ice contained in the ice accommodation chamber; And a separator for pressing the ice housed in the ice storage chamber to separate the tangled notes.

According to the ice agglomeration prevention structure of the ice bank of the refrigerator according to the present invention, the height of the ice receiving portion forming the lower portion of the ice storage chamber is formed lower than the pressing height of the pressing force of the ice pressing portion, the ice can be circulated sequentially, There is an effect of preventing the ice entanglement inside the ice storage chamber.

In addition, according to the ice agglomeration prevention structure according to the present invention, a separator is provided in the ice accommodating chamber, and the ice can be circulated, thereby preventing the ice agglomeration inside the ice accommodating chamber more reliably.

Hereinafter, with reference to the drawings will be described in detail a specific embodiment of the present invention. However, the spirit of the present invention is not limited to the embodiments presented, and those skilled in the art who understand the spirit of the present invention can easily suggest other embodiments within the scope of the same idea, but this is also within the scope of the present invention. It will be included.

1 is a perspective view of a refrigerator to which an ice tangle preventing structure of an ice bank of a refrigerator according to the present invention is applied.

Referring to FIG. 1, the refrigerator 1 to which the ice tangle preventing structure of the refrigerator ice bank according to the present invention is applied is stored in food using a predetermined refrigeration cycle composed of components such as a compressor, a condenser, an expander, and an evaporator. It is a device. The refrigerator 1 includes a refrigerating compartment 2 in which food is stored cold at an image temperature, and a freezing compartment 3 in which food such as ice is stored at a sub-zero temperature. In addition, the refrigerator 1 includes an ice maker 5 in which ice is manufactured in the freezer compartment 3, an ice bank 6 in which ice produced in the ice maker 5 is accumulated and stored, and the ice bank ( And an ice dispenser 7 so that the ice stored in 6) is properly supplied at the time desired by the user.

Here, the ice bank 6 is further formed with an ice crusher for crushing the ice to an appropriate size and a conveying portion for transferring the ice to the ice crusher.

The operation of the configuration related to the ice maker 5 will be described briefly.

First, an appropriate amount of water is supplied to the ice maker 5, and then cold air is supplied to the ice maker 5. Then, after ice is produced in the ice maker 5 by the supplied cold air, the ice is separated and dropped into the ice bank 6 by the ice maker's own operation. And, whenever the ice contained in the ice bank 6 is requested by the user, the ice dispenser 7 is supplied to the user by the desired amount.

FIG. 2 is a perspective view of the ice maker shown in FIG. 1. FIG.

Referring to FIG. 2, the illustrated ice maker 5 is an article that manufactures ice using cold air inside the refrigerator 1. The ice maker 5 includes a water supply unit 12 for supplying water from the outside, an ice maker 13 for ice making ice, and an ejector 14 for separating ice produced in the ice maker 13 from the outside. The control box 11 includes a plurality of parts for allowing the ejector 14 to rotate. In addition, a rear portion of the ice maker 13 includes a seating unit 19 for seating the ice maker 5 inside the refrigerator, and whether the ice maker 5 is operated because the ice is filled in the ice bank 6. The ice detection lever 18 is formed so that is confirmed.

In detail, the ejector 14 extends to the outside of the control box 11 to perform a rotational movement, and extends outwardly of the shaft 15 to rotate by the rotational movement of the shaft 15. And an extension 16 for pumping ice. In addition, a partition protrusion 20 is formed in the ice making chamber 13 so that a large space of the ice making chamber 13 is divided into a plurality of small spaces so that the size of the ice is adjusted. In addition, a separator 17 is installed above the ice making chamber 13 so that the ice spread by the ejector 14 is guided to the ice bank 6 and dropped. In addition, a heater (not shown) to which heat is applied is installed at the lower side of the ice making chamber 13 so that the interface between the ice and the inner circumferential surface of the ice making chamber 13 is separated from each other.

The operation or operation of the ice maker 5 will be briefly described with reference to the above-described configuration.

First, water guided by a water supply pipe having a predetermined shape is supplied to the water supply unit 12. Water supplied as described above flows into the ice making chamber 13 and is accommodated in each space divided by the partition protrusion 20. Sub-zero cold air is supplied to freeze the water contained in the ice-making chamber 13.

After the water in the ice-making chamber 13 is completely frozen while the above process is performed, the ejector 14 is operated by a predetermined driving mechanism placed inside the control box 11. In detail, the shaft 15 is rotated, and the rotation of the choir shaft 15 is linked to the rotation of the extension part 16 so that ice frozen in the ice making chamber 13 forms the inner circumferential surface of the ice making chamber 13. Therefore, it is raised. Before the ejector 14 is operated, heat is applied by the heater 21 to allow the contact surfaces of the ice and the ice making chamber 13 to be peeled from each other.

After the ice is pumped up by the ejector 14, the ice is guided by the separator 17 to fall inside the ice bank 6 and accumulate.

The above operation is repeatedly performed. After the ice is accommodated in the ice bank 6 during the repeated operation, it is detected that only the ice is accommodated by the operation of the ice detection lever 18 and the ice maker ( The operation of 5) is stopped.

3 is a perspective view of an ice bank to which the ice tangle preventing structure of the ice bank of the refrigerator according to the present invention is applied.

Referring to FIG. 3, the ice bank 6 to which the ice tangle preventing structure according to the present invention is applied has a casing 31 in which an ice storage compartment is formed and forms an integral bucket structure, and a lower side of the casing 31. The ice crusher 37 is placed, and the transfer unit 34 to smoothly transport the ice to the ice crusher 37 side. In addition, the lower side of the casing 31 is provided with an exit 38 in which the crushed ice falls, and a shutter 39 for changing the size of the ice by changing the open state of the outlet 38. Here, a spiral auger may be used as the transfer part 34.

The ice crusher 37 has a fixed blade 36 fixed in position with respect to the casing 31, a rotary blade 35 in which a rotational movement occurs with respect to the fixed blade 36, and the rotary blade 35 Is inserted into the rotary shaft 33 to which the rotational force is transmitted, and the motor 32 is connected to one end of the rotary shaft 33.

In detail, the motor 32 is placed on the outer wall of the casing 31 and connected to the rotation shaft 33 to transmit the rotational force. One end of the fixed blade 36 is fixed by the fixed blade fixing part 40 provided at one side of the casing 31, and the rotary shaft 33 is inserted and supported at a predetermined position of the fixed blade 36. do. Therefore, even if the rotating shaft 33 is rotated, the fixed blade 36 is not rotated but the position is fixed. To this end, the rotating shaft 33 and the fixed blade 36 are not fixed to each other, it may take a structure that is simply inserted.

Referring to the operation of the ice crusher 37, the ice is guided when the rotary blade 35 is rotated, when the ice is pinched between the rotary blade 35 and the fixed blade 36, the rotary blade 35 ), The ice is crushed by the pushing operation, and the ice falls through the outlet 38 at the lower side of the fixed blade 36. An ice dispenser is formed below the outlet 38 to allow the ice to be supplied to the user.

The operation of the ice bank 6 will be briefly described. In the upper side of the casing 31, the ice produced by the ice maker 5 falls and is accommodated inside the ice bank 6. The ice contained in the ice bank 6 is supplied with an appropriate amount at an appropriate size when the user desires. To this end, when the motor 32 is operated, the rotating shaft 33 is rotated to operate the transfer part 34. When the ice is transported and the conveyed ice is crushed by the ice crusher 37 is discharged through the outlet 38. In addition, not only the ice may be transferred to the ice grinder 37 by the transfer part 34, but the ice grinder 37 may also be directly contacted with the ice, so that the ice may be operated as a transport mechanism for transferring the ice. In detail, when the rotation operation of the rotary blade 35 is started, since the rotary blade 35 directly touches the ice, the ice is broken and can be moved.

In addition, the size of the ice discharged through the outlet 38 may be adjusted by the operation of the shutter 39. When the shutter 39 is opened, relatively large ice is discharged, and the shutter 39 When closed, ice of a relatively small size crushed by the fixed blade 31 is discharged.

The size of the ice supplied from the ice bank 6 may be such that a large amount of ice is discharged if it is rotated quickly by manipulating the rotation speed of the motor 32, and a small amount of ice is discharged if it is rotated slowly. When the pitch is small by adjusting the pitch of the transfer part 34, a small size and a small amount of ice are transferred, and when the pitch is large, a large size and a large amount of ice can be transferred. In addition, the size and amount of ice may be adjusted by adjusting the size and number of blades 35 and 36, and the size and amount of ice may be adjusted by adjusting the size of the outlet 38.

On the other hand, the ice bank 6 according to the present invention is characterized in that the occurrence of ice entanglement phenomenon inside the casing 31. This will be described below with reference to FIGS. 4 to 7.

4 is a vertical cross-sectional view of an ice bank of the refrigerator of the present invention according to II ′ of FIG. 1.

Referring to FIG. 4, the ice tangle preventing structure according to the present invention is connected to the ice containing chamber 50 containing the ice produced by the ice maker 5 and the ice containing chamber to pressurize the ice to prevent ice tangle. And an ice pressurizing section that circulates.

In this embodiment, the transfer part 34 installed in the ice bank 6 may function as the ice pressurization part. As described above, the transfer part 34 may be an auger.

In addition, in the present embodiment, the ice crusher 37 installed in the ice bank 6 may function as the ice pressing unit. In detail, the ice crusher 37 has a fixed blade 36 fixed to the casing 31 and a rotating blade 35 which rotates in association with the fixed blade 36. In this case, the rotating blade 35 rotates and transmits the rotational force to the ice to circulate the ice, thereby preventing ice entanglement in the ice bank 6.

Here, it is noted that the transfer part 34 and the ice crusher 37 may function together as the ice presser, or one of them may function as the ice presser.

On the other hand, the ice receiving chamber 50 includes an ice receiving portion 60 in the lower side. The ice receiving unit 60 forms a lower portion of the ice storage chamber 50 to support the ice. In addition, the ice receiving unit 60 forms a shape inclined at a predetermined angle. By forming as described above, the ice on the ice receiving unit 60 is lowered down the inclined surface, and is effectively transmitted to the ice crusher 37 and / or the conveying unit 34. Thus, the operating efficiency of the ice crusher 37 and / or the transfer part 34 can be increased.

In the present embodiment, the height h1 of the ice receiver 60 is formed to be lower than the pressurization height h2 of the transfer part 34 and / or the ice crusher 37 which is the ice presser. In detail, the height h1 of the facing portion 61 of the ice receiving part 60 with the ice pressing part is lower than the pressing height h2 of the ice pressing part. When formed as described above, the pressing force of the conveying part 34 and / or the ice crusher 37 is reliably transmitted to the ice accumulated on the ice receiving part 60. Then, due to the pressing force of the transfer part 34 and / or the ice crusher 37, the ice on the ice receiving part 60 may be pressurized and circulated in the ice receiving chamber 50. Therefore, entanglement of ice in the ice accommodating chamber 50 can be prevented.

5 is a vertical cross-sectional view showing an operating state of the ice tangle preventing structure according to the present invention shown in FIG. Referring to Figure 5, the operation of the ice tangle preventing structure according to the present invention will be described.

First, ice produced in the ice maker 5 is accommodated in the ice accommodating chamber 50. Some of the ice placed on the lower side of the ice receiving chamber 50 is placed on the ice receiving part 60 formed of an inclined surface. Then, the ice on the ice receiving part 60 is moved along the inclined surface thereof to be in contact with the conveying part 34 and / or the ice crusher 37. As the ice is moved as described above, the ice may be transferred by the transfer unit 34, and the ice may be crushed to a predetermined size by the ice crusher 37.

According to the present invention, the transfer part 34 and / or the ice crusher 37 may function as an ice press for preventing ice agglomeration. In detail, the conveying part 34 and / or the ice crusher 37 pressurizes the ice moved on the inclined surface on the ice receiving part 60. As described above, the height h1 of the face portion 61 of the ice pressurizing portion of the ice receiving part 60 is formed to be lower than the pressurization height h2 of the ice pressurizing portion, so that the pressing force of the ice pressurizing portion is the facing surface. The ice on the portion 61 is reliably pressurized.

Then, the ice pressurized by the ice pressurizing unit flows back through the ice receiving unit 60, and presses the ice contacted with it again. As described above, the pressing force generated in the ice pressurizing unit and transmitted to the ice is continuously transmitted between the ices which are in contact with each other, thereby continuously generating the backflow of the ice. Therefore, the ice in the ice receiving chamber 50 can be circulated, so that the ice does not entangle with each other in the ice receiving chamber 50, so that ice entanglement inside the ice receiving chamber 50 can be prevented. Can be.

6 is a vertical cross-sectional view of an ice bank to which an ice tangle preventing structure is applied according to another embodiment of the present invention, and FIG. 7 is a perspective view illustrating the separator shown in FIG. 6.

Referring to FIG. 6, the ice tangle preventing structure according to the present invention accommodates the ice produced by the ice maker 5, and has an ice receiving chamber 50 having an ice receiving unit 60 at a lower side thereof. And a conveying part 34 for conveying the ice contained in the seal 50. The ice agglomeration preventing structure according to the present embodiment further includes a separator 70 for pressurizing the ice contained in the ice accommodating chamber 50.

The separator 70 includes a rotation shaft insertion hole 71 to which a predetermined rotation shaft is coupled, and separator blades 72 and 73 extending therefrom. The separator blades 72 and 73 may form a symmetrical shape with respect to the rotation shaft insertion hole 71. The separator blades 72 and 73 press the ice when the separator 70 rotates.

The separator 70 presses the ice placed on the ice receiving unit 60 through a rotational movement, thereby preventing the ice from being entangled with each other. In detail, when the ice manufactured by the ice maker 5 is accommodated in the ice receiving chamber 50, some of the ice is placed on the ice receiving unit 60. Then, the pressing force of the separator 70 is transmitted to the ice on the ice receiver 60.

In the present invention, the height h1 of the facing portion 61 of the ice pressing portion of the ice receiving portion 60 is formed to be lower than the pressing height h2 of the pressing force of the ice pressing portion. Therefore, the pressing force of the separator 70 is reliably transmitted to the ice on the ice receiving part 60, so that the ice flows back. Since the reverse flow of the ice is sequentially generated between the ice in contact with each other, ice entanglement inside the ice receiving chamber 50 can be prevented.

Here, as a part for preventing ice tangles in the ice storage chamber 50, the separator 70 and the transfer unit 34 and / or the ice crusher 37, which are the ice pressurization unit, may function together. to be.

In addition, the separator 70 preferably rotates about the same axis 33 as the transfer part 34. Then, the separate driving device for rotating the separator 70 is not required, and the separator 70 may be rotated together by the power of the motor 32 which rotates the transfer part 34.

In addition, the separator 70 is preferably disposed between the ice receiving unit 60 and the transfer unit 34. When arranged as described above, the separator 70 is in direct contact with the ice on the ice receiving unit 60, the pressing force of the separator 70 can be more effectively transmitted to the ice. For the same reason, the pressing height h2 of the separator 70 is preferably higher by a predetermined height than the height h1 of the ice receiving part 60.

According to the ice tangle prevention structure of the ice bank of the refrigerator according to the present invention configured as described above, the height of the ice receiving portion forming the lower portion of the ice storage chamber is formed lower than the pressing height of the pressing force of the ice pressing portion, the upper portion of the ice receiving portion The pressing force can be reliably transmitted to the ice of. Therefore, by the pressing force, the ice can be circulated sequentially, there is an effect to prevent the ice entanglement inside the ice receiving chamber.

In addition, according to the ice agglomeration preventing structure according to the present invention, a separator is provided in the ice accommodating chamber, and the pressing force of the separator may be transmitted to the ice on the ice receiving part. Therefore, the pressing force of the separator and the pressing force of the ice receiving part are transmitted to the ice, so that the ice can be circulated, thereby preventing the ice entanglement inside the ice receiving chamber more reliably.

Claims (12)

An ice accommodating chamber accommodating the ice produced in the ice maker; And And an ice pressurizing unit disposed in the ice storage chamber and pressurizing the ice contained in the ice storage chamber to separate the tangled ice from each other. The method of claim 1, The ice storage chamber includes an ice receiving portion at a lower side, and the height of the ice receiving portion is lower than the pressing height of the ice pressing portion, ice tangle prevention structure of the ice bank of the refrigerator. The method of claim 1, The ice pressurizing portion is ice tangle prevention structure of the ice bank of the refrigerator, characterized in that the transfer unit for transferring ice. The method of claim 1, The ice pressurizing unit is an ice crusher structure of the ice bank of the refrigerator, characterized in that the ice crusher to crush the ice. The method of claim 4, wherein The ice crusher is: A fixed blade disposed in the ice storage chamber; And And a rotating blade for crushing the ice while being relatively rotated with the fixed blade and pressing the ice accommodated in the ice receiving chamber to separate the tangled ice from each other. 2. In the ice tangle prevention structure of the ice bank of the refrigerator that can store the ice produced in the ice maker, An ice accommodating chamber accommodating the ice produced by the ice maker; A transfer unit for transferring the ice by applying a transfer force to the ice contained in the ice accommodation chamber; And And an ice receiving portion forming a lower portion of the ice storage chamber and having a height of a facing portion with the transfer portion lower than a transfer height of the transfer force of the transfer portion. The method of claim 6, Ice tangle prevention structure of the ice bank of the refrigerator, characterized in that the inclined surface inclined at a predetermined angle. In the ice tangle prevention structure of the ice bank of the refrigerator that can store the ice produced in the ice maker, An ice accommodating chamber accommodating the ice produced by the ice maker and having an ice receiving portion at a lower side thereof; A transfer unit which transfers the ice contained in the ice accommodation chamber; And And a separator separating the tangled ice by pressing the ice housed in the ice storage chamber. 2. The method of claim 8, The separator is ice agglomeration prevention structure of the ice bank of the refrigerator, characterized in that for rotating the pressure to press the ice. The method of claim 9, And the separator rotates about the same axis as the transfer unit. The method of claim 8, And the separator is disposed between the ice receiving portion and the conveying portion. The method of claim 8, The height pressurized by the separator is higher than the height of the ice receiving portion, ice tangle prevention structure of the ice bank of the refrigerator, characterized in that.

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