KR101586304B1 - Apparatus for ejecting ice - Google Patents

Abstract

An ice extraction device capable of extracting a certain amount of ice is disclosed.

The ice extracting apparatus according to an embodiment of the present invention is provided in an ice reservoir S and is configured to transfer the ice I stored in the ice reservoir S to the ice discharge port D of the ice reservoir S, (200); (I) discharged from the ice discharge port (D) is sent to an ice extracting section (E) in association with the ice transfer section (200) to receive a predetermined amount of ice An extracting unit 300; The quantitative extraction unit 300 includes a quantitative extraction member 310 having at least one extraction blade 311 formed to receive a predetermined amount of ice I discharged from the ice discharge port D, A connection member 320 connecting the quantitative extraction member 310 to the rotation driving means 220 included in the ice transfer unit 200 so that the quantitative extraction member 310 is rotationally driven, The rotation position detecting means 330 is provided on the connecting member 320 and includes at least one rotation position detecting hole 331a for detecting the rotational position of the member 310, A rotational position detecting disk 331 formed thereon and a rotational position detecting sensor 332 provided to detect the rotational position through the at least one rotational position detecting hole 331a.

Ice, ice extraction, quantitative extraction

Description

[0001] APPARATUS FOR EJECTING ICE [0002]

The present invention relates to an ice extraction device capable of extracting a predetermined amount of ice.

The ice extracting device is a device for extracting ice made from an ice maker provided in a refrigerator or an ice water purifier to supply the ice to the user.

Such an ice-making apparatus is provided in an ice-maker and is provided in an ice-maker for storing ice made by the ice-maker. In addition, the ice extraction apparatus is provided with an ice transfer member for transferring the ice stored in the ice reservoir to the ice discharge port of the ice reservoir. The ice outlet of the ice storage is connected to the ice extraction unit. Therefore, the ice made in the ice maker is stored in the ice reservoir, and the ice stored in the ice reservoir is transferred to the ice outlet by the ice transfer member. Then, the ice discharged from the ice outlet is extracted through the ice extracting section and supplied to the user.

However, there is a problem that a certain amount of ice can not be extracted by the conventional ice extracting apparatus. Accordingly, there is a problem that a certain amount of ice can not be supplied to the user.

The present invention is realized by recognizing at least any one of the requirements or problems occurring in the conventional ice extracting apparatus.

An object of the present invention is to extract a predetermined amount of ice stored in an ice storage.

Another object of the present invention is to enable a user to supply a certain amount of ice.

Another object of the present invention is to make it possible to control the amount of ice to be supplied.

An ice extraction apparatus according to an embodiment for realizing at least one of the above problems may include the following features.

The present invention is basically based on transferring ice stored in an ice reservoir to an ice discharge port of an ice reservoir, receiving a predetermined amount of ice discharged from an ice discharge port, sending the ice to an ice extracting section, and extracting the ice.

An ice extraction device according to an embodiment of the present invention includes an ice transfer part provided in an ice reservoir and configured to transfer ice stored in an ice reservoir to an ice outlet of an ice reservoir; A quantitative extracting unit configured to receive a predetermined amount of the ice discharged from the ice discharge port and send it to the ice extracting unit to extract ice by a predetermined amount in connection with the ice transferring unit; The quantitative extracting unit includes a quantitative extracting member having at least one extracting blade formed to receive a predetermined amount of ice discharged from the ice discharge port and a quantitative extracting member to be included in the ice transferring unit to rotate the quantitative extracting member And a rotational position detecting means for detecting a rotational position of the quantitative extracting member, wherein the rotational position detecting means includes a rotational position detecting means provided in the connecting member and having at least one rotational position detecting hole formed therein, And a rotational position detecting sensor provided to detect the rotational position through the at least one rotational position detecting hole.

In this case, the ice conveying unit may include an ice conveying member provided with a screw-shaped conveying blade; And rotation driving means connected to the ice transferring member for rotationally driving the ice transferring member; . ≪ / RTI >

In addition, the ice transfer member may be installed in the ice reservoir so as to be inclined so that the ice discharge port is higher.

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As described above, according to the embodiment of the present invention, the ice stored in the ice reservoir can be extracted by a predetermined amount.

In addition, according to the embodiment of the present invention, a predetermined amount of ice can be supplied to the user.

Also, according to the embodiment of the present invention, the amount of ice to be supplied can be adjusted.

In order to facilitate understanding of the features of the present invention as described above, the ice extracting apparatus according to an embodiment of the present invention will be described in detail.

Hereinafter, exemplary embodiments will be described based on embodiments best suited for understanding the technical characteristics of the present invention, and the technical features of the present invention are not limited by the illustrated embodiments, It is to be understood that the present invention may be implemented as illustrated embodiments. Therefore, it is intended that the present invention covers the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. In order to facilitate understanding of the embodiments to be described below, in the reference numerals shown in the accompanying drawings, the components that perform the same function in the embodiments are denoted by the same or an extension line number.

Embodiments related to the present invention are basically based on transferring the ice stored in an ice reservoir to an ice discharge port of an ice reservoir and then receiving a predetermined amount of ice discharged from an ice discharge port and sending the ice to an ice extracting section for extraction.

The ice extracting apparatus according to the present invention may include an ice transferring unit 200 and a quantitative extracting unit 300 as in the embodiment shown in FIG.

The ice dispenser 200 may be provided in the ice reservoir S. Then, it can be configured to transfer the ice (I) stored in the ice reservoir (S) to the ice discharge port (D) of the ice reservoir (S). The ice reservoir S may be provided in an apparatus capable of making ice (I) with an ice maker (not shown) such as a refrigerator or an ice water purifier. The ice transfer unit 200 is configured to transfer the ice I stored in the ice storage unit S to the ice discharge port D of the ice storage unit S, And a rotation driving means 220,

The ice transfer member 210 may be provided with a screw-shaped transfer blade 211 as in the embodiment shown in FIG. The ice transfer member 210 may be rotated by the rotation driving means 220. As the ice conveyance member 210 rotates by the rotation driving means 220, the ice I stored in the ice reservoir S is conveyed by the screw-shaped conveyance blade 211 provided on the ice conveyance member 210, Can be transferred to the ice discharge port (D) of the ice bin (S). The ice transfer member 210 may be installed in the ice reservoir S such that the ice discharge port D is higher than the ice discharge port 210 as shown in the illustrated embodiment. Thereby, it is possible to distribute the ice I evenly to the ice reservoir S without being distributed in a concentrated manner near the ice discharge port D.

The rotation driving means 220 connected to the ice transfer member 210 to rotationally drive the ice transfer member 210 may include a motor 221 and a gear 222 as in the embodiment shown in FIG. However, the rotation driving means 220 is not limited to the illustrated embodiment, and any means may be used as long as it is connected to the ice transfer member 210 to rotationally drive the ice transfer member 210.

The quantitative extraction unit 300 may be associated with the ice transfer unit 200. The quantitative extracting unit 300 may send the ice I discharged from the ice discharge port D to the ice extracting unit E after receiving a predetermined amount of the ice. Accordingly, the ice (I) can be extracted by a predetermined amount and supplied to the user. The quantitative extracting unit 300 may include a quantitative extracting member 310 and a connecting member 320 as shown in FIG. 1 in order to extract the ice I by a predetermined amount.

The quantitative extraction member 310 may be provided with at least one extraction blade 311 as in the embodiment shown in FIG. The extraction blade 311 may be formed to receive a predetermined amount of the ice I discharged from the ice discharge port D as shown in the illustrated embodiment. Accordingly, the ice (I) discharged from the ice discharge port (D) is transferred by a predetermined amount to the extraction blade (311).

The connection member 320 may connect the quantitative extraction member 310 to the rotation driving means 220 such that the quantitative extraction member 310 is rotationally driven. One side of the connecting member 320 may be connected to the quantitative extracting member 310 and the other side of the connecting member 320 may be connected to the gear 222 of the rotation driving means 220. Therefore, the connecting member 320 is rotated by the rotation driving means 220, and the quantitative extraction member 310 is rotated by the rotation of the connecting member 320. Accordingly, the ice (I) discharged from the ice discharge port (D) and transferred to the extracting blade (311) by a predetermined amount can be sent to the ice extracting section (E). In this way, the ice (I) sent to the ice extracting unit E by a predetermined amount is extracted through the ice extracting unit E and supplied to the user. The gear 222 connected to the connecting member 320 may have more gears than the gear 222 connected to the ice transfer member 210 as shown in the illustrated embodiment. That is, the connecting member 320 can be rotated more slowly than the ice transfer member 210. However, the number of gears of the gear 222 connected to the connecting member 320 and the gear 222 connected to the ice transfer member 210 is not limited to the number of gears, D), and the number of gears that can receive the ice (I) discharged to the ice discharge port (D) and send it to the ice extracting section (E).

The quantitative extracting unit 300 may further include a rotational position detecting unit 330. The rotational position detecting means 330 can detect the rotational position of the quantitative extraction member 310. The rotational position detecting means 330 may include a rotational position detecting disk 331 and a rotational position detecting sensor 332 so that the rotational position of the quantitative extracting member 310 can be known.

The rotational position detecting disk 331 may be provided on the connecting member 320 as in the embodiment shown in FIG. The rotation position detection disk 331 may be provided with one or more rotation position detection holes 331a as shown in the illustrated embodiment. The rotation position detection hole 331a can be formed at the edge of the rotation position detection disk 331 as shown in the illustrated embodiment. However, the position for forming the rotational position detecting hole 331a is not limited to the illustrated embodiment, and any position can be used as long as it can detect the rotational position.

The rotational position detecting sensor 332 may be provided to detect the rotational position through one or more rotational position detecting holes 331a formed in the rotational position detecting disk 331 as in the embodiment shown in FIG. 1 . That is, as shown in the illustrated embodiment, the rotational position detecting sensor 332 has a "C" shape, and a path of an electromagnetic wave can be formed by passing an electromagnetic wave such as light or the like between a "C" shape. The rim of the rotational position detecting disk 331 may be located in the 'C' shape of the rotational position detecting sensor 332. As described above, one or more rotation position detecting holes 331a may be formed on the rim of the rotational position detecting disk 331. [ Thus, when the rim of the rotational position detecting disk 331, on which the rotational position detecting holes 331a are not formed, passes between the rotational position detecting sensors 332 having a "C" shape, The path of the electromagnetic wave formed between the rotational position detecting sensors 332 is cut off. When the rim of the rotational position detecting disk 331 having the rotational position detecting hole 331a passes between the rotational position detecting sensors 332 having a "C" shape, A path of an electromagnetic wave is formed between the sensors 331 and 332. When this is detected, the rotational position of the quantitative extraction member 310 connected to the connection member 320 can be known. The amount of ice (I) transferred to the extraction blade (311) of the quantitative extraction member (310) can be adjusted by adjusting the rotation speed of the quantitative extraction member (310).

Hereinafter, the operation of one embodiment of the ice extraction apparatus 100 according to the present invention will be described with reference to FIGS. 2 to 4. FIG.

Ice (I) made in an ice maker (not shown) included in a refrigerator or an ice water purifier is stored in an ice reservoir S as shown in FIG. When the rotation driving means 220 is operated while the ice I is stored in the ice storage S as described above, the motor 221 rotates and the rotation of the motor 221 is transmitted to the gear 222, The ice transfer member 210 connected to the ice transfer member 210 is rotated. When the ice conveying member 210 rotates, the ice I stored in the ice reservoir S is conveyed by the conveying blade 211 having a screw shape provided in the ice conveying member 210 as shown in FIG. 2, (D) of the reservoir (S).

The gear 222 connected to the motor 221 of the rotation driving means 220 is also connected to the connection member 320 connected to the quantitative extraction member 310. The rotation of the motor 221 transmitted to the gear 222 is also transmitted to the connecting member 320 so that the quantitative extracting member 310 connected to the connecting member 320 is also rotated. Therefore, while the ice (I) stored in the ice reservoir S is transferred to the ice discharge port (D) of the ice reservoir S as described above, the quantitative extraction member 310 also rotates, The extraction blade 311 of the quantitative extraction member 310 is positioned adjacent to the ice discharge port D of the ice reservoir S as well.

When the ice transfer member 210 further rotates in this state, the ice I transferred to the ice discharge port D of the ice storage container S is discharged from the ice discharge port D. Thus, the ice (I) discharged from the ice discharge port (D) is transferred to the extraction blade (311) located adjacent to the ice discharge port (D). The movement of the ice I discharged from the ice discharge port D to the extraction blade 311 causes the next extraction blade 311 to rotate to the ice discharge port D so that the ice I at the ice discharge port D ) Until it is stopped. Therefore, a certain amount of ice (I) is transferred from the ice discharge port (D) to the extraction blade (311).

3, when a certain amount of ice (I) is transferred from the ice discharge port (D) to the extraction blade (311), and the quantitative extraction member (310) further rotates, a certain amount of ice The extracting blade 311 is moved to the ice extracting section E as shown in FIG. Accordingly, a predetermined amount of ice (I) transferred to the extracting blade 311 can be sent to the ice extracting section E for extraction. As this process is repeated, a certain amount of ice (I) can be supplied to the user.

As described above, by detecting the rotational position of the quantitative extraction member 310 by the rotational position detection means 330 provided in the connection member 320, the rotational speed of the quantitative extraction member 310 can be adjusted So that the amount of ice (I) transferred to the extraction blade (311) of the quantitative extraction member (310) can be adjusted.

As described above, when the ice extraction apparatus 100 according to the present invention is used, the ice stored in the ice storage can be extracted by a predetermined amount.

Thus, a certain amount of ice can be supplied to the user.

Also, the amount of ice to be supplied can be adjusted.

The above-described ice extraction device can be applied to a limited number of configurations of the above-described embodiments, but all or a part of the embodiments may be selectively combined so that various modifications may be made to the embodiments .

1 is a partial cross-sectional perspective view of an embodiment of an ice extraction apparatus according to the present invention.

2 to 4 are views showing the operation of an embodiment of the ice extraction device according to the present invention.

       Description of the Related Art [0002]

100: ice extraction device 200: ice transfer

210: ice conveying member 211: conveying blade

220: rotation driving means 221: motor

222: gear 300:

310: Quantitative extraction member 311: Extraction blade

320: connecting member 330: rotational position detecting means

331: Rotation position detection disk 331a: Rotation position detection hole

332: Sensor for detecting rotation position S: Ice storage

I: ice D: ice outlet

E: ice extraction unit

Claims (6)

An ice transfer part 200 provided in the ice storage S and configured to transfer the ice I stored in the ice storage S to the ice discharge port D of the ice storage S; And (I) discharged from the ice discharge port (D) is sent to the ice extracting unit (E) by receiving a predetermined amount of ice (I) in association with the ice transfer unit (200) (300); And, The quantitative extracting unit 300 includes a quantitative extracting member 310 having at least one extracting blade 311 formed to receive a predetermined amount of ice I discharged from the ice discharge port D, A connection member 320 connecting the quantitative extraction member 310 to the rotation driving means 220 included in the ice transfer unit 200 so that the movable body 310 rotates, And a rotational position detecting means (330) for detecting the position, The rotational position detecting means 330 includes a rotational position detecting disk 331 provided on the connecting member 320 and having one or more rotational position detecting holes 331a formed thereon, And a rotational position detecting sensor (332) provided to detect a rotational position of the ice cubes. The ice making machine according to claim 1, An ice transfer member 210 provided with a screw-shaped transfer blade 211; And Rotation driving means 220 connected to the ice transfer member 210 for rotating the ice transfer member 210; Wherein the ice extraction device comprises: The ice extraction device of claim 2, wherein the ice transfer member (210) is installed in the ice reservoir (S) so that the ice discharge port (D) is higher than the ice discharge port (D). delete delete delete

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