KR101554036B1 - Ice-making assembly for refrigerator - Google Patents

Abstract

The ice making assembly for a refrigerator according to the present embodiment includes at least one tray for generating ice; An operating member for rotating the tray; And a power transmitting portion connected to the operating member for transmitting operation force of the operating member to the tray, wherein the power transmitting portion is composed of a plurality of gears, and in the rotation process of the plurality of gears, The gears are characterized by contacting only one side of the gear teeth of the meshing gears.

Tray, gear

Description

[0001] Ice-making assembly for refrigerator [0002]

This embodiment relates to an ice-making assembly for a refrigerator.

Generally, an ice-making assembly for a refrigerator is provided in a refrigerator body or a refrigerator door to generate ice by cold air.

The ice making assembly for a refrigerator includes an outer case having an outer shape, an ice maker provided in the outer case, a water container in which water supplied to the ice maker is stored, and an ice bank in which ice, .

The ice maker includes an ice-making case, at least one tray rotatably provided in the ice-making case, an operating member for rotating the tray, and a power transmitting portion for transmitting the rotational force of the operating member to the tray. . A plurality of gears are used as the power transmitting portion.

However, when a plurality of gears is used as the power transmitting portion as described above, when water penetrates between the gears, a large amount of force is applied when the user pulls the operating member, and the gears can not be smoothly rotated A problem occurs.

The present invention has been proposed in order to solve the above-described problems, and it is an object of the present invention to provide an icemaker for a refrigerator which allows a user to easily rotate the tray by a power transmitting device that can rotate smoothly with a plurality of gears engaged It is in the suggestion.

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According to an aspect of the present invention, there is provided an ice maker for a refrigerator including: at least one tray for generating ice; An operating member for rotating the tray; And a power transmitting portion connected to the operating member for transmitting operation force of the operating member to the tray, wherein the power transmitting portion is composed of a plurality of gears, and in the rotation process of the plurality of gears, Wherein one of the gears is in contact with only one side of one gear of the gears, and the front portion of one of the gears and the rear portion of the gears of the other gear And the plurality of gears are rotated in a state in which the gears are in contact with each other only one by one.
According to another aspect of the present invention, there is provided an ice maker for a refrigerator, comprising: at least one tray for generating ice; An operating member for rotating the tray; And a power transmitting portion connected to the operating member for transmitting the operating force of the operating member to the tray, wherein in the plurality of gears, the pitch between the gears of one of the gears is larger than the pitch And a plurality of gears of the gears engaged with the gears of any one of the plurality of gears can be accommodated, wherein the plurality of gears are rotated in a state in which the gears are in contact with each other only one by one.
And the operating member is formed in a lever-like shape that can be rotated by a user's hand.
The plurality of gears includes a driving gear provided on the operating member and rotated together with the operating member when the operating member is rotated; At least a driven gear coupled to the rotating shaft of the at least one tray and rotated together; And a connecting gear which is arranged to be engaged with both the driving gear and the driven gear and transmits a rotational force.

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According to the proposed embodiment, even if water flows into a contact portion between a gear of one of the gears and a gear of the adjacent gear, the cohesive force and the surface tension of the water are reduced, and the water is not easily swayed.

Further, even if freezing occurs at a contact portion of each of the gears, each of the gears that are brought into contact with each other can easily fall, so that the meshed gears can be smoothly rotated.

Further, since each of the gears is smoothly rotated, a user can easily operate the operating member.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings.

FIG. 1 is a view showing a state in which an icemaker assembly according to a first embodiment is coupled to a refrigerator door. FIG.

Referring to FIG. 1, an icemaker assembly 10 according to the present embodiment is coupled to the inside of a refrigerator door 5. At this time, the refrigerator door (5) is preferably a freezing chamber door so that ice is produced by the ice making assembly (10). However, if a separate means for supplying cold air to the icemaker assembly 10 is added, the icemaker assembly 10 may be provided in the refrigerator compartment door.

The ice maker assembly 10 includes an outer case 11 having an outer shape and an ice maker 100 housed in the outer case 11. The ice maker assembly 10 is provided above the ice maker, And an ice bank 200 provided below the ice maker 100 and storing ice that has been ice-cooled in the ice maker 100. The ice-

The water bottle 200 and the ice bank 300 are slidably coupled to the ice making assembly 10 to be drawn out to the outside.

The operation of the ice-making assembly 10 according to the above-described structure will be briefly described.

The user first fills the bucket 200 with water to obtain ice. Then, the water bottle 200 is coupled to the ice-making assembly 10 while the water bottle 200 is filled with water. Then, the water stored in the water bottle 200 is supplied to the ice making device 100 through a predetermined flow path.

The water supplied to the ice making device 100 is changed into ice by the cool air introduced into the ice making device 100. When ice is generated in the ice maker 100, the user causes the ice of the ice maker 100 to be stored in the ice bank 300. Then, the user removes the ice bank 300 from the ice-making assembly 10 to obtain ice.

Hereinafter, the icemaker according to the present embodiment will be described in detail.

2 is a perspective view of an ice maker according to the first embodiment.

2, the ice maker 100 according to the present embodiment includes an ice making case 102, a plurality of trays 110 and 120 rotatably provided in the ice making case 102, A power transmitting unit 150 for transmitting the rotational force of the operating member 140 to the trays 110 and 120 and a power transmitting unit 150 for transmitting the rotational force of the operating member 140 to the trays 110 and 120. [ And a side cover 104 coupled to the side surface and covering the power transmission portion.

In detail, the trays 110 and 120 include an upper tray 110 and a lower tray 120. The rotation shaft of the lower tray 120 is positioned behind the rotation shaft of the upper tray 110 so that the ice of the upper tray 110 does not fall into the lower tray 120 when the upper tray 110 rotates. Are spaced apart from each other by a predetermined distance.

The power transmission unit causes the trays 110 and 120 to rotate in the same direction as the rotational direction of the operating member 140 when the operating member 140 rotates.

Hereinafter, the structure of the power transmission unit 150 will be described in more detail.

FIG. 3 is a side view of the ice maker showing a state in which the side cover is separated from the ice maker, FIG. 4 is an enlarged view of a portion A of FIG. 3, to be.

3 to 5, the power transmission unit 150 includes a driving gear 160 rotated together with the operating member 140, and a driving gear 160 engaged with the driving gear 160, And an upper driven gear 180 and a lower driven gear 190 which are engaged with the connecting gear 170 and engaged with the rotation shafts of the trays 110 and 120, respectively.

The operating member 140 is coupled to one side of the ice-making case 102 and the driving gear 160 is coupled to the gear engaging portion 142 formed on the operating member 140. The connecting gear 170 and the driven gears 180 and 190 are coupled to the ice-making case 102.

Therefore, when the driving gear 160 is rotated in one direction due to the pulling of the operating member 140, the connecting gear 170 engaged with the driving gear 160 is rotated in the other direction. When the connecting gear 170 is rotated in the other direction, the driven gears 180 and 190 are rotated in one direction. That is, in this embodiment, the driving gear 160 and the driven gears 180 and 190 are rotated in the same direction.

More specifically, each gear 160, 170, 180, 190 includes a plurality of gears 162, 173, 175, 182, 192. The connecting gear 170 includes a small gear 172 engaged with the driving gear 160 and a small gear 172 having a larger diameter than the small gear 172 and engaged with the driven gears 180 and 190 And a large gear 174 are included.

The gears 162, 173, 175, 182 and 192 of the gears 160, 170, 180 and 190 are formed by freezing between the gears 162, 173, 175, 182 and 192 The pitches 162, 173, 175, 182 and 192 between the gears are formed to be wide so as to prevent the gears 160, 170, 180 and 190 from rotating. Hereinafter, the mutual action of the gears according to the formation of the pitches (the distances between the gears) of the gears 162, 173, 175, 182 and 192 is described.

First, the position of the gear teeth will be described.

In the description of the embodiment, the "front portion" of the gear teeth means the front portion of the gear teeth with reference to the rotational direction of the gears, and the "rear portion"

4, the front portion 162a of the drive gear 162 is in contact with the rear face portion 173b of the gear teeth of the small gear 172. As shown in FIG. At this time, the respective gears in contact with each other in Fig. 4 are referred to as "nth gear ". The gears that are next to each other are referred to as "(n + 1) th gears ", respectively.

In this state, when the nth gear of the driving gear 160 is rotated, the front portion 173c of the (n + 1) th gear of the small gear 172 is engaged with the nth gear of the driving gear 160 The front portion 162c of the (n + 1) -th gear of the driving gear 162 is not in contact with the rear portion 162b of the (n + 1) th gear 162 of the small gear 173, (173d).

That is, in this embodiment, the front portion 173c of the (n + 1) th gear of the small gear 172 is spaced apart from the rear portion 162b of the nth gear 162 of the driving gear 160 The small gear 172 is rotated.

According to the conventional gear structure, when the driving gear is rotated, the front portion of the nth gear of the driving gear contacts the rear portion of the nth gear of the connecting gear, and the rear portion of the nth gear (N + 1) th gear of the connecting gear. In other words, the n-th gear of the driving gear is configured so that the n-th gear of the connecting gear and the n + 1-th gear simultaneously contact with each other.

However, according to the embodiment described above, the front portion 173c of the (n + 1) th gear of the small gear 172 is rotated by the pitch of the gears of the respective gears in the rotation process of the driving gear and the driven gear, And the n-th gear 162 do not come into contact with the rear portion 162b.

Therefore, even if water flows into the contact portion between the gear of the driving gear 160 and the gear of the connecting gear 170, the cohesive force and the surface tension of the water become small, so that the water is not easily squeezed.

In addition, even if freezing occurs at a contact portion between the gear of the driving gear 160 and the gear of the coupling gear 170, the gears that are brought into contact with each other can easily fall, 170 can be smoothly rotated. Since the driving gear 160 and the coupling gear 170 are smoothly rotated, the user can easily operate the operating member 140.

Although the relationship between the driving gear 160 and the coupling gear 170 has been described above, this structure is also applicable to the coupling gear 170 and the driven gears 180 and 190.

That is, the gear of either one of the gears is in contact with only one side of the gear of the adjacent gear which meshes with it.

FIG. 6 is a side view of an ice maker showing a power transmitting portion according to a second embodiment, and FIG. 7 is an enlarged view of a portion B in FIG.

In the description of the present embodiment, the same reference numerals are used for the portions overlapping the original embodiment.

6 and 7, the power transmission unit 450 according to the present embodiment includes a driving gear 460 rotated together with the operating member 140, and a driving gear 460 engaged with the driving gear 460, An upper driven gear 480 and a lower driven gear 490 engaged with the connecting gear 470 and engaged with the rotation shafts of the trays 110 and 120, .

In detail, the connecting gear 470 includes a small gear 472 engaged with the driving gear 460, and a small gear 472 having a larger diameter than the small gear 472 and engaged with the driven gears 480 and 490 at the same time And a large gear 474 are included.

In this embodiment, the gears 460, 470, 480, and 490 of the gears 460, 470, 480, and 490 are rotated by the gears 462, 473, 475, 482, The pitch of the gears of one gear is formed to be larger than the pitch of the gears of the adjacent gears which mesh with each other.

5, the pitch of the gears of the drive gear 460 is formed to be larger than the pitch of the gear teeth 462 of the small gear 470. The first gear of the driving gear 160 is located between the first gear 462a and the second gear 462b (hereinafter referred to as "n + 1th gear" A plurality of gears of the connecting gear 470 are disposed.
6, the driving gear 460 and the small gears 472 of the connecting gear 470 have different pitches. However, in the course of the rotation, the gears of the driving gear 460 and the small gears 472 Can be brought into contact with each other so that the rotational force of the driving gear 460 can be transmitted to the small gear 472.
At this time, since the pitch between the gears of the driving gear 460 and the gear of the small gear 472 of the driving gear 460 is not the same, the rotation of the driving force is not completely transmitted 100% One gear of the one driving gear 460 can be brought into contact with one gear of the small gear 472 in the course of the rotation of the driving gear 460, The gears of the plurality of small gears 472 may be accommodated in the space between the gears of the driving gear 460 during rotation of the driving gear 460 in order to transmit the rotational force.

The gear of the connecting gear 470 located between the nth gear 462a and the (n + 1) th gear 462b of the driving gear 460 is connected to the mth gear 473a, And the (m + 1) -th gear is referred to as a gear 473b.

Then, the nth gear 462a of the driving gear 460 detects that the m-1th gear 473c and the mth gear 473b of the connecting gear 470 are engaged with each other . When the driving gear 460 is rotated in this state, the (n + 1) th gear 462b of the driving gear 460 is connected to the m + 1th gear 473b of the connecting gear 470, And the + 2nd gear is engaged with the gear 462d.

In the above description, the relationship between the driving gear 460 and the connecting gear 470 has been described. However, this structure is also applicable to the connecting gear 470 and the driven gears 480 and 490.

According to this embodiment, even if water flows into the contact portion between the gear of the driving gear 460 and the gear of the connecting gear 470, the cohesive force and the surface tension of the water become small, so that the water can not be easily squeezed.

In addition, even if freezing occurs at the contact portion between the gear of the driving gear 460 and the gear of the connecting gear 470, since each of the contacting gears can be easily dropped, (470) can be smoothly rotated.

1 is a view showing a state in which an icemaker assembly according to a first embodiment is coupled to a refrigerator door.

2 is a perspective view of an ice maker according to the first embodiment;

3 is a side view of the ice maker showing a state in which the side cover is separated from the ice maker.

4 is an enlarged view of a portion A in Fig.

5 is a view showing a state in which the driving gear and the connecting gear are rotated.

6 is a side view of an ice maker showing a power transmitting portion according to a second embodiment;

7 is an enlarged view of a portion B in Fig.

Claims (8)

delete delete delete delete At least one tray in which ice is produced; An operating member for rotating the tray; And A power transmitting portion connected to the operating member for transmitting operation force of the operating member to the tray, Wherein the power transmitting portion comprises a plurality of gears, Wherein, in the rotation process of the plurality of gears, only one side of the gears of one of the gears is in contact with only one side of one gear of the gears, A front portion of a gear of one of the gears is in contact with a rear portion of a gear of the other gear relative to a rotation direction of the plurality of gears, and the plurality of gears are rotated in a state in which gears are in contact with each other only one by one Deicing assembly for refrigerator. At least one tray in which ice is produced; An operating member for rotating the tray; And A power transmitting portion connected to the operating member for transmitting operation force of the operating member to the tray, In the plurality of gears, the pitch between the gears of one of the gears is formed to be larger than the pitch of the gears of the meshing gears, so that a plurality of gears of gears meshing between the gears of the gears can be accommodated , Wherein each of the plurality of gears is rotated in a state that the gears are in contact with each other only one by one. The method according to claim 5 or 6, Wherein the operating member is formed in a lever shape that can be rotated by a user's hand. The method according to claim 5 or 6, The plurality of gears A driving gear provided on the operating member and rotated together with the operating member when the operating member is rotated; At least a driven gear coupled to the rotating shaft of the at least one tray and rotated together; And a connecting gear which is arranged to be engaged with both the driving gear and the driven gear and transmits rotational force.

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