KR20130140384A - Apparatus for ice making - Google Patents

Abstract

Disclosed is an ice making machine. The ice making machine according to an embodiment of the present invention comprises: a partition of an ice making room, which is formed on one side in a refrigerator; and an ice transferring operation unit, which is formed on the partition. The ice transferring operation unit includes a fixing unit, which is integrally formed with the partition.

Description

[0001] APPARATUS FOR ICE MAKING [0002]

An embodiment of the present invention relates to an ice making apparatus, and more particularly, to an ice making apparatus capable of reducing noise and simplifying the entire manufacturing process.

Generally, a refrigerator has a refrigerating chamber capable of refrigerating food and a freezing chamber capable of refrigerating and storing food. At this time, the positions of the refrigerator compartment and the freezer compartment can be variously changed according to the design of the refrigerator. Conventionally, a refrigerator in which a refrigerator compartment and a freezer compartment are formed in a mainstream is formed, but in recent years, a refrigerator having a freezer compartment at a lower portion and a refrigerating compartment at an upper portion has been released.

FIG. 1 is a front view of a conventional refrigerator, and FIG. 2 is a side view of a conventional refrigerator. For convenience of explanation, the refrigerating compartments in FIGS. 1 and 2 show the inside thereof.

1 and 2, a conventional refrigerator 10 has a freezing chamber 11 formed at a lower portion thereof and a refrigerating chamber 13 formed at an upper portion thereof. In this type of refrigerator 10, when the ice maker is installed in the freezer compartment 13, there is an inconvenience that the ice in the ice maker must be taken out by bending the user's body. Therefore, The ice chamber 20 is installed.

The ice making chamber 20 is insulated from the refrigerating chamber 13 through the ice making compartment wall 21 formed at one side of the refrigerating chamber 13 and has an independent space separated from the refrigerating chamber 13. In the ice making chamber 20, an ice maker 23, an ice bank 25, and an ice transfer driver 27 are formed. The ice bank 25 is formed below the ice bank 23 on the ice bank compartment wall 21 and the ice bank transfer driver 27 is formed on the ice bank 25 on the ice bank compartment wall 21.

When ice making is completed in the ice maker 23, the ice maker 23 rotates an ejector (not shown) to discharge ice to the ice bank 25. The ice bank 25 is formed with an upper portion open to receive the ice discharged from the ice maker 23. The ice bank 25 includes an ice conveying part 31, an ice crushing part 33, and an ice discharge part 35.

The ice transfer part 31 is formed in a screw shape and is formed to cross the inside of the ice bank 25. One end of the ice transfer unit 31 is rotatably connected to the ice transfer drive unit 27, and the other end of the ice transfer unit 31 is connected to the ice grinding unit 33. Here, as the ice transfer unit 31 rotates, the ice in the ice bank 25 is transferred to the ice crushing unit 33 by the ice transfer unit 31.

The ice crushing unit 33 serves to crush the ice conveyed by the ice conveying unit 31. The ice crushing unit 33 includes a fixed blade 33-1 and a movable blade 33-2. Here, the fixed blade 33-1 and the movable blade 33-2 are connected to the other ends of the ice transfer part 31, respectively.

The ice discharge part 35 opens and closes a portion of the lower surface of the ice bank 25 to discharge the ice transferred by the ice transfer part 31 to the ice chute 70 formed at the lower portion of the ice bank 25. . The ice discharged into the ice chute 70 is discharged to the outside of the refrigerator 10 through a dispenser (not shown). The ice discharge part 35 is installed to open and close only a predetermined portion of the lower surface of the ice bank 25 based on the fixed blade 33-1 and the movable blade 33-2. In this case, depending on whether the ice discharge part 35 is opened or closed, the user can selectively obtain ice cubes and crushed ice.

Figure 3 is a front view showing a conventional ice transfer drive, Figure 4 is a rear view showing a conventional ice transfer drive.

3 and 4, the ice transfer driver 27 includes a case 41, a motor 43, and a solenoid 45. A lever connecting hole 42 is formed on the front of the case 41. The motor 43 is coupled to one end of the ice transfer part 31 through a coupling auxiliary member 47 formed on the front surface of the case 41. The motor 43 serves to rotate the ice transfer unit 31.

The lower end of the solenoid 45, the lever connection portion 46 is formed. At this time, the lever connecting portion 46 is exposed to the outside by the lever connecting hole 42. One end of the lever (not shown) is connected to the lever connecting portion 46 through the lever connecting hole 42, and the other end of the lever (not shown) is connected to the ice discharge portion 35. The solenoid 45 may operate the lever (not shown) by moving the lever connecting portion 46 up and down, thereby adjusting the opening of the ice discharge part 35 to select the size of the ice.

Since the conventional ice transfer driving unit 27 configured as described above has a separate case 41, the volume occupied by the ice transfer driving unit 27 becomes large, thereby increasing the total volume of the ice making chamber 20. There is this. In this case, power consumption for maintaining the temperature in the ice making chamber 20 below a certain temperature becomes larger.

In addition, the conventional ice transfer driving unit 27 manufactures a separate case 41, assembles the motor 43 and the solenoid 45 in the case 41, and sets the case 41 to the ice making compartment partition wall 21. Since it must be coupled to the rear of the ice bank 25 in the above, there is a problem that the entire assembly process is complicated, the accuracy of the dimensions is lowered, and the manufacturing cost is increased.

In addition, the conventional ice transfer driving unit 27 is a separate case 41 is coupled to the rear of the ice bank 25 on the ice compartment partition wall 21, so that when the motor 43 drives the case 41 and There is a problem in that noise is generated due to minute collision and tremor between the ice bank 25 and the case 41 and the ice making compartment partition wall 21.

Meanwhile, the conventional ice maker 23 is manufactured by separately manufacturing components such as an ice maker control box, an ice tray, a water cup, and a heater cover, and then assembled and used. In this case, a plurality of injection molding processes are used to manufacture each component. Since it is necessary to perform the assembly and assembly of each component, there is a problem in that the manufacturing process is complicated, the manufacturing cost is increased, and the accuracy of dimensions is inferior.

Embodiment of the present invention is to provide an ice making apparatus that can simplify the entire assembly process and reduce the noise.

Ice making apparatus according to an embodiment of the present invention, the ice compartment compartment formed on one side of the refrigerator; And an ice conveying driving part formed on the ice making compartment partition wall, wherein the ice conveying driving part includes a fixing part integrally formed with the ice making compartment partition wall.

An ice making apparatus according to another embodiment of the present invention includes an ice making compartment partition formed on one side of a refrigerator and an ice making unit formed in the ice making compartment partition, wherein the ice maker includes an ice tray and an ice tray. An ice maker control box is formed at one side, and the ice maker control box is integrally formed with the ice compartment partition wall.

An ice making apparatus according to still another embodiment of the present invention includes an ice making compartment partition formed on an inner side of a refrigerator and an ice making unit formed in the ice making compartment partition, wherein the ice making unit is combined with the ice maker. And an ice maker support for fixing and supporting the ice maker, wherein the ice maker support is integrally formed with the ice compartment partition wall.

According to the embodiment of the present invention, since the ice conveying drive unit does not have a separate case, the volume occupied by the ice conveying drive is reduced, thereby reducing the total volume of the ice making apparatus. In this case, power consumption for maintaining the temperature in the ice making apparatus below a certain temperature can be reduced.

And, since the fixed portion of the ice conveying drive unit is formed integrally with the ice making compartment partition wall, the entire assembly process can be simplified, the accuracy of the dimensions can be increased, and the manufacturing cost can be reduced.

In addition, since the fixing part of the ice conveying drive unit is formed integrally with the ice making compartment partition, noise of the ice conveying unit and the ice making compartment partition does not occur between the ice conveying drive unit and the ice making compartment partition when the conveying motor is driven, thereby reducing the noise of the ice making apparatus. Will be.

In addition, by forming at least one of the water cup, the heater cover, and the ice maker control box of the ice maker unit with the ice compartment partition wall, the injection molding process can be reduced, and the water cup, the heater cover, and the ice maker control box are formed in the ice compartment. Since the step of assembling the partition can be omitted, the manufacturing cost can be reduced while simplifying the entire manufacturing process.

In addition, by forming the ice maker support integrally with the ice compartment partition, it is possible to reduce the manufacturing cost while simplifying the entire manufacturing process of the ice making apparatus.

1 is a front view of a conventional refrigerator.
2 is a side view of a conventional refrigerator.
Figure 3 is a front view showing a conventional ice transfer drive.
Figure 4 is a rear view showing a conventional ice transfer drive.
5 is a schematic view of an ice making apparatus according to an embodiment of the present invention.
6 is a schematic view of an ice making apparatus according to another embodiment of the present invention.
7 is a view showing a state in which the ice maker support is combined with an ice tray and an ice maker control box.

Hereinafter, specific embodiments of the ice making apparatus of the present invention will be described with reference to FIGS. 5 to 7. However, this is an exemplary embodiment only and the present invention is not limited thereto.

In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intention or custom of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

The technical idea of the present invention is determined by the claims, and the following embodiments are merely a means for efficiently describing the technical idea of the present invention to a person having ordinary skill in the art to which the present invention belongs.

5 is a view schematically showing an ice making apparatus according to an embodiment of the present invention.

Referring to FIG. 5, the ice making apparatus 100 includes an ice making compartment partition 102 and an ice conveying driving unit 104.

The ice making compartment partition 102 is formed inside a refrigerator in which the ice making apparatus 100 is installed. The ice making compartment partition 102 may be formed at one side of the refrigerating compartment. Here, the ice making compartment partition 102 forms a separate space from the refrigerating compartment in the refrigerating compartment, and the space in the ice making compartment partition 102 forms an ice making compartment. In FIG. 5, the front and side portions of the ice making compartment partition 102 are opened for convenience of description, but the ice making compartment partition 102 is formed in a sealed form in the refrigerating compartment.

An insulation may be formed in the ice compartment partition wall 102. In this case, the ice making apparatus 100 is insulated from the refrigerating compartment through the ice making compartment partition 102. The space in the ice compartment partition 102 should be kept at sub-zero temperatures to freeze the ice and prevent the frozen ice from melting. On the other hand, the refrigerator should maintain the temperature of the image to prevent the food from freezing while maintaining the freshness of the food stored in the refrigerator compartment. Accordingly, the space in the ice compartment partition 102 and the refrigerating compartment are insulated through the ice compartment partition 102.

The ice transfer drive 104 includes a stationary portion 111, a transfer motor 114, and a lever drive 117. Here, the ice conveyance drive unit 104 does not have a separate case, and provides a space in which the conveying motor 114 and the lever drive unit 117 are to be formed in the ice compartment partition wall 102 through the fixing unit 111. do.

The fixing part 111 is formed in the ice making compartment partition 102. In this case, the fixing part 111 is integrally formed with the ice making compartment partition wall 102. That is, the fixing part 111 is formed together with the ice making compartment partition 102 when the ice making compartment partition 102 is manufactured. In this case, the fixing part 111 and the ice making compartment partition 102 may be integrally formed through an injection molding process. The fixing part 111 serves to fix the feed motor 114 and the lever driving part 117 on the ice making compartment partition wall 102.

The fixing part 111 may be formed across the ice compartment partition wall 102 in the width direction of the ice compartment partition wall 102 in the ice compartment partition wall 102. In this case, the fixing part 111 divides the space in the ice-making compartment 102 into two spaces. At this time, in the space existing on one side of the fixing part 111 (for example, the left side of the fixing part 111), an ice feed driving part 104 including a feeding motor 114 and a lever driving part 117 is formed. In addition, an ice bank (not shown) may be formed in a space present at the other side of the fixing part 111 (eg, the right side of the fixing part 111).

Here, an ice maker (not shown) may be formed on the ice bank (not shown). The ice bank (not shown) stores the ice formed in the ice maker (not shown), and serves to discharge the stored ice to the outside of the ice maker 100 (for example, an ice chute of a refrigerator). The ice bank (not shown) includes an ice conveying unit for transferring ice in the ice bank (not shown), an ice crushing unit for crushing the ice conveyed by the ice conveying unit, and an ice conveying unit 100 by the ice conveying unit. It includes an ice discharge to discharge to the outside. However, only the ice transfer unit 151 is shown here for convenience of description. The ice transfer unit 151 moves the ice in the ice bank (not shown) by moving forward.

The fixing unit 111 may be provided with a lever connecting hole 121 for connecting the lever driving unit 117 and the lever (not shown). The fixing part 111 may be provided with a first coupling hole 124 for coupling one end of the rotating shaft 115 of the transfer motor 114 and the ice transfer part 151 to each other. At this time, the rotating shaft 115 of the feed motor 114 may be coupled to one end of the ice transfer unit 151 through the coupling auxiliary member 129.

In addition, at least one second coupling hole 127 may be formed in the fixing part 111 to fix the transfer motor 114 to the fixing part 111. A coupling member (not shown) such as a screw may be inserted into the second coupling hole 127 to fix the transfer motor 114 to the fixing portion 111.

The feed motor 114 is fixedly coupled to the fixing part 111. The transfer motor 114 is coupled to one end of the ice transfer unit 151 and serves to rotate the ice transfer unit 151. When the transfer motor 114 is driven, the ice transfer unit 151 rotates to transfer the ice in the ice bank (not shown) toward the ice discharge unit (not shown).

The lever driver 117 is formed in the left space of the fixing part 111. In this case, the lever driver 117 may be fixedly coupled to the ice compartment partition wall 102 or may be fixedly coupled to the fixing part 111. The lever driving unit 117 controls the size of the ice discharged from the ice discharge unit (not shown) by operating the lever (not shown) up and down. For example, when the lever (not shown) is operated upward through the lever driving unit 117, the ice transferred by the ice conveying unit 151 does not go through the ice crushing unit (not shown) to the ice discharge unit (not shown). It will be discharged immediately and large ice will be discharged. When the lever (not shown) is operated downward through the lever driving unit 117, the ice transferred by the ice transfer unit 151 is discharged to the ice discharge unit (not shown) through the ice grinding unit (not shown). Small ice will be discharged.

According to the exemplary embodiment of the present invention, the ice conveyance driving unit 104 may form the fixing unit 111 integrally with the ice making compartment partition wall 102 and the space provided on the ice making compartment partition wall 102 due to the fixing unit 111. By providing the feed motor 114 and the lever drive part 117, it is not necessary to provide the separate case for accommodating the feed motor 114 and the lever drive part 117. As shown in FIG. In this case, the volume occupied by the ice transfer driver 104 may be reduced, and the total volume of the ice making apparatus 100 may be reduced. Therefore, it is possible to reduce power consumption for maintaining the temperature in the ice making apparatus 100 below a predetermined temperature.

In addition, since the fixing part 111 of the ice conveying drive part 104 is integrally formed with the ice making compartment partition wall 102, the entire assembly process can be simplified, the accuracy of dimensions can be increased, and the manufacturing cost can be reduced. Will be. That is, since the ice making compartment partition 102 and the fixing part 111 can be integrally formed in one injection molding process, the injection molding process can be reduced, and the ice transfer driving unit 104 and the ice making compartment partition 102 are assembled. The process for doing so can be skipped.

In addition, since the fixing part 111 of the ice conveying drive part 104 is formed integrally with the ice making compartment partition wall 102, the ice conveying drive part 104 and the ice making compartment partition 102 when the conveying motor 114 is driven. Since noise due to mutual collision and trembling does not occur, the noise of the ice making apparatus 100 may be reduced.

Meanwhile, although the fixing part 111 of the ice transfer driving part 104 is described as being integrally formed with the ice making compartment partition wall 102, the present invention is not limited thereto. It may be formed integrally with some components (for example, a heater cover or an ice maker control box) of an ice maker (not shown) formed in the.

6 is a schematic view of an ice making apparatus according to another embodiment of the present invention.

Referring to FIG. 6, not only the fixing part 211 of the ice transfer driving part 204 but also some components of the ice maker may be integrally formed with the ice making compartment partition wall 202. For example, at least one of the water supply cup 257, the heater cover 259, and the ice maker control box 261 of the ice maker may be integrally formed with the ice maker partition wall 202. The feed cup 257, the heater cover 259, the ice maker control box 261 and the ice compartment partition 202 may be integrally formed through an injection molding process. At this time, the heater cover 259 and the ice maker control box 261 may also be integrally formed.

Here, the water supply cup 257 serves to supply the ice making water from the upper portion of the ice tray 251 into the ice tray 251. A plurality of partitions 253 are formed in the ice tray 251 to divide the inside of the ice tray 251 into a plurality of ice making spaces.

In addition, a heater 255 may be formed on the lower surface of the ice tray 251. The heater 255 slightly melts the frozen ice on the inner wall of the ice tray 251 and serves to easily ice the ice. In this case, a heater cover 259 may be formed under the ice tray 251 to protect the heater 255.

In addition, an ice maker control box 261 may be formed at one side of the ice tray 251. In the ice maker control box 261, a controller (not shown) for controlling the overall operation of the ice maker and an ejector driver (not shown) for driving an ejector (not shown) for icing ice in the ice tray 251 may be formed. .

As such, by forming at least one of the water supply cup 257, the heater cover 259, and the ice maker control box 261 of the ice maker integrally with the ice making compartment partition wall 202, the injection molding process can be reduced. Since the process of assembling the water supply cup 257, the heater cover 259, and the ice maker control box 261 to the ice making compartment partition wall 202 can be omitted, the manufacturing cost can be reduced while simplifying the entire manufacturing process.

Meanwhile, as illustrated in FIG. 7, the ice maker may include an ice maker support 371. In this case, the ice maker support 371 may be combined with the ice tray 351 and the ice maker control box 361 at the top of the ice tray 351 and the ice maker control box 361. The ice maker support 371 is coupled to the ice compartment partition wall in a state in which the ice maker support 371 is combined with the ice tray 351 and the ice maker control box 361, thereby fixing the ice maker to the ice compartment partition wall and protecting the ice maker. Here, the ice maker support 371 may be integrally formed with the ice compartment partition wall. For example, the ice maker support 371 may be integrally formed with the ice compartment partition wall through an injection molding process. In this case, the whole manufacturing process of an ice making apparatus can be simplified, and manufacturing cost can be reduced.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, I will understand. Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by equivalents to the appended claims, as well as the appended claims.

100: ice maker 102: ice compartment partition wall
104: ice transfer drive 111: fixed portion
114: feed motor 115: motor rotation axis
117: lever drive portion 121: lever connecting hole
124: first coupling hole 127: second coupling hole
129: coupling auxiliary member 151: ice transfer unit
202: ice making compartment partition 204: ice transfer drive
251: ice tray 253: bulkhead
255: heater 257: water cup
259: heater cover 261: ice maker control box

Claims (8)

An ice compartment partition wall formed at one side of the refrigerator; And
An ice conveying drive unit formed on the ice compartment partition wall,
The ice making drive unit, the ice making apparatus including a fixing portion formed integrally with the ice making compartment partition wall.
The method of claim 1,
The ice making device,
Further comprising an ice bank formed on one side of the fixed portion in the ice compartment partition wall,
The ice bank,
An ice conveying unit which forwards the ice stored in the ice bank by moving forward by rotation; And
And an ice discharge unit for discharging the ice carried by the ice transfer unit.
3. The method of claim 2,
The ice transfer drive unit,
A motor fixed to the fixed part and rotating the ice conveying part; And
The ice making apparatus is fixed to the fixing portion, further comprising a lever drive for adjusting the size of the ice discharged to the ice discharge.
An ice making apparatus comprising an ice making compartment partition formed on an inner side of a refrigerator and an ice maker formed in the ice making compartment partition.
The ice-
Ice tray; And
It includes an ice maker control box formed on one side of the ice tray,
The ice maker control box is formed integrally with the ice compartment partition wall.
5. The method of claim 4,
The ice-
Further comprising a water cup for supplying ice-making water from the upper portion of the ice tray to the ice tray,
The water supply cup is integrally formed with the ice compartment partition wall.
5. The method of claim 4,
The ice-
A heater formed on a lower surface of the ice tray; And
Further comprising a heater cover for protecting the heater in the lower portion of the ice tray,
And the heater cover is integrally formed with the ice compartment partition wall.
5. The method of claim 4,
The ice making device,
Further comprising an ice transfer drive formed on the ice compartment partition wall,
The ice making drive unit, the ice making apparatus including a fixing portion formed integrally with the ice making compartment partition wall.
An ice making apparatus comprising an ice making compartment partition formed on an inner side of a refrigerator and an ice maker formed in the ice making compartment partition.
The ice maker further includes an ice maker support coupled to the ice maker to fix and support the ice maker.
The ice maker support is formed integrally with the ice compartment partition wall.

Images