KR200283936Y1 - Ice Maker Structure of Combined Refrigerator - Google Patents

Abstract

The present invention relates to an ice maker structure improvement of a refrigerator equipped with an ice maker, and more particularly, an ice maker structure of a multiple refrigerator in which only ice having a predetermined size and shape is discharged as iced ice is transferred to a storage unit through an ice separator. It is about.

The ice maker structure according to the present invention includes an ice making unit for forming ice, an ice separator formed on one side of the storage container unit, and an ice separating unit for separating ice into standard ice and bad ice, and a standard separated from the ice separating unit. It consists of a storage container consisting of a storage unit for storing ice.

The ice separator comprises a cover in which a plurality of shape identification holes are formed, and a container for storing defective ice through the shape identification hole, and the container is installed inside the storage container and has a removable structure. .

Description

Ice Maker Structure of Compound Refrigerator

The present invention relates to an icemaker structure improvement of a refrigerator equipped with an ice maker, and more particularly, only ice having a predetermined size and shape by moving only ice having a predetermined size or more to the ice storage unit while the icemaker passes through the ice separator. It relates to an ice maker structure of the composite refrigerator to be discharged to the outside of the refrigerator body.

In general, according to the recent trend of improving living standards and favoring large and multifunctional refrigerators, refrigerators having a relatively large capacity but having various functions are being shown. As the demand for refrigerators increases, so does its function. The structure of a conventional composite refrigerator equipped with an ice maker will be described with reference to the drawings.

1 is a schematic structural diagram of a conventional composite refrigerator equipped with an ice maker. As shown, the ice maker A is installed at one side of the freezing compartment 1. The ice maker A has an ice making unit 2 that forms ice thereon, and a storage container 3 is installed at the lower portion thereof to store ice formed in the ice making unit 2.

On the other hand, the dispensing (4) is installed on the front of the door of the refrigerating chamber (5) so that the user places a cup or the like on the dispense (4) to receive ice or water. In addition, a front panel 4a having a water selection button or an ice selection button is formed on the dispense 4.

Next, an external pipe (a) connected to a water supply source (for example, a faucet) outside the refrigerator is installed at the rear wall of the refrigerating chamber 5, and a filter 6 is installed at one side of the external pipe (a) to the outside. The water introduced through the pipe (a) is filtered. A filter pipe 6a is formed at the outflow side of the filter 6, and a water supply valve 7 is provided at the end of the filter pipe 6a to regulate the supply of filtered water while passing through the filter 6.

The water supply valve 7 is connected to the ice making pipe 7a, and the ice making pipe 7a is connected to the ice making unit 2 so that water for ice making is supplied to the ice making unit 2. In addition, the water supply valve 7 is provided with a dispensing pipe 7b connected to the water tank 7c, and the dispensing pipe 7b connected to one side of the water tank 7c includes a dispense 4 installed in the door of the refrigerating chamber 5. The water is supplied to the dispensing 4 through the dispensing pipe 7b so that the user can receive the water through the dispensing 4.

Next, the ice maker structure will be described with reference to FIG. 2 showing a cross-sectional view of the ice maker structure.

As shown, an ice maker A is installed at one side of the freezing chamber 1, and the ice maker A has an ice maker 2 forming ice thereon, and a storage container 3 is installed at the bottom thereof. The ice produced in the ice 2 is stored. On the other hand, the storage container (3) is equipped with a feeder (3a) connected to the shaft of the motor (8) installed externally, and the rotary blade (3b) is attached to the front end of the feeder (3a) storage container The ice in (3) is conveyed, and an opening 3c is formed in front of the rotary vane 3b, and an inlet 3d for discharging ice to the outside is formed below the opening 3c.

Looking at the path through which the user is supplied with ice through the dispense 4 under the structure of the conventional ice maker, the user selects an ice selection button (not shown) formed on the front panel 4a and dispenses it with a cup b or the like. (4) Press the push button (9). Accordingly, the external motor 8 is operated, and the storage container part 3 is rotated as the feeder 3a connected to the shaft of the motor 8 and the rotary vane 3b positioned at the tip of the feeder 3a rotate. The ice stored in the) is pushed through the opening 3c, whereby the ice falls through the inlet 3d located below the opening 3c and through the ice outlet 9a to the user's cup b.

Next, FIG. 3 is an operation principle diagram of the ice making unit, and FIG. 4 is a flowchart illustrating an ice making operation performed in the ice maker of the multiple refrigerator with reference to the drawing.

First, water is supplied to the ice making container 2a installed in the ice making unit 2 (step 10). The water is supplied through a water source outside the refrigerator, and the adjustment is controlled by a water supply valve located behind the refrigerator compartment. After a certain time (t), the microcomputer (not shown) determines whether the water supply is completed. (Step 20) When the water supply is not completed, the water supply is continued. When the water supply is completed, the water supply is stopped and the ice making unit 2 (Step 30) After the ice making operation is performed for a predetermined time t1 input to the microcomputer (not shown) in advance (step 40), the ice making operation is stopped and the ice making container is stopped (2a). The ejector 2b located at the () is operated. (Step 50) At this time, the ejector 2b is rotated by 90 degrees and the operation is stopped for a predetermined time (t2) while the ejector 2b is rotated by 90 degrees. At the same time, the heater (not shown) is heated for a predetermined time t3 so that the ice formed in the ice making container 2a can be easily separated (step 60). The ice formed in the ice making container 2a by the heater heat Take it back while being easily separated from the ice maker (2a). Ejector (2b) is operated to rotate and accordingly the ice in the ice making container (2a) is separated from the ice making container (2a) is transferred to the storage container part. The water supply is made into the ice making vessel from (step 80). Then, water supply is made again for a predetermined time and the ice making operation is repeatedly performed. (Step 90)

In the ice maker structure described above, the ice formed in the ice making container in the ice making unit by the ice making operation is transferred to the storage container portion, and the ice stored in the storage container portion is discharged through the dispensing installed in the front of the door and is delivered to the user as follows. Problems will arise.

In ice-making containers that form ice, not only ice having a certain size and shape (hereinafter referred to as "standard ice"), but also broken ice and ice having a small or constant size (hereinafter referred to as "bad ice") Since the ice formed in the ice making container cannot be confirmed, the ice formed in the ice making container is moved into the storage container as it is, so that not only the standard ice but also the bad ice coexist together in the storage container. There is a problem with this.

It is an object of the present invention to provide an ice maker structure in which an ice separator is installed in an ice maker so that bad ices formed in the ice maker are removed through the ice separator so that a user can always obtain high quality ice.

The present invention for achieving the above object, the ice making unit for forming an ice; An ice separator comprising a cover having a plurality of shape identification holes and a container for storing the bad ice passing through the shape identification holes to separate the ice formed in the ice making unit into standard ice and bad ice; And a storage unit for storing standard ice separated from the ice separator.

Next, an embodiment of an ice maker structure having an ice separator according to the present invention will be described with reference to the drawings. 5 is a cross-sectional view showing the structure of an ice maker (A) is an ice maker according to the prior art, (B) is an ice maker according to the present invention, Figure 6 is a plan view of the storage container according to the present invention.

As shown, the ice maker structure according to the embodiment of the present invention, the ice making unit is formed inside the freezer compartment to form ice through the ice making container is the same as the conventional one, but is stored below the ice making unit to store the ice when needed The storage container 200 for supplying to the dispense installed in the front of the door has a structure different from the conventional structure.

When the storage container 200 is described in more detail, the storage container 200 is largely formed as a storage part 204 and the other side of the ice separation part 206 with the boundary of the central partition 202 inside. Divided into

In the storage unit 204, a conveyor 204a connected to an external motor shaft is installed, and a rotary vane 204b is installed at the tip of the conveyor 204a to push the ice stored in the storage unit 204 forward. An opening 204c is formed in front of the storage unit 204 so that the ice transferred by the rotary vane 204b is discharged out through the opening 204c.

On the other hand, the ice separator 206 provided on one side of the storage container 200 is composed of a cover 206a and a container 206b.

The cover 206a has a flat plate shape, and a plurality of shape identification holes 206c are formed, and both outer sides of the cover 206a are formed at the upper end of the partition wall 202 in the center of the storage container 200 and the storage container part ( It is in contact with the upper end of the outer peripheral edge of one side of 200). At this time, the length of the inner bulkhead 202 inside the storage vessel 200 is shorter than the outer periphery of the storage vessel 200, so that the cover 206a is coupled with a constant slope, and the cover due to the above structure ( 206a) ice that has reached the top surface is smoothly transferred to the storage unit 204 along the slope. Then, the coupling portions on both outer sides of the cover 206a are ultrasonically welded to be integrally coupled with the storage container 200.

Next, the container 206b will be described. The container is installed on the left side in the drawing with the partition 202 at the center of the inside of the storage container 200 in the drawing, and the cover 206a is positioned on the upper part of the container 206b so that the shape identification hole of the cover 206a ( Store bad ice delivered through 206c. And the container 206b is installed in a structure that can be detached from the storage container 200, when the inside is filled with bad ice, the container 206b is removed by removing the bad ice, the storage container 200 again To be used in combination.

Looking at the process of separating the bad ice in the ice maker of the present invention, the ice separator 206 is installed as described above, first, after the ice (d) is formed in the ice maker 100 installed in the ice maker 102 is taken out It is operated to deliver the ice (d) into the storage container 200.

When the above process is performed, as shown in (a), in the conventional ice maker structure, all of the ice (d) formed in the ice maker 2a is transferred into the storage container 3 as it is. The ice is also transferred into the storage container part 3, but in the ice maker structure according to the present invention shown in (b), the ice d formed in the ice maker 100 is first separated by the extractor 102. It is transmitted to the upper surface of the cover 206a of 206.

On the other hand, since the size of the shape identification hole 206c formed on the upper surface of the cover 206a is formed to be a little smaller than the standard ice, the bad ice formed during ice making passes through the shape identification hole 206c and is below the cover 206a. Drop into the vessel 206b located. On the other hand, the standard ice larger than the size of the shape identification hole 206c is located on the upper surface of the cover 206a, and the cover 206a is formed with a constant slope so that the standard ice slides down along the gradient. Easily fall into the reservoir 204.

Next, the bad ice which has moved downward through the shape identification hole 206c of the cover 206a is stored in the container 206b located under the cover 206a, and a predetermined amount or more of bad ice is filled in the container 206b. If it is, the container 206b is removed from the storage container 200 to remove the bad ice.

The standard ice introduced into the storage unit 204 along the gradient of the cover 206a is discharged to the outside through the opening 204c by the rotary vane 204b of the feeder 204a in the storage unit 204 and is opened. 204c is discharged to the outside of the refrigerator through the ice outlet located at the bottom.

On the other hand, in the embodiment of the present invention, the ice separator 206 is installed in the storage container 200, but is not limited thereto. That is, unlike the present embodiment, it may be configured to install an ice separator separately above the storage container portion, and it may also be possible to provide an independent ice separator separately from the storage container portion. After the ice formed in the ice making unit is removed from the bad ice through the ice separator, the location of the ice separator may be various as long as the standard ice is transferred to the storage container.

As described above, in the ice maker structure according to the present invention, the bad ice is removed through the ice separation unit, so that the user can always obtain high quality ice and increase the reliability of the product.

1 is a schematic structural diagram of a conventional composite refrigerator equipped with an ice maker

2 is a cross-sectional view of an ice maker structure of a conventional composite refrigerator

3 is a principle diagram of the ice making operation of the ice making unit

4 is a flowchart of ice making in the prior art

5 is a cross-sectional view showing the process of ice separation and movement of the ice maker to the storage container.

(A) Configuration diagram according to the prior art

(B) is a block diagram according to the present invention

6 is a plan view of the storage container according to the present invention

* Description of the main parts of the drawings *

2: ice making unit 2a, 100: ice making container

2b, 102: take-out 3,200: storage container

3a, 204a: conveyor 3b, 204b: rotary vane

3c, 204c: opening 3d: ice inlet

4: dispense 4a: front panel

6: filter 7: feed water valve

7a: De-Icing Piping 7b: Dispensing Piping

8: Motor 9: Push Button

9a: ice outlet 9b: water outlet

202: storage container partition wall 204: storage unit

206: ice separator 206a: cover

206b: container 206c: shape identification hole

Claims (3)

An ice making unit 2 for forming ice; A cover 206a having a plurality of shape identification holes 206c formed therein and a container 206b for storing defective ice passing through the shape identification holes 206c to specify ice formed in the ice making unit 2. An ice separator 206 for separating ice from bad ice; Storage unit 204 for storing the standard ice separated from the ice separator 206; Ice maker structure of a composite refrigerator characterized in that the configuration. The ice maker structure of claim 1, wherein the container 206 b is installed inside the storage container part 200 and is formed of a detachable structure. 2. The ice maker structure of claim 1, wherein the cover (206a) is installed to be inclined downward toward the storage unit (204).