KR102354833B1 - Transparent ice making device - Google Patents

Abstract

The present invention relates to a transparent ice-making apparatus, wherein the ice-making water is stirred through a stirring module while the ice-making water is cooled through a cooling finger. In the process of cooling the ice-making water, the gas contained therein is discharged to the outside and impurities are absorbed into the ice. Since it does not contain ice, transparent ice can be created. In particular, it is easy to manufacture and maintain through the simple structure of the stirring module, and by stirring each ice-making water in the space between the plurality of cooling fingers, each cooling finger Provided is a transparent ice-making apparatus capable of generating ice having uniform transparency as a whole as well as improving the agitation performance of the surrounding area, and thus the transparency of the ice.

Description

TRANSPARENT ICE MAKING DEVICE

The present invention relates to a transparent ice-making apparatus. More specifically, by stirring the ice-making water through the stirring module while the ice-making water is cooled through the cooling fingers, the gas contained inside is discharged to the outside while the ice-making water is cooled, and the ice is in a transparent state because impurities are not contained in the ice In particular, it is easy to manufacture and maintain through a stirring module with a simple structure, and by stirring each ice-making water in the space between a plurality of cooling fingers, agitation performance for the surrounding area of each cooling finger The present invention relates to a transparent ice-making apparatus capable of producing ice having a uniform transparency as a whole as well as improving the transparency of the ice.

Recently, environmental pollution is getting worse due to rapid industrial development. Among them, water pollution has reached a serious level, and most places such as homes and government offices treat water as purified water and drink it as drinking water.

As such, a water purifier that supplies drinking water by treating water is widely used in a water purifier that treats raw water supplied through a water pipe, etc. and supplies it as cold water or hot water. Ice water purifiers that can be supplied are also rapidly spreading.

The ice purifier includes an ice maker capable of generating ice in an internal space. The ice maker includes a cooling module in which a refrigerant circulates along a refrigeration cycle, and an ice tank that generates and stores ice through heat exchange with an evaporator of the cooling module. is composed by The ice stored in the ice tank is discharged through a separate ice outlet and supplied to the user.

Looking more closely at the configuration for generating ice inside the ice tank, an ice making tank and cooling fingers are provided inside the ice tank. The ice-making water tank supplies ice-making water to the inner space, and the cooling fingers operate to cool the ice-making water through refrigerant circulation, and are disposed to be partially immersed in the ice-making water supplied to the ice-making water tank to cool the ice-making water. After a certain period of time elapses while the ice-making water is supplied to the ice-making water tank, the ice-making water is cooled by the cooling fingers to generate ice around the cooling fingers. Thereafter, the ice making tank rotates to discharge the generated ice to the ice storage unit inside the ice tank, and the discharged ice is stored in the ice storage unit. After the ice is discharged from the ice making tank, ice making water is supplied to the ice making tank again, and ice is repeatedly generated by the cooling fingers.

In such an ice making device, ice is generated by cooling by cooling fingers in a stable state in which a certain amount of ice-making water is supplied and stored in the ice-making water tank. (cloudy state) to form ice.

As described above, the ice maker according to the prior art generates opaque ice. For reasons such as opaque ice does not satisfy visual aesthetics, research and development for generating transparent ice with high transparency has recently been conducted. In order to generate transparent ice, a method of circulating the ice making water is used as a method of removing impurities from the ice making water, but satisfactory research results have not been achieved yet.

Domestic Registered Patent No. 10-1324167

The present invention was invented to solve the problems of the prior art, and an object of the present invention is to stir the ice-making water through a stirring module while cooling the ice-making water through a cooling finger, so that the To provide a transparent ice-making apparatus capable of generating transparent ice because gas is discharged to the outside and impurities are not contained in the ice, and in particular, it is easy to manufacture and maintain through a simple structure of a stirring module.

Another object of the present invention is to agitate each ice-making water in the space between the plurality of cooling fingers, thereby improving the stirring performance of the surrounding area of each cooling finger, thereby improving the transparency of the ice as well as providing uniform transparency as a whole. An object of the present invention is to provide a transparent ice-making apparatus capable of producing ice with

Another object of the present invention is to provide a transparent ice-making apparatus capable of improving the stirring performance of ice-making water and producing more transparent ice by forming a stirring module to stir the ice-making water locally and at the same time as a whole. will provide

Another object of the present invention is to apply a structure capable of improving the stirring performance during the stirring process of the ice-making water and at the same time to prevent the external discharge of the ice-making water, so that the operating state can be stably maintained during the stirring process. To provide an ice-making device.

The present invention provides an ice-making water tank in which an ice-making chamber is formed so that ice-making water is supplied and stored in an internal space; a cooling finger having at least a partial region inserted into the ice-making chamber to cool the ice-making water to generate ice; and a stirring module that moves in the ice-making chamber and stirs the ice-making water while the ice-making water is cooled by the cooling fingers.

In this case, a plurality of the cooling fingers may be provided, and the stirring module may be configured to move in a space between the cooling fingers to stir the ice-making water.

In addition, the stirring module may include: a rotation shaft rotatably disposed on one end of the ice-making water tank; a stirring finger coupled to the rotating shaft so as to be submerged in the ice-making water and rotating integrally with the rotating shaft to stir the ice-making water; And it may include a stirring driving unit for rotationally driving the rotation shaft.

In addition, the ice-making water tank is rotatably disposed about a separate rotation shaft formed on the upper portion of the other end of the ice-making tank, and the rotation shaft of the stirring module is disposed in a direction parallel to the rotation axis of the ice-making tank, and the stirring finger may be elongated in a direction orthogonal to the rotation shaft.

In addition, a plurality of the stirring fingers may be formed to be disposed in the space between the cooling fingers.

In addition, the rotating shaft may be rotationally driven by the stirring driving unit so that the stirring finger reciprocally rotates from the first position to the second position.

Also, the first position may be formed in an upper space of the water surface of the ice-making water stored in the ice-making chamber, and the second position may be formed in an inner space of the ice-making water.

In addition, an extended support portion extending toward the other end and a lower end of the ice-making tub is formed on the outer surface of the rotation shaft, and the stirring finger has one end connected to the end of the extended support portion and is attached to the rotation shaft through the extended support portion. can be combined.

In addition, a stirring protrusion protruding in the width direction of the stirring finger may be formed in the middle portion of the stirring finger.

In addition, a stirring wing portion protruding downward from the stirring finger may be formed at one end portion of the stirring finger.

In addition, an inclined surface may be formed at the other end of the stirring finger in a form in which the cross-sectional area becomes smaller toward the upper end.

According to the present invention, by stirring the ice-making water through the stirring module while the ice-making water is cooled through the cooling fingers, the gas contained inside is discharged to the outside while the ice-making water is cooled, and impurities are not contained in the ice, so that the transparent state is maintained. Ice can be produced, and in particular, through a stirring module having a simple structure, it is easy to manufacture as well as convenient to maintain.

In addition, by agitating the ice-making water in the space between the plurality of cooling fingers, the stirring performance of the surrounding area of each cooling finger is improved, thereby not only improving the transparency of the ice, but also creating ice having a uniform transparency as a whole There is an effect that can be done.

In addition, by forming a stirring module to stir the ice-making water locally and at the same time as a whole, the stirring performance for the ice-making water can be improved and more transparent ice can be produced.

In addition, by applying a structure capable of improving the stirring performance during the stirring process of the ice-making water and preventing the external discharge of the ice-making water at the same time, there is an effect that the operating state can be stably maintained during the stirring process.

1 is a perspective view schematically illustrating a configuration of a transparent ice-making apparatus according to an embodiment of the present invention;
2 is an exploded perspective view schematically illustrating a detailed configuration of a transparent ice-making apparatus according to an embodiment of the present invention;
3 is a perspective view schematically illustrating the configuration of a stirring module of a transparent ice-making apparatus according to an embodiment of the present invention;
4 is a cutaway perspective view schematically illustrating an internal arrangement structure of a transparent ice-making apparatus according to an embodiment of the present invention;
5 and 6 are diagrams schematically illustrating an operating state of a transparent ice-making apparatus according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

1 is a perspective view schematically illustrating a configuration of a transparent ice-making apparatus according to an embodiment of the present invention.

A transparent ice-icing apparatus according to an embodiment of the present invention is an apparatus for generating transparent ice by stirring ice-making water in the process of cooling the ice-making water. An ice-making water tank 100, a cooling finger 200, and a stirring module ( 300) is included.

The ice-making water tank 100 is a container with an open top, and an ice-making chamber 101 is formed so that ice-making water is supplied and stored in an internal space. A separate ice-making water supply unit 400 is disposed above the ice-making tank 100 , and a predetermined amount of ice-making water is supplied to the ice-making chamber 101 of the ice-making water tank 100 through the ice-making water supply unit 400 .

The cooling fingers 200 are disposed so that at least a partial region is inserted into the ice-making chamber 101 to cool the ice-making water to generate ice. The cooling finger 200 constitutes the evaporator of the refrigerating cycle, and is formed in a shape to protrude downward from the refrigerant circulation line 210 through which the refrigerant circulates. Through the refrigerant circulation of the refrigerating cycle, heat exchange occurs with the ice making water around the cooling fingers 200 , and the ice making water is cooled through this heat exchange to generate ice in the area around the cooling fingers 200 . At this time, a plurality of cooling fingers 200 are provided, and ice is generated in the vicinity of each cooling finger 200 . That is, a plurality of ice is simultaneously generated through the plurality of cooling fingers 200 .

The stirring module 300 is configured to agitate the ice-making water while moving in the ice-making chamber 101 while the ice-making water is cooled by the cooling fingers 200 . At this time, the stirring module 300 is configured to agitate the ice-making water while moving in the space between the plurality of cooling fingers 200 .

According to this configuration, the ice-making water stored in the ice-making chamber 101 of the ice-making water tank 100 is stirred by the stirring module 300 while it is cooled by the cooling finger 200, so that the ice-making water contained therein during the cooling process The gas is discharged to the outside. Accordingly, ice produced by cooling the ice-making water does not contain gas, and thus ice in a transparent state is generated. In addition, in the process of cooling the ice-making water from the area around the cooling finger 200 , impurities move without staying in the area around the cooling finger 200 by stirring the ice-making water, so that the ice generated by the cooling of the ice water contains impurities. This does not result in ice formation in a transparent state.

As described above, when the generation of ice in the ice making tank 100 is completed, the ice generated from the ice making tank 100 is discharged to the outside and stored in an ice storage unit inside a separate ice tank (not shown). The ice-making tub 100 is rotatably disposed about a separate rotation shaft 110 formed on one end of the ice-making tub 100 , and as the ice-making tub 100 rotates about the rotation shaft 110 , the ice-making chamber The ice generated at 101 falls downward from the ice making tank 100 and is discharged (see FIG. 5 ). At this time, a separate water tank rotation driving unit 120 is coupled to the rotating shaft 110 to rotate the rotating shaft 110 , and the ice-making water tank 100 is rotated by the rotational driving of the rotating shaft 110 to discharge ice to the outside.

Although not shown, the operation of the water tank rotation driving unit 120 and the ice making water supply unit 400 may be controlled by a separate control unit (not shown), and the water tank rotation driving unit 120 and the ice making water supply unit 400 may be operated at regular intervals. operation can be controlled to operate.

For example, after the ice-making water supply unit 400 operates to supply and store a certain amount of ice-making water in the ice-making tank 100 , after a preset time elapses (after the time when ice is generated by the cooling finger 200 ) ), the water tank rotation driving unit 120 operates to rotate the ice making tank 100 , thereby controlling the ice to be discharged from the ice making tank 100 to the outside. Thereafter, the ice making tank 100 is returned to a horizontal state by the water tank rotation driving unit 120 , and a certain amount of ice making water is again supplied and stored in the ice making water tank 100 by the ice making water supply unit 400 , and this process continues. It can be controlled to be repeated.

Next, a detailed configuration of the transparent ice-making apparatus according to an embodiment of the present invention will be described in more detail.

2 is an exploded perspective view schematically illustrating a detailed configuration of a transparent ice-making apparatus according to an embodiment of the present invention, and FIG. 3 is a schematic configuration of a stirring module of the transparent ice-making apparatus according to an embodiment of the present invention. 4 is a cutaway perspective view schematically illustrating an internal arrangement structure of a transparent ice-making apparatus according to an embodiment of the present invention, and FIGS. 5 and 6 are transparent ice according to an embodiment of the present invention. It is a diagram schematically showing the operating state of the ice making apparatus.

First, the stirring module 300 according to an embodiment of the present invention includes a rotation shaft 310 rotatably disposed on one end of the ice-making water tank 100 and a rotation shaft 310 to be submerged in ice-making water. It may be configured to include a stirring finger 320 coupled to the rotating shaft 310 and rotating integrally with the rotating shaft 310 to stir the ice-making water, and a stirring driving unit 330 for rotatingly driving the rotating shaft 310 .

The rotating shaft 310 is disposed on the upper portion of one end of the ice-making tub 100 on the opposite side where the rotating shaft 110 is formed, and is disposed in a direction parallel to the rotating shaft 110 of the ice-making tub 100 . The stirring driving unit 330 is coupled to one end of the rotation shaft 310 . The stirring driving unit 330 may be applied to an electric motor rotating by receiving power, and is connected to the rotating shaft 310 through a separate connecting shaft 331 to rotate the rotating shaft 310 .

Agitating fingers 320 are arranged long in a direction orthogonal to the rotation shaft 310, and as shown in FIGS. 2 and 3, a plurality of agitating fingers are arranged in parallel to each other, and each of the agitating fingers 320 is a plurality of cooling fingers 200 ) is arranged to be placed in the space between the

For example, the plurality of cooling fingers 200 may be arranged in two rows by three parallel to the direction of the rotation shaft 110 and the rotation shaft 310 , and the stirring finger 320 is the rotation shaft 110 and the rotation shaft 310 . ) may be arranged to cross the space between the two rows of cooling fingers 200 in a direction orthogonal to the direction. As shown in FIGS. 2 and 3, when the cooling fingers 200 are arranged in two rows of three, two stirring fingers 320 may be arranged in a direction crossing the space between the cooling fingers 200, Two stirring fingers 320 may be additionally disposed in a direction that crosses the space between the inner wall of the ice-making water tub 100 and the cooling fingers 200 located at the outermost sides along the direction of the rotation shaft 110 .

Accordingly, by disposing the stirring fingers 320 on both sides around each cooling finger 200, the ice making water 10 is stirred in the vicinity of each cooling finger 200, each cooling finger 200 Each ice 20 generated at the center is uniformly formed in a transparent state.

At this time, the stirring finger 320 rotates together with the rotating shaft 310 and stirs the ice-making water 10 , and the rotating shaft 310 reciprocally rotates the stirring finger 320 from the first position to the second position. It is rotationally driven by the stirring driving unit 330 to do so. The first position is formed in the upper surface space of the ice-making water 10 stored in the ice-making chamber 101 , and the second position is formed in the inner space of the ice-making water 10 . More specifically, the stirring finger 320 is horizontally disposed on the upper surface of the water surface of the ice-making water 10 at the first position as shown in FIG. 5, and at the second position as shown in FIG. 10) and may be disposed in an inclined state.

As described above, the stirring finger 320 reciprocates between the first position and the second position and operates in such a way that it is submerged in or out of the ice-making water 10, so that the stirring effect of the stirring finger 320 as it passes through the water surface is increased, and thus the stirring performance is improved as compared to that the stirring finger 320 moves only inside the ice-making water 10 .

On the other hand, since the ice 20 is generated centering on the cooling fingers 200 , it is advantageous to increase the transparency of the ice 20 to stir the ice making water in a wider area with respect to the area around each cooling finger 200 . .

To this end, the stirring finger 320 according to an embodiment of the present invention is not only disposed in the space between the cooling fingers 200 as described above, but also a stirring finger 320 in the middle of each stirring finger 320 . A stirring protrusion 321 protruding in the width direction (axial direction of the rotation shaft 110) may be formed. Since the stirring area for the peripheral portion of each cooling finger 200 is expanded through the stirring protrusion 321, the stirring performance is further improved, and thus the transparency of the ice is increased. The stirring protrusion 321 may be formed in a shape in which the protrusion width becomes smaller toward the protruding end, thereby avoiding interference with the ice 20 in the process of generating the ice 20 in the cooling finger 200 . In addition, it is possible to prevent a delay in ice formation caused by excessive stirring in the vicinity of the cooling finger 200 .

In addition, in order to increase the stirring effect for the ice-making water 10 , a stirring blade 322 protruding downward from the stirring finger 320 may be formed at one end portion of the stirring finger 320 . The stirring blade 322 may rotate and move together with the stirring finger 320 in the form of a simple flat plate to further stir the ice-making water 10 . Since the stirring blade 322 rotates at the end of the stirring finger 320 and pushes the ice-making water 10 toward the wall of one side of the ice-making water tank 100, the stirring effect by the stirring blade 322 is ice-making. It is exerted in such a way as to induce mixing and flow of the ice-making water 10 for the entire space of the chamber 101 .

Accordingly, the stirring function for the area around each cooling finger 200 is exhibited through the stirring finger 320 and the stirring protrusion 321, and the stirring function for the entire space of the ice-making chamber 101 through the stirring blade 322 In this way, better stirring performance can be exhibited through the two stirring functions in different ranges.

In addition, an inclined surface 323 may be formed at the other end portion of the stirring finger 320 in a form in which the cross-sectional area becomes smaller toward the upper end. As described above, by forming the inclined surface 323 at the end of the stirring finger 320, the frictional resistance to flow with the ice-making water 10 can be reduced when the stirring finger 320 is rotated and the stirring finger 320 is In the process of moving the ice-making water 10 over the water surface, it is possible to minimize a phenomenon such as splashing of the ice-making water 10 from the end of the stirring finger 320 to the surroundings, thereby maintaining a more stable operating state.

On the other hand, on the outer surface of the rotating shaft 310, the other end of the ice-making water tank 100 (the end in the opposite direction from the position of the rotating shaft 310) and an extension support 311 extending toward the lower end are formed, and a stirring finger One end of the 320 may be connected to the end of the extended support 311 and coupled to the rotation shaft 310 through the extended support 311 .

Through the extended support 311, the stirring finger 320 can be stably positioned on the upper surface of the ice-making water 10 in a horizontal state, and interference with the ice-making water tank 100 can be avoided during operation, and agitation The expansion of the ice making tank 100 according to the arrangement of the fingers 320 may be minimized.

The rotating shaft 310, the extended support part 311, and the stirring finger 320 may be manufactured and combined as separate products, respectively, but may be integrally manufactured in a form integrally molded through a single mold.

In the process of rotation of the rotating shaft 310 and the stirring finger 320, the stirring finger 320 generates a flow resistance with the ice-making water 10, and the resulting torque is transmitted to the extended support 311, so the extended support ( As shown in FIG. 3 , a concave step portion 312 in the form of a concave depression in the upper surface may be formed in the upper surface to reinforce the strength of the extended support portion 311 as shown in FIG. 3 , and the end of the extended support portion 311 protrudes downward A reinforcing rib 314 in the form of a flat plate may be formed. The strength of the extended support part 311 is reinforced through the concave step 312 and the reinforcing rib 314 , and accordingly, the stirring function according to the rotational movement of the stirring finger 320 can be made more stably. On the other hand, inside the concave step portion 312 region, a separate water discharge hole 313 is provided to prevent the ice making water 10 from accumulating in the concave step portion 312 while the stirring finger 320 rotates. can be formed.

Meanwhile, on the bottom surface of the ice making tank 100 , an ice guide groove in a downward convex shape corresponding to the position of the cooling finger 200 to guide the shape of the ice 20 formed around the cooling finger 200 . A plurality of 130 is formed. Among the plurality of ice guide grooves 130 , the stirring expansion groove 140 is formed in a concave shape on the sidewall of the adjacent ice guide groove 130 so that the stirring finger 320 can be inserted and disposed during the rotational movement. .

That is, as shown in FIGS. 4 and 6 , the ice guide groove 130 of the ice-making water tank 100 is inserted so that the tip of the stirring finger 320 is inserted and disposed while the stirring finger 320 is rotated to the second position. Stirring expansion groove 140 is formed in the side wall. As the stirring expansion groove 140 is formed in this way, the rotation angle of the stirring finger 320 is further increased to improve the stirring performance as well as the inside of the ice guide groove 130 during the rotational movement of the stirring finger 320 . of the ice-making water 10 can be diffused into the surrounding space through the stirring expansion groove 140, so that the stirring area is further expanded and the stirring performance is improved.

In addition, the expansion accommodating part 160 may be formed on the side wall of the ice making water tank 100 so that the rotational movement space of the stirring blade 322 is expanded while the stirring finger 320 is rotated to the second position. The rotational angle of the stirring finger 320 is increased by the expansion receiving part 160 as well as the flow area of the ice-making water 10 by the stirring blade 322, so that the stirring performance can also be improved.

In addition, at the upper end of one end of the ice-making water tank 100 , a side extension 150 extending outward to cover the lower region of the rotation shaft 310 and the extension support 311 of the stirring module 300 is formed. Through this, water droplets (ice water) falling from the rotation shaft 310 and the extension support 311 are received and introduced into the ice-making chamber 101 again, thereby preventing the water droplets from scattering or falling to the outside. and can maintain a more stable operating structure.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100: ice making tank
101: ice-making chamber
110: rotation shaft
120: water tank rotation driving unit
130: ice guide groove
140: stirring expansion groove
150: side extension
160: expansion receiving unit
200: cooling finger
300: stirring module
310: rotation shaft
311: extension support
320: stirring finger
321: stirring protrusion
322: stirring blades
323: slope
330: stirring driving unit

Claims (11)

an ice-making water tank in which an ice-making chamber is formed so that ice-making water is supplied and stored in the internal space;
a cooling finger having at least a partial region inserted into the ice-making chamber to cool the ice-making water to generate ice; and
A stirring module that moves in the ice-making chamber and stirs the ice-making water while the ice-making water is cooled by the cooling finger
Including, the stirring module is
a rotation shaft rotatably disposed on one end of the ice-making tank; and
A stirring finger coupled to the rotating shaft so as to be submerged in the ice-making water and rotating integrally with the rotating shaft to stir the ice-making water
and a stirring protrusion protruding in the width direction of the stirring finger at a middle portion of the stirring finger.
The method of claim 1,
The cooling finger is provided in plurality,
and the stirring module is configured to agitate the ice-making water while moving in the space between the cooling fingers.
3. The method of claim 2,
The stirring module is
Agitation driving unit for rotationally driving the rotating shaft
The transparent ice ice making device further comprising a.
4. The method of claim 3,
The ice making tank is rotatably disposed about a separate rotation shaft formed on the upper part of the other end of the ice making tank,
The transparent ice making apparatus according to claim 1, wherein the rotating shaft of the stirring module is arranged in a direction parallel to the rotation axis of the ice-making water tank, and the stirring finger is long in a direction perpendicular to the rotating shaft.
5. The method of claim 4,
and a plurality of the stirring fingers are formed to be disposed in a space between the cooling fingers.
6. The method of claim 5,
and the rotating shaft is rotationally driven by the stirring driving unit so that the stirring finger reciprocally rotates from the first position to the second position.
7. The method of claim 6,
and the first position is formed in an upper space of the water surface of the ice-making water stored in the ice-making chamber, and the second position is formed in an inner space of the ice-making water.
6. The method of claim 5,
An extended support portion extending toward the other end and the lower end of the ice-making water tank is formed on the outer surface of the rotating shaft,
and one end of the stirring finger is connected to an end of the extended support part and coupled to the rotation shaft through the extended support part.
delete an ice-making water tank in which an ice-making chamber is formed so that ice-making water is supplied and stored in the internal space;
a cooling finger having at least a partial region inserted into the ice-making chamber to cool the ice-making water to generate ice; and
A stirring module that moves in the ice-making chamber and stirs the ice-making water while the ice-making water is cooled by the cooling finger
Including, the stirring module is
a rotation shaft rotatably disposed on one end of the ice-making tank; and
A stirring finger coupled to the rotating shaft so as to be submerged in the ice-making water and rotating integrally with the rotating shaft to stir the ice-making water
and a stirring blade protruding downward from the stirring finger at one end of the stirring finger.
11. The method of claim 10,
The transparent ice-making apparatus according to claim 1, wherein an inclined surface is formed at the other end of the stirring finger in a shape in which the cross-sectional area becomes smaller toward the top.

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