KR102535914B1 - Auger type ice maker - Google Patents

Abstract

The auger-type ice maker is started.
An auger-type ice maker according to an embodiment of the present invention is an auger-type ice maker in which ice formed by cooling inflow of water flows is separated by the rotation of the auger, transported, and discharged to the outside, wherein the auger-type ice maker has water flow or an ice-making main body in which a space in which ice is transported is formed and the auger is rotatably provided through at least a part of the space, and the ice-making main body is provided so that water or ice does not leak to the outside between the auger and the auger. A sealing member through which the auger comes into contact with at least a portion thereof may be provided, and a reinforcing portion may be formed at a portion of the auger in contact with the sealing member to prevent foreign matter from being generated due to contact with the sealing member.

Description

Auger type ice maker {AUGER TYPE ICE MAKER}

The present invention relates to an auger-type ice maker in which an auger is rotatably provided.

An auger-type ice maker is a device that makes ice. The auger-type ice maker includes a screw-shaped auger rotatably.

The ice formed in the auger-type ice maker is separated from the auger-type ice maker by the rotation of the auger, transported, and discharged to the outside. In this way, the ice discharged from the auger-type ice maker by the rotation of the auger is stored in an ice bin and then supplied to the user.

The auger is rotatably supported by a bearing or the like and is rotatably provided in the auger-type ice maker. In addition, the auger is connected to a rotary driving unit including a driving motor and rotates by the rotary driving unit.

The auger-type ice maker includes an ice-making main body in which an auger is rotatably provided, and a sealing member is provided on the ice-making main body to prevent water or ice from leaking to the outside between the auger and the ice-making main body.

Since the auger of the conventional auger-type ice maker has low hardness, foreign matter is generated when it contacts the sealing member during rotation, and the foreign matter generated in this way is included in the ice and may be supplied to the user, reducing the hygiene of the auger-type ice maker.

The present invention has been made in recognition of at least one of the above-mentioned needs or problems occurring in the prior art.

One aspect of an object of the present invention is to prevent deterioration in sanitation of an auger type ice maker.

Another object of the present invention is to prevent foreign substances from being generated due to contact between a sealing member provided in an auger-type ice maker and an auger so that water or ice does not leak to the outside.

Another aspect of the object of the present invention is to form a reinforcement part with improved hardness and surface roughness in the auger.

An auger-type ice maker related to one embodiment for realizing at least one of the above objects may include the following features.

An auger-type ice maker according to an embodiment of the present invention is an auger-type ice maker in which the introduced water flows while cooling and separates ice formed by the rotation of the auger, transports it, and discharges it to the outside, wherein the auger-type ice maker has water flow or an ice-making main body in which a space in which ice is transported is formed and the auger is rotatably provided through at least a part of the space, and the ice-making main body is provided so that water or ice does not leak to the outside between the auger and the auger. A sealing member through which the auger comes into contact with at least a portion thereof may be provided, and a reinforcing portion may be formed at a portion of the auger in contact with the sealing member to prevent foreign matter from being generated due to contact with the sealing member.

In this case, the reinforcing part may include a high-hardness material.

In addition, the high-hardness material may include at least one of aluminum oxide and titanium oxide.

The reinforcing portion may be formed by coating a portion of the auger in contact with the sealing member by molten spraying the high-hardness material, and then polishing to a predetermined surface roughness or less.

In addition, the predetermined surface roughness may be 1.0 μmRa or less.

In addition, the polishing may include super-finishing polishing and electrolytic polishing.

In addition, the space may include a flow space in which water flows and ice is formed, and a discharge space connected to the flow space and discharging ice to the outside.

In addition, a refrigerant flow space formed around at least a portion of the flow space and in which a refrigerant for cooling water flowing in the flow space flows may be further formed in the ice maker main body.

In addition, in a state in which the auger does not rotate, water flowing in the flow space and cooled by the refrigerant may be discharged to the discharge space to the outside.

The sealing members may be respectively provided on portions of the ice-making main body on a side through which water is introduced and a side through which ice is discharged, and the reinforcing parts may be formed on both sides of the auger corresponding to the sealing member.

In addition, a first flow barrier preventing ice from flowing into the sealing member may be formed at a portion of the auger at a front end of the reinforcing part on a side from which ice is discharged, between the ice maker main body and the auger.

A second flow barrier may be formed at a portion of the ice-making main body between the first flow barrier and the reinforcing part.

As described above, according to the embodiment of the present invention, a reinforcement portion having improved hardness and surface roughness may be formed in the auger.

In addition, according to an embodiment of the present invention, it is possible to prevent foreign matter from being generated due to contact between the sealing member provided in the auger-type ice maker and the auger so that water or ice does not leak to the outside.

In addition, according to an embodiment of the present invention, sanitation of the auger-type ice maker can be prevented from deteriorating.

1 is a longitudinal sectional view of an embodiment of an auger-type ice maker according to the present invention.
2 is a plan sectional view of an embodiment of an auger-type ice maker according to the present invention.
3 is an enlarged view of part A of FIG. 1;
4 and 5 are diagrams showing the operation of an embodiment of the auger-type ice maker according to the present invention, wherein FIG. 4 shows ice making and FIG. 5 shows cold water generating.

In order to facilitate understanding of the features of the present invention as described above, an auger-type ice maker related to an embodiment of the present invention will be described in more detail below.

Hereinafter, the described embodiments will be described based on the most suitable embodiments for understanding the technical characteristics of the present invention, and the technical characteristics of the present invention are not limited by the described embodiments, but the following description It is to illustrate that the present invention can be implemented, such as the embodiments. Therefore, the present invention can be implemented with various modifications within the technical scope of the present invention through the embodiments described below, and these modified embodiments will be said to fall within the technical scope of the present invention. In addition, in the reference numerals described in the accompanying drawings to help understanding of the embodiments described below, among components that perform the same action in each embodiment, related components are indicated by the same or extended numbers.

Hereinafter, an embodiment of an auger type ice maker (IM) according to the present invention will be described with reference to FIGS. 1 to 5 .

1 is a longitudinal cross-sectional view of an auger-type ice maker according to an embodiment of the present invention, FIG. 2 is a planar cross-sectional view of an auger-type ice maker according to an embodiment of the present invention, and FIG. 3 is an enlarged view of part A in FIG. 1 .

4 and 5 are diagrams showing the operation of an embodiment of the auger-type ice maker according to the present invention, wherein FIG. 4 shows ice making and FIG. 5 shows cold water generating.

As shown in FIG. 4, an embodiment of the auger-type ice maker (IM) according to the present invention separates and transports ice (I) formed by cooling while the inflow water flows by the rotation of the auger (AG), and transports it to the outside. can be ejected.

The auger type ice maker IM may include an ice maker main body BD.

Spaces SF and SO in which water flows or ice I is transported may be formed in the ice maker main body BD. Also, the auger AG may be rotatably provided in the ice-making main body BD by penetrating at least a part of the spaces SF and SO.

The configuration of the ice-making main body BD is not particularly limited, and any well-known configuration is possible as long as the aforementioned spaces SF and SO are formed and the auger AG is rotatably provided.

The auger AG may have, for example, a screw shape. Also, the auger AG may be made of stainless steel. However, the material of the auger AG is not particularly limited, and any material can be rotatably provided to the ice-making main body BD by penetrating at least a part of the aforementioned spaces SF and SO of the ice-making main body BD. It can also be made of material.

The aforementioned spaces SF and SO of the ice maker main body BD may include a flow space SF and a discharge space SO, as shown in FIGS. 1 and 2 .

An auger AG may be rotatably provided through the flow space SF. Accordingly, a flow path PW may be formed between the auger AG and the flow space SF.

The flow space SF may be connected to a water supply source (not shown). As shown in FIG. 1 , the ice maker main body BD may have an inlet IW connected to the flow space SF. In addition, the flow space SF may be connected to the water supply source by connecting the inlet IW to the water supply source through a connection pipe (not shown) or the like.

The water supply source connected to the flow space SF is, for example, provided in the water purifier (not shown) if the auger type ice maker IM is provided in the water purifier and includes a water filter (not shown) to filter water. (not shown) or a storage tank (not shown) connected to the filtration unit to store water filtered by the filtration unit. In addition, the water supply source may be a cold water tank (not shown) in which water cooled in the auger type ice maker IM, that is, cold water is stored. However, the water supply source to which the flow space SF is connected is not particularly limited, and any known water supply source can be used as long as it can supply water to the flow space SF.

The water supplied from the water supply source to the flow space SF of the auger type ice maker IM through the inlet IW passes through the flow path PW between the flow space SF and the auger AG, as shown in FIG. can flow along

Meanwhile, a refrigerant flow space SR may be formed in the ice maker main body BD. The refrigerant flow space SR may be formed in at least a portion around the flow space SF. A refrigerant, for example, a refrigerant having a freezing point or less may flow in the refrigerant flow space SR. And, by the refrigerant flowing in the refrigerant flow space (SR), the water flowing in the flow space (SF), that is, as shown in FIG. 4, the flow path (PW) between the flow space (SF) and the auger (AG) Water flowing along can be cooled. Also, ice I may be formed in the flow space SF.

In this state, when the auger AG rotates, the ice I formed in the flow space SF is separated by the auger AG and is separated between the flow space SF and the auger AG as shown in FIG. It can be transported along the flow path (PW) of.

The discharge space SO may be connected to the outside and the flow space SF. And, by the rotation of the auger AG, the ice I transported along the flow path PW between the flow space SF and the auger AG passes through the discharge space SO as shown in FIG. can be discharged to the outside. In this way, the ice I discharged to the outside through the discharge space SO may be stored in an ice bin (not shown).

On the other hand, as shown in FIG. 5, although the water flowing in the flow path PW between the flow space SF and the auger AG is cooled by the refrigerant flowing in the refrigerant flow space SR, the flow space Ice (I) may not be formed in (SF). In this state, the auger AG may not rotate. Then, the water cooled by the refrigerant flowing in the refrigerant flow space (SR) while flowing in the flow path (PW) between the flow space (SF) and the auger (AG), that is, cold water is discharged to the outside through the discharge space (SO). After being discharged, it can be stored in a cold water tank.

As described above, water stored in the cold water tank may flow into the flow space SF through the inlet IW. Accordingly, after the water in the cold water tank is cooled in the auger type ice maker (IM) to become cold water, it can be returned to the cold water tank and stored as cold water. The water stored in the cold water tank may become cold water while circulating through the cold water tank and the auger type ice maker (IM). In addition, cold water stored in the cold water tank may be supplied to the auger-type ice maker IM to make ice I faster in the auger-type ice maker IM.

The auger AG is connected to the rotary drive unit DR provided in the auger-type ice maker IM and can be rotated by the rotation drive of the rotation drive unit DR.

The rotation drive unit DR may include, for example, a chain CH and a driving motor MD. As shown in FIG. 2 , the chain CH may be connected to the first sprocket SP1 provided in the auger AG. In addition, the drive motor MD may be provided with a second sprocket SP2 and connected to the chain CH. Accordingly, when the drive motor MD is driven, the chain CH makes an endless orbital motion between the first sprocket SP1 and the second sprocket SP2, so that the auger AG can rotate.

However, the rotary drive unit DR is not particularly limited, and if it is connected to the auger AG and can rotate the auger AG, the drive motor MD, the auger AG and the drive motor MD, respectively Any well-known ones may be used, such as including gears (not shown) that are connected and meshed with each other.

The auger AG may be rotationally supported by the bearings BT and BR provided in the ice-making main body BD.

Force may act on the auger AG in a radial direction due to the weight of the auger AG. In this way, both sides of the auger AG are mounted on radial bearings BR as shown in FIGS. 1 and 2 so that the auger AG can rotate against the radial force acting on the auger AG. It can be supported by rotation.

In addition, an axial force may act on the auger AG in a direction opposite to the transport direction of the ice I due to the transport of the ice I in the flow space SF. A portion of the auger AG on the opposite side of the transporting direction of the ice I may be rotationally supported by the thrust bearing BT so that the auger AG can rotate against this axial force.

As a result, as shown in FIGS. 1 and 2, the part of the auger AG on the opposite side of the conveying direction of the ice I is rotationally supported by the thrust bearing BT and the radial bearing BR, and the ice ( I) The part of the auger (AG) on the conveying direction side can be rotationally supported by the radial bearing (BR).

However, the configuration for rotationally supporting the auger AG is not particularly limited, and any known configuration can be used as long as the configuration can rotationally support the auger AG.

Meanwhile, the auger-type ice maker IM may include a drain hole DW connected to the flow space SF. An opening/closing valve (not shown) may be provided in the drain hole DW. The opening/closing valve of the drain port (DW) is normally closed, but is opened when it is necessary to drain the water in the flow space (SF) to the outside, so that the water in the flow space (SF) passes through the drain port (DW) to the outside. It can be drained with

As shown in FIGS. 1 and 2 , the ice-making main body BD may include a sealing member SM. The sealing member SM may be provided in the ice making main body BD so that the auger AG penetrates at least partially. Accordingly, even when the auger AG rotates, water or ice I may not leak outside between the ice making main body BD and the auger AG.

The sealing member SM may be respectively provided on a portion of the ice making main body BD on a side through which water is introduced and a side through which ice I is discharged. However, the portion of the ice-making main body BD provided with the sealing member SM is not particularly limited, and any portion can be used as long as it is a portion that prevents water or ice I from leaking to the outside between the auger AG. may be provided.

The sealing member SM may be made of fluororesin or polyethylene called 'Teflon'. However, the material of the sealing member SM is not particularly limited, and may be made of any material as long as it can be provided in the ice making main body BD so that the auger AG penetrates at least partially.

A reinforcement part HS may be formed in the auger AG. The reinforcing part HS has improved hardness and surface roughness, and thus foreign matter may not be generated even when the reinforcing part HS contacts the sealing member SM. Therefore, the hygiene of the auger-type ice maker IM can be prevented from deteriorating.

The reinforcing part HS may be formed in a portion of the auger AG that the sealing member SM contacts. For example, as described above and shown in FIGS. 1 and 2, if the sealing member SM is provided at the portion of the ice making main body BD on the water inlet side and the ice I discharged side, respectively, the reinforcing portion ( HS) may be formed on both sides of the auger AG corresponding to the sealing member SM.

However, the portion of the auger AG where the reinforcing portion HS is formed is not particularly limited, and may be formed at any portion of the auger AG as long as it is a portion of the auger AG that the sealing member SM contacts.

The reinforcing part HS may include a high-hardness material. As a result, the hardness of the reinforcing portion HS may be improved. The high-hardness material may include, for example, at least one of aluminum oxide and titanium oxide. However, the high-hardness material is not particularly limited, and any well-known material can be used as long as the hardness can be improved.

The reinforcing portion HS may be formed by melting and spraying a high-hardness material on a portion of the auger AG that contacts the sealing member SM, and then polishing the portion to have a predetermined surface roughness or less.

The predetermined surface roughness may be 1.0 μmRa or less. If the predetermined surface roughness exceeds 1.0 μm Ra, even if the hardness of the reinforcing part HS is improved by including a high-hardness material, the reinforcing part HS contacts the sealing member SM during rotation of the auger AG. If it does, the reinforcing part HS or the sealing member SM may be cut and foreign substances may be generated. Therefore, it is preferable that the reinforcement part HS has a surface roughness of 1.0 μmRa or less.

A polishing method used when forming the reinforcing portion HS may include super finishing polishing and electrolytic polishing. For example, a high-hardness material may be melt-sprayed and coated on a portion of the auger AG that contacts the sealing member SM, followed by super-finishing polishing and electrolytic polishing. As described above, by using the two polishing methods of super-finishing polishing and electrolytic polishing, it is possible to easily form the reinforcing portion HS having a surface roughness of 1.0 μm Ra or less.

However, the polishing method used in forming the reinforcing portion HS is not particularly limited, and any known polishing method may be used as long as the polishing method allows the surface roughness of the reinforcing portion HS to be 1.0 μm Ra or less.

A first flow barrier LG1 may be formed at a portion of the auger AG at the front end of the reinforcing part HS on the side where the ice I is discharged. In addition, a second flow barrier LG2 may be formed at a portion of the ice-making main body BD between the first flow barrier LG1 and the reinforcing part HS.

It is possible to prevent the ice I from flowing between the ice-making main body BD and the sealing member SM by the first flow prevention bump LG1 and the second flow prevention bump LG2. As a result, the sealing member SM may not be cut or damaged by the ice I, so foreign substances may not be generated even by this.

As described above, when the auger-type ice maker according to the present invention is used, a reinforcing part with improved hardness and surface roughness can be formed in the auger, and a sealing member provided in the auger-type ice maker to prevent water or ice from leaking to the outside; It is possible to prevent foreign matter from being generated due to the contact of the auger, and to prevent deterioration in hygiene of the auger-type ice maker.

The above-described auger-type ice maker is not limited to the configuration of the above-described embodiment, but the above embodiments may be configured by selectively combining all or part of each embodiment so that various modifications can be made. .

IM : Auger type ice maker I : Ice
AG: Auger BD: Ice-making main body
SM: sealing member SF: flow space
PW: flow furnace SO: discharge space
SR: refrigerant flow space HS: reinforcement part
LG1: 1st flow barrier LG2: 2nd flow barrier
DR: rotation drive part SP1: 1st sprocket
SP2 : 2nd sprocket CH : Chain
MD: drive motor BR: radial bearing
BT: Thrust bearing IW: Inlet
DW: Drain hole

Claims (12)

In the auger-type ice maker in which the ice formed by cooling the flowing water is separated by the rotation of the auger, transported, and discharged to the outside,
The auger-type ice maker includes an ice-making main body in which a space in which water flows or ice is transported is formed and the auger is provided to rotatably penetrate at least a part of the space,
The ice-making main body is provided with a sealing member through which the auger comes into contact with at least a part so that water or ice does not leak to the outside between the ice-making body and the auger.
A reinforcing portion is formed in the portion of the auger that is in contact with the sealing member to prevent foreign substances from being generated by contact with the sealing member,
The sealing member is provided on a portion of the ice-making main body on a side through which water flows in and through which ice is discharged, respectively;
The reinforcement part is formed on each side of the auger corresponding to the sealing member,
A first flow barrier is formed at a portion of the auger at a front end of the reinforcing portion on a side from which ice is discharged to prevent ice from flowing to the sealing member between the ice-making main body and the auger;
A second flow prevention bump is formed in a portion of the ice maker main body between the first flow prevention bump and the reinforcing part. The auger type ice maker according to claim 1, wherein the reinforcing part includes a high-hardness material. The auger-type ice maker according to claim 2, wherein the high-hardness material includes at least one of aluminum oxide and titanium oxide. The auger type ice maker according to claim 2, wherein the reinforcing part is formed by coating a portion of the auger in contact with the sealing member by melting and spraying the high-hardness material, and then polishing the portion to have a surface roughness of a predetermined level or less. The auger-type ice maker according to claim 4, wherein the predetermined surface roughness is 1.0 μmRa or less. The auger type ice maker according to claim 4, wherein the polishing includes super finishing polishing and electrolytic polishing. The auger type ice maker according to claim 1, wherein the space includes a flow space in which water flows and ice is formed, and a discharge space connected to the flow space and discharging ice to the outside. The auger type ice maker according to claim 7, wherein the ice maker main body further includes a refrigerant flow space formed around at least a portion of the flow space and in which a refrigerant for cooling water flowing in the flow space flows. The auger type ice maker according to claim 8, wherein water flowing in the flow space and cooled by a refrigerant is discharged to the discharge space in a state in which the auger is not rotating. delete delete delete

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