KR20180134630A - Apparatus for detecting separation of auger of auger type ice maker - Google Patents

Abstract

Disclosed is an apparatus for detecting separation of an auger of an auger type ice maker. According to an embodiment of the present invention, the apparatus for detecting separation of an auger of an auger type ice maker is rotationally provided in an auger type ice maker, separates and transfers ice formed in the auger type ice maker from the auger type ice maker to be discharged to the outside, and detects whether an auger is separated from a normal rotation position. The apparatus for detecting separation of an auger comprises at least one of an axial direction separation detection unit detecting whether an auger is separated in an axial direction and a radial direction separation detection unit detecting whether the auger is separated in a radial direction.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an auger-

The present invention relates to an auger detachment detection device for an auger type ice maker that detects whether an auger provided rotatably in an auger type ice maker has deviated from a normal rotation position.

The auger type ice maker is an ice maker. The auger type ice maker is provided with a screw-shaped auger rotatably.

By the rotation of the auger in the auger type ice maker, the ice formed in the auger type ice maker is separated from the auger type ice maker, transferred and discharged to the outside. The ice discharged from the auger type ice maker by an auger is stored in an ice reservoir and supplied to the user.

The auger is rotatably supported by an auger type ice maker and is rotatably supported by a bearing or the like.

The auger is subjected to force during rotation by its own weight or by the ice or rotating drive part transported from the auger type ice maker. When the above-mentioned force acting on the auger is excessive, the auger is deformed or the bearing or the like rotating and supporting the auger is broken and the auger is detached from the normal rotation position. When the auger moves away from the normal rotation position due to deformation or breakage, the auger comes into contact with other components of the auger type ice maker during rotation (for example, the inner face of the ice maker main body of the auger type ice maker rotatably provided) , And foreign matter is generated by cutting other components of the screw-shaped auger. Such foreign matter can be supplied to the user by being contained in ice or the like formed in the auger type ice maker, so that the sanitary property of the auger type ice maker is deteriorated.

The present invention is realized by recognizing at least any one of the above-mentioned conventional needs or problems.

One aspect of the object of the present invention is to improve the sanitary property of the auger type ice maker.

Another aspect of the present invention is to prevent an auger that is rotatably provided in an auger type ice maker from contacting with other components of an auger type ice maker during rotation so that unnecessary foreign matter is not generated due to auger.

Another aspect of the object of the present invention is to detect whether the auger is displaced from the normal rotation position due to deformation, breakage or the like.

An auger separation sensing apparatus of an auger type ice maker according to an embodiment for realizing at least one of the above problems may include the following features.

The auger detachment detecting device of the auger type ice-maker according to an embodiment of the present invention includes an auger type ice maker that is rotatably provided in an auger type ice maker and separates and transports the ice formed in the auger type ice maker, The auger detachment detection device of the auger type ice-maker detects whether the auger is out of the normal rotation position. The auger detec- tion device includes an axial detachment sensor part for detecting whether the auger has deviated in the axial direction, And a radial release sensor portion.

In this case, the axial release sensor portion may be spaced apart from the auger by a predetermined first offset distance in the axial direction, and may detect whether the auger has moved in the axial direction by more than the first offset distance.

In addition, the axial release sensor may be located at a distance from the end of the auger opposite to the ice transfer direction by the first offset distance.

The auger portion on the opposite side of the ice transfer direction is rotatably supported by the thrust bearing and the radial bearing, and the auger portion on the ice transfer direction side can be rotatably supported by the radial bearing.

In addition, the axial release sensor may include an axial sensing member positioned to be spaced apart from the auger by the first separation distance in the axial direction, and an axial direction sensing member movably provided, And an axial sensing body that senses the sensed acceleration.

The radial gap detection part may be positioned radially away from the auger by a predetermined second offset distance to detect whether the auger has moved in the radial direction more than the second offset distance.

In addition, the radial deviation detecting portion may be positioned around the auger such that a plurality of circumferentially spaced radially spaced-apart sensor portions are spaced apart from each other by a predetermined angle.

The radial deviation detecting portion may be located radially away from the auger on the side from which the ice is discharged by the second offset distance.

In addition, the auger may be connected to the rotation driving unit included in the auger type ice maker and rotated.

The radial deviation detecting portion may be positioned radially away from the auger on the side to which the rotation driving portion is connected by the second deviation distance.

The rotation driving unit may include a chain connected to a first sprocket provided in the auger, and a driving motor having a second sprocket connected to the chain.

The radial direction detecting member may include a radial direction sensing member that is radially spaced from the auger by the second displacement distance, and the radial direction sensing member is movably provided, Lt; RTI ID = 0.0 > radially < / RTI > sensing body.

In addition, the auger type ice maker is provided with a flow space in which water flows into and flows into ice, and a refrigerant flow space formed in at least a part around the flow space and in which a refrigerant for cooling water flowing in the flow space flows And the auger may be rotatably installed through the flow space.

In addition, the auger type ice maker is connected to the flow space, and a water discharge space is formed in which the water cooled by the coolant or the ice formed by cooling while flowing in the flow space is discharged to the outside.

As described above, according to the embodiment of the present invention, it is possible to detect whether the auger which is rotatably provided in the auger type ice maker has deviated from the normal rotation position.

Further, according to the embodiment of the present invention, it is possible that the auger does not come into contact with other components of the auger type ice maker during rotation, and unnecessary foreign matter is not generated due to the auger.

Further, according to the embodiment of the present invention, the sanitary property of the auger type ice maker can be improved.

FIG. 1 is a longitudinal sectional view of an auger type ice maker provided with an auger type ice detector according to an embodiment of the present invention.
FIG. 2 is a plan sectional view of an auger type ice-maker provided with an auger type ice-maker detecting apparatus according to an embodiment of the present invention.
3 is an enlarged view of a portion A in Fig.
4 is a side view of an auger-type ice-maker provided with an auger-type ice-maker detector according to an embodiment of the present invention.
5 is an enlarged view of a portion B in Fig.
FIGS. 6 and 7 are cross-sectional views illustrating the operation of the auger type ice maker provided with the auger detachment detecting device of the auger type ice maker according to the present invention, wherein FIG. 6 shows the ice making time and FIG.

In order to facilitate understanding of the features of the present invention as described above, the auger detachment detecting apparatus of the auger type ice maker according to the embodiment of the present invention will be described in detail.

Hereinafter, exemplary embodiments will be described on the basis of embodiments best suited for understanding the technical characteristics of the present invention, and the technical features of the present invention are not limited by the illustrated embodiments, And that the present invention may be implemented with other embodiments. Therefore, it is intended that the present invention covers the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. In order to facilitate the understanding of the embodiments described below, in the reference numerals shown in the accompanying drawings, among the constituent elements that perform the same function in the respective embodiments, the related constituent elements are indicated by the same or an extension line number.

Hereinafter, an auger departure detecting apparatus for an auger type ice maker according to the present invention will be described with reference to Figs. 1 to 7.

FIG. 1 is a longitudinal sectional view of an auger type ice maker provided with an embodiment of the auger type ice detector of the auger type ice maker according to the present invention. Fig. 3 is an enlarged view of a portion A in Fig. 1; Fig.

FIG. 4 is a side view of the auger type ice maker provided with an embodiment of the auger detachment detecting device of the auger type ice maker according to the present invention, and FIG. 5 is an enlarged view of a portion B of FIG.

6 and 7 are sectional views illustrating the operation of the auger type ice maker provided with the auger detachment detecting device of the auger type ice maker according to the present invention. .

First, an auger type ice maker IM having an embodiment of the auger detachment detecting device 100 of the auger type ice maker IM according to the present invention will be described.

In the auger type ice maker IM, an auger AG is rotatably provided. The auger AG may be, for example, in the form of a screw. By this rotation of the auger AG, the ice I formed in the auger type ice maker IM can be separated from the auger type ice maker IM, conveyed and discharged to the outside as shown in Fig.

In the auger type ice maker IM, a flow space SF may be formed as shown in Figs. The auger AG can be rotatably provided through the flow space SF. Thereby, the flow path PW can be formed between the auger AG and the flow space SF.

The flow space SF can be connected to a water source (not shown). The auger type ice maker IM may be provided with an inlet IW connected to the flow space SF as shown in Fig. Then, the flow space SF can be connected to the water supply source by connecting the inlet IW to the water supply source by a connection pipe (not shown) or the like.

A water source connected to the flow space SF is provided in the water purifier, for example, if the auger type ice maker IM is provided in a water purifier (not shown), and includes a water filter (not shown) (Not shown), or a storage tank (not shown) connected to the filtration unit to store the filtered water in 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 source to which the flow space SF is connected is not particularly limited, and any well-known one 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 flows into the flow path PW between the flow space SF and the auger AG as shown in Fig. Lt; / RTI >

A refrigerant flow space SR may be formed at least in part around the flow space SF. A refrigerant, for example, a refrigerant at a freezing point or lower can flow in the refrigerant flow space SR. 6, the flow path PW between the flow space SF and the auger AG as shown in FIG. 6 is formed by the refrigerant flowing in the refrigerant flow space SR, Can be cooled. The 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 so as to flow between the flow space SF and the auger AG as shown in Fig. As shown in FIG.

An exhaust space SO formed in the auger type ice maker IM may be connected to the outside of the flow space SF. The ice I conveyed along the flow path PW between the flow space SF and the auger AG by the rotation of the auger AG is discharged to the discharge space SO as shown in Fig. To the outside. In this way, the ice I discharged to the outside through the discharge space SO can be stored in an ice reservoir (not shown).

7, 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, It is possible to prevent the ice I from being formed on the surface SF. In this state, the auger AG may not rotate. 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 is cooled to the outside through the discharge space SO And may be stored in a cold water tank after being discharged.

The water stored in the cold water tank can be introduced into the flow space SF through the inlet port IW as described above. Thereby, the water in the cold water tank can be cooled in the auger type ice maker IM, converted into cold water, and then returned to the cold water tank and stored as cold water. The water stored in the cold water tank may be circulated through the cold water tank and the auger type ice maker (IM) to become cold water. In addition, cold water stored in the cold water tank can be supplied to the auger type ice maker IM to make ice I more quickly in the auger type ice maker IM.

The auger AG is connected to a rotation driving part DR provided in the auger type ice maker IM and can be rotated by rotation of the rotation driving part DR.

The rotation drive section DR may include, for example, a chain CH and a drive motor MD. The chain CH may be connected to the first sprocket SP1 provided in the auger AG as shown in Figs. The drive motor MD is provided with a second sprocket SP2 and can be 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 rotation drive section DR is not particularly limited and may be a drive motor MD and an auger AG and a drive motor MD as long as they are connected to the auger AG and can rotate the auger AG And a gear (not shown) connected and meshing with each other.

The auger AG can be rotatably supported by the bearings BT and BR.

Auger (AG) may be subjected to radial forces due to the weight of auger (AG). Both sides of the auger AG can be rotatably supported by the radial bearings BR so that the auger AG can rotate against the radial force acting on the auger AG as described above.

In addition, an axial force can be applied to the auger AG in the direction opposite to the conveying direction of the ice I by the conveyance of the ice I in the flow space SF. A portion of the auger AG on the opposite side of the ice I transport direction can be rotatably supported by the thrust bearing BT so that the auger AG can rotate against this axial force.

1 and 2, the portion of the auger AG on the opposite side of the ice I transport direction is rotatably supported by the thrust bearings BT and the radial bearings BR, I) The portion of the auger AG on the transport direction side can be rotatably supported by the radial bearing BR.

However, the structure for rotationally supporting the auger AG is not particularly limited, and any known structure can be used as long as it is capable of rotationally supporting the auger AG.

Meanwhile, the augen type ice maker IM may be provided with a drained DW connected to the flow space SF. The drape population DW may be provided with an on-off valve (not shown). The drain valve DW is normally closed and is opened when the water in the flow space SF needs to be drained to the outside so that the water in the flow space SF is discharged to the outside As shown in Fig.

The auger separation sensing apparatus 100 of the auger type ice-maker IM according to the present invention can sense whether the above-described auger AG has deviated from the normal rotation position.

For this purpose, the auger separation sensing device 100 of the auger type ice-maker IM according to the present invention may include at least one of an axial release sensor unit 200 and a radial deviation sensor unit 300.

The axial release sensor portion 200 can detect whether the auger AG has deviated in the axial direction. The axial release sensor portion 200 may be positioned away from the auger AG by a predetermined first offset distance D1 in the axial direction. For example, the axial release sensor portion 200 may be positioned at a distance of a first offset distance D1 from the end of the auger AG on the opposite side of the ice I transport direction as shown in Fig. The axial release sensor 200 can sense whether the auger AG has moved in the axial direction by more than the first offset distance D1.

As described above, the portion of the auger AG on the opposite side of the ice (I) transport direction can be rotatably supported by the thrust bearing BT. When the ice I is not smoothly conveyed by the auger AG and the axial force is excessively applied to the auger AG in the direction opposite to the direction of conveying the ice I, Thrust bearings (BT) etc. may be damaged. Thereby, the auger AG can move in the axial direction by more than the first deviation distance D1 toward the axial direction deviation detecting unit 200. Then, the axial release sensor 200 can sense the movement of the auger AG in the axial direction. In addition, the axial release sensor unit 200 can notify such an axial deviation of the auger AG by an electric signal or the like to a control unit (not shown) of the auger type ice maker IM.

In this case, the control section can stop the drive of the drive motor MD of the rotation drive section DR and stop the rotation of the auger AG. Thus, after the rotation of the auger AG is stopped by the control unit, the user can check the auger AG, replace the deformed auger AG, or replace the broken thrust bearing BT or the like.

As a result, the auger AG does not come into contact with other components of the auger type ice maker IM during rotation, and unnecessary foreign matter can be prevented from being generated by the auger AG. In addition, the sanitary property of the auger type ice maker IM can be improved.

The axial release sensor portion 200 may include an axial sensing member 210 and an axial sensing body 220.

The axial sensing member 210 may be positioned axially away from the auger AG by a first offset distance D1. For example, the axial sensing member 210 may be positioned apart from the end of the auger AG on the opposite side of the ice (I) transport direction by a first offset distance D1 as shown in Fig.

The axial direction sensing body 220 may be movably provided with the axial direction sensing member 210. The axial sensing body 220 can sense whether the axial sensing member 210 is moving.

When the auger AG moves over the first offset distance D1 in the axial direction toward the axial direction sensing member 210, the auger AG comes into contact with the axial direction sensing member 210, And the axial sensing body 220 can sense the movement of the axial sensing element 210. [

For example, the axial direction sensing member 210 is elastically supported by an elastic member (not shown) provided on the axial direction sensing body 220, and the axial direction sensing body 220 is provided with a piezoelectric element May be provided. Accordingly, when the axial direction sensing member 210 is moved by the axial movement of the auger AG to the axial direction sensing member 210, a force for exerting the elastic force of the elastic member 210 acts on the axial direction sensing member 210 , An electric signal is generated from the piezoelectric element and the movement of the axial direction sensing member 210 can be sensed.

However, the configuration of the axial direction sensing body 220 is not particularly limited, and a configuration capable of sensing the movement of the axial direction sensing member 210 in accordance with the axial movement of the auger AG beyond the first separation distance D1 Any known structure can be used.

The configuration of the axial release sensor portion 200 is not particularly limited as long as it can detect that the auger AG is moving in the axial direction by more than the first offset distance D1. And a configuration capable of detecting the non-contact type using a light-emitting diode or the like.

On the other hand, the first offset distance D1 is not particularly limited and may be any distance as long as it can detect whether the auger AG has deviated in the axial direction from the normal rotation position.

The axial release sensor unit 200 may be provided in the auger type ice maker IM by the first installation unit IS1. The construction of the first installation unit IS1 is not particularly limited, and any known construction can be employed as long as the axial release sensor unit 200 can be provided in the auger type ice maker IM.

The radial deviation detecting portion 300 can detect whether the auger AG deviates in the radial direction. The radial deviation detecting portion 300 can be positioned radially away from the auger AG by a predetermined second deviation distance D2. Then, the radial deviation detecting portion 300 can detect whether the auger AG has moved in the radial direction beyond the second offset distance D2.

A plurality of radial deviation detecting portions 300 may be positioned around the auger AG in a circumferential direction at a predetermined angle. That is, since the radial direction in which the auger AG is detached may be an arbitrary direction, it is preferable that a plurality of radial deviation detecting portions 300 are positioned at a predetermined angle to each other in the circumferential direction in order to detect the radial direction. For example, as shown in Figs. 4 and 5, two radial gap-detecting portions 300 may be positioned circumferentially at right angles to each other around the auger AG. However, the number of the radial deviation detecting portions 300 and the angle at which the plurality of radial gap detecting portions 300 are positioned so as to be spaced apart from each other in the circumferential direction is not particularly limited, and it is possible to detect whether the auger AG has deviated radially Any number or angle can be used for any number or angle.

As shown in Figs. 1 and 5, for example, the radial deviation detecting portion 300 is spaced apart from the portion of the auger AG on the side from which the ice I is discharged, by a second offset distance D2 in the radial direction Can be located.

A portion of the auger AG on the side from which the ice I is discharged is subjected to a force acting in a direction opposite to the direction in which the ice I is discharged while the ice I is discharged and a radial force acts on the auger AG . If the radial force acts excessively in the opposite direction to the side where the ice I is discharged to the auger AG due to insufficient discharge of the ice I, the radial bearing BR, etc. may be damaged . Thereby, the auger AG can move in the radial direction toward the radial deviation detecting portion 300 by the second offset distance D2 or more. Then, the radial deviation detection part 300 can sense the radial movement of the auger AG. Further, the radial deviation detecting portion 300 can notify such a radial deviation of auger AG by an electric signal or the like to a control unit of the auger type ice maker IM.

In this case, the control section can stop the drive of the drive motor MD of the rotation drive section DR and stop the rotation of the auger AG. Thus, after the rotation of the auger AG is stopped by the control unit, the user can check the auger AG, replace the deformed auger AG, or replace the damaged radial bearing BR or the like.

As a result, the auger AG does not come into contact with other components of the auger type ice maker IM during rotation, and unnecessary foreign matter can be prevented from being generated by the auger AG. In addition, the sanitary property of the auger type ice maker IM can be improved.

The radial deviation detecting portion 300 can be positioned in the radial direction away from the portion of the auger AG on the side to which the rotation driving portion DR is connected by the second deviation distance D2.

As described above, if the rotation drive part DR includes, for example, a chain CH and a drive motor MD, a part of the auger AG on the side to which the rotation drive part DR is connected , So that a radial force acts on the auger AG. If the radial force acts on the auger AG excessively due to insufficient drive of the rotary drive DR, the radial bearing BR may be damaged. Thereby, the auger AG can move in the radial direction toward the radial deviation detecting portion 300 by the second offset distance D2 or more. Then, the radial deviation detection part 300 can sense the radial movement of the auger AG. Further, the radial deviation detecting portion 300 can inform the controller of the auger type ice maker IM of the radial deviation of the auger AG by an electric signal or the like.

The radial release sensor 300 may include a radial sensing member 310 and a radial sensing body 320.

The radial sensing member 310 may be positioned radially away from the auger AG by a second offset distance D2. For example, as shown in Figs. 1 and 5, the radial sensing member 310 may include a portion of the auger AG on the side from which the ice I is discharged or an auger AG on the side to which the rotation driving portion DR is connected, And the second separation distance D2 from the second separation distance D2.

The radial sensing body 310 may be movably provided in the radial sensing body 320. [ The radial sensing body 320 may sense whether the radial sensing member 310 is moving.

When the auger AG moves over the second offset distance D2 in the radial direction toward the radially sensing member 310, the auger AG contacts the radially sensing member 310 and the radial sensing member 310 And the radial sensing body 320 can sense the movement of this radial sensing member 310. [0040]

For example, the radial sensing member 310 is movably resiliently supported by an elastic member (not shown) provided on the radial sensing body 320, and the piezoelectric sensing element 320 (not shown) May be provided. Accordingly, when the radial sensing member 310 moves due to the radial movement of the auger AG to the radial sensing member 310, a force for exerting the elastic force of the elastic member on the radial sensing member 310 is applied, An electric signal is generated from the piezoelectric element and the movement of the radial sensing member 310 can be sensed.

However, the configuration of the radial sensing body 320 is not particularly limited, and may be configured to detect movement of the radial sensing member 310 in accordance with radial movement of the auger AG beyond the second separation distance D2 Any known structure can be used.

Further, the configuration of the radial deviation detecting portion 300 is not particularly limited. As long as the auger AG can sense that the auger AG is moving in the radial direction by the second deviation distance D2 or more, the above-mentioned contact type, magnetic field, Or a non-contact type detection using a non-contact type.

On the other hand, the second offset distance D2 is not particularly limited, and any distance can be detected as long as it is possible to detect whether the auger AG deviates in the radial direction from the normal rotation position.

The auger AG is provided with an extension member EM as shown in Figs. 1 and 2, Figs. 4 and 5, 2 separation distance D2 so as to detect whether or not the auger AG has deviated in the radial direction.

The radial release sensor 300 may be provided in the auger type ice maker IM by the second installation unit IS2. The configuration of the second installation unit IS2 is not particularly limited, and any known configuration may be employed as long as the radial deviation detection unit 300 can be provided in the auger type ice maker IM.

As described above, according to the auger type ice-maker of the present invention, it is possible to detect whether the auger which is rotatably provided in the auger type ice-maker has deviated from the normal rotation position. When the auger type ice- It is possible to prevent unnecessary foreign matter from being generated by the auger, and the hygienic performance of the auger type ice-maker can be improved.

The above-described auger detachment device of the auger type ice maker can be applied to a configuration of the above-described embodiments in a limited manner, but the embodiments can be modified so that all or some of the embodiments are selectively combined .

100: auger separation detecting device of an auger type ice maker 200:
210: Axial direction sensing member 220: Axial direction sensing body
300: radial deviation detecting portion 310: radial direction detecting member
320: Radial sensing body IM: Auger type ice maker
I: Ice AG: auger
D1: first departure distance D2: second departure distance
SF: flow space PW: flow path
SO: discharge space SR: refrigerant flow space
DR: rotation driving part SP1: first sprocket
SP2: Second sprocket CH: Chain
MD: Drive motor BR: Radial bearing
BT: thrust bearing IW: inlet
DW: Drape population EM: Extension member
IS1: first installation unit IS2: second installation unit

Claims (14)

An auger type ice maker rotatably installed in an auger type ice maker and detecting whether the auger is separated from the auger type ice maker, ,
Wherein the auger separation sensing device includes at least one of an axial release sensor for sensing whether the auger has deviated in the axial direction and a radial release sensor for sensing whether the auger has deviated in the radial direction, . 2. The auger type ice maker according to claim 1, wherein the axial release sensor portion is positioned at a predetermined first offset distance in the axial direction from the auger to detect whether the auger has moved in the axial direction by more than the first offset distance, Auger departure detection device. The auger-type ice-maker as claimed in claim 2, wherein the axial release sensor portion is located at a distance from the end of the auger on the opposite side of the ice transfer direction by the first deviation distance. The ice making machine according to claim 3, wherein the auger portion on the opposite side of the ice transfer direction is rotatably supported by a thrust bearing and a radial bearing, and the auger portion on the ice transfer direction side is rotatably supported by a radial bearing Auger separation sensor. 3. The motorcycle according to claim 2, wherein the axial departure-
An axial direction sensing member positioned to be spaced apart from the auger by the first separation distance in the axial direction,
And an axial direction sensing body for sensing whether the axial direction sensing member is moving,
And an auger-type ice-maker. 2. The auger type ice maker according to claim 1, wherein the radial deviation detecting portion is spaced apart from the auger by a predetermined second offset distance in a radial direction and detects whether the auger has moved in a radial direction more than the second offset distance, Auger departure detection device. The apparatus of claim 6, wherein the radial deviation detecting portion is located around the auger in a circumferential direction so that a plurality of the radial deviation detecting portions are spaced apart from each other by a predetermined angle. 7. The auger-type ice-maker as claimed in claim 6, wherein the radial deviation detecting portion is located radially away from the auger on a side from which the ice is discharged, by a distance corresponding to the second deviation distance. The apparatus of claim 6, wherein the auger is connected to a rotation driving unit of the auger type ice maker and rotated. 10. The auger-type ice-maker as claimed in claim 9, wherein the radial deviation detecting portion is located radially away from the auger on a side to which the rotation driving portion is connected, by a distance corresponding to the second deviation distance. The apparatus as claimed in claim 10, wherein the rotation driving unit
A chain connected to a first sprocket provided in the auger,
A drive motor having a second sprocket to which the chain is connected,
And an auger-type ice-maker. 7. The apparatus according to claim 6, wherein the radially-
A radial sensing member positioned radially away from the auger by the second separation distance,
And a radial sensing body for sensing whether the radial sensing member is movable,
And an auger-type ice-maker. 7. The ice making machine according to claim 2 or claim 6, wherein the auger type ice maker is provided with a flow space in which water flows into and flows into the ice, and at least a part of the refrigerant Wherein the auger is rotatably provided through the flow space, wherein the auger is rotatably installed in the flow space. 14. The auger type ice maker according to claim 13, wherein the auger type ice maker includes an auger type ice maker connected to the flow space and having a discharge space through which water cooled or cooled by the refrigerant while flowing in the flow space is discharged to the outside, Detection device.

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