KR20190045835A - Auger type ice machine - Google Patents

Abstract

Disclosed is an auger type ice machine guiding and dispensing ice while making a helical track after the ice is made. According to the present invention, the auger type ice machine comprises: an ice making unit (1) including a horizontal ice making vessel (10) having a water inlet for supplying water to be frozen and an evaporation pipe body (3) integrally formed on the outer circumferential surface of the ice making vessel (10) and having a refrigerant inlet/outlet for circulating a refrigerant; an auger (2) having a helical blade (22) formed along an auger shaft (21) in a helical direction to be rotated on the inner surface of the ice making vessel and forming an ice making space (27) between the ice making vessel (10) and the helical blade (22) to be installed on a horizontal central axis; a driving unit (5) having an idling driven shaft part (23) formed at one end part of the auger shaft (21) to rotate the auger (2) and having a drive shaft part (26) formed on the other end part to transfer driving force of a motor (5); and an ice dispensing block (11) having an ice outlet (15) formed at one end part of the ice making vessel (10) to vertically dispense ice after the ice is made and having a helical guide surface (16) while extending the inner circumferential surface of the ice making vessel (10). The helical guide surface forms a helical track from a high point (h1) to a low point (h2) with an inclination while having a constant width (b).

Description

Auger type ice machine "

The present invention relates to an auger type ice maker. Especially, it is auger type ice maker in which nugget type ice is formed by forming an outlet in a vertical direction with respect to a horizontal direction auger axis. It improves the durability by reducing the horizontal direction pressure of ice in ice, The present invention relates to a reduced auger type ice maker.

The following are commonly known auger type ice makers:

Japanese Patent Application Laid-Open No. 10-2003-62201,

The ice making machine comprises a vertical ice tray, an auger provided on the same axis in the ice tray to continuously scrape off the ice layer growing on the same inner circumferential surface and to be transported upward, a refrigerant pipe wound and fixed on the outer periphery of the ice tray, And a pressure head fixedly installed on the upper side of the barrel, wherein when the ice scraped by the auger is pushed up and conveyed to the inner peripheral surface of the ice-making barrel by the pressure head, And an angle of intersection of the helical blade in the axial direction is set to be 90 to 110 mm. In this case, Is known,

Patent Publication No. 10-416944,

An auger provided coaxially in the ice-making cylinder, a refrigerant pipe recommended in close contact with the outer periphery of the ice-making cylinder, and a pressure head provided on an upper portion of the ice- Wherein the auger has a body portion and a spiral blade provided on the outer periphery of the main body portion, and the sectional shape of the blade portion of the spiral blade is formed by a generally thicker portion from the edge of the vertical blade toward the base portion of the spigot, Wherein the taper angle of the edge of the blade is 1 to 3 mm and the taper angle of the upper surface portion following the edge of the blade is 2 to 8, Is known,

Practical Laid-Open Publication No. 20-1983-0000407,

An ice maker for producing ice cubes by freezing ice frozen by an evaporator of a freezer and for injecting the cut ice into an extrusion head provided with an ice compaction passage to compress and produce ice cubes successively, And a compression compression piece made of an elastic material mounted on each of the partition walls so as to gradually protrude toward the ice compression passage from the side of the partition edge and gradually restrict the width of the ice compression passage from the entrance side to the exit side of the ice compression passage An extrusion head for ice compression in an ice maker is known,

Patent Registration No. 20-0138409,

A condenser for compressing the refrigerant, a radiator for liquefying the compressed refrigerant, an evaporator for freezing the ice by the vaporization of the refrigerant, a water tank for supplying water to the evaporator, and an ice- And an ice reservoir for storing the ice cubes. The water discharged from the ice tail cutter and the ice reservoir and discharged through the high artificial creature discharge pipe is combined with the water discharged from the water tank, A heat radiator cooling device of an icemaker in which heat is exchanged into the inside of the radiator through an outlet of the radiator, and then is discharged to the outside through an outlet of the radiator tube.

Conventionally, the auger type ice maker includes a vertical type vertical ice maker (hereinafter referred to as a vertical type ice maker) in which the outlet of the ice is in the same direction as the axial direction of the auger, , Hereinafter referred to as a horizontal type ice maker). Vertical type ice makers have several blowing nozzles, while horizontal type ice makers having one side blowing nozzles have one blowing nozzle. The vertical auger type ice maker has a smaller size of the evaporator in which the auger is placed as well as a vertical auger, and the size of the ice sheet that flows out from a large number of ice is also reduced. And it becomes unsuitable for use. In particular, in the case of a vertical type ice maker, since the thrust load is equal to the sum of the ice resistance on the spiral blade of the auger, the direction in which the load is applied is opposite to the direction of ice movement, The radial load applied to the side of the auger shaft acts as a force corresponding to the spiral angle of the auger with respect to the axial load, that is, the thrust load. Therefore, It is difficult to apply idle rotating means (bearings) having a sufficient capacity to the follower shaft portion so that the lifetime of the entire ice maker is shortened due to the abrasion.

On the contrary, since the horizontal ice type ice maker constitutes one outlet of the ice making box on the side of the ice maker, the size of ice particles to be ejected becomes larger than that of the vertical type having a plurality of ice making holes. Therefore, As shown in FIG.

However, since the horizontal ice maker has a greater force applied to the side of the auger shaft than the vertical ice maker, the overall durability of the ice maker is weak. Therefore, parts for preventing this are added, and parts are increased. So that the performance of the small ice maker can not be realized. In addition, the vertical type ice maker and the horizontal type ice making method were different from each other in the assembling structure.

That is, the vertical type ice maker is designed to arrange a plurality of ice making holes 1 including a drive motor, auger and the like, and a plurality of ice making holes including a function of ice-making after icing and ice-making after icing. Therefore, since the ice is compressed in the direction of the auger axis, it can be said that the force (also called the radial load) applied in the direction perpendicular to the auger axis is small.

The horizontal type ice maker is designed to be arranged in the order of the ice making unit 1 such as auger and the like, the one blowing ice containing the compression function after the ice making and ice making through the refrigerant circulation, and the driving motor, It is necessary to increase the number of components in order to overcome this problem, and the expensive parts are required to overcome the problem. Therefore, the manufacturing cost is increased. Particularly, in the known horizontal ice type ice maker (FIG. 10), there is a possibility that the number of parts is small and the cost is reduced. However, there is a problem that the ice maker is manufactured without necessary parts corresponding to the eccentric load.

In order to achieve a cooling cycle (A) through circulation of refrigerant composed of an evaporator, a compressor, a condenser and a capillary tube, the inside and outside (condensation prevention) of the ice tray is surrounded by a heat insulating material So that there is a problem in downsizing the ice maker.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an auger type ice maker in which an icemaker can be a single body.

The present invention reduces the cost and simplifies the parts and structure of the auger type ice maker and disperses the guide surface in which the horizontal movement pressure generated at the time of ice- The present invention provides a horizontal type auger type ice maker in which the structure is improved more simply.

The present invention relates to a horizontal type auger type ice maker which prevents leakage of residual water generated during ice making and also improves the adhesion rate with the auger shaft surface to prevent corrosion of the driving part.

In addition, in the horizontal type ice-making machine of the present invention, it is possible to apply a bearing having a sufficient capacity to an outlet-side driving portion in which the moving pressure is greatest, and conversely, to provide a horizontal type ice- do.

Accordingly, the auger type ice maker of the present invention intends to provide an assembly structure in which the ice making structure of the auger body is advantageously separated through the follower shaft portion.

According to an aspect of the present invention, there is provided an auger type ice-

A freezing portion formed of an evaporator tube having a coolant inlet and outlet for collecting the coolant and circulating the coolant;

An auger formed in a spiral direction along an auger axis and rotating in an inner surface of the ice-making cylinder, the auger being formed on an axis of a horizontal axis in an ice-making space between the ice-making and passing helix;

One end of the auger shaft is formed with a groove to rotate the auger, a slave shaft portion constituting a shaft receiving portion inserted with a sealing member mounted with an elastic force is formed in the groove portion, and the other end is installed to transmit a driving force of the driving motor A driving unit having a main coaxial portion; And

An ice block formed on one end of the ice-making container to form an ice-making hole for discharging ice in a vertical direction after ice making and forming a helical guide surface on an inner circumferential surface;

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The helical guide surface

The ice-making ice is moved along the ice-making space in the ice-making space in the horizontal direction by the rotary pressure of the auger, and is gradually moved from the first position (h1) to the second position (h2) (Hereinafter referred to as a contact surface, which is a contact surface perpendicularly abutting the horizontal direction ice tray) is formed.

As described above, the so-called horizontal auger type ice-maker according to the present invention is very advantageous in downsizing the ice maker, and since the ice block is formed between the auger and the main shaft portion, the eccentric load and the radial load of the auger are less influenced by the auger It is possible to prevent uneven wear in the blade and the ice tray, simplify disassembly of the follower shaft portion, improve eccentric load applied to the main shaft portion, and improve durability, thereby further improving life span of the conventional auger type ice maker.

The present invention improves the durability of the auger type ice maker as a whole by integrally forming the ice block on the base end of the ice maker provided at the base end of the ice maker installed on the center axis of the auger, and simplifies the structure, facilitates assembly and disassembly, It was.

In addition, the present invention provides a freezing block integrally formed with the ice making cylinder in the form of a cochlea to have a contact surface of a predetermined width so that ice is vertically guided after ice making at the base end of auger, so that smooth ice can be displayed, The thrust load and the radial load applied to the auger shaft are almost zero. Therefore, the structure of the bearing is not required to be applied, and only the reducer of the driving portion (main shaft portion) And a rugged driving portion that receives less radial load can be provided.

Further, in addition to the simple and robust construction of such a drive shaft portion (drive portion), the load burden on the driven shaft portion is reduced, and only the bearing and sealing member can be applied to the driven shaft portion. Further, Or an inner diameter fixing ring) to simplify the construction, and to provide a low-cost auger type ice-maker with a remarkably improved unit cost due to the ease of assembly.

Further, since the guiding surface formed like a cochlea in the horizontal direction is formed with a spiral inclination and is formed in the ice-making tray, the resistance to moving in the vertical direction is greatly reduced, and the effect of smoothly moving the presentation is obtained.

Particularly, the present invention can integrally design a moving block having an ice-making container having an ice-making container, which is structurally most important, by integrally forming a freezing block in the ice-making container, thereby simplifying the structure, There is an advantage that a very simple assembling structure can be realized by assembling and disassembling a whole auger structure only through a follower portion, assembling and disassembling the cover portion on the outside, and screwing the drive portion to the excursion block as a fastening structure .

Further, as an improved sealing member on the inner circumferential surface of the through hole of the moving block according to the present invention, the adhesion rate is increased, and leakage due to residual water generated after ice making can be prevented.

1 is a sectional view of an auger type ice maker of the present invention,
2 is a longitudinal sectional view showing a guide surface of an auger type ice maker of the present invention,
3 is a view of another embodiment of the auger type ice maker auger of the present invention,
Fig. 4 is a view of another embodiment of the auger type ice-maker sealing member of the present invention,
Fig. 5 is a sectional view of the vacuum insulator of the auger type ice-maker heat-insulating cover portion of the present invention,
6 is a sectional view of the evaporating tube of an auger type ice-maker of the present invention,
7 is a sectional view of another embodiment of the auger type ice maker of the present invention,
8 is a schematic view of a conventional vertical auger type ice maker.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a view of another embodiment of the auger type ice maker auger of the present invention, and FIG. 3 is a view of another embodiment of the auger type ice maker auger of the present invention, and FIG. Fig. 4 is a view showing another embodiment of the auger type ice-maker sealing member of the present invention, Fig. 5 is a sectional view of the vacuum insulator of the auger type ice-maker heat-insulating cover part of the present invention, and Fig.

The auger type ice maker according to the present invention comprises the ice maker 1, the auger 2, and the drier 5.

The ice making section 1 is divided into an ice tray 10, an evaporator tube 3 and a heat insulating cover section 6.

The ice making cylinder 10 is a cylindrical cylinder having both ends opened and a water supply port 12 is formed in which a screw 22 (hereinafter referred to as an auger) The auger 2 to be formed is installed in the horizontal direction. The auger 22 of the auger 2 can form a micro clearance (see Fig. 7A) on the inner surface 14 of the ice-making cylinder 10. [

The evaporating tube (3) is formed in close contact with the outer peripheral surface of the ice-making cylinder (10). The evaporating tube 3 can form a coolant circulation space 31 in the form of a jacket in which a predetermined refrigerant is circulated and filled therein. The refrigerant inlet 32 and the outlet 34 are formed, The outer peripheral surface of the ice-making cylinder 10 contacting the evaporation tube 3 can be cooled while the refrigerant is circulated and supplied through the cycle A. The evaporating tube 3 forming the refrigerant circulation space 31 can be carried out by winding a refrigerant circulation pipe in which a refrigerant other than a jacket type is circulated as shown in FIG. The evaporating tube 3 can form a partition 31a in the spiral direction as shown in FIG. 8 to form the refrigerant circulation space 31. [

The driving unit 5 can be provided with a speed reducer 52 inside the driven gear 51 and with the bearing 53 and the main shaft portion 26 formed inside the reducer 52. A bearing 55 is provided on the driven shaft portion 23 of the drive portion 5. [ That is, the bearings 53 and 55 are provided between the main shaft portion 26 and the speed reducer 52, and between the driven shaft portion 23 and the inner peripheral surface 11 of the ice-making cylinder 10, respectively.

The heat insulating cover portion 6 is formed on the outside of the evaporating tube 3 and is installed so that the evaporating tube 3 is insulated from the outside and is made of a foam insulating material 65 as shown in FIG. Will be described later).

The ice making cylinder 10 may form a freezing block 11 to be coupled with the driving part 5. [ When the auger shaft 21 rotates by applying a driving force to the driving motor 51 of the driving unit 5 as shown in Fig. 8, the excursion block 11 moves the eccentric load To prevent the flow and vibration of the auger shaft 21 and the main shaft portion 26 (also referred to as the drive shaft) of the drive motor 51 and the wear of the ice-making cylinder 10, As shown in Fig.

The excavating block 11 may be formed on the inner circumferential surface of the ice tray 10 so as to connect the drive section 5 as a single molded product integrally extended to the ice tray 10. Or the ice block 11 may be separately formed and assembled to one side of the ice tray 10. The ice cubes 11 extend in the ice making space 27 and can form an ice cubes 24 having the ice making holes 15 formed thereon so that the ice cubes that have been ice- Thereby forming an outlet 15 for presentation. The joining block 11 is provided so as to seal and form a groove 74 in which the sealing member 72 is inserted so as to prevent leakage of the ice making residual water between the joining block 11 and the main shaft portion 26 of the auger shaft 21. [ That is, as described later, at least one groove 74 contacting the face of the auger shaft 21 is formed in the excavating block 11 installed in this manner, the sealing member 72 is mounted on the groove 74, And is fixed radially by using a fixing means (not shown) in the driving unit 5. The ice block 10 and the ice block 10 integrally formed with the ice block 10 are prevented from eccentric flow of the auger shaft 21 caused by mounting the impeller of the conventional vertical plane only on the auger shaft and thus the wear of the ice tray 10, Can be reliably improved.

The auger 2 is constituted by an auger shaft 21 constituting a central axis of a rotary shaft provided in a horizontal direction and a spiral auger 22 integrally formed on the outer peripheral face of the auger shaft 21, And a driven shaft portion 26 receiving driving force from the auger shaft 21. As shown in Fig. The follower shaft portion 23 is provided with a bearing portion 7 formed with a groove portion 74 to which the bearing member 74 is mounted so that the bearing 55 idles. The main shaft portion 26 is provided in the reduction gear 52, A direction bearing 53 is installed.

The auger 2 has a spiral eugenoid 22 formed on the auger shaft 21 between the ice maker 10 and the ice making drum 10 to rotate the inner peripheral surface of the ice- And a guide surface 16 having a constant width "b" similar to the inner annular cochlea is formed at the end of the ice making space 27 (see FIGS. 1 and 2).

The guide surface 16 receives the pressing force in the horizontal direction in the ice-making space at the rotational pressure of the eugenoid, moves along the ice-making space, and gradually moves from the first position h1 to the second position h2 Can be formed.

The guiding surface 16 is a guide surface in which the ice making ice horizontally moves in the ice making space 27 at the rotary pressure of the eugenol 22 and is guided in the ice making space 24 and is gradually lowered to a constant width " And the ice-making ice hitting against the guide surface 16 is pushed in a vertical direction toward the outlet 15 formed in a vertical direction while forming a spiral trajectory. As shown in Fig. 2, the guiding surface 16 is formed such that the height of the guiding surface 16 becomes equal to the height h1 at the beginning of the spiral trajectory when the ice- (H1) to a low point (h2). Therefore, the ice-making ice to be moved moves while forming a helical trajectory from the highest point h1 to the lowest point h2 of the guide surface 16, and the ice-making ice 15, which is positioned vertically at the tip of the low point h2, .

The guide surface 16 having a spiral movement locus is concentric with the same diameter but forms an inclination gradually lowering from the high point h1 of the initial stage of the ice-making ice contact to the low point h2 of the terminal end of the ice contact, It moves by drawing the trajectory of the spiral and is moved out afterwards.

The guiding surface 16 is moved by the horizontal length of a predetermined section extending in the direction of the auger shaft 21 and then is drawn while drawing a spiral locus that is displayed in the vertical direction and the auger 22 of the auger 2, B " and " b " in the case where the helical blade 22 is reduced to two, the guide surface 16 is formed by one width An extended width can be formed.

As shown in Fig. 3, the auger tooth 22 is provided in contact with the inner peripheral surface 14 of the ice-making cylinder 10 with a minute gap therebetween. A groove 22a is formed at an end of the auger 22, The cobalt and nickel alloy based welding material 22b having good wear resistance and corrosion resistance can be formed in the groove 22a. Cobalt alloy type welding rod is a weldable material mainly made of cobalt and mixed with carbon, silicon, manganese, chromium and the like. After the welding material is melted and fused to the groove 22a and then coated, the welded portion can be post-processed to match the end shape of the Auger 22. Further, by coating the entire auger shaft 21 and the auger 22, it is possible to protect the coated portion of the welding material 22b from the outside.

On the other hand, the driven shafts 23 and 23a of the auger 2 can form two axial surfaces as shown in the figure. The bearings are mounted on the main shaft portion 26 and the driven shafts 23 and 23 23a may be provided with a bearing portion 7. In this case, The bearing member 7 can form a sealing member 72 mounted on the groove 74 as shown in Fig. The sealing member 72 can form a C-shaped insertion space 72a having one side opened, and the ring-like elastic member 73 can be inserted into the insertion space 72a.

Therefore, the ice-making cylinder 11 and the main shaft portion 23 of the drive unit 5 are formed on one side of the ice-making cylinder 10, and the subordinate shaft portions 23 and 23a of the auger shaft 21 are formed on the opposite side. And the bearing unit 7 can be assembled inside the ice tray 10 after the bearings 55 and the sealing member 72 are mounted on the inner and outer diameters.

7 is a sectional view of another embodiment of the auger type ice-maker of the present invention.

A part of the construction of the horizontal-type auger type ice-maker of the present invention shown in this embodiment is the same as that of the auger type ice-maker shown and described in Fig.

The auger type ice maker according to the present invention comprises the ice maker 1, the auger 2, and the drier 5. The ice-making section 1 comprises an ice-making cylinder 10, an evaporation tube 3 and a heat-insulating cover section 6.

The ice making cylinder 10 is a cylindrical cylinder having both ends opened and a water supply port 12 is formed in which a screw 22 (hereinafter referred to as an auger) The auger 2 to be formed is installed in the horizontal direction. The auger 22 of the auger 2 can form a micro clearance on the inner surface 14 of the ice-making cylinder 10. [

The evaporating tube (3) is formed in close contact with the outer peripheral surface of the ice-making cylinder (10). The evaporating tube 3 can form a coolant circulation space 31 in the form of a jacket in which a predetermined refrigerant is circulated and filled therein. The refrigerant inlet 32 and the outlet 34 are formed, The outer peripheral surface of the ice-making cylinder 10 contacting the evaporation tube 3 can be cooled while the refrigerant is circulated and supplied through the cycle A. The evaporating tube 3 forming the refrigerant circulation space 31 can be carried out by winding a refrigerant circulation pipe in which a refrigerant other than a jacket type is circulated as shown in FIG. The evaporating tube 3 can form a partition 31a in the spiral direction as shown in FIG. 8 to form the refrigerant circulation space 31. [

The driving unit 5 can be provided with a speed reducer 52 inside the driven gear 51 and with the bearing 53 and the main shaft portion 26 formed inside the reducer 52. A bearing 55 is provided on the driven shaft portion 23 of the drive portion 5. [ That is, the bearings 53 and 55 are provided between the main shaft portion 26 and the speed reducer 52, and between the driven shaft portion 23 and the inner peripheral surface 11 of the ice-making cylinder 10, respectively.

The heat insulating cover part 6 is formed on the outside of the evaporating tube 3 and is installed so that the evaporating tube 3 is insulated from the outside and is made of a foam insulating material 65 as shown in Fig.

The ice making cylinder 10 may form a freezing block 11 to be coupled with the driving part 5. [ When the auger shaft 21 rotates by applying a driving force to the driving motor 51 of the driving unit 5 as shown in Fig. 8, the excursion block 11 moves the eccentric load To prevent the flow and vibration of the auger shaft 21 and the main shaft portion 26 (also referred to as the drive shaft) of the drive motor 51 and the wear of the ice-making cylinder 10, As shown in Fig.

The excavating block 11 may be formed on the inner circumferential surface of the ice tray 10 so as to connect the drive section 5 as a single molded product integrally extended to the ice tray 10. Or the ice block 11 may be separately formed and assembled to one side of the ice tray 10. The ice cubes 11 extend in the ice making space 27 and can form an ice cubes 24 having the ice making holes 15 formed thereon so that the ice cubes that have been ice- Thereby forming an outlet 15 for presentation. The joining block 11 is provided so as to seal and form a groove 74 in which the sealing member 72 is inserted so as to prevent leakage of the ice making residual water between the joining block 11 and the main shaft portion 26 of the auger shaft 21. [ That is, at least one groove 74 contacting the face of the auger shaft 21 is formed in the thus-installed moving block 11, a sealing member 72 is mounted on the groove 74, (Not shown) in the radial direction. The ice block 10 and the ice block 10 integrally formed with the ice block 10 are prevented from eccentric flow of the auger shaft 21 caused by mounting the impeller of the conventional vertical plane only on the auger shaft and thus the wear of the ice tray 10, Can be reliably improved.

The auger 2 has a spiral eugenoid 22 formed on the auger shaft 21 between the ice maker 10 and the ice making drum 10 to rotate the inner peripheral surface of the ice- And a guide surface 16 having a constant width "b" to form a spiral trajectory similar to the inner annular cochlea is formed at the end of the ice making space 27 (see FIGS. 1 and 2) ).

The guide surface 16 guides the ice making ice horizontally in the ice making space 27 at the rotational pressure of the eugenol 22 and guided in the ice making space 24 and at the end of the movement in a vertical direction on the guide surface 16 in the form of a cochlea And the ice making ice bumps against the guide surface 16 moves in the vertical direction simultaneously with the pressure toward the spinning nozzle 15 while forming a spiral trajectory. As shown in Fig. 2, the guide surface 16 has a low point (h2) on the side of the ice-making tube of the ice-making tube and a spiral trajectory with a constant width (b) And has an inclination gradually lowered to a low point (h2). Therefore, the ice-making ice being moved is fed with an inclination toward the low point h2 with a constant width "b" while abutting against the high point h1 of the guide surface 16 of a certain width "b" the ice making ice is discharged from the outlet 15 positioned in the vertical direction to the outlet h2.

The guide surface 16 having a spiral rotational locus has the same diameter as the concentric circle but forms an inclination gradually lowering from the high point h1 of the initial stage of the ice-making ice contact to the low point h2 of the terminal end of the ice contact, It moves while drawing the trajectory of the spiral.

The guiding surface 16 is moved by the horizontal length of a predetermined section extending in the direction of the auger shaft 21 and then is drawn while drawing a spiral locus that is displayed in the vertical direction and the auger 22 of the auger 2, B " and " b " in the case where the helical blade 22 is reduced to two, the guide surface 16 is formed by one width An extended width can be formed.

As shown in Fig. 3, the auger tooth 22 is provided in contact with the inner peripheral surface 14 of the ice-making cylinder 10 with a minute gap therebetween. A groove 22a is formed at an end of the auger 22, The cobalt and nickel alloy based welding material 22b having good wear resistance and corrosion resistance can be formed in the groove 22a. Cobalt alloy type welding rod is a weldable material mainly made of cobalt and mixed with carbon, silicon, manganese, chromium and the like. After the welding material is melted and fused to the groove 22a and then coated, the welded portion can be post-processed to match the end shape of the Auger 22. Further, by coating the entire auger shaft 21 and the auger 22, it is possible to protect the coated portion of the welding material 22b from the outside.

On the other hand, the driven shafts 23 and 23a of the auger 2 can form two axial surfaces as shown in the figure. The bearings are mounted on the main shaft portion 26 and the driven shafts 23 and 23 23a may be provided with a bearing portion 7. In this case, The bearing member 7 can form a sealing member 72 mounted on the groove 74 as shown in Fig. The sealing member 72 can form a C-shaped insertion space 72a having one side opened, and the ring-like elastic member 73 can be inserted into the insertion space 72a.

Therefore, the ice-making cylinder 11 and the main shaft portion 23 of the drive unit 5 are formed on one side of the ice-making cylinder 10, and the subordinate shaft portions 23 and 23a of the auger shaft 21 are formed on the opposite side. And the bearing unit 7 can be assembled inside the ice tray 10 after the bearings 55 and the sealing member 72 are mounted on the inner and outer diameters.

As shown in FIG. 7, the cover portion 9 is provided on the outer side of the heat insulating cover portion 5, the ice-making block 7, and the driving portion 5 of all the embodiments described above to protect the inner ice- (9). 6, the evaporator tube 3 is disposed outside the evaporator tube 3, and the evaporator tube 3 is installed so as to be insulated from the outside, and the foam insulator 65 is provided on the outside of the evaporator tube 3, And a vacuum insulator 60 may be further included. 6, the vacuum heat insulator 60 included in the foam insulating material 65 of the heat insulating cover portion 6 of the present invention has the core material 61 of the flexible fiber laminate, An outer member 63 having a gas barrier layer covering the core held in a compressed state by the inner member, and an adsorbent 64. The inner member 62 is provided in a compressed state. The cladding 63 is formed to form the outer periphery of the vacuum insulating material and has a bag shape in which a constant width portion is joined by thermal welding from the ridgeline of a laminate film of the same size. The core material 61 was a laminate of inorganic fibers having no flexibility, which was not adhered or bonded by a binder or the like, and glass wool having an average fiber diameter of 4 탆 was used. Further, by using a laminate of an inorganic fiber material in the core material 61, the outgassing is reduced, so that the heat insulating performance is advantageously improved, but the invention is not limited thereto. For example, inorganic fibers such as ceramic fibers, rock wool, and glass wool other than glass wool may be used. Depending on the type of the core material 61, the inner member 62 may not be required. As the core material 61, in addition to the inorganic fiber material, an organic resin fiber material can be used. The laminate structure of the shell material 63 is a laminate film having at least three layers of a surface protective layer, a gas barrier layer, and a thermal welding layer. The surface protective layer is a resin film having a role of protecting the decompressed state from external impact such as piercing. A core member 61 of a flexible fiber laminate, an inner member 62 for holding the core member in a compressed state, and a gas barrier layer for covering the core member held in a compressed state by the inner member. (63), and an adsorbent (64). The encapsulant 63 is disposed to form an outer wall of the vacuum insulation material and has a bag shape in which a constant width portion is joined by thermal welding from the ridgeline of a laminate film of the same size. The core material 61 was a laminate of inorganic fibers having no flexibility, which was not adhered or bonded by a binder or the like, and glass wool having an average fiber diameter of 4 탆 was used. Further, by using a laminate of an inorganic fiber material in the core material 61, the outgassing is reduced, so that the heat insulating performance is advantageously improved, but the invention is not limited thereto. For example, inorganic fibers such as ceramic fibers, rock wool, and glass wool other than glass wool may be used. Depending on the type of the core material 61, the inner member 62 may not be required. As the core material 61, in addition to the inorganic fiber material, an organic resin fiber material can be used. The laminate structure of the shell material 63 is a laminate film having at least three layers of a surface protective layer, a gas barrier layer, and a thermal welding layer. The surface protective layer is a resin film having a role of protecting the decompressed state from external impact such as piercing.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, the technical scope of the present invention should be defined by the claims.

The present invention relates to a refrigerator and a refrigerator having a refrigerator and a refrigerator having a refrigerator and a refrigerator having a refrigerator and a refrigerator. A water supply port, 13: a spiral groove, 14: an inner circumferential surface, 15: an ejection nozzle, 16: a guide passage, 21: auger shaft, 22: auger, 22a: groove, 22b: welding material, 23, 23a: And a driving motor for driving the speed reducer and a driving motor for driving the driving motor, wherein the driving motor is driven by the driving motor, A bearing member, 54: fixing means, 72: sealing member, 74: groove portion, 72a: insertion space, 73:

Claims (1)

A freezing portion formed of an evaporator tube having a coolant inlet and outlet for collecting the coolant and circulating the coolant;
An auger formed in a spiral direction along an auger axis and rotating in an inner surface of the ice-making cylinder, the auger being formed on an axis of a horizontal axis in an ice-making space between the ice-making and passing helix;
One end of the auger shaft is formed with a groove to rotate the auger, a slave shaft portion constituting a shaft receiving portion inserted with a sealing member mounted with an elastic force is formed in the groove portion, and the other end is installed to transmit a driving force of the driving motor A driving unit having a main coaxial portion; And
An ice block formed on one end of the ice-making container to form an ice-making hole for discharging ice in a vertical direction after ice making and forming a helical guide surface on an inner circumferential surface;
/ RTI >
The helical guide surface
The ice-making ice is moved along the ice-making space in the ice-making space in the horizontal direction by the rotary pressure of the auger, and is gradually moved from the first position (h1) to the second position (h2) Is formed on the surface of the ice making chamber.

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