KR102137625B1 - Auger type ice machine - Google Patents

Abstract

Disclosed is an auger-type ice machine in which ice is guided while drawing a spiral trajectory after ice making,
An evaporation tube (3) having an ice-making tube (10) in a horizontal direction with a water supply port for supplying ice-making water, and an evaporation tube (3) integrally formed on the outer circumferential surface of the ice-making container (10) and having a refrigerant inlet and outlet for circulating refrigerant Ice section 1; A spiral blade 22 that rotates the inner surface of the ice tray is formed in a spiral direction along the auger shaft 21, and an ice-making space 27 is formed between the ice tray 10 and the spiral blade 22 in the horizontal direction. Auger (2) installed on the central axis; In order to rotate the auger (2), the driven shaft part (23) is formed to be idle at one end of the auger shaft (21), and the main shaft part (26) is installed to transmit the driving force of the drive motor (5) to the other end. A driving unit 5 formed of; And an ice block (10) which forms an ice outlet (15) to ice in one vertical direction after ice-making at one end of the ice machine (10) and extends the inner circumferential surface of the ice machine (10) but forms a spiral guide surface (16). 11); and the spiral guide surface provides an auger-type ice machine that draws a spiral trajectory with a slope from a high point (h1) to a low point (h2) while forming a constant width ("b").

Description

Auger type ice machine

The present invention relates to an auger type ice maker. In particular, it is an auger type ice machine in which nugget ice is extruded by forming an exit port in the vertical direction with respect to the horizontal auger axis, reducing the horizontal pressure of the extruded ice, improving durability, and simplifying the assembly structure. It relates to a reduced auger type ice maker.

The following are known as auger-type ice machines generally known.

Patent Publication No. 10-2003-62201,

A vertical ice tray, an auger installed on the same axis in the ice tray and augered by freezing on the same inner circumferential surface and continuously scraping the growing ice layer, and conveying it upward, a refrigerant pipe wound around and fixed to the outer periphery of the ice tray, the ice making In an auger-type ice machine having a pressure head fixedly installed on an upper side of a cylinder, when the ice scraped by the auger is pushed up to the pressure head and transferred to the inner circumferential surface of the ice cylinder, the ice is transported in the transport direction. The auger-type ice machine is formed by crossing the axial direction of the screw blade to prevent synchronous rotation with the auger while continuously compressing, and setting the crossing angle crossing in the axial direction of the spiral blade to 90 to 110 ㅀ. Is known,

Patent Publication No. 10-416944,

Vertical ice tray, auger installed coaxially in the ice tray, refrigerant pipe recommended in a spiral shape to the outer periphery of the ice tray, auger having a pressure head installed on the top of the ice tray on the auger shaft image of the auger In the expression ice machine, the auger becomes a main body portion and a spiral blade provided on the outer periphery of the main body portion, and the cross-sectional shape of the blade portion of the spiral blade is gradually thickened toward the base of the speech with the main body portion from the vertical edge of the blade. Auger type ice machine that is in the form of a truncated isosceles triangle, sets the thickness of the blade tip to 1 to 3 mm, and sets the taper angle of the upper surface portion from the blade tip to the main body portion to 2 to 8 mm, respectively, and the taper angle of the lower portion to 10 to 20 mm. Is known,

Utility Publication No. 20-1983-0000407,

In an ice maker that generates ice by cutting ice frozen by an evaporator of a freezer, and at the same time, this ice is fed into an extrusion head provided with an ice compression channel and compressed, thereby continuously extruding an ice column. From the side of the diaphragm blade toward the ice compression path, and in addition, from the inlet side to the outlet side of the ice compression path, gradually compress the width of the ice compression path, and press the compressed pieces of elastic material mounted on each of the diaphragm blades. An extrusion head for compressing ice in an ice maker is known,

Patent registration No. 20-0138409,

Compressor for compressing refrigerant, radiator for liquefying compressed refrigerant, evaporator for freezing ice through vaporization of refrigerant, water tank for supplying water to the evaporator, angle cutting ice formed in the evaporator into ice cubes of a certain size In an ice machine having an ice cutting unit and an ice storage unit for storing the cut ice, water generated from the ice cutting unit and the ice storage unit and drained through a high-end discharge pipe and water drained from the water tank are combined to form a heat sink inlet. It is known that a radiator cooling device of an ice maker that is introduced into the radiator and heat-exchanged through and then discharged to the outside through a radiating pipe outlet.

On the other hand, the conventional auger-type ice machine has a method in which the ice outlet is in the same direction as the auger's axial direction (vertical type, hereinafter referred to as a vertical type ice machine), and a method perpendicular to the auger axis direction (horizontal type) ,Hereinafter referred to as a horizontal ice maker). Vertical ice makers have multiple outlets, whereas horizontal ice makers with sideways have one outlet. When the vertical auger-type ice maker has a small capacity with a small amount of ice, the vertical type reduces the size of the evaporator in which the auger is located, as well as the size of the evaporator in which the auger is located, so the size of the ice particles to be ejected is reduced. It becomes unsuitable for use. In particular, in the case of a vertical ice maker, since the thrust load is equal to the sum of the ice resistance applied to the auger's spiral blade, the direction in which the load is applied is opposite to that of the ice, and the location where the most ice resistance is applied is ice pressure. It became the strongest side of the exit, and applied to the lateral direction of the auger shaft, that is, the radial load applied to the axial load, i.e. the thrust load, which corresponds to the spiral angle of the auger. Since it takes a lot of coaxial parts, it is difficult to apply an idling means (bearing) of sufficient capacity to the driven shaft part, so that the life of the entire ice maker is shortened due to wear.

On the other hand, since the horizontal ice maker constitutes one outlet opening on the side of the ice maker, the size of the ice particles that are released becomes larger than that of the vertical type having a plurality of outlets. Can be used as.

However, the horizontal ice maker has a greater force applied to the side of the auger shaft than the vertical ice maker, so the overall durability is weak, and parts are added to prevent this, and parts are also larger. Due to the poor performance, it was not possible to implement a compact ice maker original compact ice maker. In addition, there was a difference in the assembly structure between the vertical ice machine and the horizontal ice machine.

It is designed so as to arrange a plurality of outlets including an ice-making unit 1 such as a driving motor and auger, and a compression function after ice-making and ice-making through refrigerant circulation. Therefore, it can be said that since ice is compressed while coming in the direction of the auger shaft, the force applied in the right angle direction of the auger shaft (also called a radial load) is small.

The horizontal ice maker is designed to be arranged in the order of the auger-shaped ice-making section 1, the ice-cooling through refrigerant circulation and the compression function after de-icing, and the driving motor, so one ice-outlet in the direction perpendicular to the auger shaft Since the force applied in the right angle direction to the auger shaft increases as it moves out of the bay, the number of parts is increased to overcome this as a horizontal ice maker, and expensive parts are required, which increases the burden on manufacturing cost. Particularly, in the known horizontal ice maker (FIG. 10), the number of parts is small, and there is a possibility that the cost may be reduced, but there is a problem in that durability is reduced because it is manufactured without necessary parts corresponding to an eccentric load.

In addition, as a problem that could not be miniaturized in a horizontal ice maker, the inner and outer (preventing condensation) of the ice making container is wrapped with heat insulating material to achieve a cooling cycle (A) through refrigerant circulation consisting of an evaporator, a compressor, a condenser, and a capillary tube. Due to the arrangement, the size of the ice maker has become a problem.

The present invention mainly aims to improve the above problems, and to provide an auger-type ice machine capable of forming an ice-making container and an ice-blocking unit as one body.

The present invention reduces the cost by simplifying the parts and structures of the auger-type ice machine, and distributes the guide surface in which the horizontal movement pressure generated simultaneously with ice-making at the same time as ice-making is guided in the form of a cochlea to support the driving portion of the auger shaft. The present invention is to provide a horizontal auger-type ice machine with a simpler structure.

The present invention is a horizontal auger type ice machine, and is intended to prevent corrosion of a driving unit by preventing leakage of residual water after ice-making and the adhesion rate with the auger shaft surface.

In addition, the present invention is to provide a horizontal ice machine having a reinforcing structure for a driven shaft portion that is capable of applying a bearing having a sufficient capacity to the driving portion on the exit side where the movement pressure is most generated and, on the contrary, hardly applies force. do.

Accordingly, the present invention auger-type ice machine is intended to provide an assembly structure in which the auger integral ice-making structure is separated through the driven shaft portion.

Auger type ice machine of the present invention for achieving the above object,

An ice-making section comprising an ice-making tube in a horizontal direction with a water supply port for supplying ice-making water, and an evaporation tube integrally formed on the outer circumferential surface of the ice-making container and having a refrigerant inlet and outlet for circulating the refrigerant;

An auger which rotates an inner surface of the ice-making container is formed in a spiral direction along the auger shaft, and forms an ice-making space between the ice-making container and the auger and is installed on a horizontal central axis;

In order to rotate the auger, one end of the auger shaft forms a groove, and a driven shaft portion forming a water-reducing portion having an elastic force and a sealing member mounted therein is formed, and the other end is installed to transmit the driving force of the drive motor A driving unit forming a main coaxial unit; And

An ice block that forms a helical guide surface on an inner circumferential surface as well as forming an ice-out port to ice out in the vertical direction after ice-making at one end of the ice-making container;

Including,

The spiral guide surface,

Spiral contact surface in which ice-making ice is moved along the ice-out space by applying a pressing force in the horizontal direction from the ice-making space with the rotational pressure of the auger, and gradually lowering from the first position (h1) to the second position (h2) in this pressing direction. It can be achieved as an auger type ice machine characterized in that (hereinafter referred to as a contact surface as a contact surface abutting perpendicular to the ice-making container in the horizontal direction).

As described above, the so-called horizontal auger-type ice machine according to the present invention is very advantageous for miniaturization of the ice machine, and is formed by the appearance block between the auger and the main coaxial portion, so that it is less affected by the eccentric load and radial load of the auger. It is possible to prevent the abrasion of the blade and the ice-making container, disassembly of the driven shaft portion is simplified, and the eccentric load applied to the main shaft portion is improved to improve durability, thereby further improving the lifespan of a conventional auger-type ice machine.

The present invention improves durability by solidifying the overall auger-type ice maker by integrally forming an exit block at the base of the ice-making cylinder horizontally installed on the central axis, and assembling and disassembly are simplified by simplifying the structure, and can be optimized for miniaturization. It became.

In addition, according to the present invention, since ice is provided at the base end of the auger and a contact block of a certain width is integrally formed in the ice making container in the form of a cochlea so that the ice is guided in the vertical direction, smooth ice can be released, and a reducer is applied to the block. Since there is almost no thrust load and radial load applied to the auger shaft by assembling directly, there is no need to apply a separate bearing, etc., and the thrust is the same as a conventional vertical auger type ice machine by supporting only the reducer of the driving unit (main shaft) as a bearing. And it is possible to provide a sturdy drive that is less subjected to radial loads.

Moreover, in addition to the simple and robust construction of the drive shaft (driving unit), the load bearing of the driven shaft portion is reduced, so that only the bearing and sealing member can be applied to the driven shaft, and no additional structure is required, and only a snap ring (shaft fixing ring) Alternatively, it is possible to provide a low-cost auger type ice maker with simple fixing by using an inner diameter fixing ring), and simple assembly and improved unit cost.

In addition, since the guide surface formed like a cochlear in the horizontal direction is formed with a spiral inclination and is formed in an ice tray, it is possible to achieve an effect of greatly reducing the resistance to ice in the vertical direction, and to achieve smoothing.

Particularly, the present invention can integrally design an ice block having an ice outlet by integrally forming an ice block in an ice tray, thereby simplifying the structure, and also in assembly and disassembly. It has the advantage of realizing a very simple assembly structure by assembling and disassembling an integral auger structure only through a driven weight, assembling and disassembling a cover part on the outside, and screwing the driving part as a fastening structure to the exit block. .

In addition, as an improved sealing member on the inner circumferential surface of the exit block according to the present invention, the adhesion rate is increased to prevent leakage due to residual water generated after ice-making.

1 is a cross-sectional view of the auger type ice machine of the present invention,
Figure 2 is a longitudinal sectional view showing the guide surface of the auger type ice machine of the present invention,
3 is a view of another embodiment of the auger type ice machine auger of the present invention,
4 is a view of another embodiment of the auger type ice machine sealing member of the present invention,
5 is a cross-sectional view of the vacuum insulation material of the auger-type ice machine insulation cover portion of the present invention,
6 is a cross-sectional view of the auger ice-making tube of the present invention,
7 is a cross-sectional view of another embodiment of the auger type ice machine of the present invention,
8 is a schematic view of a conventional vertical auger type ice machine.

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

1 of the accompanying drawings is a cross-sectional view of the auger-type ice machine of the present invention, FIG. 2 is a longitudinal sectional view showing a guide surface formed in the ice-making machine of the auger-type ice machine of the present invention, and FIG. 3 is a view of another embodiment of the auger-type ice machine of the present invention, 4 is a view of another embodiment of the auger-type ice machine sealing member of the present invention, FIG. 5 is a cross-sectional view of the vacuum insulator of the auger-type ice machine insulation cover of the present invention, and FIG. 6 is a cross-sectional view of the auger-type ice machine of the present invention.

The auger-type ice machine of the present invention according to the drawings is largely composed of an ice-making unit 1, an auger 2, and a driving unit 5.

The ice making section 1 will be divided into an ice making box 10, an evaporation tube 3, and an insulating cover part 6.

The ice making container 10 is a cylindrical cylindrical body with both ends open, forming a water supply port 12, and the ice making space 27 is rotated while screws (22, hereinafter referred to as auger blades) rotate as described later. The forming auger 2 is installed in the horizontal direction. The auger blade 22 of the auger 2 may form a fine gap (see FIG. 7A) on the inner surface 14 of the ice making container 10.

The evaporation tube 3 is formed in close contact with the outer circumferential surface of the ice making container 10. The evaporation tube 3 may form a jacket-shaped refrigerant circulation space 31 in which a predetermined refrigerant is circulated and charged, and a predetermined cooling as known by forming a refrigerant inlet 32 and an outlet 34 As the refrigerant is circulated and supplied through the cycle (A), the outer circumferential surface of the ice making container 10 in contact with the evaporation tube 3 may be cooled. The evaporation tube 3 forming the refrigerant circulation space 31 may be implemented by winding a refrigerant circulation pipe through which refrigerant is circulated instead of a jacket type as shown in FIG. 6. As shown in FIG. 8, the evaporation tube 3 may form a partition 31a in a spiral direction to form a refrigerant circulation space 31.

The driving unit 5 may be provided with a reduction gear 52 inside, which is driven as a driving motor 51, and is formed by forming a main shaft 26 with a bearing 53 inside the reduction gear 52. A bearing 55 is installed in the driven shaft portion 23 of the driving portion 5. That is, the bearings 53 and 55 are installed between the main shaft portion 26 and the reduction gear 52, and between the driven shaft portion 23 and the inner circumferential surface 11 of the ice making container 10, respectively.

The heat insulation cover part 6 is formed on the outside of the evaporation tube 3 and is installed so that the evaporation tube 3 is insulated from the outside, and is made of a foam insulation 65 as shown in FIG. 5 (detailed description of the heat insulation cover part) Will be described later).

The ice-making container 10 may form an ice-blowing block 11 coupled with the driving unit 5. When the auger shaft 11 rotates the auger shaft 21 by applying a driving force as the drive motor 51 of the driving unit 5, as shown in FIG. 8, eccentric load (or eccentric load) due to the rotation of the auger shaft 21 Ice tray 10 to prevent the auger shaft 21 and the drive shaft 51 from the main shaft portion 26 (also referred to as the drive shaft) due to radial load), vibration, and wear of the ice tray 10 accordingly. ) Can be integrally formed.

The ice block 11 is formed on the inner circumferential surface of the ice making container 10, but may be formed to connect the driving unit 5 as one molded object integrally extended to the ice making container 10. Alternatively, the icing block 11 may be separately formed and assembled to one side of the ice making container 10. The ice-block 11 extends from the ice-making space 27 and can form an ice-out space 24 forming the ice-out port 15, and switches ice that has been iced and moved in the ice-making space 27 in the vertical direction. It is possible to form an exit port 15 to be released. The icing block 11 is installed so as to form and seal the groove portion 74 into which the sealing member 72 is inserted so as not to leak residual ice between the main shaft 26 of the auger shaft 21. That is, at least one groove portion 74 contacting the auger shaft 21 surface is formed on the ice block 11 installed as described below, and the sealing member 72 is attached to the groove portion 74. In addition, the driving unit 5 is fixed radially using a fixing means (not shown). The ice tray 10 and the icing block 11 integrally have eccentric flow of the auger shaft 21 generated by installing an impeller of only a vertical surface on the auger shaft, and accordingly wear of the ice cylinder 10, leakage of the sealing portion, etc. Will be able to improve reliably.

The auger (2) is composed of an auger shaft (21) constituting the central axis of the rotating shaft installed in the horizontal direction, and a spiral auger blade (22) integrally formed on the outer circumferential surface of the auger shaft (21), Both ends consist of a driven shaft part 23 that is idling and a main shaft part 26 that receives a driving force from the auger shaft 21. The driven shaft portion 23 is provided with a water-reducing portion 7 forming a groove portion 74 in which a sealing member 74 is mounted so that the bearing 55 is idling, and the main shaft portion 26 is a shaft in the reduction gear 52 Directional bearing 53 is provided.

In addition, the auger (2) is formed with a spiral auger blade (22) formed on the auger shaft (21) between the ice tray (10) while rotating and contacting the inner circumferential surface of the ice tray (10). (27) is formed, and a guide surface 16 forming a constant width ("b") similar to the cochlea on the inner peripheral surface is formed at the end of the ice-making space 27 (refer to FIGS. 1 and 2).

The guide surface 16 is moved along the exit space by receiving ice pressing force in the horizontal direction from the ice making space with the rotational pressure of the auger, and gradually moving from the first position (h1) to the second position (h2) in this pressing direction. It can form a lowered helical contact surface.

The guide surface 16 is horizontally moved in the ice-making space 27 under the rotational pressure of the ice 22, and guided in the ice-making space 24 and gradually reduced to a constant width (“b”). As it draws, it is contacted in the vertical direction in response to the horizontal movement, and the ice ice hitting the guide surface 16 is pushed in the vertical direction toward the exit port 15 formed in the vertical direction while forming a spiral trajectory. As shown in FIG. 2, the guide surface 16 has a height (step) of a high point (h1) at the beginning of forming the spiral trajectory at the same time that the exit port 15 side of the ice block of the ice-making bin becomes a low point (h2). It has a gradient that gradually decreases from the high point (h1) to the low point (h2). Therefore, the moving ice-making ice is moved while forming a spiral trajectory from the high point h1 of the guide surface 16 toward the low point h2, and the ice-making ice is formed at the exit hole 15 located vertically at the end of the low point h2. This is served.

The guide surface 16 having a spiral movement trajectory has the same diameter in a concentric circle, but forms a slope that gradually decreases from the high point h1 at the beginning of contact with the ice-making ice to the low point h2 at the end of contact, so that the horizontally moved ice is at its pressure. By this, it is moved while drawing a spiral trajectory and is released at the end of the movement.

The guide surface 16 is moved by a horizontal length of a predetermined section extending in the direction of the auger shaft 21 and then unfolded while drawing a spiral trajectory ejected in the vertical direction, and the auger blade 22 of the auger 2 is a single spiral In the case of forming a guide surface 16 of one uniform width ("b") corresponding to this, but when the organic 22 is two lines, by two widths ("b" + "b") An extended width can be formed.

As shown in FIG. 3, the auger blade 22 is installed with a micro clearance on the inner circumferential surface 14 of the ice making container 10, and forms a groove 22a at its end, where the auger blade 22 is formed. ) In order to reinforce the life of the groove, a welding material 22b of a cobalt and nickel alloy series having good abrasion resistance and corrosion resistance may be formed in the groove 22a. A cobalt alloy-based welding rod is a weldable material produced by mixing cobalt as a main component and mixing carbon, silicon, manganese, and chromium. After the welding material is melted and fused to the grooves 22a and coated, the welded portion suitable for the end shape of the auger 22 may be post-processed. Furthermore, by coating the entire auger shaft 21 and the auger blade 22, the coating portion of the welding material 22b can be protected from the outside.

On the other hand, the driven shaft portion 23, 23a of the auger 2 may form a two-stage shaft surface as shown, the main shaft portion 26 is equipped with a bearing, respectively, the driven shaft portion 23 (( 23a) can be formed in one of the water-reducing portion (7). The water-reducing portion 7 may form a sealing member 72 mounted to the groove portion 74 as shown in FIG. 4. The sealing member 72 may form a C-shaped insertion space 72a with one side open, and a ring-shaped elastic member 73 may be inserted into the insertion space 72a.

Therefore, on the one side with respect to the ice making container 10, the main shaft part 23 of the driving block 5 is formed on the one side, and the driven shaft part 23 and 23a of the auger shaft 21 are formed on the opposite side. A water-reducing portion 7 for supporting is formed, and the water-reducing portion 7 can be assembled inside and after the bearing 55 and the sealing member 72 are mounted on inner and outer diameters.

7 of the accompanying drawings is a cross-sectional view of another embodiment of the auger-type ice machine of the present invention.

Some configurations of the horizontal auger-type ice machine of the present invention shown in this embodiment are the same as the auger-type ice machine shown and described in FIG. 1, and thus redundant description is omitted.

The auger-type ice machine of the present invention according to the drawings is largely composed of an ice-making unit 1, an auger 2, and a driving unit 5. The ice making part 1 is composed of an ice making container 10, an evaporation tube 3, and an insulating cover part 6.

The ice making container 10 is a cylindrical cylindrical body with both ends open, forming a water supply port 12, and the ice making space 27 is rotated while screws (22, hereinafter referred to as auger blades) rotate as described later. The forming auger 2 is installed in the horizontal direction. The auger blade 22 of the auger 2 may form a fine gap on the inner surface 14 of the ice making container 10.

The evaporation tube 3 is formed in close contact with the outer circumferential surface of the ice making container 10. The evaporation tube 3 may form a jacket-shaped refrigerant circulation space 31 in which a predetermined refrigerant is circulated and charged, and a predetermined cooling as known by forming a refrigerant inlet 32 and an outlet 34 As the refrigerant is circulated and supplied through the cycle (A), the outer circumferential surface of the ice making container 10 in contact with the evaporation tube 3 may be cooled. The evaporation tube 3 forming the refrigerant circulation space 31 may be implemented by winding a refrigerant circulation pipe through which refrigerant is circulated instead of a jacket type as shown in FIG. 6. As shown in FIG. 8, the evaporation tube 3 may form a partition 31a in a spiral direction to form a refrigerant circulation space 31.

The driving unit 5 may be provided with a reduction gear 52 inside, which is driven as a driving motor 51, and is formed by forming a main shaft 26 with a bearing 53 inside the reduction gear 52. A bearing 55 is installed in the driven shaft portion 23 of the driving portion 5. That is, the bearings 53 and 55 are installed between the main shaft portion 26 and the reduction gear 52, and between the driven shaft portion 23 and the inner circumferential surface 11 of the ice making container 10, respectively.

The heat insulation cover part 6 is formed on the outside of the evaporation tube 3 and is installed so that the evaporation tube 3 is insulated from the outside, and is made of a foam insulation 65 as shown in FIG. 5.

The ice-making container 10 may form an ice-blowing block 11 coupled with the driving unit 5. When the auger shaft 11 rotates the auger shaft 21 by applying a driving force as the drive motor 51 of the driving unit 5, as shown in FIG. 8, eccentric load (or eccentric load) due to the rotation of the auger shaft 21 Ice tray 10 to prevent the auger shaft 21 and the drive shaft 51 from the main shaft portion 26 (also referred to as the drive shaft) due to radial load), vibration, and wear of the ice tray 10 accordingly. ) Can be integrally formed.

The ice block 11 is formed on the inner circumferential surface of the ice making container 10, but may be formed to connect the driving unit 5 as one molded object integrally extended to the ice making container 10. Alternatively, the icing block 11 may be separately formed and assembled to one side of the ice making container 10. The ice-block 11 extends from the ice-making space 27 and can form an ice-out space 24 forming the ice-out port 15, and switches ice that has been iced and moved in the ice-making space 27 in the vertical direction. It is possible to form an exit port 15 to be released. The icing block 11 is installed so as to form and seal the groove portion 74 into which the sealing member 72 is inserted so as not to leak residual ice between the main shaft 26 of the auger shaft 21. That is, at least one groove portion 74 that contacts the auger shaft 21 surface is formed on the ice block 11 installed in this way, and the sealing member 72 is mounted on the groove portion 74, and the driving portion 5 is also provided. ) Is radially fixed using a fixing means (not shown). The ice tray 10 and the icing block 11 integrally have eccentric flow of the auger shaft 21 generated by installing an impeller of a conventional vertical surface only to the auger shaft, resulting in wear of the ice cylinder 10, leakage of the sealing portion, etc. You can surely improve

In addition, the auger (2) is formed with a spiral auger blade (22) formed on the auger shaft (21) between the ice tray (10) while rotating and contacting the inner circumferential surface of the ice tray (10). (27) is formed, and at the end of the ice-making space 27, a guide surface 16 having a constant width ("b") is formed to draw a spiral trajectory similar to the cochlea on the inner circumferential surface (see FIGS. 1 and 2). ).

The guide surface 16 is horizontally moved in the ice-making space 27 under the rotational pressure of the august 22, and guided in the ice-covering space 24. At the end of the movement, the ice-making surface is impinged in the vertical direction on the guide surface 16 in the form of a cochlea. In addition, the ice ice hitting the guide surface 16 forms a spiral trajectory and moves in the vertical direction at the same time as being pressed toward the exit port 15 side. As shown in FIG. 2, the guide surface 16 has a certain width (“b”) and a spiral trajectory at the same time that the exit port side of the ice block of the ice-making bin becomes a low point (h2), but at a high point (h1). It has a slope that gradually decreases to the low point (h2). Therefore, the moving ice-making ice is transported with an inclination toward the low point h2 with a constant width ("b") while being in contact with the high point h1 of the guide surface 16 of a constant width ("b") in a vertical direction. Ice is iced from the ice outlet 15 located in the vertical direction at h2).

The guide surface 16 having a spiral rotational trajectory has the same diameter in a concentric circle, but it forms an inclination that gradually decreases from the high point h1 at the beginning of contact with the ice-making ice to the low point h2 at the end of contact, so that the horizontally moved ice is at its pressure. By moving while drawing a spiral trajectory, it is released at the same time.

The guide surface 16 is moved by a horizontal length of a predetermined section extending in the direction of the auger shaft 21 and then unfolded while drawing a spiral trajectory ejected in the vertical direction, and the auger blade 22 of the auger 2 is a single spiral In the case of forming a guide surface 16 of one constant width ("b") corresponding to this, but when the organic 22 is two lines, it is extended by two widths ("b" + "b"). Can form a wide width.

As shown in FIG. 3, the auger blade 22 is installed with a micro clearance on the inner circumferential surface 14 of the ice making container 10, and forms a groove 22a at its end, where the auger blade 22 is formed. ) In order to reinforce the life of the groove, a welding material 22b of a cobalt and nickel alloy series having good abrasion resistance and corrosion resistance may be formed in the groove 22a. A cobalt alloy-based welding rod is a weldable material produced by mixing cobalt as a main component and mixing carbon, silicon, manganese, and chromium. After the welding material is melted and fused to the grooves 22a and coated, the welded portion suitable for the end shape of the auger 22 may be post-processed. Furthermore, by coating the entire auger shaft 21 and the auger blade 22, the coating portion of the welding material 22b can be protected from the outside.

On the other hand, the driven shaft portion 23, 23a of the auger 2 may form a two-stage shaft surface as shown, the main shaft portion 26 is equipped with a bearing, respectively, the driven shaft portion 23 (( 23a) can be formed in one of the water-reducing portion (7). The water-reducing portion 7 may form a sealing member 72 mounted to the groove portion 74 as shown in FIG. 4. The sealing member 72 may form a C-shaped insertion space 72a with one side open, and a ring-shaped elastic member 73 may be inserted into the insertion space 72a.

Therefore, on the one side with respect to the ice making container 10, the main shaft part 23 of the driving block 5 is formed on the one side, and the driven shaft part 23 and 23a of the auger shaft 21 are formed on the opposite side. A water-reducing portion 7 for supporting is formed, and the water-reducing portion 7 can be assembled inside and after the bearing 55 and the sealing member 72 are mounted on inner and outer diameters.

As shown in FIG. 7, the cover part 9 is a cover part for protecting the internal ice maker or for insulating the outside of the heat insulating cover part 5, the ice block 7 and the driving part 5 of all the above-described embodiments. (9) can be implemented. That is, the insulation cover portion 6 of the auger type ice machine of the present invention is formed on the outside of the evaporation tube 3 as shown in FIG. 6 and installed so that the evaporation tube 3 is insulated from the outside, and the foam insulation 65 In addition to being made of a vacuum insulation material 60 may be further provided. That is, as shown in FIG. 6, the vacuum insulating material 60 included in the foam insulating material 65 of the heat insulating cover part 6 of the present invention comprises the core material 61 of the fibrous laminate having flexibility and its core material. It consists of an inner material (62) for holding in a compressed state, a shell material (63) having a gas barrier layer covering the core material held in a compressed state by the inner material, and an adsorbent (64). The outer shell 63 is arranged to form the outer periphery of the vacuum insulation material, and is made of a bag shape in which a constant width portion is bonded by heat fusion from a ridge of a laminate film of the same size. As the core material 61, a glass wool having an average fiber diameter of 4 µm was used as a laminate of inorganic fibers having flexibility that is not adhered or bound by a binder or the like. In addition, since the outgas is reduced by using a laminate of an inorganic fiber material for the core material 61, it is advantageous in terms of thermal insulation performance, but is not particularly limited to this. For example, inorganic fibers such as ceramic fibers, rock wool, and glass fibers other than glass wool may be used. In addition, depending on the type of the core material 61, the inner material 62 may not be required. For the core material 61, an organic resin fiber material can be used in addition to the inorganic fiber material. About the laminate structure of the shell material 63, it is set as the laminate film which has at least 3 layers of a surface protection layer, a gas barrier layer, and a heat welding layer. The surface protective layer is made of a resin film having a role of protecting the depressurized state from external impact such as stabbing. The core material 61 of the fibrous laminate having flexibility, the inner material 62 for holding the core material in a compressed state, and an outer covering material having a gas barrier layer covering the core material kept in a compressed state by the inner material (63), and a vacuum insulating material 60 made of the adsorbent 64 is further provided. The outer shell 63 is arranged to form the outer periphery of the vacuum insulation material, and is made of a bag shape in which a constant width portion is bonded by heat fusion from a ridge of a laminate film of the same size. As the core material 61, a glass wool having an average fiber diameter of 4 µm was used as a laminate of inorganic fibers having flexibility that is not adhered or bound by a binder or the like. In addition, since the outgas is reduced by using a laminate of an inorganic fiber material for the core material 61, it is advantageous in terms of thermal insulation performance, but is not particularly limited to this. For example, inorganic fibers such as ceramic fibers, rock wool, and glass fibers other than glass wool may be used. In addition, depending on the type of the core material 61, the inner material 62 may not be required. For the core material 61, an organic resin fiber material can be used in addition to the inorganic fiber material. About the laminate structure of the shell material 63, it is set as the laminate film which has at least 3 layers of a surface protection layer, a gas barrier layer, and a heat welding layer. The surface protective layer is made of a resin film having a role of protecting the depressurized state from external impact such as stabbing.

The present invention has been described with reference to the embodiment shown in the drawings, but this is only exemplary, and those skilled in the art to which the art pertains may have various modifications and other equivalent embodiments. Therefore, the technical protection scope of the present invention should be defined by the claims.

1: ice-making section, 2: auger, 3: evaporation tube, 4: bearing, 5: driving section, 6: insulating cover section, 7: water-reduction section, 9: cover section, 10: ice tray, 11: ice block, 12: Water supply port, 13: Spiral groove, 14: Inner circumferential surface, 15: Outlet port, 16: Guide surface, 21: Auger shaft, 22: Organ, 22a: Home, 22b: Welding material, 23, 23a: Follower shaft, 24: Extrusion space, 25: guide vane, 26: main shaft, 27: deicing space, 28: guide surface, 29: exit opening, 31: refrigerant circulation space, 32: entrance, 34: exit, 51: driving motor, 52: reduction gear, 53: bearing, 54: fixing means, 72: sealing member, 74: groove, 72a: insertion space, 73; ring-shaped elastic member,

Claims (1)

An ice-making section comprising an ice-making tube in a horizontal direction with a water supply port for supplying ice-making water, and an evaporation tube integrally formed on the outer circumferential surface of the ice-making container and having a refrigerant inlet and outlet for circulating the refrigerant;
An auger installed on a horizontal central axis by forming an ice-making space between the ice-making cylinder and the spiral blade;
In order to rotate the auger, a bearing is formed between the inner circumferential surface of the ice-making cylinder and a driven shaft with a sealing member, and the other end is formed with a driven shaft that is installed to transmit driving force of the driving motor; And
An ice block that forms a helical guide surface on an inner circumferential surface as well as forming an ice-out port to ice in one vertical direction at one end of the ice-making container;
Including,
The driving unit,
A water-reducing portion forming an open C-shaped insertion space and forming a groove portion in which a sealing member having an elastic member inserted therein is mounted;
Including,
The spiral guide surface,
The ice-making ice receives a pressing force in the horizontal direction from the ice-making space with the rotational pressure of the auger and draws a spiral trajectory along the ice-making space, and this trajectory is the width from the first position (h1) in the pressing direction to the second position (h2) ("b") and form a helical contact surface that gradually lowers,
The auger-type ice machine is characterized in that the forming the groove is fused to the welding material at its end.

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