KR20030069462A - Auger type ice maker - Google Patents

Abstract

Beta ice containing water can be inhibited from entering the storage as much as possible, thereby significantly shortening the start time for the normal ice making operation in which hard ice columns are formed by complete compression. A hard ice column pushed out of the compression passage hits the ice cutting edge, and the auger type is provided with a pressurizing head capable of producing high quality ice chunks with stable quality without cracking or cracking the edges of the ice chunks formed in the shape of chips. Provide an ice maker.

In the auger ice maker, the inclination angle of the outwardly inclined ice cutting part 6 provided on the upper side of the compression passage 5 of the pressure head 1 is set to 35 to 45 degrees. Moreover, the connecting head 7 which connects the compression path 5 and the ice cut | disconnected part 6 is radially inward from the passage surface 5-1 of the compression path 5 whose cross section is recessed outwardly substantially. 0.5-1.5 mm smaller, and the connection head 7 is recessed one step lower radially inward than the passage surface 5-1, thereby making it possible to stably and continuously produce high-quality ice without cracks or cracks. I could do it.

Description

Auger Ice Maker {AUGER TYPE ICE MAKER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an auger ice machine, and particularly, to remove most of the water by gradually compressing ice containing water that has been pushed up and transported by an auger disposed coaxially in the ice making machine. It is related with the improvement of the pressurizing head which produces | generates an ice column, and cut | disconnects this ice column to chip shape, and makes a mass of ice.

Background Art Conventionally, in this kind of pentagram ice maker, various pressurized heads have been proposed and known.

For example, a pressure head known from Japanese Patent Application Laid-open No. Hei 8-189736 or the like has a plurality of compression ribs extending radially from the outer circumference of the main body portion consisting of a bearing that rotatably supports the upper end of the auger in an axial direction. By forming a compression path, the cross section is concave outwardly between each of these compression ribs, and an outwardly inclined ice cut portion connected through a connecting head extending vertically to the upper side of the compression path is formed.

By the way, in this type of auger ice maker, when the predetermined amount of the ice storage part in which the chip-shaped ice mass is stored reaches a predetermined amount, the ice making operation is temporarily stopped, and the ice mass is discharged. If the amount of storage decreases by a predetermined amount, the ice-making operation is started (resumed) and the intermittent ice-making operation of sending the chip-shaped ice mass to the ice storage unit is repeated. The ice layer which grows frozen on the inner circumferential surface is pushed upward while being scraped by the auger while being soft, which is not produced to its original hardness, and introduced into the compression passage of the pressure head.

Thus, the ice introduced into the compression passage is pushed out through the compression passage with little or no ice, as illustrated in Fig. 3 (a), in the form of soft beta ice. This is inevitably somehow avoided at the beginning of the ice making operation of this kind of auger ice maker.

In addition, the generation of soft beta ice due to poor compression causes the ice tray to cool completely below the freezing point by the coolant pipe of the outer circumference to grow an ice layer having an original hardness on the inner circumferential surface of the ice tray, and the hardly grown ice layer As it is scraped off, it continues to be pushed up to the upper pressure head and continues until it is transported.

That is, until the large pressing force (lift) of the ice by the auger is sent to the compression passage of the pressurized head and the compression path necessary to remove most of the water from the ice is obtained, Ice is pushed out.

In this way, when soft beta ice caused by poor compression is pushed out of the compression passage and enters the ice storage unit, it adheres to the surface of the high-quality ice mass stored in the ice storage unit, and deteriorates the quality of the ice mass. In the worst case, the soft beta ice that has flowed into the storage unit may freeze, creating a blockage of ice, and causing a state of non-icing.

The present invention has been made in view of such a conventional situation, and an object thereof is to suppress as much as possible the entry of the beta ice containing water generated at the beginning of the ice making operation to the storage unit, and most of the It is possible to greatly shorten the start-up time to the normal ice making step in which the hard ice column with water is removed, and furthermore, the ice mass generated in the shape of chips by the hard ice column being pushed out from the compression passage impacting the ice cutting unit. It is to provide an auger ice maker having an improved pressure head to produce a high quality ice mass of stable quality that does not crack or crack the edge of the.

BRIEF DESCRIPTION OF THE DRAWINGS The example of embodiment of the pressurizing head in the auger ice machine of this invention is shown, a is a perspective view, b is a b-b longitudinal cross-sectional view of the same figure,

2 is an enlarged cross-sectional view taken along line II-II of FIG. 1A;

3 is a longitudinal sectional view showing an example of the overall configuration of an auger ice maker manufactured by assembling the pressure head;

Figure 4 is an enlarged cross-sectional view of the main portion showing the step-by-step process of the beta ice is pushed out of the compression passage in the initial stage of the ice-making operation of the auger ice maker.

5 is a normal ice operation of the auger ice maker, the hard ice column extruded from the compression passage, the upper ice cut portion is cut into a chip-shaped ice chunk, the chip-shaped ice chunk is ice An enlarged longitudinal sectional view of the main portion showing the step of pushing out along the outward inclination of the cut portion.

♣ Explanation of symbols for main part of drawing ♣

1: Pressure head 1-1: Main body

1-2: Compression rib 1-20: Long length rib

1-21: Short length rib 2: Ice bin

3: refrigerant pipe 4: auger

5: compression passage 5-1: passage surface

6: ice cutting part 7: connection head

8: inner corner 9: upper head

In order to achieve the object, the present invention provides a vertical ice tray, an auger arranged coaxially within the ice tray, a refrigerant pipe closely wound on the outer circumference of the ice tray, and spirally wound on an upper side of the ice tray. In the auger ice maker provided with the pressurization head arrange | positioned, the inclination angle of the outwardly inclined ice cut part provided in the upper side of the compression path of the pressurization head shall be set to 35-45 degrees, Preferably it is 40 You can set it to °.

Moreover, the diameter of the upper head part of the pressurizing head which has the said ice cut part is set to 27-37 mm.

In addition, a plurality of compression ribs protruding radially radially from the outer circumference of the main body portion forming the compression passages substantially outwardly in the axial direction and extending in the axial direction (up and down direction) have an axial full length of the main body portion. It consists of a long length rib projecting at equal intervals in the circumferential direction with a length up to, and a short length rib projecting with a length shorter than the rib between the long length rib, the length of the long length rib to 60 ~ 64mm And the length of a short length rib shall be set to 23-27 mm.

Further, the area of the transverse opening of the compression passage in which the cross section is formed to be concave outwardly by the long length rib and the short length rib is set to 52 to 58%.

Moreover, in this invention, the connection head part which connects the said compression path and the ice cut | disconnected part is formed 0.5-1.5 mm smaller radially inward than the passage surface of the compression passage which the cross section opens concave outwardly, and is smaller than the connection surface. The part is recessed one step lower in the radial direction, and preferably 1 mm is made smaller.

An embodiment of the present invention will be described with reference to the drawings.

Fig. 1 shows an example of an embodiment of the pressurizing head 1 in the auger ice maker of the present invention, and Fig. 3 shows the pressurizing head 1 fixedly placed on the upper side of the ice maker 2, It is a longitudinal cross-sectional view which shows an example of the whole structure of the produced auger ice machine.

The auger ice maker cools the ice maker 2 to below the freezing point by inserting and circulating a reduced pressure refrigerant into the refrigerant pipe 3 that is in close contact with the outer circumference of the ice maker 2 and is fixed in a spiral shape. (2) The ice-making water flowing into the ice is frozen on its inner circumferential surface, and the ice layer growing by the ice is pushed upward while being scraped off by the auger (4) and transported to the compression passage (5) of the pressure head (1). By introducing and completely compressing (dehydrating) the passage 5, most moisture is adjusted to a hard ice column which is removed, and the ice column is pushed out of the compression passage 5 and the upper ice cut portion 6 ), The force in the outward direction is added to form an ice cube X cut into a chip shape of an appropriate size, and the ice block X is to be stored in the storage unit P. As shown in FIG.

The pressurizing head 1 protrudes radially radially from the outer periphery of the hollow cylindrical main-body part 1-1 which consists of a bearing rotatably axially supporting the upper end small diameter shaft part of the auger 4 mentioned later, and extends axially. By providing a plurality of compression ribs 1-2 to be formed, a compression passage 5 is formed between the compression ribs 1-2 so that the cross section is concave outwardly in an outward direction, and the upper portion of the compression passage 5 is formed. On the side, an outwardly inclined ice cut part 6 connected via a connection head 7 extending vertically with a predetermined outer diameter is formed.

And between the long rib (1-20) and the long rib (1-20) protruding the compression rib (1-2) to the length across the axial full length of the main body (1-2) The length from the connecting head 7 is formed by short length ribs 1-21 which protrude in the axial direction with a length shorter than the length of the ribs 1-20, and both ribs 1-20 and 1 The compression passage 5 is formed between -21).

Further, by forming the lower ends of the ribs 1-20 and 1-21 in the shape of thin ends, the compression passage 5 faces the transverse opening area upward in the range in which the tip is formed thin. Is gradually reduced.

And in this invention, setting the inclination-angle (theta) of the ice cutting part 6 of the press head 1 in the range of 35-45 degrees is important at the point which establishes this invention.

For this reason, when the inclination angle θ is 35 ° or less, at the beginning of the ice making operation of the ice maker, the poorly compressed soft beta ice N pushed out from the compression passage 5 of the pressure head 1 is received. This is because not only the entry into the storage portion P can be prevented, but also the shortening of the start time that starts quickly at the stage where the hard column of ice M is generated can not be achieved. That is, by reliably receiving the soft beta ice (N), while reducing the amount of beta ice (N) entry into the storage unit (P), the ice is completely compressed to the original compressed state to remove most of the water This is because the inside of the compression passage 5 cannot be started in a short time. When the angle of inclination θ exceeds 45 °, the above-mentioned problem caused by the beta ice N can be completely solved. The ice machine starts with a normal ice state, and most of the water is removed to form a hard ice column ( This is because when M) is pushed out from the compression passage 5 and cut into chips of a suitable size, smooth cutting is not obtained and cracking or the like may occur.

Therefore, in the present invention, the regular compression to reduce the amount of beta ice (N) entry into the storage portion (P), and remove most of the water from the ice in the compression passage (5) to create a hard ice column Since it is possible to start quickly in a state, it is important to set the inclination angle θ of the ice cut part 6 to 35 to 45 degrees, preferably 40 degrees.

Further, in the present invention, the connecting head 7 is formed smaller in the range of the dimension L ₁ of 0.5 to 1.5 mm in the radially inward direction than the passage surface 5-1 of the compression passage 5. It is important at the point which establishes this invention by making it recessed one step lower radially inward than the surface 5-1.

For this reason, when the dimension L ₁ is 0.5 mm or less, the hard ice column M pushed out from the compression passage 5 collides with the ice cut portion 6 and along the outward inclination of the ice cut portion 6. This is because when the chip is cut outward and pushed out along the slope again, the inner edge 8 of the cut ice mass X may break in contact with the connection head 7 extending vertically. When the dimension L ₂ exceeds 1.5 mm, there is almost no worry that the edge 8 of the cut ice mass X sticks and cracks, so that the thickness itself of the connection head 7 is too large. This is because there is a risk of becoming thinner and problematic in terms of strength.

In the present invention, the length L ₂ of the long length ribs 1-20 forming the plurality of compression passages 5 on the outer circumference of the main body is in the range of 60 to 64 mm, and the short length ribs 1 to 1 are used. The length L ₃ of 21) may be set in a range of 23 to 27 mm, respectively.

In addition, the diameter (L ₄₎ at the top of the head portion 9 having the ice cut (6) is to be set in the range of 27~37㎜. In addition, the diameter L ₄ of the upper head 9 is small when the above-described inclination angle θ of the ice cutting unit 6 is set at a large angle in a range of 35 to 45 °, and a small angle. If set to, it is sufficient to increase the relationship.

In addition, the transverse opening area at the top exit side of the compression passage 5 is set in the range of 52 to 58%.

The ice maker 2 consists of a stainless steel cylindrical tube installed perpendicularly by a bolt fastener etc. on the drive housing 11 via the support body 10 fixedly fitted to the lower side, The inlet 12 and the outlet 13 of the ice-making water are attached to the lower side, and the inlet 12 is filled with the ice-making water up to a predetermined level in the ice making container 2, and the predetermined level is constantly Ice-making water is supplied so that it may be maintained, and the outlet 13 will drain ice-making water to the outside when the ice-making water is changed.

In addition, the upper side of the ice making container 2 is a bolt fastener in the state in which the press head 1 is fitted in its entirety except the upper head part 9 and the connection head part 7 which have the ice cutting part 6, and are fitted. It is formed so as to be fixedly, and is mounted in the state in which the pressing head 1 was fitted in the ice making container 2 in this way, the long length rib 1-20 of this pressing head 1, and The compression path 5 in the up-down direction is formed by the short length ribs 1-21 and the ice making cylinder 2.

The refrigerant pipe 3 is wound in a spiral shape so as to be in close contact with the outer surface of the ice making container 2, and then fixed by soldering or the like, and the reduced pressure refrigerant introduced from the refrigerant inlet 3-1 is discharged from the refrigerant outlet 3-2. An evaporator which serves to cool the ice maker 2 to below the freezing point by evaporating while flowing to the side, and is made of a suitable metal pipe such as steel having high thermal conductivity, and wound around the outer circumference of the ice maker 2 in a spiral shape. It attaches to the ice-making cylinder 2 by soldering so that the helical clearance existing between the ice-making cylinder 2 along a spiral line may be completely filled by the solder 14.

In this connection, in the present embodiment, this soldering is performed by so-called quenching soaking in a furnace in which the welded welding agent is stored, so that the welding material 14 is quickly introduced into the spiral gap, and the gap is completely made. The outer surface is covered by the welding film 15 by curing the metal so as to be filled and attaching and hardening the welding material on the outer surface of the refrigerant pipe 3.

The auger 4 consists of a main body part 4-1 and a spiral blade 4-2 provided on the outer circumferential surface of the main body part 4-1 with a predetermined spiral pitch, and the main body part 4-1. The small diameter shaft part 4-10 of the upper end is axed by the bearing 16 which fits in the axial center hole of the main-body part 1-1 of the pressurizing head 1 arrange | positioned fixedly at the upper end side of the ice-making cylinder 2. At the same time, the small-diameter shaft portion 4-11 at the lower end thereof is axially supported by a bearing 17 fitted into the axial hole of the support 10, so that the small diameter shaft portion 4-11 is rotatably assembled to the shaft center in the ice making cylinder 2. To be deployed.

Moreover, the small diameter shaft part 4-11 of the lower end which has the spline 18 is connected to the output shaft 20 of a drive motor by the spline connecting part 19, and predetermined | prescribed by the power from this output shaft 20 by predetermined | prescribed power. The scraped ice as shown in Fig. 3 is scraped of the ice layer which is rotated at the rotational speed (rpm) by the end of the blade 4-2 of the ice layer growing on the inner circumferential surface of the ice making machine 2 by freezing. It accumulates sequentially in the spiral space 21 between the blades 4-2, and is pushed upward toward the pressurized head 1 to be conveyed.

Next, the auger-type ice machine comprised as mentioned above is demonstrated briefly. First, in the initial stage which starts ice-making operation again after an ice maker temporarily stops an ice-making operation, the auger 4 is performed by the auger 4 first. Soft beta ice (N), which has been pushed upward and transported, is introduced into the compression passage (5) of the pressure head (1), and the beta ice (N) passes through the compression passage (5) and the upper ice cut portion (6) ), It is taken out by the ice cutting part 6 which inclines outward at the inclination angle (theta) which the front end side of this beta ice N prevents the passage (the state of FIG. 4A). This picking-up phenomenon is maintained by the sticking angle of the beta ice N containing a large amount of water and the set inclination angle θ of the ice cutting unit 6. In this state, beta ice (N) is pushed up by the auger (4), transported and introduced into the compression passage (5), whereby a compression action (so-called dehydration action) gradually occurs in the compression passage (5), and The compression action is transmitted to the beta ice (N) received by the ice cutting unit (6), and the beta ice (N) is gradually compressed, and is cut at a point where the hardness reaches a certain degree of hard ice mass by compression. (State of FIG. 4B).

In this way, the beta ice introduced into the compression passage 5 is continuously pushed, frozen and transported, and the beta ice introduced into the compression passage 5 and the original hardness pushed up from the back of the beta ice and transported. By the pressing force (rising force) of the grown ice, the compressed state is gradually raised to get closer to the original compressed state, and the soft ice mass is cut several times in the ice cutting unit 6 (the state of d from Fig. 4c), and the compression passage (5) ), Most of the moisture is removed by compression, and the high-quality ice column (M) following the hard rod shape is pushed out (from the state of FIG. 4D to the state of FIG. 5A).

The ice column M formed in the shape of a hard rod is pushed out of the compression passage 5, and the tip (projection end) is cut by an outward force applied by colliding with the ice cut part 6 to make ice. It becomes the mass X (state of FIG. 5B).

At this time, the upper part cut into the ice mass X of the ice column M pushed out from the compression passage 5 is in contact with the outer surface of the pressure head 1 at the time point pushed out from the outlet of the passage 5. The contact is in an open free state (state of FIG. 5A). That is, one side of the ice column pushed out of the passage 5 in contact with the passage surface 5-1 of the compression passage 5 has a radius L ₁ more than the passage surface 5-1. It is collided with the upper ice cut | disconnected part 6 in the free state which is not kept in contact with the connection head 7 which was recessed one step lower inward direction, and the ice pillar M is applied with a small force to an outward direction. Is cut. Therefore, the lump of ice X cut into chips is applied with more force than necessary and does not cause cracking inside.

Then, when the ice block X cut into chips is sent to the ice storage unit P along the outward inclination of the ice cutting unit 6, it is continuously pressurized by the ice column M pushed out from the compression passage 5. As a result, when the cut surface (protrusion end surface) of the ice column M has been moved inward so as to slide, the connection head 7 is moved by the passage surface 5-1 of the compression passage 5 as described above. By being recessed one step lower in the radially inner direction, there is no fear that the inner edge 8 of the ice mass X comes into contact with the connection head 7 (the state of FIG. 5C), and the ice cut 6 ) Is sent to the ice storage unit P along the outward inclination (). Therefore, the ice mass X of stable quality can be manufactured without causing the shape collapse that the inner edge part 8 breaks.

Since the pressurizing head in the auger ice maker of this invention is comprised as mentioned above, it has the following effects.

In the initial stage of the ice making operation, when the soft beta ice pushed upward by the auger is introduced into the compression passage of the pressure head, and the poor compression beta ice is pushed through the compression passage and pushed to the upper ice cutting section, This poor compression of beta ice is picked up by the ice cutout which is inclined outward in the inclination angle of 35 to 45 degrees. Thereby, the entry of beta ice into the ice reservoir can be completely prevented or minimized.

In this way, the beta ice can be picked up by the ice cutting unit, so that the beta ice that has been pushed up and moved by the auger is introduced into the compression passage, and the compression passage (so-called dehydration) gradually occurs in the compression passage. As a result, the beta ice in the compression passage is slowly compressed, and the compressive action is transferred to the beta ice which is received at the ice cutting part, and the beta ice is also gradually compressed. As a result, de-icing, which can compress beta ice to a certain degree of hardness, is not possible, as long as all of the uncompressed beta ice is not pushed out of the compression passage, it was impossible to produce a hard ice column where most of the moisture was removed. Since it becomes possible, the start time to the normal ice-making operation | movement which hardly compresses completely from the poor compression beta ice and produces the hard ice column from which the most water was removed can be greatly shortened.

Therefore, it is possible to manufacture and provide an auger ice maker that solves the problems caused by the poor compression of beta ice sent to the ice storage unit, and improves the ice making ability to produce a high quality ice mass quickly. .

In addition, by forming the vertical connecting head which is in continuous contact with the passage face of the compression passage in one step lower in the range of 0.5 to 1.5 mm radially inward than the passage face, the ice column generated in the shape of a rod is removed from the compression passage. When it is pushed out and its tip (projection end) collides with the ice cutting portion and is cut by the outward force applied thereto, the upper part cut by the ice mass of the ice column is pushed out of the compression passage at the point of being pushed out. The contact with the outer surface of the is left open. In other words, one side of the ice pillar pushed out of the passage in contact with the passage face of the compression passage is not in contact with the connection head which is recessed one step lower in the radial direction in the range of 0.5 to 1.5 mm than the passage face. By colliding with the ice cut portion of the upper part of the furnace, the ice column is cut by opening some force in the outward direction. Therefore, more than necessary force is applied to the lump of ice cut into chips, and there is no crack inside.

In addition, when the lump of ice cut into chip shapes is pushed out of the ice storage unit along the outward inclination of the ice cutting unit, it is continuously pressurized by the ice column pushed out of the compression passage, so as to slide the cut surface (protrusion end face) of the ice column. As described above, since the connection head is recessed one step lower radially inwardly than the passage surface of the compression passage as described above, there is no fear that the inner edge of the ice mass is in contact with the connection head. Therefore, a high quality ice mass with stable quality without causing the shape collapse that the edge part is broken can be manufactured.

Therefore, according to the present invention, it is possible to completely prevent or possibly prevent the entry of water containing beta ice into the ice storage unit at the beginning of the ice making operation, and to generate a normal column of hard ice by complete compression. The start time to the ice making operation can be significantly shortened. In addition, a hard ice column pushed out of the compression passage hits the ice cutting portion, thereby producing a high quality ice mass with stable quality without breaking or cracking the edges of the ice mass formed into chips. Auger ice maker provided with a pressurized head can be manufactured and provided.

Claims (2)

An auger having a vertical ice tray, an auger disposed coaxially in the ice maker, a refrigerant pipe wound in a spiral shape in close contact with the outer circumference of the ice maker, and a pressurized head fixedly disposed on an upper side of the ice maker. In the ice maker, An auger ice maker characterized by setting the inclination angle of the outwardly inclined ice cut portion provided on the upper side of the compression passage of the pressure head to 35 to 45 degrees. The auger type according to claim 1, wherein the connecting head portion connecting the compression passage and the ice cut portion is formed to be 0.5 to 1.5 mm smaller radially inward than the passage surface of the compression passage whose cross section is substantially concave outwardly. Ice maker.