KR102338299B1 - ice maker - Google Patents

Abstract

In order to improve cooling efficiency, the present invention provides a water supply unit for supplying liquid water, a cooling frame unit having a plurality of ice generating grooves in which water sprayed from the water supply unit is received, and the cooling frame unit selectively cooling and an ice generator including a temperature controller for temporarily heating; A plurality of discharge frames disposed on the lower side of the cooling frame part and arranged to be inclined downward toward the front, a central discharge unit spaced apart from each other at a predetermined interval, and the central discharge unit are integrally connected to both sides in the width direction of the cooling frame part a drop guide part disposed on the lower side and including a wing part having a plurality of guide frames spaced apart from each other at a predetermined interval; It is disposed in front of the drop guide part in the vertical direction, the lower rear side is disposed to face the front side of the fall guide part, and the rear upper side is disposed opposite to the front of the cooling frame part, and the ice discharge hole is formed through the front and rear direction at the lower part of the central part. wall; and a rotating discharging unit disposed to cover the ice discharging hole and having an upper end hingedly connected to an upper end of the ice discharging hole so that the lower end is selectively rotated forward around the upper end when ice is discharged.

Description

ice maker {ice maker}

The present invention relates to an ice maker, and more particularly, to an ice maker with improved cooling efficiency.

In general, an ice maker for a business is used to make a large amount of ice in a restaurant, a cafe, or the like.

Here, the commercial ice maker includes an ice making chamber in which ice is generated, a water supply unit supplying liquid water to the ice making chamber, a cooling unit cooling the temperature of the ice making chamber, and a heater to separate ice from the ice making chamber. and an ejector power-connected to a motor to discharge the ice generated by cooling in the ice-making chamber, and an ice bank in which ice generated in the ice-making chamber and discharged through the ejector is stored.

In detail, liquid water is supplied to the ice-making chamber through the water supply unit, and ice is generated in the ice-making chamber as the cooling unit is driven. Then, the generated ice is discharged from the ice making chamber to the ice bank through the ejector.

Meanwhile, FIGS. 1B and 1B are exemplary views showing a conventional ice maker.

As shown in FIGS. 1A and 1B , in the conventional ice maker 1 , a plurality of ice-making chambers 1a in which ice a is generated are disposed along the width direction so that a large amount of ice a is simultaneously generated and dropped.

In addition, a drop guide 2 is disposed below the ice-making chamber 1a to be inclined downward toward the front, and the ice a generated in each ice-making chamber 1a falls first onto the drop guide 2 . after being discharged to the front of the ice maker (1).

At this time, the width w of the drop guide 2 is adjusted so that each ice a generated in each of the ice-making chambers 1a arranged in plurality along the width direction falls on the drop guide 2 . It is preferable to be provided so as to cover the entire width of (1a).

Here, a blocking wall 3 having a width corresponding to the width of the drop guide 2 is provided on the front side of the ice making chamber 1a to prevent the water supplied from the water supply from splashing forward. At this time, the ice (a) that first fell on the drop guide 2 was discharged to the front outside of the ice maker 1 through the part opened under the blocking wall 3 .

However, since the conventional ice maker for commercial use is provided in an open state in which the ice making chamber 1a communicates with the outside, there is a problem in that cooling efficiency is lowered as cold air leaks to the outside when the ice (a) is generated.

That is, each ice (a) generated in each of the ice-making chambers (1a) arranged in plurality along the width direction is first dropped onto the drop guide (2) and then discharged to the front outside of the first ice-maker (1). There was a problem in that heat loss occurred in proportion to the area of the opening.

Accordingly, there is a problem in that the power required to generate the ice (a) is increased, and the number of ice (a) generated per unit time is reduced, thereby reducing the ice making efficiency.

Korean Patent Registration No. 10-0565605

In order to solve the above problems, an object of the present invention is to provide an ice maker with improved cooling efficiency.

In order to solve the above problems, the present invention provides a water supply unit for supplying liquid water, a cooling frame unit having a plurality of ice generating grooves in which water sprayed from the water supply unit is accommodated, and the cooling frame unit selectively an ice generating unit including a temperature control unit for cooling and temporarily heating; A plurality of discharge frames disposed on the lower side of the cooling frame part and arranged to be inclined downward toward the front, a central discharge unit spaced apart from each other at a predetermined interval, and the central discharge unit are integrally connected to both sides in the width direction of the cooling frame part a drop guide part disposed on the lower side and including a wing part having a plurality of guide frames spaced apart from each other at a predetermined interval; It is disposed in front of the drop guide part in the vertical direction, the lower rear side is disposed to face the front side of the fall guide part, and the rear upper side is disposed opposite to the front of the cooling frame part, and the ice discharge hole is formed through the front and rear direction at the lower part of the center part. wall; and a rotating discharge unit disposed to cover the ice discharge hole and having an upper end hingedly connected to an upper end of the ice discharge hole so that the lower end is selectively rotated forward around the upper end when ice is discharged, wherein the blocking wall portion is the wing It is provided as a flat plate having a width corresponding to the width of the part and includes a pair of block bulkheads disposed on both sides in the width direction around the ice discharge hole to seal and cover the front part of the space formed between the cooling frame part and the drop guide part. , Each of the block bulkheads has an inner end in the width direction in close contact with both edges of the discharge plate formed in the rotating discharge part in close contact with each other, and the wing part is disposed at the rear of each of the block bulkheads to the center in the width direction toward the central discharge part An ice maker characterized in that it is formed to be symmetrical toward the side and inclined downward, the width of the central discharge unit is set to correspond to the width of the ice discharge hole, and the front end of each discharge frame is disposed opposite to the rear of the discharge plate do.

Here, the blocking wall portion is provided with a flat plate having a width corresponding to the width of the drop guide portion, the rear surface is disposed opposite to the front of the cooling frame portion and further comprises a blocking partition wall disposed above the rotating discharge portion, each of the blocks The bulkhead is provided with a metal material with the upper back surface contacting both front surfaces of the blocking bulkhead in the width direction and being detachably coupled, and the drop guide part is cross-connected along the width direction of each of the discharge frames, and both ends are inside the wing part It is respectively connected to the wall surface and further includes a plurality of connection frames arranged to be spaced apart from each other in the front and rear directions, and disposed under the drop guide part in a container shape so that water falling between each of the discharge frames and each of the guide frames is collected It is preferable to further include a collection unit to be.

delete

In addition, the blocking wall portion is provided with rotating shaft portions to which both ends are connected to both upper ends of the ice discharge hole in the width direction, and the rotation discharge portion includes a plurality of hinge connection portions hingedly connected to the rotation shaft portion, and from the front end of each hinge connection portion. It is preferable to include a plurality of discharge plate portions extending downwardly to cover the ice discharge hole, and arranged so that both edges in the width direction are in close contact with each other.

Here, each of the hinge connection parts are spaced apart from each other, and the rotation discharge part is sequentially alternately disposed with each of the hinge connection parts along the width direction on the rotation shaft part and is hingedly connected to a plurality of double hinge connection parts, and each of the double hinge connection parts Doedoe extending downward from the rear end of each of a plurality of double discharge plate parts arranged spaced apart rearward from the rear side of both sides of the width direction of each of the discharge plate parts so as to simultaneously rotate and press both sides of the borders in the width direction of a pair of adjacent to each other to the front more It is preferable to include

Through the above solution means, the present invention provides the following effects.

First, the size of the ice discharge hole is minimized through the blocking wall that seals and covers the front part of the cooling frame part where ice is generated and the drop guide part, thereby minimizing the cold air leakage area and at the same time, the ice is formed on the wing part that is inclined downward toward the center of the fall guide part. Since it is dropped and guided and is easily discharged to the rotating discharge unit through the central discharge unit, heat loss is minimized and energy efficiency can be remarkably improved.

Second, the front of the wing is hermetically covered by a pair of block bulkheads, and the inner end of each block bulkhead is in close contact with the discharging plate that rotates when ice is discharged so that communication between the ice generating unit and the outside is minimized. Since the ice is discharged to the front of the central discharge unit after moving along the slope, the ease of taking out the ice can be remarkably improved.

Third, it is provided with a flat plate having a width corresponding to the drop guide part and the upper and rear surfaces of each block bulkhead to minimize the heat loss area on both fronts of the blocking bulkheads disposed opposite to the front of the cooling frame part are in surface contact and are detachably coupled. After separating it, the inside of the ice maker and the drop guide can be easily cleaned, so that the usability can be significantly improved.

Fourth, both edges of the width direction of each discharge plate extending downward from the front end of the plurality of hinge connection units are arranged in close contact with each other so as to cover the ice discharge hole disposed opposite the center of the drop guide unit through which ice is discharged, so that only when ice is discharged Since the discharge plate is rotated and opened, heat loss due to cold air leakage can be minimized.

1b and 1b are exemplary views showing a conventional ice maker.
2 is a block diagram illustrating an ice maker according to an embodiment of the present invention.
3 is an exemplary view illustrating a process of generating ice in an ice maker according to an embodiment of the present invention;
4 is an exemplary view showing a state of use of the ice maker according to an embodiment of the present invention.
5 is a perspective view illustrating a drop guide unit in the ice maker according to an embodiment of the present invention;
6 is a perspective view illustrating an ice maker according to an embodiment of the present invention;
7 is an exemplary view showing a rotating discharge unit in the ice maker according to an embodiment of the present invention.

Hereinafter, an ice maker according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram illustrating an ice maker according to an embodiment of the present invention, FIG. 3 is an exemplary diagram illustrating a process of ice generation in the ice maker according to an embodiment of the present invention, and FIG. 4 is an embodiment of the present invention. It is an exemplary view showing the state of use of the ice maker according to the example, FIG. 5 is a perspective view showing a drop guide unit in the ice maker according to an embodiment of the present invention, and FIG. 6 is a perspective view showing the ice maker according to an embodiment of the present invention, 7 is an exemplary view showing a rotating discharge unit in the ice maker according to an embodiment of the present invention.

2 to 7 , the ice maker 100 according to an embodiment of the present invention includes an ice generating unit 10 , a fall guide unit 20 , a blocking wall unit 30 , and a rotating discharge unit 40 . includes

Here, referring to FIGS. 2 to 4 , the ice generating unit 10 includes a water supply unit 11 for supplying liquid water. In this case, the water supply unit 11 may include a plurality of supply pipes to which liquid water is supplied, and a plurality of injection nozzles connected to the ends of each of the supply pipes. In addition, each of the injection nozzles may be disposed under the cooling frame unit 12, and the arrangement position is not limited thereto.

In addition, the ice generating unit 10 includes the cooling frame unit 12 in which ice generating grooves 12a for receiving water sprayed from the water supply unit 11 are depressed upwardly at a plurality of places. At this time, in an embodiment of the present invention, each of the ice generating grooves 12a is formed to be depressed upwardly from the lower portion of the cooling frame unit 12 and a plurality of the ice generating grooves 12a are arranged along the width direction of the cooling frame unit 12 as an example. illustrated and described.

In addition, the ice generating unit 10 includes a temperature adjusting unit 13 for selectively cooling and temporarily heating the cooling frame unit 12 . At this time, the temperature control unit 13 includes a cooling means for selectively cooling the cooling frame portion 12, and a heating means for selectively heating the cooling frame portion (12). In addition, the ice generating unit 10 preferably includes a control unit 14 for controlling the temperature adjusting unit 13 .

Referring to FIG. 3 , liquid water is sprayed upward from the water supply unit 11 to the inner surface of each of the ice generating grooves 12a , and at the same time, the control unit 14 controls the temperature control unit 13 . By controlling the cooling means, the cooling frame unit 12 is cooled below the temperature for freezing to occur. Accordingly, the liquid water sprayed on the inner surface of each of the ice generating grooves 12a starts to freeze, and as time elapses, ice a is formed in the entire inside of each of the ice generating grooves 12a.

And, referring to FIG. 4 , the control unit 14 temporarily drives and controls the heating means of the temperature control unit 13 to partially cut the surface of the ice a bound to each of the ice generating grooves 12a. The melted ice (a) falls first to the drop guide unit 20 disposed under the cooling frame unit 12 .

Meanwhile, referring to FIGS. 4 to 5 , the drop guide part 20 is provided including a central discharge part 21 and a wing part 22 . The drop guide unit 20 may be made of a synthetic resin, a metal material, or the like.

In detail, the central discharge unit 21 includes a plurality of discharge frames 21a disposed below the cooling frame 12 and inclined downward toward the front, and each discharge frame 21a has a predetermined interval. It is preferable that they are spaced apart from each other. In this case, the preset interval may be set to be less than the diameter or length and width of each ice a generated by the ice generating unit 10 . In addition, it is preferable that the angle of the discharge frame 21a is set to be greater than or equal to a preset angle so that the falling ice a moves along the slope.

Here, it is preferable that the rear end of each of the discharge frames 21a is integrally connected to the outer frame 23 and disposed at uniform intervals between the inner wall surfaces 22b of the pair of wing portions 22 .

In addition, each of the discharging frames 21a is disposed to be inclined downward toward the front, and the front end is preferably disposed opposite to the lower side of the ice discharging hole 31 of the blocking wall portion 30 . At this time, the front end of each of the discharge frame (21a) is preferably disposed opposite to the lower rear of the discharge plate portion 42 and the double discharge plate portion 44 to be described later.

In addition, the central discharge part 21 is cross-connected along the width direction of each of the discharge frames 21a, and both ends are connected to the inner wall surface 22b of each of the wing portions 22. A plurality of connection frames 21b ) is further included, but each of the connection frames 21b is preferably disposed to be spaced apart from each other in the front-rear direction.

That is, in the central discharge part 21, when viewed from the upper side, each of the discharge frames 21a and the connection frames 21b are arranged to cross each other in a '#' shape, so that the ice ( a) can be supported even by the impact that occurs during the fall.

In this case, the width of the central discharge part 21 may be set to correspond to the width of the ice discharge hole 31 , and the length of the connection frame 21b is set to correspond to the width of the ice discharge hole 31 . can be

On the other hand, the wing part 22 is integrally connected to both sides of the central discharge part 10 in the width direction and is disposed below the cooling frame part 12, and a plurality of guide frames 22a are mutually connected at a predetermined interval. It is preferable to be spaced apart. In this case, the preset interval may be set to be less than the diameter or length and width of each ice a generated by the ice generating unit 10 . In addition, the wing portion 22 is preferably disposed at the rear of the pair of block partition walls (32).

Here, the outer edge of the wing portion 22 is symmetrical and inclined downwardly toward the center side in the width direction toward the central discharge portion 21, and the arrangement position of each guide frame 22a increases toward the center side in the width direction. It is preferable to set it to be continuously lowered. At this time, it is preferable that the angle of the wing portion 22 is set to be greater than or equal to a preset angle so that the falling ice a moves along the slope.

At this time, in one embodiment of the present invention, each of the guide frames 22a is shown and described as an example in which each of the guide frames 22a is disposed in the front and rear direction of the drop guide part 20 and both ends are connected to the front and rear inner surfaces of the outer rim. do. Of course, in some cases, each of the guide frames 22a may be disposed along the width direction of the drop guide unit 20, and both ends may be respectively connected to both inner surfaces of the outer rim in the width direction. Alternatively, each of the guide frames 22a may be connected to cross each other in the front-rear direction and the width direction of the drop guide unit 20 .

Accordingly, when the ice (a) falls first from the cooling frame part 12 to the upper part of the wing part 22 that is inclined downward toward the center in the width direction, the ice (a) falls along the inclination to the fall guide part ( 20) is moved to the inner side in the width direction and is guided to the central discharge unit 21, and then is finally discharged to the front of the central discharge unit 21.

In addition, the extension portion 22c may extend integrally to the inner front portion of each of the wing portions 22 in a rectangular cross-sectional shape. Here, the lower surface of the extension part 22c may be seated on the inner bottom surface of the ice maker 100 , and the front surface of the extension part 22c may be in face-to-face contact with the blocking wall part 30 .

The drop guide unit 20 is provided in a detachable manner so that it can be seated on the inner bottom surface of the ice maker 100, and when contamination occurs, the user can easily separate the drop guide unit 20 from the ice maker 100. Since it can be washed afterward, cleanliness and ease of use can be improved. In addition, since the drop guide unit 20 can be replaced with the conventional ice maker 100 , economic efficiency can be improved.

Here, the ice maker 100 is disposed under the drop guide unit 20 and is provided in a container shape to collect water that has fallen between each of the discharge frames 21a and the guide frames 22a. (not shown) and a discharge pipe part (not shown) provided in the form of a pipe to discharge the water collected in the collection part (not shown) may be further included. In this case, the collecting unit (not shown) may be seated on the inner bottom surface of the ice maker 100 , and the drop guide unit 20 may be arranged to be seated on the upper portion of the collecting unit (not shown).

On the other hand, referring to FIG. 6 , the blocking wall part 30 is disposed in the vertical direction in front of the drop guide part 20 so that the lower rear side faces the front side of the fall guide part 20 , and the rear upper side is disposed It is preferable that the cooling frame part 12 is disposed opposite to the front side, and the ice discharge hole 31 is formed to penetrate in the front and rear directions below the central part.

In detail, the blocking wall part 30 is provided as a flat plate having a width corresponding to the width of the wing part 22 to cover the entire surface of the space formed between the cooling frame part 12 and the drop guide part 20 . It is preferable to include a pair of block partition walls 32 disposed on both sides in the width direction around the ice discharge hole 31 .

At this time, each of the block partition walls 32 is preferably in close contact with both sides of the width direction edges of the discharge plate portion 42 formed in the rotation discharge portion 40 at the inner end of the width direction, and is made of a metal material such as iron. can be In addition, the height of each blow bulkhead 32 is preferably set to correspond to the interval between the cooling frame part 12 and the drop guide part 20 .

In addition, the blocking wall portion 30 is provided as a flat plate having a width corresponding to the width of the drop guide portion 20 and is connected to each of the block partition walls 32 and is disposed above the rotation discharge portion 40 It is preferable to include a blocking partition wall (33).

Here, it is preferable that the rear surface of the blocking partition wall 33 is opposite to the front of the cooling frame part 12 . Through this, when liquid water is sprayed from the water supply unit 11 to the cooling frame unit 12 , splashing of water to the outside is prevented by the blocking partition wall 33 , thereby improving usability.

At this time, the upper and rear surfaces of each of the block partition walls 32 are in surface contact with both front surfaces of the blocking partition wall 33 in the width direction, and the blocking partition wall 33 and each of the block partition walls 32 are connected to each other by means of fastening such as butterfly bolts. can be coupled and fastened to each other in a detachable manner through

Accordingly, the user can selectively separate and wash each of the block partition walls 32 from the blocking partition wall 33, so that cleanliness and ease of use can be improved. With the structure in which the cooling efficiency is improved as heat loss is reduced only by additionally installing the block partition wall 32, assembly property can be remarkably improved.

In addition, the blocking wall portion 30 integrally extends downward from the lower ends of both sides in the width direction of the blocking partition wall 33 to the rear end of the support portion 34 supported in contact with the upper portion of the drop guide portion 20 . may include more. Of course, in some cases, the support part 34 may extend integrally from the rear surface of the block partition wall 32 .

Meanwhile, referring to FIGS. 6 to 7 , the rotating discharging part 40 is disposed to cover the ice discharging hole 31, and when the ice (a) is discharged, the lower end is selectively rotated forward around the upper end. It is preferable that the upper end is hinged to the upper end of the ice discharge hole 31 . Here, the ice discharge hole 31 may be formed through a rectangular cross-sectional shape, but is not limited thereto.

In this case, it is preferable that the blocking wall part 30 is provided with a rotation shaft part 35 having both ends connected to both upper ends of the ice discharge hole 31 in the width direction. Here, it is preferable that the rotation shaft part 35 is provided as a cylindrical bar, so that both ends are connected to both upper ends of the ice discharge hole 31 in the width direction. At this time, the rotation shaft part 35 may be spaced apart from the lower end of the blocking partition wall 33 at a predetermined interval, and although not shown in the drawing, an elastic space between the rotation shaft part 35 and the blocking partition wall 33 . A sealing member (not shown) made of a material may be further provided.

In addition, it is preferable that the rotation discharge part 40 includes a plurality of hinge connection parts 41 hingedly connected to the rotation shaft part 35 . In addition, the rotation discharge unit 40 integrally extends downward from the front end of the hinge connection unit 41 to cover the ice discharge hole 31, and a plurality of discharge plate portions are arranged so that both edges in the width direction are in close contact with each other. (42) is preferably included.

Here, it is preferable that the width of the discharge plate part 42 is set to exceed the width of the hinge connection part 41 . In addition, the vertical length of the discharge plate portion 42 is preferably set to correspond to the interval between the rotation shaft portion 35 and the lower end of the ice discharge hole 31 .

And, each of the discharge plate portion 42 is preferably rotated forward individually when the rear side is pressed forward. Through this, in the initial state in which each of the discharge plate parts 42 is not rotated, each of the discharge plate parts 42 covers the ice discharge hole 31 to minimize heat loss, and the discharge plate part 42 at the pressurized part Only partially rotated and opened, so that the remaining portion that is not pressurized remains in a state of covering the ice discharge hole 31, so that heat loss can be minimized.

On the other hand, referring to FIG. 7 , the rotation discharge part 40 is alternately disposed with each of the hinge connection parts 41 along the width direction on the rotation shaft part 35 and a plurality of double hinge connection parts 43 that are hinged are connected. It is preferable to include more. At this time, it is preferable to understand that each of the double hinge connection parts 43 is disposed between each of the hinge connection parts 41 spaced apart from each other.

In addition, the rotation discharge part 40 extends downward from the rear end of each of the double hinge connection parts 43, and a plurality of double discharge plate parts 44 are arranged to be spaced apart from the rear side of both sides of the edge in the width direction of the discharge plate part 42 to the rear. It is preferable to further include

Here, the width of each of the double discharge plate portions 44 may be set to correspond to the width of each of the double hinge connection portions 43 . At this time, each of the double discharge plate parts 44 is spaced apart from the rear side of both sides of the width direction of each of the discharge plate parts 42 to simultaneously rotate and press both sides of the width direction of the adjacent pair of the discharge plate parts 42 forward. This is preferable. That is, each of the double discharge plate parts 44 is spaced apart along the width direction corresponding to the spacing of each of the double hinge connection parts 43, and the center of each of the double discharge plate parts 44 in the width direction is a pair of the discharge plate parts ( 42) is preferably arranged so as to be opposed to both sides of the width direction in the front-back direction.

At this time, each of the discharge plate parts 42 extends downward from the front end of the hinge connection part 41 disposed on the rotation shaft part 35 , while each of the double discharge plate parts 44 is disposed on the rotation shaft part 35 . It extends downwardly from the rear end of the double hinge connection part 43 . Accordingly, each of the discharge plate portion 42 and each of the double discharge plate portion 44 may be disposed to be spaced apart from each other in the front-rear direction with an interval corresponding to the diameter of the rotation shaft portion 35 .

And, the ice (a) moving forward of the drop guide part 20 along the inclination of the central discharge part 21 of the drop guide part 20 causes any one of the double discharge board parts 44 to apply gravity. When pressed, the lower end of the pressurized double discharge plate part 44 is rotated forward around the double hinge connection part 43, and a pair of the discharge plate parts 42 disposed in front of the double discharge plate part 44 are moved forward. pressurize with Then, the ice (a) may be discharged as the pair of discharging plate parts 42 are rotated forward with respect to the hinge connection part 41 at the lower end thereof.

As described above, the ice maker 100 according to an embodiment of the present invention operates through the blocking wall part 30 that hermetically covers the front part of the cooling frame part 12 and the drop guide part 20 where ice (a) is generated. By minimizing the size of the ice discharge hole 31, the area of cold air leakage is minimized. At the same time, the ice (a) is dropped and guided to the wing portion 22 that is inclined downward toward the center of the drop guide portion 20, and is directed to the rotation discharge portion 40 through the central discharge portion 21. Since it is discharged, heat loss is minimized, and cooling efficiency and power efficiency can be remarkably improved.

In other words, after the ice (a) generated in a large amount by the ice generating unit 10 falls on the wing unit 22 formed to be inclined downward toward the center of the fall guide unit 20, the central discharge unit 21 The energy efficiency is significantly improved because the cold air leakage area is minimized through the blocking wall part 30 that seals and covers the front part of the ice generating part 10 and the falling guide part 20 while being guided to the outside and being easily discharged to the outside. can

That is, since the amount of ice (a) that can be generated in the same time increases as the time required to generate the ice (a) once is further shortened compared to the prior art, productivity and economic feasibility can be remarkably improved.

In addition, the front of the wing part 22 is hermetically covered by a pair of the block partition walls 32 , and the inner end of each block partition wall 32 is rotated when the ice (a) is discharged. In a state in which communication between the ice generating unit 10 and the outside is minimized by being in close contact, the ice (a) that has fallen on the wing unit 22 is moved along the slope and then discharged to the front of the central discharge unit 21 . Therefore, the ease of taking out the ice (a) can be significantly improved.

Furthermore, each of the above for minimizing the heat loss area on both front surfaces of the blocking partition wall 33 disposed opposite to the front of the cooling frame part 12 provided as a flat plate having a width corresponding to the drop guide part 20 Since the upper rear surface of the block partition wall 32 is in surface contact and is detachably coupled, the inside of the ice maker 100 and the drop guide unit 20 can be easily washed after separation, so that the usability can be remarkably improved.

In addition, a plurality of hinge connection parts 41 to cover the ice discharging hole 31 opposite to the center front of the drop guide unit 20 from which the ice (a) is discharged, that is, in front of the central discharging unit 21 . ), both edges of each of the discharge plate parts 42 in the width direction extending downward from the front end are arranged in close contact with each other, so that only a part of the discharge plate part 42 is pressed by the ice (a) only when the ice (a) is discharged. Since it is rotated and opened, heat loss due to cold air leakage can be minimized.

Furthermore, each of the double discharge plate portions 44 extending downward from the rear end of the plurality of hinge connection portions 43 that are sequentially alternately arranged with each of the hinge connection portions 41 on the rotation shaft portion 35 and are hingedly connected are respectively the The discharge port 42 is spaced apart from both edges of the discharge plate 42 to the rear, and when the ice (a) is discharged, the opposite discharge panel 42 is rotated and pressed forward at the same time. Clogging is prevented and durability can be significantly improved.

In this case, terms such as "comprises", "comprises" or "include" described above mean that the corresponding component may be inherent unless otherwise stated, so other components are excluded. Rather, it should be construed as being able to include other components further. All terms, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs, unless otherwise defined. Terms commonly used, such as those defined in the dictionary, should be interpreted as being consistent with the contextual meaning of the related art, and are not interpreted in an ideal or excessively formal meaning unless explicitly defined in the present invention.

As described above, the present invention is not limited to each of the above-described embodiments, and variations can be implemented by those of ordinary skill in the art to which the present invention pertains without departing from the scope of the claims of the present invention. and such modifications are within the scope of the present invention.

1,100: ice maker 10: ice generating unit
11: water supply part 12: cooling frame part
13: temperature control unit 14: control unit
20: fall guide part 21: central discharge part
21a: discharge frame 21b: connection frame
22: wing portion 22a: guide frame
30: blocking wall 31: ice discharge hole
32: block bulkhead 33: block bulkhead
34: rotation shaft unit 40: rotation discharge unit
41: hinge connection part 42: discharge plate part
43: double hinge connection part 44: double discharge plate part

Claims (5)

A water supply unit for supplying liquid water, a cooling frame unit having a plurality of ice generating grooves in which water sprayed from the water supply unit is accommodated, and a temperature control unit for selectively cooling and temporarily heating the cooling frame unit ice generator;
A plurality of discharge frames disposed on the lower side of the cooling frame part and arranged to be inclined downward toward the front, a central discharge unit spaced apart from each other at a predetermined interval, and the central discharge unit are integrally connected to both sides in the width direction of the cooling frame part a drop guide portion disposed on the lower side and including a wing portion in which a plurality of guide frames are spaced apart from each other at a predetermined interval;
It is disposed in the vertical direction in front of the drop guide part, the lower rear side is disposed to face the front side of the fall guide part, and the rear upper side is disposed to face the front of the cooling frame part, and the ice discharge hole is formed through the front and rear direction at the lower part of the center part. wall; and
a rotating discharge unit disposed to cover the ice discharge hole, the rotation discharge unit having an upper end hinged to the upper end of the ice discharge hole so that the lower end portion is selectively rotated forward around the upper end when ice is discharged;
The barrier wall portion is provided as a flat plate having a width corresponding to the width of the wing portion, and is disposed on both sides in the width direction around the ice discharge hole so as to seal and cover the front portion of the space formed between the cooling frame portion and the drop guide portion. Including block partition walls of, each of the block partition walls has an inner edge in the width direction in close contact with both sides of the width direction edge of the discharge plate formed in the rotation discharge part,
The wing portions are disposed at the rear of each of the block bulkheads and are symmetrically formed toward the central side in the width direction toward the central discharge portion and inclined downward, and the width of the central discharge portion is set to correspond to the width of the ice discharge hole, and each The discharge frame has a front end disposed opposite to the rear of the discharge plate. delete The method of claim 1,
The blocking wall portion is provided with a flat plate having a width corresponding to the width of the drop guide portion, the rear surface is disposed opposite to the front of the cooling frame portion and further comprises a blocking partition wall disposed above the rotation discharge portion,
Each of the block barrier ribs is provided as a metal material and is detachably coupled with an upper rear surface in surface contact with both front sides in the width direction of the blocking barrier rib,
The drop guide portion further comprises a plurality of connecting frames cross-connected along the width direction of each of the discharge frames, both ends are respectively connected to the inner wall surface of each of the wing portions and are spaced apart from each other in the front-rear direction,
The ice maker according to claim 1, further comprising: a collecting unit disposed under the drop guide unit and provided in a container shape to collect water that has fallen between each of the discharge frames and each of the guide frames. The method of claim 1,
The blocking wall portion is provided with rotating shaft portions connected to both ends at upper ends of both sides in the width direction of the ice discharge hole,
The rotation discharge unit includes a plurality of hinge connection units hingedly connected to the rotation shaft unit;
and a plurality of discharge plate portions extending integrally downward from the front end of each of the hinge connection portions to cover the ice discharge hole, and disposed in close contact with both sides of the width direction edge. 5. The method of claim 4,
Each of the hinge connection parts are spaced apart from each other,
The rotation discharge unit includes a plurality of double hinge connection units which are sequentially arranged alternately with each of the hinge connection units along the width direction of the rotating shaft unit and are hingedly connected;
A plurality of spaced apart from the rear side of both sides of the width direction of the discharge plate part to simultaneously extend downwardly from the rear end of each of the double hinge connection parts and rotate and press both sides of the adjacent pair of the discharge plate parts in the front at the same time Ice maker, characterized in that it further comprises a double discharge plate portion.

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