KR102154029B1 - Ice manufacturing apparatus - Google Patents

Abstract

An object of the present invention is to provide an ice maker that prevents ice from sticking to each other in the ice storage unit and allows ice to be smoothly discharged through an ice discharge gate. The ice maker of the present invention for implementing this comprises: an ice storage unit for storing ice generated by the ice making unit; An ice discharge port for discharging the ice stored in the ice storage unit to the outside; A bottom plate forming the bottom of the ice storage unit; Includes a blade rotating to prevent ice from sticking to the ice storage unit, wherein a guide rib is formed on the upper surface of the bottom plate, protruding along an outer circumference, and stepped in front of the ice discharge port based on the rotation direction of the blade. do.

Description

Ice maker {ICE MANUFACTURING APPARATUS}

The present invention relates to an ice maker, and more particularly, to an ice maker capable of smoothly discharging ice from an ice storage unit through an ice discharge port.

An ice maker is a device that generates ice and supplies it to a user, and is configured to generate ice by receiving cold air from a refrigerant flowing inside an evaporation tube constituting a refrigeration cycle.

In addition, among the water purifiers, a water purifier having an ice making function has been developed so as to supply ice as well as cold and hot water. As an example, Korean Utility Model No. 20-330516 is disclosed.

In the prior art, an evaporator through which a low-temperature refrigerant flows, an ice-making plate coupled to receive cool air from the evaporator, a nozzle for spraying purified water onto the ice-making plate, and an ice reservoir for storing ice made from the ice-making plate are provided. .

A groove is formed in the ice making plate so that ice of a certain shape is formed, and when water sprayed from the nozzle contacts the inner surface of the groove, ice is generated in the groove by the cold air transmitted from the evaporator. The frozen ice is stored in an ice storage and then supplied to the user.

The ice reservoir is provided with a blade rotating by a motor, and the ice in the ice reservoir is rotated by the blade and then discharged to the outside through a discharge port.

According to this prior art, the entire plate on which the wing-shaped protrusion is formed on the upper surface is rotated, so that a large load is placed on the motor, and the ice in the central area of the ice storage is not discharged smoothly, and ice and ice are stuck together. There is a problem that it is not discharged through the discharge port.

The present invention was conceived to solve the above-described problems, and an object thereof is to provide an ice maker that prevents ice from sticking to each other in the ice storage unit and allows ice to be smoothly discharged through the ice discharge gate. .

The ice maker of the present invention for achieving the above object comprises: an ice storage unit for storing ice generated by the ice making unit; An ice discharge port for discharging the ice stored in the ice storage unit to the outside; A bottom plate forming the bottom of the ice storage unit; Includes a blade rotating to prevent ice from sticking to the ice storage unit, wherein a guide rib is formed on the upper surface of the bottom plate, protruding along an outer circumference, and stepped in front of the ice discharge port based on the rotation direction of the blade. do.

The guide rib may be formed to be inclined to increase toward the ice discharge port.

The guide rib may be formed to be inclined in the width direction so as to decrease toward the inside direction of the ice storage unit.

A stopper rib protruding from an upper surface of the bottom plate may be formed at a position spaced apart from the front end of the guide rib.

The lower end of the ice discharge port may be formed at a position higher than the upper surface of the bottom plate.

The blade is composed of a first blade and a second blade respectively connected to an upper side and a lower side of a rotating shaft that rotates by driving a motor; The first blade includes a first horizontal portion extending in a horizontal direction from the rotation axis, and a first bent portion downwardly bent outward from an end of the first horizontal portion; The second blade has an overall length shorter than that of the first blade; The first blade and the second blade may be provided to intersect when viewed in a plan view.

The bottom plate may have an inclined shape that decreases from the center to the edge.

A plurality of drain holes may be formed around an edge of the bottom plate.

According to the ice maker according to the present invention, ice is prevented from sticking to each other by providing a blade rotating in the ice storage unit, and by forming a guide rib protruding along the outer circumference of the bottom plate, ice between the blade and the body surrounding the ice storage unit This can be prevented from getting stuck.

In addition, a stopper rib protruding from the upper surface of the bottom plate is formed at a position spaced apart from the front end of the guide rib with the ice discharge port interposed therebetween, so that ice is smoothly discharged to the ice discharge port.

In addition, blades arranged vertically at different inclination angles are provided so that the ice inside the ice storage unit can be evenly discharged to the outside through the ice discharge port.

1 is a perspective view showing a cross-sectional structure of an ice maker of the present invention,
Figure 2 is a side cross-sectional view showing the ice maker of the present invention,
3 is a perspective view showing the internal structure of the ice maker of the present invention,
4 is a perspective view showing the bottom plate and the blade of the present invention,
5 is an exploded view showing a part of the cross section of the bottom plate of the present invention.

Hereinafter, the configuration and operation of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a cross-sectional structure of an ice maker of the present invention, FIG. 2 is a side cross-sectional view showing an ice maker of the present invention, FIG. 3 is a perspective view showing the internal structure of the ice maker of the present invention, and FIG. 4 is a bottom plate and a blade of the present invention 5 is an exploded view showing a partial cross-sectional view of the bottom plate of the present invention.

The ice maker of the present invention includes a water purification tank 100 that stores water filtered by a filter unit (not shown) in a purified water state at room temperature, and a cold water tank 500 that receives purified water from the water purification tank 100 and stores it in a cold water state. ), an ice making unit 200 for generating ice by using water in the cold water tank 500, and an ice storage unit 400 for storing ice generated by the ice making unit 200.

The ice-making unit 200 includes an ice-making frame 210 in which ice of a certain shape is formed, and an evaporation tube coupled to the ice-making frame 210 so that heat exchange is performed between the refrigerant flowing therein and the ice-making frame 210 (220; 220a, 220b), an ice-making frame holder 230 supporting a lower portion of the ice-making frame 210, and ice generated in the ice-making frame 210 by being installed under the ice-making frame 210 To the nozzle unit 250 having an ice guide 240 for guiding to fall to 400, and a plurality of nozzles 251 for spraying water supplied from the cold water tank 500 to the ice making frame 210 Done.

The ice-making frame 210 includes a body part 211 made of a metal material, and an ice-making groove 212 formed concavely in the body part 211 to become a space in which ice is to be formed. A plurality of ice-making grooves 212 are formed to correspond to the plurality of nozzles 251.

The evaporation pipe 220 constitutes a part of a refrigeration cycle (not shown), but includes an evaporation pipe inlet 220a through which refrigerant flows in and an evaporation pipe outlet 220b through which refrigerant heat exchanged flows out. The low-temperature refrigerant flows so that the water sprayed from the nozzle 251 generates ice in the ice making groove 212, and after the ice making is completed, the high-temperature refrigerant flows to melt the ice surface created in the ice making groove 212 Let it ice cream. In this case, a heater may be provided in the ice-making frame 120 to perform ice removal.

The body part 211 of the ice making frame 210 is integrally combined with the evaporation tube 220 by die casting, so that heat transfer from the refrigerant flowing inside the evaporation tube 220 to the body part 211 is performed. It is done efficiently.

The ice guide 240 includes a sloping plate 241 installed in an inclined manner to guide the ice that has been de-icing and dropped from the ice-making frame 210 to the ice storage unit 400, and water sprayed on the ice-making frame 210 is splashed. Includes an ice curtain 244 for preventing scattering into the ice storage unit 400, and the swash plate 241 has a through hole 241a so that water sprayed from the nozzle 251 toward the ice making groove 212 passes. ) Is formed.

The nozzle unit 250 includes a plurality of nozzles 251, an upper nozzle plate 252 in which the plurality of nozzles 251 protrude upward, and a nozzle connection passage between the upper nozzle plate 252 ( It consists of a lower nozzle plate 253 coupled to form 255. The nozzle connection passage 255 connects the plurality of nozzles 251 to each other, and water supplied from the cold water tank 500 is filled in the nozzle connection passage 255 and sprayed through the plurality of nozzles 251 do.

The ice storage unit 400 includes a body part 400a surrounding an inner space in which ice is stored, and an ice discharge port 400b for discharging ice is formed in the body part 400a, and the body part (400a) is formed integrally with the body portion (500a) constituting the cold water tank (500), the ice and cold water in the upper and lower space divided by the bottom plate (300) forming the bottom of the ice storage unit (400). Each is saved.

A stepped part 450 is formed at a portion where the body part 400a of the ice storage part 400 and the body part 500a of the cold water tank 500 are connected, and the bottom plate 300 is the stepped part 450 Settled in.

In the ice storage unit 400, blades 421 and 422 periodically rotate around a rotation shaft 410 to prevent ice from sticking to each other while discharging ice through the ice discharge port 400b, and the ice discharge port An ice discharge gate 430 for discharging ice to a user by opening and closing (400b), and a full ice sensor 440 for sensing that ice is full in the ice storage unit 400 are provided, and the ice discharge gate ( 430 is driven by the gate driving device 700.

The blades 421 and 422 are formed of a first blade 421 and a second blade 422 respectively connected to the upper and lower sides of the rotating shaft 410 rotated by the driving of the motor 600.

The first blade 421 includes a first horizontal portion 421a extending in a horizontal direction from the rotation shaft 410 and a first bent portion 421b bent downward from an end portion of the first horizontal portion 421a. ), and the second blade 422 extends in a horizontal direction from the rotation shaft 410 and is formed to be shorter than the first horizontal part 421a, and the second horizontal part ( Consisting of a second bent portion 422b bent downward at an end of 422a) and bent at an angle smaller than that of the first bent portion 421b, the first blade 421 and the second blade 422 It is coupled to the rotation shaft 410 so as to intersect when viewed in a plan view.

In this embodiment, it is illustrated that the second bent portion 422b is formed on the second blade 422, but extends horizontally by the length of the second bent portion 422b from the horizontal portion 422a without the second bent portion 422b. It can also consist of being.

In this way, the first bent portion 421a is formed on the first blade 421, and the second blade 422 is shorter than the first blade 421 under the first blade 421, The ice 10 may be evenly stirred from the inside to the outside of the ice storage unit 400 and from the lower side to the upper side.

The first blade 421 and the second blade 422 may be configured to cross 90 degrees on a plan view, or may be configured to alternately form an acute angle and an obtuse angle, and two or more of the second blades 422 It can also be configured to intersect at a plurality of acute angles.

The bottom plate 300 has an inclined shape that decreases from the center to the edge so that ice stored in the ice storage unit 400, which is an upper space of the bottom plate 300, is The ice dispersed to the edge of the bottom plate 300 and dispersed to the edge of the bottom plate 300 It is discharged through the ice discharge port 400b while being in contact with the rotating blades 421 and 422 and being pushed outward.

A guide rib 310 having a predetermined width is formed along the circumference of the upper surface 300a of the bottom plate 300. The guide surface 311 of the guide rib 310 protrudes upward from the edge of the upper surface 300a of the bottom plate 300, and the end of the guide surface 311 than the start 312 of the guide surface 311 (313) The position is formed higher, so that when the blades 421 and 422 rotate in a counterclockwise direction as a reference, it is gradually increased toward the ice discharge gate 430 located in front of the end 313 of the guide rib 310 It consists of an inclined shape.

In addition, the guide surface 311 of the guide rib 310 has a higher edge portion 314 than the inner portion 315, so that it is inclined in the width direction to gradually decrease toward the inner direction of the ice storage unit 400 Consists of.

If the guide rib 310 is not formed and the top surface 300a of the bottom plate 300 is flat, the end of the first bent portion 421b of the first blade 421 and the side end of the ice discharge port 400b ( 400c) between the ice is caught, and if the first blade 421 is continuously rotated while the ice is stuck, an overload is applied to the motor 600 and the ice is broken.

In the case of the present invention, due to the formation of the guide ribs 310, the step difference from the end 313 of the guide surface 311 located just before the ice discharge port 400b is based on the counterclockwise direction in which the blades 421 and 422 rotate. Therefore, the ice 10 of the ice storage unit 400 is guided counterclockwise along the guide surface 311 of the guide rib 310 by rotation of the first blade 421 to prevent the It falls from the end 313 to the upper surface 300b of the bottom plate 300. In this case, as the rotational motion of the blade 421 is added to the falling ice 10, the ice 10 falls as the ice 10 falls and the portion of the ice in contact with the first blade 421 changes. It is smoothly discharged through the ice discharge port 400b without being pinched between the blade 421 and the side end portion 400c of the ice discharge port 400b.

In addition, a stopper rib 320 protruding from the upper surface 300a of the bottom plate 300 at a position spaced apart from the end 313 of the guide rib 310 with the ice discharge port 400b interposed therebetween is the bottom plate 300 ) Is formed extending from the center to the edge.

The ice 10 rotated by being pushed by the first blade 421 is caught by the stopper rib 320 and cannot cross the stopper rib 320 and is guided outward along the stopper rib 320 to the ice discharge port 400b. Is ejected. In addition, the ice in the inner space of the ice storage unit 400 is pushed to the outside by the second blade 422 and then guided to the outside along the stopper rib 320 by the first blade 421 to the ice discharge port 400b. Since it is discharged, the ice in the ice storage unit 400 is evenly stirred and is smoothly discharged through the ice discharge port 400b.

Meanwhile, a plurality of slit-shaped drain holes 330 are formed around an edge of the bottom plate 300. The ice stored in the ice storage unit 400 is melted as time passes, and the water in which the ice melts is introduced into the cold water tank 500 through the drain hole 330.

Since the inner space of the ice storage unit 400 and the cold water tank 500 communicate with each other through the drain hole 330, when the drain hole 330 is enlarged, the temperature is relatively higher than that of the ice storage unit 400. The amount of melting of ice increases due to the influence of the high temperature of the cold water tank 500.

Therefore, the drain hole 330 is preferably formed to have a minimum size in order to minimize the amount of ice melting due to the temperature of the cold water tank 500, so that the drain hole 330 has a narrow slit shape. At the same time, it is formed only in a partial area around the edge of the bottom plate 300.

Referring to FIG. 5, a stopper rib 320 is formed at a position spaced apart from the front end 313 of the guide rib 310, and an ice discharge port is formed on the upper side between the guide rib 310 and the stopper rib 320. (400b) is formed.

When the lower end (400d) of the ice discharge port (400b) is formed at the same or lower position as the upper surface (300b) of the bottom plate (300), the ice melted water is between the ice discharge gate (430) and the ice discharge port (400b) It can leak through the gap of.

In the present invention, the lower part (400d) of the ice discharge port (400b) is formed at a higher position than the upper surface (300b) of the bottom plate (300). The space (G) between the upper surface (300b) of the plate (300), the side surface of the bottom plate (300) and the body part (400a) of the ice storage unit (400) by sequentially passing through the inner surface to the cold water tank (500). By allowing it to flow down, it is possible to prevent leakage through the gap between the ice discharge gate 430 and the ice discharge port 400b.

In addition, the melted ice water is blocked by the stopper rib 320 and does not pass to the area of the top surface 300b of the bottom plate 300 and flows toward the drain hole 330. Therefore, it is possible to prevent water from accumulating in the area of the top surface 330b. Can be prevented.

Inside the cold water tank 500, a circulation pump (not shown) for supplying the water in the cold water tank 500 to the nozzle 251, and a nozzle connection passage 255 between the circulation pump and the nozzle unit 250 ) Is provided with a cold water tank connection line (not shown) connecting between.

The cold water tank 500 is not provided with a separate cooling means such as a cooling coil, and the water cooled by the ice making unit 200 flows into the cold water tank 500, so that the number of components is reduced and the structure is improved. It becomes simple.

According to the configuration as described above, ice is prevented from sticking to each other by providing a rotating blade in the ice storage unit, and a guide rib and a stopper rib protruding along the outer circumference of the bottom plate are formed to form ice between the blade and the body of the ice storage unit. It prevents the sticking and the ice is smoothly discharged through the ice discharge port.

As described above, the present invention is not limited to the above-described embodiments, and modifications are apparent by those of ordinary skill in the art without departing from the technical spirit of the present invention claimed in the claims. It is possible, and such modifications are within the scope of the present invention.

100: water purification tank 200: ice-making unit
210: ice maker 211: body
212: ice making groove 220: evaporation pipe
230: ice maker holder 240: ice guide
241: swash plate 241a: through hole
244: ice curtain 250: nozzle part
251: nozzle 252: upper nozzle plate
253: lower nozzle plate 255: nozzle connection passage
300: bottom plate 310: guide rib
320: stopper rib 400: ice storage unit
410: rotation shaft 421: first blade
422: second blade 430: ice discharge gate
440: ice sensor 500: cold water tank
600: motor

Claims (12)

An ice storage unit for storing ice generated in the ice making unit;
An ice discharge port for discharging the ice stored in the ice storage unit to the outside;
A bottom plate forming the bottom of the ice storage unit;
Including a blade rotating to prevent the ice from sticking to the ice storage unit,
At the edge of the upper surface of the bottom plate, a guide rib protruding upward along the outer circumference and formed at a position immediately before the ice discharge port based on the rotation direction of the blade, the front end is stepped, and a guide rib formed to be inclined toward the ice discharge port. Formed ice machine. delete The method of claim 1,
The ice maker, wherein the guide rib is formed to be inclined in a width direction so as to decrease toward an inner direction of the ice storage unit. The method of claim 1,
An ice maker, wherein a stopper rib protruding from an upper surface of the bottom plate is formed at a position spaced apart from a front end of the guide rib. The method of claim 4,
The stopper rib is an ice maker, characterized in that extending from the center to the edge of the bottom plate. The method of claim 1,
An ice maker, characterized in that the lower end of the ice discharge port is formed at a position higher than the upper surface of the bottom plate. The method of claim 1,
A cold water tank for storing cold water is provided under the ice storage unit,
The ice storage unit and the cold water tank, characterized in that one body is divided into upper and lower spaces by the bottom plate. The method of claim 1,
The blade is composed of a first blade and a second blade respectively connected to an upper side and a lower side of a rotating shaft that rotates by driving a motor;
The first blade includes a first horizontal portion extending in a horizontal direction from the rotation axis, and a first bent portion downwardly bent outward from an end of the first horizontal portion;
The second blade has an overall length shorter than that of the first blade;
The ice maker, characterized in that the first blade and the second blade are provided to intersect when viewed in a plan view. The method of claim 8,
The second blade has a second horizontal portion extending in a horizontal direction from the rotation axis and formed shorter than the first horizontal portion, and downwardly bent downward at an end of the second horizontal portion, but bent at a smaller angle than the first bent portion. An ice maker comprising a second bent portion. The method of claim 1,
The ice maker, wherein the bottom plate has an inclined shape that decreases from the center to the edge. The method of claim 1,
An ice maker, characterized in that a plurality of drain holes are formed around an edge of the bottom plate. The method of claim 11,
The drain hole is an ice maker, characterized in that formed only in a partial area around the edge of the bottom plate.

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