KR20120138851A - Ice maker - Google Patents

Abstract

PURPOSE: An ice supply device is provided to include an elastic member generating elastic force in between a cover unit and a connection unit and the cover unit is closely adhered to an outlet, thereby completely blocking a discharge of ice. CONSTITUTION: An ice supply device(1) comprises an ice storage unit, an ice discharging module(10), and an ice supply unit. The ice storage unit is composed of a first ice storage unit(110) and a second ice storage unit(120). The second ice storage unit is extended from the first ice storage unit to a first direction and an outlet is formed in the second ice storage unit. The ice discharging module is arranged in the first and second ice storage units. The ice discharging module comprises a transferring member(140) transferring the ice stored in the ice storage unit to the outlet. The ice supply unit is formed on the top of the ice discharging module and supplies the ice to the ice storage unit by generating the ice.

Description

Ice Feeder {ICE MAKER}

The present invention relates to an ice feeder, and more particularly, to an ice feeder used for an ice water purifier.

Recently, the use of water purifiers providing cold water and hot water is increasing in homes and offices. In particular, the use of a water purifier having an ice supply device capable of supplying ice in addition to cold water or hot water is increasing. In general, the ice supply device stores the ice generated by the ice generating module in the ice reservoir, and controls the discharge of the ice by controlling a cover part which controls opening and closing of the transfer member and the discharge port disposed in the ice reservoir.

When an outlet for discharging ice is formed on one sidewall of the ice reservoir, in the region adjacent to the outlet, ice stacked up to an upper region of the transfer member interferes with adjacent ice between the transfer member and the sidewall. The phenomenon occurs. As a result, the transfer member may not operate smoothly, and as a result, the movement of the ice may not be smooth and the discharge of the ice may not be easily performed. In addition, the cover part is rotated about the upper portion of the outlet opening and closing the outlet, the upper surface of the cover portion is in close contact with the outlet due to the characteristic of rotating around the top of the outlet, but the lower surface of the cover portion is slightly spaced apart from the outlet And stop. Therefore, there was a problem that the outlet can not be completely closed.

Accordingly, the technical problem of the present invention was conceived in this respect, and an object of the present invention is to provide an ice supply device which can easily discharge ice and stably open and close the ice discharge port.

Ice supply apparatus according to an embodiment for realizing the above object of the present invention includes an ice discharge module and an ice supply unit. The ice discharge module includes an ice storage unit and a transfer member. The ice storage unit includes a first ice storage unit and a second ice storage unit extending in a first direction from the first ice storage unit and having an outlet. The transport member is disposed in the first and second ice storage units, The ice stored in the ice storage unit is transferred to the outlet. The ice supply unit is formed on the ice discharge module and generates ice and provides the ice to the ice storage unit.

In one embodiment, the ice receiving space of the first ice storage unit may be larger than the receiving space of the second ice storage unit.

In one embodiment, the transfer member may include a rotation center axis extending in the first direction and a guide unit for rotating the ice around the rotation center axis to guide the ice.

In one embodiment, the second ice storage portion is formed in a cylindrical shape, the inner diameter of the second ice storage portion may be the same as the diameter of the guide portion.

In one embodiment, adjacent to the second ice storage unit, it may further include an ice discharge unit for rotating the top of the outlet to control the opening and closing of the outlet.

In one embodiment, the ice discharge portion may have a shape corresponding to the discharge port and may include a cover part in close contact with the discharge hole.

In one embodiment, the cover portion may include a close contact with the outlet, the close contact portion is divided into an upper surface and a lower surface, the lower surface is controlled by an elastic force may be in close contact with the outlet.

In one embodiment, the rotation angle of the lower surface portion with respect to the upper portion of the outlet may be greater than the rotation angle of the upper surface portion.

In one embodiment, the ice discharge portion is connected to the cover portion further comprises a connecting portion for rotating the cover portion about the upper portion of the discharge port, the cover portion elastic member for generating a tension force between the cover portion and the connecting portion It may include.

In an embodiment, the cover part may include a first rib, and the first rib may be coupled to the connection part to prevent the cover part from rotating about the connection part.

In one embodiment, the discharge port may be formed with a discharge guide for guiding the discharged ice.

In one embodiment, the discharge guide portion may include a plurality of second ribs arranged in parallel with each other, the interval of the second ribs may be narrower than the width of the ice discharged.

According to the present invention, the ice storage unit includes a first ice storage unit and a second ice storage unit extending from the first ice storage unit, and the transfer member is disposed in the first and second ice storage units, The inner diameter of the second ice storage unit may be the same as the diameter of the guide unit, thereby preventing interference caused by ice accumulated from the region adjacent to the outlet to the upper region of the guide unit. Therefore, the mutual interference between the ice and the guide unit may be reduced within the second ice storage unit, and ice may be discharged to the discharge port more smoothly.

The ice discharge part may include a cover part and a connection part to rotate the cover part, and the cover part may include an elastic member that generates an elastic force between the cover part and the connection part, and thus the cover part may be controlled by an elastic force to be provided to the outlet. It can be in close contact overall. This can completely block the discharge of ice.

1 is a schematic block diagram showing an ice supply apparatus according to an embodiment of the present invention.
2 is a perspective view showing the ice discharge module of FIG.
3 is a cross-sectional view of the ice discharge module of FIG. 2 taken along the line II '.
4 is a perspective view illustrating the lid of FIG. 2.
FIG. 5 is an enlarged cross-sectional view of region 'A' of FIG. 2.
6A and 6B are cross-sectional views illustrating a closed state of the lid of FIG. 3.
FIG. 7 is a plan view illustrating the discharge guide unit of FIG. 2. FIG.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. It is to be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but on the contrary, is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. Like reference numerals are used for like elements in describing each drawing. The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "comprise" or "consist of" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

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

1 is a schematic block diagram showing an ice supply apparatus according to an embodiment of the present invention.

Referring to FIG. 1, the ice supply device 1 according to the present embodiment includes an ice supply unit 20, an ice discharge module 10, and a cold water storage unit 30.

The ice supply unit 20 receives ice from the outside to generate ice, and defrosts the ice to supply the ice to the outside. Specifically, the ice supply unit 20 receives the purified water from the outside to generate ice, and supplies the ice to the ice storage unit 100 and the cold water storage unit 30 of the ice discharge module 10. The ice supply unit 20 includes an ice generator 22 for generating ice and a guide adjuster 24 for guiding and controlling the movement of the generated ice. The ice generator 22 includes an ice making frame (not shown) used as a frame of ice generated and a cooling tube (not shown) for cooling the ice making frame. When a refrigerant having a temperature below freezing point circulates along the cooling tube, the ice making mold in contact with the cooling tube is cooled to instantly cool and ice the water provided to the ice making mold. The iced ice particles grow, resulting in ice.

The ice discharge module 10 is an ice storage unit 100 for receiving and storing the ice generated by the ice supply unit 20 and an ice discharge unit for discharging the ice stored in the ice storage unit 100 to the outside ( 200). The ice storage unit 100 has a constant ice receiving space with an open top, and is formed at the lower portion of the ice supply unit 20 to receive and store the ice generated by the ice supply unit 20. The ice discharge unit 200 is formed at one side of the ice storage unit 100 to provide a passage for discharging the ice stored in the ice storage unit 100 to the outside. The ice discharge module 10 will be described in more detail below with reference to FIGS. 2 to 6.

The cold water storage unit 30 has a constant cold water receiving space with an open upper portion, is formed in the lower portion of the ice supply unit 20. Cold water is stored in the cold water storage unit 30, and the cold water storage unit 30 receives ice selectively from the ice supply unit 20 to adjust the temperature of the cold water stored in the cold water storage unit 30.

2 is a perspective view showing the ice discharge module of FIG. 3 is a cross-sectional view taken along the line II ′ of the ice discharge module of FIG. 2. 4 is a perspective view illustrating the lid of FIG. 2. FIG. 5 is an enlarged cross-sectional view of region 'A' of FIG. 2.

2 and 3, the ice discharge module 10 according to the present embodiment includes an ice storage unit 100 and an ice discharge unit 200.

The ice storage unit 100 has a constant ice receiving space with an open top, and accommodates and stores ice desorbed from the ice supply unit. The ice storage unit 100 includes a first ice storage unit 110 and a second ice storage unit 120. The second ice storage unit 120 extends in the first direction D1 from the first ice storage unit 110. Specifically, the ice storage unit 100 includes a first side wall 112 and a second side wall 114 opposite to the first side wall 112, and the second ice storage unit 120 includes the first side wall 112. The first sidewall 112 extends in the first direction D1. The second ice reservoir includes an outlet 124. In detail, the second ice storage unit 120 has a cylindrical shape and includes a third sidewall 122 facing the second sidewall 114. The third sidewall 122 is formed with an outlet 124 for discharging ice. The ice storage unit 100 may include a temporary storage unit 130 for receiving water formed by melting some of the ice stored in the first and second ice storage units.

The ice storage unit 100 includes a transfer member 140 for moving the ice stored in the ice storage unit 100 in one direction. The transfer member 140 includes a rotation center axis 142 extending in the first direction D1 and a guide part 144 rotating around the rotation center axis 142 to guide ice in one direction. . For example, the guide part 144 has a shape of a rotary blade formed in a screw manner, and moves ices stored between the rotary blades in the first direction D1 according to the rotation of the central axis of rotation 142. Let's do it.

The transfer member 140 is disposed in the first and second ice storage units 110 and 120. Specifically, the transfer member 140 extends from the second side wall 114 of the first ice storage unit 110 to the third side wall 122 of the second ice storage unit 120. Specifically, the rotation center axis 142 of the transfer member 140 is formed to penetrate from the second side wall 114 to the third side wall 122, the guide portion 144 and the second side wall ( It extends from 114 to the third side wall 122. A driving unit (not shown) for rotating the rotation center axis 142 may be formed at one end of the rotation center axis 142.

The ice receiving space of the second ice storage 120 is smaller than the ice containing space of the first ice storage 110. For example, the height of the second ice storage unit 120 is smaller than the height of the first ice storage unit 110. The inner diameter of the second ice storage unit 120 having a cylindrical shape is the same as or slightly larger than the diameter of the guide unit 144 of the transfer member 140. Accordingly, the guide part 144 extends to the inside of the second ice storage part 120, and the end of the guide part 144 is in close contact with the upper surface of the second ice storage part 120.

The outlet 124 of the second ice storage unit 120 is formed under the third sidewall 122. The outlet 124 is formed by opening the third sidewall 122 in a predetermined shape, and is formed below the region through which the rotation center axis 142 of the transfer member 140 penetrates the third sidewall 122. . The outlet 124 is formed to have a size enough to pass the ice stored in the ice storage unit 100.

The transfer member 140 rotates so that the ice stored in the ice storage unit 100 can move in the direction in which the discharge port 124 is formed. Therefore, the ice stored between the guide part 144 moves to the discharge port 124 as the transfer member 140 rotates, and is finally discharged to the discharge port 124.

According to the present embodiment, the ice storage unit includes a first ice storage unit and a second ice storage unit extending in a first direction from the first ice storage unit and having an outlet, and the transfer member includes the first and second ice storage units. Placed in ice reservoirs. When the ice reservoir includes only the first ice reservoir and an outlet for discharging ice is formed in the first ice reservoir, ice stacked from the region adjacent to the outlet to the upper region of the guide portion of the transfer member. They interfere with each other and the ice disposed between the guide portion or the guide portion. As a result, the guide portion may not rotate smoothly, and as a result, the movement of the ice is not smooth and the discharge of the ice is not easy. However, according to the present embodiment, the second ice storage portion has a smaller ice receiving space than the first ice storage portion, and the inner diameter of the second ice storage portion is formed to be the same as the diameter of the guide portion, thereby adjoining the outlet. The interference phenomenon due to the ice accumulated from the region to the upper region of the guide part can be prevented. That is, since the guide part of the conveying member is inserted in close contact with the second ice storage part, only the height of the guide part is loaded in the second ice storage part. Therefore, the mutual interference between the ice and the guide unit may be reduced within the second ice storage unit, and ice may be discharged to the discharge port more smoothly.

The ice discharge unit 200 is disposed adjacent to the second ice storage unit 120, and rotates about the upper portion of the discharge port 124 to control the opening and closing of the discharge port 124. The ice discharge part 200 includes a cover part 210 and a connection part 220.

The cover portion 210 has a shape corresponding to the inlet of the outlet 124 and has a structure in close contact with the outlet 124. Specifically, the cover part 210 includes a close contact portion 211 in close contact with the outlet 124, the close contact portion 211 is in close contact with the inlet of the outlet 124 to the outlet 124 To close. For convenience of description, the close contact portion 211 is divided into an upper surface portion 211a and a lower surface portion 211b. The close contact portion 211 may include an elastic member such as rubber to completely close the outlet 124.

The connection part 220 is connected to the cover part 210 to rotate the cover part about an upper portion of the outlet 124. In detail, the connection part 220 forms a rotation shaft 222 on the upper portion of the outlet 124, and rotates around the rotation shaft 222 according to an external driving force. The ice discharge unit 200 may include a driving device 230 for generating a rotational force, the driving device 230 is connected to one side of the rotating shaft 222 to connect the connection portion 220 to the discharge port 124 Can be rotated around the top of the The connection part 220 includes a rotation connection part 224 connecting the rotation shaft 222 and the central portion 212 of the cover part 210. The cover portion 210 is rotated about the upper portion of the outlet 124 together with the connecting portion 220 by the rotation connecting portion 224. A detailed shape of the cover 210 will be described below in more detail with reference to FIGS. 4 and 5.

The cover portion 210 includes an elastic member 214 for generating a tensile force between the center portion 212 and the rotary connection portion 220 of the cover portion. The elastic member 214 includes a spring. When the center portion 212 of the cover portion and the connection portion 220 are coupled, the elastic member 214 corresponds to a compressed state. The elastic member 214 basically has a tensile force that pushes the central portion 212 and the connecting portion 220 to each other. The cover part 210 and the connection part 220 are not completely fixed and fastened, and the cover part 210 and the connection part 220 are fastened so that the gap between the cover part center 212 and the connection part 220 may be flown by a predetermined distance. Therefore, the tensile force of the elastic member 214 also varies according to the separation distance between the center portion 212 of the cover portion and the connection portion 220.

The ice discharge unit 200 may further include a discharge guide unit 240 for guiding the ice discharged from the discharge port 124. The discharge guide part 240 includes a guide plate 242 which guides ice in one direction and has a plate shape, and sidewalls 244 formed at both ends of the guide plate to prevent the ice from escaping. Ice discharged from the discharge port 124 is moved along the discharge guide 240 to be finally discharged to a designated position.

2, 4, and 5, the cover part 210 has a central portion 212 connected to the connection part 220. The central portion 212 includes a recess 216 recessed to a predetermined depth and a first rib 218 projecting to a predetermined length.

The elastic member 214 is inserted into the recess 216. The elastic member 214 is in a compressed state by the rotation connecting portion 224 of the connecting portion. Thus, the elastic member 214 provides a tension force for pushing the connecting portion 220 and the cover portion 210 in opposite directions. The cover part 210 and the connection part 220 are fastened so that a gap between the central part 212 of the cover part and the connection part 220 can be moved by a predetermined distance. Specifically, the center portion 212 of the cover portion has a protrusion 212a protruding to a predetermined length, the connection connecting portion 224 of the connecting portion is fastened to be able to move a predetermined distance along the protrusion 212a. When the separation distance between the center portion 212 of the cover portion and the rotation connecting portion 224 is changed, the tensile force of the elastic member 214 is also changed.

As a result, the cover 210 is in close contact with the outlet 124 not only by the rotational force of the connecting portion 220 but also by the elastic force of the elastic member 214, that is, the tensile force. In particular, the lower surface portion 211b of the close contact portion 211 of the cover 210 may be in close contact with the outlet 124 to the elastic force of the elastic member 214. The lower surface portion 211b is in close contact with the outlet 124 to the elastic force of the elastic member 214 will be described in detail with reference to Figure 6a and 6b. A plurality of recesses 216 may be formed, and an elastic member 214 may be inserted into each of the recesses 216.

The first rib 218 extends in one direction on the center portion 212 of the cover part. Concave portions (not shown) corresponding to the first ribs 218 are formed in the rotation connecting portion 224, and the first ribs 218 are coupled to the concave portions. Therefore, the cover part 210 is prevented from rotating about the center portion 212 by the combination of the first rib 218 and the concave portion, thereby being able to be securely and accurately adhered to the outlet 124. have.

6A and 6B are cross-sectional views illustrating a closed state of the lid of FIG. 3.

3 and 6A, the cover part 210 rotates about an upper portion of the outlet 124 according to the rotation of the connection part 220 to close the outlet 124. However, since the rotating shaft 222 of the connecting portion 220 is slightly spaced apart from the outlet 124, only the rotation of the connecting portion 220 allows the cover portion 210 to be in close contact with the outlet 124. Can't. Specifically, since the upper surface portion 211a of the close contact portion 211 of the cover portion is closer to the discharge port 124 than the lower surface portion 211b, the upper surface portion 211a is in close contact with the discharge hole 124. The rotation angle θ is smaller than the rotation angle θ ′ for the lower surface portion 211b to closely contact the outlet 124. Therefore, as the connecting portion 220 rotates, the upper surface portion 211a comes into close contact with the outlet 124 earlier than the lower surface portion 211b. Therefore, in this case, the lower surface portion 211b does not come into close contact with the outlet 124 and has a predetermined distance. Therefore, the outlet 124 is not completely closed.

However, since the cover part 210 includes an elastic member 214 for generating a tensile force between the cover part and the connecting part 220, the cover part 210 is a tensile force of the elastic member 214. It is pushed toward the outlet 124 by the. Therefore, the lower surface portion 211b having a predetermined distance from the outlet 124 is in close contact with the outlet 124 by the tensile force of the elastic member 214. That is, torque is generated about the upper surface portion 211a by the elastic member 214 to bring the lower surface portion 211b into close contact with the outlet. A configuration in which the lower surface portion 211b is in close contact with the discharge port 124 will be described with reference to FIG. 6B.

3 and 6B, the lower surface portion 211b of the close contact portion 211 is in close contact with the outlet 124 together with the upper surface portion 211a. Specifically, the upper surface portion 211a is in close contact with the outlet 124 by the rotation of the connecting portion 220, the lower surface portion 211b is the rotation of the connecting portion 200 and the elastic member 214 of It is in close contact with the outlet 124 by a tensile force. As a result, the rotation angle θ 'of the lower surface portion 211b is larger than the rotation angle θ of the upper surface portion 211a. Therefore, the cover part 210 may be in close contact with the outlet 124 as a whole to completely block the discharge of ice.

FIG. 7 is a plan view illustrating the discharge guide unit of FIG. 2. FIG.

2 and 7, the discharge guide part 240 guides the ice discharged from the discharge port 124 in one direction. The guide plates 242 of the discharge guide part 240 are formed with a plurality of second ribs 246 arranged in parallel with each other. The second ribs 246 are formed in the direction in which the ice is guided, and the gap between the second ribs 246 is formed to be smaller than the width of the ice discharged. When the ribs are not formed in the guide plate 242, the entire surface of one surface of the ice is in surface contact with the guide plate, and the surface contact interferes with the movement of the ice. Therefore, there is a problem that the ice does not move smoothly to the bottom. However, the guide plate 242 includes the second ribs 246 formed at a narrower interval than a width of one ice to be formed, so that the ice and the guide plate 242 are in line contact with each other. The ice can move smoothly.

As described above, the ice storage unit includes a first ice storage unit and a second ice storage unit extending from the first ice storage unit, and the transfer member is disposed in the first and second ice storage units. The inner diameter of the second ice storage unit may be the same as the diameter of the guide unit, thereby preventing interference caused by ice accumulated from the region adjacent to the outlet to the upper region of the guide unit. Therefore, the mutual interference between the ice and the guide unit may be reduced within the second ice storage unit, and ice may be discharged to the discharge port more smoothly.

The ice discharge part may include a cover part and a connection part to rotate the cover part, and the cover part may include an elastic member that generates an elastic force between the cover part and the connection part, and thus the cover part may be controlled by an elastic force to be provided to the outlet. It can be in close contact overall. This can completely block the discharge of ice.

The ice supply apparatus according to the present invention has industrial applicability that can be used for ice water purifiers used for home and business.

Although described above with reference to the embodiments, those skilled in the art can be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims below. I can understand.

1: ice supply device 10: ice discharge module
20: ice supply unit 30: cold water storage unit
100: ice storage unit 110, 120: first and second ice storage unit
130: temporary storage 140: transfer member
200: ice discharge portion 210: cover portion
220: connecting portion 230: driving element
240: discharge guide portion

Claims (12)

An ice storage unit including a first ice storage unit and a second ice storage unit extending in a first direction from the first ice storage unit and having an outlet;
An ice discharge module disposed in the first and second ice storage units and including a transfer member for transferring the ice stored in the ice storage unit to the discharge port; And
And an ice supply unit formed on an upper portion of the ice discharge module and generating ice and providing the ice to the ice storage unit. The ice supply apparatus of claim 1, wherein an ice receiving space of the first ice storage unit is larger than an accommodation space of the second ice storage unit. The ice supply apparatus of claim 2, wherein the transfer member comprises a rotation center axis extending in the first direction and a guide part rotating around the rotation center axis to guide ice. The ice supply apparatus of claim 3, wherein the second ice storage unit has a cylindrical shape, and an inner diameter of the second ice storage unit is the same as a diameter of the guide unit. The ice supply apparatus of claim 1, further comprising an ice discharge unit adjacent to the second ice storage unit and rotating around an upper portion of the discharge port to control the opening and closing of the discharge port. The ice supply apparatus according to claim 5, wherein the ice discharge part has a shape corresponding to the discharge hole and includes a cover part in close contact with the discharge hole. The ice supply apparatus according to claim 6, wherein the cover part includes a close contact part in close contact with the outlet, the close contact part is divided into an upper face part and a lower face part, and the lower face part is controlled by an elastic force to be in close contact with the outlet part. The ice supply apparatus of claim 7, wherein a rotation angle of the lower surface portion with respect to an upper portion of the outlet is greater than a rotation angle of the upper surface portion. The method of claim 7, wherein
The ice discharge part further comprises a connection part connected to the cover part to rotate the cover part about the upper portion of the outlet,
The cover part is characterized in that the ice supply device characterized in that it comprises an elastic member for generating a tensile force between the cover portion and the connecting portion. The ice supply apparatus of claim 9, wherein a first rib is formed on the cover part, and the first rib is coupled to the connection part to prevent the cover part from rotating about the connection part. The ice supply apparatus of claim 1, wherein the discharge port has a discharge guide part configured to guide the discharged ice. The ice supply apparatus of claim 11, wherein the discharge guide part comprises a plurality of second ribs arranged in parallel with each other, and a distance between the second ribs is narrower than a width of ice discharged.

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