KR20120138850A - Ice making module and ice maker having the same - Google Patents

Abstract

PURPOSE: An ice supply module and an icing supply device with the same are provided to judge first to third positions on a guide plate depending on positions of a position bar, thereby properly adjusting a position of a storage unit where ice generated by an icing generating unit is moved to. CONSTITUTION: An ice supply module(100) comprises an ice making unit(110), a guide plate(120), and a guide regulating unit(130). The icing generating unit generates ice. The guide plate is formed in the lower part of the icing generating unit. The guide plate guides the ice separated from the ice generating unit. The guide regulating unit comprises a driving unit(134) and a position sensor. The driving unit rotates the guide plate and the position sensor judges a position of the guide plate.

Description

ICE MAKING MODULE AND ICE MAKER HAVING THE SAME

The present invention relates to an ice supply module and an ice supply apparatus having the same, and more particularly, to an ice supply module and an ice supply apparatus having the same.

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 unit sprays purified water to an ice tray that simultaneously ices a plurality of ices, cools the water filled in the ice tray to ice the ice, and forms ice iced from the ice tray under the ice tray. Follow the guide plate to the ice reservoir using the guide plate.

The guide plate is rotated by a separate drive to adjust the supply position of the ice, the conventional ice supply device, the configuration of the drive is configured separately from the guide plate is not simple and occupies a rather large space. In addition, the configuration of the sensor unit for determining the position of the guide plate is also formed separately, the use of space as a whole was inefficient. In addition, since the position of the guide plate controlled by the driving unit is limited, the distribution of ice stored in the ice storage unit is uneven, and thus the discharge of the ice is not easy.

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 module and an ice supply device having the same, which can efficiently control the supply of ice with a simple configuration.

Ice supply module according to an embodiment for realizing the object of the present invention includes an ice generating unit, a guide plate and a guide adjusting unit for generating ice. The guide plate is formed under the ice generator, and guides the ice separated from the ice generator. The guide adjusting part includes a driving part for rotating the guide plate and a position sensor part for determining the position of the guide plate.

In one embodiment, the driving unit may include a position bar that rotates in conjunction with the rotation of the guide plate.

In one embodiment, the position sensor unit may be formed adjacent to the position bar and determine the position of the guide plate through the position of the position bar.

In one embodiment, the driving unit may adjust the rotation of the guide plate according to the position of the guide plate provided through the position sensor unit.

The position sensor unit may include a plurality of position sensors formed around the position bar, and each of the position sensors may determine different positions of the position bar.

In one embodiment, the guide plate may include a plurality of ribs arranged parallel to each other.

In one embodiment, the spacing of the ribs may be narrower than the width of the ice generated from the ice generator.

In one embodiment, the guide plate may further include a water injection unit formed in the lower portion of the guide plate for injecting water into the ice generating unit.

In one embodiment, the water jet unit may include a jet hole formed through the guide plate.

Ice supply apparatus according to an embodiment for realizing another object of the present invention is an ice supply module, a cold water reservoir having a cold water storage space disposed in the lower portion of the ice supply module and adjacent to the cold water reservoir and the ice receiving space It includes an ice reservoir having a. The ice supply module includes an ice generator that generates ice, a guide plate, and a guide adjuster. The guide plate is formed under the ice generator, and guides the ice separated from the ice generator. The guide adjusting part includes a driving part for rotating the guide plate and a position sensor part for determining the position of the guide plate.

In one embodiment, the drive unit may include a position bar that rotates in conjunction with the rotation of the guide plate, the position sensor unit may be adjacent to the position bar and determine the position of the guide plate through the position of the position bar.

In one embodiment, the position sensor unit includes first to third position sensors formed around the position bar, wherein the first to third position sensors respectively determine the first to third positions of the position bar. Can be.

In one embodiment, the first position of the position bar corresponds to a position where ice guided by the guide plate is transferred to the first region of the ice reservoir, and the second position of the position bar is guided by the guide plate. The guided ice may correspond to a position where the ice is transferred to the second region, and the third position of the position bar may correspond to a position where the ice guided by the guide plate is transferred to the cold water reservoir.

In one embodiment, the location bar includes first and second location bars extending in opposite directions from the center of the drive unit, the first location sensor is formed at an end of the second location bar, The second position sensor may be formed at an upper portion of the first position bar, and the third position sensor may be formed at a lower portion of the first position bar.

According to the present invention, the ice supply module is disposed on the side of the guide plate includes a guide adjusting portion for adjusting the rotation of the guide plate, the driving portion of the guide adjusting portion includes a drive element and the position bar, the position of the guide adjusting portion The sensor unit may appropriately adjust the position of the reservoir to which the ice generated from the ice generator is to be moved by determining the first to third positions of the guide plate according to the position of the location bar. Thereby, the ice stored in the ice reservoir can be evenly distributed or the cold water temperature of the cold water reservoir can be efficiently controlled.

In addition, the guide plate may include a plurality of ribs to smoothly move the ice. In addition, by forming a water jetting portion in the lower portion of the guide plate, it is possible to spray the purified water to the ice generating unit more efficiently.

1 is a schematic side view showing an ice supply apparatus according to an embodiment of the present invention.
2 is a perspective view showing the ice supply module of FIG.
3 is a cross-sectional view taken along the line II ′ of the ice supply module of FIG. 2.
4 is a schematic plan view illustrating a main body of an ice generator of FIG. 2.
FIG. 5 is a cross-sectional view of the guide plate and the water jetting part of FIG. 2 taken along the line II-II '. FIG.
6a to 6b are side views for explaining the movement of the ice supply module of 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 side view showing an ice supply apparatus according to an embodiment of the present invention.

Referring to FIG. 1, the ice supply device 10 according to the present embodiment includes an ice supply module 100, an ice reservoir 200, and a cold water reservoir 300.

The ice supply module 100 generates ice by receiving water from the outside, and defrosts the generated ice and supplies it to the outside. Specifically, the ice supply module 100 receives the purified water from the outside to generate ice, and supplies the ice to the ice reservoir 200 and the cold water reservoir 300. Detailed configuration of the ice supply module 100 will be described in detail with reference to FIGS. 2 and 3.

The ice reservoir 200 has a constant ice receiving space is opened at the top, is formed in the lower portion of the ice supply module (100). The ice reservoir 200 accommodates and stores the ice generated by the ice supply module 100. A temporary storage unit 210 may be formed at a lower portion of the ice reservoir 200 to accommodate water formed by melting some of the ice stored in the ice reservoir. The ice reservoir 200 may include a transfer member 220 for moving the ice stored in the ice reservoir 200 in one direction.

The cold water reservoir 300 has a constant cold water receiving space is opened at the top, is formed in the lower portion of the ice supply module (100). Specifically, the cold water reservoir 300 is formed by being divided by the ice reservoir 200 and a predetermined partition 310, and is formed directly under the ice supply module 100. That is, the ice reservoir 200 is formed to be spaced apart from the ice supply module 100 by a predetermined distance in the horizontal direction, and the cold water reservoir 300 is divided into the ice reservoir 200 and the partition 310. It is formed in the direct lower region of the ice supply module 100.

Cold water is stored in the cold water reservoir 300. Specifically, the cold water reservoir 300 stores a constant amount of purified water, and receives the ice from the ice supply module 100 continuously. The temperature of the water stored in the cold water reservoir 300 may be adjusted to the reference cold water temperature by the ices supplied from the ice supply module 100. The location of the reservoir in which the ice produced by the ice supply module 100 is accommodated is controlled by the ice supply module 100.

The cold water reservoir 300 may include a temperature sensor unit 320 capable of measuring the temperature of the cold water stored in the cold water reservoir 300. The temperature sensor unit 320 determines the temperature of the cold water stored in the cold water reservoir 300, and according to the determined cold water temperature, the ice supply module 100 determines the position of the reservoir where the produced ice is to be accommodated. Done. The temperature sensor unit 320 may be formed on a sidewall of the cold water reservoir 300. Alternatively, the temperature sensor unit 320 may be formed at an appropriate position for determining the temperature of the cold water. For example, the temperature sensor unit 320 may be formed in the ice supply module 100.

2 is a perspective view showing the ice supply module of FIG. 3 is a cross-sectional view taken along the line II ′ of the ice supply module of FIG. 2. 4 is a schematic plan view illustrating a main body of an ice generator of FIG. 2. FIG. 5 is a cross-sectional view of the guide plate and the water jetting part of FIG. 2 taken along the line II-II '. FIG.

1 to 4, the ice supply module 100 includes an ice generator 110, a guide plate 120, a guide adjuster 130, and a water sprayer 140. The ice supply module 100 is disposed above the cold water reservoir 300.

The ice generator 110 includes a cover 110a and a main body 110b. The main body 110b includes an ice making frame 112, a cooling tube 114, and a heating unit 116.

The ice making frame 112 includes a body portion 112a and an intaglio portion 112b. The body portion 112a has a plate shape having a constant thickness, and the intaglio portion 112b is formed in plural number integrally with the body portion on the body portion. The intaglio portions 112b each have a shape of ice to be iced and are formed in a predetermined pattern on the body portion 112a. For example, the intaglio portions 112b are formed in a row at regular intervals on the body portion 112a. The intaglio portions 112b may form two rows parallel to the body portion 112a. The ice making frame 112 is disposed such that the open surface of the intaglio portion 112b faces the lower side where the guide plate 120 is formed.

The cooling tube 114 is formed on the body portion 112a. The cooling tube 114 is formed to extend continuously to contact the side surfaces and the bottom surfaces of the intaglio (112b). The cooling tube 114 is formed of a metal material having high thermal conductivity. For example, the cooling tube 114 may include copper. When the refrigerant having a temperature below freezing point circulates along the cooling tube 114, the intaglio portions 112b contacting the cooling tube are cooled, and water injected into the intaglio portions 112b is instantly cooled and iced. . As the iced ice particles grow, ice having the same shape as the engraved portion 112b is made.

The heating part 116 is disposed along the bottom surfaces of the engraved parts 112b. The heating unit 116 includes heating tubes 116a that receive heat from outside to generate heat. The heating tube 116a may be formed on the heat transfer plate 116b disposed along the bottom surfaces of the intaglio portions 112b. The heating unit 116 transfers heat to the intaglio portions 112b of the ice making frame 112. When the heat generated from the heating unit 116 is transferred to the intaglio 112b, a part of the ice of the intaglio 112b is melted, and the ice is freed from the intaglio 112b and falls. . Therefore, the ice formed in the intaglio portion 116 may be appropriately defrosted and dropped by controlling whether the heating unit 116 is heated.

The ice generator 110 may further include a sensor unit 118 disposed on the heating unit 116 and determining whether the heating unit is heated by measuring the temperature of the heating unit 116. have.

The guide plate 120 has a rectangular plate shape having a predetermined thickness and is disposed between the ice generator 110 and the cold water reservoir 300. Sidewalls may be formed at both sides of the guide plate 120 to prevent separation of ice. The guide plate 120 basically forms an angle with the ice making frame 112 of the ice generator 110, and one end of the guide plate 120 has the ice reservoir 200 and the cold water reservoir 300. It is arranged to be in close contact with the partition wall (310). A protrusion 312 may be formed at an upper end of the partition 310 to be in close contact with one end of the guide plate 120. Therefore, the ice that has been removed from the ice generator 110 falls on the guide plate 120 and moves downward along the guide plate 120 inclined at a predetermined angle.

A plurality of ribs 122 are formed in the guide plate 120 to smoothly move the ice dropped to the guide plate 120. The ribs 122 extend in a first direction D1 corresponding to a moving direction of ice according to gravity, and are formed in parallel with each other. Specifically, the ribs 122 are formed in a pattern of a grid, and the gaps of the ribs 122 are formed to be narrower than the width of one ice to be formed. When the ribs are not formed in the guide plate 120, 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 120 includes the ribs 122 formed at a narrower interval than a width of one ice to be formed, so that the ice and the guide plate 120 are in line contact with each other, so that You can move smoothly. The ribs 122 may be formed in a plurality of groups in which a predetermined number of ribs form one group. In the present embodiment, the ribs are formed of a plurality of groups, three ribs form a group.

The guide adjuster 130 is disposed on one side of the guide plate 120 to adjust the inclination of the guide plate 120. Specifically, the guide adjuster 130 is connected to one side of the guide plate 120, the guide plate 120 around the point where the guide adjuster 130 and the guide plate 120 is connected. By rotating), the inclination angle of the guide plate 120 is adjusted. When the guide plate 120 is inclined by the guide adjuster 130 at a larger angle, ie, counterclockwise, in the lower direction D2, a space between the partition 310 and the guide plate 120 is provided. This may cause ice to flow into the space. Accordingly, when the guide adjuster 420 cools the temperature of the cold water reservoir 300, the guide adjuster 420 rotates the guide plate 120 in a downward direction D2, that is, counterclockwise. Ice iced from 110 is introduced into the cold water reservoir 300.

The guide adjuster 130 includes a fixed body 132, a driver 134, and a position sensor 136. The fixed main body 132 has a shape of a rectangular frame for accommodating the driving unit 134 and the position sensor unit 136, and generates the guide plate 120 and the ice at one side of the guide plate 120. Connect the unit 110 to fix it. The driving unit 134 and the position sensor unit 136 are accommodated in the fixed body 132 and fixed.

The driving unit 134 is formed in the central region of the fixed body portion 132 and is connected to the guide plate 120 through the fixed body portion. In detail, the driving unit 134 includes a driving element 134a and a position bar 135. The driving element 134a provides a rotational force according to external power, and the rotation axis of the driving element is connected to the guide plate 120. Therefore, the guide plate 120 rotates around the driving unit 134 according to the driving of the driving unit 134.

The position bar 135 of the driving unit 134 provides a rotational position of the guide plate 120. Specifically, the position bar 135 includes a first position bar 135a and a second position bar 135b extending in opposite directions from the driving element 134a. The first and second location bars 135a and 135b rotate in association with the guide plate to indicate the rotational position of the guide plate 120. In this embodiment, the first and second position bars 135a and 135b are formed in parallel with the guide plate. That is, the first and second location bars 135a and 135b are formed in parallel with the first direction D1. The location bar 135 is connected to the guide plate 120 to rotate together with the rotation of the guide plate 120, thereby providing the inclined position of the guide plate 120 to the sensor unit 136. do.

The position sensor unit 136 includes first to third sensors 136a, 136b, and 136c to detect the inclined position of the guide plate 120. The first to third sensors 136a, 136b, and 136c are disposed along the circumference of the driving unit 134. Specifically, the first position sensor 136a is formed on the side of the second position bar 135b and is in contact with an end portion of the second position bar 135b. The second position sensor 136b is formed at an upper portion of the first position bar 135a, and the third position sensor 136c is formed at a lower portion of the first position bar 135a. That is, the first position bar 135a is disposed between the second and third position sensors 136b and 136c.

The first position sensor 136a serves to determine a basic position of the guide plate 120 (hereinafter referred to as a “first position”). Specifically, the first position of the guide plate 120 corresponds to a case where one side end of the guide plate 120 is in close contact with the partition 310 separating the ice reservoir 200 and the cold water reservoir 300. . Therefore, in the first position of the guide plate 120, all the ice dropped to the guide plate 120 is moved to the ice reservoir 200. The first position sensor 136a is formed to correspond to the position of the second position bar 135b corresponding to the guide plate 120 when the guide plate 120 is in the first position. That is, it is formed to be in close contact with an end portion of the second position bar 135b corresponding to the first position. Therefore, the first position sensor 136a may determine the case where the guide plate 120 is in the first position. Ice dropped to the guide plate 120 at the first position of the guide plate 120 is moved to the first area A of the ice reservoir 200.

The second position sensor 136b determines the maximum position (hereinafter, referred to as a “second position”) in which the guide plate 120 may rotate in the fourth direction D4, that is, the clockwise direction. Do it. Specifically, the second position of the guide plate 120 corresponds to a case where one end of the guide plate 120 is rotated further in the fourth direction D4 than at the first position. Ice dropped to the guide plate 120 in the second position is moved to the ice reservoir 200 as in the first position. However, in the second position, the guide plate 120 is further inclined in the fourth direction D4, so that the ice falling on the guide plate 120 is in the first direction rather than the first area A. The second area B spaced apart from the area D1 is dropped. Therefore, when ice is gathered to one side in the ice storage 200, by dispersing the receiving space of the ice, the ice in the ice storage 200 to be mixed evenly. In addition, the transfer of ice by the transfer member 220 can be more smoothly. The second position sensor 136b is formed on the first position bar 135a corresponding to the guide plate 120 when the guide plate 120 is in the second position. That is, the second position sensor 136b may determine the case where the guide plate 120 is in the second position.

The third position sensor 136c determines a maximum position (hereinafter, referred to as a “third position”) in which the guide plate 120 may rotate in the second direction D2 that is a downward direction, that is, counterclockwise. It plays a role. Specifically, the third position of the guide plate 120 corresponds to a case where one side end of the guide plate 120 is rotated further in the second direction D2 than at the first position. In the third position, a space is formed between the partition 310 and the guide plate 410, and ice may flow into the space. Therefore, the ice dropped to the guide plate 120 is moved to the cold water reservoir 300 differently from the first position. Thus, the inflow of ice in the cold water reservoir 300 can be controlled. The third position sensor 136c is formed under the first position bar 135a corresponding to the guide plate 120 when the guide plate 120 is in the third position. That is, the third position sensor 136c may determine the case where the guide plate 120 is in the third position.

Therefore, the driving unit 134 may adjust the rotation of the guide plate 120 using the position sensor unit 136. That is, the driving unit 134 is based on the temperature of the cold water provided from the temperature sensor unit 320 of the cold water reservoir 300 and the ice storage state of the ice reservoir 200, the first plate of the guide plate 120. To third position can be appropriately adjusted.

The water injection unit 140 is formed under the guide plate 120 to inject water into the ice generator 110 located above the guide plate 120. The water injection unit 140 includes a supply passage 142 for receiving water from the outside and an injection hole 144 for injecting water. The supply path 142 extends along the third direction D3 at a lower portion of the center of the guide plate 120. The supply path 142 receives a purified water from the outside and provides a pipe that provides the injection port 144. The injection hole 144 is connected to the supply path 142 and is formed through the guide plate 120. The outlet of the injection hole 144 is formed to face the ice generator 110. A plurality of injection holes 144 are formed, and sprays purified water to the ice making frame 110 of the ice generator 110 in a spray form.

As described above, the ice supply module 100 is disposed on the side of the guide plate and includes a guide adjustment unit for adjusting the rotation of the guide plate. The driving part of the guide adjusting part includes a driving element and a position bar, and the position sensor part of the guide adjusting part determines the first to third positions of the guide plate according to the position of the location bar, thereby creating ice generated from the ice generating part. The position of the reservoir to be moved can be properly adjusted.

In addition, the guide plate may include a plurality of ribs to smoothly move the ice. In addition, by forming a water jetting portion in the lower portion of the guide plate, it is possible to spray the purified water to the ice generating unit more efficiently.

6a to 6b are side views for explaining the movement of the ice supply module of FIG. The basic position of the guide plate of the ice supply module is shown in FIG. 1, which will be described with reference to FIG. 1 again.

1 and 2, the guide plate 120 of the ice supply module 100 is located at a first position which is a basic position. The first position corresponds to a state in which an end of the guide plate 120 is in close contact with an upper end of the partition 310. In the first position, the ice generated and dropped from the ice generator 110 is moved along the guide plate 120 to fall into the ice reservoir 200. The first position is determined by the first position sensor 136a, and the driving unit 134 basically maintains the first position of the guide plate 120.

2 and 6A, the guide plate 120 of the ice supply module 100 is located at a second position. The second position corresponds to a state in which an end portion of the guide plate 120 is rotated at an angle from the first position in an upward direction. When the ice is continuously supplied to the ice reservoir 200, the ice reservoir 200 receives ice only in an area adjacent to the partition 310 so that the ice is unevenly disposed as a whole. Therefore, the discharge of ice to the outside is not smooth and the utilization of the storage space becomes inefficient. In this case, the driving element 134a of the driving unit 134 rotates the guide plate 120 in the fourth direction D4 to adjust the falling point of the ice. In other words, by narrowing the angle formed by the guide plate to the horizontal plane to adjust the ice to fall further outward, the ice is accommodated to the area spaced apart from the partition wall (310). Therefore, ice may be uniformly disposed in the ice reservoir 200 as a whole. The second position is determined by the second position sensor 136b, and the driving unit 134 stops when the guide plate 120 reaches the second position.

2 and 6B, the guide plate 120 of the ice supply module 100 is located at a third position. The third position corresponds to a state in which an end portion of the guide plate 120 is rotated at an angle from the first position in a downward direction. When the cold water temperature of the cold water reservoir 300 is higher than the reference temperature, the temperature sensor 320 determines this and provides it to the guide adjuster 130. In this case, in order to provide ice to the cold water reservoir 300, the driving element 134a of the driving unit 134 rotates the guide plate 120 in the second direction D2 to adjust the falling point of the ice. do. That is, when the guide plate 120 is inclined at a larger angle in the downward direction D2, a space is formed between the partition 310 and the guide plate 120, and ice may flow into the space. . Accordingly, the ice generated from the ice generator 110 may be introduced into the space between the partition 310 and the guide plate 120 to provide ice to the cold water reservoir 300. As a result, the cold water temperature of the cold water reservoir 300 may be lowered to a reference temperature. The third position is determined by the third position sensor 136c, and the driving unit 134 stops when the guide plate 120 reaches the third position.

As described above, the position sensor unit of the guide adjusting unit determines the first to third positions of the guide plate according to the position of the position bar of the driving unit, thereby determining the position of the reservoir where the ice generated from the ice generating unit is to be moved. It can be adjusted appropriately. In addition, by adjusting the position of the guide plate in three steps, it is possible to uniformly distribute the ice stored in the ice reservoir, and to efficiently control the cold water temperature of the cold water reservoir.

In addition, the guide adjusting unit is disposed on the side of the guide plate and includes a drive unit and a position sensor unit, it is possible to efficiently control the movement of the ice in an integrated simple configuration.

The ice supply module and the ice supply device having the same according to the present invention have industrial applicability that can be used for an ice water purifier 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.

10: ice supply device 100: ice supply module
110: ice generator 120: guide plate
130: guide adjusting portion 132: fixed body portion
134: drive unit 135: position bar
136: sensor unit 140: water injection unit
200: ice cellar 300: cold water cellar

Claims (14)

An ice generator for generating ice;
A guide plate formed below the ice generator and configured to guide the ice separated from the ice generator; And
Ice supply module comprising a guide adjusting unit including a drive unit for rotating the guide plate and a position sensor for determining the position of the guide plate. The ice supply module of claim 1, wherein the driving unit comprises a position bar which rotates in association with the rotation of the guide plate. The ice supply module of claim 2, wherein the position sensor unit is formed adjacent to the position bar and determines the position of the guide plate based on the position of the position bar. The ice supply module of claim 3, wherein the driving unit adjusts the rotation of the guide plate according to the position of the guide plate provided through the position sensor unit. The ice supply module of claim 4, wherein the position sensor unit includes a plurality of position sensors formed around the position bar, and each of the position sensors determines a different position of the position bar. The ice supply module of claim 1, wherein the guide plate comprises a plurality of ribs arranged in parallel with each other. 7. The ice supply module according to claim 6, wherein the interval of the ribs is narrower than the width of the ice generated from the ice generator. The ice supply module of claim 1, further comprising a water spraying unit formed under the guide plate to spray water onto the ice generating unit. The ice supply module of claim 8, wherein the water spray unit comprises a spray hole formed through the guide plate. An ice generating unit for generating ice, a guide plate formed under the ice generating unit and guiding the ice separated from the ice generating unit, a driving unit for rotating the guide plate, and a position sensor unit for determining the position of the guide plate. An ice supply module including a guide control unit including;
A cold water reservoir disposed under the ice supply module and having a cold water storage space; And
And an ice reservoir adjacent to the cold water reservoir and having an ice receiving space. The method of claim 10, wherein the drive unit comprises a position bar that rotates in conjunction with the rotation of the guide plate, the position sensor unit adjacent to the position bar, characterized in that determining the position of the guide plate through the position of the position bar. Ice feeder. 12. The apparatus of claim 11, wherein the position sensor unit includes first to third position sensors formed around the position bar, and the first to third position sensors respectively determine first to third positions of the position bar. Ice supply device characterized in that. The method of claim 12,
The first position of the position bar corresponds to a position where the ice guided by the guide plate is transferred to the first region of the ice reservoir,
The second position of the position bar corresponds to a position where the ice guided by the guide plate is transferred to the second region of the ice reservoir,
And a third position of the position bar corresponds to a position where the ice guided by the guide plate is transferred to the cold water reservoir. The method of claim 13,
The location bar includes first and second location bars extending in opposite directions from the center of the drive unit,
The first position sensor is formed at an end of the second position bar, the second position sensor is formed on the first position bar, and the third position sensor is formed on the lower portion of the first position bar. Ice supply apparatus characterized in that the.

Images