KR20110006870A - A refrigerator - Google Patents

Abstract

PURPOSE: A refrigerator is provided to reduce the thickness of an ice storage box and prevent the attachment of ices to each other since the ices are smoothly mixed inside an ice storage box. CONSTITUTION: A refrigerator comprises an ice storage box(100), an auger(200), a separating member(250), and an opening and closing member(300). The ice storage box comprises an ice outlet. The auger is pivotally installed in the ice storage box and rotating vanes(210) for transferring ices. The separating member is installed in the auger in order to separate ice blocks which are created by the attachment of the ices. The opening and closing member is installed to contact the auger and opens and closes the ice outlet according to the rotation of the auger.

Description

Refrigerator {A refrigerator}

The present invention relates to a refrigerator, and more particularly, to a refrigerator capable of smoothly taking out ice, and preventing a phenomenon in which ice is mixed well and adhered to each other in an ice container.

A refrigerator is a device for refrigeration or freezing storage of food and other storage by using a refrigerant cycle. The configuration of the refrigerator for performing such a function includes a main body including a storage compartment and a door for opening and closing the storage compartment.

The refrigerator is equipped with an ice maker for making ice required by the user, and is provided with an ice container for storing the ice de-iced in the ice maker and a dispenser connected with the ice container to take out the ice to the outside of the ice container.

When the user drives the dispenser, an ice extraction device provided in the ice container operates to send ice toward the dispenser, whereby the user receives and uses ice in a container such as a cup.

However, in the case of extracting ice from a conventional refrigerator, a jam phenomenon occurs in which ice is not extracted due to ice being caught between one surface of the ice container and the ice extracting device while the ice is taken out, or the jammed space. There was a problem that the ice is taken out excessively to the next space of the ice.

In addition, when the ice is stored inside the ice container, there is a problem that the ice is attached to the ice is attached to the entire volume is not taken out by the ice extraction device.

In addition, when a plurality of ice is attached to form a large lump in the ice container, there is a problem that it cannot be discharged and hinders the extraction of the ice.

The present invention is to solve the above problems, it is an object of the present invention to provide a refrigerator so that the ice is taken out more smoothly, and does not occur when taking out the ice.

In addition, an object of the present invention is to provide a refrigerator capable of preventing ice from adhering to each other by mixing the ice contained in the ice container well.

In addition, an object of the present invention is to provide a refrigerator in which an ice block made of a plurality of ice can be easily separated inside the ice container.

The present invention for achieving this object, the ice container having an ice outlet; An auger rotatably installed in the ice container, the auger being provided with a rotary wing to move the ice to take out the ice out of the ice container; A separating member provided in the auger so as to separate the ice mass formed by attaching a plurality of ice; It is provided to be in contact with the auger provides a refrigerator comprising an opening and closing member for opening and closing the ice outlet in accordance with the rotation of the auger.

The auger has a central portion that is the center of rotation, the rotary blades are provided in the form of a plurality of spaced apart from each other, is provided in a form extending outward from the outer peripheral surface of the central portion, the separating member is the outer peripheral surface of the rotary blades It is characterized in that it is formed in a form extending outward from the.

The rotary blade is bent in the opposite direction to the rotation direction of the auger so as to receive the ice and push the opening and closing member at the same time, the separating member is a plurality of ice mass in contact with the separating member It is formed to extend in the rotational direction of the auger to be separated into two pieces of ice, characterized in that the height is provided in the form of sequentially increasing toward the extension direction.

The separating member is provided with a plurality, characterized in that disposed on the outer circumferential surface of the mutual rotary blades spaced apart from each other.

The separating member is provided detachably from the auger, wherein the separating member includes a coupling part accommodated in the rotating blade; and a contact part exposed to the outside of the rotating blade to be in contact with the ice.

A through hole provided in the rotary blade to correspond to the position of the coupling portion; and a fixing member inserted into the through hole and the coupling portion to fix the separation member to the rotary blade.

The contact portion extends in the rotation direction of the auger, characterized in that a predetermined groove is provided at the end of the contact portion to increase the contact area with the ice.

It is formed on the rotary blades characterized in that it comprises an insertion slot into which the separating member is inserted.

The separating member and the auger is characterized in that it is formed integrally.

The rotary blade is provided in plurality, the separating member is characterized in that provided on all the rotary blades.

It is characterized in that it further comprises a through groove provided in the opening and closing member and the separation member passes when the auger rotates.

The rotary blade is provided in a concave shape to accommodate the ice and has a predetermined curvature; and is provided convex to contact the opening and closing member; includes an outer surface for opening the opening and closing member by pushing the opening and closing member when rotating the auger, The separating member is characterized in that it is provided to protrude to the outside of the outer surface portion.

Further comprising an inclined portion provided on the outer surface portion to guide the ice sandwiched between the outer surface portion and the opening and closing member to move forward of the auger when the auger rotation to minimize the open state of the opening and closing member. It is characterized by.

In order to form the inclined portion, the thickness of the rotary blade is characterized in that it is provided in a form that decreases sequentially from the rear to the front.

It characterized in that it further comprises a projection protruding outward from the inner surface portion to reduce the contact area between the ice and the inner surface portion.

The outer surface portion may be provided in a curved shape so that ice sandwiched between the outer surface portion and the opening and closing member may move in the radial direction of the auger when the auger rotates.

The opening and closing member is rotated by the rotary blades when the auger rotates in contact with the rotary blades to open the ice outlet, and return to its original position when the contact with the rotary blades is released to close the ice outlet. It is characterized by.

It characterized in that it comprises an elastic member provided in the rotation center of the opening and closing member for the return to the original position of the opening and closing member.

And a cam surface provided on an outer circumferential surface of the support plate provided at the rear of the auger and contacting the opening / closing member to limit the return speed of the opening / closing member when the opening / closing member is returned to its original position.

It is characterized in that it further comprises a contact groove which is provided in the stepped shape in the opening and closing the cap surface is in contact.

The cam surface is protruded in order to gradually increase in the opposite direction of the rotation direction of the auger,

It is characterized in that the degree of protruding gradually increases from the portion corresponding to the position where one of the rotary blades in contact with the opening and closing member from the portion corresponding to the position in which the next rotary blade is in contact with the opening and closing member.

The number of the cam surface is characterized in that corresponding to the number of the rotary blades.

On the other hand, the present invention is an ice container having an ice outlet; An auger installed inclined inside the ice storage box, the auger rotating the movement to extract the ice to the outside of the ice storage box; the auger provided in the auger to mix the ice according to the rotation of the auger or separate an ice mass consisting of a plurality of ices Separation member and; And an opening and closing member provided to be in contact with the auger to open and close the ice outlet according to the rotation of the auger, wherein the auger pushes the opening and closing member to open the opening and closing member, and the ice caught between the auger and the opening and closing member. It characterized in that it comprises a rotary blade for guiding to move in a predetermined direction.

The separating member is provided on the front of the rotary blade is characterized in that it protrudes to the outside.

Further provided with an installation hole provided in the ice container, the auger is installed,

The separating member is exposed to the outside of the installation hole is characterized in that it is provided to contact with the ice.

By the present invention as described above, the ice is taken out more smoothly, and there is an effect that the obstacle does not occur when the ice is taken out.

In addition, the present invention has the effect of preventing the phenomenon that the ice is attached to each other so that the ice contained in the ice container is mixed well.

In addition, there is an advantage that the storage space of the storage compartment can be increased or the thickness of the refrigerator can be reduced by the thickness of the ice storage box, which is made slimmer than the thickness of the ice storage box, compared to the prior art.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 1, the refrigerator according to the present invention includes a main body 1 in which a storage compartment 3 is provided, and a door 10 that is rotatably provided in the main body 1 to open and close the storage compartment 3. It is included.

The storage chamber 3 is divided into a freezing chamber 4 and a refrigerating chamber 5, and the door 10 is also divided into a door 10 for opening and closing the refrigerating chamber 5 and the freezing chamber 4.

An ice maker 13 for ice making ice is mounted on an inner surface of the door for opening and closing the freezing compartment 4, and an ice storage box 100 for storing ice is provided under the ice maker 13.

An ice outlet 102 is provided below the ice container 100, and the ice outlet 102 is in communication with a dispenser (not shown) mounted to the door 10.

The ice outlet 102 is rotatably mounted to an auger 200 capable of selectively moving ice in the direction of the dispenser (not shown), and may be in contact with the auger 200 at one side of the auger 200. The opening member 300 is provided to open and close the ice outlet 102 according to the rotation of the auger 200.

In addition, an outer circumferential surface of the auger 200 is provided with a separating member 250 capable of separating the lump in the frozen state of ice contained in the ice container 100.

As shown in Figure 2, the ice container 100 is preferably in the form of a square barrel, the upper portion is open, a portion of the lower portion is open, the shape is not limited to the rectangular cylinder shape.

Here, the auger 200 is rotatably mounted on the rear of the ice container (100). An interior of the ice container 100 is provided with an inclined surface 105 provided around the auger 200 to allow the ice to move smoothly in the auger 200 direction.

Here, the inclined surface 105 is provided to be inclined downward from the side of the ice container 100 toward the auger 200, and the extension line of the inclined surface 105 faces the central portion 205 of the auger 200. It is preferable to be.

Here, the auger 200 includes a central portion 21 serving as a central axis of the rotation and a rotary blade 210 extending outward from an outer circumferential surface of the central portion 205, wherein the rotary blades 210 are provided in plurality. It is characterized in that it is provided in a form spaced apart from each other.

The rotary wing 210 serves to open and close the opening and closing member 300 by pushing the opening and closing member 300 in contact with the opening and closing member 300, the opening and closing member (so that the contact and the sliding phenomenon occurs smoothly) The outer surface portion 211 of the rotary blade 210 in contact with 300 is formed convex.

In addition, the inner surface portion 212 positioned on the opposite side to the outer surface portion 211 is preferably formed to be concave so that a space for receiving ice is formed.

On the other hand, the outer surface portion 211 of the auger 210 is provided with the separating member 250, the separating member 250 is preferably provided in a plurality spaced apart from the outer surface portion 211 by a predetermined interval. .

Here, the separating member 250 is preferably provided in the form of a hook or a blunt blade form to be easily inserted into the ice and the ice is attached to the form that can be separated.

2 shows that the separating member 250 is installed only on one of the plurality of rotary blades 210, but is not limited thereto, and may be mounted on all rotary blades or a plurality of rotary blades.

In addition, the rotary blade 210 is provided with an insertion slot 225 into which the separation member 250 is inserted and fixed. The number of the insertion slots 255 is the same as or larger than the number of the separation members 250. It is preferable.

This is to change the position of the rotary blade 210 according to the situation.

In the present embodiment, when the auger 200 is rotated in the clockwise direction, the opening and closing member 300 is in contact with the rotary wing 210, and pushed downward, the opening and closing member 300 and the rotary wing When the contact of 210 is released, the opening and closing member 300 returns to its original state.

This is because the elastic member (see Fig. 4, 304) for returning the opening and closing member 300 is provided, which will be described later.

When the opening and closing member 300 is returned, the cam surface 240 in contact with the opening and closing member 300 is provided at the rear of the rotary blade 210 in order to limit the return speed of the opening and closing member 300. On one side of the opening / closing member 300, a contact groove 302 is inserted into and partially contacted with the cam surface 240.

The contact groove 320 is preferably provided in a stepped form.

In addition, the end of the opening and closing member 300, it is preferable that the passage groove 303 is formed so that the separation member 250 can pass.

 This is to prevent the breakage of the opening and closing member 300 by preventing the separating member 250 and the opening and closing member 300 in contact with the opening and closing member 300 and the rotary blade 210 in contact. It is for.

As shown in FIG. 3, the inclined surfaces 105 and 106 are formed on the lower surface of the ice container 100 as described above, and the inclined surfaces 105 and 106 are preferably provided at both sides of the auger 200.

On the other hand, the inclined surface 106 formed on the side provided with the opening and closing member 300 is preferably formed higher than the inclined surface 105 on the other side.

In the case of the inclined surface 105 of the portion side without the opening and closing member 300, the purpose is to guide the ice in the auger 200 direction, for this purpose, the lower end of the inclined surface 105 of the auger 200 It should be slightly higher or substantially the same height as the central portion 205.

However, the inclined surface 106 provided adjacent to the opening / closing member 300 does not guide the ice in the auger 200 direction, but instead faces the ice outlet 102 provided in the lower part of the auger 200. Since the purpose is to guide the difference, the height difference of the upper end portion of the inclined surface 105, 106 is bound to occur.

On the other hand, by having the same inclination angle between the inclined surface 106 provided adjacent to the opening and closing member 300 and the upper surface of the opening and closing member 300 in the open state, the ice smoothly falls in the direction of the ice outlet 102 It is desirable to leave.

The separating member 250 may extend in the radial direction of the auger 250 while extending in the radial direction of the auger 210.

This is to allow the auger 250 to contact as much ice as the separating member 250 while rotating.

When the auger 250 rotates, the position of the ice inside the ice container 100 may be changed, thereby reducing the possibility of ice sticking together.

Furthermore, if the separating member 250 is provided, the effect of mixing the ice is further increased because the distribution range of the ice affected by the rotational movement of the auger 200 will be increased by the movement of the separating member 250. This will further prevent ice from adhering to each other and freezing.

As shown in FIG. 4, the coupling relationship between the ice container 100 and the auger 200 is as follows.

The rear of the ice container 100 is provided with a storage box body 110, the storage box body 110 is formed with a passage hole 115 through which the connecting shaft 230 provided on the rear of the auger 200 passes. do.

The connecting shaft 230 passing through the passage hole 115 is connected to a rotary motor (not shown) for rotating the auger 200.

On the other hand, the rear of the auger 200 is provided with a sealing member 140 and a support member 150 for supporting the mounting state.

The opening and closing member 300 is disposed on one side of the auger 300, one end of which is rotatably fixed to the ice container 100, the other end is in contact with the rotary blade 210 of the auger 200 It is provided to move up and down.

In addition, the through groove 303 is formed at one side of the contact groove 302.

One end of the opening and closing member 300 is provided with an insertion portion 310 inserted into a fixed shaft (not shown) provided in the ice container 100 so that the opening and closing member 300 is rotatably supported. Before and after the part 310, the support piece 311 which supports the coupling is provided, respectively.

On the other hand, the elastic member 304 is provided in the insertion portion 310 of the opening and closing member 300 so that the opening and closing member 300 can move elastically.

 One end of the elastic member 304 is in contact with the opening and closing member 300 in a state in which the elastic member 304 is fitted into the fixing groove 312 provided in the insertion part 310, and the other end of the elastic member 304 contacts the ice container 100. It is preferable that it is comprised with the spring to make.

The front of the ice container 100 is mounted with a first cover member 120 of a transparent material, the auger 200 and the opening and closing member 300 in the front lower portion of the first cover member 120 from the front A second cover member 122 is provided to make it invisible.

As shown in Figure 5, the rotary blade 210 is provided in a form extending outward from the outer peripheral surface of the central portion 205, the shape of the cross section is directed in the direction opposite to the rotation direction of the auger 200 It is preferable that it be formed to bend.

The rotary blade 210 extends in the radial direction from the central portion 205, and is formed integrally with the first extension part 215 and the first extension part that become thicker in the extension direction. The second extension part 216 extends from the first extension part 215 in the opposite direction to the rotation direction of the auger 200 and is made thinner in the extension direction.

Then, as described above, the outer surface portion 211 of the rotary blade 210 is formed to be convex to the outside is provided to be in contact with the opening and closing member 300, the inner surface portion 212 of the rotary blade 210 ) Is formed concave so that ice can be accommodated.

Here, a tapered inclined portion 218 is formed on the surface of the outer surface portion 211, and the surface of the outer surface portion 211 and the opening / closing member 300 are partially contacted by the inclined portion 218. do.

That is, the thickness of the rotary blade 210 is formed to decrease sequentially from the rear to the front, to form the inclined portion 218.

Thus, the distance between the opening and closing member 300 and the outer surface portion 211 is widened toward the front, the distance between the opening and closing member 300 and the outer surface portion 211 at the front of the rotary blade 200 is maximum Becomes

Forming the inclined portion 218 as described above is when the ice is caught between the outer surface portion 211 of the rotary blade 210 and the opening and closing member 300, the stagnation of the rotary blade 210 The ice is moved forward along the inclined portion 212 by the pressing force, and then to be discharged to the lower portion.

The inner surface portion 212 is formed with a plurality of protrusions 219, which reduces the contact area between the ice accommodated in the inner surface portion 212 and the inner surface portion 212, the ice is attached to the inner surface portion 212 This is to prevent it.

On the other hand, when the separating member 250 is coupled to the auger 200 as described above, the auger 200 is made of a resin material, while the separating member 250 is made of stainless steel to prevent breakage. It is preferable to consist of the same metal material.

However, the separation member 250 may be integrally formed with the auger 200 for convenience of manufacturing.

As shown in Figure 6, the outer surface portion 211 is provided in a curved shape projecting in the radial direction, which is the outer surface portion 211 and the opening and closing member 300 and when rotating the rotary blades 210 At the same time, the ice is formed to push the ice radially in the A direction so as to prevent the ice in contact with the interstitial ice.

On the other hand, the cam surface 240 is provided on the outer circumferential surface of the support plate 239 provided at the rear of the rotary blade 210, which is in contact with the opening and closing member 300 when the opening and closing member 300 returns to its original position It serves to limit the speed of the opening and closing member 300.

The cam surface 240 is configured to protrude outward in order to extend in the opposite direction of the rotation direction of the auger 200.

Specifically, the one corresponding to the position where the rotary blade 210 is in contact with the opening and closing member 300, the next rotary blade 210 corresponds to the position that will be in contact with the opening and closing member 300. As you go to the part, the degree of protrusion will be increased sequentially.

To this end, the number of the cam surface 240 preferably corresponds to the number of the rotary blades 210.

That is, one cam surface starts at S1 and ends at P1, where the distance D1 from the center 205 to S1 becomes the shortest distance, and the distance D2 from the center to P1 becomes the longest distance. , The distance increases from S1 to P1.

Next to the P1, a S2 point at which a new cam surface starts is formed, and another cam surface started at a S2 point is formed up to a P2 point. This relationship also applies to S3 and P3.

Accordingly, the distances between S1, S2, and S3 in the central portion 205 are the same, and the distances between P1, P2, and P3 in the central portion are also the same.

Therefore, when a specific rotary wing 210 is in contact with the opening and closing member 300 for the first time, the bottom end of the outer surface portion 211 of the rotary wing 210 is in contact with the opening and closing member 300, At this time, the contact grooves (FIGS. 4 and 5, 302) provided in the opening and closing member 300 is located in the S3 (or S1 or S2).

When the auger 200 rotates in that state, the rotary blade 210 pushes the opening / closing member 300 downward to open the opening / closing member 200. In this case, the outer surface portion ( 211 is a contact movement relative to the opening and closing member 300.

Thereafter, when the contact between the opening and closing member 300 and the rotary blade 210 is released, the opening and closing member 300 is returned to its original state by the elastic member (see Fig. 4, 304).

However, at this time, the contact groove 302 and the cam surface 240 is in contact with each other, the degree of protrusion of the cam surface 240 toward the return direction of the opening and closing member 300 is the return direction of the opening and closing member 300 Since it becomes larger as it goes, the contact area or degree between the cam surface 240 and the contact groove 302 is increased.

As a result, the presence of the cam surface 240 acts as a resistance of the return movement of the opening and closing member 300, and serves to lower the return speed of the opening and closing member 300.

This is to prevent breakage of the opening and closing member 300 and other components connected to the opening and closing member 300 when the opening and closing member 300 is closed at a high speed.

As shown in FIG. 7, the separating member 250 is installed at an outer surface portion 211 of any one of the plurality of rotary blades 210.

In addition, the separating member 250 is extended in the rotational direction of the auger 250 so that the ice mass in contact with the separating member can be separated into a plurality of ice, it is preferable that the height gradually increases in the extending direction Do.

The separating member 250 is inserted into the insertion slot 225 as described above, and the separating member 250 inserted into the insertion slot 225 is inserted into the through hole 295 provided in the rotary blade 210. It is fixed by the fixing member 290 in the form of rod or long bolt.

On the other hand, as shown in Figure 8, it is also conceivable that the separating member 250 is installed on all of the plurality of rotary blades 210.

At this time, the through hole 295 is formed on the front of all the rotary blades 210, the fixing member 290 is also inserted into the through holes 295 formed in all the rotary blades 210.

However, if the rotary blade 210 is formed integrally with the separation member 250, the through hole 295 and the fixing member 210 will be unnecessary.

9 to 11 illustrate various forms of the separating member 250.

As shown in FIG. 9, a lower portion of the separation member 250 corresponds to a position of the through hole 295 illustrated in FIG. 8, and a coupling part 253 having a hole shape through which the fixing member 290 passes. ) Is provided.

And the upper portion of the separating member 250 is provided with a contact portion 252 is extended to one side in the shape of a hook or sickle and in contact with the ice.

In FIG. 10, a part of the separating member 250 of FIG. 9 is deformed and a separating member 250a is disclosed. Here, the difference in construction is to increase the contact area with ice at the end of the contact portion 252a and to increase the separating effect. To this end, there are a plurality of protrusions 255 and grooves 254 between the protrusions 255, and the hole-shaped coupling portion 253a is the same as the configuration shown in FIG.

11 discloses another type of separating member 250a. Here, the separating member 250a has a trapezoidal shape, unlike the separating member 250 illustrated in FIG. 9.

The reason for taking the trapezoidal shape in this way is to make the shape of the portion C exerting force on the ice have a straight shape so that the entire portion C can be exerted on the ice.

Hereinafter, an operation of the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 12, when the rotor blade 210 and the opening / closing member 300 of the auger 200 remain in contact with the ice container 100 inside the ice container, the ice outlet Communication between the 102 and the ice container 100 is blocked.

At this time, since the upper surface of the opening and closing member 300 is inclined upward, the ice cannot move in the direction of the ice outlet 102.

However, when the user presses a lever (not shown) in the dispenser (not shown), as shown in FIG. 13, the auger 200 rotates.

And, when the rotary blade 210 in contact with the opening and closing member 300 by pressing the opening and closing member 300, the upper surface of the opening and closing member 300 to form a downward slope, the ice is the opening and closing member 300 It moves down along the upper surface of the) to fall to the ice outlet 102 to the dispenser (not shown).

At this time, the separating member 250 provided in the rotary blade 210 also rotates in the direction of the auger 200 and comes into contact with ice, and moves along the ice.

By doing so, it not only acts as a split between ice and ice, but also cuts off the bonds of the ice that are attached to each other to prevent the ice mass from forming and growing.

On the other hand, when the auger 200 is further rotated so that the contact between the rotary blade 210 and the opening and closing member 300 is released, the opening and closing member 300 is returned to its original state by the elastic force, and again another rotary blade ( In contact with 210 to close the ice outlet 102.

14 and 15 show another embodiment of the present invention, which discloses that the auger 200 is inclined in this embodiment.

Herein, the ice maker 13 and the ice container 1100 are included at the rear of the door 10, and a dispenser 300 capable of taking out ice is provided under the ice container 1100.

In addition, the auger 200 for bending the rotary blades 210 may be disposed upward by a predetermined angle toward the rear of the door 10.

Here, an installation hole 1120 in which the auger 200 is installed is formed on the bottom surface 1110 formed to be inclined of the ice container 1100, and the auger 200 is rotatable inside the installation hole 1120. It is installed so as to, the rear of the auger 200 is provided with a drive device 280.

Meanwhile, the separation member 1250 is also provided in the auger 200. The separation member 1250 shown in the second embodiment is different from the separation member 250 shown in FIGS. 1 to 13. It is provided in the front portion, not the outer peripheral surface of the 250).

This is to allow the separating member 1250 to protrude more than the position of the installation hole 1120 to stir the ice accommodated around the installation hole 1120.

Here, the separating member 1250 may be provided only on a part of the rotary blade 210 of the auger or may be provided in its entirety.

 Here again when the auger 200 is rotated, the contact with the opening and closing member 300, the rotary wing 210 by pressing the opening and closing member 300 to move it downwards ice dispenser (30) Will fall in the direction.

In addition, as the auger 200 rotates, the separating member 1250 may also rotate to separate ice or agglomerated ice.

Specific configuration of the auger 200 and the opening and closing member 300 is the same as the configuration described in the first embodiment, so a detailed description thereof will be omitted.

Figure 16 shows a third embodiment of the present invention, where the auger 200 is also installed on the ice container 2100 inclined. In addition, here, the installation hole 2120 in which the auger 200 is installed is provided, and a driving device 280 is provided at the rear of the auger 200.

However, the inclined direction is to maintain the state raised up by a predetermined angle in the direction toward the side of the door (10).

In addition, the separating member 2250 is installed on the front of the rotary blade 210 of the auger 200 is protruded.

In addition, the separation member 2250 also maintains a state that is raised upward by a predetermined angle from the side to the upper side, and protrudes outward from the installation hole 2120.

Thus, in contact with the ice around the installation hole 2120, it is possible to mix the ice or to separate the ice chunks according to the rotation of the auger 200.

In the case of the second embodiment or the third embodiment, the position of the auger 200 may be changed according to the position of various devices mounted on the rear surface of the door 10.

Therefore, since the construction of the auger 200 and the opening and closing member 300 of the third embodiment is the same as that of the first embodiment, a detailed description thereof will be omitted.

1 is a perspective view of a refrigerator according to the present invention.

2 is a perspective view of an auger equipped with an ice container and a separating member according to the present invention.

3 is a front view of an auger equipped with an ice container and a separating member according to the present invention.

Figure 4 is an exploded perspective view of an auger equipped with an ice container and a separating member according to the present invention.

5 is a perspective view of the auger and the opening and closing member mounted with a separating member according to the present invention.

6 is a front view of the auger and the opening and closing member mounted with the separating member according to the present invention.

7 and 8 are perspective views showing various mounting examples of the separating member.

9 to 11 are front views illustrating various shapes of the separating member.

12 is a perspective view showing a closed state of the opening and closing member in the present invention.

Figure 13 is a perspective view showing an open state of the opening and closing member in the present invention.

Fig. 14 is a side sectional view showing a second embodiment of the present invention.

15 is a perspective view of an ice container in a second embodiment of the present invention.

Figure 16 is a front view of the third embodiment of the present invention.

<Description of main parts of drawing>

100: Ice Locker 200: Auger

210: rotary blade 240: cam surface

250: separating member 300: opening and closing member

Claims (25)

An ice container having an ice outlet; An auger rotatably installed in the ice container, the auger being provided with a rotary wing to move the ice to take out the ice out of the ice container; A separating member provided in the auger so as to separate the ice mass formed by attaching a plurality of ice; And an opening and closing member provided to be in contact with the auger to open and close the ice outlet according to the rotation of the auger. The method of claim 1, The auger has a central portion that is the center of rotation, The rotary blades are provided in the form of a plurality of spaced apart from each other, is provided in a form extending outward from the outer peripheral surface of the central portion, The separating member is characterized in that the refrigerator is formed in a form extending outward from the outer peripheral surface of the rotary blade. The method of claim 2, The rotary blade is formed to be bent in the opposite direction of the rotation direction of the auger so as to receive the ice at the same time to push the opening and closing member, The separating member extends in the rotational direction of the auger so that the ice mass in contact with the separating member can be separated into a plurality of ice, the refrigerator is characterized in that the height is provided in the form of sequentially increasing in the extending direction . The method according to any one of claims 1 to 3, The separating member is provided with a plurality, Refrigerator, characterized in that spaced apart from each other on the outer peripheral surface of the rotary blades. The method of claim 2, The separating member is provided to be separated from the auger, The separating member and the coupling portion accommodated in the rotary blade; And a contact part exposed to the outside of the rotary blade to come into contact with the ice. The method of claim 5, A through hole provided in the rotary blade so as to correspond to the position of the coupling part; And a fixing member inserted into the through hole and the coupling part to fix the separating member to the rotary blade. The method of claim 5, The contact portion extends in the rotation direction of the auger, A refrigerator, characterized in that a predetermined groove is provided at the end of the contact portion to increase the contact area with the ice. The method of claim 5, Refrigerator, characterized in that formed on the rotary blade including an insertion slot into which the separating member is inserted. The method of claim 2, And the separating member and the auger are integrally formed. The method of claim 2, The rotary wing is provided in plurality, The separator is characterized in that the refrigerator is provided on all the rotary blades. The method according to claim 1 or 2, Refrigerator, characterized in that provided in the opening and closing member further comprises a through groove through which the separating member passes when the auger rotates. The method of claim 3, The rotary blade is provided in a concave shape to accommodate the ice and has an inner surface portion having a predetermined curvature; It is provided with a convex to contact the opening and closing member includes an outer surface for opening the opening and closing member by pushing the opening and closing member when rotating the auger, The separation member is a refrigerator, characterized in that provided to protrude to the outside of the outer surface portion. The method of claim 12, Further comprising an inclined portion provided on the outer surface portion to guide the ice sandwiched between the outer surface portion and the opening and closing member to move forward of the auger when the auger rotation to minimize the open state of the opening and closing member. Refrigerator, characterized in that. The method of claim 13, Refrigerator, characterized in that the inclined portion is formed in the thickness of the rotary blade is sequentially reduced from the rear to the front. The method of claim 12, And a protrusion protruding outward from the inner surface portion to reduce the contact area between the ice and the inner surface portion. The method of claim 12, And an outer surface portion is provided in a curved shape so that ice sandwiched between the outer surface portion and the opening / closing member can move in the radial direction of the auger when the auger rotates. The method of claim 1, The opening and closing member is rotated by the rotary blades when the auger rotates in contact with the rotary blades to open the ice outlet, and return to its original position when the contact with the rotary blades is released to close the ice outlet. Refrigerator characterized in that. The method of claim 17, And an elastic member provided at a rotation center of the opening and closing member to return the opening member to its original position. The method of claim 17, And a cam surface provided on an outer circumferential surface of the support plate provided at the rear of the auger and contacting the opening / closing member to limit the return speed of the opening / closing member upon returning to the opening / closing member. The method of claim 19, And a contact groove provided in the opening and closing member in a stepped shape to contact the cap surface. The method of claim 19, The cam surface is protruded in order to gradually increase in the opposite direction of the rotation direction of the auger, The refrigerator, characterized in that the degree of protruding sequentially increases from the portion corresponding to the position where one of the rotary blades in contact with the opening and closing member from the portion corresponding to the position where the next rotary blade is in contact with the opening and closing member. The method of claim 19, And the number of the cam surfaces corresponds to the number of the rotary blades. An ice container having an ice outlet; An auger installed inclined inside the ice container, and rotating the movement to take the ice out of the ice container; A separating member provided in the auger to mix the ice according to the rotation of the auger or to separate an ice mass composed of a plurality of ices; It is provided to be in contact with the auger, including an opening and closing member for opening and closing the ice outlet in accordance with the rotation of the auger, The auger is provided with a rotary blade for sliding the opening and closing member by pushing the opening and closing member to guide the movement of the ice caught between the auger and the opening and closing member in a predetermined direction. 24. The method of claim 23, The separating member is provided on the front of the rotary blades, characterized in that protrudes to the outside. The method of claim 24, Further provided with an installation hole provided in the ice container, the auger is installed, The separating member is exposed to the outside of the installation hole refrigerator, characterized in that provided in contact with the ice.

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